KR102388872B1 - Control module for controlling flow and speed of fluid - Google Patents

Abstract

The present invention relates to an integrated device for controlling the flow and speed of fluid, which can distribute the flow direction of fluid to a desired destination and is modularized to control the flow and speed of fluid to each destination. The present invention integrates fluid flow control parts in a single valve block and modularizes the same, instead of assembling the fluid flow control parts such as a plurality of speed controllers, solenoid valves and pipes individually for each desired small place of hydraulic/pneumatic equipment and facilities. Therefore, it is possible to easily control the flow and speed of fluid heading for each destination as well as easily distribute the flow direction of fluid to various desired destinations such as hydraulic/pneumatic equipment and facilities.

Description

CONTROL MODULE FOR CONTROLLING FLOW AND SPEED OF FLUID

The present invention relates to a fluid flow and velocity control device, and more particularly, a modular integrated type that can distribute the flow direction of a fluid to a desired destination as well as control the flow rate and speed of the fluid for each destination. It relates to fluid flow and velocity control devices.

Most of the fluid flow control parts mounted on hydraulic and pneumatic devices and equipment to control the flow and speed are composed of a large number of small parts. It is difficult to assemble.

For example, in hydraulic devices and equipment, the fluid flow control parts for adjusting the flow rate and at the same time adjusting the speed include a plurality of speed controllers, solenoid valves, a plurality of pipes, etc. It is difficult to assemble one by one at a desired location such as a facility.

In particular, when fluid flow control parts including a plurality of speed controllers, solenoid valves, and a plurality of pipes are to be assembled at desired locations such as hydraulic and pneumatic equipment and equipment, if the assembly location is narrow, each fluid flow control part is desired. There is a problem that the position cannot be assembled.

Publication No. 10-2019-0021313 (2019.03.05)

The present invention has been devised to solve the problems of the prior art, and it is possible to control the distribution of the flow direction of the fluid to various desired destinations such as hydraulic and pneumatic devices and facilities, as well as control the flow rate and speed of the fluid toward each destination. An object of the present invention is to provide a modular, integrated fluid flow and velocity control device that can be easily controlled.

In order to achieve the above object, the present invention provides: an integral valve block in which a plurality of main conduits connected to a fluid supply side and a plurality of sub conduits extending from each main conduit to a fluid destination are formed; a solenoid valve detachably mounted to the inlet of each main pipe connected to the fluid supply side; and a plurality of valve units mounted on the boundary flow path between the main pipe and the sub pipe to control the flow rate and speed of the fluid. It provides an integrated fluid flow and velocity control device, characterized in that it comprises a.

The valve unit may include: a valve housing having a hollow structure through which a fluid passage hole is formed in a radial direction, and being inserted and mounted in a boundary passage between a main tube and a sub-pipe of the integral valve block; a valve cover having a structure in which a female screw portion is formed in an inner diameter, the valve cover being stacked on an upper portion of the valve housing; A head portion exposed to the outside of the integral valve block for rotation operation is formed in the upper portion, a male screw portion screwed to the female screw portion of the valve cover is formed in the middle portion, and the flow rate inserted into the lower opening portion of the valve housing is formed in the lower portion a valve body for controlling a fluid having a control end formed therein; a fixing nut fastened to an upper portion of the male screw portion of the fluid control valve body; a check ring mounted on the lower outer diameter of the valve housing and contacting the lower inner diameter of the boundary passage; and an O-ring mounted on the upper outer diameter of the valve housing and pressed against the upper inner diameter of the boundary passage. It is characterized in that it comprises a.

Preferably, the inlet portion of each main pipe connected to the fluid supply side is characterized in that a mounting hole for detachably mounting the solenoid valve is formed.

Through the means for solving the above problems, the present invention provides the following effects.

According to the present invention, the fluid flow control parts are integrated into one valve block without assembling the fluid flow control parts (multiple speed controllers, solenoid valves, pipes, etc.) for each desired narrow location such as hydraulic/pneumatic equipment and equipment. By integrating into the module, it is possible to easily distribute and control the flow direction of the fluid to various desired destinations such as hydraulic and pneumatic devices and equipment, as well as easily control the flow rate and speed of the fluid toward each destination.

1 is an exploded view showing an integrated fluid flow and velocity control device according to the present invention;
2 is a cross-sectional view showing a valve unit in the configuration of an integrated fluid flow and speed control device according to the present invention;
3 is a cross-sectional view illustrating a state of fluid flow through a single valve during the configuration of an integrated fluid flow and speed control device according to the present invention.

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

1 is an exploded view showing an integrated fluid flow and speed control device according to the present invention, and FIGS. 2 and 3 are cross-sectional views showing a single valve unit in the configuration of the integrated fluid flow and speed control device according to the present invention As such, each reference numeral 100 designates an integral valve block.

A plurality of at least two or more main conduits 100 and a plurality of sub conduits 130 branching from each main conduit 100 are formed in the integrated valve block 100 .

At this time, the inlet side of each main conduit 100 of the integrated valve block 100 is connected to the fluid supply side, and the outlet side of each sub conduit 130 branched from each main conduit 110 is a fluid destination requiring a fluid. is connected with

In addition, at the inlet of each main conduit 110 of the integrated valve block 100 connected to the fluid supply side, a mounting hole 210 through which the solenoid valve 200 is detachably mounted is vertical to the main conduit 110 . is formed through

Accordingly, when the solenoid valve 200 is inserted and fastened through the mounting hole 210 , the inlet of the main conduit 110 may be opened and closed according to the on/off operation of the solenoid valve 200 .

In particular, the integral valve block 100 is equipped with a plurality of valve units 300 for distributing the fluid flow from the main flow path 100 to the fluid destination through the sub pipe line 130 .

That is, the valve unit 300 for controlling the flow rate and speed of the fluid is mounted on each boundary flow path 120 between each main pipe line 110 and the sub pipe line 130 of the integrated valve block 100 .

As shown in FIG. 2, the valve unit 300 includes a valve housing 310, a valve cover 320, a valve body 330 for fluid control, etc. assembled in the boundary flow path 120 of the integral valve block 100. is comprised of

The valve housing 310 is provided with a hollow structure in which the fluid passage hole 312 is formed through the radial direction, and the boundary flow path 120 between the main pipe line 110 and the sub pipe line 130 of the integrated valve block 100 . is inserted and mounted inside.

The valve cover 320 is provided in a structure in which a female screw part 322 is formed in its inner diameter, is inserted into the integral valve block 100 , and is stacked and mounted on the valve housing 310 at the same time.

The fluid control valve body 330 has a head 332 exposed to the outside of the integral valve block 100 for rotation operation on its upper portion, and a female screw portion 322 of the valve cover 320 in the middle portion. ) is formed with a male screw part 334 screwed to the bottom, and a circular pin-shaped flow rate control end 336 inserted into the lower opening part 314 of the valve housing 310 is formed at the bottom thereof.

At this time, the fixing nut 340 for fixing the position of the fluid control valve body 330 is fastened to the upper portion of the male screw part 334 that is just below the head 332 of the fluid control valve body 330 .

In addition, a check ring 350 in contact with the lower inner diameter of the boundary flow passage 120 is mounted on the lower outer diameter portion of the valve housing 310 , and the check ring 350 maintains a constant normal flow pressure of the fluid. It serves to regulate the pressure level.

Preferably, an O-ring 360 compressed to the upper inner diameter of the boundary passage 120 is mounted on the upper outer diameter portion of the valve housing 310 , and the O-ring 360 passes through the boundary passage 120 . It serves as an airtight function to block the fluid from leaking to the outside of the integral valve block (100).

Here, the operating flow for the integrated fluid flow and speed control device of the present invention configured as described above will be described with reference to FIGS. 1 and 3 attached thereto.

First, when the solenoid valve 200 is inserted and fastened into the mounting hole 210 formed in the inlet part of each main pipe line 110 of the integrated valve block 100, the main according to the on/off operation of the solenoid valve 200 The inlet of the conduit 110 is in a state that can be opened and closed.

Then, when the solenoid valve 200 is operated to open, a fluid (hydraulic oil for hydraulic pressure or air for pneumatic pressure) flows from the fluid supply side through the main conduit 110 to the boundary flow path 120 .

On the other hand, when the solenoid valve 200 is operated to close, the inlet of the main pipe 110 may be closed, and the fluid will no longer flow into the boundary flow path 120 .

Subsequently, the fluid that has reached the boundary flow path 120 flows to the sub pipe line 130 while controlling the flow rate and speed by the valve unit 300 .

At this time, the fluid flows into the sub-pipeline 130 while the flow pressure is adjusted to a constant normal pressure level by the check ring 350 of the fluid control valve body 330 .

At the same time, when the fluid passes between the gap between the flow rate control end 336 of the fluid control valve body 330 and the lower opening 314 of the valve housing 310, the speed is controlled and the sub-pipeline (130).

That is, when the head 332 of the valve body 330 for fluid control is rotated with a tool, the male screw portion 334 is screwed with the female screw portion 322 of the valve cover 320 while the valve housing 310 is rotated. The flow rate control end 336 inserted into the lower opening 314 of The speed of the fluid passing between the gap between the flow rate control end 336 of the fluid control valve body 330 and the lower opening 314 of the valve housing 310 may be adjusted.

Accordingly, the fluid flowing into the sub-pipeline 130 is sent to a fluid destination (eg, a part requiring fluid such as hydraulic equipment or equipment) connected to the sub-pipeline, and the fluid reaching the fluid destination is transmitted to the corresponding machine (eg, It is used for the operation of hydraulic equipment or equipment, etc.).

On the other hand, after the fluid that has reached the fluid destination is used for the operation of the corresponding machine (eg, hydraulic equipment or equipment, etc.), it passes through the sub-pipe line 130 and the fluid control valve body 330 again to the main pipe line. When the circulation returning to 110 is made, when the solenoid valve 200 is removed from the mounting hole 210, the fluid returned to the main conduit 110 passes through the mounting hole 210 to the outside (eg, a fluid reservoir, etc.) ) and can be stored as discharged.

On the other hand, when a larger fluid pressure (hydraulic or pneumatic) and flow rate is required at the fluid destination, the size of the main flow path 110 and the sub flow path 130, and the size of the valve unit 300, etc. are adjusted, Greater fluid pressures and flow rates can be provided.

In this way, by integrating the single valve unit 300 into one valve block 100 and modularizing it, fluid flow control parts (a plurality of speed controllers, solenoids, etc.) Without assembling valves, pipes, etc.) individually, it is possible to easily distribute and control the flow direction of the fluid to various desired destinations such as hydraulic/pneumatic devices and facilities, as well as to easily control the flow rate and speed of the fluid toward each destination. can

Meanwhile, an anticorrosion coating layer may be applied to the valve block 100 to prevent corrosion of the metal surface.

The coating material of this anticorrosion coating layer is triethanolamine 15% by weight, indiazole 25% by weight, hafnium 20% by weight, molybdenum emulsified (MoS ² ) 10% by weight, titanium oxide (TiO ² ) 15% by weight, propionamide 15% by weight %, and the coating thickness can be formed to 8㎛.

Triethanolamine, indiazole, and propionamide act as corrosion protection and discoloration protection.

Hafnium is a transition metal element with corrosion resistance, and serves to have excellent waterproof and corrosion resistance.

Molybdenum emulsified plays a role in imparting lubricity and lubricity to the surface of the coating film.

Titanium oxide is added for the purpose of fire resistance and chemical stability.

The reason why the ratio of the constituents and the coating thickness were numerically limited as described above, the inventors of the present invention repeatedly failed several times and analyzed through the test results. As a result, the optimal anti-corrosion effect was exhibited at the above ratio.

In addition, an antifouling coating layer made of an antifouling coating composition may be applied to the solenoid valve 200 to effectively prevent adhesion and removal of contaminants.

The antifouling coating composition contains cocoamphodiacetate and alkyl glycol ether in a molar ratio of 1:0.01 to 1:2, and the total content of cocoamphodiacetate and alkyl glycol ether is 1 to 10% by weight based on the total aqueous solution. am.

The molar ratio of cocoamphodiacetate and alkyl glycol ether is preferably 1:0.01 to 1:2. When the molar ratio is out of the above range, the applicability of the solenoid valve 200 decreases or water adsorption on the surface after application increases. Accordingly, there is a problem in that the coating film is removed.

The cocoamphodiacetate and the alkyl glycol ether are preferably 1 to 10% by weight in the entire aqueous solution of the composition, and when it is less than 1% by weight, there is a problem in that the applicability of the solenoid valve 200 is reduced, and when it exceeds 10% by weight, it is applied Crystal precipitation is likely to occur due to an increase in the film thickness.

On the other hand, as a method of applying the present antifouling coating composition on the solenoid valve 200, it is preferable to apply by a spray method. In addition, the final coating film thickness on the solenoid valve 200 is preferably 550 ~ 2000Å, more preferably 1100 ~ 1900Å. If the thickness of the coating film is less than 550 Å, there is a problem in that it is deteriorated in the case of high-temperature heat treatment, and if it exceeds 2000 Å, there is a disadvantage that crystal precipitation on the coated surface is easy to occur.

In addition, the present antifouling coating composition can be prepared by adding 0.1 mol of cocoamphodiacetate and 0.05 mol of alkyl glycol ether to 1000 ml of distilled water and then stirring.

And, the O-ring 360 may be made of a rubber material, and the raw material content ratio of the O-ring 360 is rubber 55% by weight, organic acid cobalt salt 6% by weight, naphthalic anhydride 6% by weight, carbon black 22 % by weight, 3C (N-PHENYL-N'-ISOPROPYL-P-PHENYLENEDIAMINE) 6% by weight, and sulfur 5% by weight are mixed.

Carbon black is added to increase or improve abrasion resistance and thermal conductivity, and organic acid cobalt salt and naphthalic anhydride are added to improve adhesion.

3C (N-PHENYL-N'-ISOPROPYL-P-PHENYLENEDIAMINE) is added as an antioxidant, and oil is added to act as an accelerator.

Therefore, according to the present invention, since elasticity, toughness and rigidity of the O-ring 360 are increased, durability is improved, and thus the life of the O-ring 360 is increased.

The reason for limiting the rubber material constituents and constituents and limiting the numerical value of the mixing ratio is that the present inventor repeatedly failed several times and analyzed the test results to show the optimal effect in the composition and numerical limit ratio it was

100: valve block
110: main pipeline
120: border euro
130: sub pipe
200: solenoid valve
210: mounting hole
300: single valve
310: valve housing
312: fluid passage hole
314: lower opening
320: valve cover
322: female thread part
330: valve body for fluid control
332: head
334: male thread part
336: flow control stage
340: fixing nut
350: check ring
360: O-ring

Claims (3)

An integrated valve block 100 in which a plurality of main conduits 110 connected to the fluid supply side and a plurality of sub conduits 130 extending from each main conduit 110 to a fluid destination are formed;
a solenoid valve 200 detachably mounted to the inlet portion of each main conduit 110 connected to the fluid supply side; and
It is mounted on the boundary flow path 120 between the main pipe line 110 and the sub pipe line 130 and is configured to include a plurality of valve units 300 for controlling the flow rate and speed of the fluid;
The valve unit 300 includes:
A valve housing ( 310);
a valve cover 320 having a structure in which a female screw part 322 is formed in an inner diameter and stacked on an upper portion of the valve housing 310;
A head portion 332 exposed to the outside of the integral valve block 100 is formed on the upper portion for rotation operation, and a male screw portion 334 screwed to the female screw portion 322 of the valve cover 320 is formed in the middle portion. is formed, and a fluid control valve body 330 having a flow rate adjusting end 336 inserted into the lower opening 314 of the valve housing 310 at a lower portion thereof;
a fixing nut 340 fastened to an upper portion of the male screw portion 334 of the fluid control valve body 330;
a check ring 350 mounted on the lower outer diameter of the valve housing 310 and in contact with the lower inner diameter of the boundary passage 120 ; and
an O-ring 360 mounted on the upper outer diameter of the valve housing 310 and compressed on the upper inner diameter of the boundary passage 120 ;
An integral fluid flow and velocity control device, characterized in that it comprises a.
delete The method according to claim 1,
An integrated fluid flow and speed control device, characterized in that a mounting hole (210) for detachably mounting a solenoid valve (200) is formed at the inlet portion of each main pipe line (110) connected to the fluid supply side.

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