KR101368217B1 - An apparatus on the ground for measuring water presure of water pipe - Google Patents

Abstract

The present invention can be installed without installing the pressure sensor for measuring the water pressure in the water supply pipe buried underground and the accompanying device on the shore to be installed on the ground without disturbing the traffic of the vehicle and pedestrians, the water supply pipe and pressure The present invention relates to a water pressure monitoring device installed on the ground which is installed on the ground to prevent freezing without additional heating means by heating the space in which the pressure sensor and the accessory device are housed in geothermal insulation between the sensors.

Description

Water pressure monitoring device installed on the ground {AN APPARATUS ON THE GROUND FOR MEASURING WATER PRESURE OF WATER PIPE}

The present invention can be installed without installing the pressure sensor for measuring the water pressure in the water supply pipe buried underground and the accompanying device on the shore to be installed on the ground without disturbing the traffic of the vehicle and pedestrians, the water supply pipe and pressure The present invention relates to a water pressure monitoring device installed on the ground which is installed on the ground to prevent freezing without additional heating means by heating the space in which the pressure sensor and the accessory device are housed in geothermal insulation between the sensors.

Water supply pipes for water supply are buried underground above the prescribed depth so as not to freeze in winter, and a number of branch points are provided at each necessary place to form branch pipes to supply to each customer.

These water pipes are likely to leak from branch points or connection points between water pipes, or from water breakage due to ground changes. Therefore, water leaks from water pipes are detected early to intensify water quality and ground subsidence. It should be prevented from spreading. As a general countermeasure, measure the water pressure of the water supply through the water pipe.

The installation of a pressure sensor for water pressure is to install a manhole or handhole at the point where the water supply pipe passes, install a pressure sensor in the water supply pipe that passes through the manhole or handhole, and cover the manhole or handhole with a lid. Is done. In addition, the lid is covered because the water supply pipe is buried along the roadway or sidewalk, and a manhole or handhole is also installed in the roadway or sidewalk.

However, the pressure sensor installed in the manner described above should be periodically checked due to water or moisture penetrating into the manhole (or handhole) or due to aging due to prolonged use. This was followed by a difficult checkout process.

Moreover, in rural areas that are out of the city center, water supply facilities are not supplied by the water purification plant. Instead, they are constructed with a water supply system. Since the water supply lines are laid along narrow alleys, the construction of manholes is very difficult, In order to check the pressure sensor inside a difficult manhole, it was necessary to completely block alleys.

In addition, since the pressure sensor can be accurately found the leaking point only when installed in various places of the water supply pipe installed as a long branch, it is very difficult to install the manhole at each installation point of the pressure sensor, but the installation conditions are very difficult.

In addition, even if the manhole is buried and covered with a lid, there is a risk of freezing. Therefore, it is difficult to insulate the entire manhole with such insulation. Instead, it is used to wrap the exposed water pipe and pressure sensor. do. However, it is very cumbersome to insulate with such insulation and does not prevent freezing.

On the other hand, in order to collect the measured value of the pressure sensor installed in many places, since the measured value of the pressure sensor must be transmitted to the remote monitoring center, it is also necessary to facilitate the connection of the communication device and power supply device for this.

KR 10-2002-0045430 A 2002.06.19. KR 10-0945296 B1 2010.02.24.

Accordingly, an object of the present invention is to install a pressure sensor on the ground so that it can be checked at any time without disturbing the traffic of vehicles or pedestrians, water pressure pipe installed on the ground to overcome the limitations of thermal insulation by insulation to prevent freezing It is to provide a monitoring device.

In order to achieve the above object, the present invention is connected to the detection pipe line 52 branched from the water supply pipe 50 buried underground, the air valve (2), the detection pipe (installed at the end of the detection pipe line 52) In the water supply pipe hydraulic pressure monitoring device having a pressure sensor (1) and a valve (3) installed in the middle of the 52, and transmits the water pressure value measured by the pressure sensor (1) to a remote monitoring center, the inspection opening (12) It is provided with a built-in space (11) having a lower portion to be insulated, and is built on the ground, extending the detection pipe 52 to the built-in space 11 to the air valve (2), pressure sensor (1) and A pillar 10 accommodating the valve 3 in the built-in space 11; It is embedded to surround the detection pipe (52) but continues to the interior of the interior space (11), wrap the heat insulating material (21, 22) and the heat insulating material (21, 22) surrounding the detection pipe 52, the heat insulating material (21, 22) It is composed of a protective tube 23 having an inner diameter larger than the outer diameter of, the thermal insulation means for allowing the geothermal heat to be transmitted to the interior space 11 through the internal air layer 24 between the insulating material (21, 22) and the protective tube (23) 20); A power generation module 30 installed at an upper end of the support 10 to generate power using solar or wind power; A control panel 40 which is fixed to the support 10 and operates with electricity generated by the power generation module 30, and collects the water pressure value detected by the pressure sensor 1 and transmits it to a remote monitoring center; .

The control panel 40, the data logger 41 for collecting the hydraulic pressure value detected by the pressure sensor (1); A battery 43 in which electricity is charged; A charge control device 42 for charging the electricity generated in the power generation module 30 with the battery 23; A transmitter 44 for wirelessly transmitting a hydraulic pressure value; Characterized in that configured to include.

The protective tube 23 of the thermal insulation means 20 is characterized in that the buried portion vertically buried underground.

The present invention constituted as described above, since the pressure sensor and the attachment to be installed in the detection pipe branched from the water supply pipe is built into the support poles installed on the ground, it can be installed without the construction of the manhole or handhole, and does not interfere with the passage You can check the building at any time without limiting the traffic of pedestrians or pedestrians by installing props in the branches, and there is no fear of freezing by transferring geothermal heat to the space where pressure sensors and accessories are installed.

1 is a perspective view of a water pipe pressure monitoring device installed on the ground according to an embodiment of the present invention.
Figure 2 is a sectional view of the installation of the water pressure monitoring device for water pipes installed on the ground according to an embodiment of the present invention.

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

1 is a perspective view of a water pipe pressure monitoring device installed on the ground according to an embodiment of the present invention, Figure 2 is a cross-sectional view of the installation of the water pressure pipe pressure monitoring device installed on the ground according to an embodiment of the present invention.

1 and 2, the water supply pipe pressure monitoring device according to an embodiment of the present invention measures the water pressure value of the constant supplied through the water supply pipe 50, and the measured water pressure value of the remote monitoring center (100) ), Which is not directly installed in the water supply pipe 50 embedded underground, but is installed on the ground surface of the roadside or the edge of the sidewalk, and which is described later, the detection pipe 52 branching from the underground water supply pipe 50. It extends to the interior space 11 of the components for measuring the water pressure is installed in the interior space 11 to be described later.

The present invention for this purpose is a support (10) built on the ground, the thermal insulation means 20 of the hollow tube shape embedded in the basement, the pressure sensor (1) and accessories attached to the support (10), support (10) It is configured to include a power generation module 30 is installed on the top of, and the control panel 40 is installed on the outer peripheral surface of the support (10).

Specifically, the support 10 has a built-in space 11 for installing the pressure sensor 1 and the accessory at the bottom, the thermal insulation means 20 is buried underground the built-in space 11 It is erected perpendicular to the ground to extend to In addition, the lower structure provided with the internal space 11 is provided with a check opening (12) that can be opened and closed, and installs and checks the pressure sensor (1) and the accessory through the check opening (12). In addition, the inner surface constituting the interior space 11 is an inner surface including the inner surface of the inspection opening 12 by attaching the heat insulating material 13 and insulated, thereby penetrating the insulation means 20 to the interior space 11. Even if the pressure sensor 1 and the accessory are installed at the end of the detection pipe 52 introduced into the chamber, the freezing of the pressure sensor 1 and the accessory is prevented.

The insulating means 20 is connected to the water supply pipe 50 embedded in the basement is a component surrounding the detection pipe line 52 extending to the interior space 11 of the support 10, the detection pipe line 52 Instead of wrapping the whole section of the inside of the interior space (11), starting from the inside only a section to reach a predetermined depth is wrapped.

In addition, the thermal insulation means 20 is insulated with heat insulating material, and also serves to transfer geothermal heat to the interior space 11 of the support 10. The insulation means 20 for this purpose is configured to include a heat insulating material (21, 22) surrounding the detection pipe 52, and a protective tube 23 surrounding the outside of the heat insulating material (21, 22). Here, the heat insulating material (21, 22) is not a single heat insulating material, but as shown in the figure double insulation, that is, the inner heat insulating material 21 and the outer peripheral surface of the internal heat insulating material 21 surrounding the outer peripheral surface of the detection pipe 52 It is preferable that the outer heat insulating material 22 wraps.

In addition, the inner diameter of the protective tube 23 is formed larger than the outer diameter of the insulating material (21, 22) surrounding the outside of the detection pipe 52, the inner air layer 24 between the protective tube 24 and the insulating material (21, 22) ) Is formed.

The internal air layer 24 formed as described above has a top and bottom open state so that geothermal heat of underground soil is transmitted to the air of the internal air layer 24 through the opening at the bottom thereof, and the geothermal heat transferred to the air passes through the top of the support ( It is delivered to the interior space 11 of 10).

In general, the basement at a suitable depth maintains a temperature within a certain range in all seasons, even if the air temperature changes, for example, at a temperature of 14 ° C. to 16 ° C. at a 6 m underground. However, the water pipe pressure monitoring device according to the present invention does not need to use the above-described underground temperature, but is satisfied if it is enough to prevent freezing in the built-in space 11 of the support 10 installed on the ground surface. It is not necessary to manufacture and embed the thermal insulation means 20 to reach 6m underground. Furthermore, according to the embodiment of the present invention, the detection pipe 52 must be inserted through the lower opening of the heat insulating means 20. If the heat insulating means 20 is made too long and embedded deeply, it is difficult to construct it. Therefore, the thermal insulation means 20 may vary depending on the region, but considering the freezing prevention and construction convenience, it is determined that it is appropriate to make it 1m long and bury it vertically and bury it underground.

On the other hand, in order to prevent falling or tilting when the support 10 is set on the ground surface, when the foundation concrete is embedded at the point where the support 10 is to be mounted and the support 10 is fixed to the foundation concrete, the detection pipe ( 52) may be installed to bend at a portion penetrating the base concrete for the convenience of construction. In this case, the detection pipe 52 is preferably buried vertically underground after passing the foundation concrete. In addition, the support 10 is preferably formed of a stainless material excellent in corrosion resistance.

The detection pipe line 52 is a hollow pipe connected to one end in communication with the underground water pipe 50 so that the constant of the water pipe 50 is filled in the hollow inside, and the other end is embedded in the support 10. Since the space 11 is reached, the water pressure of the constant can be measured by the pressure sensor 1 installed in the built-in space 11. Here, the detection pipe line 52 is installed in such a way that one end is connected to the branch pipe branched by the water fountain 51 after the water fountain 51 is installed in the water pipe 50. Fractional field 51 is to branch the water pipe 50 in the middle to flow the constant to the branched branch pipe, generally using a saddle fountain with a bird for wrapping the water pipe 50.

Meanwhile, although the manhole or the handhole may be installed in the water supply pipe section 50 branched by the fountain 51, the fountain 51 may be inspected, but the fountain 51 is not necessary. ), It is not necessary to install manholes or handholes. However, according to the prior art, since the pressure sensor (1) and the accessory is installed in the fountain 51, the installation space of the pressure sensor (1) and the accessory is necessary, and the maintenance for maintenance also requires a manhole or Hand holes must be constructed. In other words, according to the present invention, since the pressure sensor 1 and the accessory are installed on the support 10 which stands on the ground, the manhole or the handhole is not installed for the purpose of installing and checking the pressure sensor 1 and the accessory. You do not have to.

The pressure sensor 1 and the accessory device are accommodated in the interior space 11 of the support 10 and installed in the detection conduit 52. The pressure sensor 1 is installed in the middle of the detection pipe 52 protruding into the built-in space 11, and measures the pressure of the constant filled in the detection pipe (52). In addition, the accessory consists of an air valve 2 and a valve 3 according to an embodiment of the present invention as an additionally installed component.

Here, the air stool 2 is installed at the end of the detection pipe 52 to collect and discharge the bubbles generated by the constant. Bubbles are generated due to vortices, refractions, or diffraction when water flows through the interior of the water supply pipe 50 and gathers to a high place due to the difference in specific gravity, so that the air valve 2 is formed through the detection pipe 52. Is collected and discharged.

The valve (3) is a component provided to block the constant when installing, replacing or checking the pressure sensor (1) or the air valve (2), the lower side than the pressure sensor (1) and air valve (2) Is installed on.

The power generation module 30 is installed on the top of the support 10 to generate power, but in the drawing is shown as a solar cell module for generating electricity by receiving sunlight, it may be configured as a wind power generator for generating electricity with wind power Alternatively, the solar cell module and the wind generator may be configured in parallel in a circuit. On the other hand, since the power generation module 30 should be constructed in the direction of receiving as much sunlight as possible when adopting a solar cell module, the bracket for fixing the power generation module 30 to the upper end of the support (10) by rotating It is preferable to be easy to install in the support | pillar 10. In addition, the power generation module 30 is preferably rotated according to the wind direction when adopting a wind power generator.

The control panel 40 is fixed to the midway of the support (10) collects the water pressure value measured by the pressure sensor 1 and transmits to the remote monitoring center 100, the measurement of the water pressure value, the collection of water pressure value In addition, electricity required for an operation such as data transmission is covered by electricity generated by the power generation module 30. To this end, the control panel 40, a data logger 41 for receiving and collecting the hydraulic pressure value measured by the pressure sensor 1, a battery 43 provided to charge the electricity, the power generation module ( Charge control device 42 and the data logger 41 that charges the electricity generated in the 30 to the battery 43 and supplies to the data logger 41, the pressure sensor 1 and the transmitter 44 And a transmitter 44 for wirelessly transmitting hydraulic pressure data. In this case, the transmitter 44 and the remote monitoring center 100 may be connected to each other by a communication line to transmit data through wired communication. However, since wiring of the communication line is difficult, it is preferable to transmit data by wireless communication.

Here, an error occurs between the water pressure at the water fountain 51 and the water pressure measured by the actual pressure sensor 10 due to the height difference between the pressure sensor 10 and the water fountain 51, so that the data logger ( 41) it is preferable to correct the hydraulic pressure value measured by the pressure sensor 10 by the error due to the height difference.

In addition, since the natural discharge occurs at a low temperature in the battery 43, it is preferable that the inner surface of the control panel 40 attaches the heat insulating material 13 to insulate the internal space in which the battery 43 is installed.

The present invention configured as described above is to install a pressure sensor (1) and accessories (2, 3) for measuring the water pressure of the constant flowing through the water pipe 50 in the water pipe 50 is buried underground Rather, since the support 10 is provided on the ground surface, the support 10 is installed at a place that does not interfere with the passage of vehicles or pedestrians at the roadside or sidewalk, so that the manager is not bound by the vehicle or pedestrian. You can check and repair at any time.

In addition, according to the present invention, when embedding the detection conduit 52 between the water supply pipe 50 and the support 10, the surface close to the support 10 is maintained by the thermal insulation means 20, the surface of the ground which is greatly affected by the atmospheric temperature It prevents freezing by heat insulation without losing heat, and also transmits geothermal heat to the internal space 11 of the support 10 to compensate for insufficient heat insulation effect of the thermal insulation materials 21 and 22, and internal space. Geothermal heat is also transmitted to (11) to prevent freezing of the pressure sensor (1) and accessories (2, 3) installed in the interior space (11).

On the other hand, since the thermal insulation means 20 deprives heat from the ground surface close to the lower end of the support 10, it is preferable to wrap the outer peripheral surface of the portion passing through the ground surface with a heat insulating material except for the lower portion.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, . ≪ / RTI > Accordingly, such modifications are deemed to be within the scope of the present invention, and the scope of the present invention should be determined by the following claims.

1: pressure sensor 2: air valve 3: valve
10: prop 11: interior space 12: inspection opening
13: insulation
20: insulation means 21: internal insulation 22: external insulation
23: protective tube 24: internal air layer
30: power generation module
40: control panel 41: data logger 42: charge control device
43: battery 44: transmitter 45: insulation
50: water supply pipe 51: before the fountain 52: detection pipe
100: monitoring center

Claims (3)

delete delete Connected to the detection pipe line 52 branched from the water supply pipe 50 buried underground, the air sensor 2 is installed at the end of the detection pipe line 52, the pressure sensor is installed in the middle of the detection pipe line ( 1) and a valve (3), the water supply pressure monitoring device for transmitting the water pressure value measured by the pressure sensor (1) to a remote monitoring center,
A built-in space 11 having a check hole 12 is provided on the lower portion to be insulated, and stands on the ground, and extends the detection pipe 52 to the built-in space 11 so that the air valve 2 and the pressure sensor (1) and the support (10) accommodating the valve (3) in the interior space (11);
It is embedded to surround the detection pipe (52) but continues to the interior of the interior space (11), wrap the heat insulating material (21, 22) and the heat insulating material (21, 22) surrounding the detection pipe 52, the heat insulating material (21, 22) It is composed of a protective tube 23 having an inner diameter larger than the outer diameter of, the thermal insulation means for allowing the geothermal heat to be transmitted to the interior space 11 through the internal air layer 24 between the insulating material (21, 22) and the protective tube (23) 20);
A power generation module 30 installed at an upper end of the support 10 to generate power using solar or wind power;
A control panel 40 which is fixed to the support 10 and operates with electricity generated by the power generation module 30, and collects a hydraulic pressure value detected by the pressure sensor 1 and transmits the pressure value to a remote monitoring center;
≪ / RTI >
The control panel 40,
A data logger 41 for collecting a hydraulic pressure value detected by the pressure sensor 1;
A battery 43 in which electricity is charged;
A charge control device 42 for charging the electricity generated in the power generation module 30 with the battery 23;
A transmitter 44 for wirelessly transmitting a hydraulic pressure value;
And,
The protective pipe 23 of the thermal insulation means 20, the water pipe pressure monitoring device, characterized in that the buried portion vertically buried underground.

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