KR101491711B1 - Method for controlling flow rate of liquid or gas using diaphragm valve - Google Patents

Abstract

Since the diaphragm valve is constituted by one or a plurality of piston grooves made of a metal material, a shaft groove, a valve groove, an inlet port and a discharge port, it is possible to control the flow of a high temperature liquid or gas, The present invention relates to a method of controlling a flow rate of a liquid or a gas using a diaphragm valve, the method comprising: an upper body having a piston groove and a shaft groove formed in a vertical direction inside the piston, A diaphragm valve coupled to a lower side of the valve seat and including a lower body formed with an inlet, a flow path, and a discharge port, and a solenoid valve controlling air to be injected into the piston groove, To the inlet and outlet of one or more diaphragm valves in series, And controlling the solenoid valve of the diaphragm valve through a control signal according to a target value and a time value set by the control unit so that the liquid or gas flowing through the inlet And controlling the flow rate of the liquid or gas controlled through the diaphragm valve to a controlled flow rate target value set in the controller and a time value for operating the diaphragm valve, Comparing the flow rate measured value and the target value of the liquid or gas measured through the flowmeter or the balance at the control unit and comparing the measured value and the target value with each other, Stops the operation of the control unit And controlling the diaphragm valve until the measured value and the target value coincide when the comparison result of the measured value and the target value do not match.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method for controlling a flow rate of a liquid or a gas using a diaphragm valve,

The present invention relates to a method of controlling a flow rate of a liquid or a gas using a diaphragm valve, and more particularly, to a method of controlling a flow rate of a liquid or a gas by using a diaphragm valve, The present invention relates to a method of controlling a flow rate of a liquid or a gas using a diaphragm valve capable of controlling a flow of a high temperature liquid or gas and capable of controlling a minute flow rate.

Flow control valves, which generally control the flow rate, are operated through pressure differentials. Of the many flow valves operated by such pressure differentials, the following prior art publications: US Nos. 2, 980, 385; No. 3,493,008 of P. J. Scaglione; S. Perez (inventor) Patent Application US No. 08 / 545,890. U.S. Patent No. 2,980,385 to Hunter discloses a valve having a hemispherical, yieldable membrane, wherein the wall of the valve is relatively thick so that even if the pressure is significantly high in the recess of the valve, Is not locked in the flow outlet. On the other hand, the excessive wall thickness prevents the valve from reacting to minute pressure differences, so that the valve can be permanently closed or only a very small flow rate can be released without the required flow rate release at the minute opening of the valve have.

U.S. Patent No. 3,493,008 to Scaglione discloses a valve having a valve-active element composed of a disk cup and a metallic weld seamed, flexible bellow. Since the metallic flexible bellows wall is easily collapsed when the inner pressure is higher than the external pressure due to the pressure difference on both sides of the wall, the bellows design with a more resistant wall is required in high pressure operation, Is obtained.

On the other hand, the disk-shaped cup is basically rigid and this disk-shaped cup sealing device loses efficiency with the valve seat when the flow rate in the conduit carries impurities. In addition, a substantial loss of load due to the valve structure is created.

Most valves in the prior art, operated by pressure differentials, have a complicated structure with considerable load loss and are very inflexible with regard to hydraulic pressure in the conduit. In other words, these valves are designed to regulate flow within a smaller range of pressures, losing efficiency for significant pressure changes within the conduit.

U.S. Patent Application No. 08 / 545,890 to Perez discloses a differential type valve which is sensitive to minute pressure changes and which is resistant to significant operating pressures, which allows for a very simple design with few components. The differential valve shows a rigid valve body having an opening for the flow inlet and a flow outlet which is located in an approximately intersecting manner with respect to the inlet opening. The valve body has a main cavity between the flow inlet and the outlet and a valve seat at the boundary of the main cavity and the flow inlet. The valve body is also provided with a control flow outlet conduit connected to the control flow transfer means of the valve. The valve has an elastomeric body located inside the main cavity of the valve, said elastomer being hollow and having one of its axial ends open and a central opening provided at the other end.

The central opening transfers the control flow inlet to the cavity, which is of the same nature as the flow rate of the network in which the valve is operating.

Although this last kind of valve is a useful and simple design, it is not possible to use a control flow that is different from the flow rate of the network, which is essential in automatic controls or in devices where a large amount of control flow must be controlled through fine signals . The present invention has several components disclosed in U.S. Patent Application No. 08 / 545,890, except that it has an inlet means for control flow which can be independent of the main flow of the network, Lt; RTI ID = 0.0 > valve < / RTI >

However, the above-mentioned configuration has a problem that the flow rate can not be changed because the hole located in the sealing wall of the elastomer of the valve has a constant cross-section, and even if the flow rate can be changed, it is difficult to control the minute flow rate.

Since the diaphragm valve is constituted by one or a plurality of piston grooves made of a metal material, a shaft groove, a valve groove, an inlet port and a discharge port, it is possible to control the flow of a high temperature liquid or gas, And to provide a method for controlling the flow rate of a liquid or gas using a diaphragm valve.

The technical objects to be achieved by the present invention are not limited to the above-mentioned technical problems.

According to an aspect of the present invention, there is provided a method of controlling a flow rate of a liquid or a gas using a diaphragm valve, the method comprising: an upper body having a piston groove and a shaft groove formed therein in a vertical direction to insert the piston and the shaft; And a solenoid valve connected to a lower side of the valve seat for controlling air to be injected into the piston groove and a lower body formed with an inlet, a flow path and a discharge port, and a diaphragm valve Connecting an inlet pipe and a discharge pipe, through which liquid or gas flows, to the inlet and outlet of the at least one diaphragm valve coupled in series with each other, and connecting the solenoid valve of the diaphragm valve to a target value And a time value to control the flow rate of the refrigerant through the inlet port Wherein the flow rate of the liquid or gas controlled through the diaphragm valve is equal to the controlled flow rate target value set in the controller and the time value for operating the diaphragm valve, Comparing the flow rate measurement value and the target value of the liquid or gas measured through the flow meter or the balance connected between the valve and the control unit at the control unit and comparing the measurement value and the target value, And stopping the operation of the diaphragm valve when it is matched and controlling the diaphragm valve until the measured value matches the target value when the comparison result of the comparison between the measured value and the target value compared by the control unit does not match . ≪ / RTI >

Specifically, the diaphragm valve has one or a plurality of piston grooves formed in a vertical direction, a solenoid valve is coupled to one side, a shaft groove is formed in a direction perpendicular to the piston groove and a lower portion of the diaphragm valve, A valve seat which is connected to a lower end of the upper body and which is formed in a thin film shape and is lifted and lowered through the operation of the piston, A lower body coupled to the lower side of the upper body and having an inlet through which the liquid or gas introduced from the outside flows into the lower portion and a discharge port through which the liquid or gas introduced through the inlet is discharged, And the air is injected into the piston groove of the upper body, It may include a solenoid valve that allows the river.

The upper body, the lower body, the solenoid valve, the piston, and the valve seat may be formed of a metal material to open or close the flow of the hot liquid or gas.

The diaphragm valves may be connected in series to each other to form a module, and other diaphragm valves may be coupled in parallel to the diaphragm valve composed of the modules.

The controller may control the flow rate target value and the time value inputted through an external input device to pump the liquid or gas into which the diaphragm valve is introduced to operate the diaphragm valve as a pump.

As described above, according to the present invention, since the diaphragm valve is constituted by one or a plurality of piston grooves made of a metal material, a shaft groove, a valve groove, an inlet and an outlet, the flow of a high temperature liquid or gas can be controlled, , It can be modularized and driven as a single pump, and there is an advantage that a minute amount of flow can be controlled.

1 is a flowchart showing a flow rate control method of a liquid or a gas using a diaphragm valve according to an embodiment of the present invention.
2 is a view showing a diaphragm valve of a method for controlling a flow rate of a liquid or a gas using the diaphragm valve according to the present invention.
3 is a cross-sectional view of a diaphragm valve of a method for controlling the flow rate of a liquid or a gas using the diaphragm valve according to the present invention.
FIG. 4 is a view illustrating a method of controlling a flow rate of a liquid or a gas using a diaphragm valve according to the present invention, in which a plurality of diaphragm valves are coupled.
5 is a side view of a state where a plurality of diaphragm valves are coupled in a method of controlling a flow rate of a liquid or a gas using the diaphragm valve according to the present invention.
FIG. 6 is a cross-sectional view of a diaphragm valve according to the present invention, in which a plurality of diaphragm valves are combined in a method for controlling the flow rate of a liquid or a gas.
FIG. 7 is a vertical cross-sectional view illustrating a state where a plurality of diaphragm valves are coupled in a method of controlling a flow rate of a liquid or a gas using the diaphragm valve according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same components are denoted by the same reference symbols whenever possible. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

FIG. 1 is a view showing a method of controlling the flow rate of a liquid or a gas using a diaphragm valve according to an embodiment of the present invention. The upper body 10, the valve seat 30, the lower body 40, and the solenoid valve 50 (S10) of connecting an inlet pipe and a discharge pipe into which the liquid or gas flows into the inlet port 41 and the discharge port 42 of the diaphragm valve, respectively, and connecting one or more diaphragm valves (S20) of controlling a flow rate of a liquid or a gas through a target value and a time value set in the control unit, a step (S30) of measuring a flow rate of the flowing liquid or gas and comparing the flow rate with a set target value, (Step S40) of maintaining or stopping the operation of the solenoid valve 50 through a predetermined value.

The step of forming the diaphragm valve as a module and connecting the inlet pipe and the discharge pipe includes first connecting the upper body 10 and the diaphragm valve including the valve seat 30, the lower body 40, and the solenoid valve 50 And then combines at least one of them to form one module.

2 to 6, the piston groove 11 is formed in a vertical direction, a solenoid valve 50 is coupled to one side of the diaphragm valve, a piston 20 is inserted into the piston groove 11, A valve seat 30 coupled to a lower portion of the upper body 10 and formed in a thin film form; an inlet 41 connected to the lower side of the valve seat and through which liquid or gas flows; A solenoid valve 50 connected to one side of the upper body 10 to inject air into the piston groove 11 to move the piston 20 up and down, .

The upper body 10 of the diaphragm is formed with a piston groove 11 in which a piston 20 can be inserted and raised in a vertical direction and a shaft groove 12 is formed between the piston groove 11 and the lower end do.

A solenoid valve 50 is connected to one side of the upper body 10 to form a communication hole 13 to be connected to the piston groove 11.

The solenoid valve 50 injects air into the piston groove 11 to allow the piston 20 to move up and down through the air.

A piston 20 is inserted into a piston groove 11 of the upper body 10 and a shaft 21 is coupled to a lower portion of the piston 20 to form a shaft groove 12 formed in the upper body 10 And the shaft 21 is lifted and lowered along the shaft groove 12 as the piston 20 moves up and down.

A valve groove (14) through which the valve seat (30) can flow is formed below the shaft groove (12) of the upper body (10).

The lower body 40 is coupled to the lower portion of the valve seat 30. The lower body 40 is formed with an inlet 41 through which liquid or gas flows in a direction perpendicular to the interior of the lower body 40, A discharge port 42 through which the liquid or gas introduced through the inlet port 41 is discharged is formed.

A flow passage 15 is formed between the inlet 41 and the outlet 42 of the lower body 40 to open and close the flow passage 15 through the operation of the valve seat 30.

The lower body 40 is formed with a valve groove 14 into which the valve seat 30 can be inserted downward to open and close the inlet 41 and the outlet 42 of the lower body 40.

The upper body 10, the lower body 40, the solenoid valve, the piston 20, the shaft 21, and the valve seat 30 are formed of a metal material so as to open and close the flow of the hot liquid or gas. do.

When the air is introduced into the piston groove 11 by the operation of the solenoid valve 50 constructed as described above, the piston 20 and the shaft 21 are lifted and lowered. When the shaft 21 is lifted and raised, 12 and the valve seat 30 are brought into a vacuum state so that the valve seat 30 coupled to the lower portion of the upper body 10 is lifted and inserted into the valve groove 14 formed in the upper body 10 .

The liquid or gas supplied to the inlet port 41 of the lower body 40 flows to the discharge port 42 through the flow path 15.

When the flow of the liquid or gas flowing through the inlet port 41 is blocked, the solenoid valve 50 injects or discharges air into the piston groove 11 so that the piston 20 descends, The shaft 21 is lowered by pushing the air to lower the valve seat 30 and the lowered valve seat 30 is inserted into the valve groove 14 formed in the lower body 40 to shut off the inlet 41 .

At this time, the valve seat 30 opens and closes the inlet port 41 by the operation of the piston 20 in a state where inflow pressure for injecting liquid or gas is always applied to the inlet port 41.

When a plurality of piston grooves 11, shaft grooves 12 and valve grooves 14 are formed in the structure of the present invention, the plurality of pistons 20 are respectively operated to control the flow of liquid or gas.

A plurality of the piston grooves 11, the shaft grooves 12, and the valve grooves 14 are formed as follows.

When three piston grooves 11 are formed in the upper body 10, a piston 20 is inserted into each of the piston grooves 11 and a shaft 21 coupled to a lower portion of each of the pistons 20 The groove of the shaft 21 to be inserted is formed in a direction perpendicular to the upper body 10. [

A valve seat 30 is coupled to the lower portion of the upper body 10 and an inlet port 41 and a flow passage 15 are formed on the lower side of the valve seat 30 and a plurality of valve grooves 14 and a discharge port 42 are formed. The lower body 40 is joined.

At this time, the lower body 40 may have a plurality of inlet ports 41, a flow path 15, and a discharge port 42.

The diaphragm valves are connected in series to each other to form a module, and other diaphragm valves are connected in parallel to the diaphragm valve composed of a module so that a large amount of flow can be controlled.

As described above, when a plurality of diaphragm valves are connected in parallel with the series, and the flow rate is controlled through the control of the controller, the diaphragm valve can be used as a pump.

When at least one of the diaphragm valves is connected to the diaphragm valve to form a module, an inlet pipe for injecting liquid or gas into the inlet port 41 and the discharge port 42 of the diaphragm valve and a discharge pipe for discharging the liquid or gas .

A control unit is connected to the solenoid valve 50 of the diaphragm valve, and a flow meter or balance is connected between the control unit and the discharge port 42 of the diaphragm valve.

In the step S20 of controlling the flow rate of the liquid or the gas, when the diaphragm valve is installed in a facility for controlling the flow rate through the step of connecting the inlet pipe and the discharge pipe, A target value of the target flow rate and a time value for controlling the operation time of the diaphragm valve for achieving the target value are set in the control unit through an external input device connected to the control unit.

The solenoid valve 50 is operated by a control signal transmitted from the control unit on the basis of the target value and the time value set in the control unit to operate the diaphragm valve.

The flow rate of the liquid or gas measured through the diaphragm valve is measured and compared with the set target value (S30), the flow rate flowing through the flow meter or the balance connected between the control part and the discharge port 42 of the diaphragm valve is measured, And the control unit compares the measured flow rate measured value with the target value set in the control unit.

When the control signal is transmitted to the solenoid valve 50 of the diaphragm valve with the flow rate value compared in the control unit and the comparison result value controlled by the diaphragm valve reaches the target value through the step of controlling the diaphragm valve, The operation of the diaphragm valve is stopped to block the flow of liquid or gas (S40).

On the contrary, if the comparison result obtained by comparing the measured value with the target value does not match, the control unit controls the diaphragm valve until the measured value matches the target value (S40).

The operation of operating the diaphragm valve is as follows.

The piston 20 in the upper body 10 is lifted and lowered by the air flowing into the groove of the piston 20 through the solenoid valve 50 through the control signal of the control unit and the shaft 21 The valve seat 30 on the upper side of the inlet port 41 is raised to open the inlet port 41. As a result,

At this time, when the direction in which the air is injected from the solenoid valve 50 is above the piston 20, the diaphragm valve may simply serve as a valve.

The central piston 20 is operated through the solenoid valve 50 so that the valve seat 20 positioned on the flow passage 15 due to the suction force generated in the groove of the shaft 21 when the central piston 20 is lifted, The liquid or gas of the inlet 41 is sucked into the flow path 15 by the suction force of the valve seat 30 which is raised.

When the liquid or gas flows into the flow path 15 in this way, the piston 20 on the upper side of the inlet port 41 is lowered through the solenoid valve 50 so that the valve groove 14 on the upper side of the inlet port 41 is connected to the valve seat 30, .

At the same time, the piston 20 on the upper side of the discharge port 42 is raised through the solenoid valve 50, thereby opening the valve seat 30 of the valve groove 14 of the discharge port 42. The central piston 20 is lowered to lower the central valve seat 30 to shut off the valve groove 14 formed on the flow passage 15, Or the gas flows toward the discharge port 42 side.

When the liquid or gas is discharged to the discharge port 42, the piston 20 on the discharge port 42 is lowered to close the valve groove 14 on the discharge port 42, and at the same time, The piston 20 of the valve body 41 is lifted to raise the valve seat 30 above the inlet port 41 to open the valve groove 14 of the inlet port 41. [

Such an operation is repeatedly performed so that the configuration of the present invention can serve as a general pump.

When the communication hole 13 between the solenoid valve 50 and the piston groove 11 is formed on the upper side of the piston 20 so that the direction of the air injected from the solenoid valve 50 is opposite to that of the diaphragm valve 50, Thereby enabling the valve to function as a simple valve and to be used as a pump that operates only in the opposite direction.

According to the present invention configured as described above, since the diaphragm valve is constituted by one or a plurality of piston grooves made of a metal material, a shaft groove, a valve groove, an inlet port and a discharge port, the flow of a hot liquid or gas can be controlled, When configured, it can be modularized and driven like a single pump and has the advantage of controlling a minute amount of flow.

The diaphragm valve as described above is not limited to the configuration and operation of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

10: upper body 11: piston groove
12: shaft groove 13:
14: valve groove 15: flow path
20: piston 21: shaft
30: Valve seat
40: lower body 41: inlet
42:
50: Solenoid valve

Claims (5)

An upper body formed with a piston groove and a shaft groove in a vertical direction inside thereof and into which a piston and a shaft are inserted, a valve seat coupled to a lower side of the upper body, a valve seat coupled to a lower side of the valve seat, And a solenoid valve for controlling the air to be injected into the piston groove are connected in series to each other to form a module, and a liquid or a liquid is supplied to the inlet and the outlet of the at least one diaphragm valve in series, Connecting an inlet pipe and a discharge pipe into which gas flows;
Controlling a flow rate of the liquid or gas flowing through the inlet by controlling the solenoid valve of the diaphragm valve through a control signal according to a target value and a time value set by the controller;
The flow rate of the liquid or gas controlled through the diaphragm valve is measured through a flowmeter or a balance connected between the diaphragm valve and the control unit so that the flow rate of the liquid or gas controlled by the diaphragm valve coincides with the controlled flow rate target value set in the control unit and the time value for operating the diaphragm valve Comparing the flow measurement value and the target value of the liquid or gas at the control unit; And
And stopping the operation of the diaphragm valve when the comparison result of the comparison between the measured value and the target value is equal to the comparison result in the control unit and when the comparison result of the comparison between the measured value and the target value, And controlling the diaphragm valve until a value and a target value coincide with each other,
Wherein the control unit controls the flow rate target value and the time value input through an external input device to pump the liquid or gas into which the diaphragm valve is introduced to operate the diaphragm valve as a pump, Flow rate control method.
The method according to claim 1,
Wherein the diaphragm valve has one or more piston grooves formed in the vertical direction, a solenoid valve is coupled to one side of the diaphragm valve, a shaft groove is formed in a direction perpendicular to the piston groove and the lower portion, a piston is inserted into the piston groove, An upper body into which a shaft connected to a lower portion of the piston is inserted into the shaft groove;
A valve seat coupled to a lower end of the upper body and formed in a thin film shape and lifted and lowered through the operation of the piston;
A lower body coupled to a lower side of the valve seat and having an inlet through which the liquid or gas introduced from the outside flows down and a discharge port through which the liquid or gas introduced through the inlet is discharged is formed as a side or a lower side; And
And a solenoid valve coupled to one side of the upper body to inject air into the piston groove of the upper body to move the piston upward and downward.
The method of claim 2,
Wherein the upper body, the lower body, the solenoid valve, the piston, and the valve seat are made of a metal material so as to be capable of opening and closing a flow of a high temperature liquid or gas.
The method according to claim 1,
Wherein the diaphragm valve is connected in series to one or more of the modules, and the diaphragm valve is coupled in parallel with the diaphragm valve composed of the module.
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