CN220588132U - Automatic discharging seasoning box - Google Patents

Abstract

The embodiment of the application discloses automatic unloading condiment box, including: the surface of the base is provided with at least one feeding hole for placing the material box and at least one discharging hole; the material box is arranged on the material inlet and is provided with a material storage cavity with an opening at the bottom and a discharging mechanism which is positioned below the material storage cavity and is in butt joint with the material inlet; the driving assembly is arranged in the base and is provided with a driving motor and a driving circuit connected with the driving motor; the bidirectional gear is arranged between the feeding port and the discharging port in the base, horizontally meshed with the output end of the driving assembly and detachably meshed with the material box up and down, and a material passing hole corresponding to the feeding port and the discharging port is arranged at the axial center of the bidirectional gear. The method can achieve the effects of taking materials, avoiding manual uncovering, conveniently controlling the using amount of the seasonings and ensuring the taste of dishes.

Description

Automatic discharging seasoning box

Technical Field

The embodiment of the application relates to the field of kitchen supplies, in particular to an automatic discharging seasoning box.

Background

Seasoning boxes used in home kitchens, whether in a single or multiple structures in a row, are manually opened during use. The seasoning box is complicated in taking operation, time-consuming, and difficult to control in dosage, and the taste of dishes is easily affected.

Disclosure of Invention

The embodiment of the application provides an automatic unloading condiment box to reach the effect that get the material and need not manual uncapping, convenient control condiment quantity, assurance dish taste.

For solving the technical problem, the embodiment of the application provides an automatic unloading condiment box, including:

the surface of the base is provided with at least one feed inlet and at least one discharge outlet;

the material box is arranged on the material inlet and is provided with a material storage cavity with an opening at the bottom and a discharging mechanism which is positioned below the material storage cavity and is in butt joint with the material inlet;

the driving assembly is arranged in the base and is provided with a driving motor and a driving circuit connected with the driving motor;

the bidirectional gear is arranged between the feeding port and the discharging port in the base, horizontally meshed with the output end of the driving assembly and detachably meshed with the material box up and down, and a material passing hole corresponding to the feeding port and the discharging port is arranged at the axial center of the bidirectional gear.

In some possible embodiments, the bidirectional gear comprises a horizontal base with an annular shape and a vertical base extending vertically upwards by the coaxial center of the inner edge of the horizontal base;

the outer edge of the horizontal base is provided with a horizontal outward external engaging tooth, and the upper edge of the vertical base is provided with a vertical upward upper engaging tooth;

the bottom of the material box is downwards provided with lower meshing teeth which are meshed with the upper meshing teeth in an up-down separable way.

In some possible embodiments, adjacent bidirectional gears and/or the bidirectional gears and the driving motor are/is connected through at least one intermediate wheel.

In some possible embodiments, the diameter of the intermediate wheel is greater than the diameter of the horizontal base; and/or, the bidirectional gear is staggered with the intermediate wheel; and/or the outside of the vertical base is also sleeved with a vertical reset spring which is abutted to the upper shell of the base.

In some possible embodiments, the driving circuit is provided with a switch assembly including any one of a smart voice switch, an electronic switch, and a mechanical switch.

In some possible embodiments, the mechanical switch assembly comprises:

the contact switch is arranged on the driving circuit;

the sliding plate is movably arranged below the bidirectional gear and is detachably contacted with the contact switch, and the sliding plate is provided with a discharging hole and a plurality of bone positions which are arranged in parallel along the moving direction of the sliding plate;

the switch handle assembly is arranged below the sliding plate and is connected with the sliding plate in a poking way.

In some possible embodiments, the front end of the bone site in the direction of movement is provided as a bevel; and/or the sliding plate is contacted with the contact switch through a horizontal reset spring; and/or the lower surface of the bidirectional gear is provided with an annular lower edge which is abutted with the upper surface of the sliding plate.

In some possible embodiments, the blanking mechanism comprises a rotating shaft assembly arranged along the axis of the storage cavity and with the top end extending into the bottom opening, and a blanking opening arranged below the rotating shaft assembly;

the material storage cavity is internally provided with a fixed ring, and the rotating shaft assembly comprises a rotating shaft rotatably fixed between the fixed ring and the material discharging opening and a shaft sleeve sleeved outside the rotating shaft.

In some possible embodiments, the rotating shaft assembly further comprises a scraping rod rotatably connected with the top output end of the rotating shaft along the horizontal direction; and/or

The blanking port is provided with a fixed wing with a hollow structure, and the bottom of the rotating shaft is arranged on the fixed wing with the hollow structure; and/or that the number of the groups of groups,

the bottom of the rotating shaft is provided with a worm structure; and/or

The lower end of the shaft sleeve is provided with a structure corresponding to the blanking opening and is attached to the inner wall of the shaft sleeve.

In some possible embodiments, the scraping rod is axially connected with the rotating shaft through a planetary gear, and the planetary gear comprises an inner gear ring, at least two planetary gears and a sun gear, which are arranged from outside to inside.

In some possible embodiments, the sun gear is disposed below the top output end of the rotating shaft, a circular table type planet carrier is disposed below the sun gear, the at least two planet gears are disposed on the planet carrier and are engaged with the sun gear, and/or the inner gear ring is disposed on the top inner wall of the shaft sleeve and is engaged with the at least two planet gears.

In some possible embodiments, the storage cavity comprises a hollow cylindrical structure arranged at the upper part of the material box and a large hopper structure arranged below the hollow cylindrical structure; and/or

The blanking opening is arranged into a small hopper structure;

and/or the blanking opening is downwards provided with lower meshing teeth.

In some possible embodiments, the switch handle assembly is integrally formed as a U-shaped structure, a top of the U-shaped structure is rotatably connected to the slide plate, and/or a bottom of the U-shaped structure is disposed obliquely with respect to a top thereof.

In some possible embodiments, a fixed pendant is provided on the back of the base; and/or the outer edge of the feed inlet is also provided with an annular boss which can extend into the bottom surface of the material box; and/or the bottom of the material box and the outer edge of the material inlet are provided with mutually matched fastening structures.

The beneficial effects of this application are:

according to the embodiment of the application, the blanking mechanism is arranged in the material box, the bidirectional gear which can be simultaneously meshed and connected with the driving motor in the horizontal direction and meshed and connected with the blanking mechanism in the vertical direction is arranged, and therefore the effects that the material taking is achieved, the material opening is not needed manually, the seasoning consumption is conveniently controlled, and the dish taste is guaranteed are achieved.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, a brief description will be given below of the drawings required for the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are some embodiments of the present application, and that other drawings may be obtained according to these drawings without the need for inventive effort for a person skilled in the art.

Fig. 1 is a schematic perspective view of an automatic feeding seasoning box according to an embodiment of the present application.

Fig. 2 is a schematic diagram showing a separation state of an automatic discharging seasoning box according to an embodiment of the present application.

Fig. 3 is an exploded view of an automatic blanking seasoning box of an embodiment of the present application.

Fig. 4 is a schematic cross-sectional view of an automatic blanking seasoning box of an embodiment of the present application.

Fig. 5 is a schematic side view of an automatic blanking seasoning box of an embodiment of the present application.

Fig. 6 is a schematic cross-sectional view of a cartridge in an automatic blanking seasoning cartridge according to an embodiment of the present application.

Fig. 7 is a schematic structural diagram of a blanking mechanism in an automatic blanking seasoning box according to an embodiment of the present application.

Fig. 8 is an exploded view of a blanking mechanism in an automatic blanking seasoning box according to an embodiment of the present application.

Fig. 9 is a schematic cross-sectional view of a drive switch assembly in an automatic feed seasoning box according to an embodiment of the present application.

Fig. 10 is an exploded view of the drive switch assembly in the automatic feed seasoning box of an embodiment of the present application.

Fig. 11 is a schematic view of a structure of one direction of a slide plate in an automatic discharging seasoning box according to an embodiment of the present application.

Fig. 12 is a schematic view of another orientation of a slide plate in an automatic feed seasoning box according to an embodiment of the present application.

Reference numerals illustrate:

1-base: 11-a feed inlet, 12-a discharge outlet, 13-a fixed buckle, 14-an annular boss, 15-a material box groove and 16-a fixed hanging piece;

2-magazine: 20-a feed opening, 201-lower meshing teeth and 202-fixed wings; 21-a storage cavity, 211-a hollow cylinder and 212-a large hopper; 22-blanking mechanism, 220-rotating shaft component, 221-rotating shaft, 222-shaft sleeve, 223-scraping rod, 224-worm, 225-planetary gear, 2251-annular gear, 2252-planetary gear, 2253-sun gear, 2254-planetary carrier, 2221-vertical beam and 2222-oblique beam; 23-fixing rings;

3-drive assembly: 31-driving motor, 32-driving circuit and 33-intermediate wheel;

4-bidirectional gear: 40-material passing holes, 41-horizontal bases, 42-vertical bases, 43-external meshing teeth, 44-upper meshing teeth and 45-annular lower edges;

5-a vertical return spring;

6-switch assembly: 61-contact switch, 62-slide plate, 63-switch handle assembly, 64-horizontal reset spring, 620-discharge hole, 621-bone position.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be described in detail by way of embodiments with reference to the accompanying drawings in the examples of the present application. Obviously, embodiments and features of embodiments in this application may be combined with each other without conflict.

It should be noted that: in the drawings, like or similar reference numerals refer to like or similar elements throughout or elements having like or similar functions; in the description of the present application, the terms "center," "longitudinal," "transverse," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present application and simplify description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and therefore should not be construed as limiting the scope of protection of the present application; in the description of the present application, "first", "second", etc. are used merely for distinguishing one from another, and do not denote their importance or order or the like.

In the description of the present application, unless explicitly stated and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, movably connected, or detachably connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, can be communicated with the inside of two elements, and the like. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context.

Referring to fig. 1-10, an embodiment of the present application discloses an automatic discharging seasoning box, which includes:

the surface of the base 1 is provided with at least one feed inlet 11 and at least one discharge outlet 12;

the material box 2 is arranged on the material inlet 11, and is provided with a material storage cavity 21 with an opening at the bottom and a discharging mechanism 22 which is positioned below the material storage cavity 21 and is in butt joint with the material inlet 11;

a drive unit 3 provided in the base 1 and having a drive motor 31 and a drive circuit 32 connected to the drive motor 31;

the bidirectional gear 4 is arranged between the feed inlet 11 and the discharge outlet 12 in the base 1, horizontally meshed with the output end of the driving assembly 3 and detachably meshed with the material box 2 up and down, and a material passing hole 40 corresponding to the feed inlet 11 and the discharge outlet 12 is arranged at the axial center position of the bidirectional gear 4.

The working principle of the embodiment of the application is as follows:

during operation, the driving circuit 32 starts the driving motor 31 to rotate to drive the bidirectional gear 4 horizontally meshed with the output end of the driving motor to rotate, the bidirectional gear 4 drives the discharging mechanism 21 to rotate through the discharging opening 20 vertically meshed with the bidirectional gear 4, so that seasonings stored in the storage cavity 21 move downwards under the action of rotation and gravity, and flow out from the discharging opening 12 after passing through the discharging opening 20, the feeding opening 11 and the passing hole 40, at the moment, the seasonings can be conveniently taken out under the condition that a cover is not required, the operation is simple, convenient and time-saving, the dosage is easy to control, and the taste of dishes is ensured.

In some possible embodiments, the bidirectional gear 4 includes a horizontal base 41 having a ring shape and a vertical base 42 extending vertically upwards by the center of the inner periphery of the horizontal base 41. The outer edge of the horizontal base 41 is provided with a horizontally outward outer engagement tooth 43, and the upper edge of the vertical base 42 is provided with a vertically upward upper engagement tooth 44.

The cartridge 2 is provided with a lower engaging tooth 20 downwardly at the bottom thereof, which is engaged with the upper engaging tooth 44 so as to be separable up and down.

The external gear teeth 43 playing a role in horizontal transmission and the upper gear teeth playing a role in vertical transmission are integrated on the bidirectional gear 4 through the horizontal base 41 and the vertical base 42 respectively, and then transmitted to the blanking mechanism 22 through the upper gear teeth 44, so that the direction conversion of the output power of the driving motor 31 is realized through the simplest structure.

In some possible embodiments, adjacent bidirectional gears 4 and/or bidirectional gears 4 and driving motor 31 are connected by at least one intermediate wheel 33. The intermediate wheel 33 can play a transitional role under the condition that a plurality of material boxes 2 are arranged and the wheelbase between the two-way gears 4 is overlarge.

In some possible embodiments, the diameter of the intermediate wheel 33 is greater than the diameter of the horizontal base 41. Because the transmission structure of the bidirectional gear 4 is slightly more complex than that of the intermediate wheel 33, the diameter of the intermediate wheel 33 can be set larger, thereby achieving the effects of more compact structure and balance.

In some possible embodiments, the bidirectional gear 4 and the intermediate wheel 33 are staggered, so as to save product design space.

In some possible embodiments, a vertical return spring 5 is also housed outside the vertical base 42, abutting the upper casing of the base. The vertical reset spring 5 plays an auxiliary reset role in the process of meshing connection and separation of the bidirectional gear 4 and the material box 2.

In some possible embodiments, the driving circuit 32 is provided with a switch assembly 6, and the switch assembly 6 includes any one of a smart voice switch, an electronic switch and a mechanical switch. The switch assembly 6 can conveniently control the on-off of the driving circuit 32, thereby playing a role in controlling the automatic blanking of the blanking mechanism 22.

In some possible embodiments, the mechanical switch assembly comprises:

a contact switch 61 provided on the drive circuit 32;

a sliding plate 62 movably arranged below the bidirectional gear 4 and detachably contacted with the contact switch 61, and provided with a discharging hole 620 and a plurality of bone positions 621 arranged in parallel along the moving direction of the sliding plate 62;

the switch handle assembly 63 is arranged below the sliding plate 62 and is connected with the sliding plate 62 in a poking way.

When the switch handle assembly 63 is in operation, the switch handle assembly 63 is only pushed, and the action of starting or stopping the operation of the driving motor 31 by controlling the on-off of the switch assembly 6 can be achieved through the toggle connection of the switch handle assembly 63 with the sliding plate 62 and the contact switch 61; the horizontal movement of the sliding plate 62 can be used for jacking the bidirectional gear 4, so that the bidirectional gear is converted into an engaged state with the blanking mechanism 22 from a separated state, the power output by the driving motor 31 along the horizontal direction is converted into a vertical direction, and the blanking mechanism 22 is driven to rotate, so that the automatic blanking effect is realized.

To ensure smooth sliding of the horizontal gear 4 on the slide plate 72, in some possible embodiments the front end of the bone site 610 in the direction of movement is provided as a bevel.

In some possible embodiments, the slide plate 62 is in contact with the contact switch 61 by a horizontal return spring 64. The horizontal return spring 64 plays an auxiliary return role in the contact and separation of the slide plate 62 and the contact switch 61.

In some possible embodiments, the lower surface of the bi-directional gear 4 is provided with an annular lower edge 45 that abuts the upper surface of the slide plate. The inner side of the annular lower edge 45 may form a space for accommodating the bone site 610, so that the product design is more compact.

In some possible embodiments, the discharging mechanism 22 includes a rotating shaft assembly 220 disposed along the axis of the storage cavity 21 and having a top end extending into the bottom opening, and a discharging opening 20 disposed below the rotating shaft assembly 220.

During operation, the rotating shaft assembly 220 is driven to rotate, the rotating shaft assembly 220 extending into the cavity of the storage cavity 21 from the bottom opening of the storage cavity 21 drives the seasonings stored in the storage cavity 21 to move through rotation and fall under the action of gravity, and flows out from the feed opening 20.

In some possible embodiments, a fixing ring 23 is further disposed in the storage cavity 21, and the rotating shaft assembly 220 includes a rotating shaft 221 rotatably fixed between the fixing ring 23 and the feed opening 20, and a shaft sleeve 222 sleeved outside the rotating shaft 221.

In some possible embodiments, the shaft assembly 220 further includes a scraping bar 223 rotatably connected to the top output end of the rotation shaft 221 in a horizontal direction. The scraping rod 223 is connected to the output end of the rotary shaft 221, and can synchronously rotate with the rotary shaft 221, so that the discharging speed is increased, and the seasoning caking can be effectively prevented.

In some possible embodiments, the feeding opening 20 is erected with a hollow fixed wing 202, and the bottom of the rotating shaft 221 is erected on the hollow fixed wing 202. The fixing wing 202 is provided at the discharge opening 20, which can firmly and stably fix the rotation shaft 221 and prevent the accumulation of seasoning due to excessively complicated structure.

In some embodiments, the bottom of the rotating shaft 221 is configured as a worm 224, so that the amount of seasoning can be precisely controlled by controlling the number of turns of the worm 224.

In some specific real-time modes, the bottom end of the sleeve 222 has a structure corresponding to the feeding hole 20 and is attached to the inner wall of the feeding hole. The fit design of the sleeve 222 and the feed opening 20 achieves the effect of stable and compact overall structure.

In some possible embodiments, the scraping bar 223 is axially connected to the rotating shaft 221 through a planetary gear 225, and the planetary gear 225 includes an inner gear ring 2251, at least two planetary gears 2252, and a sun gear 2253, which are disposed from outside to inside. The planetary gear 225 may function to adjust the rotational speed of the scraper bar 223.

In some possible embodiments, the sun gear 2253 is disposed below the top output end of the rotating shaft 221, a circular-table-shaped planet carrier 2054 is disposed below the sun gear 2253, and the at least two planet gears 2052 are disposed on the planet carrier 2254 and are in external engagement with the sun gear 2253, and/or the ring gear 2051 is disposed on the top inner wall of the shaft sleeve 222 and is in internal engagement with the at least two planet gears 2252. The components of the planetary gear 225 are respectively arranged on the rotating shaft 221 and the shaft sleeve 222, so that the structure is effectively simplified, and the optimal transmission matching effect is achieved.

In some possible embodiments, the shaft sleeve 222 is in overhead connection with the ring gear 2051 through a plurality of vertical beams 2221 arranged in parallel along the vertical direction corresponding to the position of the worm 224.

In some possible embodiments, the shaft sleeve 222 is further connected to the ring gear 2051 by a diagonal beam 2222 protruding into the storage cavity 1 at a position corresponding to the worm 224.

In some possible embodiments, the storage cavity 21 includes a hollow cylinder 211 structure disposed at an upper portion of the case 10 and a large hopper 212 structure disposed below the hollow cylinder 211 structure. The hollow cylinder 211 structure maximizes the amount of seasoning stored, while the large hopper 212 structure achieves the best discharging effect.

In some possible real-time modes, the feed opening 20 is provided as a small hopper structure. The small hopper structure can further achieve the best discharging effect.

In some possible embodiments, a lower engagement tooth 201 is provided downwards at the feed opening 20. The lower engagement teeth 201 may function as an engagement connection with an external rotary drive mechanism.

In some possible embodiments, the top opening of the small hopper 20 abuts the bottom opening of the large hopper 212, thereby forming a seamless blanking channel.

In some possible embodiments, the switch handle assembly 6 is integrally formed in a U-shaped structure, and the top of the U-shaped structure is rotatably connected with the sliding plate. The U-shaped structure has large contact area and is convenient to push.

In some possible embodiments, the bottom of the U-shaped structure is inclined relative to the top of the U-shaped structure, so that the U-shaped structure is easier to push in an inclined position, and is convenient and labor-saving.

In some possible embodiments, a fixing hanger 16 is provided on the back of the base 1.

In some possible embodiments, the outer edge of the feed inlet is further provided with an annular boss which can extend into the bottom surface of the cartridge.

In some possible embodiments, a snap structure is provided on the bottom of the cartridge 2 and the outer edge of the inlet.

One application scenario of the automatic blanking seasoning box of the embodiment of the present application is exemplarily described below with reference to fig. 1.

The machine body is fixed on a wall through a fixing hanging piece (such as a wall-mounted glue piece, 3M glue and the like) arranged on the back surface of the machine body, and is connected with a power supply;

filling the seasoning into the material box, placing the material box into a groove on the machine body through a buckle fixing structure below the material box, and enabling the material box to rotate anticlockwise and be clamped and fixed;

by means of tools such as a spoon and the like, any one of the 4 switch handles is pushed, the seasoning in the corresponding material box can fall into the spoon, the switch handle is loosened, the discharging hole is closed, and the seasoning taking operation is completed. The specific operation is as follows:

the switch handle toggles the slide plate to move forward, the discharging hole on the slide plate moves to the discharging hole of the material box, and discharging can be achieved.

The inclined bone position on the slide plate pushes the bidirectional gear to move upwards until the bidirectional gear is meshed with the worm gear of the seasoning box.

Simultaneously, the forward movement of the slide plate triggers a tact switch on the drive circuit.

Any one of the tact switches is closed, and the driving motor starts to rotate, so that the 4 intermediate wheels and the 4 bidirectional gears start to rotate.

At this time, only the horizontal gear pushing the switch handle is meshed with the lower meshing teeth of the material boxes upwards, so that only the rotating shaft of one material box rotates to drive the worm and the planetary gear to rotate and simultaneously drive the scraping rod to rotate. The planetary gear drives the inner ring gear to reversely rotate at a low speed, so that the seasoning can be prevented from caking. The worm conveys the seasoning to the discharge hole and falls into the spoon. The other 3 horizontal gears do not move upwards, so that the other 3 seasoning box worms do not rotate and do not discharge.

The user holds the spoon by hand, releases the switch handle, turns off the tact switch, and stops the rotation of the driving motor to stop discharging; or the user triggers the tact switch through the microphone and the voice, and the driving motor automatically stops after rotating corresponding turns according to the required discharging quantity.

The horizontal reset spring drives the sliding plate to move backwards and pushes the switch handle to reset. Meanwhile, the blanking hole on the sliding plate is staggered with the blanking hole of the bidirectional gear and the blanking hole of the material box to form a seal.

The bidirectional gear moves downwards under the elasticity of the vertical reset spring, and is released from being meshed with the feed opening.

Note that the above is only a preferred embodiment of the present application and the technical principle applied. Those skilled in the art will appreciate that the present application is not limited to the particular embodiments described herein, but is capable of numerous obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the present application. Therefore, while the present application has been described in connection with the above embodiments, the present application is not limited to the above embodiments, but may include many other equivalent embodiments without departing from the spirit of the present application, the scope of which is defined by the scope of the appended claims.

Claims (14)

1. An automatic unloading condiment box, which is characterized by comprising:

the surface of the base is provided with at least one feed inlet and at least one discharge outlet;

the material box is arranged on the material inlet and is provided with a material storage cavity with an opening at the bottom and a discharging mechanism which is positioned below the material storage cavity and is in butt joint with the material inlet;

the driving assembly is arranged in the base and is provided with a driving motor and a driving circuit connected with the driving motor;

the bidirectional gear is arranged between the feeding port and the discharging port in the base, horizontally meshed with the output end of the driving assembly and detachably meshed with the material box up and down, and a material passing hole corresponding to the feeding port and the discharging port is arranged at the axial center of the bidirectional gear.

2. The automatic feed seasoning box of claim 1 wherein:

the bidirectional gear comprises a ring-shaped horizontal base and a vertical base which extends vertically upwards by the coaxial center of the inner edge of the horizontal base;

the outer edge of the horizontal base is provided with a horizontal outward external engaging tooth, and the upper edge of the vertical base is provided with a vertical upward upper engaging tooth;

the bottom of the material box is downwards provided with lower meshing teeth which are meshed with the upper meshing teeth in an up-down separable way.

3. An automatic feed seasoning box as recited in claim 2 wherein:

and adjacent two-way gears and/or two-way gears and the driving motor are/is connected through at least one intermediate wheel.

4. An automatic feed seasoning box as claimed in claim 3 wherein:

the diameter of the intermediate wheel is larger than that of the horizontal base; and/or, the bidirectional gear is staggered with the intermediate wheel; and/or the outside of the vertical base is also sleeved with a vertical reset spring which is abutted to the upper shell of the base.

5. The automatic feed seasoning box of any one of claims 1 to 4 wherein: the driving circuit is provided with a switch assembly, and the switch assembly comprises any one of an intelligent voice switch, an electronic switch and a mechanical switch.

6. The automatic feed seasoning box of claim 5 wherein the mechanical switch assembly comprises:

the contact switch is arranged on the driving circuit;

the sliding plate is movably arranged below the bidirectional gear and is detachably contacted with the contact switch, and is provided with a discharging hole and bone positions which are arranged in parallel along the moving direction of the sliding plate;

the switch handle assembly is arranged below the sliding plate and is connected with the sliding plate in a poking way.

7. The automatic feed seasoning box of claim 6 wherein:

the front end of the bone position along the moving direction is set to be an inclined plane; and/or the sliding plate is contacted with the contact switch through a horizontal reset spring; and/or the lower surface of the bidirectional gear is provided with an annular lower edge which is abutted with the upper surface of the sliding plate.

8. The automatic feed seasoning box of any one of claims 1 to 7 wherein:

the discharging mechanism comprises a rotating shaft assembly and a discharging opening, wherein the rotating shaft assembly is arranged along the axis of the storage cavity, the top end of the rotating shaft assembly stretches into the bottom opening, and the discharging opening is arranged below the rotating shaft assembly;

the material storage cavity is internally provided with a fixed ring, and the rotating shaft assembly comprises a rotating shaft rotatably fixed between the fixed ring and the material discharging opening and a shaft sleeve sleeved outside the rotating shaft.

9. The seasoning box of claim 8 wherein:

the rotating shaft assembly further comprises a scraping rod which is rotationally connected with the top output end of the rotating shaft along the horizontal direction; and/or

The blanking port is provided with a fixed wing with a hollow structure, and the bottom of the rotating shaft is arranged on the fixed wing with the hollow structure; and/or that the number of the groups of groups,

the bottom of the rotating shaft is provided with a worm structure; and/or

The lower end of the shaft sleeve is provided with a structure corresponding to the blanking opening and is attached to the inner wall of the shaft sleeve.

10. The seasoning box of claim 9 wherein:

the scraping rod is axially connected with the rotating shaft through a planetary gear, and the planetary gear comprises an inner gear ring, at least two planetary gears and a sun gear which are arranged from outside to inside.

11. The seasoning box of claim 10 wherein:

the sun gear is arranged below the top output end of the rotating shaft, a circular truncated cone type planet carrier is arranged below the sun gear, at least two planet gears are arranged on the planet carrier and are externally meshed with the sun gear, and/or the inner gear ring is arranged on the inner wall of the top end of the shaft sleeve and is internally meshed with the at least two planet gears.

12. The seasoning box of claim 8 wherein:

the material storage cavity comprises a hollow cylindrical structure arranged at the upper part of the material box and a large hopper structure arranged below the hollow cylindrical structure; and/or

The blanking opening is arranged into a small hopper structure;

and/or the blanking opening is downwards provided with lower meshing teeth.

13. The automatic feed seasoning box of claim 6 wherein:

the switch handle assembly is integrally formed into a U-shaped structure, the top of the U-shaped structure is rotationally connected with the sliding plate, and/or the bottom of the U-shaped structure is obliquely arranged relative to the top of the U-shaped structure.

14. The automatic feed seasoning box of any one of claims 1 to 13 wherein:

a fixed hanging piece is arranged on the back surface of the base; and/or the outer edge of the feed inlet is also provided with an annular boss which can extend into the bottom surface of the material box; and/or the bottom of the material box and the outer edge of the material inlet are provided with mutually matched fastening structures.