CN116250739A - Low-noise food processor - Google Patents

Abstract

The invention relates to a small kitchen appliance, in particular to a low-noise food processor, which is characterized in that: including smashing the cup subassembly, setting in smashing the cup subassembly below and carrying out the pedestal that supports and the cover in smashing the cup subassembly outside, smash cup subassembly and casing contactless, just smash the cup subassembly and keep apart through the silica gel piece at the rim of a cup with the casing, smash the cup subassembly and position on the pedestal, wherein, be provided with flexible first shock attenuation piece between smashing cup subassembly and the pedestal, first shock attenuation piece keeps apart smashing cup subassembly and pedestal, smash the cup subassembly and including cup body and motor, the motor shaft of motor runs through the cup body and stretches into in the cup body. The crushing cup component of the food processor is isolated from the seat body in a damping way and is isolated from the rigid shell body so as not to be contacted with the seat body, so that vibration energy generated in the working process of the food processor can be absorbed and converted, and noise generated in the working process can be greatly reduced.

Description

Low-noise food processor

Technical Field

The invention relates to small kitchen appliances, in particular to a low-noise food processor.

Background

The current soybean milk machine cup in market includes shell and installs the metal in the shell in the cup, and wherein, the diapire of metal in the cup can be fixed in on the base through the screw direct fixation, and the metal in cup top can be provided with outside horizontal turn-ups, and the top edge of horizontal turn-ups dress in the shell is taken. For the soymilk machine, because the bottom wall of the metal inner cup is in direct contact with the base, and the horizontal flanging is in direct contact with the shell, vibration generated by the machine head can be transmitted to the shell of the cup body through the coupler in the soymilk making process of the soymilk machine, because the metal inner cup is in rigid contact with the shell and the base, continuous high-frequency impact vibration can be generated between the shell and the base and the metal inner cup while the shell and the base vibrate, and the impact vibration can generate harshness noise, so that the normal life and rest of a user are influenced.

Based on this, in order to reduce the shock impact of the metal inner cup with the outer shell, researchers will plug the silicone between the metal inner cup and the outer shell, and clamp the silicone in the gap between the metal inner cup and the outer shell by means of a squeeze mounting. Although this mounting means, the silica gel piece can absorb partial vibrations, reduces pulping noise, but the silica gel piece is in the compressed state by the extrusion all the time, and in metal inner cup and shell vibrations extrusion's in-process, the volume of taking place deformation is limited, therefore absorbs vibration energy also very limited to after long-term use, the silica gel piece is hardened easily, and loses the effect of deformation energy-absorbing easily. In addition, in the installation, the silica gel piece is clamped between the metal inner cup and the shell, so that interference fit is formed between the silica gel piece and the metal inner cup and between the silica gel piece and the shell, and therefore, when the metal inner cup is installed, the problem that the silica gel piece is difficult to install only by overcoming the elasticity of the silica gel piece is solved.

Disclosure of Invention

The invention aims to provide a food processor, wherein a crushing cup component of the food processor is isolated from a base body and is isolated from a rigid shell into a non-contact structure, and a cup opening of the crushing cup component floats relative to the shell, so that vibration energy generated in the working process of the food processor can be absorbed and converted, and noise generated in the working process can be greatly reduced.

In order to achieve the above purpose, the invention adopts the following technical scheme: a low noise food processor characterized by: including smashing the cup subassembly, setting in smashing the cup subassembly below and carrying out the pedestal that supports and the cover in smashing the cup subassembly outside, smash cup subassembly and casing contactless, just smash the cup subassembly and keep apart through the silica gel piece at the rim of a cup with the casing, smash the cup subassembly and position on the pedestal, wherein, be provided with flexible first shock attenuation piece between smashing cup subassembly and the pedestal, first shock attenuation piece keeps apart smashing cup subassembly and pedestal, smash the cup subassembly and including cup body and motor, the motor shaft of motor runs through the cup body and stretches into in the cup body.

Further, smash the cup subassembly still including setting up in the motor support of cup body below, smash the cup subassembly and pass through motor support location seat, wherein, first damping piece sets up between pedestal and motor support, and keeps apart both.

Further, a penetrating mounting hole is formed in the motor support, a screw column penetrating the mounting hole is arranged on the base, the first damping piece comprises a silica gel damping sleeve, and the silica gel damping sleeve is sleeved on the outer side of the screw column to isolate the motor support from the base;

or, be provided with spacing support on the motor support, first damping piece includes compression spring and silica gel damping sleeve, silica gel damping keeps apart motor support and spacing support, compression spring suit is in the outside of spacing post to keep apart spacing support and pedestal.

Further, a third damping piece for isolating the motor bracket from the cup body is arranged between the motor bracket and the cup body;

alternatively, the motor is fixed to the motor bracket.

Further, the seat body is positioned in the shell;

or the seat body and the shell are integrally formed.

Further, the crushing cup assembly further comprises a heating pipe arranged on the cup body;

or the shell is a cup shell, the seat body is a base, and the base is arranged at the bottom of the cup shell;

or the top of the cup body is provided with an outward flanging, the shell is a cup shell sleeved outside the cup body, and the silica gel piece is arranged between the flanging and the top edge of the cup shell;

further, an annular installation gap is formed between the crushing cup assembly and the shell, and the silica gel piece is sleeved at the cup opening and is arranged in the installation gap.

Further, the first damping piece comprises a plurality of silica gel damping sleeves, and a connecting seam is formed in each silica gel damping sleeve;

or, the first damping piece is a rubber pad, and the rubber pad isolates the crushing cup component from the seat body.

Further, the cup body is a metal cup body or a glass cup body or a ceramic cup body.

Further, the cup mouth of the crushing cup assembly floats radially and axially relative to the shell.

After adopting above-mentioned technical scheme, owing to smash between cup subassembly and the pedestal and keep apart through first shock attenuation piece, and smash cup subassembly and not contact with the casing, keep apart through the silica gel piece between the two, consequently, at the in-process of food processor work, between rigid smashing cup subassembly and the casing, and can not take place the vibrations striking of high frequency between smashing cup subassembly and the pedestal, isolated the production of vibrations from the source, and, first shock attenuation piece still has the effect of absorbing partial vibration energy, first shock attenuation piece can dispel partial vibration energy conversion self heat energy owing to having the damped unique characteristic. Meanwhile, the cup mouth of the crushing cup assembly can float relative to the shell, and part of vibration energy of the cup mouth of the crushing cup assembly can be converted into kinetic energy of the crushing cup assembly in the floating process, so that further attenuation of the vibration energy is realized. Therefore, the food processor can greatly reduce vibration noise generated in the working process, and greatly improve the acquisition sense and experience sense of consumers.

Drawings

The invention is further described below with reference to the accompanying drawings:

fig. 1 is a schematic view of a food processor according to a first embodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of a left side view of an embodiment of the present invention;

FIG. 3 is an enlarged schematic view of FIG. 2A;

FIG. 4 is a schematic view of an exploded view of the cup assembly and the connecting ring;

FIG. 5 is a schematic cross-sectional view of a front view of an embodiment of the present invention;

FIG. 6 is an enlarged schematic view of the structure shown at B in FIG. 5;

FIG. 7 is an enlarged schematic view of FIG. 5C;

FIG. 8 is a schematic diagram of an exploded view of a whole machine according to an embodiment of the present invention;

FIG. 9 is a schematic diagram of a second embodiment of the present invention;

FIG. 10 is a schematic diagram of a third embodiment of the present invention;

FIG. 11 is a partially exploded view of a third embodiment of the present invention;

FIG. 12 is a schematic diagram of a fourth embodiment of the present invention;

FIG. 13 is an enlarged schematic view of the structure of FIG. 12 at D;

fig. 14 is a schematic diagram of the whole structure of a fourth embodiment of the present invention;

FIG. 15 is a schematic diagram of a fifth embodiment of the present invention;

FIG. 16 is an enlarged schematic view of the structure of FIG. 15 at E;

fig. 17 is a schematic structural diagram of a sixth embodiment of the present invention.

Detailed Description

Embodiment one:

fig. 1 to 8 are schematic structural views of a first embodiment of the present invention. The utility model provides a food processor, includes casing 1 and installs the cup subassembly 2 in casing 1, have cyclic annular installation clearance (not marked in the figure) between casing 1 and the cup subassembly 2 for cup subassembly 2 and casing 1 do not contact, and the installation clearance department is provided with the flexible connecting piece 3 that connects casing 1 and cup subassembly 2 into an organic whole respectively, wherein, the one end of connecting piece 3 is fixed in on casing 1, and the other end is fixed in on the cup subassembly 2, realizes that the rim of a cup of cup subassembly 2 can float relative casing 1.

In this embodiment, the connecting piece 3 is a connecting ring of silica gel surrounding the cup opening 21 of the cup assembly, an inner ring of the connecting ring is fixed on the cup opening 21, and an outer ring of the connecting ring is fixed on the housing 1, so that the connecting ring seals an installation gap between the housing 1 and the cup opening 21. The shell 1 comprises a fixing support 11 and an upper shell 12 covered on the outer sides of the cup body assembly 2 and the fixing support 11, the upper shell 12 and the fixing support 11 are fixed through screws (not marked in the figure), and the upper shell 12 and the fixing support 11 clamp the outer ring of a fixed connection ring to realize connection and sealing of the connection ring and the shell 1, in order to prevent the outer ring of the connection ring from falling out from between the upper shell 12 and the fixing support 11, a falling-off-preventing surrounding edge 33 is further arranged on the outer ring of the connection ring, meanwhile, in order to enhance the sealing effect between the connection ring and the shell 1, sealing ribs (not marked in the figure) are further arranged on the outer ring of the connection ring, and the upper shell 12 compresses the sealing ribs on the fixing support 11.

As shown in fig. 4, the cup opening 21 is provided with an outward flange 211, the flange 211 is provided with a downward recessed annular groove 210, and the bottom surface of the annular groove 210 is provided with a through flange through hole 212, wherein the inner ring of the connecting ring is provided with an annular positioning edge 31 inserted into the annular groove 210, and the bottom surface of the annular positioning edge 31 is provided with a buckle plug 32, when the annular positioning edge 31 is inserted into the annular groove 210, the buckle plug 32 is plugged into the flange through hole 212 and is clamped at the outer edge of the flange through hole 212, so as to realize connection and sealing between the connecting ring and the cup opening 21.

As shown in fig. 3, the upper casing 12 is further provided with a latch 13, a cover opening button 14 for pushing the latch 13 to move, and a spring 15, the cup opening 21 is covered with a cover body 4, the cover body 4 is provided with a slot 43 into which the latch 13 is clamped, wherein the cover body 4 and the cup opening 21 are sealed by a sealing ring (not shown in the drawing), and the risk of pulp overflow in the pulping process can be prevented.

In the actual use process, the clamping tongue is fixed on the shell, the clamping groove is formed in the cover body, and due to the influence of assembly tolerance and size chain design, normal pressing of the cover body often occurs, and the clamping tongue cannot be clamped into the clamping groove, namely, the situation that the cover cannot be closed occurs. However, in this embodiment, even if the normal lid-closing latch cannot be snapped into the latch groove, since the cup assembly is flexibly connected to the housing, the cup opening is floatable relative to the housing, and after the pressure applied to the lid is increased, the lid will press the cup assembly downward, so that the cup assembly has a small displacement amount downward, thereby ensuring that the latch groove on the lid and the latch tongue on the housing can be aligned to complete the closing of the lid. Therefore, the scheme of the embodiment is superior to the mounting structure that the cup body and the shell are rigidly fixed and the small displacement of the cup body cannot occur in the prior art.

As shown in fig. 5, 6 and 7, in this embodiment, the cup assembly 2 is a pulverizing cup assembly, and the pulverizing cup assembly includes a cup body 22, a motor support 23 disposed below the cup body 22, and a motor 24 fixed on the motor support 23, and a third shock absorbing member 25 isolating the motor support 23 and the cup body 22 is disposed between the motor support and the cup body 22. Meanwhile, in this embodiment, a base 16 for supporting the cup assembly is disposed below the motor support 23, and the base 16 is located in the upper housing 12, where a first shock absorbing member 5 for isolating the base 16 and the motor support 23 is disposed between them.

In this embodiment, the motor support 23 is provided with a through mounting hole 230, the base 16 is provided with a screw post 161 penetrating through the mounting hole 230, the first damping member 5 is a silica gel damping sleeve sleeved outside the screw post 161 and isolating the motor support 23 from the base 16, and the screw a is fastened on the screw post 161, so that the motor support 23 is fixed on the base 16. In this embodiment, the motor support 23 is fixed with the seat 16 by four screws, wherein, every two silica gel damping sleeves are integrally formed on the silica gel matrix, so that the molding and the installation of the silica gel damping sleeves are more convenient, and the opening of each silica gel damping sleeve is provided with a connecting seam, so that when the silica gel damping sleeve is extruded during the screw fixation, the silica gel damping sleeve can deform through the connecting seam, and the extrusion stress of the silica gel damping sleeve is reduced.

In this embodiment, keep apart through the silica gel damping sleeve between cup body subassembly and the pedestal, and the installation clearance department between rim of a cup and the casing is provided with flexible go-between and is connected and seal cup body subassembly and casing, but the rim of a cup of cup subassembly is floatable (including radial trace swing and axial trace removal) relative to the casing. Because keep apart through first shock attenuation piece between cup subassembly and the pedestal, and cup subassembly and casing contact, consequently, between food processor work's in-process, and can not take place the vibrations striking of high frequency between rigid cup subassembly and the pedestal, keep apart the production of vibrations from the source, and, first shock attenuation piece still has the effect of absorbing partial vibration energy, and first shock attenuation piece can dispel partial vibration energy conversion self heat energy owing to having the shock attenuation unique characteristic. Meanwhile, the cup mouth of the cup body assembly can float relative to the shell, and part of vibration energy of the cup mouth of the cup body assembly can be converted into kinetic energy of the cup body assembly in the floating process, so that further attenuation of the vibration energy is realized. Therefore, the food processor of the embodiment can greatly reduce vibration noise generated in the working process, and greatly improve the acquisition sense and experience sense of consumers.

In this embodiment, since the upper end of the cup assembly is isolated from the housing by the connection ring and the lower end is isolated by the silicone damping sleeve, the cup assembly is not in hard contact with the rigid housing, and the path of vibration energy generated by the cup assembly to the housing is completely isolated. Meanwhile, as the connecting ring and the silica gel damping sleeve are flexible silica gel pieces, the connecting ring and the silica gel damping sleeve have isolation function and function of absorbing vibration energy through deformation, even if vibration energy generated by the cup body assembly is transmitted to the shell, the vibration energy is greatly weakened. In addition, in this embodiment, since the motor vibration is a source of vibration noise, when the vibration energy generated by the motor is transmitted to the motor support, a third damping member is further disposed between the motor support and the cup body, and the third damping member can also isolate and absorb the vibration energy, so that the vibration energy is weakened when transmitted to the cup body. Therefore, the embodiment has triple vibration and noise reduction effects, and can greatly reduce vibration noise.

It should be noted that, in this embodiment, the outer ring of the connecting ring is clamped and fixed by the upper housing and the fixing bracket, and of course, in this embodiment, the upper housing and the fixing bracket may also be a housing with an integrally formed structure, where the connecting manner of the connecting ring and the housing may have various structures, for example, the outer ring of the connecting ring and the housing are integrally formed by two-shot molding, or are adhered to form an integral body, or are integrally connected by other fixing structures. It is also contemplated that the inner ring of the coupling ring may be coupled to the cup assembly in a variety of configurations, such as in the same manner as described for the housing.

For the embodiment, the motor support is isolated from the base body through the first damping part, and although the motor support and the base body are positioned through the screws, the first damping part is a silica gel damping sleeve with a certain deformation amount, and even if the lower end of the cup body assembly is fixed with the base body, the connection position and state of the cup mouth at the upper end of the cup body assembly with the upper shell and the fixing support can be adjusted in a radial and axial self-adaptive manner, namely, the cup mouth can float relative to the shell. Of course, in this embodiment, the motor support and the base may not be directly fixed, for example, a through mounting hole is formed in the motor support, a limiting post penetrating into the mounting hole is formed in the base, the first damping member is a compression spring sleeved outside the limiting post and isolating the motor support from the base, and the limiting post is matched with the mounting hole to limit the radial swing of the cup assembly, so that the cup assembly is positioned on the base, and the cup opening of the cup assembly is floatable relative to the shell.

The food processor of the embodiment is of a frame structure with a lower motor, and can be a soymilk machine with an upper motor, and the cup body component can be a metal cup body, a glass cup body, a ceramic cup body, a plastic cup body or the like. In addition, for the soymilk machine with the motor arranged on the upper part, the shell can be integrally formed with the base body or the base under the cup body component.

Of course, the connecting piece of this embodiment also can be the spring, and with the one end of spring taut on the casing, the other end is taut on the rim of a cup of cup subassembly, realizes that cup subassembly is fixed in the casing through the mode of spring hoist and mount. At this time, a sealing member for sealing the installation gap may be provided between the cup opening of the cup assembly and the housing, and the spring pulls the cup assembly and the housing so that the cup assembly and the housing clamp the sealing member. In this case, the spring has only a connecting function, and the sealing function is a sealing member, and the connecting and sealing functions are mutually independent members.

It should be noted that, the arrangement of the connecting piece at the installation gap in the embodiment includes the arrangement of the connecting piece in the installation gap space, and also includes the arrangement of the connecting piece between the cup opening and the upper surface of the housing adjacent to the installation gap.

The above structural changes of the present embodiment may be applied to other embodiments of the present invention.

Embodiment two:

fig. 9 is a schematic structural view of a second embodiment of the present invention. The first difference between this embodiment and the second embodiment is that: in this embodiment, the connection ring has a clasping portion 36 clasping the outer wall of the cup assembly 2, and the clasping portion 36 forms the inner ring of the connection ring. Meanwhile, an outward flanging 211 is arranged at the cup opening, and a step 361 for supporting the flanging 211 is arranged on the enclasping part 36, so that the inner ring of the connecting ring is fixed on the cup body assembly 2. Meanwhile, the outer ring of the connecting ring is provided with an inverted buckle 37, when the upper shell 12 is fixed with the fixed support 11 through the screw b and the upper shell 12 is fixed with the fixed support 11, the outer ring of the connecting ring is clamped, so that the inverted buckle 37 is tightly attached to the fixed support 11, and the outer ring of the connecting ring is fixed on the shell.

In this embodiment, the outer wall of the cup body assembly is tightly hooped through the enclasping part by the connecting ring, and the step holds the flanging, realizes that the inner circle of the connecting ring is firmly connected with the cup body assembly and is not loosened, and is provided with the back-off on the outer lane of the connecting ring, and when the outer lane of the connecting ring is tightly clamped by the upper casing and the fixed bolster, the back-off can prevent the connecting ring from loosening with the casing. The above structural changes of the present embodiment may be applied to other embodiments of the present invention.

Embodiment III:

fig. 10 and 11 are schematic structural views of a third embodiment of the present invention. The second difference between this embodiment and the second embodiment is that: in this embodiment, there is no fixing support, a through hole 100 is provided on the side wall of the housing 1, a buckling plug 38 is provided on the outer ring of the connection ring, the buckling plug 38 is plugged into the through hole 100 and is clamped at the outer edge of the through hole 100, so as to fix the outer ring of the connection ring on the housing 1. At the same time, a clip 6 is provided on the outer side of the clasping portion 36 to clasp the clasping portion 36.

The clamp 6 in this embodiment includes a left clamp 61 and a right clamp 62, and the left clamp 61 and the right clamp 62 are fixed by a screw c to fasten the clasping portion 36 to the outer wall of the cup assembly 2.

The fixing member for tightening the clasping portion in this embodiment is not limited to the clip in this embodiment, and may be a binding buckle or other fastening rope. The above structural variations of the present embodiment can also be applied to other embodiments of the present invention.

Embodiment four:

fig. 12, 13 and 14 are schematic structural views of a fourth embodiment of the present invention. The present embodiment is different from the above embodiment in that the mounting structure of the motor bracket and the base is different. In this embodiment, the motor support 23 is provided with a through mounting hole 230, a limit support 7 with a screw post 71 is disposed below the mounting hole 230, the screw post 71 penetrates into the mounting hole 230, a screw d is fastened on the screw post 71, so that the limit support 7 is fixed on the motor support 23, the lower portion of the limit support 7 is provided with a limit post 72, the base 16 is provided with a limit cavity 162 for the insertion of the limit post 72, the limit cavity 162 is surrounded by a rib 163 on the base 16, wherein the first shock absorbing member comprises a silica gel shock absorbing sleeve 51 and a compression spring 52, the silica gel shock absorbing sleeve 51 is sleeved outside the screw post 71 and isolates the motor support 23 from the limit support 7, the compression spring 52 is sleeved outside the limit post 72, one end of the compression spring is abutted against the limit cavity 162 of the base, and the other end of the compression spring is abutted against the limit support 7, so as to isolate the limit support 7 from the base 16.

In this embodiment, the cup assembly and the base are indirectly isolated by the compression spring, which has the same beneficial effects as those of the above embodiment, and will not be described here again. It should be noted that, the lower part of the motor bracket of the embodiment also needs not to be provided with a limit bracket, and the motor bracket is directly isolated from the seat body by the compression spring. The above structural changes of the present embodiment may be applied to other embodiments of the present invention.

Fifth embodiment:

fig. 15 and 16 are schematic structural views of a fifth embodiment of the present invention. The embodiment is a cup of soybean milk machine, including cup subassembly 2, suit in the casing 1 of cup subassembly outside and be used for the pedestal 16 of location cup subassembly, wherein, cup subassembly 2 is the metal cup that has the heating pipe, and casing 1 is the cup shell, and pedestal 16 is the base that is used for fixed metal cup, metal cup bottom is provided with screw post 29, is provided with corresponding screw hole 160 on the base, and the cover is equipped with first shock-absorbing member 5 in the screw e outside, and this first shock-absorbing member 5 is flexible rubber pad, and first shock-absorbing member 5 keeps apart metal cup and base. Meanwhile, the cup mouth of the metal cup body is positioned, an annular installation gap 101 is formed between the metal cup body and the cup body outer shell, the installation gap 101 separates the metal cup body from the cup body outer shell, the top of the metal cup body is further provided with an outward flanging 211, the flanging 211 is higher than the top edge of the cup body outer shell and is not contacted with the top edge of the cup body outer shell, and meanwhile, the flanging 211 protrudes out of the outer side of the top edge of the cup body outer shell so as to shield the installation gap 101, conceal the installation gap 101 and prevent slurry from flowing into the installation gap 101 in the slurry pouring process.

For this embodiment, the metal cup is isolated from and secured to the base, and the rim of the metal cup does not contact the cup shell, with the rim of the metal cup floating relative to the cup shell. In this embodiment, since the bottom of the metal cup is fixed, when the metal cup is to be floated relative to the shell, the metal cup does not contact with the shell of the cup, and the width C of the installation gap is required to be not less than 1mm. If the width of the installation gap is smaller than 1mm, the collision between the metal cup body and the cup body shell is not excluded in the working process of the soymilk machine, so that high-frequency collision noise is possibly generated. Of course, the heights of the metal cups are different, and the widths of the installation gaps are also different, and when the heights of the metal cups are smaller than 120mm, the widths C of the installation gaps are generally 1 mm-2 mm, and the heights of the metal cups are 140 mm-220 mm, so that the widths C of the installation gaps are preferably 3 mm-5 mm.

It should be noted that, the shielding part for shielding the installation gap in this embodiment is not limited to the flange provided on the metal cup body in this embodiment, and may be a flange protruding inwards provided on the cup body shell, or flanges shielding the installation gap may be provided on both the metal cup body and the cup body shell. It should be noted that the above structural changes of the present embodiment may also be applied to other embodiments of the present invention.

Example six:

fig. 17 is a schematic structural view of a sixth embodiment of the present invention. This embodiment is an improvement over the fifth embodiment. The fifth embodiment is different from the fifth embodiment in that: in this embodiment, a second shock absorbing member 8 is disposed in the installation gap 101 to isolate the metal cup from the cup shell, and the second shock absorbing member 8 is sleeved at the cup mouth of the metal cup.

For this embodiment, the cup opening of the metal cup is required to be floatable relative to the cup shell, so that the second damping member needs to have a larger deformation amount, and generally the deformation amount of the second damping member is required to be not less than 1mm, if the deformation amount of the second damping member is less than 1mm, the cup opening of the metal cup may not be floatable relative to the cup shell, at this time, vibration energy cannot be converted into motion energy, and accordingly generated noise will be larger. In this embodiment, the deformation amount of the second shock absorbing member is specifically the deformation amount that is still present when the second shock absorbing member is clamped in the installation gap. If the height of the metal cup body is less than 120mm, the deformation amount of the second shock absorbing member is generally 1mm to 2mm, and the height of the metal cup body is 140mm to 220mm, so the deformation amount of the second shock absorbing member is preferably 3mm to 5mm. It should be noted that the above structural variations of the present embodiment may also be applied to other embodiments of the present invention.

It will be appreciated by persons skilled in the art that the present invention includes, but is not limited to, the accompanying drawings and what has been described in the foregoing detailed description. Any modifications which do not depart from the functional and structural principles of the present invention are intended to be included within the scope of the appended claims.

Claims (10)

1. A low noise food processor characterized by: including smashing the cup subassembly, setting in smashing the cup subassembly below and carrying out the pedestal that supports and the cover in smashing the cup subassembly outside, smash cup subassembly and casing contactless, just smash the cup subassembly and keep apart through the silica gel piece at the rim of a cup with the casing, smash the cup subassembly and position on the pedestal, wherein, be provided with flexible first shock attenuation piece between smashing cup subassembly and the pedestal, first shock attenuation piece keeps apart smashing cup subassembly and pedestal, smash the cup subassembly and including cup body and motor, the motor shaft of motor runs through the cup body and stretches into in the cup body.

2. The low noise food processor of claim 1, wherein: the crushing cup assembly further comprises a motor support arranged below the cup body, and the crushing cup assembly is positioned on the seat through the motor support, wherein the first damping piece is arranged between the seat body and the motor support and isolates the seat body and the motor support.

3. The low noise food processor of claim 2, wherein: the motor support is provided with a penetrating mounting hole, the base is provided with a screw column penetrating the mounting hole, the first damping piece comprises a silica gel damping sleeve, and the silica gel damping sleeve is sleeved on the outer side of the screw column to isolate the motor support from the base;

or, be provided with spacing support on the motor support, first damping piece includes compression spring and silica gel damping sleeve, silica gel damping keeps apart motor support and spacing support, compression spring suit is in the outside of spacing post to keep apart spacing support and pedestal.

4. The low noise food processor of claim 2, wherein: a third damping piece for isolating the motor bracket and the cup body is arranged between the motor bracket and the cup body;

alternatively, the motor is fixed to the motor bracket.

5. The low noise food processor of claim 1, wherein: the seat body is positioned in the shell;

or the seat body and the shell are integrally formed.

6. The low noise food processor of claim 1, wherein: the crushing cup assembly further comprises a heating pipe arranged on the cup body;

or the shell is a cup shell, the seat body is a base, and the base is arranged at the bottom of the cup shell;

or, the top of the cup body is provided with an outward flanging, the shell is a cup shell sleeved outside the cup body, and the silica gel piece is arranged between the flanging and the top edge of the cup shell.

7. The low noise food processor of claim 1, wherein: an annular installation gap is formed between the crushing cup assembly and the shell, and the silica gel piece is sleeved at the cup opening and is arranged in the installation gap.

8. The low noise food processor of claim 1, wherein: the first damping piece comprises a plurality of silica gel damping sleeves, and a connecting seam is formed in each silica gel damping sleeve;

or, the first damping piece is a rubber pad, and the rubber pad isolates the crushing cup component from the seat body.

9. The low noise food processor of claim 1, wherein: the cup body is a metal cup body or a glass cup body or a ceramic cup body.

10. The low noise food processor of claim 1, wherein: the cup mouth of the crushing cup assembly floats radially and axially relative to the shell.

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