KR20200036393A - Pounded garlic quantitative distribution device - Google Patents

Abstract

Provided is an apparatus for distributing a fixed amount of crushed garlic, capable of weighing and supplying a preset amount of crushed garlic. According to an exemplary embodiment of the present invention, the apparatus comprises: a storage unit including a storage tank storing the crushed garlic therein and a transfer chamber connected to the storage tank; a first pressing unit connected to the transfer chamber and including a pressing piston and pressing cylinder pressing the crushed garlic placed in the storage unit; a discharge unit connected to a surface opposite to a side connected to the first pressing unit of the transfer chamber and discharging the crushed garlic transferred by the first pressing unit; a first transfer pipe connecting the transfer chamber and the storage tank and connected to a first opening/closing member; and a second transfer pipe connecting the transfer chamber and the discharge unit and connected to a second opening/closing member. The storage tank includes an injection unit for transferring the crushed garlic to the first transfer pipe having one side sealed by the first opening/closing member.

Description

{POUNDED GARLIC QUANTITATIVE DISTRIBUTION DEVICE}

The present invention relates to a chopped garlic quantitative distribution device.

In general, splitters were used to evenly distribute viscous materials such as chopped garlic, flour dough, and cement. Such a splitter usually has a storage tank, a discharge pipe connected to the storage tank, and an air injection part for injecting air.

When a worker injects a viscous material into a storage tank, the viscous materials are transferred to the discharge pipe under their own weight or external force. Thereafter, when air is injected into the discharge pipe through the air injection unit, the viscous material is moved to a place requiring air pressure to distribute the viscous material.

This air-injected splitter has the advantage of simple structure and easy distribution of viscous material without the need for additional equipment.However, due to the viscosity of the viscous material, the viscous material could not be properly discharged by blocking the discharge pipe. , This causes a problem that the accuracy of distribution is deteriorated.

In addition, since the distribution amount of the viscous material is determined only by the injection time and amount of air, it is difficult to accurately measure the amount, and there is a problem that it is difficult to easily change the distribution amount according to the size of each container.

One embodiment of the present invention is to provide a chopped garlic quantitative distribution device capable of quantifying and supplying chopped garlic in a preset amount.

According to an aspect of the present invention, a storage tank having a storage tank for storing chopped garlic therein and a transmission chamber connected to the storage tank; A first pressurizing part connected to the transfer chamber and having a pressurizing piston and a pressurizing cylinder pressurizing the chopped garlic located inside the storage part; And an outlet portion connected to the opposite side of the side to which the first pressing portion of the transmission chamber is connected, and discharging the chopped garlic moved by the first pressing portion. A first transmission tube connected between the transmission chamber and the storage tank, to which a first opening / closing member is connected; And a second transmission pipe connecting the transmission chamber and the discharge unit, and a second opening / closing member connected thereto, wherein the storage tank is chopped to the first transmission tube whose one side is sealed by the first opening / closing member. Provided is a chopped garlic quantitative distribution device including an injection unit for transferring garlic.

In addition, the injection portion, the injection body is located on the upper surface of the storage tank, a rotating member for generating a rotational force therein; An injection member extending in the storage tank direction, one end of which is located inside the storage tank and connected to the rotating member to rotate; And it is formed along the circumference of the outer surface of the injection member, and may include a spiral-shaped injection blade for pressing the chopped garlic in the storage tank in the direction of the first transmission tube.

In addition, the first pressing portion, the first pressing tube is connected to the first opening and closing member to determine the opening and closing of the first opening and closing member by applying air pressure to the first opening and closing member; And a second pressure pipe connected to the second opening / closing member to determine opening / closing of the second opening / closing member by applying air pressure to the second opening / closing member.

In addition, the discharge unit, a discharge member for storing the chopped garlic supplied from the transfer chamber therein; A driving cylinder positioned adjacent to the discharge member and having a driving piston therein; And a connecting member connected to the discharge member and the driving piston to adjust the height of the discharge member according to the movement of the driving piston.

In addition, the chopped garlic quantitative dispensing device may further include a second pressurizing portion connected to the discharge portion, positioned inside the discharge portion, and pressurizing and discharging the chopped garlic through air pressure.

The chopped garlic quantitative distribution device according to an embodiment of the present invention can quantify and supply chopped garlic in a preset amount.

1 is a perspective view of a chopped garlic quantitative distribution device according to an embodiment of the present invention.
2 is a cross-sectional view of the storage unit shown in FIG. 1.
3 is a view showing a state in which chopped garlic is injected into the transfer chamber of the storage unit shown in FIG. 2.
4 is a view showing a state in which the chopped garlic is transferred from the transfer chamber of the storage unit shown in FIG. 2.
5 is a cross-sectional view of the discharge unit shown in FIG. 1.
6 is a view showing a state in which chopped garlic is injected into the discharge member of the discharge unit shown in FIG.
7 is a view showing a state in which the chopped garlic is discharged from the discharge member of the discharge unit shown in FIG. 5 to the outside.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains may easily practice. The present invention can be implemented in many different forms and is not limited to the embodiments described herein. In the drawings, parts not related to the description are omitted in order to clearly describe the present invention, and the same reference numerals are attached to the same or similar elements throughout the specification.

1 is a perspective view of a chopped garlic quantitative distribution device according to an embodiment of the present invention.

Referring to FIG. 1, the chopped garlic quantitative distribution device 1 according to an embodiment of the present invention may include a storage unit 100, a first pressing unit 300, and a discharge unit 500.

At this time, the storage unit 100 may include a storage tank 110 and a transmission chamber 170.

2 is a cross-sectional view of the storage unit shown in FIG. 1.

1 and 2, the storage tank 110 may have an opening formed in an upper surface, and a first storage space 111 may be formed therein. The operator may inject chopped garlic through the upper surface of the storage tank 110 to store the chopped garlic in the first storage space 111.

At this time, the cross-sectional area in the width direction of the storage tank 110 may gradually decrease as the opening is formed from upward to downward. Through this, the storage tank 110 allows the operator to easily store the chopped garlic inside the storage tank 110 by increasing the cross-sectional area of the upper portion, and gradually narrowing the cross-sectional area to reduce the chopped garlic into the first transmission tube 130 ) Can be easily moved.

At this time, the injection part 200 may be located on the upper surface of the storage tank 110. Referring to FIG. 1, the injection body 230 of the injection unit 200 may be connected to the first support 210 formed extending upward from the upper surface of the first pressing unit 300.

Also, referring to FIG. 2, a rotating member 231 may be located on the inner surface of the injection body 230. For example, the rotating member 231 is an electric motor whose rotating shaft is formed toward the direction of the storage tank 110, or is in contact with a vertical gear and a vertical gear fitted to the rotating shaft extending along the longitudinal direction of the injection body 230, and It may be a horizontal gear that rotates with a rotational axis in a direction perpendicular to the longitudinal direction, but is not limited thereto.

The injection member 250 may be located on the surface of the rotating member 231 facing the storage tank 110. For example, the injection member 250 may be formed in a column shape extending in a direction toward the inner surface of the storage tank 110.

At this time, a spiral-shaped injection blade 251 that descends along the circumference of the injection member 250 may be formed. The injection blade 251 may be formed in a downward direction along the outer surface of the injection member 250.

The worker operates the rotating member 231 inside the injection body 230 by operating the injection unit 200 connected to the storage tank 110. At this time, the rotating member 231 rotates the connected injection member 250 and the injection blade 251 formed on the outer surface of the injection member 250.

The rotating injection member 250 pushes the chopped garlic stored in the storage tank 110 through the injection blade 251 to the lower portion of the first storage space 111, and the chopped garlic moves toward the first transmission tube 130 It can be pressurized as much as possible.

Through this, the injection unit 200 can press the chopped garlic of the storage tank 110 downward, so that the chopped garlic can be easily moved.

Meanwhile, the transmission chamber 170 may be provided in a plurality corresponding to the plurality of first transmission tubes 130. At this time, one side of the transmission chamber 170, for example, the upper surface may be connected to the first transmission pipe 130, and the other side may be connected to the second transmission pipe 400 connected to the discharge unit 500.

In addition, a second storage space 171 in which chopped garlic transferred through the transmission space 131 of the first transmission tube 130 is stored may be formed inside the transmission chamber 170. That is, chopped garlic stored in the first storage space 111 is moved to the second storage space 171 of the transmission chamber 170 through the first transmission pipe 130. The chopped garlic moved to the second storage space 171 is moved to the discharge unit 500 through the second transmission pipe 400.

On the other hand, a first transmission tube 130 in the shape of a pipe may be located on the lower surface of the storage tank 110. Also, a transmission space 131 may be formed in the first transmission tube 130.

The transmission space 131 may be provided to communicate with the first storage space 111 of the storage tank 110. That is, the first transmission pipe 130 may allow the chopped garlic stored in the first storage space 111 to be transferred to the transmission chamber 170 through the transmission space 131.

In addition, referring to FIG. 1, a plurality of first transmission tubes 130 may be provided on the lower surface of the storage tank 110. The plurality of first transmission tubes 130 may simultaneously transmit the chopped garlic by transmitting the chopped garlic stored in the storage tank 110 to the transfer chamber 170 in parallel.

That is, the chopped garlic moved due to the injection unit 200 in the storage tank 110 is directed to the transmission chamber 170 through the transmission space 131 of the first transmission tube 130.

On the other hand, referring to Figure 2, the first opening and closing member 150 is located between the first transmission tube 130 and the transmission chamber 170, the second between the transmission chamber 170 and the second transmission tube 400 The opening and closing member 190 may be located.

At this time, the first opening and closing member 150 may include a first opening and closing body 151, a first opening and closing cylinder 153 and a first opening and closing partition wall 155.

The first opening / closing body 151 is positioned adjacent to the first transmission tube 130, and a first opening / closing cylinder 153 having a tube-like shape with both ends opened inside the first opening / closing body 151 is mounted. Through this, the first opening / closing body 151 may wrap the outer surface of the first opening / closing cylinder 153 to protect the first opening / closing cylinder 153 in an external environment such as an impact.

A first opening and closing nozzle 154 may be formed on one side of the first opening and closing body 151. One end of the first opening and closing nozzle 154 may be connected to the end of the first opening and closing cylinder 153. In addition, the other end of the first opening and closing nozzle 154 may be connected to the first pressing pipe 331 of the first pressing unit 300 to be described later. In addition, the first opening and closing cylinder 153 may be connected to communicate with the transmission space 131, which is an internal space of the first transmission tube 130.

At this time, a first opening and closing partition wall 155 may be located inside the first opening and closing cylinder 153. The first opening / closing partition wall 155 is located inside the first opening / closing cylinder 153 and can be activated along the inner surface of the first opening / closing cylinder 153. In this case, the area of the first opening and closing partition wall 155 may be provided to correspond to the cross-sectional area in the width direction of the first transmission tube 130.

For example, the first opening / closing partition 155, which is activated along the inner side wall of the first opening / closing cylinder 153, is pushed out due to the air supplied from the first pressing tube 331 of the first pressing unit 300, , The first transmission tube 130 can be sealed. Conversely, when a negative pressure is generated in the first pressure pipe 331, the first opening / closing partition 155 is pulled in the direction of the first opening / closing body 151 due to a pressure difference, and the first transmission pipe 130 is opened. .

Through this, the first opening / closing member 150 may determine whether the first transmission tube 130 is opened or closed with the first opening / closing partition 155.

Meanwhile, the second opening / closing member 190 may include a second opening / closing body 191, a second opening / closing cylinder 193, and a second opening / closing partition 195.

The second opening / closing body 191 is positioned adjacent to the second transmission tube 400, and a second opening / closing cylinder 193 having a tube-like shape with both ends opened inside the second opening / closing body 191 is mounted. Through this, the second opening / closing body 191 may wrap the outer surface of the second opening / closing cylinder 193 to protect the second opening / closing cylinder 193 in an external environment such as an impact.

A second opening and closing nozzle 194 may be formed on one side of the second opening and closing body 191. One end of the second opening and closing nozzle 194 may be connected to the end of the second opening and closing cylinder 193. In addition, the other end of the second opening and closing nozzle 194 may be connected to the second pressure pipe 333 of the first pressing portion 300 to be described later. In addition, the second opening and closing cylinder 193 may be connected to communicate with the inner space of the second transmission tube 400.

At this time, a second opening and closing partition 195 may be located inside the second opening and closing cylinder 193. The second opening / closing partition 195 is located inside the second opening / closing cylinder 193 and can be activated along the inner surface of the second opening / closing cylinder 193. At this time, the area of the second opening / closing partition 195 may be provided to correspond to the cross-sectional area in the width direction of the second transmission tube 400.

For example, the second opening / closing partition 195, which is activated along the inner side wall of the second opening / closing cylinder 193, is pushed out due to the air supplied from the second pressure pipe 333 of the first pressing unit 300, , It is in close contact with the inner surface of the second transmission tube 400 and can seal the second transmission tube 400. Conversely, when a negative pressure is generated in the second pressure pipe 333, the second opening and closing partition 195 is pulled in the direction of the second opening and closing body 191 due to the pressure difference, and the second transmission pipe 400 is opened. .

Through this, the second opening / closing member 190 may determine whether the second transmission pipe 400 is opened or closed with the second opening / closing partition 195.

Meanwhile, the first pressing part 300 may be located on the lower surface of the storage part 100 and the injection part 200. For example, one or more air pumps (not shown) that can adjust the air pressure may be formed inside the first pressing unit 300.

In this case, the first pressing part 300 may include a first pressing pipe 331, a second pressing pipe 333 and a pressing cylinder 350.

Each air pump is connected to the first pressure pipe 331 and the second pressure pipe 333 shown in Figure 1, the first pressure pipe 331 and the second pressure pipe 333 by injecting air to the positive pressure It can be generated or sucked the air of the first pressurized pipe 331 and the second pressurized pipe 333 by negative pressure and discharged to the outside.

Meanwhile, the first pressure pipe 331 and the second pressure pipe 333 may communicate with the outside through a first communication hole 330 formed on one surface of the first pressure unit 300, for example, an upper surface. have. In addition, the first pressure pipe 331 and the second pressure pipe 333 may be provided in plurality in correspondence with the number of the first opening and closing members 150 or the second opening and closing members 190 of the storage unit 100. .

Each first pressure pipe 331 is connected to the first opening and closing member 150, the second pressure pipe 333 is connected to the second opening and closing member 190, the first transmission pipe 130 through the air pressure And it can control whether the second transmission tube 400 is opened or closed.

On the other hand, the pressing cylinder 350 may be formed in a tubular shape in which the pressing space 355, which is a hollow portion therein, is formed. In addition, one end of the pressurized cylinder 350 may be connected to a side surface of the transfer chamber 170, for example, a surface opposite to the surface to which the second transfer pipe 400 of the transfer chamber 170 is connected.

At this time, the pressing cover 310 may be formed along the outer circumferential surface of the pressing cylinder 350. The pressure cover 310 covers the outer surface of the pressure cylinder 350 to prevent the pressure cylinder 350 from being directly exposed to the outside.

Meanwhile, the pressure cylinder 350 may have a pressure nozzle 351 formed at the other end. The pressurizing nozzle 351 may be connected via an air pump inside the first pressurizing portion 300 and a third pressurizing pipe 335. The air pump of the first pressurization unit 300 may adjust the internal air pressure of the pressurization cylinder 350 through the third pressurization pipe 335.

In addition, the pressurized piston 353 may be located inside the pressurized cylinder 350. The cross-sectional area of the pressure cylinder 350 in the width direction may be formed to be the same as the cross-sectional area of the pressure piston 353. For example, when the pressure cylinder 350 is a cylindrical tube material, the pressure piston 353 may be formed of a cylinder having the same cross-sectional area as the cross-sectional area of the inner surface of the pressure space 355 of the pressure cylinder 350. You can.

The pressurized piston 353 having the same cross-sectional area as the pressurized space 355 of the pressurized cylinder 350 is pressed in accordance with the air pressure control of the third pressurized tube 335 in close contact with the inner surface of the pressurized cylinder 350 ( 350).

For example, when air is injected into the third pressurized pipe 335 and positive pressure occurs, the injected air pushes the pressurized piston 353 in the direction of the transfer chamber 170 and the second inside the transfer chamber 170 The storage space 171 is pressed. Conversely, when negative pressure is generated in the third pressure pipe 335, the pressure piston 353 moves in the direction of the pressure nozzle 351.

FIG. 3 is a view showing a state in which chopped garlic is injected into a transfer chamber of the storage unit shown in FIG. 2, and FIG. 4 is a view showing a state in which chopped garlic is transferred from the transfer chamber of the storage unit shown in FIG. 2.

2 to 4, one embodiment of a process of quantitatively distributing chopped garlic 2 to the storage unit 100 and the first pressing unit 300 will be described.

The chopped garlic 2 stored in the first storage space 111 of the storage tank 110 is quantified by the injection unit 200 and moves to the transmission space 131 of the first transmission tube 130.

At this time, the amount of chopped garlic 2 transmitted to the first transmission tube 130 per unit time through rotation of the injection member 250 may correspond to the volume change of the pressing space 355 due to the pressing piston 353. .

For example, when the injection member 250 and the injection blade 251 rotates and transmits the chopped garlic 2 to the first transmission tube 130, the rotational force of the rotation member 231 connected to the injection member 250 The size determines the amount of chopped garlic 2 that is transmitted to the first transmission tube 130.

At this time, by adjusting the rotational speed of the rotating member 231, the volume per unit time of the pressurized space 355 due to the pressurized piston 353, the transmission amount of the chopped garlic 2 transmitted to the first transmission pipe 130 per unit time It can be adjusted to match the change. That is, by performing the pre-quantification with the injection unit 200 before performing the quantification with the pressurized piston 353 and the pressurized cylinder 350, it is possible to facilitate the subsequent quantification work.

Through this, the injection unit 200 may be controlled to constant the amount of the chopped garlic is transmitted before quantifying the chopped garlic through the pressurized piston 353 and the pressurized cylinder 350 to quantify the chopped garlic.

In addition, the volume of the transmission space 131 may be formed to be the same as the amount of change in the volume of the internal space of the pressure cylinder 350 due to the pressure piston 353 to be described later.

The chopped garlic injected from the injection unit 200 is primarily located in the transmission space 131 of the first transmission tube 130. At this time, the pressurized piston 353 is moved along the inside of the pressurized cylinder 350 and changes the volume of the inner space of the pressurized cylinder 350 and transfers the chopped garlic inside the storage unit 100.

At this time, by forming the volume of the transmission space 131 to be the same as the amount of change in the volume of the interior space of the pressure cylinder 350, which changes according to the movement of the pressure piston 353, only the chopped garlic of a predetermined amount is transferred space ( 131) to determine the minced garlic.

Through this, the first transmission tube 130 may quantify chopped garlic through the volume of the transmission space 131.

Meanwhile, the air pump connected to the first pressurizing pipe 331 of the first pressurizing portion 300 applies a negative pressure that sucks the air of the first pressurizing pipe 331, thereby providing a first located inside the first opening / closing member 150. The first opening / closing member is opened by moving the opening / closing partition 155 in the direction of the first opening / closing nozzle 154.

At the same time, the air pump connected to the second pressurizing pipe 333 of the first pressurizing portion 300 opens and closes the second inside the second opening and closing member 190 through positive pressure pushing air into the second pressurizing pipe 333. The second transmission tube 400 is sealed by allowing the partition wall 195 to move in the direction of the inner surface of the second transmission tube 400.

Subsequently, the first pressurizing part 300 applies a negative pressure to suck air from the third pressurizing tube 335 with an air pump connected to the third pressurizing tube 335 to pressurize the piston 353 inside the pressurizing cylinder 350. Is moved in the direction of the pressure nozzle 351.

At this time, the product of the transfer chamber 170 by the volume of the pressing space 355 reduced by the product of the moved distance of the pressing piston 353 and the cross-sectional area in the width direction of the pressing piston 353, that is, the pressing piston 353 is moved. 2 The volume of the storage space 171 is increased. In the volume change, an air pressure difference is formed between the second storage space 171 and the external space.

Due to this difference in air pressure, the chopped garlic 2 in the transmission space 131 moves to the transmission chamber 170. The moved chopped garlic 2 is stored in the second storage space 171 and reduces the volume of the second storage space 171 to increase the air pressure accordingly. Finally, the crushed garlic 2 in an amount corresponding to the volume of the second storage space 171 increased as the pressurized cylinder 350 is pushed to move to the second storage space 171.

The operator can control the amount of chopped garlic 2 to be quantified by adjusting the size of the negative pressure applied to the third pressure pipe 335. For example, by increasing the size of the eup pressure, the amount of chopped garlic 2 flowing into the second storage space 171 can be increased, and conversely, by reducing the size of the negative pressure, the moving distance of the pressurized piston 353 is increased. The amount of chopped garlic 2 to be quantified can be reduced.

Through this, the chopped garlic quantitative distribution device 1 according to an embodiment of the present invention can quantify the chopped garlic 2 using a pressurized cylinder 350 and a pressurized piston 353.

Subsequently, when the chopped chopped garlic 2 is stored in the second storage space 171 inside the transfer chamber 170, the first pressing unit 300 applies positive pressure to inject air into the first pressing tube 331. By applying the first opening and closing member 150 to seal the first transmission tube 130, it is to prevent the minced garlic (2) of the intended amount or more from being moved to the second storage space (171).

In addition, the first pressing unit 300 applies negative pressure to the second pressing pipe 333 so that the second opening / closing partition 195 moves in the direction of the second pressing nozzle 351, so that the second transmission pipe 400 is Will open.

When the second transmission pipe 400 is opened, the first pressure unit 300 applies positive pressure to inject air into the third pressure pipe 335 so that the pressure piston 353 moves in the direction of the transmission chamber 170. . The pressurized piston 353 is pushed in the direction of the transfer chamber 170, thereby reducing the volume of the second storage space 171 of the transfer chamber 170.

The second storage space 171 having a reduced volume correspondingly has an increased air pressure than the external space. Due to the difference in the air pressure, a flow of air from the transfer chamber 170 toward the second transfer pipe 400 is formed, and this flow of air pushes the chopped garlic 2 into the second transfer pipe 400 It is to be moved in the discharge part 500 direction.

At this time, the length of the pressurized piston 353 may be configured to be the same as the retracted distance in the process of moving the chopped garlic 2 to the second storage space 171. That is, the chopped garlic 2 may allow the pressurized piston 353 to retreat and move to the discharge unit 500 only in a predetermined amount.

Through this, the chopped garlic quantitative distribution device 1 can transmit only the chopped garlic 2 in a quantified amount to the discharge unit 500.

Meanwhile, referring to FIG. 1, a second pressing unit 800 and a conveyor 710 may be positioned below the discharge unit 500.

The second pressurization unit 800 may have an air pump (not shown) located inside the same as the first pressurization unit 300. In addition, the air pump is connected to the fourth pressure pipe 831 and the fifth pressure pipe 833 connected to each component of the discharge part 500, and the fourth pressure pipe 831 and the fifth pressure pipe 833 May communicate with the outside through the second communication hole 830 formed on the upper surface of the second pressing unit 800. Through this, the second pressing unit 800 may supply air pressure to each component of the discharge unit 500.

On the other hand, the conveyor 710, for example, may be located on the upper surface of the second pressing unit 800. The conveyor 710 may be formed to extend in one direction, be formed in the form of a belt that moves along the length direction, or may be configured such that rollers (not shown) or other transport means are disposed in parallel.

At this time, a storage container 730 may be formed on the upper surface of the conveyor 710. The storage container 730 may receive chopped garlic quantified from the storage unit 100 from the discharge unit 500 and store it in the container.

5 is a cross-sectional view of the discharge unit shown in FIG. 1.

1 and 5, the discharge unit 500 may include a driving cylinder 530, a connection member 560 and a discharge member 570.

The driving cylinder 530 may be formed in a tube shape with one end closed and the other end open. Also, a plurality of driving cylinders 530 may be provided corresponding to the number of the transfer chambers 170 of the storage unit 100, for example.

At this time, the driving cylinder 530 may be positioned perpendicularly to the upper surfaces of the second pressing unit 800 and the conveyor 710 in a state where one end is closed upward. A driving nozzle 531 into which the fourth pressure pipe 831 is fitted may be formed at a closed one end of the driving cylinder 530.

In addition, the driving piston 540 may be located inside the driving cylinder 530. At this time, the driving piston 540 may have a shape corresponding to a cross-sectional area on the inner surface of the driving cylinder 530 having a tube shape. For example, when the shape of the driving cylinder 530 is a cylindrical tube material, the driving piston 540 may be formed in a cylindrical shape corresponding thereto.

The cross-sectional area in the width direction of the driving piston 540 may be formed to have the same value as the driving cylinder 530. That is, the driving cylinder 530 is connected to the air pump of the second pressing unit 800 via the fourth pressing pipe 831, and the inner portion of the driving cylinder 530 according to the operating state of the second pressing unit 800 The pressure of can be changed.

When the pressure inside the driving cylinder 530 is changed, for example, when a positive pressure is injected into the air from the fourth pressure pipe 831, the pressure inside the driving cylinder 530 increases and the driving piston 540 It is pushed in the lower direction, that is, in the direction of the conveyor 710.

Conversely, when air pressure is drawn in from the fourth pressure pipe 831, the driving piston 540 rises toward the driving nozzle 531.

Through this, the driving piston 540 may be pushed down or pushed up according to the pressure of the second pressing part 800 and may be activated inside the driving cylinder 530.

Meanwhile, the plurality of driving cylinders 530 may be fixed by being connected to the support members 511 shown in FIGS. 1 and 5. For example, the support member 511 is formed in a square plate shape, and a plurality of driving cylinders 530 may be coupled to one side of the support member 511.

Also, at least one of the side surfaces of the support member 511 may be connected to the second support 510. The second support 510 may be formed, for example, in the form of a pillar extending upward from the upper surface of the second pressing unit 800 adjacent to the conveyor 710. The support member 511 is coupled to the second support 510, and may be positioned at a predetermined distance from the conveyor 710.

Meanwhile, as illustrated in FIGS. 1 and 5, the driving cylinder 530 may further include a discharge pipe support 513 formed to protrude on one side of the driving cylinder 530. In addition, the discharge pipe support 513 may be connected to the discharge pipe 550.

For example, the discharge pipe 550 may be formed in a tube shape formed to extend perpendicular to the ground, and may pass through the discharge pipe support 513 vertically and be combined with the discharge pipe support 513. At this time, a fifth pressing pipe 833 connected to the second pressing portion 800 may be fitted to the upper end of the discharge pipe 550. In addition, the lower end of the discharge pipe 550 may penetrate the upper end of the connecting member 560 and be located inside the discharge member 570.

At this time, the air pump of the second pressurization unit 800 connected via the discharge pipe 550 and the fourth pressure pipe 831 may inject air into the discharge pipe 550 through positive pressure. The injected air moves through the discharge pipe 550 to the interior space of the discharge member 570. Due to this, the internal pressure of the discharge member 570 increases, and chopped garlic stored inside the discharge member 570 may be discharged to the outside through air pressure.

Meanwhile, a connecting member 560 may be formed at an end of the driving piston 540 below. The connecting member 560 may be formed in a square plate shape, for example, as shown in FIG. 1, and may be coupled to the lower ends of the plurality of driving pistons 540.

The connecting member 560 connected to the driving piston 540 is moved up and down according to the movement of the plurality of driving pistons 540, and the position of the discharge member 570 can be adjusted. For example, when a positive pressure is generated through which the air is supplied through the fourth pressure pipe 831, the driving piston 540 moves downward and moves the connecting member 560 below the discharge unit 500, that is, the conveyor ( 710, the connecting member 560 can be moved. Conversely, when the negative pressure absorbing the air is generated in the air pump connected to the fourth pressure pipe 831 and the fourth pressure pipe 831, the driving piston 540 moves upward along the inner surface of the driving cylinder 530. As it moves, the connecting member 560 is lifted upward.

On the other hand, the discharge member 570 extends in the vertical direction, both ends are formed in an open tube shape, penetrating through one side of the connection member 560 and can be combined with the connection member 560. At this time, inside the discharge member 570, a discharge space 571 in which chopped garlic can be stored is formed, and an outlet 573 through which chopped garlic is discharged may be formed at an end of the bottom of the discharge member 570. .

In addition, the side portion of the discharge member 570 may be connected to the second transmission pipe 400. The second transmission pipe 400 is connected to be able to communicate with the discharge space 571 of the discharge member 570, and discharges the chopped garlic quantified by the storage unit 100 and the first pressing unit 300 ( It can be transferred to the discharge space 571 of 570).

6 is a view showing a state in which chopped garlic is injected into the discharge member shown in FIG. 5, and FIG. 7 is a view showing a state in which the chopped garlic is discharged from the discharge member shown in FIG. 5 to the outside.

6 and 7, the process of discharging the minced garlic 2 in which the discharge unit 500 is quantified will be described.

The chopped garlic 2 transferred to the second transmission pipe 400 is pressurized by the pressure piston 353 of the storage unit 100 to move to the discharge space 571 of the discharge member 570. At this time, the conveyor 710 loaded with the storage container 730 on the upper side adjusts the position of the storage container 730 such that the storage space 731 in which the chopped garlic 2 is stored is located below the outlet 573. Is done.

Thereafter, the second pressurization unit 800 applies positive pressure to the fourth pressurization pipe 831 to transmit air to the driving cylinder 530. Due to this, the pressure in the internal space of the driving cylinder 530 increases, and the air pushes the driving piston 540 downward.

Due to this, the connecting member 560 and the connecting member 560 connected to the lower end of the driving piston 540 and the discharge member 570 connected to the connecting member 560 move downward and access to the storage container 730 Is done.

At this time, the volume of air injected through the fourth pressure pipe 831 may correspond to the product of the cross-sectional area in the width direction of the driving piston 540 and the moving distance of the driving piston 540. For example, when the driving piston 540 and the driving cylinder 530 have a tubular shape, the product of the cross-sectional area of the driving piston 540 and the moving distance, that is, the upper portion of the driving piston 540 increased by injecting air The volume of the internal space of the driving cylinder 530 located may have the same value as the amount of air injected into the fourth pressure pipe 831.

Accordingly, the operator can adjust the amount of air injected into the fourth pressure pipe 831 to control the moving distance between the driving piston 540 and the connection member 560 and the discharge member 570 connected thereto. For example, when the amount of chopped garlic 2 to be quantified is large, the worker reduces the distance of the driving piston 540 so that the chopped garlic 2 discharged to the storage container 730 comes into contact with the outlet 573 The shape can be prevented from being crushed or sticking to the outer surface of the outlet 573.

Through this, the chopped garlic quantitative distribution device 1 according to an embodiment of the present invention can easily discharge the chopped garlic 2 quantified by adjusting the height of the discharge member 570.

On the other hand, when the discharge member 570 approaches the storage container 730, the second pressure unit 800 applies positive pressure through the fifth pressure pipe 833 to inject air. The injected air passes through the fifth pressure pipe 833 and moves to the interior of the discharge member 570, thereby pressing the chopped garlic 2 stored in the discharge space 571.

The chopped garlic 2 pressurized by air is pushed out, and the discharge port 573 is moved from the discharge space 571 to the storage space 731 and discharged from the discharge unit 500. When the discharge is finished, the second pressurizing part 800 applies a town pressure that sucks air to the fourth pressurizing pipe 831 to connect the pressure piston 353 and the connecting member 560 connected to the pressure piston 353 and the discharge member The 570 is lifted above the storage container 730.

Thereafter, the conveyor 710 moves in one direction and moves the storage container 730 to move another storage space 731 in which the chopped garlic 2 of the storage container 730 is not stored to the lower portion of the discharge port 573 Will be moved.

Through this, the chopped garlic quantitative dispensing device 1 according to an embodiment of the present invention can continuously perform the quantification and discharge of the chopped garlic 2, thereby efficiently distributing the chopped garlic 2 have.

Although one embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments presented herein, and those skilled in the art to understand the spirit of the present invention may add elements within the scope of the same spirit. However, other embodiments may be easily proposed by changing, deleting, adding, or the like, but this will also be considered to be within the scope of the present invention.

1: Minced garlic quantitative distribution device 2: Minced garlic
100: storage unit 110: storage tank
111: first storage space 130: first transmission tube
131: transmission space 150: first opening and closing member
151: first opening and closing body 153: first opening and closing cylinder
154: first opening and closing nozzle 155: first opening and closing bulkhead
170: Transmission chamber 171: Second storage space
190: second opening and closing member 191: the second opening and closing body
193: second opening and closing cylinder 194: second opening and closing nozzle
195: second opening and closing bulkhead 200: injection
210: first support 230: injection body
231: rotating member 250: injection member
251: injection blade 300: first pressing portion
310: pressure cover 330: the first communication hole
331: 1st pressure pipe 333: 2nd pressure pipe
335: third pressurized pipe 350: pressurized cylinder
351: Pressurized nozzle 353: Pressurized piston
355: pressurized space 400: second transmission pipe
500: outlet 510: second support
511: support member 513: discharge pipe support
530: driving cylinder 531: driving nozzle
540: driving piston 550: discharge pipe
560: connecting member 570: discharge member
571: discharge space 573: discharge port
710: Conveyor 730: Storage container
731: Storage space 800: Second pressing part
830: 2nd communication hole 831: 4th pressure pipe
833: 5th pressure pipe

Claims (5)

A storage tank having a storage tank for storing chopped garlic therein and a transmission chamber connected to the storage tank;
A first pressurizing part connected to the transfer chamber and having a pressurizing piston and a pressurizing cylinder pressurizing the chopped garlic located inside the storage part; And
A discharge portion connected to the opposite side of the side to which the first pressing portion of the transfer chamber is connected and discharging the chopped garlic moved by the first pressing portion;
A first transmission tube connected between the transmission chamber and the storage tank, to which a first opening / closing member is connected; And
It comprises a second transmission pipe connecting the transmission chamber and the discharge portion, the second opening and closing member is connected,
The storage tank,
A quantum garlic quantitative distribution device including an injection unit for transferring the chopped garlic to the first transmission tube whose one side is closed by the first opening and closing member. According to claim 1,
The injection unit,
An injection body located on the upper surface of the storage tank and having a rotating member generating a rotating force therein;
An injection member extending in the storage tank direction, one end of which is located inside the storage tank and connected to the rotating member to rotate; And
It is formed along the circumference of the outer surface of the injection member, chopped garlic quantitative distribution device comprising a spiral-shaped injection blade for pressing the chopped garlic in the storage tank in the direction of the first transmission tube. According to claim 1,
The first pressing portion,
A first pressurizing pipe connected to the first opening and closing member to determine opening and closing of the first opening and closing member by applying air pressure to the first opening and closing member; And
It is connected to the second opening and closing member, chopped garlic quantitative distribution device comprising a second pressure pipe for determining the opening and closing of the second opening and closing member by applying air pressure to the second opening and closing member. According to claim 1,
The discharge unit,
A discharge member for storing the chopped garlic supplied from the transfer chamber therein;
A driving cylinder positioned adjacent to the discharge member and having a driving piston therein; And
A chopped garlic quantitative distribution device comprising a connection member connected to the discharge member and the driving piston and adjusting the height of the discharge member according to the movement of the driving piston. According to claim 1,
It is connected to the discharge portion, the chopped garlic quantitative distribution device further comprising a second pressing portion for discharging by pressing the chopped garlic through air pressure.

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