Multifunctional food processor
Technical Field
The present invention relates to food processors, and more particularly, to a weighing structure for a food processor.
Background
Some existing food processors, for example: the soup cooker is provided with a weighing unit for weighing food conveniently. The realization mode of the weighing unit mainly comprises two modes, wherein a single electronic scale is fixed on the machine body of the food processor to realize the external weighing of the machine, so that when the weighing is carried out, other containers for containing food are needed to be used externally or the bowl container of the existing food processor is needed to be moved repeatedly, and the operation steps of weighing, peeling and the like are needed to be carried out, so that the weighing is complicated; the other is a way of fixing the three electronic scale sensors inside the machine body of the food processor and supporting the whole machine body by using the three electronic scales as fulcrums, and the weighing way adopts the three electronic scale sensors, so that the supporting points (also called feet) of the whole machine, which are correspondingly contacted with the supporting table surface, can be only three points, and when the whole machine operates at a high speed or stirs food at a high speed, the whole machine is easy to shake or move, so that the stability of the whole machine is poor.
Disclosure of Invention
The invention aims to solve the technical problems of the prior art, and provides a multifunctional food processor which can simply and conveniently realize weighing.
The technical scheme adopted by the invention for solving the technical problems comprises the following steps: provided is a food processor including a bowl assembly, a housing assembly, a movement assembly, and a base assembly; the shell component comprises a shell and weighing keys arranged on the shell; at least four electronic scale sensors are arranged at the bottom of the machine core assembly, the bowl assembly is arranged on the machine core assembly, and a gap exists between the bowl assembly, the machine core assembly and the machine shell assembly; the movement assembly takes the electronic scale sensors as supporting points and is arranged on the base assembly; the weighing key is controlled to weigh food in the bowl assembly arranged on the movement assembly.
In some embodiments, the base assembly includes a bottom case, and a plurality of supports are provided on the bottom case in an upward protruding manner, and each of the electronic scale sensors is correspondingly mounted on one of the supports.
In some embodiments, each of the electronic scale sensors is secured to a corresponding support by a fastener.
In some embodiments, the bottom shell is provided with a plurality of fixing columns in an upward protruding mode; the shell is fixedly connected with the bottom shell through fasteners arranged on the fixing columns.
In some embodiments, the base assembly is provided with at least four feet protruding downward for smooth support of the machine.
In some embodiments, the feet are in one-to-one correspondence with the electronic scale sensors.
In some embodiments, the electronic scale sensors are symmetrically distributed in the same horizontal plane.
In some embodiments, the deck assembly includes a deck to which the electronic scale sensors are secured by fasteners.
In some embodiments, the bowl assembly comprises a bowl body and a bowl seat, wherein a buckle is arranged on the outer side of the bowl seat; the movement assembly comprises a bowl fixing seat, and the bowl seat is clamped and fixed on the bowl fixing seat through the buckle.
In some embodiments, the food processor is a soup cooker.
Compared with the prior art, the food processor provided by the invention has the advantages that at least four electronic scale sensors are adopted as the supporting points of the machine core assembly and the base assembly, and the bowl assembly, the machine core assembly and the machine shell assembly are separated, so that the weighing of food in the bowl assembly arranged on the machine core assembly can be realized simply and conveniently by controlling the weighing keys on the machine shell.
Drawings
Fig. 1 is a perspective view of an embodiment of the food processor of the present invention, wherein the housing is partially cut away.
Fig. 2 is an exploded perspective view of an embodiment of the food processor of the invention.
Wherein reference numerals are as follows: 100. the bowl cover 13 bowl body 14 handle 15 buckle 16 bowl seat 17 shell 18 electronic scale circuit board 19 bottom shell 191 support 192 fixed column of the electronic scale base plate 19 of the bowl seat 18 electronic scale of the electronic scale base assembly 1 bowl fixing seat 2 safety switch control assembly 3 electronic scale sensor 4 core bottom plate 5 power panel 6 radiator fan 7 motor drive system 8 power switch 9 footing 10 line pressing code 11 measuring cup 12 bowl body 14 of the food processor a bowl assembly b shell assembly c electronic control unit.
Detailed Description
Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings.
Referring to fig. 1 and 2, the present invention, taking a soup cooker as an example, proposes a food processor 100 comprising: bowl assembly a, cabinet assembly b, movement assembly d, and base assembly e.
The bowl assembly a comprises: measuring cup 11, bowl lid 12, bowl body 13, handle 14, buckle 15 and bowl seat 16. Wherein, the bowl body 13 is a stainless steel heating bowl. The bowl 13 is combined with the bowl seat 16. The bowl cover 12 can be correspondingly arranged at the top end opening of the bowl body 13. The bowl cover 12 is provided with a central mounting hole. The measuring cup 11 may be correspondingly installed at the center mounting hole. The handle 14 is provided at a side of the bowl 13. The clasp 15 is arranged on the side of the bowl seat 16.
The housing assembly b comprises: a housing 17 and an electronic control unit c mounted on the housing 17. The electronic control unit c comprises a plurality of control keys which are arranged on the shell 17 and are exposed, wherein one of the control keys is a weighing key.
The movement assembly d includes: bowl fixing base 1, safety switch control assembly 2, four electronic scale sensors 3, core bottom plate 4, power strip 5, radiator fan 6 and motor drive system 7. Wherein, four electronic scale sensors 3 are symmetrically distributed. In the present embodiment, four electronic scale sensors 3 are distributed at four corners of a rectangle located in the horizontal plane, and are fixed to deck 4 with fasteners such as screws.
The base assembly e comprises: a power switch 8, four feet 9, a wire pressing code 10, an electronic scale circuit board 18 and a bottom shell 19. The bottom shell 19 is provided with four holders 191 for correspondingly holding the four electronic scale sensors 3. The feet 9 are in one-to-one correspondence with the electronic scale sensors 3. The bottom case 19 is also provided with fixing posts 192 to be coupled with the cabinet 17 by corresponding fasteners such as screws. In this structure, the movement assembly d is correspondingly placed on the base assembly e, and the four electronic scale sensors 3 on the movement assembly d are in one-to-one correspondence with the four holders 191 on the base assembly e, so that the whole movement assembly d only has the four electronic scale sensors 3 in contact with the bottom shell, and other parts are in a suspended state relative to the base assembly e.
In the present embodiment, first, the connection wires of the four electronic scale sensors 3 are connected to the electronic scale circuit board 18 on the base assembly e; then, after all the connecting leads are connected, the connecting leads are fixed on the relevant positions of the bottom shell 19 by the wire pressing code 10; then, the electric control unit c on the shell component b, the power board 5 on the core component d and the electronic scale circuit board 18 are connected by related connecting leads; after the connection is finished, the shell component b and the base component e are connected and fixed by screws; after the fixing, the movement component d and the shell component b are separated and have no mutual assembly relation and do not interfere with each other, so that the whole machine is assembled.
When the bowl assembly a is put into the bowl fixing seat 1 on the machine core assembly d, two buckles 15 on the bowl assembly a are buckled with the bowl fixing seat 1 on the machine core assembly d; then, the power supply is turned on, the power switch 8 is turned on, and the weighing key on the electric control unit c is pressed, so that the whole machine can be weighed. When weighing, the bowl component a only has an inter-assembly relation with the movement component d, and a certain interval exists between the bowl component a and the casing component b, so that the bowl component a and the casing component b have no inter-assembly relation. The realization mode of the weighing function is quite simple and convenient to operate; in addition, the bottom of the base assembly e can use four or more feet 9 to support the whole machine, so that good stability of the whole machine during operation can be ensured.
Compared with the prior art, the food processor 100 of the present invention has the advantages of: four supporting points are formed between the movement bottom plate 4 on the movement assembly d and the base assembly e by using four electronic scale sensors 3, so that the weighing of the whole machine can be realized; the bowl component a, the core component d and the base component e are mutually assembled, the bowl component a, the core component d and the shell component b are not assembled, a certain interval exists, and the whole machine weighing mode can be greatly convenient for a user to operate; in addition, the bottom of the base assembly e can use four or more bottom corners 9 to support the whole machine, so that the whole machine can work more stably.
It should be noted that the above description is given by taking four electronic scale sensors 3 as an example, and in other embodiments, the electronic scale sensors 3 may be five, six or more; the number of feet 9 mentioned above corresponds to the number of electronic scale sensors 3, which may also be different in other embodiments.
It should be understood that the foregoing embodiments are merely illustrative of the technical solutions of the present invention, and not limiting thereof, and that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art; such modifications and substitutions are intended to fall within the scope of the appended claims.