JPH02575Y2 - - Google Patents

Description

[Detailed description of the invention] The present invention relates to a new heating device that effectively utilizes the characteristics of aerated concrete, and is used in rooms with aerated concrete walls that constitute the outer wall of a building and whose inner surface is an interior wall. An air intake port is formed at the upper part of the inner side, and an air outlet is formed at the lower part of the indoor side thereof, and a ventilation path communicating with the air intake port and the air outlet is formed in the wall, and the air intake port side of the ventilation path is formed. The present invention provides a heating device built into an aerated concrete wall, characterized in that an intake fan is disposed at the side of the air outlet, and a heater is disposed at the outlet side.

Hereinafter, an embodiment in which the heating device of the present invention is applied to an outer wall made of aerated concrete will be described based on the drawings.

In Fig. 1, reference numeral 1 denotes an aerated concrete wall that constitutes the outer wall of a building and whose inner surface is an indoor wall.An air intake port 2 is provided at the upper part of the indoor side of the wall 1, and an air intake port 2 is provided at the upper part of the indoor side of the wall 1. Air outlet ports 3 are formed in the lower part, and an air intake port 2 and an air outlet port 3 are formed in the wall 1.
A ventilation passage 4 is formed to communicate with the. An intake fan 5 is disposed on the inlet side of the ventilation passage 4, and a heater 6 is disposed on the outlet side.

The number of intake ports 2, outlet ports 3, and ventilation channels 4 is not particularly limited, but it is preferable to arrange a plurality of them in parallel.
These are preferably formed integrally when forming the cellular concrete wall 1. It is preferable to attach a louver 7 to the inlet 2 and a guard 7' to the outlet 3, as shown in the drawings.

Further, as the heater 6, it is preferable to use a ceramic heater which has a large number of ventilation holes and whose Curie point can be arbitrarily set. This ceramic heater has the characteristic that when it is heated above the set temperature, its internal resistance rapidly increases and the value of the current flowing through it sharply decreases. It has the advantage that it does not need to be attached.

Further, the fan 5 and heater 6 can be controlled by an electric circuit as shown in FIG. In FIG. 2, 8 is a power supply, 9 is a main switch, and 10 is a thermostat. If such a circuit is used, the fan 5 and heater 6 can be turned off by the thermostat 10 at a set temperature, or the heater 6 can be turned off depending on the characteristics of the ceramic heater as described above.
can be turned off. However, Juan 5
The control of the heater 6 is not limited to the above-mentioned control, and especially when a plurality of fans 5 and heaters 6 are used as described above, various types of control are possible. For example, if the Curie points of the respective heaters 6 are made different, it is possible to sequentially turn off a plurality of heaters 6 in response to a rise in temperature;
The thermostat 10 can be constructed using multiple circuits shown in the figure.
If the operating points of the fan 5 and heater 6 are set to be different, the fan 5 and heater 6 can be turned off sequentially as the temperature rises.Furthermore, the air volume can be changed by the thermostat 10, the air volume can be changed by the manual changeover switch, and the airflow can be changed by the manual changeover switch. It is possible to perform switching, turn on/off the heater 6, etc.

In addition, in Figure 1, 11 is the foundation, 12 is the floor, 1
3 is a ceiling part, and 14 is a roof part.

Since the heating device of the present invention shown in FIG. 1 is configured as described above, by operating the fan 5 and heater 6, indoor air is sucked into the ventilation path 4 from the intake port 2 by the fan 5. The sucked air is heated by the heater 6 and blown out from the outlet 3, so that the air can be effectively convected indoors.

The effects of the heating device of the present invention shown in FIG. 1 are listed below.

(1) Unlike general heating equipment that is installed indoors, it is built into the aerated concrete wall 1, allowing a wider living space to be used.

(2) Since the wiring can be embedded within the aerated concrete wall 1, there is no need to worry about cords getting in the way.

(3) Since it is built into the aerated concrete wall 1, a casing is not required and there is a cost advantage.

(4) Since the aerated concrete wall 1 is used, the air inlet 2, outlet 3, ventilation passage 4, and space for embedding the fan 5, heater 6, and cord can be formed at the same time as forming the wall.

(5) The aerated concrete wall 1 has superior thermal insulation properties compared to solid concrete, so it has good thermal efficiency.

(6) Since it is built into the aerated concrete wall 1, there is no need to store it outside of the season, and no space is required.

(7) By using a ceramic heater as the heater 6, heating can be easily prevented.

(8) Rapid heating is possible compared to floor heating.

(9) Odorless and harmless compared to kerosene and gas methods.

The heating device of the present invention is not limited to being built into an outer wall as in the above embodiment, but can be built into a partition wall made of aerated concrete.
Further, a ventilation hole communicating with the outdoors may be provided in the ventilation passage 4 to perform ventilation or to perform heat exchange.

As mentioned above, since the heating device of the present invention is built into the aerated concrete wall, it has various advantages and its practical value is extremely high.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view of an embodiment of the present invention, and FIG. 2 is a wiring diagram showing an example of an electric circuit used therein. 1...Aerated concrete wall, 2...Intake port, 3
...Air outlet, 4...Ventilation path, 5...Intake fan,
6...Heater.

Claims (1)

[Scope of utility model registration request] An air inlet is formed at the upper part of the indoor side of the aerated concrete wall that constitutes the outer wall of the building and whose inner surface is the indoor wall, and an air outlet is formed at the lower part of the indoor side, and the air inlet and the air outlet are formed. A heating unit built into an aerated concrete wall, characterized in that a communicating ventilation passage is formed in the wall, and an intake fan is arranged on the intake port side of the ventilation passage, and a heater is arranged on the outlet side of the ventilation passage. Device.