KR20100041958A - Dehumidification system for bridge and method of controlling the same - Google Patents

Abstract

PURPOSE: A bridge dehumidification system including a dehumidifier and a control method of the same are provided to prevent the corrosion of a bridge by operating a dehumidifier. CONSTITUTION: A bridge dehumidification system comprises a main cable dehumidification part(110), an anchorage dehumidification part(120), a main tower dehumidification part(130), a stiffening dehumidifying unit(140) and a controller(150). Each dehumidification part comprises a dehumidifier, a sensor(S) and a dehumidifying unit data transmitting-receiving device(DT). The dehumidifier dehumidifies each dehumidification part. The sensors are arranged in the part to be dehumidified and measure temperature and humidity. The controller controls the operation of the dehumidifier after receiving a control signal.

Description

Dehumidification system for bridge and method of controlling the same

The present invention relates to a dehumidification system of a bridge and a method of controlling the same.

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.

In general, the main components of suspension bridges are: ① Main cable, which is the main tension member, ② Anchor part that leads the tension of the main cable to earth, ③ Tower of steel or reinforced concrete structure that supports the highest point of the main cable, ④ Reinforcement type (plate) Girder or truss), ⑤ It is five kinds of suspending material that hangs reinforced type to main cable. In addition, suspension bridges can be classified according to the type of reinforcement. In a typical suspension bridge, the reinforcement is supported at both ends, but there is a hinge in the center of the type. In addition, there are only one reinforcement type between the towers, sometimes there are suspension bridges with reinforcement types on the outside of the tower, and many suspension bridges in which three reinforcement types are continuous. In the suspension bridge as described above, the main cable is led to the ground and connected to the anchor block. Alternatively, there is a suspension bridge connecting the main cable to both ends of the continuous reinforcement type, which is called a self-sustaining suspension bridge.

The reinforcement type of these suspension bridges has 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.

In addition, the main cable has a structure in which a plurality of steel wires are twisted to form a bundle.

As such, in the case of suspension bridges, the structures are generally made of metal, in particular steel, and thus, suspension bridges are vulnerable to corrosion by moisture.

In order to solve the problem of corrosion caused by moisture, conventionally, the box girders of the reinforcement type are rust-proofed, or after drying the inside of the box girders, a method of removing existing rust and spraying a rust conversion agent or using a dehumidification filter. This has been used.

However, this method is cumbersome due to the deterioration of the antirust treatment over time, the process of removing existing rust and the use of a rust conversion agent, and the need to replace the dehumidification filter when the dehumidification filter reaches the end of its life. .

In order to solve the above problems, an object of the present invention is to provide a bridge dehumidification system that can be installed to the dehumidifying device in the vulnerable portion of the bridge to prevent the bridge from aging due to corrosion.

In order to achieve the above object, the present invention is a bridge dehumidification system consisting of a main cable dehumidifying unit, an anchorage dehumidifying unit, a main tower dehumidifying unit, a reinforced type dehumidifying unit and a control unit, wherein each dehumidifying unit dehumidifying each dehumidifying unit Dehumidifier for; A controller for controlling the operation of the dehumidifier; A plurality of dehumidifying units are arranged in a part to be dehumidified to transmit the sensors for measuring temperature and humidity and the data about the temperature and humidity measured by the sensor to the controller and to receive a controller control signal to control the operation of the dehumidifier. And a dehumidifying unit data transmitting and receiving device, wherein the control unit comprises: a control unit data transmitting and receiving device which receives temperature and humidity data transmitted from each dehumidifying unit and transmits a control signal for controlling the controller of the dehumidifying unit; An industrial microcomputer unit for calculating a control signal for controlling the controller of each dehumidifying unit, and a memory unit for storing the reference data of temperature and humidity for the operation of each dehumidifying unit.

In addition, the dehumidifier of the present invention comprises a dehumidifier having a suction hose for sucking air; At least one mixing box connected to the dehumidifying air discharge inlet of the dehumidifier and configured to blow air dehumidified in a direction requiring dehumidification by a booster fan therein; At least one distributor having a closed space and having a booster fan mounted therein to suck dehumidified air in one direction; The air sucked from the mixing box is transferred, the outer surface includes a dehumidification tube covering the insulating cover and connecting the mixing box and the distributor and a plurality of dehumidification hoses mounted on one side of the distributor and extending to a predetermined length to the other side. It is characterized by.

The present invention also provides a control method of a bridge dehumidification system including a main cable dehumidifying unit, an anchorage dehumidifying unit, a main tower dehumidifying unit, a reinforced dehumidifying unit, and a control unit, the method comprising: measuring temperature and humidity at a sensor of each dehumidifying unit; Each dehumidifying unit may include transmitting the temperature and humidity data measured through the data transmitting and receiving device to the control unit, and comparing the received data with reference data stored in the memory unit.

In addition, the reference data stored in the memory unit of the present invention is the lower limit of the allowable temperature and the upper limit of the humidity, and the control unit calculates a control signal when the temperature measured in each dehumidifying unit is equal to or lower than the lower limit of the temperature or higher than the measured humidity upper limit. It characterized in that for transmitting a control signal to each dehumidifying unit.

In addition, the present invention, if the temperature and humidity data received from the control unit out of the reference data range, the control unit calculates a control signal for controlling each dehumidifying unit, and transmitting the calculated control signal to each dehumidifying unit and Each dehumidifying unit further comprises a step of allowing the controller to control the dehumidifying apparatus through the received control signal to perform dehumidification.

By the above-described configuration, it is possible to prevent deterioration due to corrosion by installing a dehumidifying apparatus in a part vulnerable to moisture of the bridge.

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

The detailed description set forth below in connection with the appended drawings is made with the intention of describing preferred embodiments of the invention, and does not represent the only forms in which the invention may be practiced. It should be noted that the same and equivalent functions included in the spirit or scope of the present invention may be achieved by other embodiments. In particular, although the embodiment of the accompanying drawings relates to suspension bridges, the present invention is found to be applicable to cable-stayed bridges, arch bridges, and the like. In addition, certain features disclosed in the drawings are enlarged for ease of description, and the drawings and their components are not necessarily drawn to scale. However, those skilled in the art will readily understand these details. The data transmission and reception used in the practice of the present invention is a concept including a wired and wireless method.

1 is a conceptual diagram illustrating a bridge dehumidification system according to an embodiment of the present invention.

Referring to Figure 1, the bridge dehumidification system of the present invention will be described by taking an example of the dehumidification system mounted on the suspension bridge.

Bridge dehumidification system according to an embodiment of the present invention comprises a main cable dehumidifying unit 110, anchorage dehumidifying unit 120, the main tower dehumidifying unit 130, reinforced dehumidifying unit 140 and the controller 150. .

The dehumidifying parts 110, 120, 130, and 140 are dehumidifying devices D / H for dehumidifying the dehumidifying parts 110, 120, 130, and 140, and the dehumidifying parts 110, 120, 130, and 140, respectively. ) Are disposed in a portion to be dehumidified, and the sensors S measuring temperature and humidity, and the data about the temperature and humidity measured by the sensor S are transmitted to the controller 150 and the controller 150 And a dehumidifier data transmitting / receiving device (DT) configured to receive a control signal to control the operation of the dehumidifier (D / H).

The controller 150 receives temperature and humidity data transmitted from each of the dehumidifiers 110, 120, 130, and 140, and transmits a control signal for controlling the dehumidifiers 110, 120, 130, and 140. A control unit data transmitting and receiving device DT, an industrial microcomputer unit 151 for calculating a control signal for controlling the dehumidifying units 110, 120, 130, and 140, and the dehumidifying units 110, 120, Memory unit 152 for storing the reference data of the temperature and humidity for the operation of the 130,140.

2 is a view for explaining a dehumidifying apparatus used in each dehumidifying unit of the bridge dehumidification system according to an embodiment of the present invention.

Referring to Figure 2, the dehumidifier (D / H) is connected to the dehumidifier (D / Hb) having a suction hose (D / Ha) for sucking air, and the dehumidification air discharge inlet of the dehumidifier (D / Hb) At least one mixing box (D / Hd) for blowing air dehumidified in a direction requiring dehumidification by the booster fan (D / Hc) and air dehumidified in one direction while having a closed space At least one distributor (D / Hf) equipped with a booster fan (D / He) for sucking the air, and the air sucked from the mixing box (D / Hd) is transferred, the outer surface is covered with a heat insulating cover and the mixing box Dehumidification tube (D / Hg) connecting the (D / Hd) and the distributor (D / Hf), and the dehumidification hose (D / Hh) is mounted on one side of the distributor (D / Hg) and extends to the other side It is composed.

The dehumidifier D / H removes moisture from the dehumidifier D / Hb through the suction hose D / Ha, and the dehumidified air is transferred to the mixing box D / Hd. , By the booster fan (D / He) of the distributor (D / Hf) is discharged through the dehumidification hose (D / Hh) to the space for dehumidification.

3 is a view for explaining the reinforced dehumidifying unit of the bridge dehumidification system according to an embodiment of the present invention, Figure 4 is a view for explaining the main tower dehumidification unit of the bridge dehumidification system according to an embodiment of the present invention, Figure 5 The figure for explaining the anchorage dehumidifier of the bridge dehumidification system according to an embodiment of the present invention.

3 to 5, each dehumidifying unit 120, 130, 140 of the bridge dehumidifying system according to an embodiment of the present invention is a dehumidifying apparatus (D) responsible for dehumidifying each of the dehumidifying units 120, 130, and 140. / H) and a controller CT for controlling the operation of the dehumidifier.

In more detail, the dehumidifier (D / H) is the air is introduced through the suction hose (D / Ha) for sucking the air, the introduced air is removed through the dehumidifier (D / Hb) to remove moisture The dehumidified air is strongly transferred to the distributor by the booster fan of the mixing box (D / Hd), and the U-lip (u ) is operated through the dehumidification hose (D / Hh) by the operation of the booster fan (D / He) of the distributor. The dehumidified air is discharged into spaces requiring dehumidification, that is, anchorage, pylon, reinforcement, and saddle, in the dehumidifying parts 120, 130, and 140 through an outlet formed in the rib. U-Rib used in this embodiment refers to the role of sending out the dry air by forming an outlet in the bottom (outlet), as shown in Figure 3 attached.

The dehumidifier D / H is controlled by the operation of the controller CT installed in a part of each dehumidifier 120, 130, 140.

The controller CT is electrically connected to the plurality of sensors S and the data transceiver DT shown in FIG. 1, and controls the temperature and humidity data measured by each sensor through the data transceiver DT. The controller transmits a control signal for controlling the operation of the dehumidifying apparatus D / H to the data transmitting / receiving apparatus of the enhanced dehumidifying unit 140 by analyzing the received temperature and humidity data.

The controller DT controls the operation of the dehumidifier D / H through the transmitted control signal.

6 is a block diagram for explaining the operation of the bridge dehumidification system according to an embodiment of the present invention.

Referring to FIG. 6, the bridge dehumidification system according to the present invention includes a reinforced dehumidifying unit 140, a main tower dehumidifying unit 130, and an anchorage dehumidifying unit 120, and control of each dehumidifying unit 120, 130, and 140. It comprises a control unit 150 is installed in the engine room for.

The reinforcing type dehumidifying unit 140, the main tower dehumidifying unit 130, and the anchorage dehumidifying unit 120 of the dehumidifying unit may be a dehumidifying apparatus as shown in FIG. 2, a temperature sensor measuring temperature and humidity of each part, and And a humidity sensor and a dehumidifying unit data transmitting and receiving device for transmitting temperature and humidity data to the control unit and receiving a control signal transmitted from the control unit.

The control unit 150 receives the temperature and humidity data transmitted from the dehumidifying unit, a control unit data transmission and reception device for transmitting a control signal for controlling each of the dehumidifying unit (120, 130, 140), and the reinforcement type of the control unit Industrial microcomputer unit for calculating the control signal for controlling the operation of the dehumidifying unit 140, the main tower dehumidifying unit 130 and the anchorage dehumidifying unit 120, and for operation of each dehumidifying unit (120, 130, 140) It comprises a memory unit for storing the reference data of temperature and humidity.

7 is a flowchart illustrating the operation of the bridge dehumidification system according to an embodiment of the present invention.

Referring to FIG. 7, first, reference data of temperature and humidity for performing dehumidification of a part requiring dehumidification such as a reinforced dehumidifying part, a main tower dehumidifying part, a main cable dehumidifying part, and an anchorage dehumidifying part is included in a memory part of a controller. Is pre-stored. At this time, the reference data stored in the memory unit is the lower limit of the allowable temperature and the upper limit of the humidity.

Measures data regarding temperature and humidity measured by the temperature sensor and the humidity sensor of the reinforced dehumidifying unit, the main tower dehumidifying unit, the main cable dehumidifying unit, and the anchorage dehumidifying unit.

Then, the data on the measured temperature and humidity is transmitted to the control unit through the data transmitting and receiving device of each dehumidifier (S110).

The transmitted temperature and humidity data is transmitted to the industrial microcomputer unit through the control unit data transmission and reception device, and the industrial microcomputer unit compares the transmitted data about temperature and humidity with reference data stored in the memory unit. )

In this case, the industrial microcomputer unit determines whether the measured temperature and humidity data are outside the temperature and humidity range of the reference data.

If the measured temperature and humidity data are out of the range of the reference data, the industrial microcomputer unit of the control unit calculates a control signal for dehumidifying the dehumidifying unit requiring dehumidification among the dehumidifying units, and sends the data transmission / reception apparatus. And transmits to each dehumidifying unit. (S140)

The dehumidification unit requiring dehumidification receives the control signal through the data transmission and reception device, and the received control signal operates the dehumidification device through the controller to perform dehumidification.

While the dehumidification is in progress, the temperature and humidity sensors continuously measure and transmit the temperature and humidity to the control unit. If the transmitted temperature and humidity are determined to be within the range of the reference data of the memory unit, the industrial microcomputer unit dehumidifies. A control signal for stopping is calculated and sent to the dehumidifying unit to stop the dehumidification.

1 is a conceptual diagram for explaining a bridge dehumidification system according to an embodiment of the present invention,

2 is a view for explaining a dehumidifying apparatus used in each dehumidifying unit of the bridge dehumidification system according to an embodiment of the present invention,

3 is a view for explaining the reinforced dehumidifying unit of the bridge dehumidification system according to an embodiment of the present invention,

4 is a view for explaining the main tower dehumidification unit of the bridge dehumidification system according to an embodiment of the present invention,

5 is a view for explaining the anchorage dehumidifier of the bridge dehumidification system according to an embodiment of the present invention,

Figure 6 is a block diagram for explaining the operation of the bridge dehumidification system according to an embodiment of the present invention,

7 is a flowchart illustrating the operation of the bridge dehumidification system according to an embodiment of the present invention.

Claims (5)

In the bridge dehumidification system consisting of a main cable dehumidification unit, an anchorage dehumidification unit, a main tower dehumidification unit, a reinforced type dehumidification unit, and a control unit, Each dehumidifying unit, Dehumidifier for dehumidifying each dehumidifying unit; A controller for controlling the operation of the dehumidifier; A plurality of sensors each of which is disposed at a portion to be dehumidified to measure temperature and humidity; And And a dehumidifier data transmitting / receiving device which transmits data about temperature and humidity measured by the sensor to the controller and receives a controller control signal to control the operation of the dehumidifier. The control unit, A controller data transmission / reception apparatus for receiving temperature and humidity data transmitted from each dehumidifying unit and transmitting a control signal for controlling the controller of each dehumidifying unit; An industrial microcomputer unit for calculating a control signal for controlling the controller of each dehumidifying unit; And A memory unit for storing reference data of temperature and humidity for operating the dehumidifying units; Bridge dehumidification system comprising a. The method of claim 1, The dehumidifier is, A dehumidifier having a suction hose for sucking air; At least one mixing box connected to the dehumidifying air discharge inlet of the dehumidifier and configured to blow air dehumidified in a direction requiring dehumidification by a booster fan therein; At least one distributor having a closed space and having a booster fan mounted therein to suck dehumidified air in one direction; A dehumidifier tube to which the air sucked from the mixing box is transferred, and an outer surface of the mixing box is connected to the outer surface and connects the mixing box and the distributor; And A plurality of dehumidification hoses mounted at one side of the distributor and extending to a predetermined length to the other side; Bridge dehumidification system comprising a. In the control method of the bridge dehumidification system including a main cable dehumidifying unit, an anchorage dehumidifying unit, a main tower dehumidifying unit, a reinforced dehumidifying unit and a control unit, Measuring temperature and humidity at each sensor of the dehumidifying unit; Each dehumidifying unit transmitting temperature and humidity data measured through a data transmitting and receiving device to the control unit; And The control unit comparing the received data with reference data stored in the memory unit; Control method of a bridge dehumidification system comprising a. The method of claim 3, The reference data stored in the memory unit is a lower limit of allowable temperature and an upper limit of humidity. The control unit calculates a control signal and transmits a control signal to each dehumidifying unit when the temperature measured by each dehumidifying unit is equal to or lower than a temperature lower limit or more than the measured humidity upper limit. The method of claim 3, If the temperature and humidity data received from the controller is out of the reference data range The control unit calculating a control signal for controlling each dehumidifying unit and transmitting the calculated control signal to each dehumidifying unit; And Each dehumidifying unit controls the dehumidifying apparatus to perform dehumidification by the controller through the received control signal; Control method of a bridge dehumidification system, characterized in that further comprises.

Images