CN216724283U - Low-noise food processor - Google Patents

Abstract

The utility model relates to the technical field of household appliances, and discloses a low-noise food processor which comprises a host and a processing cup component arranged on the host, wherein the host comprises a base, a shell component arranged above the base and a power heating assembly arranged in the shell component, and the power heating assembly is flexibly connected with the processing cup component. This application sets up to flexonics between power heating assembly and the processing cup subassembly, and the vibrations that power heating assembly produced can be filtered to flexible connection structure to the reduction is to the vibrations transmission of processing cup subassembly, reduces food preparation machine's noise at work.

Description

Low-noise food processor

Technical Field

The utility model relates to the technical field of household appliances, in particular to a low-noise food processing machine.

Background

At present, food processors have been increasingly used, which mainly cut and crush food by a processing knife assembly disposed at the bottom of an inner cavity of the food processor, so that the food can be crushed to a desired degree for a user to eat.

In order to meet diversified use requirements of users, some existing food processors are also configured with a heating function to heat food slurry. The food processing machine with the processing function generally comprises a main machine and a processing cup assembly, wherein the main machine is provided with a shell, a base and a power heating assembly arranged in the shell, the power heating assembly comprises a motor assembly and a heating plate, the motor assembly provides power for a processing cutter assembly in the processing cup assembly, and the heating plate provides heat energy for food materials in the processing cup assembly. In order to ensure the coaxiality of the power heating assembly and the cutter head of the machining cutter assembly, the motor assembly is locked on the inner side of the lower portion of the heating plate, a motor output shaft penetrates through the heating plate and is fastened with the machining cutter assembly, the machining cup assembly is in rigid contact with the heating plate, the machining cup assembly is in rigid contact with the shell of the host machine, in addition, the shell of the host machine is in rigid contact with the base, and when the machine works, the vibration of the motor assembly sequentially passes through the heating plate, the machining cup assembly, the shell of the host machine and the base are transmitted outwards, so that the vibration of the whole machine is large, and the noise is high.

SUMMERY OF THE UTILITY MODEL

To solve one or more of the problems in the prior art or to at least provide a useful alternative, the present invention provides a low noise food processor that reduces operating noise by vibrating between the components of the food processor.

The utility model discloses a low-noise food processor which comprises a host and a processing cup component arranged on the host, wherein the host comprises a base, a shell component arranged above the base and a power heating assembly arranged in the shell component, and the power heating assembly is flexibly connected with the processing cup component.

Inside power heating assembly of food processing machine host computer is as the vibrations source that produces vibrations, because power heating assembly and host computer shell subassembly in traditional food processing machine, base isotructure all is the rigid contact, lead to when food processing machine during operation, the produced vibrations of power heating assembly can be respectively through the host computer, the outside transmission of processing cup subassembly, this application sets up to flexonics between with power heating assembly and the processing cup subassembly, the vibrations that power heating assembly produced can be filtered to flexible connection structure, thereby reduce the vibrations transmission to processing cup subassembly, reduce food processing machine's noise at work.

As a preferred technical scheme of low noise food preparation machine, power heating assembly is including setting up in the heating plate of processing cup subassembly below, and processing cup subassembly includes the cup and installs in the cup of cup, cup and heating plate flexonics.

The heating plate sets up in the below of processing cup subassembly, surround with the cup of processing cup subassembly and form the process chamber, the cup of processing cup subassembly is used for installing the cup and with host computer fixed connection, because processing cup subassembly and cup assembly are fixed, and heating plate and power part snap-on, consequently, through injecing flexonics between cup and the heating plate, the vibrations that the power part produced can not directly transmit the cup through the heating plate on, thereby reduce the cup and connect the vibrations that other parts of cup received and influence.

As a preferred technical scheme of the low-noise food processor, the sealing washer is axially clamped between the heating plate and the cup body so as to form an axial clearance a between the heating plate and the cup body and/or the cup seat, wherein a is more than 0 mm.

Seal ring sets up the tip of port under the cup, the centre gripping can guarantee the seal performance of the process chamber that cup and heating plate surround between heating plate and cup, and simultaneously, because seal ring's self volume reason, must form the clearance between heating plate and cup, cup and cup fixed connection, effect through seal ring, also form axial clearance between cup and heating plate, this axial clearance can avoid the power part during operation of power heating assembly, the vibrations that produce lead to heating plate and cup to take place the rigid contact, thereby the effect of straining the shake has been guaranteed.

As a preferred technical scheme of the low-noise food processor, a supporting frame fixed above the base is further arranged in the shell component, and the power heating assembly is fixed on the supporting frame and is flexibly connected with the supporting frame.

The support frame can guarantee the bearing of power heating assembly, because the support frame is fixed on the base, the power heating assembly produces vibrations and can directly pass through the support frame and transmit to the base, also can pass through the table surface that food preparation machine placed in the use and transmit to the user, influences user's use and experiences. This application avoids power heating assembly during operation vibrations to pass through the direct transmission of support frame to base with support frame and power heating assembly flexonics, reduces the use noise.

As a preferred technical scheme of low noise food preparation machine, processing cup subassembly includes the cup and installs in the cup of cup, and power heating assembly is including setting up the heating plate in processing cup subassembly below, support frame respectively with heating plate and/or cup flexible connection.

The lower extreme of cup is fixed on the cup to on being fixed in the host computer with the cup through the cup, the heating plate setting surrounds formation process chamber at the lower extreme of cup and with the cup, because cup and cup fixed connection, the support frame can be connected with the cup, and/or with cup flexonics, so as to avoid in the course of the work processing cup subassembly to pass through the outside transmission of support frame because of the cup vibrations that inside edible material processing produced. Simultaneously because support frame and power heating assembly flexonics, consequently the vibrations of power heating assembly also can not pass through the outside transmission of support frame to make support frame and processing cup subassembly, power heating assembly all form the relation of flexible transmission, reduce vibrations and pass outward the influence that uses the experience to the user.

As a preferred technical scheme of low noise food preparation machine, the support frame is equipped with the erection column, and the erection column passes heating plate and cup in proper order to with heating plate and cup fastening connection.

Because heating plate and cup all are the flexonics with the support frame, therefore the erection column passes the heating plate in proper order and forms fixedly with the cup, when the erection column forms the fastening connection with heating plate and cup respectively, still forms the flexonics to this avoids the working process, and the vibrations of power heating assembly and processing cup subassembly pass through the outside shell subassembly transmission of living of support frame, reduces the noise in use.

As a preferred technical scheme of low noise food preparation machine, processing cup subassembly includes the cup and installs in the cup of cup, and food preparation machine still includes the upper bracket of fixed cup, upper bracket and cup flexonics.

The processing cup component can vibrate due to the whipping of the internal food materials in the working process and also can vibrate due to the high-speed rotation of the power heating assembly below the processing cup component, and the vibration between the processing cup component cup body and the upper bracket can be filtered by arranging the flexible connection between the processing cup component and the upper bracket, so that the vibration noise is reduced.

As a preferred technical scheme of the low-noise food processor, the food processor also comprises an upper cover body which can be buckled on the upper bracket, and the upper cover body is flexibly connected with the cup body.

Go up the lid and cover the wholeness that fits the upper bracket in order to improve the complete machine, in order to avoid the vibrations of processing cup subassembly to pass through the outside transmission of last lid, also set up to flexonics between the cup of last lid and processing cup subassembly to vibrations between filtering processing cup subassembly cup and the last lid reduce vibration noise.

As a preferred technical scheme of the low-noise food processor, the upper bracket at least surrounds part of the cup body, a gap is formed between the upper bracket and the side wall of the cup body, and the first flexible cushion is clamped at the gap.

But the upper bracket is in can the separation cup inner chamber on the direction of centers on and stirs edible material production noise outward transmission, and the clearance between upper bracket and the cup also can form a further noise reduction of syllable-dividing clearance and pass outward, through the first flexible pad of centre gripping in clearance department, can avoid the cup vibrations to collide to the upper bracket, when keeping the cup stable, reduces the vibration noise.

As a preferred technical scheme of low noise food preparation machine, the rim periphery of the cup body is provided with a convex edge, and a second flexible cushion is clamped between the upper bracket and the convex edge of the cup body.

In the vibration process of the cup body, the amplitude of the cup opening is large, the second flexible pad can buffer the vibration between the cup opening of the cup body and the upper support, and the vibration noise at the upper end of the cup body is reduced.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model and not to limit the utility model. In the drawings:

FIG. 1 is a cross-sectional view of a food processor according to an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a main body of the food processor shown in fig. 1.

Fig. 3 is an exploded view of the host machine in the embodiment shown in fig. 2.

Fig. 4 is a partially enlarged view of a portion a in fig. 3.

FIG. 5 is a top sectional view of the mainframe according to an embodiment of the present invention.

FIG. 6 is a side sectional view of a host in an embodiment of the utility model.

Fig. 7 is a partially enlarged view of fig. 6 at B.

Description of reference numerals:

10-a main engine, 110-a shell assembly, 111-a support frame, 112-a mounting column, 120-a power assembly, 121-a motor assembly, 122-a motor cover, 130-a heating disc and 140-a base;

20-processing cup assembly, 210-cup body, 211-convex edge, 220-crushing assembly, 230-cup seat, 240-mounting part and 250-sealing gasket;

30-a shock pad;

40-rigid spacers;

50-upper support, 510-first flexible mat, 520-second flexible mat;

60-upper cover body.

Detailed Description

In order to more clearly explain the overall concept of the present invention, the following detailed description is given by way of example in conjunction with the accompanying drawings.

It should be noted that in the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and thus the scope of the present invention is not limited by the specific embodiments disclosed below.

In addition, in the description of the present invention, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", etc., indicate orientations and positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; they may be directly connected or indirectly connected through intervening media, or may be connected through the use of two elements or the interaction of two elements. However, the direct connection means that the two bodies are not connected through a transition structure, but connected through a connection structure to form a whole. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may be directly contacting the second feature or the first and second features may be indirectly contacting each other through intervening media. In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The specific scheme is as follows:

the utility model discloses a low-noise food processor, as shown in fig. 1-4, the food processor comprises a main machine 10 and a processing cup component 20 installed on the main machine 10, the processing cup component 20 comprises a cup body 210, the cup body 210 forms a processing cavity, a crushing component 220 capable of rotating at a high speed is arranged in the processing cavity to cut and crush food materials, the main machine 10 comprises a base 140, a shell component 110 arranged above the base 140 and a power heating assembly arranged in the shell component 110, the power heating assembly is used for providing power for the crushing component 220, specifically, the power heating assembly comprises a power assembly 120 and a heating plate 130, wherein the power assembly 120 comprises a motor component 121 and a motor cover 122 arranged outside the motor component 121, and the motor cover 122 is covered outside the motor component 121 and used for guiding airflow to the motor component 121. The reason why the power heating assembly is a main noise source of noise generated by the food processor during the operation is that the power heating assembly in the conventional food processor is in rigid contact with the housing assembly 110 of the main machine 10, the base 140 and other structures, so that when the food processor operates, the vibration generated by the power heating assembly is transmitted to the outside through the main machine 10 and the processing cup assembly 20 respectively. Furthermore, the power assembly 120 and the heating plate 130 may be limited to be flexibly connected to improve the vibration-absorbing effect, for example, an extended connection portion is provided on the heating plate 130, and a soft pad is provided at the connection portion with the motor assembly 121 or other components in the power assembly 120 to achieve the flexible connection, so as to avoid noise generated by rigid connection.

It will be understood by those skilled in the art that the present application is not limited to any particular connection structure between the power heating assembly and the processing cup assembly 20, and the flexible connection between the power heating assembly and the processing cup assembly can reduce the vibration transmission of the power heating assembly to the processing cup assembly 20. As in some embodiments, the power heating assembly and the processing cup assembly 20 are flexibly connected by clamping the flexible pad structure and acting on the flexible pad through the fastening member, so as to reduce the vibration transmission and further reduce the noise transmission while maintaining the reliable connection of the power heating assembly and the processing cup assembly 20.

As shown in fig. 1, 3 and 6, in one embodiment, the power heating assembly includes a heating plate 130 disposed below the processing cup assembly 20, the heating plate 130 and the cup body 210 of the processing cup assembly 20 surround to form a processing cavity, the processing cup assembly 20 includes a cup base 230 and the cup body 210 mounted on the cup base 230, since the cup body 210 is a generally cylindrical cup body 210 with an upper opening and a lower opening, in order to facilitate the mounting of the cup body 210, the cup base 230 is disposed at the lower opening of the cup body 210 to be fixedly assembled with other components of the food processor, and further, in order to prevent vibration generated during the operation of the power heating assembly from being transmitted to the outside through the cup base 230, the cup base 230 is flexibly connected with the heating plate 130. Since the processing cup assembly 20 and the cup body 210 are assembled and fixed, and the heating plate 130 and the power part are directly fixed, by defining the flexible connection between the cup holder 230 and the heating plate 130, the vibration generated by the power part is not directly transmitted to the cup holder 230 through the heating plate 130, thereby reducing the influence of the vibration on the cup holder 230 and other components connected to the cup holder 230. In one embodiment, the cup holder 230 and the heating plate 130 can be flexibly connected by providing a flexible pad at the connection, and the flexible pad can filter out the vibration transmitted from the motor assembly 121 to the heating plate 130. Further, in order to facilitate the connection between the heating plate 130 and the cup holder 230, the cup holder 230 is extended radially outward to form a mounting portion 240, the cup holder 230 is formed with a mounting portion 240 at an axially corresponding position, and the heating plate 130 and the cup holder 230 are assembled and positioned by the respective mounting portions 240 and are flexibly connected. In the illustrated embodiment, the mounting portions 240 of the cup holder 230 and the cup 210 are mounting bosses, the two mounting bosses are provided with through holes aligned in the axial direction, and a connecting member is arranged to pass through the two through holes to fasten the cup holder 230 and the heating plate 130.

It can be understood by those skilled in the art that, since the cup 210 is made of a transparent material, such as borosilicate, for the convenience of the user to observe the processing state of the food material inside the cup 210, in some cases, the cup 210 is not required to be set in a transparent form, such as the whole cup 210 is embedded inside the main body 10 and enclosed inside the main body 10, in one embodiment, the cup 210 and the cup holder 230 can also be an integral structure. Under this premise, the heating plate 130 and the integrated cup body 210 and cup base 230 form a flexible connection structure.

As shown in fig. 6 and 7, in general, a sealing washer 250 is disposed between the hotplate 130 and the cup 210 of the food processor, and the sealing washer 250 is disposed at the end of the lower port of the cup 210, so as to ensure the sealing performance of the processing chamber enclosed by the cup 210 and the hotplate 130, and at the same time, due to the self-volume of the sealing washer 250, a gap must be formed between the hotplate 130 and the cup 210, in one embodiment, the sealing washer 250 is axially clamped between the hotplate 130 and the cup 210, so as to form an axial gap a, a > 0mm, between the hotplate 130 and the cup 210, the cup 230 and the cup 210 are fixedly connected, and through the action of the sealing washer 250, an axial gap is also formed between the cup 230 and the hotplate 130, and the axial gap can prevent the hotplate 130 and the cup 230 from rigidly contacting due to the shock generated when the power part of the power heating assembly works, thereby ensuring the effect of filtering vibration. It will be appreciated that in one embodiment, the axial gap a between the hotplate 130 and the cup 210 and the cup 230 may also be achieved by the sealing washer 250, thereby preventing the hotplate 130 and the cup 210 or the cup 230 from generating noise due to vibration.

As shown in fig. 1, 6, and 7, a supporting frame 111 fixed above the base 140 is further disposed in the housing assembly 110, the power heating assembly is fixed to the supporting frame 111, and the supporting frame 111 can ensure the load bearing of the power heating assembly, and since the supporting frame 111 is fixed on the base 140, the vibration generated by the power heating assembly can be directly transmitted to the base 140 through the supporting frame 111, and can also be transmitted to a user through a working table placed on a food processor during use, which affects the use experience of the user.

As shown in fig. 1, 3, 6, and 7, in one embodiment, the processing cup assembly 20 includes a cup holder 230 and a cup 210 mounted on the cup holder 230, the power heating assembly includes a heating plate 130 disposed below the processing cup assembly 20, and the support frame 111 is flexibly connected to the heating plate 130 and/or the cup holder 230, respectively. Wherein, the lower extreme of cup 210 is fixed on cup 230 to on being fixed in host computer 10 with cup 210 through cup 230, heating plate 130 sets up the lower extreme at cup 210 and surrounds with cup 210 and form the processing chamber, because cup 210 and cup 230 fixed connection, support frame 111 can be connected with cup 210, and/or with cup 230 flexonics, so as to avoid in the course of the work processing cup subassembly 20 to pass through support frame 111 outwards because of the cup 210 vibrations that inside edible material processing produced. Simultaneously because support frame 111 and power heating assembly flexonics, consequently the vibrations of power heating assembly also can not pass through support frame 111 and outwards transmit to make support frame 111 and processing cup subassembly 20, power heating assembly all form the relation of flexible transmission, reduce vibrations and pass outward the influence that experiences to user's use.

Specifically, in one embodiment, the support bracket 111 is provided with a mounting post 112, and the mounting post 112 sequentially penetrates the heating plate 130 and the cup 230 and tightly connects the heating plate 130 and the cup 230, as shown in fig. 7. Because the heating plate 130 and the cup holder 230 are flexibly connected with the support frame 111, when the mounting post 112 sequentially penetrates through the heating plate 130 and the cup holder 230 to form a fixed connection, the mounting post 112 is respectively and fixedly connected with the heating plate 130 and the cup holder 230, and meanwhile, a flexible connection is formed, so that the vibration of the power heating assembly and the processing cup assembly 20 is transmitted through the shell assembly 110 which is supported outside by the support frame 111 in the working process, and the use noise is reduced.

As shown in fig. 7, in one embodiment, the flexible connection of the mounting posts 112 to the heater plate 130 and the cup holder 230, respectively, is achieved by: the periphery of the mounting column 112 is provided with the shock pad 30, the cup holder 230 extends radially outwards to form a mounting part 240, the cup holder 230 also forms a mounting part 240 at the corresponding position in the axial direction, and the heating plate 130 and the cup holder 230 are assembled and positioned through the respective mounting parts 240 and form a flexible connection. In the illustrated embodiment, the mounting portions 240 of the cup holder 230 and the cup body 210 are mounting bosses, the two mounting bosses are provided with through holes aligned in the axial direction, the mounting posts 112 sequentially pass through the two through holes, the shock absorbing pad 30 is embedded in the two through holes, and when the mounting posts 112 are mounted and sequentially pass through the heating plate 130 and the cup holder 230, the shock absorbing pad 30 forms a sleeve for the mounting posts 112. Further, in order to improve the axial shock absorption performance, the upper end and the lower end of the shock pad 30 respectively extend along the radial direction to form an I-shaped structure, so as to increase the axial abutting area and improve the shock absorption effect. Furthermore, in order to avoid the phenomenon that the cup body 210 connected with the cup base 230 obviously shakes due to the fact that the axial distance between the cup base 230 and the heating plate 130 is too large, a rigid spacer 40 is further arranged between the end faces of the two shock absorbing pads 30, the rigid spacer 40 is an annular gasket, and the rigid spacer 40 can support the shock absorbing pads 30 at the upper and lower positions when the shock absorbing pads 30 vibrate, so that effective shock absorption of any shock absorbing pad 30 is ensured on the premise that excessive deformation is not generated.

As shown in fig. 6, in order to improve the shock absorbing effect, in one embodiment, the processing cup assembly 20 includes a cup holder 230 and a cup 210 mounted to the cup holder 230, the food processor further includes an upper bracket 50 for fixing the cup 210, and the upper bracket 50 is flexibly connected to the cup 210. Because the processing cup component 20 can vibrate due to the stirring of the internal food materials in the working process and also can vibrate due to the high-speed rotation of the power heating assembly below, the flexible connection is arranged between the processing cup component 20 and the upper bracket 50, so that the vibration between the cup body 210 of the processing cup component 20 and the upper bracket 50 can be filtered, and the vibration noise is reduced.

The upper bracket 50 is not particularly limited in this application to the shock absorbing structure of the processing cup assembly 20, and may be configured to absorb shock to the processing cup assembly 20 through one or more of the following structures:

as shown in fig. 3 and 6, in one embodiment, the upper rack 50 surrounds a portion of the cup body 210, another portion of the cup body 210 is exposed to allow a user to observe the processing status of the cavity of the processing cup assembly 20, and a gap is formed between the upper rack 50 and the sidewall of the cup body 210, the upper rack 50 can obstruct the food material stirred in the cavity of the cup body 210 from generating noise to be transmitted outwards in the surrounding direction, and the gap between the upper rack 50 and the cup body 210 can also form a sound insulation gap to further reduce the noise to be transmitted outwards. Further at the first flexible pad 510 of clearance department centre gripping, it is concrete, can set up the mounting hole at upper bracket 50 lateral wall, first flexible pad 510 imbeds in the mounting hole to at the clearance department formation centre gripping of the outer wall of upper bracket 50 inner wall and cup 210, can avoid cup 210 vibrations to collide to upper bracket 50, when keeping cup 210 stable, reduce the vibration noise.

It can be understood that, in order to further improve the sound insulation and noise reduction effects, the upper bracket 50 may also surround the whole cup 210, so as to form a 360 ° wrap around the cup 210 in the circumferential direction, and block the transmission of the noise generated by processing the food material inside the processing cup assembly 20.

In another embodiment, the rim of the cup 210 has a convex edge 211, and the upper bracket 50 and the convex edge 211 of the cup 210 clamp the second flexible mat 520 therebetween, as shown in fig. 6. Specifically, the second flexible pad 520 surrounds protruding 211 surface along, and extend along cup 210 outer wall, upper bracket 50 respectively with the cup 210 outer wall, protruding 211 lower wall butt along, it is fixed to form cup 210, and simultaneously, upper bracket 50 respectively with the cup 210 outer wall, protruding 211 diapire along forms the centre gripping, it is fixed with second flexible pad 520, cup 210 vibrations in-process, the amplitude of rim of a cup department is great, the flexible pad 520 of second can cushion and be located the vibrations between cup 210 rim of a cup department and the upper bracket 50, reduce the vibrations noise of cup 210 upper end.

The food processor further includes an upper cover 60 that can be fastened to the upper bracket 50, the upper cover 60 covers the upper bracket 50 to improve the integrity of the whole machine, as shown in fig. 6, in order to avoid the vibration of the processing cup assembly 20 being transmitted to the outside through the upper cover 60, the upper cover 60 is flexibly connected to the cup body 210, so as to filter the vibration between the cup body 210 and the upper cover 60 of the processing cup assembly 20 and reduce the vibration noise. Specifically, in combination with the foregoing embodiment, in the assembly process, the upper cover 60 and the upper bracket 50 are fixedly assembled together, and the upper and lower two-direction clamping of the convex edge 211 is formed, so as to reliably fix the cup 210, and meanwhile, in the process of clamping the convex edge 211, the cup 210 is kept flexibly connected with the upper cover 60 and the upper bracket 50 through the second flexible pad 520, so that vibration transmission is reduced, working noise is reduced, and user experience is improved.

The technical solutions protected by the present invention are not limited to the above embodiments, and it should be noted that the combination of the technical solution of any one embodiment and the technical solution of one or more other embodiments is within the protection scope of the present invention. Although the utility model has been described in detail with respect to the general description and the specific embodiments, it will be apparent to those skilled in the art that modifications and improvements may be made based on the utility model. Accordingly, such modifications and improvements are intended to be within the scope of the utility model as claimed.

Claims (10)

1. A low-noise food processor comprises a host and a processing cup component arranged on the host, and is characterized in that the host comprises a base, a shell component arranged above the base and a power heating assembly arranged in the shell component, and the power heating assembly is flexibly connected with the processing cup component.

2. A low noise food processor as defined in claim 1, wherein said powered heating assembly includes a heating plate disposed below said processing cup assembly, said processing cup assembly including a cup base and a cup body mounted to said cup base, said cup base being flexibly connected to said heating plate.

3. A low noise food processor according to claim 2, wherein a sealing gasket is axially clamped between the hotplate and the cup to provide an axial clearance a > 0mm between the hotplate and the cup and/or the cup holder, respectively.

4. A low noise food processor as defined in claim 1, wherein said housing assembly further includes a support bracket secured to said base, said power heating assembly being secured to and flexibly connected to said support bracket.

5. A low noise food processor according to claim 4, wherein the processing cup assembly comprises a cup holder and a cup body mounted to the cup holder, the powered heating assembly comprises a heating plate disposed below the processing cup assembly, and the support frame is flexibly connected to the heating plate and/or the cup holder, respectively.

6. A low noise food processor according to claim 5, wherein the support frame is provided with mounting posts which pass through the heating plate and the cup in turn and securely connect the heating plate and the cup.

7. A low noise food processor as defined in claim 1, wherein said processing cup assembly includes a cup holder and a cup body mounted to said cup holder, said food processor further comprising an upper bracket for securing said cup body, said upper bracket being flexibly connected to said cup body.

8. The low noise food processor of claim 7, further comprising an upper cover that snaps onto the upper bracket, wherein the upper cover is flexibly coupled to the cup.

9. A low noise food processor as defined in claim 7, wherein said upper frame surrounds at least a portion of said cup body with a gap between said cup body and said sidewall, said gap holding said first flexible mat.

10. A low noise food processor as defined in claim 7, wherein said cup body has a lip around its mouth, and said upper bracket holds a second flexible mat between said lip and said cup body.

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