CN114468806A - Food processing device - Google Patents

Abstract

The present invention provides a food processing apparatus comprising: a bearing; the bearing is arranged in the bearing seat; the base is provided with a bearing seat; the cup body is in threaded connection with the base and is a light-transmitting cup body or a metal cup body; the food processing assembly comprises a shaft, and the bearing is sleeved on the shaft; wherein, the bearing frame is the plastics bearing frame. The food processing apparatus that this scheme provided for prior art, set up the bearing frame to the base on, and the bearing frame is plastics bearing frame, consequently can with base integrated into one piece, does not basically need the postprocessing to handle, can reduce the quantity of production processes. And simple structure, light in weight, the shaping precision is high, still is favorable to promoting food processing apparatus's dynamic balance performance to reduce the abnormal sound of during operation, the noise reduction.

Description

Food processing device

Technical Field

The embodiment of the invention relates to the technical field of household appliances, in particular to a food processing device.

Background

The wall breaking machine hot cup bearing block has three structures, one is an independent hardware bearing tool apron, a special-shaped mounting hole is punched in the center of a heating plate, and the heating plate is assembled and fixed by a large nut in the reverse direction; the other is that the center of the steel disc of the heating plate is directly stretched reversely to form a large high boss to press an aluminum sleeve as a bearing seat, and the other is an integrally cast aluminum bearing seat;

the bearing blocks are subjected to post-processing treatment, the processing technology is complex, and an inner hole and a clamp spring groove are turned by a numerical control machine tool or a special device is used for heading and bending a pier shape. Low production efficiency and unstable quality.

Disclosure of Invention

In order to solve at least one of the above technical problems, an embodiment according to the present invention aims to provide a food processing apparatus.

To achieve the above object, there is provided a food processing apparatus according to an embodiment of the present invention, including: a food processing assembly comprising a shaft; the bearing is sleeved on the shaft; the bearing is arranged in the bearing seat; the base is provided with a bearing seat; the cup body is in threaded connection with the base and is a light-transmitting cup body or a metal cup body; wherein, the bearing frame is the plastics bearing frame.

In the technical scheme, the bearing seat is arranged to be the plastic bearing seat, and the bearing seat can be produced by adopting a one-time injection molding processing mode, so that post-processing treatment is not needed, and the production process of the bearing seat is favorably simplified. And the plastic bearing seat is adopted, so that the production precision and efficiency are high, and the product quality is stable. More importantly, the base generally adopts a plastic bearing seat, so that the base and the bearing seat are made of the same material and are convenient to assemble and connect, and compared with the bearing seat made of a metal material, the bearing seat is easier to be consistent with the dynamic balance of the base after assembly. In addition, because the plastic bearing seat is adopted and arranged on the base instead of being connected with the chassis, compared with the prior art, the load of the chassis is lightened, and the chassis can not bear the centrifugal force generated when the bearing rotates, so that the strength of the chassis can be reduced, and the thinner chassis can be adopted.

Specifically, the bearing frame sets up on the base, and for the mode that prior art, bearing frame and chassis are connected, the position of bearing frame in equipment has sunk, and the focus reduces when using. After the gravity center is lowered, the stability of the bearing rotating at high speed is improved, the dynamic balance performance of the bearing and the whole equipment can be correspondingly improved, and the phenomena of abnormal sound, noise and the like are reduced. And the bearing frame sets up on the base, has realized the separation with the chassis of equipment, and the chassis no longer bears the gravity of bearing, bearing frame, also does not bear the centrifugal force of the high-speed rotatory of bearing, consequently can reduce the intensity of chassis. Accordingly, the thickness of the chassis can be reduced, the material can be saved, and the weight can be reduced. Further, the bearing frame sets up on the base, is favorable to promoting the uniformity of assembly between bearing frame and the base to the base often can adopt plastics production, and both the same material, thereby can carry out integrated into one piece, shorten production route, promote production efficiency. In addition, the bearing seat is arranged on the base, and compared with a mode of being connected with the chassis in the prior art, the bearing seat can be directly and stably supported, and the working stability and reliability of the bearing are further improved.

The shaft sleeve of the food processing assembly is arranged on the shaft, and the bearing is arranged in the bearing seat, so that the shaft is conveniently and rotatably connected with the bearing seat through the bearing, and the rotating function is realized.

The cup body is in threaded connection with the base, so that the cup body is convenient to assemble and disassemble, and the maintenance of the cup body and the base is convenient. The cup body adopts a light-transmitting cup body, so that a user can observe the processing condition of food in the cup body conveniently. The cup body is made of metal, so that the strength is high and the durability is good.

In the above technical scheme, the base and the bearing seat are integrally formed.

In this technical scheme, base and bearing frame integrated into one piece can regard as a whole simultaneous production to come out like this in the process, and do not produce bearing frame and base alone, consequently can reduce process quantity by a wide margin, reduce the production degree of difficulty, promote production efficiency. Further, base and bearing frame integrated into one piece, then both do not need later stage assembly as a whole rather than two detached monomers, have reduced the assemble duration. The bearing seat and the base are integrally formed, the material is the same, the consistency is good, and in addition, the dynamic balance performance of the bearing seat and the base is greatly improved compared with that of a split bearing seat and a split base in the prior art due to the fact that the bearing seat and the base are a whole.

In any one of the above technical solutions, the bearing seat is located at a lower portion of the base.

In the technical scheme, the bearing seat is arranged at the lower part of the base, so that other parts can be avoided, and the overall height of the equipment is reduced. More importantly, the bearing seat can sink further, so that the gravity center of the bearing seat can be further reduced, and the working stability and reliability of the bearing are improved.

In the above technical scheme, the bottom of base is formed with first connecting portion, and first connecting portion connects the lateral wall of bearing frame and base.

In this technical scheme, through setting up the lateral wall that first connecting portion connect bearing frame and base, that is to say the bearing frame is not directly put in the bottom of base, but is provided with independent connection structure. Thus, the bottom of the base is beneficial to digging out a part of hollow structure, thereby reducing the whole weight of the food processing device and saving materials.

In the above technical solution, the number of the first connection portions is plural, and the plural first connection portions are distributed at intervals.

In this technical scheme, through setting up a plurality of first connecting portions, and a plurality of first connecting portions distribute at intervals, be favorable to providing the support for the bearing frame from a plurality of directions like this, promote the homogeneity of bearing frame atress to promote the stability and the reliability of bearing frame work.

In the above technical solution, the first connection portion is configured to extend from the side wall of the base to the central axis direction of the base, and the first connection portion is configured with an arc-shaped structure.

In this technical scheme, first connecting portion construct and extend to the center pin direction of base from the lateral wall of base, are favorable to putting the central point of base in this way to make the centre of gravity of bearing frame, the center of rotation of bearing and the center pin of base these three on same straight line. Therefore, the dynamic balance performance of the whole food processing device is improved, especially when the bearing rotates at high speed, the working stability and reliability of the equipment can be further improved, and the phenomena of abnormal sound and noise are reduced. First connecting portion structure has the cambered surface structure, is favorable to reducing the moment that the lateral wall hookup location department of first connecting portion and cup received because of the gravity of bearing to the dispersion atress promotes the mechanical properties of each first connecting portion and prolongs the life of first connecting portion.

In the above technical solution, the first connecting portion is provided with a plurality of reinforcing ribs.

In this technical scheme, through setting up a plurality of strengthening ribs, be favorable to promoting the intensity of first connecting portion, prolong the life of first connecting portion.

In above-mentioned technical scheme, be equipped with first step in the bearing frame, the bottom of first step is equipped with holds the chamber, holds the chamber and is used for holding the bearing.

In this technical scheme, through setting up first step, and the bottom of first step is equipped with and holds the chamber, provides a relatively independent installation space and working space for the bearing, has reduced the interference of external object to bearing work, is favorable to the bearing to carry out reliable and stable work. The first step can form an accommodating cavity together with the bearing seat and can limit the axial displacement of the bearing.

In the above technical solution, the food processing apparatus further comprises: the supporting piece is arranged at the bottom of the bearing seat and connected with the bearing seat, and the supporting piece, the first step and the side wall of the bearing seat enclose the accommodating cavity.

In this technical scheme, set up support piece in the bottom of bearing frame to link to each other with the bearing frame, be favorable to sealing like this and hold the chamber, ensure bearing workspace's independence and stability. More importantly, the bottom of bearing frame is located to support piece, can provide the support for the bearing, avoids under the action of gravity, perhaps leads to the bearing to deviate from because of other reasons and hold the chamber to further restrict the axial displacement of bearing, promoted the stability of bearing work. It should be noted that, in the related art, since the bearing seat is usually a metal part, a platform or a step is generally formed at the bottom of the bearing seat by turning or the like to support the bearing. The supporting structure in the related art has the advantages of more complex processing mode, long process route, low production efficiency and more complex and longer assembly process. In the technical scheme, the supporting piece is arranged to be independent and connected with the bearing seat, so that the bearing can be supported, the structure of the bearing seat is simplified, the production process of the bearing seat and the supporting piece is simplified, the production difficulty of the bearing seat is reduced, and the bearing is more convenient to install and maintain. Furthermore, because the supporting pieces are independent individuals instead of being integrated with the bearing seats, the mounting mode and the mounting sequence are more flexible, the whole mounting process and the mounting sequence of the food processing device are optimized, and the mounting efficiency is improved. In addition, when the bearing seat or the supporting piece is in failure and needs maintenance and replacement, the number of replacement parts can be reduced, and materials and parts are saved.

In the above technical solution, the food processing apparatus further comprises: the clutch is sleeved on the shaft, is positioned on one side of the supporting piece away from the bearing seat and is used for connecting the driving device; the gasket is sleeved on the shaft and is positioned between the clutch and the supporting piece.

In the technical scheme, the clutch is arranged, so that the driving device is convenient to connect, and power is provided for the rotation of the shaft. Simultaneously, the clutch can also separate with drive arrangement to disconnection axle pivoted power avoids the user to get when putting the edible material food processing assembly take place to rotate and causes the incident, has promoted convenience and the security of equipment usage. The clutch sleeve is arranged on the shaft, so that the shaft can be driven to rotate conveniently. The clutch is located on the side of the support member remote from the bearing seat, i.e. on the side of the bottom of the bearing seat, so as to facilitate connection with the drive means on the base. Through setting up the gasket between clutch and support piece, be convenient for protect with keep apart support piece, avoid taking place wearing and tearing between clutch and the support piece to can prolong support piece's life.

In the above technical solution, the food processing apparatus further comprises: the base plate is arranged in the base, and a cavity for containing food materials is surrounded by the base plate and the cup body; the base extends to the top direction and is formed with the third connecting portion, and the cup is connected with third connecting portion fixed connection.

In this technical scheme, surround out the cavity that is used for holding edible material through chassis and cup, namely cup and chassis are split type structure, and the cup is cylindric structure, rather than adopting tubbiness structure. Due to the arrangement, the cup body can be made of glass, and on one hand, the glass has better heat resistance and transparency and also has longer service life. Glass is also safer and healthier than plastic. It can be understood that, because the shaft needs to penetrate into the cup body, if the barrel-shaped cup body is made of glass, a through hole needs to be formed in the glass, and the process is complex and difficult to process. By adopting the structure, the whole process of the equipment is facilitated to be simplified, and the processing difficulty is reduced.

It will be appreciated that the chassis may also be provided integrally with the cup, but such a construction generally requires the cup to be provided as a plastics material to facilitate the machining of the through-hole in the chassis.

The base extends to the top direction and is formed with the third connecting portion, that is to say, the cup is connected with the first half of base, and the bearing frame is connected with the latter half of base, has realized the sunken purpose of bearing frame for the focus of bearing frame shifts down, noise and abnormal sound when being favorable to reducing the bearing rotation. It can be understood that the third connecting portion is provided with a thread structure, and the cup body is connected with the base through the thread structure on the third connecting portion.

In the above technical solution, a fourth connecting portion is provided between the third connecting portion and the first connecting portion, and the fourth connecting portion is used for connecting the chassis.

In the technical scheme, the fourth connecting part is arranged, so that the chassis can be conveniently connected and the support can be provided for the chassis. Simultaneously, the fourth connecting portion are located the position between first connecting portion and the third connecting portion, that is to say the fourth connecting portion comparatively is close to the middle part of base, are favorable to the bottom seat of cup to go into in the base like this for the focus of cup reduces, receives the spacing of base simultaneously. After food materials are contained in a cavity defined by the cup body and the chassis, the cup body is favorable for limiting through the base, and the stability and the reliability of the cup body are improved.

In the above technical solution, the cross-sectional area of the third connecting portion is larger than that of the fourth connecting portion, and the cross-sectional area of the fourth connecting portion is larger than that of the first connecting portion.

In this technical solution, the cross-sectional area of the third connecting portion is larger than the cross-sectional area of the fourth connecting portion, and the cross-sectional area of the fourth connecting portion is larger than the cross-sectional area of the first connecting portion, that is, in the three connecting portions, the cross-sectional area is smaller as the three connecting portions are closer to the bottom of the base. Because the inside of base is hollow structure, adopts the structure of this kind of shrink gradually formula, is favorable to the structure of below to form stable support to the top to play spacing effect, be favorable to avoiding the cup to sink too much and take place the contact with structures such as bearing frame.

In the above technical solution, a first connecting step is provided between the first connecting portion and the fourth connecting portion; and/or a second connecting step is arranged between the third connecting part and the fourth connecting part.

In this technical scheme, the setting of first connection step can play the effect of reinforcing to promote the bulk strength and the rigidity of base. Set up the second between third connecting portion and fourth connecting portion and connect the step, be convenient for make cup and second connect the step and lean on, correspondingly, the second is connected the step and can also be formed the support to the cup. By adopting the structure, the cup body can be supported without a chassis, and the stress of the chassis is reduced.

In the technical scheme, the bearing seat is also provided with a first through hole; the food processing device also comprises a first fastener, and the first fastener penetrates through the first through hole; the chassis is also fixedly connected with the supporting piece through a first fastener.

In this solution, the chassis and the support are fixedly connected together, that is, the chassis, the support, the bearing seat and the bearing in the bearing seat are all connected together, and the base is connected with the bearing seat, which form a whole. During the assembly of the appliance, this whole can be managed and assembled as a modular module. Adopt this kind of structure, can accomplish this kind of holistic module assembly earlier, assemble the module to whole equipment again to can promote the holistic assembly speed of equipment and production efficiency, be difficult for appearing the phenomenon that accessories lost, forgotten the assembly moreover.

The first through hole is formed in the bearing seat, so that after the first fastener penetrates through the bearing seat, the supporting piece, the chassis, the bearing seat and the base are connected into a whole, and a module is formed.

In the technical scheme, a first through hole suitable for a shaft to pass through is formed in the chassis; the food processing assembly further comprises: the work execution component is arranged in the cup body and sleeved on the shaft penetrating through the first through hole.

In the technical scheme, the base plate is provided with the first through hole, so that the shaft can penetrate through the base plate conveniently, and the shaft can extend out of the base plate, thereby facilitating the connection of the work execution part and the shaft on one side of the base plate far away from the bearing seat, or facilitating the connection of the work execution part in the cup body and the shaft. Such structure is favorable to setting up the one side of keeping away from the bearing frame on the chassis with the cavity that holds edible material to be convenient for stir, cut edible material in the cup through the work executive component. And the cavity that holds the edible material sets up in the chassis and keeps away from one side of bearing frame, has bigger space, can hold more edible materials.

In the above technical solution, the work executing component includes any one or a combination of the following: blades, stirring blades or cleaning elements.

In this technical scheme, the work executive component is the blade to in cutting and smashing the food material. The work execution part is a stirring blade so as to stir the food materials. The work executing component can also be a cleaning component which can clean the cup body or the food material through rotation. The work implement may also include a combination of blades and stirring vanes.

In the technical scheme, the thickness of the chassis is 0.3 mm-2.5 mm.

In the technical scheme, the thickness of the chassis is set to be 0.3-2.5 mm, and two conditions are met. In one case, the chassis is a single layer of metal sheet, such as steel. In the case of a single layer of sheet metal, it is only used for unheated cup assemblies, or the base plate is not connected to a heating element. The chassis is not connected with a heating element, and when a single-layer metal plate structure is adopted, the thickness of the chassis is 0.3mm, 0.5mm, 0.6mm and the like. In another case, the chassis is a double-layer metal plate and needs to be connected with a heating element; a layer of metal plate is used for bearing, for example, a steel plate with the thickness of 0.3mm, 0.5mm, 0.6mm and the like is adopted; another layer of metal plate is used for heat generation and heat conduction, for example, an aluminum plate, the thickness of which may be 1mm, 1.2mm, 1.5mm, 2mm, etc. It will be appreciated that aluminum has a low density and good thermal conductivity and can therefore be made thicker. The steel plate has high strength and high density, so the steel plate has a thinner thickness. Compared with the prior art, the thickness of the chassis is reduced no matter the single-layer metal plate or the double-layer metal plate is adopted, so that the weight of the equipment can be reduced, the material can be saved, and the space occupied by the chassis can be reduced.

It should be noted that, because the chassis and the bearing seat are separately arranged, the bearing seat sinks to the bottom of the base, so that the chassis does not need to bear the weight of the bearing seat any more and bear the centrifugal force when the bearing rotates at high speed. After the stress is reduced, the requirements on the strength and the rigidity of the chassis are reduced, so that the thickness of the chassis can be reduced through the structural improvement, and the chassis is not simply increased or decreased in size.

In the above technical solution, the food processing apparatus further comprises: the heating element is connected with the chassis and used for heating the chassis.

In this technical scheme, through setting up the heating member on the chassis, can heat the edible material in the cup through the heating to the chassis. The food processing device has the advantages that the functions of the food processing device can be expanded, food can be smashed and stirred, the food can be directly heated, and the food can be directly cooked after being smashed. This provides more convenience to the user in using the food processing device.

In the above technical solution, the food processing apparatus further comprises: and the oil seal is arranged at the top of the first step and sleeved on the shaft.

In this technical scheme, set up the oil blanket through the top at first step, the oil blanket cover is established epaxially, and the oil blanket of being convenient for seals at the epaxial enterprising line of axle, reduces the seepage of liquid to promote the smooth and easy degree of the stability and the pivoted of axle work. The oil seal is sleeved on the shaft, and the oil seal can be prevented from falling off or shifting, so that the working stability and reliability of the oil seal are ensured. In addition, the first step also plays a role of supporting the oil seal here.

In any one of the above technical solutions, the food processing apparatus further includes: the top of bearing frame is equipped with the ring channel, and the ring channel is located to the sealing washer.

In this technical scheme, through setting up the sealing washer, can provide radial sealed for the bearing frame, avoid liquid to the bearing infiltration along the radial of bearing frame and influence the work of bearing. The annular groove is convenient for fixing the sealing ring, and the sealing ring is prevented from shifting or falling off, so that the working stability and reliability of the sealing ring are ensured.

In any one of the above technical solutions, the food processing apparatus further includes: a base; the base is detachably connected with the base.

In this technical scheme, base and base are connected, are convenient for set up the power supply part in the base to for the part in the base provides electric power, drive food processing assembly and rotate. The base and the base are detachably connected, so that the base and the base are convenient to maintain and repair, and the installation is convenient. It is understood that the base may not be provided with a power supply member, and may serve only as a support structure for the base.

In the above technical solution, the food processing apparatus further comprises: the coupler is used for circuit coupling communication; the bottom of base is equipped with the second connecting portion, and the coupler passes through the second connecting portion and links to each other with the base.

In the technical scheme, the coupler is used for circuit coupling communication, so that the base and the base can be conveniently matched for use, namely the coupler can be matched with the connector on the base for power supply, and power is provided for rotation of the shaft. The coupler is connected with the base through the second connecting portion, namely the coupler is of an independent structure relative to the base, so that the coupler is convenient to produce independently as an electronic structure, and the convenience and the quality of production are ensured.

In the above technical solution, the food processing apparatus further comprises: the microswitch is arranged on the base; the trigger bar is arranged at the bottom of the base and used for triggering the micro switch.

In the technical scheme, the microswitch on the base is arranged, the trigger rod is arranged at the bottom of the base, so that the microswitch on the base is conveniently triggered through the trigger rod, and the convenience in controlling the food processing device is improved.

In the above technical solution, the center lines of the trigger lever, the shaft and the coupler are in one plane.

In the technical scheme, the center lines of the trigger rod, the shaft and the coupler are in one plane, and the structures of the trigger rod, the shaft and the coupler have certain symmetry. Because the three are at least partially arranged at the bottom of the base, the bottom structure of the base has certain symmetry. With such a configuration, the dynamic balance performance is greatly enhanced relative to an eccentric or asymmetric configuration, thereby enhancing the dynamic balance performance of the food processing apparatus when the shaft is rotated at high speeds. In addition, because the trigger bar and the coupler are arranged at the bottom of the base, the centers of the trigger bar and the coupler are also approximately in the same plane or in a relatively close plane, so that the dynamic balance performance of the food processing device is further improved, abnormal sound is reduced, and noise is eliminated.

In the above technical solution, the food processing apparatus includes any one of: a wall breaking machine, a food processor, a soybean milk machine and a meat grinder.

Additional aspects and advantages of embodiments in accordance with the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of embodiments in accordance with the invention.

Drawings

The above and/or additional aspects and advantages of embodiments according to the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is a schematic view of a partially exploded perspective view of a food processing apparatus according to one embodiment of the present invention;

FIG. 2 is a schematic partial perspective view of a food processing device according to one embodiment of the present invention;

FIG. 3 is a schematic partial front view of a food processing device according to one embodiment of the present invention;

FIG. 4 is a schematic sectional view taken along line A-A in FIG. 3;

FIG. 5 is a schematic top view of a portion of a food processing device according to an embodiment of the present invention;

FIG. 6 is a schematic partial perspective view of a food processing device according to an embodiment of the present invention;

FIG. 7 is a schematic partial perspective view of a food processing device according to an embodiment of the present invention;

FIG. 8 is a schematic partial perspective view of a food processing device according to another embodiment of the present invention;

FIG. 9 is a schematic view in partial perspective cross-sectional configuration of a food processing device according to yet another embodiment of the present invention;

FIG. 10 is a schematic perspective view of a chassis according to an embodiment of the present invention;

FIG. 11 is a perspective view of a support according to one embodiment of the present invention;

FIG. 12 is a schematic illustration in partial cross-sectional configuration of a food processing device according to an embodiment of the present invention;

fig. 13 is an exploded view of a food processing device according to an embodiment of the present invention.

Wherein, the correspondence between the reference numbers and the component names in fig. 1 to 13 is:

10 food processing apparatus, 100 food processing assembly, 102 shaft, 104 work implement, 106 bearing, 108 bearing seat, 1080 first step, 1082 receiving cavity, 1084 first through hole, 1086 annular groove, 1088 second screw hole, 1190 second through hole, 120 base, 1200 first connecting portion, 1202 reinforcing rib, 1204 second connecting portion, 1206 third connecting portion, 1208 fourth connecting portion, 1210 first connecting step, 1212 second connecting step, 1214 threaded structure, 124 support, 1240 second through hole, 126 chassis, 1262 first through hole, 1264 first screw hole, 1266 nut post, 130 oil seal, 132 sealing ring, 134 coupler, 136 trigger lever, 138 clutch, 140 spacer, 142, bottom cover, 146 third screw hole, 148 clearance hole, 150 second spacer, 200 first fastener, 202 second fastener, 300 cup, 302 base.

Detailed Description

In order that the above objects, features and advantages of embodiments in accordance with the present invention can be more clearly understood, embodiments in accordance with the present invention are described in further detail below with reference to the accompanying drawings and detailed description. It should be noted that features of various embodiments according to the present invention may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of embodiments according to the invention, however, embodiments according to the invention may be practiced in other ways than those described herein, and therefore the scope of embodiments according to the invention is not limited by the specific embodiments disclosed below.

Some embodiments provided according to the present invention are described below with reference to fig. 1 to 13.

Example 1

As shown in fig. 1-10, embodiments according to a first aspect of the present invention provide a food processing apparatus 10 including a food processing assembly 100, a bearing 106, a bearing seat 108, a base 120, and a cup 300. Cup 300 is threadably connected to mount 120. Cup 300 is a clear cup or a metal cup. The cup body 300 can contain food materials, so that the food processing assembly 100 can conveniently cut or stir the food materials.

The food processing assembly 100 includes a shaft 102, a bearing 106 disposed on the shaft 102, and a bearing seat 108 disposed within the bearing seat 108. The base 120 is provided with a bearing seat 108. Bearing housing 108 is a plastic bearing housing.

In this embodiment, the bearing seat 108 is made of plastic, and can be produced by one-time injection molding, so that post-processing is not required, and the production process of the bearing seat 108 is simplified. And the plastic bearing seat is adopted, so that the production precision and efficiency are high, and the product quality is stable. More importantly, the base 120 is generally a plastic bearing seat, so that the base and the plastic bearing seat are made of the same material, thereby facilitating assembly and connection, and compared with the bearing seat 108 made of a metal material, the base is more easily consistent with the dynamic balance of the base 120 after assembly. In addition, because the plastic bearing seat is adopted and arranged on the base 120 instead of being connected with the chassis 126, compared with the prior art, the load of the chassis 126 is reduced, the chassis 126 can not bear the centrifugal force generated when the bearing 106 rotates, the strength of the chassis 126 can be reduced, and the thinner chassis 126 can be adopted.

Specifically, the bearing seat 108 is disposed on the base 120, and the bearing seat 108 is depressed in position in the apparatus and the center of gravity is lowered in use, as compared to the prior art in which the bearing seat 108 is connected to the chassis 126. After the center of gravity is lowered, the stability of the bearing 106 rotating at high speed is improved, accordingly, the dynamic balance performance of the bearing 106 and the whole equipment can be improved, and phenomena such as abnormal sound and noise are reduced. And the bearing seat 108 is arranged on the base 120, and is separated from the chassis 126 of the equipment, and the chassis 126 does not bear the gravity of the bearing 106 and the bearing seat 108 any more, and does not bear the centrifugal force generated by the high-speed rotation of the bearing 106, so that the strength of the chassis 126 can be reduced. Accordingly, the thickness of the chassis 126 can be reduced, saving material and reducing weight. Further, bearing frame 108 sets up on base 120, is favorable to promoting the uniformity of assembly between bearing frame 108 and the base 120 to base 120 often can adopt plastics production, and the same material of both, thereby can carry out integrated into one piece, shorten production route, promote production efficiency. In addition, the bearing seat 108 is disposed on the base 120, which can be supported more directly and stably compared to the prior art that is connected to the chassis 126, thereby further improving the stability and reliability of the operation of the bearing 106.

The shaft 102 of the food processing assembly 100 is sleeved on the shaft 102, and the bearing 106 is arranged in the bearing seat 108, so that the shaft 102 is rotatably connected with the bearing seat 108 through the bearing 106, and the rotating function is realized.

The cup body 300 is connected with the base 120 by screw threads, so that the cup body 300 and the base 120 can be conveniently maintained. The cup body 300 is a transparent cup body, such as a glass cup body, a crystal cup body or an organic glass cup body, so that a user can observe the processing condition of food in the cup body 300 conveniently. The cup body 300 is made of metal, so that the strength is high and the durability is good.

Example 2

As shown in fig. 1-10, another embodiment according to the first aspect of the present invention provides a food processing device 10 comprising a food processing assembly 100, a bearing 106, a bearing seat 108, a base 120, and a cup 300. Cup 300 is threadably connected to mount 120. Cup 300 is a clear cup or a metal cup. As shown in fig. 8 and 9, the plastic base 120 and the plastic bearing seat 108 are integrally formed.

In this embodiment, through setting up base 120 and bearing frame 108 to integrated into one piece, base 120 and bearing frame 108 can be produced as a whole in the process simultaneously promptly, and not produce bearing frame 108 and base 120 alone, consequently can reduce process quantity by a wide margin, reduce the production degree of difficulty, promote production efficiency. Further, the base 120 and the bearing seat 108 are integrally formed, and the base and the bearing seat are integrated instead of two separated single bodies, so that later assembly is not needed, and the assembly time is reduced. The bearing seat 108 and the base 120 which are integrally formed are made of the same material and have good consistency, and the dynamic balance performance of the bearing seat 108 and the base 120 is greatly improved compared with that of the split bearing seat 108 and the base 120 in the prior art due to the fact that the bearing seat and the base are a whole. It should also be noted that the base 120 and the bearing seat 108, which are integrally formed, are often made of plastic material, and the forming speed and efficiency are high. For the bearing seat 108 made of metal, the bearing seat 108 is not required to be manufactured in a mode of stretching a convex hull, and the bearing seat 108 is not required to be independently processed, so that the processing procedures can be greatly reduced, the production efficiency is improved, and materials can be greatly saved.

Further, as shown in fig. 2, the food processing assembly 100 includes a shaft 102. Bearing 106 is fitted over shaft 102 and is disposed within bearing seat 108. The shaft 102 is rotatably connected to a bearing block 108 by a bearing 106. The bearing housing 108 is disposed within the base 120.

By providing the food processing assembly 100, and the food processing assembly 100 including the shaft 102, the food processing assembly 100 can cut and stir the food material by rotating the shaft 102. By arranging the bearing 106 and sleeving the shaft 102, the bearing 106 is arranged in the bearing seat 108, so that the shaft 102 is rotatably connected with the bearing seat 108 through the bearing 106. The bearing seat 108 is disposed in the base 120, and the bearing seat 108 and the base 120 are integrally formed, so that the base 120 provides a stable support for the bearing seat 108 and a support point for the food processing assembly 100. The bearing seat 108 and the base 120 are integrally formed, so that the production link can be shortened, and the production efficiency is improved. The bearing seat 108 and the base 120 do not need secondary assembly, and the bearing seat and the base are integrally formed into a whole, so that the consistency of the bearing seat and the base is favorably improved, no fit clearance exists between the bearing seat and the base, the dynamic balance performance is good, the phenomena of abnormal sound and noise can not occur, and the working stability and reliability are improved.

Further, the bearing seat 108 is located at the lower portion of the base 120, which is beneficial to avoiding other components such as the cup 300 and reducing the overall height of the device. More importantly, the bearing seat 108 can sink further, so that the center of gravity of the bearing seat 108 can be further lowered, and the stability and reliability of the operation of the bearing 106 are improved. Preferably, the bearing seat 108 is located at the bottom of the base 120, so that the space between the bearing seat 108 and the chassis 126 is increased to the maximum, the structure of the base 120 can be set more reasonably, the space of the base 120 is utilized more reasonably under the condition of meeting the strength, and the miniaturization design is facilitated. And bearing frame 108 is located the bottom of base 120, has realized the subsidence of bearing frame 108 to the maximize, makes the focus of bearing frame 108 fall in the minimum of equipment, is favorable to guaranteeing the stability of equipment work.

Example 3

As shown in fig. 1-10, according to yet another embodiment of the first aspect of the present invention, there is provided a food processing apparatus 10 comprising a food processing assembly 100, a bearing 106, a bearing seat 108, a pedestal 120, and a cup 300. Cup 300 is threadably connected to mount 120. Cup 300 is a clear cup or a metal cup. The cup body 300 can contain food materials, so that the food processing assembly 100 can conveniently cut or stir the food materials. As shown in fig. 8 and 9, the base 120 and the bearing housing 108 are integrally formed. The food processing assembly 100 includes a shaft 102. Bearing 106 is fitted over shaft 102 and is disposed within bearing seat 108. The shaft 102 is rotatably connected to a bearing block 108 by a bearing 106. The bearing housing 108 is disposed within the base 120.

As shown in fig. 4 and 7, a plurality of first connection portions 1200 are formed at a lower portion of the base 120, and the plurality of first connection portions 1200 are spaced apart from each other. One end of each first connection portion 1200 is connected to the bearing housing 108, and the other end of each first connection portion 1200 is connected to a sidewall of the base 120.

Preferably, the bearing housing 108 is disposed at the bottom of the base 120, and accordingly, the first connection portion 1200 is formed at the bottom of the base 120. This facilitates maximum subsidence of bearing housing 108, increasing the space between bearing housing 108 and chassis 126, and thus facilitating a more rational arrangement of base 120. With bearing frame 108 set up in the bottom of base 120, first connecting portion 1200 forms the bottom at base 120 correspondingly, under the condition that satisfies intensity, the space of base 120 that can utilize more rationally, is favorable to the miniaturized design.

In this embodiment, the bearing housing 108 and the sidewall of the base 120 are connected by providing the first connection portion 1200, that is, the bearing housing 108 is not directly placed on the bottom of the base 120, but a separate connection structure is provided. This advantageously draws a portion of the hollow structure at the bottom of the base 120, thereby reducing the overall weight of the food processing apparatus 10 and saving material.

By providing a plurality of first connection portions 1200, and the plurality of first connection portions 1200 are distributed at intervals, which is beneficial to provide support for the bearing seat 108 from multiple directions, the uniformity of the force applied to the bearing seat 108 is improved, and thus the stability and reliability of the operation of the bearing seat 108 are improved.

Further, each of the first connection portions 1200 is configured to extend from a sidewall of the base 120 toward the central axis 102 of the base 120 in a linear direction so as to position the bearing housing 108 at the center of the base 120, thereby aligning the center of gravity of the bearing housing 108, the rotation center of the bearing 106, and the central axis 102 of the base 120. This is beneficial to improving the overall dynamic balance performance of the food processing apparatus 10, and especially when the bearing 106 rotates at a high speed, the stability and reliability of the operation of the apparatus can be further improved, and the phenomena of abnormal sound and noise can be reduced.

In addition, the first connection portion 1200 is configured with a cambered surface structure. The cambered surface structure is favorable for reducing the moment received by the gravity of the bearing 106 at the connecting position of the side walls of the first connecting portion 1200 and the cup body 300, and dispersing the stress, thereby improving the mechanical property of each first connecting portion 1200 and prolonging the service life of the first connecting portion 1200.

As shown in fig. 8, the first connection portion 1200 is further provided with a plurality of ribs 1202, so as to improve the strength of the first connection portion 1200 and prolong the service life of the first connection portion 1200.

Example 4

As shown in fig. 9, in any of the above embodiments, a receiving cavity 1082 is provided in the bearing seat 108. The receiving cavity 1082 is used for receiving the bearing 106. Specifically, a first step 1080 is provided within the bearing seat 108. As shown in fig. 4, the top of the first step 1080 is provided with an oil seal 130 for sealing in the axial direction 102. The bottom of the first step 1080 is provided with a receiving cavity 1082.

In this embodiment, by providing the first step 1080 and providing the accommodating cavity 1082 at the bottom of the first step 1080, a relatively independent installation space and a relatively independent working space are provided for the bearing 106, so that the interference of an external object on the working of the bearing 106 is reduced, and the bearing 106 can work stably and reliably. The first step 1080 is provided to both define the receiving cavity 1082 with the bearing seat 108 and limit axial displacement of the bearing 106 from the shaft 102. In addition, the first step 1080 may also be used to support the oil seal 130.

Example 5

As shown in fig. 1-10, according to yet another embodiment of the first aspect of the present invention, there is provided a food processing device 10 comprising a bearing housing 108 and a base 120. Bearing housing 108 is disposed within base 120, and base 120 and bearing housing 108 are integrally formed.

In this embodiment, through setting up base 120 and bearing frame 108 to integrated into one piece, base 120 and bearing frame 108 can be produced as a whole in the process simultaneously promptly, and not produce bearing frame 108 and base 120 alone, consequently can reduce process quantity by a wide margin, reduce the production degree of difficulty, promote production efficiency. Further, the base 120 and the bearing seat 108 are integrally formed, and the base and the bearing seat are integrated instead of two separated single bodies, so that later assembly is not needed, and the assembly time is reduced. The bearing seat 108 and the base 120 which are integrally formed are made of the same material and have good consistency, and the dynamic balance performance of the bearing seat 108 and the base 120 is greatly improved compared with that of the split bearing seat 108 and the base 120 in the prior art due to the fact that the bearing seat and the base are a whole. It should also be noted that the base 120 and the bearing seat 108, which are integrally formed, are often made of plastic material, and the forming speed and efficiency are high. Compared with the bearing seat 108 made of metal, the bearing seat 108 is not required to be manufactured in a mode of stretching a convex hull, and the bearing seat 108 is not required to be independently processed, so that the processing procedures can be greatly reduced, the production efficiency is improved, and materials can be greatly saved.

Further, the food processing apparatus 10 also includes a food processing assembly 100. The food processing assembly 100 includes a shaft 102. The food processing device 10 further includes a bearing 106, wherein the bearing 106 is disposed on the shaft 102 and is disposed in the bearing seat 108. The shaft 102 is rotatably connected to a bearing block 108 by a bearing 106.

By arranging the food processing assembly 100, and the food processing assembly 100 comprises the shaft 102, the food processing assembly 100 can cut and stir food materials through the rotation of the shaft 102. By arranging the bearing 106 and sleeving the shaft 102, the bearing 106 is arranged in the bearing seat 108, so that the shaft 102 is rotatably connected with the bearing seat 108 through the bearing 106. The bearing seat 108 is disposed in the base 120, and the bearing seat 108 and the base 120 are integrally formed, so that the base 120 provides a stable support for the bearing seat 108 and a support point for the food processing assembly 100. The bearing seat 108 and the base 120 are integrally formed, so that the production link can be shortened, and the production efficiency is improved. The bearing seat 108 and the base 120 do not need secondary assembly, and the bearing seat and the base are integrally formed into a whole, so that the consistency of the bearing seat and the base is favorably improved, no fit clearance exists between the bearing seat and the base, the dynamic balance performance is good, the phenomena of abnormal sound and noise can not occur, and the working stability and reliability are improved.

As shown in fig. 1, 4 and 6, further, the food processing device 10 further includes a support 124. The support 124 is disposed at the bottom of the bearing seat 108 to support the bearing 106 and limit axial displacement of the bearing 106 in the axial direction 102. The support 124 is removably connected to the bearing block 108. The support 124 and the first step 1080, the side wall of the bearing seat 108 enclose a receiving cavity 1082.

In this embodiment, the support member 124 is disposed at the bottom of the bearing seat 108 and connected to the bearing seat 108, which facilitates the closing of the accommodating cavity 1082, and ensures the independence and stability of the working space of the bearing 106. More importantly, the support member 124 is disposed at the bottom of the bearing seat 108, and can provide support for the bearing 106, so as to prevent the bearing 106 from falling out of the accommodating cavity 1082 under the action of gravity or due to other reasons, thereby further limiting the axial displacement of the bearing 106, and improving the stability of the operation of the bearing 106. It should be noted that, in the related art, since the bearing seat 108 is usually a metal part, a platform or a step is generally formed on the bottom of the bearing seat 108 by turning or the like to support the bearing 106. The supporting structure in the related art has the advantages of more complex processing mode, long process route, low production efficiency and more complex and longer assembly process. In this embodiment, the supporting member 124 is provided as a separate body and connected to the bearing seat 108, so that the bearing 106 can be supported, the structure of the bearing seat 108 is simplified, the production processes of the bearing seat 108 and the supporting member 124 are simplified, the production difficulty of the bearing seat 108 is reduced, and the installation and maintenance of the bearing 106 are more convenient. Further, since the supporting members 124 are independent bodies rather than being integrated with the bearing housing 108, the installation manner and the installation order are more flexible, and the overall installation process and the installation order are advantageously optimized, thereby improving the installation efficiency. In addition, when the bearing seat 108 or the support 124 breaks down and needs maintenance and replacement, the number of replaced parts can be reduced, and materials and parts are saved.

In this embodiment, the bearing seat 108 is detachably connected to the support 124, which is beneficial to improving convenience of assembly and maintenance. In addition, the mounting process, the mounting sequence and the like of the support member 124 and the bearing 106 can be adjusted, so that the flexibility of the mounting process and the mounting sequence is improved.

As shown in fig. 1 and 11, the support member 124 is provided with a second through hole 1240, as shown in fig. 7, the bearing seat 108 is provided with a second screw hole 1088, and the food processing apparatus 10 further includes a second fastening member 202.

As shown in fig. 6, after passing through the second through hole 1240, the second fastening member 202 is connected to the bearing seat 108 through the second screw hole 1088, so as to realize the detachable connection between the support member 124 and the bearing seat 108.

It is understood that the connection between the support member 124 and the bearing seat 108 is not limited to removable threaded connection, but may be adhesive, riveted, clamped, welded, etc.

Example 6

In addition to the above embodiments, the food processing device 10 further includes a clutch 138 and a spacer 140. The clutch 138 is sleeved on the shaft 102, the clutch 138 is located on one side of the support 124 away from the bearing seat 108, and the clutch 138 is used for connecting a driving device. The washer 140 is disposed on the shaft 102, and the washer 140 is disposed between the clutch 138 and the support 124.

In this embodiment, a clutch 138 is provided to facilitate connection to a drive device to power rotation of the shaft 102. Meanwhile, the clutch 138 can be separated from the driving device to disconnect the power for rotating the shaft 102, so that safety accidents caused by rotation of the food processing assembly 100 when a user takes and places food materials are avoided, and the convenience and safety of equipment use are improved. The clutch 138 is disposed on the shaft 102 to drive the shaft 102 to rotate. The clutch 138 is located on the side of the support 124 remote from the bearing housing 108, i.e. on the bottom side of the bearing housing 108, to facilitate connection to a drive device on the base 302. By providing a spacer 140 between the clutch 138 and the support 124, the support 124 is protected and isolated from wear between the clutch 138 and the support 124, thereby extending the useful life of the support 124.

Example 7

As shown in fig. 1 to 10, according to yet another embodiment of the first aspect of the present invention, there is provided a food processing apparatus 10 including a food processing assembly 100, a bearing 106, a bearing seat 108, a pedestal 120, and a cup 300, the cup 300 being threadedly coupled to the pedestal 120. Cup 300 is a clear cup or a metal cup. Wherein the base 120 and the bearing housing 108 are integrally formed.

Further, the bearing housing 108 is provided at the bottom of the base 120. The bearing 106 is disposed within a bearing seat 108. The food processing assembly 100 includes a shaft 102. The bearing 106 is further sleeved on the shaft 102, and the shaft 102 is rotatably connected with the bearing seat 108 through the bearing 106.

The food processing apparatus 10 further comprises: an oil seal 130 and a seal 132. A first step 1080 is provided in the bearing housing 108, the bearing 106 is provided at the bottom of the first step 1080, and the oil seal 130 is provided at the top of the first step 1080. The oil seal 130 is used to seal the axial 102 gap of the shaft 102. The oil seal 130 is also sleeved on the shaft 102.

As shown in fig. 1 and 10, in the present embodiment, by providing the oil seal 130 on the top of the first step 1080, the oil seal 130 is sleeved on the shaft 102, so that the oil seal 130 seals the shaft 102 of the shaft 102 upwards, and leakage of liquid is reduced, thereby improving the working stability and the smooth degree of rotation of the shaft 102. The oil seal 130 is sleeved on the shaft 102, and the oil seal 130 can be prevented from falling off or shifting, so that the working stability and reliability of the oil seal 130 are ensured. In addition, the first step 1080 here also functions to support the oil seal 130.

The seal ring 132 is used to provide a radial seal for the bearing housing 108 to prevent liquid from seeping into the bearing housing 108. The top of the bearing seat 108 is provided with an annular groove 1086, and the sealing ring 132 is arranged in the annular groove 1086.

By providing the sealing ring 132, a radial seal can be provided for the bearing seat 108, so as to prevent liquid from penetrating into the bearing 106 along the radial direction of the bearing seat 108 and affecting the operation of the bearing 106. The annular groove 1086 is provided to fix the sealing ring 132, so as to prevent the sealing ring 132 from being displaced or falling off, thereby ensuring the working stability and reliability of the sealing ring 132.

Example 8

As shown in fig. 4, in any of the above embodiments, a third connecting portion 1206 is formed on the base 120 of the food processing device 10 extending in the top direction, and the cup 300 is fixedly connected to the third connecting portion 1206.

In this embodiment, the base 120 of the food processing device 10 is extended to form a third connecting portion 1206, as shown in fig. 12, that is, the cup body 300 is connected to the upper half of the base 120, and the bearing seat 108 is connected to the lower half of the cup, so as to achieve the purpose of sinking the bearing seat 108, so that the center of gravity of the bearing seat 108 is moved downward, which is beneficial to reducing noise and abnormal sound when the bearing 106 rotates.

Example 9

According to yet another embodiment of the present application, a food processing device 10 is provided that includes a food processing assembly 100, a bearing 106, a bearing seat 108, a base 120, a cup 300, and a chassis 126.

The food processing assembly 100 includes a shaft 102, a bearing 106 disposed on the shaft 102, and a bearing seat 108 disposed within the bearing seat 108. The base 120 is provided with a bearing seat 108. Bearing housing 108 is a plastic bearing housing.

Third connecting portion 1206 is formed on base 120 extending in the top direction, and cup 300 is fixedly connected to third connecting portion 1206. The chassis 126 is disposed in the base 120, and the chassis 126 and the cup 300 enclose a cavity for accommodating food materials. Further, the bearing seat 108 is located on the underside of the bottom wall of the chassis 126.

A cavity for containing food materials is surrounded by the chassis 126 and the cup body 300, namely the cup body 300 and the chassis 126 are of split type structures, and the cup body 300 is of a cylindrical structure instead of a barrel-shaped structure. Due to the arrangement, the cup body 300 can be made of glass, and on one hand, the glass has better heat resistance and transparency and longer service life. Glass is also safer and healthier than plastic. It will be appreciated that, since the food processing assembly 100 needs to penetrate into the cup 300, if the barrel-shaped cup 300 is made of glass, a through hole needs to be formed in the glass, which is complicated and difficult to process. By adopting the structure, the whole process of the equipment is facilitated to be simplified, and the processing difficulty is reduced. The bearing seat 108 is located on the underside of the bottom wall of the chassis 126, and is adapted to be connected to the base 120 and avoid a cavity for receiving food material.

It will be appreciated that the tray 126 may be integral with the bowl 300, but such a construction generally requires the provision of a plastics material body to facilitate the machining of the through-holes in the tray 126.

It should be noted that, because the bearing seat 108 is disposed in a sunken manner, the chassis 126 can no longer bear the weight of the bearing seat 108 and the bearing 106, and the centrifugal force generated when the bearing 106 rotates at a high speed, compared with the prior art, and therefore the chassis 126 can be made thinner than the chassis 126 of the prior art, thereby saving material.

As shown in fig. 5 and 9, a thread structure 1214 is further provided on the third connecting portion 1206 to mount the cup 300. Specifically, the base 120 may be fixedly coupled to the cup 300 via a threaded structure 1214.

By arranging the thread structure 1214 on the inner circumferential surface of the base 120, the cup body 300 can be conveniently installed, and is stable and reliable after installation and is not easy to fall off. The stability of the threaded connection of the base 120 is greater when the shaft 102 is rotated at high speeds. When needing to maintain, threaded connection's mode is easily dismantled, is favorable to promoting work efficiency.

Example 10

According to yet another embodiment of the present application, a food processing device 10 is provided that includes a food processing assembly 100, a bearing 106, a bearing seat 108, a base 120, a cup 300, and a chassis 126.

The food processing assembly 100 includes a shaft 102, a bearing 106 disposed on the shaft 102, and a bearing seat 108 disposed within the bearing seat 108. The base 120 is provided with a bearing seat 108. Bearing housing 108 is a plastic bearing housing.

Third connecting portion 1206 is formed on base 120 extending in the top direction, and cup 300 is fixedly connected to third connecting portion 1206. The bottom plate 126 is disposed in the base 120, and the bottom plate 126 and the cup body 300 enclose a cavity for accommodating food materials. Further, the bearing seat 108 is located on the underside of the bottom wall of the chassis 126.

Further, a fourth connecting portion 1208 is disposed between the third connecting portion 1206 and the first connecting portion 1200, and the fourth connecting portion 1208 is used for connecting the chassis 126.

In this embodiment, the fourth connection 1208 is provided to facilitate connection to the chassis 126 and provide support for the chassis 126. Meanwhile, there is fourth connecting portion 1208 located at a position between first connecting portion 1200 and third connecting portion 1206, that is, fourth connecting portion 1208 is closer to the middle of base 120, which is beneficial for the bottom of cup 300 to be seated in base 120, so that the center of gravity of cup 300 is lowered and is limited by base 120. After the food material is taken in the cavity enclosed by the cup body 300 and the chassis 126, the limit of the base 120 is facilitated, and the stability and the reliability of the cup body 300 are improved.

In addition, a fourth connecting portion 1208 is arranged in the base 120, and the chassis 126 is connected to the fourth connecting portion 1208, so that the fourth connecting portion 1208 provides support for the chassis 126, and the chassis 126 and the bearing seat 108 keep a certain interval instead of being directly abutted against the bearing seat 108, thereby further reducing the mutual influence among the chassis 126, the bearing seat 108 and the bearing 106, and improving the working stability and reliability of the bearing 106.

Further, the cross-sectional area of the third connecting portion 1206 is larger than that of the fourth connecting portion 1208, and the cross-sectional area of the fourth connecting portion 1208 is larger than that of the first connecting portion 1200.

In this embodiment, the cross-sectional area of the third connecting portion 1206 is larger than that of the fourth connecting portion 1208, and the cross-sectional area of the fourth connecting portion 1208 is larger than that of the first connecting portion 1200, that is, the cross-sectional area is smaller closer to the bottom of the base 120 among the three connecting portions. Because the inside of base 120 is hollow structure, adopts the structure of this kind of shrink gradually formula, is favorable to the structure of below to form stable support to the top to play spacing effect, be favorable to avoiding cup 300 to sink too much and take place the contact with structures such as bearing frame 108.

As shown in fig. 4 and 9, a first connection step 1210 is disposed between the first connection portion 1200 and the fourth connection portion 1208. The first connection step 1210 may play a role of reinforcement, thereby improving the overall strength and rigidity of the base 120.

A second connection step 1212 is provided between the third connection portion 1206 and the fourth connection portion 1208. This facilitates abutment of the sidewall of cup 300 with second connecting step 1212, and accordingly second connecting step 1212 can also provide support for cup 300. This configuration may eliminate the need for the bottom tray 126 to support the bowl 300, which may help reduce the stress on the bottom tray 126.

Example 11

As shown in fig. 1 and fig. 7, on the basis of the above embodiments, the bearing seat 108 and the support 124 are further respectively provided with a first through hole 1084. The food processing device 10 further includes a first fastener 200, the first fastener 200 extending through the first through hole 1084.

As shown in fig. 10, a nut post 1266 is provided on the bottom of the chassis 126, i.e., on the side close to the bearing seat 108, and a first screw hole 1264 is provided on the nut post 1266. The chassis 126 is also removably connected to the support member 124 by engagement of the first fasteners 200 with the first threaded holes 1264.

As shown in fig. 3 and 4, in the present embodiment, the chassis 126 and the support 124 are detachably connected, that is, the chassis 126, the support 124, the bearing seat 108, and the bearing 106 in the bearing seat 108 are all connected together. Further, the bearing seat 108 and the base 120 are integrally formed, so that the chassis 126, the support 124, the base 120, the bearing 106, the bearing seat 108, and the like are all connected to form a whole. Thus, in the process of assembling the electric appliance, the whole can be managed and assembled as a module. Adopt this kind of structure, can accomplish this kind of holistic module assembly earlier, assemble the module to whole equipment again to can promote the holistic assembly speed of equipment and production efficiency, be difficult for appearing the phenomenon that accessories lost, forgotten the assembly moreover.

The chassis 126 is detachably connected to the support 124 by the first fastening member 200, so that it is convenient to install and maintain, and it is easy to adjust the assembly process of the module in the event of a failure. As shown in fig. 6, the first through hole 1084 is formed in the bearing seat 108, so that the support member 124, the chassis 126 and the bearing seat 108 can be integrally connected after the first fastener 200 passes through the bearing seat 108, thereby forming a module.

It should be noted that the first fastening member 200 connects the chassis 126 and the supporting member 124 together, not only connects the chassis 126 and the bearing seat 108 as a whole, but also fixes the supporting member 124, which has two advantages, and is beneficial to reducing the number of fastening members and saving material and space.

In other embodiments, the chassis 126 and the support 124 may be fixedly connected by riveting or the like.

Example 12

According to yet another embodiment of the present application, a food processing device 10 is provided that includes a food processing assembly 100, a bearing 106, a bearing seat 108, a base 120, a cup 300, and a chassis 126.

The food processing assembly 100 includes a shaft 102, a bearing 106 disposed on the shaft 102, and a bearing seat 108 disposed within the bearing seat 108. The base 120 is provided with a bearing seat 108. Bearing housing 108 is a plastic bearing housing.

Third connecting portion 1206 is formed on base 120 extending in the top direction, and cup 300 is fixedly connected to third connecting portion 1206. The chassis 126 is disposed in the base 120, and the chassis 126 and the cup 300 enclose a cavity for accommodating food materials. Further, the bearing seat 108 is located on the underside of the bottom wall of the chassis 126.

Further, the chassis 126 is provided with a first through hole 1262 adapted to pass the shaft 102. As shown in fig. 5, the food processing assembly 100 further includes a work implement 104. The work implement 104 is disposed on the shaft 102 through the first through hole 1262 and on a side of the chassis 126 remote from the bearing seat 108.

In this embodiment, the base plate 126 is provided with a first through hole 1262 to facilitate the shaft 102 to pass through, so that the shaft 102 can extend out of the base plate 126, thereby facilitating the connection of the work implement 104 to the shaft 102 at the side of the base plate 126 away from the bearing seat 108. Such structure is favorable to holding the cavity setting of eating the material and keeping away from one side of bearing frame 108 in chassis 126 to both can let chassis 126 generate heat, can stir, cut the edible material in the one side of keeping away from bearing frame 108 through work executive component 104 simultaneously again. And the cavity for accommodating the food materials is arranged on one side of the chassis 126 far away from the bearing seat 108, so that a larger space is provided, and more food materials can be accommodated.

The work performing part 104 may be a blade to facilitate cutting and crushing of the food material. The operation executing member 104 may be a stirring blade to stir the food material. The work implement 104 may be a washing member that washes the cup 300 or the food material by rotating. The work executing unit 104 may be a combination of a blade and a stirring blade to perform cutting and crushing work while stirring.

Example 13

As shown in fig. 1-10, a food processing device 10 is provided according to yet another embodiment of the present application, including a food processing assembly 100, a bearing 106, a bearing seat 108, a base 120, a cup 300, and a chassis 126.

The food processing assembly 100 includes a shaft 102, a bearing 106 disposed on the shaft 102, and a bearing seat 108 disposed within the bearing seat 108. The base 120 is provided with a bearing seat 108. The bearing housing 108 is a plastic bearing housing.

Third connecting portion 1206 is formed on base 120 extending in the top direction, and cup 300 is fixedly connected to third connecting portion 1206. The bottom plate 126 is disposed in the base 120, and the bottom plate 126 and the cup body 300 enclose a cavity for accommodating food materials.

Further, the bearing seat 108 is located on the underside of the bottom wall of the chassis 126. The thickness of the chassis 126 is 0.3mm to 2.5 mm.

In the present embodiment, the thickness of the bottom plate 126 is set to 0.3mm to 2.5mm, which is greatly reduced compared to the prior art. This thickness is achieved by structural improvement, not simple size increase or decrease.

Specifically, because the chassis 126 and bearing seat 108 are spaced apart, the bearing seat 108 is recessed to the bottom of the base 120, which eliminates the need for the chassis 126 to bear the weight of the bearing seat 108, as well as the centrifugal forces of the bearing 106 when rotating at high speeds. After the stress on the bottom plate 126 is reduced, the requirements on the strength and the rigidity of the bottom plate 126 are reduced, so that the thickness of the bottom plate 126 can be reduced, but the thickness is not simply reduced.

In some embodiments, the bottom plate 126 is only used for receiving food materials, and does not need to be connected with the heating element 142, and the bottom plate 126 is formed by punching a single layer of metal plate because the bottom plate does not bear the weight of the bearing seat 108. The single-layer metal plate is, for example, a steel plate. The heating members 142 are not connected to the base plate 126, and the thickness of the base plate 126 is 0.3mm to 1mm, for example, the thickness of the base plate 126 using a single metal plate is 0.3mm, 0.5mm, 0.6mm, or the like.

In other embodiments, the chassis 126 is also used to heat food material. The food processing device 10 also includes a heating element 142. The heating element 142 is connected to the base plate 126, and the heating element 142 is used to heat the base plate 126.

By providing the heating element 142 on the bottom plate 126, the food material in the cup 300 can be heated by heating the bottom plate 126. This is advantageous for expanding the function of the food processing apparatus 10, and not only can the food material be smashed and stirred, but also the food material can be directly heated, that is, after the food material is smashed, the cooking can be directly performed. This provides more convenience to the user in using the food processing device 10.

The chassis 126 with the heating element 142 at the bottom is a composite of two layers of metal plates, one layer of metal plate is used for bearing, for example, a steel plate is adopted, the strength of the chassis 126 can be improved by adopting the steel plate, and the thickness of the steel plate is 0.3mm, 0.5mm, 0.6mm and the like; another layer of metal plate is used for heating and conducting heat, for example, an aluminum plate is used, which not only reduces the overall weight of the chassis 126, but also facilitates connection with the heating element and increases the heating area. The aluminum plate may have a thickness of 1mm, 1.2mm, 1.5mm, 2mm, etc. In the case of the double-layer metal plate, the thickness of the bottom plate 126 is the sum of the thicknesses of the two layers of metal plates, and specifically, the thickness of the bottom plate 126 of the double-layer metal plate is 1mm to 2.5mm, for example, 1.2mm, 1.4mm, 1.5mm, 1.8mm, 2mm, 2.5mm, or the like. It will be appreciated that aluminum has a low density and good thermal conductivity and can therefore be made thicker. The steel plate has high strength and high density, so the steel plate has a thinner thickness.

Compared with the prior art, the thickness of the chassis 126 is reduced no matter the single-layer metal plate connected with the heating element 142 or the double-layer metal plate connected with the heating element 142 is needed, so that the weight of the equipment can be reduced, the material can be saved, and the space occupied by the chassis 126 can be reduced.

Example 14

As shown in fig. 1-10, a food processing device 10 is provided according to yet another embodiment of the present application, including a food processing assembly 100, a bearing 106, a bearing seat 108, a base 120, a cup 300, and a chassis 126.

The food processing assembly 100 includes a shaft 102, a bearing 106 disposed on the shaft 102, and a bearing seat 108 disposed within the bearing seat 108. The base 120 is provided with a bearing seat 108. Bearing housing 108 is a plastic bearing housing.

As shown in FIG. 13, the food processing device 10 further includes a base 302, the base 302 being removably connected to the base 120.

In the above embodiment, the base 302 and the base 120 are connected to facilitate the provision of power supply components in the base 302 to provide power to the components in the base 120 to drive the food processing assembly 100 to rotate. The base 302 and the base 120 are detachably connected, so that the base 302 and the base 120 are convenient to maintain and repair, and the installation is convenient. It is understood that the base 302 may not be provided with a power supply member, and only serves as a support structure for the base 120.

Example 15

As shown in fig. 1-10, according to yet another embodiment of the first aspect of the present invention, there is provided a food processing apparatus 10 comprising a food processing assembly 100, a bearing 106, a bearing seat 108, a pedestal 120, and a cup 300. Cup 300 is threadably connected to mount 120. Cup 300 is a clear cup or a metal cup. Wherein the base 120 and the bearing housing 108 are integrally formed.

Further, the food processing assembly 100 includes a shaft 102. Bearing 106 is fitted over shaft 102 and is disposed within bearing seat 108. The shaft 102 is rotatably connected to a bearing block 108 by a bearing 106. The bearing housing 108 is disposed within the base 120.

In this embodiment, through setting up base 120 and bearing frame 108 to integrated into one piece, base 120 and bearing frame 108 can be produced as a whole in the process simultaneously promptly, and not produce bearing frame 108 and base 120 alone, consequently can reduce process quantity by a wide margin, reduce the production degree of difficulty, promote production efficiency. Further, the base 120 and the bearing seat 108 are integrally formed, and the base and the bearing seat are integrated instead of two separated single bodies, so that later assembly is not needed, and the assembly time is reduced. The bearing seat 108 and the base 120 which are integrally formed are made of the same material and have good consistency, and the dynamic balance performance of the bearing seat 108 and the base 120 is greatly improved compared with that of the split bearing seat 108 and the base 120 in the prior art due to the fact that the bearing seat and the base are a whole. It should also be noted that the base 120 and the bearing seat 108, which are integrally formed, are often made of plastic material, and the forming speed and efficiency are high. Compared with the bearing seat 108 made of metal, the bearing seat 108 is not required to be manufactured in a mode of stretching a convex hull, and the bearing seat 108 is not required to be independently processed, so that the processing procedures can be greatly reduced, the production efficiency is improved, and materials can be greatly saved.

By arranging the food processing assembly 100, and the food processing assembly 100 comprises the shaft 102, the food processing assembly 100 can cut and stir food materials through the rotation of the shaft 102. By arranging the bearing 106 and sleeving the shaft 102, the bearing 106 is arranged in the bearing seat 108, so that the shaft 102 is rotatably connected with the bearing seat 108 through the bearing 106. The bearing seat 108 is disposed in the base 120, and the bearing seat 108 and the base 120 are integrally formed, so that the base 120 provides a stable support for the bearing seat 108 and a support point for the food processing assembly 100. The bearing seat 108 and the base 120 are integrally formed, so that the production link can be shortened, and the production efficiency is improved. The bearing seat 108 and the base 120 do not need secondary assembly, and the bearing seat and the base are integrally formed into a whole, so that the consistency of the bearing seat and the base is favorably improved, no fit clearance exists between the bearing seat and the base, the dynamic balance performance is good, the phenomena of abnormal sound and noise can not occur, and the working stability and reliability are improved.

As shown in fig. 6, further, the food processing device 10 also includes a coupler and a trigger lever 136. The coupler and the trigger bar 136 are all located at the bottom of the base 120, and the centerlines of the trigger bar 136, the shaft 102, and the coupler are in a plane.

In the present embodiment, the center lines of the trigger bar 136, the shaft 102 and the coupler are in a plane, and the three structures have certain symmetry. Since at least part of the three components are disposed at the bottom of the base 120, the bottom structure of the base 120 has a certain symmetry. With such a configuration, the dynamic balance performance is greatly improved relative to an eccentric or asymmetric configuration, so that the dynamic balance performance of the shaft 102 can be improved when rotating at a high speed.

In addition, because the trigger bar 136 and the coupler are both disposed at the bottom of the base 120, the centers of the two are also substantially in one plane or in a relatively close plane, thereby further improving the dynamic balance performance, and being beneficial to reducing abnormal sound and eliminating noise.

It will be appreciated that the coupler is used for circuit coupled communication. The bottom of the base 120 is provided with a second connecting portion 1204, and the coupler is connected to the base 120 through the second connecting portion 1204. Specifically, the coupler is provided with a plurality of pins, and the pins are used for connecting the leads. Of the plurality of pins, a part of the pins are used for connecting and grounding, a part of the pins supply power to the live wire and the neutral wire of the heating element 142 on the food processing device 10, and a part of the pins supply power to the temperature sensor and the micro-motion protection switch. The coupler is used in combination with a mating connector on the base 302, the connector of the base 302 plugging in electrical components such as a control circuit board and a power circuit board.

By providing a coupler for circuit-coupled communication, it is convenient to use with the base 302, i.e., the coupler can be energized to mate with a connector on the base 302 to provide power for rotation of the shaft 102. The coupler is connected to the base 120 through the second connection portion 1204, that is, the coupler is a separate structure with respect to the base 120, which facilitates the coupler to be independently produced as an electronic structure, ensuring convenience of production and production quality.

A microswitch is provided on the base 302. The trigger lever 136 is provided at the bottom of the base 120. The trigger bar 136 is used to trigger the micro switch to prevent the cover of the food processing apparatus 10 from continuing to work when the cover is opened, so as to improve the convenience and safety of the operation of the apparatus.

In the above embodiment, the food processing device 10 includes any one of: a wall breaking machine, a food processor, a soybean milk machine and a meat grinder.

Example 16

According to an embodiment of the present invention, there is provided a food processing apparatus 10, which includes a base 120, the base 120 having a threaded structure 1214 for engaging with the glass cup 300, a support shoulder (second connection step 1212) for engaging with the bottom plate 126, a mounting post (second connection portion 1204) for engaging with the coupler, and a third threaded hole 146 for engaging with the bottom cover 144. The center of base 120 has a receiving cavity 1082 in which bearing 106 is mounted. The two sides of the accommodating cavity 1082 are respectively provided with a first through hole 1084 and a second screw hole 1088 for passing a screw, the upper portion of the accommodating cavity 1082 is provided with a first step 1080 for mounting the oil seal 130 and an annular groove 1086 for mounting the sealing ring 132, and the center of the bearing seat 108 is a second through hole 1190 for passing the shaft 102.

In particular, the depth of central receptacle 1082 is less than the overall height of the ball bearing 106 assembly, and the side walls of receptacle 1082, i.e., the side walls of bearing housing 108, are mounted in a clearance fit with ball bearing 106.

The food processing apparatus 10 further includes a press plate (support 124) having first and second through holes 1084 and 1240 for screws to pass through, and a central clearance hole 148, provided at both sides.

The oil seal 130 is placed on the first step 1080 of the bearing seat 108 on the base 120, and after the sealing ring 132 is placed in the annular groove 1086, the chassis 126 assembly is placed on the heat generating tray support shoulder surface (second connecting step 1212) on the base 120. Second spacer 150 is placed within pocket 1082 of base 120 and shaft 102, with assembled ball bearing 106, is loaded into pocket 1082. The top end of the shaft 102 is inserted through the second through hole 1190 of the base 120, the oil seal 130, the seal ring 132 and the chassis 126 assembly, and then the pressing plate is placed thereon, and the first fastener 200 is inserted through the first through hole 1084 of the pressing plate (the support 124), and then the first through hole 1084 of the bearing seat 108 is locked on the chassis 126 assembly. It is understood that the chassis 126 assembly includes the chassis 126, the heating member 142. The second fastener 202 is then passed through the second through hole 1240 of the press plate (support 124) and locked into the second threaded hole 1088 of the bearing housing 108. The blade assembly (i.e., the work implement 104) is mounted on the shaft 102 and, after rotation, riveted. The installation of the modular assembly is completed by attaching the coupler 134 to the second connecting portion 1204 of the base 120. The modular assembly integrates a heating function, a whipping function, and a base function.

In summary, according to the food processing apparatus provided by the embodiment of the present invention, compared to the prior art, the bearing seat is disposed on the base, and the bearing seat is a plastic bearing seat, so that the bearing seat and the base can be integrally formed, post-processing is basically not required, and the number of production processes can be reduced. And simple structure, light in weight, the shaping precision is high, still is favorable to promoting food processing apparatus's dynamic balance performance to reduce the abnormal sound of during operation, the noise reduction.

In embodiments according to the present invention, the terms "first", "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; the term "plurality" means two or more unless expressly limited otherwise. The terms "mounted," "connected," "fixed," and the like are to be construed broadly, and for example, "connected" may be a fixed connection, a removable connection, or an integral connection; "coupled" may be direct or indirect through an intermediary. Specific meanings of the above terms in the embodiments according to the present invention can be understood by those of ordinary skill in the art according to specific situations.

In the description of the embodiments according to the present invention, it should be understood that the terms "upper", "lower", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings only for convenience in describing the embodiments according to the present invention and simplifying the description, but do not indicate or imply that the referred devices or units must have a specific direction, be configured in a specific orientation, and operate, and thus, should not be construed as limiting the embodiments according to the present invention.

In the description herein, the description of the terms "one embodiment," "some embodiments," "specific embodiments," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of an embodiment according to the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above description is only a preferred embodiment of the embodiments according to the present invention, and is not intended to limit the embodiments according to the present invention, and various modifications and variations may be made to the embodiments according to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the embodiment according to the present invention should be included in the protection scope of the embodiment according to the present invention.

Claims (25)

1. A food processing apparatus, comprising:

a bearing (106);

a bearing seat (108), wherein the bearing (106) is arranged in the bearing seat (108);

the base (120), the said bearing bracket (108) is set on the said base (120);

the cup body (300) is in threaded connection with the base (120), and the cup body (300) is a light-transmitting cup body or a metal cup body;

a food processing assembly (100), said food processing assembly (100) comprising a shaft (102), said bearing (106) being sleeved on said shaft (102);

wherein, the bearing seat (108) is a plastic bearing seat.

2. The food processing apparatus of claim 1,

the base (120) is integrally formed with the bearing seat (108).

3. Food processing device according to claim 1 or 2,

the bearing seat (108) is positioned at the lower part of the base (120).

4. Food processing device according to claim 1 or 2,

the base (120) is formed with a first connection portion (1200), and the first connection portion (1200) connects the bearing housing (108) and a sidewall of the base (120).

5. Food processing device according to claim 4,

the number of the first connection parts (1200) is multiple, and the multiple first connection parts (1200) are distributed at intervals.

6. The food processing apparatus of claim 4,

the first connection portion (1200) is configured to extend from a side wall of the base (120) toward a central axis direction of the base (120), and the first connection portion (1200) is configured with an arc structure.

7. The food processing apparatus of claim 4,

the first connecting portion (1200) is provided with a plurality of reinforcing ribs (1202).

8. The food processing apparatus of claim 4,

be equipped with first step (1080) in bearing frame (108), the bottom of first step (1080) is equipped with and holds chamber (1082), hold chamber (1082) are used for holding bearing (106).

9. The food processing device of claim 8, further comprising:

the supporting piece (124) is arranged at the bottom of the bearing seat (108) and connected with the bearing seat (108), and the accommodating cavity (1082) is enclosed by the supporting piece (124), the first step (1080) and the side wall of the bearing seat (108).

10. The food processing device of claim 9, further comprising:

the clutch (138) is sleeved on the shaft (102), the clutch (138) is positioned on one side, away from the bearing seat (108), of the support piece (124), and the clutch (138) is used for connecting a driving device;

a washer (140), the washer (140) being sleeved on the shaft (102), and the washer (140) being located between the clutch (138) and the support (124).

11. The food processing device of claim 9, further comprising:

the chassis (126) is arranged in the base (120), and a cavity for containing food materials is surrounded by the chassis (126) and the cup body (300);

the base (120) extends towards the top to form a third connecting part (1206), and the cup body (300) is fixedly connected with the third connecting part (1206).

12. The food processing apparatus of claim 11,

a fourth connecting part (1208) is arranged between the third connecting part (1206) and the first connecting part (1200), and the fourth connecting part (1208) is used for connecting the chassis (126).

13. The food processing apparatus of claim 12,

the cross-sectional area of the third connecting portion (1206) is larger than the cross-sectional area of the fourth connecting portion (1208), and the cross-sectional area of the fourth connecting portion (1208) is larger than the cross-sectional area of the first connecting portion (1200).

14. The food processing apparatus of claim 13,

a first connecting step (1210) is arranged between the first connecting part (1200) and the fourth connecting part (1208); and/or

And a second connecting step (1212) is arranged between the third connecting part (1206) and the fourth connecting part (1208).

15. The food processing apparatus of claim 11,

a first through hole (1084) is further formed in the bearing seat (108);

the food processing apparatus further comprises a first fastener (200), the first fastener (200) extending through the first via (1084);

the chassis (126) is also fixedly connected with the support (124) through the first fastener (200).

16. The food processing apparatus of claim 11,

a first through hole (1262) which is suitable for the shaft (102) to pass through is arranged on the chassis (126);

the food processing assembly (100) further comprises: and the work execution component (104) is arranged in the cup body and sleeved on the shaft (102) penetrating through the first through hole (1262).

17. The food processing apparatus of claim 16,

the work execution component (104) comprises any one or a combination of the following: blades, stirring blades or cleaning elements.

18. Food processing device according to claim 11,

the thickness of the chassis (126) is 0.3 mm-2.5 mm.

19. The food processing device of claim 11, further comprising:

the heating element (142) is connected with the bottom plate (126), and the heating element (142) is used for heating the bottom plate (126).

20. The food processing device of claim 8, further comprising:

and the oil seal (130) is arranged at the top of the first step (1080) and sleeved on the shaft (102).

21. Food processing device according to claim 1 or 2,

the food processing apparatus (10) further comprises: the top of bearing frame (108) is equipped with annular groove (1086), sealing washer (132) are located annular groove (1086).

22. Food processing device according to claim 1 or 2, characterized in that the food processing device (10) further comprises:

a base (302);

the base (120) is detachably connected to the base (302).

23. The food processing device according to claim 22, wherein the food processing device (10) further comprises:

a coupler (134), the coupler (134) for circuit coupled communication;

the bottom of the base (120) is provided with a second connecting part (1204), and the coupler (134) is connected with the base (120) through the second connecting part (1204).

24. The food processing device of claim 23, further comprising:

the microswitch is arranged on the base (302);

the trigger rod (136) is arranged at the bottom of the base (120), and the trigger rod (136) is used for triggering the micro switch.

25. The food processing apparatus of claim 24,

the centerlines of the trigger lever (136), the shaft (102), and the coupler (134) are in a plane.

Images