CN215157090U - Quantitative material taking mechanism and material storage device - Google Patents

Abstract

The utility model belongs to the technical field of the material distribution, a ration feeding agencies and material storage device is provided for the solid material in the ration output container, include: the device comprises a shell, a first accommodating cavity is formed in the shell, a feeding port is formed in the top of the shell, and a discharging port is formed in the bottom of the shell; the material distributing part is movably arranged in the first containing cavity, and a second containing cavity which can be communicated with the material inlet or the material outlet is formed in the material distributing part; the driver is used for driving the material distribution part to move and is connected with the material distribution part; when the material distributing part moves to the second containing cavity and is communicated with the material inlet, the second containing cavity is separated from the material outlet; when the material distributing part moves to the second containing cavity and is communicated with the material outlet, the second containing cavity is separated from the material inlet; the second containing cavity is communicated with the feeding port or the discharging port independently in the moving process, and the material component discharged from the discharging port and the material component received from one side of the feeding port of the second containing cavity at each time are equal to the volume of the second containing cavity, so that the functions of quantitative material taking and discharging are realized.

Description

Quantitative material taking mechanism and material storage device

Technical Field

The utility model belongs to the technical field of the material distribution, especially, relate to a ration feeding agencies and material storage device.

Background

In a conventional material storage device, the opening or closing of the discharge port is generally controlled by a simple switch structure, so that the material is conveniently discharged or the discharge port is closed. The advantages of using this switch structure are: simple design, easy manufacture and production and low cost. However, the simple structure can not accurately measure the amount of the materials released at every time, the requirement for quantitatively releasing the materials can not be met, a user needs to weigh the materials for the second time after taking the materials, and the materials are required to be put back into the storage device again if the materials exceed the requirement, so that the operation is complex, the material taking efficiency is low, and the material taking device is not humanized.

Therefore, some manufacturers develop a material storage device with a weighing control system, and in the process of discharging materials, the materials are weighed and then the sealing of a discharge port is controlled by an electric switch, so that the requirement of releasing the materials quantitatively is met, but the structure is complex, the design and installation are difficult, and the production cost is high.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome above-mentioned prior art not enough, provide a simple structure, be convenient for install and use extensive ration extracting mechanism and adopt this kind of ration extracting mechanism's device to solve the technical problem that the material storage device structure that can measure among the prior art is complicated.

The utility model discloses a realize like this, provide a ration feeding agencies for the solid material in the ration output container, include:

the device comprises a shell, a first cavity is formed in the shell, a feeding hole communicated with the first cavity is formed in the top of the shell, and a discharging hole communicated with the first cavity is formed in the bottom of the shell;

the material distributing part is movably arranged in the first containing cavity, and a second containing cavity which can be communicated with the material inlet or the material outlet is formed in the material distributing part;

the driver is used for driving the material distributing part to move, is arranged on the shell and is connected with the material distributing part;

when the material distributing part moves to the second containing cavity and is communicated with the material inlet, the second containing cavity is separated from the material outlet; when the material distributing part moves to the second containing cavity and is communicated with the material outlet, the second containing cavity is separated from the material inlet.

Preferably, the first cavity is cylindrical, and the driver is used for driving the material distribution component to rotate along the axial direction of the first cavity;

or the first cavity is spherical, and the driver is used for driving the material distributing part to rotate;

or, the first containing cavity is a cuboid, and the driver is used for driving the material distributing component to linearly move in the first containing cavity.

Further, when the first containing cavity is cylindrical:

the shell comprises a cylinder, a first end plate arranged at one end of the cylinder and a second end plate covered with the other end of the cylinder, the first end plate, the cylinder and the second end plate enclose a cylindrical first containing cavity, the first end plate is provided with a discharge hole, and the second end plate is provided with a feeding hole; in the axial direction of the cylinder: the projection of the feeding port and the projection of the discharging port are arranged in a staggered manner; two ends of the second cavity penetrate through the material distributing part.

Furthermore, the cross sectional area of one side of the second cavity connected with the feeding port is smaller than or equal to that of the feeding port, and the cross sectional area of one side of the second cavity connected with the discharging port is smaller than or equal to that of the discharging port.

Furthermore, the material distributing part is cylindrical, and the material distributing part is rotatably arranged in the cylindrical first containing cavity; or the material distributing part is spherical and is rotatably arranged in the spherical first containing cavity; or the material distributing part is blocky and is arranged in the first accommodating cavity of the cuboid in a sliding mode.

Furthermore, the driver is a rotating motor or a rotating cylinder, and a rotating shaft of the driver penetrates through the first cavity and is connected with the material distribution component; or the driver is a linear cylinder or a linear module, and an output shaft/end of the driver penetrates into the first cavity and is connected with the material distributing component.

Furthermore, the number of the second cavities is at least one, and the driver drives the material distribution part to move in a reciprocating manner so that at least one second cavity is communicated with the material inlet or the material outlet alternately;

the size of the cross section of the second cavity is in uniform transition from one side of the second cavity to the other side of the second cavity, or in gradual transition, or in uniform transition and then in gradual transition.

Specifically, the number of the second cavities is more than two, and the driver drives the material distributing part to move periodically so that the second cavities are communicated with the material inlet or the material outlet in a circulating manner; the second end plate can at least completely shield one side of any two adjacent second cavities facing the second end plate;

the size of the cross section of the second cavity is in uniform transition from one side of the second cavity to the other side of the second cavity, or in gradual transition, or in uniform transition and then in gradual transition.

Specifically, the second end plate is arranged in a gradient manner; and the height of one side, close to the feeding port, of the second end plate is lower than the height of one side, far away from the feeding port, of the second end plate.

The utility model also provides a material storage device, including the feed bin that can save the material, still include as before ration feeding agencies, ration feeding agencies set up in the bottom of feed bin.

In the embodiment of the utility model, when the second chamber is communicated with the material inlet, the second chamber is isolated from the material outlet, when the second chamber is communicated with the material outlet, the second chamber is isolated from the material inlet, that is, the second chamber can only be communicated with the material inlet or the material outlet independently in the process of moving under the drive of the driver, when the second chamber is communicated with the material inlet to receive the material above the material inlet, the second chamber is one side opening for communicating with the material inlet and one side closed for communicating with the material outlet, the second chamber can only receive the material with the volume corresponding to the volume from the material inlet, after the second chamber is filled with the material, the second chamber is moved to the position where the second chamber is communicated with the material outlet under the drive of the driver, at the moment, the second chamber is used for being closed with one side of the material inlet and one side opening for communicating with the material outlet, the material in the second chamber is discharged from the material outlet, the second containing cavity is used for sealing one side communicated with the feeding port, and materials at the position of the feeding port cannot enter the second containing cavity communicated with the discharging port, so that the weight of the materials discharged from the discharging port of the second containing cavity at each time is equal to the weight of the materials received from one side of the feeding port of the second containing cavity at each time, namely, the volume of the second containing cavity, the quantitative material taking and discharging functions are realized, the quantitative material taking can be realized without the help of a weighing device, in addition, the structure is simple, the installation is convenient, and the quantitative material taking device can be applied to various devices or equipment, such as various material storage devices or food processing equipment.

Drawings

Fig. 1 is a cross-sectional view of a quantitative material taking mechanism provided by an embodiment of the present invention;

fig. 2 is an exploded view of the second end plate, the dispensing member, and the position of the driver of the quantitative dispensing mechanism provided by an embodiment of the present invention;

fig. 3 is a cross-sectional view of a material storage device having a quantitative material taking mechanism according to an embodiment of the present invention;

1-a material storage device; 1 a-a quantitative material taking mechanism; 1 b-a storage bin; 10-a housing; 11-a first cavity; 12-a feeding port; 13-a discharge hole; 100-cylinder; 101-a first end plate; 102-a second end plate; 2-a material separating part; 21-a second cavity; 3-a driver; 31-sealing member.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

As shown in fig. 1 to 3, the embodiment of the utility model provides a quantitative material taking mechanism 1a for the solid material in the ration output container, the solid material of here mainly includes some graininess materials, graininess material is convenient to get into the latter second under the action of gravity smoothly and is held chamber 21, be convenient for smoothly discharge from second appearance chamber 21 simultaneously, thereby conveniently realize the ration and get the material function, certainly also do not get rid of some powdered or other can get into the latter second smoothly under gravity or other effort interfere and hold chamber 21 and the convenient material that holds the chamber 21 and discharge from the latter second, this department lists one by one, this quantitative material taking mechanism 1a includes:

the device comprises a shell 10, wherein a first containing cavity 11 is formed in the shell 10, a feeding hole 12 communicated with the first containing cavity 11 is formed in the top of the shell 10, and a discharging hole 13 communicated with the first containing cavity 11 is formed in the bottom of the shell 10;

the material distributing part 2 is movably arranged in the first containing cavity 11, and a second containing cavity 21 which can be communicated with the material inlet 12 or the material outlet 13 is formed in the material distributing part 2;

the driver 3 is used for driving the material distributing part 2 to move, the driver 3 is arranged on the shell 10, and the driver 3 is connected with the material distributing part 2;

when the material distributing part 2 moves to the second containing cavity 21 to be communicated with the material inlet 12, the second containing cavity 21 is separated from the material outlet 13; when the material distributing part 2 moves to the second containing cavity 21 to be communicated with the material outlet 13, the second containing cavity 21 is separated from the material inlet 12; the partition is that the second cavity 21 is not communicated with the material inlet 12 or the material outlet 13, or one side of the second cavity 21, which is communicated with the material inlet 12, or one side of the second cavity which is communicated with the material outlet 13 is in a closed/closed state.

In the embodiment of the present invention, when the second accommodating chamber 21 is communicated with the feeding port 12, the second accommodating chamber 21 is separated from the discharge port 13, when the second accommodating chamber 21 is communicated with the discharge port 13, the second accommodating chamber 21 is separated from the feeding port 12, that is, the second accommodating chamber 21 is moved under the driving of the driver 3, and only can be separately communicated with the feeding port 12 or communicated with the discharge port 13, so that when the second accommodating chamber 21 is communicated with the feeding port 12 to receive the material above the feeding port 12, the second accommodating chamber 21 is an opening on one side for being communicated with the feeding port 12, and is closed on one side for being communicated with the discharge port 13, the second accommodating chamber 21 can only receive the material corresponding to the volume component from the feeding port 12 at each time, after the second accommodating chamber 21 is filled with the material, and is moved to the position where the second accommodating chamber 21 is communicated with the discharge port 13 under the driving of the driver 3, at this time, the second accommodating chamber 21 is used for being closed on one side of the feeding port 12, The quantitative material taking and discharging device is simple in structure and convenient to install, and can be applied to various devices or equipment, such as various material storage devices or food processing equipment.

Specifically, in this embodiment, the first cavity 11 is cylindrical, and the driver 3 is configured to drive the material distribution component 2 to rotate along the axial direction of the first cavity 11;

in other embodiments, the first cavity 11 may also be spherical, and the driver 3 is used for driving the material-separating part 2 to rotate;

or, the first cavity 11 is a cuboid, and the driver 3 is used for driving the material distributing part 2 to move linearly in the first cavity 11;

or the first cavity 11 may be in other shapes as long as the driver 3 is allowed to drive the material distributing part 2 to move in the first cavity 11, so that the second cavity 21 is alternately and independently communicated with the material inlet 12 or the material outlet 13 to realize the separation of the filling material and the discharging material, thereby smoothly realizing the quantitative material taking function, which is not listed here; the phrase "alternately and independently communicate with the material inlet 12 or the material outlet 13" herein means that the second cavity 21 is independently communicated with the material inlet 12, and at this time, the second cavity 21 and the material outlet 13 are in a separated state; or, the second cavity 21 is separately communicated with the discharge port 13, and at this time, the second cavity 21 is separated from the feeding port 12.

Specifically, in this embodiment, the first cavity 11 is cylindrical;

the shell 10 comprises a cylinder 100, a first end plate 101 arranged at one end of the cylinder 100 and a second end plate 102 covered with the other end of the cylinder 100, the first end plate 101, the cylinder 100 and the second end plate 102 enclose a cylindrical first cavity 11, a discharge hole 13 is formed in the first end plate 101, and a feeding hole 12 is formed in the second end plate 102; on the cylinder axis: the projection of the feeding port 12 and the projection of the discharging port 13 are arranged in a staggered manner, namely the projection of the feeding port 12 facing to one side of the discharging port 13 is not overlapped with the discharging port 13; both ends of the second cavity 21 penetrate through the material-distributing part 2.

The first end plate 101, the cylinder 100 and the second end plate 102 limit the material distribution part 2 in the interior, materials can only enter the material distribution part 2 from the material inlet 12, and the driver 3 drives the material distribution part 2 to transfer the materials to the second containing cavity 21 to be separated from the material inlet 12, and the materials are discharged under the condition that the second containing cavity 21 is communicated with the material outlet 13, so that quantitative filling and discharging are ensured, and the quantitative material taking function is realized.

Specifically, the cross sectional area of the side of the second cavity 21 connected to the material inlet 12 is smaller than or equal to the cross sectional area of the material inlet 12, which is beneficial for the material to smoothly enter the second cavity 21; the cross sectional area of the side of the second cavity 21 connected to the discharge port 13 is smaller than or equal to the cross sectional area of the discharge port 13, which is beneficial to the smooth discharge of the material in the second cavity 21 from the second cavity 21.

Specifically, in this embodiment, the material distributing part 2 is cylindrical, and the material distributing part 2 is rotatably disposed in the cylindrical first accommodating cavity 11;

in other embodiments, the material distributing part 2 may also be spherical, and the material distributing part 2 is rotatably arranged in the spherical first cavity 11; or the material distributing part 2 is in a block shape, and the material distributing part 2 is arranged in the first accommodating cavity 11 of the cuboid in a sliding manner; as long as the material distributing part 2 can rotate or move in the first cavity 11, and the second cavity 21 is alternatively and independently communicated with the material inlet 12 or the material outlet 13, which is not listed here, the term "alternatively and independently communicated" here means that the second cavity 21 is only communicated with the material inlet 12 or only communicated with the material outlet 13.

Specifically, in this embodiment, the driver 3 is a rotary motor or a rotary cylinder, a rotating shaft of the driver 3 penetrates through the first accommodating cavity 11 and is connected to the material distribution component 2, the driver 3 is disposed outside the first end plate 101, the rotating shaft of the driver 3 penetrates through the first end plate 101 and is connected to the material distribution component 2, and a sealing member 31 is disposed at a position where the rotating shaft of the driver 3 penetrates through the first end plate 101; in other embodiments, the driver 3 may have other structures, and the driving manner of the driver 3 for the material distribution mechanism is not limited to rotational driving, for example, the driver 3 is a linear cylinder or a linear module provided with a motor, an output shaft/end of the driver 3 penetrates through the first cavity 11 and is connected to the material distribution part 2, as long as the driver 3 can drive the material distribution part 2 to move, so that the second cavity 21 on the material distribution part 2 is alternately and independently communicated with the material inlet 12 or the material outlet 13, which is not listed here, where "alternately and independently communicated" means that the second cavity 21 is only communicated with the material inlet 12 or only communicated with the material outlet 13.

Preferably, the number of the second cavities 21 is at least one, the driver 3 drives the material distribution part 3 to reciprocate so that the second cavities 21 are alternatively communicated with the material inlet 12 or the material outlet 13, when the driver 3 is the linear driving material distribution part 2 or the circumferential driving linear part, the material distribution part 2 can be alternatively and independently communicated with the material inlet 12 or the material outlet 13 in a reciprocating manner, where "alternatively and independently communicated" means that the second cavities 21 are only communicated with the material inlet 12 or only communicated with the material outlet 13.

Preferably, the number of the second cavities 21 is two or more, the driver 3 drives the material distribution part 3 to move periodically so as to make the second cavities 21 communicate with the material inlet 12 or the material outlet 13 in a circulating manner, in this embodiment, the periodic movement mainly means that the second cavities 21 move circumferentially along with the rotation of the material distribution part 2 by taking a rotating shaft of the driver 3 as a center, in other embodiments, the material distribution part 2 can also move periodically in a closed loop other than a circle under the driving of the driver 3, so that the functions of material taking and material discharging of the second cavities 21 in a circulating manner can be also achieved, and the description is omitted; the second end plate 102 can completely shield any two adjacent second cavities 21 towards one side of the second end plate 102 at least, so that the second end plate 102 can always shield the second cavities 21 when the material distribution part 2 moves periodically along with the driver 3, the second cavities 21 are gradually communicated and gradually separated from the discharge port 13, and the material inlet 12 is communicated with the second cavities 21 which are discharging, so that the quantitative material taking function cannot be realized.

Specifically, in this embodiment, the size of the cross section of the second cavity 21 is uniformly transitioned from one side of the second cavity 21 to the other side, and in other embodiments, the size of the cross section of the second cavity 21 may be gradually transitioned from one side of the second cavity 21 to the other side, or may be gradually transitioned after being uniform, or may be transitioned at irregular rate, as long as the filling and discharging of the second cavity 21 are not affected, and this is not particularly limited.

Further, the second end plate 102 is disposed at a slope; the height of the side, close to the material inlet 12, of the second end plate 102 is lower than the height of the side, far away from the material inlet 12, of the second end plate 102; be favorable to like this letting the equal smooth position that drops to pan feeding mouth 12 of material of pan feeding mouth 12 top, avoid a small amount of materials to gather the unable position that gets into pan feeding mouth 12 of long term on second end plate 102, and exceed its effective shelf life, thereby influence the save of other materials in second end plate 102 top, here especially be convenient for to some preserve of eating material class material, if eating material class material is detained on second end plate 102 for a long time, it is rotten and putrefaction to probably take place, thereby influence the shelf life and the new freshness of other edible materials, just can solve this problem well after setting up through letting second end plate 102 be the slope.

The embodiment of the utility model also provides a material storage device 1, which comprises a material bin 1b capable of storing materials and a quantitative material taking mechanism 1a, wherein the quantitative material taking mechanism 1a is arranged at the bottom of the material bin 1b of the material storage device 1; the outer wall of the bin 1b and the outer wall (namely the cylinder 100) of the shell 10 are integrally formed, the outer wall (namely the cylinder 100) of the shell 10 and the bottom plate (namely the first end plate 101) are integrally formed, namely the outer wall of the bin 1b, the cylinder 100 and the first end plate 101 are integrally formed, so that the manufacturing is convenient, and the sealing performance of the whole material storage device is ensured after the upper part of the bin 1b is sealed and the discharge hole 13 of the shell 10 is sealed; since the material storage device 1 employs the quantitative material taking mechanism 1a as described above, all technical effects of the quantitative material taking device as described above are obtained, and will not be described in detail herein.

The foregoing is a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations are also considered as the protection scope of the present invention.

Claims (10)

1. A quantitative take off mechanism for quantitatively outputting solid materials in a container, comprising:

the device comprises a shell, a first cavity is formed in the shell, a feeding hole communicated with the first cavity is formed in the top of the shell, and a discharging hole communicated with the first cavity is formed in the bottom of the shell;

the material distributing part is movably arranged in the first containing cavity, and a second containing cavity which can be communicated with the material inlet or the material outlet is formed in the material distributing part;

the driver is used for driving the material distributing part to move, is arranged on the shell and is connected with the material distributing part;

when the material distributing part moves to the second containing cavity and is communicated with the material inlet, the second containing cavity is separated from the material outlet; when the material distributing part moves to the second containing cavity and is communicated with the material outlet, the second containing cavity is separated from the material inlet.

2. The quantitative material taking mechanism according to claim 1, wherein the first cavity is cylindrical, and the driver is used for driving the material distributing component to rotate along the axial direction of the first cavity;

or the first cavity is spherical, and the driver is used for driving the material distributing part to rotate;

or, the first containing cavity is a cuboid, and the driver is used for driving the material distributing component to linearly move in the first containing cavity.

3. The dosing and reclaiming mechanism as claimed in claim 2 wherein, when the first cavity is cylindrical:

the shell comprises a cylinder, a first end plate arranged at one end of the cylinder and a second end plate covered with the other end of the cylinder, the first end plate, the cylinder and the second end plate enclose a cylindrical first containing cavity, the first end plate is provided with a discharge hole, and the second end plate is provided with a feeding hole; in the axial direction of the cylinder: the projection of the feeding port and the projection of the discharging port are arranged in a staggered manner; two ends of the second cavity penetrate through the material distributing part.

4. The metered dose take off mechanism of claim 3, wherein the cross-sectional area of the side of said second cavity connected to said inlet is less than or equal to the cross-sectional area of said inlet, and the cross-sectional area of the side of said second cavity connected to said outlet is less than or equal to the cross-sectional area of said outlet.

5. The quantitative material taking mechanism according to claim 2, wherein the material distributing part is cylindrical, and the material distributing part is rotatably arranged in the cylindrical first accommodating cavity; or the material distributing part is spherical and is rotatably arranged in the spherical first containing cavity; or the material distributing part is blocky and is arranged in the first accommodating cavity of the cuboid in a sliding mode.

6. The quantitative material taking mechanism as claimed in claim 2, wherein the driver is a rotary motor or a rotary cylinder, and a rotating shaft of the driver penetrates into the first cavity and is connected with the material distributing part; or the driver is a linear cylinder or a linear module, and an output shaft/end of the driver penetrates into the first cavity and is connected with the material distributing component.

7. The quantitative material taking mechanism according to claim 1, wherein the number of the second cavities is at least one, and the driver drives the material distributing part to reciprocate so that at least one of the second cavities is communicated with the material inlet or the material outlet alternatively;

the size of the cross section of the second cavity is in uniform transition from one side of the second cavity to the other side of the second cavity, or in gradual transition, or in uniform transition and then in gradual transition.

8. The quantitative material taking mechanism according to claim 3, wherein the number of the second cavities is more than two, and the driver drives the material distributing part to move periodically to enable the second cavities to be communicated with the material inlet or the material outlet in a circulating manner; the second end plate can at least completely shield one side of any two adjacent second cavities facing the second end plate;

the size of the cross section of the second cavity is in uniform transition from one side of the second cavity to the other side of the second cavity, or in gradual transition, or in uniform transition and then in gradual transition.

9. The quantitative take off mechanism as in claim 3, wherein the second end plate is sloped; and the height of one side, close to the feeding port, of the second end plate is lower than the height of one side, far away from the feeding port, of the second end plate.

10. A material storage device comprising a silo for storing material, and further comprising a dosing and reclaiming mechanism as claimed in any one of claims 1 to 9 disposed at the bottom of the silo.

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