JPH0248711B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a snow melting device for a roof, and particularly to a snow melting device provided above a roof panel.

[Conventional technology]

One method for removing snow that has accumulated on roofs in areas with heavy snowfall is to melt the snow by heating the roof panels. One example of this is passively transmitting heat to the roof panels using indoor heating, melting the contact surface of the snow, and causing the snow to slide down along the roof slope toward the eaves.

However, with this method, heating heat does not reach the eaves side, so the snow that moves freezes on the eaves side and forms an embankment, where melt water accumulates and this water flows toward the ridge. Water flows backwards, causing a leak called "sugamori."

In order to prevent this, it has been proposed to arrange a band-shaped electric heating sheet B on the back side of the roof board A at the edge of the eaves, as shown in FIG.

Additionally, the applicant of this invention had previously applied for the
No. 99985 (filed on July 4, 1982) is proposed. As shown in Japanese Utility Model Publication No. 1-37069, this device is installed in a vertically rectangular shape on the eave side part extending from the sloped edge of the eaves to slightly toward the ridge side from the boundary between the eaves and the upper part of the main roof. Flexible electric heating sheets are placed in close contact with the back surface of the roof panel at regular intervals and lined up across the entire horizontal direction of the roof.

Furthermore, as shown in Japanese Unexamined Patent Publication No. 56-6848, heating elements made of heat pipes are supported on the roof plate, and these heating elements are spread horizontally along the vertical direction of the roof over the entire surface of the roof. In some cases, fins made of metal pipes or the like were arranged vertically along the horizontal direction of the roof on the heating element.

[Problem to be solved by the invention] However, the electric heating sheet B is applied only to the edge of the eaves as described above.
In the conventional type, only the outer periphery of the electric heating sheet B melts and becomes hollow, but the snow does not fall and it is difficult to completely melt the bank against the snow melting water W that forms between it and the indoor roof surface. Instead, the melted water refreezes, resulting in plate-shaped freezing.
There was a problem in that it was difficult to obtain sufficient water leakage prevention effects and snow melting effects.

In addition, conventional snow melting equipment that has a heating element placed all over the roof uses the heating element to heat the entire snow pile on the roof plate, which increases the cost of the heat source during use. Since these parts are directly supported, there is a problem in that the contact area between them becomes large and dust tends to accumulate thereon. In addition, in the previous proposal by the applicant of this invention, an electric heating sheet is installed on the eaves side of the roof, which saves on heat source costs, but a vertically rectangular electric heating sheet is installed in close contact with the back side of the roof panel. Because of this, it is difficult to install it on an existing roof, as it requires removing the roof panel, and maintenance after installation is also troublesome, as it is difficult to locate the location in the event of a failure.

This invention is a further improvement on the one previously proposed by the applicant, and can be installed relatively easily even on an existing roof, and maintenance after installation is easy.
Another object of the present invention is to provide a roof snow melting device that prevents dust from accumulating on the roof panel, has a low heat source cost, and can prevent leakage of snow melting water on the roof panel.

[Means for solving problems]

In the roof snow melting device according to the present invention, brackets are protruded at appropriate intervals on the roof plate, and a heating element made of a heat pipe is supported and fixed on these brackets with a gap between the brackets and the roof plate. A heating element is placed on the eave side of the roof along the roof slope.

[Effect]

In the roof snow melting device according to the present invention, a heating element made of a heat pipe is disposed on the eaves side part of the roof, and the eave side part is heated by the heating element when snow is falling, so that the snow accumulated on the roof can slide off. By forming a snow cave around the heating element in the embankment formed on the eaves side part, which penetrates to the eaves, snowmelt water flowing on the roof plate due to the roof slope will not accumulate on the ridge side of the embankment.
The melted snow water flows down to the underside of the eaves through the snow cave and does not refreeze. Therefore, it is possible to prevent melted snow water from leaking indoors from the eave side of the roof. Compared to heating and melting with a heating element disposed above, when the same type of heat source is used, the cost of the heat source can be significantly reduced. In addition, in the roof snow melting device according to the present invention, the heating element is supported and fixed on a bracket protruding above the roof plate, and a gap is provided between the heating element and the roof plate, so that an electric heating sheet can be placed on the back side of the roof plate. Unlike the applicant's previous application in which a heating element is installed, the snow melting device can be installed by working from above without removing the roof panels, so it can be installed relatively easily on an existing roof. , since there is a heating element on the roof,
It is easy to find and replace a malfunctioning heating element, and maintenance after installation is also easy.Furthermore, there is a gap between the heating element and the roof plate, so only the bracket comes into contact with the roof plate. Because these contact areas are small, the heating element is directly supported over the entire length of the heating element like the conventional one mentioned above, and unlike those with large contact areas, dust does not collect on the contact areas. It is difficult to accumulate, and problems caused by this can be reduced.

〔Example〕

Embodiments of the present invention will be described in detail below with reference to FIGS. 1 to 6.

1 to 3 show a first embodiment of the present invention. In these figures, a building 1 is provided with a gable-shaped roof 2, and a large number of heat pipes, which are heating elements 3, are arranged in parallel in the horizontal direction of the roof along the roof slope on the eaves side of the roof 2. At the same time, a second snow melting device is installed on the eaves side part from the eaves to slightly closer to the ridge than the aggregate 4 that makes up the building frame.
It is provided as shown in the figure.

As shown in FIG. 1, the roof 2 consists of a main building 5 made of C-channel steel arranged intersectingly on aggregate 4 made of H steel that constitutes the frame of the building 1, and rafters 6 made of hat-shaped steel. It consists of a horizontal roof panel 7 superimposed on the rafters 6 in a clinker-like manner from the eaves side to the ridge side, and a nose cover 9 provided at the edge of the eaves side.

Round bar-shaped brackets 8, which also have a bolt function, are protruded at appropriate intervals on the rafters 6 through the face plate 7, and these brackets 8
A heating element 3 made of the heat pipe is supported and fixed to the upper end protruding onto the roof plate 7, and a gap is provided between the roof plate 7 and the heating element 3. Incidentally, a snow-stopping bar 19 that intersects with the heating element 3 is fixed on the bracket 8.

The heating element 3, which is a heat pipe, has a heating medium such as hot water flowing through it, or a heating wire such as a nichrome wire is buried inside, and the tip of the heating element 3 extends from the outside of the eaves to the lower side. A hanging portion 3a is formed by bending. 15 is a support member for the rafter 6, which is welded to the rafter at a predetermined location. 1
6 is a subtruss made of H steel.

In the above configuration, the snow S accumulated on the roof 2 forms an embankment at the eave side part of the roof 2, but due to the snow melting action caused by the heating of the heating element 3, snow caves are formed around these edges as shown in FIG. form 10, snow cave 1
0 penetrates to the eaves. Therefore, as the surface of the roof 2 facing the indoor ceiling is heated by indoor heating as shown in FIG. 7, the melted snow water flows down along the roof slope and does not accumulate on the ridge side of the embankment. , it flows down the snow cave 10 to the bottom of the eaves.

4 and 5 show a second embodiment of the invention. In this embodiment, in addition to the heating element 3 made up of a heat pipe in the vertical direction, a heating element 12 made up of a plurality of heat pipes in the horizontal direction is provided at appropriate intervals so that the heating elements 3 and 12 cross each other. It is installed on the eave side part of roof 2.

In this second embodiment, a snow cave is also formed in the lateral direction.

As shown in FIG. 6, it is of course possible to dispose the heating elements 3 made up of a large number of heat pipes diagonally across each other on the eaves side of the roof.

〔Effect of the invention〕

As explained above, according to the present invention, brackets are made to protrude at appropriate intervals on the roof plate, and a heating element made of a heat pipe is supported and fixed on these brackets with a gap between them and the roof plate. Since these heating elements are arranged along the roof slope on the eaves side of the roof, the following effects can be obtained.

That is, the roof snow melting device according to the present invention is
A heating element made of a heat pipe is placed on the eaves side of the roof, and the eaves side is heated by the heating element when it snows, and the embankment that is formed on the eaves side due to the sliding of the snow accumulated on the roof. By forming a snow cave around the heating element that penetrates to the eaves, snowmelt water flowing on the roof plate due to the roof slope does not accumulate on the ridge side of the embankment, but flows down to the bottom of the eaves through the snow cave, and melts snow. Water does not refreeze, and therefore water from melting snow can be prevented from leaking indoors from the eaves side of the roof.
Compared to the conventional method in which the snow on the entire roof is heated and melted by a heating element placed on the roof face plate, when the same type of heat source is used, the cost of the heat source can be significantly reduced. In addition, in the roof snow melting device according to the present invention, the heating element is supported and fixed on a bracket protruding above the roof plate, and a gap is provided between the heating element and the roof plate, so that an electric heating sheet can be placed on the back side of the roof plate. Unlike the applicant's previous application in which a heating element is installed, the snow melting device can be installed by working from above without removing the roof panels, so it can be installed relatively easily on an existing roof. Since the heating element is on the roof, it is easy to find and replace a malfunctioning heating element, and maintenance after installation is also easy.Furthermore, there is a gap between the heating element and the roof plate. Only the brackets make contact with the roof panel, and because these contact areas are small,
Unlike the conventional type described above, in which the heating element is directly supported over its entire length on the roof plate, and unlike those in which the contact portions are large, it is difficult for dust to accumulate on the contact portions, and problems caused by this can be reduced.

[Brief explanation of the drawing]

1 to 3 show a first embodiment of the present invention, FIG. 1 is a side view of the main part of a building to which this invention is applied, and FIG. 2 is an overall view showing a snow melting device on the roof of the same building. Perspective view, Figure 3 is - of Figure 2.
Line sectional views, FIGS. 4 and 5 show the second embodiment,
Figure 4 is an external perspective view of the building, Figure 5 is a sectional view taken along the - line in Figure 4, Figure 6 is an explanatory diagram showing the installation shape of the heating element, and Figure 7 is a section showing an example of a conventional snow melting device. FIG. 1... Building, 2... Roof, 3, 12... Heating element (heat pipe), 3a... Drooping part of heating element, 5...
...Main building, 6...Rafter, 7...Roof plate, 8...Bracket, 9...Nose cover.

Claims (1)

[Scope of Claims] 1. Protruding brackets are provided at appropriate intervals on the roof panels, and a heating element made of a heat pipe is supported and fixed on these brackets with a gap between the brackets and the roof panel, and these heating elements are A snow melting device for a roof, characterized in that it is arranged along the slope of the roof at the eave side part of the roof. 2. The snow melting device for a roof according to claim 1, wherein the heating elements are arranged horizontally in parallel along the longitudinal direction of the roof, and the drooping part formed at the tip is arranged outside the eaves of the roof. . 3 Multiple heating elements are arranged vertically and horizontally,
The roof snow melting device according to claim 1, which is arranged so as to intersect with each other. 4. The roof snow melting device according to claim 1, wherein a large number of the heating elements are arranged diagonally and intersecting each other.