KR101964086B1 - Controllable Apparatus of Specified Quantity of A Fluid - Google Patents

Abstract

The present invention relates to a quantitative release device capable of releasing only a necessary amount, and according to the present invention, there is provided a quantitative release device capable of releasing a liquid agent to be discharged to the outside and supplying a liquid agent to be discharged to the outside; An emitter receiving the liquid agent supplied from the liquid agent supply unit and discharging the liquid agent to the outside; And a liquid supply unit connected to the liquid supply unit and the discharge unit so as to be supplied from the liquid supply unit and to be delivered to the discharge unit and to transfer the liquid supply supplied from the liquid supply unit to the discharge unit side, A quantitative supply unit capable of adjusting the amount of the fluid; A technique capable of suppressing the occurrence of a drop phenomenon of the remaining liquid agent by allowing only a necessary amount of the liquid agent to be released is disclosed.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a controllable apparatus,

The present invention relates to a quantitative release device capable of releasing only a necessary amount of a liquid type liquid agent to the outside.

In the process of manufacturing a product in various fields today, a pigment or various solutions (collectively referred to as a liquid agent) is uniformly applied to form a coating or the like. In order to coat a uniform thickness, a certain amount of the solution is uniformly sprayed through a device such as a sprayer.

When the liquid agent is applied in this manner, when the liquid agent remains at the nozzle end of the sprayer, the problem of dropping in the form of droplets is likely to occur. As the liquid drops from the tip of the nozzle, the uniform coating is not formed and the quality is deteriorated.

Accordingly, there has been a demand for a technique that the liquid agent is sent to the nozzle side exactly by the amount of the liquid agent to be injected and injected, thereby preventing the liquid agent from remaining at the nozzle tip and falling down.

Korean Patent No. 10-1401585 Korean Patent No. 10-1091088

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-described conventional problems, and to provide a quantitative release device which can be released only by a necessary amount of a liquid agent.

According to an aspect of the present invention, there is provided a quantitative ejection apparatus including: a liquid agent supply unit for receiving a liquid agent to be discharged to the outside and supplying a liquid agent to be discharged to the outside; An emitter receiving the liquid agent supplied from the liquid agent supply unit and discharging the liquid agent to the outside; And a liquid supply unit connected to the liquid supply unit and the discharge unit so as to receive the liquid supply from the liquid supply unit and to transfer the liquid supply to the discharge unit and to transfer the liquid supply supplied from the liquid supply unit to the discharge unit, A fixed amount supply unit capable of adjusting the amount of the liquid agent; May be included as one feature.

Here, the liquid supply unit may include: a liquid tank for providing a space for accommodating the liquid agent; And a liquid supply pipe connected to the liquid reservoir at one side and connected to the reservoir at the other side for guiding the liquid contained in the liquid reservoir to the reservoir; May be another feature of the present invention.

Furthermore, the liquid supply pipe may be made of a flexible material so that it can be bent flexibly.

Further, the liquid supply pipe may be made of a transparent material so as to confirm the state of the liquid in the liquid supply pipe.

Here, the fixed amount supply unit may include a screw shaft having a screw-shaped thread for transferring the liquid supplied from the liquid supply unit to the discharge unit, A screw cap positioned at one side of the screw shaft and having a pumping hole formed therein so that the screw shaft rotates; A supply body having at least a portion of the screw cap and the screw shaft, the supply body supporting the screw cap and the screw shaft; A servo motor connected to the other side of the screw shaft and rotating the screw shaft; Wherein one end of the screw shaft is inserted into the pumping hole of the screw cap and at least a portion of the screw thread is in contact with the inner surface of the pumping hole, It is also possible to provide a liquid injection hole for injecting the liquid supplied from the supply part side and supply the liquid solution to the inside of the pumping hole through the liquid injection hole.

Furthermore, the discharging portion may be located at one side of the fixed amount supplying portion, and may include a needle having a transfer hole formed therein so that the liquid can be transferred; And a nozzle cap positioned at one side of the fixed amount supply unit and having the needle inserted therein, May be included as another feature.

An air supply unit connected to the fixed amount supply unit and supplying air to the fixed amount supply unit or the discharge unit side so that the liquid is sprayed from the discharge unit; May be further included.

Further, the supply body of the fixed amount supply unit is provided with an air injection hole through which air supplied from the air supply unit side is injected, and the air injection hole formed in the supply body communicates with the injection hole side provided in the nozzle cap It may be another feature.

Further, the inner surface of the nozzle cap may be provided with an air stream guider for guiding the flow of air while suppressing generation of vortex of the air injected through the air injection hole. have.

The quantitative release device according to the present invention is capable of releasing only the necessary amount of the liquid agent, thereby suppressing the occurrence of the phenomenon of the remaining liquid agent falling.

1 is an exploded perspective view schematically showing a quantitative release device according to an embodiment of the present invention.
FIG. 2 is a partly exploded view schematically showing a quantitative release device according to an embodiment of the present invention. FIG.
3 is a side cross-sectional view schematically showing a side cross-section of a quantitative emission device according to an embodiment of the present invention.
4 is a partial cross-sectional perspective view schematically showing a nozzle cap and a needle of a quantitative ejection apparatus according to an embodiment of the present invention.
5 is a partial cross-sectional perspective view schematically illustrating an application form of a nozzle cap in a quantitative ejection apparatus according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is an exploded perspective view schematically showing a quantitative ejection apparatus according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view of a quantitative ejection apparatus according to an embodiment of the present invention. FIG. 4 is a partial cross-sectional perspective view schematically showing a nozzle cap and a needle of a quantitative release device according to an embodiment of the present invention. FIG.

1 to 4, a quantitative release device according to an embodiment of the present invention includes a liquid supply portion, a discharge portion, and a fixed amount supply portion, and more preferably, an air supply portion.

In this description, a raw material to be discharged or jetted by a certain amount with a coating, a spray or a dispenser is simply referred to as a liquid agent.

The liquid supply portion accommodates a liquid agent to be discharged to the outside, and supplies the liquid agent to be discharged to the outside. The liquid supply portion may include a liquid tank 110 and a liquid supply pipe 130.

The liquid tank 110 provides a space in which a liquid agent (not shown) is accommodated. To this end, the liquid tank 110 has a space for receiving the liquid agent therein, as shown in the figure, and a liquid supply pipe 130 is connected to one side thereof. Therefore, the liquid agent contained in the liquid tank 110 can be moved to the supply body side of the fixed amount supply unit through the liquid supply pipe 130.

One side of the liquid supply pipe 130 is connected to the liquid tank 110 and the other side is connected to the fixed amount supply side so that the liquid agent contained in the liquid tank 110 can be guided to the side of the fixed amount supply unit.

That is, the liquid agent is moved from the liquid tank 110 to the liquid supply pipe 130, and the liquid agent moved along the liquid supply pipe 130 is injected into the supply body of the constant amount supply unit connected to the other side of the liquid supply pipe 130.

The liquid supply pipe 130 is preferably made of a flexible material so that it can be bent flexibly. If the liquid supply pipe 130 is made of a flexible material, it is preferable that the gradient and position of the liquid tank 110 can be changed.

Also, it is preferable that the liquid supply pipe 130 is made of a transparent material so that the state of the liquid in the liquid supply pipe 130 can be confirmed. When the liquid supply pipe 130 is made of a transparent material, it is preferable that the liquid supply pipe 130 is properly filled with liquid.

The fixed amount supply unit is coupled to the liquid supply unit and the discharge unit so that the liquid supply unit can receive the liquid supply from the liquid supply unit and transfer it to the discharge unit. Then, the liquid agent supplied from the liquid agent supply unit is transferred to the discharge unit side, and the amount of the liquid agent delivered to the discharge unit side is adjusted.

Preferably, the dosing unit includes a screw shaft 220, a screw cap 240, a supply body 260, and a servomotor 210.

The screw shaft 220 transfers the liquid agent supplied from the liquid agent supply unit to the discharge unit side. And screw-shaped threads for one side are formed in order to transfer the liquid agent to the discharge part side.

This screw shaft 220 is inserted and embedded in the supply body 260 together with the screw cap 240 as referenced in the figure. As will be described later, a space is formed inside the supply body 260 so as to accommodate the screw shaft 220 together with the screw cap 240.

The screw shaft 220 is rotated by the servomotor 210, which will be described later.

The screw cap 240 is located on one side of the screw shaft 220. Inside the screw cap 240, a pumping hole is formed so that a part of the screw shaft 220 is inserted and rotated.

On the upper side of the screw cap 240, a liquid agent injection hole 241 is formed to communicate with the pumping hole so that the liquid agent that has passed through the liquid agent supply pipe 130 can be supplied.

The screw thread of the screw shaft 220 rotates inside the pumping hole and the liquid agent flowing into the pumping hole through the liquid injecting hole 241 is pushed by the screw thread as the screw shaft 220 rotates, (310).

It is preferable that the upper end portion of the screw in the form of a screw thread is in contact with the inside surface of the pumping hole of the screw cap 240 so that the liquid agent can be accurately moved toward the needle 310 side.

In this way, one side of the screw shaft 220 is inserted into the pumping hole of the screw cap 240 so that at least a part of the screw-shaped thread is in contact with the inside surface of the pumping hole, and the supply body 260 and the screw cap 240, Liquid injection holes 261 and 241 for injecting the liquid supplied from the liquid supply portion side are preferably formed and the liquid supply is preferably supplied to the inside of the pumping hole through the liquid injection hole 241. [

When the servo motor 210 rotates the screw shaft 220, the liquid agent contained in the grooves between the threads and the threads is pushed to the needle 310 side. The amount of the liquid agent to be discharged to the outside can be fixed to a predetermined amount by the degree of rotation of the screw shaft 220 through the servo motor 210 because the amount of the liquid agent to be delivered is one after the rotation of the screw shaft 220 .

Here, the liquid agent may be rotated in one direction according to the rotating direction of the screw formed in the screw shaft 220, or the liquid agent may be collected by rotating in a direction opposite to the one direction. Accordingly, it is possible to prevent the liquid agent remaining at the end of the needle 310 from dropping from the end of the needle 310 to the droplet, if at all.

At least a portion of the screw cap 240 and the screw shaft 220 are contained in the supply body 260 and the screw cap 240 and the screw shaft 220 are supported by the supply body 260 do.

As described above, the supply body 260 is provided with a liquid injection hole 261 on the upper side so that the liquid can be introduced into the pumping hole of the screw cap 240. The liquid injection hole 261 is connected to the liquid supply pipe 130.

The supply body 260 is formed with an air injection hole 225 through which air supplied from the air supply unit is injected and an air injection hole 225 formed in the supply body 260 is connected to the air hole (333) provided in the nozzle cap (330).

The servo motor 210 is connected to the other side of the screw shaft 220 as described above, and rotates the screw shaft 220. The direction of rotation of the screw shaft 220 by the servomotor 210 and the rotational speed of the screw shaft 220 can adjust the discharge amount of the liquid agent.

It is further preferable that a display (not shown) is provided to display the emission of the liquid agent according to the rotation speed of the servo motor 210 so that the liquid can be recognized from the outside.

It is also preferable that a control unit (not shown) for controlling the operation of the servo motor 210 is provided.

An air supply unit (not shown) is connected to the metering supply unit and supplies air to the metered dose supply unit or the discharge unit side so that the liquid agent can be sprayed from the discharge unit.

The air supplied from the air supply unit is injected into the air injection hole 225 provided in the supply body 260 of the fixed amount supply unit. The air injected into the air injection hole 225 passes through the air hole 313 formed in the needle 310 of the discharge part and flows into the spray hole 333 provided inside the nozzle cap 330 of the discharge part. The air introduced into the spray hole 333 of the nozzle cap 330 is exhausted to the outside at one end of the nozzle cap 330. At this time, the liquid sprayed along the transfer hole 311 of the needle 310 is sprayed .

It is also desirable to further include such an air supply.

The discharging portion receives the liquid agent supplied from the liquid agent supplying portion side via the fixed amount supplying portion and discharges the liquid agent to the outside.

Preferably, this release comprises needle 310 and nozzle cap 330.

The needle 310 is located at one side of the supply body 260 of the fixed amount supply part and has a transfer hole 311 formed therein so that the liquid agent can be transferred. The transfer hole 311 is formed to penetrate from one end to the other end of the needle 310 as shown in the figure.

The transfer hole 311 communicates with the inner space of the screw cap 240 mentioned above. Therefore, the liquid agent, which is generated by the rotation of the screw shaft 220, enters the feed hole 311 of the needle 310 from the screw cap 240.

The liquid agent that has entered the transfer hole 311 moves to one end of the transfer hole 311 and is discharged to the outside. The shape to be ejected here may be a form sprayed like a spray or a form ejected like a droplet like a dispenser, and may be selected or adjusted by the nozzle cap 330.

The needle 310 is provided with an air hole 313 so that the air injected through the air injection hole 225 of the supply body 260 can be introduced into the nozzle cap 330 as schematically shown in the figure.

The air injected through the air injection hole 225 flows into the injection hole 333 side of the nozzle cap 330 through the air hole 313 of the needle 310 and flows to the outside through the one end of the nozzle cap 330 Exhausted.

The nozzle cap 330 is located at one side of the supply body 260 of the metering supply. The needle 310 is inserted into the nozzle cap 330 to be inserted therein. The needle 310 is inserted into the injection hole 333 which is a space provided inside the nozzle cap 330 and the outside of the needle 310 and the inside of the nozzle cap 330 There is an empty space. Air flows into this empty space.

As described above, the liquid agent moved along the transfer hole 311 at one end of the needle 310 moves along the injection hole 333, and the air discharged from the one end of the nozzle cap 330 to the outside, Lt; / RTI >

With this configuration, spraying can be performed while suppressing generation of dust even at a relatively low pressure.

It is also preferable that an air stream guider 337 is provided on the inner surface of the nozzle cap 330 as a more applied form. The air stream guider 337 guides the flow of air while suppressing vortex generation of the air injected through the air injection hole.

It is sufficient that the air stream guider 337 has a form capable of setting the air flow so that the air flow can be uniformly formed. Accordingly, various forms other than those illustrated in the drawings are possible.

It is preferable that the air flows toward the one end of the nozzle cap 330 while the air is wrapped around the needle 310 by the air stream guider 337.

As described above, when the air is discharged from the one end of the nozzle cap 330 to the outside in a constant flow, the liquid agent can be uniformly sprayed, and the spraying of the liquid agent from one end of the nozzle cap 330 due to vortex can be suppressed It is preferable.

In the quantitative ejection apparatus described in one or more of the above, it is also possible to additionally include the following configuration.

That is, it is also preferable that the liquid tank 110 is provided with a tilting means so that the central axis of the liquid tank 110 can be tilted at a predetermined angle with respect to the screw shaft 220. In this case, the liquid supply pipe 130 is preferably made of a flexible material as described above, since the liquid tank 110 can be smoothly tilted.

The tilting of the liquid tank 110 may be advantageous because the liquid remaining in the liquid tank 110 can be smoothly introduced into the liquid supply pipe 130 side.

As described above, the quantitative ejection apparatus according to the present invention has an advantage that it can be released only by a necessary amount of the liquid agent, thereby suppressing the occurrence of the phenomenon that the remaining liquid agent falls.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the scope of the present invention is to be construed as being limited only by the embodiments, and the scope of the present invention should be understood as the following claims and their equivalents.

110: liquid tank 130: liquid supply pipe
210: Servo motor 220: Screw shaft
240: screw cap 260: supply body
310: Needle 330: Nozzle cap

Claims (9)

A liquid agent supply part for containing the liquid agent to be discharged to the outside and supplying the liquid agent to be discharged to the outside;
An emitter receiving the liquid agent supplied from the liquid agent supply unit and discharging the liquid agent to the outside; And
Wherein the liquid agent supply unit is connected to the liquid agent supply unit and the discharge unit to receive the liquid agent from the liquid agent supply unit and to transfer the liquid agent to the discharge unit, A quantitative supply unit capable of adjusting the amount of the fluid; , ≪ / RTI &
The quantitative feeder
A screw shaft having a screw thread for feeding the liquid agent supplied from the liquid agent supply unit to the discharge unit side;
A screw cap positioned at one side of the screw shaft and having a pumping hole formed therein so that the screw shaft rotates;
A supply body having at least a portion of the screw cap and the screw shaft, the supply body supporting the screw cap and the screw shaft; And
A servo motor connected to the other side of the screw shaft and rotating the screw shaft; Lt; / RTI >
Wherein one end of the screw shaft is inserted into the pumping hole of the screw cap so that at least a part of the screw thread is in contact with the inner surface of the pumping hole,
Characterized in that the supply body and the screw cap are provided with a liquid injection hole through which the liquid supplied from the liquid supply part side is injected and the liquid supply is supplied through the liquid injection hole to the inside of the pumping hole Device.
The method according to claim 1,
The liquid-
A liquid tank for providing a space in which the liquid agent is accommodated; And
A liquid supply pipe which is connected to the liquid tank at one side and connected to the side of the fixed amount supply unit and guides the liquid stored in the liquid tank to the side of the fixed amount supply unit; And a discharge port for discharging the liquid.
3. The method of claim 2,
Characterized in that the liquid supply pipe is made of a flexible material so as to be flexibly bent.
The method of claim 3,
Wherein the liquid supply pipe is made of a transparent material so as to confirm the state of the liquid in the liquid supply pipe.
delete The method according to claim 1,
The emitter
A needle positioned at one side of the fixed amount supply unit and having a transfer hole for transferring the liquid agent; And
A nozzle cap positioned at one side of the fixed amount supply unit, the nozzle cap being inserted and contained inside; And a discharge port for discharging the ion beam.
The method according to claim 6,
An air supply unit connected to the fixed amount supply unit and supplying air to the fixed amount supply unit or the discharge unit side so that the liquid is sprayed from the discharge unit; Further comprising a plurality of quantum discharge devices.
8. The method of claim 7,
Wherein the supply body of the fixed amount supply unit is formed with an air injection hole into which air supplied from the air supply unit side is injected,
Wherein the air injection hole formed in the supply body communicates with the injection hole side of the nozzle cap.
9. The method of claim 8,
The inner surface of the nozzle cap
Wherein an air stream guider is provided for guiding the flow of air while suppressing generation of vapors of air injected through the air injection holes.

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