CN221180144U - Drinking device - Google Patents

Abstract

The utility model discloses drinking equipment, which comprises a machine body and a container detachably connected with the machine body; the machine body comprises a switch mechanism; the switch mechanism comprises a supporting piece, a switch and a pressing piece, and the switch comprises a triggering part; the pressing piece comprises a mounting part and is elastically arranged on the supporting piece through the mounting part, the pressing piece comprises an extrusion end face, the extrusion end face and the mounting part are arranged at intervals, the extrusion end face is opposite to the triggering part, and the extrusion end face comprises a second plane; when the container applies a force to the pressing piece, the pressing piece can move towards the first direction under the pushing action of the container, meanwhile, the second plane approaches to the trigger component, and when the container is mounted on the machine body, the second plane presses the trigger component in the second direction to enable the switch to be conducted. The utility model can improve the combination tightness between the container and the switch and avoid the condition of shutdown caused by the working vibration of drinking equipment.

Description

Drinking device

Technical Field

The utility model relates to the technical field of water purification, in particular to drinking equipment.

Background

Along with the heat of domestic reverse osmosis water purifier in market is higher and higher, the outward appearance, the function of purifier are also in constantly iterating the upgrading, in order to adapt to market demand, the container is by built-in undetachable upgrading to external removable, and the benefit lies in that the user can take away the container, can use water everywhere at any time, the multiple demands such as convenient cooking, washing dish.

When the external container is arranged on the drinking equipment, the switch can be triggered to make the drinking equipment work to produce water. Because the stroke of the switch is about 0.5mm, if the booster pump works to cause vibration in the water making process, the container retreats under the vibration effect and can be disconnected from the switch, and the processor determines that the container is disassembled according to the detected signal of the switch and controls the drinking equipment to stop working. Therefore, it is necessary to design the combination and disconnection structure of the container and the switch, so as to avoid the shutdown caused by the working vibration of the drinking equipment.

Disclosure of utility model

Aiming at the defects existing in the prior art, the utility model aims to provide drinking equipment, which can improve the combination compactness between a container and a switch and avoid the condition of shutdown caused by the working vibration of the drinking equipment.

The present disclosure provides a drinking device comprising a body and a container detachably connected to the body; the machine body comprises a switch mechanism;

The switching mechanism includes:

A support;

A switch including a trigger member;

The pressing piece comprises a mounting part and is elastically arranged on the supporting piece through the mounting part, the pressing piece comprises an extrusion end face, the extrusion end face and the mounting part are arranged at intervals, the extrusion end face and the triggering part are arranged oppositely, and the extrusion end face comprises a second plane;

When the container applies a force to the pressing piece, the pressing piece can move towards a first direction under the pushing action of the container, meanwhile, the second plane approaches to the trigger component, and when the container is mounted on the machine body, the second plane presses the trigger component in the second direction to enable the switch to be conducted.

Optionally, the length of the second plane in the first direction is greater than a first length, the first length being a maximum length that allows the container to move in a direction opposite to the first direction.

Optionally, the second direction is perpendicular to the first direction, and in the second direction, the pressing end surface is located between the mounting portion and the trigger member.

Optionally, a second elastic member is provided on the support member, and one end of the second elastic member is connected to the support member in the elastic movement direction of the second elastic member, and the other end of the second elastic member is connected to the mounting portion, so that the pressing member is elastically provided on the support member;

Upon application of a force by the container to the follower, the follower moves in a first direction to compress the second resilient member; when the container is disassembled, the second elastic piece resets and drives the pressing piece to be far away from the supporting piece.

Optionally, the pressing end surface further includes a first plane and a guide surface located between the first plane and the second plane, the first plane, the guide surface, and the second plane sequentially contact the trigger member during movement of the pressing element in the first direction, and distances between the first plane, the guide surface, and the second plane and the trigger member are sequentially decreased.

Optionally, the triggering component includes a triggering button and a spring piece, the triggering button extends out of a switch shell of the switch, the spring piece has a fixed part and a movable part, the fixed part is connected with the switch shell, and the movable part is contacted with the triggering button;

When the container is separated from the machine body, the first plane is in contact with the movable part of the elastic sheet, and when the container is mounted on the machine body, the second plane presses the movable part, and the movable part applies force to the trigger button to conduct the switch.

Optionally, the triggering component includes a triggering button, and the triggering button extends out of a switch shell of the switch;

When the container is separated from the machine body, the first plane is in contact with the trigger button, and when the container is mounted on the machine body, the second plane applies force to the trigger button to conduct the switch.

Optionally, the moving direction of the trigger button is perpendicular to the moving direction of the pressing piece.

Optionally, the machine body comprises a base, a casing, a raw water tank, a filter assembly, a booster pump and a water outlet waterway, wherein the raw water tank and the casing are arranged on the base, the filter assembly, the booster pump and the water outlet waterway are arranged in the casing, and the raw water tank, the booster pump, the filter assembly and the water outlet waterway are sequentially connected;

The water outlet waterway comprises a communicating vessel, a water delivery pump, a heater and a water purification water intake, wherein a water inlet of the communicating vessel is communicated with the filtering assembly, and a second water outlet of the communicating vessel, the water delivery pump, the heater and the water purification water intake are sequentially communicated.

Optionally, the pressing piece includes a pressing rod, the pressing rod protrudes out of the casing of the machine body, and a long axis of the pressing rod is parallel to a deformation direction of the second elastic piece; the switch triggering part comprises a limiting part and an abutting part arranged in the limiting part; when the container is mounted on the machine body, the compression bar passes through the limiting part and abuts against the abutting part.

Optionally, the switch mechanism is disposed below the communicating vessel and near the bottom of the machine body, and the switch triggering portion is disposed at the bottom of the container.

Optionally, the communicating vessel comprises a first containing cavity, a second containing cavity, a water level sensor and a water quantity adjusting mechanism, wherein the first containing cavity is provided with a water inlet, a first water outlet and a second water outlet, the second containing cavity is communicated with the first containing cavity through a diversion hole, and the water level sensor is arranged in the second containing cavity and is used for detecting the water level in the second containing cavity;

When the container is arranged on the machine body, the water purifying inlet is communicated with the first water outlet, and when water is injected through the water inlet or taken from the second water outlet, the water quantity adjusting mechanism adjusts the water passing area of at least one guide hole, so that the water level in the second containing cavity is at least basically level with the water level in the container when water is injected, the second containing cavity is quickly filled with water in the container, and the water level in the second containing cavity is at least basically level with the water level in the container when water is taken.

Optionally, a switch triggering part is arranged on the container, when the container is mounted on the machine body, the first water outlet is communicated with the purified water inlet, and the switch triggering part applies force to the pressing piece to enable the switch to be communicated.

Optionally, the volume of the second containing cavity is smaller than the volume of the container, and under the adjusting action of the water quantity adjusting mechanism, the water passing area of the diversion hole when water is injected into the water inlet is larger than the water passing area of the diversion hole when water is taken out from the second water outlet.

Optionally, the first cavity, the second cavity and the container are all communicated with the atmosphere.

Optionally, the communicating vessel includes communicating vessel shell and baffle, the baffle will the inner space of communicating vessel shell divide into first appearance chamber with the second holds the chamber, the water conservancy diversion hole is located the lower part of baffle, be equipped with the exhaust hole on the baffle, the exhaust hole intercommunication first appearance chamber with the second holds the chamber.

Optionally, the water quantity adjusting mechanism is arranged in the second containing cavity;

The water quantity adjusting mechanism comprises a stop piece, a balancing weight and a first rotating shaft, wherein the first rotating shaft is fixed on the inner wall of the second containing cavity, the stop piece is connected with the first rotating shaft in a rotating mode, the balancing weight is arranged on the stop piece to drive the stop piece to partially shield the diversion hole, liquid injected into the second containing cavity from the diversion hole can drive the stop piece to overcome the acting force of the balancing weight to rotate in the direction away from the diversion hole so as to change the water passing area of the diversion hole.

Optionally, the backstop piece include the backstop board and with the first spacing box that the backstop board is connected, the backstop board with the junction of first spacing box is equipped with the shaft hole, first pivot passes the shaft hole, the balancing weight is established in the first spacing box.

Optionally, the balancing weight and the stop plate are located at two sides of the first rotating shaft, and the gravity center of the water quantity adjusting mechanism is located on the balancing weight.

Optionally, the stop plate has a first face facing the separator, the first stop box has a second face facing the separator, the second face is far away from the separator when the first face is attached to the separator, and the first face is far away from the separator when the second face is attached to the separator.

Optionally, the stop plate is provided with a water passing hole, and when the stop plate shields the diversion hole, the water passing hole is partially overlapped with the diversion hole.

Optionally, the communicator includes a communicator housing;

The flow guide hole is provided with a first water passing part and a second water passing part, and the cross section area of the second water passing part is larger than that of the first water passing part;

When water is injected through the water inlet, the second water passing part is communicated with the first containing cavity and the second containing cavity, and the first water passing part is not communicated with the first containing cavity and the second containing cavity; when water is taken from the second water outlet, the second water passing part is not communicated with the first containing cavity and the second containing cavity, and the first water passing part is communicated with the first containing cavity and the second containing cavity.

Optionally, the water quantity adjusting mechanism comprises an electromagnet and a first magnetic attraction body, the first magnetic attraction body is arranged in the communicating vessel shell through a first elastic piece, the electromagnet is arranged outside the communicating vessel shell,

When water is taken through the second water outlet, the electromagnet is electrified, and the first magnetic attraction body moves towards the electromagnet to shield the second water passing part of the diversion hole; when water is injected into the water inlet, the electromagnet is powered off, and the first magnetic attraction body is driven by the first elastic piece to reset and shield the first water passing part of the diversion hole.

Optionally, the electromagnet is disposed below the first accommodating cavity, the first magnetic attraction body is disposed in the first accommodating cavity, one end of the first elastic element is connected to the bottom of the first accommodating cavity, and the other end of the first elastic element is connected to the first magnetic attraction body; or alternatively

The electromagnet is arranged below the second containing cavity, the first magnetic attraction body is arranged in the second containing cavity, one end of the first elastic piece is connected with the bottom of the second containing cavity, and the other end of the first elastic piece is connected with the first magnetic attraction body.

Optionally, the number of the diversion holes is multiple, and at least part of the diversion holes are correspondingly provided with the water quantity adjusting mechanism; the total water passing area of all diversion holes when water is injected from the first containing cavity to the second containing cavity is larger than the total water passing area of all diversion holes when water is discharged from the second containing cavity to the first containing cavity.

Optionally, the water quantity adjusting mechanism is a unidirectional film arranged in the second containing cavity and used for shielding the diversion hole, when water is injected from the first containing cavity to the second containing cavity, the unidirectional film moves in a direction away from the diversion hole so as to expose the diversion hole, and when water is discharged from the second containing cavity to the first containing cavity, the unidirectional film moves in a direction close to the diversion hole so as to shield the diversion hole.

Optionally, the water level sensor comprises a guide rod, a floating structure sleeved on the guide rod, and a first detection element and a second detection element which are arranged in the guide rod, wherein the guide rod is vertically arranged in the second containing cavity, the first detection element is positioned at the lower part of the guide rod, the second detection element is positioned at the upper part of the guide rod, and the floating structure can move along the long axis of the guide rod under the action of liquid buoyancy;

when the water level of the liquid in the second containing cavity is lowered to the first position of the guide rod, the floating structure moves to the lower part of the guide rod and triggers the first detection element, and when the water level of the liquid in the second containing cavity is raised to the second position of the guide rod, the floating structure moves to the upper part of the guide rod and triggers the second detection element.

Optionally, the machine body further comprises a controller, the controller is respectively and electrically connected with the first detection element, the second detection element, the booster pump and the water delivery pump, when the first detection element is triggered, the controller controls the water delivery pump to stop working, and when the second detection element is triggered, the controller controls the booster pump to stop working.

Optionally, the first detecting element and the second detecting element are magnetic reed switches, and a magnetic block is arranged in the floating structure.

Optionally, the floating structure comprises a first float and a second float, a first water level section is arranged at the lower part of the guide rod, a second water level section is arranged at the upper part of the guide rod, the first float is sleeved on the guide rod and can be driven to move in the first water level section by liquid buoyancy, the second float is sleeved on the guide rod and can be driven to move in the second water level section by liquid buoyancy, the first detection element is arranged in the first water level section, the second detection element is arranged in the second water level section,

When the water level of the liquid in the second containing cavity is reduced to the first position of the guide rod, the first floater moves to the lower end of the first water level section and triggers the first detection element, and when the water level of the liquid in the second containing cavity is increased to the second position of the guide rod, the second floater moves to the upper end of the second water level section and triggers the second detection element.

Optionally, the guide rod is provided with a first limiting part, a second limiting part, a third limiting part and a fourth limiting part in sequence, the part of the guide rod between the first limiting part and the second limiting part is the first water level section, and the part of the guide rod between the third limiting part and the fourth limiting part is the second water level section.

Optionally, the floating structure includes a third float, when the water level of the liquid in the second cavity drops to the first position of the guide rod, the third float moves to the lower end of the guide rod and triggers the first detection element, and when the water level of the liquid in the second cavity rises to the second position of the guide rod, the third float moves to the upper end of the guide rod and triggers the second detection element.

Optionally, the height of the second cavity is the same as the height of the inner space of the container.

Optionally, the first water outlet, the diversion hole and the second water outlet are arranged at the lower part of the communicating vessel, and the water inlet is arranged at the upper part of the communicating vessel.

Optionally, the second water outlet is arranged on the bottom surface of the communicating vessel shell, a partition board is arranged in the communicating vessel shell, the diversion hole is arranged at the lower part of the partition board, the first water outlet is arranged on the side surface of the communicating vessel shell adjacent to the partition board, and the second water outlet is closer to the diversion hole than the first water outlet;

the water inlet is lower than the highest water level of the communicating vessel.

Optionally, the exhaust hole is arranged at the upper part of the communicating vessel.

Optionally, the machine body comprises a locking mechanism and a water outlet valve assembly arranged at the first water outlet, and the container comprises a receiving mechanism and a water inlet valve assembly arranged at the purified water inlet;

When the container is mounted on the machine body, the water inlet valve assembly is abutted against the water outlet valve assembly, the first water outlet is communicated with the purified water inlet, and the locking mechanism is in clamping fit with the bearing mechanism; when the container is separated from the machine body, the locking mechanism is separated from the bearing mechanism, the water outlet valve assembly seals the first water outlet, and the water inlet valve assembly seals the purified water inlet.

Optionally, the communicating vessel comprises a communicating vessel shell, a first water guide pipe is arranged on the communicating vessel shell around the first water outlet, and the water outlet valve assembly is arranged in the first water guide pipe.

Optionally, the water outlet valve assembly includes first valve core seat, first spring and first case, first valve core seat is established in the first aqueduct, first valve core includes first end cap, first valve rod and first limiting plate, first valve rod's one end is connected first end cap, the other end pass behind the through-hole of first valve core seat with first limiting plate links to each other, first spring butt is in first valve core seat with between the first valve rod, first valve core can be under external force drive effect to first delivery port is close to so that first end cap breaks away from first valve core seat, first spring can drive first valve core resets and makes first end cap shutoff the through-hole of first valve core seat.

Optionally, a second water guide pipe is arranged on the container around the purified water inlet, and the water inlet valve assembly is arranged in the second water guide pipe.

Optionally, the water inlet valve assembly includes a second valve core seat, a second spring and a second valve core, the second valve core seat is arranged in the second water guide pipe and is connected with the second water guide pipe in an expanding way, the second valve core seat includes a first seat ring, a second seat ring and a plurality of connecting ribs for connecting the first seat ring and the second seat ring, the second valve core includes a second plug and a second valve rod, one end of the second valve rod is connected with the second plug, the other end of the second valve rod penetrates through a through hole of the second seat ring, and the second spring is abutted between the second seat ring and the second plug; the second valve core can be close to the inside of the container under the action of external force driving so that the second plug is separated from the first seat ring, and the second spring can drive the second valve core to reset so that the second plug plugs the through hole of the first seat ring.

Optionally, the locking mechanism includes a fixing piece and a buckle, the fixing piece is sleeved on the outer wall of the first water guide pipe, and the buckle is connected with the fixing piece; the container is provided with a baffle plate which is arranged around the second water guide pipe, a ring groove is formed between the baffle plate and the second water guide pipe, and the bearing mechanism comprises a clamping groove which is arranged on the baffle plate; when the container is mounted on the machine body, the water inlet valve assembly abuts against the water outlet valve assembly, the first water guide pipe and the fixing piece enter the annular groove, and the buckle is clamped into the clamping groove.

Optionally, the buckle has stiff end and expansion end, the stiff end with the mounting links to each other, the expansion end outstanding in the outer wall of mounting, the buckle with have the clearance between the outer wall of first aqueduct, and the clearance is not less than the expansion end surpasses the height of mounting outer wall.

Optionally, the locking mechanism further comprises a valve core sleeve sleeved on the first water conduit, the valve core sleeve comprises an outer sleeve, an inner sleeve arranged in the outer sleeve and a transition part connecting the outer sleeve and the inner sleeve, the inner sleeve is positioned between the water outlet valve assembly and the inner wall of the first water conduit, the outer sleeve is positioned between the outer wall of the first water conduit and the inner wall of the fixing piece, the movable end of the buckle is opposite to the outer sleeve, and the transition part is positioned between the end face of the first water conduit and the end face of the fixing piece;

When the container is mounted on the machine body, the second water guide pipe enters the first water guide pipe and is sealed with the second water guide pipe through the inner sleeve; when the container is separated from the machine body, the outer ring sleeve drives the movable end of the buckle to reset.

Optionally, a first convex ring and a second convex ring are arranged on the inner wall of the inner ring sleeve, a first groove corresponding to the first convex ring and a second groove corresponding to the second convex ring are arranged on the outer wall of the inner ring sleeve, the first convex ring and the first groove are close to the transition part, and the second convex ring and the second groove are close to the first plug; the height of the first convex ring protruding from the inner wall of the inner race is larger than that of the second convex ring protruding from the inner wall of the inner race, and the area of the first groove is larger than that of the second groove.

Optionally, the buckle is close to the bottom of the machine body, and the clamping groove is close to the bottom of the container.

Optionally, the device further comprises a casing, a front cover assembly and a water collecting box, wherein the front cover assembly is arranged at the upper part of the casing, the water collecting box is detachably connected with the lower part of the casing, and a space for placing the container is formed between the water collecting box and the front cover assembly;

The front cover assembly is provided with a water outlet nozzle, the water outlet nozzle is communicated with the water purifying and intake nozzle, the water collecting box is located below the first water guide pipe and the water outlet nozzle, and the water collecting box is provided with a first water filtering hole corresponding to the first water guide pipe and a second water filtering hole corresponding to the water outlet nozzle.

Optionally, the machine body comprises a sterilizing lamp and a driving mechanism, and the container is provided with a via hole and a via hole adjusting mechanism; when the container is separated from the machine body, the via hole adjusting mechanism is positioned at a first position and seals the via hole; when the container is mounted on the machine body, the through hole is opposite to the sterilizing lamp, the driving mechanism drives the through hole adjusting mechanism to be in a second position and expose the through hole, and light rays of the sterilizing lamp can be injected into the container through the through hole.

Optionally, the driving mechanism is configured to drive the via adjusting mechanism to rotate from the first position until the container is mounted to the body, and the via adjusting mechanism is in the second position during the process of mounting the container to the body.

Optionally, in the process of detaching the container from the machine body, the acting force of the driving mechanism on the via hole adjusting mechanism is gradually reduced, the via hole adjusting mechanism starts to rotate from the second position until the container is separated from the machine body, and the via hole adjusting mechanism is located at the first position.

Optionally, the via hole adjusting mechanism includes a shade and a second magnetic body, the shade is rotatably connected with the top of the container, and the second magnetic body is arranged on the shade and drives the shade to close the via hole.

Optionally, the driving mechanism is disposed at a side of the germicidal lamp close to the communicating vessel.

Optionally, the driving mechanism is a magnet, and is configured to attract the second magnetic body when the container is mounted on the machine body, so that the mask member rotates in a direction away from the via hole.

Optionally, the via hole adjusting mechanism further comprises a second rotating shaft;

the shade piece is fixed on the second rotating shaft, the second rotating shaft is rotationally connected with the top of the container, or the second rotating shaft is fixed on the top of the container, and the shade piece is rotationally connected with the second rotating shaft.

Optionally, the container includes that container casing and lid are established container lid at container casing top, container casing's upper portion is equipped with the container water outlet, be equipped with on the container lid the via hole adjustment mechanism and support, the support is located the container water outlet with between the via hole and to the inside protrusion of container, the second pivot is located on the support.

Optionally, the shade piece is made of a non-magnetic material and comprises a cover plate and a second limit box connected with the cover plate, and the second magnetic attraction body is arranged in the second limit box; when the container is separated from the machine body, the cover plate seals the through hole, and when the container is mounted on the machine body, the cover plate rotates to a direction close to the water outlet nozzle of the container and is separated from the through hole.

Optionally, the distance between the second pivot with the container lid is greater than the circumscribed circle of the cross section of second spacing box, still be equipped with limit structure on the container, the container is installed when on the organism, the second spacing box get into the second pivot with the space between the container lid and with limit structure butt.

Optionally, the limiting structure is a limiting surface arranged on the bracket or a limiting piece arranged on the container cover.

Optionally, in a state that the cover plate seals the through hole, a center of gravity of the second magnetic attraction body is between a center line of the second rotating shaft and the container water outlet nozzle.

Optionally, the container cover is provided with a circle of protrusions protruding towards the inside of the container around the through holes, the cover plate comprises a plug body and a cover edge surrounding the plug body, when the container is mounted on the machine body, the plug body enters the through holes, and the cover edge clings to the protrusions and seals gaps between the plug body and the through holes.

Optionally, the rotation angle of the shroud is 60 ° to 150 °.

Optionally, the mass of the cover plate is smaller than the sum of the mass of the second magnetic attraction body and the mass of the second limit box.

Optionally, when the via hole adjusting mechanism is at the second position, the driving mechanism is located between the second magnetic attraction body and the germicidal lamp.

Optionally, in the moving direction of the container, the front projection of the driving mechanism is between the front projection of the second magnetic attraction body and the front projection of the sterilizing lamp.

By implementing the scheme, the method has the following beneficial effects:

This disclosure carries out institutional advancement to the switch mechanism on the organism, establishes casting die and switch side by side on support piece, the casting die passes through the second elastic component and links to each other with support piece, the extrusion terminal surface of casting die is relative with the triggering part of switch, when the second elastic component is compressed, when the container is installed on the organism, the casting die is close to support piece, extrusion terminal surface extrusion triggering part makes the switch on, when container and organism separation, the second elastic component drives the casting die and resets, the extrusion terminal surface releases the application of force to triggering part thereby closes the switch. The pressing piece and the switch are subjected to position limitation through the supporting piece, the force applied by the container on the pressing piece is converted into the pressing force of the pressing end of the pressing piece to the switch on the side, the stability of the pressing piece in abutting against the switch triggering part is improved, and the switch triggering part still keeps in an abutting state with the pressing piece even if the container slightly backs up due to working vibration of drinking equipment.

Drawings

FIG. 1 is a schematic structural view of a drinking apparatus of the present disclosure;

FIG. 2 is a schematic structural view of the drinking apparatus of the present disclosure;

FIG. 3 is a cross-sectional view of the drinking device of the present disclosure;

FIG. 4 is a schematic view of the structure of the body of the present disclosure;

FIG. 5 is a schematic view of the waterway structure of the body of the present disclosure;

FIG. 6 is a schematic view of the waterway structure of the body of the present disclosure;

FIG. 7 is a schematic view of the construction of the communicating vessel of the present disclosure;

FIG. 8 is a cross-sectional view of a communication vessel of the present disclosure;

FIG. 9 is a schematic view of a partial structure of the communicating vessel of the present disclosure;

Fig. 10 is a schematic structural view of the water amount adjusting mechanism of the present disclosure;

FIG. 11 is a schematic view of the structure of the water quantity adjusting mechanism of the present disclosure;

fig. 12 is a schematic structural view of a water amount adjusting mechanism of the present disclosure

FIG. 13 is a cross-sectional view of a communication vessel of the present disclosure;

FIG. 14 is an enlarged view of a portion of FIG. 13;

FIG. 15 is a schematic structural view of a body of the present disclosure for interfacing with a container;

FIG. 16 is a partial cross-sectional view of the body of the present disclosure;

FIG. 17 is a schematic structural view of a container of the present disclosure;

FIG. 18 is a partial schematic structural view of a container of the present disclosure;

FIG. 19 is a schematic view of the structure of the container of the present disclosure for interfacing with a body;

FIG. 20 is a schematic view of the structure of the container docking portion of the present disclosure docked with the body docking portion;

fig. 21 is a schematic view of a structure in which a water collecting cartridge of the present disclosure is mounted to a body;

FIG. 22 is a schematic structural view of a water collection cartridge of the present disclosure;

FIG. 23 is a schematic structural view of a housing of the body of the present disclosure;

FIG. 24 is a schematic structural view of a switching mechanism of the present disclosure;

FIG. 25 is an exploded view of the switching mechanism of the present disclosure;

FIG. 26 is a schematic illustration of one state of the switch mechanism of the present disclosure;

FIG. 27 is another state schematic of the switch mechanism of the present disclosure;

FIG. 28 is a schematic structural view of a container trigger switch mechanism of the present disclosure;

FIG. 29 is a schematic structural view of the front cover assembly of the present disclosure;

FIG. 30 is a schematic structural view of the front cover assembly of the present disclosure;

FIG. 31 is a schematic view of the structure of the upper portion of the container of the present disclosure;

FIG. 32 is a schematic structural view of a container lid of the present disclosure;

FIG. 33 is a schematic view of the structure of the container lid of the present disclosure;

FIG. 34 is a schematic structural view of a container lid of the present disclosure;

FIG. 35 is a schematic structural view of a via adjustment mechanism of the present disclosure;

FIG. 36 is a schematic view of a state of the container of the present disclosure during approaching the body;

FIG. 37 is a schematic view of a state of the container of the present disclosure during approaching to a body;

fig. 38 is a schematic view of a state of the container of the present disclosure in approaching the body.

In the figure: 100 machine bodies, 101 bases, 102 machine shells, 103 raw water tanks, 104 filter assemblies, 105 booster pumps, 106 water delivery pumps, 107 heaters, 109 slotted holes, 110 communicating vessels, 111 communicating vessel shells, 112 partition boards, 113 first containing chambers, 114 second containing chambers, 115 water inlets, 116 first water outlets, 117 second water outlets, 118 diversion holes, 119 exhaust holes, 120 first water guide pipes, 121 water outlet valve assemblies, 122 first valve core seats, 124 first valve cores, 125 first plugs, 126 first valve rods, 127 first limiting plates, 129 balancing weights, 130 first rotating shafts, 131 baffle boards, 132 first limiting boxes, 133 shaft holes, 134 first faces, 135 second faces, 136 water passing holes, 137 first water passing parts, 138 second water passing parts, 139 electromagnets, 140 first magnetic absorbers, 141 first elastic pieces, 142 guide rods, 145 first floats, 146 second floats, 147 first water level sections, 148 second water level sections, 149 first limiting members, 150 second limiting members, 151 third limiting members, 152 fourth limiting members, 153 fixing members, 154 buckles, 155 fixing ends, 156 movable ends, 157 gaps, 158 valve core sleeves, 159 outer ring sleeves, 160 inner ring sleeves, 161 transition parts, 162 first convex rings, 163 second convex rings, 164 first grooves, 165 second grooves, 166 front cover components, 167 water outlets, 168 sterilizing lamps, 169 driving mechanisms, 170 switching mechanisms, 171 supporting members, 172 pressing members, 173 switches, 174 second elastic members, 175 extrusion end surfaces, 176 first planes, 177 second planes, 178 guide surfaces, 179 triggering buttons, 180 elastic sheets, 181 pressing rods, 182 supporting columns, 183 fixing parts and 184 movable parts; 200 containers, 201 container shells, 202 container covers, 203 container water outlets, 204 water purifying inlets, 205 second water guide pipes, 206 baffle plates, 207 ring grooves, 208 clamping grooves, 209 limit parts, 210 abutting parts, 211 through holes, 212 through hole adjusting mechanisms, 213 shielding pieces, 214 second magnetic attraction bodies, 215 second rotating shafts, 216 brackets, 217 cover plates, 218 second limit boxes, 220 limit surfaces, 221 bulges, 222 plug bodies, 223 cover edges, 224 water inlet valve assemblies, 228 first seat rings, 229 second seat rings, 230 connecting ribs, 231 second plugs, 232 second valve rods, 233 handles and 234 water outlet nozzle abutting parts; 300 catchment box, 301 catchment box base, 302 catchment box cover, 303 first drainage hole, 304 second drainage hole, 305 pothooks.

Detailed Description

For the purposes of making the objects, technical solutions and advantages of the embodiments of the present disclosure more apparent, the technical solutions of the embodiments of the present disclosure will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present disclosure, and it is apparent that the described embodiments are some embodiments of the present disclosure, but not all embodiments. The components of the embodiments of the present disclosure, which are generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present disclosure provided in the accompanying drawings is not intended to limit the scope of the disclosure, as claimed, but is merely representative of selected embodiments of the disclosure. All other embodiments, which can be made by one of ordinary skill in the art without inventive effort, based on the embodiments in this disclosure are intended to be within the scope of this disclosure.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In the description of the present disclosure, it should be noted that the terms "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, or are those conventionally put in use in the present utility model, merely for convenience in describing the present disclosure and simplifying the description, and do not indicate or imply that the apparatus or elements to be referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present disclosure. Furthermore, the terms "first," "second," "third," and the like are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance. In the description of the present disclosure, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present disclosure, it should also be noted that, unless explicitly stated and limited otherwise, the terms "disposed," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; either mechanically or electrically. The specific meaning of the terms in this disclosure will be understood by those of ordinary skill in the art in the specific context.

In this disclosure, unless expressly stated or limited otherwise, a first feature being "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other by way of additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

Embodiments of the present disclosure are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are exemplary only for explaining the present disclosure and are not to be construed as limiting the present disclosure.

The present embodiment provides a drinking apparatus including a body 100 and a container 200 detachably connected to the body 100. The body 100 is provided with a sterilizing lamp 168, a first water outlet 116 and a switch mechanism 170, and the container 200 is provided with a through hole 211, a purified water inlet 204 and a switch triggering part. When the container 200 is mounted on the machine body 100, the first water outlet 116 is communicated with the purified water inlet 204, the sterilizing lamp 168 is opposite to the through hole 211, and the switch mechanism 170 can be opened by the switch triggering part; when the switch mechanism 170 is turned on and the water producing condition is satisfied, the machine body 100 can process the raw water into purified water and convey the purified water to the container 200 through the first water outlet 116 and the purified water inlet 204, and the sterilizing lamp 168 irradiates and sterilizes the inside of the container 200 through the through hole 211. The container 200 may be a clean water tank, a cup, a brew cup, a coffee brew cup, etc. The drinking device may be used to provide water purification, tea making, tea boiling, coffee brewing, and the like. The following examples illustrate the use of vessel 200 as a fresh water tank.

The machine body 100 may include a base 101, a housing 102, a raw water tank 103, a filter assembly 104, a booster pump 105, a water outlet channel, and a front cover assembly 166, where the raw water tank 103 and the housing 102 are disposed on the base 101, the front cover assembly 166 is disposed on an upper portion of the housing 102, and the filter assembly 104, the booster pump 105, and the water outlet channel are disposed in the housing 102, and the raw water tank 103, the booster pump 105, the filter assembly 104, and the water outlet channel are sequentially connected. Referring to fig. 4 and 5, the raw water tank 103 is disposed at the rear end of the housing 102, the front cover assembly 166 is disposed at the front end of the housing 102, the filter assembly 104 is adjacent to the raw water tank 103, and the booster pump 105 and the water outlet path are adjacent to the front end of the housing 102.

With continued reference to fig. 5-8, the water outlet path includes a communicating vessel 110, a water pump 106, a heater 107 and a purified water intake, the communicating vessel 110 has a water inlet 115, a first water outlet 116 and a second water outlet 117, the water inlet 115 is communicated with the filter assembly 104, the first water outlet 116 is used for being in butt joint with the purified water inlet 204 of the container 200, and the second water outlet 117, the water pump 106, the heater 107 and the purified water intake are sequentially communicated.

Referring to fig. 8, the communicating vessel 110 includes a first cavity 113, a second cavity 114, a water level sensor and a water volume adjusting mechanism, wherein the first cavity 113 is provided with a water inlet 115, a first water outlet 116 and a second water outlet 117, the second cavity 114 is communicated with the first cavity 113 through a diversion hole 118, the water volume adjusting mechanism is used for adjusting the size of the diversion hole 118, and the water level sensor is arranged in the second cavity 114 and is used for detecting the water level in the second cavity 114; when the container 200 is mounted on the machine body 100, the purified water inlet 204 is communicated with the first water outlet 116, and when water is injected through the water inlet 115 or taken from the second water outlet 117, the water level in the second containing cavity 114 and the water level in the container 200 are simultaneously reduced.

In one possible implementation, the volume of the second cavity 114 may be the same as the volume of the inner cavity of the container 200, the height of the second cavity 114 is identical to the height of the inner cavity of the container 200, and the flow area of the diversion hole 118 is equal to the flow area of the first water outlet 116 when the container 200 is mounted on the machine body 100, so that when water is injected through the water inlet 115, the water flow uniformly disperses and flows into the second cavity 114 and the container 200, and when water is taken through the second water outlet 117, the water in the second cavity 114 and the water in the container 200 synchronously decreases, so that the water level in the second cavity 114 and the water level in the container 200 can be leveled without adjusting the size of the diversion hole 118. However, this design increases the volume of the body 100, affecting the aesthetic appearance of the device.

When the volume of the second cavity 114 is designed to be smaller than the volume of the inner cavity of the container 200, since the volumes of the second cavity 114 and the container 200 are different, if the water levels of the two are to be balanced when taking water, the water outlet with the volume size matching with the two needs to be designed, as a result, the water outlet section of the second cavity 114 is far smaller than the water outlet section of the container 200, and the water outlet section of the second cavity 114 is too small, but the water inlet time is required to be shortened and the water outlet section of the second cavity 114 needs to be increased. In order to simultaneously take into consideration the requirements of fast water feeding and water level balance between the second accommodating cavity 114 and the container 200 during water discharging, the water flow adjusting mechanism is adopted in the embodiment to adjust the overflow of the diversion hole 118 in different scenes, namely, the water passing area of the diversion hole 118 is enlarged during water injection through the water inlet 115, the water passing area of the diversion hole 118 is reduced during water intake through the second water outlet 117, the accurate water level detection during water intake can be ensured, and the water feeding speed can be improved during water injection.

Specifically, the communicating vessel 110 may include a communicating vessel housing 111 and a partition 112, the partition 112 divides an inner space of the communicating vessel housing 111 into a first accommodating cavity 113 and a second accommodating cavity 114, a water inlet 115 is provided at an upper portion of the communicating vessel housing 111, a first water outlet 116 and a second water outlet 117 are provided at a lower portion of the communicating vessel housing 111, the water inlet 115, the first water outlet 116 and the second water outlet 117 are all communicated with the first accommodating cavity 113, and a diversion hole 118 is provided at a lower portion of the partition 112. The upper portion of the first chamber 113 is communicated with the upper portion of the second chamber 114, specifically, as shown in fig. 8, a communication space 119 is provided between the partition 112 and the inner wall of the communicating vessel housing 111, however, in other embodiments, an exhaust hole may be provided at the upper portion of the partition 112, and the first chamber 113 and the second chamber 114 may be communicated through the exhaust hole. When water is injected through the water inlet 115, air in the first accommodating cavity 113 can be discharged into the second accommodating cavity 114 through the communicating space 119, so that the water feeding speed of the container 200 is improved.

In one possible implementation, the water volume adjusting mechanism is disposed in the second accommodating cavity 114, and the water volume adjusting mechanism includes a stopper and a weight 129, the stopper is rotatably disposed in the first accommodating cavity 113, and the weight 129 is disposed on the stopper to drive the stopper to partially block the deflector hole 118. The stopper partially obstructs the deflector aperture 118 when there is no liquid within the communication 110 or when the liquid within the communication 110 is at rest. In the water making process, the liquid injected into the second accommodating cavity 114 from the diversion hole 118 can drive the stop plate 131 to rotate in a direction away from the diversion hole 118 against the acting force of the balancing weight 129. During water outflow, the liquid injected into the first cavity 113 from the diversion hole 118 and the balancing weight 129 cooperate, so that the stopper partially shields the diversion hole 118.

In one possible implementation, the water volume adjustment mechanism further comprises a first shaft 130, the first shaft 130 being fixed to an inner wall of the second chamber 114, and the stopper being rotatably connected to the first shaft 130. Referring to fig. 10, the stopper includes a stopper plate 131 and a first limiting box 132 connected to the stopper plate 131, a shaft hole 133 is formed at a connection portion between the stopper plate 131 and the first limiting box 132, the first rotating shaft 130 passes through the shaft hole 133, and the balancing weight 129 is disposed in the first limiting box 132. The balancing weight 129 and the stop plate 131 are positioned on two sides of the first rotating shaft 130, and the gravity center of the water quantity adjusting mechanism is arranged on the balancing weight 129. The stopper plate 131 has a first surface 134 facing the partition 112, and the first stopper case 132 has a second surface 135 facing the partition 112, the second surface 135 being away from the partition 112 when the first surface 134 is attached to the partition 112, and the first surface 134 being away from the partition 112 when the second surface 135 is attached to the partition 112.

In the structure shown in fig. 9, the stopper is disposed near the partition 112, the weight 129 is located above the first rotation shaft 130, the stopper plate 131 is located below the first rotation shaft 130, and the weight 129 falls under the action of gravity, so that the stopper plate 131 on the other side is tilted and abuts against the partition 112, thereby partially shielding the diversion hole 118 on the partition 112. Further, the stop plate 131 may further be provided with a water passing hole 136, and when the stop plate 131 shields the diversion hole 118, the water passing hole 136 at least partially coincides with the diversion hole 118. The water passing hole 136 is partially overlapped with the water guiding hole 118, the water guiding hole 118 is partially blocked by the stop plate 131, the water passing area S1 of the non-blocked part of the water guiding hole 118 and the water passing area S2 of the water outlet of the container 200 meet the following conditions: s1: s2=v1: v2, where V1 refers to the volume of the second chamber 114 and V2 refers to the volume of the container 200. When water is injected into the first containing cavity 113 from the water inlet 115, the water enters the second containing cavity 114 from the diversion hole 118 to impact the baffle plate 131, so that the baffle plate 131 is conveniently punched away by the impact force of the water, the water passing area of the diversion hole 118 is enlarged, the water injection speed is increased, and the water injection time is shortened; after stopping the water injection to the first receiving chamber 113, the stop plate 131 resets the portion blocking the diversion hole 118, so that the water passing area of the diversion hole 118 becomes smaller, thereby ensuring that the water level of the second receiving chamber 114 is level with the water level of the container 200 when the water is discharged from the second receiving chamber 114.

In the embodiment, a water quantity adjusting mechanism is arranged at the position of the diversion hole 118, and under the action of the balancing weight 129, the water quantity adjusting mechanism is in a normally closed state, and the diversion hole 118 is partially shielded; when water is injected into the first containing cavity 113 from the water inlet 115, the water flows to flush the stop plate 131, the diversion holes 118 are exposed, the overflow area is increased, and purified water in the first containing cavity 113 can rapidly enter the second containing cavity 114, so that the water feeding speed of the second containing cavity 114 is improved, and the water feeding speed of the container 200 is further improved; when water is taken through the second water outlet 117, the water in the second containing cavity 114 flows to the first containing cavity 113, the stop plate 131 always shields the diversion hole 118, the overflow area is smaller, and the water draining speed of the second containing cavity 114 is reduced. The water quantity adjusting mechanism of the embodiment not only improves the water feeding speed of the second containing cavity 114, but also does not influence the water level balance between the second containing cavity 114 and the container 200 during water feeding.

In one possible implementation, the baffle aperture 118 has a first water passing portion 137 and a second water passing portion 138, the cross-sectional area of the second water passing portion 138 being greater than the cross-sectional area of the first water passing portion 137. When water is injected through the water inlet 115, the second water passing part 138 is communicated with the first accommodating cavity 113 and the second accommodating cavity 114, and the first water passing part 137 is not communicated with the first accommodating cavity 113 and the second accommodating cavity 114; when water is taken through the second water outlet 117, the second water passing portion 138 is not communicated with the first accommodating cavity 113 and the second accommodating cavity 114, and the first water passing portion 137 is communicated with the first accommodating cavity 113 and the second accommodating cavity 114. The water quantity adjusting mechanism comprises an electromagnet 139 and a first magnetic attraction body 140, wherein the first magnetic attraction body 140 is arranged in the communicating vessel shell 111 through a first elastic piece 141, and the electromagnet 139 is arranged outside the communicating vessel shell 111. When water is taken through the second water outlet 117, the first magnet 140 moves toward the electromagnet 139 to shield the second water passing portion 138 of the deflector hole 118 when the electromagnet 139 is energized. When water is injected through the water inlet 115, and when the electromagnet 139 is powered off, the first magnetic attraction body 140 is driven by the first elastic piece 141 to reset and shield the first water passing portion 137 of the diversion hole 118.

The electromagnet 139 may be disposed below the first cavity 113, the first magnetic body 140 is disposed in the first cavity 113 and clings to the partition 112, one end of the first elastic member 141 is connected to the bottom of the first cavity 113, and the other end is connected to the first magnetic body 140. Alternatively, the electromagnet 139 may be disposed below the second cavity 114, the first magnetic body 140 is disposed in the second cavity 114 and clings to the partition 112, one end of the first elastic member 141 is connected to the bottom of the second cavity 114, and the other end is connected to the first magnetic body 140. In one possible implementation, the first magnetic attraction body 140 is internally coated with an iron sheet, and the first elastic member 141 is a spring.

Referring to fig. 11 and 12, the upper portion of the flow guiding hole 118 is a first water passing portion 137, the lower portion is a second water passing portion 138, the lower end of the first elastic member 141 is connected to the bottom of the second cavity 114, the upper end of the first elastic member is connected to the first magnetic attraction body 140, the width of the first magnetic attraction body 140 is greater than the widths of the first water passing portion 137 and the second water passing portion 138, the height of the first magnetic attraction body 140 is less than the sum of the heights of the first water passing portion 137 and the second water passing portion 138, and the electromagnet 139 is disposed below the first elastic member 141. When the second cavity 114 discharges water to the first cavity 113, the electromagnet 139 is electrified to generate electromagnetic force, the first magnetic attraction body 140 is attracted to approach the electromagnet, the first elastic piece 141 is compressed to block the second water passing portion 138 of the water guide hole 118, the water is guided between the first cavity 113 and the second cavity 114 through the first water passing portion 137, and the flow passing area is small. When the first containing cavity 113 is filled with water to the second containing cavity 114, the electromagnet 139 is powered off, the first magnetic attraction body 140 is supported by the first elastic piece 141 to block the first water passing portion 137, the first containing cavity 113 and the second containing cavity 114 are guided by the second water passing portion 138, and the overflowing area is increased. The present embodiment increases the water supply speed of the second chamber 114 and ensures that the second chamber 114 is balanced with the water level of the container 200 when draining.

In one possible implementation, the number of diversion holes 118 is multiple, and the water volume adjustment mechanism is configured to block or expose at least a portion of the diversion holes 118 such that the total water flow area of all the diversion holes 118 when water is injected from the first cavity 113 to the second cavity 114 is greater than the total water flow area of all the diversion holes 118 when water is discharged from the second cavity 114 to the first cavity 113. Specifically, the water amount adjusting mechanism may be a unidirectional film disposed in the second chamber 114 for blocking the diversion hole 118, and when water is injected from the first chamber 113 to the second chamber 114, the unidirectional film moves away from the diversion hole 118 to expose the diversion hole 118, and when water is discharged from the second chamber 114 to the first chamber 113, the unidirectional film moves toward the direction close to the diversion hole 118 to block the diversion hole 118. Of course, in other embodiments, a plurality of diversion holes 118 may be provided, where the plurality of diversion holes 118 includes at least one first diversion hole and at least one second diversion hole, the first diversion hole is normally open, the water amount adjusting mechanism exposes the second diversion hole when water is injected from the first cavity 113 to the second cavity 114, and the water amount adjusting mechanism blocks the second diversion hole when water is discharged from the second cavity 114 to the first cavity 113.

The water level sensor may include a guide rod 142, a floating structure sleeved on the guide rod 142, and a first detection element and a second detection element arranged in the guide rod 142, where the guide rod 142 is vertically arranged in the second cavity 114, the first detection element is located at the lower part of the guide rod 142 and used for detecting the lowest pre-warning water level of the second cavity 114, the second detection element is located at the upper part of the guide rod 142 and used for detecting the highest pre-warning water level of the second cavity 114, and the floating structure can move along the long axis of the guide rod 142 under the action of liquid buoyancy. When the water level of the liquid in the second cavity 114 drops to the first position of the guide rod 142, the floating structure moves to the lower part of the guide rod 142 and triggers the first detection element, and when the water level of the liquid in the second cavity 114 rises to the second position of the guide rod 142, the floating structure moves to the upper part of the guide rod 142 and triggers the second detection element. The floating structure can move up and down along with the increase and decrease of the liquid in the second cavity 114, that is, the liquid increases, the liquid level rises, the floating structure moves up along the guide rod 142, the liquid decreases, and the liquid level falls, the floating structure moves down along the guide rod 142.

Further, the body 100 also includes a controller, which may be disposed within the base 101, within the housing 102, or on the front cover assembly 166. The controller is electrically connected to the first detecting element, the second detecting element, the booster pump 105, and the water delivery pump 106, respectively. When the first detection element is triggered, the controller controls the water pump 106 to stop working, and when the second detection element is triggered, the controller controls the booster pump 105 to stop working.

In one possible implementation, the floating structure includes a first float 145 and a second float 146, a first water level section 147 is provided at a lower portion of the guide rod 142, a second water level section 148 is provided at an upper portion of the guide rod 142, the first float 145 is sleeved on the guide rod 142 and can be driven to move in the first water level section 147 by liquid buoyancy, the second float 146 is sleeved on the guide rod 142 and can be driven to move in the second water level section 148 by liquid buoyancy, the first detection element is provided inside the first water level section 147, and the second detection element is provided inside the second water level section 148. When the water level of the liquid in the second cavity 114 drops to the first position of the guide rod 142, the first float 145 moves to the lower end of the first water level section 147 and triggers the first detection element, and when the water level of the liquid in the second cavity 114 rises to the second position of the guide rod 142, the second float 146 moves to the upper end of the second water level section 148 and triggers the second detection element. As shown in fig. 8, a first limiting member 149, a second limiting member 150, a third limiting member 151 and a fourth limiting member 152 are sequentially disposed on the guide rod 142, a portion of the guide rod 142 between the first limiting member 149 and the second limiting member 150 is a first water level section 147, and a portion of the guide rod 142 between the third limiting member 151 and the fourth limiting member 152 is a second water level section 148.

Wherein, the first detecting element and the second detecting element comprise magnetic reed switches, and the first floater 145 and the second floater 146 are respectively provided with a magnetic block. When the first floater 145 moves to the position of the first detecting element, the magnetic reed switch of the first detecting element is conducted under the magnetic attraction of the magnetic block of the first floater 145, the first detecting element is triggered, and when the first floater 145 is far away from the position of the first detecting element, the magnetic reed switch of the first detecting element is automatically opened. When the second floater 146 moves to the position of the second detecting element, the magnetic reed switch of the second detecting element is conducted under the magnetic attraction of the magnetic block of the second floater 146, the second detecting element is triggered, and when the second floater 146 is far away from the position of the second detecting element, the magnetic reed switch of the second detecting element is automatically disconnected.

In this embodiment, the lower portion of the guide rod 142 corresponds to the low water level region of the second cavity 114, and the upper portion of the guide rod 142 corresponds to the high water level region of the second cavity 114, and a second water level region 148 is provided, so that the first float 145 moves in the first water level region 147, and the second float 146 moves in the second water level region 148, so that the moving distance of the float along the guide rod 142 is shortened, and the smoothness of the float movement can be ensured.

In one possible implementation, the floating structure may include a third float that moves to a lower end of the guide rod 142 and triggers the first detecting element when the level of the liquid in the second chamber 114 drops to the first position of the guide rod 142, and moves to an upper end of the guide rod 142 and triggers the second detecting element when the level of the liquid in the second chamber 114 rises to the second position of the guide rod 142. The first detection element and the second detection element comprise a magnetic reed switch, and a magnetic block is arranged in the third floater. When the third floater moves to the position where the third floater is located with the first detection element, the magnetic reed switch of the first detection element is conducted under the magnetic attraction of the magnetic block of the third floater, the first detection element is triggered, and when the third floater moves to the position where the third floater is located with the second detection element, the magnetic reed switch of the second detection element is conducted under the magnetic attraction of the magnetic block of the third floater, and the second detection element is triggered. Compared with the embodiment shown in fig. 8, the advantage of this embodiment is that only one float needs to be provided, and fewer elements are required, but because the travel is longer, the floats have possibility of being blocked, while the scheme shown in fig. 8 can ensure the accuracy of detection by providing the upper and lower floats, and effectively avoid the situations of blocking or malfunctioning of the floats, etc.

In this embodiment, the communicating vessel 110 is provided on the machine body 100, the communicating vessel 110 is configured to include a first containing cavity 113 and a second containing cavity 114, and the first containing cavity 113 is provided with a water inlet 115, a second water outlet 117, a first water outlet 116 in butt joint with the container 200, and a diversion hole 118 in communication with the second containing cavity 114, and a water quantity adjusting mechanism is provided to adjust the size of the diversion hole 118, so that the water quantity of the diversion hole 118 is increased when water is injected through the water inlet 115, and the water quantity of the diversion hole 118 is reduced when water is taken through the second water outlet 117, so that the effect that the water level in the second containing cavity 114 is level with the water level in the container 200 is achieved, and the water level in the container 200 can be obtained by measuring the water level in the second containing cavity 114 through the water level sensor. The present embodiment achieves the function of obtaining the purified water level in the container 200 while maintaining the aesthetic appearance of the container 200.

In one possible implementation manner, the second water outlet 117 is provided on the bottom surface of the connector housing 111, the partition 112 is provided in the connector housing 111, the diversion hole 118 is provided on the lower portion of the partition 112, the first water outlet 116 is provided on the side surface of the connector housing 111 adjacent to the partition 112, and the second water outlet 117 is closer to the diversion hole 118 than the first water outlet 116. The water inlet 115 is lower than the highest water level of the communicating vessel 110.

The body 100 includes a locking mechanism and a water outlet valve assembly 121 disposed at the first water outlet 116, and the container 200 includes a receiving mechanism and a water inlet valve assembly 224 disposed at the clean water inlet 204. When the container 200 is mounted on the machine body 100, the water inlet valve assembly 224 is abutted against the water outlet valve assembly 121, the first water outlet 116 is communicated with the purified water inlet 204, and the locking mechanism is in clamping fit with the bearing mechanism; when the container 200 is separated from the machine body 100, the locking mechanism is separated from the receiving mechanism, the water outlet valve assembly 121 seals the first water outlet 116, and the water inlet valve assembly 224 seals the purified water inlet 204.

Referring to fig. 13-16, a first water conduit 120 is disposed on the connector housing 111 around the first water outlet 116, and a water outlet valve assembly 121 is disposed in the first water conduit 120. The water outlet valve assembly 121 comprises a first valve core seat 122, a first spring and a first valve core 124, the first valve core seat 122 is arranged in the first water guide pipe 120 and is in sealing connection with the inner wall of the first water guide pipe 120, the first valve core 124 comprises a first plug 125, a first valve rod 126 and a first limiting plate 127, one end of the first valve rod 126 is connected with the first plug 125, the other end of the first valve rod 126 penetrates through a through hole of the first valve core seat 122 and then is connected with the first limiting plate 127, the first spring is abutted between the first valve core seat 122 and the first valve rod 126, the first valve core 124 can approach the first water outlet 116 under the action of external force driving so that the first plug 125 is separated from the first valve core seat 122, and the first spring can drive the first valve core 124 to reset so that the through hole of the first valve core seat 122 is blocked.

Referring to fig. 17-19, a second water conduit 205 is disposed around the clean water inlet 204 of the container 200, and a water inlet valve assembly 224 is disposed in the second water conduit 205. The water inlet valve assembly 224 comprises a second valve core seat, a second spring and a second valve core, the second valve core seat is arranged in the second water guide pipe 205 and is connected with the second water guide pipe 205 in an expansion mode, the second valve core seat comprises a first seat ring 228, a second seat ring 229 and a plurality of connecting ribs 230 for connecting the first seat ring 228 and the second seat ring 229, the second valve core comprises a second plug 231 and a second valve rod 232, one end of the second valve rod 232 is connected with the second plug 231, the other end of the second valve rod penetrates through a through hole of the second seat ring 229, and the second spring is abutted between the second seat ring 229 and the second plug 231; the second valve core can approach the inside of the container 200 under the action of external force driving so that the second plug 231 is separated from the first seat ring 228, and the second spring can drive the second valve core to reset so that the second plug 231 seals the through hole of the first seat ring 228. The second stopper 231 is positioned near the outer end of the clean water inlet 204 with respect to the second valve stem 232, so that the water sealing of the container 200 can be more quickly performed and the liquid flowing out of the clean water inlet 204 can be reduced after the container 200 is taken out of the body because the second stopper 231 is positioned near the outer end of the clean water inlet 204. Specifically, upon installation of the container 200, the first valve stem 126 of the first valve spool 124 pushes the second plug 231 toward the interior of the container 200 to disengage the second plug 231 from the first seat 228.

As shown in fig. 14, the locking mechanism includes a fixing member 153 and a buckle 154, the fixing member 153 is sleeved on the outer wall of the first water conduit 120, and the buckle 154 is connected with the fixing member 153. As shown in fig. 18, the container 200 has a baffle 206 disposed around the second water conduit 205, a ring groove 207 is formed between the baffle 206 and the second water conduit 205, and the receiving mechanism includes a slot 208 disposed on the baffle 206. As shown in fig. 20, when the container 200 is mounted on the machine body 100, the water inlet valve assembly 224 abuts against the water outlet valve assembly 121, the first water guide pipe 120 and the fixing member 153 enter the ring groove 207, and the buckle 154 is engaged with the clamping groove 208. In one possible implementation, the clasp 154 may be positioned near the bottom of the body 100 and the catch 208 positioned near the bottom of the container 200, with the locking mechanism not visible to the user during normal use of the drinking device, improving the aesthetic appearance of the drinking device.

With continued reference to fig. 14, the buckle 154 has a fixed end 155 and a movable end 156, the fixed end 155 is connected to the fixing member 153, the movable end 156 protrudes from the outer wall of the fixing member 153, and a gap 157 is formed between the buckle 154 and the outer wall of the first water conduit 120. During the process of mounting the container 200 to the machine body 100, the movable end 156 of the buckle 154 is restrained by the baffle 206 to be close to the first water guide pipe 120, the restraint on the movable end 156 is released when the movable end 156 moves to the position of the clamping groove 208 on the baffle 206, the movable end 156 slides into the clamping groove 208, the container 200 is firmly connected with the machine body 100, and even if vibration occurs during the operation of the drinking equipment, the container 200 cannot be easily separated from the machine body 100.

Further, the locking mechanism further comprises a valve core sleeve 158 sleeved on the first water conduit 120, the valve core sleeve 158 comprises an outer sleeve 159, an inner sleeve 160 arranged in the outer sleeve 159 and a transition part 161 connecting the outer sleeve 159 and the inner sleeve 160, the inner sleeve 160 is positioned between the water outlet valve assembly 121 and the inner wall of the first water conduit 120, the outer sleeve 159 is positioned between the outer wall of the first water conduit 120 and the inner wall of the fixing piece 153, the movable end 156 of the buckle 154 is opposite to the outer sleeve 159, and the transition part 161 is positioned between the end face of the first water conduit 120 and the end face of the fixing piece 153. When the container 200 is mounted on the machine body 100, the second water guide pipe 205 enters the first water guide pipe 120 and is sealed with the second water guide pipe 205 through the inner ring sleeve 160; when the container 200 is separated from the machine body 100, the outer collar 159 drives the movable end 156 of the buckle 154 to reset. The valve core sleeve 158 may be made of silica gel. The valve core sleeve 158 is arranged on the first conduit, so that on one hand, the sealing effect on the joint of the container 200 and the machine body 100 can be achieved when the container 200 is mounted on the machine body 100, and on the other hand, the auxiliary buckle 154 can rebound and reset when the container 200 is separated from the machine body 100, the fatigue resistance of the buckle 154 is improved, and the service life is prolonged.

With continued reference to fig. 14-16, the inner wall of the inner collar 160 is provided with a first convex ring 162 and a second convex ring 163, the outer wall of the inner collar 160 is provided with a first groove 164 corresponding to the first convex ring 162 and a second groove 165 corresponding to the second convex ring 163, the first convex ring 162 and the first groove 164 are close to the transition portion 161, and the second convex ring 163 and the second groove 165 are close to the first plug 125; the first protruding ring 162 protrudes from the inner wall of the inner race 160 to a greater extent than the second protruding ring 163 protrudes from the inner wall of the inner race 160, and the first recess 164 has a greater area than the second recess 165. Considering the use experience of the user when installing or detaching the container 200, if the first protrusion 221 and the second protrusion 221 are set to be the same, the interference between the valve core sleeve 158 and the first water conduit 120 and the second water conduit 205 is increased, the interference is increased, the user needs to use a larger force for plugging, but the interference is reduced, and the situation of poor tightness may occur. In order to improve the experience of users when inserting and extracting the container 200, the first convex ring 162 and the second convex ring 163 are designed differently, and the height of the first convex ring 162 close to the orifice of the first water conduit 120 is designed to be larger than the height of the second convex ring 163 close to the first water outlet 116, so that when inserting the container 200 into the machine body 100, water can be sealed as soon as possible, and purified water is prevented from flowing out of the equipment; the design of the second collar 163 strengthens the seal between the front end of the second water conduit 205 and the rear end of the first water conduit 120, so that the container 200 is more tightly connected with the machine body 100, and the seal is more reliable. The first groove 164 corresponds to the first protrusion 221, the second groove 165 corresponds to the second protrusion 221, and when the height of the first protrusion 221 is greater than that of the second protrusion 221, the area of the first groove 164 is greater than that of the second groove 165, so that enough deformation space is reserved for the first protrusion 221 and the second protrusion 221, and smooth deformation of the valve core sleeve 158 in the plugging process is ensured.

Referring to fig. 21 and 22, the drinking apparatus further includes a water collecting case 300, the water collecting case 300 being detachably coupled to the lower portion of the cabinet 102, a space for accommodating the container 200 being formed between the water collecting case 300 and the front cover assembly 166. The front cover assembly 166 is provided with a water outlet 167, the water outlet 167 is communicated with a purified water intake, and the water collecting box 300 is positioned below the first water guide pipe 120 and the water outlet 167. The water collecting box 300 comprises a water collecting box base 301 and a water collecting box cover 302, wherein the water collecting box cover 302 is arranged at the top opening of the water collecting box base 301, a clamping hook 305 is arranged on the side face of the water collecting box base 301, a slotted hole 109 is arranged at the lower part of the casing 102, and the clamping hook 305 enters the slotted hole 109 to fix the water collecting box 300 on the casing 102. The water collection box cover 302 is provided with a first water filtering hole 303 and a second water filtering hole 304, the first water filtering hole 303 is positioned below the first water guide pipe 120, and the second water filtering hole 304 is positioned below the water outlet 167.

In this embodiment, the first water outlet 116 and the locking mechanism are disposed on the machine body 100, the clean water inlet 204 and the receiving mechanism are disposed on the container 200, when the container 200 is mounted on the machine body 100, the first water outlet 116 is communicated with the clean water inlet 204, and the locking mechanism is engaged with the receiving mechanism in a clamping manner, so that the container 200 is prevented from being separated from the machine body 100 due to vibration generated when the machine body 100 is used for producing water, and the connection stability of the two is improved.

The switch mechanism 170 includes a support 171, a switch 173, and a presser 172; the switch 173 includes a triggering member; the pressing member 172 includes a mounting portion and is elastically disposed on the support member 171 by the mounting portion, the pressing member 172 includes a pressing end surface 175, the pressing end surface 175 is disposed at a distance from the mounting portion, the pressing end surface 175 is disposed opposite to the triggering member, and the pressing end surface 175 includes a second plane 177. When the container 200 applies a force to the pressing member 172, the pressing member 172 can move in a first direction under the pushing action of the container 200, and the second plane 177 approaches the triggering member, and when the container 200 is mounted to the body 100, the second plane 177 presses the triggering member in a second direction to turn on the switch 173. Wherein the second plane 177 has a length in the first direction that is greater than the first length, which is the maximum length that allows the container 200 to move in a direction opposite to the first direction. The second direction is perpendicular to the first direction, and in the second direction, the pressing end face 175 is located between the mounting portion and the trigger member.

In one possible implementation, the support member 171 is provided with a second elastic member 174, and one end of the second elastic member 174 is connected to the support member 171 and the other end is connected to the mounting portion in an elastic movement direction of the second elastic member 174, so that the pressing member 172 is elastically disposed on the support member 171. When the container 200 applies a force to the compression element 172, the compression element 172 moves in a first direction to compress the second resilient member 174; when the container 200 is removed, the second elastic member 174 is restored and drives the pressing member 172 away from the supporting member 171.

Referring to fig. 23-28, the switch mechanism 170 is disposed below the communicating vessel 110 and near the bottom of the machine body 100, and the switch triggering portion is disposed at the bottom of the container 200. The switch mechanism 170 includes a support member 171, a pressing member 172, and a switch 173, the support member 171 is fixed to the inner wall of the casing 102 by a support post 182, the switch 173 and the pressing member 172 are both provided on the opposite side of the support member 171 to the inner wall of the casing 102, the switch 173 is provided at one end of the support member 171, the pressing member 172 is connected to the other end of the support member 171 by a second elastic member 174, and the pressing end face 175 of the pressing member 172 is opposite to the triggering member of the switch 173. The container 200 is provided with a switch trigger. The switch triggering part can push the pressing piece 172 to move towards the supporting piece 171 against the acting force of the second elastic piece 174, and drives the extrusion end face 175 to approach towards the triggering part, when the container 200 is installed on the machine body 100, the first water outlet 116 is communicated with the purified water inlet 204, and the extrusion end face 175 extrudes the triggering part to enable the switch 173 to be communicated; when the container 200 is separated from the machine body 100, the second elastic member 174 drives the pressing member 172 to reset, the pressing member 172 releases the force applied by the pressing member 172 to the triggering member, the triggering member resets, and the switch 173 is turned off. Wherein the second elastic member 174 is a spring.

Referring to fig. 26 and 27, the pressing end surface 175 further includes a first plane 176 and a guide surface 178 between the first plane 176 and the second plane 177, the first plane 176, the guide surface 178, and the second plane 177 sequentially contact the trigger member during movement of the pressing member 172 in the first direction, and distances between the first plane 176, the guide surface 178, and the second plane 177 and the trigger member sequentially decrease.

As shown in fig. 28, the pressing member 172 includes a pressing rod 181, the pressing rod 181 protrudes out of the casing 102 of the machine body 100, and a long axis of the pressing rod 181 is parallel to a deformation direction of the second elastic member 174. The switch triggering portion includes a limiting portion 209 and an abutting portion 210 disposed in the limiting portion 209. The limiting portion 209 may be a notch or a through hole formed in the container housing 201, the abutting portion 210 may be a protrusion formed on an outer wall of the second water conduit 205, and the abutting portion 210 may be located between the clamping groove 208 and the limiting portion 209. When the container 200 is mounted on the body 100, the pressing rod 181 passes through the limiting portion 209 and abuts against the abutting portion 210.

In one possible implementation, the trigger component may include a trigger button 179, the trigger button 179 protruding from the switch housing of the switch 173. The direction of movement of the trigger button 179 is perpendicular to the direction of movement of the follower 172. When the container 200 is separated from the body 100, the first flat surface 176 contacts the trigger button 179, and when the container 200 is mounted on the body 100, the second flat surface 177 applies a force to the trigger button 179 to turn on the switch 173.

In one possible implementation, referring to fig. 25, the triggering component includes a triggering button 179 and a spring plate 180, the triggering button 179 protrudes out of the switch housing of the switch 173, the spring plate 180 has a fixed portion 183 and a movable portion 184, the fixed portion 183 is connected to the switch housing, and the movable portion 184 contacts the triggering button 179. The direction of movement of the trigger button 179 is perpendicular to the direction of movement of the follower 172. When the container 200 is separated from the body 100, the first plane 176 contacts the movable portion 184 of the spring 180, as shown in fig. 26; when the container 200 is mounted on the body 100, the second plane 177 presses the movable portion 184, and the movable portion 184 applies a force to the trigger button 179 to turn on the switch 173, as shown in fig. 27.

In this embodiment, the structure of the switch mechanism 170 on the machine body 100 is improved, the pressing member 172 and the switch 173 are arranged on the supporting member 171 side by side, the pressing member 172 is connected with the supporting member 171 through the second elastic member 174, the pressing end surface 175 of the pressing member 172 is opposite to the triggering member of the switch 173, when the second elastic member 174 is compressed, the pressing member 172 approaches the supporting member 171 when the container 200 is mounted on the machine body 100, the pressing end surface 175 presses the triggering member to conduct the switch 173, and when the container 200 is separated from the machine body 100, the second elastic member 174 drives the pressing member 172 to reset, and the pressing end surface 175 releases the force applied to the triggering member to close the switch 173. The present embodiment performs position limitation on the pressing member 172 and the switch 173 by the supporting member 171, converts the force applied by the container 200 to the pressing member 172 into the pressing force of the switch 173 on the side of the pressing end surface 175 of the pressing member 172, improves the stability of the pressing member 172 against the switch triggering portion, and maintains the switch triggering portion in the abutting state with the pressing member 172 even if the container 200 is slightly reversed due to the operational shock of the drinking apparatus.

The front cover assembly 166 is provided with a germicidal lamp 168 and a drive mechanism 169, and the top of the container 200 is provided with a via 211 and a via adjustment mechanism 212. When the container 200 is separated from the machine body 100, the via hole 211 is closed by the via hole adjusting mechanism 212; when the container 200 is mounted on the machine body 100, the via hole 211 is located below the germicidal lamp 168, and the driving mechanism 169 drives the via hole adjusting mechanism 212 to rotate and expose the via hole 211, so that light of the germicidal lamp 168 can be injected into the container 200 through the via hole 211. Wherein the germicidal lamp 168 may be a UV lamp.

Wherein, the driving mechanism 169 is used for driving the via adjusting mechanism 212 to rotate from the first position until the container 200 is mounted to the machine body 100, and the via adjusting mechanism 212 is at the second position during the process of mounting the container 200 to the machine body 100. During the process of removing the container 200 from the machine body 100, the acting force of the driving mechanism 169 on the via adjusting mechanism 212 becomes smaller, and the via adjusting mechanism 212 starts to rotate from the second position until the container 200 is separated from the machine body 100, and the via adjusting mechanism 212 is in the first position.

Referring to fig. 31-35, the via hole adjusting mechanism 212 includes a shielding member 213 and a second magnetic body 214, wherein the shielding member 213 is rotatably connected to the top of the container 200, and the second magnetic body 214 is disposed on the shielding member 213 and drives the shielding member 213 to close the via hole 211. In one possible implementation, the drive mechanism 169 is provided on a side of the germicidal lamp 168 that is proximate to the communicating vessel 110. The driving mechanism 169 is a magnet, and the second magnetic body 214 is made of iron.

Referring to fig. 1 and 2, the container 200 may be pushed toward the machine body 100 to mount the container 200 to the machine body 100, and the container 200 may be pulled out to separate the container 200 from the machine body 100. The second magnet 214 is in front of the shade 213 in the advancing direction of the container 200. During the process that the container 200 is pushed to the machine body 100, the second magnetic body 214 is attracted by the driving mechanism 169 on the machine body 100 to rotate clockwise, so as to drive the shielding member 213 to rotate away from the through hole 211, thereby gradually exposing the through hole 211. When the container 200 is pulled out, as the container 200 gradually moves out, the acting force of the driving mechanism 169 on the second magnetic attraction body 214 is smaller and smaller, the second magnetic attraction body 214 rotates anticlockwise under the action of gravity of the second magnetic attraction body 214, the shielding piece 213 is driven to rotate towards the direction close to the through hole 211, and when the second magnetic attraction body 214 moves out of the magnetic attraction range of the driving mechanism 169, the second magnetic attraction body 214 falls to the initial position under the action of gravity, and the shielding piece 213 is driven to close the through hole 211.

The container 200 includes a container housing 201 and a container cover 202 covering the top of the container housing 201, a container water outlet nozzle 203 is provided on the upper portion of the container housing 201, a through hole 211, a through hole adjusting mechanism 212 and a bracket 216 are provided on the container cover 202, and the bracket 216 is located between the container water outlet nozzle 203 and the through hole 211 and protrudes toward the inside of the container 200. In one possible implementation, the bracket 216 is provided with a second rotating shaft 215, and the second rotating shaft 215 is rotatably connected to the bracket 216, and the shielding member 213 is fixedly connected to the second rotating shaft 215, so that the shielding member 213 is rotatably connected to the top of the container 200. In another possible implementation, the bracket 216 is provided with a second rotating shaft 215, and the second rotating shaft 215 is fixedly connected to the bracket 216, and the shielding member 213 is rotatably connected to the second rotating shaft 215, so that the shielding member 213 is rotatably connected to the top of the container 200.

To facilitate the user to hold and take and place the container 200, the container housing 201 is further provided with a container 200 handle 233. In one possible implementation, the container spout 203 and the handle 233 of the container 200 are respectively located on two opposite sides of the container housing 201, so as to improve the convenience of the user in use and reduce the wrist force.

Wherein the mask 213 is made of a non-magnetic material, the magnet does not attract the mask 213. Referring to fig. 33 and 35, the shielding member 213 includes a shielding plate 217 and a second limit case 218 connected to the shielding plate 217, and the second magnetic body 214 is disposed in the limit case, and in a possible implementation, the second magnetic body 214 is sealed in the limit case to avoid the second magnetic body 214 from being wetted and weakening the magnetic attraction force. When the container 200 is separated from the body 100, the cover plate 217 seals the through hole 211, and when the container 200 is mounted on the body 100, the cover plate 217 rotates in a direction approaching the container nozzle 203 and is separated from the through hole 211. By designing the second limiting box 218, on one hand, the second magnetic attraction body 214 can be fixed, and on the other hand, the attraction of the magnet to the specific surface of the second magnetic attraction body 214 can be weakened, so that the attraction of the magnet to the second magnetic attraction body 214 can drive the second magnetic attraction body 214 to rotate around the second rotating shaft 215.

The container cover 202 is provided with a circle of protrusions 221 protruding into the container 200 around the through holes 211, the cover plate 217 comprises a plug body 222 and a cover edge 223 surrounding the plug body 222, when the container 200 is mounted on the machine body 100, the plug body 222 enters the through holes 211, and the cover edge 223 clings to the protrusions 221 and seals gaps between the plug body 222 and the through holes 211. The plug body 222 may be made of a soft material, such as silicone. This configuration improves the sealing effect of the cover plate 217 against the via hole 211 in the container cover 202.

The mass of the cover plate 217 is smaller than the sum of the masses of the second magnetic attraction body 214 and the second limit case 218. The center of gravity of the via hole adjusting mechanism 212 is concentrated on the side where the second magnetic body 214 is located, and when the container 200 is separated from the machine body 100, the side of the second magnetic body 214 falls down under the action of gravity, and the cover plate 217 is tilted to automatically seal the via hole 211. When the user pours the purified water in the container 200, the container 200 tilts and the purified water flows out of the container water outlet nozzle 203, and at this time, the second magnetic body 214 is still at the low position of the via hole adjusting mechanism 212, and continuously provides a force to the via hole 211 for the cover plate 217, so that the via hole 211 can be effectively sealed during use of the container 200.

The rotation angle of the cover plate 217 is 60 ° to 150 °. If the second stop box 218 can enter the space between the container cover 202 and the bracket 216, the rotation angle of the cover plate 217 is large, and the cover plate 217 blocks little light of the germicidal lamp 168; if the second stop 218 cannot enter the space between the cover 202 and the bracket 216, the second stop 218 is blocked by the bracket 216, which results in a small rotation angle of the cover plate 217, and the cover plate 217 blocks the light of the germicidal lamp 168 more.

In one possible implementation, the distance between the rotating shaft and the container cover 202 is greater than the circumscribing circle of the cross section of the second limit box 218, so as to enlarge the rotation angle of the cover plate 217, reduce the blocking of the light of the sterilizing lamp 168 by the cover plate 217, and improve the sterilizing effect. Further, in order to prevent the blocking phenomenon during the resetting caused by the excessive rotation angle of the cover plate 217, the container 200 is further provided with a limiting structure, and specifically, the limiting structure may be a limiting surface 220 provided on the bracket 216 or a limiting member provided on the container cover 202. When the container 200 is mounted on the machine body 100, the second limiting box 218 enters the space between the rotating shaft and the container cover 202 and abuts against the limiting structure.

Referring to fig. 36-38, a faucet butt joint 234 corresponding to the structure of the container faucet 203 on the container 200 is provided on the casing 102 of the machine body 100, the container 200 is combined with the machine body 100, the container 200 is placed on the water collection box 300 so that the container faucet 203 faces the faucet butt joint 234, at this time, the via hole adjusting mechanism 212 is located at the outer side of the magnet, the second magnetic body 214 enters the magnetic attraction range of the magnet, the second magnetic body 214 approaches the magnet, and the cover plate 217 is separated from the via hole 211, as shown in fig. 36; pushing the container 200 to approach the machine body 100, as the second magnetic attraction body 214 is closer to the magnet, the second magnetic attraction body 214 is further attracted by the magnet to deflect towards the magnet, and the cover plate 217 is driven by the second magnetic attraction body 214 to deflect towards the bottom of the container 200, so that the through hole 211 is further exposed, as shown in fig. 37; the container 200 is pushed to a position combined with the machine body 100, at this time, the first water outlet 116 of the machine body 100 is communicated with the purified water inlet 204 of the container 200, the buckle 154 of the machine body 100 enters the clamping groove 208 of the container 200, the container water outlet 203 enters the water outlet nozzle butt joint part 234, the second limit box 218 abuts against the limit structure, the cover plate 217 rotates to a position between the container water outlet nozzle 203 and the through hole 211, the through hole 211 is positioned under the sterilizing lamp 168, and as shown in fig. 38, the light of the sterilizing lamp 168 can enter the container 200 through irradiation of the through hole 211, so that sterilization of purified water in the container 200 is realized.

In this embodiment, the sterilizing lamp 168 and the driving mechanism 169 are arranged on the machine body 100, the via hole 211 and the via hole adjusting mechanism 212 are arranged on the top of the container 200, when the container 200 is mounted on the machine body 100, the via hole 211 is located below the sterilizing lamp 168, the driving mechanism 169 drives the via hole adjusting mechanism 212 to rotate so that the via hole 211 is exposed, the light of the sterilizing lamp 168 can be injected into the container 200 through the via hole 211 for sterilization, and when the container 200 is separated from the machine body 100, the via hole adjusting mechanism 212 automatically closes the via hole 211 to prevent bacteria and impurities from entering the container 200 from the via hole 211. The bacteria in the container 200 mainly come from air, and the sterilizing lamp 168 is arranged above the container 200 in the embodiment, so that the liquid in the container 200 can be sterilized, and the air above the container 200 can be sterilized, so that the sterilizing effect is good.

Note that the above is only a preferred embodiment of the present disclosure and the technical principle applied. Those skilled in the art will appreciate that the present disclosure is not limited to the particular embodiments described herein, and that various obvious changes, rearrangements and substitutions can be made by those skilled in the art without departing from the scope of the disclosure. Therefore, while the present disclosure has been described in connection with the above embodiments, the present disclosure is not limited to the above embodiments, but may include many other equivalent embodiments without departing from the spirit of the present disclosure, the scope of which is determined by the scope of the appended claims.

Claims (64)

1. A drinking device, characterized by comprising a body (100) and a container (200) detachably connected to said body (100); the body (100) comprises a switching mechanism (170);

The switching mechanism (170) includes:

A support (171);

a switch (173) comprising a trigger member;

A pressing member (172) including a mounting portion and elastically disposed on the support member (171) by the mounting portion, the pressing member (172) including a pressing end surface (175), the pressing end surface (175) being disposed at a distance from the mounting portion, the pressing end surface (175) being disposed opposite to the triggering member, the pressing end surface (175) including a second plane (177);

When the container (200) applies a force to the pressing piece (172), the pressing piece (172) can move towards a first direction under the pushing action of the container (200), meanwhile, the second plane (177) approaches to the triggering component, and when the container (200) is mounted on the machine body (100), the second plane (177) presses the triggering component in a second direction to enable the switch (173) to be conducted.

2. The apparatus of claim 1, wherein the device comprises a plurality of sensors,

The second plane (177) has a length in the first direction that is greater than a first length, the first length being a maximum length that allows the container (200) to move in a direction opposite the first direction.

3. The apparatus of claim 1, wherein the device comprises a plurality of sensors,

The second direction is perpendicular to the first direction, and in the second direction, the pressing end surface (175) is located between the mounting portion and the trigger member.

4. The apparatus of claim 1, wherein the device comprises a plurality of sensors,

The support member (171) is provided with a second elastic member (174), and one end of the second elastic member (174) is connected with the support member (171) and the other end is connected with the mounting part in the elastic movement direction of the second elastic member (174), so that the pressing member (172) is elastically arranged on the support member (171);

-said pressure member (172) moves in a first direction to compress said second resilient member (174) when said container (200) applies a force to said pressure member (172); when the container (200) is disassembled, the second elastic piece (174) resets and drives the pressing piece (172) to be far away from the supporting piece (171).

5. The apparatus of claim 1, wherein the device comprises a plurality of sensors,

The extrusion end face (175) further comprises a first plane (176) and a guide surface (178) located between the first plane (176) and the second plane (177), wherein the first plane (176), the guide surface (178) and the second plane (177) sequentially contact the trigger component in the process that the pressing piece (172) moves along the first direction, and the distances between the first plane (176), the guide surface (178) and the second plane (177) and the trigger component are sequentially decreased.

6. The apparatus of claim 5, wherein the device comprises a plurality of sensors,

The trigger component comprises a trigger button (179) and a spring piece (180), wherein the trigger button (179) extends out of a switch shell of the switch (173), the spring piece (180) is provided with a fixed part (183) and a movable part (184), the fixed part (183) is connected with the switch shell, and the movable part (184) is contacted with the trigger button (179);

When the container (200) is separated from the machine body (100), the first plane (176) is in contact with the movable part (184) of the elastic sheet (180), and when the container (200) is mounted on the machine body (100), the second plane (177) presses the movable part (184), and the movable part (184) applies force to the trigger button (179) to conduct the switch (173).

7. The apparatus of claim 5, wherein the device comprises a plurality of sensors,

The trigger component comprises a trigger button (179), the trigger button (179) extends out of a switch housing of the switch (173);

When the container (200) is separated from the machine body (100), the first plane (176) is in contact with the trigger button (179), and when the container (200) is mounted on the machine body (100), the second plane (177) applies a force to the trigger button (179) to conduct the switch (173).

8. The apparatus according to claim 6 or 7, wherein,

The direction of movement of the trigger button (179) is perpendicular to the direction of movement of the follower (172).

9. The apparatus of claim 1, wherein the device comprises a plurality of sensors,

The machine body (100) comprises a base (101), a machine shell (102), a raw water tank (103), a filtering component (104), a booster pump (105) and a water outlet waterway, wherein the raw water tank (103) and the machine shell (102) are arranged on the base (101), the filtering component (104), the booster pump (105) and the water outlet waterway are arranged in the machine shell (102), and the raw water tank (103), the booster pump (105), the filtering component (104) and the water outlet waterway are sequentially connected;

The water outlet waterway comprises a communicating vessel (110), a water delivery pump (106), a heater (107) and a purified water intake, wherein a water inlet (115) of the communicating vessel (110) is communicated with the filtering assembly (104), and a second water outlet (117) of the communicating vessel (110) is communicated with the water delivery pump (106), the heater (107) and the purified water intake in sequence.

10. The apparatus of claim 4, wherein the device comprises a plurality of sensors,

The pressing piece (172) comprises a pressing rod (181), the pressing rod (181) protrudes out of the shell (102) of the machine body (100), and the long axis of the pressing rod (181) is parallel to the deformation direction of the second elastic piece (174); the switch triggering part comprises a limiting part (209) and an abutting part (210) arranged in the limiting part (209); when the container (200) is mounted on the machine body (100), the pressure lever (181) passes through the limiting part (209) and abuts against the abutting part (210).

11. The apparatus of claim 9, wherein the device comprises a plurality of sensors,

The switch mechanism (170) is arranged below the communicating vessel (110) and is close to the bottom of the machine body (100), and the switch triggering part is arranged at the bottom of the container (200).

12. The apparatus of claim 9, wherein the device comprises a plurality of sensors,

The communicating vessel (110) comprises a first containing cavity (113), a second containing cavity (114), a water level sensor and a water quantity regulating mechanism, wherein the first containing cavity (113) is provided with a water inlet (115), a first water outlet (116) and a second water outlet (117), the second containing cavity (114) is communicated with the first containing cavity (113) through a diversion hole (118), and the water level sensor is arranged in the second containing cavity (114) and is used for detecting the water level in the second containing cavity (114);

When the container (200) is mounted on the machine body (100), the water purifying inlet (204) is communicated with the first water outlet (116), and when water is injected through the water inlet (115) or taken from the second water outlet (117), the water quantity adjusting mechanism adjusts the water passing area of at least one flow guiding hole (118) so that the water level in the second containing cavity (114) is at least basically level with the water level in the container (200) and the second containing cavity (114) and the container (200) are quickly filled with water, and the water level in the second containing cavity (114) and the water level in the container (200) are at least basically level when water is taken.

13. The apparatus of claim 12, wherein the device comprises a plurality of sensors,

The container (200) is provided with a switch triggering part, when the container (200) is mounted on the machine body (100), the first water outlet (116) is communicated with the purified water inlet (204), and the switch triggering part applies force to the pressing piece (172) to enable the switch (173) to be communicated.

14. The apparatus of claim 13, wherein the device comprises a plurality of sensors,

The volume of the second containing cavity (114) is smaller than the volume of the container (200), and the water passing area of the diversion hole (118) when water is injected into the water inlet (115) is larger than the water passing area of the diversion hole (118) when water is taken out from the second water outlet (117) under the regulation action of the water quantity regulating mechanism.

15. The apparatus of claim 14, wherein the first volume (113), the second volume (114), and the container (200) are all in communication with the atmosphere.

16. The apparatus of claim 12, wherein the device comprises a plurality of sensors,

The communicating vessel (110) comprises a communicating vessel shell (111) and a partition board (112), wherein the partition board (112) divides the inner space of the communicating vessel shell (111) into a first containing cavity (113) and a second containing cavity (114), a flow guide hole (118) is formed in the lower portion of the partition board (112), an exhaust hole (119) is formed in the partition board (112), and the exhaust hole (119) is communicated with the first containing cavity (113) and the second containing cavity (114).

17. The apparatus of claim 16, wherein the device comprises a plurality of sensors,

The water quantity adjusting mechanism is arranged in the second containing cavity (114);

The water quantity adjusting mechanism comprises a stop piece, a balancing weight (129) and a first rotating shaft (130), wherein the first rotating shaft (130) is fixed on the inner wall of the second containing cavity (114), the stop piece is rotationally connected with the first rotating shaft (130), the balancing weight (129) is arranged on the stop piece to drive the stop piece to partially shield the diversion hole (118), liquid injected into the second containing cavity (114) from the diversion hole (118) can drive the stop piece to overcome the acting force of the balancing weight (129) to rotate in the direction away from the diversion hole (118), so that the water passing area of the diversion hole (118) is changed.

18. The apparatus of claim 17, wherein the device comprises a plurality of sensors,

The stopper comprises a stopper plate (131) and a first limit box (132) connected with the stopper plate (131), a shaft hole (133) is formed in the joint of the stopper plate (131) and the first limit box (132), the first rotating shaft (130) penetrates through the shaft hole (133), and the balancing weight (129) is arranged in the first limit box (132).

19. The apparatus of claim 18, wherein the device comprises a plurality of sensors,

The balancing weight (129) and the stop plates (131) are located on two sides of the first rotating shaft (130), and the gravity center of the water quantity adjusting mechanism is located on the balancing weight (129).

20. The apparatus of claim 19, wherein the device comprises a plurality of sensors,

The stop plate (131) is provided with a first surface (134) facing the partition plate (112), the first limit box (132) is provided with a second surface (135) facing the partition plate (112), the second surface (135) is far away from the partition plate (112) when the first surface (134) is attached to the partition plate (112), and the first surface (134) is far away from the partition plate (112) when the second surface (135) is attached to the partition plate (112).

21. The apparatus of claim 20, wherein the device comprises a plurality of sensors,

Be equipped with water hole (136) on backstop board (131), when backstop board (131) shelter from water conservancy diversion hole (118), water hole (136) with water conservancy diversion hole (118) part coincidence.

22. The apparatus of claim 16, wherein the device comprises a plurality of sensors,

The communicator includes a communicator housing (111);

The diversion hole (118) is provided with a first water passing part (137) and a second water passing part (138), and the cross-sectional area of the second water passing part (138) is larger than that of the first water passing part (137);

When water is injected through the water inlet (115), the second water passing part (138) is communicated with the first containing cavity (113) and the second containing cavity (114), and the first water passing part (137) is not communicated with the first containing cavity (113) and the second containing cavity (114); when water is taken through the second water outlet (117), the second water passing part (138) is not communicated with the first containing cavity (113) and the second containing cavity (114), and the first water passing part (137) is communicated with the first containing cavity (113) and the second containing cavity (114).

23. The apparatus of claim 16, wherein the device comprises a plurality of sensors,

The water quantity adjusting mechanism comprises an electromagnet (139) and a first magnetic attraction body (140), the first magnetic attraction body (140) is arranged in the communicating vessel shell (111) through a first elastic piece (141), the electromagnet (139) is arranged outside the communicating vessel shell (111),

When water is taken through the second water outlet (117), the electromagnet (139) is electrified, and the first magnetic attraction body (140) moves towards the electromagnet (139) to shield the second water passing part (138) of the diversion hole (118); when water is injected into the water inlet (115), the electromagnet (139) is powered off, and the first magnetic attraction body (140) is driven by the first elastic piece (141) to reset and shield the first water passing portion (137) of the diversion hole (118).

24. The apparatus of claim 23, wherein the device comprises a plurality of sensors,

The electromagnet (139) is arranged below the first accommodating cavity (113), the first magnetic attraction body (140) is arranged in the first accommodating cavity (113), one end of the first elastic piece (141) is connected with the bottom of the first accommodating cavity (113), and the other end of the first elastic piece is connected with the first magnetic attraction body (140); or alternatively

The electromagnet (139) is arranged below the second containing cavity (114), the first magnetic attraction body (140) is arranged in the second containing cavity (114), one end of the first elastic piece (141) is connected with the bottom of the second containing cavity (114), and the other end of the first elastic piece is connected with the first magnetic attraction body (140).

25. The apparatus of claim 13, wherein the device comprises a plurality of sensors,

The number of the diversion holes (118) is multiple, and at least part of the diversion holes (118) are correspondingly provided with the water quantity adjusting mechanism; the total water passing area of all diversion holes (118) when water is injected from the first containing cavity (113) to the second containing cavity (114) is larger than the total water passing area of all diversion holes (118) when water is discharged from the second containing cavity (114) to the first containing cavity (113).

26. The apparatus of claim 21, wherein the device comprises a plurality of sensors,

The water quantity adjusting mechanism is a one-way film which is arranged in the second containing cavity (114) and used for shielding the flow guide hole (118), when water is injected into the second containing cavity (114) from the first containing cavity (113), the one-way film moves away from the flow guide hole (118) so as to expose the flow guide hole (118), and when water is discharged from the second containing cavity (114) to the first containing cavity (113), the one-way film moves towards the direction close to the flow guide hole (118) so as to shield the flow guide hole (118).

27. The apparatus of claim 12, wherein the device comprises a plurality of sensors,

The water level sensor comprises a guide rod (142), a floating structure sleeved on the guide rod (142), and a first detection element and a second detection element which are arranged in the guide rod (142), wherein the guide rod (142) is vertically arranged in the second accommodating cavity (114), the first detection element is positioned at the lower part of the guide rod (142), the second detection element is positioned at the upper part of the guide rod (142), and the floating structure can move along the long axis of the guide rod (142) under the action of liquid buoyancy;

when the water level of the liquid in the second accommodating cavity (114) is lowered to the first position of the guide rod (142), the floating structure moves to the lower part of the guide rod (142) and triggers the first detection element, and when the water level of the liquid in the second accommodating cavity (114) is raised to the second position of the guide rod (142), the floating structure moves to the upper part of the guide rod (142) and triggers the second detection element.

28. The apparatus of claim 27, wherein the device comprises a plurality of sensors,

The machine body (100) further comprises a controller, the controller is respectively and electrically connected with the first detection element, the second detection element, the booster pump (105) and the water delivery pump (106), when the first detection element is triggered, the controller controls the water delivery pump (106) to stop working, and when the second detection element is triggered, the controller controls the booster pump (105) to stop working.

29. The apparatus of claim 27, wherein the device comprises a plurality of sensors,

The first detection element and the second detection element are magnetic reed switches, and a magnetic block is arranged in the floating structure.

30. The apparatus of claim 27, wherein the device comprises a plurality of sensors,

The floating structure comprises a first floater (145) and a second floater (146), a first water level section (147) is arranged at the lower part of the guide rod (142), a second water level section (148) is arranged at the upper part of the guide rod (142), the first floater (145) is sleeved on the guide rod (142) and can be driven by liquid buoyancy to move in the first water level section (147), the second floater (146) is sleeved on the guide rod (142) and can be driven by liquid buoyancy to move in the second water level section (148), the first detection element is arranged in the first water level section (147), the second detection element is arranged in the second water level section (148),

When the water level of the liquid in the second containing cavity (114) is reduced to the first position of the guide rod (142), the first floater (145) moves to the lower end of the first water level section (147) and triggers the first detection element, and when the water level of the liquid in the second containing cavity (114) is increased to the second position of the guide rod (142), the second floater (146) moves to the upper end of the second water level section (148) and triggers the second detection element.

31. The apparatus of claim 30, wherein the device comprises a plurality of sensors,

The guide rod (142) is sequentially provided with a first limiting part (149), a second limiting part (150), a third limiting part (151) and a fourth limiting part (152), the part of the guide rod (142) between the first limiting part (149) and the second limiting part (150) is the first water level section (147), and the part of the guide rod (142) between the third limiting part (151) and the fourth limiting part (152) is the second water level section (148).

32. The apparatus of claim 27, wherein the device comprises a plurality of sensors,

The floating structure comprises a third floater, when the water level of the liquid in the second containing cavity (114) falls to the first position of the guide rod (142), the third floater moves to the lower end of the guide rod (142) and triggers the first detection element, and when the water level of the liquid in the second containing cavity (114) rises to the second position of the guide rod (142), the third floater moves to the upper end of the guide rod (142) and triggers the second detection element.

33. The apparatus of claim 12, wherein the device comprises a plurality of sensors,

The height of the second cavity (114) is the same as the height of the inner space of the container (200).

34. The apparatus of claim 13, wherein the device comprises a plurality of sensors,

The first water outlet (116), the diversion hole (118) and the second water outlet (117) are arranged at the lower part of the communicating vessel (110), and the water inlet (115) is arranged at the upper part of the communicating vessel (110).

35. The apparatus of claim 23, wherein the device comprises a plurality of sensors,

The second water outlet (117) is arranged on the bottom surface of the communicating vessel shell (111), a partition board (112) is arranged in the communicating vessel shell (111), the flow guide hole (118) is arranged at the lower part of the partition board (112), the first water outlet (116) is arranged on the side surface, adjacent to the partition board (112), of the communicating vessel shell (111), and the second water outlet (117) is closer to the flow guide hole (118) than the first water outlet (116);

The water inlet (115) is lower than the highest water level of the communicating vessel (110).

36. The apparatus of claim 16, wherein the device comprises a plurality of sensors,

The exhaust hole (119) is provided in the upper part of the communicating vessel (110).

37. The apparatus of claim 30, wherein the device comprises a plurality of sensors,

The machine body (100) comprises a locking mechanism and a water outlet valve assembly (121) arranged at the first water outlet (116), and the container (200) comprises a bearing mechanism and a water inlet valve assembly (224) arranged at the purified water inlet (204);

When the container (200) is mounted on the machine body (100), the water inlet valve assembly (224) abuts against the water outlet valve assembly (121), the first water outlet (116) is communicated with the purified water inlet (204), and the locking mechanism is in clamping fit with the bearing mechanism; when the container (200) is separated from the machine body (100), the locking mechanism is separated from the bearing mechanism, the water outlet valve assembly (121) seals the first water outlet (116), and the water inlet valve assembly (224) seals the purified water inlet (204).

38. The apparatus of claim 37, wherein the device comprises a plurality of sensors,

The communicating vessel (110) comprises a communicating vessel shell (111), a first water guide pipe (120) is arranged on the communicating vessel shell (111) around the first water outlet (116), and the water outlet valve assembly (121) is arranged in the first water guide pipe (120).

39. The apparatus of claim 38, wherein the device comprises a plurality of sensors,

The water outlet valve assembly (121) comprises a first valve core seat (122), a first spring and a first valve core (124), the first valve core seat (122) is arranged in the first water guide pipe (120), the first valve core (124) comprises a first plug (125), a first valve rod (126) and a first limiting plate (127), one end of the first valve rod (126) is connected with the first plug (125), the other end of the first valve rod passes through a through hole of the first valve core seat (122) and then is connected with the first limiting plate (127), the first spring is abutted between the first valve core seat (122) and the first valve rod (126), the first valve core (124) can approach the first water outlet (116) under the action of external force driving so that the first plug (125) is separated from the first valve core seat (122), and the first spring can drive the first valve core (124) to reset so that the first plug (125) is connected with the through hole of the first valve core seat (122).

40. The apparatus of claim 39, wherein the device comprises a processor,

A second water guide pipe (205) is arranged on the container (200) around the purified water inlet (204), and the water inlet valve assembly (224) is arranged in the second water guide pipe (205).

41. The apparatus of claim 40, wherein the device comprises,

The water inlet valve assembly (224) comprises a second valve core seat, a second spring and a second valve core, the second valve core seat is arranged in the second water guide pipe (205) and is connected with the second water guide pipe (205) in an expanded mode, the second valve core seat comprises a first seat ring (228), a second seat ring (229) and a plurality of connecting ribs (230) for connecting the first seat ring (228) and the second seat ring (229), the second valve core comprises a second plug (231) and a second valve rod (232), one end of the second valve rod (232) is connected with the second plug (231), the other end of the second valve rod penetrates through a through hole of the second seat ring (229), and the second spring is abutted between the second seat ring (229) and the second plug (231); the second valve core can be close to the inside of the container (200) under the action of external force driving so that the second plug (231) is separated from the first seat ring (228), and the second spring can drive the second valve core to reset so that the second plug (231) seals the through hole of the first seat ring (228).

42. The apparatus of claim 40, wherein the device comprises,

The locking mechanism comprises a fixing piece (153) and a buckle (154), the fixing piece (153) is sleeved on the outer wall of the first water guide pipe (120), and the buckle (154) is connected with the fixing piece (153); the container (200) is provided with a baffle plate (206) arranged around the second water guide pipe (205), a ring groove (207) is formed between the baffle plate (206) and the second water guide pipe (205), and the receiving mechanism comprises a clamping groove (208) arranged on the baffle plate (206); when the container (200) is mounted on the machine body (100), the water inlet valve assembly (224) abuts against the water outlet valve assembly (121), the first water guide pipe (120) and the fixing piece (153) enter the annular groove (207), and the clamping buckle (154) is clamped into the clamping groove (208).

43. The apparatus of claim 42, wherein the device comprises,

The buckle (154) is provided with a fixed end (155) and a movable end (156), the fixed end (155) is connected with the fixing piece (153), the movable end (156) protrudes out of the outer wall of the fixing piece (153), a gap (157) is formed between the buckle (154) and the outer wall of the first water guide pipe (120), and the gap (157) is not smaller than the height that the movable end (156) exceeds the outer wall of the fixing piece (153).

44. The apparatus of claim 42, wherein the device comprises,

The locking mechanism further comprises a valve core sleeve (158) sleeved on the first water guide pipe (120), the valve core sleeve (158) comprises an outer ring sleeve (159), an inner ring sleeve (160) arranged in the outer ring sleeve (159) and a transition part (161) connecting the outer ring sleeve (159) and the inner ring sleeve (160), the inner ring sleeve (160) is positioned between the water outlet valve assembly (121) and the inner wall of the first water guide pipe (120), the outer ring sleeve (159) is positioned between the outer wall of the first water guide pipe (120) and the inner wall of the fixing piece (153), a movable end (156) of the buckle (154) is opposite to the outer ring sleeve (159), and the transition part (161) is positioned between the end face of the first water guide pipe (120) and the end face of the fixing piece (153).

When the container (200) is mounted on the machine body (100), the second water guide pipe (205) enters the first water guide pipe (120) and is sealed with the second water guide pipe (205) through the inner sleeve (160); when the container (200) is separated from the machine body (100), the outer ring sleeve (159) drives the movable end (156) of the buckle (154) to reset.

45. The apparatus of claim 44, wherein the device comprises,

The inner wall of the inner sleeve (160) is provided with a first convex ring (162) and a second convex ring (163), the outer wall of the inner sleeve (160) is provided with a first groove (164) corresponding to the first convex ring (162) and a second groove (165) corresponding to the second convex ring (163), the first convex ring (162) and the first groove (164) are close to the transition part (161), and the second convex ring (163) and the second groove (165) are close to the first plug (125); the height of the first convex ring (162) protruding from the inner wall of the inner sleeve (160) is larger than the height of the second convex ring (163) protruding from the inner wall of the inner sleeve (160), and the area of the first groove (164) is larger than the area of the second groove (165).

46. The apparatus of claim 42, wherein the device comprises,

The buckle (154) is close to the bottom of the machine body (100), and the clamping groove (208) is close to the bottom of the container (200).

47. The apparatus of claim 38, wherein the device comprises a plurality of sensors,

The device further comprises a shell (102), a front cover assembly (166) and a water collecting box (300), wherein the front cover assembly (166) is arranged at the upper part of the shell (102), the water collecting box (300) is detachably connected with the lower part of the shell (102), and a space for placing the container (200) is formed between the water collecting box (300) and the front cover assembly (166);

Be equipped with water outlet (167) on protecgulum subassembly (166), water outlet (167) intercommunication the water purification intake, water collecting box (300) are located first aqueduct (120) with the below of water outlet (167), be equipped with on water collecting box (300) with first drainage hole (303) that first aqueduct (120) corresponds and with second drainage hole (304) that water outlet (167) corresponds.

48. The apparatus of claim 9, wherein the device comprises a plurality of sensors,

The machine body (100) comprises a sterilizing lamp (168) and a driving mechanism (169), and the container (200) is provided with a through hole (211) and a through hole adjusting mechanism (212); when the container (200) is separated from the machine body (100), the via hole adjusting mechanism (212) is in a first position and seals the via hole (211); when the container (200) is mounted on the machine body (100), the through hole (211) is opposite to the sterilizing lamp (168), the driving mechanism (169) drives the through hole adjusting mechanism (212) to be in a second position and expose the through hole (211), and light rays of the sterilizing lamp (168) can be injected into the container (200) through the through hole (211).

49. The apparatus of claim 48, wherein the device comprises,

The driving mechanism (169) is used for driving the via hole adjusting mechanism (212) to start rotating from the first position until the container (200) is mounted to the machine body (100) during the process of mounting the container (200) to the machine body (100), and the via hole adjusting mechanism (212) is in the second position.

50. The apparatus of claim 48, wherein the device comprises,

During the process of detaching the container (200) from the machine body (100), the acting force of the driving mechanism (169) on the via hole adjusting mechanism (212) is gradually reduced, the via hole adjusting mechanism (212) starts to rotate from the second position until the container (200) is separated from the machine body (100), and the via hole adjusting mechanism (212) is in the first position.

51. The apparatus of claim 48, wherein the device comprises,

The via hole adjusting mechanism (212) comprises a shielding piece (213) and a second magnetic attraction body (214), the shielding piece (213) is rotatably connected with the top of the container (200), and the second magnetic attraction body (214) is arranged on the shielding piece (213) and drives the shielding piece (213) to seal the via hole (211).

52. The apparatus of claim 51, wherein the device comprises,

The driving mechanism (169) is arranged at one side of the sterilizing lamp (168) close to the communicating vessel (110).

53. The apparatus of claim 52, wherein the device comprises,

The driving mechanism (169) is a magnet and is used for adsorbing the second magnetic attraction body (214) when the container (200) is mounted on the machine body (100), so that the shielding piece (213) rotates in a direction away from the through hole (211).

54. The apparatus of claim 52, wherein the device comprises,

The via hole adjusting mechanism (212) further comprises a second rotating shaft (215);

The shielding piece (213) is fixed on the second rotating shaft (215), the second rotating shaft (215) is rotatably connected with the top of the container (200), or the second rotating shaft (215) is fixed on the top of the container (200), and the shielding piece (213) is rotatably connected with the second rotating shaft (215).

55. The apparatus of claim 54, wherein the device comprises,

The container (200) comprises a container shell (201) and a container cover (202) arranged at the top of the container shell (201), a container water outlet nozzle (203) is arranged at the upper part of the container shell (201), the container cover (202) is provided with a through hole (211), a through hole adjusting mechanism (212) and a support (216), the support (216) is positioned between the container water outlet nozzle (203) and the through hole (211) and protrudes towards the inside of the container (200), and the second rotating shaft (215) is arranged on the support (216).

56. The apparatus of claim 55, wherein the device comprises,

The shielding piece (213) is made of a non-magnetic material and comprises a cover plate (217) and a second limit box (218) connected with the cover plate (217), and the second magnetic attraction body (214) is arranged in the second limit box (218); when the container (200) is separated from the machine body (100), the cover plate (217) seals the through hole (211), and when the container (200) is mounted on the machine body (100), the cover plate (217) rotates in a direction approaching the container water outlet nozzle (203) and is separated from the through hole (211).

57. The apparatus of claim 56, wherein,

The distance between the second rotating shaft (215) and the container cover (202) is greater than the circumcircle of the cross section of the second limit box (218), a limit structure is further arranged on the container (200), and when the container (200) is installed on the machine body (100), the second limit box (218) enters a space between the second rotating shaft (215) and the container cover (202) and is abutted to the limit structure.

58. The apparatus of claim 57, wherein the device comprises a processor,

The limiting structure is a limiting surface (220) arranged on the bracket (216) or a limiting piece arranged on the container cover (202).

59. The apparatus of claim 56, wherein,

The center of gravity of the second magnetic body (214) is located between the center line of the second rotating shaft (215) and the container water outlet nozzle (203) in a state that the cover plate (217) seals the through hole (211).

60. The apparatus of claim 56, wherein,

The container cover (202) is provided with a circle of protrusions (221) protruding towards the inside of the container (200) around the through holes (211), the cover plate (217) comprises a plug body (222) and a cover edge (223) surrounding the plug body (222), when the container (200) is installed on the machine body (100), the plug body (222) enters the through holes (211), and the cover edge (223) is tightly attached to the protrusions (221) and seals gaps between the plug body (222) and the through holes (211).

61. The apparatus of claim 56, wherein,

The rotation angle of the cover plate (217) is 60-150 degrees.

62. The apparatus of claim 56, wherein,

The mass of the cover plate (217) is smaller than the sum of the mass of the second magnetic attraction body (214) and the mass of the second limit box (218).

63. The apparatus of claim 51, wherein the device comprises,

When the via hole adjusting mechanism (212) is at the second position, the driving mechanism (169) is positioned between the second magnetic attraction body (214) and the sterilizing lamp (168).

64. The apparatus of claim 51, wherein the device comprises,

In the moving direction of the container (200), the front projection of the driving mechanism (169) is positioned between the front projection of the second magnetic attraction body (214) and the front projection of the sterilizing lamp (168).