KR200376651Y1 - Pressure reducing and temperature control valve - Google Patents

Abstract

The pressure reducing temperature control valve of the present invention includes a pressure reducing part and a temperature controlling part, and the pressure reducing part controls a working pressure introduced from the outside to a predetermined pressure to supply a storage tank in which the heated object is stored, and the temperature adjusting part adjusts the pressure reduction. It is connected to the front and rear of the negative pilot screen and detects the temperature of the heating object and controls the supply of working fluid to the pilot screen according to the detected temperature. The temperature control unit is electric, and the temperature control unit can be separated from the pressure control unit.

Description

Pressure reducing and temperature control valve

The present invention relates to a pressure-reducing temperature control valve, and more particularly to a pressure-reducing temperature control valve that can maintain a constant temperature of the heating object and at the same time reduce the working fluid.

In general, a structure for supplying hot water to a large building or an apartment complex is connected to a storage tank 120 in which a plurality of pipes 110 connected to each other as shown in FIG. 3 are stored with water. The working fluid (eg, steam) is supplied to a heat exchanger (not shown) installed in the storage tank 120 through the pipe 110 in the direction of the arrow. In this case, the heat exchanger has a structure capable of exchanging heat with a storage body (not shown) in which water or the like is stored, and thus the water is heated due to the heat of the working fluid supplied to the heat exchanger. In addition, the heated water is supplied to each home or a predetermined place along separate pipes (not shown) connected to the outside from the storage tank 120.

Typically, since the working fluid supplied through the pipe 110 is in a high temperature and high pressure state, a pressure reduction is performed to lower the pressure of the working fluid to a predetermined pressure before the fluid is supplied to the storage tank 120. 200 'is connected to a predetermined position of the pipe 110.

In addition, since the temperature of the water stored in the storage tank 120 must be constantly maintained at a predetermined temperature, the supply of the working fluid must be regulated according to the temperature of the water, and for this purpose, the temperature control valve 300 'is provided in the storage tank 120. And a pipe 110 at an adjacent position.

4 and 5, the conventional pressure reducing valve 200 'and the temperature control valve 300' will be described briefly as follows.

The pressure reducing control valve 200 ′ is connected to the pipe 110 and has a main body 201 through which the working fluid Q ₁ is introduced, stored and discharged. The inner center lower portion of the main body 201 is provided with a screen 202 for filtering out some working fluid Q ₁₁ to remove foreign substances.

The screen 202 is provided with a sheet 203 through which a portion of the upper surface is opened to allow the working fluid Q ₁₁ to flow, and a disk 204 is provided inside the sheet 203. In addition, the lower end of the disk 204 is provided with a spring 205 to elastically support the disk 204, the spring 205 is supported by the bottom flange 206 coupled to the lower end of the main body 201. The bottom flange 206 is provided with a drain plug 207 to discharge the working fluid in the body 201 to the outside.

In addition, a cylinder 208 is provided on the inner central upper portion of the main body 201, and a piston 209 for pressing the disk 204 downward by applying an external force (downward force) according to the situation in the cylinder 208 is provided. Is mounted.

The housing 210 is mounted on the upper surface of the main body 201.

The upper surface of the housing 210 is provided with a pressure adjusting bolt 211 is wrapped in a cap 212, the bottom of the pressure adjusting bolt 211 is provided with a spring 213.

In addition, the inner center of the housing 210 is provided with a diaphragm 214 to be in close contact with the spring 213, a pilot disk chamber consisting of a pilot stem 215 and a pilot ball disk 216 under the diaphragm 214 217 is provided, wherein the pilot ball disk 216 is elastically supported by the spring 218.

In addition, a pilot screen 219 is provided on the inner left side of the housing 210 to filter the working fluid Q ₁₂ flowing through the flow path 220 ′ formed in the main body 201, and the flow path above the piston 209. The working fluid Q ₁₂ is introduced from the pilot disk chamber 217 through 222.

In addition, the inside of the main body 201 on which the working fluid Q ₁₁ is discharged and the inside of the housing 210 are connected by a flow path 221 so that the working fluid Q ₁₁ may flow toward the diaphragm 214. Can be.

Referring to FIGS. 3 and 4, the principle of driving such a conventional pressure reducing valve is as follows.

The working fluid Q ₁ flows into the inlet of the pressure reducing control valve 200 ′ main body 201, and some working fluid Q ₁₁ is filtered by the screen 202 and stored under the seat 203 to stand by. The remaining working fluid Q ₁₂ is introduced into the pilot screen 219 through the flow path 220 'and filtered, and then flows into the pilot disk chamber 217 and is stored and waits. Since the pilot disc chamber 217 is open in a range (pressure) set by the pressure adjusting bolt 211, the working fluid Q ₁₂ flows upward through the flow path 222 to the piston 209. Accordingly, the piston 209 receives the external force (downward force) and presses the disk 204 downward.

As the disk 204 is pressurized, the working fluid Q ₁₁ waiting at the bottom of the seat 203 flows through the open upper surface of the seat 203 and is discharged to an outlet connected to the pipe 110. At this time, since the working fluid Q ₁₁ is discharged to the outlet, the pressure at the outlet side of the pressure reducing control valve 200 'is increased, and this rising pressure is diaphragm 214 through the flow path 221 of the pressure reducing control valve. To the upper side by pressing the spring 213 under the pressure adjusting bolt 211 upward, thereby raising the pilot ball disk 216, thereby closing the pilot disk chamber 217, and the bottom flange ( The disk 204 is urged upward by the elastic force of the spring 205 supported by 206 to block the open top portion of the seat 203, thereby stopping the flow of the working fluid Q ₁₁ . Thereafter, as the working fluid is discharged through the outlet, the pressure at the outlet side is lowered again, and thus, the pilot disk chamber 217 is opened in the range set by the pressure adjusting bolt 211 to operate the working fluid Q ₁₁ . As a series of operations are repeated, such as being supplied again, the working fluid Q ₁₁ may be reduced in pressure below a predetermined pressure and supplied to the outlet pipe 110.

Next, the conventional temperature control valve 300 ′ has a main body 301 into which the working fluid Q ₂ introduced through the pipe 110 is introduced, stored and discharged.

The lower center of the inside of the main body 301 is provided with a screen 302 for removing the foreign matter by filtering some of the working fluid (Q ₂₁ ) of the working fluid (Q ₂ ).

The screen 302 is provided with a sheet 303 through which a part of the upper surface is opened to allow the working fluid Q ₂₁ to flow, and a disk 304 is provided inside the sheet 303. In addition, the bottom of the disk 304 is provided with a spring 305 to elastically support the disk 304, the spring 305 is supported by the bottom flange 306 coupled to the bottom of the main body 301. The bottom flange 306 is provided with a drain plug 307 to discharge the working fluid in the main body 301 to the outside.

In addition, a cylinder 308 is provided in the upper center of the inside of the main body 301, and the piston 309 is applied to the disc 304 by pressing an external force (downward force) according to the situation in the cylinder 308. Is mounted.

The outer cover 310 is coupled to the upper surface of the main body 301.

A solenoid valve 311 is mounted on an upper portion of the outer cover 310, and a bypass valve 313 is provided on a flow path 312 between the outer cover 310 and the solenoid valve 311 to provide a power failure or solenoid valve 311. It is used to manually operate the temperature control valve in case of failure.

In addition, the left and right sides of the outer cover 310 is provided with a pilot screen 314 and a speed valve 315, respectively. The pilot screen 314 is located between the flow path 316 formed on the left side of the main body 301 and the flow path 317 formed on the left side of the outer cover 310, and the speed valve 315 is located on the right side of the main body 301. Located between the formed flow path 318 and the flow path 319 formed on the right side of the outer cover 310 and regulates the flow rate and flow rate of the working fluid.

The temperature controller 320 is connected to an external power source, connected to the solenoid valve 311 through the wire 321, and also connected to the temperature sensing unit 323 through the wire 322.

Temperature controller 320 is a power / function button 324 for setting the supply of power and change the function, the temperature control button 325 for setting the desired temperature, the temperature display window for displaying the set temperature or the detected temperature ( 326 and an operating state indicator lamp 327 for displaying respective operating states.

The temperature sensing unit 323 includes a connection part 328 coupled to the storage tank 20 and a sensing rod 329 in contact with a heated object such as water.

Referring to FIGS. 3 and 5, the principle of driving the conventional temperature control valve 300 ′ is as follows.

The working fluid Q ₂ is introduced to the inlet of the main body 301 of the temperature control valve 300 ′ through the pipe 110. Some working fluid (Q ₂₁₎ of the flow into the main body 301, the working fluid (Q ₂₎ is filtered through a screen 301 sheet 303 is stored in the lower atmosphere, and the remaining working fluid (Q ₂₂₎ is a passage ( It is filtered by pilot screen 314 along 316 and then stands by.

Whether or not the solenoid valve 311 in the temperature control valve 300 'is opened or closed is detected by the temperature sensing unit 323 in the temperature of the heating element in the storage tank 120 and the resultant value is stored in the temperature controller 320. It is determined by comparing with the set temperature. When the temperature of the heating element is lower than the set temperature, the conventional temperature control valve 300 'is operated. Specifically, the solenoid valve 311 of the temperature control valve 300' is driven to open the flow path 312. As a result, the atmospheric working fluid Q ₁₂₂ flows to the upper portion of the piston 309, and the piston 309 receives an external force (downward force) to press the disk 304 downward.

As the disk 304 is pressurized, the working fluid Q ₂₁ waiting at the bottom of the seat 303 is discharged through the open upper surface of the seat to the outlet of the temperature control valve 300 ′. The discharged working fluid Q ₂₃ may include a working fluid Q ₂₁ flowing from the bottom of the seat 303 and a working fluid Q ₂₂ flowing through the speed valve 315.

As such, the conventional temperature control valve 300 ′ is operated by an electric temperature controller 320 connected to an external power source and a solenoid valve 311 connected thereto. The flow of the working fluid through the temperature control valve is determined according to whether the solenoid valve 311 is driven, and whether the solenoid valve 311 is driven is a temperature (sensing temperature) and a temperature controller (detected temperature) from the heating element in the storage tank. After comparing the preset temperature (set temperature) in 320, it is installed to be driven when the detected temperature is lower than the set temperature.

However, in the structure having the above-described configuration, since the pressure reducing valve 200 'for reducing the working fluid and the temperature control valve 300' for controlling the supply of the working fluid are separately installed according to the temperature of the water to be heated. Not only did the installation work take a lot of time, but the replacement was not easy.

The present invention has been made to solve the above-mentioned problems of the prior art, an object of the present invention is a temperature control valve and a working fluid for controlling the supply of the working fluid according to the temperature of the water (heated body) stored in the storage tank It is to provide a pressure reducing temperature control valve that is easy to install or replace by forming a pressure reducing valve to control the pressure of the unit integrally.

In order to achieve the above object of the present invention, the present invention is to reduce the pressure of the working fluid introduced from the outside to a predetermined pressure to reduce the pressure control unit for discharged to the storage tank is stored, and the front and rear of the pilot screen of the pressure control unit It is connected to and provides a pressure-reducing temperature control valve comprising a temperature control unit for sensing the temperature of the heating element and for controlling the supply of the working fluid to the pilot screen according to the detected temperature.

The pressure reducing temperature control valve of the present invention may be an electric temperature control unit, and the heating body may be water, oil or air.

In addition, the temperature control unit may be detachably connected to the pressure reduction control unit.

It is a feature of the present invention to provide a pressure reducing temperature control valve in which a conventional pressure reducing valve and a temperature control valve are integrally combined. Decompression temperature control valve according to the present invention is provided as a single unit in which the pressure reduction control unit and the temperature control unit is combined, it is characterized in that the temperature control unit functions as a means for operating the pressure reduction control unit. To this end, the inlet and outlet of the temperature control unit of the present invention is presented a structure connected to a specific position (eg, the flow path before and after the pilot screen of the pressure reduction control unit). Specifically, when the temperature control unit detects that the temperature of the heated object such as water in the storage tank is lower than a predetermined set temperature, the working fluid is transferred to the decompression control unit through the temperature control unit so that the pressure reducing unit operates at a high pressure. The working fluid can be discharged to the pipe connected to the storage tank while reducing the pressure.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the pressure reducing temperature control valve according to a preferred embodiment of the present invention. For reference, the same reference numerals are used for the same components as compared with the conventional structure, and some of the details are omitted.

1 is a schematic cross-sectional view showing the main portion of the pressure reducing temperature control valve 100 according to the present invention, Figure 2 is a view showing an example in which the pressure reducing temperature control valve according to the present invention is applied.

Decompression temperature control valve 100 according to the present invention detects the pressure of the pressure reducing unit 200 and the heating element to control the pressure of the working fluid to a predetermined pressure to adjust the supply of the working fluid in accordance with the detected temperature It is configured to include a temperature control unit (300).

Decompression control unit 200 of the present invention is connected to the pipe 110 as in the prior art, has a main body 201 through which the operating fluid (Q ₁ ) is introduced, stored and discharged, the inner central lower portion of the main body 201 Screen 202 is provided.

The screen 202 is provided with a sheet 203 through which a portion of the upper surface is opened to allow the working fluid Q ₁₁ to flow, and a disk 204 is provided inside the sheet 203. In addition, the lower end of the disk 204 is provided with a spring 205 to elastically support the disk 204, the spring 205 is supported by the bottom flange 206 coupled to the lower end of the main body 201. The bottom flange 206 is provided with a drain plug 207 to discharge the working fluid in the body 201 to the outside.

In addition, a cylinder 208 is provided on the inner central upper portion of the main body 201, and a piston 209 for pressing the disk 204 downward by applying an external force (downward force) according to the situation in the cylinder 208 is provided. Is mounted.

The housing 210 is mounted on the upper surface of the main body 201.

The upper surface of the housing 210 is provided with a pressure adjusting bolt 211 is wrapped in a cap 212, the bottom of the pressure adjusting bolt 211 is provided with a spring 213.

In addition, the inner center of the housing 210 is provided with a diaphragm 214 to be in close contact with the spring 213, a pilot disk chamber consisting of a pilot stem 215 and a pilot ball disk 216 under the diaphragm 214 217 is provided, wherein the pilot ball disk 216 is elastically supported by the spring 218.

In addition, a pilot screen 219 is provided at the inner left side of the housing 210 to filter the working fluid Q ₁₃ introduced through the flow path 220 and the temperature control part 300 formed in the main body 201, The filtered working fluid Q ₁₃ is stored in the open pilot disk chamber 217 and then flows into the upper portion of the piston 209 through the flow path 222.

For reference, the flow path 222 connecting the pilot disk chamber 217 and the piston 209 may be disposed at the rear surface of the spring 218 (see FIG. 1). In this embodiment, as shown in FIG. 1, For convenience of description, it is shown as the side of the spring 218.

In addition, the inside of the main body 201 on which the working fluid Q ₁₁ is discharged and the inside of the housing 210 are connected by a flow path 221 so that the working fluid Q ₁₁ may flow toward the diaphragm 214. Can be.

Next, the temperature control unit 300 of the present invention is basically the same as the structure of the conventional temperature control valve 300 '(see FIG. 5), the conventional inlet / outlet that was connected to the pipe 110 in the present invention The point connected to the depressurization control unit 200 is different. In other words, the temperature control unit 300 of the present invention is connected to the flow path 220 and the pilot screen 219 of the pressure reduction control unit 200 via the outer tube (300a) through the body of the pressure reduction control unit 201 and It is coupled to the housing 210 from the outside.

In addition, the present invention corresponds to the working fluid represented by Q ₂ to the working fluid represented by Q ₁₂ and the exhaust fluid represented by Q ₂₃ to the working fluid represented by Q ₁₃ . The principle may be described, and thus details of the structure of the temperature control unit 300 will be omitted.

2 shows an example in which the pressure-reducing temperature control valve 100 having the above-described configuration is applied according to the present invention.

According to Figure 2, the pressure reducing valve 100 according to the present invention is installed at a predetermined position of the pipe 110, the working fluid is supplied in the direction of the arrow, the storage tank 120 is connected to the pipe 110 After sensing the temperature of the object to be heated, such as water stored in it, and maintaining the temperature of the object to be heated (for example, the temperature inside the storage tank) at a predetermined value based on the result, a high temperature and high pressure working fluid It may be provided to supply to the storage tank by adjusting the pressure to below the pressure of.

Next, the operating principle of the pressure-reducing temperature control valve 100 according to the present invention with reference to the flow path of the working fluid as follows.

According to the present invention, the working fluid Q ₁ is introduced into the main body 201 inlet of the depressurization control unit 200 of the depressurization temperature control valve 100 and some working fluid Q ₁₁ is filtered through the screen 202. It is stored below the sheet 203 and waits. The remaining working fluid (Q ₁₂ ) is introduced into the temperature control unit 300 through the outer tube (300a) along the flow path 220, the temperature of the heating element in the storage tank 120 in the temperature control unit 300 and After comparing with the set temperature in the temperature controller, the temperature control unit is selectively operated according to the resultant value so that the working fluid Q ₁₃ is discharged to the outlet side of the temperature control unit 300. The discharged working fluid Q ₁₃ flows back into the pilot screen 219 of the depressurization control unit 200, is filtered, and then flows into the pilot disc chamber 217 and is stored and waits. Since the pilot disc chamber 217 is open in the range (pressure) set by the pressure adjusting bolt 211, the working fluid Q ₁₃ flows upward through the flow path 222 to the piston 209. Accordingly, the piston 209 receives the external force (downward force) and presses the disk 204 downward.

As the disk 204 is pressurized, the working fluid Q ₁₁ waiting at the bottom of the seat 203 flows through the open upper surface of the seat 203 and is discharged to an outlet connected to the pipe 110. At this time, since the high-pressure working fluid Q ₁₁ is discharged to the outlet, the pressure at the outlet side of the depressurization control unit 200 is increased, and this rising pressure is diaphragm 214 through the flow path 221 of the depressurization control unit. To the upper side by pressing the spring 213 under the pressure adjusting bolt 211 upward, thereby raising the pilot ball disk 216, thereby closing the pilot disk chamber 217, and the bottom flange ( The disk 204 is urged upward by the elastic force of the spring 205 supported by 206 to block the open top portion of the seat 203, thereby stopping the flow of the working fluid Q ₁₁ . Thereafter, as the working fluid is discharged through the outlet, the pressure at the outlet side is lowered again, and thus, the pilot disk chamber 217 is opened in the range set by the pressure adjusting bolt 211 to operate the working fluid Q ₁₁ . As a series of operations are repeated, such as being supplied again, the working fluid Q ₁₁ may be decompressed to a predetermined pressure or lower and supplied to the storage tank 120 through the pipe 110.

The pressure reduction control unit 200 of the present invention can adjust the pressure reduction range of the working fluid by adjusting the pressure adjusting bolt 211, for example, locking the pressure adjusting bolt 211 clockwise or releasing it counterclockwise. The decompression range can be adjusted by working.

In addition, the temperature control unit 300 of the present invention is characterized by being operated by an electric temperature controller 320 (see FIG. 5) and a solenoid valve 311 (see FIG. 5) connected thereto. The flow of the working fluid through the temperature control unit is determined according to whether the solenoid valve 311 is driven, and whether or not the solenoid valve 311 is driven is a temperature (sensing temperature) and a temperature controller 320 detected from the heating element in the storage tank. After comparing the preset temperature (set temperature) within), it is installed to be driven when the detected temperature is lower than the set temperature.

The temperature control unit 300 is detachably attached to the pressure reduction control unit 200, the inlet / outlet of the temperature control unit by engaging the front and rear of the pilot screen of the flow path of the working fluid in the pressure reduction unit (the temperature control unit ( Whether or not the operation of 300 is configured to force the operation of the depressurization control unit 200.

As described above, the pressure reducing valve according to the present invention is to reduce the high-pressure working fluid to a predetermined pressure or less when the temperature of the heating element (eg, water) in the storage tank is sensed below a predetermined value. Can be supplied to storage tanks. Therefore, the reduced pressure working fluid is intermittently supplied to the storage tank, whereby the heated object in the storage tank is heated through heat exchange, thereby maintaining the predetermined temperature. At this time, in the pressure-reducing temperature control valve according to the present invention, the temperature control unit acts as a means for controlling the operation of the pressure-reducing control unit.

Such a configuration may be provided in the form of a pressure reducing temperature control valve of a single structure which is integrally formed at the same time while sufficiently performing the functions provided by the pressure reducing control valve and the temperature control valve which are conventionally formed separately. In addition, since it is provided in a single structure it can provide a convenient operation in installation and replacement thereof.

As described above, the pressure reducing valve of the present invention has been described with reference to the preferred embodiment of the present invention, but it is apparent to those skilled in the art that modifications, changes, and various modifications can be made without departing from the spirit of the present invention.

According to the pressure reducing temperature control valve of the present invention, since the pressure reducing part for depressurizing the high-pressure working fluid and the temperature control part for controlling the supply of the working fluid according to the temperature of the heating body are provided together, the installation is easy and breakdown. It is easy to replace the lamp in case of occurrence.

1 is a schematic cross-sectional view showing the main portion of the pressure reducing temperature control valve according to the present invention;

Figure 2 is a view showing an example in which the pressure reducing temperature control valve of Figure 1 is applied;

Figure 3 is a simplified view showing a conventional structure for supplying a working fluid to the storage tank;

4 is a schematic cross-sectional view showing the main portion of a conventional pressure reducing control valve; And

5 is a schematic cross-sectional view showing the main portion of a conventional temperature control valve.

<Explanation of symbols for main parts of drawing>

100: decompression temperature control valve 200: decompression control unit

200 ': pressure reducing valve 300: temperature control part

300 ': temperature control valve 201, 301: main body

202, 302: screen 203, 303: sheet

204, 304: Disc 205, 305: Spring

206, 306: Bottom flange 207, 307: Drain plug

208, 308: Cylinder 209, 309: Piston

210: housing 211: pressure adjusting bolt

212: cap 213: spring

214: diaphragm 215: pilot system

216: pilot disc 217: pilot disc chamber

218: spring 219, 314: pilot screen

310: outer cover 311: solenoid valve

313: bypass valve 315: speed valve

320: temperature controller 323: temperature detection unit

329 temperature sensing rod

Claims (3)

Decompression control unit for discharging the working fluid introduced from the outside to a predetermined pressure to discharge to the storage tank in which the heated object is stored; And Decompression temperature is connected to the front and rear of the pilot screen of the depressurization control unit and includes a temperature control unit for sensing the temperature of the heated object and controlling the supply of the working fluid to the pilot screen according to the detected temperature Control valve. The pressure reducing valve according to claim 1, wherein the temperature control part is electric. The pressure reducing valve according to claim 1 or 2, wherein the temperature adjusting part is detachably connected to the pressure reducing part.