KR101968193B1 - Fluid-material Ejecting Apparatus - Google Patents

Abstract

The present invention relates to a liquid substance dispensing apparatus for discharging a liquid substance to a target point in a quantitative manner. More specifically, the present invention relates to a stator having a female threaded through-hole formed in a cylindrical direction in a flow direction from an inlet to an outlet. And a rotor which is inserted into the through hole of the stator to form a transfer space between the stator and rotates to move the liquid material from the inlet side to the outlet side along the transfer space while sliding the inner circumferential surface of the through hole. The diameter of the rotor is increased from the inlet side toward the discharge port side and decreases as the volume of the transfer space is directed toward the flow direction, thereby compressing the liquid substance moving along the transfer space and discharging the liquid substance as the rotor is rotated. Liquid water in the transport space It can be removed from the cell, and presents a liquid material discharge device that can maintain a constant density and the amount of ejection of the liquid material to be discharged by the compacting of a liquid material to reduce the volume of the feed space gradually toward the flow direction.

Description

Liquid-material Ejecting Apparatus

The present invention relates to a liquid substance dispensing apparatus, and more particularly, to a liquid substance discharging apparatus capable of quantitatively discharging a liquid substance to a target point.

In general, a liquid material discharging device is a device used to quantitatively discharge a viscous liquid and is mainly used for molding, bonding, and sealing operations in various fields such as semiconductors, optical products, and general home appliances.

Such a liquid material discharging device typically uses a solenoid valve and an actuator to instantaneously open a nozzle to discharge liquid material, and transfers liquid material by rotating the rotor in a passage filled with liquid material using a motor and a rotor. It can be divided into a manner to discharge the conveyed liquid material. Particularly, when more precise work is required in a field requiring precision of semiconductors, optical products, home appliances, etc., a method of discharging liquid materials using a motor and a rotor for continuous quantitative discharge of liquid materials is one of the above-described discharging methods. Mainly used.

However, the discharging method using a motor and a rotor needs to maintain a constant volume of the liquid-filled space even when the rotor rotates in a passage filled with the liquid material so that the liquid material can be discharged in a fixed amount. In order to control the fine discharge amount, a passage filled with a liquid material is formed in a spiral shape, and a rotor is formed in a spiral shape corresponding to the spiral shape of the passage to control the discharge amount. However, the liquid material is often a mixture of somewhat different materials kneaded in order to have a specific function, and such kneaded liquid material contains a relatively large amount of bubbles even if an antifoaming agent is used. As a result, even if the liquid substance is discharged in a quantitative manner, the discharge amount of the liquid substance discharged due to the bubbles of the liquid substance changes depending on the distribution of the bubbles, and thus the change of the discharge amount of the liquid substance in the field requiring precision is simple. There can be a variety of problems ranging from faults to critical errors.

The liquid material discharge device as described above is disclosed in Korean Patent Laid-Open Publication No. 0177371 and No. 1998-087586 as a prior art, but a solution to the above-described problems is not presented.

Accordingly, an object of the present invention devised to solve the above problems is to provide a liquid material dispensing apparatus capable of removing bubbles from the liquid material in the transport space when discharging the liquid material as the rotor is rotated. .

In addition, another object of the present invention is to provide a liquid material discharging device capable of maintaining a constant density and discharge amount of the liquid material discharged by compressing the liquid material by gradually reducing the volume of the transport space toward the flow direction.

In addition, another object of the present invention is to provide a liquid material discharge device that can discharge the gas generated while removing bubbles with respect to the liquid material moved in the transport space to the outside without interfering with the discharge of the liquid material. .

In order to achieve the above object, the liquid material discharging device according to the present invention has a stator having a female screw-shaped through hole formed in a flow direction from an inlet to an outlet of a cylindrical shape, and is formed in a male screw shape, and inserted into the through-hole of the stator. And a rotor for forming a conveying space between the stator and being rotated to move the liquid material from the inlet side to the outlet side along the transport space while sliding the inner circumferential surface of the through hole, wherein the diameter of the rotor is the outlet port at the inlet side. It is increased toward the side to decrease the volume of the transport space toward the flow direction, it characterized in that the liquid material moving along the transport space is compressed.

The apparatus may further include a through-hole penetrated to the outside of the rotor in a reverse direction of the flow direction from the inlet to the outlet, such that the gas generated as the liquid material moves along the transport space and is compressed to the outside through the through-hole. Can be released.

The apparatus may further include a sealing member formed to surround the upper outer circumferential surface of the rotor between the inlet and the through hole to prevent backflow of the liquid material.

In addition, the sealing member may be opened by the pressure of the gas generated from the liquid material to form a gas discharge path from the inlet to the through hole.

In addition, the liquid material discharging device according to the present invention is a stator having a female screw through hole formed in the flow direction from the inlet to the discharge port in a cylindrical shape, and is formed in the male screw shape is inserted into the through hole of the stator, the diameter is inlet side In order to increase the discharge port toward the discharge side to form a transport space is reduced between the stator and the volume in the flow direction, and rotates to move the liquid material from the inlet side to the discharge port side along the transfer space while sliding the surface of the through hole A first block having a rotor to be coupled to an upper side of the stator, and having a supply port formed to supply liquid material to one side, and having a storage space connected to the inlet port from the supply port so that the liquid material stays predetermined; The outer wall is coupled to the upper side of the first block and the center The second block is coupled to the upper side of the rotor has a sealing member for sealing the upper surface of the rotor while having a sealing unit for supplying a rotational force to the rotor, and includes a second block formed with a through hole penetrating into the outer wall, A collection space for collecting the gas generated while the liquid material moved along the transport space is compressed is formed on the upper side of the storage space, to release the gas collected in the collection space through the through hole of the second block It is done.

In addition, the through hole may be formed on the upper side of the sealing member.

In addition, the sealing member may be opened by the pressure of the gas to form a gas discharge path from the collecting space toward the through-hole.

In addition, the sealing member may be a plurality of, stacked on the upper side from the collecting space, each sealing member may be sequentially opened by the pressure of the gas.

According to the liquid substance ejecting apparatus of the present invention as described above, as the rotor is rotated, it is possible to remove bubbles from the liquid substance in the transport space when discharging the liquid substance.

In addition, the volume of the conveying space is gradually reduced in the flow direction to compress the liquid substance, thereby maintaining the density and discharge amount of the liquid substance discharged.

In addition, there is an advantage that the gas generated while removing the bubbles with respect to the liquid material moved in the transport space can be released to the outside without interfering with the discharge of the liquid material.

Effects according to the present invention in the above is not limited to the above, other effects of the present invention through the matters described in the embodiments and claims to be described later clearly by those skilled in the art to which the present invention belongs. It can be understood.

1 is an overall perspective view of a liquid material discharge apparatus according to a preferred embodiment of the present invention.
2 is an exploded perspective view of FIG.
3 is a cross-sectional view of a liquid material discharge apparatus according to a preferred embodiment of the present invention.
4 is a partial cross-sectional view of FIG.
5A is a schematic cross-sectional view of FIG. 4.
5B is a cross-sectional view of FIG. 5A.
6 is a functional diagram of FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, the same reference numerals are used for components having the same function within the scope of the same idea, and redundant description thereof will be omitted.

First, FIG. 1 is an overall perspective view of a liquid substance discharging apparatus according to a preferred embodiment of the present invention, FIG. 2 is an exploded perspective view of FIG. 1, and FIG. 3 is a cross-sectional view of a liquid substance discharging apparatus according to a preferred embodiment of the present invention. As shown, the present invention is a liquid material discharge device for quantitatively discharging the liquid material, the cylindrical through-hole 110 formed in the flow direction from the inlet 112 to the discharge port 113 in a cylindrical direction The stator 100 has a male screw shape and is inserted into the through-hole 110 of the stator 100 to form a transfer space 111 between the stator 100 and rotates. The rotor 200 for moving the liquid material from the inlet 112 side to the discharge port 113 side while sliding the inner circumferential surface of the), the straight line of the rotor 200 The increase in the inflow port 112 side toward the discharge port 113 side decreases as the volume of the transfer space 111 is directed toward the flow direction, thereby compressing the liquid material moving along the transfer space 111.

Here, it is coupled to the upper side of the stator 100, has a supply port 310 formed to supply the liquid material on one side, connected to the inlet 112 from the supply port 310 therein so that the liquid material stays predetermined The first block 300 having a storage space 311, the outer wall is cylindrically coupled to the upper side of the first block 300, the upper side of the rotor 200 is coupled to the center of the upper portion of the rotor 200 It may include a second block 400 having a driving unit for supplying a rotational force to the rotor 200 while having a sealing member 431 for sealing the surface, the through-hole 420 is formed through the outer wall. In this case, a collecting space 432 is formed above the storage space 311 to collect the gas generated while the liquid material moved along the transport space 111 is compressed, so that the second block 400 Collected in the collection space 432 through the through hole 420 The sieve is released to the outside.

Specifically, FIG. 4 is a partial cross-sectional view of a liquid material discharging device according to a preferred embodiment of the present invention. As shown, the liquid material discharging device according to a preferred embodiment of the present invention may include a stator 100 and a rotor 200. ).

The stator 100 is cylindrical and has a through-hole 110 having a female thread shape therein. In detail, the through hole 110 is an inlet 112 through which one side of the liquid material is introduced, and a discharge hole 113 through which the liquid material is discharged, and forms a flow direction from the inlet 112 to the outlet 113. The through hole 110 of the stator 100 has a substantially elliptical through hole 110 when the vertical section of the stator 100 is viewed, and the through hole 110 is discharged from the inlet 112 to the outlet 113. A female screw shape is formed while making a forward or reverse rotation.

The rotor 200 is inserted into the through hole 110 of the stator 100, and the outer circumferential surface thereof is formed into a male screw shape. Through this, a transfer space 111 is formed between the inner circumferential surface of the through hole 110 and the outer circumferential surface of the rotor 200, and the liquid substance discharged to the transfer space 111 is filled. As the rotor 200 rotates, the liquid material in the transfer space 111 gradually moves from the inlet 112 to the outlet 113 according to the rotation of the rotor 200 while sliding the inner circumferential surface of the through hole 110. Done.

In other words, as the rotor 200 is rotated, when the through hole 110 is viewed in a vertical section as shown, the rotor 200 is moved while rotating from the end of the long axis of the elliptical axis to the other end. In other words, a transfer space 111 is formed between each screw bone of the female screw shape of the stator 100 and the male screw shape of the rotor 200, and the rotor 200 is formed in the through hole according to the rotation of the rotor 200. The transport space 111 is gradually moved from the inlet 112 to the discharge port 113 through the reciprocating motion while rotating from the end of the long axis of the 110 to the other end at the inlet 112 along the transport space 111. The liquid material is moved toward the discharge port 113 and discharged to the outside.

The rotor 200 may increase in diameter from the inlet 112 toward the outlet 113. FIG. 5A is a schematic cross-sectional view of FIG. 4, and FIG. 5B is a vertical cross-sectional view of FIG. 5A, in which the diameter of the rotor 200 increases as the liquid material flows, ie, from the inlet 112 to the outlet 113. Can be increased gradually. At this time, the cross-sectional area of each through hole 110 in the flow direction is preferably configured to be the same. More specifically, the through hole 110 gradually increases only the pitch of the female thread to correspond to the diameter of the rotor 200 increasing from the inlet 112 to the outlet 113 so that the cross-sectional area of the through hole 110 is the same. Will be able to maintain.

As a result, when the stator 100 is viewed in a vertical cross-section, the elliptical long axis is gradually shortened in the flow direction, ie, each portion of the screw except the rotor 200, that is, the female screw shape of the stator 100 and the male screw shape of the rotor 200. The volume of the transfer space 111 in between is gradually reduced. Therefore, the liquid material introduced at the same pressure from the inlet 112 is compressed by the liquid material by the volume gradually reduced in the flow direction. At this time, the gas contained in the liquid material is pushed toward the inlet 112 with a relatively low pressure from the discharge port 113 where the pressure is relatively high when the discharge port 113 and the inlet 112 are compared. That is, as the volume of the transfer space 111 gradually decreases in the flow direction from the inlet 112 to the discharge port 113, the gas contained in the liquid material is removed from the liquid material moved along the transfer space 111. As a result, the amount and density of the liquid substance discharged to the discharge port 113 can be kept uniform.

Subsequently, the liquid material discharging device according to the preferred embodiment of the present invention includes a stator 100 and a rotor for continuously supplying the liquid material to the inlet 112 of the stator 100 together with the rotor 200. Block 300 and the rotor 200 may include a second block 400 for supplying a rotational force. In detail, the first block 300 is a hollow body coupled to the upper side of the stator 100. In the present invention, a part or the entirety of the stator 100 is preferably inserted into and fixed to the first block 300. Here, the nozzle is coupled to the lower end of the first block 300 by forming a long hole through the center of the stator 100 so as to surround the end of the stator 100 to easily discharge the discharged liquid material at a desired position. Sphere 330 may be constructed.

The first block 300 has a supply port 310 formed therein so as to supply a liquid material to one side of the outer circumferential wall. Here, in order to move the liquid material supplied to the supply port 310 to the inlet 112 of the stator 100 therein has a storage space 311 connected from the supply port 310 to the inlet 112 It is preferable. For example, when the liquid material is supplied from the supply port 310, the liquid material stays in the storage space 311 for a predetermined time, and is continuously supplied to the inlet 112 by the supply pressure of the liquid material supplied from the supply port 310. The liquid substance is moved.

Subsequently, the second block 400 has a cylindrical shape in which the lower end is opened and the upper end is closed, and an outer wall of the lower end is coupled to an upper side of the first block 300. In addition, the upper side of the rotor 200 is coupled to the center, and the inside has a drive unit 410 for supplying rotational force to the rotor 200, the upper side of the rotor 200 and the drive unit 410 Connected.

Here, the drive unit 410 is installed in the second block 400 to supply the rotational force to the rotor 200, between the drive motor 411, the drive motor 411 and the rotor 200. Is connected to the rotational force transmission body 412 for transmitting the rotational force of the drive motor 411 to the rotor 200 may be configured. In the present invention, the drive motor 411 may be composed of a general motor such as a forward and reverse motor, the power connector 413 for supplying power may be connected to the upper side of the drive motor 411. In addition, the torque transmitting member 412 may be configured with a general reduction gear arranged in the same straight line as the rotor 200. However, the driving motor 411 and the rotational force transmission body 412 can be implemented by a conventional motor driving technique, so the detailed description thereof will be omitted.

Subsequently, the liquid material discharging device of the present invention may further include a through hole 420 penetrated to the outside of the rotor 200 in the reverse direction of the flow direction from the inlet 112 to the discharge port 113. As a result, the gas generated while the liquid substance is moved and compressed along the transport space 111 may be discharged to the outside through the through hole 420. For example, the through hole 420 may be formed to penetrate inward from the outer wall of the second block 400. A sealing member 431 may be formed between the inlet 112 and the through hole 420 so as to surround the upper outer circumferential surface of the rotor 200 to be hermetically sealed. As a result, the liquid material may be prevented from flowing out to the second block 400 in a direction opposite to the flow direction from the inlet 112 to the outlet 113. In the present invention, the sealing block 430 having a cylindrical sealing member 431 is installed in the inner space to facilitate the assembly of the first block 300 and the second block 400, and the assembly of the sealing member 431 It may be further included. Specifically, the sealing block 430 is installed between the second block 400 to which the rotor 200 is coupled and the first block 300 to which the stator 100 is coupled to seal the upper outer peripheral surface of the rotor. Member 431 may be enclosed.

Through this, the through hole 420 is located above the sealing member 431, and the transfer space 111 between the storage space 311 and the sealing member 431 of the first block 300. A predetermined collection space 432 may be formed in which gas generated while the liquid material moved along the surface is compressed is collected. Here, the sealing member 431 preferably has an elastic material, more preferably may be a rubber material. The sealing member 431 may be composed of at least one or more pieces, and may be stacked upward from the collection space. That is, the sealing member 431 may have a predetermined elasticity by an elastic material, wherein the sealing member 431 is a gas generated from the liquid material moved in the transfer space 111 is the collection space 432 When collected in the air, the gas discharge path 433 is formed from the collecting space 432 toward the through hole 420 while being elastically opened by the pressure of the gas. In addition, when the sealing member 431 is composed of at least one or more, each sealing member 431 may be sequentially opened by the pressure of the gas. At this time, it is preferable that each sealing member 431 has a different elasticity so that each sealing member 431 can be sequentially opened from the collecting space 432.

As shown in FIG. 6, in the liquid material ejecting apparatus of the present invention, the gas generated therefrom from the liquid material moved along the transport space 111 does not go out to the supply port of the first block 300, but is a collecting space. The gas is discharged to the outside through the gas discharge passage 433 formed by the through hole 420 from 432. Therefore, in the present invention, the gas generated from the liquid material may not interfere with the supply of the liquid material continuously supplied to the supply port 310. In the liquid material discharge device of the present invention, the liquid material may be separated from the stator 100. There is an advantage that can easily discharge the gas generated while being compressed by the rotor 200 to the outside.

As described above, the liquid material discharge device according to the present invention has been described in detail a specific embodiment of the present invention, those skilled in the art to understand the spirit of the present invention to add, change, delete other components within the scope of the same spirit It will be possible to easily suggest other embodiments that fall within the scope of the inventive concept and other inventive concepts. Therefore, it should be understood that the embodiments described above are exemplary in all respects and not restrictive. The scope of the present invention is indicated by the scope of the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalent concept are included in the scope of the present invention. Should be interpreted.

100: stator 110: through hole
111: transfer space 112: inlet
113: discharge port 200: rotor
300: first block 310: supply port
311: storage space 330: nozzle hole
400: second block 410: drive unit
411: drive motor 412: torque transmission body
420: through hole 430: sealing block
431: sealing member 432: collecting space
433 gas release furnace

Claims (8)

delete delete delete delete A stator having a female threaded through hole formed in a flow direction from the inlet to the outlet in a cylindrical shape;
It is formed into a male thread and is inserted into the through hole of the stator, and the diameter increases as the diameter is directed from the inlet side to the outlet side, thereby forming a conveying space that decreases as the volume is directed in the flow direction, and rotates, A rotor for moving a liquid material from an inlet side to an outlet side along the transfer space while sliding a surface;
A first block coupled to an upper side of the stator and having a supply port formed to supply liquid material to one side, and having a storage space connected to the inlet port from the supply port to retain the predetermined liquid material;
The outer wall is cylindrically coupled to the upper side of the first block and the upper side of the rotor is coupled to the center having a sealing unit for sealing the upper surface of the rotor while having a drive unit for supplying rotational force to the rotor, on the outer wall A second block having a through hole formed therein; Including;
A collection space for collecting the gas generated while the liquid material moved along the transport space is compressed is formed on the upper side of the storage space, to release the gas collected in the collection space through the through hole of the second block But
The through hole is formed on the upper side of the sealing member,
The sealing member is opened by the pressure of the gas to form a gas discharge path from the collecting space toward the through hole,
The sealing member is a plurality of, a plurality of the different elastic force is laminated to the upper side from the collecting space, each sealing member is opened sequentially by the pressure of the gas,
The sealing member is installed in the sealing block, the sealing block is installed between the second block to which the rotor is coupled and the first block to which the stator is coupled, surrounding the sealing member on the outer peripheral surface of the rotor A liquid substance discharge device. delete delete delete

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