KR101410440B1 - Natural ventilation and heating system using solar radiation energy for buildings - Google Patents

Abstract

The present invention relates to an air conditioner which is formed as a space capable of flowing air into an outer wall of a building and has a heat collecting plate and is formed so that the inside air can be heated and raised by solar radiation heat, And a suction port through which the outside air can be introduced into the upper portion; A supply port connected to the heat collection chamber and providing supply air to a building interior; An outside air bypass regulator installed in the intake port and selectively allowing the air to flow into the air supply duct or the air heated and raised in the interior of the heat collection chamber into the air supply duct; An exhaust duct which is installed on the outer wall of the building in such a manner that a lower end thereof is opened in a height direction and is formed of a material capable of absorbing solar heat and is capable of forming a rising air flow therein; And an exhaust pipe connected to the exhaust duct and serving as a passage through which indoor air is discharged.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a natural ventilation and heating system using solar radiation,

[0001] The present invention relates to a building ventilation and heating system using solar radiation, and more particularly, to a system and a method for reducing energy consumption by allowing natural ventilation and heating of indoor air using solar radiation And to a building natural ventilation and heating system using solar radiation.

A building ventilation and heating system using solar heat as a building ventilation and heating system capable of reducing energy use has been proposed.

1 is a schematic view showing a schematic configuration of a building ventilation and heating system using solar radiation. Referring to FIG. 1, a building ventilation and heating system using solar heat is composed of a heat collection chamber 3 And a gas supply duct 8 for connecting the heat collection chamber 3 and the building interior 2.

The heat collecting chamber 3 is provided in the building outer wall 1 and has a space separated from the building outer wall 1 so as to be able to receive and flow air therein. So that the internal air can be heated using solar radiation. An air inlet port 4 through which outside air can flow is formed in the lower part of the heat collection chamber 3 and an air inlet port 6 provided with a damper 5 for controlling the inflow of outside air to the upper side is formed.

The air supply duct 8 is a passage through which air flows into the inside of the building 2. The inlet is located in the heat collection chamber 3 and is connected to the heat collection chamber 3, It is configured to be able to flow in forced ventilation mode. The inlet of the air supply source (8) is arranged to face the damper (5) for controlling the inflow of outside air.

FIGS. 2 and 3 are views for explaining the winter season and the summer season operation of the building ventilation and heating system using the solar radiation heat of the above-described configuration.

Referring to FIG. 2, in the winter, the damper 5 for controlling the inflow of outside air is closed so that the outside air is introduced only through the air inlet 4. The heat collecting plate of the heat collecting chamber 3 uses solar heat irradiated toward the building, Thereby heating the air inside the chamber 3. Therefore, the outside air flowing through the air inlet (4) is heated and buoyant, and the air introduced into the room for ventilation during the winter is introduced into the heated state by utilizing the solar radiation heat, have.

Referring to FIG. 3, since the air heated in the heat collecting chamber 3 is not required during the summer when cooling is required, the outside air can be directly introduced into the room through the air supply duct 8. The damper 5 for controlling the inflow of outside air is opened and the damper 5 for controlling the influx of outside air is opened by the suction pressure when the fan 9 of the air supply source 8 is driven, Ventilation is performed.

According to the building ventilation and heating system using the solar radiation of this configuration, since the solar radiation heat is not used unlike the winter in summer, the energy saving effect is limited and the ventilation is performed only when the fan 9 is in operation. There is a problem of noise generation due to consumption and fan operation.

In addition, the outside air inflow controlling damper 5 is opened in order to directly introduce the unheated outside air into the interior of the building in summer, but the air heated and raised inside the heat collecting chamber 3 during operation of the fan 9 of the air supply / There is a problem in that the energy required for cooling increases because it flows into the air supply duct 8 also.

The present invention has been devised to solve the above-mentioned problems. It is an object of the present invention to provide an air conditioner that can perform natural ventilation of building indoor air by using air heating by solar radiant heat in winter or summer, And to provide a building natural ventilation and heating system using solar radiation that can reduce energy use.

The object of the present invention is to provide a building natural ventilation and heating system using solar radiation which can further reduce energy consumption because the ventilation is performed in a natural ventilation mode without the operation of the fan by the flow of air heated by solar radiation heat do.

In order to achieve the above-described object, the present invention provides an air conditioner comprising: a space formed in an outer wall of a building to allow air to flow therein; A heat collecting chamber in which an air inlet for introducing air is formed and an inlet port through which outside air can be introduced is formed in an upper portion; A supply port connected to the heat collection chamber and providing supply air to a building interior; An outside air bypass regulator installed in the intake port and selectively allowing the air to flow into the air supply duct or the air heated and raised in the interior of the heat collection chamber into the air supply duct; An exhaust duct which is installed on the outer wall of the building in such a manner that a lower end thereof is opened in a height direction and is formed of a material capable of absorbing solar heat and is capable of forming a rising air flow therein; And an exhaust pipe connected to the exhaust duct and serving as a passage through which indoor air is discharged.

According to the present invention, the air supply duct and the exhaust pipe are provided with an air supply damper and an exhaust damper which can control the amount of air supply and the amount of exhaust according to opening degrees, respectively.

According to the present invention, the air supply and exhaust pipes are respectively provided with an air supply fan and an exhaust fan, and heat exchange between the air exhausted to the outside through the exhaust pipe in the building and the air introduced into the building through the air supply pipe And an air flow path is formed in the air flow path.

According to the present invention, a first temperature sensor capable of measuring the outside air temperature, a second temperature sensor capable of measuring a building room temperature, and a temperature sensor for measuring the temperature of the air heated and raised in the heat collecting chamber And controlling the opening degree of the outside air bypass regulator, the air supply damper, and the exhaust damper by comparing the measured values of the first to third temperature sensors with a preset indoor optimum temperature value, do.

According to the present invention, the outside-air bypass regulating unit is rotatably installed in the intake port, and opens a path through which the air raised inside the heat-collecting chamber flows into the inside of the air supply duct while closing the intake port in accordance with the rotation position And a plate-shaped bypass damper for opening the air inlet so as to allow outside air to flow directly into the air supply duct, while blocking a path through which the air raised inside the heat collection chamber flows into the air supply duct.

According to the present invention, it is possible to perform natural ventilation for building indoor air by using air heating by solar radiation heat in a winter or summer season in a building such as a multi-family house or an office building, and auxiliary heating using outside air can be performed in winter The use can be reduced.

According to the present invention, it is possible to perform the ventilation in a natural ventilation mode without the operation of the fan due to the flow of the air heated by the solar radiation heat, so that it is possible to reduce the energy consumption and the noise reduction effect by the fan operation.

1 is a schematic view showing a schematic configuration of a building ventilation and heating system using solar heat.
FIG. 2 is a schematic view for explaining the winter operation of the building ventilation and heating system using the solar heat shown in FIG. 1. FIG.
FIG. 3 is a view for explaining the winter season and summer season operation of the building ventilation and heating system using the solar heat shown in FIG. 1; FIG.
4 is a schematic diagram of a building natural ventilation and heating system using solar radiation heat according to the present invention.
FIG. 5 is a schematic view showing a building natural ventilation and heating system using solar radiation heat according to the present invention in a front view.
FIG. 6 is a schematic view showing the structure of a steam engine and an exhaust pipe in a building ventilation and heating system using solar radiation heat according to the present invention.
7 is a schematic view for explaining the operation of a heat collecting chamber in a building natural ventilation and heating system using solar radiation heat according to the present invention.
8 is a schematic view for explaining the operation of an exhaust duct in a building natural ventilation and heating system using solar radiation heat according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 and 5 are schematic diagrams of a building natural ventilation and heating system using solar radiation heat according to the present invention, and FIG. 6 is a schematic view of a building and an exhaust pipe in a building ventilation and heating system using solar radiation heat according to the present invention Fig.

4 to 6, the building natural ventilation and heating system using solar radiation heat according to the present invention includes a heat collecting chamber 10, a gas engine 20, an exhaust duct 30, and an exhaust pipe 40 .

The heat collecting chamber 10 is installed in the building outer wall 1 and has a space separated from the building outer wall 1 so as to be a space portion for accommodating and flowing air therein, So that the internal air can be heated by solar radiation.

When the building natural ventilation and heating system is installed in a multi-storey apartment building or office building, the heat-collecting chamber 10 is formed separately corresponding to each household or office having an independent air supply duct and an exhaust duct. Referring to FIGS. 4 and 5, it can be seen that the heat collecting chamber 10 is installed separately for each office of the first and second floors.

In the lower part of the heat-collecting chamber 10, a plurality of air inlets 12 through which external air can flow are formed. When the inside of the heat collecting chamber 10 is heated by the buoyant force and positive pressure is formed, the outside air flows into the heat collecting chamber 10 through the air inlet 12.

An air inlet 14 through which outside air can flow is provided on the outer side surface of the heat collecting chamber 10. The outside air is introduced into the air intake port 14 directly through the intake port 14 and the outside air flowing through the intake port 14 is blocked and heated in the interior of the heat collecting chamber 10, An outside air bypass adjusting unit is provided for allowing the user to select whether to enter the inside of the engine 20 only.

According to the embodiment of the present invention, the outside-air bypass regulating portion is formed of a plate-shaped bypass damper 16 rotatably provided at the lower end of the intake port 14.

The bypass damper 16 opens the path through which the air raised inside the heat collecting chamber 10 flows into the air supply duct 20 while closing the intake port 14 according to the selected position, And operates to shut off the flow of the air that has risen inside the heat collecting chamber 10 into the inside of the air supply tube 20. 7, when the bypass damper 16 is vertically erected, the intake port 14 is closed and the path of the air heated and raised in the heat collecting chamber 10 into the air supply duct 20 is opened. However, When the damper 16 is laid horizontally, the path of the air heated and raised in the heat collecting chamber 10 into the air supply duct 20 is blocked and the air inlet 14 is opened.

According to the present invention, the outside-air bypass regulating unit is not limited to the constitution of the bypass damper 16, and may be configured so that the air introduced into the air supply source 20 flows through the intake port 14 and the inside of the heat- A variety of structures can be employed that can be selected from the air heated to the elevated temperature. A tubular member having a first damper for opening and closing the intake port 14 and a second damper for connecting the intake port 14 and the air supply tube 20 to control the flow of air raised inside the heat collecting chamber , Direct inflow of outside air through the inlet port (14) is interrupted while the first damper is closed and the second damper is opened, and air heated and raised inside the heat collecting chamber (10) flows through the tubular member In the state where the first damper is opened and the second damper is closed, the air heated and raised in the heat collecting chamber 10 is shut off, and only the outside air introduced through the intake port 14 flows through the tubular member to the air supply port 20 To the inside of the housing.

The bypass damper 16 can be configured to selectively control the air introduced into the air supply duct 20 through the intake port 14 and the air heated and raised inside the heat collecting chamber 10 with a simple structure There are advantages.

7 is a schematic view for explaining the operation of the heat collecting chamber 10 in a building natural ventilation and heating system using solar radiation heat according to the present invention. Referring to FIG. 7, in operation mode of the heat collecting chamber 10, the bypass damper 16 is positioned vertically in the ventilation mode by the outside air heating in which the ventilation is performed by heating using the outside air such as during winter, The inflow of the outside air through the inlet port 14 is blocked and only the air heated inside the heat collecting chamber 10 is allowed to flow up into the inside of the air supply tube 20 by the buoyant force.

The bypass damper 16 is positioned horizontally during the summer without the need for heating by the outside air so that the inflow of the heated air from the interior of the heat collecting chamber 10 into the air supply source 20 is blocked, So that outside air can be directly exposed to the air supply unit 20.

The vise damper 16 is controlled according to the necessity of heating to control the flow of the heated air into the air supply tube 20 or the unheated ambient air into the air supply tube 20.

Referring again to FIGS. 4 to 6, the present invention includes an exhaust duct 30 for exhausting air in a building to the atmosphere. The exhaust duct 30 is installed on the building outer wall 1 in a height direction, and exhaust pipes 40 for each generation or office are connected. That is, the heat collection chamber 10 is installed for each generation or office, but the exhaust duct 30 is installed in common.

The exhaust duct 30 is formed in a shape that the lower end thereof is opened so that air can be introduced into the air exhaust duct 30, and is formed of a material capable of absorbing solar heat. When receiving the solar heat, the indoor air is heated, And can be discharged through a chimney effect.

8 is a schematic view for explaining the operation of the exhaust duct in the building natural ventilation and heating system using solar radiation heat according to the present invention. Referring to FIG. 8, the natural exhaust principle by the exhaust duct 30 will be described. A differential pressure is generated between the exhaust duct 3 and the building room 2 due to the upward flow of air in the exhaust duct 30. Accordingly, the indoor air of each household or each office in the building flows into the exhaust duct 30 through the respective exhaust pipes 40 and is exhausted together into the atmosphere. Since the exhaust duct 30 forms a natural exhaust flow due to the differential pressure, it is possible to exhaust the exhaust without the power consumption by the operation of the exhaust fan 44 or with the power consumption minimized.

The present invention includes a gas engine 20 connecting the heat collecting chamber 10 and the building room 2 and an exhaust pipe 40 connecting the exhaust duct 30 and the building room 2.

The air supply duct 20 is connected to the heat collection chamber 10 and is heated by the inside of the heat collecting chamber 10 by the control of the bypass damper 16, The outside air that flows in or is not heated through the air inlet 14 directly flows.

An air supply damper 22 for controlling air flow through the air supply unit 20 and an air supply fan 24 for forced air supply are provided in the air supply unit 20.

The exhaust pipe 40 is a passage through which the air in the building is discharged to the exhaust duct 30. The exhaust pipe 40 is provided with an exhaust damper 42 capable of controlling the air flow through the exhaust pipe 40, An exhaust fan 44 is installed.

The building natural ventilation and heating system using the solar radiation heat according to the present invention is controlled by the air supply damper 22 and the exhaust damper 42 to control the natural ventilation and heating system without driving the air supply fan 24 and the exhaust fan 44, Lt; / RTI >

When the air supply damper 22 is opened in the ventilation mode by outside air heating, a natural air supply flow is formed in which the air heated in the heat collecting chamber 10 flows into the room through the air supply duct 20 without operating the air supply fan 24 . At this time, the supply amount is adjusted by controlling the opening degree of the air supply damper 22.

When the differential pressure between the exhaust duct 30 and the building 2 is generated, the exhaust duct 42 is opened to allow the air in the building 2 to be discharged to the outside without operating the exhaust fan 44. [ A flow is formed. At this time, the exhaust amount is adjusted through opening of the exhaust damper.

According to the present invention, the total enthalpy heat exchanger (50) is installed between the power unit (20) and the exhaust pipe (40). The total enthalpy heat exchanger (50) is a well-known device having an air flow path to allow heat exchange between the air discharged from the room to the outside and the air flowing from the outside to the room. The air flowed from the outside through the air supply / Thereby enabling heat exchange between the air discharged to the outside through the heat exchanger (40).

Referring to FIG. 7, the building natural ventilation and heating system using the solar radiation heat according to the present invention includes first to third temperature sensors 61, 61, 62, 63, and 64 capable of measuring outside air temperature, building room temperature, 62 and 63 and a CO ₂ sensor 64 capable of measuring the concentration of CO _{2 in the} building so as to control the temperature and the CO ₂ concentration measured by the first to third temperature sensors 61, As shown in FIG.

Hereinafter, the operation of the natural ventilation and heating system using solar heat according to the present invention will be described in terms of ventilation control.

When the outdoor air temperature is higher than the indoor proper temperature as in the summer, heating by outside air is unnecessary. Therefore, the bypass damper 16 of the outside air bypass adjusting section is adjusted to the horizontal position, and both the air supply damper 22 and the exhaust damper 42 are closed. The outdoor air temperature is a value measured by the first temperature sensor 61 and the indoor proper temperature is a value to be set.

Air supply damper 22 and the exhaust damper 42 are both if the CO ₂ sensor 64 is installed in the closed state in the case that the CO ₂ sensor 64 is installed in accordance with the CO ₂ concentration in the building interior, the pre-programmed schedule The air supply fan 24 and the exhaust fan 44 are driven so that ventilation can be performed while minimizing heat loss by the total heat exchange by the total enthalpy heat exchanger 50. [

When the outside air temperature is higher than the proper indoor temperature as in winter, the outdoor air heating mode is performed in which ventilation is performed while heating is performed using outside air. The bypass damper 16 of the outside air bypass control unit is adjusted to the vertical position so that the air heated and raised inside the heat collecting chamber 10 flows into the air supply duct 20 while blocking the unheated outside air.

When the air heated inside the heat collecting chamber 10 is higher than the room temperature, the air supply damper 22 and the exhaust damper 42 are completely opened to allow heating and natural ventilation using the heated air in the heat collecting chamber 10. At this time, the temperature of the air heated by the first temperature sensor 61, the indoor temperature of the building, and the temperature of the air in the heat collecting chamber 10 are measured by the third temperature sensor 63.

When the temperature of the heated air measured by the second temperature sensor 62 is lower than the room temperature even in the outside air heating mode, the ventilation is performed while minimizing the heat loss by the total heat exchanging method by the total enthalpy heat exchanger 50. That is, the air supply damper 22 and the exhaust damper 42 is in both cases a closed, CO ₂ sensor 64 is installed in the case that the CO ₂ sensor 64 is installed in accordance with the CO ₂ concentration in the building interior, the pre-programmed The air supply fan 24 and the exhaust fan 44 are driven in accordance with the schedule so that the air is ventilated by the total heat exchanging method by the total enthalpy heat exchanger 50.

The bypass damper 16 of the outside air bypass regulator is adjusted to the horizontal position and the natural ventilation is performed while adjusting the amount of opening of the air supply damper 22 and the exhaust damper 42 do.

According to the present invention, not only the air heating effect by the solar radiation heat is used for the heating but also the generation of the differential pressure by the buoyancy is used together with the natural exhaust, whereby the energy efficiency is improved.

The embodiments of the present invention have been described with reference to the accompanying drawings. However, the scope of the present invention is not limited by the above-described embodiments, and substitutions, changes, and the like that can be easily made by an average person in the technical field of the present invention fall within the scope of the present invention.

10: heat collecting chamber 12: air inlet
14; Intake port 16: Bypass damper
20: air supply source 22: supply damper
24: air supply fan 30: exhaust duct
40: Exhaust pipe 42: Exhaust damper
44: exhaust fan 50: total heat exchanger
61, 62, 63: temperature sensor 64: CO ₂ sensor

Claims (5)

The air conditioner according to any one of claims 1 to 3, wherein the indoor air is heated by the solar radiation heat to raise the indoor air, A heat collecting chamber in which an inlet port through which outside air can be introduced is formed;
A supply port connected to the heat collection chamber and providing supply air to a building interior;
An outside air bypass regulator installed in the intake port and selectively allowing the air to flow into the air supply duct or the air heated and raised in the interior of the heat collection chamber into the air supply duct;
An exhaust duct which is installed on the outer wall of the building in such a manner that a lower end thereof is opened in a height direction and is formed of a material capable of absorbing solar heat so that a rising airflow can be formed therein; And
And an exhaust pipe connected to the exhaust duct and serving as a passage through which indoor air of the building is discharged,
The outside air bypass regulating unit is provided to be rotatable on the intake port and opens a path through which the air raised inside the heat collecting chamber flows into the inside of the air supply tube while closing the intake port according to the rotation position, And a bypass damper in the form of a plate for blocking the passage of the air that has risen inside the heat collecting chamber into the inside of the air supply tube while allowing outside air to flow directly into the air supply tube. Natural ventilation and heating system. The method according to claim 1,
Wherein the air supply duct and the exhaust pipe are provided with an air supply damper and an exhaust damper capable of controlling a supply amount and an exhaust amount according to opening degrees, respectively. 3. The method of claim 2,
The air supply duct and the exhaust duct are respectively provided with an air supply fan and an exhaust fan. The air supply duct and the exhaust duct are connected to each other through an air duct so that heat can be exchanged between the air discharged from the building through the exhaust pipe to the outside, And a total enthalpy heat exchanger having a solar radiation heat exchanger. 3. The method of claim 2,
A third temperature sensor capable of measuring a temperature of outside air, a second temperature sensor capable of measuring a temperature of a building room, and a third temperature sensor capable of measuring a temperature of air heated and raised in the heat collecting chamber, Further comprising a sensor for controlling an opening degree of the outside air bypass regulator, the air supply damper, and the exhaust damper by comparing the measured values of the first to third temperature sensors with a preset indoor optimum temperature value. Building natural ventilation and heating system using solar radiation. delete

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