CN215777573U - Food processor - Google Patents

Abstract

The utility model discloses a food processor, which comprises a cup body for adding food to be processed, a cutter holder for crushing the food to be processed and a machine body mechanism, wherein the cup body is arranged on the cutter holder, the cutter holder is arranged on the machine body mechanism, the machine body mechanism comprises a shell, the shell is in a sphere-like shape, the sphere-like shape is a partial sphere shape left after a sphere is cut by two parallel planes, and an annular inner cavity is formed on the inner side of the shell. According to the utility model, the shell of the machine body mechanism is set to be in the shape of a sphere, the sphere is the remaining part of the sphere after the sphere is cut off by two parallel planes, and thus the inner side of the shell is provided with the annular inner cavity, so that vibration noise or friction noise generated by the whole food processor can form circulation in the annular inner cavity of the shell, the noise circularly flows along the annular inner cavity and is not transmitted to the outside of the shell, but is gradually attenuated in the shell, the transmission of the noise can be effectively reduced, and the noise reduction effect is good.

Description

Food processor

Technical Field

The utility model relates to the technical field of small household appliances, in particular to a food processor.

Background

With the improvement of living standard, various household appliances such as a refrigerator, a washing machine, an air conditioner and the like are configured in the household of the residents, and the household appliances provide convenience for the daily life of the residents. Especially small household appliances such as a food processor can be used for making various foods such as fruit juice, soybean milk, jam, dry powder, shaved ice, minced meat and the like.

At present, the processing mode of the food processor is mostly driven by a motor, and the blade is driven by the motor to rotate at a high speed so as to realize effective stirring and crushing effects. In actual production process, in order to guarantee better stirring and crushing effect, the high rotational speed operation of motor is used widely, and correspondingly, certain drawback also can be brought simultaneously to high rotational speed, the high rotational speed makes the vibration aggravation of motor during operation on the one hand, the instability of motor or blade work probably causes, on the other hand, when the blade contacts with materials such as beans, high-speed rotation leads to the frictional force increase, and the material can be more frequent striking processing machine's cup inner wall, the noise of processing machine during operation can inevitably be caused too big in these two aspects. The use experience of users can be seriously influenced by overlarge noise, potential safety hazards also exist, and the service life of each part of the processing machine is shortened to a certain extent.

However, the noise reduction of the food processor is mainly focused on two parts of the motor and the cup body, the noise reduction of the motor is generally realized by adding a motor cover outside the motor and adding a noise reduction material, and the noise reduction of the cup body is mainly focused on changing the manufacturing material of the cup body, and the outer wall of the cup body is generally made of a special sound insulation material, so that the noise is mostly enclosed in the processor. However, these noise reduction methods are costly, have poor noise reduction effects, and are difficult to achieve large noise reduction at low cost.

SUMMERY OF THE UTILITY MODEL

The utility model provides a food processor, and aims to solve the problems of high working noise, high noise reduction cost and poor noise reduction effect of the food processor in the prior art.

In a first aspect, the utility model provides a food processor, which comprises a cup body for adding food to be processed, a cutter holder for crushing the food to be processed and a machine body mechanism, wherein the cup body is arranged on the cutter holder, the cutter holder is arranged on the machine body mechanism, the machine body mechanism comprises a shell, the shell is in a sphere-like shape, the sphere-like shape is a partial sphere shape remained after a sphere is cut by two parallel planes, and an annular inner cavity is formed in the inner side of the shell.

Furthermore, the cup body is in a cylindrical shape with one axial end open and the other axial end closed, at least one turbulence rib is arranged on the inner side wall surface of the cup body, and the turbulence ribs extend along the axial direction of the cup body and are distributed along the circumferential direction of the cup body; the depth of the spoiler ribs in the radial direction of the cup body is D1, the radius of the cup body is D2, and D2 is 6-9 times of D1.

Furthermore, the turbulence ribs are hollow ribs formed by the side wall of the cup body which is inwards sunken along the radial direction; or the turbulence ribs are solid ribs formed by the side wall of the cup body protruding inwards along the radial direction.

Further, the tool apron comprises a tool bit, a transmission piece and a base, wherein the middle of the base is bulged to form a dome portion, an inner cavity is formed on the inner side of the dome portion, and the transmission piece is placed in the inner cavity and penetrates through the top end of the dome portion to be connected with the tool bit.

Further, the cutter head includes at least one blade including a root portion connected to the driving member and a wing portion extending in a direction away from the root portion, the wing portion being inclined toward the surface of the dome portion.

Further, the driving medium includes pivot, bearing, rotatory piece and sealing washer, the one end of pivot pass through the bearing with the tool bit is connected, the other end of bearing with rotatory piece is connected, the sealing washer cover is located the bearing, rotatory piece is used for receiving the drive of external drive source and rotates.

Further, fuselage mechanism still includes micro-gap switch, toggle switch, drive assembly and controller, micro-gap switch toggle switch drive assembly and the controller all install in on the casing, micro-gap switch toggle switch drive assembly all with the controller is connected, the controller is used for micro-gap switch with toggle switch all opens down control drive assembly work.

Furthermore, the shell comprises an inner cylinder shell, an outer cylinder shell and a drain pipe, a first drain hole is formed in the bottom wall of the inner cylinder shell, a second drain hole is formed in the bottom wall of the outer cylinder shell, the outer cylinder shell is in a sphere-like shape, the outer cylinder shell is sleeved on the inner cylinder shell, and two ends of the drain pipe are communicated with the first drain hole and the second drain hole respectively.

Furthermore, the micro switch comprises an elastic contact which is connected with the controller, the elastic contact movably penetrates through the bottom wall of the inner cylinder shell, the micro switch is closed when the elastic contact protrudes out of the bottom wall, and the micro switch is opened when the elastic contact sinks into the bottom wall.

Further, the toggle switch comprises a toggle lever, the toggle lever is connected with the controller, a strip-shaped toggle hole is formed in the side wall of the outer cylinder shell in an extending mode along the circumferential direction of the side wall, the toggle lever is installed in the strip-shaped toggle hole, the toggle switch is turned off when the toggle lever toggles to one end of the strip-shaped toggle hole, and the toggle switch is turned on when the toggle lever toggles to the other end of the strip-shaped toggle hole.

Compared with the prior art, the utility model has the beneficial effects that: through improving the casing to fuselage mechanism, set up the casing of fuselage mechanism into the quasi-sphere, this type of sphere is remaining partial sphere form after the spheroid is cut by two planes that parallel, thereby the inboard of casing is formed with annular inner chamber, from this, the produced vibration noise of whole cooking machine or friction noise can form the circulation in the annular inner chamber of casing, the noise can not transmit outside the casing along annular inner chamber circulation flow, but in the inside gradual decay of casing, can reduce the propagation of noise effectively, the noise reduction effect is good, and simple structure is with low costs.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 shows a schematic view of a food processor according to an embodiment of the utility model;

fig. 2 shows an exploded view of a food processor according to an embodiment of the utility model;

FIG. 3 illustrates a schematic view of a food processor housing according to an embodiment of the present invention;

fig. 4 shows a cross-sectional view of a food processor housing according to an embodiment of the utility model;

FIG. 5 illustrates a schematic view of a cup according to an embodiment of the present invention;

FIG. 6 illustrates a schematic view of a section A-A of a cup according to an embodiment of the present invention;

FIG. 7 illustrates a schematic view of a longitudinal cross-section of a cup according to an embodiment of the present invention;

FIG. 8 illustrates a dimensional schematic of a cup according to an embodiment of the present invention;

FIG. 9 shows a schematic view of a tool holder according to an embodiment of the utility model;

FIG. 10 illustrates a top view of a tool holder according to an embodiment of the utility model;

FIG. 11 shows a schematic view of a cutting insert of a tool holder according to an embodiment of the utility model;

FIG. 12 shows an exploded view of a tool holder according to an embodiment of the utility model;

FIG. 13 shows a schematic view of a rotating block of a tool holder according to an embodiment of the utility model;

FIG. 14 shows a schematic view of a base according to an embodiment of the utility model;

FIG. 15 shows an enlarged view of section A of FIG. 14;

FIG. 16a shows a further schematic view of a base according to an embodiment of the utility model;

FIG. 16b shows a further schematic view of a base according to an embodiment of the utility model;

FIG. 17 shows an exploded view of the fuselage mechanism according to an embodiment of the utility model

FIG. 18 illustrates another exploded view of the fuselage mechanism according to an embodiment of the utility model;

FIG. 19 illustrates a schematic view of a rotary drive block of a fuselage mechanism according to an embodiment of the utility model;

FIG. 20 illustrates a schematic view of an inner shell of a fuselage mechanism according to an embodiment of the utility model;

FIG. 21 illustrates a top view of a fuselage mechanism according to an embodiment of the utility model;

FIG. 22 shows an enlarged view of section A of FIG. 21;

FIG. 23 illustrates a bottom view of the fuselage mechanism of an embodiment of the present invention;

a cup body 100; a spoiler rib 110; the incident flow surface 111; a back flow surface 112; a mounting portion 120;

a tool holder 200; a base 210; dome portion 211; an evacuation slot 212; a limit card slot 213; a stopper 2131; clearance gaps 214; a pressing portion 2141; a cutter head 220; a blade 221; root 2211; wing 2212; a transmission member 230; a rotating shaft 231; a rotation block 232; the ridge 2321;

a body mechanism 300; a housing 310; an inner cylindrical shell 311; a first drain hole 3111; a limit clamp groove 3112; a positioning section 3113; an outer cylindrical shell 312; the second drain hole 3121; a strip-shaped toggle hole 3122; a heat dissipation hole 3123; a drain pipe 313; a heat-dissipating mesh enclosure 314; an annular lumen 315; a micro switch 320; the elastic contact 321; a toggle switch 330; a shift lever 331; a drive assembly 340; a motor 341; the rotation driving block 342; the ridge portion 3421; a controller 350.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It will be understood that the terms "comprises" and/or "comprising," when used in this specification and the appended claims, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

It is also to be understood that the terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. As used in the specification of the present invention 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 be further understood that the term "and/or" as used in this specification and the appended claims refers to and includes any and all possible combinations of one or more of the associated listed items.

Referring to fig. 1-23, preferred embodiments of the present invention are provided.

The utility model provides a food processor, as shown in fig. 1 and 2, the food processor comprises a cup body 100 for adding food to be processed, a tool apron 200 for crushing the food to be processed, and a machine body mechanism 300, wherein the cup body 100 is mounted on the tool apron 200, the tool apron 200 is mounted on the machine body mechanism 300, the machine body mechanism 300 comprises a shell 310, the shell 310 is in a sphere-like shape, the sphere-like shape is a partial sphere shape left after a sphere is cut by two parallel planes, and an annular inner cavity 315 is formed inside the shell 310.

Specifically, as shown in fig. 3 and 4, the cross-section of the housing 310 is a circular shape with two symmetrical curved surfaces removed to form a pattern of the remaining portion. The entire housing 310 is in the shape of a flattened sphere when viewed from the outside of the housing 310, and the upper and lower sides of the housing 310 are truncated, the lower side being for placing on a plane and the upper side being for placing the tool holder 200. While the interior of the housing 310 can form an annular cavity 315 within the interior of the housing 310 due to the unique design of the spheroidal shape. Since the food processor is often accompanied by friction and vibration noise during operation, such as noise generated by the rotation friction of the motor, and the food to be processed collides with the cup body 100 to generate vibration noise, when the noise is transmitted to the housing 310, a noise circulation can be formed in the annular cavity 315, the noise circulates in the annular cavity 315 all the time and is not transmitted to the outside of the housing 310, and the noise is gradually attenuated along with the energy of the circulation so as to reduce the decibel of the noise.

By implementing the embodiment, the casing 310 of the body mechanism 300 is improved, and the casing 310 of the body mechanism 300 is set to be a sphere-like shape, which is a partial sphere shape remaining after the sphere is cut off by two parallel planes, so that the annular inner cavity 315 is formed inside the casing 310, and therefore, vibration noise or friction noise generated by the whole food processor can form a circulation flow in the annular inner cavity 315 of the casing 310, and the noise circularly flows along the annular inner cavity 315 and is not transmitted to the outside of the casing 310, but is gradually attenuated inside the casing 310, so that the propagation of noise can be effectively reduced, the noise reduction effect is good, and the structure is simple and the cost is low.

In an embodiment, referring to fig. 5, the cup body 100 is in a cylindrical shape with one axial end open and the other axial end closed, at least one turbulence rib 110 is disposed on an inner side wall surface of the cup body 100, and the turbulence rib 110 extends along an axial direction of the cup body 100 and is distributed along a circumferential direction of the cup body 100; the depth of the spoiler 110 in the radial direction of the cup body 100 is D1, the radius of the cup body 100 is D2, and D2 is 6-9 times of D1.

Specifically, the cup body 100 in this embodiment is cylindrical, one side of the cup body is closed, the other side of the cup body is open, and a cavity for containing food to be processed is formed inside the cup body. When the cup is used, food to be processed is put into the cup body 100, the cup body 100 is installed on the tool apron 200, the cup body 100 and the tool apron 200 form a seal, and the food to be processed in the cup body 100 is crushed and made into pulp along with the rotation of the tool bit. Wherein, the cup body 100 is made of glass materials, the cup body 100 made of glass materials has the advantages of easy cleaning, easy processing and low cost, and the processed food residues can be easily cleaned after being washed.

It should be noted that, in order to solve the problem of poor crushing effect in the prior art, the inventor finds, through a plurality of experiments and tests, that the reason for poor food crushing effect is that, due to the fact that the cutter head is driven by the motor to rotate at a high speed when the food processor is in operation, food to be processed is driven by the cutter head to rotate at a high speed around the inner circumference of the cup body 100, so as to generate a high-speed centrifugal rotation movement in the same direction as the cutter head, that is, to generate a vortex, and the probability of rotary cutting and collision between the material and the cutter head is reduced. For this reason, the inventor creatively proposes a solution to this problem, and the main technical idea is to make the food to be processed in the optimum position between the inner wall of the cup body 100 and the cutter head during the movement of the cutter head, so that the food to be processed can sufficiently collide with the cutter head.

Referring to fig. 6, in the present embodiment, a spoiler rib 110 is disposed on an inner side wall surface of the cup body 100, the spoiler rib 110 extends along an axial direction of the cup body 100, and the spoiler ribs 110 are distributed along a circumferential direction of the cup body 100. Therefore, when processing, the food to be processed forms a vortex at the inner periphery of the cup body 100, and the food to be processed touches the turbulence ribs 110 when rotating along the inner periphery of the cup body 100, so that the resistance in the circumferential direction is met, and the force towards the center of the cup body 100 is generated after the food to be processed receives the resistance, so that the food to be processed moves towards the center of the cup body 100, the distance between the food to be processed and the tool bit is shortened, and the probability of collision between the food to be processed and the tool bit is increased.

With reference to fig. 6, in addition, considering the distance between the spoiler rib 110 and the center of the cup body 100, the present embodiment associates the distance between the spoiler rib 110 and the center of the cup body 100, so that the food to be processed is in a proper position during processing, and thus sufficient collision with the cutter head is obtained. On one hand, the food to be processed cannot be too close to the cutter head during processing, and the best crushing effect is at the peripheral edge of the rotation of the cutter head when the cutter head rotates, so that the food to be processed is too close to the rotation center of the cutter head, and the crushing effect is poor; on the other hand, when processing, the food to be processed can not be too far away from the cutter head, and the food to be processed is difficult to touch the cutter head even under the action of the turbulence ribs 110 due to the too far away from the cutter head, so that the crushing effect is poor. Therefore, in order to find a proper position, the inventor determined that the food to be processed can sufficiently collide with the cutter head when the radius D2 of the cup body 100 is 6 to 9 times the depth D1 of the spoiler 110 after many experiments. Illustratively, the D1 is 5.2mm, the D2 is 40mm, and the crushing effect can reach more than 90% when the D2 is 8 times that of the D1.

Through implementing this embodiment, the cup 100 simple structure that from this obtains does not need other supplementary slurrying parts, and it is convenient to wash, utilizes vortex muscle 110 to change the direction of motion of food, orders about food and carries in order to increase the probability that food and cutter collided toward the cutter, sets up the vortex muscle 110 of suitable degree of depth and makes food be in the optimum position between cup 100 lateral wall and the cutter, and food can be smashed by the cutter fully, and slurrying effect is good.

In one embodiment, referring to fig. 7, the spoiler 110 is a hollow rib formed by a sidewall of the cup body 100 being recessed radially inward. The strip-shaped groove on the side wall of the cup body 100 is the turbulence rib 110, and because the turbulence rib 110 is a hollow rib, the outer side wall of the cup body 100 corresponding to the turbulence rib 110 is recessed inwards, so that a hollow shape is formed. The hollow ribs can reduce the weight of the cup body 100, so that the whole food processor is lighter and convenient to carry.

In another embodiment, it is understood that the turbulator ribs 110 are solid ribs (not shown) formed by the sidewall of the cup 100 protruding radially inward. Set up as solid rib 110, can be so that the lateral wall of cup 100 is smooth state, and cup 100 does not have the difference with ordinary glass in the aspect of the appearance, changes in and grips, and the outward appearance is more regular. And solid rib can increase the weight of cup 100 for the cooking machine is difficult for shaking in the course of the work, thereby reduces the noise, and noise reduction effect is good.

In an embodiment, referring to fig. 6 and 7, the spoiler 110 includes an incident surface 111 facing the water flow and a back surface 112 facing away from the water flow, the incident surface 111 and the back surface 112 are both arc-shaped, and the incident surface 111 and the back surface 112 are in arc transition. The cutter head enables food to be processed to form a water vortex in the cup body 100 in the rotating process, the food to be processed rotates clockwise or anticlockwise along the inner periphery of the cup body 100, one surface, subjected to resistance of the turbulence ribs 110, of the food to be processed is a stream facing surface 111 in the rotating process, and one surface, facing away from the stream facing surface 111 in the circumferential direction of the cup body 100, of the food to be processed is a stream backing surface 112. The overall spoiler rib 110 is semi-cylindrical, and the overall cross section of the spoiler rib 110 is similar to the shape of an R angle and is composed of the incident flow surface 111 and the back flow surface 112. The turbulence rib 110 is arc-shaped, so that the cleaning is convenient, dirt is not hidden, and the structure is simple.

Specifically, as shown in fig. 6, four turbulence ribs 110 are arranged on the inner side wall surface of the cup body 100, the turbulence ribs 110 are symmetrically arranged in pairs, and the turbulence ribs 110 are uniformly distributed along the circumferential direction of the cup body 100. Four turbulence ribs 110 are arranged to enable food to be processed to move towards the center of the cup body 100 from four directions, and the efficiency of the steric hindrance effect is improved.

In one embodiment, referring to fig. 8, the height of the spoiler 110 is H1, the height of the cup 100 is H2, and the D2 is 1.4-1.1 times of the D1. Illustratively, the H1 is 84.3mm, the H2 is 115, the D2 is 1.36 times of the D1, and the crushing effect can reach more than 90% when the H2 is 1.36 times of the H1.

In one embodiment, with continued reference to fig. 8, a gap is left between the turbulator rib 110 and both the top and bottom of the cup 100. The spoiler 110 is not completely equal to the cup 100 in height, but a gap is left between the top and the bottom of the cup 100 to save the space of the cup 100 and increase the capacity of the cup 100.

In this embodiment, with continued reference to fig. 4, the bottom wall of the cup 100 transitions in a circular arc with the side wall of the cup 100. The arc transition between the side wall and the bottom wall of the cup body 100 is easier to clean, dirt cannot be hidden, and the cup body can be cleaned up by simple washing.

In one embodiment, referring to fig. 5 and 8, the cup 100 is formed with a mounting portion 120 protruding outward from the opening in the axial direction, and the mounting portion 120 is provided with an external thread for screwing. Installation department 120 forms along cup 100 opening border, installation department 120's outline is less than cup 100's outline, be equipped with the external screw thread on installation department 120's the lateral wall, can form sealedly with cooking machine blade holder 200's internal thread during the use spiral shell mutually. It will be appreciated, of course, that the mounting portion 120 may have other configurations, such as a snap-fit configuration, as long as it is removable.

In one embodiment, referring to fig. 9, the tool holder comprises a tool bit 220, a transmission member 230, and a base 210, wherein the middle of the base 210 is bulged to form a dome portion 211, an inner cavity is formed inside the dome portion 211, and the transmission member 230 is disposed in the inner cavity and connected to the tool bit 220 through the top end of the dome portion 211.

Specifically, the base 210 in this embodiment is cylindrical, and the inner sidewall of the base 210 is provided with an internal thread, and when in use, the internal thread of the base 210 is screwed with the external thread of the cup 100, so that the base 210 and the cup 100 form a seal. The dome 211 is formed by the central bulge at the bottom of the base 210, and the top end of the dome 211 is flush with the height of the cylinder wall of the base 210 or slightly higher than the height of the cylinder wall of the base 210. And the inner side of the dome portion 211 is hollow, that is, the inner side of the dome portion 211 forms an inner cavity for installing the transmission member 230, which can save space and make the whole machine smaller. The cutter head 220 is disposed at the top end of the dome portion 211 and rotated by the transmission member 230, so that food residue does not remain between the cutter head 220 and the top end of the dome portion 211, and because the dome portion 211 has a height difference and a certain inclination, the residue slides down along the top end of the dome portion 211 to the bottom of the base 210 under the action of gravity. The tool apron 200 can be cleaned only by simple flushing after being processed, and the cleaning is simple and convenient.

Through implementing this embodiment, utilize dome portion 211 to improve the position of tool bit 220 for tool bit 220 is in the high-order department at base 210 center, and blade holder 200 food waste can follow the landing to the bottom of dome portion 211 at the during operation, and food waste can not remain in the clearance between tool bit 220 and base 210, only needs simply to wash can the sanitization, the convenient high efficiency of clearance.

In one embodiment, referring to FIG. 10, the surface of the dome portion 211 transitions in a circular arc. The dome part 211 is arranged to have a certain radian on the surface, so that food residues slide smoothly and have a small friction coefficient. And the dome-shaped surface of the arc transition has a certain gradient, so that food residues are more easily slipped off.

In one embodiment, referring to fig. 11, the cutting head 220 comprises at least one blade 221, wherein the blade 221 comprises a root portion 2211 and a wing portion 2212 extending away from the root portion 2211, wherein the root portion 2211 is connected to the driving member 230, and the wing portion 2212 is inclined to the surface of the dome portion 211. The root 2211 of the blade 221 refers to the axial center position of the blade 221 when rotating, and the wing 2212 is the main body of the blade 221, that is, the portion that most sufficiently collides with the food to be processed when rotating.

In another embodiment, the cutting head 220 comprises two blades 221, and the wing portion 2212 of the other blade 221 is tilted away from the dome portion 211.

In this embodiment, with continued reference to fig. 11, the cutting head 220 includes a first blade 221 and a second blade 221, the root portions 2211 of the first blade 221 and the second blade 221 are coaxially connected, and the wing portions 2212 of the two are angularly separated by a cross. The first blade 221 and the second blade 221 rotate to cut around the connection point of the root 2211 under the driving of the transmission member 230. Wherein the wing portion 2212 of the first blade 221 is inclined to the surface of the dome portion 211, and the root portion 2211 of the first blade 221 and the wing portion 2212 form an included angle α, which is between 180 degrees and 90 degrees. Preferably between 160 and 130 degrees. Since the food to be processed may be caught between the gap between the dome portion 211 and the inner sidewall of the base 210 during the processing, it is cut in a flat manner by rotation if there is no included angle between the wing portion 2212 and the root portion 2211 of the blade 221, and if the volume of the food to be processed is small, it may occur that it is caught between the gap between the dome portion 211 and the inner sidewall of the base 210 at all times, and is not cut by the blade 221. Therefore, in order to avoid this, the present embodiment inclines the wing portion 2212 of the first blade 221 toward the surface of the dome portion 211, so that the blade 221 can be ensured to cut the food to be processed between the gaps, and the efficiency of the pulping is improved.

Further, with continued reference to fig. 11, the wing portion 2212 of the second blade 221 is tilted away from the dome portion 211, and the root portion 2211 of the second blade 221 and the wing portion 2212 form an included angle β, where β is between 180 and 90 degrees. Preferably between 160 and 130 degrees. Because the food is in a variety of types and different food has different volume sizes, for the food to be processed with large volume, if there is no included angle between the wing portion 2212 and the root portion 2211 of the blade 221, it is cut in a flat cutting manner, and at this time, the blade 221 can only cut the bottom of the food to be processed, the contact area for cutting is small, resulting in poor crushing effect. Therefore, in order to avoid this, the present embodiment tilts the wing portion 2212 of the second blade 221 away from the dome portion 211, which can ensure that the blade 221 cuts the main body portion of the food to be processed, thereby improving the efficiency of the pulping.

Therefore, the wing parts 2212 of the first blade 221 and the second blade 221 of the embodiment are respectively inclined or tilted at different angles to form the irregular cutter head 220, and irregular vortex can be generated during the rotating process, so that the cutter head 220 can be fully contacted with the food to be processed, and a good crushing effect can be obtained.

In an embodiment, referring to fig. 12, the transmission member 230 includes a rotating shaft 231, a bearing (not shown), a rotating block 232, and a sealing ring (not shown), wherein one end of the rotating shaft 231 is connected to the cutter head 220 through the bearing, the other end of the bearing is connected to the rotating block 232, the sealing ring is sleeved on the bearing, and the rotating block 232 is driven by an external driving source to rotate. Since the tool holder 200 needs to be cleaned, the driving source needs to be separated from the tool holder 200, otherwise, electric leakage is likely to occur. Therefore, the transmission member 230 needs to be provided with a rotation block 232 to cooperate with a driving source on the body mechanism 300, so as to rotate the rotation shaft 231 under the driving of the driving source. The rotating shaft 231 and the rotating block 232 are both located in the inner cavity of the dome portion 211, the rotating block 232 is fixed with one end of the rotating shaft 231, the other end of the rotating shaft 231 penetrates through the top end of the dome portion 211 to be connected with the cutter head 220, and the bearing is sleeved on the rotating shaft 231. Due to the presence of the lubricant within the bearings, black mold may easily appear on the base 210 after a period of use, affecting the user's dietary health. In order to avoid the seepage of lubricating oil in the bearing, locate the bearing with the sealing washer cover for lubricating oil in the bearing can not ooze, thereby can not produce black mould, guarantees that user's diet is healthy.

In this embodiment, referring to fig. 13, a surface of the rotating block 232 facing away from the rotating shaft 231 has a plurality of edge portions 2321, and the edge portions 2321 are radially distributed. The surface of the rotating block 232 opposite to the rotating shaft 231 is used for being matched with the driving source of the machine body mechanism 300, so that the surface is provided with a plurality of edge portions 2321, and the edge portions 2321 are distributed radially, therefore, the driving source of the machine body mechanism 300 can utilize the bulge of the edge portions 2321 to arrange a transmission component matched with the edge portions 2321 to be abutted against the transmission component, so as to generate a force along the circumferential direction on the whole rotating block 232, further drive the rotating shaft 231 of the rotating block 232, and drive the cutter head 220 to rotate through the rotating shaft 231, thereby realizing a transmission process. The rotating block 232 of the embodiment is simple in structure, does not need complex assembly actions, can realize transmission only by contact and offset, and is simple and efficient.

In an embodiment, referring to fig. 14, the sidewall of the base 210 is recessed along a radial direction thereof to form a clearance groove 212, and a groove wall of the clearance groove 212 extends along a circumferential direction to further form a limit slot 213. The tool post 200 is detachably mounted on the body mechanism 300, the tool post 200 can be detachably mounted in a variety of ways, and the embodiment adopts a rotary clamping manner to realize detachable assembly. Specifically, a clearance groove 212 is provided on a side wall of the base 210, and the clearance groove 212 is used to clearance a positioning member on the body mechanism 300 when the base 210 is placed on the body mechanism 300. Meanwhile, in the embodiment, a limiting slot is further formed in the slot wall of the clearance slot 212, the limiting slot 213 extends along the axial direction of the base 210, and the limiting slot 213 is used for the positioning component on the body mechanism 300 to be clamped in. The specific installation method is to first place the base 210 on the body mechanism 300, and then the positioning component on the body mechanism 300 is in the clearance groove 212, and then rotate the base 210 to make the positioning component on the body mechanism 300 snap into the limit slot 213, so as to complete the positioning. The assembly mode that the rotation card that this embodiment adopted goes into, simple structure, the installation is convenient firm, easy operation, and the user uses and experiences well.

In this embodiment, referring to fig. 15, the limiting slot 213 is in a channel shape with one end closed and the other end open, and a limiting portion 2131 is formed by a protruding groove wall of the limiting slot 213 close to the opening. The limiting portion 2131 is a protrusion located at an opening of the limiting slot 213, and a positioning component of the body mechanism 300 is usually provided with a recess adapted to the shape of the protrusion, and in the assembling and positioning, the protrusion is just snapped into the recess, so as to provide a circumferential pre-tightening force for the base 210 and prevent the base 210 from rotating relative to the body mechanism 300.

In an embodiment, referring to fig. 16a, the sidewall of the base 210 has a clearance gap 214 along the circumference thereof, and the base 210 further has a pressing portion 2141 extending into the clearance gap 214. The clearance gap 214 is used for clearance of the micro switch on the body mechanism 300 when the base 210 is placed on the body mechanism 300, and the pressing portion 2141 is used for pressing the micro switch. With reference to the above-mentioned embodiment, the base 210 is placed on the body mechanism 300, the contact of the micro switch on the body mechanism 300 is located in the clearance gap 214, and the pressing portion 2141 presses against the contact of the micro switch when the base 210 is rotated, so as to turn on the switch. The switch mode that this embodiment adopted, simple structure, easy operation, user experience is good.

In another embodiment, referring to fig. 16b, the sidewall of the base 210 corresponding to one side of the opening of the clearance gap 214 is inclined. When the tool post is placed on the machine body mechanism 300, the tool post may not be placed at the correct position, and there may be a situation where the positioning component on the machine body mechanism 300 is located in the clearance gap 214, and at this time, the base 210 is locked due to the positioning component being located in the clearance gap 214, and cannot be rotated to the position corresponding to the micro switch, and the user cannot align correctly by rotating the base 210. Therefore, in order to avoid the situation that the base 210 is locked and can not be rotated and aligned due to the misplacement of the placed position, the whole mouth of the clearance gap 214 of the present embodiment is shaped like "Jiong", wherein either side of the clearance gap 214 of the "Jiong" shape is inclined, for example, the right side is inclined, or the left side is inclined, but it should be understood that both sides may be inclined, specifically, according to the requirement of the actual rotation direction. Through the positioning component of inclined plane form lateral wall butt to fuselage mechanism 300 when base 210 is rotatory, along with the rotation of base 210, whole base 210 jack-up is gone up with inclined plane form lateral wall, continues to rotate base 210 again until the positioning component of fuselage mechanism 300 falls into the groove 212 of keeping away of base 210, and the micro-gap switch of fuselage mechanism 300 falls into and keeps away in the breach 214 to realized the conversion of wrong counterpoint to correct counterpoint, base 210 can not be blocked because of the dislocation counterpoint.

In an embodiment, referring to fig. 17, the body mechanism 300 further includes a micro switch 320, a toggle switch 330, a driving assembly 340, and a controller 350, the micro switch 320, the toggle switch 330, the driving assembly 340, and the controller 350 are all mounted on the housing, the micro switch 320, the toggle switch 330, and the driving assembly 340 are all connected to the controller 350, and the controller 350 is configured to control the driving assembly 340 to operate when the micro switch 320 and the toggle switch 330 are both turned on.

Specifically, since the single switch control driving assembly 340 is prone to mistaken touch during operation, the present embodiment adopts a dual-switch manner in combination with an actual application scenario to solve the problem of idle rotation of the cutter head caused by the mistaken touch. Usually, the knife holder 200 of the food processor is separated from the body mechanism 300, and after the knife holder 200 is installed on the body mechanism 300, the body mechanism 300 can drive the knife head of the knife holder 200 to work. Therefore, this embodiment adopts micro-gap switch 320 to realize that the mode of double switch guarantees safe in utilizationly, even stir toggle switch 330 and also can not drive the tool bit work after blade holder 200 is installed to fuselage mechanism 300, still need trigger micro-gap switch 320 simultaneously and just can drive the tool bit work, consequently, even the user mistake accidentally touches toggle switch 330 carelessly, also can not lead to driving tool bit work to the idle problem of tool bit that leads to because of the mistake is touched has been avoided effectively.

Through implementing this embodiment, set up micro-gap switch 320 and toggle switch 330 on casing 310, be connected micro-gap switch 320 with toggle switch 330 and controller 350, just control drive assembly 340 work under the circumstances that micro-gap switch 320 and toggle switch 330 were opened simultaneously under controller 350, therefore, drive assembly 340 must just can work under the circumstances that two switches were all opened, utilize the rotation of dual switch trigger tool bit, avoid because the user mistake touches a switch and lead to the danger that the idle running of tool bit brought, factor of safety is high, reliability is improved.

In an embodiment, referring to fig. 18, the housing 310 includes an inner cylindrical shell 311, an outer cylindrical shell 312 and a water discharge pipe 313, a first water discharge hole 3111 is formed on a bottom wall of the inner cylindrical shell 311, a second water discharge hole 3121 is formed on a bottom wall of the outer cylindrical shell 312, the outer cylindrical shell 312 is sleeved on the inner cylindrical shell 311, and two ends of the water discharge pipe 313 are respectively communicated with the first water discharge hole 3111 and the second water discharge hole 3121. Specifically, the inner cylinder 311 and the outer cylinder 312 are both cylindrical with one end open and the other end closed. The inner housing 311 is used for mounting the tool holder 200, and the outer housing 312 is used for mounting functional modules, such as a micro switch 320, a toggle switch 330, a driving assembly 340, a controller 350, and the like. Because the cooking machine can produce the vibration all the time in the in-service use, the liquid in the cup 100 can spill over to the outside unavoidably, consequently in order to avoid appearing leaking the condition that leads to the short circuit, this embodiment adopts the mode of two casing 310 drains, realizes the complete isolation with the liquid that spills over. Specifically, drain holes are formed in the bottom walls of the two cylindrical shells, and the two drain holes are communicated through the drain pipe 313, the cup body 100 is usually mounted on the machine body mechanism 300 after being mounted on the tool apron 200, in this embodiment, the inner cylindrical shell 311 is mounted on the tool apron 200, so that liquid overflowing from the cup body 100 can only overflow to the inner cylindrical shell 311, and liquid in the inner cylindrical shell 311 can only flow out to the drain pipe 313 through the drain hole in the bottom wall thereof, and finally flows into the drain hole in the bottom of the outer cylindrical shell 312 through the drain pipe 313 to be discharged, and the functional module is mounted on the outer cylindrical shell 312, and liquid cannot flow into the functional module, so that complete water blocking is realized.

In one embodiment, with continued reference to fig. 17, the driving assembly 340 includes a motor 341 and a rotation driving block 342, the motor 341 is installed in the outer cylinder shell 312, the rotation driving block 342 is disposed on the bottom wall of the inner cylinder shell 311, and an output shaft of the motor 341 passes through the bottom wall of the inner cylinder shell 311 and is connected to the rotation driving block 342. Since the tool holder 200 is to be cleaned, it is usually separated from the body mechanism 300 and needs to be mounted to the body mechanism 300 to be operated. There are various ways to drive the knife head of the knife holder 200 to move, in this embodiment, the rotation driving block 342 is implemented by disposing the rotation driving block 342 on the bottom wall of the inner cylindrical shell 311, the motor 341 is mounted on the outer cylindrical shell 312 and connected to the rotation driving block 342 through the bottom wall of the inner cylindrical shell 311, and the motor 341 drives the rotation driving block 342 to rotate when operating. When the tool apron 200 is installed on the inner cylinder shell 311, the rotary driving block 342 can be matched with a transmission part of a tool bit on the tool apron 200, so that the tool bit is driven to work, and the transmission structure is simple.

In this embodiment, referring to fig. 19, a surface of the rotation driving block 342 facing away from the output shaft has a plurality of ridge portions 3421, and the ridge portions 3421 are radially distributed. The rotary driving block 342 is shaped like an oblate cylinder as a whole, a space for matching transmission is formed by the middle of the rotary driving block being sunken, a plurality of edge parts 3421 are distributed in the space, and the edge parts 3421 are distributed in a radial shape. From this, utilize the protruding inconsistent cooperation of the driving medium of the last tool bit of edge portion 3421 and blade holder 200, it is rotatory to drive this driving medium under the work of motor 341, and then drives the tool bit rotation to realize driven process. The rotating block driving block of the embodiment has a simple structure, does not need complex assembly actions, can realize transmission only by contact and offset, and is simple and efficient.

In an embodiment, referring to fig. 20 to 22, the micro switch 320 includes an elastic contact 321, the elastic contact 321 is connected to the controller 350, the elastic contact 321 is movably disposed through a bottom wall of the inner cylinder 311, the micro switch 320 is turned off when the elastic contact 321 protrudes from the bottom wall, and the micro switch 320 is turned on when the elastic contact 321 sinks into the bottom wall. The bottom wall of the inner cylinder shell 311 is provided with a hole, the elastic contact 321 penetrates through the hole, in a natural state, the elastic contact 321 protrudes out of the bottom wall of the inner cylinder shell 311, the elastic contact 321 is a switch contact of the micro switch 320, the micro switch 320 is opened by pressing the elastic contact 321, the elastic contact 321 rebounds and resets to close the micro switch 320, that is, in a natural state, the micro switch 320 is closed, and the micro switch 320 can be opened only by operation of a user. Specifically, the elastic contact 321 includes a body and a contact located at an end of the body, a periphery against which a spring is abutted is further formed on the body, the spring is sleeved on the periphery of the body, one end of the spring abuts against the periphery of the body, and the other end of the spring abuts against a bottom wall of the inner cylindrical shell 311, so that the elastic return of the elastic contact 321 is realized. Because interior cartridge shell 311 is used for installing blade holder 200, this embodiment sets up elastic contact 321 on the diapire of interior cartridge shell 311, consequently, can utilize blade holder 200 to open micro-gap switch 320, simple structure, easy operation is convenient, and user experience is good.

There are various ways to turn on the micro switch 320 by using the tool holder 200, and this embodiment is implemented by turning the tool holder 200 to turn on the micro switch 320. A pressing member is generally provided on the tool holder 200, and the contact of the micro switch 320 is pressed down by the pressing member, so that the micro switch 320 is turned on. Referring to fig. 6, specifically, a limiting slot 3112 is disposed on the bottom wall of the inner cylinder housing 311, the limiting slot 3112 extends along the circumferential direction of the inner cylinder housing 311, and the elastic contact 321 is located in the limiting slot 3112 when protruding out of the bottom wall. This embodiment utilizes spacing draw-in groove 3112 to guide the part that supports on the blade holder 200, and during the part that supports entered into spacing draw-in groove 3112, can easily push down elastic contact 321 along the motion of spacing draw-in groove 3112 to open micro-gap switch 320. That is, when the tool holder 200 is mounted on the inner cylindrical shell 311, the tool holder 200 rotates a certain angle relative to the inner cylindrical shell 311, and then the pressing member on the tool holder 200 presses the elastic contact 321 to open the micro switch 320. Utilize spacing draw-in groove 3112 to the guide of pressing the part, rotatory pushing down is more accurate, and the switch is easier, easy operation.

In one embodiment, referring to fig. 20 and 21, a positioning section 3113 is disposed on a sidewall of the inner cartridge housing 311, and the positioning section 3113 extends along a circumferential direction of the inner cartridge housing 311. After the microswitch 320 is turned on by rotating the tool apron 200, it is necessary to ensure that the tool apron 200 does not continue to rotate, otherwise, the microswitch 320 cannot be turned on after the abutting part of the tool apron 200 is dislocated with the elastic contact 321, and thus the tool bit on the tool apron 200 cannot be controlled to work. Therefore, a positioning section 3113 is required to be disposed on the inner cylinder 311 to position the tool holder 200, so that the tool holder 200 stops when rotating to the position where the micro switch 320 is turned on. In order to realize positioning, the tool holder 200 is provided with a positioning part matching with the positioning section 3113, the side wall of the inner cylinder 311 is provided with the positioning section 3113, the tool holder 200 rotates relative to the inner cylinder 311 until the positioning part on the tool holder 200 matches with the positioning section 3113 on the inner cylinder 311, and at this time, the tool holder 200 stops rotating relative to the inner cylinder 311. Adopt the mode that location section 3113 realized the switch location, simple structure, convenient operation, user experience is good.

In an embodiment, referring to fig. 17, the toggle switch 330 includes a toggle lever 331, the toggle lever 331 is connected to the controller 350, a strip-shaped toggle hole 3122 is formed in the side wall of the outer cylindrical shell 312 in an extending manner along the circumferential direction thereof, the toggle lever 331 is installed in the strip-shaped toggle hole 3122, the toggle switch 330 is turned off when the toggle lever 331 is toggled to one end of the strip-shaped toggle hole 3122, and the toggle switch 330 is turned on when the toggle lever 331 is toggled to the other end of the strip-shaped toggle hole 3122. In this embodiment, a strip-shaped toggle hole 3122 is formed on the side wall of the outer cylinder shell 312, two ends of the strip-shaped toggle hole 3122 represent two states, one is a state in which the toggle switch 330 is turned on, and the other is a state in which the toggle switch 330 is turned off, so that the user operation is simple and clear, and the use experience is good. It should be noted that, the present embodiment is further provided with a return tension spring, which is used for connecting the shift lever 331, and when the shift lever 331 is located at one end of the strip-shaped shift hole 3122, which closes the toggle switch 330, the return tension spring is in a natural state; when the driving lever 331 is located at one end of the strip-shaped shifting hole 3122 where the toggle switch 330 is opened, the reset tension spring is in a stretching state, and along with the reset contraction of the reset tension spring, the driving lever 331 will slowly move along the strip-shaped shifting rod to the other end.

In an embodiment, referring to fig. 18 and 23, the heat dissipation device further includes a heat dissipation mesh enclosure 314, the bottom wall of the outer cylinder casing 312 is provided with heat dissipation holes 3123, and the heat dissipation mesh enclosure 314 covers the heat dissipation holes 3123. The heat dissipation holes 3123 are provided to dissipate heat from the motor 341, thereby preventing the motor 341 from being overheated and stopping. The heat dissipation mesh enclosure 314 adopts metal materials, and the heat conduction is faster, and the radiating effect is good, and the heat dissipation mesh enclosure 314 seals louvre 3123, can also prevent the cockroach from climbing into, and the protection circuit board avoids the circuit board short circuit to damage, guarantees food safety.

The following describes the installation and opening and closing process of the food processor.

The cup 100 is first screwed to the holder 200, and the cup 100 and the holder 200 are mounted to be sealed. Then, the tool holder 200 is placed on the inner cylinder shell 311 of the body mechanism 300, at this time, the positioning section 3113 on the inner cylinder shell 311 is located in the clearance groove 212 of the base 210, and the limiting slot 3112 of the inner cylinder shell 311 is located in the clearance notch 214 of the base 210. The outer cylinder shell 312 is provided with an unlocking and locking mark, and rotates towards the locking mark, and at this time, the positioning section 3113 on the inner cylinder shell 311 is embedded into the limiting clamping groove 213 of the base 210, so that the locking action is completed. Meanwhile, the pressing portion on the base 210 is screwed into the limit slot 3112 of the inner cylinder housing 311, and the elastic contact 321 in the limit slot 3112 is pressed under the guidance of the limit slot 3112 of the inner cylinder housing 311, so as to press the elastic contact 321 downward, thereby opening the micro switch 320. Toggle switch 330 is stirred again afterwards, because the rotatory drive block 342 is balanced with rotatory piece 232 both of the blade holder 200 driving medium after blade holder 200 has installed, the drive assembly of fuselage mechanism 300 is rotatory through the rotatory drive block 342 of drive, rotatory drive block 342 drive rotatory piece 232 is rotatory, and then it is rotatory to drive the tool bit through pivot 231, the tool bit is rotatory to smash the slurrying with the food of treating in the cup 100 to the whole installation and the switching process of cooking machine have been accomplished.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. The utility model provides a food processer, is used for smashing including being used for adding the cup of treating the processing food blade holder and the fuselage mechanism of treating the processing food, the cup install in the blade holder, the blade holder install in fuselage mechanism, a serial communication port, fuselage mechanism includes the casing, the casing is the spheroidicity, the spheroidicity is that remaining part spheroid form after the spheroid is cut by two planes that parallel is described, the inboard of casing is formed with annular inner chamber.

2. The food processor of claim 1, wherein the cup body is in a cylindrical shape with one axial end open and the other axial end closed, at least one turbulence rib is arranged on the inner side wall of the cup body, and the turbulence rib extends along the axial direction of the cup body and is distributed along the circumferential direction of the cup body; the depth of the spoiler ribs in the radial direction of the cup body is D1, the radius of the cup body is D2, and D2 is 6-9 times of D1.

3. The food processor of claim 2, wherein the spoiler rib is a hollow rib formed by a sidewall of the cup body being recessed radially inward; or the turbulence ribs are solid ribs formed by the side wall of the cup body protruding inwards along the radial direction.

4. The food processor of claim 1, wherein the knife holder comprises a knife head, a transmission member and a base, the middle of the base is bulged to form a dome portion, an inner cavity is formed on the inner side of the dome portion, and the transmission member is arranged in the inner cavity and connected with the knife head through the top end of the dome portion.

5. The food processor of claim 4, wherein the cutter head comprises at least one blade, the blade comprising a root portion and a wing portion extending away from the root portion, the root portion being connected to the drive member, the wing portion being inclined toward the surface of the dome portion.

6. The food processor of claim 5, wherein the transmission member comprises a rotating shaft, a bearing, a rotating block and a sealing ring, one end of the rotating shaft is connected with the cutter head through the bearing, the other end of the bearing is connected with the rotating block, the sealing ring is sleeved on the bearing, and the rotating block is driven by an external driving source to rotate.

7. The food processor of any one of claims 1-6, wherein the machine body mechanism further comprises a micro switch, a toggle switch, a driving assembly and a controller, the micro switch, the toggle switch, the driving assembly and the controller are all installed on the housing, the micro switch, the toggle switch and the driving assembly are all connected with the controller, and the controller is used for controlling the driving assembly to work when the micro switch and the toggle switch are both turned on.

8. The food processor of claim 7, wherein the housing comprises an inner cylindrical shell, an outer cylindrical shell and a drain pipe, a first drain hole is formed on the bottom wall of the inner cylindrical shell, a second drain hole is formed on the bottom wall of the outer cylindrical shell, the outer cylindrical shell is in the sphere-like shape, the outer cylindrical shell is sleeved on the inner cylindrical shell, and two ends of the drain pipe are respectively communicated with the first drain hole and the second drain hole.

9. The food processor of claim 8, wherein the micro switch comprises an elastic contact, the elastic contact is connected with the controller, the elastic contact is movably arranged on the bottom wall of the inner cylinder shell in a penetrating way, the micro switch is closed when the elastic contact protrudes out of the bottom wall, and the micro switch is opened when the elastic contact sinks into the bottom wall.

10. The food processer according to claim 8, wherein the toggle switch comprises a toggle lever, the toggle lever is connected with the controller, a strip-shaped toggle hole is formed in the side wall of the outer cylinder shell in an extending manner along the circumferential direction of the side wall, the toggle lever is installed in the strip-shaped toggle hole, the toggle switch is turned off when the toggle lever is toggled to one end of the strip-shaped toggle hole, and the toggle switch is turned on when the toggle lever is toggled to the other end of the strip-shaped toggle hole.

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