KR102666405B1 - Freeze prevention apparatus and constructuin method of freeze prevention facility - Google Patents

Abstract

The present invention relates to a freeze prevention device with a piping support function and a method of constructing a freeze prevention facility. More specifically, the construction of a device for earthquake resistance and freeze prevention of piping equipment can be carried out together to reduce the number of construction works, lower the construction cost, and provide thermal insulation. It relates to a freeze prevention mechanism with an improved pipe support function and a method of constructing a freeze prevention facility. The heating element 410 is equipped with a heating element and is in close contact with the outer surface of the pipe (P) to heat it, and protrudes to one side of the heating unit 410. A connecting protrusion 420, a fixing flange 430 having a through hole (H1) and formed on the connecting protrusion 420, and an anchor bar 440 fastened through the through hole (H1) of the fixing flange 430. ) heater (400) with; A pipe connection portion 310 that surrounds the pipe (P) and is detachably fixed and has a groove 313 formed on the opposite side of the pipe (P) so that the connection protrusion 420 is inserted and engaged with the pipe (P), and a pipe to support the pipe (P). By including an anti-shake brace (300) equipped with a support (S) that secures the connection portion (310) to the structure (B), it is easier to install the anti-shake brace and freeze prevention equipment, while reducing installation costs and time, and reducing the risk of damage to piping. It has the effect of increasing freeze prevention efficiency.

Description

Freeze prevention equipment with pipe support function and construction method for freeze prevention equipment {FREEZE PREVENTION APPARATUS AND CONSTRUCTUIN METHOD OF FREEZE PREVENTION FACILITY}

The present invention relates to a freeze prevention device with a piping support function and a method of constructing a freeze prevention facility. More specifically, the construction of a device for earthquake resistance and freeze prevention of piping equipment can be carried out together to reduce the number of construction works, lower the construction cost, and provide thermal insulation. This relates to a freeze prevention mechanism with an improved pipe support function and a construction method for freeze prevention equipment.

When installing pipes in various artificial structures such as buildings and underground passages, fix the pipes to the structure using earthquake-resistant anti-shaking braces in accordance with relevant regulations. Referring to Figure 1 (a partial cross-sectional view schematically showing a conventional pipe installation structure), as is well known, the anti-shake brace 100 consists of a support portion S and a pipe connection portion 110. The support part (S) consists of an attachment unit 120 that is directly anchored to the structure (B) and a support unit 130 that connects and supports the pipe (P) and the attachment unit 120. The support unit 130 may be of round bar type or wire type depending on the installation location of the pipe (P) and the specifications of the pipe (P). The support unit 130 in FIG. 1 is a steel round bar type. The pipe connection part 110 directly supports the pipe (P), and a couple-type C-type clamp is generally used.

The adapter 140 connecting the pipe connection 110 and the support unit 130 of the anti-shake brace 100 may vary depending on the longitudinal brace type or the lateral brace type. Since the structure of the adapter 140 in the anti-shake brace 100 is already a known technology, description of the shape and structure of the adapter 140 for connecting the pipe connection portion 110 and the support unit 130 will be omitted.

Meanwhile, since the pipe (P) is a passage for fluid, related fluid flows through the pipe (P) depending on the purpose of the pipe (P). However, when the surrounding temperature drops to the cold point of the fluid, the fluid flowing through the pipe (P), especially water, expands due to cooling and may freeze and rupture the pipe (P). Therefore, in order to prevent such pipe freezing, freeze prevention equipment 200 consisting of a heater 210 and a power check box 220 that checks the state of power supplied to the heater 210 is installed in the pipe P. In general, the heating element of the heater 210 is of a heating wire type and a metal type that operate with electric power, and is manufactured in a plate shape that covers one point of the pipe (P) or a ring shape that covers the circumference. A plurality of heaters 210 are installed in the pipe (P) at specified intervals according to relevant regulations, and the ON/OFF of the heaters 210 is collectively controlled by a separate control module 500 (see FIG. 7). The control module 500 measures the current temperature and controls the heater 210 to operate when the specified temperature is reached. The power check box 220 is connected to a temperature sensor (not shown) that measures the temperature of the pipe (P) at the point where the heater 210 is located, so that the power check box 220 itself or the control module 500 measures the temperature. The heater 210 may be operated based on the temperature measured by the sensor.

The power check box 220 branches off the sub-wire (L1) from the main wire (L2) electrically connected to the control module 500, electrically connects it to the heater 210, and checks the energization status of the sub-wire (L1). This visually displays whether the heater 210 is in operation. In addition, by checking the current status of the sub-wire L1, it is possible to alarm whether there is an abnormality in the heater 210 or to forcibly cut off electricity in an emergency. Generally, the power confirmation box 220 is configured in conjunction with the heater 210, but only the heater 210 or the power confirmation receiver 220 may be installed.

In addition, the pipe (P) is wrapped and sealed with insulation (W1, W2, W3) to protect the pipe (P) from external forces and maintain the heat insulation of the pipe (P). However, since the anti-shake brace 100 and the power confirmation box 220 are exposed to the outside through the open hole H of the insulation materials W2 and W3, there is bound to be a limitation in sealing the pipe P. In other words, the insulation material (W2) dedicated to the section where the anti-shake brace 100 is located and the insulation material (W3) dedicated to the section where the power confirmation box 220 is located have a lower thermal insulation effect compared to the insulation material (W1) that covers only the pure pipe (P). It has no choice but to happen. In addition, field processing of the insulation materials (W2, W3) for the hole (H) is inevitable in order to expose the anti-shake brace (100) and the power confirmation box (220). ) is an independent equipment, so the insulation materials (W2, W3) must be processed on-site one by one at each point where the anti-shake brace (100) and the power confirmation box (220) are located, which inevitably increases the workload and is inefficient. Moreover, when the insulation material (W2) dedicated to the section where the anti-shaking brace 100 is located, the insulation material (W3) dedicated to the section where the power confirmation box 220 is located, and the insulation material (W1) dedicated to the pure piping (P) section are separated from each other, the insulation material There was a problem in that the warmth was lost at the boundary between (W1, W2, and W3) and the thermal insulation effect was significantly reduced.

In addition, in the case of the anti-shake brace 100 made of a metal material with high thermal conductivity, even if the insulation materials (W2, W3) are processed for sealing, external cold air flows through the support portion S of the anti-shake brace 100 to the piping connection ( Since it is transferred to 110) and cools the pipe (P), the warmth of the heater 210 applied to the pipe (P) was bound to be easily lost to the outside through the pipe connection portion 110 and the support portion (S). In the end, there was a problem in that the point connected to the anti-shake brace 100 in the pipe P was relatively easily frozen and ruptured compared to other points.

Ultimately, in this field, it is easier to install the anti-shake brace (100) and freeze prevention equipment (200), which are essential for piping (P) equipment, while reducing installation costs and time, and preventing freeze and burst for the pipe (P). Methods to increase efficiency continue to be researched.

Prior Art Document 1. Patent Registration No. 10-1681956 (announced on December 12, 2016)

Accordingly, the present invention is intended to solve the above problems, and can more easily install anti-shaking braces and freeze prevention equipment that are essential for piping equipment, while reducing installation costs and time and increasing freeze prevention efficiency for pipes. The problem to be solved is to provide a freeze prevention device with a pipe support function and a method of constructing freeze prevention equipment.

In order to achieve the above task, the present invention,

A fixing flange provided with a heating part 410 that is in close contact with the pipe (P) and heated, a connecting protrusion 420 protruding from one side of the heating part 410, and a through hole (H1) and formed on the connecting protrusion 420. A heater (400) equipped with (430) and an anchor bar (440) fastened through the through hole (H1) of the fixing flange (430); and

A pipe connection portion 310 that surrounds the pipe (P) and is detachably fixed and has a groove 313 formed on the opposite side of the pipe (P) so that the connection protrusion 420 of the heater 400 is inserted into and engaged with the pipe (P). ) An anti-shaking brace (300) equipped with a support portion (S) for fixing the pipe connection portion (310) to the structure (B) to support the structure (B);

It is a freeze prevention device with a pipe support function that includes.

In order to achieve the above other technical problems, the present invention,

A first step of mounting the piping connection part 310 on which the heater 400 is installed to the piping (P) and fixing it to the structure (B) via the support part (S);

A second step of forming a pipe path by connecting the pipe (P) and another pipe, mounting a pipe connection part 310 on the other pipe, and fixing it to the structure (B) via a support portion (S);

A third step of mounting the power confirmation box 220, which is electrically connected to the main wire (L2), to a specific pipe (P);

A fourth step of electrically connecting the sub wire (L1) branched from the main wire (L2) to the heating unit 410 of the heater 400 through the power check box 220; and

A product that surrounds the pipe (P) and the other pipe with insulation materials (W1, W4) so that the support portion (S) and the power confirmation box (220) mounted on the pipe (P) and the other pipe in the pipe route are exposed, respectively. Step 5;

This is a freeze prevention facility construction method that includes.

The present invention as described above integrates the heater into the pipe connection of the anti-shake brace for piping support, so that the heater is also installed when the anti-shake brace is installed, making it easier to install the anti-shake brace and freeze prevention equipment while reducing installation costs and time. It has the effect of saving money and increasing the freeze prevention efficiency of pipes.

Figure 1 is a partial cross-sectional view showing a conventional piping installation structure,
Figure 2 is a front view schematically showing the installation of the freeze prevention mechanism according to the present invention;
Figure 3 is a bottom perspective view showing the piping connector and heater configured in the freeze prevention mechanism according to the present invention combined with each other and installed in the piping;
Figure 4 is a front perspective view showing an example of the piping connector and heater configured in the freeze prevention device according to the present invention being combined and disassembled;
Figure 5 is a bottom perspective view showing an example of a heater according to the present invention;
Figure 6 is a bottom perspective view showing another example of the piping connection part and the heater configured in the freeze prevention mechanism according to the present invention being combined and disassembled;
Figure 7 is a partial cross-sectional view showing the piping installation structure of the freeze prevention mechanism according to the present invention;
Figure 8 is a flow chart sequentially showing the freeze prevention equipment construction method according to the present invention.

The terms used in the embodiments are general terms that are currently widely used as much as possible while considering the function in the present invention, but this may vary depending on the intention or precedent of a person working in the art, the emergence of new technology, etc. In addition, in certain cases, there are terms arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the relevant invention. Therefore, the terms used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than simply the name of the term.

When it is said that a part “includes” a certain element throughout the specification, this means that it does not exclude other elements, but may further include other elements, unless specifically stated to the contrary. In addition, “…” stated in the specification. wealth", "… Terms such as “module” refer to a unit that processes at least one function or operation, which may be implemented as hardware or software, or as a combination of hardware and software.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein.

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

Figure 2 is a front view schematically showing the installation of the freeze prevention mechanism according to the present invention, and Figure 3 is a bottom perspective view showing the piping connector and heater comprised in the freeze prevention mechanism according to the present invention combined with each other and installed in the pipe. 4 is a front perspective view showing an example of the piping connector configured in the freeze prevention mechanism according to the present invention and the heater combined and disassembled, and Figure 5 shows an example of the heater according to the present invention. One side is a perspective view.

Referring to Figures 1 to 5, the freeze prevention mechanism according to the present invention includes a heater 400 that is in close contact with the pipe (P) and heats it, and a shake prevention brace (300) that secures the pipe (P) to the structure (B). ) is composed of. To describe each configuration in more detail, the heater 400 includes a heating element 410 on which a heating element (not shown) is mounted and which heats in close contact with the outer surface of the pipe P, and one side of the heating unit 410. A connecting protrusion 420 protruding, a fixing flange 430 having a through hole (H1) and formed on the connecting protrusion 420, and an anchor bar fastened through the through hole (H1) of the fixing flange 430. Equipped with (440).

In this embodiment, the heating unit 410 forms a panel that covers a portion of the pipe (P). The panel shape may have a curved surface corresponding to the outer surface of the pipe (P) or may be entirely in the form of a curved plate. A heating element (not shown) is mounted on the heating unit 410, and the heating element may be a heating wire type or a metal type that operates on electric power. It is preferable that the sub-wire L1 that supplies power to the heating element is drawn out from the side of the heating unit 410 so as not to interfere with the insulation material W4 (see FIG. 7) and the pipe P.

The connecting protrusion 420 protrudes from one side of the heating unit 410. In this embodiment, the connecting protrusion 420 is in the form of a panel having one surface connected to the opposite surface of the heating part 410 in contact with the pipe (P). However, the shape of the connecting protrusion 420 is not limited to this and may be modified in various ways. The connecting protrusion 420 may be integrated with the housing of the heating unit 410 that accommodates the heating element, but may be fastened to the housing via a fastening flange 421 as shown in FIG. 5. The fastening flange 421 can be used as an opening door of the housing, and when the fastening flange 421 is separated, the hollow of the housing can be opened to expose the heating element. The unexplained reference number 'F' refers to a fastening means such as a bolt that fastens the housing and the fastening flange 421 to each other.

The fixing flange 430 has a through hole (H1) and is formed on the connecting protrusion 420. Since the piping connection part 310 must be located between the heating unit 410, the fixing flange 430 is located at a distance greater than the width of the piping connection part 310 from the connecting protrusion 420. In this embodiment, the connecting protrusion 420 is formed to have a length longer than the width of the pipe connecting portion 310, and the fixing flange 430 is formed at the end of the connecting protrusion 420.

The anchor bar 440 is fastened through the through hole (H1) of the fixing flange 430. In this embodiment, the anchor bar 440 passing through the through hole H1 passes through the outer surface of the pipe connection part 310 to cover the pipe connection part 310. Therefore, the anchor bar 440 holds and secures the pipe connection portion 310 in a sandwich structure together with the connection protrusion 420 that engages with the groove portion 313 of the pipe connection portion 310. Furthermore, the end of the anchor bar 440 can be engaged with the heating part 410, and through this, the connecting protrusion 420, the fixing flange 430, the anchor bar 440, and the heating part 410 are connected to the pipe ( 310), completing a solid interconnection structure. To this end, an insertion hole (not shown) is formed on one side of the housing of the heating unit 410 facing the fixing flange 430, and the end of the anchor bar 440 is inserted into the insertion hole and fastened. The anchor bar 440 may be a threaded bolt, and at least one of the through hole H1 and the insertion hole may be a screw hole corresponding to the anchor bar 440.

Figure 6 is a bottom perspective view showing another example of the piping connection part and the heater configured in the freeze prevention device according to the present invention being combined and disassembled.

Referring to Figures 2 and 6, the piping connection part 310 of the freeze prevention mechanism according to the present invention has a connection flange 314 facing the fixing flange 430 protruding on the outer surface, and the fixing flange 430 has a A connection hole (H2) communicating with the through hole (H1) is formed in the connection flange (314), and the anchor bar (440) penetrating the through hole (H1) is connected to the connection hole (H2) of the connection flange (314). is inserted. Ultimately, the heating unit 410 and the piping connection unit 310 form a solid fastening structure without shaking.

In this embodiment, the connection flange 314 is placed on one side of the piping connection part 310 so as to directly contact the fixing flange 430, but may also be placed spaced apart from each other. In addition, the end of the anchor bar 440 is finished after being inserted into the connection hole (H2) of the connection flange 314, but in addition, after the anchor bar 440 penetrates the connection hole (H2), the end is connected to the heating unit 410. It may be finished by engaging the housing.

The freeze prevention mechanism according to the present invention has an insertion hole (not shown) formed on one side of the pipe connection portion 310 facing the fixing flange 430, and an anchor bar 440 penetrating the through hole H1. is inserted into the insertion hole of the pipe connection part 310. For this purpose, the part of the piping connection part 310 or the piping connection part 310 facing the fixing flange 430 covers the through hole (H1), and the fixing flange 430 is an anchor bar without a separate connection flange 314. It is fastened to the piping connection part 310 via (440). In this embodiment, the end of the anchor bar 440 is finished after being inserted into the insertion hole of the pipe connection part 310, but in addition, after the anchor bar 440 penetrates the insertion hole, the end is engaged with the housing of the heating unit 410. It may be finished.

The shake prevention brace 300 of the freeze prevention mechanism according to the present invention is detachably fixed around the pipe (P) and has a groove portion 313 so that the connecting protrusion 420 is inserted and engaged with the pipe (P). It is equipped with a formed pipe connection portion 310 and a support portion (S) for fixing the pipe connection portion 310 to the structure (B) to support the pipe (P). The anti-shake brace 300 according to the present invention can be made of materials and structures that not only have the function of simply supporting the load of the pipe (P) but also have an earthquake-proof or seismic isolation function.

In this embodiment, the pipe connection portion 310 has a structure in which a pair of C-type clamps 311 and 311' covers and surrounds the circumference of the pipe P. The C-type clamps 311 and 311' have connection plates 312 formed at both ends, so that the paired C-type clamps 311 and 311' are bolted to each other. Meanwhile, in this embodiment, the groove portion 313 is formed in one of the pair of C-type clamps 311 and 311'. Since the groove portion 313 is a section that defines the position of the heater 400, the groove portion 313 is formed so that the heater 400, especially the heating portion 410, is located at the lower part of the pipe (P). For reference, a heated fluid has a tendency to rise compared to a cold fluid due to its relatively low density. Therefore, it is desirable to have the heater 400 heat the lower part of the pipe (P) in order to increase the heat diffusion rate for the fluid moving through the pipe (P).

The support part (S) is composed of a support unit 330 connected to the pipe connection part 310 to which the pipe (P) is connected, and an attachment unit 320 that fixes the support unit 330 to the structure (B). The attachment unit 320 has a structure in which the main body is attached to the structure (B) by an anchor, and the support unit 330 is rotatably connected to the attachment unit 320. As described above, the support unit 330 may be of round bar type or wire type depending on the installation location of the pipe (P) and the specifications of the pipe (P).

Meanwhile, the support unit 330 of the round bar type may be directly connected to the pipe connection part 310, but in this embodiment, the support unit 330 is rotatably connected to the pipe connection part 310 via an adapter 340. . As described above, the adapter 340 connecting the pipe connection 310 and the support unit 130 may vary depending on whether the anti-shake brace 300 is a longitudinal brace type or a lateral brace type. .

Since the anti-shake brace 300 is already a known technology, detailed description thereof will be omitted.

Figure 7 is a partial cross-sectional view showing the piping installation structure of the freeze prevention equipment according to the present invention, and Figure 8 is a flow chart sequentially showing the construction method of the freeze prevention equipment according to the present invention.

Referring to FIGS. 2 to 8, in the freeze prevention facility construction method according to the present invention, the pipe connection portion 310 on which the heater 400 is installed is mounted on the pipe (P) and the structure (B) is connected to the structure (B) through the support portion (S). The first step of fixing (S10); A second step (S20) of connecting the pipe (P) and other pipes to form a pipe path, mounting the pipe connection part 310 to the other pipe, and fixing it to the structure (B) through the support portion (S); A third step (S30) of mounting the power confirmation box 220, which is electrically connected to the main wire (L2), to a specific pipe (P); A fourth step (S40) of electrically connecting the sub wire (L1) branched from the main wire (L2) to the heating unit 410 of the heater 400 through the power check box 220; A product that surrounds the pipe (P) and the other pipe with insulation materials (W1, W4) so that the support portion (S) and the power confirmation box (220) mounted on the pipe (P) and the other pipe in the pipe route are exposed, respectively. Includes step 5 (S50);

To describe each step in more detail, the pipe connection portion 310 in which the heater 400 is integrally installed is mounted on the pipe (P). Since the installation structure of the heater 400 to the pipe connection part 310 has been described above, its description is omitted here.

The pipe connection portion 310 of the anti-shake brace 300 is connected to one end of the support unit 330, which is a component of the support portion S, and the other end of the support unit 330 is connected to the attachment unit 320. Therefore, the support unit 330 fixed to the structure (B) by the attachment unit 320 supports the pipe connection portion 310, so the pipe (P) is stably fixed to the structure (B) (S10).

Thereafter, in order to construct a pipeline, other pipes are connected to the pipe (P) in series, and an anti-shake brace (300) is mounted on the other pipe to secure the other pipe to the structure (B) (S20). At this time, the heater 400 may or may not be installed in the pipe connection portion 310 of the anti-shake brace 300 mounted on the other pipe according to relevant laws and regulations.

When the piping route is completed, the power confirmation box 220 is mounted on the pipe (P) or another pipe along the piping route (S30). When installing the power check box 220 for the pipe (P), the main wire (L2) may already be electrically connected to the power check box 220, and the main wire (L2) may be connected after installing the power check box 220. It can also be connected electrically. The main wire (L2) is electrically connected to the control module 500, which controls the energization of the main wire (L2) for ON/OFF control of the heater 400.

In the power check box 220, the main wire (L2) branches off the sub wire (L1) and is electrically connected to the heating unit 410 of the heater 400 (S40). Therefore, the power of the main wire (L2) is provided to the heating unit 410 through the sub wire (L1). In addition, the power check box 220 determines the energization state of the sub wire (L1) and checks whether the power check box 220 connected to the sub wire (L1) is operating.

Once construction of the piping route, installation of the power check box 220, and wiring of the main wire (L2) and sub-wire (L1) are completed, the support unit (S) and the power source respectively mounted on the piping (P) and other pipes in the piping route The circumference of the pipe (P) and the other pipes is wrapped with insulation materials (W1, W4) so that the confirmation box 220 is exposed (S50). The insulation materials (W1, W4) surrounding the pipe (P) can be sealed through external taping, or the open sections of the insulation materials (W1, W4) can be sealed by applying adhesive to the open ends of the insulation materials (W1, W4). .

In this embodiment, the power check box 220 is placed relatively adjacent to the piping connection part 310, and a single insulating material (W4) is used around the pipe perimeter of the section where the power check box 220 and the piping connection part 310 are mounted. wrap it around Therefore, in the piping path, between the insulation material (W4) in the section where the power check box 220 and the pipe connection part 310 is installed and the insulation material (W1) in the section where the power check box 220 and the pipe connection part 310 are not installed. Since the number of boundary points can be reduced, the amount of leakage at the boundary for the warmth of the pipe (P) can be dramatically reduced and a stable winterization effect can be expected. In addition, since the power confirmation box 220 and the support part (S) can be concentrated at one point in the piping route, on-site processing of the insulation material (W4) to expose the power confirmation box 220 and the support part (S) is performed. It can be processed at one time at one point, and through this, freeze prevention equipment can be efficiently constructed on site.

Although the detailed description of the present invention described above has been described with reference to preferred embodiments of the present invention, those skilled in the art or those skilled in the art will understand the spirit of the present invention as described in the patent claims to be described later. It will be understood that the present invention can be modified and changed in various ways without departing from the technical scope.

100; Anti-sway brace 110; Piping connection
120; Attachment unit 130; support unit
140; adapter 200; Freeze prevention equipment
210; heater 220; Power check box
300; Anti-sway brace 310; Piping connection
320; Attachment unit 330; support unit
340; adapter 400; heater
410; Heating unit 420; connecting protrusion
430; Fixed flange 440; anchor bar

Claims (8)

A fixing flange provided with a heating part 410 that is in close contact with the pipe (P) and heated, a connecting protrusion 420 protruding from one side of the heating part 410, and a through hole (H1) and formed on the connecting protrusion 420. A heater (400) equipped with (430) and an anchor bar (440) fastened through the through hole (H1) of the fixing flange (430); and
A pipe connection portion 310 that surrounds the pipe (P) and is detachably fixed and has a groove 313 formed on the surface facing the pipe (P) so that the connection protrusion 420 of the heater 400 can be inserted through and engaged with the pipe (P), An anti-shake brace (300) equipped with a support portion (S) for fixing the pipe connection portion (310) to the structure (B) to support the pipe (P);
A freeze prevention mechanism with a pipe support function comprising a. According to claim 1,
The connection protrusion 420 is formed so that the fixing flange 430 is located at a distance greater than the width of the pipe connection part 310, and the fixing flange 430 is such that the through hole (H1) is exposed to the outer surface of the pipe connection part 310. is formed;
The anchor bar 440 penetrating the through hole (H1) has a structure that covers the outer surface of the pipe connection portion 310;
A freeze prevention mechanism with a pipe support function, characterized by According to claim 2,
The end of the anchor bar 440 is engaged with the heating unit 410;
A freeze prevention mechanism with a pipe support function, characterized by According to claim 1,
A connection flange 314 facing the fixing flange 430 protrudes from the outer surface of the piping connection part 310, and a connection hole (H2) communicating with the through hole (H1) of the fixing flange (430) is a connection flange. It is formed at 314, and the anchor bar 440 passing through the through hole (H1) is inserted into the connection hole (H2) of the connection flange (314);
A freeze prevention mechanism with a pipe support function, characterized by According to claim 1,
An insertion hole is formed on one side of the piping connection part 310 facing the fixing flange 430, and the anchor bar 440 passing through the through hole (H1) is inserted into the insertion hole of the piping connection part 310. thing;
A freeze prevention mechanism with a pipe support function, characterized by The method according to any one of claims 1 to 5,
The pipe connection portion 310 has a structure in which a pair of C-shaped clamps 311 and 311' covers and surrounds the circumference of the pipe P;
A freeze prevention mechanism with a pipe support function characterized by . A first step of mounting the piping connection part 310 on which the heater 400 is installed to the piping (P) and fixing it to the structure (B) via the support part (S);
A second step of forming a pipe path by connecting the pipe (P) and another pipe, mounting a pipe connection part 310 on the other pipe, and fixing it to the structure (B) via a support portion (S);
A third step of mounting the power confirmation box 220, which is electrically connected to the main wire (L2), to a specific pipe (P);
A fourth step of electrically connecting the sub wire (L1) branched from the main wire (L2) to the heating unit 410 of the heater 400 through the power check box 220; and
A product that surrounds the pipe (P) and the other pipe with insulation materials (W1, W4) so that the support portion (S) and the power confirmation box (220) mounted on the pipe (P) and the other pipe in the pipe route are exposed, respectively. Step 5;
A freeze prevention facility construction method comprising: According to claim 7,
In the third step, the power confirmation box 220 is placed relatively adjacent to the piping connection part 310;
In the fifth step, wrapping a single insulation material (W4) around the pipe in the section where the power confirmation box 220 and the pipe connection part 310 are installed;
A freeze prevention facility construction method characterized by: