KR100654379B1 - Dehumidifier for bridge - Google Patents

Abstract

The present invention relates to a bridge dehumidifying apparatus, the bridge dehumidifying apparatus according to the present invention is installed in the communication pipe and the box girder of any one of the box girder communicating two box girders installed in parallel with each other to distribute the inside of the box girder. It is installed at one side of the indoor side heat exchanger box girder where the refrigerant evaporates to condense moisture in the air to generate condensed water, and is installed at the lower side of the outdoor heat exchanger and the indoor heat exchanger where the internal refrigerant is condensed by the flow of external air. And a discharge part for discharging the condensate generated and collected by the indoor heat exchanger to the outside of the box girder, and the bridge dehumidifier according to the present invention applies an indoor heat exchanger and an outdoor heat exchanger in which a refrigeration cycle operation is performed. It is possible to dehumidify moisture in the air circulating inside two box girders. There is an effect that allows the internal girder can be prevented from rusting and extend the life span of the bridge, increase the reliability.

Description

Bridge dehumidifier using electric heat exchanger {Dehumidifier for bridge}

1 is an elevation view of a bridge to which a box girder according to the present invention is applied.

FIG. 2 is a cross-sectional view illustrating an arrangement structure and a dehumidifier of the box girder of FIG. 1.

3 is a detailed view showing an installation state of the dehumidifying apparatus according to the present invention.

<Description of the symbols for the main parts of the drawings>

11.Box Girder

100.Communication tube

110.Guide duct

120 ... inside heat exchanger

150 ... Exhaust pipe

170.Outside Heat Exchanger

The present invention relates to a bridge dehumidifier, and more particularly, to a bridge dehumidifier using an electric heat exchanger to perform dehumidification with an outdoor side and an indoor side heat exchanger installed in a box girder.

In general, the structural elements of the basic suspension bridge can be divided into reinforcement type, main cable, pylon, and anchorage part. The reinforcement supports and distributes the load and bears the aerodynamic stability of the overall structure. The load on the reinforcement is transmitted to the main cable through a hanger.

Reinforcement types of these suspension bridges have been constructed in a variety of forms, which can be divided into type I, trust and box girder. Type I molds were used in early Dandan suspension bridges, but they are rarely used since they are known to be aerodynamically disadvantageous. Trusts and box girders have advantages and disadvantages, depending on their aerodynamic properties, ease of installation, and ease of maintenance, and are selected for their superiority.

Box girders can be divided into PSC box girders and steel box girders depending on the material. Steel box girders are mainly used for large bridges.

However, steel box girders used in bridges are more likely to form oxides on the surface of metals because of the high moisture content around them and the sealed interior. The outer surface of the box girder can prevent the surface from rusting by performing antirust treatment such as painting, but there is a problem that the inside of the box girder is difficult to paint. In addition, even a slight anti-rust treatment, the anti-rust effect is lost over time, and there is a possibility that oxidized on the inner surface of the box girder due to the moisture inside.

A technique for preventing corrosion and removing rust inside a box girder is disclosed in Patent Publication No. 2000-59796. This technique uses a flexible shaft wire brush, which inserts a wire brush into the box girder to remove rust, removes rust by using a vacuum cleaner, dries the box girder, and then uses a box to inject the box. Dispersing a rust converting agent on the entire surface of the girder to convert the residual rust to the anticorrosive coating, and further comprises the step of adding a vaporizing corrosion inhibitor.

However, this technique is not only a method of removing rust after the rust has already occurred, but also requires a person to remove it using a machine or a tool. There is a problem to break through. And if the box girder is long, there is a problem that it is difficult to remove the rust deep in the wire brush and vacuum cleaner.

The present invention is to solve such a problem, an object of the present invention is to effectively remove the moisture inside the box girder of the bridge to prevent the inside of the box girder to prolong the life of the bridge, to increase the reliability of the bridge It is to provide a dehumidifier.

Dehumidification apparatus of the bridge using the electric heat exchanger according to the present invention for achieving the above object is installed in parallel with each other communicating tube communicating with one end and the other end of the two box girder to support the top plate reinforcement; An indoor heat exchanger installed inside one of the two box girders, the refrigerant evaporating to condense water in the air flowing through the box girders to generate condensed water; An indoor blower installed between the inlet of the communication tube and the indoor heat exchanger to allow air inside the box girder to flow into the indoor heat exchanger; An outdoor heat exchanger mounted on one side of the box girder and configured to condense refrigerant inside by flow of external air; An outdoor blower installed at one side of the outdoor heat exchanger to allow forced flow of external air to the outdoor heat exchanger; And a discharge part installed under the indoor heat exchanger to discharge condensed water generated and collected by the indoor heat exchanger to the outside of the box girder.

Preferably, a guide duct is provided on the air inlet side of the indoor heat exchanger to guide the air inside the box girder to the indoor heat exchanger.

Also preferably, one end of the box girder is provided with a separator to isolate the part where the indoor side heat exchanger is installed and the part where the outdoor side heat exchanger is installed, and to allow external air to flow to one side and the other side.

In addition, the discharge unit is installed in the lower portion of the indoor heat exchanger and includes a collecting plate for collecting the condensate generated in the indoor heat exchanger and a discharge pipe for guiding the condensate collected from the collecting plate to the outside of the box girder It features.

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

1 schematically shows a bridge to which a bridge dehumidification apparatus using an electric heat ventilator according to the present invention is applied. The bridge includes a girder 10 forming a substructure of the bridge and a box girder 11 and 11 ′ forming a superstructure and a supporting structure for supporting the box girder 11 and 11 ′. 11) 11 'are provided on both sides, each extending in the longitudinal direction of the bridge. And the top plate 12 is installed on the box girder (11, 11 ') upper portion, the packaging for the passage and walking of the vehicle is made thereon.

And the bridge dehumidifier according to the present invention is installed on both ends of the box girder (11) (11 '), respectively, as shown in Figure 2, the middle part inside the box girder (11) (11') is insulated from each other Becomes Since the box girders 11 and 11 'are extended by the length of the bridge, the box girders 11 and 11' are installed to be considerably longer depending on the width and the installation location. Therefore, it is preferable to isolate the insides of the box girders 11 and 11 'at appropriate positions according to the length of the bridges, and then install separate bridge dehumidifiers in the isolated portions.

The one box girder 11 isolated as described above is communicated with each other by the communication tube 100 at both ends and the other box girder 11 'arranged together in parallel on the side thereof. Therefore, in the two box girders 11 and 11 ', continuous air circulation is generated by the blowing force generated by the dehumidifier.

As shown in FIG. 2 and FIG. 3, the bridge dehumidifier according to the present invention includes an indoor heat exchanger 120 and an indoor heat exchanger 120 installed before the inlet of the communication tube 100. It is provided with a guide duct 110 for reducing the size of the flow path to guide the air intensively.

The indoor side heat exchanger 120 is installed at the outlet side of the indoor side heat exchanger 120 to circulate air inside the box girder 11 and the indoor side heat exchanger 120. It is provided with a collecting plate 140 through which the condensed water is collected and the discharge pipe 150 for guiding the condensed water collected in the collecting plate 140 to the outside of the box girder 11.

Here, a check valve (not shown) is provided inside the discharge pipe 150 to prevent the inflow of air from the outside of the box girder 11 and to simultaneously open the flow path to the outlet side of the discharge pipe 150 so as to smoothly discharge the condensate. It is preferable to install.

On the other hand, the end of the box girder 11 is separated from the inside of the box girder 11 and is provided with a portion where the outdoor heat exchanger 170 is installed. The part where the outdoor heat exchanger 170 is installed is inside the box girder 11 by a separator 160 disposed diagonally toward the side of the box girder 11 at one corner of the box girder 11. The separator 160 is not only insulates the inside and the outside of the box girder 11, but also serves to guide the air distribution between the indoor heat exchanger 120 and the inlet of the communication tube 100. do.

In addition, the box girder 11 has a corner portion and a side coupling portion of the box girder 11 to which both ends of the separator 160 are coupled to the outside, and an outdoor heat exchanger at an outer opening portion of the side coupling portion. 170 is provided.

An outdoor blower 180 is installed inside the outdoor heat exchanger 170, and a compressor 190 is installed at the bottom of the outdoor heat exchanger 170. Therefore, when the outdoor blower 180 is operated, the outside air flows in from the side end of the box girder 11 and is discharged to the front open portion. At this time, the refrigerant is condensed in the outdoor heat exchanger 170 by the flowing air.

Hereinafter, an operation state of the bridge dehumidifier using the electric heat exchanger according to the present invention configured as described above will be described.

In the bridge dehumidifier according to the present invention, two box girders 11 are installed in parallel on the piers 10, and the box girders sealed in a state in which both ends of the box girders 11 communicate with each other through the communication tube 100 ( 11) It dehumidifies the inside.

The indoor heat exchanger 120 cools the air introduced through the guide duct 110 by the operation of the indoor blower 130. At this time, the moisture generated during the cooling of the air is condensed, and the condensed water is the indoor heat exchanger. After being collected in the collecting plate 140 mounted at the lower part of the 120, the dehumidification is performed by being discharged to the outside of the box girder 11 through the discharge pipe 150.

And the air dehumidified by the continued operation of the indoor blower 130 proceeds to the other box girder 11 'through the communication pipe 100, the air proceeded to the other box girder 11' again The inside of the box girder (11) (11 ') is circulated to reach the indoor heat exchanger (120) to continue dehumidification of air.

On the other hand, the dehumidifying apparatus according to the present invention uses a conventional refrigeration cycle. That is, the dehumidification of the inside of the box girder 11 is performed by using a refrigerant that is compressed, condensed, and evaporated in the indoor heat exchanger 120 and the outdoor heat exchanger 170. The outdoor heat exchanger 170 and the outdoor blower 180 perform compression and condensation of the refrigerant on the outdoor side.

The outdoor heat exchanger 170 exchanges heat with the air introduced from the side of the box girder 11 by the operation of the outdoor blower 180 for condensation of the refrigerant, and the air that has undergone heat exchange is again in the box girder 11. It is discharged to the shear edges. Here, the discharge side may be formed at the front end of the box girder 11, but in some cases, it may be formed on the other side of the box girder 11 by changing the installation position of the separator 160.

As described above, the dehumidifier of the present invention has an indoor side heat exchanger 120 and an outdoor side heat exchanger 170 through which refrigerant is circulated, thereby lowering the air inside the box girder 11 to a temperature lower than that of the surrounding environment. (11) Since the dehumidification is performed inside, the dehumidifier will be operated mainly in summer.

On the other hand, in winter, since the outside temperature is low, the air inside the box girder 11 is condensed to produce condensed water even without using the dehumidifier of the present invention, and the condensed water freezes below freezing point.

In order to dehumidify the winter season before the condensed water inside the box girder 11 is frozen, a separate condensate drain structure associated with the configuration of the discharge pipe 150 in the present invention inside the box girder 11, for example, a box The bottom of the girder 11 may be inclined or another method may be implemented to discharge the condensate.

And when the moisture inside the box girder 11 is frozen and ice making occurs, a four-way valve is separately installed in the dehumidifying apparatus of the present invention to heat the inside of the box girder 11 through the indoor side heat exchanger 120. After generating the constant, it is possible to perform the moisture removal by draining the defrost water to the outside with the drain structure as mentioned above.

That is, the bridge dehumidification apparatus according to the present invention can effectively perform the operation for dehumidification if the configuration is partially modified anywhere in the tropics and cold regions, the installation state according to the place and environment in which the bridge is installed Even if it is deformed, it should be considered that if the dehumidification of the box girder is basically performed using a refrigeration cycle, all of them are included in the technical scope of the present invention.

Bridge dehumidifier using an electric heat exchanger according to the present invention as described above by applying an indoor heat exchanger and an outdoor heat exchanger in which the refrigeration cycle operation is performed to dehumidify the moisture in the air circulating in the two box girders box It prevents the inside of the girder from rusting, thus extending the life of the bridge and improving reliability.

Claims (4)

Communication pipes installed in parallel with each other to communicate one end and the other end of the two box girders to support the top plate reinforcement; An indoor heat exchanger installed inside one of the two box girders, the refrigerant evaporating to condense water in the air flowing through the box girders to generate condensed water; An indoor blower installed between the inlet of the communication tube and the indoor heat exchanger to allow air inside the box girder to flow into the indoor heat exchanger; An outdoor heat exchanger mounted on one side of the box girder and configured to condense refrigerant inside by flow of external air; An outdoor blower installed at one side of the outdoor heat exchanger to allow forced flow of external air to the outdoor heat exchanger; And a discharge unit installed at a lower portion of the indoor heat exchanger and discharging condensate generated and collected by the indoor heat exchanger to the outside of the box girder. The bridge dehumidifier of claim 1, wherein a guide duct for guiding the air inside the box girder is provided at the air inlet side of the indoor heat exchanger. According to claim 1, One end of the box girder is characterized in that the separator is installed to allow the outside air flow to one side and the other side is separated from each other and the portion where the indoor side heat exchanger is installed is installed. Bridge dehumidifier using an electric heat exchanger. According to any one of claims 1 to 3, wherein the discharge portion is installed in the lower portion of the indoor heat exchanger to collect the condensate generated in the indoor heat exchanger and the condensate collected from the collecting plate Bridge dehumidifier using an electric heat exchanger comprising a discharge pipe for guiding the outside of the box girder.

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