JP6622585B2 - Piping structure - Google Patents

Description

  The present invention relates to a piping structure.

  In a multi-storied building, a vertical pipe that penetrates each floor and extends vertically is provided (for example, see Patent Document 1).

  A horizontal pipe extending in the horizontal direction is connected to a lower end portion of the vertical pipe via an elbow-shaped joint member.

JP 2006-283814 A

  In such a piping structure, the weight of the entire vertical pipe and the pressure of water flowing in the vertical pipe are applied to the joint member at the lower end of the vertical pipe.

  Furthermore, when hot water or the like is passed through the vertical pipe or the horizontal pipe, the vertical pipe or the horizontal pipe is thermally expanded by the heat of the hot water, and the load due to the thermal expansion of the vertical pipe or the horizontal pipe is also reduced by the lower end of the vertical pipe. It will act on this joint member.

  The elbow-shaped joint member is deformed so that the angle between the vertical pipe and the horizontal pipe changes due to the thermal extension of the vertical pipe, so that the piping structure itself may be damaged. May not be able to withstand

  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:
Inside the multi-story building, a vertical pipe that penetrates each floor and extends up and down,
A horizontal tube extending laterally from the lower end of the vertical tube;
In a piping structure having a joint member connecting the lower end of the vertical pipe and the end of the horizontal pipe,
A first fixing portion that regulates at least a lateral movement of the vertical pipe at a position above the floor surface of the lowest floor, the vertical pipe;
The horizontal pipe includes a second fixing portion that regulates the vertical movement of the horizontal pipe at a position below the floor surface of the lowest floor,
The vertical pipe is provided with an enlarged diameter portion, and the enlarged diameter portion is an electrothermal fusion joint ,
The vertical pipe is position-regulated so as to fix the position in the vertical direction by the first fixing part via the enlarged diameter part,
The second fixing portion is installed at a position above the joint member and supports the horizontal tube from above.

According to the present invention, the above structure can protect the piping structure against thermal expansion. At this time, the enlarged diameter portion can be used to fix the position of the vertical tube in the left-right direction regardless of the thermal expansion of the horizontal tube. Further, the enlarged diameter portion can be used as a position reference for fixing the vertical position of the vertical tube regardless of the thermal expansion of the vertical tube. Then, the first fixing portion is locked and fixed to the enlarged diameter portion provided by the electric heat fusion joint on the vertical tube, so that no positional deviation occurs between the first fixing portion and the vertical tube. Further, since the second fixing portion supports the horizontal pipe from the upper side of the joint member, the vertical pipe and the joint member can be appropriately supported even when the ground is uneven.

It is a side view which shows the whole structure of the building provided with the piping structure concerning a present Example. It is an enlarged view of the floor penetration part of the vertical pipe of FIG. It is an enlarged side view which shows the state of the vertical pipe and horizontal pipe in the lowest floor of FIG. It is an enlarged side view which shows the 1st fixing | fixed part of FIG. It is a perspective view of the 1st fixing | fixed part of FIG. It is a top view of the 1st fixing | fixed part of FIG. It is a side view of a 2nd fixing | fixed part. It is a side view of another 2nd fixing | fixed part.

Hereinafter, the present embodiment will be described in detail with reference to the drawings.
1 to 8 are for explaining this embodiment.

  <Configuration> The configuration will be described below.

  FIG. 1 shows a multi-storey building 1. The following piping structure 2 is provided inside the multi-storey building 1.

This piping structure 2 is
Inside the multi-storey building 1, a vertical pipe 3 extending vertically through each floor;
A horizontal tube 4 extending in the horizontal direction for each floor from the vertical tube 3 is provided.

  Here, the multi-storey building 1 is a building 1 having at least three stories. In this case, the multi-storey building 1 is assumed to have 10 levels from the first floor (1F) to the 10th floor (10F), but the level of the building 1 is not limited to this. It may be higher or lower than the floor. Moreover, an underground floor may be included. The building 1 is made of reinforced concrete, and each floor is partitioned by a reinforced concrete floor surface 11 (a floor slab serving as a layer interval wall).

  The above-described piping structure 2 is, for example, one constituting a hot water supply pipe for supplying hot water into the building 1.

  As shown in FIG. 2, the vertical pipe 3 serves as a main pipe and is installed so as to pass through a through-hole portion 12 formed in the floor surface 11. A heat-expandable refractory material 13 is wound around the through-hole portion 12 of the vertical pipe 3 and backfilled with mortar 14 from above.

  As the vertical pipe 3, a resin pipe having a larger amount of thermal expansion than a steel pipe is used. As this resin pipe, for example, a polyethylene pipe, a polybutene pipe, a polypropylene pipe, a vinyl chloride pipe, a cross-linked polyethylene pipe, a polypropylene composite pipe, a polyethylene composite pipe and the like can be used. The vertical pipe 3 does not necessarily have to be a resin pipe as a whole, and a part of the vertical pipe 3 or a joint may be a steel pipe.

Among these, the polypropylene composite tube and the polyethylene composite tube are, for example, in order from the inside, at least a first resin layer for passing hot water, a fiber reinforced layer for suppressing thermal expansion and contraction, and an electrothermal fusion joint described later. 45 (see FIG. 3) and a second resin layer for fusing, and a multilayer structure (multilayer pipe) in which the second resin layer is laminated. The first and second resin layers and the resin used for the fiber reinforced layer preferably include the same resin material. For the fiber reinforced layer, a resin such as polyethylene or polypropylene containing fibers such as glass fiber, carbon fiber, or inorganic fiber such as wollastonite can be used. Since the linear expansion coefficient of polyethylene and polypropylene is 10 × 10 ⁻⁵ / ° C. or more and the amount of thermal expansion is large, the linear expansion coefficient of the multilayer tube is 10 × 10 ⁻⁵ / ° C. Hereinafter, it is preferable to adjust so that it may become 5 * 10 < ^-5 > / ^degreeC or less more preferably. Thermal expansion and contraction can be reduced by setting the linear expansion coefficient of the multilayer tube to the above value.

  Furthermore, an oxygen barrier layer can be provided outside the second resin layer via an adhesive layer. The adhesive layer is provided for adhering the second resin layer and the oxygen barrier layer. The oxygen barrier layer is provided to prevent rusting of metal parts connected to the piping structure 2, for example, internal piping of an air conditioner. An ethylene vinyl alcohol copolymer (EVOH) resin, aluminum, or the like can be used for the oxygen barrier layer. The oxygen barrier layer is not limited to the outside of the second resin layer, but inside the first resin layer, between the first resin layer and the fiber reinforced layer, or between the fiber reinforced layer and the second resin layer. It can be provided in between.

  In this case, as shown in FIG. 3, the horizontal pipe 4 is a horizontal branch pipe (or a branch pipe) disposed along the lower surface side of the floor surface 11 (that is, the ceiling portion of the lower floor) on each floor. At the same time, it is supported by being suspended from the floor surface 11 by using a hanging tool 15. The horizontal pipe 4 can be the same pipe member (steel pipe or resin pipe) as the vertical pipe 3.

  A branch joint such as cheese is used for the connecting portion of the horizontal tube 4 to the vertical tube 3. In the vicinity of the connecting portion between the vertical tube 3 and the horizontal tube 4, an offset portion 51 having a shape offset in the vertical direction is installed. The offset portion 51 is a combination of two elbow joints 55 in a crank shape. “Offset” means that the horizontal pipe 4 absorbs the displacement to a predetermined level even when the vertical pipe 3 is displaced by connecting the horizontal pipe 4 or the like so as to form different axes using joint members. A configuration that can be used.

  A heat insulating material 16 is attached to the outside of the vertical tube 3 and the horizontal tube 4 as necessary. This heat insulating material 16 can also be provided with respect to the penetration part of the through-hole part 12 in the vertical pipe 3 (refer FIG. 4). The heat insulating material 16 will be described later.

  As shown in FIG. 1, a horizontal pipe 18 constituting a part of the main pipe is connected to a lower end portion of the vertical pipe 3 via an elbow-shaped joint member 17. The horizontal pipe 18 is also supported by being suspended from the lower surface side of the floor surface 11 by using a hanging tool 15 (see FIG. 7) similar to the horizontal pipe 4 of each floor. Here, the elbow-shaped joint member 17 is bent at 90 degrees.

  In addition to the basic or overall configuration as described above, this embodiment has the following configuration.

(1) The first fixing portion 21 that restricts the vertical pipe 3 at least in the horizontal direction at a position above the floor surface 11a of the lowest floor,
The horizontal pipe 18 is provided with a second fixing portion 23 (see FIG. 8) that restricts the vertical movement of the horizontal pipe 18 at a position below the floor surface 11a on the lowest floor.

  Here, the floor surface 11a of the lowest floor is the floor surface 11 that is the lowest among the floor surfaces 11 of each floor through which the vertical pipe 3 penetrates including the underground floor. The joint member 17 and the horizontal pipe 18 are disposed in the underfloor space 24 below the lowermost floor surface 11. Further, the movement of the vertical tube 3 in at least the horizontal direction is a horizontal movement of the vertical tube 3 due to thermal expansion of the horizontal tube 18. The vertical movement of the horizontal tube 18 is the vertical movement of the horizontal tube 18 due to thermal expansion of the vertical tube 3. In addition, cold / hot water type air conditioning equipment such as a pump is often installed on the lowest floor of the building 1, and if the amount of thermal expansion of the vertical pipe 3 is large in the vicinity of these equipment, the vertical pipe 3 and the cold / hot water type are installed. The load applied to the connection part with the air conditioning equipment increases. The reason why the first fixing portion 21 and the second fixing portion 23 are provided near the floor 11a on the lowest floor is to suppress this load. The first fixing part 21 and the second fixing part 23 will be described later.

(2) The vertical pipe 3 is provided with an enlarged diameter portion 41.
The vertical tube 3 is positionally regulated by the first fixing portion 21 through the enlarged diameter portion 41.
More specifically, the enlarged diameter portion 41 is partially provided with respect to the vertical tube 3.
The first fixing portion 21 is locked and fixed to the vertical tube 3 by the enlarged diameter portion 41.

  Here, the diameter-expanded portion 41 is literally a part of the diameter of the vertical tube 3 enlarged. The enlarged diameter portion 41 is provided integrally with the vertical tube 3. The enlarged diameter portion 41 is provided with respect to the installation position of the first fixed portion 21. The enlarged diameter portion 41 can be used to fix the position of the vertical tube 3 in the left-right direction regardless of the thermal expansion of the horizontal tube 18. Further, the enlarged diameter portion 41 can be used as a position reference for fixing the vertical position of the vertical tube 3 regardless of the thermal expansion of the vertical tube 3.

  In this case, for the diameter-expanded portion 41, for example, a joint (electric heat fusion joint 45) provided with an electric heat fusion mechanism can be used. The electric heat fusion joint 45 softens and melts the resin constituting the electric heat fusion joint 45 by heat and fuses it with a resin pipe (longitudinal tube 3) (or fixes the structure in a fused state). It is what I did. The electrothermal fusion joint 45 has a heating coil 46 embedded in the vicinity of the inner surface of a cylindrical joint body made of the same resin as the pipe to be fused, and supplies power to the heating coil 46 on the outer surface. The terminal portion 47 is provided (see FIG. 4).

  The electric heat fusion joint 45 is preliminarily cut on the surface (the oxygen barrier layer and the adhesive layer) by energizing the terminal portion 47 and heating the heating coil 46 in a state of being externally fitted to the vertical tube 3. It is integrated with the vertical tube 3 (second resin layer) by heat fusion. And by this electric heat fusion joint 45, the enlarged diameter part 41 has the level | step-difference part 48 with respect to the vertical pipe 3 in both ends. The first fixing portion 21 is locked and fixed using this stepped portion 48.

  On the other hand, as the first fixing portion 21, for example, the one shown in FIGS. 4 to 6 (mainly see FIG. 5) is used. The first fixing portion 21 is made of metal. The first fixing portion 21 includes two metal band members 25 having a semicircular recess having an inner diameter substantially equal to the outer diameter of the vertical tube 3 at the intermediate portion. Are attached so that the recesses face each other, and both ends thereof are fixed together so that an annular tube holding portion 26 that can be attached to the outer periphery of the vertical tube 3 and a connection extending in the radial direction from the tube holding portion 26 are provided. The clamp member includes a portion 27 and a fastener (fixture 28) such as a bolt and nut capable of coupling and fixing the coupling portions 27 to each other. Note that a rubber protective member or the like is interposed on the inner peripheral surface of the tube holding portion 26 in order to prevent the outer peripheral surface of the vertical tube 3 from being damaged.

  Furthermore, a leg portion 32 having a required length that can be fixed to the floor surface 11 (the upper surface thereof) with an anchor bolt 31 or the like is attached to the position of the connecting portion 27 in the first fixing portion 21 (FIG. 4). reference). A pair of left and right legs 32 are attached to both end portions (connecting portion 27) of the first fixing portion 21 (fastened together with the connecting portion 27 by a fixing tool 28). In this case, the leg portion 32 is longer than the electrothermal fusion joint 45 and is attached in a state of opening in a letter C shape so as to straddle the through-hole portion 12. In addition, it is preferable to interpose the heat insulating material 33 (refer FIG. 4) etc. between the leg part 32 and the floor surface 11. FIG.

  In the case of this embodiment, the first fixing portion 21 is sandwiched from above and below using a pair of upper and lower electric heat fusion joints 45.

  In addition, it is preferable that the through-hole portion 12 of the floor surface 11 has a size through which the electrothermal fusion joint 45 passes.

  (3) And as shown in FIG. 7, said 2nd fixing | fixed part 23 shall be installed in the position below the said joint member 17, and shall support the joint member 17 from the bottom.

  Here, the second fixing portion 23 includes a support base 71 installed on the bottom surface of the underfloor space 24 below the lowermost floor surface, and an elbow-shaped joint attached to the support base 71. The holding member 72 that can hold the member 17 is used.

  The support base 71 is a support block having a height capable of directly contacting the receiving portion of the joint member 17 with respect to the horizontal tube 18 from below. The holding member 72 is an inverted U-shaped holding member (bolt or band) that can hold the periphery of the receiving portion of the joint member 17 with respect to the horizontal tube 18 from above. The holding member 72 is bolted at both arms to the upper surface of the support block.

  (4) Alternatively, as shown in FIG. 8, the second fixing portion 23 may be installed at a position above the joint member 17 to support the horizontal tube 18 from above.

  Here, the second fixing portion 23 is a support plate 75 attached to the back surface of the lowermost floor surface, and the attachment portion 17 attached to the support plate 75 to the joint member 17 of the horizontal pipe 18. A holding member 76 capable of holding the periphery is used.

  The support plate 75 is a horizontal surface portion 75a serving as a mounting portion for the back surface of the lowermost floor surface, and a vertical surface that is suspended from the horizontal surface portion 75a toward the side portion of the opening portion for the joint member 17 of the horizontal pipe 18. An L-shaped metal fitting having a surface portion 75b is used. The holding member 76 is a laterally U-shaped holding member (bolt or band) that can hold the periphery of the receiving portion of the joint member 17 with respect to the horizontal tube 18. The holding member 76 is bolted at both arms to the vertical surface 75 b of the support plate 75.

  (5) Also, as shown in FIG. 2, at least the floor surface 11 on which the fixing portions 21 and 23 are installed, the above-described heat expansion type refractory material 13 (for example, registered trademark “Fibro”) In addition, as shown in FIGS. 3 and 4, a normal or heat expansion type heat insulating material 16 is provided on the floor surface 11 on which the fixing portions 21 and 23 are installed. May be.

  <Operation> The operation of this embodiment will be described below.

  In the piping structure 2 of this embodiment, warm water can be distributed to each floor of the building 1 via the horizontal pipe 4 by flowing warm water through the vertical pipe 3.

  At this time, the vertical tube 3, the horizontal tube 4, and the horizontal tube 18 are thermally expanded by flowing warm water.

  In addition, such a piping structure 2 can be used for a hot water supply facility or a cold / hot water air conditioning facility of the building 1.

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

  (Operation Effect 1) At least the horizontal movement of the vertical tube 3 is restricted by the first fixing portion 21, and the vertical movement of the horizontal tube 18 is restricted by the second fixing portion 23. Thereby, it becomes possible to regulate the movement of the joint member 17 with respect to the biaxial direction. Therefore, even if the vertical tube 3 or the horizontal tube 18 is thermally expanded in the vertical direction or the horizontal direction due to a high-temperature fluid flowing through the vertical tube 3 or the horizontal tube 18, the joint member 17 and its surroundings can be supported without any trouble. become able to.

  Thereby, it becomes possible to protect the piping structure 2 against thermal expansion of the vertical tube 3 and the horizontal tube 18.

  (Operation effect 2) The position of the vertical pipe 3 is regulated through the enlarged diameter portion 41 (provided in the vertical pipe 3). Specifically, the first fixing portion 21 was locked and fixed to the enlarged diameter portion 41 partially provided in the vertical pipe 3. As a result, no displacement occurs between the first fixed portion 21 and the vertical tube 3, so that the vertical tube 3 is completely in the vertical direction (and the horizontal direction) with respect to the building 1 at the position of the enlarged diameter portion 41. The position can be fixed. Therefore, it is possible to eliminate such a problem that the entire position of the vertical tube 3 with respect to the building 1 gradually shifts due to repeated thermal expansion and contraction, and the vertical tube 3 cannot be accommodated in the building 1.

  (Operation effect 3) The second fixing portion 23 supports the joint member 17 from the lower side of the joint member 17. As a result, the position directly below the vertical pipe 3 and the joint member 17 can be supported by the ground or the like, and the vertical pipe 3 and the joint member 17 can be reliably supported.

  (Effect 4) The 2nd fixing | fixed part 23 was made to support the horizontal pipe 18 from the upper side of the coupling member 17. FIG. Thereby, even when the ground is uneven, the vertical pipe 3 and the joint member 17 can be appropriately supported.

  (Effect 5) Moreover, the heat expansion type refractory material 13 is used at least with respect to the floor surface 11 in which the fixing parts 21 and 23 are installed. Furthermore, you may provide the normal or heat expansion type heat insulating material 16 with respect to the floor surface 11 in which the fixing | fixed parts 21 and 23 are installed. As described above, the piping structure 2 of the present embodiment has a characteristic that the displacement amount increases as the distance from the fixing portions 21 and 23 increases. Therefore, the floor close to the fixing portions 21 and 23 whose displacement amount is small in long-term use. By separately using a member such as a heat expansion type refractory material 13 or a normal or heat expansion type heat insulating material 16 for the surface 11, a system with high long-term reliability for fire prevention can also be realized.

  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 Piping structure 3 Vertical pipe 11 Floor surface 11a The floor surface of the lowest floor 13 Heat expansion type refractory material 16 (Heating expansion type) heat insulating material 17 Joint member 18 Horizontal pipe 21 1st fixing | fixed part 23 2nd Fixed part 41 Expanded part

Claims (3)

Inside the multi-story building, a vertical pipe that penetrates each floor and extends up and down,
A horizontal tube extending laterally from the lower end of the vertical tube;
In a piping structure having a joint member connecting the lower end of the vertical pipe and the end of the horizontal pipe,
A first fixing portion that regulates at least a lateral movement of the vertical pipe at a position above the floor surface of the lowest floor, the vertical pipe;
The horizontal pipe includes a second fixing portion that regulates the vertical movement of the horizontal pipe at a position below the floor surface of the lowest floor,
The vertical pipe is provided with an enlarged diameter portion, and the enlarged diameter portion is an electrothermal fusion joint ,
The vertical pipe is position-regulated so as to fix the position in the vertical direction by the first fixing part via the enlarged diameter part,
The second fixing portion is installed at a position above the joint member and supports the horizontal pipe from above.   2. The piping structure according to claim 1, wherein the first fixing portion is locked and fixed to the vertical piping by the enlarged diameter portion. The piping structure according to claim 1, wherein the vertical pipe is a polyethylene pipe, a polybutene pipe, or a polypropylene pipe.