JPH0754554Y2 - Bathroom door with internal heating device - Google Patents

Description

[Detailed Description of the Invention] <Industrial field of application> The present invention relates to a door provided in an entrance / exit of a bathroom, more specifically, a bathroom door suitable for heating a dressing room and a bathroom and dehumidifying the inside of the bathroom. Regarding

<Prior art and its problem> A bathroom is provided inside and a dressing room is provided outside with a bathroom door as a boundary. In the winter, heating the dressing room and heating the bathroom,
To dehumidify, it is customary to install heating and dehumidifying equipment in the bathroom or dressing room. However, in order to heat the dressing room and the bathroom by one heating and dehumidifying device and further dehumidify the inside of the bathroom, a sufficient space for installing the heating and dehumidifying device must be secured, and the duct configuration is complicated. There are many problems such as

<Means for Solving the Problems> The present invention has been devised in view of the above problems, and is a bathroom door that is arranged between the dressing room and the bathroom to heat the dressing room and the bathroom, respectively. A pair of passages are formed inside the door along the vertical direction of the door, and between these passages, a Peltier element is used to form a heat-dissipating surface and a heat-absorbing surface on the front and back sides. The passage is provided such that the surface faces one of the passages and the heat absorbing surface faces the other, and the lower portion of the door is in communication with the passage facing the heat radiating surface of the heat device and the undressing chamber. Means are provided, and at the upper part of the door on the side of the dressing room, a blow-out port for communicating the passage facing the heat dissipation surface with the dressing room is provided so as to be openable and closable. A suction port that connects the passage facing the heat dissipation surface with the inside of the bathroom is provided, and the bathroom side of the door is provided. An air outlet that connects the passage facing the heat radiating surface and the inside of the bathroom is openably and closably provided in the upper portion, and an inlet that communicates between the passage facing the heat absorbing surface and the inside of the bathroom is provided on the upper portion of the door on the bathroom side. A mouth is provided, a drainage channel is provided in the lower part of the door for communicating the passage facing the heat absorbing surface with the bathroom, and the door is provided from the lower side to the upper side in the passage facing the heat radiating surface. A fan is provided for causing the air to flow toward, and for causing the air to flow downward from above in the passage facing the heat absorbing surface.

<Operation> That is, according to the bathroom door of the present invention, while performing the opening and closing function in the opening and closing of the conventional bathroom, the air in the dressing room is circulated to the passage facing the heat dissipation surface of the heating device and the air in the dressing room is undressed. The dressing room is heated by blowing it toward the room.
Similarly, the bathroom air is circulated through the passage facing the heat dissipation surface to heat the air, and the air is blown to the bathroom side to heat the bathroom. Moreover, at this time, if the bathroom air is sucked through the suction port provided above the bathroom door and circulated through the passage facing the heat absorbing surface, the heat absorbing surface dehumidifies the bathroom air. That is, heating is performed in the dressing room, and dehumidification is performed together with heating in the bathroom. Therefore, in winter, there is no temperature difference between the dressing room and the bathroom, and it is possible to provide comfortable bathing conditions.

<Embodiment> A bathroom door in which the heating device of the present invention is installed will be described in detail with reference to the drawings.

FIG. 1 is a schematic vertical sectional view of a bathroom door 1 in which a heating device is installed. Bathroom door 1 has slit 11 downwards and intake port upwards
12 is provided, and at the lower part of the suction port 12, there are provided an outlet 13 on the bathroom side and an outlet 14 on the dressing room side, respectively. The air outlet 13 and the air outlet 14 are configured to be openable / closable by a known opening / closing means such as a louver.

A suction port 15 is opened below the door and on the bathroom side. The suction port 15 communicates with the slit 11 via the bathroom, and thus the suction port 15 in combination with the slit 11 allows the air on the dressing room side to flow in, as will be described later. It constitutes a communication means. In the bathroom door 1 having the above-mentioned configuration, the heating device 2 is installed in a state where the door inner surface is substantially centered and the inner surface direction of the door is partitioned by the pair of passages 16 and 17. Heat dissipation surface 21 of heat device 2
Is disposed toward the passage 16, that is, facing the passage 16, while the heat absorption surface 22 is directed toward the other passage 17, that is, the passage.
It is located facing 17. A rotary fan 3 is built in the suction port 15 on the bathroom side. The rotary fan 3 sucks each air from the dressing room O and the bathroom I through the suction port 15 through a passage 16 as described later. Bathroom outlet 13
And, it is blown out from the outlet 14 on the side of the dressing room. The air from the passage 16 is blown into the air outlet 13 on the bathroom side and the air outlet 14 on the dressing room side, respectively.
A switching damper 4a is provided in order to blow the air to the other side, and another switching damper 4b is used to open and close the outlet 14 on the dressing room side.
Is provided.

On the other hand, the heat device 2 sandwiches a semiconductor Peltier element made of a bismuth tellurium (Bi ₂ Te ₃ ) compound or the like in a sandwich shape by a heat radiating surface 21 and a heat absorbing surface 22, and connects a DC power supply circuit (not shown) to either one of the Peltier elements. It is connected. That is, when a predetermined voltage, for example, a voltage of about 15v is applied to the Peltier device by this DC power supply circuit, the heat dissipation surface 21 performs heat dissipation. At this time, the heat absorbing surface 22 absorbs heat, and a so-called Peltier effect is exhibited. Usually this heat device 2
Is sealed with a resin mold and has high moisture resistance. Moreover, since the Peltier effect is exhibited by the applied voltage of the DC power supply circuit, unlike the conventional cooling and heating device,
No medium such as liquid or gas is required, and operation and maintenance are very simple. Further, it is less likely to cause noise and vibration, and is suitable for being incorporated in an indoor bathroom door.

The heating and dehumidifying actions of the bathroom door 1 having the above configuration will be described.

FIG. 1 (a) shows a state in which the dressing room O is heated. First, the switching dampers 4a and 4b are driven to connect the outlet 14 and the passage 16 on the dressing room side. When the slit 11 is opened and the rotary fan 3 is rotated, the air in the undressing chamber O passes through the slit 11 and the suction port 15 to the rotary fan 3
Is pumped to passage 16. At this time, the air is radiating surface
It is heated by the heat from 21 and is blown into the dressing room O from the outlet 14 on the dressing room side. A part of the warm air enters the passage 17 and is cooled by the heat absorbing surface 22 when it is blown out from the outlet 14 on the side of the dressing room, but the amount thereof is a little and reduces the heating effect of the dressing room O. is not.

On the other hand, when heating the bathroom I, as shown in FIG. 1 (b), the switching damper 4a is driven to communicate the passage 16 and the outlet 13 on the bathroom side, and the switching damper 4b allows the outlet 14 on the dressing room side to be communicated. Close. In addition, the slit 11 is closed. Then, by rotating the rotary fan 3, the suction port
The air in the bathroom I is pushed into the passage 16 from 15 and heated by the heat radiation surface 21. Further, the air heated by the pressing of the rotary fan 3 is blown to the bathroom I side from the bathroom outlet 13 so that the bathroom I is heated. Further, in such a state, above the bathroom I, air is sucked from the suction port 12 provided between the upper parts of the bathroom doors and circulates in the passage 17. At this time, air is absorbed on the heat absorbing surface 22. The air has a high humidity above the bathroom I. Therefore, when the heat absorbing surface 22 is cooled, condensed water is generated. As a result, the inside of the bathroom I is dehumidified.

The condensed water is discharged into the bathroom I from the drainage channel 8 communicating with the lower part of the passage 17. FIG. 2 is a schematic vertical sectional view showing another embodiment of the present invention. This example shows two fans
6,7 and four dampers 4a, 4b, 5a, 5b are used.
Therefore, the rotary fan 3 is not required as in the above-described embodiment, and the fans 6 and 7 can forcibly suck and discharge air from the dressing room O and the bathroom I. The figure (a) is a dressing room O
Is for heating. Although a distribution path similar to that of FIG. 1 (a) is obtained, in this embodiment, the damper 5a closes the intake port 15a on the bathroom side, and the damper 5b is actuated to establish the communication means in the present invention. The inlet 15b on the side of the changing room is opened. Then, similar to the above, the switching dampers 4a and 4b are respectively rotated to rotate the passage 16 and the outlet 14 on the side of the changing room.
And communicate with. Then, the fan 6 provided at the outlet 14 on the dressing room side is rotated. As a result, the air from the dressing room O is sucked into the passage 16 through the suction port 15b. At this time, the air is heated on the heat dissipation surface 21 of the heat device 2. If this air is blown into the dressing room O from the outlet 14 on the dressing room side, the dressing room O will be heated.

On the other hand, FIG. 2 (b) is for heating the bathroom I. In this case, the switching dampers 4a and 4b are respectively rotated to move the passage 16 as described above.
And the air outlet 13 on the bathroom side are communicated with each other, and the air outlet 14 on the dressing room side is closed by the switching damper 4b. Further damper
The suction port 15a on the bathroom side is opened by rotating 5a. Then, the damper 5b closes the inlet 15b on the side of the dressing room.

In such a state, the fan 7 provided at the outlet 13 on the bathroom side
When is rotated, the air in the bathroom I is sucked into the bathroom side intake port 15a.
Is inhaled into the passage 16 via the. In this passage 16, as described above, the inhaled air is heated by the heat dissipation surface 21.
When this heated air is blown into the bathroom through the outlet 13 on the bathroom side, the air in the bathroom I becomes warm and the tiles forming the bathroom floor are also warmed. Further, when the bathroom I is heated, the air in the bathroom is sucked from the suction port 12 provided in the upper portion of the door 1 to reach the passage 17 and is absorbed by the heat absorbing surface 22. That is, the dehumidifying action is performed as described above, and the dew condensation water generated at this time is discharged to the bathroom I side through the drainage channel 8.

The air dehumidified in the passage 17 enters the passage 16, but this is a small amount and does not reduce the heating efficiency of the bathroom I.

<Effect of device> As described above, the bathroom door in which the heating device of the present invention is installed not only serves the function of opening and closing the bathroom, but also heats the dressing room and the bathroom by the Peltier effect of the installed heating device. Moreover, since the bathroom itself can be dehumidified, the cold air at the time of undressing can be softened at the time of bathing in the winter season, and the cold feeling of the floor tiles of the bathroom can be eliminated, so that the effect can be mitigated. In addition, a heating device that uses a Peltier element that simultaneously radiates and absorbs heat allows both heating and dehumidification to be performed at the same time, which simplifies the overall piping structure and reduces the size and size of the heating device itself. Since the thickness of the bathroom door is not increased, the opening / closing operability of the bathroom door is not significantly impaired as compared with the conventional one. Furthermore, since no cooling / heating medium such as liquid or gas is used for heating and dehumidifying, operation and maintenance are extremely easy. Further, a suction port is provided in the upper part of the door on the bathroom side so that the passage facing the heat absorbing surface of the heat device communicates with the inside of the bathroom, and the lower part of the door allows the passage facing the heat absorbing surface to communicate with the inside of the bathroom. Since the drainage channel is provided, the air in the bathroom can be cooled by allowing the air in the bathroom to flow into the passage facing the heat absorbing surface, condensing its moisture content into water and discharging it. When using the bathroom as a drying room to dry laundry, etc., the bathroom can be heated (dried) and dehumidified at the same time, and therefore laundry can be dried extremely quickly and at low cost. You can

[Brief description of drawings]

FIG. 1 is a schematic vertical sectional view showing a bathroom door of the present invention, and FIG. 2 is a schematic vertical sectional view showing another embodiment. 1 …… Bathroom door, 12 …… Suction port, 13 …… Bathroom outlet, 14
...... Outlet on the side of the changing room, 15 …… Suction port, 16, 17 …… Aisle, 2
...... Heat device, 21 ...... Heat dissipation surface, 22 ...... Heat absorption surface, 3 ...... Rotary fan, 4a, 4b …… Switching damper, 5a, 5b …… Damper,
6,7 …… Fans.

Claims (1)

[Scope of utility model registration request] 1. A dressing room disposed between the dressing room and a bathroom,
A bathroom door for heating a bathroom, wherein a pair of passages are formed inside the door along the vertical direction of the door, and a Peltier element is used between the passages to radiate heat on the front and back sides. And a heat-absorbing surface is formed, the heat-dissipating surface is provided so as to face one of the passages, and the heat-absorbing surface faces the other, the lower portion of the door of the heat device. A communication means for communicating the passage facing the heat radiating surface with the undressing chamber is provided, and a blowout opening for communicating the passage facing the heat radiating surface with the undressing chamber is provided on the upper part of the door on the undressing chamber side. In the lower part of the door on the bathroom side, there is provided an inlet for communicating the passage facing the heat dissipation surface with the inside of the bathroom, and on the upper part of the door on the bathroom side, the passage facing the heat dissipation surface and the bathroom. An air outlet that communicates with the inside is provided so that it can be opened and closed, and the upper part of the door on the bathroom side is A suction port is provided for communicating the passage facing the heat absorbing surface with the inside of the bathroom, and a drainage passage for communicating the passage facing the heat absorbing surface with the inside of the bathroom is provided at a lower portion of the door, and the door is provided at the door. A fan is provided for causing air to flow from below to above in the passage facing the heat dissipation surface, and to flow air from above to below in the passage facing the heat absorbing surface. A bathroom door with a built-in heat device.