KR20090088978A - Piping work structure for heating system - Google Patents

Abstract

A heating duct structure is provided to reduce the inter-layer noise and oscillation sound by fixing a heating pipe without a bracket. A heating duct structure comprises a heat-insulating panel(1), a heating pipe(3) and a cement mortar layer. The heat-insulating panel has a male/female assembly unit. The heat-insulating panel is arranged on a slab of a building to the checkerboard type. A pipe groove is formed at the heat-insulating panel. The heating pipe is zigzag piped at the pipe groove. The cement mortar layer is formed on the heating pipe. The depth of the pipe groove of the heat-insulating panel is more deeply formed than the general depth.

Description

Piping Structure for Heating {PIPING WORK STRUCTURE FOR HEATING SYSTEM}

The present invention relates to an improvement in the heating piping structure to improve the thermal efficiency and workability of the heating pipe installed for floor heating, such as apartments, houses, mall buildings.

In general, in the construction of hot water pipes for heating, the insulating panels having pipe grooves are prefabricated on the slab, and the hot water pipes are arranged in a jig-jack shape, and then coated with foam concrete and cement mortar.

Plumbing boards for heating pipes are usually made of styrofoam or synthetic resin panels. The upper surface of the panel has a checkered pipe groove for the hot water pipes to be jig-jacked. During piping work, the hoses or pipes are pressed into the pipe grooves so that the heating pipes are embedded in the pipe grooves and the brackets are fixed so as not to move the heating pipes.

In the above-described conventional heating tube construction structure, the hot water pipe is embedded in the pipe groove dug into the upper surface of the panel so that only the upper surface of the pipe is exposed and the remaining portion is embedded in the pipe groove, so that the heat source of the heating tube is lost to the bottom layer through the panel. There is a problem that the loss of thermal energy and the thermal efficiency is not good.

Another problem is that the use of a plurality of brackets at regular intervals in order to fix the heating tube in the pipe groove of the panel is a factor in the rise of materials and construction costs and workability is also reduced.

An object of the present invention is to improve the structure of the pipe groove of the panel to improve the thermal efficiency and to fix the heating tube without using the bracket, and to provide a wet and dry heating piping structure that can effectively reduce the noise and vibration between the floor.

      In order to achieve the above object, the present invention forms a projection for floating in the pipe grooves of the panel at regular intervals so that the heating tube is floating slightly upwards without touching the floor, so that the floating space acts as a heating space as well as noise and vibration. One feature is that it is configured to act as a space to absorb and reduce.

       Another feature of the present invention is to improve the structure of the anti-vibration bridge provided on the bottom of the panel. The present invention is different from the general dustproof hole that is used as a leg with elasticity by inserting a rubber-proof bridge in the holes formed in all four sides of the panel, the length of the bridge is formed by extending the length of the bridge to protrude above the pipe groove By forming a U-shaped narrowing groove for clamping and fixing the heating tube at the top of the barrier, the heating tube can be clamped in the clamping groove of each barrier during the piping work so that the heating tube can be supported without a separate bracket. It is also possible to improve the effect of reducing vibration and noise transferred to the anti-shock bridge.

The present invention reduces heat loss and improves thermal efficiency by improving the pipe groove structure of the heating pipe panel to have a heat and storage function in the lower part of the heating pipe, and by improving the structure of the pipe groove and the structure of the barrier rib. Noise and vibration generated in the bottom layer is absorbed in the space portion to reduce the effect. The piping structure of the present invention can be usefully applied to wet heating as well as dry ondol heating structure.

1 and 2 show the overall main configuration of the heat insulation panel of the present invention.

In the present invention, the heat insulation panel 1 having the female assembly means 5 is arranged on the slab of the building in a checkerboard shape, and the heating pipe 3 is jig-jacked in the pipe groove 2 formed on the upper surface of the heat insulation panel 1. The basic heating structure for forming the cement mortar layer 4 thereon by pipework is the same as a known technical structure.

The present invention is characterized by improving the structure of the piping groove (2) of the insulation panel (1), characterized in that the heating pipe (3) is installed to float up so as not to touch the bottom of the piping groove (2). . In the present invention, it is preferable to use various kinds of panels having different lengths, widths, and shapes of the pipe grooves.

To this end, the present invention forms a depth K of the pipe groove 2 dug into the heat insulation panel 1 deeper than the normal pipe groove depth P, as shown in FIG. (7) forming a support projection (8) about half the depth (W) of the pipe groove (2) depth in the gorge (F) between (7) and seating the heating tube (3) on the bottom of the heating tube (3) It is configured to have a heating space (9).

In order to support the heat insulation panel 1, the prevention leg 10 is installed in all four sides of the panel.

A plurality of fastening holes 11 are formed on all four sides of the panel to install the anti-vibration bridge 10, and the anti-finger bridge 10 inserted vertically into the fastening hole 11 has a landing plate and a vertical column integrally. As the formed stretchable structure, the upper end portion has a characteristic structure for applying to the piping structure of the present invention.

The anti-tip 10 of the present invention is formed to be the same as the height of the heat insulation panel by forming the upper end of the body long, and has a U-shaped gripping groove 12 on the upper end.

The gripping groove 12 functions to fix the heating tube 3 to be piped so as not to flow, and supports the gripping groove 12 of the insulation protrusion 1 and the barrier rib 10 of the insulation panel 1. It is characterized in that the heating tube 3 is installed in a floating manner as a means.

The anti-bangji leg 10 of the present invention is formed of a soft rubber or a synthetic rubber material which is easy to stretch elasticity. In addition, the center is composed of a cylindrical body having a vertical hole 13 to induce vibration and noise upward.

According to the present invention, the upper part of the body of the anti-limbing leg 10 is separated and may be a separate type or an integral body consisting of a body and a head (H). It is configured in such a way as to be able to adjust the gripping groove 12 in the required direction by turning the head during construction work.

 The present invention is used in the first state by inserting the anti-limb bridge 10 in the fastening hole 11 of each insulation panel 1, using a plurality of female assembly means (5) formed in each heating panel (1). The panel is assembled in the usual way and laid on the floor of the slab, followed by adjusting the gripping grooves 12 of each of the anti-limb bridges 10 in the required direction (direction to be piped).

Figure 4 shows a state in which the heating pipe (3) is piped to the insulating panel (1) assembled in a checkerboard shape, by pressing the heating pipe (3) in the pipe groove (2) matched in one direction by a jig jack type Piping. The heating tube 3 is supported by the clamping grooves 12 and the support protrusions 8 installed in the pipe grooves 2 and is fixed in a state where the lower part is floating like a pier, and is fixed without flow by the clamping force thereof. Therefore, the lower part of the heating tube forms a void space and acts as a heat space where hot air stays, thereby suppressing heat loss downward and improving thermal efficiency upward.

In addition, since vibration and noise transmitted from the bottom layer are alleviated through the primary anti-vibration bridge and absorbed into the hollow part, the effect of reducing the interlayer noise is great.

1 is a perspective view showing a piping structure of the present invention insulation panel

Figure 2 is a plan view of the heat insulation panel of the present invention.

Figure 3 is a cross-sectional view illustrating the pipe groove structure of the present invention insulation panel

4 is an assembly construction state of the heating pipe according to the present invention

5 is a cross-sectional view taken along the line A-A of FIG.

6 is a cross-sectional view taken along the line B-B of FIG.

[Code Description of Important Parts of Drawing]

1: insulation panel 2: pipe groove

3: heating tube 5: assembly means

6,7: circular protrusion 8: base protrusion

9: heat space 10: Bangji Bridge

11: fastener 12: clamping groove

H: head

Claims (2)

The insulation panel 1 having the female assembly means 5 is arranged on the slab of the building in the form of a tile, and the heating tube 3 is piped in a jig-jack type to the pipe groove 2 formed on the upper surface of the insulation panel 1. In the heating structure in which the cement mortar layer 4 is formed thereon, the depth of the pipe groove 2 of the heat insulation panel 1 is formed deeper than the general depth, and the pipes are formed in the valleys of both circular protrusions 6 and 7. A support projection 8 of about half the depth of the groove 2 is formed, and the heating tube 3 is seated thereon, so that the heat generating space 9 is provided at the lower portion and inserted into the fastening hole 11 of the insulation panel 1. The ground is formed in the upper end of the jijiji 10 to form a U-shaped holding groove 12 for fixing the heating tube to support the support projection 8 of the heat insulation panel (1) and the holding groove 12 of the jijimji 10. Floor heating piping structure characterized in that the heating tube (3) is installed in a floating manner. The floor according to claim 1, wherein the anti-limbing bridge (10) is composed of a rod-shaped body having a vertical hole (13) in the center and the upper portion of the body is separated to form a separate or integral body composed of the body and the head (H). Piping structure for heating.

Images