CN217852601U - Cup seat pad and cooking machine of cooking machine - Google Patents

Abstract

The application relates to a cup seatpad and cooking machine of cooking machine. The cup saucer is used for installing between the host computer of cooking machine and stirring cup, makes by deformable elastic material, the cup saucer including be used for with the first surface of stirring cup contact with be used for with the second surface of host computer contact, the first surface and/or the second surface forms a shock attenuation arch, the cup saucer is still including the motor shaft hole that is located central zone and the coupler hole that is located marginal zone, motor shaft hole and coupler hole are followed the thickness direction of cup saucer pad link up, first shock attenuation arch sets up the coupler hole is kept away from one side in motor shaft hole. So, vibrations can be alleviated and absorbed to first shock attenuation arch, improves the shock attenuation effect of cooking machine.

Description

Cup seat pad and cooking machine of cooking machine

Technical Field

The application relates to the field of small household appliances, in particular to a cup seat cushion of a food processor and the food processor.

Background

Along with the increasing living standard of people, many different types of food processors appear on the market, and the food processors are more and more popular with people. The functions of the food processor include but are not limited to functions of making soybean milk, squeezing fruit juice, making rice paste, mincing meat, shaving ice, making coffee and/or preparing facial mask and the like. However, the cooking machine easily causes the shaking amount of the stirring cup relative to the host machine to be large in the working process, so that the generated noise is large, and the user experience is poor.

SUMMERY OF THE UTILITY MODEL

The application provides a cup seatpad and cooking machine of cooking machine, and the shock attenuation effect is better.

The utility model provides a cup pad of cooking machine, cup pad is used for installing between the host computer of cooking machine and stirring cup, is made by deformable elastic material, cup pad includes:

the cup base pad comprises a first surface and a second surface, wherein the first surface is used for being in contact with the stirring cup, the second surface is used for being in contact with the host, a first shock absorption bulge is formed on the first surface and/or the second surface, the cup base pad further comprises a motor shaft hole located in a central area and a coupler hole located in an edge area, the motor shaft hole and the coupler hole are communicated along the thickness direction of the cup base pad, and the first shock absorption bulge is arranged on one side, away from the motor shaft hole, of the coupler hole.

Optionally, first shock attenuation arch includes a plurality of first sub-archs, a plurality of first sub-archs center on the center in motor shaft hole is the multirow and distributes, and follows the circumference in motor shaft hole, a plurality of first sub-archs concentrate and distribute along motor shaft hole's radial just to the region in coupler hole. Compared with the bulges of the integral structure, the plurality of first sub-bulges separated from each other have the advantages of larger flexibility, large deformation, better shock absorption effect and capability of better relieving and absorbing shock and impact at the periphery of the coupler hole.

Optionally, the first shock absorption protrusion further includes an arc-shaped strip-shaped boss disposed on the first surface and/or the second surface, and the plurality of first sub-protrusions protrude from the arc-shaped strip-shaped boss. The arc-shaped strip-shaped boss can increase the thickness of the cup seat cushion at the first shock absorption bulge, so that the strength of the area can be increased, and the risk of crushing and breakage of the area is reduced on the premise of keeping the elastic deformation.

Optionally, the range of the circumferential dimension of the arc-shaped strip-shaped boss in the motor shaft hole is 50mm to 80mm, and the range of the radial dimension of the arc-shaped strip-shaped boss in the motor shaft hole is 20mm to 30mm. The circumferential size and the radial size of the arc-shaped strip-shaped boss are set in the range, so that the peripheral space of the coupler hole can be effectively utilized, the shock absorption can be realized, and the interference can be avoided.

Optionally, the length of the arc-shaped strip-shaped boss in the circumferential direction of the motor shaft hole at least exceeds the length of the coupler hole in the direction by more than 2mm. Therefore, the circumferential length of the arc-shaped strip-shaped boss can be increased, and the vibration of a larger area around the coupler hole can be buffered and absorbed.

Optionally, the plurality of first sub-protrusions are cylindrical protrusions, a diameter range of the cylindrical protrusions is 3mm to 7mm, and a height range of the cylindrical protrusions protruding from the surface of the arc-shaped strip-shaped boss is 1mm to 3mm. The diameter and the height of the first sub-protrusion are selected within the size range, so that the elastic deformation of the first sub-protrusion can be ensured, and the strength of the first sub-protrusion can be ensured.

Optionally, the cup holder further includes a second shock absorption protrusion formed on the first surface, and the second shock absorption protrusion is disposed at the edge of the motor shaft hole and surrounds the center of the motor shaft hole. The vibrations that produce when second shock attenuation arch can be alleviated and the transmission of absorption arbor and motor shaft further improve the shock-absorbing capacity of cooking machine, promote user experience.

Optionally, the second shock absorbing protrusion includes a plurality of second sub-protrusions, top portions of the plurality of second sub-protrusions are separated from each other, and bottom portions of the plurality of second sub-protrusions are connected. The plurality of second sub-protrusions are mainly used for relieving and absorbing shock through the tops, the deformation amount of the plurality of second sub-protrusions can be increased through separation of the tops, the strength and the rigidity can be increased through connection of the plurality of second sub-protrusions at the bottoms, and fatigue damage of the plurality of second sub-protrusions under the action of pressure is avoided.

Optionally, a gap is left between the tops of the two adjacent second sub-protrusions, the range of the circumferential length of the motor shaft hole of the gap is 2mm to 3mm, the range of the radial width of the motor shaft hole of the gap is 4mm to 6mm, and the range of the axial height of the motor shaft hole of the gap is 5mm to 8mm. Therefore, the gap can provide a proper deformation space for the plurality of second sub-protrusions, the size of the gap is selected within the range, on one hand, the small deformation caused by the small size of the gap can be avoided, and on the other hand, the strength reduction caused by the large size of the gap is avoided.

A food processor, comprising:

the main machine comprises a motor shaft;

a blender cup comprising a knife assembly; and

the cup holder pad of any one of the above claims, wherein the cup holder pad is mounted between the host and the stirring cup. The cup seat cushion can relieve and absorb the vibration between the main machine and the stirring cup, and the noise is reduced.

Optionally, the mixing cup comprises a handle, and in an orthographic projection of the mixing cup in the height direction, a projection area of the first shock absorption bulge at least partially overlaps with a projection area of the handle. The first shock absorption protrusion can improve the shock absorption effect at the handle.

The utility model provides a cup seatpad and cooking machine of cooking, wherein, first surface and/or second surface are equipped with first shock attenuation arch, and first shock attenuation arch sets up the one side of keeping away from the motor shaft hole in the coupler hole, and first shock attenuation arch can be alleviated and absorb vibrations, can reduce the vibrations that host computer and stirring cup produced in first shock attenuation arch department from this to reach absorbing effect, promote user experience.

Drawings

Fig. 1 is a schematic perspective view of an embodiment of a food processor;

fig. 2 is a longitudinal sectional view of the food processor shown in fig. 1;

fig. 3 is an exploded view of the food processor shown in fig. 1;

fig. 4 is an exploded longitudinal sectional view of the food processor shown in fig. 3;

FIG. 5 shows a bottom view of the housing shown in FIG. 3;

FIG. 6 is a schematic structural view of the motor connecting post of FIG. 3;

FIG. 7 is a partial cross-sectional view of the housing, motor and motor connection post assembly shown in FIG. 3;

FIG. 8 is a schematic view of the cup holder shown in FIG. 3 without the bottom cover;

FIG. 9 is a schematic view of the bottom cap of the cup holder shown in FIG. 3;

FIG. 10 is a longitudinal cross-sectional view of the cup holder shown in FIG. 3;

FIG. 11 is a cross-sectional view of the cup holder shown in FIG. 3;

FIG. 12 is a schematic view of the host housing shown in FIG. 3;

FIG. 13 is a front view of the host housing shown in FIG. 5;

FIG. 14 is a side view of the host housing shown in FIG. 4;

FIG. 15 is a schematic view of the bottom of the blender cup shown in FIG. 3;

FIG. 16 is a schematic view of a first surface of the cup seat cushion shown in FIG. 3;

FIG. 17 is a schematic view of a second surface of the cup seat cushion shown in FIG. 16;

FIG. 18 is a front elevational view of the cup seat cushion of FIG. 16;

FIG. 19 is a side view of the cup seat cushion shown in FIG. 16;

fig. 20 is a partial cross-sectional view of the cup rest pad of fig. 3 positioned in engagement between a blender cup and a host.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present application. Rather, they are merely examples of apparatus consistent with certain aspects of the present application, as detailed in the appended claims.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. Unless otherwise defined, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this application belongs. The terms "first," "second," and the like, as used in the description and in the claims, do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. Also, the use of the terms "a" or "an" and the like do not denote a limitation of quantity, but rather denote the presence of at least one. "plurality" or "a number" means two or more. The word "comprising" or "comprises", and the like, means that the element or item listed after "comprises" or "comprising" is inclusive of the element or item listed after "comprising" or "comprises", and the equivalent thereof, and does not exclude additional elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. As used in this specification and the appended claims, the singular forms "a", "an", and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items.

Referring to fig. 1 to 4, fig. 1 is a schematic diagram of an embodiment of a food processor 10. Fig. 2 is a longitudinal sectional view of the food processor 10 shown in fig. 1. Fig. 3 is an exploded view of the food processor 10 shown in fig. 1. Fig. 4 is an exploded longitudinal sectional view of the food processor 10 shown in fig. 3.

The food processor 10 comprises a main machine 11 and a stirring cup 12. The mixing cup 12 is detachably assembled to the main body 11. In the illustrated embodiment, the main body 11 is in the form of a stand, and the main body 11 is assembled below the mixing cup 12.

The host 11 comprises a host shell 22 and a motor 23 accommodated in the host shell 22, wherein the motor 23 comprises a motor shaft 21, and the motor shaft 21 extends out of the host shell 22. The main body housing 22 may include a lower connection hole 31 provided at a top wall thereof, and the motor shaft 21 may extend out of the main body 11 from the lower connection hole 31, with an axial direction of the motor shaft 21 being the same as an axial direction of the lower connection hole 31. The host 11 can provide electric energy to realize the operation of the food processor 10.

Referring to fig. 5-7, fig. 5 is a bottom view of the host housing 22 shown in fig. 3. Fig. 6 is a schematic structural view of the motor connecting pole 30 in fig. 3. Fig. 7 is a partial cross-sectional view of the mating of the main body housing 22, motor 23 and motor connection post 30 shown in fig. 3.

One of the motor 23 and the main body case 22 is provided with a connecting column 30, the other is provided with a connecting groove 40, the connecting column 30 is inserted and fixed in the connecting groove 40, and the connecting groove 40 and the connecting column 30 are arranged in a polygonal structure with a matched shape. Therefore, the motor 23 and the main body shell 22 are limited through the connecting column 30 and the connecting groove 40 which are of the polygonal structures, and the motor 23 and the main body shell 22 are prevented from rotating relatively. The polygonal structure may be rectangular, triangular, elliptical, irregular, etc. In the embodiment shown in fig. 5, the head 51 of the connecting post 30 and the connecting groove 40 are both square, wherein the length, width and height of the connecting groove 40 can be set to 6.4mm x 2.2mm, and the length, width and height of the head 51 of the connecting post 30 can be set to 6mm x 2mm, but not limited thereto.

In some embodiments, the connection pole 30 can be disposed on the motor 23 and fixedly connected to the motor 23, the connection slot 40 is disposed on the main housing 22, and the connection pole 30 is inserted into the connection slot 40. For example, a plurality of connecting posts 30 may be provided, and a plurality of connecting slots 40 may be provided in correspondence with the host housing 22, with one-to-one correspondence therebetween. The connecting post 30 may be fixed in the connecting groove 40 by means of bolts, screws, adhesives, etc. In another embodiment, the connection post 30 may be provided on the main housing 22 and the connection slot 40 may be provided on the motor 23.

The mixing cup 12 may be assembled to the main body 11. In some embodiments, blender cup 12 is removably assembled to host 11. As shown in FIG. 1, blender cup 12 includes a cup body 24, a lid 25, and a base 26. The cup body 24 is provided with a cup cavity for containing food materials, and the food materials can be crushed, heated and the like in the cup cavity. The cup cover 25 covers the opening of the cup body 24. A cup holder 26 is assembled to the bottom of the cup body 24. In some embodiments, lid 25 is removably assembled to cup 24.

Referring to fig. 8 to 10, fig. 8 is a schematic structural view illustrating that the cup holder 26 shown in fig. 3 does not include the bottom cover 261. Fig. 9 is a schematic structural view of the bottom cover 261 of the cup holder 26 in fig. 3. Figure 10 shows a longitudinal cross-sectional view of the cup holder 26 shown in figure 3.

In one embodiment, the cup holder 26 includes a bottom cover 261 and a cup holder body 262, the bottom cover 261 being assembled to the bottom of the cup holder body 262. One of the cup holder body 262 and the bottom cover 261 is provided with a clamping portion 273, the other is provided with a clamping matching portion 264, and the clamping matching portion 264 is connected with the clamping portion 273 in a clamping manner. So, when bottom 261 assembles in cup base body 262, bottom 261 emergence upwarping can be avoided in the cooperation of joint portion 273 and the 264 block of joint cooperation portion, is favorable to guaranteeing the balance of stirring cup 12. In the illustrated embodiment, a clamping portion 273 is disposed at the edge of the bottom cover 261, a clamping and matching portion 264 is disposed at the edge of the cup holder body 262, the clamping portion 273 may be a claw, and the clamping and matching portion 264 may be a groove, but is not limited thereto. In some embodiments, a plurality of clamping portions 273 may be disposed on the edge of the bottom cover 261, a plurality of clamping matching portions 264 may be disposed on the edge of the cup holder body 262, and the plurality of clamping portions 273 and the plurality of clamping matching portions 264 may be clamped in a one-to-one correspondence.

As shown in FIG. 2, blender cup 12 includes a knife assembly 13, knife assembly 13 being rotatably assembled to the bottom of cup body 24. The knife assembly 13 includes a knife shaft 131 and blades 27, the blades 27 are fixedly assembled on the knife shaft 131, and the number of the blades 27 is not limited. The shaft 131 is coupled to the motor shaft 21, and the shaft 131 has the same axial direction as the motor shaft 21 and the same height direction as the cup 24. The motor shaft 21 can rotate the knife shaft 131 and the knife blade 27 to whip and break the food material in the cup cavity.

The mixing cup 12 may include an upper coupling hole 32 provided at a bottom thereof, the upper coupling hole 32 may be particularly provided at the bottom cover 261, the upper coupling hole 32 is coaxial with the lower coupling hole 31, and the cutter shaft 131 is provided to be engaged with the motor shaft 21 of the main body 11 within the upper coupling hole 32.

Referring to fig. 9 and 11, fig. 11 is a sectional view of the cup holder 26 shown in fig. 3.

The bottom cover 261 is located at the bottom of the stirring cup 12, the bottom cover 261 comprises a base 2621 and a surrounding barrier 263, the base 2621 is formed with an upper connecting hole 32, and the upper connecting hole 32 is arranged to penetrate through the base 2621. In order to increase the space of the upper connection hole 32, the base 2621 further includes a first boss 274 extending around the upper connection hole 32 and protruding in the direction of the knife shaft 131, wherein the first boss 274 is hollow, and the hollow portion is the upper connection hole 32.

The knife shaft 131 is disposed to engage with the motor shaft 21 of the main body 11 in the upper coupling hole 32, the surrounding shield 263 is coupled to the base 2621 and is coupled to a side surface of the base 2621 where the first protrusion 274 is disposed, and the surrounding shield 263 is disposed around the upper coupling hole 32, which can also be understood as being disposed around the first protrusion 274. The distances between the surrounding barriers 263 and the centers of the upper connecting holes 32 at least two positions along the circumferential direction of the cutter shaft are different, that is, the surrounding barriers 263 are located on circles with different radiuses at least two positions by taking the connecting holes 32 as the center of a circle, so that the surrounding barriers 263 form an asymmetric structure or an irregular structure.

When motor shaft 21 and arbor 131 are synchronous and high-speed when rotating, can form the powerful vortex of wind direction in the rotation process, and the position department that the vortex struck can form the noise, on the one hand, through enclosing establishing of enclosing 263 to last connecting hole 32, can play the effect of keeping apart partial noise. On the other hand, enclose that keep off 263 at two at least positions of week department and the distance of the center of last connecting hole 32 and vary, realized enclosing the asymmetric design of keeping off 263, so can effectually block the inertial flow direction of noise vortex, and then can effective separation noise wind direction to improve cooking machine 10's noise reduction.

As shown in fig. 9, the base 2621 is provided with a mounting hole 265 for mounting the coupler 50 (refer to fig. 2), and the mounting hole 265 is surrounded by the surrounding wall 263. In one embodiment, the skirt 263 is broken at the mounting hole 265, separating a portion of the skirt facing the mounting hole 265 from the remaining portion of the skirt. The part of the enclosure facing the mounting hole 265 is a first enclosure 2631, and the rest of the enclosure is a second enclosure 2632. First enclose fender 2631 and second and enclose fender 2632 mutual separation, first enclose fender 2631 and second and enclose and reserve the clearance between fender 2632, make hot-blast can be discharged from the clearance, realize the heat dissipation.

In one embodiment, the enclosure 263 is provided with heat dissipating ports 266, the heat dissipating ports 266 communicate between the space inside the enclosure 263 and the space outside the enclosure 263, and the gap between the first enclosure 2631 and the second enclosure 2632 may serve as the heat dissipating ports 266. In this manner, heat dissipation of the coupler 50 may also be facilitated. In the illustrated embodiment, there are two heat sinks 266, one on each side of the first enclosure 2631.

The heat dissipating port 266 penetrates the enclosure 263 along the axial direction of the arbor 131, and at least one side of the heat dissipating port 266, the top of the surface of the enclosure 263 facing the heat dissipating port 266 is inclined toward the side away from the heat dissipating port 266, so as to form a tapered heat dissipating port with a small bottom and a large top, wherein the inclination angle is not limited. For example, the range of the inclination angle may be set to 5 degrees to 30 degrees. The top of the heat dissipation opening 266 is large, which can increase the flow of hot air, and can sufficiently and effectively dissipate heat of the motor 23, the coupler 50, and the like, and the bottom of the heat dissipation opening 266 is small, which can maintain the noise reduction effect of the enclosure 263. So, can improve the radiating effect, guarantee to enclose the noise reduction effect who keeps off 263 again.

The width of the heat dissipating port 266 ranges from 6mm to 12mm in the circumferential direction of the shroud 263. For example, the width of the heat vents 266 may be 6mm, 7mm, 8mm, 9mm, 10mm, 11mm, 12mm. Thus, the heat dissipation effect is ensured, and the noise reduction effect of the enclosure 263 is prevented from being reduced due to the overlarge width of the heat dissipation opening 266.

In some embodiments, as shown in FIG. 9, the surround 263 includes a plurality of baffles 267 arranged around the upper coupling aperture 32, with at least a portion of the baffles 267 connected end-to-end. Thus, the plurality of end-to-end baffles 267 can improve the sealing performance of the enclosure 263, which is beneficial to improving the noise reduction effect. In the illustrated embodiment, the plurality of baffles 267 forming the second enclosure 2632 are positioned end-to-end, and the baffles 267 forming the first enclosure 2631 are positioned separately from the remaining baffles 267.

In some embodiments, the plurality of baffles 267 includes a first baffle 268 and a second baffle 269, the first baffle 268 and the second baffle 269 are unequal in length in the alignment direction, and the first baffle 268 and the second baffle 269 alternate. Therefore, in the circumferential direction, the distance between the surrounding shield 263 and the center of the upper connecting hole 32 is unequal, so that the asymmetric design of the surrounding shield 263 can be realized, and the effect of blocking the vortex wind direction is achieved.

The specific structure of the first baffle 268 and the second baffle 269 is not limited. In some embodiments, the first baffle 268 and the second baffle 269 are both circular arc shaped baffles, and one of the first baffle 268 and the second baffle 269 protrudes in a direction closer to the upper coupling hole 32, and the other protrudes in a direction away from the upper coupling hole 32. The circle center of the first baffle 268 is located inside the space enclosed by the enclosing wall 263, and the circle center of the second baffle 269 is located outside the space enclosed by the enclosing wall 263. Therefore, the vortex disturbing function can be further realized, the vortex can be better dispersed, and the noise is reduced. In the illustrated embodiment, the first baffle 268 projects away from the upper attachment hole 32, and the second baffle 269 projects toward the upper attachment hole 32. It should be noted that in other embodiments, the first baffle 268 and the second baffle 269 may also be flat plates.

In one embodiment, the arc length of the first baffle 268 is less than the arc length of the second baffle 269 and the ratio of the arc length of the first baffle 268 to the arc length of the second baffle 269 ranges from 0.3 to 0.8. Therefore, the difference in the shapes of the first baffle 268 and the second baffle 269 is increased, and the first baffle 268 and the second baffle 269 which are different in length and alternately arranged can make the capability of the enclosure 263 for resisting the inertia of the noise vortex higher, and the noise reduction effect of the enclosure 263 is better.

Referring to fig. 12 to 15, fig. 12 is a schematic diagram of the host housing 22 shown in fig. 3. Fig. 13 is a front view of the host housing 22 shown in fig. 5. Fig. 14 is a side view of the host housing 22 shown in fig. 4. Fig. 15 is a schematic view of the bottom of the blender cup 12 shown in fig. 3.

In one embodiment, one of the main body 11 and the stirring cup 12 is provided with a shock-absorbing boss 28 protruding in the axial direction of the motor shaft 21, and the other is provided with a shock-absorbing recess 29 recessed in the axial direction of the motor shaft 21, the shock-absorbing boss 28 being inserted into the shock-absorbing recess 29. In the illustrated embodiment, a shock absorbing boss 28 is provided on the main body 11, specifically on the top of the main body housing 22, and a shock absorbing recess 29 is provided on the bottom of the mixing cup 12. In other embodiments, the shock absorbing boss 28 may be disposed on the mixing cup 12, and the shock absorbing groove 29 may be disposed on the main body 11.

The shock absorbing boss 28 protrudes from the top of the main body housing 22 toward the mixing cup 12, and the shock absorbing boss 28 is disposed around the lower connecting hole 31 and the motor shaft 21 without being connected end to end. Wherein, motor shaft 21 can drive knife tackle spare 13 to rotate along first direction, and correspondingly, the outstanding height of shock attenuation boss 28 can increase along first direction gradually. In the illustrated embodiment, the shock absorbing boss 28 includes a head end 281 and a tail end 282, the head end 281 is not connected to the tail end 282, and the height of the shock absorbing boss 28 may gradually increase from the head end 281 to the tail end 282, wherein a direction extending from the head end 281 to the tail end 282 is a first direction, which is the same as the rotation direction of the knife assembly 13. In the present embodiment, the first direction is the clockwise direction of the illustrated embodiment. In other embodiments, the first direction may also be counterclockwise in the illustrated embodiment.

The bottom of the mixing cup 12 is provided with a damping groove 29. In one embodiment, the shock absorbing groove 29 may be formed at the bottom surface of the bottom cover 261. Wherein, the damping groove 29 is recessed along the axial direction of the motor shaft 21, and the recessed depth is gradually increased along the first direction, so that the damping boss 28 can be inserted into the damping groove 29.

The food processer 10 provided by the embodiment of the application can generate spiral vortex when the knife assembly 13 rotates at a high speed along the first direction in the cup cavity filled with fluid and other substances, and the matching scheme of the shock absorption boss 28 gradually increasing in height along the first direction and the shock absorption groove 29 gradually increasing in depth along the first direction is adopted, an oblique upward supporting force can be provided for the shock absorption boss 28 through the bottom surface of the shock absorption groove 29, the horizontal component of the supporting force can provide a resistance moment for the rotation of the knife assembly 13, the direction of the resistance moment is opposite to the first direction, so that the impact force of the stirring cup 12 along the first direction under the effect of the spiral vortex can be relieved, and the vibration of the food processer 10 in the working process is further reduced.

In some embodiments, the height difference between the head end 281 and the tail end 282 of the shock absorbing boss 28 in the direction around the motor shaft 21 ranges from 3mm to 8mm. For example, the height difference between the head and the tail can be 3mm, 4mm, 5mm, 6mm, 7mm, 8mm, but is not limited thereto. The smaller the height difference is, the smaller the gradient of the top surface of the shock absorption boss 28 is, the smaller the horizontal component force is, the smaller the resisting moment is, the larger the height difference is, the larger the gradient of the top surface of the shock absorption boss 28 is, and the larger the horizontal component force is, the larger the resisting moment is, therefore, the height difference of the head end and the tail end of the shock absorption boss 28 can be selected within the range of 3 mm-8 mm, and the rotating moment of the cutter assembly 13 can be effectively balanced.

In one embodiment, as shown in fig. 12, the damper boss 28 includes a plurality of sub-bosses 288 arranged around the motor shaft 21 and the lower coupling hole 31, a space 283 is left between adjacent two sub-bosses 288, and the height of each sub-boss 288 projected may gradually increase in the first direction. With this arrangement, the space 283 does not require a material, so that the material and cost can be saved, and the weight of the main body 11 can be reduced. Moreover, horizontal component force and resisting moment can be generated at each sub-boss 288, which is beneficial to reducing vibration and realizing noise reduction.

In one embodiment, the plurality of sub-bosses 288 are located on the same circumference with the axis of the motor shaft 21 and extend around the axis of the motor shaft 21. Accordingly, the position and shape of the shock absorbing groove 29 are matched with those of the plurality of sub-bosses 288. Thus, the sub-bosses 288 are inserted into the damping grooves 29 and rotated to adjust the relative positions of the mixing cup 12 and the main body 11.

In one embodiment, shock absorbing bosses 28 are provided with slot portions 284, and slot portions 284 may reduce material usage and cost. In the illustrated embodiment, the shock absorbing boss 28 includes an inner portion 285, an outer portion 286, and a connecting rib 287, the outer portion 286 surrounding the outer side of the inner portion 285, the connecting rib 287 connecting the outer portion 286 to the inner portion 285, and a gap between the outer portion 286 and the inner portion 285 forming the slot 284. Thus, the shock absorption boss 28 forms a double-layer structure, which not only reduces the cost, but also can ensure the strength of the shock absorption boss 28. In the illustrated embodiment, each sub-boss 288 includes an inner portion 285, an outer portion 286, and a connecting rib 287, the inner portion 285 and the outer portion 286 being connected by the connecting rib 287. The connecting rib 287 may be a rib, and the length, width and height of the connecting rib 287 may be set to be 3mm, 4mm, 12mm, but are not limited thereto. It should be noted that, the groove 284 may be filled with plastic material to enhance the deformation resistance of the shock absorbing boss 28.

In one embodiment, the size of the groove 284 in the radial direction of the motor shaft 21 ranges from 2mm to 5mm. For example, the radial dimension of the slot 284 may be, but is not limited to, 2mm, 3mm, 4mm, 5mm. With this arrangement, sufficient strength of the inner portion 285 and the outer portion 286 can be ensured, and material can be saved.

In one embodiment, the groove portion 284 penetrates in the protruding direction of the damper boss 28, and the dimension of the groove portion 284 in the axial direction of the motor shaft 21 ranges from 8mm to 12mm. For example, the axial dimensions of the slot 284 may be 8mm, 9mm, 10mm, 11mm, 12mm. Thus, the groove 284 can be ensured to penetrate through different parts of the shock absorption boss 28, and the groove 284 can be conveniently machined.

In some embodiments, the damping recess 29 is provided on a circumference having a diameter ranging from 110mm to 118mm with the center of the shaft center of the motor shaft 21 as a center. For example, the center line of the shock absorbing groove 29 may be disposed on a circumference having a diameter of 110mm, 112mm, 114mm, 116mm, 118mm, but is not limited thereto. Accordingly, the circumference of the shock absorbing boss 28 corresponds to the circumference of the shock absorbing groove 29, so as to ensure the smooth matching between the shock absorbing boss 28 and the shock absorbing groove 29. The larger the diameter of the circumference in which the damper groove 29 is located, the closer the damper groove 29 is to the rim of the mixing cup 12, and accordingly, the more stable the engagement with the damper boss 28.

In some embodiments, the width dimension of the damping recess 29 in the radial direction of the motor shaft 21 ranges from 10mm to 18mm, and the damping boss 28 is clearance-fitted to the damping recess 29. For example, the radial width dimension of the shock absorbing groove 29 may be 10mm, 12mm, 14mm, 16mm, 18mm. The radial width dimension of the damping groove 29 is small, the radial width dimension of the damping boss 28 is correspondingly small, the radial width dimension of the damping groove is selected within the range of 10 mm-18 mm, the radial width dimension of the damping boss 28 can be prevented from being too small, and the strength and the pressure resistance of the damping boss 28 can be improved.

In some embodiments, the damping grooves 29 do not meet end to end, and the depth dimension of the damping grooves 29 at the smallest depth is not less than 1mm and the depth dimension at the largest depth is not less than 4mm in the direction around the motor shaft 21. Therefore, the situation that the shock absorption groove 29 is too small in depth and separated from the shock absorption boss 28 can be avoided, and the reliability of inserting the shock absorption boss 28 into the shock absorption groove 29 is improved.

In some embodiments, the main machine 11 further comprises a cup seat 14 made of a flexible material, the cup seat 14 being assembled between the blending cup 12 and the main machine 11. So that the vibration of the food processor 10 can be absorbed and buffered to reduce the vibration of the food processor 10 and reduce noise. The flexible material may include, but is not limited to, polyvinyl alcohol, polyester, polyimide, polyethylene naphthalate, and the like.

Referring to fig. 16 to 20, fig. 16 is a schematic view of a first surface of the cup seat 14 shown in fig. 3. Fig. 17 is a schematic view of a second surface of the cup holder 14 shown in fig. 16. Fig. 18 is a front view of the cup holder 14 shown in fig. 16. Fig. 19 shows a side view of the cup holder 14 shown in fig. 16. Fig. 20 is a partial cross-sectional view of the cup seat 14 shown in fig. 3 disposed between the blending cup 12 and the main body 11.

The cup seat 14 is disposed between the main body 11 of the food processor 10 and the stirring cup 12, and is made of a deformable elastic material, which includes but is not limited to silica gel, polyethylene, and the like. In one embodiment, the coaster 14 is assembled on top of the host computer 11 and conforms to the shape of the top of the host computer 11.

As shown in fig. 16 and 17, the coaster 14 includes a first surface 141 and a second surface 142 in a thickness direction, the first surface 141 being for contact with the mixing cup 12, and the second surface 142 being for contact with the main body 11. In the embodiment shown in fig. 16, the first surface 141 of the cup seat 14 is formed with a convex portion 275, the second surface 142 of the cup seat 14 is formed with a concave portion 143 corresponding to the convex portion 275, the convex portion 275 is hollow, the shock absorbing boss 28 is embedded in the concave portion 143 and covered by the convex portion 275, and the cup seat 14 is clamped between the main body 11 and the mixing cup 12, thereby improving the shock absorbing effect.

In one embodiment, the first surface 141 is formed with a first shock absorbing protrusion 145, and the cup seat cushion 14 further includes a motor shaft hole 147 at a central region and a coupler hole 60 at an edge region, wherein the motor shaft hole 147 and the coupler hole 60 penetrate in a thickness direction of the cup seat cushion 14, the motor shaft hole 147 passes the motor shaft 21, and the coupler hole 60 passes the coupler 50. The first shock-absorbing projection 145 is provided at a side of the coupler hole 60 away from the motor-shaft hole 147.

In a practical application scenario, after the cup mat 14 is installed on the host 11, the first shock absorption protrusions 145 on the cup mat 14 can relieve and absorb shock, so that shock generated by the host 11 and the stirring cup 12 at the first shock absorption protrusions 145 can be reduced. For example, the first shock absorbing protrusion 145 may be aligned with the handle 122 of the cup body 24 in the height direction of the cup body 24, thereby providing a better shock absorbing effect at the handle 122. It should be noted that the second surface 142 may also be provided with a first shock absorbing protrusion 145.

The first shock absorbing protrusion 145 may include a plurality of first sub-protrusions 146, the plurality of first sub-protrusions 146 are distributed around the center of the motor shaft hole 147 in a plurality of rows, and along the circumferential direction of the motor shaft hole 147, the plurality of first sub-protrusions 146 are distributed in a concentrated manner in a region facing the coupler hole 60 in the radial direction of the motor shaft hole 147. The plurality of first sub-protrusions 16 separated from each other are more flexible, more deformable, and more shock-absorbing than the protrusions of the unitary structure, and can better absorb and absorb shock and impact at the periphery of the coupler hole 60. In the embodiment shown in fig. 16, the plurality of first sub-protrusions 146 are arranged in three rows around the center of the motor shaft hole 147, and each row is provided with three first sub-protrusions 146, but is not limited thereto.

In one embodiment, the first shock absorbing protrusion 145 further includes an arc-shaped strip-shaped protrusion 1491 disposed on the first surface 141, and the plurality of first sub-protrusions 146 protrude from the arc-shaped strip-shaped protrusion 1491. The arc-shaped strip-shaped protrusions 1491 can increase the thickness of the cup pad 14 at the first shock absorbing protrusion 145, thereby increasing the strength of the area and reducing the risk of crushing and breaking the area while maintaining the elastic deformation.

The shape and size of the first sub-protrusion 146 are not limited. In one embodiment, the plurality of first sub-protrusions 146 are cylindrical protrusions having a diameter ranging from 3mm to 7mm. For example, the diameter of the cylindrical protrusion may be 3mm, 4mm, 5mm, 6mm, 7mm. The range of the height of the first sub-protrusions 146 protruding out of the surface of the arc-shaped strip-shaped boss 1491 is 1 mm-3 mm. For example, the protrusion heights of the plurality of first sub-protrusions 146 are equal and may be 1mm, 2mm, or 3mm. The larger the diameter of the first sub-protrusion 146 is, the less the elastic deformation amount is, the less the ability to alleviate the impact and the shock, while the smaller the diameter of the cylindrical protrusion is, the greater the elastic deformation amount is, the better the ability to alleviate the impact and the shock, but the lower the strength is, the easier it is to break. Similarly, the higher the height of the first sub-protrusion 146, the greater the elastic deformation, and if the height of the first sub-protrusion 146 is too high, the strength is low, and the probability of breakage or fracture is high. Therefore, it may be selected within the above size range, for example, when the height of the first sub-protrusion 146 is 1mm, the diameter may be set to 3mm, 4mm, or 5mm. When the height of the first sub-protrusion 146 is 3mm, the diameter may be set to 5mm, 6mm, or 7mm. Thus, it is possible to secure both the elastic deformation amount of the first sub-protrusion 146 and the strength of the first sub-protrusion 146.

In one embodiment, the size of the arc-shaped strip-shaped protruding portion 1491 in the circumferential direction of the motor shaft hole 147 ranges from 50mm to 80mm, and the size of the arc-shaped strip-shaped protruding portion 1491 in the radial direction of the motor shaft hole 147 ranges from 20mm to 30mm. For example, the arc-shaped strip-shaped protrusion 1491 may have an outer arc length of 50mm and a radial dimension of 30mm, or an outer arc length of 80mm and a radial dimension of 20mm, but is not limited thereto. The circumferential dimension and the radial dimension of the arc-shaped strip-shaped boss 1491 are set in the range, so that the peripheral space of the coupler hole can be effectively utilized, the shock absorption can be realized, and the interference can be avoided.

In one embodiment, the length of the arc-shaped strip-shaped protruding portion 1491 in the circumferential direction of the motor shaft hole 147 exceeds the length of the coupler hole 60 in this direction by more than 2mm. This increases the circumferential length of the arcuate strip 1491, which dampens and absorbs shock over a greater area around the coupler bore 60.

It should be noted that the second surface 142 may be provided with an arc-shaped strip-shaped boss, and the first shock absorption protrusion is disposed on the arc-shaped strip-shaped boss and protrudes toward a side away from the first surface 141.

In some embodiments, the cup pad 14 further includes a second shock absorbing protrusion 148 formed on the first surface 141, and the second shock absorbing protrusion 148 is disposed at an edge of the motor shaft hole 147 around a center of the motor shaft hole 147. The vibrations that produce when second shock attenuation arch 148 can alleviate and absorb arbor 131 and the transmission of motor shaft 21 further improve cooking machine 10's shock-absorbing capacity, promote user experience.

In one embodiment, the second shock absorbing protrusion 148 includes a plurality of second sub-protrusions 1480, and the plurality of second sub-protrusions 1480 are separated from each other at the top and connected at the bottom. The plurality of second sub-protrusions 1480 are mainly used for relieving and absorbing shock through the tops, the deformation amount of the plurality of second sub-protrusions 1480 can be increased by separating the plurality of second sub-protrusions 1480 at the tops, the strength and the rigidity can be increased by connecting the plurality of second sub-protrusions 1480 at the bottoms, and fatigue failure of the plurality of second sub-protrusions 1480 under the action of pressure is avoided.

In one embodiment, a gap 310 is left between the tops of two adjacent second sub-protrusions 1480, and the length of the gap 310 in the circumferential direction of the motor shaft hole 147 ranges from 2mm to 3mm, for example, the circumferential length may be 2mm or 3mm, but is not limited thereto. The width of the gap 310 in the radial direction of the motor shaft hole 147 ranges from 4mm to 6mm, and for example, the radial width is 4mm, 5mm, or 6mm, but is not limited thereto. The height of the gap 310 in the axial direction of the motor shaft hole 147 is in a range of 5mm to 8mm, for example, 5mm, 6mm, 7mm, and 8mm, but is not limited thereto. Therefore, a sufficient deformation space can be provided for the plurality of second sub-protrusions 1480, the size of the gap 310 is selected within the range, on one hand, the small deformation caused by the undersize of the gap 310 can be avoided, on the other hand, the overlarge size and strength reduction of the gap 310 can be avoided, and therefore the shock can be better relieved and absorbed, and the shock absorption effect is improved.

As shown in FIG. 3, blender cup 12 includes a handle 122, handle 122 facilitating access to blender cup 12 by a user. In the orthographic projection of the height direction of the mixing cup 12, the projection area of the first shock absorption bulge 145 at least partially overlaps with the projection area of the handle 122. In this way, the shock absorbing effect at the handle 122 can be improved.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the scope of protection of the present application.

Claims (10)

1. The utility model provides a cup seatpad of cooking machine, its characterized in that, cup seatpad (14) are used for installing between host computer (11) and the stirring cup (12) of cooking machine, are made by deformable elastic material, cup seatpad (14) include:

a first surface (141) used for contacting with the stirring cup (12) and a second surface (142) used for contacting with the main machine (11), wherein the first surface (141) and/or the second surface (142) form a first shock absorption bulge (145), the cup seat cushion (14) further comprises a motor shaft hole (147) positioned in a central area and a coupler hole (60) positioned in an edge area, the motor shaft hole (147) and the coupler hole (60) penetrate along the thickness direction of the cup seat cushion (14), and the first shock absorption bulge (145) is arranged on one side, far away from the motor shaft hole (147), of the coupler hole (60).

2. The cup holder cushion according to claim 1, wherein the first shock absorbing protrusion (145) comprises a plurality of first sub-protrusions (146), the plurality of first sub-protrusions (146) are distributed in a plurality of rows around the center of the motor shaft hole (147), and the plurality of first sub-protrusions (146) are concentrated in a region facing the coupler hole (60) in the radial direction of the motor shaft hole (147) in the circumferential direction of the motor shaft hole (147).

3. The cup holder cushion according to claim 2, wherein the first shock absorbing protrusion (145) further comprises an arc-shaped strip-shaped protrusion (1491) provided on the first surface (141) and/or the second surface (142), and the plurality of first sub-protrusions (146) protrude from the arc-shaped strip-shaped protrusion (1491).

4. The cup cushion according to claim 3, wherein the arc-shaped strip-shaped protrusion (1491) has a size in a circumferential direction of the motor shaft hole (147) in a range of 50mm to 80mm, and the arc-shaped strip-shaped protrusion (1491) has a size in a radial direction of the motor shaft hole (147) in a range of 20mm to 30mm; and/or

The length of the arc-shaped strip-shaped boss (1491) in the circumferential direction of the motor shaft hole (147) at least exceeds the length of the coupler hole (60) in the direction by more than 2mm.

5. The cup pad according to claim 3, wherein the plurality of first sub-protrusions (146) are cylindrical protrusions having a diameter ranging from 3mm to 7mm, and a height of the cylindrical protrusions protruding from the surface of the arc-shaped bar-shaped protrusion (1491) ranging from 1mm to 3mm.

6. The cup holder cushion according to any one of claims 1 to 5, wherein the cup holder cushion (14) further comprises a second shock-absorbing protrusion (148) formed at the first surface (141), the second shock-absorbing protrusion (148) being provided at an edge of the motor shaft hole (147) around a center of the motor shaft hole (147).

7. The cup holder cushion according to claim 6, wherein the second shock absorbing protrusions (148) comprise a plurality of second sub-protrusions (1480), the plurality of second sub-protrusions (1480) being separated from each other at the top and connected at the bottom.

8. The cup holder pad according to claim 7, wherein a gap (310) is left between tops of adjacent two of the second sub-protrusions (1480), a length of the gap (310) in a circumferential direction of the motor shaft hole (147) ranges from 2mm to 3mm, a width of the gap (310) in a radial direction of the motor shaft hole (147) ranges from 4mm to 6mm, and a height of the gap (310) in an axial direction of the motor shaft hole (147) ranges from 5mm to 8mm.

9. A food processor, comprising:

a main body (11) including a motor shaft (21);

a blender cup (12) comprising a knife assembly (13); and

the cup holder pad (14) according to any of claims 1 to 8, the cup holder pad (14) being mounted between the main machine (11) and the mixing cup (12).

10. The food processor of claim 9, wherein the mixing cup (12) comprises a handle (122), and a projection area of the first shock absorbing protrusion (145) at least partially overlaps a projection area of the handle (122) in an orthographic projection of the mixing cup (12) in a height direction.

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