CN215383438U - Low-height food processor - Google Patents

Abstract

The utility model discloses a low-height food processor which comprises a machine base and a stirring cup arranged on the machine base, wherein the machine base comprises a machine shell, a motor and an air duct flowing through the motor, the height of the machine shell is H1, and H1 is less than or equal to 100 mm. The utility model has the beneficial effects that: the machine base of the food processor is low in height, so that the height of the stirring cup is low, the shaking of the machine base and the stirring cup in the processing process is reduced, and the noise is reduced.

Description

Low-height food processor

Technical Field

The utility model relates to a food processing technology, in particular to a low-height food processor.

Background

Existing food processors typically include a base and a blender cup mounted to the base. The base comprises a shell, a motor and an air duct flowing through the motor. The bottom of the machine shell is provided with an air inlet and an air outlet of an air duct. The two air inlets are respectively positioned on the left side and the right side of the motor; the air outlet is provided with one and is positioned at the rear side of the motor. The motor cover is wrapped outside the motor, and the inside heat dissipation chamber that encloses of motor cover. The upper end of the motor cover forms a heat dissipation cavity inlet communicated with the air inlet, and the lower end of the motor cover forms a heat dissipation cavity outlet communicated with the air outlet. The air duct comprises a heat dissipation cavity, an air inlet channel and an air outlet channel, wherein air flows from the air inlet to the inlet of the heat dissipation cavity, and air flows from the outlet of the heat dissipation cavity to the air outlet. A fan positioned in the air outlet channel is arranged below the motor. Under the drive of the fan, air enters the interior of the shell from the air inlets on the left side and the right side of the motor, then flows upwards to the inlet of the heat dissipation cavity, flows downwards through the motor and then reaches the outlet of the heat dissipation cavity, and finally is discharged out of the shell from the air outlet, so that the heat dissipation of the motor is completed.

However, the whole machine base is higher, so that the height of the stirring cup is raised, the gravity centers of the machine base and the stirring cup are raised, the machine base and the stirring cup are easy to shake in the machining process, noise is increased, and improvement is needed.

SUMMERY OF THE UTILITY MODEL

The object of the present invention is to provide a food processor of low height. The machine base of the food processor is low in height, so that the height of the stirring cup is low, the shaking of the machine base and the stirring cup in the processing process is reduced, and the noise is reduced.

The technical purpose of the utility model is realized by the following technical scheme:

a low-height food processor comprises a machine base and a stirring cup arranged on the machine base, wherein the machine base comprises a machine shell, a motor and an air duct flowing through the motor, the height of the machine shell is H1, and H1 is less than or equal to 100 mm.

By adopting the technical scheme, the height of the base of the existing food processor is about 200mm generally, which is equivalent to that the maximum height of the base of the application is half of the height of the base of the existing food processor. Correspondingly, the height of the stirring cup can be reduced, so that the center of gravity of the machine base and the stirring cup is reduced, the shaking of the machine base and the stirring cup in the machining process is reduced, and the noise is reduced. Meanwhile, the height of the base and the height of the stirring cup are reduced, so that people can conveniently take, place and operate the base and the stirring cup, and the user experience is improved.

The utility model is further configured to: the projection area of the shell in the horizontal plane is S, and H1/S is more than or equal to 0.005 and less than or equal to 0.08.

By adopting the technical scheme, H1/S is more than 0.08, the projection area of the shell in the horizontal plane is too small, and the floor area of the shell is smaller. In the operation process of the food processor, the food processor needs to be placed on a working table, and the machine shell is in direct contact with the working table. Thus, the support surface of the housing is too small, resulting in poor stability of the food processor on the countertop. If H1/S is less than 0.005, the projected area of the housing in the horizontal plane becomes too large, and the housing area becomes too large, which is not favorable for storage. H1/S is more than or equal to 0.005 and less than or equal to 0.08, and the machine shell is convenient for a user to store on the premise of meeting the stability of the food processor placed on a working table.

The utility model is further configured to: when the stirring cup is arranged on the machine base, the total height of the machine base and the stirring cup is H2, and H2/S is more than or equal to 0.03 and less than or equal to 0.35.

By adopting the technical scheme, H2/S is more than 0.35, the projection area of the machine shell in the horizontal plane is too small, and the floor area of the machine shell is smaller. In the operation process of the food processor, the food processor needs to be placed on a working table, and the machine shell is in direct contact with the working table. Thus, the support surface of the housing is too small, resulting in poor stability of the food processor on the countertop. If H2/S is less than 0.03, the projected area of the housing in the horizontal plane becomes too large, and the footprint of the housing becomes too large, which is not favorable for storage. H2/S is more than or equal to 0.03 and less than or equal to 0.35, and the machine shell can be conveniently stored by a user on the premise of meeting the stability of the food processor placed on the working table.

The utility model is further configured to: the height of the air duct is Z, and Z/H1 is more than or equal to 0.4 and less than 1.

By adopting the technical scheme, Z/H1 is less than 0.4, which means that Z is too small. Air generally flows through the motor in the axial direction of the motor, so that Z is too small, meaning that there is less area for air to flow through the motor, which is detrimental to heat dissipation of the motor. Therefore, Z/H1 is more than or equal to 0.4 and less than 1, air flows through the motor as much as possible, and the heat dissipation of the motor is enhanced.

The utility model is further configured to: the height of the air duct is Z, the height of the motor is D, and D/Z is more than or equal to 0.6 and less than or equal to 2.5.

Through adopting above-mentioned technical scheme, the motor includes motor shaft, the rotor of parcel motor shaft, the stator of parcel rotor, is located stator top and stator below upper cover plate and lower apron respectively. And for the maximum height of the motor, the motor shaft is not considered to be used as a part of the motor for measurement, and if the fan is sleeved with the motor shaft and is driven by the motor shaft to rotate, the fan is used as a part of the motor for measurement. If D/Z is greater than 2.5, D is too large. Under the less prerequisite in height in wind channel, the height of motor is still great, and then the height of frame also can be great, and the height of stirring cup is still great, leads to the focus of frame and stirring cup still higher, and frame and stirring cup rock still great in the course of working, lead to producing more noise. D/Z is less than 0.6, if D is too small, the corresponding motor torque is small, and therefore a good crushing effect cannot be achieved. D/Z is more than or equal to 0.6 and less than or equal to 2.5, so that the height of the machine base and the height of the stirring cup can be reduced on the premise that the height of the air channel is smaller, the shaking of the machine base and the stirring cup in the machining process is reduced, the noise is reduced, and the requirement for the torque of the motor can be met.

The utility model is further configured to: the air duct comprises an air inlet and an air outlet, the distance between projections of the air inlet in the horizontal direction and projections of a motor shaft of the motor in the horizontal direction is X1, the distance between projections of the air outlet in the horizontal direction and projections of the motor shaft of the motor in the horizontal direction is X2, the sum of X1 and X2 is X, and Z is less than X.

By adopting the technical scheme, for the existing food processor, the rear side of the heat dissipation cavity is close to the air outlet, the left side and the right side of the heat dissipation cavity are close to the air inlet, and the front side of the heat dissipation cavity is far away from the air inlet and the air outlet. Therefore, in the shortest path for the air to flow from the air inlet to the air outlet, the air easily flows through the left, right, and rear sides of the heat dissipation chamber but hardly flows through the front side of the heat dissipation chamber, and thus the heat dissipation efficiency of the left, right, and rear sides of the heat dissipation chamber is higher than that of the front side of the heat dissipation chamber, resulting in difficulty in uniform heat dissipation of the motor. In order to promote the heat dissipation uniformity degree of motor, the height of motor cover is higher. At the moment, the height of the air inlet channel is high, and the retention time of air in the air inlet channel is prolonged, so that the uniform distribution degree of air in the air inlet channel is increased, the air can also flow through the front side of the heat dissipation cavity, and the heat dissipation uniformity degree of the motor is improved. However, the height of the air inlet channel is high, so that the height of the air channel is high, the height of the base is naturally high, the height of the stirring cup is further raised, the center of gravity of the base and the gravity of the stirring cup are raised, the base and the stirring cup are prone to shaking in the machining process, and noise is increased.

In the utility model, Z is less than X, which means that the ratio of the horizontal moving distance to the vertical moving distance of the air in the air duct is higher than that of the vertical moving distance, so that after the vertical moving distance is reduced, the requirement of uniform distribution of the air can be met by increasing the horizontal moving distance, and the uniform heat dissipation degree of the motor is improved. And the vertical migration distance of air in the wind channel reduces, and the height in wind channel reduces promptly, and then the height of frame also can reduce, and correspondingly, the height of stirring cup also can reduce, makes the focus of frame and stirring cup reduce, and frame and stirring cup rock in the reduction course of working to noise reduction produces.

The height of the machine base is limited by the height of the air duct, and the horizontal maximum distance of the machine base is limited by the maximum horizontal moving distance of air in the air duct. The maximum horizontal moving distance of air in the air duct is greater than the height of the air duct, which means that the maximum horizontal distance of the base can be greater than the height of the air duct, and the base is flat. On the basis of the reduction of the height and the center of gravity of the machine base, the occupied area of the machine base is increased, the stability of the machine base is higher, and the shaking of the machine base in the machining process is reduced, so that the noise is reduced.

Meanwhile, the height of the base and the stirring cup is reduced, so that people can conveniently take, place and operate the base and the stirring cup, and the user experience is improved.

The utility model is further configured to: along the air flow direction, the wind channel includes the air-out passageway that is located the motor low reaches, the air-out passageway is located the outside of motor lateral wall.

Through adopting above-mentioned technical scheme, current food preparation machine sets up the air-out passageway in the motor below. At this time, the height of the base is at least the sum of the heights of the motor and the air outlet channel. When the air outlet channel is positioned on the outer side of the side wall of the motor, the lowest height of the base can be the highest height of the motor and the air outlet channel. Therefore, the height of the machine base can be reduced, the height of the stirring cup is further reduced, the shaking of the machine base and the stirring cup in the machining process is reduced, and the noise is reduced.

The utility model is further configured to: the wind channel is including forming in the inside heat dissipation chamber of motor, the heat dissipation chamber is provided with the heat dissipation chamber import that is used for the air admission heat dissipation chamber and is used for the air to leave the heat dissipation chamber export in heat dissipation chamber, the motor is including forming motor up end or lower terminal surface apron wherein at least, heat dissipation chamber import and heat dissipation chamber export all are located the below or the top of apron.

Through adopting above-mentioned technical scheme, at least one is located the side of motor in heat dissipation chamber import and the heat dissipation chamber export, perhaps heat dissipation chamber import and heat dissipation chamber export all are located the up end of motor or terminal surface down to need not to set up the space between apron and the casing and be used for the air current. On the premise of ensuring air heat dissipation, the distance between the motor and the outside is reduced, heat transfer between the motor and the outside is improved, and the heat dissipation effect is enhanced. Meanwhile, the height of the base can be reduced, and the height of the stirring cup can be reduced, so that the center of gravity of the base and the stirring cup is lower, and the stability is higher. In addition, the height of the base and the height of the stirring cup are reduced, so that people can conveniently take, place and operate the base and the stirring cup, and the user experience is improved.

The utility model is further configured to: along the air flow direction, the wind channel is including the inlet air channel that is located the motor upper reaches, the air-out passageway that is located the motor low reaches and be located the heat dissipation chamber between inlet air channel and the air-out passageway, the heat dissipation chamber is provided with the heat dissipation chamber import that is used for the air admission heat dissipation chamber and is used for the air to leave the heat dissipation chamber export in heat dissipation chamber, the horizontal distance of heat dissipation chamber import and heat dissipation chamber export is greater than vertical distance.

The utility model is further configured to: along the air flow direction, the wind channel is including the inlet air channel who is located the motor upper reaches, inlet air channel is including the installation cavity that is used for installing control assembly, control assembly is horizontal.

Through adopting above-mentioned technical scheme, if the control assembly adopted vertical setting, then the height of frame can be subject to the height of control assembly and can't reduce, and then is unfavorable for reducing the height of stirring cup. And the control assembly is horizontal, then the control assembly can not restrict the frame height to the frame can reduce the height after the wind channel height reduces, and then reduces the stirring cup height, and frame and stirring cup rock in the reduction course of working, thereby noise abatement produces.

Drawings

FIG. 1 is a schematic structural view of example 1 of the present invention;

fig. 2 is a schematic structural view of a base part in embodiment 1 of the present invention;

fig. 3 is a schematic structural view of a base in a bottom view according to embodiment 1 of the present invention;

fig. 4 is a schematic structural view of the base of embodiment 1 of the present invention after the air inlet is partially displaced in the bottom direction;

fig. 5 is a schematic structural view of a base part in embodiment 2 of the present invention;

fig. 6 is a schematic structural view of a base part in embodiment 3 of the present invention;

fig. 7 is a schematic structural view of a base part in embodiment 4 of the present invention;

FIG. 8 is an exploded view of example 4 of the present invention;

FIG. 9 is a structural diagram of the base in the bottom view according to embodiment 4 of the present invention;

fig. 10 is a schematic structural view of the base according to embodiment 4 of the present invention after the air inlet is displaced in the bottom direction;

fig. 11 is a schematic structural view of the base according to embodiment 4 of the present invention after deformation of the air outlet channel in the bottom view direction.

FIG. 12 is a schematic structural view of example 5 of the present invention;

FIG. 13 is a schematic structural view of example 6 of the present invention;

FIG. 14 is a schematic structural view of example 7 of the present invention;

fig. 15 is a schematic structural view of embodiment 7 with the bottom cover removed and a portion of the base viewed from below.

Reference numerals: 1. a machine base; 2. a stirring cup; 3. a housing; 4. a motor; 5. a control component; 6. a main body; 7. a base; 8. a top wall; 9. a front side wall; 10. a rear sidewall; 11. a left side wall; 12. a right side wall; 13. an air inlet; 14. an air outlet; 15. an inner motor cover; 16. a motor housing; 17. a stud; 18. a motor cover seal ring; 19. an air outlet channel; 20. a heat dissipation cavity; 21. a communication port; 22. a fan; 23. an air inlet channel; 24. a flow-through hole; 25. a motor shaft; 26. a rotor; 27. a stator; 28. an upper cover plate; 29. a lower cover plate; 30. a heat dissipation channel; 31. a communicating hole; 32. a power panel; 33. a control panel; 34. an air inlet partition plate; 35. an air outlet clapboard; 36. a shaft hole; 37. an inlet of the heat dissipation cavity; 38. an outlet of the heat dissipation cavity; 39. positioning a plate; 40. an upper mounting hole; 41. a placement section; 42. a projection; 43. a through hole; 44. a support plate; 45. a lower mounting hole; 46. a bottom cover; 47. a wind deflector; 48. a side mounting groove; 49. side sound-absorbing cotton; 50. a bottom mounting groove; 51. bottom sound-absorbing cotton.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Example 1

Referring to fig. 1 and 2, a flat food processor includes a housing 1 and a blending cup 2 mounted on the housing 1. The stand 1 comprises a machine shell 3, a motor 4 and a control component 5.

Referring to fig. 2 and 3, the cabinet 3 includes a main body 6 and a base 7 located below the main body 6. The body 6 includes a top wall 8, a front side wall 9, a rear side wall 10, a left side wall 11 and a right side wall 12. The top wall 8 of the main body 6 is used as the upper end of the machine shell 3, the base 7 is used as the lower end of the machine shell 3, the maximum height difference between the top wall 8 of the main body 6 and the base 7, namely the height of the machine shell 3 is H1, and H1 is less than or equal to 100 mm. Preferably, H1=80 mm. The height of the machine base 1 of the existing food processor is about 200mm generally, and the height of the machine base 1 of the present application is equal to the maximum half of the height of the machine base 1 of the existing food processor. Correspondingly, the height of the stirring cup 2 can be reduced, so that the gravity center of the machine base 1 and the gravity center of the stirring cup 2 are reduced, the shaking of the machine base 1 and the stirring cup 2 in the machining process is reduced, and the noise is reduced. Simultaneously, frame 1 and 2 height reductions of stirring cup are also convenient for people to get and put and operate, promote user experience. The projection area of the machine shell 3 in the horizontal plane is S, H1/S is more than or equal to 0.005 and less than or equal to 0.08, and the unit is cm/cm 2. Preferably, H1/S =0.012cm/cm 2. When H1/S is more than 0.08, the projection area of the casing 3 in the horizontal plane is too small, and the floor area of the casing 3 is small. During operation of the food processor, the food processor needs to be placed on a work surface with the housing 3 in direct contact with the work surface. Thus, the supporting surface of the housing 3 is too small, resulting in poor stability of the food processor on the countertop. If H1/S is less than 0.005, the projected area of the housing 3 in the horizontal plane becomes too large, and the footprint of the housing 3 becomes too large, which is disadvantageous for storage. H1/S is more than or equal to 0.005 and less than or equal to 0.08, and the housing 3 can be conveniently stored by a user on the premise of meeting the stability of the food processor placed on the working table. When the stirring cup 2 is arranged on the machine base 1, the total height of the machine base 1 and the stirring cup 2 is H2, H2/S is more than or equal to 0.03 and less than or equal to 0.35, and the unit is cm/cm 2. Preferably, H2/S =0.045cm/cm 2. When H2/S is more than 0.35, the projection area of the machine shell 3 in the horizontal plane is too small, and the floor area of the machine shell 3 is small. During operation of the food processor, the food processor needs to be placed on a work surface with the housing 3 in direct contact with the work surface. Thus, the supporting surface of the housing 3 is too small, resulting in poor stability of the food processor on the countertop. If H2/S is less than 0.03, the projected area of the housing 3 in the horizontal plane becomes too large, and the footprint of the housing 3 becomes too large, which is not favorable for storage. H2/S is more than or equal to 0.03 and less than or equal to 0.35, and the housing 3 can be conveniently stored by a user on the premise of meeting the stability of the food processor placed on the working table. The base 7 is protruded upwards to form steps near the left side wall 11 and the right side wall 12 and is provided with an air inlet 13 at the steps. The air inlet 13 is located at one end of the base 7 close to the front side wall 9, and the rear side wall 10 is provided with an air outlet 14. At this time, the air inlet 13 and the air outlet 14 are respectively located on both sides of a boundary surface passing through the center of gravity of the motor 4 in the vertical direction. The motor 4 is located in an enclosure formed by the shortest projected connecting line of the air inlet 13 and the air outlet 14 in the plane perpendicular to the motor shaft 25. The periphery of the motor 4 is covered by the air inlet 13 and the air outlet 14 as much as possible, so that air can flow through the motor 4 everywhere, and the heat dissipation uniformity of the motor 4 is improved.

Referring to fig. 2, the casing 3 is provided with a motor inner cover 15 wrapping the motor 4 and a motor outer cover 16 surrounding the motor inner cover 15. When outwards propagating from the periphery of the motor 4, the noise generated by the motor 4 is sequentially blocked by the motor inner cover 15 and the motor outer cover 16, so that the noise propagation generated by the motor 4 is greatly reduced, and the effect of reducing the noise is achieved. A stud 17 extends downwards from the top wall 8 of the main body 6, and a motor inner cover 15 is hung on the top wall 8 of the main body 6 through the matching of screws and the stud 17 and clamps the motor 4 with the top wall 8 of the main body 6. The lower end of the motor inner cover 15 is positioned above the lower end of the motor outer cover 16, and a motor cover sealing ring 18 is abutted between the lower end of the motor inner cover 15 and the lower end of the motor outer cover 16 in an interference fit manner. The upper end of the motor outer cover 16 is fixedly connected with the top wall 8 of the main body 6, so that an air outlet channel 19 is defined by the motor outer cover 16, the motor inner cover 15 and the top wall 8 of the main body 6. The motor inner cover 15 encloses a heat dissipation cavity 20, and a gap exists between the upper end of the motor inner cover 15 and the inner side of the top wall 8 of the main body 6, so that the heat dissipation cavity 20 is communicated with the air outlet channel 19. At this time, the air outlet channel 19 is located outside the side wall of the motor 4 and surrounds the side wall of the motor 4. The existing food processor arranges the air outlet channel 19 below the motor 4. At this time, the height of the base 1 is at least the sum of the respective heights of the motor 4 and the air outlet channel 19. When the air outlet channel 19 is disposed around the side wall of the motor 4, the lowest height of the base 1 may be the highest height of the motor 4 and the air outlet channel 19. Therefore, the height of the machine base 1 is reduced, the height of the stirring cup 2 is further reduced, and the shaking of the machine base 1 and the stirring cup 2 in the machining process is reduced, so that the noise is reduced. The motor 4 is a major source of noise for the food processor. The noise generated by the motor 4 is blocked by the stirring cup 2 when propagating upwards and is blocked by the worktable when propagating downwards, so that the noise generated by the motor 4 is mainly propagated outwards from the periphery of the motor 4. In the existing food processor, the air outlet channel 19 is located below the motor 4, and the air outlet channel 19 cannot block the noise generated by the motor 4 from spreading around the motor 4. When air-out passageway 19 encircles the lateral wall of motor 4, the noise that motor 4 produced can receive air-out passageway 19 to block when outwards propagating around motor 4 to reduce the noise propagation that motor 4 produced, play the effect of noise reduction. Simultaneously, the height reduction of frame 1 and stirring cup 2 is also convenient for people to get and put and operate, promotes user experience. The motor housing 16 is provided with a communication opening 21 aligned with the outlet opening 14, thereby communicating the outlet air passage 19 with the outlet opening 14. A fan 22 is provided at the communication port 21 to drive air out of the housing 3 from the outlet port 14.

Referring to fig. 2, the motor inner cover 15, the motor outer cover 16, the main body 6 and the base 7 enclose an air inlet passage 23, so that the air inlet passage 23 surrounds the air outlet passage 19. If the air inlet channel 23 is located below the motor 4 and/or below the air outlet channel 19, the height of the base 1 is at least the sum of the heights of the motor 4 and the air inlet channel 23 or the sum of the heights of the air inlet channel 23 and the air outlet channel 19. And the air inlet channel 23 surrounds the air outlet channel 19, then the air inlet channel 23, the motor 4 and the air outlet channel 19 are in a transverse distribution form. At this time, the lowest height of the base 1 may be the highest height among the air inlet channel 23, the motor 4 and the air outlet channel 19. Therefore, the height of the machine base 1 is reduced, the height of the stirring cup 2 is further reduced, and the shaking of the machine base 1 and the stirring cup 2 in the machining process is reduced, so that the noise is reduced. And the air inlet 13 is formed in the base 7 so that the air inlet passage 23 communicates with the air inlet 13. The heat dissipation chamber 20 comprises a heat dissipation chamber inlet 37 for air entering the heat dissipation chamber 20 and a heat dissipation chamber outlet 38 for air leaving the heat dissipation chamber 20. The lower end of the motor inner cover 15 is formed with a circulation hole 24 as a heat radiation chamber inlet 37 so that the air intake passage 23 communicates with the heat radiation chamber 20. The horizontal distance between the air inlet 13 and the heat dissipation chamber inlet 37 is greater than the vertical distance. With prior food processors, the air flows from the intake vent 13 to the heat dissipation chamber inlet 37 in a longitudinal direction. And the horizontal distance of air intake 13 and heat dissipation chamber import 37 is greater than vertical distance, then means that the air flows to the whole horizontal extension that is of the in-process of heat dissipation chamber import 37 from air intake 13 to can reduce the wind channel height, correspondingly, frame 1 height also can reduce, and then reduces stirring cup 2's height, makes the focus of frame 1 and stirring cup 2 reduce, reduces frame 1 and stirring cup 2 and rocks in the course of working, thereby noise abatement produces. The motor 4 includes a motor shaft 25, a rotor 26 wrapping the motor shaft 25, a stator 27 wrapping the rotor 26, and an upper cover plate 28 and a lower cover plate 29 respectively located above and below the stator 27. A fan 22 sleeved with the motor shaft 25 is arranged between the upper cover plate 28 and the rotor 26. The maximum height difference between the upper cover plate 28 and the lower cover plate 29 is taken as the height D of the motor 4. A gap exists between the lower cover plate 29 and the motor inner cover 15, and a gap exists between the upper cover plate 28 and the top wall 8 of the main body 6. A plurality of heat dissipation channels 30 are formed between the stator 27 and the rotor 26. The upper cover plate 28 and the lower cover plate 29 are also provided with a plurality of communication holes 31 communicating with the heat dissipation channel 30, wherein the communication holes 31 of the upper cover plate 28 serve as heat dissipation chamber outlets 38. In the horizontal direction, the plurality of heat dissipation passages 30 surround the flow hole 24, and the plurality of communication holes 31 also surround the flow hole 24. If the projection of the heat dissipation channel 30 in the horizontal plane is only located on one side of the heat dissipation chamber inlet 37, the projection of the heat dissipation channel 30 in the horizontal plane has a portion close to the heat dissipation chamber inlet 37 and a portion far from the heat dissipation chamber inlet 37. The heat dissipation channel 30 corresponding to the portion of the projection of the heat dissipation channel 30 in the horizontal plane close to the heat dissipation cavity inlet 37 is relatively easy to intake air, and the heat dissipation channel 30 corresponding to the portion close to the heat dissipation cavity outlet 38 is relatively difficult to intake air, so that the impact of air on each portion of the heat dissipation channel 30 is different, the motor 4 is easy to shake under the impact of air, and the noise is increased. Meanwhile, the heat dissipation efficiency of the heat dissipation channel 30 corresponding to the portion of the projection of the heat dissipation channel 30 in the horizontal plane close to the heat dissipation chamber inlet 37 is higher, and the heat dissipation efficiency of the heat dissipation channel 30 corresponding to the portion close to the heat dissipation chamber outlet 38 is lower, so that the heat dissipation efficiency of each portion of the heat dissipation channel 30 is not uniform enough. The projection of the heat dissipation channel 30 in the horizontal plane surrounds the heat dissipation cavity inlet 37, so that air can uniformly enter the heat dissipation channel 30 from the heat dissipation cavity inlet 37, the impact of the air on each part of the heat dissipation channel 30 can be uniformly applied, the shaking of the motor 4 is reduced, the noise is reduced, and the heat dissipation efficiency of each part of the heat dissipation channel 30 is uniform. The motor outer cover 16 and the motor inner cover 15 play a role of a partition plate to prevent the air inlet channel 23 from being directly communicated with the air outlet channel 19. The air inlet 13, the air inlet channel 23, the heat dissipation cavity 20, the air outlet channel 19 and the air outlet 14 form a complete air duct. When air flows in the air inlet channel 23 and the air outlet channel 19, the whole air flow direction is along the length direction of the machine shell 3, so that the air flow direction in the air inlet channel 23 and the air flow direction in the air outlet channel 19 are the same. Compare in current food preparation machine's air inlet channel 23 longitudinal extension, set air inlet channel 23 to horizontal extension to can reduce the wind channel height, it is corresponding, the frame 1 height also can reduce, and then reduces stirring cup 2 height, makes the focus of frame 1 and stirring cup 2 reduce, and frame 1 rocks with stirring cup 2 in the reduction course of working, thereby noise abatement produces. Simultaneously, frame 1 and 2 height reductions of stirring cup are also convenient for people to get and put and operate, promote user experience.

Referring to fig. 2, an included angle between a connecting line of a midpoint of the air inlet 13 and the motor shaft 25 of the motor 4 and a connecting line of a midpoint of the air outlet 14 and the motor shaft 25 of the motor 4 is α, and α is greater than or equal to 90 ° and less than or equal to 180 °. Preferably, α =135 °. After entering the housing 3 from the air inlet 13, the air flows through the motor 4 and is discharged from the air outlet 14. Alpha is more than or equal to 90 degrees and less than or equal to 180 degrees, so that the whole flowing directions of the air from the air inlet 13 to the motor 4 and the air from the motor 4 to the air outlet 14 are the same. Compared with the situation that the overall flowing direction of the air from the air inlet 13 to the motor 4 and from the motor 4 to the air outlet 14 is opposite, when the overall flowing direction of the air from the air inlet 13 to the motor 4 and from the motor 4 to the air outlet 14 is the same, the occupied area of the engine base 1 is increased, the stability of the engine base 1 is higher, and then the engine base 1 is shaken in the process of machining is reduced, so that the noise is reduced. The distance between the projection of the midpoint of the air inlet 13 in the horizontal direction and the projection of the motor shaft 25 of the motor 4 in the horizontal direction is X1, the distance between the projection of the midpoint of the air outlet 14 in the horizontal direction and the projection of the motor shaft 25 of the motor 4 in the horizontal direction is X2, and the sum of X1 and X2 is X. The height difference between the highest point and the lowest point of the air duct, namely the height of the air duct is Z. Wherein, Z/X is more than or equal to 0.1 and less than or equal to 0.4. In this embodiment, the lowest point of the air duct is located between the base 7 and the inner motor cover 15, and the highest point of the air duct is located between the upper cover plate 28 and the top wall 8 of the main body 6. The height Z =78mm of the wind tunnel, whereas X =200mm, Z/X = 0.39. For existing food processors, the rear side of the heat dissipation chamber 20 is close to the air outlet 14, the left and right sides of the heat dissipation chamber 20 are close to the air inlet 13, and the front side of the heat dissipation chamber 20 is far from the air inlet 13 and the air outlet 14. Therefore, in the shortest path in which the air flows from the air inlet 13 to the air outlet 14, the air easily flows through the left, right, and rear sides of the heat dissipation chamber 20 but hardly flows through the front side of the heat dissipation chamber 20, and thus the heat dissipation efficiency of the left, right, and rear sides of the heat dissipation chamber 20 is higher than that of the front side of the heat dissipation chamber 20, resulting in difficulty in uniformly dissipating the heat of the motor 4. In order to improve the heat dissipation uniformity of the motor 4, the height of the motor 4 cover is higher. At this moment, the height of the air inlet channel 23 is higher, and the staying time of the air in the air inlet channel 23 is prolonged, so that the uniform distribution degree of the air in the air inlet channel 23 is increased, the air can also flow through the front side of the heat dissipation cavity 20, and the heat dissipation uniformity degree of the motor 4 is improved. However, the height of the air inlet channel 23 is high, so that the height of the air duct is high, the height of the base 1 is naturally high, the height of the stirring cup 2 is raised, the gravity center of the base 1 and the gravity center of the stirring cup 2 are raised, the base 1 and the stirring cup 2 are easy to shake in the machining process, and noise is increased. And in this application, Z < X, means that the horizontal migration distance of air in the wind channel compares than vertical migration distance to after reducing vertical migration distance, can rely on the horizontal migration distance to increase in order to compensate air evenly distributed's demand, thereby promote motor 4's the even degree of heat dissipation. And the vertical migration distance of air in the wind channel reduces, and the height in wind channel reduces promptly, and then the height of frame 1 also can reduce, and correspondingly, the height of stirring cup 2 also can reduce, makes the focus of frame 1 and stirring cup 2 reduce, and frame 1 and stirring cup 2 rock in the reduction course of working to the noise reduction produces. The height of the machine base 1 is limited by the height of the air duct, and the horizontal maximum distance of the machine base 1 is limited by the maximum horizontal moving distance of air in the air duct. The maximum horizontal moving distance of air in the air duct is greater than the height of the air duct, which means that the maximum horizontal distance of the machine base 1 can be greater than the height of the air duct, and the whole machine base 1 is flattened. On the basis of the height reduction of the machine base 1 and the reduction of the gravity center, the occupied area of the machine base 1 is increased, the stability of the machine base 1 is higher, and the shaking of the machine base 1 in the machining process is further reduced, so that the noise is reduced. Simultaneously, the height reduction of frame 1 and stirring cup 2 is also convenient for people to get and put and operate, promotes user experience. Z/X < 0.1 means that Z is too small. Air generally flows through the motor 4 in the axial direction of the motor 4, so that Z is too small, meaning that the area through which air flows through the motor 4 is small, which is disadvantageous for dissipating heat from the motor 4. Z/X > 0.4, then mean Z too big, the height of frame 1 is limited by the height of wind channel and is difficult to reduce to be unfavorable for reducing the height of frame 1, and then be unfavorable for reducing the height of stirring cup 2, be unfavorable for reducing frame 1 and stirring cup 2 and rock in the course of working, thus be unfavorable for noise abatement to produce. Therefore, Z/X is more than or equal to 0.1 and less than or equal to 0.4, air can flow through the motor 4 as much as possible, heat dissipation of the motor 4 is enhanced, the height of the base 1 can be reduced, and noise is reduced. The height Z of the air duct and the height H1 of the machine shell 3 meet the condition that Z/H1 is more than or equal to 0.4 and less than 1, and preferably, Z/H1= 0.975. If Z/H1 is less than 0.4, H1 is too large. Z/H1 < 0.4 means that Z is too small. Air generally flows through the motor 4 in the axial direction of the motor 4, so that Z is too small, meaning that the area through which air flows through the motor 4 is small, which is disadvantageous for dissipating heat from the motor 4. Therefore, Z/H1 is more than or equal to 0.4 and less than 1, air flows through the motor 4 as much as possible, and heat dissipation of the motor 4 is enhanced. The air outlet channel 19 is located within the height range of the motor 4. The lowest height of the stand 1 can be the height of the motor 4, so that the height of the stand 1 is prevented from being influenced by the air outlet channel 19. Therefore, the height of the machine base 1 is reduced, the height of the stirring cup 2 is further reduced, and the shaking of the machine base 1 and the stirring cup 2 in the machining process is reduced, so that the noise is reduced. The height h of the longitudinal overlapping part of the air outlet channel 19 and the motor 4 and the height D of the motor 4 meet h/D =0.1-1: 1. Preferably, h/D = 0.9. At this time, the air outlet channel 19 is located within the height range of the motor 4, so the height of the longitudinally overlapped portion of the air outlet channel 19 and the motor 4 is the height of the air outlet channel 19. h/D is less than 0.1, the height of the longitudinal overlapped part of the air outlet channel 19 and the motor 4 is too small, namely the height of the air outlet channel 19 is too small, so that the flowing resistance of air in the air outlet channel 19 is large, the power of the fan 22 needs to be increased, and the noise is not reduced. Therefore, h/D =0.1-1:1, which not only prevents the air from flowing too much in the air outlet channel 19, but also reduces the height of the machine base 1, further reduces the height of the stirring cup 2, and reduces the shaking of the machine base 1 and the stirring cup 2 in the processing process, thereby reducing the noise. The height Z of the air duct and the height D of the motor 4 meet the requirement that D/Z is more than or equal to 0.6 and less than or equal to 2.5. Preferably, D/Z = 0.641. Regarding the height D of the motor 4, regardless of the motor shaft 25 as a part of the motor 4, if the fan 22 is sleeved on the motor shaft 25 and rotated by the motor shaft 25, the fan 22 is measured as a part of the motor 4. If the fan 22 is sleeved on the motor shaft 25 and rotated by the motor shaft 25, the fan 22 is measured as a part of the motor 4. If D/Z is greater than 2.5, D is too large. Under the less prerequisite in height in wind channel, motor 4's height is still great, then the height of frame 1 also can be great, and stirring cup 2's height is still great, leads to the focus of frame 1 and stirring cup 2 still higher, and frame 1 and stirring cup 2 rock still great in the course of working, lead to producing more noise. If D/Z is less than 0.6, D is too small, and the corresponding torque of the motor 4 is small, so that a good crushing effect cannot be achieved. D/Z is more than or equal to 0.6 and less than or equal to 2.5, so that the height of the machine base 1 and the height of the stirring cup 2 can be reduced on the premise that the height of the air channel is smaller, the shaking of the machine base 1 and the stirring cup 2 in the machining process is reduced, the noise is reduced, and the requirement on the torque of the motor 4 can be met.

Referring to fig. 2, the control assembly 5 is disposed in the air inlet channel 23 and functions to control the operation of the control motor 4. The control assembly 5 includes a power board 32 and a control board 33 located above the power board 32. The power panel 32 and the control panel 33 are disposed transversely and above the air inlet 13. If the power board 32 and the control board 33 are disposed vertically, the height of the base 1 is limited by the height of the control assembly 5 and cannot be lowered, which is not favorable for lowering the height of the mixing cup 2. And control assembly 5 is horizontal, then control assembly 5 can not restrict frame 1 height to frame 1 can reduce the height after the wind channel height reduces, and then reduces stirring cup 2 height, and frame 1 rocks with stirring cup 2 in the reduction course of working, thereby noise abatement produces.

Referring to fig. 4, it is understood that the air inlet 13 may not be located at the end of the base 7 near the front side wall 9, but directly below the motor inner cover 15 and the motor outer cover 16. At this time, the air inlet 13 and the air outlet 14 are still located on both sides of the interface passing through the center of gravity of the motor 4 in the vertical direction, respectively. The motor 4 is still located in the enclosure formed by the shortest projected connecting line of the air inlet 13 and the air outlet 14 in the plane perpendicular to the motor shaft 25.

It will be appreciated that when the control unit 5 is no longer located in the housing 3, the overall size of the housing 3 is close to that of the motor 4. The height of the housing 3 is H1, and the projected area of the housing 3 on the horizontal plane is S. Preferably, H1/S =0.08 cm/cm 2. When the stirring cup 2 is mounted on the machine base 1, the total height of the machine base 1 and the stirring cup 2 is H2, preferably H2/S =0.3cm/cm 2.

Example 2

Embodiment 2 is different from embodiment 1 in the distribution of the air outlet channel 19 and the motor 4.

Referring to fig. 5, in embodiment 2, the motor inner cover 15 and the motor outer cover 16 are eliminated, and the motor 4 is hung on the top wall 8 of the main body 6 by screws matched with screw posts on the top wall 8 of the main body 6. Two opposite side surfaces of the motor 4 are respectively provided with an air inlet partition plate 34 and an air outlet partition plate 35. The air inlet partition 34 has an upper end in sealing abutment with the motor 4 and a lower end extending downward to sealing abutment with the base 7, and both sides are in sealing abutment with the left side wall 11 and the right side wall 12 of the main body 6 respectively. Air-out baffle 35 lower extreme and the sealed butt of motor 4, the upper end upwards extend to with the 8 sealed butts of roof of main part 6, both sides respectively with the left side wall 11 and the sealed butt of right side wall 12 of main part 6. The side that motor 4 and air inlet baffle 34 and air-out baffle 35 butt all with the sealed butt of main part 6.

At this time, one side of the air inlet partition 34 and the air outlet partition 35, the main body 6 and the base 7 enclose an air inlet channel 23, the other side, the main body 6 and the base 7 enclose an air outlet channel 19, and the inside of the motor 4 forms a heat dissipation cavity 20. At this time, the air inlet channel 23 and the air outlet channel 19 are located at both sides of the motor 4. The communication hole 31 of the lower cover plate 29 is a heat radiation chamber inlet 37, and the communication hole 31 of the upper cover plate 28 is a heat radiation chamber outlet 38. If the air inlet channel 23 is located below the motor 4 and/or below the air outlet channel 19, the height of the base 1 is at least the sum of the heights of the motor 4 and the air inlet channel 23 or the sum of the heights of the air inlet channel 23 and the air outlet channel 19. And the air inlet channel 23 and the air outlet channel 19 are positioned at two sides of the motor 4, and the air inlet channel 23, the motor 4 and the air outlet channel 19 are in a transverse distribution form. At this time, the lowest height of the base 1 may be the highest height among the air inlet channel 23, the motor 4 and the air outlet channel 19. Therefore, the height of the machine base 1 is reduced, the height of the stirring cup 2 is further reduced, and the shaking of the machine base 1 and the stirring cup 2 in the machining process is reduced, so that the noise is reduced.

Example 3

Embodiment 3 differs from embodiment 1 in that the heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38 are distributed differently from the motor 4.

Referring to fig. 6, in embodiment 3, the motor inner cover 15 and the motor outer cover 16 are eliminated, and the motor 4 is hung on the top wall 8 of the main body 6 by screws matched with screw posts on the top wall 8 of the main body 6. The opposite two sides of the motor 4 are respectively provided with an air inlet clapboard 34 and an air outlet clapboard 35. The periphery of the air inlet partition plate 34 is in sealing butt joint with the casing 3, and the periphery of the air outlet partition plate 35 is in sealing butt joint with the casing 3. The air inlet partition 34 is provided with a circulation hole 24 aligned with the side of the motor 4, and the air outlet partition 35 is provided with a circulation hole 24 aligned with the side. The areas of the circulation holes 24 of the air inlet partition plate 34 and the air outlet partition plate 35 are not more than the area of the side surface of the motor 4.

At this time, a heat dissipation cavity 20 is enclosed between the air inlet partition plate 34, the air outlet partition plate 35 and the casing 3, an air inlet channel 23 is enclosed by one side of the air inlet partition plate 34 departing from the motor 4 and the casing 3, and an air outlet channel 19 is enclosed by one side of the air outlet partition plate 35 departing from the motor 4 and the casing 3. The circulation hole 24 of the air inlet partition plate 34 forms a heat dissipation chamber inlet 37, and the circulation hole 24 of the air outlet partition plate 35 forms a heat dissipation chamber outlet 38. At this time, the heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38 are located at both sides of the motor 4, and the horizontal distance between the heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38 is greater than the vertical distance. Under the action of the fan 22 at the air outlet 14, the air flows through the air inlet 13, the air inlet channel 23, the heat dissipation cavity 20, the air outlet channel 19 and the air outlet 14 in sequence.

Example 4

Embodiment 4 differs from embodiment 1 in that the structure of the motor 4, the position of the fan 22, and the distribution of the air inlet channel 23 and the air outlet channel 19 are different.

Referring to fig. 7, in embodiment 4, motor 4 includes motor shaft 25, rotor 26 wrapping motor shaft 25, stator 27 wrapping rotor 26, upper cover plate 28 and lower cover plate 29 respectively located above and below stator 27. The upper cover plate 28 is centrally provided with a shaft hole 36, and the upper end of the motor shaft 25 is protruded from the shaft hole 36. The upper cover plate 28 covers the upper ends of the stator 27 and the rotor 26, and the lower cover plate 29 covers the lower ends of the stator 27 and the rotor 26. The lower end of the motor shaft 25 is fixedly sleeved with the fan 22 positioned above the lower cover plate 29. The motor 4 is internally provided with a heat dissipation chamber 20, and the heat dissipation chamber 20 passes between the stator 27 and the rotor 26. An inlet 37 of the heat dissipation chamber is formed between the upper cover plate 28 and the stator 27, and an outlet 38 of the heat dissipation chamber is formed between the lower cover plate 29 and the stator 27. The heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38 are formed by the gap between the stator 27 and the upper and lower cover plates 28 and 29, thereby increasing the contact area of air with the stator 27, and thus enhancing the heat dissipation effect. The heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38 are located between the upper cover plate 28 and the lower cover plate 29 of the motor 4, so that there is no need to provide a gap for air flow between the upper cover plate 28 and the casing 3 and between the lower cover plate 29 and the casing 3. On the premise of ensuring air heat dissipation, the distance between the motor 4 and the outside is reduced, heat transfer between the motor 4 and the outside is improved, and the heat dissipation effect is enhanced. Meanwhile, the height of the machine base 1 is reduced, and the height of the stirring cup 2 is also reduced, so that the gravity center of the machine base 1 and the gravity center of the stirring cup 2 are lower, and the stability is higher. If heat dissipation chamber export 38 is located 8 roof or diapire of motor 4, and air-out passageway 19 is connected with heat dissipation chamber export 38 again, thereby lead to leading to unavoidably to have some air-out passageway 19 to be located the top or the below of motor 4, thereby make the height of frame 1 can only reach the sum of the height separately of some air-out passageway 19 and the motor 4 that are located the top or the below of motor 4 at least, thereby be unfavorable for reducing the height of frame 1, and then be unfavorable for reducing the height of stirring cup 2, be unfavorable for reducing in the course of working frame 1 and the rocking of stirring cup 2, thereby be unfavorable for noise abatement to produce. In addition, frame 1 and 2 height reductions of stirring cup are also convenient for people to get and put and operate, promote user experience. At this time, the heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38 are longitudinally displaced. If the cooling chamber inlet 37 and the cooling chamber outlet 38 are in longitudinal alignment, it is assumed that the cooling chamber inlet 37 and the cooling chamber outlet 38 are both located between the stator 27 and the upper cover plate 28. If no partition is provided between the heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38, the heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38 are in a direct communication state, and air less enters the heat dissipation channel 30, and naturally, the winding inside the motor 4 cannot be sufficiently dissipated. If a partition is provided between the heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38 to prevent the heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38 from being directly communicated, the air can dissipate heat of the winding inside the motor 4 through the heat dissipation channel 30. However, only a part of the space between the stator 27 and the upper cover plate 28 is used for air intake, and the other part of the space is used for air exhaust, so that the heat dissipation effect is poor. The heat dissipation cavity inlet 37 and the heat dissipation cavity outlet 38 are longitudinally staggered, so that air can fully enter the heat dissipation channel 30 to dissipate heat of the winding inside the motor 4, the air inlet space and the air outlet space can be fully utilized, and the heat dissipation effect is enhanced.

The height of the machine shell 3 is H1, H1 is less than or equal to 100mm, and the preferred H1=50 mm. The projection area S of the shell 3 on the horizontal plane is more than or equal to 0.005 and less than or equal to H1/S and less than or equal to 0.08, and the unit is cm/cm 2. Preferably, H1/S =0.007cm/cm 2. When the stirring cup 2 is arranged on the machine base 1, the total height of the machine base 1 and the stirring cup 2 is H2, H2/S is more than or equal to 0.03 and less than or equal to 0.35, and the unit is cm/cm 2. Preferably, H2/S =0.041cm/cm 2. The maximum height difference between the heat dissipation cavity inlet 37 and the heat dissipation cavity outlet 38 is d, and d/H1 is more than or equal to 0.2 and less than 1. Preferably, d/H1= 0.4. The height of the air duct is Z, and d/Z is more than or equal to 0.5 and less than or equal to 1. Preferably, d/Z = 0.6. The maximum height difference between the upper cover plate 28 and the lower cover plate 29, namely the height of the motor 4 is D, and D/D is more than or equal to 0.4 and less than 1. Preferably, D/D = 0.6. The height h of the longitudinal overlapping part of the air outlet channel 19 and the motor 4 and the height D of the motor 4 meet h/D =0.1-1: 1. Preferably, h/D = 0.3. The stator 27 is wrapped by a positioning plate 39, the lower cover plate 29 is fixedly connected with the positioning plate 39, and the upper cover plate 28 is fixedly connected with the positioning plate 39. The outer diameter of the positioning plate 39 is larger than that of the lower cover plate 29.

Referring to fig. 7 and 8, the top wall 8 of the main body 6 is provided with an upper mounting hole 40, and the upper cover plate 28 is in sealing abutment with the top wall 8 of the main body 6 at the edge portion of the mounting hole. At this time, the upper cover plate 28 is exposed from the housing 3 and is in direct contact with the outside. Compared with the upper cover plate 28 and the lower cover plate 29 which are positioned in the casing 3, the upper cover plate 28 is exposed out of the casing 3, and the upper cover plate 28 exposed out of the casing 3 can also be a heat dissipation path of the motor 4, so that the heat dissipation of the motor 4 is accelerated, and the heat dissipation effect is enhanced. Preferably, the edge of upper cover plate 28 forms a step, and the top wall 8 of main body 6 at the edge of the mounting hole is just caught at the step of upper cover plate 28, so that the upper surface of upper cover plate 28 and the upper surface of top wall 8 of main body 6 form a flat surface.

Referring to fig. 7, 8 and 9, the pedestal 7 includes a placing portion 41 contacting the table top and a projection 42 projecting upward. The placing portion 41 surrounds the front, left and right sides of the projection 42. The upper end of the projection 42 is formed with a through hole 43. The portion of the motor 4 below the positioning plate 39 passes through the through hole 43 to bring the positioning plate 39 into sealing abutment with the boss 42. The side of the protruding portion 42 away from the placing portion 41 is provided with a downward extending flange provided with the air outlet 14. The side of the flange far away from the bulge 42 is integrally connected with a supporting plate 44 which is in sealing contact with the lower part of the lower cover plate 29. The support plate 44 is centrally provided with a lower mounting hole 45. Preferably, the edge of the lower cover plate 29 forms a step, and the edge of the support plate 44 located at the lower mounting hole 45 is partially and exactly clamped at the step of the lower cover plate 29, so that the lower cover plate 29 is exposed out of the casing 3, and the lower surface of the lower cover plate 29 and the lower surface of the support plate 44 form a flat surface. Compared with the upper cover plate 28 and the lower cover plate 29 which are positioned in the casing 3, the lower cover plate 29 is exposed out of the casing 3, and the lower cover plate 29 exposed out of the casing 3 can also be a heat dissipation path of the motor 4, so that the heat dissipation of the motor 4 is accelerated, and the heat dissipation effect is enhanced. The main body 6 and the base 7 enclose the air inlet channel 23, and the portion of the motor 4 above the positioning plate 39 is located between the top wall 8 of the main body 6 and the protrusion 42, so that the heat dissipation chamber inlet 37 is communicated with the air inlet channel 23. An air outlet channel 19 is formed between the flanging and the heat dissipation cavity outlet 38, and the part of the motor 4 below the positioning plate 39 is positioned in the air outlet channel 19. Therefore, the heat dissipation chamber outlet 38 communicates with the air outlet passage 19. The positioning plate 39 is in sealing abutment with the protruding portion 42, so that the positioning plate 39 and the protruding portion 42 form a partition function for partitioning the air inlet channel 23 and the air outlet channel 19.

Since the front, left and right sides of the convex portion 42 are surrounded by the placing portion 41, the exhaust resistance of the heat dissipation chamber outlet 38 is large. The rear heat dissipation chamber outlet 38 is not restricted by the placement portion 41, so that the rear heat dissipation chamber outlet 38 dominates. Therefore, the front, left, and right heat dissipation chamber outlets 38 may be eliminated, leaving only the rear heat dissipation chamber outlet 38. When the heat dissipation chamber outlets 38 on the front, left and right sides are not provided, the flanges and the support plate 44 may be eliminated, and a plurality of ribs may be formed between the rear side of the lower cover plate 29 and the rear side of the stator 27. And a heat dissipation cavity outlet 38 at the rear side is formed between two adjacent blocking ribs. At this time, the rear-side heat dissipation chamber outlet 38 is completely exposed. An air outlet channel 19 is defined by the placing part 41, the protruding part 42 and the working table, an air outlet 14 is formed at the mouth of the air outlet channel 19, and the heat dissipation cavity outlet 38 at the rear side is just located at the air outlet 14. If the outlet 38 of the heat dissipation chamber is located in the housing 3, the air needs to flow from the air inlet 13 of the housing 3 to the inlet 37 of the heat dissipation chamber and from the outlet 38 of the heat dissipation chamber to the air outlet 14 of the housing 3. During the air flow, heat transfer occurs continuously. When the air flows from the outlet 38 to the outlet 14 of the housing 3, the heat of the air is high, and heat transfer occurs inside the housing 3, so that a part of the heat is retained inside the housing 3 and is not discharged out of the housing 3 along with the air, and the heat dissipation effect is poor. Meanwhile, the air needs to flow from the heat dissipation chamber outlet 38 to the air outlet 14 of the housing 3, so that the flow path of the air in the housing 3 is extended, and the kinetic energy of the air is lost, at this time, more energy needs to be provided to overcome the kinetic energy loss increased by the extension of the air flow path, and more energy provided to the air also generates more heat, thereby reducing the heat dissipation effect. The heat dissipation cavity outlet 38 is exposed in the casing 3, so that heat can be taken out of the casing 3 by air as much as possible, the heat is reduced and left in the casing 3, and meanwhile, the air flow path is shortened, so that the requirement on air kinetic energy is reduced, the heat dissipation effect can be enhanced, and the effect of reducing energy consumption can be achieved. If the outlet channel 19 of the food processor is located in the housing 3, the air will be continuously subjected to heat transfer during the air flow. When air enters the air outlet channel 19, the heat of the air is high, and heat transfer occurs inside the casing 3, so that part of the heat is left inside the casing 3 and is not discharged out of the casing 3 along with the air, and the heat dissipation effect is poor. Meanwhile, the flow path of the air in the housing 3 is extended, so that the kinetic energy of the air is lost, and at this time, more energy needs to be provided to overcome the loss of the kinetic energy increased by the extension of the air flow path, and more energy provided to the air also generates more heat, thereby reducing the heat dissipation effect. The air outlet channel 19 is located outside the casing 3, so that heat can be taken out of the casing 3 by air as far as possible, the heat is reduced and left inside the casing 3, and meanwhile, the air flow path is shortened, so that the requirement on air performance is reduced, the heat dissipation effect can be enhanced, the effect of reducing energy consumption can be achieved, parts required by the air outlet channel 19 in the casing 3 can be reduced, and the production cost is reduced.

Referring to fig. 8 and 9, two air intakes 13 are respectively provided at left and right sides of the placing portion 41, and half of the two air intakes 13 are respectively located at left and right portions of the placing portion 41 surrounding the protruding portion 42. At this time, the air intake passage 23 communicates with the air intake opening 13, but the air intake opening 13 and the rear heat dissipation chamber outlet 38 are still located on both sides of the interface passing through the center of gravity of the motor 4. The motor 4 is located in an enclosure surrounded by the shortest projection connecting line of the air inlet 13 and the air outlet 14 in the plane perpendicular to the motor shaft 25.

At this time, the air inlet 13, the air inlet channel 23, the heat dissipation cavity 20, the air outlet channel 19, and the air outlet 14 form a complete air duct.

It will be appreciated that a cooling chamber outlet 38 may also be formed between the upper cover plate 28 and the stator 27, and a cooling chamber inlet 37 formed between the corresponding lower cover plate 29 and the stator 27.

It will be appreciated that the top wall 8 of the body 6 may also be provided without the upper mounting hole 40, but directly abut the upper cover plate 28. Compared with the case that the upper cover plate 28 is positioned in the case 3 and a gap is arranged between the upper cover plate 28 and the case 3, the upper cover plate 28 is abutted to the case 3, and the upper cover plate 28 abutted to the case 3 can also be a heat dissipation way of the motor 4, so that the heat dissipation of the motor 4 is accelerated.

Referring to fig. 10, it is understood that the air inlet 13 may be located at one end of the placing portion 41 near the front side wall 9. At this time, X =200mm, the lowest point of the air duct is the heat dissipation chamber outlet 38, and the highest point of the air duct is the heat dissipation chamber inlet 37. The height difference between the highest point and the lowest point of the air duct is Z. At this time, Z =48 mm. At this time, Z < X and Z/X = 0.24. Z and D satisfy the condition that D/Z is more than or equal to 0.6 and less than or equal to 2.5. Preferably, D/Z = 1.04. The heights H1 and Z of the machine shell 3 meet the condition that Z/H1 is more than or equal to 0.4 and less than 1. Preferably, Z/H1= 0.96. An included angle between a connecting line of the midpoint of the air inlet 13 and the motor shaft 25 of the motor 4 and a connecting line of the midpoint of the air outlet 14 and the motor shaft 25 of the motor 4 is alpha, and alpha is more than or equal to 90 degrees and less than or equal to 180 degrees. Preferably, α =135 °.

Referring to fig. 11, it will be appreciated that the flanges and brackets 44 may be eliminated and a plurality of ribs may be formed between the lower cover plate 29 and the stator 27. And a heat dissipation cavity outlet 38 is formed between two adjacent blocking ribs. Meanwhile, the projecting portion 42 may be extended forward to penetrate the placing portion 41 such that the placing portion 41 surrounds only the left and right sides of the projecting portion 42. At this time, the heat dissipation chamber outlet 38 is completely exposed, and the air inlet channel 23 is located above the air outlet channel 19. At this time, when the food processor is placed on the working table, the placing portion 41, the protruding portion 42 and the working table define an air outlet channel 19, and the mouth portions at the two ends of the air outlet channel 19 form the air outlet 14. And the part of the motor 4 below the positioning plate 39 is located in the air outlet channel 19, so that the heat dissipation cavity outlet 38 is communicated with the air outlet channel 19.

Example 5

The difference between embodiment 5 and embodiment 4 is that the air inlet 13 and the air outlet 14 are distributed differently with respect to the motor 4.

Referring to fig. 12, in embodiment 5, the air intake vents 13 located on the left side of the placing portion 41 extend rearward to be aligned with the heat dissipation chamber outlet 38 on the left side, and the air intake vents 13 located on the right side of the placing portion 41 extend rearward to be aligned with the heat dissipation chamber outlet 38 on the right side. In addition, the placing part 41 is also provided with the air inlets 13 near the front side portion of the protruding part 42 and is spliced with the air inlets 13 on the left side and the right side of the placing part 41, so that the air inlets 13 surround the left side, the right side and the front side of the protruding part 42. Projected in the same horizontal plane, the inlet 13 surrounds 3/4 the perimeter of the motor 4, and the outlet 14 surrounds 1/4 the perimeter of the motor 4. Compare in the condition that air intake 13 and air outlet 14 are located motor 4 one side, air intake 13 and air outlet 14 encircle motor 4 and can increase air intake 13 and air outlet 14 to motor 4 cover degree to increase the even degree of air inlet and air-out, thereby promote motor 4's the even degree of heat dissipation.

Example 6

The difference between embodiment 6 and embodiment 4 is that the relative positions of the heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38 are different.

Referring to fig. 13, in embodiment 6, a heat radiation chamber inlet 37 and a heat radiation chamber outlet 38 are formed between the upper cover plate 28 and the stator 27 at opposite sides of the motor 4, respectively. Or between the lower cover plate 29 and the stator 27 on opposite sides of the motor 4, a heat dissipation chamber inlet 37 and a heat dissipation chamber outlet 38 are formed, respectively. At this time, the heat dissipation chamber inlet 37 and the heat dissipation chamber outlet 38 are in longitudinal alignment.

Example 7

Embodiment 7 differs from embodiment 4 in the structure of the air outlet duct 19.

Referring to fig. 14 and 15, in embodiment 7, the pedestal 7 includes a placing portion 41 which contacts the table top and a projecting portion 42 which projects upward. The placing portion 41 surrounds the front, left and right sides of the projection 42. The upper end of the projection 42 is formed with a through hole 43. The portion of the motor 4 below the positioning plate 39 passes through the through hole 43 to bring the positioning plate 39 into sealing abutment with the boss 42. One side of the protruding portion 42 away from the placing portion 41 is provided with a hollow-out flange extending downward. The side of the turned-over edge far from the convex part 42 is integrally connected with a supporting plate 44 abutted to the lower part of the lower cover plate 29. Meanwhile, the base 7 is further provided with a bottom cover 46 contacting the table top, the bottom cover 46 is located below the protrusion 42 to cover the protrusion 42, and the air outlet 14 is provided at the rear side of the bottom cover 46. The bottom cover 46 is centrally provided with a lower mounting hole 45, preferably, the edge of the support plate 44 forms a step, and the bottom cover 46 is positioned at the edge of the lower mounting hole 45 and is partially and exactly clamped at the step of the support plate 44, so that the support plate 44 is exposed out of the bottom cover 46. The lower surface of the tray 44 and the lower surface of the bottom cover 46 form a flat surface.

The protruding portion 42 is provided with a wind shield 47 extending toward the bottom cover 46 and surrounding the motor 4. The wind deflector 47 is overall spiral, a side mounting groove 48 is provided on the lower end surface of the wind deflector 47, and side sound absorbing cotton 49 used as a noise reduction member is provided in the side mounting groove 48. The upper end surface of the bottom cover 46 is provided with a bottom mounting groove 50, bottom sound absorbing cotton 51 is arranged in the bottom mounting groove 50, and the side sound absorbing cotton 49 and the bottom sound absorbing cotton 51 are in interference contact, so that the wind shield 47, the protruding part 42 and the bottom cover 46 jointly enclose an air outlet channel 19 which spirally surrounds the motor 4. And the projections 42 form partitions that separate the inlet air channel 23 and the outlet air channel 19. The spiral wind outlet channel 19 is characterized in that the wind outlet channel 19 is gradually enlarged along the air flowing direction. At this time, the air may be emitted and interfered during the flowing process in the air outlet channel 19, thereby reducing noise. The noise generated by the motor 4 is more lost through the sound-absorbing cotton than directly through the wind-guard 47, thereby contributing to noise reduction.

It will be appreciated that the provision of the flange and the support plate 44 may be eliminated, with the bottom cover 46 abutting directly against the lower cover plate 29 of the motor 4.

Wherein the arrows in fig. 1-15 indicate the direction of air flow.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications without inventive contribution to the present embodiment as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.

Claims (10)

1. The utility model provides a food preparation machine of low height, includes the frame and installs the stirring cup on the frame, the frame includes casing, motor and the wind channel of motor of flowing through, characterized by: along the air flow direction, the wind channel is including the inlet air channel that is located the motor upper reaches, the air-out passageway that is located the motor low reaches and be located the heat dissipation chamber between inlet air channel and the air-out passageway, the heat dissipation chamber is provided with the heat dissipation chamber import that is used for the air admission heat dissipation chamber and is used for the air to leave the heat dissipation chamber export in heat dissipation chamber, the height of casing is H1, and H1 is less than or equal to 100 mm.

2. A low profile food processor as defined in claim 1, wherein: the projection area of the shell in the horizontal plane is S, and H1/S is more than or equal to 0.005 and less than or equal to 0.08.

3. A low profile food processor as defined in claim 1, wherein: when the stirring cup is arranged on the machine base, the total height of the machine base and the stirring cup is H2, and H2/S is more than or equal to 0.03 and less than or equal to 0.35.

4. A low profile food processor as defined in claim 1, wherein: the height of the air duct is Z, and Z/H1 is more than or equal to 0.4 and less than 1.

5. A low profile food processor as claimed in claim 4, wherein: the height of the air duct is Z, the height of the motor is D, and D/Z is more than or equal to 0.6 and less than or equal to 2.5.

6. A low profile food processor as defined in claim 1, wherein: the air duct comprises an air inlet and an air outlet, the distance between projections of the air inlet in the horizontal direction and projections of a motor shaft of the motor in the horizontal direction is X1, the distance between projections of the air outlet in the horizontal direction and projections of the motor shaft of the motor in the horizontal direction is X2, the sum of X1 and X2 is X, and Z is less than X.

7. A low profile food processor as defined in claim 1, wherein: along the air flow direction, the wind channel includes the air-out passageway that is located the motor low reaches, the air-out passageway is located the outside of motor lateral wall.

8. A low profile food processor as defined in claim 1, wherein: the motor comprises a cover plate at least forming one of the upper end surface or the lower end surface of the motor, and the heat dissipation cavity inlet and the heat dissipation cavity outlet are both positioned below or above the cover plate.

9. A low profile food processor as defined in claim 1, wherein: the horizontal distance between the heat dissipation cavity inlet and the heat dissipation cavity outlet is larger than the vertical distance.

10. A low profile food processor as defined in claim 1, wherein: along the air flow direction, the wind channel is including the inlet air channel who is located the motor upper reaches, inlet air channel is including the installation cavity that is used for installing control assembly, control assembly is horizontal.

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