KR101344420B1 - Apparatus for discharging fixed quantity of liquid - Google Patents

Abstract

The present invention relates to an apparatus for discharging a fixed quantity of liquid and, more specifically, to a liquid fixed quantity discharge apparatus which accurately controls the quantity of liquid to discharge and prevents a leakage. The apparatus for discharging a fixed quantity of liquid according to the present invention includes: a chamber unit in which liquid flows and is stored and which has a discharge port for discharging the liquid; a cylinder which is attached to the upper end of the chamber unit; a piston which is inserted to be able to move up and down inside the cylinder; a needle which moves up and down in one united body by combining the upper end with the piston and opens and closes the discharge port of the chamber unit; a needle unit which has an end cap which is combined with the upper side of the cylinder; and a control unit which is attached to the flank of the needle unit and has a double action solenoid valve which controls the piston to move up or down by working fluid by supplying the working fluid to the upper or lower side of the cylinder.

Description

Apparatus for discharging fixed quantity of liquid}

The present invention relates to a liquid metering dispensing apparatus, and more particularly, to a liquid metering dispensing apparatus in which the amount of liquid to be discharged is precisely controlled and leakage is prevented.

Liquid-quantity dispensing apparatuses are apparatuses which are mainly used to apply electronic materials to electronic substrates. Generally, screw and needle valve methods are used.

The screw method is a method in which a liquid flowing from a liquid storage container is stored in a chamber, and a screw is mounted in the chamber to discharge the liquid by rotating the screw. This screw method has the advantage that the liquid can be stably discharged without being affected by the viscosity and fluidity of the liquid and the amount of liquid in the storage container. There is a problem that the liquid leaks according to the clearance between the inner peripheral surface and the outer peripheral surface of the screw. In addition, since the liquid is pushed out by a predetermined amount as the screw rotates, there is a problem that it is difficult to spray the liquid at high pressure.

On the other hand, the needle valve method is a method of mechanically opening and closing the discharge port by using a needle to adjust the pressure in the liquid storage container and the chamber so that the liquid is discharged the moment the discharge port is opened. This needle valve method has the advantage that the liquid does not leak even in the air state compared to the screw method and can be instantaneously high pressure discharge as needed, but for this purpose, the needle is integral with the piston when the needle is momentarily moved to open and close the discharge port. Needle placement and accurate operation are very important because they must be placed in the center of the discharge port simultaneously with movement.

In other words, if the needle is not correctly placed in the center of the discharge port, there is a problem of liquid leakage into the gap between the discharge port and the needle, and if the needle does not block the discharge port at the correct timing, the amount of liquid discharged is not controlled. It is most important to do.

However, in general, the discharge port is often a nozzle having a small diameter and the needle is difficult to arrange the needle precisely in the center of the discharge port because the needle is configured to open and close the discharge port as the end is inserted into the hole of the nozzle of the discharge port. . In addition, most of the needle valve method is that when the discharge port is opened while giving a signal, the pressure is applied to the needle by gravity or spring at the moment when the signal is cut off, and it is difficult to accurately control the closing time because the discharge port is closed by the needle falling under such pressure. there is a problem.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a liquid metering dispensing device which is easy to engage and dispose of needles and prevents leakage of liquid.

Another object of the present invention is to provide a liquid quantitative dispensing apparatus capable of quantitative discharging of liquid by precisely controlling the opening and closing time, and the liquid can be injected at a high pressure.

An object of the present invention described above, a chamber unit having a discharge port for injecting and storing liquid and for discharging the liquid, a cylinder attached to an upper end of the chamber unit, a piston inserted into the cylinder so as to be lifted and lowered; An upper end is fixedly coupled to the piston, the needle unit has a needle for opening and closing the discharge port of the chamber unit, a needle unit having an end cap coupled to an upper side of the cylinder, and attached to a side of the needle unit, It can be achieved by providing a liquid metering dispensing device comprising a control unit having a double-acting solenoid valve which controls the piston to be lowered or raised by the working fluid by supplying the working fluid upward or downward.

According to a preferred feature of the invention, the needle unit further comprises a wedge for integrally coupling the piston and the needle, the wedge has a tapered shape of the upper end is formed inside the hollow through which the needle penetrates the outer surface A thread is formed in the piston, and the screw groove is tapered inside so that the piston is inserted into the wedge. As the piston and the wedge are screwed together, the wedge is tightened so that the inner surface presses the outer surface of the needle. Can be fixed.

According to another preferred feature of the present invention, the liquid metering dispensing device may further include a pressurizing unit interposed between the chamber unit and the needle unit and pressurizing the needle of the needle unit downward.

According to another preferred feature of the invention, the pressing unit is a body having a space portion formed inside, a compression spring is inserted into the space portion of the body and one end is fixed to the lower surface of the cylinder, the upper surface of the compression spring The other end is fixed, and the needle of the needle unit is fixed through and a spring flange which is raised and lowered integrally with the needle, the spring flange is pressed downward by the compression spring when no external force is applied to the piston of the needle unit As a result, the needle descends to close the discharge port of the chamber unit.

According to another preferred feature of the invention, the pressing unit further comprises a wedge for integrally coupling the spring flange and the needle, the wedge has a tapered shape of the upper end of the hollow penetrating the inside It is formed and the thread is formed on the outer surface, the spring flange is formed with a threaded groove in the inner side so that the wedge is inserted, the wedge is tightened as the spring flange and the wedge is screwed, the inner surface is the outer surface of the needle The needle can be fixed by pressing.

According to another preferred feature of the present invention, the liquid metering dispensing device is an adjust body coupled to the upper side of the end cap of the needle unit, an indicator attached to the upper side of the adjust body and integral with the adjust body; And an adjust knob attached to an upper side of the indicator and integrally formed with the indicator, a stopper penetrating the adjust body and inserted into the adjust knob to be integrally formed and spaced apart from an upper end of the needle of the needle unit. It further comprises an adjustment unit having a needle, the movement distance of the needle unit upward by the stopper can be limited.

According to another preferred feature of the invention, the end cap of the needle unit and the adjust body of the control unit is screwed, the stopper is rotated integrally as the rotating the adjust knob is raised and lifted by the stopper The position can be adjusted.

According to another preferred feature of the present invention, the control unit may further include a compression spring that one end is fixed to the upper surface of the end cap and the other end is inserted into the adjust body to press upward.

According to another preferred feature of the invention, the chamber unit has a chamber body in which the liquid is introduced and stored, and a sheet provided on the lower side of the chamber body and the discharge port is discharged, the sheet is formed inside The groove may be tapered toward the discharge port, and the needle of the needle unit may be inserted into the groove of the sheet.

According to another preferred feature of the invention, the chamber unit is the upper end is screwed to the lower side of the chamber body, but the union unit protruding inwardly formed at the lower end, and the upper side has the shape of a cylindrical opening The seat housing is formed in the seat hole is formed to be seated and seated on top of the projection jaw to be seated on the engaging jaw of the union unit further comprises a seat housing, as the union unit is screwed with the chamber body Since the seat housing is moved upward, the sheet inserted into the seat housing may be attached to the lower side of the chamber body.

According to still another preferred feature of the present invention, the liquid metering dispensing apparatus may further include a heater into which the lower side of the chamber unit is inserted and which can control the liquid temperature inside the chamber body.

According to the liquid metering dispensing apparatus according to the present invention, the piston and the needle are firmly coupled by using the wedges, and the needle is easily disposed at the center of the piston and the center of the discharge port, thereby preventing the leakage of liquid.

According to the liquid metering dispensing apparatus according to the present invention, the piston is operated by the double-acting solenoid valve to precisely control the opening and closing time, thereby enabling the metering of the liquid. Can be discharged.

1 is a front view of a liquid metering discharge device according to the present invention.
FIG. 2 is a cross-sectional view of the liquid metering discharge device shown in FIG. 1. FIG.
3 is an exploded cross-sectional view of the liquid quantitative ejection device shown in FIG.
4 is an enlarged cross-sectional view of the chamber unit of the liquid quantitative ejection device shown in FIG.
FIG. 5 is an enlarged cross-sectional view of the needle unit of the liquid quantitative ejection device shown in FIG. 1; FIG.
6 is an enlarged cross-sectional view of the pressurizing unit of the liquid quantitative ejection device shown in FIG.
FIG. 7 is an enlarged cross-sectional view of a control unit of the liquid metering discharge device shown in FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the embodiments described below are merely illustrative of exemplary embodiments of the present invention so that those skilled in the art can easily carry out the invention, Do not.

With reference to FIGS. 1-7, the liquid quantitative discharge apparatus which concerns on embodiment of this invention is demonstrated. As shown, the liquid metering dispensing apparatus according to the embodiment of the present invention includes a chamber unit 100, the needle unit 200 and the control unit 300, the pressure unit 400, the control unit 500 and The heater 600 may further include.

The chamber unit 100 flows in and stores liquid supplied from the outside and discharges the liquid. To this end, as shown in FIGS. 2 to 4, a space is formed inside the chamber unit 100, and a side surface is formed with a passage connected to the inside space to allow liquid to flow from the outside. The liquid flowing through the passage is stored in the inner space of the chamber unit 100 and is discharged through the discharge hole formed in the lower center.

The chamber unit 100 includes a chamber body 110, a union unit 120, a seat housing 130, and a seat 140. The chamber body 110 forms a body of the chamber unit 100, and a space portion (not shown) is formed therein for storing liquid therein, and a hole for discharging liquid is provided in the lower portion of the space portion. Is formed. The outer surface of the chamber body 110 is formed with a passage through which liquid is introduced from the outside is connected to the interior space, the liquid to be discharged is introduced through the passage is stored in the space of the chamber body 110. To this end, an adapter 150 for delivering a liquid supplied from the liquid storage container 30 may be coupled to the passage of the outer surface of the chamber body 110, and the liquid of the liquid storage container 30 may be connected to the adapter 150. It is introduced into the chamber body 110 through. In addition, the lower outer peripheral surface of the chamber body 110 is formed with a screw thread so that the union unit 120 can be coupled.

Union unit 120 is screwed to the lower side of the chamber body 110 serves to secure the seat housing 130 and the seat 140. To this end, a screw groove corresponding to the thread of the chamber body 110 is formed at an upper end of the union unit 120, and a locking jaw (not shown) is protruded at an inner side of the union unit 120.

The seat housing 130 has a shape of a cylinder having an upper opening and a space formed therein so that the seat 140 can be inserted into an inner center thereof. In addition, a fitting hole (not shown) may be formed at the center of the lower surface of the seat housing 130 to seat the seat 140. On the upper side of the seat housing 130, a protruding jaw (not shown) is formed to protrude outward so as to be seated on the locking jaw of the union unit 120, and thus the union unit 120 is screwed into the chamber body 110. When it is rotated to be coupled to the projection jaw of the seat housing 130 seated on the locking jaw of the union unit 120 is moved upward to the seat 140 seated inside the seat housing 130 of the chamber body 110 It is attached to the lower side.

The sheet 140 has a discharge port (not shown) for discharging the liquid, and is provided below the chamber body 110. As shown in FIG. 4, the sheet 140 has a discharge port formed in the center thereof, and a groove (not shown) is tapered toward the discharge hole inside. In addition, a stage is formed on the outside to be seated in the seat housing 130, the seat housing 130 is raised by the union unit 120, and thus the seat 140 seated inside the seat housing 130 is By being raised together, the seat 140 is attached to the chamber body 110.

The needle unit 200 is attached to the upper end of the chamber body 110 and serves to open and close the discharge port of the chamber body 110. The needle unit 200 includes a cylinder 210, a piston 220, a needle 230, and an end cap 240, and may further include a wedge 250.

The cylinder 210 is attached to the top of the chamber body 110, as shown in Figures 2, 3 and 5, the space portion (not shown) so that the piston 220 can be inserted therein Is formed. The upper side of the space portion is finished by the end cap 240, the lower side is formed with a hole (not shown) so that the needle 230 can penetrate. In addition, the upper and lower sides of the cylinder 210 is formed with a port 212 through which the working fluid for raising and lowering the piston 220 is formed, the lower surface of the lip seal 10 to prevent the working fluid from leaking to the outside ) Is placed. To this end, a groove (not shown) is formed in the lower surface of the cylinder 210 so that the lip seal 10 can be inserted, and a lock nut (below) of the lip seal 10 is prevented from loosening of the lip seal 10. 20) is arranged.

The piston 220 is inserted into the space portion of the cylinder 210 and is elevated. For this purpose, the piston 220 has an outer diameter corresponding to the diameter of the space portion of the cylinder 210, and the working fluid does not leak along the outer surface. It is double sealed. Therefore, when the working fluid flows into the upper port 212 of the cylinder 210, the piston 220 is lowered by the downward force by the working fluid, and the working fluid flows into the lower port 212 of the cylinder 210. When the piston 220 is raised by the force upwards. The piston 220 has a hole formed at the center to penetrate the needle 230, and a screw groove (not shown) for tapering the wedge 250 is formed at the lower end of the hole.

Needle 230 forms a rod shape, one end is formed in a tapered form. The needle 230 is disposed above the discharge port of the chamber unit 100, and when the piston 220 moves up and down, the needle 230 moves up and down integrally with the piston 220 to open and close the discharge port. In other words, when the piston 220 descends, the needle 230 descends together to close the discharge port while contacting the discharge port, and when the piston 220 rises, the needle 230 rises together to open the discharge port. The liquid stored in the chamber body is discharged through the discharge port. At this time, the needle 230 may strike the discharge port while falling together in accordance with the lowering operation of the piston 220, the liquid discharged by this operation may be injected at a high pressure.

Meanwhile, the needle 230 is coupled to the piston 220 by the wedge 250 so that the piston 220 and the needle 230 may be lifted and integrated, and the wedge 250 is formed in a tapered shape at the top thereof. The thread is formed on the outer circumferential surface extending downward from the upper end. A hollow (not shown) is formed in the wedge 250 to allow the needle 230 to penetrate therein. The wedge 250 is connected to the piston 220 while the needle 230 penetrates the hollow 230. The needle 230 is coupled to the piston 220 by coupling to the screw groove. In other words, since the inclination angle of the threaded groove of the piston 220 is formed more gentle than the inclination angle of the thread of the wedge 250, and the needle 230 is inserted into the wedge 250, the wedge 250 may be inserted into the wedge 250. Is coupled to the piston 220, the wedge 250 is tightened by the piston 220, so that the inner surface of the wedge 250 presses the outer surface of the needle 230 so that the needle 230 is connected to the piston 220. It is fixed. In this process, the needle 230 may be naturally disposed at the center of the piston 220, and thus the needle 230 may be easily disposed at the center of the discharge port of the chamber unit 100.

End cap 240 is attached to the upper side of the cylinder 210 serves to prevent the working fluid inside the cylinder 210 from leaking. The end cap 240 has a space portion (not shown) is formed therein, the upper side of the space portion is formed with a screw groove for the adjustment unit 500 is coupled. In addition, a hole (not shown) is recessed and formed in the center lower portion of the space to allow the needle 230 to penetrate therein, and the working fluid inside the cylinder 210 is formed while the needle 230 penetrates. Lip seal 10 and the lock nut 20 is inserted to prevent leakage.

The control unit 300 is attached to the side of the cylinder 210 of the needle unit 200, and serves to supply the working fluid to the cylinder (210). As shown in Figures 2 and 3, such a control unit 300 is composed of a double acting solenoid valve 310, the working fluid supplied from the outside by the double acting solenoid valve 310 is selectively The piston 220 of the needle unit 200 is operated by being supplied to the upper port or the lower port 212. To describe this in detail, when the working fluid flows into the lower port 212 of the cylinder 210 by the double-acting solenoid valve 310, the piston 220 is lifted upward by the piston 220, and As the needle 230 which is integrally raised together is lifted together, the discharge port is opened to discharge the liquid stored in the chamber unit 100.

On the other hand, when the working fluid flows into the upper port 212 of the cylinder 210 by the double-acting solenoid valve 310, the piston 220 is lowered by force downward, and is integrally lowered with the piston 220 As the needle 230 descends together, the discharge port of the chamber unit 100 is closed. Since the discharge port is opened and closed under the control of the double-acting solenoid valve 310 in this process, the amount of liquid to be discharged is determined according to the opening and closing time of the discharge port, and the needle 230 is actively lowered by the double-acting solenoid valve 310. As a result, the liquid discharged by the needle 230 hitting the discharge port may be injected at a high pressure.

2, 3 and 6, the pressurizing unit 400 is disposed between the chamber unit 100 and the needle unit 200, the needle 230 in the discharge port direction of the chamber unit 100 It serves to pressurize. The pressure unit 400 includes a body 410, a compression spring 420, a spring flange 430, a wedge 440. The body 410 is interposed between the chamber body 110 of the chamber unit 100 and the cylinder 210 of the needle unit 200, and forms an external shape of the pressure unit 400. The body 410 has a space portion (not shown) is formed inside, the compression portion 420, the spring flange 430, the wedge 440 is inserted into the space portion, the needle unit 200 Needle 230 is inserted through.

One end of the compression spring 420 is fixed to the lower surface of the cylinder 210 of the needle unit 200, and the spring flange 430 is fixed to the other end of the compression spring 420.

The spring flange 430 has a through hole (not shown) through which the needle 230 of the needle unit 200 penetrates therein, and is coupled to the needle 230 by the wedge 440 so that the needle ( 230 is integrated with the lift. To this end, the spring flange 430 has a threaded groove formed along the through hole, and the wedge 440 has a thread corresponding to the through hole of the spring flange 430. Here, the same as the coupling relationship between the piston 220 and the needle 230 of the needle unit 200 described above, the wedge 440 is made of a tapered shape, the needle 230 inside the wedge 440 Since the hollow is formed to penetrate, the needle 230 is coupled to the spring flange 430 by the wedge 440 coupled to the spring flange 430 while the needle 230 penetrates the hollow. In other words, since the inclination angle of the screw groove of the spring flange 430 is formed more gentle than the inclination angle of the thread of the wedge 440, and the needle 230 is inserted into the wedge 440, the wedge 440. ) Is coupled to the spring flange 430, the wedge 440 is tightened by the spring flange 430, so that the needle 230 is the spring flange by the inner surface of the wedge 440 to press the outer surface of the needle 230 430 is fixed.

Therefore, the spring flange 430 is lowered by the force downward from the compression spring 420, the needle 230 which is lowered integrally with the spring flange 430 is lowered together to block the discharge port. In addition, the compression spring 420 is raised and lowered in the needle 230 because the compression spring 420 has a compression force smaller than the force of the piston 220 of the needle unit 200 when the liquid metering discharge device is operating normally. Does not affect.

However, when no pressure is applied to the piston 220 as in the case of setting the liquid metering dispensing device for the first time, the discharge port of the chamber unit 100 is easily opened because the needle 230 does not receive any external force except gravity. There is a risk of liquid leakage. In this case, as described above, the compression spring 420 of the pressing unit 400 presses the needle 230 downward so that the needle 230 can stably close the discharge port.

Meanwhile, the adjustment unit 500 may be coupled to the upper side of the needle unit 200, as shown in FIGS. 2, 3, and 7, and the adjustment unit 500 includes an adjust body 510 and an indicator ( 520, an adjust knob 530, and a stopper 540, and may further include a compression spring 550. The adjust body 510 is formed on the outer circumferential surface of the threaded groove corresponding to the screw groove of the end cap 240 of the needle unit 200 is screwed to the end cap 240, the compression spring 550 and the stopper (inside) A space portion (not shown) is formed to allow the 540 to be inserted. The indicator 520 and the adjust knob 530 are attached to the upper side of the adjust body 510 in order, and the stop knob 540 is inserted and coupled to the adjust knob 530, and the adjust body 510 and The indicator 520, the adjust knob 530, and the stopper 540 are integrally rotated together.

Here, the indicator 520 is a scale and number is displayed along the outer surface serves to tell how much the adjust knob 530 is rotated, the adjust knob 530 of the handle to rotate the adjustment unit 500 Play a role. In addition, the stopper 540 serves to limit the moving distance upward of the needle 230 when the needle 230 of the needle unit 200 is raised. To this end, the stopper 540 is coupled to the adjust knob 530 through the adjust body 510 and is spaced apart from the upper end of the needle 230.

In other words, the stopper 540 is initially arranged to be in contact with the needle 230 of the needle unit 200, and then, by turning the adjust knob 530, by adjusting the thread of the adjust body 510. 500 is lifted, and thus the stopper 540 is also lifted together so that the stopper 540 is spaced apart from the needle 230. In this process, a distance is generated between the stopper 540 and the needle 230 as the adjust knob 530 is rotated, and when the piston 220 of the needle unit 200 is raised, the needle 230 The movement of the needle 230 is limited because the movement is restricted by the stopper 540.

On the other hand, the compression spring 550 one end is fixed to the upper surface of the end cap 240 and the other end is inserted into the inside of the adjust body 510 to press the adjust body 510 upwards, which is the needle 230 It can be said to adjust the moving distance of. In other words, as described above, the position of the stopper 540 is adjusted by the stopper 540 being lifted by the thread of the adjust body 510 while the adjust knob 530 is rotated. In this case, the needle unit 200 Since there is a minute gap between the screw groove of the end cap 240 of the) and the thread of the adjust body 510, the stopper 540 of the adjustment unit 500 may be generated up and down by the interval of the screw. In order to prevent such flow, the compression spring 550 presses the adjust body 510 upward so that the thread always has a fixed position with respect to the screw groove, so that the stopper 540 does not flow so that the needle 230 does not flow. It is possible to precisely control the moving distance.

On the other hand, the heater unit 600 may be coupled to the chamber unit 100. This is to solve the problem that a certain amount is not discharged because the characteristics vary depending on the temperature when the liquid to be discharged has viscosity. The lower side of the chamber unit 100 is inserted into the heater 600, and controls the temperature of the liquid inside the chamber body 110 by applying heat to the chamber body 110.

An operation state of the liquid metering discharge device according to the embodiment of the present invention as described above will be described in detail with reference to FIGS. 1 to 7.

In the case of initially setting the liquid dosing device according to the present invention, the needle of the needle unit 200 of the liquid dosing device is kept in a closed state. To this end, as described above, the pressurizing unit 400 is interposed between the needle unit 200 and the chamber unit 100, and the compression spring 420 of the pressurizing unit 400 moves the spring flange 430 downward. The needle 230, which is raised and lowered integrally with the spring flange 430, is pressed downward to close the discharge port. Here, the stopper 540 of the adjustment unit 500 is in contact with the upper portion of the needle 230 of the needle unit 200, the pressure is not applied to the piston 220 of the needle unit 200. .

Next, the adapter 150 and the liquid storage container 30 are coupled to the chamber body 110 of the chamber unit 100, and then the double acting solenoid valve 310 of the control unit 300 is operated to operate the needle unit 200. The working fluid is introduced into the lower port 212 of the cylinder 210 so that the piston 220 is pressurized upward.

Next, the adjust knob 530 of the adjusting unit 500 is turned to raise the stopper 540 and adjust the moving distance of the needle 230. In other words, since the piston 220 is being pushed upward, the needle 230 which is raised and lowered integrally with the piston 220 is also pushed upward and the needle 230 is also raised as the stopper 540 is raised.

Here, the adjust body 510 is pressed upward by the compression spring 550 in the adjusting unit 500 to the screw coupling of the adjust body 510 and the end cap 240 of the needle unit 200. Microfluidic flow is prevented, and the stopper 540 that is elevated up and down with the adjust body 510 is also microfluidic is prevented so that the needle 230 has a certain moving distance. Through this process, the moving distance upward of the needle 230 is determined.

On the other hand, in the case where the liquid metering dispensing device is operated after the setting is completed, the double acting solenoid valve 310 of the control unit 300 has the lower and upper ports 212 in the cylinder for a short interval of 1/1000 second or 1.5 / 1000 second. Flow the working fluid in order. Accordingly, the piston 220 which is subjected to the force of the working fluid is instantaneously raised and lowered, and the needle 230 which is raised and lowered integrally with the piston 220 is raised and lowered together so that the piston unit of the chamber unit 100 is raised. The liquid is discharged through the discharge port of the sheet 140, and the discharged liquid is injected at a high pressure by the needle 230 hitting the discharge port at the moment when the discharge port is closed to descend.

In addition, the heater 600 coupled to the chamber unit 100 heats the chamber body 110 so that the discharged liquid is maintained at a constant temperature so that a constant amount is always discharged without a change in viscosity according to the temperature.

Through this process, the liquid metering dispensing device is the piston 220 and the needle 230 of the needle unit 200 is coupled using the wedge 250 by the piston 220 and the needle 230 is firmly coupled to the needle at the same time 230 is easily disposed at the center of the piston 220 and the center of the outlet of the chamber unit 100, so that the leakage of the liquid can be prevented. In addition, since the piston 220 of the needle unit 200 is operated by the double acting solenoid valve 310 of the control unit 300, the opening and closing time is precisely controlled to allow the quantitative discharge of the liquid, and the discharge port by the needle 230. The liquid can be discharged at a high pressure by hitting the discharge port when the needle is closed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: Lip seal 20: Lock nut
30: liquid storage container 100: chamber unit
110: chamber body 120: union unit
130: seat housing 140: seat
150: adapter 200: needle unit
210: cylinder 212: port
220: piston 230: needle
240: end cap 250: wedge
300: control unit 310: double acting solenoid valve
400: pressure unit 410: body
420: compression spring 430: spring flange
440: wedge 500: control unit
510: adjust body 520: indicator
530: Adjust Knob 540: Stopper
550: compression spring 600: heater

Claims (11)

A chamber unit into which the liquid is introduced and stored and having a discharge port for discharging the liquid;
A cylinder attached to an upper end of the chamber unit, a piston inserted into the inner side of the cylinder so as to be lifted, an upper end coupled to the piston to be lifted and lifted integrally, and a needle to open and close the discharge port of the chamber unit; Needle unit having an end cap coupled to the upper side; And
A control unit attached to a side of the needle unit, the control unit having a double-acting solenoid valve that controls the piston to be lowered or raised by the working fluid by supplying a working fluid to the upper or lower side of the cylinder,
The needle unit further includes a wedge for integrally coupling the piston and the needle, wherein the wedge has a tapered shape at an upper end thereof, a hollow through which the needle penetrates, and a thread is formed on an outer surface thereof. The thread groove is tapered on the inside so that the wedge is inserted, the wedge is tightened as the piston and the wedge is screwed, the inner surface is fixed to the needle by pressing the outer surface of the needle. Discharge device. The method according to claim 1,
And a pressurizing unit interposed between the chamber unit and the needle unit, for pressurizing the needle of the needle unit downward. The method according to claim 2,
The pressurizing unit includes a body having a space portion formed therein, a compression spring inserted into a space portion of the body and having one end fixed to a lower side of the cylinder, and the other end of the compression spring fixed to an upper surface of the needle of the needle unit. And a spring flange which is fixed through and integrally lifted with the needle, and when the external force is not applied to the piston of the needle unit, the spring flange is pushed downward by the compression spring to lower the needle so that A liquid quantitative discharging device, characterized in that the discharge port is closed. The method according to claim 3,
The pressurizing unit further includes a wedge for integrally coupling the spring flange and the needle, wherein the wedge has a tapered shape at the top thereof, a hollow through which the needle penetrates, and a thread is formed on an outer surface thereof. The spring flange is formed with a tapered groove in the inner side so that the wedge is inserted, and as the spring flange and the wedge are screwed, the wedge is tightened so that the needle is fixed by the inner side pressing the outer surface of the needle. Liquid metering discharge device. A chamber unit into which the liquid is introduced and stored and having a discharge port for discharging the liquid;
A cylinder attached to an upper end of the chamber unit, a piston inserted into the inner side of the cylinder so as to be lifted, an upper end coupled to the piston to be lifted and lifted integrally, and a needle to open and close the discharge port of the chamber unit; Needle unit having an end cap coupled to the upper side; And
A control unit attached to a side of the needle unit, the control unit having a double-acting solenoid valve that controls the piston to be lowered or raised by the working fluid by supplying a working fluid to the upper or lower side of the cylinder,
It is interposed between the chamber unit and the needle unit, further comprising a pressure unit for pressing the needle of the needle unit downward,
The pressurizing unit includes a body having a space portion formed therein, a compression spring inserted into a space portion of the body and having one end fixed to a lower side of the cylinder, and the other end of the compression spring fixed to an upper surface of the needle of the needle unit. And a spring flange which is fixed through and integrally lifted with the needle, and when the external force is not applied to the piston of the needle unit, the spring flange is pushed downward by the compression spring to lower the needle so that The outlet is closed,
The pressurizing unit further includes a wedge for integrally coupling the spring flange and the needle, wherein the wedge has a tapered shape at the top thereof, a hollow through which the needle penetrates, and a thread is formed on an outer surface thereof. The spring flange is formed with a tapered groove in the inner side so that the wedge is inserted, and as the spring flange and the wedge are screwed, the wedge is tightened so that the needle is fixed by the inner side pressing the outer surface of the needle. Liquid metering discharge device. A chamber unit into which the liquid is introduced and stored and having a discharge port for discharging the liquid;
A cylinder attached to an upper end of the chamber unit, a piston inserted into the inner side of the cylinder so as to be lifted, an upper end coupled to the piston to be lifted and lifted integrally, and a needle to open and close the discharge port of the chamber unit; Needle unit having an end cap coupled to the upper side; And
A control unit attached to a side of the needle unit, the control unit having a double-acting solenoid valve that controls the piston to be lowered or raised by the working fluid by supplying a working fluid to the upper or lower side of the cylinder,
An adjust body coupled to an upper side of the end cap of the needle unit, an indicator attached to an upper side of the adjust body and integral with the adjust body, and an ad attached to an upper side of the indicator and integral with the indicator. And a control unit having a just knob and a stopper which penetrates through the adjust body and is inserted into and coupled to the adjust knob to be integral and spaced apart from an upper end of the needle of the needle unit. A liquid quantitative discharging device, characterized in that the movement distance upward is limited by the stopper. The method of claim 6,
The end cap of the needle unit and the adjust body of the control unit is screwed, the stopper is integrally rotated and lifted by rotating the adjust knob, characterized in that the position of the stopper can be adjusted Liquid metering discharge device. The method of claim 7,
The control unit further comprises a compression spring for which one end is fixed to the upper surface of the end cap and the other end is inserted into the inside of the adjust body to press upward. The method according to claim 1 or 6,
The chamber unit has a chamber body into which the liquid is introduced and stored, and a sheet provided at a lower side of the chamber body and having a discharge port through which the liquid is discharged, the sheet having a groove formed to taper toward the discharge hole inside. And a needle of the needle unit is inserted into a groove of the sheet. The method of claim 9,
The chamber unit is screwed on the lower side of the chamber body, but the union unit is formed in the lower end projection protrusion on the inner side, and the upper side has the shape of a cylindrical opening is fitted into the center can be seated seated And a seat housing having a hole formed therein and a protruding jaw seated on the engaging jaw of the union unit, wherein the seat housing is moved upwards as the union unit is screwed into the chamber body. And a sheet inserted into the chamber body is attached to the lower side of the chamber body. The method of claim 10,
The lower side of the chamber unit is inserted, the liquid dosing device characterized in that it further comprises a heater for controlling the liquid temperature inside the chamber body.

Images