KR100481403B1 - Pressure reducing and pressure sustaining control valve system - Google Patents

Abstract

The present invention relates to a pressure reducing and pressure maintaining control valve system, and more particularly, is installed on an auxiliary flow path connecting an inlet and an outlet of a main valve connected in series to a main pipe to which fluid is supplied to maintain a constant inlet pressure. The present invention relates to a pressure reducing and pressure maintaining control valve system which prevents the inlet side pressure from dropping even when the flow rate of the outlet side rapidly increases, thereby enabling a stable flow rate and pressure control not only at the outlet side but also at the inlet side.

To this end, the present invention, the inlet and outlet which are connected in series to the main pipe to which the fluid is supplied is provided to form a flow path, the upper chamber communicated by the inlet and the auxiliary passage by a diaphragm and the lower chamber communicated to the outlet Main valves which are separated from each other, and in which a flow path between the inlet and the outlet is selectively adjusted according to a difference in pressure applied to the upper and lower chambers; Fluid flows through the first inlet connected to the auxiliary inlet formed in the inlet of the main valve and the first auxiliary channel, and the upper chamber of the main valve through the first outlet connected to the second auxiliary channel. (S1) and when the inlet side pressure is equal to or greater than a predetermined set pressure, a flow path between the first inlet and the second outlet for discharging the controlled fluid is opened to open a third auxiliary passage through the second outlet. Relief valve to discharge to; Fluid flows through a second inlet connected by the third auxiliary channel, and discharges the introduced fluid into a fourth auxiliary channel connected to an auxiliary outlet formed at an outlet of the main valve through a third outlet, and the outlet of the fluid. And a pressure reducing valve configured to reduce a flow path between the third outlet and the second inlet when the side pressure is greater than or equal to a predetermined set pressure.

Description

Pressure reducing and pressure sustaining control valve system

The present invention relates to a pressure reducing and pressure maintaining control valve system, and more particularly, is installed on an auxiliary flow path connecting an inlet and an outlet of a main valve connected in series to a main pipe to which fluid is supplied to maintain a constant outlet pressure. The present invention relates to a pressure reducing and pressure maintaining control valve system which prevents the inlet side pressure from dropping even when the flow rate of the outlet side rapidly increases, thereby enabling a stable flow rate and pressure control not only at the outlet side but also at the inlet side.

In general, the water supply is a large amount of water pressure, and a large amount of fluid is sent through large-diameter tap, water, and drainage pipes. In the form of a gradient, water is sent to a drainage basin in a high altitude place to supply water to the demand for water in the lower region.

In this case, since the water pressure rises in the lower region due to the difference in altitude between the drainage and the demand for water, a pressure reducing valve is required to supply water at an appropriate pressure in the lower region.

However, when a general pressure reducing valve is installed, the inlet side pressure, that is, the primary side pressure of the pressure reducing valve decreases during a time when water is used in a large amount of time, such as daytime, which causes a problem that the water is not supplied at the demand located near the drainage basin.

Therefore, in such a place, it is important not only to maintain the outlet pressure, that is, the pressure on the secondary side at a set pressure, but also to maintain the primary pressure at a constant pressure so that water can be used in the highlands on the primary side. There is an urgent need for the development of valves having the same function.

Therefore, the present invention has been devised to solve the above problems, while maintaining a constant pressure on the outlet side, even if the flow rate on the outlet side is increased rapidly, the inlet side pressure is prevented from falling so that the inlet side as well as the inlet side is stable. It is an object of the present invention to provide a pressure reducing and pressure maintaining control valve system that enables flow supply and pressure control.

In addition, the present invention by installing a pilot-type pressure reducing valve and a relief valve on the auxiliary flow path connecting the inlet and outlet of the main valve to reduce the pressure and pressure maintenance to enable easy adjustment and easy maintenance while responding to small pressure changes The aim is to provide a control valve system.

With reference to the accompanying drawings, a preferred embodiment of the pressure reducing and pressure maintaining control valve system according to the present invention for achieving the above object will be described in detail as follows.

1 is a view showing the configuration of the control piping of the pressure reducing and pressure maintaining control valve system according to the present invention, Figure 2 is a cross-sectional view showing the configuration of the main valve of Figure 1, Figure 3 is a configuration of the relief valve of Figure 1 4 is a cross-sectional view showing the configuration of the pressure reducing valve of FIG.

First, as shown in FIG. 1, the pressure reducing and pressure maintaining control valve system according to the present invention is largely provided with an inlet port 110 and an outlet port 120 connected in series to a main pipe through which a fluid is supplied to form a main passage. A relief valve 200 mounted on an auxiliary flow path connecting the valve 100 and the auxiliary inlet port 110a formed at the inlet port 110 of the main valve 110 and the auxiliary outlet port 120a formed at the outlet port 120. ) And the pressure reducing valve 300.

The auxiliary inlet 110a is connected to the relief valve 200 through a first auxiliary channel P1, and the relief valve 200 is connected to the main valve 100 through a second auxiliary channel P2. .

In addition, the relief valve 200 is connected to the pressure reducing valve 300 through a third auxiliary flow path P3, and the pressure reducing valve 300 is connected to the main valve 100 through a fourth auxiliary flow path P4. It is connected to the secondary outlet 120a formed in the outlet 120 of the.

In addition, on and off valves 400 and 500 are provided on the first auxiliary channel P1 and the fourth auxiliary channel P4 to open and close the channel.

The configuration of the main valve 100 in the present invention made as described above is shown in detail in FIG.

As shown in the drawing, the main valve 100 communicates with the inlet 110 by a diaphragm 144 and an auxiliary flow passage, that is, by the first auxiliary flow passage P1 and the second auxiliary flow passage P2. The inlet 110 and the outlet 120 are separated from each other by the lower chamber S2 communicating with S1 and the outlet 120 and acting on the upper pressure S1 and the lower chamber S2. The flow path between them is selectively adjusted.

Main valve 100 according to the present invention as described above, the inlet 110 and the outlet 120 is provided with a valve body 130 to form a flow path, and the diaphragm assembly coupled to the valve body 130 140.

Here, the diaphragm assembly 140 is coupled to an intermediate plate 142 having a lower communication hole 142a communicating with the outlet 120 at one side thereof, and an inner chamber coupled to an upper portion of the intermediate plate 142. And a cover plate 143 having an upper communication hole 143a communicating with the second auxiliary flow path P2 on one side thereof.

A diaphragm 144 is disposed between the intermediate plate 142 and the cover plate 143 to separate the upper chamber S1 and the lower chamber S2, and a diaphragm plate (upper and lower surfaces) of the diaphragm 144 is provided. 145a and 145b are mounted, respectively.

The plunger 146 which moves up and down in accordance with the up and down movement of the diaphragm 144 is supported by the diaphragm plates 145a and 145b, and is coupled to the plunger 146 to move the valve body 130 according to the lifting and lowering movement. The flow path between the inlet 110 and the outlet 120 of the, i.e. the disk sheet 147 for opening or closing the sheet portion 131.

The diaphragm assembly 140 made as described above is coupled to the opening 132 in the upper portion of the valve body 130 to constitute the main valve 100 according to the present invention.

The configuration of the main valve 100 as described above is as disclosed in the Utility Model Registration No. 0318348 of the applicant, it should be understood that the present invention includes both such configuration and description.

Next, the relief valve 200 according to the present invention is shown in detail in FIG. 3.

First, the relief valve 200 according to the present invention is a pilot type, the first inlet 210 by the auxiliary inlet (110a) and the first auxiliary passage (P1) formed in the inlet 110 of the main valve 100. ) And an internal flow path is formed between the first inlet 210 and the second outlet 220 for discharging the controlled fluid.

On the other hand, the first inlet 210 is also connected to the upper chamber (S1) of the main valve 100 through the first outlet 215 connected to the second auxiliary passage (P2), and also through the inner passage It is also connected to the first inlet 310 of the pressure reducing valve 300 to be described later through the second outlet 220 and the third auxiliary flow path (P3).

More specifically, the relief valve 200 according to the present invention is largely coupled between the body 230, the cover 250 coupled to the body 230, and the body 230 and the cover 250. It consists of a diaphragm assembly 260 and an adjustment unit 270 to elastically adjust it.

First, the body 230 is a seat portion 231 through which the flow path is opened and closed between the first inlet 210 and the second outlet 220, and an auxiliary spool provided in a lower space of the seat 231. The pipe 240 and the connection pipes 211 and 212 connecting the portion 240, the fluid flowing from the first inlet 210 to the auxiliary spool part 240 and the first outlet 215, and the connection pipe 211. And a needle valve 217 formed at 212, and an orifice 232 penetrating upward from the first inlet 210.

Here, a needle valve 217 is installed on the connection pipes 211 and 212 connecting between the first inlet 210, the first outlet 215, and the auxiliary spool part 240, and the needle valve 217. ) Moves linearly in accordance with the pressure of the fluid flowing through the connecting pipe passage (211, 212).

To this end, the needle valve 217 is preferably installed on the connection pipe 211 branched from the first inlet 210 to the first outlet 215 and the auxiliary spool portion 240.

When the pressure of the fluid flowing through the connection pipe line 211 is small, the needle valve 217 is kept in a state in which the connection pipe line 211 is blocked, and when the pressure is high, the needle valve 217 is assisted with the first outlet 215. The flow path to the spool portion 240 is formed at the same time.

The needle valve 217 can appropriately set the sensitivity to the hydraulic pressure by adjusting the bolt nut from the outside of the valve.

In the first inlet 210, an orifice 232 is formed to penetrate the upper end of the body 230 so that the diaphragm 261 coupled to the top of the body 230 and the body 230 is formed in the inner chamber. The pressure of the first inlet 210 is transmitted.

Between the first inlet 210 and the second outlet 220 through which the controlled fluid is discharged, the sheet part 231 through which the flow path is opened and closed, and the auxiliary spool part provided in the lower space of the seat part 231. 240 is provided, and the seat part 231 is a path through which the fluid introduced from the first inlet 210 passes, and is opened and closed by the diaphragm 261 moving up and down according to hydraulic pressure.

Meanwhile, a cover 250 is mounted on the upper portion of the body 230 to form an inner space, and the diaphragm assembly 260 is coupled to the body 230.

The diaphragm assembly 260 includes a diaphragm 261 interposed between the body 230 and the cover 250, diaphragm plates 262 and 263 coupled to the diaphragm 261, and the diaphragm. A plunger 264 supported by the pram plates 262 and 263 to move up and down in accordance with the up and down movement of the diaphragm 261, and coupled with the plunger 264 to open the flow path of the seat 231 according to the up and down movement. Or a disk sheet 265 for closing.

As shown, the disk seat 265 of the diaphragm assembly 260 is positioned at the upper second outlet 220 side of the body seat part 231 to control the opening and closing of the flow path.

The plunger 264 is coupled to penetrate the guide hole of the guide bushing 233 provided in the body 230 so that the lifting movement is guided, and the disk seat 265 of the diaphragm assembly 260 is the body seat. Located at the upper outlet side of the portion 231 to control the opening and closing of the flow path.

The diaphragm assembly 260 configured as described above is controlled by the pressure on the side of the first inlet 210 acting on the lower surface of the diaphragm 261 and the adjusting unit 270 according to the present invention.

The control unit 270 according to the present invention is a support plate 272 that is moved up and down by the rotation of the adjustment screw 273 provided on the cover 250, the support plate 272 and the diaphragm An elastic spring 271 interposed between the plates 262 to elastically support the channel of the seat 231 to be closed.

That is, the support plate 272 elastically supporting the elastic spring 271 is screwed to the female screw portion 274 in the cover 250 and moved up and down by a predetermined distance by the adjustment screw 273, the adjustment screw When the screw 273 is turned to tighten the gap between the support plate 272 and the diaphragm plate 262, the elastic force of the elastic spring 271 becomes stronger, and conversely, when the adjusting screw 273 is loosened, The distance between the support plate 272 and the diaphragm plate 262 is widened so that the elastic force of the elastic spring 271 is weakened.

Therefore, when a predetermined set pressure P_1 is applied through the adjusting unit 270, the disk sheet 265 when the pressure transmitted to the first inlet 210 does not reach the set pressure P_1. Is located at the upper second outlet 220 side of the body sheet part 231, so that the flow path is still kept closed by the elastic force of the elastic spring 271.

However, when the pressure is greater than or equal to the set pressure P_1, the pressure is transmitted to the lower surface of the diaphragm 261 via the orifice 232 through the first inlet 210 of the relief valve 200 and the upper elastic spring ( The elastic force of 271 is overcome, and as a result, as the diaphragm assembly 260 moves upward, the disc seat 265 closing the seat 231 also rises, so that the second outlet from the seat 231 is increased. The flow path to 220 is opened so that a significant amount of the introduced fluid is discharged.

Next, the pressure reducing valve 300 according to the present invention is shown in detail in FIG. 4.

First, the pressure reducing valve 300 according to the present invention is pilot type, and is connected to the first inlet 310 in a third auxiliary flow path P3 connected to the second outlet 220 of the relief valve 200. An internal flow path is formed between the first inlet 310 and the first outlet 320 for discharging the controlled fluid.

The first outlet 320 is connected to the auxiliary outlet 120a formed at the outlet 120 of the main valve 100 through the fourth auxiliary passage P4.

More specifically, the pressure reducing valve 300 according to the present invention includes a body 330, a cover 350 coupled to the body 330, and positioned between the body 330 and the cover 350. It consists of a diaphragm assembly 360 and an adjustment unit 370 to elastically adjust it.

The pressure reducing valve 300 configured as described above is substantially the same in terms of the basic configuration as the relief valve 200 described above, and will be described in detail here based only on differences.

First, the orifice 332 formed of the body 330 is formed to penetrate from the first outlet 320 to the upper end, unlike the relief valve 200 penetrated from the first inlet 210 to the upper end.

Therefore, the pressure at the side of the first outlet 320 is transmitted to the inner chamber formed by the diaphragm 361 coupled to the top of the body 330 and the body 330 by the orifice 332.

In addition, the plunger 364 that moves up and down is extended from the diaphragm 361 to the auxiliary spool part 340, and the plunger 364 extending to the auxiliary spool part 340 has a seat portion 331. The disk sheet 365 for opening and closing the flow path is coupled.

That is, the disk seat 365 of the diaphragm assembly 360 is located in the lower side spool part 340 of the body seat part 331 to control the opening and closing of the flow path.

Meanwhile, a first elastic spring 271 interposed between the support plate 272 and the diaphragm plate 262 is disposed below the auxiliary spool portion 340 and the disc sheet 365 on which the disc sheet 365 is located. The second elastic spring 380 has a separate so as to maintain a predetermined distance from the sheet portion 331 to the disk sheet 365, and also to disperse the impact due to the rapid movement of the disk sheet 365 It is desirable to.

Therefore, in the case of the pressure reducing valve 300 according to the present invention, when a predetermined set pressure P_2 is applied through the adjusting unit 370, the pressure transmitted to the first outlet 320 side is the set pressure P_2. If not, the flow path will remain open.

However, when the pressure transmitted to the lower surface of the diaphragm 361 through the orifice 332 communicating with the first outlet 320 becomes greater than or equal to the set pressure P_2, the elastic force of the elastic spring 371 is overcome. As a result, as the diaphragm assembly 360 moves upward, the disc seat 365 also rises, thereby gradually closing the seat part 331, thereby reducing the flow path.

Referring to the operation process according to the pressure reduction and pressure maintaining control valve system of the present invention made as described above in detail.

5 is a view showing the flow of water according to the pressure retention process.

For reference, the arrow indicates the flow of water, the dotted line indicates the flow before control, and the solid line indicates the flow after control.

First, in order to maintain the pressure at the inlet 110 side, that is, the primary side, of the main valve 100 at a predetermined set pressure P_1, the pressure is previously provided through the adjustment unit 270 of the relief valve 200 according to the present invention. Set.

Next, when the water is supplied within the set pressure, the water passes through the flow path between the inlet 110 and the outlet 120 of the main valve 100, and at this time, the auxiliary inlet 110a and the second inlet 110 of the inlet 110. The primary pressure is transmitted to the lower surface of the diaphragm 261 of the relief valve 200 through the first auxiliary channel P1.

At this time, if the pressure of the primary side is lower than the set pressure (P_1) of the relief valve 200, since the internal flow path of the relief valve 200 is not opened, the auxiliary inlet (110a) and the first auxiliary flow path (P1). The fluid introduced into the first inlet 210 passes through the internal connection pipe and enters the upper chamber S1 of the main valve 100 through the first outlet 215 and the second auxiliary channel P2. The flow path of the main valve 100 is blocked.

However, when the pressure on the primary side is greater than or equal to the set pressure P_1, the pressure is transmitted to the lower surface of the diaphragm 261 via the orifice 232 through the first inlet 210 of the relief valve 200 and the upper portion thereof. The elastic force of the elastic spring 271 is overcome. As a result, as the diaphragm assembly 260 moves upward, the disk seat 265 closing the seat portion 231 also rises to the seat portion 231. The flow path to the second outlet 220 is opened.

In this case, a substantial amount of the fluid flowing into the first inlet 210 is controlled through an internal flow path and is discharged to the third auxiliary flow path P3 through the second outlet 220. By being discharged to the fourth auxiliary flow path (P4) through the end will be sent to the auxiliary outlet (120a) formed in the outlet 120 of the main valve (100).

That is, when the flow rate flowing from the pump suddenly increases or the pressure on the primary side becomes equal to or higher than the set pressure P_1 on the pipeline in which the main valve 100 is installed, the fluid pressurizing the upper chamber S1 of the main valve 100. A considerable amount of is discharged to the pressure reducing valve 300 through the relief valve 200, as a result of the upper chamber (S1) relative to the lower chamber (S2) in communication with the outlet 110 of the main valve (100) As the pressure of the diaphragm 144 is moved upward while the disc seat 147 is also moved upward from the seat portion 131, the flow path between the inlet 110 and the outlet 120 is opened, thereby causing an excess of the primary side. Pressure is to be released immediately.

Therefore, when the pressure on the pipe line in which the main valve 100 is installed becomes equal to or higher than the set pressure P_1, the main valve 100 is opened and the excess pressure is discharged to the secondary side to discharge the primary pressure to the set pressure of the relief valve 200. By maintaining constant at (P_1), it is possible to prevent damage to the equipment and piping due to the excess pressure in advance.

Here, the set pressure (P_1) through the relief valve 200 can be appropriately changed according to the flow rate or the pipe condition.

On the other hand, in the case of the present invention in addition to the pressure on the secondary side can also be maintained at the set pressure, Figure 6 is a view showing the flow of water in the decompression process.

For reference, the arrow indicates the flow of water, the dotted line indicates the flow before control, and the solid line indicates the flow after control.

First, in order to maintain the pressure at the outlet 120 side, that is, the secondary side of the main valve 100 at a predetermined set pressure P_2, in advance through the adjustment unit 370 of the pressure reducing valve 300 according to the present invention. Set the pressure.

In this case, when the pressure at the first outlet 320 is less than or equal to the set pressure P_2, the flow path between the first inlet 310 and the first outlet 320 is always open and is discharged from the relief valve 200. The fluid can always be relief to the outlet 120 side of the main valve (100).

If the flow rate decreases suddenly and the secondary pressure rapidly increases, the pressure at the first outlet 320 is increased through the fourth auxiliary passage P4 connected to the outlet 120 of the main valve 100. In this case, the increased pressure is transmitted to the lower surface of the diaphragm 361 through the orifice 332 in communication with the first outlet 320.

At this time, when the pressure transmitted to the lower surface of the diaphragm 361 becomes more than the set pressure (P_2) to overcome the elastic force of the elastic spring 371, as a result the diaphragm assembly 360 is moved upward, the disk The seat 365 also rises to reduce the flow path passing through the seat part 331.

That is, a substantial amount of fluid that is released through the second outlet 220 of the relief valve 200 passes through the upper chamber S1 of the main valve 100 through the first outlet 215 and the second auxiliary flow path P2. The pressure of the upper chamber S1 is relatively increased as compared with the lower chamber S2 communicating with the outlet 110 of the main valve 100, and the diaphragm 144 of the main valve 100 moves downward. At the same time, since the disk sheet 147 is moved downward to the seat portion 131, the flow path between the inlet 110 and the outlet 120 is reduced so that the high pressure of the secondary side is immediately resolved.

Therefore, when the pressure on the pipeline passing through the main valve 100 becomes equal to or greater than the set pressure P_2, the pressure of the upper chamber S1 of the main valve 100 is increased to reduce the flow path of the main valve 100. As a result, the secondary pressure is kept constant at the set pressure P_2 of the pressure reducing valve 300.

In addition, even if the flow rate is gradually reduced, even when there is no flow rate completely, the flow of the main valve 100 is completely blocked to maintain a constant pressure on the secondary side.

Here, the set pressure (P_2) through the pressure-reducing valve 300 can be appropriately changed according to the flow rate or the pipe condition.

According to the present invention as described above, when the secondary pressure does not become equal to or higher than the set pressure P_2 of the pressure reducing valve 300, the pressure reducing valve 300 is always open, so the primary pressure is the set pressure of the pressure reducing valve 300. The flow path of the main valve 100 is opened even below P_2, and when the primary pressure is greater than or equal to the set pressure P_1 of the relief valve 200, the main valve (according to the set pressure P_2 of the pressure reducing valve 300) 100 is maintained at a constant pressure by controlling the flow path of the discharge to the secondary side, and even if the flow rate of the secondary side is rapidly increased, the primary pressure is always set to the set pressure (P_1) of the relief valve 200 This ensures stable flow and pressure control not only on the secondary side but also on the primary side.

As described above, the present invention is mounted on the auxiliary flow path connecting the inlet and the outlet of the main valve, while maintaining the inlet side pressure at the set pressure of the relief valve, the outlet side can discharge the fluid decompressed to the set pressure of the pressure reducing valve. In order to provide a pressure reducing and pressure maintaining control valve system, it can be seen that there are basic technical ideas.

And within the scope of such technical ideas, a person of ordinary skill in the art that many various modifications and applications are of course possible.

As described above, according to the present invention, it is installed on the auxiliary flow path connecting the inlet and the outlet of the main valve connected in series with the main pipe to which the fluid is supplied to maintain the pressure in the outlet side pipe at a set low pressure, By preventing the pressure from being lower than the set pressure, it is possible to provide a stable flow rate and pressure control at the inlet side as well as the outlet side.

In addition, it responds precisely to the minute pressure change acting through the orifice, so it is very reliable, and the main valve is provided with pressure reducing and pressure maintaining functions as an integrated structure, allowing easy adjustment and simple maintenance. It is expected.

1 is a view showing a control piping configuration of a pressure reducing and pressure maintaining control valve system according to the present invention

2 is a cross-sectional view showing the configuration of the main valve of FIG.

3 is a cross-sectional view showing the configuration of the relief valve of FIG.

Figure 4 is a cross-sectional view showing the configuration of the pressure reducing valve of Figure 1

5 is a view showing the flow of water in the pressure maintaining process according to a preferred embodiment of the present invention

6 is a view showing the flow of water in the decompression process according to a preferred embodiment of the present invention

* Description of the symbols for the main parts of the drawings *

100..Main valve 110, 120..Inlet, outlet

110a, 120a .. Auxiliary inlet, auxiliary outlet

131. Seat 130. Main valve body

140 .... Diaphragm assembly 142a, 143a .. Lower communication hole, upper communication hole

143 .... cover plate 144 .... diaphragm

146 .... plunger 147 .... disc seat

200 .... Relief Valve

210, 215, 220..First inlet, first outlet, second outlet

211, 212 .. Connection line 230 .... Relief valve body

231 ... seat 232. Orifice

250. Cover 260 Diaphragm assembly

264..Plunger 265 .... Disc seat

270 .... Adjustment unit 271 .... Elastic spring

273 .. Adjusting screw 300 .... Reducing valve

310, 320..First inlet, first outlet

330 ... pressure reducing valve body

332. Orifice 350 .... Cover

360 ... Diaphragm assembly 364. Plunger

365 .... Disc seat 370 .... Adjustment unit

371, 380 .. First elastic spring, second elastic spring

S1, S2 .. Upper chamber, lower chamber

Claims (4)

An inlet and an outlet are connected to the main pipe to which the fluid is supplied in series to form a flow path, and the upper chamber S1 communicated by the inlet and the auxiliary channel by a diaphragm 144 and the lower chamber communicated with the outlet. A main valve 100 separated from each other by S2 and selectively controlling a flow path between the inlet and the outlet according to a difference in pressure acting on the upper and lower chambers; Fluid is introduced through the first inlet 210 connected by the auxiliary inlet 110a and the first auxiliary channel P1 formed at the inlet of the main valve, and the fluid flows into the second auxiliary channel P2. The first outlet port 215 is discharged to the upper chamber S1 of the main valve, and when the inlet side pressure is greater than or equal to a predetermined set pressure P_1, the first inlet port 210 and the fluid controlled to A relief valve 200 for discharging the flow path between the discharged second outlets 220 to discharge to the third auxiliary passage P3 through the second outlet; The fluid is introduced through the first inlet 310 connected by the third auxiliary channel P3, and the auxiliary fluid outlet 120a is formed at the outlet of the main valve through the first outlet 320. Is discharged to the fourth auxiliary flow path (P4) connected to the outlet, and when the outlet pressure is more than a predetermined set pressure (P_2) or more, the flow path between the first outlet 320 and the first inlet 310 is reduced Pressure reducing valve 300; Pressure reduction and pressure maintaining control valve system characterized in that consisting of. The method of claim 1, wherein the main valve 100, A valve body 130 having an inlet and an outlet to form a flow path; An intermediate plate 142 coupled to an opening of the upper portion of the valve body and having a lower communication hole 142a communicating with the outlet at one side thereof, and coupled to an upper portion of the intermediate plate to form an inner chamber, and having the second auxiliary at one side thereof; A cover plate 143 provided with an upper communication hole 143a communicating with the flow path P2, a diaphragm 144 interposed between the intermediate plate and the cover plate and separated into an upper chamber and a lower chamber, and the dia A diaphragm plate 145a and 145b mounted to a ram, a plunger 146 supported by the diaphragm plate to move up and down in accordance with the up and down movement of the diaphragm, and a plunger coupled to the plunger, A diaphragm assembly (140) comprising a disk seat (147) for opening or closing a flow path between an inlet and an outlet. And pressure maintaining control valve systems. The method of claim 1, wherein the relief valve 200, A seat portion for opening and closing the flow path between the first inlet and the second outlet, the auxiliary spool portion provided in the lower space of the seat portion, and connecting the fluid flowing from the first inlet to the auxiliary spool portion and the first outlet A valve body (230) comprising a connection pipe, a needle valve formed in the connection pipe, and an orifice penetrating upward from the first inlet; A cover 250 mounted on the body to form an inner space; A diaphragm interposed between the body and the cover, a diaphragm plate coupled to the diaphragm, a plunger supported by the diaphragm plate to move up and down in accordance with an up and down movement of the diaphragm, and combined with the plunger to move up and down Diaphragm assembly 260 consisting of a disk sheet for opening or closing the flow path of the seat portion; Adjustment unit 270 consisting of a support plate that is moved up and down by the rotation of the adjustment screw provided on the cover upper side, and an elastic spring interposed between the support plate and the diaphragm plate to elastically support the flow path of the seat portion. ); The disk seat of the diaphragm assembly is located on the upper second outlet side of the body seat portion to control the opening and closing of the flow path to perform a relief function, characterized in that the pressure control valve. The method of claim 1, wherein the pressure reducing valve 300, A seat part through which the flow path is opened and closed between the second inlet port and the third outlet port, an auxiliary spool part provided in the lower space of the seat part, a connecting pipe path connecting the fluid flowing from the second inlet port to the auxiliary spool part, A valve body 330 formed of a needle valve formed in a connection pipe and an orifice penetrating upward from the third outlet; A cover 350 mounted on the body to form an inner space; A diaphragm interposed between the body and the cover, a diaphragm plate coupled to the diaphragm, a plunger supported by the diaphragm plate to move up and down in accordance with an up and down movement of the diaphragm, and combined with the plunger to move up and down A diaphragm assembly 360 made of a disc sheet for opening or closing a flow path of the sheet portion according to the present invention; A support plate which is vertically moved by the rotation of the adjustment screw provided at the upper side of the cover, a first elastic spring interposed between the support plate and the diaphragm plate to elastically support the passage of the seat part, and the disc And a control unit 370 installed below the seat and made of a second elastic spring that elastically supports the flow path of the seat to be closed. The disk seat of the diaphragm assembly is located in the sub-spool portion of the lower side of the body seat portion to control the opening and closing of the flow path to perform a pressure reduction and pressure retention control valve system.