KR101066427B1 - Apparatus for monitoring heat pipe line - Google Patents

Abstract

The present invention relates to a buried heat pipe monitoring panel having a buried antenna and capable of transmitting and receiving radio waves smoothly in a state buried in the ground surface. A heat pipe monitoring device panel having a supply device, comprising: an outer housing having a lower surface and a side surface embedded in an earth surface and having an open structure in an upward direction; An inner housing detachably installed in the outer housing and having an antenna mounting portion having a concave structure opened upward; A buried antenna installed in the antenna installation unit so as to coincide with the ground surface and connected to the heat pipe monitoring apparatus to transmit radio waves; And a fixed concrete supporting the lower and side surfaces of the outer housing and preventing settlement and fine movement of the housing.

Heat piping, monitoring devices, antennas, embedded

Description

Flush type heat pipe supervision panel {APPARATUS FOR MONITORING HEAT PIPE LINE}

The present invention relates to a buried heat pipe supervision panel, and more particularly, to a buried heat pipe supervisory panel having a buried antenna and capable of smoothly transmitting and receiving radio waves in a state of being buried in an earth surface.

In general, when laying a heat pipe underground to circulate district heating water, it is very difficult to identify the occurrence of water leakage, water penetration, water leakage, location of leakage due to damage of the heat pipe.

Accordingly, in order to be able to effectively and easily detect leaks and damages caused by burnout or aging of the pipe network, a leak detection line is installed in the double insulation tube to detect leaks and water infiltration through the pipe network, and when leak occurs. Use a heat pipe monitoring system that allows the location and leaks to be known.

In such a heat pipe monitoring system, a heat pipe monitoring device is installed at regular intervals in a pipe network of the heat pipe, and the information sent from the plurality of heat pipe monitoring devices is integrated to detect the leakage. Recently, a wireless transmission / reception scheme for transmitting and receiving information sensed by the heat pipe monitoring apparatus to and from the central control station is widely used. In the case of wireless transmission and reception, the heat pipe monitoring panel is installed to be exposed to the ground for smooth transmission and reception of radio waves. The heat pipe monitoring device and the power supply device are installed in the heat pipe monitoring device panel. Therefore, the heat pipe supervision panel should be equipped with a separate wiring network to supply power to the heat pipe monitoring device and the power supply, or a battery should be installed if the wiring network is difficult to install.

However, in the related art, since the heat pipe monitoring panel is installed in a form protruding to the ground, as well as a risk of being damaged by various external forces, there is a problem that may cause an accident and damages the beauty of the city. Therefore, there is a demand for the development of a technology capable of safely and efficiently managing such a heat pipe monitoring panel on the ground.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide a buried heat pipe monitoring panel having a buried antenna, which can smoothly transmit and receive radio waves in a buried state on the ground.

In the buried heat pipe monitoring panel according to the present invention for achieving the above technical problem, in the heat pipe monitoring device panel having a heat pipe monitoring device and a power supply device therein, the bottom and side surfaces are embedded in the ground surface, the upper direction An outer housing having an open structure; An inner housing detachably installed in the outer housing and having an antenna mounting portion having a concave structure opened upward; A buried antenna installed in the antenna installation unit so as to coincide with the ground surface and connected to the heat pipe monitoring apparatus to transmit radio waves; And a fixed concrete supporting the lower and side surfaces of the outer housing and preventing settlement and fine movement of the housing.

In the present invention, the buried antenna, the lower body is embedded in the antenna installation portion, the main body having a reflection groove formed concave to open to the upper side; An antenna installed in the reflection groove through the center of the main body; And a protective member filled in the reflective groove to fill the antenna.

And the reflecting groove is formed in a bowl (bowl) shape, the wrinkles are preferably formed on the surface.

In addition, the protective member is preferably made of an epoxy which is filled in the reflective groove in the resin state with fluidity, and cured.

And embedded buried heat pipe monitoring panel according to the present invention, the upper surface is provided in the open state on the inner housing, the solar cell installation made of a metal material of high hardness; A solar cell module installed inside the solar cell installation box and generating electricity using solar light and supplying the heat pipe monitoring device and the power supply device; It is preferably made of a transparent material, and further provided with a solar cell protective device that is installed to surround the solar cell module on the solar cell installation box, it can be used to generate electricity by itself.

And the power supply is preferably characterized in that it comprises a battery for storing a certain amount of current.

The embedded heat pipe supervisory panel of the present invention includes an embedded antenna capable of smoothly transmitting and receiving radio waves even in a state of being embedded on the ground surface, so that the entire monitoring panel may be embedded in the ground surface. Thus, if the heat pipe monitoring panel is buried in the ground and does not protrude onto the surface, it not only has a good effect on the aesthetic appearance of the city, but also has the advantage of not causing a problem such as causing a safety accident or an external force.

In addition, since there is almost no obstacle in the installation place because it does not protrude to the outside, there is an advantage that can be freely installed in various locations.

Hereinafter, with reference to the accompanying drawings will be described in detail a specific embodiment of the present invention.

In the embedded heat pipe monitoring panel according to the present embodiment, as shown in FIG. 1, the heat pipe monitoring device 50, the power supply device 40, the outer housing 12, the inner housing 14, and the buried antenna ( 20) and fixed concrete 60.

First, the outer housing 12 has a structure in which a lower surface and a side are embedded in the ground surface 70 and open upward. The outer housing 12 is preferably made of a metal material having excellent hardness in order to stably protect the above-mentioned components and to withstand the pressure applied on the ground surface 70.

Next, the inner housing 14 is a component detachably installed in the outer housing 12. It is preferable that the inner housing 14 also be made of a metal material excellent in hardness similar to the outer housing 12. And the inner housing 14 has a structure that can be opened to maintain the inside of the embedded heat pipe monitoring panel according to the present embodiment. Therefore, as described above, the inner housing 14 is detachably installed in the outer housing 12. In addition, a sealing member 16 is further provided on the contact surface of the outer housing 12 and the inner housing 14 for waterproofing the inside of the panel. The sealing member 16 is pressed between the inner housing 14 and the outer housing 12 by the weight of the inner housing 14 to seal the space of the inner housing 14 and the outer housing 12 to seal the inside of the panel. Do not allow water to flow in.

In addition, an antenna installation portion is further formed on the inner housing 14. The antenna mounting portion is formed concave from the upper side to the lower side. That is, the antenna installation unit refers to a groove having a shape and a size on which the embedded antenna 20 may be seated. The embedded antenna 20 is inserted into this antenna mounting portion.

In addition, the inner housing 14 is further formed with a solar cell installation portion accommodating portion on which the solar cell installation portion 36 to be described later is mounted. The solar cell mounting portion accommodating portion is formed through the inner housing 14 and has a catching jaw so that the solar cell mounting portion 36 can be caught.

The heat pipe monitoring device 50, the power supply device 40, and the like are installed in a space sealed by the outer housing 12 and the inner housing 14.

Meanwhile, the heat pipe monitoring device 50 and the power supply device 40 are substantially the same as those of the conventional heat pipe monitoring panel. Therefore, detailed description thereof will be omitted here.

Next, the buried antenna 20 is installed in the antenna installation portion so that the upper surface and the ground surface height, is connected to the heat pipe monitoring device 50 is a component for receiving and transmitting radio waves. The embedded antenna 20 may have various structures. For example, the embedded antenna 20 may include a main body 22, an antenna 24, and a protective member 26, as shown in FIG. 1. Can be configured.

First, the main body 22 is a component having a recessed recess formed in a lower surface thereof in the inner housing 14 and recessed to open upward. It is preferable that the main body 22 is made of a metal material which is easy to be molded and has excellent strength so as not to be deformed or broken by pressure applied from the ground in the state embedded in the inner housing 14. For example, the body 22 may be made of cast iron.

As described above, the main body 22 is formed with a reflecting groove, which has a concave bowl shape as a whole. And the reflecting groove is not formed in a smooth curved surface, as shown in Figure 1, it is preferable that a plurality of wrinkles that are deeply curved inwardly is formed. This wrinkle portion is combined with a protective member 26 to be described later, to prevent the protective member 26 from being separated or separated from the main body 22.

In addition, it is preferable that a reflective coating film reflecting radio waves is further formed on the reflective groove surface. The reflective coating film reflects radio waves emitted from the antenna 24 or radio waves received from the outside, so that radio waves can be more easily transmitted and received by the antenna 24. The reflective coating film may be made of a general material capable of reflecting radio waves.

Next, the antenna 24 penetrates the center of the main body 22 and is a component installed in the reflective groove. The antenna 24 is formed inside the reflection groove so as not to protrude outward from the reflection groove of the main body 22, and has a structure completely covered by the protection member 26 to be described later. This antenna 24 has a structure substantially the same as a general antenna, and serves to transmit or receive radio waves.

The lower end of the antenna 24 is connected to the coaxial cable 28 that is connected to the transceiver 56 buried underground. In order to install the antenna 24, an antenna mounting portion is formed in the central portion of the main body 22. The antenna 24 is fixed to this antenna mounting portion.

Next, the protection member 26 is a component that is filled in the reflection groove so as to completely fill the antenna 24. The protective member 26 is formed to form the same surface as the upper surface of the main body 22, and when viewed from the upper side, it appears to be integral with the main body 22.

In the present embodiment, in order to completely contact the protective member 26 to the reflective groove of the main body 22, the protective member 26 is formed by pressing and filling the reflective groove in the resin state with fluidity, and hardened. It is desirable to. When the resin is filled in the reflective groove in the state of fluidity, the protective member 26 is molded into a shape corresponding to the shape of the plurality of wrinkles formed in the reflective groove, and thus hardened in a state in which it is completely in contact with the reflective groove. The protective member 26 is not separated or separated from the body 22.

The protective member 26 may be made of various resins having properties of being filled in such a flowable state and cured after being filled, for example, may be made of epoxy resin. In particular, the epoxy is preferably a colored epoxy because it improves the appearance.

Next, the fixed concrete 60 supports the bottom and side surfaces of the outer housing 12, and is a component that prevents the settlement and fine movement of the outer housing 12. The fixed concrete 60 is installed as necessary, but is not necessarily installed. However, when the buried heat pipe monitoring panel needs to be more securely fixed according to the topography or the shape of the place where the buried heat pipe monitoring panel is installed.

The fixed concrete 60 may have various structures. For example, as shown in FIG. 1, the fixed concrete 60 surrounds the bottom and side surfaces of the outer housing 12 and has a larger area than the outer housing 12. It is preferable because the outer housing 12 can be stably supported. In addition, the lower surface of the fixed concrete 60 is formed with a projection having a grid shape, to increase the frictional force with the lower ground 70 to prevent the left and right flow of the outer housing 12 and the fixed concrete 60. It is preferable to be able.

On the other hand, the buried heat pipe monitoring panel according to the present embodiment, it is preferable that the solar cell module 30 is further provided. To this end, the inner housing 14 further includes a solar cell mounting portion accommodating portion adjacent to the antenna mounting portion, and as shown in FIG. 1, the solar cell mounting portion 36 is provided in the solar cell mounting portion accommodating portion. Removably received. The solar cell mounting portion 36 may be made of the same metal material as the inner housing 14, and has a structure that can be caught on the locking jaw of the solar cell mounting portion receiving portion. In this case, as shown in FIG. 1, a sealing member 38 is further provided on a contact surface of the inner housing 14 and the solar cell installation unit 36 to prevent water or the like from flowing into the inner space. Do.

The reason why the solar cell installation unit 36 is detachably installed in the inner housing 14 is that the solar cell installation unit (at the time of maintenance work on the inside of the embedded heat pipe monitoring panel according to the present embodiment) 36) to open and to do internal maintenance work. Of course, as described above, the inner housing 14 itself has a structure that can be opened, but the entire panel maintenance work is not required, when only partial maintenance is required to open and maintain only the solar cell installation unit 36 This is to make the work more efficient.

In the solar cell installation unit 36, a solar cell installation box 34, a cell 32, and a solar cell protective device 36 are installed. As shown in FIG. 1, the first installation box 34 is provided with an upper surface open to an upper portion of the solar cell installation unit 36, and is a component made of a hard metal material. The solar cell mounting box 34 may have various shapes such as a hexahedron. The solar cell mounting box 34 has a constant internal space, the solar cell module 32 is installed in the space, the upper surface is opened and covered with the solar cell protection 36.

Next, the solar cell module 32 is installed at the same height or higher than the upper surface of the solar cell installation box 34 inside the solar cell installation box 34, and performs solar power generation to monitor the heat pipe. 50) and the power supply 40 is a component for supplying power. The solar cell module 32 is generally a commercially available solar cell module is sufficient, various solar cell modules can be used as needed.

Next, the solar cell protection device 36 is made of a transparent material, and is a component installed to surround the solar cell module 32 on the solar cell installation box 34. Since the solar cell protection device 36 must protect the solar cell from external contamination or external force and transmit sunlight without loss, it is preferable that the solar cell protective device 36 is made of a transparent material having excellent strength. For example, it may be made of a transparent plastic material such as tempered glass or PMMA.

In this embodiment, the solar cell protection device 36 is configured to completely cover the upper surface of the solar cell installation box 34, as shown in Figure 1, the shape is made of a parabolic (parabolic) shape of the solar It is preferable to make it advantageous for condensing.

In addition, in the present embodiment, the light of a wavelength suitable for photovoltaic power generation of the solar cell module 32 passes through the surface of the solar cell protection device 36, and further forms a beam splitting coating that reflects light of the remaining wavelengths. It is preferable. Beamsplit coatings are coatings that allow light of a particular wavelength to pass and reflect light of another wavelength.

Specifically, the spectral characteristics of sunlight in a specific wavelength region of the beam splitting coating are a pair of a thin film made of one of HfO, ZrO ₂ , TiO ₂ and TaO ₂ and a protective coating film made of SiO ₂ . This is achieved by a method of laminating as a specific number of times. When coating the beam splitter for forming a reflective film for a hot mirror or a cold mirror, the material is formed of any one of Hfo, ZrO ₂ , TiO ₂ and TaO ₂ . It is common to make a reflective surface by coating a thin film 1/4 times the wavelength of the wavelength to be reflected. When a protective coating film made of transparent SiO ₂ is coated on it, the coating is protected and the sun according to a specific wavelength range is applied. The light may be selectively separated according to the wavelength range by the thickness of the protective coating layer or the number of laminations.

More specifically, SiO ₂ is deposited on a thin film of any one of Hfo, ZrO ₂ , TiO ₂ and TaO ₂ to selectively disperse sunlight having a desired coating wavelength band in the beam splitting coating. If the protective coating film formed is coated with one composite coating layer, the composite coating layer is coated on the surface of the beam splitting coating unit in a plurality of times.

In the present embodiment, the beam splitting coating film may be configured differently according to the solar cell module 32 to be installed. For example, when the solar cell module 32 includes a crystalline solar cell, light having a low absorbance of crystalline silicon of 1100 nm or more is reflected and light having a wavelength of less than 1100 nm that can be used for power generation is passed through. The beam splitting coating film may be manufactured.

On the other hand, when the solar cell module 32 includes a thin-film solar cell, the beam splitting coating preferably allows light having a wavelength of less than 900 nm to pass through and reflects light of 900 nm or more.

Meanwhile, the anti-fouling dustproof coating surface (not shown) may be further formed on the surface of the solar cell protective device 36. When the surface of the solar cell protective equipment 36 is contaminated by external dust or the like to reduce the transmittance of the solar light, the power generation efficiency of the solar cell is rapidly decreased. Therefore, although the surface of the solar cell protection device 36 should be kept clean, it is very difficult to periodically clean the solar cell protection device 36 installed in the plurality of heat pipe monitoring device panels.

Therefore, by forming an antifouling dust-proof coating surface (not shown in the figure) on the surface of the solar cell protective equipment 36, it is to prevent contamination by default. The antifouling dust-proof coating surface may be configured in various ways, for example, may be composed of a film having a very small number of properties. The superhydrophobic surface is coated with a hydrophobic material or formed with a structure having fine protrusions of 100 nm or less, so that the contact angle with water is larger than 150 °. When coated with a superhydrophobic film in this way, the external contaminants do not adhere to the surface of the solar cell protection device, and some attached contaminants are naturally washed by rain or the like.

1 is a cross-sectional view showing the structure of a buried heat pipe monitoring panel according to an embodiment of the present invention.

Claims (7)

In the heat pipe monitoring device panel with a heat pipe monitoring device and a power supply installed therein, An outer housing having a lower surface and a side embedded in the ground, and having an open structure in an upward direction; An inner housing detachably installed in the outer housing and having an antenna mounting portion having a concave structure opened upward; A buried antenna installed in the antenna installation unit so as to coincide with the ground surface and connected to the heat pipe monitoring apparatus to transmit radio waves; And a fixed concrete supporting the lower and side surfaces of the outer housing and preventing settlement and fine movement of the housing. The method of claim 1, wherein the buried antenna, A main body having a lower surface embedded in the antenna installation portion and having a reflective groove formed concave so as to open upward; An antenna installed in the reflection groove through the center of the main body; A buried heat pipe supervision panel comprising: a protective member filled in the reflective groove to bury the antenna. The method of claim 2, The reflective groove is formed in a bowl shape (bowl), the buried heat pipe supervision panel, characterized in that the surface is formed wrinkles. The method of claim 3, The protection member is a buried heat pipe monitoring panel, characterized in that made of an epoxy filled in the reflecting groove, the cured resin is formed in a flowable resin state. The method of claim 2, The buried heat pipe supervision panel, characterized in that the reflective groove is further formed on the reflective groove surface. The method of claim 2, An upper surface of the inner housing is detachably provided in an open state, and a solar cell is formed of a hard metal material; A solar cell module installed inside the solar cell installation box and generating electricity using solar light and supplying the heat pipe monitoring device and the power supply device; The buried heat pipe monitoring panel further comprises a solar cell protective device made of a transparent material and installed to surround the solar cell module on the solar cell installation box. The method of claim 6, The power supply device is a buried heat pipe monitoring panel, characterized in that it comprises a battery for storing a certain amount of current.

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