JP2017057969A - Pipeline support structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a structure capable of mainly preventing deviation between a pipeline and a pipeline holding part.SOLUTION: In a pipeline support structure 5, to a through hole 3 formed on a floor slab 2 of a building 1, a pipeline 4 is arranged in a penetratable manner. In the vicinity of a penetration portion of the pipeline 4 to the through hole 3, an enlarged diameter part integrated with the pipeline 4 is formed. Between the enlarged diameter part and the floor slab 2, attached to a pipeline holding part configured to hold a position of the enlarged diameter part to the floor slab 2 regardless of thermal expansion of the pipeline 4.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a pipe support structure.

  A pipe fixing tool is used to fix the pipe to the building (see, for example, Patent Document 1).

  Such a pipe fixture is a fixture for fixing provided with a fixing part for a building and a clamp part for the pipe.

JP 2006-283814 A

  However, since the piping fixture described in Patent Document 1 is configured to clamp the pipe with the clamp portion, there is a problem that the clamp portion is displaced with respect to the pipe when thermal expansion or contraction occurs in the pipe. there were.

  In this way, when the clamp part is displaced from the pipe, for example, the pipe is displaced in the longitudinal direction (for example, the upper end side of the pipe) as a whole due to repeated thermal expansion and contraction, and a defective fitting with respect to the building occurs. May cause problems such as sudden bending at the upper end of the pipe due to the top end of the pipe being abutted against the ceiling of the building or concentration of stress at the branch of the branch pipe connected to the pipe. .

  Accordingly, the main object of the present invention is to solve the above-described problems.

In order to solve the above problems, the present invention provides:
Piping is arranged through the through hole formed in the floor slab of the building,
In the vicinity of the penetrating part of the pipe with respect to the through hole, an enlarged diameter part integrated with the pipe is formed,
A pipe support structure in which a pipe holding part that holds the position of the enlarged diameter part with respect to the floor slab is attached between the enlarged diameter part and the floor slab regardless of thermal expansion and contraction of the pipe.

  According to the present invention, the above configuration can prevent the displacement between the pipe and the pipe holding portion.

It is a side view showing the 1st example of the piping support structure concerning this embodiment. It is a side view which shows the 2nd Example of a piping support structure. It is a perspective view of a metal horizontal member. It is a top view of a metal horizontal member. It is a side view which shows the 3rd Example of piping support structure. It is a side view which shows the 4th Example of a piping support structure. It is a side view showing the 5th example of piping support structure. It is a side view which shows the modification of FIG. (A) is a side view which shows the 6th Example of a piping support structure. (B) is a side view of the enlarged diameter part of (a). It is a figure which shows the state which applied the piping support structure in any one of the 1st-6th Example with respect to the vertical piping (longitudinal pipe) installed in the building. It is a figure similar to FIG. 7 which shows the state which heat expansion / contraction produced in piping. FIG. 8 is a view similar to FIG. 7 showing a state where thermal expansion and contraction has occurred in the pipe when the pipe support structure is not applied.

Hereinafter, the present embodiment will be described in detail with reference to the drawings.
1 to 9 are for explaining this embodiment. Of these, FIGS. 1 to 6 show specific examples 1 to 6, respectively, FIG. 7 is a building to which any of the pipe support structures of FIGS. 1 to 6 is applied, and FIG. FIG. 9 shows a state in which the pipe support structure is not applied, and FIG. 9 shows a state where the pipe support structure is not applied.

  <Configuration> The configuration will be described below.

(1) As shown in FIG. 7, a pipe 4 is disposed through a wall or floor of a building 1, particularly a through hole 3 formed in a floor slab 2. The following pipe support structure 5 is applied to such a pipe 4.
As shown in any of FIGS. 1 to 6, an enlarged diameter portion 7 integrated with the pipe 4 is formed in the vicinity of the through portion 4 h of the pipe 4 with respect to the through hole 3.
A pipe holding portion 8 that holds the position of the enlarged diameter portion 7 with respect to the floor slab 2 is attached between the enlarged diameter portion 7 and the floor slab 2 regardless of the thermal expansion and contraction of the piping 4.

  Here, the building 1 is made of reinforced concrete having a multi-level hierarchical structure.

  The floor slab 2 is, for example, a hierarchical space wall (floor slab or the like) of the building 1.

  The through hole 3 is sufficiently large with respect to the pipe 4 (and through which the enlarged diameter portion 7 passes). The through hole 3 is finally buried by the mortar 11.

  As shown in FIG. 7, in this case, the pipe 4 is a vertical pipe extending in the vertical direction. From the middle of the pipe 4, another pipe (horizontal pipe 13) extending in the lateral direction is connected to each floor via the branch joint 12. For the uppermost floor, a horizontal pipe 13 is connected to the upper end of the pipe 4 via a bent joint such as an elbow 14 or a T-shaped joint with an air valve. However, the pipe 4 described above may be a horizontal pipe 13 or the like.

  The pipe 4 is, for example, a hot water pipe or a cold water pipe. In the case of a hot water pipe or a cold water pipe, a heat insulating material 15 such as glass wool, rock wool, polyethylene foam, or polystyrene foam is generally attached to the outer periphery of the pipe 4 or the horizontal pipe 13.

  Steel pipes are usually used for such hot water pipes and cold water pipes, but the use of resin pipes instead of steel pipes has been studied. However, when resin pipes are used for hot water pipes and cold water pipes, the amount of heat expansion and contraction due to the heat (hot and cold) of the fluid flowing inside becomes much larger than that of steel pipes. Since the metal pipe fixture having the fixing part and the clamp part for the pipe 4 cannot hold the pipe 4 (particularly the vertical pipe), a new pipe support structure 5 suitable for the resin pipe is required. Become.

  When the pipe 4 is a resin pipe, for example, a polyethylene pipe, a polybutene pipe, a polypropylene pipe, a vinyl chloride pipe, a crosslinked polyethylene pipe, a polypropylene composite pipe, a polyethylene composite pipe, or the like can be used as the resin pipe. Polypropylene composite pipes and polyethylene composite pipes can be pipes having an oxygen barrier layer for preventing rust such as pipes in air conditioners and a fiber reinforced layer for suppressing thermal expansion and contraction. Examples of the vinyl alcohol copolymer (EVOH) resin, aluminum, and fiber reinforced layer include resins such as polyethylene and polypropylene containing glass fibers and carbon fibers. The structure of the polypropylene composite tube and the polyethylene composite tube includes, in order from the surface layer, an oxygen barrier layer, an adhesive layer for adhering the oxygen barrier layer and the resin layer, a resin layer to be fused with an electrothermal fusion joint described later, and a fiber reinforced layer And a resin layer, and the resin used for the resin layer and the fiber reinforced layer preferably contains the same resin material.

  The pipe support structure 5 is provided, for example, on at least the floor slab 2 of the uppermost floor 1A and the lowermost floor 1B of the building 1. When the building 1 is tall, it is appropriately attached between the uppermost floor 1A and the lowermost floor 1B, for example, every second floor or every third floor. In addition, on the lower side (lower floor 1C) of the floor slab 2 of the lowest floor 1B of the building 1, another horizontal pipe 16 extending in the horizontal direction is installed at the lower end of the pipe 4, and the lower end of the pipe 4 is You may provide the support part 17 to support. When the other horizontal pipe 16 or the support portion 17 exists on the lower side, the pipe 4 is displaced upward by thermal expansion and contraction. The horizontal pipe 13 and the horizontal pipe 16 described above can be fixed without any trouble even by using an existing metal pipe fixture 18 having a fixing part for the building 1 and a clamp part for the pipe 4. it can. However, it goes without saying that the pipe support structure 5 of this embodiment may be used in a wall penetration portion or the like.

  As shown in FIGS. 1 to 6, the enlarged diameter portion 7 is literally a partially enlarged diameter of the pipe 4. For the enlarged diameter portion 7, for example, a joint (electric heat fusion joint 21) having an electric heat fusion mechanism can be used. This electric heat fusion joint 21 is obtained by softening and melting the resin constituting the electric heat fusion joint 21 with heat and fusing it with the resin pipe 4. It has a heating coil 22 embedded in the vicinity of the inner surface of the joint body made of the same resin, and has a terminal portion 23 for supplying power to the heating coil 22 on the outer surface. The electrothermally welded joint 21 is integrated with the pipe 4 whose surface has been cut in advance by heat-fitting the pipe 4 and energizing the terminal portion 23 to heat the heating coil 22. And by this electric heat fusion joint 21, the enlarged diameter part 7 has the level | step-difference part 24 with respect to the piping 4 in both ends.

  The pipe holding unit 8 is configured to hold the position of the enlarged diameter portion 7 (the longitudinal direction of the pipe 4) with respect to the floor slab 2 at a constant level.

  Hereinafter, the arrangement of the enlarged diameter portion 7 and the pipe holding portion 8 will be described.

  (2) As shown in FIGS. 2 to 6, the enlarged diameter portion 7 and the pipe holding portion 8 restrict displacement of the enlarged diameter portion 7 to at least the other side with respect to one side of the floor slab 2. It may be installed so that it can.

  Here, in FIGS. 2, 3, 5, and 6, one side of the floor slab 2 is an upper surface side of the floor slab 2, and the other side of the floor slab 2 is a lower surface side of the floor slab 2. In FIG. 4, one side of the floor slab 2 is the lower surface side of the floor slab 2, and the other side of the floor slab 2 is the upper surface side of the floor slab 2. However, the top and bottom may be reversed.

  (3) As shown in FIG. 1, the enlarged diameter portion 7 and the pipe holding portion 8 are displaced to one side of the enlarged diameter portion 7 and displaced to the other side with respect to both sides of the floor slab 2. You may install so that both can be controlled.

  Here, in FIG. 1, the combination of the enlarged diameter portion 7 and the pipe holding portion 8 on one side of the floor slab 2 is set to be opposite to each other with respect to both sides of the floor slab 2. ing. 2 to 6, two sets may be installed on both sides of the floor slab 2 such that the combination of the enlarged diameter portion 7 and the pipe holding portion 8 is opposite to each other. Moreover, about the thing of FIG. 1, you may make it install the combination of the enlarged diameter part 7 and the piping holding part 8 only in the one side of the floor slab 2 similarly to FIGS.

  Hereinafter, a basic structure of the pipe holding unit 8 will be described.

(4) The pipe holding part 8 has a hole-shaped part 31 having a size that does not allow the enlarged diameter part 7 to pass through the pipe 4 and has a lateral part 32 that is larger than the through-hole 3 of the floor slab 2. The frame member 33 is used.
The horizontal member 33 is locked or fixed around the through hole 3 of the floor slab 2 with the pipe 4 passing through the hole 31 and the expanded diameter portion 7 locked. I try to do it.

Here, the horizontal member 33 may be a flange ring made of resin such as polyvinyl chloride as shown in FIGS. In this case, the planar shape of the horizontal member 33 is preferably a circular shape, but may be a polygonal shape or other shapes, for example.
Or it is good also as a metal thing (metal fitting) as shown in FIGS. For example, as shown in FIGS. 2A and 2B, the metal horizontal member 33 is formed by combining two metal band members 38 having a semicircular recess substantially equal to the outer diameter of the pipe 4 in the intermediate portion. The shape portion 31 and the outer shape portion 32 can be formed. The two metal band members 38 are integrally fixed by a fastener (fixture 39) such as a bolt and nut. The horizontal member 33 described above may be provided with a leg portion 37 that can be fixed to the floor slab 2 with a bolt 36 substantially in a plane. The above-described leg portions 37 have at least the same length as or longer than the electric heat fusion joint 21 and are provided in the circumferential direction. In this case, a pair of left and right legs 37 are provided at both ends of the horizontal member 33, but three or more legs 37 may be provided. In addition, when the through-hole 3 of the floor slab 2 is large, each leg part 37 is good also as a thing of the shape opened in the C shape which straddles the through-hole 3, etc.

  Hereinafter, a more specific embodiment of the pipe support structure 5 will be described.

  (5) In the embodiment of FIG. 1, the pipe holding portion 8 is installed between the enlarged diameter portion 7 and the floor slab 2.

  In this case, with the lower surface of the pipe holding portion 8 (horizontal member 33) in contact with the upper surface of the floor slab 2, the enlarged diameter portion 7 (electrical portion 7) is formed on the upper surface of the pipe holding portion 8 (horizontal member 33). The enlarged diameter portion 7 is attached without a gap so that the lower end portion of the heat-sealing joint 21) contacts. However, even if a slight gap of about 1 mm to 3 mm is generated between the lower end portion of the enlarged diameter portion 7 and the upper surface of the pipe holding portion 8 or between the lower surface of the pipe holding portion 8 and the upper surface of the floor slab 2. Permissible.

  In addition, in the state where the upper surface of the pipe holding portion 8 (horizontal member 33) is in contact with the lower surface of the floor slab 2, the enlarged diameter portion 7 (electric heat) is formed on the lower surface of the pipe holding portion 8 (horizontal member 33). The enlarged diameter portion 7 is attached without a gap so that the upper end portion of the fusion joint 21) contacts. However, even if a slight gap of about 1 mm to 3 mm is generated between the upper end portion of the enlarged diameter portion 7 and the lower surface of the pipe holding portion 8 or between the upper surface of the pipe holding portion 8 and the lower surface of the floor slab 2. Permissible.

  In FIG. 1, the pipe holding portion 8 (horizontal member 33) is fixed to the floor slab 2 in a direction perpendicular to the floor slab 2, but the two pipe holding portions 8 (horizontal member 33) are fixed. Therefore, the bolt 36 is not always necessary.

  (6) In the embodiment of FIG. 2, the pipe holding part 8 is provided between the two enlarged diameter parts 7.

  In this case, the upper and lower electrothermal fusion joints 21 are attached so as to sandwich the upper and lower surfaces of the horizontal member 33 with the legs 37 of the metal horizontal member 33 fixed to the floor slab 2 with bolts 36. Yes. However, a slight gap of about 1 mm to 3 mm is allowed between the both sides of the horizontal member 33 and the enlarged diameter portion 7.

  (7) In the embodiment of FIGS. 3 and 4, the pipe holding portion 8 is provided so as to sandwich both sides of the enlarged diameter portion 7.

  In this case, the upper and lower surfaces of the electric heat fusion joint 21 attached to the pipe 4 are sandwiched between two metal horizontal members 33, and the legs 37 of the horizontal members 33 are fixed to the floor slab 2 with bolts 36. I try to fix it. The two metal horizontal members 33 may be integrally connected by a connecting member or the like. However, even a slight gap of about 1 mm to 3 mm is allowed between both end portions of the enlarged diameter portion 7 and the horizontal member 33.

  3 shows a case where the floor slab 2 is provided on the upper surface side, and FIG. 4 shows a case where the floor slab 2 is provided on the lower surface side. In FIG. 4, the branch joint 12 for connecting the horizontal pipe 13 is an electrothermal fusion joint 21. The horizontal pipe 13 is further connected to the branch joint 12 via another electric heat fusion joint 21a. And inside the above-mentioned electrothermal fusion joint 21, the upper pipe 4a and the lower pipe 4b are joined.

  (8) In the embodiment of FIG. 5, the pipe holding portion 8 is provided integrally with the enlarged diameter portion 7.

In this case, the horizontal member 33 is integrally provided at the lower end portion of the electric heat fusion joint 21. The resin horizontal member 33 is directly fixed to the upper surface of the floor slab 2 with bolts 36 in the direction perpendicular to the surface. However, a slight gap of about 1 mm to 3 mm is allowed between the horizontal member 33 and the floor slab 2.
5A, the horizontal member 33 may be integrally provided at the upper end portion of the electrothermal fusion joint 21. In this case, the horizontal member 33 is fixed to the floor slab 2 via the legs 37.

  (9) In the embodiment of FIG. 6, the pipe holding portion 8 is fitted into a groove portion 41 formed in the intermediate portion of the enlarged diameter portion 7.

  (10) In each of the above cases, the heat insulating material 51 (glass wool) is attached around the through portion 4 h with respect to the through hole 3 of the pipe 4.

  In this case, the heat insulating material 51 is glass wool or the like. However, a heat insulating material 51 other than glass wool may be used.

  Furthermore, a fireproof sheet 52 is further wound around the heat insulating material 51. The refractory sheet 52 includes, for example, thermally expandable graphite so that the thermally expandable graphite is thermally expanded at the time of occurrence of a fire or the like so as to close the through hole 3.

  As described above, the mortar 11 is placed between the fireproof sheet 52 and the through hole 3.

  <Effect> According to this embodiment, the following effects can be obtained.

  (Operation Effect 1) The piping 4 is disposed through the through hole 3 formed in the floor slab 2 of the building 1. Thereby, for example, a hot water pipe or a cold water pipe that passes through the upper and lower hierarchical spacing walls (floor slab 2) of the building 1 and extends in the vertical direction can be installed.

  An enlarged diameter portion 7 integrated with the pipe 4 was formed in the vicinity of the through portion 4 h with respect to the through hole 3 of the pipe 4. Thereby, the enlarged diameter portion 7 can be determined at a position fixing point in the pipe 4 that is thermally expanded and contracted, and a position fixing point of the pipe 4 with respect to the building 1 can be determined in the vicinity of the through hole 3. Further, the enlarged diameter portion 7 can be used as an attachment portion of the pipe holding portion 8 with respect to the pipe 4.

  A pipe holding portion 8 was attached between the enlarged diameter portion 7 and the floor slab 2. Thereby, since the pipe holding part 8 can be easily attached using the enlarged diameter part 7, the construction time can be shortened.

  Further, when the pipe 4 is thermally expanded and contracted, the position of the enlarged diameter portion 7 can be held near the floor slab 2 by the piping holding portion 8 attached between the enlarged diameter portion 7 and the floor slab 2. . At this time, since the enlarged diameter portion 7 is integrated with the pipe 4, the pipe holding portion 8 is displaced along the pipe 4 by attaching the pipe holding portion 8 using the enlarged diameter portion 7. This can be prevented, and the pipe holding portion 8 can be firmly installed. As a result, the fixing property between the pipe 4 and the floor slab 2 is enhanced, and the influence of thermal expansion and contraction of the pipe 4 is absorbed as the bending of the pipe 4 between the pipe holding portions 8 as shown in FIG. Become. Therefore, for example, as shown in FIG. 9, the displacement between the pipe 4 and the pipe holding portion 8 causes the pipe 4 to be displaced in the longitudinal direction (for example, the upper end side of the pipe 4) as a whole. 1 or the upper end side of the pipe 4 displaced upward hits the ceiling portion 2a of the building 1 and a sharp bend occurs at the upper end side, or the branch pipe 13 connected to the pipe 4 branches off. It is possible to prevent such a problem that stress is concentrated on the joint 12 or the like, or the pipe fixture 18 that supports the horizontal pipe 13 is damaged.

  (Effect 2) The enlarged diameter portion 7 and the pipe holding portion 8 are provided on one side of the floor slab 2 so as to restrict the displacement of the enlarged diameter portion 7 to at least the other side. Thereby, the support structure which prevents effectively the displacement to the other side of the enlarged diameter part 7 at least with respect to the thermal expansion and contraction of the piping 4 can be obtained. Moreover, since the enlarged diameter part 7 and the piping holding part 8 should just be provided only in one side of the floor slab 2, construction can be made easy.

  (Effect 3) The enlarged-diameter part 7 and the pipe holding part 8 are provided on both sides of the floor slab 2 so as to restrict both the displacement toward the one side and the displacement toward the other side. Thereby, the support structure which prevents effectively the displacement of the enlarged diameter part 7 with respect to the thermal expansion-contraction of the piping 4 can be obtained. Further, by providing the enlarged diameter portion 7 and the pipe holding portion 8 on both sides of the floor slab 2, a stronger and more reliable construction state can be obtained.

  (Effect 4) The pipe holding part 8 was used as the horizontal member 33. Then, the enlarged diameter portion 7 is locked to the hole-shaped portion 31 of the horizontal member 33 through the pipe 4, and the outer portion 32 is locked or fixed around the through hole 3 of the floor slab 2. Thereby, the piping holding part 8 can restrain the displacement of the enlarged diameter part 7 effectively with a simple structure.

  (Effect 5) The piping holding part 8 was installed between the enlarged diameter part 7 and the floor slab 2. As shown in FIG. Thereby, the enlarged diameter part 7 and the piping holding | maintenance part 8 can be installed collectively in a small space compactly.

  (Operation Effect 6) A pipe holding portion 8 is provided between the two enlarged diameter portions 7. Thereby, the displacement to the both directions of the enlarged diameter part 7 at the time of expansion / contraction of the piping 4 can be restrained with the two enlarged diameter parts 7. FIG. Further, the piping holding part 8 can be easily installed by sandwiching the pipe holding part 8 between the two enlarged diameter parts 7.

  (Effect 7) The piping holding part 8 was provided so that the both sides of the enlarged diameter part 7 might be pinched | interposed. Thereby, the displacement to the both directions of the enlarged diameter part 7 at the time of expansion / contraction of the piping 4 can be restrained at once by the piping holding part 8 which pinches the both sides of the enlarged diameter part 7. FIG. Moreover, the number of installation of the enlarged diameter part 7 can be decreased.

  (Effect 8) The pipe holding part 8 was integrally provided in the said enlarged diameter part 7. FIG. Thereby, the simple structure which put together the enlarged diameter part 7 and the piping holding part 8 is obtained. In addition, by fixing the pipe holding portion 8 around the through hole 3, the displacement of the enlarged diameter portion 7 in both directions when the pipe 4 is expanded and contracted can be restricted at a time.

  (Effect 9) The pipe holding part 8 was fitted in the groove part 41 formed in the intermediate part of the enlarged diameter part 7. Thereby, the displacement to the both directions of the enlarged diameter part 7 at the time of expansion / contraction of the piping 4 can be restrained at once by the one enlarged diameter part 7. FIG.

  (Effect 10) The heat insulating material 51 was attached to the penetration part 4h of the piping 4. FIG. Thereby, heat insulation is securable also about the penetration part 4h of the piping 4. FIG. And lack of heat insulation can be eliminated.

  As mentioned above, although embodiment of this invention has been explained in full detail with drawing, embodiment is only an illustration of this invention. Therefore, the present invention is not limited only to the configuration of the embodiment, and it goes without saying that design changes and the like within a scope not departing from the gist of the present invention are included in the present invention. Further, for example, when each embodiment includes a plurality of configurations, it is a matter of course that possible combinations of these configurations are included even if not specifically described. In addition, in the case where a plurality of examples and modifications are disclosed in the embodiment as those of the present invention, possible combinations of combinations extending over these are included even if not specifically described. Of course. Further, the configuration depicted in the drawings is of course included even if not particularly described. Further, when there is a term of “etc.”, it is used in the sense that the equivalent is included. In addition, when there are terms such as “almost”, “about”, “degree”, etc., they are used in the sense that they include those in the range and accuracy recognized by common sense.

DESCRIPTION OF SYMBOLS 1 Building 2 Floor slab 3 Through-hole 4 Piping 4h Through-hole 5 Piping support structure 7 Expanded diameter part 8 Piping holding part 31 Hole-shaped part 32 Outer part 33 Horizontal member 41 Groove part 51 Thermal insulation

Claims (10)

Piping is arranged through the through hole formed in the floor slab of the building,
In the vicinity of the penetrating part of the pipe with respect to the through hole, an enlarged diameter part integrated with the pipe is formed,
A pipe support structure in which a pipe holding part that holds the position of the large diameter part with respect to the floor slab is attached between the enlarged diameter part and the floor slab regardless of thermal expansion and contraction of the pipe. . In the piping support structure according to claim 1,
The pipe support structure, wherein the enlarged diameter part and the pipe holding part are installed with respect to one side of the floor slab so as to restrict displacement of the enlarged diameter part to at least the other side. In the piping support structure according to claim 1,
The enlarged diameter part and the pipe holding part are installed on both sides of the floor slab so as to be able to regulate both displacement to one side of the enlarged diameter part and displacement to the other side. Piping support structure. In the piping support structure according to any one of claims 1 to 3,
The pipe holding part has a hole-like part that does not allow the enlarged diameter part to pass through the pipe, and is a horizontal member having a larger outer part than the through hole of the floor slab,
The pipe support is characterized in that the pipe is passed through the hole-shaped part and the enlarged-diameter part is locked, and the outer part is locked or fixed around the through hole of the floor slab. Construction. In the piping support structure according to claim 4,
The pipe support structure, wherein the pipe holding part is installed between the enlarged diameter part and a floor slab. In the piping support structure according to claim 4,
The pipe support structure, wherein the pipe holding part is provided between the two enlarged diameter parts. In the piping support structure according to claim 4,
The pipe support structure, wherein the pipe holding part is provided so as to sandwich both sides of the enlarged diameter part. In the piping support structure according to claim 4,
The pipe support structure, wherein the pipe holding part is provided integrally with the enlarged diameter part. In the piping support structure according to claim 4,
The pipe support structure, wherein the pipe holding part is fitted in a groove part formed in an intermediate part of the enlarged diameter part. In the piping support structure according to any one of claims 1 to 9,
A pipe support structure, wherein a heat insulating material is attached around a through portion with respect to a through hole of the pipe.