KR101893825B1 - coolant dosing device - Google Patents

Abstract

The present invention relates to a technique related to an injecting device which safely subsidizes a harmful coolant to a fixed amount. A temporary container for temporarily storing the coolant extracted from a large size coolant container and a container tray for securing the coolant container are provided in a low position, and a means for sucking and injecting the stored coolant to a subsidizing container is arranged in a position relatively higher than that of the temporary container of the coolant such that remaining harmful scraps after subsidizing the coolant in the subsidizing container is effectively prevented from being injected to the outside. According to the present invention, a water level detecting sensor and a reverse flow driving motor are provided such that the coolant scraps remaining in an injection nozzle portion after injecting the coolant into the subsidizing container can be prevented from being exposed to the outside.

Description

Coolant dosing device

The present invention relates to an injection apparatus for safely subdividing a coolant as a harmful substance in a fixed amount.

More particularly, the present invention relates to a temporary storage container for temporarily storing a coolant from a large-capacity coolant container and a container tray for placing the coolant container in a low position, Is located at a relatively higher position than the temporary storage container of the coolant, it is possible to effectively block the remaining harmful residue from being injected into the outside after subdividing the coolant into the small container.

In general, semiconductor or display manufacturing facilities must cool down the heat generated by their operation.

Here, as a means for cooling the manufacturing facility, there is a method of putting a predetermined amount of the coolant into the manufacturing facility.

To this end, the coolant is placed in a small container of the standard corresponding to the amount of the coolant to be charged once, and the coolant is put into the corresponding manufacturing facility.

However, the coolant used for the cooling of the manufacturing facility is a volatile substance and splashes harmful substances when exposed to the outside.

As a result, when the manager of the manufacturing facility moves the coolant from a large capacity coolant container to a plurality of small size containers, it is inconvenient to perform the operation while wearing the gas mask.

Further, when the coolant is transferred from the coolant container to the sub-container, there is a problem that a part of the harmful coolant flows to the outside, thereby contaminating the surrounding space.

It is an object of the present invention to provide a coolant dosing device for preventing a coolant, which is a harmful substance, from being scattered to the outside during a process of transferring coolant to a subminiature container.

It is another object of the present invention to provide a coolant dosing device for effectively preventing the coolant residue remaining in the injection means from being exposed to the outside after the coolant is injected into the small container.

It is another object of the present invention to provide a coolant dosing device for preventing the coolant in the coolant container from being scattered to the outside during the process of extracting the coolant from the coolant container.

It is also an object of the present invention to provide a coolant dosing device which allows a copper wire carrying a coolant-filled coolant container or a copper wire carrying a coolant-filled copper container to provide a safe working environment to an operator.

In order to attain the above object, the present invention provides a coolant dosing device for injecting a predetermined amount of coolant into a subminiature container in a state that a coolant is supplied from a coolant container and stored therein, the device comprising: A suction unit that sucks the coolant from the coolant vessel and feeds the coolant to the storage tank; And an injection unit for sucking the coolant from the storage tank and injecting a predetermined amount of coolant into the subdivided container.

A base plate disposed horizontally and extending to support the storage tank and the suction unit; A container tray for moving the coolant container to a desired position while sliding the upper surface of the base plate with the coolant container on its upper surface; An upper plate disposed parallel to the base plate and corresponding to the upper portion of the reservoir and the suction unit to support the injection unit and to seat the sub-fraction container; A base plate, and an upper plate, and a container gate mounted on a side wall of the container tray for loading / unloading the container tray into and out of the container, And a housing having an upper gate on its side wall for allowing the user to enter and exit the user's own home.

The apparatus may further include a stationary blade for guiding the position of the coolant container that is seated on the container tray as being horizontally mounted on the inner wall of the housing where the container tray is located.

At this time, the suction unit includes: a suction nozzle unit for sucking the coolant from the coolant vessel while entering and exiting the coolant vessel from the upper portion of the coolant vessel seated in the vessel tray; A suction line unit connecting the suction nozzle unit and the storage tank in communication to transfer the coolant sucked from the coolant vessel by the suction nozzle unit to the storage tank; A coolant suction pump for providing a suction force to the suction nozzle portion so that the suction nozzle portion sucks the coolant from the coolant container; A guide frame disposed upright on the base plate and guiding movement of the suction nozzle unit in a state connected to the suction nozzle unit so that the suction nozzle unit moves in the vertical direction along the longitudinal direction of the guide frame; And a suction up-down driving motor for providing power for movement of the suction nozzle portion relative to the guide frame.

Here, the injection unit includes: an injection nozzle unit for injecting the coolant in the reservoir into a submerged vessel which is seated on the upper plate; An injection line unit for connecting the injection nozzle unit and the storage tank to each other to transfer the coolant in the storage tank to the injection nozzle unit; A coolant injection pump for supplying a discharge power to the injection nozzle so that the injection nozzle part sucks a predetermined amount of coolant from the storage tank and discharges the coolant to the outside; A support frame disposed upright on the upper plate and guiding the movement of the injection nozzle unit in a state connected to the injection nozzle unit so that the injection nozzle unit moves in the vertical direction along the longitudinal direction thereof; And an injection up-down drive motor that provides power for movement of the injection nozzle portion relative to the support frame.

The injection unit further includes a sleep sensor connected to the injection nozzle unit and sensing a surface of the coolant in the small container when the coolant is injected from the injection nozzle unit into the small container, Up operation of the injection up-down drive motor such that the injection nozzle portion moves upward along the support frame while maintaining a predetermined distance from the water surface by the coolant in the sub-unit container sensed by the water surface sensor in the process of injecting the coolant into the sub- And an injection control unit for controlling the injection control unit.

On the other hand, the injection unit is mounted on the injection nozzle unit and supplies the pressure to flow backward from the injection nozzle unit toward the reservoir tank. Accordingly, the injection unit unit is capable of supplying the residual coolant remaining in the injection line unit adjacent to the injection nozzle unit to the reservoir And a driving motor.

On the other hand, the suction unit is arranged so as to surround the rim of the suction nozzle part, and when the suction nozzle part reaches the entry / exit part of the coolant container, the entry / exit part of the coolant container is mechanically closed, And a pressure regulating valve for controlling the pressure in the coolant container as air is injected into the coolant container when the coolant is sucked from the coolant container through the suction nozzle portion.

The present invention has a suction unit for transferring the coolant in the coolant container to the storage tank and an injection unit for transferring the coolant in the storage tank to the subunit container so that the coolant as the harmful material is transferred to the outside It shows an advantage of preventing scattering.

In addition, the present invention has an advantage that the coolant is injected into the sub-container due to the water sensor and the back-flow drive motor, and the coolant residue remaining in the injection nozzle is prevented from being exposed to the outside.

Further, the present invention has an advantage of preventing the coolant in the coolant container from being scattered to the outside in the process of extracting the coolant from the coolant container by having the pressure control valve disposed at the inlet of the coolant container.

In addition, the present invention is characterized in that a structure in which a coolant container is arranged in a housing and a structure in which a reservoir is disposed are arranged at a lower portion and a structure in which a small-volume container and an injection unit are disposed, A copper wire carrying coolant filled subcontainer container provides an advantage of providing a safe working environment for the operator.

1 is a perspective view illustrating a coolant metering device according to the present invention,
2 is a side sectional view showing a coolant metering device according to the present invention,
[Fig. 3] to [Fig. 5] are diagrams showing the state of use of the coolant metering dosing device through [Fig. 2]
3 is a view illustrating a process of injecting a coolant container into a coolant dosing device according to the present invention,
4 is an exemplary view showing a state before and after a suction unit, which is a constitution of the present invention, sucks a coolant from a coolant container and transfers it to a storage tank of the present invention,
5 is an exemplary view showing a state before and after the injection unit, which is a constitution of the present invention, injects the coolant from the storage tank and injects the coolant into the small container.

Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 1 is a perspective view showing a coolant metering device according to the present invention, and FIG. 2 is a side sectional view showing a coolant metering device according to the present invention.

1 and 2, the present invention is a coolant dosing device for injecting a predetermined amount of coolant into a subminiature container 20 in a state where a coolant is supplied from a coolant container 10 and stored, 100, the suction unit 200, the injection unit 300, the injection control unit (not shown), the base plate 410, the container tray 420, the upper plate 430, the housing 440, 500).

The reservoir 100 may be mounted on the upper surface of the base plate 410 in a hollow hexagonal shape so as to temporarily store the coolant.

The reservoir 100 can be designed to have a large capacity corresponding to the capacity of the plurality of coolant containers 10. [ The base plate 410 may be mounted on the inner wall of the housing 440 while being mounted on the upper surface of the base plate 410.

The suction unit 200 sucks the coolant from the coolant vessel 10 and transfers it to the storage tank 100.

Here, the suction unit 200 is provided with a suction nozzle unit 210, a suction unit 210, and a suction unit 210. The suction unit 200 includes a suction nozzle unit 210, And may include a line unit 220, a coolant suction pump 230, a guide frame 240, a suction up / down driving motor 250, and a pressure control valve 260.

The suction nozzle unit 210 sucks the coolant from the coolant vessel 10 while entering and exiting the coolant vessel 10 in the vertical direction of the coolant vessel 10 from the top of the coolant vessel 10 that is seated in the container tray 420 .

That is, as shown in FIG. 2, the suction nozzle unit 210 is formed in the shape of a nozzle rod and is arranged long in the vertical direction and moves in the vertical direction.

At this time, when the coolant suction pump 230 operates while the lower part of the suction nozzle unit 210 is inserted into the coolant vessel 10, the suction nozzle unit 210 sucks the coolant in the coolant vessel 10 To the storage tank (100) through a suction line unit (220) connected to the storage tank (100).

The suction line unit 220 connects the suction nozzle unit 210 and the storage tank 100 so that the suction nozzle unit 210 and the storage tank 100 communicate with each other so that the suction nozzle unit 210 is sucked from the coolant vessel 10 To the storage tank (100).

The coolant suction pump 230 provides a suction force to the suction nozzle unit 210 so that the suction nozzle unit 210 sucks the coolant from the coolant vessel 10.

That is, the coolant suction pump 230 operates so that the suction nozzle unit 210 sucks the coolant in the coolant vessel 10 as the lower part of the suction nozzle unit 210 operates in a state of being inserted into the coolant vessel 10 do.

2, the guide frame 240 preferably has a plurality of rod shapes and is vertically disposed on the base plate 410. The suction nozzle unit 210 is vertically disposed along the longitudinal direction of the guide plate 240, So that the suction nozzle unit 210 is moved in a state that the suction nozzle unit 210 moves.

The suction up-down driving motor 250 provides power for moving the suction nozzle unit 210 relative to the guide frame 240. The suction up-down driving motor 250 is also connected to the guide frame 240 And moves in the vertical direction along the longitudinal direction of the guide frame 240.

2, the block mounted with the suction up / down driving motor 250 is connected to the guide frame 240 in a slidable manner, and the suction nozzle unit 210 is connected to one end of the block .

As a result, when the suction up / down driving motor 250 moves up and down along the longitudinal direction of the guide frame 240, the suction nozzle unit 210 integrally connected to the suction up / down driving motor 250 moves up and down.

The pressure regulating valve 260 is disposed so as to surround the rim of the suction nozzle unit 210. When the suction nozzle unit 210 enters the inlet and the outlet of the coolant vessel 10, Mechanically closes the department.

At this time, the pressure control valve 260 blocks the coolant in the coolant vessel 10 from bouncing out and operates as a purge valve when the coolant is sucked from the coolant vessel 10 through the suction nozzle unit 210, The pressure in the coolant vessel 10 is adjusted.

As a result, the coolant in the coolant vessel 10 is prevented from being scattered to the outside in the process of extracting the coolant from the coolant vessel 10.

The injection unit 300 sucks the coolant from the reservoir 100 and injects a predetermined amount of coolant into the subdivided container 20.

Here, the injection unit 300 is provided with an injection nozzle unit 310, an injection unit 310, and an injection unit 310 so as to prevent the coolant, which is a harmful substance, from being scattered to the outside during the process of sucking the coolant from the storage tank 100 and transferring the coolant to the sub- A cooling medium injection pump 330, a support frame 340, an injection up / down driving motor 350, a water surface sensor 360, and a back flow driving motor 370. [

The injection nozzle unit 310 injects the coolant into the subdivided container 20 while moving into and out of the subdivided container 20 in the vertical direction of the subdivided container 20 from the upper portion of the subdivided container 20 seated on the upper plate 430 .

Here, as shown in FIG. 2, the injection nozzle unit 310 is formed in the form of a nozzle rod, and is arranged long in the vertical and horizontal directions, and moves up and down.

At this time, when the coolant injection pump 330 operates in a state where the lower part of the injection nozzle part 310 is inserted into the sub-container 20, the coolant in the reservoir 100 is injected through the injection line part 320, (Not shown).

The injection line unit 320 connects the injection nozzle unit 310 and the storage tank 100 so that the storage tank 100 and the injection nozzle unit 310 are in communication with each other to connect the coolant in the storage tank 100 to the injection nozzle unit 310 .

The coolant injection pump 330 supplies the injection nozzle unit 310 with the discharge power through the pumping operation so that the injection nozzle unit 310 sucks a predetermined amount of the coolant from the storage tank 100 and discharges the coolant to the outside.

That is, the coolant injection pump 330 causes the injection nozzle unit 310 to inject the coolant into the sub-container 20 as the injection nozzle unit 310 is pumped in the state of being inserted into the sub-container 20 .

2, the support frame 340 preferably has a plurality of rod shapes and is vertically disposed on the upper plate 430. The injection nozzle unit 310 is vertically arranged along its longitudinal direction So that the movement of the injection nozzle unit 310 is guided in a state of being connected to the injection nozzle unit 310.

Here, the injection up / down drive motor 350 provides power for movement of the injection nozzle unit 310 to the support frame 340, and this injection up / down drive motor 350 is also connected to the support frame 340 And moves up and down along the longitudinal direction of the support frame 340.

2, the injection nozzle unit 310 is connected to one end of the support frame 340 in a state where the block mounting the injection up / down driving motor 350 is slidably connected to the support frame 340 do.

As a result, when the injection up / down driving motor 350 moves up and down along the longitudinal direction of the support frame 340, the injection nozzle unit 310 integrally connected to the injection up / down driving motor 350 moves in the vertical direction.

The water surface sensor 360 is connected to the injection nozzle unit 310 and senses the water surface by the coolant in the sub-container 20 during the process of injecting the coolant into the sub-container 20 from the injection nozzle unit 310.

When the coolant is injected into the subminiature container 20 from the injection nozzle part 310, the coolant is dropped on the bottom surface of the subminiature container 20 so that the coolant does not protrude to the outside of the subminiature container 20 310) need to be adjusted.

For example, as the lower end of the injection nozzle unit 310 is positioned adjacent to the bottom surface of the small container 20, the coolant is injected, and as the surface of the small container 20 is raised, Direction.

As a result, the coolant does not jump out from the water surface in the sub-container 20 as the lower end of the injection nozzle unit 310 and the water surface of the sub-container 20 maintain a close distance.

In order to maintain a constant distance between the lower end of the injection nozzle unit 310 and the surface of the sub-container 20, the sleep sensor 360 must detect the rising surface of the sub-container 20.

On the other hand, an injection control unit (not shown) controls the operation of the injection up / down driving motor 350 so that the injection nozzle unit 310 moves upward along the support frame 340.

At this time, in consideration of the surface of the coolant in the sub-container 20 sensed by the surface sensor 360 in the process of injecting the coolant from the injection nozzle unit 310 into the sub-container 20, Down driving motor 350 while maintaining a separation distance between the injection nozzle 310 and the lower end of the injection nozzle unit 310. [

The backward driving motor 370 is mounted on the injection nozzle unit 310 and supplies the pressure to the injection nozzle unit 310 and the injection nozzle unit 310 The residual coolant in the adjacent injection line 320 flows into the reservoir 100.

For example, the backflow drive motor 370 is operated by a main control unit (not shown). The main control unit controls the backflow drive motor 370 such that a predetermined amount of coolant is supplied from the storage tank 100 to the injection line unit 310 And is driven through the injection nozzle unit 310 to drive the backward driving motor 370.

As a result, when the injection nozzle unit 310 injects the coolant into the subdivided container 20 and then removes the subdivided container 20 from the upper plate 430, the coolant residue remaining in the injection nozzle unit 310 And then flows into the storage tank 100 again through the injection line unit 320.

Here, when the storage tank 100 is placed on the base plate 410 in the housing 440 and the injection nozzle unit 310 is disposed on the upper plate 430, when the backward driving motor 370 is operated, The coolant debris in the nozzle unit 310 can easily flow toward the reservoir 100 due to the viscosity of the liquid and the gravity force without dropping onto the upper plate 430.

On the other hand, the base plate 410 is disposed horizontally and wide to support the storage tank 100 and the suction unit 200, as shown in FIGS. 1 and 2.

The container tray 420 is placed in a desired position while sliding the upper surface of the base plate 410 while seating the coolant container 10 on its upper surface as shown in FIGS. 1 and 2 10).

The upper plate 430 is disposed in parallel with the base plate 410 in correspondence with the upper portion of the storage tank 100 and the suction unit 200 to support the injection unit 300, 20).

The housing 440 includes a reservoir 100, a suction unit 200, an injection unit 400, and a suction unit 500. The housing 440 includes therein a base plate 410 and an upper plate 430, as shown in FIGS. 1 and 2, (300).

The housing 440 is provided with a container gate 441 for allowing the container tray 420 to move in and out of the container tray 420. The container 440 includes a small container container 20 mounted on the top plate 430, And has an upper gate 442 on its side wall for entry and exit.

On the other hand, the stationary blade 500 is mounted on the container tray 420 as it is horizontally mounted on the inner wall of the housing 440 where the container tray 420 is located, as shown in FIG. 2 10).

For example, when the container tray 420 slides on the upper surface of the base plate 410 while the coolant container 10 is mounted on the upper surface of the container tray 420, the entrance of the coolant container 10 is connected to the suction nozzle part 210 The stationary blade 500 abuts the side wall of the coolant vessel 10 to limit the movement of the coolant vessel 10.

3] to [5] are diagrams for explaining the use state of the coolant metering injector through [FIG. 2], FIG. 3 is a view illustrating a process for injecting the coolant vessel into the coolant metering injector according to the present invention And FIG. 4 is an exemplary view showing a state before and after the suction unit, which is a constitution of the present invention, sucks the coolant from the coolant container and transfers it to the storage tank of the present invention. FIG. Fig. 8 is a view showing a state before and after the unit is sucked from the storage tank and the coolant is injected into the sub-container.

3, a large-capacity coolant container 10 is mounted on the container tray 420 and then the container tray 420 is slid so that the base tray 410 corresponding to the inside of the housing 440 As shown in Fig. 4, on the upper surface.

4, the suction nozzle unit 210 moves downward and the lower portion of the suction nozzle unit 210 enters the inside of the coolant vessel 10, and then the coolant suction pump 230 is operated The coolant in the coolant vessel 10 is transferred to the storage tank 100 through the suction line unit 220.

5, the sub-container 20 is disposed on the upper surface of the upper plate 430 corresponding to the vertical lower portion of the injection nozzle unit 310. As shown in FIG.

Subsequently, the coolant injection pump 330 operates to transfer the coolant in the reservoir 100 to the injection nozzle unit 310 through the injection line unit 320.

At this time, the injection nozzle unit 310 gradually moves upwards while discharging the coolant into the sub-container 20 in a state where the lower end of the injection nozzle unit 310 is disposed adjacent to the bottom surface of the sub-container 20.

As a result, in the process of discharging the coolant from the injection nozzle unit 310, the coolant in the sub-container 20 can be prevented from splashing and the coolant can be filled.

10: coolant container
20: Sub-container
100: Storage tank
200: Suction unit
210: suction nozzle part
220: Suction line section
230: coolant suction pump
240: guide frame
250: Suction up-down drive motor
260: Pressure regulating valve
300: injection unit
310: injection nozzle part
320:
330: coolant injection pump
340: Support frame
350: injection up-down drive motor
360: Sleep sensor
370: Reverse flow drive motor
410: base plate
420: container tray
430: upper plate
440: Housing
441: container gate
442: upper gate
500: fixed blade
600:

Claims (8)

A coolant quantitative injection device for injecting a predetermined amount of coolant into a small container with a coolant supplied from a coolant container,
A reservoir 100 for storing the coolant;
A suction unit (200) for sucking the coolant from the coolant container and delivering the coolant to the storage tank;
A base plate 410 disposed horizontally and wider and supporting the reservoir and the suction unit;
A container tray (420) for moving the coolant container to a desired position while sliding the upper surface of the base plate while the coolant container is seated on its upper surface;
An upper plate (430) disposed on the upper part of the reservoir and the suction unit and disposed in parallel with the base plate to seat the subdivided container on its upper surface;
A container gate 441 for mounting the storage tank and the suction unit inside and inserting the container tray into and out of the inner and outer sides of the base plate and the upper plate, A housing 440 having an upper gate 442 on its side wall to allow the sub-container to be seated in and out of the housing 440;
An injection nozzle part 310 supported by the upper plate in a state of being mounted in the housing and sucking the coolant from the reservoir to inject a predetermined amount of coolant into the subminiature container and injecting the coolant in the reservoir into the subminiature container; , A support frame (340) vertically installed on the upper plate and guiding movement of the injection nozzle part connected to the injection nozzle part so that the injection nozzle part moves up and down along its longitudinal direction, A water detection sensor 360 connected to the injection nozzle unit for detecting a water surface caused by the coolant in the sub-fractional container in the process of injecting the coolant into the sub-fractional container from the injection nozzle unit, And an injection up / down drive motor (350) for providing power for negative movement Unit 300;
Wherein the injector nozzle portion is moved upward along the support frame while maintaining a predetermined distance from the surface of the coolant in the sub-section container sensed by the surface sensor during the injection of the coolant from the injection nozzle portion to the inside of the sub- An injection control unit for controlling an operation of the injection up-down driving motor to move the injection up /
And the coolant metering device.
delete The method according to claim 1,
A stationary blade (500) for guiding the position of a coolant container that is seated on the container tray as it is horizontally mounted on an inner wall of the housing where the container tray is located;
Further comprising: a coolant injection device for injecting coolant.
The method of claim 3,
The suction unit (200)
A suction nozzle part (210) for sucking the coolant from the coolant container while entering and exiting the coolant container from the upper part of the coolant container seated on the container tray;
A suction line part (220) connecting the suction nozzle part and the storage tank and communicating the suction nozzle part with the coolant sucked from the coolant container to the storage tank;
A coolant suction pump (230) for providing a suction force to the suction nozzle unit such that the suction nozzle unit sucks the coolant from the coolant vessel;
A guide frame (240) vertically installed on the base plate and guiding movement of the suction nozzle part in a state connected to the suction nozzle part so that the suction nozzle part moves in the vertical direction along its longitudinal direction;
A suction up / down driving motor (250) for providing power for movement of the suction nozzle part with respect to the guide frame;
Wherein the coolant injection device is configured to inject coolant.
The method of claim 4,
The injection unit (300)
An injection line part (320) for connecting the injection nozzle part and the reservoir to communicate the coolant in the reservoir to the injection nozzle part;
A coolant injection pump (330) for injecting a predetermined amount of coolant from the reservoir and supplying the injection nozzle part with discharge power for discharging the coolant to the outside;
Further comprising: a coolant injection device for injecting coolant.
delete The method of claim 5,
The injection unit (300)
The injection nozzle portion and the remaining coolant remaining in the injection line portion adjacent to the injection nozzle portion are flowed into the storage tank by supplying pressure to the injection nozzle portion to flow backward from the injection nozzle portion toward the storage tank A backflow drive motor 370;
Further comprising: a coolant injection device for injecting coolant.
The method of claim 7,
The suction unit (200)
And the coolant in the coolant container is blown out to the outside as the suction nozzle covers the inlet and the outlet of the coolant container when the suction nozzle reaches the inlet and the outlet of the coolant container and mechanically closes the inlet and the outlet of the coolant container. A pressure regulating valve (260) for regulating a pressure in the coolant container by injecting air into the coolant container when the coolant is sucked from the coolant container through the suction nozzle part;
Further comprising: a coolant injection device for injecting coolant.

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