KR102039895B1 - Stairway snow melting structure using carbon heat - Google Patents

Abstract

The present invention relates to a step snow melting structure using carbon heat, and can prevent the stairs from freezing in cold weather can prevent the safety accident injured by falling as the pedestrians such as the elderly and infants slip on the frozen stairs. Of course, in particular, it is possible to install more easily on the stairs by connecting a plurality of heat generating plate parts with each other, there is a very good workability.

Description

Stairway snow melting structure using carbon heat}

The present invention can prevent the stairs from freezing in cold weather can prevent the safety accident injured by falling over the sliding of pedestrians such as the elderly and infants in the frozen stairs, as well as, in particular, by connecting a plurality of heating plate parts It will be easier to install on the stairs, so it will be related to the step snow melting structure using carbon heat generation, which has very good workability.

In general, the staircase non-slip is installed on the corner of the staircase to replace the wear of the edge of the staircase, and to prevent the pedestrians to walk and help to walk, safety slip that can occur during normal walking slip It is a non-slip jaw to reduce the pressure.In recent years, the non-slip horizontal and vertical frames are precisely fixed to the corners where the horizontal and vertical surfaces of the stairs come into contact with each other. A staircase non-slip to prevent separation has been proposed in Korea Patent Publication No. 10-1614446.

However, when the stairs are exposed to cold weather such as the polar region, there is a problem that safety accidents occur when the pedestrian non-slip freezes and the pedestrians walking the stairs, especially the elderly or the infant, fall down while slipping.

Domestic Patent Registration No. 10-1614446

The present invention was created in order to solve the above problems, it is possible to prevent the stairs from freezing in cold weather can prevent the safety accident injured by falling down while the pedestrians such as the elderly and infants slip on the frozen stairs. Of course, in particular, a plurality of heating plate parts can be connected to each other more easily installed on the stairs to provide a step snow melting structure using carbon heat generation is very good workability.

The present invention for achieving the above object is provided with a heat insulation layer, a heat conduction plate provided on the upper portion of the heat insulation layer and the fixing groove is formed, a carbon heating wire fixed in the fixing groove of the heat conduction plate, and the upper portion of the heat conduction plate A plurality of heat generating plate portions each consisting of a bottom plate which is seated on a horizontal surface of the stairs; It provides a staircase snow melting structure using a carbon heating comprising a; a finishing cover provided on the vertical surface of the stairs to be located between a plurality of the heating plate.

Here, the fixing groove is preferably formed in the lower portion of the heat conductive plate.

And, it is preferable that the fixing jaw is formed in the lower portion of the heat conduction plate, the lower opening is formed in the fixing groove inside.

In addition, the heat transfer pin is formed on the upper portion of the heat conductive plate, it is preferable that the insertion groove for inserting the heat transfer pin is formed in the lower portion of the bottom plate material.

Further, one end of the heat conduction plate is located on both sides of the bottom plate material from both ends of the bottom plate material, is provided on one side of the heat conduction plate, the bottom side is formed with a groove that is open on the other side for receiving the carbon heating wire; It is preferably provided on the other side of the heat conduction plate, the other side finishing material is formed on the bottom and one side and the front side and the rear side open groove.

In addition, it is preferable that the groove for accommodating the waterproof connector for connecting the carbon heating wire to the inner side of the finishing cover is formed up and down.

In addition, the finishing cover is made of at least a portion of the transparent or translucent material, it is preferable that the light emitting unit or the light emitting portion is provided around the waterproof connector.

And, the bottom plate is preferably made of any one material of wood, stone, synthetic resin, metal.

The present invention can more easily prevent the stairs from freezing in cold weather through the high temperature heat emitted by the carbon heating wires of the plurality of heating plate portion installed on the stairs, so that the pedestrians such as the elderly and the infant slip on the frozen stairs. Injury of the safety accident can be prevented in advance, and in particular, a plurality of the heating plate can be connected to each other more easily installed on the stairs, the workability is very good.

1 is a perspective view schematically showing a heating plate of the stepped snow melting structure using carbon fiber heat generation according to an embodiment of the present invention,
2 is a partially cutaway perspective view of FIG. 1,
3 is an enlarged cross-sectional view of FIG.
4 to 8 are perspective views sequentially illustrating a process in which the heating plate and the finishing cover is installed on the stairs,
9 is a perspective view schematically illustrating a state in which a plurality of heating plate parts and a plurality of finishing covers are installed on stairs;
10 is a cross-sectional view taken along the line AA of FIG. 9,
11 is a cross-sectional view taken along the line BB of FIG. 9,
12 is a plan view schematically illustrating a series connection state of carbon heating wires,
13 is a plan view schematically showing the parallel connection state of the carbon heating wire,
14 is a block diagram schematically illustrating a control state of a controller.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and various modifications can be made by those skilled in the art without departing from the technical gist of the present invention.

1 is a perspective view schematically showing a heat generating plate portion of a stepped snow melting structure using carbon fiber heat generation according to an embodiment of the present invention, FIG. 2 is a partially cutaway perspective view of FIG. 1, and FIG. 3 is an enlarged cross-sectional view of FIG. 1.

Step snow melting structure using carbon fiber heat generation of one embodiment of the present invention, it comprises a plurality of heating plate portion 10 and the finish cover.

First, as shown in FIGS. 1 to 3, the heating plate part 10 is composed of a heat insulating layer 110, a heat conducting plate 120, a carbon heating wire 130, and a bottom plate material 140, and is mounted on a horizontal surface of the stairs.

The heat insulation layer 110 may be made of various types such as styrofoam and may be seated on a horizontal surface of the stairs.

The high temperature emitted by the carbon heating wire 130 through the heat insulating layer 110 may prevent the heat from being transferred to the stairs located in the lower direction of the heat insulating layer 110.

The heat conduction plate 120 may be made of various materials such as aluminum, and seated on the upper portion of the heat insulation layer 110.

As shown in FIG. 3, the supporting jaw 121 supports the load of the bottom plate 140 by protruding at a predetermined length in the lower direction of the heat conduction plate 120 at the lower front side and the lower back side of the heat conduction plate 120. ) May be formed.

One fixing groove 122 or two or more fixing grooves 122 may be formed in the thermal conductive plate 120 at predetermined intervals from the front side of the thermal conductive plate 120 to the rear side.

The carbon heating wire 130 may be made of various types such as carbon fiber heating wire, it is fixed in the fixing groove 122 of the heat conducting plate 120.

The bottom plate material 140 is mounted on the upper portion of the heat conductive plate 120.

Next, the fixing groove 122 of the heat conduction plate 120 may be formed in the lower portion of the heat conduction plate 120 to be located between the support jaw 121 as shown in FIG.

In order to more easily form the fixing groove 122 in the lower portion of the thermal conductive plate 120, one fixing jaw 123 or two or more fixing jaws 123 in the lower portion of the thermal conductive plate 120. It may be formed at a predetermined interval from the front side of the heat conductive plate 120 to the rear side so as to be located between the support jaw 121.

The fixing groove 122 may be formed inside the fixing jaw 123, and an operator may easily fix the carbon heating wire 130 in the fixing groove 122 formed inside the fixing jaw 123. The fixing jaw 123 may be formed in a 'C' shape and the like with a lower opening so as to be inserted and fixed.

 The support jaw 121 and the fixing jaw 123 formed on the lower portion of the heat conductive plate 120 press the upper portion of the heat insulation layer 110, which may be made of styrofoam, toward the bottom of the heat insulation layer 110. It may be drawn into the upper inside of the 110, respectively.

On the other hand, the fixing groove 122 may be formed on the upper portion of the heat conduction plate 120, but the fixing that may be formed in a 'C' shape or the like to open the upper portion for forming the fixing groove 122 Since there is a hassle to form a groove for accommodating the jaw 123 in the lower portion of the bottom plate material 140, the fixed groove 122 in the lower portion of the heat conductive plate 120 as shown in FIG. It is preferable that the fixing jaw 123 is formed to form.

Next, in order to more easily transfer the high temperature heat emitted by the carbon heating wire 130 to the bottom plate material 140 provided on the heat conducting plate 120, as shown in FIG. As described above, the heat transfer fins 124 protruding at a predetermined length in the upper direction of the heat conduction plate 120 may be formed at a predetermined interval from the front side of the heat conduction plate 120 in the rear direction. .

Inserting grooves 141 into which the heat transfer fins 124 are inserted may be formed at the bottom of the bottom plate 140 facing the heat transfer fins 124.

4 to 8 are perspective views sequentially illustrating a process in which the heating plate portion and the finishing cover are installed on the stairs, and FIG. 9 is a perspective view schematically showing a state in which the plurality of heating plate portions and the plurality of finishing covers are installed on the stairs.

Next, as shown in FIGS. 4 to 8, the plurality of heating plate parts 10 may be fixed to the plurality of horizontal surfaces 31 of the stairs 3 in various ways such as bolt fixing and adhesive fixing. .

In order for both ends of the heat conduction plate 120 to be positioned in a predetermined width from both ends of the bottom plate 140, as shown in FIG. 4, a central portion of the heat conduction plate 120 and one side of the heat conduction plate 120 are provided. The left and right length L ₁ may be formed to be shorter than the left and right length L ₂ between the center of the bottom plate 140 and one side of the bottom plate 140, and the center of the heat conducting plate 120. The left and right length L ₃ between the other side of the heat conductive plate 120 may be shorter than the left and right length L ₄ between the center of the bottom plate 140 and the other side of the bottom plate 140.

As shown in FIG. 4, one side finisher 30 may be provided at one side of the heat conduction plate 120 so as to be positioned at one side downward direction of the bottom plate material 140, and the other of the heat conduction plate 120 may be provided. The other side of the bottom plate material 140 may be provided with the other finish material 40 to be located in the lower direction.

The one side finisher 30 and the other side finisher 40 may be made of various materials such as aluminum.

10 is a cross-sectional view taken along line AA of FIG. 9.

As shown in FIG. 10, a groove 301 accommodating one side of the first carbon heating wire (131 of FIG. 12) of the carbon heating wire 130 may be formed on the bottom surface of the one side finishing material 30.

As shown in FIG. 10, one side of the groove 301 of the one side finisher 30 may be closed, and the other side of the groove 301 of the one side finisher 30 may be opened.

The other side of the first carbon fiber heating wire (131 of FIG. 12) and the second carbon fiber heating wire (132 of FIG. 12) or the first carbon fiber heating wire of the carbon heating wire 130, which will be described later, on the bottom of the other finishing material 40. Grooves 401 may be formed to accommodate the other side of 131 of FIG. 13 and second and third carbon fiber heating wires 132 and 133 of FIG. 13.

As shown in FIG. 10, one side and a front side and a rear side of the groove 401 of the other side finisher 40 may be opened.

On the upper rear side of the other finishing material 40, a cutting groove (202 of FIG. 4) communicating with a groove (201 of FIG. 4) to be described later of the closing cover 20 in the front direction from the rear side of the other finishing material 40. Horizontal extension can be formed.

In addition, the cutting groove 202 may be horizontally extended from the rear side of the bottom plate 140 to the front side at the rear side of the other side of the bottom plate 140.

FIG. 11 is a cross-sectional view taken along line BB of FIG. 9.

Next, the finishing cover 20 is located on the vertical surface 32 of the staircase 3 so as to be located between the other side of the opposite side of the one side of the plurality of heating plate 10 as shown in Figures 4 to 9 and 11 Each can be vertically mounted in various ways, such as bolting.

An inner surface of the finishing cover 20 facing the vertical surface 32 of the staircase 3 accommodates the waterproof connector 50 for connecting the carbon heating wires 130 of the plurality of heating plate parts 10. The groove 201 may extend in the vertical direction of the vertical surface 32 of the staircase 3.

12 is a plan view schematically illustrating a series connection state of carbon heating wires.

Next, in a state where two or more fixing grooves 122 are formed at predetermined intervals in the thermal conductive plate 120, as shown in FIG. 12, the carbon heating wires 130 may be connected in series.

To this end, the carbon heating wire 130 may be large, as shown in Figure 8, the first, second carbon heating wire (131, 132).

The first carbon heating wire 131 may pass through the plurality of fixing grooves 122 in a zigzag form, such as a 'ㄹ' shape.

The second carbon heating wire 132 is in the front-rear direction of the first carbon heating wire 131 on the outside of the other side of the first carbon heating wire 131 while maintaining a predetermined interval with the first carbon heating wire 131. Can be extended back and forth by a certain length.

The front side of the other side of the first carbon heating wire 131, the front side of the second carbon heating wire 132 and the rear side of the other side of the first carbon heating wire 131 and the rear side of the second carbon heating wire 132, respectively Waterproof connector 50 may be provided.

The waterproof connector 50 may include a female waterproof connector 510 and a waterproof connector 520.

The female waterproof connector 510 may be provided at the rear side of the other side of the first carbon heating wire 131 and the rear side of the second carbon heating wire 132.

The waterproof connector 520 may be provided at the front side of the other side of the first carbon heating wire 131 and the front side of the second carbon heating wire 132.

Of course, the positions of the female waterproof connector 510 and the waterproof connector 520 may be reversed.

The rear side of the other side of the first carbon heating wire 131 and the rear side of the second carbon heating wire 132 respectively cut the cutting groove 202 of the other finish material 40 and the cutting groove 202 of the bottom plate 140, respectively. Can pass vertically.

The female waterproof connector 510 of one heating plate unit 10 is connected to the waterproof connector 520 of the other heating plate unit 10, and the waterproof connector 520 of any one heating plate unit 10. The plurality of heating plate parts 10 may be more easily connected to each other as is connected to the female waterproof connector 510 of the other heating plate part 10.

13 is a plan view schematically illustrating a parallel connection state of carbon heating wires.

As another example, as shown in FIG. 13, the carbon heating wires 130 may be connected in parallel.

To this end, the carbon heating wire 130 may be composed of the first, second carbon heating wires (131, 132) and the third carbon heating wire 133, as shown in FIG.

The third carbon heating wire 133 extends back and forth along the second carbon heating wire 132 in the other outside direction of the second carbon heating wire 132 while maintaining a predetermined interval with the second carbon heating wire 132. It may be provided in a state.

The female and female connectors 510 and the male and female connectors 520 may be provided at the rear and front sides of the second and third carbon heating wires 132 and 133, respectively. Of course, the positions of the connectors 520 may be reversed.

The rear side of the other side of the second carbon heating wire 132 and the rear side of the third carbon heating wire 133 respectively cut the cutting groove 202 of the other finishing material 40 and the cutting groove 202 of the bottom plate material 140. Can pass vertically.

The rear side of the other side of the first carbon heating wire 131 may be connected to the rear side of the second carbon heating wire 132 so as to be located between the female waterproof connector 510 and the waterproof connector 520.

The front side of the other side of the first carbon heating wire 131 may be connected to the front side of the third carbon heating wire 133 to be located between the female waterproof connector 510 and the waterproof connector 520.

The carbon heating wire 130 may receive power through a power supply line 60 such as an electric wire to radiate high temperature heat.

For example, as shown in FIGS. 12 and 13, the female connector 510 or the waterproof connector 520 may be provided at the front side of the power supply line 60 such as an electric wire.

The male and female connectors 510 or the male and female connectors 520, which are provided at the front side of the power supply line 60, are the male and female connectors of one heating plate part 10 located at the top of the stairs 3, respectively. 520 or the female connector 510 may be connected to each other.

14 is a block diagram schematically illustrating a control state of a controller.

Next, a control unit 70 may be provided that is formed of a controller connected to the rear side of the power supply line 60.

As shown in FIG. 14, a timer 80, a temperature sensor 90, and a light emitting unit 100 may be provided.

The timer 80 may be provided in the controller 70 in various ways such as a push button or a dial button to set an operation time interval of the carbon heating wire 130.

The control unit 70 may supply the power of the power supply unit 710 to the carbon heating wire 130 so that the carbon heating wire 130 may dissipate high temperature heat at an operating time interval set in the timer 80. .

The temperature sensor 90 is provided at various positions such as the outer surface of the bottom plate 140 or the outer surface of the finishing cover 20 to determine an external temperature around the plurality of heating plate parts 10 or the finishing cover 20. It can be detected.

The light emitting unit 100 is made of various types such as LED, waterproof connector (50) accommodated in the outer surface of the waterproof connector 50 accommodated in the groove 201 of the closing cover 20 or the groove 201 of the closing cover 20 ( 50 may be provided in various ways, such as bolt fixing, adhesive fixing to the inner surface of the groove 201 of the closing cover 20 to be positioned around.

The light emitting unit 100 may be connected to the carbon heating wire 130 located in the groove 201 of the finishing cover 20 through a separate power supply line which may be made of an electric wire.

Pedestrians who want to use the stairs 3 can visually see the light emitted by the light emitting unit 100 so that the pedestrians can more easily check the position of the stairs 3 so that they can help walking the stairs 3. The closing cover 20 may be at least a portion, for example, any one of the upper, lower, one side, the other side, the middle portion of the closing cover 20 is made of a transparent or translucent material, or the whole may be made of a transparent or translucent material. .

The controller 70 may control whether the carbon heating wire 130 is heat dissipated by comparing the reference temperature set in advance in the controller 70 with the external temperature measured by the temperature sensor 90. .

When the external temperature value measured by the temperature sensor 90 is less than the reference temperature value, the carbon heating wire 130 is supplied with power from the power supply unit 710 under the control of the controller 70 to generate high temperature heat. It can diverge.

When the external temperature value measured by the temperature sensor 90 is equal to or greater than the reference temperature value, the supply of power to the carbon heating wire 130 is cut off by the control of the controller 70, so that the carbon heating wire 130 has a high temperature. The heat will not be released.

As a result, the carbon heating wire 130 does not dissipate heat unnecessarily in summer, not in winter, thereby preventing unnecessary waste of power.

Next, the bottom plate 140 may be made of a variety of materials, such as may be made of any one material of wood, stone, synthetic resin, metal.

In particular, the bottom plate material 140 may be made of a synthetic wood with excellent thermal conductivity, less cleavage, warpage, etc. than the splint wood so that the durability of the bottom plate material 140 can be significantly improved.

The present invention configured as described above more easily to freeze the stairs (3) in cold weather through the high temperature heat emitted by the carbon heating wire 130 of the plurality of heating plate portion 10 installed in the stairs (3). In addition, it is possible to prevent the safety accident injured by falling as a pedestrian such as an elderly person or an infant slips on the frozen stairs 3, and in particular, by connecting the plurality of heating plate parts 10 to each other. ) Can be installed more easily, so the workability is very good.

10; Heating plate portion 20; Finish cover.

Claims (8)

A heat conduction layer, a heat conduction plate provided at an upper portion of the heat insulation layer and having a fixing jaw formed at a lower portion thereof, a lower portion of the fixing jaw being opened and a fixing groove formed at an inner side of the fixing jaw, and a heat transfer pin formed at an upper portion thereof; A carbon heating wire inserted into and fixed in the fixing groove of the bottom plate, and a bottom plate formed at an upper portion of the heat conduction plate and having an insertion groove into which the heat transfer pin is inserted, respectively, being seated on a horizontal surface of the stairs, and both ends of the heat conduction plate. A plurality of heating plate parts positioned in a predetermined width from both ends of the bottom plate material;
A finishing cover provided on a vertical surface of the stairs to be positioned between a plurality of the heating plate parts;
A side finisher provided on one side of the heat conduction plate and having a groove open at the other side to receive one side of the carbon heating wire at a bottom thereof;
The other side of the heat conduction plate, and the other side of the bottom side receiving the other side portion of the carbon heating wire and the other side finishing material is formed in the groove is open to the rear side; step melting using carbon heat generation, characterized in that it comprises a rescue.
The method of claim 1,
The support jaw is formed on the lower front side and the lower rear side of the heat conduction plate to protrude a predetermined length in the lower direction of the heat conduction plate to support the load of the bottom plate material.
The fixing jaw is a stepped snow structure using carbon heat generation, characterized in that formed on the lower portion of the heat conduction plate to be located between the support jaw.
The method of claim 1,
A timer for setting an operation time interval of the carbon heating wire;
A temperature sensor for sensing an external temperature around the plurality of heating plate parts or the finishing cover;
The power supply unit supplies power to the carbon heating wire to dissipate high temperature heat at an operating time interval set in the timer, and when the external temperature measured by the temperature sensor is less than a reference temperature value, the carbon heating wire supplies power from the power supply unit. When the external temperature value measured by the temperature sensor is higher than the reference temperature value, the power supply to the carbon heating wire is cut off so that the carbon heating wire does not emit high temperature heat. Step control snow melting structure using a carbon heating, characterized in that provided;
The method of claim 1,
Steps snow melting structure using carbon heat generation, characterized in that the groove for receiving the waterproof connector for connecting the carbon heating wire to the inner surface of the finish cover is formed up and down.
The method of claim 4, wherein
The finishing cover is made of at least a portion of a transparent or translucent material,
Step snow melting structure using carbon heat generation, characterized in that the light emitting portion is provided around the waterproof connector or the waterproof connector.
The method of claim 1,
The bottom plate is a stepped snow melting structure using carbon heat, characterized in that made of any one material of wood, stone, synthetic resin, metal. delete delete

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