KR102235842B1 - Hybrid type radiant heating device - Google Patents

Abstract

The present invention relates to a hybrid radiant heating apparatus. According to the present invention, the hybrid radiant heating apparatus comprises: a power supply which provides electric energy; a heat source which provides heat energy; a radiant heating unit embedded in the indoor floor to generate heat by using electric energy applied from the power supply and heat energy applied from the heat source; and an air blower unit installed on a side unit of the radiant heating unit to blow air toward an upper surface of the radiant heating unit and to spread the heat. The heat source includes a steam generation unit which is installed outdoors to accommodate water and to generate steam by combustion heat of fuel. As such, according to the present invention, the hybrid radiant heating apparatus is able to perform heating by using both the electric energy and the heat energy, be operated efficiently, drive by using only heat energy according to the circumstances, and be operable even in a region where no electricity is available.

Description

Hybrid type radiant heating device

The present invention relates to a radiant heating apparatus that heats an indoor space, and more particularly, to a hybrid type radiant heating apparatus that can be driven using heat energy as well as electricity, and thus has excellent utility and can be used outdoors.

There are various types of heating devices for heating an indoor space, and a suitable heating device is selected and applied according to the shape of the building or the characteristics of the space.

There are largely convective heating and radiant heating in the heating method. Convection heating is a heating method in which air is heated so that heated air is filled in an indoor space. However, convective heating has a disadvantage in that only the temperature around the heat supply source is high, and the temperature difference increases as the distance increases, and the temperature difference above and below the indoor space is large. In addition, in order to deliver high-temperature air to every corner of the room, a powerful blower must be used, so mechanical vibration or noise cannot be avoided.

Radiant heating is a heating method that uses heat radiation energy generated from a heated heat dissipation surface, and requires little ventilation of the room, and a rapid heating effect can be obtained even when room temperature is low. Radiant heating devices are electric heaters that use electric energy, and are often embedded in walls or ceilings.

As a background technology related to radiant heating, radiant cooling and heating panels have been disclosed through Korean Utility Model Publication No. 20-0465054. The disclosed radiant cooling and heating panel includes: a cold and hot water circulation pipe that is bent in a plurality of S-shapes and has hot and cold water inlets attached to both ends thereof; A circulation pipe cover formed along the longitudinal direction of the cold and hot water circulation pipe and wrapped around the cold and hot water circulation pipe and welded to the heat sink; Circulation pipe fixing plates formed on both sides of the heat sink to fix the cold and hot water circulation pipe; A heat sink welded to the circulation pipe cover in a state in contact with the bottom of the hot and cold water circulation pipe; It consists of an insulating material board to prevent heat loss to the wall or ceiling and an insulating material fixing guide for fixing the insulating material board to the top of the heat sink.The insulating material board is to prevent heat loss when the heat sink is installed on the wall or ceiling. It has a structure that is provided on the top of the heat sink and is fixedly installed by an insulating material fixing guide provided on the U-shaped edge on the top of the heat sink (5).

Domestic Registration Utility Model Publication No. 20-0465054 (radiative cooling and heating panel) Domestic Patent Publication No. 10-1078605 (radiative heating and cooling system and its construction method)

An object of the present invention is to provide a hybrid type radiant heating apparatus that can use both electric energy and thermal energy and can be used even in an area where electricity is not supplied.

The hybrid type radiant heating apparatus of the present invention as a means of solving the problems for achieving the above object comprises: a power supply for providing electric energy; A heat source providing heat energy; A radiant heating unit embedded in the floor of the room and generating heat using electric energy applied from the power source and heat energy applied from a heat source; It is installed on the side of the radiant heating unit and comprises a blowing unit that blows air to the upper surface of the radiant heating unit to diffuse heat, and the heat source is installed outdoors, receives water, and generates steam by combustion heat of fuel Includes a generator.

In addition, on the floor of the room, an installation space that is open toward the indoor space and in contact with a lower end of the wall is provided, and the radiant heating unit; An insulating housing seated inside the installation space and providing a space portion open to the top, a conductive cover plate horizontally disposed on the top of the insulating housing, and mounted on the bottom of the cover plate by power transmitted from the power source. A plate-shaped heating unit including a heating line for heating the cover plate by generating heat, and a heat pipe installed on the bottom surface of the cover plate to generate heat by heat applied from the heat source to heat the cover plate; A honeycomb plate installed on the upper part of the cover plate to prevent deformation of the cover plate due to a load applied from the outside, and having a through path through which heat of the cover plate passes upward; A stone plate that is placed on the honeycomb plate and is heated by receiving heat generated from the plate-shaped heating unit to serve as an ondol; It is located on the side of the heat insulating housing and includes a plate-shaped heating unit and a controller for controlling the operation of the air blower.

In addition, in the stone plate, a plurality of array holes for preventing overheating of the stone plate are formed by passing heat generated from the plate-shaped heating unit upward, and at the bottom of the stone plate, it is inserted into the through path of the honeycomb plate to prevent movement of the stone plate. A hexagonal protrusion is provided to prevent, and the wall has a fan accommodation space, and an inlet which communicates internally with the fan accommodation space and guides indoor air to the fan accommodation space, and the blower part; A motor built into the fan accommodation space, a fan rotating by the motor to blow air, and a grill installed in front of the fan and lowering the air blown from the fan to the upper surface of the radiant heating unit.

In addition, the radiation heating device is installed in the camping car, and outside the vehicle body of the camping car, a casing connected to the steam generating unit through a connection hose to receive the steam supplied from the steam generating unit is provided, and the inside of the casing , The heat transfer module is connected to the heat pipe and transfers the heat of the steam to the heat pipe.

The hybrid type radiant heating apparatus of the present invention made as described above can be operated efficiently because it can perform heating by using both electric energy and thermal energy, and in some cases, it can be driven using only thermal energy, so that no electricity is supplied. Can also be used locally.

1 is a cut-away perspective view showing a radiant heating unit of a hybrid radiant heating apparatus according to an embodiment of the present invention.
2 is a cross-sectional view for explaining the internal configuration of the radiant heating unit shown in FIG. 1.
3 is an exploded perspective view of the radiant heating unit of FIG. 2.
4 is a bottom view of the heating unit shown in FIG. 3.
5 is a block diagram showing the overall structure of a hybrid type radiant heating apparatus according to an embodiment of the present invention.
6 is a view showing a state in which the hybrid type radiant heating apparatus according to an embodiment of the present invention is applied to a camping car.

Hereinafter, one embodiment according to the present invention will be described in more detail with reference to the accompanying drawings.

The hybrid radiant heating apparatus of the present invention has a structure capable of outputting heating heat using electricity and heat. Electricity and heat can be used selectively or at the same time. The basic configuration of such a radiant heating apparatus includes a power supply for providing electric energy; A heat source providing heat energy; A radiant heating unit embedded in the floor of the room and generating heat using electric energy applied from the power source and heat energy applied from a heat source; It is installed on the side of the radiant heating unit and comprises a blowing unit that blows air to the upper surface of the radiant heating unit to diffuse heat, and the heat source is installed outdoors, receives water, and generates steam by combustion heat of fuel. Includes a generator.

1 is a partially cut-away perspective view showing a radiant heating unit 21 in a hybrid type radiant heating apparatus 20 according to an embodiment of the present invention, and FIG. 2 is a diagram illustrating the internal configuration of the radiant heating unit shown in FIG. 1 It is a cross-sectional view. In addition, FIG. 3 is an exploded perspective view of the radiant heating unit, and FIG. 4 is a bottom view of the heating unit shown in FIG. 3. And, Figure 5 is a block diagram showing the overall structure of the hybrid type radiant heating apparatus.

The radiant heating device 20 according to the present embodiment includes a power source 81, a heat source, a radiant heating unit 21, a blower 70, and a heat exchanger 85. In addition, the radiant heating unit 21 is provided with a heat pipe 45, a heating wire 43, and a controller 25. In addition, the heat source is a steam generator 83 to be described later.

The power source 81 may be an outlet for power supply in an environment where 220 volts of power is supplied. Alternatively, if the radiation heating device 20 is installed in a camping car (91 in FIG. 6) as shown in FIG. 6, the battery of the vehicle is a power source.

The power source 81 supplies electric power to the heating wire 43 to cause the smoke wire 43 to heat the cover plate 41 of the radiant heating unit 21. Since the heating principle of the heating wire 43 is a general matter, a description thereof will be omitted.

The steam generator (83 in FIG. 6) as a heat source generates steam by boiling water using the combustion heat of fuel, and a description thereof will be described later. The heat of the steam produced by the steam discharge unit 83 is transferred to the heat pipe 45. The heat pipe 45 heats the cover plate 41 by receiving heat from the steam and generating heat.

The power source 81 and the steam generator 83 may be selectively used in accordance with the surrounding environment, or may be used at the same time. That is, the radiant heating unit 21 can be operated only by electricity, only by heat, or by using both electricity and heat.

The radiant heating unit 21 is embedded in the floor 12 of the room 10 and generates heat using electric power and heat, and takes the shape of a rectangular panel as a whole, and is attached to the lower part of the wall 14. .

An installation space 12a is provided on one side of the floor 12. The installation space 12a is attached to the lower part of the wall 14 (as mentioned above) and is a space open to the upper part. The radiant heating apparatus of this embodiment is constructed on the floor, not on the ceiling nor on the wall, which is designed to realize both the effects of radiant heating and convection heating.

In addition, an inlet 15 and a fan accommodation space 16 are provided at one side wall 14. The fan accommodation space 16 is a space open toward the interior 10 and accommodates the blower 70. The blower 70 serves to blow air to the upper surface of the radiant heating unit 21. The inlet 15 is a passage that communicates with the fan accommodation space 16 inside the wall 14 and guides indoor air to the fan accommodation space 16. Indoor air enters the inlet 15, passes through the fan receiving space 16, and is discharged back into the room.

The radiant heating unit 21 includes an insulating housing 30, a plate-shaped heating unit 40, a honeycomb plate 50, a stone plate 60, and a controller 25.

The insulating housing 30 provides a space portion 30a that is seated in the installation space 12a and opened to the top. The insulation housing 30 may be made of ocher or stone, and in some cases, may be made of a tile for insulation on a wooden board.

The insulating housing 30 supports and supports the plate-shaped heating part 40, and accommodates the heating wire 43 and the heat pipe 45 in the space part 30a, as well as the heating wire 43 and the heat pipe 45. ) To prevent the heat from scattering to the floor as much as possible. As long as it can play such a role, the structure of the insulating housing 30 can be changed as much as possible. Reference numeral 32 denotes a pedestal for horizontally supporting the cover plate 41.

The plate-shaped heating part 40 is composed of a cover plate 41, a heating wire 43, and a heat pipe 45. The cover plate 41 is a rectangular plate made of aluminum and is supported by the frame 31 and the pedestal 32 of the insulating housing 30 to maintain the horizontal. The cover plate 41 is a heating plate that generates heat. According to an embodiment, a far-infrared layer capable of emitting far-infrared rays may be stacked on the upper surface of the cover plate 41.

As shown in FIG. 4, the heating line 43 is bent in a U-shape and is maintained in a fixed state through a plurality of heating line supports 43a. Heat generated from the heating line 43 passes through the heating line support 43a and is conducted to the cover plate 41. In addition, the end of the heating line 43 is connected to the controller 25 and receives power from the power source 81 through the controller 25.

The heat pipe 45 is also bent in a U-shape and is installed inside and outside the heating line support 43a, respectively. The heat pipe 45 is fixed to the bottom of the cover plate 41 using a plurality of fixing brackets 45a. In order to enlarge the interview area of the heat pipe 45 with respect to the cover plate 41, the heat pipe 45 has a flat pressed shape.

The end of the heat pipe 45 passes through the controller 25 and is inserted into the casing 85b of the heat exchanger (85 in FIG. 6), and then is coupled with the heat transfer module 45c. Heat transferred through the heat transfer module 45c heats the heat pipe 45, and the heat from the heat pipe 45 is transferred to the cover plate 41.

Eventually, the cover plate 41 is heated through the heating wire 43 and the heat pipe 45. In order to maximize the heat output of the radiant heating device, the heating line 43 and the heat pipe 45 are simultaneously operated, and when power is sufficient and external fire cannot be made, heat is generated only through the heating line 43. In addition, if heating is required while there is little remaining power of the battery, the power source 81 is turned off and only the heat pipe is operated.

The controller 25 is located on the side of the heat insulating housing 30, but is exposed to the top of the floor 12 as shown in FIG. 1, and controls the operation of the plate-shaped heating unit 40 and the blower. The controller 25 is provided with various operation buttons (no reference numerals) and a display window, and the user can operate the radiation heating device 20 through the controller 25.

The honeycomb plate 50 is installed on the cover plate 41 to prevent deformation of the cover plate 41 due to a load applied from the outside. For example, when the user sits or lies on the top of the radiant heating unit 21, it is to prevent sagging due to the user's weight. In addition, the hexagonal through-path 51 formed in the honeycomb plate 50 allows the heat of the cover plate 41 to pass upward.

The stone plate 60 is placed on the top of the honeycomb plate 50 and is heated by receiving heat generated from the plate-shaped heating unit, thereby acting as an ondol. The stone type of the stone slab can be applied in various ways. It is also possible to apply a reinforced soil plate instead of a stone plate.

A plurality of array holes 63 are formed in the stone plate 60. The array hole 63 is a hole that prevents overheating of the stone plate by passing heat generated in the plate-shaped heating part 40 upward. In addition, a plurality of hexagonal protrusions 61 are provided on the bottom surface of the stone plate 60. The hexagonal protrusion 61 is inserted into the through path 51 of the honeycomb plate to prevent movement of the stone plate. That is, it prevents the stone plate 60 from moving sideways.

The stone plate 60 may not be used. That is, there is no need for an ondol, and in order to quickly heat the air in the indoor space, the stone plate 60 is erected or moved to another place to completely open the through path 51. And, as long as it has the purpose of opening and closing the through passage 51, a lightweight synthetic resin plate or an aluminum plate may be applied in place of the stone plate.

The air blower 70 includes a motor 73, a fan 75, and a grill 71. The motor 73 is installed in the fan accommodation space 16 and is operated by the controller 25 to rotate the fan 75. The fan 75 is a propeller that is rotated by a motor and blows air. The grill 71 is installed in front of the fan 75 and guides the air blown from the fan downward to the upper surface of the radiant heating unit 21.

The air output from the blower 70 passes through the upper surface of the stone plate 60 or the honeycomb plate 50 and is heated. It has been mentioned above that indoor air is supplied to the fan receiving space 16 through the inlet 15 when the blower 70 is operated. It goes without saying that a filter (not shown) can be mounted on the inlet 15 if necessary.

6 is a view showing a state in which the hybrid type radiant heating apparatus 20 according to an embodiment of the present invention is applied to the camper 91. As shown in FIG.

As shown, the heat exchanger 85 is mounted outside the vehicle body of the camper 91. As shown in FIG. The heat exchanger 85 includes a casing 85b and a heat transfer module 45c, and the heat transfer module 45c is connected to the heat pipe 45.

Reference numeral 85c is a relief valve, and 85f is a drain valve. The relief valve 85c serves to discharge the pressure when the internal pressure of the casing 85b is higher than the set value. In addition, the drain valve 85f serves to drain the condensed water generated through heat exchange to the outside.

The heat exchanger 85 is connected to the steam generator 83 through a connection hose 83e. The steam generator 83 includes a heating chamber 83a for accommodating water 83c and a relief valve 83f, and generates steam by boiling water by heat transferred from the outside. The relief valve 83f is opened when the pressure inside the heating chamber 83a rises above the normal range to discharge steam.

The high-temperature steam generated in the steam generator 83 is supplied to the casing 85b through the connection hose 83e to heat the heat transfer module 45c. Of course, as the heat transfer module 45c is heated by receiving heat from the steam, the heat pipe 45 is also heated. The steam is condensed through heat exchange with the heat transfer module 45c and then discharged to the outside through the drain valve 85f. The above-described heat transmitted from the outside is combustion heat generated by burning fuel, and may be, for example, a bonfire 93.

In this way, since the radiant heating unit 21 in the room can be heated through the bonfire 93, so to speak, while spending time in front of the bonfire, in particular, without consuming power, the air in the room 10 can be heated in advance. There is.

In the above, the present invention has been described in detail through specific embodiments, but the present invention is not limited to the above embodiments, and various modifications are possible by those of ordinary skill within the scope of the technical idea of the present invention.

10: indoor 12: floor 12a: installation space
14: wall 15: inlet 16: fan accommodation space
20: radiant heating device 21: radiant heating unit 25: controller
30: insulation housing 30a: space 31: frame
32: base 40: plate-shaped heating part 41: cover plate
43: heating wire 43a: heating wire support 45: heat pipe
45a: fixing bracket 45c: heat transfer module 50: honeycomb plate
51: passageway 60: stone plate 61: hexagonal projection
63: array hole 70: air blower 71: grill
73: motor 75: fan 81: power
83: steam generator 83a: heating chamber 83c: water
83e: connection hose 83f: relief valve 85: heat exchanger
85b: casing 85c: relief valve 85f: drain valve
91: camping car 93: bonfire

Claims (4)

delete A power source providing electrical energy; A heat source providing heat energy; A radiant heating unit embedded in the floor of the room and generating heat using electric energy applied from the power source and heat energy applied from a heat source; It is installed on the side of the radiant heating unit and comprises a blowing unit that blows air to the upper surface of the radiant heating unit to diffuse heat, and the heat source is installed outdoors, receives water, and generates steam by combustion heat of fuel. Including a generator,
On the floor of the room, there is provided an installation space that opens toward the indoor space and contacts the bottom of the wall
The radiant heating unit; An insulating housing seated inside the installation space and providing a space portion open to the top, a conductive cover plate horizontally disposed on the top of the insulating housing, and mounted on the bottom of the cover plate by power transmitted from the power source. A plate-shaped heating unit including a heating line for heating the cover plate by generating heat; A honeycomb plate installed on the top of the cover plate to prevent deformation of the cover plate due to a load applied from the outside, and having a through path through which heat of the cover plate passes upward; A stone plate that is placed on the honeycomb plate and is heated by receiving heat generated from the plate-shaped heating unit to serve as an ondol; Located on the side of the heat insulating housing and having a plate-shaped heating unit and a controller for controlling the operation of the air blower,
Hybrid type radiant heating system. The method of claim 2,
In the stone plate, a plurality of array holes are formed to prevent overheating of the stone plate by passing heat generated from the plate-shaped heating unit upward,
A hexagonal protrusion is provided on the bottom of the stone plate to prevent movement of the stone plate by being inserted into the through path of the honeycomb plate,
The wall has a fan accommodation space, and an inlet which communicates internally with the fan accommodation space and guides indoor air to the fan accommodation space,
The blower;
A motor built into the fan accommodation space, a fan rotating by the motor and blowing air, a grill installed in front of the fan and lowering the air blown from the fan to the upper surface of the radiant heating unit,
Hybrid type radiant heating system. The method of claim 2,
The radiation heating device is installed in a camping car,
Outside the vehicle body of the camper, there is provided a casing connected to the steam generator through a connection hose to receive the steam supplied from the steam generator,
Inside the casing, a heat transfer module connected to the heat pipe to transfer the heat of the steam to the heat pipe is built,
Hybrid type radiant heating system.

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