JPH0119715Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a heat insulating separator for a clamping hardware of a concrete formwork, which is a part of the component of the clamping hardware used in a concrete formwork.

Fastener 1 used for concrete formwork is the first
As shown in the figure, a separator 3 that sets the interval between the left and right formworks 2a, 2b and receives lateral pressure on the formworks 2a, 2b during pouring, and a round pipe 6.
It consists of form timers 4a, 4b that hold the formworks 2a, 2b from the left and right through the formworks 2a, 2b, and washers 5a, 5b for round pipes, and has a strength suitable for the lateral pressure generated on the formwork by the fresh concrete to be poured. It is necessary to select the fastener 1.

Therefore, conventionally, the separator 3 of the fastener 1, Huotai (registered trademark) 4a, 4b, etc., were usually made of iron.

However, as shown in FIG. 2, the separator 3 is usually left embedded in the concrete wall 7 during concrete pouring, and the other formwork, form ties, etc. (not shown) are removed.
Separator 3 embedded in concrete wall 7
Since it is a metal, it has a high thermal conductivity, and especially in cold regions, a so-called thermal bridge (cold bridge) occurs in which the low temperature of the cold air outside 8 is transmitted to the interior 9 through the separator 3. Even if the heat insulating material 10 is installed on the side of the room 9 as shown in FIG.
1 peels off, mold grows, or even drops of water fall onto the floor, which can cause the floor covering material and joists (not shown) to rot. This is the same even in the case of external wall insulation in which the heat insulating material 10 is stretched on the outside 8 side.

The above-mentioned thermal bridge means that due to the temperature difference between the air inside the room 9 and the outside 8, heat from the indoor 9 side is rapidly transferred to the outside through the metal separator 3. On the indoor 9 side, the separator 3 is transferred to the concrete wall As a result, the air near the interior of the room 9 where the separator 3 is embedded and the water vapor that permeates through the wall become below the dew point and condense.

In order to prevent problems caused by the thermal bridge described above, the embedded separator end hole 12 (for example, P
The cone (hole where the plastic cone was removed) was filled with mortar, injected with urethane, or finished with mortar filled with pieces of heat insulating material such as PE, but mortar filling is less effective, and urethane injection requires more material. This is time-consuming and the combination of insulation pieces and mortar finishing tends to result in incomplete construction. Another construction method is to embed a separator with an extrapolated PVC pipe 3a, etc., then pull out the separator 3a and fill it with urethane 13, etc., as shown in Figure 3. There are doubts about waterproofness, which increases construction costs.

As a means to solve these problems, it has been considered in the past to make the separator 3 embedded in the concrete wall 7 from a resin with low thermal conductivity such as polycarbonate, acetal, nylon, etc., but as a result of experiments,
All of them lacked strength and could not withstand use.

The present invention was developed in view of the above-mentioned circumstances, and aims to provide a heat insulating separator for formwork clamping hardware that does not cause thermal bridging even if it is left embedded in a concrete wall. .

Therefore, in the present invention, at least one of the parts constituting the separator is made of injection molded glass fiber-reinforced nylon 6.6 or glass fiber-reinforced polyacetal resin.

The present invention will be described in detail below with reference to the accompanying drawings. Figure 4 is a cross-sectional view of a concrete wall in which a single round separator is embedded, showing one embodiment of the present invention, and Figure 5 is a concrete wall in which a multi-part separator is embedded, showing another embodiment of the present invention. It is a sectional view of a wall.

Fig. 4 shows a case in which a heat insulating material 10 is stretched outside the wall on the exterior 8 side, and a panel 16 made of a board 14 made of GRC, ceramics, cement, etc. is pasted to the heat insulating material 10 is separately cast. It is fixed to the wall 7 with a plastic plug 15.

The separator 3 is a single-component round separator made by injection molding of glass fiber-reinforced nylon 6.6 or glass fiber-reinforced acetal resin instead of metal.

In Fig. 5, a heat insulating material 10 is stretched on the outside 8 side, but a panel 16 made of the same material as in Fig. 4 is used in place of one of the "weir plates" and the panels 16 are simultaneously driven in. be. That is, separator 3
0 consists of a tie rod 31, a panel mounting bracket 32, and a joint nut 33 that connects the two, and on the outside 8 side, the panel 16 is used as a weir plate using form ties and round pipes (not shown), and on the indoor 9 side, a sheath plate made of plywood or the like (not shown) is used. A formwork is set using form ties, round pipes, etc., and the heat insulating panel 16 and concrete wall 7 are cast simultaneously. The panel mounting bracket 32 is as shown in the figure.
Most of the panel, except for the panel tightening portion 32a, is buried within the concrete wall 7, and the tie rod 31 and joint nut 33 are entirely buried within the concrete wall 7. In another embodiment shown in FIG.
Tie rod 31, panel mounting bracket 32, joint nut 3, which are components of the separator 30
For at least one of 3, injection molded glass fiber reinforced nylon 6.6 or glass fiber reinforced polyacetal resin is used.

The above-mentioned glass fiber reinforced nylon 6.6 and glass fiber reinforced polyacetal resin are commercially available as engineering plastics from various companies, but glass fiber reinforced nylon 6.6 is sold under the trade name Ultramid A, and gas fiber reinforced polyacetal resin is sold under the trade name Ultraform. ,
It is commercially available from BASF Japan Co., Ltd. Depending on the grade, the former has a tensile yield strength of 1600 Kg/cm ²
~2300Kg/ ^cm2 , and the latter has a tensile strength of about 1200Kg/ ^cm2 , although the strength is lower than the former.In the case of steel, the tensile strength is 4100Kg/ ^cm2 ~5000Kg/ ^cm2 at SS41, so glass fiber If you make a separator by injection molding reinforced nylon 6.6 or glass fiber reinforced polyacetal resin, the strength of the threaded part will not decrease, so you may need to make the diameter slightly larger than in the case of steel, or change the outer diameter of the threaded part, or the thread shape. By adjusting the length, it is possible to make separators as strong as conventional metal separators. Furthermore, the thermal conductivity λ (Kcal/mh℃) of the above glass fiber reinforced nylon 6.6 and glass fiber reinforced polyacetal resin is
0.17 to 0.2, which is extremely small compared to the conventional separator material iron, which has a λ of 30 to 50, and even smaller than concrete, which has a λ of 0.7 to 1.2. If a part of the separator made of glass fiber-reinforced polyacetal resin is used as a part of the separator, the thermal bridge will be blocked at that point, and the indoor interior material near the separator will become damp and water droplets will accumulate. This prevents interior materials from peeling off, mold from forming, water droplets falling onto the floor, and rotting the floor covering materials and joists. Since it does not take time and effort to fill mortar for heat insulation, it has the effect of improving work efficiency.

[Brief explanation of drawings]

Figure 1 is an example of an assembly diagram when formwork is constructed, Figure 2 is a sectional view of a concrete wall with a conventional separator embedded in it, Figure 3 is a sectional view of a concrete wall with a conventional separator removed, and Figure 4 is a sectional view of a concrete wall with a conventional separator removed. The figure is a cross-sectional view of a concrete wall in which a single round separator is embedded, showing one embodiment of the present invention. Figure 5 is a cross-sectional view of a concrete wall in which a separator made of multiple parts is embedded, showing another embodiment of the present invention. FIG. 1... Clamping hardware, 2a... Left side frame, 2b...
Right formwork, 3... Separator, 4a, 4b...
Form tie, 7... concrete wall.

Claims (1)

[Scope of utility model registration request] In fasteners used in concrete formwork, at least one part of the separator that is left largely or completely embedded in the concrete is injection molded with glass fiber reinforced nylon 6.6 or glass fiber reinforced polyacetal resin. A heat insulating separator for formwork fastening hardware, characterized by the use of parts made of aluminum.