CN220210189U - Intelligent food transmission control system and food processing equipment - Google Patents

Abstract

The utility model discloses an intelligent food transmission control system and food processing equipment. The intelligent food transmission control system comprises: the device comprises a case, a control center, a permanent magnet motor, a transmission mechanism, an output terminal and a terminal feedback element; the permanent magnet motor is provided with a variable frequency controller which is electrically connected with the control center; the permanent magnet motor transmits driving force to the output terminal through the transmission mechanism; the output terminal is arranged in a working area, and the working area is used for placing food raw materials; the terminal feedback element comprises a temperature sensor electrically connected with the control center. The utility model has the advantages that the heat dissipation capacity of the permanent magnet motor is small, a heat dissipation fan is not needed to be additionally arranged, the volume of the case is effectively reduced, the whole volume and noise are reduced, the heat output is small, the control center can be matched and adjusted in real time according to the temperature parameters fed back by the temperature sensor, the rotating speed and the torsion of the output terminal can be accurately measured, and the food temperature parameters of a working area can be accurately measured, so that various parameters of standardized production of food can be accurately executed.

Description

Intelligent food transmission control system and food processing equipment

Technical Field

The utility model relates to the technical field of food processing equipment, in particular to an intelligent food transmission control system and food processing equipment.

Background

Food processing equipment refers to mechanical equipment that processes food raw materials into finished or semi-finished products. For example: dough mixer, dough press, vegetable cutter, meat grinder, etc.

The existing food processing equipment generally uses a variable-frequency single-phase motor, and is matched with a gearbox and a belt transmission structure to realize power transmission. For example, patent No. CN201820094481.0 discloses a variable frequency double-acting dough mixer, which uses a frequency converter to control the motor rotation speed and torque of a single-phase motor, so that the motor output meets the actual dough mixing requirement.

In order to switch multiple torque gears, a complex gearbox structure is often required to be arranged, and speed change adjustment is carried out in a mode of multistage gear sets or planetary gears and the like; for example, CN202222618000.0 discloses a gearbox for a food stirring device, which utilizes a multistage gear set in combination with a gear lever to achieve a variable speed adjustment.

However, the variable-frequency single-phase motor works by generating an alternating magnetic field in a mode that alternating current is required to pass through the stator winding; therefore, the single-phase motor inevitably suffers from excitation loss during operation, and the damage is transferred to the outside environment by heat dissipation, and is often discharged by a radiator fan. On one hand, under the combination of elements such as a cooling fan, the whole motor and noise are larger, and the whole volume of food processing equipment is difficult to reduce due to the complex gearbox structure; on the other hand, in the production process of standardized food stirring processing and the like, high requirements on operation temperature, time and load torque force are often met; during processing, heat generated in the stirring and cutting process and heat generated by the motor, so that the food processing temperature parameters are difficult to accurately control.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the utility model provides an intelligent food transmission control system and food processing equipment.

The technical scheme adopted by the embodiment of the utility model for solving the technical problems is as follows: an intelligent food drive control system comprising: the device comprises a case, a control center, a permanent magnet motor, a transmission mechanism, an output terminal and a terminal feedback element;

the permanent magnet motor is arranged on the chassis, the permanent magnet motor is provided with a variable frequency controller, and the variable frequency controller is electrically connected with the control center; the permanent magnet motor transmits driving force to an output terminal through a transmission mechanism; the output terminal is arranged in a working area, and the working area is used for placing food raw materials;

the terminal feedback element comprises a temperature sensor electrically connected with the control center; the temperature sensor can detect the temperature of the food raw materials in the working area and feed back the temperature to the control center.

Optionally, the terminal feedback element further comprises a load torsion sensor; the load torsion sensor is arranged on the output terminal, can detect the load torsion of the output terminal, and feeds back the load torsion to the control center.

Optionally, the temperature sensor is mounted on the output terminal.

Optionally, the temperature sensor is mounted to the working area.

Optionally, the transmission mechanism comprises a reduction gearbox and a belt transmission assembly.

Optionally, the control center is provided with a gear switching module.

Optionally, the control center is provided with a time control module.

Optionally, the control center is provided with a remote communication module; the remote communication module comprises one or more of a Bluetooth module, a WIFI module and a cellular communication module.

The permanent magnet motor uses the permanent magnet to provide excitation, so that the motor structure is simpler, the processing and assembly cost is reduced, a collector ring and an electric brush which are easy to cause problems are omitted, and the operation reliability of the motor is improved; and because exciting current is not needed, exciting loss is avoided, and the efficiency and the power density of the motor are improved.

The utility model has the beneficial effects that: the variable-frequency single-phase motor in the food processing equipment is replaced by the permanent magnet motor, and because the permanent magnet motor provides excitation by the permanent magnet without exciting current and excitation loss, the heat dissipation capacity of the permanent magnet motor is small, a cooling fan is not required to be additionally arranged, the volume of a machine case can be effectively reduced, the whole volume of the processing equipment is reduced, the working noise is effectively reduced, the heat output is small, the food temperature parameters of a working area can be measured more accurately, the matching time and the output torque force are accordingly matched, various parameters of standardized production of food are more accurately executed, and the difference between the produced semi-finished products and finished products is lower; in addition, the permanent magnet motor has small rotational inertia, large allowable pulse torque and can still provide larger and stable output torque at low rotation speed, so that the requirements of working conditions of low rotation speed and high torque in the food processing processes such as dough kneading, stirring and the like are met. The permanent magnet motor is provided with a variable frequency controller, the variable frequency controller is electrically connected with the control center, and the output rotating speed can be adjusted by changing the input current of the permanent magnet motor through the variable frequency controller; the temperature sensor in the working area can detect the temperature of the food raw materials in the working area and feed back the temperature to the control center; the control center changes the input current of the permanent magnet motor through the variable frequency controller according to the temperature parameters fed back by the temperature sensor, and can match and adjust the rotating speed and the torsion of the output terminal in real time, so that the rotating speed and the torsion of the output terminal can be changed with the change of the state of the food materials, and more intelligent matching and adjustment can be achieved.

The utility model also provides another technical scheme: a food processing device comprises the intelligent food transmission control system.

In order to make the above objects, features and advantages of the present utility model more comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

The foregoing and/or additional aspects and advantages of the utility model will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic diagram of an intelligent food drive control system according to one embodiment of the present utility model;

FIG. 2 is a schematic view of a food processing device according to an embodiment of the present utility model;

fig. 3 is a schematic structural view of a food processing device according to another embodiment of the present utility model.

Description of main reference numerals:

10. a chassis; 20. a control center; 21. a gear switching module; 22. a time control module; 23. a remote communication module; 30. a permanent magnet motor; 31. a variable frequency controller; 40. a transmission mechanism; 41. a reduction gearbox; 42. a belt drive assembly; 50. an output terminal; 60. a terminal feedback element; 61. a temperature sensor; 62. a load torque sensor; 70. a work area.

Detailed Description

Reference will now be made in detail to the present embodiments of the present utility model, examples of which are illustrated in the accompanying drawings, wherein the accompanying drawings are used to supplement the description of the written description so that one can intuitively and intuitively understand each technical feature and overall technical scheme of the present utility model, but not to limit the scope of the present utility model.

In the description of the present utility model, plural means two or more, and greater than, less than, exceeding, etc. are understood to not include the present number, and the above, below, within, etc. are understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present utility model, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present utility model and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present utility model.

In the present utility model, unless clearly defined otherwise, the terms "disposed," "mounted," "connected," and the like are to be construed broadly and may be connected directly or indirectly through an intermediary; the connecting device can be fixedly connected, detachably connected and integrally formed; may be a mechanical connection; may be a communication between two elements or an interaction between two elements. The specific meaning of the words in the utility model can be reasonably determined by a person skilled in the art in combination with the specific content of the technical solution.

Examples

Referring to fig. 1 to 3, an intelligent food transmission control system according to the present utility model includes: the device comprises a case 10, a control center 20, a permanent magnet motor 30, a transmission mechanism 40, an output terminal 50 and a terminal feedback element 60;

the permanent magnet motor 30 is arranged on the case 10, the permanent magnet motor 30 is provided with a variable frequency controller 31, and the variable frequency controller 31 is electrically connected with the control center 20; the permanent magnet motor 30 transmits the driving force to the output terminal 50 through the transmission mechanism 40; the output terminal 50 is arranged in a working area 70, and the working area 70 is used for placing food raw materials;

the terminal feedback element 60 includes a temperature sensor 61 electrically connected to the control center 20; the temperature sensor 61 may detect the temperature of the food ingredients in the work area 70 and feed back to the control center 20.

The permanent magnet motor uses the permanent magnet to provide excitation, so that the motor structure is simpler, the processing and assembly cost is reduced, a collector ring and an electric brush which are easy to cause problems are omitted, and the operation reliability of the motor is improved; and because exciting current is not needed, exciting loss is avoided, and the efficiency and the power density of the motor are improved.

In the utility model, the variable frequency single-phase motor in the food processing equipment is replaced by the permanent magnet motor 30, and because the permanent magnet motor 30 provides excitation with permanent magnet without exciting current and excitation loss, the heat dissipation capacity of the permanent magnet motor 30 is small, a cooling fan is not required to be additionally arranged, the volume of the machine case 10 can be effectively reduced, the whole volume of the processing equipment is reduced, the working noise is effectively reduced, the heat output is smaller, the food temperature parameter of the working area 70 can be measured more accurately, the matching time and the output torque force are accordingly matched, various parameters of standardized production of food are more accurately executed, and the difference between the produced semi-finished product and the finished product is lower; in addition, the permanent magnet motor 30 has small rotational inertia, large allowable pulse torque and can still provide larger and stable output torque at low rotation speed, so that the requirements of working conditions of low rotation speed and high torque in the food processing processes such as dough kneading, stirring and the like are met. The permanent magnet motor 30 is provided with a variable frequency controller 31, the variable frequency controller 31 is electrically connected with the control center 20, and the output rotating speed can be adjusted by changing the input current of the permanent magnet motor 30 through the variable frequency controller 31; the temperature sensor 61 in the working area 70 can detect the temperature of the food raw material in the working area 70 and feed back to the control center 20; the control center 20 changes the input current of the permanent magnet motor 30 through the variable frequency controller 31 according to the temperature parameters fed back by the temperature sensor 61, and can match and adjust the rotation speed and the torsion of the output terminal 50 in real time, so that the change of the rotation speed and the torsion of the output terminal 50 and the state of the food materials can be achieved, and more intelligent matching and adjustment can be achieved.

On food processing equipment such as dough mixers, mixers and the like, the existing variable-frequency single-phase motor generally outputs torque force between 10Nm and 15Nm under the rated current of about 30A; and the output torque of the permanent magnet motor 30 can reach 20Nm to 30Nm under the rated current of about 30A. The permanent magnet motor 30 can output larger torsion force under smaller volume, and meets the requirements of food processing operation. In addition, the speed-adjustable range of the permanent magnet motor 30 is larger, the torque output at low rotation speed is stable, scalding is not easy to occur, and the processing conditions of low rotation speed and high-load torque food materials such as dough kneading and meat mincing are more met.

During processing of the food material, the resistance to be applied by the output terminal 50 varies with the form of the food material, such as the form of batter stirring, the form of meat material mixing, drawing, and the like. Therefore, the processing state of the food material can be reflected according to the change of the load resistance of the food material.

In some embodiments, the terminal feedback element 60 further includes a load torsion sensor 62; the load torque sensor 62 is mounted on the output terminal 50, and detects the load torque of the output terminal 50 and feeds back to the control center 20. The load torque sensor 62 is installed on the output terminal 50, and can detect the load torque of the output terminal 50, and feed back to the control center 20, and the control center 20 matches with the preset load torque of the food material according to the magnitude of the load torque, such as the load torque of the batter or the meat material in different states. Thereby adjust permanent-magnet machine 30's input current through the converter, and then adjust output torsion and rotational speed, more nimble matching adjusts the operating condition of food processing equipment output terminal 50, matches laminating standardized intelligent production.

In some embodiments, a temperature sensor 61 is mounted to the output terminal 50. For example, it may be mounted on a mixer head of a dough mixer or blender.

In some embodiments, the temperature sensor 61 is mounted to the work area 70. For food processing equipment such as dough mixers or blenders, a blender drum is provided for holding food material, at which time the blender drum serves as the working area 70, and the temperature sensor 61 may be mounted to the drum wall of the blender drum. For food processing equipment such as vegetable cutters and dough presses, the work area 70 is typically a flat base upon which the temperature sensor 61 may be mounted.

In this embodiment, the transmission mechanism 40 includes a reduction gearbox 41 and a belt transmission assembly 42. Since the permanent magnet motor 30 can output a larger torque force in a low rotation speed state, the reduction gearbox 41 only needs to be provided with a simple gear reduction structure, a complex planetary gear or a multi-stage gear reduction structure is not needed, and the structure of the reduction gearbox 41 can be obviously simplified.

In some embodiments, the arrangement of the reduction gearbox 41 may be omitted and the power transfer may be accomplished solely by a belt drive configuration while still meeting a steady torque demand at low output speeds of the permanent magnet motor 30. Further simplifying and shrinking the structure of the enclosure 10.

In the present embodiment, the control center 20 is provided with a gear switching module 21. The control center 20 is provided with a plurality of gear buttons or gear operation levers, and the output rotation speed and the output torque of the permanent magnet motor 30 can be switched through the frequency converter by the gear switching module 21, so that the working state of the output terminal 50 can be switched.

In the present embodiment, the control center 20 is provided with a time control module 22. The time control module can control the working time of the permanent magnet motor 30 and the time of different working states under different output torque forces.

In some embodiments, the control center 20 is provided with a remote communication module 23; the remote communication module 23 includes one or more of a bluetooth module, a WIFI module, and a cellular communication module. The control center 20 realizes wireless interaction with a mobile phone or other remote control terminals through a communication module, so that an operator can remotely control food processing equipment, control conveniently and realize the layout of an intelligent unmanned factory.

The utility model also provides another technical scheme: a food processing device comprises the intelligent food transmission control system.

Of course, the present utility model is not limited to the above-described embodiments, and those skilled in the art can make equivalent modifications or substitutions without departing from the spirit of the present utility model, and these equivalent modifications and substitutions are included in the scope of the present utility model as defined in the appended claims.

Claims (9)

1. An intelligent food drive control system, comprising: the device comprises a case (10), a control center (20), a permanent magnet motor (30), a transmission mechanism (40), an output terminal (50) and a terminal feedback element (60);

the permanent magnet motor (30) is arranged on the chassis (10), the permanent magnet motor (30) is provided with a variable frequency controller (31), and the variable frequency controller (31) is electrically connected with the control center (20); the permanent magnet motor (30) transmits driving force to an output terminal (50) through a transmission mechanism (40); the output terminal (50) is arranged in a working area (70), and the working area (70) is used for placing food raw materials;

the terminal feedback element (60) comprises a temperature sensor (61) electrically connected with the control center (20); the temperature sensor (61) can detect the temperature of the food ingredients in the working area (70) and feed back to the control center (20).

2. The intelligent food transmission control system of claim 1, wherein: the terminal feedback element (60) further comprises a load torsion sensor (62); the load torsion sensor (62) is mounted on the output terminal (50), and can detect the load torsion of the output terminal (50) and feed back the load torsion to the control center (20).

3. The intelligent food transmission control system of claim 1, wherein: the temperature sensor (61) is mounted to the output terminal (50).

4. The intelligent food transmission control system of claim 1, wherein: the temperature sensor (61) is mounted to the work area (70).

5. The intelligent food transmission control system of claim 1, wherein: the transmission mechanism (40) comprises a reduction gearbox (41) and a belt transmission assembly (42).

6. The intelligent food transmission control system of claim 1, wherein: the control center (20) is provided with a gear switching module (21).

7. The intelligent food transmission control system of claim 1, wherein: the control center (20) is provided with a time control module (22).

8. The intelligent food transmission control system of claim 1, wherein: the control center (20) is provided with a remote communication module (23); the remote communication module (23) comprises one or more of a Bluetooth module, a WIFI module and a cellular communication module.

9. A food processing apparatus, characterized in that: comprising the intelligent food drive control system of any one of claims 1-8.