CN217137769U - Do benefit to abluent food preparation machine - Google Patents

Abstract

The utility model discloses a do benefit to abluent food preparation machine, food preparation machine including the host computer that holds the motor, set up in the stirring cup and the functional component of host computer, the functional component is including selectively setting up in the stirring cup and by motor drive's piece of kneading dough and stirring piece, the motor is interior to be formed into and to drive piece of kneading dough or stirring piece pivoted output, and piece of kneading dough and stirring piece are all protruding be equipped with output complex transmission. Through the design that the output part is concave and the part of the dough kneading piece matched with the transmission part is convex, no matter the dough kneading piece is provided with a matching hole, no matter the flour is poured into the stirring cup at the beginning or the volume of the dough is gradually increased in the dough kneading process, the flour can not be accumulated inside the dough kneading piece and only can be accumulated on the surface of the dough kneading piece due to the convex design of the part of the dough kneading piece in transmission connection with the output part, so that the cleaning of the dough kneading piece is facilitated; the stirring bar does not allow the crushed material to accumulate inside the stirring bar.

Description

Do benefit to abluent food preparation machine

Technical Field

The utility model belongs to the food processingequipment field, concretely relates to do benefit to abluent food preparation machine.

Background

In order to meet the multifunctional requirements of food processing machines in the current market, the food processing machines have a coaxial dual-output function and can simultaneously meet the functions of mincing meat and kneading dough, and during use, the kneading dough rod and the mincing knife are switched to realize the functions of kneading dough and mincing meat.

In the actual working process of kneading dough, the flour pours into the stirring cup through kneading dough the cup in, and in order to reduce user's the number of times that adds, the size of kneading dough the cup also can corresponding increase, pours flour easily when empting flour on the pole of kneading dough, forms the flour and piles up the region, and at the in-process of kneading dough, the flour is stained with the viscidity increase behind the water stirring, if not clear up in time, the flour can adhere to the host computer, leads to the clearance difficulty.

SUMMERY OF THE UTILITY MODEL

To foretell not enough, the utility model provides a do benefit to abluent food preparation machine avoids the material to pile up inside kneading dough spare or stirring piece, makes things convenient for the washing of kneading dough spare and stirring piece.

The utility model discloses a realize through following technical scheme:

the utility model provides a do benefit to abluent food preparation machine, food preparation machine is including the host computer that holds the motor, set up in the stirring cup and the functional block of host computer, and the functional block is including setting up optionally in stirring cup and by motor drive's dough mixing spare and stirring piece, and the motor indent forms and drives dough mixing spare or stirring piece pivoted output, and dough mixing spare and stirring piece all are protruding to be equipped with output complex transmission portion. Through the design that the output part is concave and the part of the dough kneading piece matched with the transmission part is convex, a matching hole is not required to be arranged on the dough kneading piece, no matter the flour is poured into the stirring cup at the beginning, or the volume of the dough is gradually increased in the dough kneading process, even if the flour is accumulated at the dough kneading piece, the flour cannot be accumulated inside the dough kneading piece and only can be accumulated on the surface of the dough kneading piece due to the convex design of the part of the dough kneading piece in transmission connection with the output part, so that the cleaning of the dough kneading piece is facilitated; similarly, for the stirring piece, the part of the stirring piece, which is in transmission connection with the output part, is also in a convex design, so that after the materials are crushed, the crushed materials cannot be accumulated in the stirring piece, and the cleaning of the stirring piece is also facilitated.

Further, the output part comprises a first output part in transmission connection with the dough kneading piece and a second output part in transmission connection with the stirring piece, and the second output part is accommodated in the first output part. The second output part does not increase the height of the motor in the axial direction, so that the overall height of the motor is reduced.

Furthermore, the dough kneading piece is provided with a first transmission part matched with the first output part, and the first transmission part extends into the first output part for transmission connection and is arranged opposite to the second output part. The second output part can not influence the connection of the dough kneading piece, and the transmission part is arranged opposite to the second output part, so that the space in the first output part is utilized more sufficiently, the height of the first output part is effectively reduced, and the integral height of the motor is further reduced.

Furthermore, the dough kneading piece is provided with a first transmission part matched with the first output part, and the first output part is provided with a stage for limiting the first transmission part to move towards the second output part. The first transmission part is limited to continue extending into the first output part through the stage, so that the distance between the first transmission part and the second output part is kept.

Further, the stage is disposed around the second output portion. The stage limits the stretching of the first transmission part through the part surrounding the second output part, and meanwhile, the hollow area also provides a space for the stretching of the second transmission part, so that the first output part is contained in the second output part, and even if the stage is arranged, the transmission connection of the first transmission part and the second transmission part cannot be influenced.

Further, the motor includes the oil-retaining bearing who sets up in the platform stage, and the second output passes through oil-retaining bearing joint to the platform stage. The oil-retaining bearing is abutted to the step section, so that the second output part is supported, and the friction coefficient of the second output part in the motion process is reduced.

Furthermore, the stirring piece is provided with a second transmission part matched with the second output part, and the second transmission part extends into the first output part to be connected to the second output part in a transmission manner. First output portion can play the guide effect when second transmission portion stretches into to make things convenient for being connected of second transmission portion and second output portion.

Furthermore, the inner diameter of the second output part meshed with the stirring piece is d1, the outer diameter of the second output part is d2, the inner diameter of the first output part meshed with the dough kneading piece is d3, the ratio of d1 to d2 is 1: 1.1-1.3, and the ratio of d2 to d3 is 1: 1.1-1.3. If the ratio of d1 to d2 is too large, that is, the outer diameter of the second output part is too small, then the ratio of d2 to d3 is too small, the structural strength of the second output part is reduced, and the radial gap between the second output part and the first output part is increased, so that the second output part is easy to shake, and even if the second output part is limited by the stage surrounding the second output part, the size of the stage is increased, so that the cost is increased; if the ratio of d1 to d2 is too small, that is, the outer diameter of the second output part is too large, then the ratio of d2 to d3 is too large, the gap between the second output part and the first output part in the radial direction is also shortened, which easily causes collision between the second output part and the first output part, and also causes the size of the stage to be too small during the stage of setting the stage, which increases the difficulty of manufacturing the stage.

Furthermore, the output part comprises a first output part in transmission connection with the dough kneading part and a second output part in transmission connection with the stirring part, the motor comprises a motor shaft and a speed regulating assembly in transmission connection with the motor shaft and the output part, the speed regulating assembly comprises an adapter in transmission connection with the second output part, a first planetary gear in transmission connection with the adapter and a gear support for supporting the first planetary gear, and the gear support and the adapter are molded in an encapsulation mode; the speed regulation assembly further comprises a second planetary gear in transmission connection with the second output part and the first output part. The gear support can support first planetary gear, and the rubber coating shaping between gear support and the adapter is favorable to improving the axiality between gear support and the adapter, reduces the holistic eccentricity of gear support, avoids the adapter off-centre to lead to the adapter at the uneven condition that rocks of during operation atress, is favorable to further improving the stability of adapter at the during operation to be favorable to further improving the stability of motor when doing.

Furthermore, the adapter is connected with the second output part in an interference mode, and the joint of the adapter and the second output part is of a flat structure. Interference is connected between adapter and the second output to make the contact inseparabler between adapter and the second output, avoid taking place relative rotation between adapter and the second output, flat bit architecture then further strengthens the stability of being connected between adapter and the second output, thereby makes the adapter can drive the synchronous rotation of second output.

Drawings

FIG. 1 is a schematic diagram illustrating an exemplary embodiment of a food processor according to the present invention;

FIG. 2 is a partially enlarged view of the portion A in FIG. 1;

FIG. 3 is a schematic diagram illustrating another exemplary embodiment of a food processor according to the present invention;

FIG. 4 is a schematic enlarged view of a portion B of FIG. 3;

fig. 5 is a schematic diagram illustrating an exemplary embodiment of an electric machine according to the present invention.

Reference numerals are as follows:

1. the stirring device comprises a main machine, 2, a stirring cup, 3, a motor, 31, a first output part, 32, a second output part, 33, a stage, 34, a motor shaft, 35, a speed regulating component, 351, an adapter, 352, a first planetary gear, 353, a second planetary gear, 354, a gear support, 36, an oil bearing, 4, a dough kneading piece, 41, a first transmission part, 5, a stirring piece, 51 and a second transmission part.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

It should be noted that the terms of orientation such as left, right, up, down, front and back in the embodiments of the present invention are only relative concepts or are referred to the normal use state of the product, i.e. the traveling direction of the product, and should not be considered as limiting.

In addition, it should be noted that the dynamic terms such as "relative movement" mentioned in the embodiments of the present invention include not only a change in position but also a movement in which a state changes without a relative change in position such as rotation or rolling.

Finally, it is noted that when an element is referred to as being "on" or "disposed" to another element, it can be on the other element or intervening elements may also be present. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or intervening elements may also be present.

As shown in fig. 1 to 5, the food processor beneficial to cleaning comprises a main machine 1 for accommodating a motor 3, a stirring cup 2 arranged in the main machine 1 and a functional assembly, wherein the functional assembly comprises a dough kneading piece 4 and a stirring piece 5 which are selectively arranged in the stirring cup 2 and driven by the motor 3, the motor 3 is internally recessed to form an output part for driving the dough kneading piece 4 or the stirring piece 5 to rotate, and the dough kneading piece 4 and the stirring piece 5 are both convexly provided with a transmission part matched with the output part; one of the dough piece 4 and the stirring piece 5 is arranged in the stirring cup 2, so that the food processor can process different materials, for example, dough kneading can be realized through the dough kneading piece 4, the stirring piece 5 can stir and crush the materials, the dough kneading piece 4 or the stirring piece 5 is driven by an output part formed by the motor 3 during the work, the output part is arranged in a concave way, and the output part of the surface piece 4 or the stirring piece 5 is designed to be convex correspondingly when in transmission connection, so that the output part can extend into the transmission part to be in transmission connection with the transmission part, and simultaneously, for the dough kneading piece 4 or the stirring piece 5, when the material is processed, the material needs to be stirred, so the material can rotate and rise under the driving of the functional component, particularly in the dough kneading process, the volume of the dough is gradually increased, and the whole viscosity is higher, so that the dough is easier to adhere to the dough piece.

Through the design that the output part is concave and the part of the dough kneading piece matched with the transmission part is convex, a matching hole is not required to be arranged on the dough kneading piece, so that no matter the flour is poured into the stirring cup at the beginning or the volume of the dough is gradually increased in the dough kneading process, even if the flour is accumulated at the dough kneading piece, the flour cannot be accumulated inside the dough kneading piece and only can be accumulated on the surface of the dough kneading piece due to the convex design of the part of the dough kneading piece in transmission connection with the output part, thereby being convenient for cleaning the dough kneading piece; similarly, for the stirring piece, the part of the stirring piece, which is in transmission connection with the output part, is also in a convex design, so that after the materials are crushed, the crushed materials cannot be accumulated in the stirring piece, and the cleaning of the stirring piece is also facilitated.

The required rotation speed is different between the kneading member 4 and the stirring member 5 because the materials to be processed are different, the required rotation speed is low and the torsion is large for the kneading member 4, and the required rotation speed is high and the torque is small for the stirring member 5, so that the requirement of the rotation speed different from that of the kneading member 4 or the stirring member 5 needs to be satisfied when the kneading member 4 or the stirring member 5 is driven by the output part.

As shown in fig. 1 and 2, the output part comprises a first output part 31 in transmission connection with the dough kneading piece 4 and a second output part 32 in transmission connection with the stirring piece 5, and the second output part 32 is accommodated in the first output part 31; the first output portion 31 and the second output portion 32 are both retracted, and the second output portion 32 is accommodated in the first output portion 31, so that the second output portion 32 does not increase the height of the motor 3 in the axial direction, thereby reducing the overall height of the motor 3.

Preferably, the first output portion 31 and the second output portion 32 are coaxially disposed, and the second output portion 32 is housed in the first output portion 31, so that the first output portion 31 and the second output portion 32 are more coaxially disposed as a whole.

Since the first output part 31 is used for driving the dough kneading member 4 to rotate, and the second output part 32 is used for driving the stirring member 5 to rotate, the rotating speed output by the first output part 31 is lower than the rotating speed output by the second output part 32, so that the rotating speed at the second output part 32 needs to be subjected to speed regulation processing when being transmitted to the first output part 31, thereby reducing the rotating speed of the second output part 32 and improving the torque of the second output part 32.

The output part comprises a first output part 31 in transmission connection with the dough kneading member 4 and a second output part 32 in transmission connection with the stirring member 5, the motor 3 comprises a motor shaft 34 and a speed regulating assembly 35 in transmission connection with the motor shaft 34 and the output part, the speed regulating assembly 35 comprises an adapter 351 in transmission connection with the second output part 32, a first planetary gear 352 in transmission connection with the adapter 351 and a gear bracket 354 supporting the first planetary gear 352, and the gear bracket 354 is formed by encapsulation with the adapter 351; the governor assembly 35 further includes a second planetary gear 353 drivingly connecting the second output 32 and the first output 31; when the motor 3 drives the dough kneading piece 4 or the stirring piece 5 to rotate, the rotating speed of the motor shaft 34 after one-time speed reduction is transmitted to the adapter 351 through the first planetary gear 352, the adapter 351 is in transmission connection with the second output part 32, so that the second output part 32 outputs the rotating speed of the motor 3 after one-stage speed reduction, and when the stirring piece 5 is in transmission connection with the second output part 32, materials can be stirred and crushed through the stirring piece 5; meanwhile, the first output part 31 and the second output part 32 are in transmission connection through the second planetary gear 353, the second output part 32 rotates through the second planetary gear 353 when rotating, so that the rotating speed of the second output part 32 is transmitted to the first output part 31 through the second planetary gear 353 in a speed reduction mode, and when the dough kneading piece 4 is in transmission connection with the first output part 31, materials can be processed through the dough kneading piece 4; gear support 354 can support first planetary gear 352, and rubber coating shaping between gear support 354 and adapter 351, be favorable to improving the axiality between gear support 354 and the adapter 351, reduce the holistic eccentricity of gear support 354, avoid adapter 351 off-centre to lead to adapter 351 at the uneven condition that rocks of during operation atress, be favorable to further improving the stability of adapter 351 at the during operation, thereby be favorable to further improving the stability when motor 3 does.

Preferably, the adapter 351 is in interference connection with the second output part 32, and the joint of the adapter 351 and the second output part 32 is in a flat structure; interference connection between adapter 351 and the second output portion 32 to make the contact inseparabler between adapter 351 and the second output portion 32, avoid taking place relative rotation between adapter 351 and the second output portion 32, the stability of being connected between adapter 351 and the second output portion 32 is then further strengthened to flat bit architecture, thereby makes adapter 351 can drive the synchronous rotation of second output portion 32.

In the present application, since the second output portion 32 is housed in the first output portion 31, and the kneading member 4 is drivingly connected to the first output portion 31, the kneading member 4 also has a portion located in the first output portion 31 when the kneading member 4 is mated with the first output portion 31; as shown in fig. 2, the dough kneading member 4 has a first transmission part 41 engaged with the first output part 31, and the first transmission part 41 extends into the first output part 31 for transmission connection and is disposed opposite to the second output part 32; when the dough kneading piece 4 is in transmission connection with the first output part 31 through the first transmission part 41, the first transmission part 41 correspondingly extends into the first output part 31, the second output part 32 is also accommodated in the first output part 31, the first transmission part 41 and the second output part 32 are arranged oppositely, so that the second output part 32 cannot influence the connection of the dough kneading piece 4, the transmission part and the second output part 32 are arranged oppositely, the space in the first output part 31 is more fully utilized, the height of the first output part 31 is effectively reduced, and the overall height of the motor 3 is further reduced.

Preferably, in order to ensure that the first output portion 31 still leaves a space for the first transmission portion 41 to extend into when the second output portion 32 is accommodated in the first output portion 31, the bottom end of the second output portion 32 is located in the middle area of the first output portion 31, that is, when the first transmission portion 41 extends into the first output portion 31, the second output portion 32 and the first transmission portion 41 are respectively located at two ends of the first output portion 31, the space of the first output portion 31 is reasonably utilized, the extending of the first transmission portion 41 is not affected, and when the stirring member 5 is in transmission connection with the second output portion 32, the stirring member 5 only needs to extend into the second output portion 32 through the first output portion 31.

As shown in fig. 3 and 4, the stirring member 5 has a second transmission part 51 matched with the second output part 32, and the second transmission part 51 extends into the first output part 31 to be connected to the second output part 32 in a transmission manner; because the second output part 32 is accommodated in the first output part 31, the stirring part 5 needs to extend into the first output part 31 when in transmission connection with the second output part 32, the second transmission part 51 is a part of the stirring part 5 extending into the first output part 31 and in transmission connection with the second output part 32, and meanwhile, when the stirring part 5 is in transmission connection, the second transmission part 51 extends into the first output part 31, so that the first output part 31 can play a role of guiding when the second transmission part 51 extends, thereby facilitating the connection of the second transmission part 51 and the second output part 32; preferably, when the first output part 31 and the second output part 32 are coaxially arranged, the first output part 31 has a better guiding effect on the second transmission part 51, and the coaxiality among the first output part 31, the second output part 32 and the second transmission part 51 is higher.

Since the second output part 32 is accommodated in the first output part 31, the dough kneading member 4 or the stirring member 5 needs to be inserted into the first output part 31, the dough kneading member 4 is in transmission connection with the first output part 31 through the first transmission part 41, and the second transmission part 51 of the stirring member 5 needs to be inserted into the first output part 31 to enter the second output part 32 and be in transmission connection with the second output part 32, so that when the dough kneading member 4 is in transmission fit with the first output part 31, the dough kneading member 4 needs to be prevented from influencing the second output part 32.

As shown in fig. 4, the dough piece 4 has a first transmission part 41 engaged with the first output part 31, and the first output part 31 is provided with a step section 33 for restricting the first transmission part 41 from moving toward the second output part 32; since the dough kneading member 4 is engaged with the first output part 31 through the first transmission part 41, and the second output part 32 is in an idle state at this time, in order to avoid the mutual influence between the first transmission part 41 and the second output part 32, when the first transmission part 41 extends into the first output part 31, the first transmission part 41 is limited to continue to extend into the first output part 31 through the stage 33, so that the distance between the first transmission part 41 and the second output part 32 is kept.

Preferably, the stage 33 is arranged around the second output 32; the stage 33 can not affect the extending of the second transmission part 51 while limiting the movement of the first transmission part 41 towards the second output part 32, so that the stage 33 is disposed around the second output part 32, that is, the stage 33 is a ring structure with a hollow middle area, the stage 33 limits the extending of the first transmission part 41 through the part surrounding the second output part 32, and the hollow middle area provides a space for the extending of the second transmission part 51, so that the transmission connection of the first transmission part 41 and the second transmission part 51 is not affected even if the stage 33 is disposed while the second output part 32 is accommodated in the first output part 31.

Regarding the stage 33 and the second output portion 32, the stage 33 is disposed around the second output portion 32 so that the second output portion 32 can still be in transmission connection with the second transmission section 32 after being accommodated in the first output portion 31, and the step section 33 can also limit the first transmission portion 41, preferably, when the stage 33 is matched with the second output portion 32, the second output portion 32 extends into the stage 33, so that the hollow portion of the stage 33 can also accommodate a part of the second output portion 32, and thus the height of the whole motor 3 is not increased after the stage 33 is disposed.

The second output portion 32 is clamped at the first output portion 31 through the stage 33, and the second output portion 32 extends into the stage 33, so that the second output portion 32 is configured as a T-shaped structure, the protruding portions at two sides of the second output portion 32 are clamped on the upper surface of the stage 33, and the portion in the middle of the second output portion 32, which is used for transmission connection of the second transmission portion 51, extends into the stage 33.

In the present application, the stage 33 is used for supporting the second output portion 32 and limiting the movement of the first output portion 31, and the step 33 is of an annular structure, so that, for the stage 33, in order to enable the stage 33 to limit the movement of the first transmission portion 41, the inner diameter of the step 33 needs to be smaller than the outer diameter of the first transmission portion 41, so that the first transmission portion 41 cannot pass through the stage 33, and the limitation of the first transmission portion 41 is realized, and at the same time, the stage 33 needs to be larger than the outer diameter of the second transmission portion 51 so that the second transmission portion 51 can extend into the stage 33, so that the inner diameter of the stage 33 needs to be larger than the outer diameter of the second transmission portion 51.

As shown in fig. 5, the engaging inner diameter of the second output part 32 and the stirring piece 5 is d1, the outer diameter of the second output part 32 is d2, the engaging inner diameter of the first output part 31 and the dough kneading piece 4 is d3, the engaging inner diameter of d1: d2 is 1: 1.1-1.3, and the engaging inner diameter of d2: d3 is 1: 1.1-1.3; the part of the stirring piece 5 meshed with the second output part 32 is the second transmission part 51, the part of the face piece 4 meshed with the first output part 31 is the first transmission part 41, if the ratio of d1 to d2 is too large, namely the outer diameter of the second output part 32 is too small, at this time, the ratio of d2 to d3 is too small, the structural strength of the second output part 32 can be reduced, and meanwhile, the radial gap between the second output part 32 and the first output part 31 can be increased, so that the second output part 32 is easy to shake, even if the second output part 32 is limited by arranging the table stage 33 around the second output part 32, the size of the table stage 33 can be increased, and the cost is increased; if the ratio of d1 to d2 is too small, that is, the outer diameter of the second output section 32 is too large, then the ratio of d2 to d3 is too large, and the gap between the second output section 32 and the first output section 31 in the radial direction is also shortened, which easily causes collision between the second output section 32 and the first output section 31, and also causes the size of the stage 33 to be too small when the stage 33 is installed, thereby increasing the difficulty in manufacturing the stage 33.

In this application, since the motor 3 needs to drive the stirring element 5 or the kneading element 4, and the rotation speeds of the stirring element 5 and the kneading element 4 are different, the speed adjusting assembly 35 is selected as a two-stage reduction gearbox, wherein the connection between the speed adjusting assembly 35 and the motor shaft 34 can be referred to the above description, which is not described herein again, and for the speed adjusting assembly 35, not only the fixing of the first planetary gear 352 and the second planetary gear 353 is realized through the gear bracket 354, but also the fixing of the first output part 31 and the second output part 32 is realized, and when the first output part 31 and the second output part 32 are fixed, since the second output part 32 is accommodated in the first output part 31, after the first output part 31 is fixed, the limit of the second output part 32 is realized through the first output part 31.

As shown in fig. 5, the motor 3 includes an oil bearing 36 provided at the stage 33, and the second output portion 32 is snap-fitted to the stage 33 through the oil bearing 36; the stage 33 acts as a barrier to the first transmission part 41, preventing the first transmission part 41 from moving towards the second output part 32 and contacting the second output part 32, and at the same time, the upper end surface of the stage 33 also provides a space for installing the second output part 32, and the oil-containing bearing 36 abuts against the stage 33, thereby supporting the second output part 32 and reducing the friction coefficient of the second output part 32 during movement.

The second output part 32 is clamped at the step section 33 formed by the first output part 31 through an oil-retaining bearing 36, the height of the first output part 31 is L, the depth of the second output part 32 which is received in the first output part 31 is L1, namely the length of the second output part 32 from the lower end of the first output part 31 is L1, and the height of the second output part 32 is L-L1, namely the second output part 32 does not exceed the height of the first output part 31.

Preferably, in order to improve the sealing performance, a felt seal is provided at a position where the oil-impregnated bearing 36 abuts against the stage 33, and the second output part 32 is restricted and sealed by the felt seal and the oil-impregnated bearing 36.

The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (10)

1. The utility model provides a do benefit to abluent food preparation machine, food preparation machine is including the host computer that holds the motor, set up in the stirring cup and the functional block of host computer, and the functional block is including setting up optionally in stirring cup and by motor drive's dough mixing spare and stirring piece, its characterized in that, the motor indent forms the drive dough mixing spare or stirring piece pivoted output, dough mixing spare with stirring piece all protruding be equipped with output complex transmission.

2. A food processor as claimed in claim 1, wherein the output portion comprises a first output portion in driving connection with the dough kneading member and a second output portion in driving connection with the stirring member, the second output portion being received in the first output portion.

3. A food processor as claimed in claim 2, wherein the dough kneading member has a first transmission part cooperating with the first output part, the first transmission part extending into the first output part for transmission connection and being arranged opposite the second output part.

4. A food processor facilitating cleaning according to claim 2, wherein the dough piece has a first transmission cooperating with the first output, the first output being provided with a stage limiting the movement of the first transmission towards the second output.

5. A food processor facilitating cleaning according to claim 4, wherein the table stage is arranged around the second output.

6. A food processor as claimed in claim 4, wherein the motor comprises an oil bearing provided at the stage, the second output being snapped into the stage by means of the oil bearing.

7. A food processor as claimed in claim 2, wherein the stirring element has a second transmission part which cooperates with the second output part, the second transmission part extending into the first output part for transmission connection to the second output part.

8. The food processor facilitating cleaning of claim 4, wherein the second output portion has an inner diameter d1 engaged with the stirring member, the second output portion has an outer diameter d2, the first output portion has an inner diameter d3 engaged with the dough kneading member, d1: d2: 1: 1.1-1.3, and d2: d3: 1: 1.1-1.3.

9. The food processor as defined in claim 1, wherein said output portion includes a first output portion drivingly connected to said dough kneading element and a second output portion drivingly connected to said blending element, said motor including a motor shaft and a speed adjustment assembly drivingly connecting said motor shaft and said output portion, said speed adjustment assembly including an adapter drivingly connected to said second output portion, a first planetary gear drivingly connected to said adapter, and a gear carrier supporting said first planetary gear, said gear carrier being overmolded with said adapter;

the speed regulating assembly further comprises a second planetary gear in transmission connection with the second output part and the first output part.

10. A food processor as claimed in claim 9, wherein the adaptor is in interference fit with the second output portion, and the junction of the adaptor and the second output portion is of a flat configuration.

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