KR20130090939A - Heat exchanger using air supply system - Google Patents

Abstract

PURPOSE: A system which supplies air purified in a plant air purifier to each room is provided to supply the air purified in the plant purifier using plant photosynthesis, a culture medium and the action of microorganisms on the basis of the culture medium to each indoor room through a total heat exchanger. CONSTITUTION: A system which supplies air purified in a plant air purifier to each indoor room by using a total heat exchanger (50) includes a heat exchanger (52) placed in the center, an indoor air suction chamber (60) which is formed as a partition wall around the heat exchanger, an indoor air discharging chamber (70), an outside air discharging chamber (90) and the total heat exchanger including an outside air inhaling chamber (80). The purified air circulating in an air duct (130) by the driving of an outside air discharging fan (94) is supplied to the each indoor room through the outside air discharging chamber.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a plant air purifier,

The present invention relates to a system for supplying purified air from a plant air purifier to an indoor space using an all-heat exchanger, and more particularly, to a system for controlling the photosynthesis of a plant, a medium itself and a micro- The present invention relates to a system for supplying purified air from an indoor plant air purifier to each room using an all-air heat exchanger, which is capable of supplying purified air from an air purifier to each room through an all-air heat exchanger as a ventilation means.

In order for a person to live, inevitably, the ventilation device for exchanging the indoor air with the outside air is necessary.

Generally, a ventilator adopts a system in which only air in a room is forcibly discharged to the outside by using a single blower. However, when the indoor air is forcibly discharged by using only one blower, the room air is discharged to the outside without filtration, and the outdoor air flows into the room without heat exchange through the door or the opening of the room. The cost of air conditioning was unnecessarily expensive.

In addition, sudden cool air and heat are introduced from the outside to the inside, resulting in a sudden change in the temperature of the room air, which makes people in the room feel uncomfortable. Especially, in a closed state of a window or a door of a room, In addition, the indoor air can not be kept in a comfortable environment despite the fact that the humidity of the indoor air is not adjusted at all and the ventilator is provided. .

In order to solve such a problem, there has been proposed an exhaust heat exchanging type ventilating apparatus in which outdoor air is first heat-exchanged with indoor air discharged outdoors and then supplied to the room.

In the ventilation system of the total heat exchange type, an all-air heat exchanger for exchanging sensible heat and latent heat of the room is provided. Generally, the total heat exchanger is used as a component of the air conditioning system of a building. The indoor air discharged from the room to the outside of the building for ventilation of the building and the indoor air discharged from the room during the suction of the outdoor air to the room are exchanged with each other to reduce the heat loss caused by the ventilation to be.

However, the conventional total enthalpy heat exchanger simply enforces the outdoor air to be introduced into the room to realize the ventilation action. Even if the outdoor air is polluted by the pollution or other external factors, even if the ventilation action is realized, It is not possible to transmit it.

Particularly, even if heat exchange is performed between the room and the outside air through the total heat exchanger, the efficiency of the heat exchanger is about 75%, and the heat exchanged outdoor air flows into the room and then cooled and heated to a desired temperature. have.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a plant air purifier for purifying air using a plant, which is capable of supplying purified air to each room through a total heat- The present invention also provides a system for supplying purified air from an indoor plant air purifier to each room using an all-air heat exchanger that can supply beneficial air to the room.

Another object of the present invention is to provide a system and a method for controlling air in a plant air purifier by using a total heat exchanger capable of supplying a purified air from a plant air purifier to each room, And to provide a system for supplying various rooms indoors.

According to another aspect of the present invention, there is provided an indoor air conditioner, comprising: an indoor heat exchanger for connecting outdoor air circulating cooling / heating pipes to an outdoor air exhaust chamber to increase heat exchange efficiency of outdoor air introduced into the outdoor air exhaust chamber; And a system for supplying purified air from the air purifier to each room of the room.

According to another aspect of the present invention, there is provided a system for supplying purge air from a plant air purifier to an indoor unit using an total enthalpy heat exchanger, the system comprising: a heat exchanger disposed at a center; An indoor air suction chamber, an indoor air discharge chamber, an outdoor air discharge chamber, and an outdoor air suction chamber, wherein the indoor air suction chamber and the indoor air discharge chamber are connected to each other through the heat exchanger, The indoor air exhaust fan installed in the discharge chamber discharges the contaminated air in each room to the outside. The outdoor air discharge chamber and the outdoor air suction chamber are connected to each other through the heat exchanger, When the external air exhaust fan installed in the chamber is driven, external air is sucked And the air is supplied to each room in a state of heat exchange with indoor air discharged through the heat exchanger to the outside, one end of a purified air discharge line is connected to the outside air discharge chamber of the total heat exchanger, And the other end of the air is connected to an air duct circulating the purified air by the photosynthesis action of the plant, and the purified air circulated in the air duct according to the driving of the external air exhaust fan, To the second power supply.

The external air suction chamber is connected to an external air suction line for supplying external air to the external air suction chamber, and a damper for opening and closing the external air suction line is further installed on the external air suction line. Do.

Preferably, the outside air discharge chamber is connected to a cooling / heating pipe branched from the boiler installed in the room.

The present invention provides a function of supplying purified air to a room through a total enthalpy heat exchanger as a ventilation means in a plant air purifier for purifying air using a plant, thereby supplying useful air to the inside of the room .

Further, according to the present invention, a damper is installed in the external air suction line, and only the purified air from the plant air purifier can be supplied to each room of the room, if necessary, thereby realizing practical effects.

Further, the present invention achieves a synergistic effect of increasing the heat exchange efficiency of outdoor air introduced into the external air discharge chamber by connecting cold and hot pipes circulating the room to the external air discharge chamber.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of a system for supplying purified air from a plant air purifier to a room using an entire heat exchanger to be implemented in the present invention; FIG.
Fig. 2 is a three-dimensional view illustrating the configuration of the total enthalpy heat exchanger shown in Fig. 1; Fig.
FIG. 3 is a view showing in detail the construction of a boiler capable of cooling and heating shown in FIG. 1; FIG.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings. In the following detailed description, exemplary embodiments of the present invention will be described in order to accomplish the above-mentioned technical problems. And other embodiments which may be presented by the present invention are replaced by descriptions in the constitution of the present invention.

1 is a view showing the configuration of a system for supplying the purified air from the plant air purifier to the room using the heat exchanger to be implemented in the present invention, Figure 2 is an extract of the heat exchanger shown in FIG. 3 is a view showing in detail the configuration of the boiler shown in FIG.

As shown in Figures 1 to 3, the system implemented in the present invention is largely divided into a total heat exchanger (50) and a plant air purifier (110).

The heat exchanger (50) is a heat loss generated in the process of ventilating the indoor air and the indoor air is sucked by the indoor air discharged in the process of discharging the indoor air to the outside and the indoor air to be sucked to exchange heat to each other to ventilate the building As an equipment provided for the purpose of reducing the heat exchanger, a heat exchanger (52) is disposed in the center, the indoor air suction chamber (60) and the indoor air discharge chamber (70) around the heat exchanger (52), and The external air suction chamber 80 and the external air discharge chamber 90 are each formed by partitions 58. The indoor air suction chamber 60 and the indoor air discharge chamber 70 are connected to each other through the heat exchanger 52, and the external air suction chamber 80 and the external air discharge chamber 90 are connected to each other. It is connected to each other by 52.

The heat exchanger 52 is an external air suction chamber 80 using the temperature of the indoor polluted air discharged to the outside through the indoor air suction chamber 60 and the indoor air discharge chamber 70 as shown in FIG. And an external air discharge chamber 90, which is provided for the purpose of reducing the energy waste of cooling and heating the external air by heat-exchanging the external air discharged to each room, and an approximately square plate-shaped heat transfer film ( 54 constitutes an upper side and a lower side, and a plurality of bending plates 56 bent a plurality of times so that the cross section is formed in a substantially triangular cross section between the heat transfer membranes 54 are arranged to cross each other. The bending plate 56 is a passage through which the indoor air and the outside air flow, thereby inducing the indoor air and the outside air to exchange heat with each other.

Next, a description will be given of each chamber partitioned by diaphragms 58 around the heat exchanger 52.

First, the indoor air suction chamber 60 is connected to the indoor air suction line 62 installed in each room to suck the air sucked in each room according to the driving of the indoor air exhaust fan 74 which will be described later. Done.

The indoor air exhaust chamber 70 communicates with the indoor air suction chamber 60 through the bent plate 56 of the heat exchanger 52 described above, and the indoor air suction chamber is driven by the outdoor exhaust fan 74. After the forced intake of air in each room through the (60), it is forced through the heat exchanger (52) to be forcibly discharged to the outside through the indoor air discharge line (72).

The external air suction chamber 80 is a chamber in which external air is forcibly sucked through the external air suction line 82 according to the operation of the indoor exhaust fan 94 to be described later.

The external air discharge chamber 90 communicates with the external air suction chamber 80 through the bent plate 56 of the heat exchanger 52 described above, and the external air suction is driven by the external air exhaust fan 94. Through the heat exchanger communicating with the chamber, the outside air is supplied to each room in the state where heat is exchanged with the indoor air.

That is, the heat exchanger 50 having the above-described structure may exhaust the outside air into each room in a state where heat is exchanged with the indoor air to ventilate the room, and in addition, the indoor air and the outdoor air may exchange each other through the heat exchanger. By allowing heat exchange, energy loss can be reduced.

On the other hand, the external air discharge chamber 90 is further configured to be connected to the purge air discharge line 150, the purge air discharge line 150 is the above-described external air exhaust air purged by the plant air purifier 110 Forced suction according to the driving of the fan 94 is supplied to the external air discharge chamber (90).

Specifically, the plant air purifier 110 is a device provided for the purpose of purifying the indoor air by using the air improvement effect of the plant, the filter layer 120, the air duct 130, the heat pipe 140 and It comprises a purge air discharge line 150.

The filter layer 120 filters out various contaminants of indoor air and purifies the contaminated air by using photosynthesis of plants.

The air duct 130 is disposed on the back of the filter layer 120 and receives purified air through the filter layer 130. In this case, a perforated plate having fine pores is installed on the front surface of the air duct 130 to circulate air passing through the filter layer 130 into the air duct.

The heat pipe 130 is installed inside the air duct 130 and heat exchanges the purified air supplied into the air duct 130 with the purified air having a temperature suitable for cold and diffused cooking.

The purified air discharge line 150 is one end is connected to the air duct 130, the other end is configured to be connected to the external air discharge chamber 90 of the aforementioned heat exchanger, it is installed in the external air discharge chamber 90 Purified air supplied to the air duct 130 is forcibly discharged to the external air discharge chamber 90 according to the operation of the external air exhaust fan 94, and discharged to the external air discharge chamber 90. The purified air is supplied to the purified air to each room through the external air discharge line 92 again.

On the other hand, a damper 84 is further installed in the external air suction line 82 configured to be connected to the external air suction chamber 80. The damper 84 selectively opens and closes the external air suction line 82 to selectively block suction of external air supplied to the external air discharge chamber 90.

That is, to supply the purified air from the plant air purifier 110 to each room through the purified air discharge line 150, only the purified air may be supplied to each room in a state in which outdoor air is blocked. In this case, when the damper 84 is operated to close the external air suction line 82 and then the external air exhaust fan 94 is driven, the external air discharge chamber 90 has the purified air. Purified air introduced into the air duct 130 through the discharge line 150 is sucked, through which the plant air purification apparatus 110 can supply only purified air beneficial to the human body in each room.

On the other hand, the external air discharge chamber (90) for the temperature compensation cold and hot water circulation branch formed in the FCU cold and hot water supply and FCU cold and hot water return line (54, 55) connecting the boiler 10 and the FCU (48), which is an indoor individual heating device. The line 64 is further installed to heat-exchange the external air sucked into the external air discharge chamber 90 in the state of being heat-exchanged with the indoor air through the heat exchanger 52, and operate the damper 84 to externally. In the state in which the air suction line 82 is closed, the purified air sucked into the external air discharge chamber 80 through the purge air discharge line 150 is supplied to each room in a heat exchange state.

4 is a view showing the configuration of the boiler in detail.

As shown in FIG. 4, the boiler 10 is provided with a burner 12 that uses city gas or electricity as a fuel, a multifunctional heat exchanger 24, and a hot water supply pipe 20, respectively. The ceiling is further configured to be connected to the boiler and FCU cold and hot water supply and FCU cold and hot water return line (54, 55) to perform convection cooling and heating is further installed.

The burner 12 selectively operates only when the temperature of the heating water passing through the multi-functional heat exchanger 24 is heated below the set temperature, thereby directly heating the heating water. At this time, the operation of the burner 12 is automatically operated according to the control operation of the control unit through the measurement of the temperature sensor (not shown) installed in the cold and hot water supply pipe (40). In addition, the burner 12 is preferably configured to indirectly heat the heating pipe 14 through the heat exchanger 13 without directly heating the heating pipe 14 through which the heating water circulates.

The heating pipe 14 is a closed loop type pipe that continuously circulates the heating water according to the pumping operation of the heating water circulation pump 15. The heating pipe 14 is a multifunctional heat exchanger 24 of the boiler 10. And the heat exchanger provided in the burner 12 together.

The heating water circulated to the heating pipe 14 is heat-exchanged in the process of passing through the multi-function heat exchanger 24 and then supplied to the indoor heating unit 19 to perform a heating function (ie, radiant heating). At this time, when the temperature of the heating water circulating the heating pipe 14 is lower than the set temperature, the burner 12 is operated to heat the heating water above the set temperature to supply the indoor heating unit 19. As mentioned above, it is configured to be made automatically through the measurement of the temperature sensor installed in the cold and hot water supply pipe (40). That is, the temperature sensor measures the temperature of the hot water passing through the cold and hot water supply pipe 40 during heating, and when the set temperature, for example, the temperature of the hot water is measured to 45 ℃ or less signal to the control unit (not shown) By outputting the automatic operation of the burner 12, the heating water can be automatically heated above the set temperature.

The heating pipe 14 is provided with a selection valve 16 (three-way valve), the heating valve 14 is connected to the heating valve 14 via the hot water supply pipe 20. The heating water supply pipe 18 is supplied to the hot water supply pipe 20 when the temperature of the heat exchanged time water is low, receiving the heating water circulating in the heating pipe 14 in accordance with the operation of the selection valve 16 the heating Heat the time water supplied to the hot water supply pipe 20 at a temperature of water to heat it.

The hot water supply pipe 20 is a pipe for supplying hot water (tap water) supplied from the water supply port 22, and is configured to pass through the multifunctional heat exchanger 24 of the boiler 10 and flowed into the hot water supply pipe 20. The time water is heat-exchanged in the multifunctional heat exchanger 24, and then heated with hot water to be discharged to the place of use. At this time, the hot water supplied to the hot water supply pipe 20 is supplied with the hot water through the temperature of the heating water supplied to the heating water supply pipe 18 branched to the selection valve 16 installed in the above-described heating pipe 14 as necessary. Can be heat exchanged.

The fan coil unit (FCU) 48 is a means for individually installing the indoor ceiling for each generation to implement both convection cooling and convection heating functions according to the supply of cold water and hot water. The FCU 48 is connected to the FCU cold and hot water supply line 54 and the FCU cold and hot water return line 55, respectively, wherein the FCU cold and hot water supply line 54 is a selection valve installed in the above-mentioned cold and hot water supply pipe 40 By connecting to 42, the cold water and hot water supplied through the cold and hot water supply pipe 40 in accordance with the operation of the selection valve 42 is supplied to the FCU (48). In addition, the FCU cold and hot water return line 55 is to return the cold and hot water discharged from the FCU to the cold and hot water return pipe 44. The selection valve 42 installed in the cold / hot water supply pipe 40 is configured to enable proportional control, so that when hot water is supplied, the hot water can be simultaneously supplied to the multifunctional heat exchanger 24 and the FCU 48. This allows household members to adjust the flow rate appropriately to the ratio of FCU (48) continental heating and floor radiant heating.

One end of the temperature compensation cold and hot water circulation line 64 is installed in the FCU cold and hot water supply line 54, and the other end of the temperature compensation cold and hot water circulation line 64 is an external air discharge chamber of the aforementioned heat exchanger 50 ( 90) After passing through the inside, it is configured to be connected to the FCU cold and hot water return line (55).

The temperature compensation cold and hot water circulation line 64 is configured to be connected to the external air discharge chamber 90 of the total heat exchanger 50 to heat-exchange the first heat exchanged external air, as well as purifying air discharge line 150. Through the heat exchange of the temperature of the purified air supplied to the external air discharge chamber 90 to compensate.

In addition, the temperature compensation cold and hot water circulation line 64 is further provided with a separate flow control valve 86 to control the flow rate circulating the temperature compensation cold and hot water circulation line 64 by the operation of the flow control valve 86. To adjust the temperature of the external air to the room.

That is, after connecting the heating pipe 14 to the boiler 10 having the above-described configuration, the heating pipe 14 is connected to the external air discharge chamber 90 of the total enthalpy heat exchanger 50 Heat exchanged with the primary heat-exchanged outside air again, as well as the purified air supplied to the outside air discharge chamber 90 through the purified air discharge line 150 can also effectively heat-exchange.

10: boiler 14: heating piping
21: Temperature sensor 42: Selection valve (proportional control type)
40: cold / hot water supply pipe 44: cold / hot water supply pipe
48: FCU (pen coil unit) 50: total heat exchanger
52: Heat exchanger 54: FCU cold / hot water supply line
55: FCU cold / hot water return line 60: indoor air sucking chamber
64: cold / hot water circulation line for temperature compensation 70: indoor air exhaust chamber
74: Indoor air exhaust fan 80: Outside air intake chamber
82: Outside air suction line 84: Damper
90: Outside air discharge chamber 92: Outside air discharge line
94: Outside air exhaust fan 110: Plant air cleaner
120: filter layer 130: air duct
140: Heat pipe 150: Purified air discharge channel

Claims (3)

A system for supplying purified air from a plant air purifier to an indoor space using an overall heat exchanger,
A heat exchanger (52) disposed in the center;
An indoor air suction chamber 60 and an indoor air discharge chamber 70 partitioned by diaphragm around the heat exchanger 52 and an outer air suction chamber 80 composed of an outer air discharge chamber 90 and an outer air suction chamber 80, (50);
The indoor air sucking chamber 60 and the indoor air sucking chamber 70 are connected to each other through the heat exchanger 52 and connected to the indoor air exhaust fan 74 Driving to exhaust polluted air in each room in the room;
The external air intake chamber 80 and the external air exhaust chamber 90 are connected to each other through the heat exchanger 52 to pass through the external air exhaust fan 94 installed in the external air exhaust chamber 90. It is configured to supply to each room in the state in which the heat exchanged with the indoor air discharged to the outside through the heat exchanger 52 in the state in which the external air is sucked in accordance with the driving;
One end of the purge air discharge line 150 is connected to the external air discharge chamber 90 of the total heat exchanger 50, and the other end of the purge air discharge line 150 circulates the air purified by the photosynthetic action of the plant. Is configured to be connected to the air duct 130, the purified air circulated in the air duct 130 in accordance with the drive of the external air exhaust fan 94 through the external air discharge chamber 90 to each room A system for supplying the purified air from the plant air purification device to each room using a total heat exchanger, characterized in that configured to supply.
The method of claim 1,
An external air suction line (82) for supplying external air to the external air suction chamber (80) is connected to the external air suction chamber (80);
The external air suction line 82 is supplied with a damper 84 for opening and closing the external air suction line 82 to supply the air purified by the plant air purifier to each room using a heat exchanger. System.
The method of claim 2,
The external air discharge chamber 90 is purified by a plant air purifier using a total heat exchanger, characterized in that the temperature compensation cold and hot water circulation line (64) branched from the boiler 10 installed indoors is connected to be configured. System to supply compressed air to each room.

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