CN212879049U - Metering output device and rice bin - Google Patents

Abstract

The utility model discloses a metering output device and a rice bin, which comprises a box body, a metering component and a driving component, wherein the metering component comprises a metering plate and a metering frame, and the metering frame is fixedly connected with the bottom end of the box body; an outlet is arranged on the metering frame; the metering plate and the driving assembly are both arranged on the metering frame; a metering groove is formed in the metering plate; the metering plate is movably arranged on the metering frame and driven by the driving assembly to move close to or far away from the outlet along a linear direction; the bottom end of the metering slot is used for being communicated with the outlet after the metering plate moves close to the outlet. The rice box comprises the metering output device, a drawer is arranged at the bottom end of the box body, and the drawer is connected to the bottom end of the box body in a sliding manner; the drawer is located below the metering rack and is used for receiving the material falling from the outlet. The utility model discloses can quantitative output material.

Description

Metering output device and rice bin

Technical Field

The utility model relates to a rice case technical field especially relates to measurement output device and rice case.

Background

At present, the rice box is a common kitchen utensil for storing rice and preserving rice, so that people can take rice when cooking, and the rice can be taken quantitatively by the existing rice box through a measuring cup when taking rice, so that the rice can not be taken quantitatively under the condition that the measuring cup is lost.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, one of the purposes of the utility model is to provide a metering output device which can output materials quantitatively.

The utility model discloses a second purpose provides the rice case, and it can be in the box deposit rice, gets rice through the drawer ration.

The utility model discloses an one of the purpose adopts following technical scheme to realize:

the metering output device comprises a box body, a metering assembly and a driving assembly, wherein the metering assembly comprises a metering plate and a metering frame, and the metering frame is fixedly connected with the bottom end of the box body; an outlet is arranged on the metering frame; the metering plate and the driving assembly are both arranged on the metering frame; a metering groove is formed in the metering plate; the metering plate is movably arranged on the metering frame and driven by the driving assembly to move close to or far away from the outlet along a linear direction; the bottom end of the metering slot is used for being communicated with the outlet after the metering plate moves close to the outlet.

Furthermore, the bottom end of the metering plate is pivoted with a roller wheel, and the roller wheel is matched with the top end of the metering frame in a rolling manner.

Furthermore, the metering assembly further comprises an elastic component, the elastic component is clamped between the metering frame and the metering plate, and the elastic component is used for providing elastic stress for driving the metering plate to move away from the outlet.

Further, the elastic component is a spring.

Furthermore, the driving assembly comprises a motor, a gear and a rack, the motor is mounted on the metering plate, and the gear is connected with a rotating shaft of the motor; the rack is fixedly connected to the metering frame and extends along the linear direction; the gear is meshed with the rack.

Further, the driving assembly comprises an electromagnet, and the metering plate is connected with a movable iron core of the electromagnet.

Furthermore, the bottom end of the box body is provided with a metering port, and the metering groove is communicated with the metering port or the outlet when used for the movement of the metering plate.

The second purpose of the utility model is realized by adopting the following technical scheme:

the rice box comprises the metering output device, a drawer is arranged at the bottom end of the box body, and the drawer is connected to the bottom end of the box body in a sliding manner; the drawer is located below the metering rack and is used for receiving the material falling from the outlet.

Furthermore, a drawer cavity is formed at the bottom end of the box body, and a drawer opening is formed at the front end of the drawer cavity; the drawer is installed to the drawer cavity through the drawer opening and is in sliding fit with the inner wall of the drawer cavity.

Compared with the prior art, the beneficial effects of the utility model reside in that: its accessible metering board moves on the measurement frame, and the metering tank of metering board can correspond with the export in the motion process, and the metering tank alright derive the material in the box by the export, regularly go out a meter after, the outlet motion alright be kept away from to the metering board, and export and metering tank stagger, so realize the measurement output.

Drawings

Fig. 1 is a schematic structural view of a metering output device of the present invention;

fig. 2 is a schematic view of another perspective structure of the metering output device of the present invention;

fig. 3 is a schematic structural view of the metering assembly of the present invention;

fig. 4 is a schematic view of another perspective structure of the metering assembly of the present invention;

fig. 5 is another schematic structural diagram of the metering and conveying device of the present invention;

fig. 6 is a schematic structural view of the rice bin of the present invention.

In the figure: 10. a box body; 11. a drawer; 12. a drawer cavity; 20. a metering plate; 21. a metering tank; 22. a roller; 30. a metering rack; 31. an outlet; 41. a motor; 42. a rack; 43. a gear; 44. an electromagnet; 50. an elastic member.

Detailed Description

The invention will be further described with reference to the accompanying drawings and specific embodiments:

the metering output device shown in fig. 1-5 comprises a box body 10, a metering assembly and a driving assembly, wherein the metering assembly comprises a metering plate 20 and a metering frame 30, the metering frame 30 is fixedly connected with the bottom end of the box body 10, and an outlet 31 is arranged on the metering frame 30. The measuring plate 20 and the driving unit are mounted on the measuring frame 30.

In addition, a measuring slot 21 is provided on the measuring plate 20, the measuring plate 20 is movably mounted on the measuring rack 30, and the measuring plate 20 can move close to or away from the outlet 31 along a linear direction, which is the length direction or the width direction of the measuring rack 30 in this embodiment, under the driving of the driving assembly. After the metering plate 20 moves adjacent to the outlet 31, the bottom end of the metering slot 21 may communicate with the outlet 31.

On the basis of the structure, the utility model discloses a during the measurement output device, can place the material in box 10, the material can drop to the metering tank 21 in under self gravity, the material ration of depositing in the metering tank 21. In the initial state, the metering tank 21 is displaced from the outlet 31, and the metering shelf 30 is closed at the bottom end of the metering tank 21. When the rice is quantitatively output, the driving component can drive the metering plate 20 to move to the outlet 31 along the metering frame 30, at the moment, the bottom end of the metering groove 21 is communicated with the outlet 31, and the rice metered in the metering groove 21 can directly drop, so that the quantitative output is realized.

Specifically, in this embodiment, a metering opening may be disposed at the bottom end of the box 10, and the metering slot 21 is used for communicating with the metering opening or the outlet 31 when the metering plate 20 moves, so that the metering slot 21 of the metering plate 20 is driven by the driving component to move toward the metering opening at the bottom end of the box 10, so that the top end of the metering slot 21 is communicated with the metering slot 21, and the material in the box 10 can drop into the metering slot 21 through the metering opening for quantitative storage. Thereafter, the driving assembly drives the metering slot 21 on the metering plate 20 to move close to the outlet 31, the top end of the metering slot 21 is staggered with the metering port, the bottom end of the metering slot 21 is communicated with the outlet 31, and quantitative materials in the metering slot 21 can fall off.

Of course, when the housing 10 has no metering opening, that is, the metering plate 20 is directly attached to the bottom end of the housing 10, the metering slot 21 of the metering plate 20 directly outputs the material quantitatively, and the time for the metering slot 21 to pass through the outlet 31 may be controlled.

Further, a roller 22 may be pivotally connected to the bottom end of the metering board 20, and the roller 22 is in rolling fit with the top end of the metering rack 30, that is, when the metering board 20 moves on the metering rack 30, the roller 22 may roll on the metering rack 30, so that the movement of the metering board 20 is more stable.

Furthermore, the measuring assembly further includes an elastic member 50, the elastic member 50 is clamped between the measuring rack 30 and the measuring plate 20, when the measuring plate 20 moves towards the outlet 31, the elastic member 50 can be compressed, after the quantitative output operation is completed, the elastic member 50 can be reset, the provided elastic stress can accelerate the movement of the measuring plate 20, and the reset speed of the measuring plate 20 is increased. The elastic member 50 may be implemented by a spring in the prior art.

Further, referring to fig. 2 and 3, the driving assembly in this embodiment may include a motor 41, a gear 43 and a rack 42, the motor 41 is mounted on the metering plate 20, and the gear 43 is connected to a rotating shaft of the motor 41; the rack 42 is fixedly connected to the metering rack 30, and the rack 42 extends along the linear direction; the gear 43 meshes with the rack 42. Thus, when the metering plate 20 is driven, the motor 41 can rotate to drive the gear 43 to rotate, the gear 43 can rotate to move along the rack 42 meshed with the gear 43, the metering plate 20 is driven to move, and the gear 43 and the rack 42 are meshed for transmission, so that the transmission precision is higher.

Of course, referring to fig. 5, the above-mentioned driving assembly can also be implemented by using an electromagnet 44 in the prior art, the metering plate 20 is connected to the movable iron core of the electromagnet 44, after the electromagnet 44 is powered on, the movable iron core can drive the metering plate 20 to move, and the elastic component 50 can be reset to drive the metering plate 20 to reset. Therefore, the control can be realized only by electrifying and powering off.

In addition, the driving component can also be realized by other linear motion output mechanisms such as a screw rod transmission mechanism, a belt transmission mechanism and the like in the prior art.

In the case of the example 2, the following examples are given,

referring to fig. 1-6, the rice bin comprises the metering output device, which comprises a box body 10, a metering component and a driving component, wherein the metering component comprises a metering plate 20 and a metering frame 30, the metering frame 30 is fixedly connected with the bottom end of the box body 10, and an outlet 31 is arranged on the metering frame 30. The measuring plate 20 and the driving unit are mounted on the measuring frame 30.

In addition, a measuring slot 21 is provided on the measuring plate 20, the measuring plate 20 is movably mounted on the measuring rack 30, and the measuring plate 20 can move close to or away from the outlet 31 along a linear direction, which is the length direction or the width direction of the measuring rack 30 in this embodiment, under the driving of the driving assembly. After the metering plate 20 moves adjacent to the outlet 31, the bottom end of the metering slot 21 may communicate with the outlet 31.

A drawer 11 is arranged at the bottom end of the box body 10, and the drawer 11 is connected to the bottom end of the box body 10 in a sliding manner; the drawer 11 is located below the metering rack 30 and is used to receive the rice dropped by the outlet 31.

On the basis of the structure, the utility model discloses a during the rice case, can place rice in box 10, rice can drop to the metering tank 21 in under self gravity, the rice ration of depositing in the metering tank 21. In the initial state, the metering tank 21 is displaced from the outlet 31, and the metering shelf 30 is closed at the bottom end of the metering tank 21. When the rice is quantitatively output, the driving component can drive the metering plate 20 to move to the outlet 31 along the metering frame 30, at the moment, the bottom end of the metering groove 21 is communicated with the outlet 31, the rice metered in the metering groove 21 can directly fall into the drawer 11, then the drawer 11 is taken out from the box body 10, and the quantitative rice taking can be realized.

Specifically, in this embodiment, a metering opening may be disposed at the bottom end of the box 10, and the metering slot 21 is used for communicating with the metering opening or the outlet 31 when the metering plate 20 moves, so that the metering slot 21 of the metering plate 20 is driven by the driving component to move toward the metering opening at the bottom end of the box 10, so that the top end of the metering slot 21 is communicated with the metering slot 21, and the rice in the box 10 can drop into the metering slot 21 through the metering opening for quantitative storage. Then, the driving component drives the metering slot 21 on the metering plate 20 to move close to the outlet 31, the top end of the metering slot 21 is staggered with the metering port, the bottom end of the metering slot 21 is communicated with the outlet 31, and quantitative rice in the metering slot 21 can fall off.

Of course, when the housing 10 has no metering opening, that is, the metering plate 20 is directly attached to the bottom end of the housing 10, the metering slot 21 of the metering plate 20 directly outputs rice quantitatively, and the time for the metering slot 21 to pass through the outlet 31 may be controlled.

Further, a roller 22 may be pivotally connected to the bottom end of the metering board 20, and the roller 22 is in rolling fit with the top end of the metering rack 30, that is, when the metering board 20 moves on the metering rack 30, the roller 22 may roll on the metering rack 30, so that the movement of the metering board 20 is more stable.

Furthermore, the measuring assembly further includes an elastic member 50, the elastic member 50 is clamped between the measuring rack 30 and the measuring plate 20, when the measuring plate 20 moves towards the outlet 31, the elastic member 50 can be compressed, after the quantitative output operation is completed, the elastic member 50 can be reset, the provided elastic stress can accelerate the movement of the measuring plate 20, and the reset speed of the measuring plate 20 is increased. The elastic member 50 may be implemented by a spring in the prior art.

Further, referring to fig. 2 and 3, the driving assembly in this embodiment may include a motor 41, a gear 43 and a rack 42, the motor 41 is mounted on the metering plate 20, and the gear 43 is connected to a rotating shaft of the motor 41; the rack 42 is fixedly connected to the metering rack 30, and the rack 42 extends along the linear direction; the gear 43 meshes with the rack 42. Thus, when the metering plate 20 is driven, the motor 41 can rotate to drive the gear 43 to rotate, the gear 43 can rotate to move along the rack 42 meshed with the gear 43, the metering plate 20 is driven to move, and the gear 43 and the rack 42 are meshed for transmission, so that the transmission precision is higher.

Of course, referring to fig. 5, the above-mentioned driving assembly can also be implemented by using an electromagnet 44 in the prior art, the metering plate 20 is connected to the movable iron core of the electromagnet 44, after the electromagnet 44 is powered on, the movable iron core can drive the metering plate 20 to move, and the elastic component 50 can be reset to drive the metering plate 20 to reset. Therefore, the control can be realized only by electrifying and powering off.

In addition, the driving component can also be realized by other linear motion output mechanisms such as a screw rod transmission mechanism, a belt transmission mechanism and the like in the prior art.

Further, a drawer cavity 12 can be formed at the bottom end of the box body 10, a drawer 11 opening is formed at the front end of the drawer cavity 12, the drawer 11 can be installed to the drawer cavity 12 through the drawer 11 opening and is in sliding fit with the inner wall of the drawer cavity 12, therefore, rice can be taken and placed through the drawer 11 sliding in the drawer cavity 12, and after the rice is connected in the drawer 11, the drawer 11 can be taken out through the drawer 11 opening.

Various other modifications and changes may be made by those skilled in the art based on the above-described technical solutions and concepts, and all such modifications and changes are intended to fall within the scope of the claims.

Claims (9)

1. The metering output device is characterized by comprising a box body, a metering assembly and a driving assembly, wherein the metering assembly comprises a metering plate and a metering frame, and the metering frame is fixedly connected with the bottom end of the box body; an outlet is arranged on the metering frame; the metering plate and the driving assembly are both arranged on the metering frame; a metering groove is formed in the metering plate; the metering plate is movably arranged on the metering frame and driven by the driving assembly to move close to or far away from the outlet along a linear direction; the bottom end of the metering slot is used for being communicated with the outlet after the metering plate moves close to the outlet.

2. The metering output device of claim 1, wherein the bottom end of the metering plate is pivotally connected with a roller, and the roller is in rolling fit with the top end of the metering frame.

3. The metering output device of claim 1, wherein the metering assembly further comprises a resilient member, the resilient member being sandwiched between the metering shelf and the metering plate, the resilient member being configured to provide a resilient force urging the metering plate away from the outlet.

4. A metered output device as claimed in claim 3 wherein said resilient member is a spring.

5. The metering output device of claim 1, wherein the drive assembly comprises a motor, a gear and a rack, the motor is mounted on the metering plate, and the gear is connected with a rotating shaft of the motor; the rack is fixedly connected to the metering frame and extends along the linear direction; the gear is meshed with the rack.

6. The metering output device of claim 1, wherein the drive assembly comprises an electromagnet, and the metering plate is coupled to a plunger of the electromagnet.

7. The metering device of claim 1, wherein the bottom end of the box body is provided with a metering port, and the metering slot is used for communicating with the metering port or the outlet when the metering plate moves.

8. Rice bin, characterized in that it comprises a metering device according to any one of claims 1-6, the bottom end of said bin being provided with a drawer slidably connected to the bottom end of said bin; the drawer is located below the metering rack and is used for receiving the material falling from the outlet.

9. The rice bin as claimed in claim 8, wherein the bottom end of the bin body is formed into a drawer cavity, and a drawer opening is formed at the front end of the drawer cavity; the drawer is installed to the drawer cavity through the drawer opening and is in sliding fit with the inner wall of the drawer cavity.

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