KR102192466B1 - Energy saving partial maintenance and reinforcement apparatus and method using LED light source - Google Patents

Abstract

The present invention relates to a device for energy saving partial maintenance and reinforcement using an LED light source, and a method therefor. The device comprises a repair member reacted and solidified when preferentially photo-initiating a specific wavelength of an LED light source to maintain and reinforce a portion of a pipe such as the water and sewage pipe where degradation or a defect occurs. Therefore, the method can significantly reduce energy consumption and increase durability as compared to another maintenance and reinforcement method solely using an existing UV lamp or hot air.

Description

Energy saving partial maintenance and reinforcement apparatus and method using LED light source}

In the present invention, in repairing and reinforcing old or defective parts of pipelines such as water and sewage pipes, the present invention provides a repair member that is cured by reacting to a specific wavelength of an LED light source, thereby preventing existing UV lamps or hot air. The present invention relates to an energy-saving partial repair and reinforcement device and method using an LED light source to improve durability while dramatically reducing energy use compared to the repair and reinforcement method used alone.

In general, installed sewer pipes or water supply pipes have a stepped, open, or partially damaged joint, and if rust occurs, the original function is degraded.

When a defect occurs in a conduit, problems such as sewage flowing into and out of the conduit flow out and enter, contaminating the soil and groundwater, and economic damage such as a sink hole that turns off the ground, safety issues, and the environment The situation is causing enemy problems.

In this way, in repairing and reinforcing a conduit where a defect has occurred, the non-excavation repair and reinforcement method is used. The non-excavation repair and reinforcement method does not excavate the ground and attaches the repair/reinforcement member to the conduit where the defect has occurred. It refers to a method of repairing and reinforcing a conduit that improves its original function.

As an example of such a non-drilling repair and reinforcement method, in Korean Patent Registration No. 10-0594825, in the non-drilling sewage pipe repair and reinforcement hose lining method in which a hose liner is installed and hardened inside the sewer pipe, the hose lining method is (a ) The process of inserting a CCTV-equipped robot into the sewer pipe section (A) to be repaired and reinforced among sewer pipes with an inner diameter of 200 to 1200 mm, photographing the inside of the sewer pipe, and inspecting the inside of the sewer pipe, and confirming the damaged part (B); (b) a process of blocking the inflow of upstream sewage by installing a blocking device for water supply on the upstream (C) side of the sewer pipe section (A) to be repaired and reinforced; (c) a process of washing the sewer pipe section to be repaired and reinforced using a sewer washing vehicle; (d) inserting a pre-liner into the sewer pipe section (A) to be repaired and reinforced; (e) inserting a liner hose made of glass fiber reinforced plastic on the preliner and supplying compressed air to the liner hose to expand the hose; (f) After inserting the UV light lamp curing vehicle into the expanded liner hose, install water-repellent packers on the upstream (C) and downstream (D) sides of the sewer pipe section (A) to be repaired and reinforced. A process of operating the connected compressor to make the packer in close contact with the preliner and liner of the sewer pipe section to be repaired and reinforced; Curing the liner while moving the UV light lamp curing vehicle; (g) after the curing process is completed, the UV light lamp curing vehicle is moved, sealing both ends of the hose liner with a sealing device to make water, and injecting water into the liner for a watertight test; And (h) a process of crushing the inlet of the branch pipe by inserting a crushing robot into the liner, and a hoselining method for repairing and reinforcing a non-excavating sewage pipe.

However, in the application of the above technology, there is a problem in that sufficient watertightness, impact resistance, etc. for repair and reinforcement cannot be expected.

In particular, in the case of the above-described conventional technology, an example in which a UV light lamp is applied alone in the curing process is presented. As a result of the use of the lamp to irradiate UV wavelength light, a lot of energy must be consumed. Due to the shortcomings of a short service life and a short replacement cycle, there is an uneconomical problem due to an increase in construction cost as well as maintenance cost in operating the device.

Korean Patent Registration No. 10-0594825

Therefore, the object of the present invention is to provide a repair member that is cured by reacting to a specific wavelength of an LED light source in repairing and reinforcing old or defective parts of pipelines such as water and sewer pipes. It is to provide an energy-saving partial pipe repair/reinforcement device and construction method using an LED light source that can significantly reduce energy use and improve durability compared to the repair/reinforcement method that uses hot air alone.

As a means to solve the above problem, the energy-saving partial repair and reinforcement device using the LED light source of the present invention (hereinafter referred to as the'partial repair and reinforcement device of the present invention') is a curing means for irradiating an LED light source therein. And an air injection means configured, and a moving means including a body portion formed with a packer expanded by the air injection means while allowing the LED light source by the curing means to be irradiated to the outside and a moving means mounted at both ends of the body portion respectively ; And a repair mounted on the packer, attached to the inner periphery of the pipe to be repaired by the movement of the moving tool and expansion of the packer, and cured while attached to the inner periphery of the pipe to be repaired by the LED light source irradiated from the curing means It is characterized by including;

As an example, the repair member includes: a geotextile sheet contacting the inner periphery of the pipe to be repaired; And a curable resin including a photoinitiator that is impregnated in the geotextile sheet and cured by photoinitiating reaction with an LED light source.

As an example, the curing means includes an LED lamp mounted so that the LED light source is irradiated from the inside of the body portion toward the inner circumference of the pipe to be repaired.

As an example, the curing means may include a UV lamp mounted to irradiate a light source of a UV (ultraviolet) wavelength range from the inside of the body portion toward the inner circumference of the pipe to be repaired; And a control module that selectively operates the LED lamp and the UV lamp, and controls the UV lamp to operate after operating the LED lamp in advance with a set time difference.

As an example, the curing means may include a hot air ejection unit mounted to eject hot air from the inside of the body portion toward the inner circumference of the pipe to be repaired; And a control module for selectively operating the LED lamp and the hot air blowing unit, and controlling the hot air blowing unit to be operated after operating the LED lamp in advance with a set time difference.

As an example, the curing means may include a heating unit mounted so that heat is applied from the inside of the body portion toward the inner circumference of the pipe to be repaired; And a control module that selectively operates the LED lamp and the heating unit, and controls the heating unit to operate after the LED lamp is operated in advance with a set time difference.

On the other hand, as a means to solve the above problem, the energy-saving partial repair and reinforcement method using the LED light source of the present invention (hereinafter referred to as the'partial repair and reinforcement method of the present invention') is a method of dredging the pipeline to be repaired. Performing the step (S10); Checking a location in which maintenance/reinforcement is required within the pipeline (S20); Mounting the repair member according to any one of claims 1 to 6 to the moving port and moving it to a position of a pipe line requiring repair and reinforcement (S30); Inflating the packer using the air injection means of the moving port to attach the repair member in close contact with the inner circumference of the pipe to be repaired (S40); Hardening the repair member using a hardening means of the moving tool (S50); Removing the air injected into the packer of the moving port to separate the repair member attached to the inner periphery of the pipe to be repaired from the moving port (S60); And withdrawing the moving port from the pipeline (S70).

As described above, the partial repair and reinforcement device and construction method of the present invention uses an LED light source as a curing means in repairing and reinforcing old or defective parts of pipelines such as water and sewer pipes, and repairs by reacting light initiated by the LED light source. As the member is configured to be cured, there is an effect of significantly reducing energy use and improving durability compared to the existing UV lamp or maintenance/reinforcement method that alone uses hot air.

In addition, when curing means is installed in parallel by installing different types of heat or light irradiation devices such as UV lamps in addition to LED lamps, curing is performed in advance by the LED lamps, which is used for the operation of additional heat or light irradiation devices. As a result, it is possible to minimize the proportion of energy, and as a result, there is an effect of reducing the construction cost in operating the device while reducing the maintenance cost due to the minimization of energy use.

1 is a perspective view showing a partial repair and reinforcement device of the present invention.
Figure 2 is a schematic diagram showing the configuration of a moving tool that is one configuration of the present invention.
Fig. 3 is a schematic diagram showing an example of mounting a maintenance member, which is one configuration of the present invention.
Figure 4 is a side cross-sectional view showing the configuration of a maintenance member according to an embodiment of the present invention.
Figure 5 is a side cross-sectional view showing a basic example of the curing means of one configuration of the present invention.
6A to 6C are side views showing an embodiment of the curing means of the present invention.
7 is a flow chart showing a partial repair and reinforcement method of the present invention.

Hereinafter, the configuration and operation of the present invention will be described in more detail based on the accompanying drawings. In describing the present invention, terms or words used in the present specification and claims are the present invention based on the principle that the inventor can appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted as a meaning and concept consistent with the technical idea of

1, the partial repair and reinforcement device of the present invention comprises a curing means 20 and an air injection means 21 for irradiating an LED light source therein, and the LED light source by the curing means 20 is external A moving tool including a body portion 22 on which a packer 220 is formed and a moving means 23 mounted at both ends of the body portion 22 while being irradiated with the air injection means 21 (2) and mounted on the packer 220, attached to the inner circumference of the pipe 1 to be repaired by the movement of the moving port 2 and the expansion of the packer 220, and irradiated by the curing means 20 It includes a repair member (3) hardened in a state attached to the inner periphery of the pipe (1) to be repaired by the LED light source.

That is, the partial repair and reinforcement device of the present invention allows repair and reinforcement with excellent watertightness and rigidity to a portion of the pipe 1 where defects such as deterioration are generated as the repair member 3 is hardened.

First, the moving port (2) is provided with moving means (23) at both ends of the body part (22) to move the repair member (3) to a location where a defect such as a crack occurs inside the pipe (1). It moves, and operates so that the repair member 3 can be in close contact with the inner periphery of the corresponding part of the conduit 1.

The moving means 23 may have one or more wheel structures as shown in FIG. 1, and in this case, the wheels are configured to be hinged to each other so that they can be applied to pipes having different diameters.

As shown in FIG. 2, the body part 22 has a curing means 20 and an air injection means 21 therein, and the curing means 20 and the air injection means 21 are various known technologies. Since there is a detailed description thereof will be omitted.

The packer 220 of the body portion 22 has a cylindrical shape and is made of a light-transmitting material through which light can be transmitted. As shown in FIG. 3, the packer 220 does not expand on its outer periphery. A repair member 3 having a relatively larger diameter than the original diameter is inserted and installed.

This body portion 22 is in a state in which the repair member 3 before expansion of the packer 220 is placed in the packer 220 to the portion to be repaired in the conduit 1 where defects are generated by the moving means 23. After being moved, the packer 220 is expanded by the operation of the air injecting means 21 so that the repair member 3 contacts the inner periphery of the portion to be repaired, and in this state, the light of the curing means 20 Alternatively, the repair member 3 can be cured by heat irradiation.

In this way, the repair member 3 hardened by light or heat irradiation forms an exposed surface on the repair target portion of the conduit 1.

On the other hand, the repair member 3 is light irradiation or heat irradiation according to the operation of the curing means 20 provided in the inner space of the body part 22 in a state attached to the inner periphery of the part to be repaired of the conduit 1 It is hardened in response to one or more of the selected ones to reinforce the rigidity and ductility of the part to be repaired.

At this time, the repair member 3 allows the curing by the LED light source to be started during the curing process by the curing means 20, thereby minimizing the energy required for curing the repair member 3.

For example, the repair member 3 is a photoinitiator that is impregnated in the geotextile sheet 300 and the geotextile sheet 300 in contact with the inner periphery of the portion to be repaired of the conduit 1 and cured by reacting to the LED light source. It may be configured to include a curable resin 310 including 311.

The curable resin 310 is configured in a state impregnated with the geosynthetic sheet 300 as mentioned above.

The curable resin 310 is a known photocurable resin or a thermosetting resin or a photocurable resin and a thermosetting resin to be included together, so that the light irradiated from the curing means 20 while impregnated in the geosynthetic sheet 300 or It hardens in response to heat.

The geotextile sheet 300 is configured in a state impregnated with the curable resin 310, and may be, for example, a glass fiber sheet.

That is, the geosynthetic sheet 300 is composed of a high-strength and highly ductile glass fiber sheet to further strengthen strength, and in the case of a pipe buried in soft ground by increasing elasticity (ductility), it can accommodate deformation due to differential settlement. It will be possible.

When the geotextile sheet 300 is a glass fiber sheet, the curable resin 310 may be impregnated in the gap between the glass fiber yarns constituting the glass fiber sheet, and in particular, a curable resin in the curing process by heat or light irradiation ( Since the impregnation resin) is hardened in the state where it is filled in the gap between the glass fiber yarns, in addition to the rigidity, the watertightness can be doubled.

The glass fiber sheet may be formed by weaving of glass fibers, and at this time, it is preferable to make it woven so as to have some degree of elasticity so that the change of elasticity can be made flexibly in response to expansion of the packer 220.

In addition, the curable resin 310 may include a photoinitiator 311 that is cured by photoinitiating reaction to an LED light source.

The photoinitiator 311 is a monomer that absorbs light to form a radical in a triplet state, and the light-initiating reaction to the LED light source irradiated from the curing means 20 described below, and the repair member 3 To cure.

Meanwhile, the curing means 20 irradiates one or more of light or heat so that the repair member 3 can be cured.

That is, the curing means 20 is provided inside the body part 22 of the moving tool 2 and irradiates heat or light toward the repair member 3 or irradiates heat and light in parallel, so that the repair member 2 The curable resin 310 is to allow the curing reaction to be carried out.

As shown in FIG. 5, the curing means 20 is directed toward the inner circumference of the main body 200 installed inside the body part 22 of the moving port 2, and the repair target portion of the conduit 1 It may include an LED lamp 201 mounted on the main body 200 so that the LED light source is irradiated.

In this case, the main body 200 may be installed in a fixed form in the inner space of the packer 220 or may be installed so as to be movable in the inner space of the packer 220 along its longitudinal direction.

In addition, the LED lamp 201 includes a plurality of LED elements 202 mounted along the front outer periphery of the main body 200 so that the LED light source passing through the packer 220 is placed on the outer periphery of the packer 220. It can be irradiated to the repair member (3).

The LED light source irradiated from the LED lamp 201 reacts the photoinitiator 311 included in the curable resin 310 of the repair member 3 so that the repair member 3 can be cured.

In particular, the light irradiated from the LED light source may be UV (ultraviolet) wavelength, that is, 100 to 405 nm light, most preferably UV-A (315 to 405 nm) may be configured to irradiate light.

In addition, the curable resin 310 of the repair member 3 may be a photocurable resin in which a curing reaction is performed at a UV wavelength.

That is, the curable resin 310 is a photocurable resin containing a photoinitiator 311, and the LED lamp 201 reacts to light initiation by the LED light source of the LED lamp 201 and curing proceeds, and the LED lamp 201 is in the UV wavelength band. By irradiating the light of the repair member 3 is to be completely cured.

As described above, in the partial repair/reinforcement device of the present invention, the light curing method using the conventional UV lamp alone can be replaced with the LED lamp 201, and light irradiation by such an LED light source requires energy use rather than general UV lamp application conditions. It can be reduced by more than 60%, and it has a long life and durability that can operate for up to 25,000 hours, so it is more effective in terms of maintenance.

In addition, while a general UV lamp contains mercury, the LED light source does not contain any environmentally harmful substances, so there is an effect that the device can be operated environmentally.

Such hardening means 20 is not shown in the drawing, but heat or light irradiation is controlled with the movement of the main body 200 by an operator while being connected to a control unit provided on the ground through a wired or wireless communication network to receive power. To be able to.

Meanwhile, in the partial repair/reinforcement device of the present invention, in constituting the curing means 20, the LED lamp 201 is installed in front of the main body 200 so that the curable resin 310 proceeds with the initial light initiation reaction. After making it possible, an example in which a different type of heat or light irradiation device is additionally installed at the rear so that the thermosetting or photocuring of the curable resin 310 can be completed is presented.

As an example, the curing means 20 is an LED toward the inner periphery of the main body 200 installed in the body part 22 of the moving port 2 as shown in FIG. 6A. In addition to the LED lamp 201 mounted on the main body 200 so that the light source is irradiated, the inner circumference of the maintenance target portion of the conduit 1 in the main body 200 is relatively rearward than the LED lamp 201 It may further include a UV lamp 203 mounted to irradiate the light source of the UV (ultraviolet) wavelength band toward.

At this time, as mentioned above, the main body 200 may be installed in a fixed form on the packer 220 or may be installed to be movable along the length direction of the packer 220. In this embodiment, the LED The lamp 201 and the UV lamp 203 are selectively operated, but after operating the LED lamp 201 in advance with a set time difference, a control module 204 for controlling the UV lamp 203 to be operated is further added. Including, the light initiation reaction of the maintenance member 3 by the LED light source is performed in advance.

In addition, as another example, the curing means 20 is the main body 200 installed inside the body portion 22 of the moving port 2, as shown in FIG. 6B, and the inner periphery of the repair target portion of the conduit 1 In addition to the LED lamp 201 mounted on the main body 200 so that the LED light source is irradiated toward, the maintenance target portion of the conduit 1 from the rear relative to the LED lamp 201 in the main body 200 It may further include a hot air ejection unit 205 mounted to eject the hot air toward the inner periphery of the.

That is, in the present embodiment, after the photo-initiation reaction of the curable resin 310 is performed in advance by the LED light source, the curable resin 310 is thermally cured by the hot air of the hot air blowing unit 205.

In the case of this embodiment as well, the curing means 20 may include a control module 204, and the control module 204 selectively operates the LED lamp 201 and the hot air blowing unit 205, After operating the LED lamp 201 in advance with a set time difference, the hot air blowing unit 205 is controlled to operate so that the light initiation reaction and the thermal curing reaction of the maintenance member 3 can be sequentially performed.

On the other hand, another embodiment for thermally curing the repair member 3 is shown in FIG. 6C. In the curing means 20 of this embodiment, instead of the hot air blowing part 205 of the previous embodiment, the pipe line 1 ) May further include a heating unit 206 mounted so that heat is applied toward the inner periphery of the portion to be repaired.

In this case, the heating unit 206 may be any one of a heating coil or a heating plate mounted along the outer periphery of the main body 200 and heated by operating on an external input power source.

As described above, in the present invention, the LED lamp 201, which has excellent durability and can relatively minimize energy use, is installed in the front so that the curing of the repair member 3 proceeds in advance according to the light initiation reaction, and then at the rear. By installing a different type of heat or light irradiation device such as a UV lamp 203, the maintenance member 3 is configured so that the heat curing or light curing can be completed continuously.

Accordingly, it is possible to minimize the proportion of energy used for the operation of UV lamps, and as a result, energy use can be significantly reduced compared to the existing repair and reinforcement methods that use the existing UV lamps or hot air alone in operating the device. The effects that can be made can be derived.

Hereinafter, the partial repair and reinforcement method of the present invention will be described with reference to FIG. 7.

In the partial repair and reinforcement method of the present invention, as shown in FIG. 7, the step of dredging the conduit 1 to be repaired (S10) and the step of confirming a location within the conduit 1 that requires repair and reinforcement (S20) and the step (S30) of mounting the repair member (3) to the moving port (2) to a position of the pipe (1) requiring maintenance and reinforcement (S30), and air injection means of the moving port (2) It includes the step (S40) of inflating the packer 220 using (21) and attaching the repair member 3 to the inner circumference of the pipe 1 to be repaired in close contact.

First, in step S10, as a pretreatment process for the conduit 1 to be partially repaired, a process such as removing foreign substances from the inner periphery of the conduit 1 is performed.

In water and sewage, various foreign substances such as soil, organic substances, and metals (including rust) are deposited on the inner periphery of the pipeline. By removing these foreign substances, partial repair by controlling jams caused by foreign substances in the arrangement of the moving port 2 It minimizes the occurrence of defects and facilitates construction (placement).

After the pre-treatment process is completed in this way, steps S20 and S30, that is, the location inside the pipeline (1) that requires repair and reinforcement is checked, and the repair member (3) is mounted on the moving port (2) to facilitate repair and reinforcement. Move it to the position of the necessary pipe (1).

In the step S30, the moving port 2 is moved while the repair member 3 is placed on the outer periphery of the packer 220 in the moving port 2, and partial repair must be performed in the previous process. Move it to the confirmation position.

And in the step S40, the air injection means 21 provided inside the body part 22 of the moving port 2 is operated to expand the packer 220, and pressurization by the expansion of the packer 220 As the repair member 3 is in close contact with the inner periphery of the portion to be repaired of the conduit 1, the repair member 3 corresponds to the adhesive impregnated resin included in the curable resin 310 of the repair member 3 The attachment is made in close contact at the site.

In the step S50, the LED lamp 201 of the curing means 20 provided on the body 220 is operated while the repair member 3 is attached to the repair target portion of the pipe 1 The light source is irradiated so that the photoinitiator 311 included in the curable resin 310 reacts so that the initial curing proceeds, and then the UV lamp 203 or the hot air blowing unit 205 or the control module 204 is used. By irradiating at least one of light or heat through the heating unit 206 or the like, the repair member 3 may be cured.

Thereafter, the partial repair and reinforcement method of the present invention removes the air injected into the packer 220 of the moving port 2, and the repair member attached to the inner periphery of the pipe 1 to be repaired from the moving port 2 (3) A step of separating (S60) and a step (S70) of withdrawing the moving port 2 from the pipeline 1 are performed to complete partial repair and reinforcement of the pipeline 1.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention defined in the following claims are also present. It belongs to the scope of rights of

1: pipeline 2: moving port
3: repair member 20: hardening means
21: air injection means 22: body
23: moving means 200: main body
201: LED lamp 202: LED element
203: UV lamp 204: control module
205: hot air blowing unit 206: heating unit
220: T-shaped packer 300: Geotextile sheet
310: curable resin 311: photoinitiator

Claims (7)

A curing means for irradiating an LED light source and an air injection means are configured inside, and a packer expanded by the air injection means is formed while allowing the LED light source by the curing means to be irradiated to the outside, and at both ends of the body part. A moving tool including moving means to be mounted respectively; And
A repair member mounted on the packer, attached to the inner periphery of the pipe to be repaired by the movement of the moving tool and the expansion of the packer, and cured while attached to the inner periphery of the pipe to be repaired by the LED light source irradiated from the curing means Including ;,
The maintenance member,
The geosynthetic fiber sheet made of a glass fiber sheet by weaving of glass fibers and in contact with the inner periphery of the pipe to be repaired is impregnated into the gap between the glass fiber yarns of the geosynthetic fiber sheet, and is cured by reacting to light initiation by an LED light source. And one or more of a photocurable resin or a thermosetting resin that is impregnated into the gap between the glass fiber yarns of the geosynthetic fiber sheet and causes a curing reaction to be performed by one selected from light or heat after the photoinitiation reaction by the photoinitiator. It contains a curable resin that
The curing means,
The main body installed inside the body part, an LED lamp mounted in front of the main body so that an LED light source is irradiated toward the inner circumference of the pipe to be repaired to react in advance with the photoinitiator of the curable resin, and the pipe to be repaired A heat or light irradiation device mounted at the rear of the main body to cure selected one of the photocurable resin or thermosetting resin of the curable resin by irradiating one of light or heat toward the inner periphery of the curable resin, and the LED lamp and heat or It includes a control module that selectively operates the light irradiation device, but controls either the heat or the light irradiation device to operate after operating the LED lamp in advance with a set time difference,
The curing means,
A UV lamp mounted relatively rearward than an LED lamp in the main body so that a light source of a UV (ultraviolet) wavelength range is irradiated from the inside of the body portion toward the inner periphery of the pipe line to be repaired, or within the body portion of the pipe line to be repaired. Relatively rearward than the LED lamp in the main body so that heat is applied toward the inner circumference of the conduit to be repaired from the inside of the main body or the hot-air blowing unit mounted relatively rearward than the LED lamp so that the hot air is blown toward the periphery Includes any one of the heating parts mounted on,
The control module,
Selectively operating any one of the LED lamp and the UV lamp or the hot air blowing unit or the heating unit, but first operating the LED lamp with a set time difference, and then any one of the selected UV lamp or hot air blowing unit or heating unit Energy-saving partial repair and reinforcement device using an LED light source, characterized in that it is controlled to operate.
delete delete delete delete delete The step of dredging the pipeline to be repaired (S10);
Checking a location in which maintenance/reinforcement is required within the pipeline (S20);
Mounting the repair member of claim 1 to the moving port to move it to a position of a pipe requiring repair and reinforcement (S30);
Expanding the packer using the air injecting means of the moving port to attach the repair member in close contact with the inner circumference of the pipe to be repaired (S40);
Hardening the repair member using the hardening means of claim 1 (S50);
Removing the air injected into the packer of the moving port to separate the repair member attached to the inner periphery of the pipe line to be repaired from the moving port (S60); And
The step of withdrawing the moving port from the pipeline (S70); energy-saving partial repair and reinforcement method using an LED light source comprising a.

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