CN219126428U

CN219126428U - Ultrasonic diagnostic apparatus

Info

Publication number: CN219126428U
Application number: CN202222918926.1U
Authority: CN
Inventors: 胡俊; 王友祥
Original assignee: Shenzhen Mindray Bio Medical Electronics Co Ltd
Current assignee: Shenzhen Mindray Bio Medical Electronics Co Ltd
Priority date: 2022-10-31
Filing date: 2022-10-31
Publication date: 2023-06-06
Anticipated expiration: 2032-10-31

Abstract

The utility model discloses an ultrasonic diagnostic apparatus, which comprises a display, a control panel and a host, wherein the host comprises a host shell, a socket, a first control main board and an illuminating lamp component, the display and the control panel are respectively and electrically connected with the first control main board, the socket is arranged on the host shell and is electrically connected with the first control main board, the illuminating lamp component is electrically connected with the first control main board and is used for illuminating the area where the socket is positioned, and the host shell comprises: the shell main body, the socket and the lighting lamp assembly are all arranged on the shell main body; the probe cover has a first state connected with the housing body and covering the socket and a second state separated from the housing body, wherein the ultrasonic diagnostic apparatus is configured to switch from the first state to the second state in response to the probe cover for controlling the illumination lamp assembly to be turned off. In this scheme, thereby first control mainboard can acquire the state that the probe covered through the electric connection state that obtains first contact and second contact, has promoted the convenience that user control light was lighted.

Description

Ultrasonic diagnostic apparatus

Technical Field

The utility model relates to the technical field of medical equipment, in particular to an ultrasonic diagnostic apparatus.

Background

When the ultrasonic equipment is in a use environment with darker light, the probe is inconvenient to replace by a user. The switch mode of the lighting device for changing the probe is troublesome in the ultrasonic device in the current market, the lighting device is turned on after a user presses the lighting switch when the ultrasonic device is used, the lighting device can be turned off after the user presses the lighting switch after the ultrasonic device is used up, and the operation process is intelligent and convenient.

Disclosure of Invention

The utility model mainly aims to provide an ultrasonic diagnostic apparatus which can improve convenience for a user to control an illuminating lamp.

In order to achieve the above object, the present utility model provides an ultrasonic diagnostic apparatus, comprising a display, a control panel and a host, wherein the host comprises a host housing, a socket, a first control main board and an illumination lamp assembly, the display and the control panel are respectively and electrically connected to the first control main board, the socket is mounted on the host housing and electrically connected to the first control main board, the socket is used for electrically connecting with a probe assembly, the illumination lamp assembly is electrically connected to the first control main board and is used for illuminating an area where the socket is located, and the host housing comprises:

The shell main body, the socket and the lighting lamp assembly are arranged on the shell main body, and the shell main body is provided with a first contact electrically connected with the first control main board;

a probe cover having a first state connected to the housing main body and covering the socket, and a second state separated from the housing main body, the probe cover being connected with a second contact, the second contact being in contact with the first contact and electrically connected to each other in the first state;

the ultrasonic diagnostic apparatus is configured to respond to the probe cover to be switched from the first state to the second state, the first control main board obtains that the first contact and the second contact are changed from the mutually electric connection state to the mutually disconnection state, and then a first control signal is generated, and the first control signal is used for controlling the lighting lamp assembly to be lightened; the ultrasonic diagnostic apparatus is further configured to generate a second control signal in response to the probe cover being switched from the second state to the first state, wherein the first control main board obtains that the first contact and the second contact are switched from a state of being disconnected from each other to a state of being electrically connected with each other, and the second control signal is used for controlling the lighting lamp assembly to be turned off.

In some embodiments, the first control motherboard includes a timing module for causing the first control motherboard to generate a third control signal after a first preset time for generating the first control signal, the third control signal for controlling the lighting lamp assembly to be turned off.

In some embodiments, the shell body is further provided with a third contact, a second control main board is arranged in the probe cover, a fourth contact electrically connected with the second control main board is arranged in the probe cover, and the third contact is contacted with and electrically connected with the fourth contact in the first state of the probe cover;

the ultrasonic diagnostic apparatus further comprises an atmosphere lamp assembly, the atmosphere lamp assembly is arranged on the periphery of the probe cover, the ultrasonic diagnostic apparatus is configured to respond to the probe cover to be switched from the second state to the first state, the second control main board obtains that the first contact and the second contact are changed from a disconnected state to an electrically connected state, and then a fourth control signal is generated, and the fourth control signal is used for controlling the atmosphere lamp assembly to light; the ultrasonic diagnostic apparatus is further configured to generate a fifth control signal after the second control main board obtains that the first contact and the second contact are changed from the mutually electric connection state to the mutually disconnection state in response to the probe cover being switched from the first state to the second state, and the fifth control signal is used for controlling the atmosphere lamp assembly to be turned off.

In some embodiments, the atmosphere lamp assembly comprises:

the first connecting pipe is provided with a first connecting groove in a concave mode at one end, and a second connecting groove in a concave mode at the opposite end, and the first connecting groove and the second connecting groove are communicated with each other;

the first light-emitting element is connected to the first connecting groove;

a first optical fiber having a first end and a second end opposite to each other, wherein the first end is connected to the second connection groove, and the light emitted by the first light emitting element can enter the first end and be conducted to the second end;

wherein the first optical fiber is disposed at an outer periphery of the probe cover.

In some embodiments, an annular protrusion is disposed in the first connection pipe and located between the first connection groove and the second connection groove, and an internal through hole of the annular protrusion is respectively communicated with the first connection groove and the second connection groove, and the annular protrusion has an annular end face away from the first light-emitting element, and the annular end face abuts against an end face of the first end facing the first light-emitting element.

In some embodiments, the first connecting groove comprises a first groove section and a second groove section communicated with the first groove section, the second groove section is positioned at the end part of the first connecting pipe, which is away from the second connecting groove, the inner diameter of the second groove section is larger than the inner diameter of the first groove section, and the inner periphery of the second groove section comprises a first arc-shaped surface and a first plane connected with the first arc-shaped surface;

The light-emitting element comprises a light-emitting part and a connecting part connected to one end of the light-emitting part, the light-emitting part is arranged on the first groove section, the connecting part is arranged on the second groove section, the periphery of the connecting part is provided with a second arc-shaped surface and a second plane connected with the second arc-shaped surface, the second arc-shaped surface is abutted to the first arc-shaped surface, and the second plane is abutted to the first plane.

In some embodiments, the atmosphere lamp assembly further comprises:

a second connecting pipe, one end of which is concavely provided with a third connecting groove, and the other opposite end of which is concavely provided with a fourth connecting groove, wherein the third connecting groove and the fourth connecting groove are communicated with each other;

a second light emitting element connected to the third connection groove;

the second end is connected to the fourth connecting groove, and light emitted by the second light-emitting element can enter the second end and be conducted to the first end.

In some embodiments, the periphery of a side wall of the probe cover is provided with a first accommodation groove extending along the circumferential direction of the probe cover, the atmosphere lamp assembly is arranged in the first accommodation groove, the probe cover further comprises a first light-transmitting cover plate, and the first light-transmitting cover plate is arranged at the notch position of the first accommodation groove.

In some embodiments, the wall surface of the first light-transmitting cover plate facing the first accommodating groove is provided with a second accommodating groove, the second accommodating groove and the first accommodating groove jointly form a first accommodating cavity for accommodating the atmosphere lamp assembly, the first light-transmitting cover plate is provided with a first rib plate, the first rib plate is abutted to the wall surface of the first connecting pipe, the first accommodating groove is internally provided with a second rib plate, and the second rib plate is abutted to the wall surface of the first connecting pipe.

In some embodiments, the housing body is provided with a first recess, the first contact is disposed in the first recess, the probe cover is provided with a first protrusion, the second contact is disposed at an end of the first protrusion, and in the first state of the probe cover, the first protrusion extends into the first recess.

In some embodiments, the shell body is provided with a first magnetic part and a second magnetic part, the first magnetic part and the second magnetic part are arranged close to two opposite ends of the first groove in a one-to-one correspondence manner, the probe cover is provided with a third magnetic part and a fourth magnetic part, the third magnetic part and the fourth magnetic part are arranged at two opposite ends of the first protrusion in a one-to-one correspondence manner, the probe cover is in the first state, the first magnetic part is in magnetic attraction connection with the third magnetic part, and the second magnetic part is in magnetic attraction connection with the fourth magnetic part.

In some embodiments, the housing body is provided with a distance sensor, and the ultrasonic diagnostic apparatus is configured to control the illumination lamp assembly to be illuminated by the first control main board and to maintain a first preset time in response to the distance sensor sensing that a distance of a human body approaching the socket is less than a preset distance.

In some embodiments, a touch switch is disposed on the control panel, and the ultrasonic diagnostic apparatus is configured to control the illumination lamp assembly to be turned on by the first control main board and to maintain a first preset time in response to the touch switch acquiring a touch operation.

The second aspect of the present application also provides an ultrasonic diagnostic apparatus, including display, control panel and host computer, the host computer includes host computer shell, socket, first control mainboard and light subassembly, display and control panel respectively the electricity connect in first control mainboard, the socket install in host computer shell and electricity connect in first control mainboard, the socket is used for the electricity to connect the probe, the light subassembly with first control mainboard electricity is connected and is used for shining the region that the socket is located, the host computer shell includes the shell main part, the shell main part is equipped with the distance sensor, the ultrasonic diagnostic apparatus is configured to respond to the distance sensor senses that the human body is close to the distance of socket is less than the distance of predetermineeing, first control mainboard control light subassembly lights to keep first default time.

The third aspect of the present application further provides an ultrasonic diagnostic apparatus, including display, control panel and host computer, the host computer includes host computer shell, socket, first control mainboard and light subassembly, display and control panel respectively the electricity connect in first control mainboard, the socket install in host computer shell and electricity connect in first control mainboard, the socket is used for the electricity to connect the probe, the light subassembly with first control mainboard electricity is connected and is used for shining the region that the socket is located, the host computer shell includes the shell main part, be provided with touch switch on the control panel, the ultrasonic diagnostic apparatus is configured to respond to touch switch obtains touch operation, first control mainboard control light subassembly lights to keep first default time.

In some embodiments, the housing body includes a first sidewall including an interior recess, the receptacle being mounted to the interior recess;

the concave part is including being located the periphery, the periphery is towards the inside sunken arc of shell main part, the light connect in the periphery, the light is located the top of socket, the light is configured to follow slope decurrent direction illumination the socket.

In some embodiments, the lighting lamp assembly comprises a third light emitting element, a light homogenizing member and a light guide member, the lighting lamp assembly is arranged on the inner side of the peripheral wall, a light hole is formed in the peripheral wall, the light guide member covers the light hole, the light homogenizing member is attached to the wall surface, deviating from the light hole, of the light guide member, and the third light emitting element is arranged on one side, deviating from the light guide member, of the light homogenizing member.

In some embodiments, a second groove is formed in a side, facing away from the light guide member, of the light homogenizing member, the third light emitting element is disposed in the second groove, a third groove is formed in a side, facing away from the light hole, of the light guide member, and the light homogenizing member is disposed in the third groove.

In some embodiments, the lighting lamp assembly includes a plurality of the third light emitting elements, each of the third light emitting elements is arranged at intervals in a lateral direction, the second groove is a bar-shaped groove extending in the lateral direction, the third groove is a bar-shaped groove extending in the lateral direction, and the light hole is a bar-shaped hole extending in the lateral direction.

Compared with the prior art, the utility model has the beneficial effects that:

in the technical scheme of the utility model, the first contact is arranged on the shell main body, the second contact is arranged on the probe cover, when the probe cover is connected to the shell main body, the first contact and the second contact are abutted and electrically connected with each other, and when the probe cover is separated from the shell main body, the first contact and the second contact are separated. The first control main board can acquire the state of covering the probe by acquiring the electric connection state of the first contact and the second contact. In the application, the ultrasonic diagnostic apparatus is configured to generate a first control signal after the probe cover is switched from the first state to the second state (i.e., the probe cover is removed from the shell body), and the first control main board obtains that the first contact and the second contact are switched from the mutually electric connection state to the mutually disconnection state, and the first control signal is used for controlling the lighting lamp assembly to be lightened. The ultrasonic diagnostic apparatus is further configured to generate a second control signal for controlling the illumination lamp assembly to be turned off after the first control main board acquires that the first contact and the second contact are changed from the mutually disconnected state to the mutually electrically connected state in response to the probe cover being switched from the second state to the first state (i.e., the probe cover is re-covered onto the housing main body). In the above-mentioned scheme, when the user needs to use or change the probe subassembly, take off the probe and cover and can make the light subassembly light to make the region that the socket is located light, made things convenient for the user to take or change the probe subassembly, and this process user need not the switching of extra control light subassembly, has promoted the convenience of user to the light subassembly control.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic side view of an ultrasonic diagnostic apparatus according to an embodiment of the present utility model;

FIG. 2 is a schematic perspective view of a mainframe of an ultrasonic diagnostic apparatus according to an embodiment of the present utility model;

FIG. 3 is a schematic perspective view of a mainframe of an ultrasonic diagnostic apparatus according to an embodiment of the present utility model; wherein the probe cover is removed;

FIG. 4 is an enlarged partial schematic view of FIG. 3A;

FIG. 5 is a schematic rear view of a probe cover in accordance with an embodiment of the utility model;

FIG. 6 is an enlarged partial schematic view at B in FIG. 5;

FIG. 7 is a cross-sectional view of a first side wall of an ultrasonic diagnostic apparatus according to an embodiment of the present utility model;

FIG. 8 is an enlarged partial schematic view of FIG. 7 at C;

FIG. 9 is a partially enlarged schematic illustration of FIG. 7 at D;

FIG. 10 is a cross-sectional view of a probe cover attached to a first sidewall in combination in accordance with one embodiment of the utility model;

FIG. 11 is an enlarged partial schematic view of FIG. 10 at E;

FIG. 12 is a schematic view of an explosion of a portion of an atmosphere lamp assembly of an ultrasonic diagnostic apparatus according to an embodiment of the present utility model;

FIG. 13 is an exploded schematic view of a partial cross-sectional view of an atmosphere lamp assembly of an ultrasonic diagnostic apparatus in accordance with an embodiment of the present utility model;

FIG. 14 is an enlarged partial schematic view of FIG. 13 at E;

FIG. 15 is a schematic cross-sectional view of a partial combination of a second connection tube, a second light emitting element, and a second end of a first optical fiber in an ambient light assembly of an ultrasonic diagnostic apparatus according to an embodiment of the present utility model;

FIG. 16 is an exploded view of a probe cover and atmosphere lamp assembly combination of an ultrasonic diagnostic apparatus according to an embodiment of the present utility model;

FIG. 17 is a schematic view in partial cross-section of a probe cover and atmosphere lamp assembly combination of an ultrasonic diagnostic apparatus according to an embodiment of the present utility model.

Reference numerals illustrate:

10-an ultrasonic diagnostic apparatus;

a 100-display;

200-a control panel;

300-host computer;

310-a main housing; 311-shell body; 3111-a first sidewall; 3112-recesses; 3113-peripheral walls; 3114-light holes; 3115-first groove; 3116-a first magnetic member; 3117-a second magnetic member; 3118-first contacts; 3119-third contacts; 312-probe covering; 3121-a first receiving slot; 3124-a first light transmissive cover plate; 3125-a first protrusion; 3126-a second contact; 3127-fourth contacts; 3128—a third magnetic member; 3129-fourth magnetic elements;

320-a probe assembly;

330-mounting base;

340-a socket;

350-an illumination lamp assembly; 351-a third light emitting element; 352-light homogenizing element; 3521-a second groove; 353-a light guide; 3531-third groove;

360-atmosphere lamp assembly; 361-a first light emitting element; 3611-a light-emitting portion; 3612-connecting part; 3613-a second arcuate surface; 3614-a second plane; 362-a first connection tube; 3621-first connecting groove; 36211-first groove section; 36212-second groove section; 36213—a first arcuate surface; 36214-a first plane; 3622-a second connecting groove; 363-annular projection; 3631-annular end face; 364-a first optical fiber; 3641-a first end; 3642-second end; 365-a second light emitting element; 366-second connecting pipe;

410-a first mechanical arm;

420-a second mechanical arm.

The achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that, if a directional indication (such as up, down, left, right, front, and rear … …) is included in the embodiment of the present utility model, the directional indication is merely used to explain a relative positional relationship, a movement condition, and the like between the components in a specific posture, and if the specific posture is changed, the directional indication is correspondingly changed.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present utility model, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, if "and/or", "and/or" and/or "are used throughout, the meaning includes three parallel schemes, for example," a and/or B ", including a scheme, or B scheme, or a scheme where a and B meet simultaneously. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

Referring to fig. 1 to 17, an embodiment of the present utility model provides an ultrasonic diagnostic apparatus 10, and the ultrasonic diagnostic apparatus 10 specifically includes a display 100, a control panel 200, and a host 300. The control panel 200 and the display 100 are electrically connected to the host 300, respectively (specifically, electrically connected to a first control motherboard (not shown) in the host 300). Referring to fig. 1-3, in some embodiments, the ultrasonic diagnostic apparatus 10 may further comprise a mount 330, a first robotic arm 410, and a second robotic arm 420. The mounting base 330 is connected to the upper portion of the host 300, one end of the first mechanical arm 410 is connected to the mounting base 330, and the other end is connected to the control panel 200. One end of the second mechanical arm 420 is connected to one end of the first mechanical arm 410 facing away from the mounting seat 330, and the other end is connected to the display 100. The display 100 may display pattern information and text information. At least one of a physical button, a physical knob or a touch screen may be disposed on the control panel 200, and the control parameters of the ultrasonic diagnostic apparatus 10 may be correspondingly adjusted by operating the physical button, the physical knob or the touch screen.

The host 300 includes a host housing 310, a socket 340, an illumination lamp assembly 350, and a first control motherboard. Main housing 310 includes a housing body 311 and a probe cover 312. The socket 340 and the lamp assembly 350 are mounted to the housing body 311, and the housing body 311 is provided with a first contact 3118 electrically connected to the first control board. The probe cover 312 has a first state of being connected to the housing main body 311 and covering the receptacle 340, and a second state of being separated from the housing main body 311. The probe cover 312 is connected with the second contact 3126, the second contact 3126 is in contact with the first contact 3118 and electrically connected to each other in the first state of the probe cover 312, the probe cover 312 is separated from the housing main body 311 in the second state of the probe cover 312, and the first contact 3118 and the second contact 3126 are separated from each other.

The socket 340 is connected to the case body 311 and electrically connected to the first control main board. In some embodiments, the ultrasonic diagnostic apparatus 10 may further include a probe assembly 320, where the probe assembly 320 is electrically connected to the socket 340, so as to achieve the purpose of electrically connecting the probe assembly 320 to the first control main board. After the probe assembly 320 is electrically connected to the first control motherboard, on one hand, electrical energy can be obtained from the host computer 300, on the other hand, the detected data can be transmitted to the first control motherboard, the first control motherboard obtains the data and then performs analysis processing to form an image signal, and the display 100 obtains the image signal and then displays a corresponding image.

The lamp assembly 350 is electrically connected to the first control board and is used for illuminating the area where the socket 340 is located. The location of the connection of the lamp assembly 350 is determined by the specific requirements, and only the area where the socket 340 is located need be illuminated. In some embodiments, the lamp assembly 350 can be mounted to the housing body 311, and in other embodiments, the lamp assembly 350 can be mounted to the control panel 200. For convenience of description, a structure in which the illumination lamp assembly 350 is mounted to the housing main body 311 and is mounted in a position where the probe cover 312 is covered by the illumination lamp assembly 350 on the housing main body 311 in the first state will be described below as an example.

In the present utility model, a first contact 3118 is provided on a housing main body 311, and a second contact 3126 is provided on a probe cover 312, the first contact 3118 and the second contact 3126 are abutted against and electrically connected to each other when the probe cover 312 is connected to the housing main body 311, and the first contact 3118 and the second contact 3126 are separated when the probe cover 312 is separated from the housing main body 311. The first control motherboard can acquire the state of the probe cover 312 by acquiring the electrical connection state of the first contact 3118 and the second contact 3126. And, the ultrasonic diagnostic apparatus 10 is configured to generate a first control signal for controlling the illumination lamp assembly 350 to illuminate after the first control main board acquires the first contact 3118 and the second contact 3126 to be changed from the electrically connected state to the disconnected state after the probe cover 312 is switched from the first state to the second state (i.e., after the probe cover 312 is removed from the housing main body 311). The ultrasonic diagnostic apparatus 10 is further configured to generate a second control signal for controlling the lamp assembly 350 to be turned off in response to the probe cover 312 being switched from the second state to the first state (i.e., the probe cover 312 being re-covered onto the housing body 311), after the first control main board acquires that the first contact 3118 and the second contact 3126 are changed from the mutually disconnected state to the mutually electrically connected state. In the above-mentioned scheme, when the user needs to use or change probe subassembly 320, take off probe cover 312 can make light subassembly 350 light to make the region that socket 340 is located light, made things convenient for the user to take or change probe subassembly 320, and this process user need not the switching of extra control light subassembly 350, has promoted the convenience of user to light subassembly 350 control.

It is contemplated that the user may remove the probe cover 312 and then reinstall the probe cover 312 to the housing body 311 for a longer period of time, which may cause the lamp assembly 350 to be lit for an excessive amount of time, thereby rendering the lamp assembly 350 ineffective. In view of this, in some embodiments, the first control motherboard includes a timing module for causing the first control motherboard to generate a third control signal after a first preset time for generating the first control signal, the third control signal being for controlling the illumination lamp assembly 350 to be turned off. Specifically, the first preset time may be less than or equal to one minute. Illustratively, the first preset time may be thirty seconds, forty seconds, fifty seconds, or one minute. The first preset time is taken as an example of one minute. In this solution, when the user removes the probe cover 312, the first control main board generates a first control signal, the first control signal controls the lighting lamp assembly 350 to light up, and after the lighting lamp assembly 350 lights up for one minute, the first control main board generates a third control signal, and the third control signal controls the lighting lamp assembly 350 to turn off. In this scheme for light assembly 350 can light one minute back self-closing, on the one hand has further promoted the convenience to light assembly 350 control, on the other hand also can reduce the invalid illumination time of light assembly 350, has practiced thrift the electric power cost.

It should be noted that, after the first control main board generates the first control signal, the illumination lamp is turned on, if the probe cover 312 is mounted on the shell main body 311 within the first preset time after the first control main board generates the first control signal, the first control main board generates the second control signal for turning off the illumination lamp assembly 350, and then the illumination lamp is not required to be turned off again. In some embodiments, the first control motherboard may not subsequently generate the third control signal, thereby causing the light assembly 350 to remain in an off state. In other embodiments, the first control motherboard may still generate the third control signal after a first preset time after generating the first control signal, and the lighting lamp assembly 350 is turned off again after acquiring the third control signal (at this time, the atmosphere lamp assembly 360 is still turned off).

In order to enable the first contact 3118 to accurately contact the second contact 3126 after the probe cover 312 is mounted to the housing body 311, referring to fig. 4 and 7-9, in some embodiments the housing body 311 is provided with a first recess 3115, the first contact 3118 being disposed within the first recess 3115. The probe cover 312 is provided with a first protrusion 3125 and a second contact 3126 is provided at an end of the first protrusion 3125, the first protrusion 3125 protruding into the first recess 3115 in the first state of the probe cover 312 and allowing the first contact 3118 to contact and electrically connect with the second contact 3126. In this solution, on the one hand, the cooperation of the first protrusion 3125 and the second groove 3521 can make the connection between the probe cover 312 and the housing body 311 more stable, so that the probe cover 312 is difficult to slide along the lateral direction relative to the housing body 311, on the other hand, the guiding action of the probe cover 312 can be given to the probe cover 312 in the process that the first protrusion 3125 stretches into the first groove 3115, so that the positioning position of the probe cover 312 on the housing body 311 is more accurate, and the first contact 3118 can more accurately contact with the second contact 3126, so that the problem that when the probe cover 312 is mounted on the housing body 311, positional misalignment is generated between the first contact 3118 and the second contact 3126, and thus no good electrical connection is performed between the two contacts is effectively avoided.

Further, in some embodiments, the housing body 311 is provided with a first magnetic member 3116 and a second magnetic member 3117, and the first magnetic member 3116 and the second magnetic member 3117 are disposed adjacent to opposite ends of the first recess 3115. In other words, one side of the first groove 3115 is provided with a first magnetic member 3116, and the opposite side of the first groove 3115 is provided with a second magnetic member 3117. The first magnetic element 3116 and the second magnetic element 3117 may be disposed on the upper and lower sides or the lateral sides of the first recess 3115, respectively, in this embodiment, the first magnetic element 3116 and the second magnetic element 3117 are disposed on the lateral sides of the first recess 3115, respectively. Correspondingly, third magnetic member 3128 and fourth magnetic member 3129 are disposed on probe covering 312, with third magnetic member 3128 and fourth magnetic member 3129 being disposed at opposite ends of first protrusion 3125 in a one-to-one correspondence. In other words, one side of the first protrusion 3125 is provided with the third magnetic member 3128, the opposite side of the first protrusion 3125 is provided with the fourth magnetic member 3129, the third magnetic member 3128 and the fourth magnetic member 3129 may be respectively disposed at the upper and lower sides or the lateral sides of the first protrusion 3125, when the first magnetic member 3116 and the second magnetic member 3117 are respectively disposed at the lateral sides of the first recess 3115, the third magnetic member 3128 and the fourth magnetic member 3129 are respectively disposed at the lateral sides of the first protrusion 3125, thereby facilitating the magnetic connection of the first magnetic member 3116 and the third magnetic member 3128 and the magnetic connection of the second magnetic member 3117 and the fourth magnetic member 3129 when the probe cover 312 is in the first state. In the above-mentioned scheme, on the one hand, make the probe cover 312 and the shell main body 311 detachably connected through the mode of magnetic attraction, promoted the convenience that the probe cover 312 was installed and was dismantled, on the other hand, the magnetic attraction between first magnetic part 3116 and third magnetic part 3128 and the magnetic attraction between second magnetic part 3117 and fourth magnetic part 3129 can also provide the extrusion force between first contact 3118 and second contact 3126, reduced the probability that contact failure appears between first contact 3118 and the second contact 3126.

In order to make the lighting effect of the ultrasonic diagnostic apparatus 10 better, an atmosphere lamp assembly 360 may be provided on the ultrasonic diagnostic apparatus 10. Specifically, in some embodiments, the housing body 311 is further provided with a third contact 3119, the probe cover 312 is provided with a second control motherboard therein, the probe cover 312 is provided with a fourth contact 3127 electrically connected to the second control motherboard, the third contact 3119 is in contact with and electrically connected to the fourth contact 3127 in the first state of the probe cover 312, and the third contact 3119 is separated from the fourth contact 3127 in the second state of the probe cover 312. The atmosphere lamp assembly 360 of the ultrasonic diagnostic apparatus 10 is disposed at the outer periphery of the probe cover 312, and the ultrasonic diagnostic apparatus 10 is configured to generate a fourth control signal for controlling the atmosphere lamp assembly 360 to be turned on after the second control main board acquires that the first contact 3118 and the second contact 3126 are changed from the off state to the electrically connected state in response to the probe cover 312 being switched from the second state to the first state. The ultrasonic diagnostic apparatus 10 is further configured to generate a fifth control signal for controlling the atmosphere lamp assembly 360 to be turned off after the second control main board acquires that the first contact 3118 and the second contact 3126 are changed from the electrically connected state to the disconnected state in response to the probe cover 312 being switched from the first state to the second state. In other words, when the probe cover 312 is separated from the housing body 311, the first control board controls the illumination lamp assembly 350 to illuminate the area where the socket 340 is located, and the second control board controls the atmosphere lamp assembly 360 to be turned off. When the probe cover 312 is subsequently connected to the housing body 311, the first control board controls the lighting lamp assembly 350 to be turned off, and the second control board controls the atmosphere lamp assembly 360 to be turned on. This scheme can make atmosphere lamp subassembly 360 can illuminate the at least partial outline that probe covered 312 when probe cover 312 installs in shell main part 311 on the one hand, and convenience of customers discerns probe cover 312's arrangement position under the dim light environment to can accurately take off probe cover 312, on the other hand also can be through the connection of probe cover 312 in dismantling thereby realize atmosphere lamp subassembly 360's automatic control, promoted the convenience of control atmosphere lamp subassembly 360 switching.

When the third contact 3119 is provided on the housing body 311 and the fourth contact 3127 is provided on the probe cover 312, in some embodiments, referring to fig. 6-7 and 11, the third contact 3119 may be provided within the first recess 3115 of the housing body 311 and the fourth contact 3127 may be provided at an end of the first protrusion 3125. So that the magnetic attraction between the first magnetic member 3116 and the third magnetic member 3128 and the magnetic attraction between the second magnetic member 3117 and the fourth magnetic member 3129 can provide a compressive force between the third contact 3119 and the fourth contact 3127, the chance of poor contact between the third contact 3119 and the fourth contact 3127 is reduced.

Referring to fig. 12-15, in some embodiments, the ambient light assembly 360 includes a first connection tube 362, a first light emitting element 361, and a first optical fiber 364. The first connection pipe 362 is concavely provided with a first connection groove 3621 at one end and a second connection groove 3622 at the opposite end, and the first connection groove 3621 and the second connection groove 3622 communicate with each other. The first light emitting element 361 is connected to the first connection groove 3621. The first optical fiber 364 has a first end 3641 and a second end 3642 opposite to each other, the first end 3641 is connected to the second connecting slot 3622, and the light emitted by the first light emitting element 361 can enter the first end 3641 and be conducted to the second end 3642. Wherein the first optical fiber 364 is disposed at the outer periphery of the probe cover 312. In this embodiment, the light emitted by the first light emitting element 361 enters the first end 3641 of the first optical fiber 364 and propagates to the second end 3642 of the first optical fiber 364 along the length direction of the first optical fiber 364, i.e. the first optical fiber 364 is used to display the strip-shaped light band effect in this embodiment. Compared with the technical scheme that a plurality of linearly arranged lamp beads are adopted to display the light band effect in the prior art, the light emitted by the first light-emitting element 361 cannot directly irradiate eyes of a user, so that comfort of the user in observing the atmosphere lamp is improved. And, the first optical fiber 364 is used for transmitting light, so that the light emitting effect is softer and more uniform. Also, the first optical fiber 364 of the atmosphere lamp is provided at the outer periphery of the probe cover 312, and the atmosphere lamp can mark the arrangement position of the probe cover 312 when the ultrasonic diagnostic apparatus 10 is in a dark environment, and also can show at least a partial outline of the probe cover 312, so that the user can accurately observe the arrangement position of the probe cover 312.

To facilitate positioning of the first optical fiber 364, in some embodiments, an annular protrusion 363 is disposed within the first connection tube 362 between the first connection slot 3621 and the second connection slot 3622, with an interior through-hole of the annular protrusion 363 communicating with the first connection slot 3621 and the second connection slot 3622, respectively, the annular protrusion 363 having an annular end face 3631 facing away from the first light-emitting element 361, the annular end face 3631 abutting an end face of the first end 3641 facing the first light-emitting element 361. In this aspect, the first end 3641 of the first optical fiber 364 is positioned by the annular protrusion 363 disposed between the first and

second connection grooves

3621 and 3622, so that the relative position between the first light emitting element 361 and the first end 3641 of the first optical fiber 364 can be made more accurate.

Referring to fig. 12, in some embodiments, first connecting slot 3621 includes a first slot segment 36211 and a second slot segment 36212 in communication with first slot segment 36211, second slot segment 36212 is located at an end of first connecting tube 362 facing away from second connecting slot 3622, an inner diameter of second slot segment 36212 is greater than an inner diameter of first slot segment 36211, and an inner circumference of second slot segment 36212 includes a first arcuate surface 36213 and a first planar surface 36214 connected to first arcuate surface 36213. The light emitting element includes a light emitting portion 3611 and a connecting portion 3612 connected to one end of the light emitting portion 3611, the light emitting portion 3611 is provided in the first groove section 36211, the connecting portion 3612 is provided in the second groove section 36212, a second arc surface 3613 and a second plane 3614 connected to the second arc surface 3613 are provided on an outer periphery of the connecting portion 3612, the second arc surface 3613 abuts against the first arc surface 36213, and the second plane 3614 abuts against the first plane 36214. In this solution, after the first light-emitting element 361 is positioned on the first connection tube 362, the first light-emitting element 361 is difficult to rotate along the direction around the axis of the first connection tube 362 relative to the first connection tube 362, so that after the position of the wire of the atmosphere lamp assembly 360 is fixed, the position of each power supply contact of the first light-emitting element 361 is determined, which facilitates the electrical connection between the first light-emitting element 361 and the power supply board.

The first optical fiber 364 may have only the first end 3641 provided with the light emitting element, and the first optical fiber 364 may have both the first end 3641 and the second end 3642 provided with the light emitting element. It is contemplated that when the first optical fiber 364 is provided with a light emitting element at only the first end 3641, the light entering the first end 3641 of the first optical fiber 364 may have some attenuation after being transmitted to the second end 3642 of the first optical fiber 364, which may reduce the uniformity of the light throughout the first optical fiber 364. In view of this, in the present embodiment, the first end 3641 and the second end 3642 of the first optical fiber 364 are provided with light emitting elements. Specifically, the atmosphere lamp assembly 360 further includes a second connection pipe 366 and a second light emitting element 365. One end of the second connecting pipe 366 is concavely provided with a third connecting groove, the opposite end is concavely provided with a fourth connecting groove, and the third connecting groove and the fourth connecting groove are communicated with each other. The second light emitting element 365 is connected to the third connection groove. Wherein the second end 3642 is connected to the fourth connection groove, and light emitted by the second light emitting element 365 can enter the second end 3642 and be conducted to the first end 3641. The specific structure of the second connection pipe 366 can be referred to the first connection pipe 362, and will not be described herein. In this solution, the two ends of the first optical fiber 364 can obtain light, so that the light emitting effect of the first optical fiber 364 is better, and the light emitting effect of each place in the first optical fiber 364 is more uniform.

Referring to fig. 12 and 16-17, in some embodiments, a first receiving groove 3121 extending along a circumferential direction of the probe cover 312 is provided at an outer periphery of a side wall of the probe cover 312, the atmosphere lamp assembly 360 is provided at the first receiving groove 3121, the probe cover 312 further includes a first light-transmitting cover plate 3124, and the first light-transmitting cover plate 3124 covers a notch position of the first receiving groove 3121. In this solution, the first optical fiber 364 is not exposed, and the user can only observe the light-emitting effect of the first transparent cover plate 3124 from the outer side of the probe cover 312, so that on one hand, the first optical fiber 364 can be well protected, and on the other hand, the positioning effect of the first optical fiber 364 is better, and the first optical fiber 364 is not easy to separate from the probe cover 312.

In some embodiments, the wall surface of the first light-transmitting cover plate 3124 facing the first receiving groove 3121 is provided with a second receiving groove, which together with the first receiving groove 3121 constitutes a first receiving chamber for receiving the atmosphere lamp assembly 360. The first light-transmitting cover plate 3124 is provided with a first rib plate, the first rib plate abuts against the wall surface of the first connection pipe 362, and the first accommodating groove 3121 is provided with a second rib plate, the second rib plate abuts against the wall surface of the first connection pipe 362. In this solution, the first rib plate of the first light-transmitting cover plate 3124 and the second rib plate in the first groove of the probe cover 312 can jointly position the first connection pipe 362, so that the positioning of the first connection pipe 362 is more reliable.

The specific placement of the lamp assembly 350 is dependent upon the actual requirements and in some embodiments, referring to fig. 7-10, the housing body 311 includes a first side wall 3111, the first side wall 3111 including an interior recess 3112, and the receptacle 340 is mounted to the interior recess 3112. The inner recess 3112 includes a peripheral wall 3113 at the outer periphery, the peripheral wall 3113 being arc-shaped recessed toward the inside of the housing main body 311, an illumination lamp being connected to the peripheral wall 3113, the illumination lamp being provided above the socket 340, the illumination lamp being configured to illuminate the socket 340 in an obliquely downward direction. The light is connected in being the concave wall of arc can reduce the probability that the light is directly shot user's eyes, promotes user's use experience.

Referring to fig. 7-8, in some embodiments, the illumination lamp assembly 350 includes a third light emitting element 351, a light homogenizing member 352, and a light guide member 353. The third light emitting element 351 is configured to generate illumination light, the light homogenizing element 352 is configured to uniformly emit light emitted from the third light emitting element 351 outwards, and the light guiding element 353 is configured to conduct optical fibers transmitted through the light homogenizing element 352 in a predetermined direction. The lamp assembly 350 is disposed inside the outer circumferential wall 3113, the outer circumferential wall 3113 is provided with light-transmitting holes 3114, and the light-guiding member 353 covers the light-transmitting holes 3114. The light homogenizing member 352 is attached to a wall surface of the light guide member 353 facing away from the light hole 3114, and the third light emitting element 351 is disposed on a side of the light homogenizing member 352 facing away from the light guide member 353. In the above-mentioned scheme, through the cooperation of dodging piece 352 and leaded light spare 353, on the one hand can make the light that third light emitting component 351 sent according to predetermined direction send, on the other hand, the light that third light emitting component 351 sent also can be softer.

Referring to fig. 8, in some embodiments, a second groove 3521 is disposed on a side of the light homogenizing element 352 facing away from the light guide element 353, a third light emitting element 351 is disposed on the second groove 3521, a third groove 3531 is disposed on a side of the light guide element 353 facing away from the light hole 3114, and the light homogenizing element 352 is disposed on the third groove 3531. In this aspect, the light uniformizing member 352 and the light guiding member 353 can obtain the light emitted by the third light emitting element 351 to the maximum, so as to improve the visual brightness of the illumination lamp assembly 350.

To further enhance the light emitting brightness of the illumination lamp assembly 350, in some embodiments, the illumination lamp assembly 350 includes a plurality of third light emitting elements 351, each third light emitting element 351 is arranged at intervals along a lateral direction, the second recess 3521 is a bar-shaped groove extending along the lateral direction, the third recess 3531 is a bar-shaped groove extending along the lateral direction, and the light-transmitting hole 3114 is a bar-shaped hole extending along the lateral direction. In this embodiment, the plurality of third light emitting elements 351 collectively emit illumination light, so that the overall brightness of the illumination lamp assembly 350 can be further improved. Further, by providing the light uniforming member 352 and the light guide 353 with elongated grooves and disposing the light emitting elements in the elongated grooves of the light uniforming member 352, the positional arrangement of the light emitting elements is facilitated.

The ultrasonic diagnostic apparatus 10 can control the opening and closing of the illumination lamp assembly 350 only by mounting and dismounting the probe cover 312, and the ultrasonic diagnostic apparatus 10 can additionally provide other control modes to control the opening and closing of the illumination lamp assembly 350. When the ultrasonic diagnostic apparatus 10 further controls the opening and closing of the illumination lamp assembly 350 through other control modes additionally provided, the additional control modes may be specific depending on actual requirements, and in some embodiments, the housing main body 311 is further provided with a distance sensor, and the ultrasonic diagnostic apparatus 10 is configured to control the illumination lamp assembly 350 to be turned on by the first control main board and maintain the first preset time in response to the distance sensor sensing that the distance of the human body approaching the socket 340 is less than the preset distance. In the following scenario, when the probe cover 312 is in the second state and the light assembly 350 is off. If the distance sensor senses that the distance between the human body and the socket 340 is smaller than the preset distance, the first control main board can control the lighting lamp assembly 350 to be turned on, and the lighting lamp assembly is turned off after a first preset time (specifically, one minute) is turned on, and the scheme can enable the opening and closing of the lighting lamp assembly 350 to be automatically controlled after the probe cover 312 is taken down, so that the convenience of lighting lamp control is further improved.

In addition to adding a distance sensor to control the turning on and off of the lamp assembly 350, in some embodiments, a touch switch is provided on the control panel 200, and the ultrasonic diagnostic apparatus 10 is configured to control the lamp assembly 350 to be turned on and to maintain a first preset time by the first control main board in response to the touch switch acquiring a touch operation. In this scheme, the on/off of the illumination lamp assembly 350 can also be controlled by touching a touch switch on the control panel 200. In some embodiments, the ultrasonic diagnostic apparatus 10 may also control the opening and closing of the illumination lamp assembly 350 by using both the installation and the removal of the probe cover 312, and the distance between the human body and the socket 340 sensed by the distance sensor, and simultaneously control the opening and closing of the illumination lamp assembly 350 by using a touch switch on the control motherboard.

The second aspect of the present application also provides an ultrasonic diagnostic apparatus 10, the ultrasonic diagnostic apparatus 10 including a display 100, a control panel 200, and a host computer 300. The host 300 includes a host housing 310, a socket 340, a first control motherboard, and an illumination lamp assembly 350, and the display 100 and the control panel 200 are electrically connected to the first control motherboard, respectively. The socket 340 is mounted on the main housing 310 and electrically connected to the first control motherboard, and the socket 340 is used for electrically connecting with a probe. The lamp assembly 350 is electrically connected to the first control board and is used to illuminate the area where the socket 340 is located. The main housing 310 includes a housing body 311, the housing body 311 being provided with a distance sensor, and the ultrasonic diagnostic apparatus 10 is configured to control the illumination lamp assembly 350 to be illuminated by the first control main board and to maintain a first preset time in response to the distance sensor sensing that the distance of the human body near the receptacle 340 is less than a preset distance. The ultrasonic diagnostic apparatus 10 in this embodiment is different from the ultrasonic diagnostic apparatus 10 in the foregoing embodiment in that the ultrasonic diagnostic apparatus 10 in this embodiment can control the opening and closing of the illumination lamp assembly 350 by sensing the distance between the human body and the socket 340 only by the distance sensor, can control the opening and closing of the illumination lamp assembly 350 without the need for mounting and dismounting the probe cover 312, and can control the opening and closing of the illumination lamp assembly 350 without the need for a touch switch on the control panel 200. Other structures of the ultrasonic diagnostic apparatus 10 in this embodiment can be referred to the foregoing embodiments, and will not be described here.

The third aspect of the present application also provides an ultrasonic diagnostic apparatus 10, the ultrasonic diagnostic apparatus 10 including a display 100, a control panel 200, and a host computer 300. The host 300 includes a host housing 310, a socket 340, a first control motherboard, and an illumination lamp assembly 350, and the display 100 and the control panel 200 are electrically connected to the first control motherboard, respectively. The socket 340 is mounted on the main housing 310 and electrically connected to the first control motherboard, and the socket 340 is used for electrically connecting with a probe. The lamp assembly 350 is electrically connected to the first control board and is used to illuminate the area where the socket 340 is located. The main housing 310 includes a housing main body 311, and the control panel 200 is provided with a touch switch, and the ultrasonic diagnostic apparatus 10 is configured to control the illumination lamp assembly 350 to be illuminated by the first control main board and to maintain a first preset time in response to the touch switch acquiring a touch operation. The ultrasonic diagnostic apparatus 10 in this embodiment is different from the ultrasonic diagnostic apparatus 10 in the foregoing embodiment in that the ultrasonic diagnostic apparatus 10 in this embodiment can control the opening and closing of the illumination lamp assembly 350 only by the touch switch on the control panel 200, can control the opening and closing of the illumination lamp assembly 350 without the need for mounting and dismounting the probe cover 312, and can control the opening and closing of the illumination lamp assembly 350 without the need for sensing the distance between the human body and the socket 340 by using the distance sensor. Other structures of the ultrasonic diagnostic apparatus 10 in this embodiment can be referred to the foregoing embodiments, and will not be described here.

The foregoing description of the preferred embodiments of the present utility model should not be construed as limiting the scope of the utility model, but rather should be understood to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the utility model as defined by the following description and drawings or any application directly or indirectly to other relevant art(s).

Claims

1. The utility model provides an ultrasonic diagnostic apparatus, includes display, control panel and host computer, the host computer includes host computer casing, socket, first control mainboard and light subassembly, display and control panel respectively the electricity connect in first control mainboard, the socket install in the host computer casing and electrically connect in first control mainboard, the socket is used for electrically connecting probe subassembly, the light subassembly electricity connect in first control mainboard and be used for shining the region that the socket is located, its characterized in that, the host computer casing includes:

2. The ultrasonic diagnostic device of claim 1, wherein,

the first control main board comprises a timing module, the timing module is used for enabling the first control main board to generate a third control signal after generating a first preset time of the first control signal, and the third control signal is used for controlling the lighting lamp assembly to be turned off.

3. The ultrasonic diagnostic device of claim 1, wherein,

The shell main body is also provided with a third contact, a second control main board is arranged in the probe cover, a fourth contact electrically connected with the second control main board is arranged in the probe cover, and the third contact is contacted with the fourth contact and electrically connected in the first state of the probe cover;

4. The ultrasonic diagnostic device of claim 3, wherein the atmosphere lamp assembly comprises:

the first light-emitting element is connected to the first connecting groove;

5. The ultrasonic diagnostic device of claim 4, wherein,

the first connecting pipe is internally provided with an annular bulge positioned between the first connecting groove and the second connecting groove, the inner through holes of the annular bulge are respectively communicated with the first connecting groove and the second connecting groove, the annular bulge is provided with an annular end face deviating from the first light-emitting element, and the annular end face is abutted against the end face of the first end facing the first light-emitting element.

6. The ultrasonic diagnostic device of claim 4, wherein,

The first connecting groove comprises a first groove section and a second groove section communicated with the first groove section, the second groove section is positioned at the end part of the first connecting pipe, which is away from the second connecting groove, the inner diameter of the second groove section is larger than that of the first groove section, and the inner periphery of the second groove section comprises a first arc-shaped surface and a first plane connected with the first arc-shaped surface;

7. The ultrasonic diagnostic device of claim 4, wherein the atmosphere lamp assembly further comprises:

a second light emitting element connected to the third connection groove;

8. The ultrasonic diagnostic device of claim 4, wherein,

the periphery of a side wall that the probe covers is provided with the edge the first holding tank that the circumference that the probe covered extends, atmosphere lamp subassembly is located first holding tank, the probe covers still includes first printing opacity apron, first printing opacity apron lid is located the notch position of first holding tank.

9. The ultrasonic diagnostic device of claim 8, wherein,

the first light-transmitting cover plate faces the wall surface of the first accommodating groove and is provided with a second accommodating groove, the second accommodating groove and the first accommodating groove jointly form a first accommodating cavity for accommodating the atmosphere lamp assembly, the first light-transmitting cover plate is provided with a first rib plate, the first rib plate is abutted to the wall surface of the first connecting pipe, the first accommodating groove is internally provided with a second rib plate, and the second rib plate is abutted to the wall surface of the first connecting pipe.

10. The ultrasonic diagnostic device of claim 1, wherein,

the shell main body is provided with a first groove, the first contact is arranged in the first groove, the probe covers and is provided with a first bulge, the second contact is arranged at the end part of the first bulge, and the first bulge stretches into the first groove in the first state of the probe cover.

11. The ultrasonic diagnostic device of claim 10, wherein,

the probe cover is provided with a third magnetic piece and a fourth magnetic piece, the third magnetic piece and the fourth magnetic piece are arranged at the opposite ends of the first protrusion, the probe cover is in the first state, the first magnetic piece is in magnetic attraction connection with the third magnetic piece, and the second magnetic piece is in magnetic attraction connection with the fourth magnetic piece.

12. The ultrasonic diagnostic device of claim 1, wherein,

the housing body is provided with a distance sensor, and the ultrasonic diagnostic apparatus is configured to control the illumination lamp assembly to be turned on by the first control main board and to maintain a first preset time in response to the distance sensor sensing that a distance of a human body approaching the socket is smaller than a preset distance.

13. The ultrasonic diagnostic device of claim 1, wherein,

the control panel is provided with a touch switch, the ultrasonic diagnostic apparatus is configured to respond to the touch operation obtained by the touch switch, and the first control main board controls the lighting lamp assembly to be lightened and keeps a first preset time.

14. The utility model provides an ultrasonic diagnostic apparatus, includes display, control panel and host computer, the host computer includes host computer shell, socket, first control mainboard and light subassembly, display and control panel respectively the electricity connect in first control mainboard, the socket install in the host computer shell and the electricity connect in first control mainboard, the socket is used for the electricity to connect the probe, the light subassembly with first control mainboard electricity is connected and is used for shining the region that the socket is located, a serial communication port, the host computer shell includes the shell main part, the shell main part is equipped with the distance sensor, the ultrasonic diagnostic apparatus is configured to respond to the distance sensor senses the human body is close to the distance of socket is less than the default distance, first control mainboard control light subassembly lights to keep first default time.

15. The utility model provides an ultrasonic diagnostic apparatus, includes display, control panel and host computer, the host computer includes host computer shell, socket, first control mainboard and light subassembly, display and control panel respectively the electricity connect in first control mainboard, the socket install in the host computer shell and the electricity connect in first control mainboard, the socket is used for the electricity to connect the probe, light subassembly with first control mainboard electricity is connected and is used for shining the area that the socket is located, the host computer shell includes the shell main part, a serial communication port, be provided with touch switch on the control panel, ultrasonic diagnostic apparatus is configured to respond to touch switch obtains touch operation, first control mainboard control light subassembly lights to keep first default time.

16. The ultrasonic diagnostic apparatus according to any one of claims 1 to 15, wherein,

the housing body includes a first sidewall including an interior recess, the receptacle being mounted to the interior recess;

17. The ultrasonic diagnostic device of claim 16, wherein,

the illuminating lamp assembly comprises a third light-emitting element, a light-homogenizing part and a light guide part, wherein the illuminating lamp assembly is arranged on the inner side of the peripheral wall, a light hole is formed in the peripheral wall, the light hole is covered by the light guide part, the light-homogenizing part is attached to the wall surface, deviating from the light hole, of the light guide part, and the third light-emitting element is arranged on one side, deviating from the light guide part, of the light-homogenizing part.

18. The ultrasonic diagnostic device of claim 17, wherein,

the light-homogenizing part is arranged on one side, deviating from the light-guiding part, of the light-homogenizing part, the second groove is formed in the third light-emitting element, the third groove is formed in one side, deviating from the light-transmitting hole, of the light-guiding part, and the light-homogenizing part is arranged in the third groove.

19. The ultrasonic diagnostic device of claim 18, wherein,

the illuminating lamp assembly comprises a plurality of third light-emitting elements, the third light-emitting elements are arranged at intervals in the transverse direction, the second grooves are strip-shaped grooves extending in the transverse direction, the third grooves are strip-shaped grooves extending in the transverse direction, and the light holes are strip-shaped holes extending in the transverse direction.