JPH08233319A - Natural ventilating device - Google Patents

Abstract

PURPOSE: To effect natural ventilation without intercepting the inside of a building from the outside of the same and without occupying any big space. CONSTITUTION: A controller 3c recognizes the direction and the angle of sun 1 and controls the direction of a mirror 4 based on a signal from a light sensor 3b so that the surface of the mirror 4 is faced to the direction of the sun 1 and reflecting light is projected immediately downward against a tracking device 3. A photo detector 10 absorbs heat from reflecting light 5 from the mirror 4 whereby the temperature of the same is risen. The photo detector 10 is insulated from a floor 9 through a heat insulating material 12 while the heat, absorbed by the photo detector 10, is transferred efficiently to air, contacting with the surface of the same. As a result, the temperature of air on the surface of the photo detector 10 rises and the air produces ascending stream 6, ascending upward in the building and discharged out of an exhaust port 11 to the outside of the building. Further, the ascending airstream is generated in such a manner whereby fresh air 7 flows into the building through the opened side part of the building.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for ventilation inside a building.

[0002]

2. Description of the Related Art In buildings where a large number of people gather, in order to take in fresh air from the outside and in the summer, for ventilation,
Ventilation is provided. The most common ventilator is
It is a ventilation fan that blows air by rotating the fan with a motor.
On the other hand, the natural ventilation system uses the pressure difference between the inside and outside of the building due to the temperature difference between the inside and the outside of the building and the wind pressure as the driving force for moving the air, and it generates noise like a ventilation fan. Does not occur and consumes no power,
Alternatively, it has a characteristic that the consumption amount is extremely small.

[0003]

However, in the conventional natural ventilation system, there must be a difference in atmospheric pressure between the inside and the outside of the building, and therefore, in order to maintain such a pressure difference, the inside of the building must be maintained. Need to be properly shielded from the outside.
As a result, it is not necessarily suitable for a building that has a large number of people coming in and going out and the entrance and exit must be sufficiently wide, and a building having a large interior space. Further, in the case of a natural ventilation device that uses wind pressure, it is necessary to install a monitor or the like in order to effectively use the wind pressure, and a space for it must be secured in the room.

An object of the present invention is to solve the above problems and to provide a natural ventilation device that does not require the building to be shielded from the outside and can effectively utilize the space inside the building.

[0005]

In order to achieve the above object, the invention of claim 1 is a device for ventilating an interior of a building, comprising a mirror for reflecting sunlight and a mirror driving means for changing the direction of the mirror. Provided in the building, the light receiving means on which the sunlight reflected by the mirror is incident, the heat insulating means for thermally insulating the light receiving means from other constituent elements of the building, and the upper part of the building. And an air vent, which raises the temperature of the light receiving means by sunlight and heats the surrounding air to form an updraft.

According to the present invention, the mirror driving means includes a first motor for changing the horizontal direction of the mirror, and a second motor for changing the vertical direction of the mirror.
An optical sensor that receives sunlight and outputs an electrical signal, and the first and second optical sensors based on the signal from the optical sensor.
And a control device for controlling the motor.

Further, the present invention is characterized in that the light receiving means is provided in a lower portion in the building. Further, the invention is characterized in that the light receiving means forms part of the floor of the building. Further, the present invention is characterized in that the building is provided with a doorway that is widely opened to the surroundings.

[0008]

In the natural ventilation apparatus of the present invention, the mirror driving means can change the angle and direction of the mirror so that the reflecting surface of the mirror is always directed toward the sun. The sunlight reflected by this mirror enters a light receiving means provided at a predetermined place in the building. As a result, the temperature of the light receiving means rises, so that the surrounding air is also warmed. The warmed air becomes an updraft and is discharged to the outside of the building through the ventilation hole at the top of the building. Since the light receiving means is thermally insulated by the heat insulating means, the heat absorbed by the light receiving means from sunlight is efficiently transferred to the air.

[0009]

EXAMPLES Next, examples of the present invention will be described. FIG.
FIG. 1 is a schematic sectional view of a building including an example of a natural ventilation device according to the present invention. Since this building is an outdoor rest facility,
There are no walls between most of the pillars 13 that support the roof 8 so that people can enter and leave freely.

At the top of the center of the building, the sun tracking device 3 is provided on the cylindrical projection 8a of the roof 8. 3a
Is a dome made of transparent plastic, in which the mirror 4 is housed. The mirror 4 is attached to a drive mechanism (not shown) including two motors, and one motor can change the horizontal direction of the mirror 4 and the other motor can change the vertical direction. ing. An optical sensor 3b that receives sunlight and outputs an electric signal is provided at the tip of the dome 3a. Then, the control device 3c of the sun tracking device 3 controls the drive mechanism based on the signal from the optical sensor 3b to set the direction and angle of the mirror 4. An exhaust port 11 is formed in the projecting portion 8a so that the air in the building can be discharged. On the other hand, since walls are not provided between most of the columns 13 as described above, air can freely flow into the building from that portion.

On the floor 9 directly below the protruding portion 8a, there is arranged a light receiving portion 10 which is illuminated by sunlight. FIG. 2 is a sectional view showing the light receiving unit 10 in detail. The light receiving unit 10 is made of a material that easily absorbs heat of sunlight, and has a dark surface color so as to easily absorb heat. Since the light receiving portion 10 forms a part of the floor 9, the surface thereof has the same height as the floor 9. Then, in order to prevent the heat absorbed by the light receiving unit 10 from escaping downward and sideward, a heat insulating material 12 is arranged between the lower portion of the light receiving unit 10 and the floor of the side portion. Since the heat insulating material 12 is a part of the floor, a material having a sufficient heat insulating effect and a required strength is used as the material.

Next, the operation will be described. The optical sensor 3b receives the light 2 from the sun 1 and converts it into an electric signal and outputs it. The control device 3c recognizes the direction of the sun 1 based on the signal, and controls the drive mechanism so that the surface of the mirror 4 faces the direction of the sun 1 and the reflected light goes directly below the tracking device 3. The control device 3c always performs such control.

Therefore, the light 2 from the sun 1 always enters the mirror 4, is reflected by the surface thereof, and enters the light receiving portion 10 provided directly below the tracking device 3. The light receiving section 10 absorbs heat from the reflected light 5 from the mirror 4, and as a result, the temperature rises. Since the light receiving unit 10 is insulated from the floor 9 by the heat insulating material 12, the heat absorbed by the light receiving unit 10 is efficiently transferred to the air in contact with the surface thereof. Therefore, the temperature of the air on the surface of the light receiving unit 10 rises, becomes an updraft 6 and travels upward in the building, and is discharged to the outside of the building through the exhaust port 11. Further, when such an ascending airflow is generated, fresh air 7 flows into the building from the open portion on the side of the building. That is, the air in the building becomes the rising airflow 6 and is exhausted, and the fresh air 7 flows in from the outside to realize the ventilation of the building.

Next, another embodiment of the present invention will be described. FIG. 3 is a schematic cross-sectional view showing a high-rise building having a large space inside, which is equipped with a natural ventilation device according to another embodiment of the present invention. In the figure, the same components as those in FIG. 1 are designated by the same reference numerals. Reference numeral 19 is the main body of the building, which is composed of multiple floors. The space between the main body portions 19 is a large open space. A cylindrical protruding portion 19a is formed on the roof of the one main body portion 19.

The sun tracking device 3 is arranged on the protruding portion 19a. Since this configuration is exactly the same as that of FIG. 1, description thereof is omitted here. An inverted L-shaped light guide path 14 penetrating the body portion 19 is provided below the protruding portion 19a.
Is formed, and a reflecting mirror 15 is provided on the bent portion.
However, a reflecting mirror 16 is arranged at the outlet.

A light receiving portion 10 is formed at the center of the floor 9 as in the case of FIG. The structure of the light receiving unit 10 is also
Since it is the same as the light receiving unit in FIG. 1, description thereof will be omitted here. An exhaust port 17 is formed in the roof part in the center of the building so that the air in the large space can be exhausted. In addition, an opening to the outside of the building is provided on the first floor of the main body portion 19 so that air can flow in from the outside. A shielding screen 18 is provided at the upper part of the space to prevent direct sunlight from entering the interior. This screen has a large number of holes so that the air flow is not obstructed.

Next, the operation will be described. The operation of the sun tracking device 3 is basically the same as the case of FIG. That is, the optical sensor 3b (see FIG. 1) receives light from the sun 1, converts it into an electric signal, and outputs it. The control device 3c (see FIG. 1) recognizes the direction and angle of the sun 1 based on the signal, and drives so that the surface of the mirror 4 faces the direction of the sun 1 and the reflected light goes directly under the tracking device 3. Control the mechanism. The control device 3c always performs such control.

Therefore, the light 2 from the sun 1 always enters the mirror 4, is reflected by the surface thereof, and enters the reflecting mirror 15 provided directly below the tracking device 3. The light 5 reflected by this mirror is further reflected by the reflecting mirror 16 and enters the light receiving unit 10. Then, the light receiving unit 10 absorbs heat from the reflected light 5, and as a result, the temperature rises. Since the light receiving unit 10 is insulated from the floor 9 by the heat insulating material 12 (see FIG. 2), the heat absorbed by the light receiving unit 10 is efficiently transferred to the air in contact with the surface thereof.

Since a shielding screen 18 is provided above the space portion to block direct sunlight, the air in the space portion is not entirely warmed by the sunlight, so that only the air on the surface of the light receiving portion 10 is heated. Rises and becomes an ascending air current 6 and goes upward in the building, and is discharged to the outside of the building through an exhaust port 17. Further, when such an ascending air current is generated, fresh air 7 flows into the building from the open portion on the first floor of the building. That is, the air in the building becomes the rising airflow 6 and is exhausted, and the fresh air 7 flows in from the outside to realize the ventilation of the building.

In these embodiments, the optical sensor 3b
The sun is detected by and the direction of the mirror 4 is controlled. However, since the position of the sun corresponds to the time, the direction of the mirror may be set according to the time by correcting the position according to the season. In that case, the sensor 3b is unnecessary. Further, although the light receiving unit 10 is provided as a part of the floor 9, it may be provided as a part of a wall or the like, or may be provided independently of other structures. The exhaust port 11 is preferably provided at the uppermost portion of the building, but is not necessarily limited to this, and may be at the uppermost portion as long as sufficient exhaust is possible.

[0021]

As described above, in the natural ventilation device of the present invention, the direction of the mirror is changed by the mirror driving means,
The reflective surface of the mirror can be set to always face the sun.
The sunlight reflected by this mirror enters a light receiving means provided at a predetermined place in the building. As a result, the temperature of the light receiving means rises, so that the surrounding air is also warmed. The warmed air becomes an updraft and is discharged to the outside of the building through the ventilation hole at the top of the building. Since the light receiving means is thermally insulated by the heat insulating means, the heat absorbed by the light receiving means from sunlight is
Efficiently transmitted to the air.

As described above, in the natural ventilation device of the present invention, ascending airflow is generated in the building by utilizing solar heat to perform ventilation, so that it is not necessary to shut off the building to the outside as in the conventional case, and the entrance / exit Ventilation can be effectively performed even in a building that is always open or a building that has a large space inside. Moreover, since it is not necessary to install a device such as a monitor in the room of the building, the space of the building can be effectively used.

[Brief description of drawings]

FIG. 1 is a schematic cross-sectional view showing a building of a rest facility equipped with an example of a natural ventilation device of the present invention.

FIG. 2 is a partial cross-sectional view showing in detail a light receiving portion that constitutes an example of the natural ventilation device of FIG.

FIG. 3 is a schematic cross-sectional view showing a high-rise building having a large space inside, which is provided with an example of the natural ventilation device of the present invention.

[Explanation of symbols]

 1 sun 2 light 3 sun tracking device 3c control device 4 mirror 5 reflected light 8 roof 9 floor 10 light receiving part 11, 17 exhaust port 12 heat insulating material

Claims (5)

[Claims] 1. A device for ventilating an interior of a building, comprising: a mirror that reflects sunlight; a mirror driving means that changes the direction of the mirror; and sunlight that is provided inside the building and reflected by the mirror. A light receiving unit, a heat insulating unit that thermally insulates the light receiving unit from other components of the building, and a vent provided in the upper part of the building, and increase the temperature of the light receiving unit by sunlight. A natural ventilation device, characterized in that the surrounding air is heated to form an ascending air current. 2. The mirror driving means includes a first motor for changing the horizontal direction of the mirror, a second motor for changing the vertical direction of the mirror, and an electric signal received by sunlight. The natural ventilation device according to claim 1, further comprising an optical sensor for outputting and a control device for controlling the first and second motors based on a signal from the optical sensor. 3. The natural ventilation device according to claim 1, wherein the light receiving means is provided in a lower portion of the building. 4. The natural ventilation device according to claim 1, wherein the light receiving means forms part of a floor of the building. 5. The natural ventilation device according to claim 1, wherein the building is provided with a doorway that is open to the periphery.