KR20110060228A - Water supply system using pressure controlling tank in hilly areas - Google Patents

Abstract

In the present invention, the water source discharged from the water structure is returned to a pressure control tank installed at predetermined intervals of the supply pipe, and then temporarily stored and discharged back to the lower portion so that the pressure of the supply pipe according to the altitude difference can be adjusted. High-altitude water supply system using a pressure control tank that not only eliminates the need but also prevents damage to the supply pipe, resulting in a safer water supply system.

Pressure Control Tank, Reservoir, Highlands, Lowlands, Water Pressure

Description

High-altitude water supply system using pressure control tank {WATER SUPPLY SYSTEM USING PRESSURE CONTROLLING TANK IN HILLY AREAS}

The present invention relates to a high-altitude constant water supply system using a pressure control tank for supplying water to low-lying houses through a supply pipe from the high-altitude reservoir in the mountainous region.

In general, the mountainous areas of highlands are difficult to install the water supply structure and supply pipes for the supply of water supply is not smooth drinking water supply.

In particular, the reservoirs installed in the highlands of the mountainous areas are collected and purified as rainwater and discharged whenever necessary and supplied to the houses. For this purpose, the supply pipe is connected from the reservoirs of the highlands to the lowland houses. .

At this time, when the monasteries of the reservoirs are discharged, the monasteries descend to the low-water houses along the supply pipes. Frequently it is not able to burst.

In practice, the water pressure of the water pipe is preferably 1.5 kg per unit area of 1 square meter, but in the high water supply system of such a structure, if the altitude difference is 500 m from the low water structure to the low water supply pipe, the water pressure theoretically increases to 50 kg per unit area of 1 square meter. do.

In order to solve this problem, a pressure reducing valve is installed at predetermined intervals of the supply pipe, and when the altitude difference is large, the pressure of the water pressure is controlled by reducing the altitude difference by blocking the supply pipe from the intermediate pressure reducing valve.

However, such a pressure reducing valve is expensive and the breakage or failure often occurs, the actual utility is in reality is inferior.

An object of the present invention for solving the above problems, high-altitude constant water supply system using a pressure control tank to install a pressure control tank to be connected in a branched form at predetermined intervals to supply the water supply temporarily discharged from the reservoir structure. To provide.

In addition, an object of the present invention is to supply the high-altitude constant water using the pressure control tank to be connected to the inlet pipe and the outlet pipe so that the water supply flowing along the supply pipe is stored in the pressure control tank and discharged again. To provide a system.

In addition, another object of the present invention, by installing the opening and closing valve in the inlet and outlet pipes and supply pipes of the pressure control tank, respectively, to control the on-off valves of the corresponding section according to the water pressure of the supply pipe according to the altitude difference, temporarily in the pressure regulation tank of the corresponding section This is to provide a high-altitude constant water supply system using a pressure control tank for storing.

In addition, another object of the present invention, the pressure control tank level of each section in the control room and the pressure to receive information in real time about the water pressure status measured in the supply pipe in real time pressure to enable the wireless control of the valve in the appropriate supply pipe section To provide a high-altitude constant water supply system using a control tank.

The object of the present invention according to the problem to be solved above, is connected to the tube-to-pipe to move the water source collected in the reservoir structure of the highland to the water supply pipe of the lowland, passing through to block the flow of the water source A supply pipe for installing valves at predetermined altitude intervals; It is installed in each of the sections of the supply pipe to lower the water pressure of the water supply flowing down the supply pipe, the water supply flows back to the inlet pipe is stored as the passage valve is closed, and the stored water source is back along the supply pipe through the water supply pipe It is achieved by a high-altitude constant water supply system using a pressure regulating tank, characterized in that it consists of a plurality of pressure regulating tanks having inlet and outlet valves in the inlet and outlet pipes, respectively.

In addition, according to the present invention, it is preferable that one pressure control tank is installed at an altitude of 100 m.

In addition, according to the invention, the pressure sensor is installed in each of the predetermined intervals to measure the water pressure inside the supply pipe; It is preferable to include a wireless unit for wirelessly transmitting the pressure signal measured by the pressure sensor.

In addition, according to the present invention, the water storage structure and the pressure control tank, the water level sensor for sensing the level of the stored water source; Preferably, the water level sensor comprises a wireless unit for transmitting the water level signal wirelessly.

In addition, according to the present invention, the passage valve, the inlet valve, the outlet valve is provided with a wireless unit, respectively, it is preferable to receive the opening and closing command signal through the wireless unit to operate accordingly.

According to the present invention, the water level sensing signal is wirelessly received from the water storage structure and the plurality of pressure regulating tanks, and the water supply structure opening / closing valve control signal is discharged along the supply pipe so that the water supply of the water storage structure flows according to the received water level sensing signal. When the water pressure signal transmitted wirelessly from the pressure sensor exceeds the standard water pressure, the water supply flows back to the upper pressure control tank of the corresponding section and is stored and discharged back to the supply pipe. It is preferable to further include a control room for transmitting the control signal of the water outlet valve and the passage valve to each valve radio unit.

The high-altitude constant water supply system using the pressure regulating tank of the present invention by the above-mentioned problem solving means is to return the water source discharged from the water structure to the pressure regulating tank installed at predetermined intervals of the supply pipe to temporarily store and discharge the water back to the bottom. Since it is possible to adjust the water pressure of the supply pipe according to the altitude difference, not only does not need to use an expensive pressure reducing valve, it is possible to prevent damage to the supply pipe to build a safe water supply system.

In addition, the high-altitude constant water supply system using the pressure control tank of the present invention is to monitor the water pressure of the supply pipe and the water level of the pressure control tank in real time, and accordingly according to the automation of the water supply system by wireless control of the opening and closing valve to allow the water source to flow in the appropriate section Can be implemented.

Hereinafter, an embodiment of the high-altitude constant water supply system using the pressure regulation tank of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing the overall configuration of the high-altitude constant water supply system using the pressure control tank of the present invention, Figure 2 is a diagram showing the configuration for automatic control of the opening and closing valve through the wireless data processing of the control room.

As shown in the figure, the present invention is composed of the reservoir structure 100, the pressure control tank 200, the supply pipe 300, the control room 400.

The water storage structure 100 is a storage tank installed in highlands such as a mountainous region, and collects rainwater, etc. to be purified and then discharged through a supply pipe.

To this end, the water storage structure 100 is installed in a buried or semi-buried type, the bottom or bottom is connected to the supply pipe.

The water storage structure 100 is attached to the water level sensor 120 at regular intervals along the height direction of the inner wall, to inform the state of the internal water level, and to generate the water level detection signal generated by the water level sensor 120 Reservoir wireless unit 110 is connected to the water level detection sensor to be delivered to the control room to be described in is installed on the top of the reservoir structure (100).

The supply pipe 300 is also installed in a buried or semi-embedded type, the tube-to-pipe is tightly connected to transport the water source from one end of the reservoir structure 100 to the pressure control tank 200 of the other end.

In addition, the supply pipe 300 may be installed to be bent according to the topographical characteristics of the mountainous region, it is preferable that the supply pipe 300 is closely connected to the straight in view of the pressure received.

In addition, the supply pipe 300 is connected to each other through the pressure control tank and the inlet pipe 202 and the outlet pipe 204 is installed at a predetermined altitude.

That is, one side of the inlet pipe 202 and the outlet pipe 204 is tightly connected to the side of the supply pipe 300, the water supply flowing through the supply pipe 300 is returned to the inlet pipe 202 pressure The water supply that is transported to the control tank 200 and transported to the pressure control tank 200 flows back to the supply pipe 300 through the water outlet pipe 204.

The supply pipe 300 has a pressure sensor installed at predetermined intervals in the longitudinal direction of the pipe to measure the water pressure inside the pipe in real time, and wirelessly transmits the water pressure information measured through the wireless unit attached to one side of the pressure sensor to the control room. Be sure to

As a result, in the section where the water pressure is higher than the reference pressure, the passage valve 301 is blocked so that the water source flows back to the pressure control tank 200 just below it.

The passage valve 301 is an on-off valve installed to block the flow of the water supply of the supply pipe 300 between the inlet pipe 202 and the outlet pipe 204, the water source by blocking the passage valve 301 It is returned to the water inlet pipe 202 and stored in the pressure control tank 200 and the water supply is no longer increased because the water supply source does not flow through the supply pipe to the lower portion of the passage valve 301.

The through valve 301 is provided with a wireless unit, and receives the opening and closing command of the control material through the wireless unit is automatically operated accordingly.

The pressure control tank 200 connected to the other end of the water inlet pipe 202 and the water outlet pipe 204 is installed at a predetermined altitude interval, preferably one is installed every 100m altitude.

The pressure regulation tank 200 is connected to the distribution pipe 205 which is connected to the water supply pipe of the houses to supply the water supply to the neighboring houses.

Like the water storage structure 100, the pressure control tank 200 is also provided with a water level control sensor and a pressure tank wireless unit, it detects the water level of the pressure control tank 200 and transmits it to the control room wirelessly.

The inlet pipe 202 is a pipe connected between the supply pipe 300 and the pressure control tank 200, receives a water supply flowing along the supply pipe 300 and delivers it to the pressure control tank 200.

The inlet pipe 202 is provided with an inlet valve 201 at an intermediate point, the valve may be opened to send a water source flowing from the supply pipe 300 to the pressure control tank 200, and shut off the valve to adjust the pressure It is also possible to prevent the supply of water to the tank 200 anymore.

The water intake valve 201 is provided with a wireless part, and receives the open / close command signal from the control room from the wireless part and is automatically opened and closed accordingly.

The outlet pipe 204 is a pipe connected between the supply pipe 300 and the pressure control tank 200, to discharge the water supply stored in the pressure control tank 200 to flow to the supply pipe 300.

The water outlet pipe 204 is provided with a water outlet valve 203 at the intermediate point, the valve may be opened to flow the water source stored in the pressure control tank 200 to the supply pipe 300, or the pressure control tank as it is. It may be blocked so that the water source is stored in (200).

The water outlet valve 203 also includes a wireless unit, and receives an open / close command signal from the control room from the wireless unit and is automatically opened and closed accordingly.

The control room 400 is installed in the lower part of the mountain area where the supply pipe is installed, receives the status signal of the water storage structure 100, the supply pipe 300 and the pressure control tank 200 according to the command to open and close the valve accordingly Pass the signal.

That is, the control room 400 receives the water level detection signal of the water level detection sensor through the water reservoir wireless unit 110 of the water storage structure 100, and the water level through the pressure tank wireless unit 210 of the pressure control tank 200. The water level detection signal of the sensor is received.

In addition, the control room 400 receives the water pressure information of the pressure sensor 320 through the wireless unit of the supply pipe (300).

The control room 400 receives the water level detection signal and the water pressure information so that the water source flows back to the pressure control tank 200 located immediately below when a section exceeding the standard water pressure value occurs in the water pressure state of the supply pipe 300. It generates a command for opening and closing the valve of the supply pipe 300 and the inlet pipe and the outlet pipe and delivers to each valve wireless unit.

When the water level inside the tank of the reservoir 100 is collected and stored as rainwater or groundwater, the water level signal sensed by the water level sensor 120 of the reservoir 100 is stored through the reservoir 110. The control room 400 will be delivered.

Similarly, the water level detection sensor 220 of the pressure control tank 200 also detects the internal water level of the pressure control tank 200 and transmits the detected water level signal to the control room 400 through the pressure tank wireless unit 210. do.

 The control room 400 receives and determines these water level signals, and when the internal water level of the water reservoir 100 is high or the water level of the specific pressure control tank 200 is low, the valve and the pressure of the water structure 100 are low. The valve open signal is transmitted to the valve wireless part of each corresponding valve so as to open the inlet pipe 202 valve of the adjustment tank 200.

When the valve of the water storage structure 100 is opened, the water source collected in the water storage structure 100 flows out through the supply pipe 300, and at this time, a pressure sensor installed at a predetermined interval inside the supply pipe 300. The hydraulic pressure is checked in real time to generate pressure signals for each section, and the wireless unit transmits these pressure signals to the control room 400.

The control room 400 determines the water pressure signal for each section transmitted through the wireless unit, if the water pressure of the corresponding section is higher than the standard water pressure, of the pressure control tank 200 is installed directly above the section where the pressure sensor is attached The inlet valve opening signal is generated to open the inlet valve 201 and transmitted to the inlet valve wireless unit.

At the same time, to generate the passage valve closing signal to close the passage valve of the corresponding section (section receiving the inlet valve open signal) and transmits to the closing valve wireless unit.

Therefore, the inlet valve 201 opens the valve according to the open signal of the wireless part, and the passage valve closes the valve according to the closed signal of the wireless part.

At this time, if the outlet valve of the outlet pipe 204 of the pressure control tank 200 is open, the control room 400 generates the outlet valve closing signal and transmits it to the outlet valve wireless unit.

As a result, the water source flowing along the supply pipe 300 no longer flows by the passage valve 301, but flows into the pressure control tank 200 through the inlet pipe 202 of the corresponding section.

In this state, when the water level of the pressure control tank 200 is increased, the water supply valve 204 is opened to the water supply pipe 202 to enter the water supply at the same time to the water supply pipe 300 through the water supply pipe 204 to go out. You can do it. Only the inlet valve is opened until the water level of the pressure control tank 200 is increased, and when the water level is increased, the inlet valve is closed and only the outlet valve is opened to allow the water supply to flow into the lower portion of the supply pipe 300.

Similarly, when the water supply flows again in the supply pipe 300, the water supply flows back into the pressure control tank 200 in the corresponding section through the pressure check of the pressure sensor as described above, and then discharges again from the pressure control tank 200. Keep the water pressure below the reference value.

1 is an overall configuration diagram of a high-altitude constant water supply system using a pressure control tank of the present invention,

Figure 2 is a block diagram of a high-altitude constant water supply system using a pressure control tank of the present invention.

* Detailed Description of Drawings *

100: reservoir structure 110: reservoir tank

120: water level sensor 200: pressure control tank

201: inlet valve 202: inlet pipe

203: water outlet valve 204: water outlet pipe

205: distribution pipe 206: house water pipe

210: Pressure tank wireless unit 220: Water level sensor

300: supply pipe 301: through valve

310: supply pipe wireless part 320: pressure sensor

400: control room

Claims (6)

A supply pipe connected to a pipe-to-pipe to move the water supply collected in the high-level water storage structure to a low-temperature water supply pipe, and having a passing valve installed at a predetermined altitude interval to block the flow of the water supply; Installed at every predetermined altitude interval of the supply pipe to lower the water pressure of the water supply flowing down the supply pipe, the water supply flows back to the inlet pipe as the passage valve is closed, and the stored water source is supplied again through the water supply pipe. The high-altitude constant water supply system using the pressure control tank, characterized in that it consists of a plurality of pressure control tanks having inlet and outlet valves in the inlet and outlet pipes, respectively. The method of claim 1, The pressure control tank is a high-altitude constant water supply system using a pressure control tank, characterized in that one installed per 100m altitude. The method of claim 1, A pressure sensor installed in each of the predetermined intervals to measure the water pressure inside the supply pipe; High-altitude constant supply system using a pressure control tank, characterized in that it comprises a wireless unit for transmitting the hydraulic pressure signal measured by the pressure sensor wirelessly. The method of claim 1, The reservoir structure and the pressure control tank,  A level sensor for sensing the level of the stored water source; High-altitude constant supply system using a pressure control tank, characterized in that consisting of a wireless unit for transmitting the water level signal of the water level sensor wirelessly. The method of claim 1, The passage valve, the inlet valve, the outlet valve is provided with a wireless portion, respectively, the high-altitude constant water supply system using a pressure control tank, characterized in that receiving the operation command via the wireless unit to operate accordingly. The method of claim 1, Receiving the water level sensing signal wirelessly from the water storage structure and the plurality of pressure control tank, according to the received water level detection signal, the water supply structure opening and closing valve control signal flows to the water storage structure so that the water supply flows along the supply pipe. When the water pressure signal transmitted from the pressure sensor wirelessly exceeds the standard water pressure, the inlet valve, the outlet valve, and the pass valve of the inlet valve and outlet valve can be returned to the upper pressure control tank of the corresponding section so that the water can be stored and discharged back to the supply pipe. A high-altitude constant water supply system using a pressure control tank, characterized in that it further comprises a control room for transmitting a control signal to each valve wireless unit.

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