KR20100110480A - Ventilation system for recovering exhaust heat of boiler - Google Patents

Abstract

PURPOSE: A ventilation system for recovering the exhaust heat of a boiler is provided to reduce the heating cost by the heating of the outdoor air of a low temperature supplied to a ventilation system through the recovering of the exhaust heat exhausted from a boiler. CONSTITUTION: A ventilation system for recovering the exhaust heat of a boiler comprises a heat exchange ventilator(100), an air supply line(210), an exhaust pipe(20), and a heat exchanger(300). The heat exchange ventilator transfers the exhaust heat of the indoor air exhausted to outdoor, to the outdoor air supplied to the indoor space. One end of the air supply line is communicated with the outdoor air intake part into which the outdoor air flows, and the other end is communicated with the outdoor air inhaling port of the heat exchange ventilator. The exhaust pipe exhausts the exhaust gas burnt in a boiler. The heat exchanger recovers the exhaust gas exhausted through the exhaust pipe and transfers the exhaust heat to the outdoor air supplied to the heat exchange ventilator through the air supply line.

Description

Ventilation system for recovering exhaust heat of boiler

The present invention relates to a boiler exhaust heat recovery type ventilation system, and more particularly, to recover the high-temperature exhaust heat from the exhaust gas discharged through the exhaust flue after being burned in the boiler, the low temperature outdoor air supplied to the ventilator over a predetermined temperature Heating to the room to prevent condensation from winter ventilation system and to stabilize indoor heating load to prevent indoor air pollution caused by unpurified air from entering the room. A boiler exhaust heat recovery type ventilation system.

In general homes and offices, air-conditioning and heating systems are installed to perform indoor cooling and heating according to the change of seasons. Air conditioners, boilers, etc.

Indoors such as homes and offices with air conditioning and heating systems are kept closed to improve cooling and heating efficiency, and the sealed indoor spaces have increased air pollution after a certain period of time. Odor occurs or foreign matter such as dust becomes suspended.

Therefore, in order to remove such odors and dust in the room to ventilate the room air every predetermined time, the ventilation system is used for faster ventilation.

In general, when the outdoor air temperature is below a certain temperature during the operation of the winter ventilation system, the ventilation system is operated in two ways.

The first method is to install a temperature compensating heater on the air side that sucks outside air and heat outdoor cold air to a predetermined temperature to supply the room.

However, since this method consumes a separate power to operate the heater, not only the operating cost of the ventilation system increases, but also a problem that may cause a fire due to accumulation of dust in the heater over time.

The second method is to operate the outdoor air intermittently when the outdoor air temperature is lower than a predetermined temperature, or to stop the air supply when the temperature becomes lower.

However, in this method, as the operating time increases, the negative pressure of the indoor side is lower than the atmospheric pressure, and when the pressure difference from the atmospheric pressure exceeds a certain pressure, outdoor air that has not been purified by a gap such as a window flows into the room. Pollution of indoor air, as well as the heating load has a problem.

The present invention has been made to solve the above problems, by preventing the condensation phenomenon in the winter ventilation system by recovering the exhaust heat discarded in the boiler through the heat exchange between the supply side of the ventilation system and the exhaust side of the boiler. The purpose is to provide an exhaust heat recovery type ventilation system that can contribute to energy saving by reducing indoor heating costs.

Exhaust heat recovery type ventilation system of the present invention for realizing the object as described above, the indoor air is discharged to the outside and the outdoor air is purified and supplied to the indoor, the indoor air discharged to the outdoor air supplied to the indoor A heat exchange ventilator having a heat exchanger configured to transfer exhaust heat; A first air supply line having one end communicating with an outdoor air inlet through which outdoor air is introduced and the other end being connected to a first outdoor air inlet of the heat exchange type ventilator to move outdoor air to be supplied; Exhaust flue exhaust gas exhausted from the boiler; and Heat exchange to recover the exhaust heat of the exhaust gas discharged through the exhaust flue to transfer the exhaust heat to the outdoor air supplied to the heat exchange type ventilator through the first air supply line It characterized in that it comprises a;

A first damper is provided on the first air supply line to open and close the flow of air, and branched to one side in the middle of the first air supply line to communicate with a second outdoor air inlet of the heat exchange type ventilator, and to a point on an internal passage. It characterized in that the second air supply line is provided with a second damper for opening and closing the flow of air.

The heat exchange part is a heat exchange medium surrounding the exhaust flue is filled to recover the exhaust heat from the exhaust flue; A plurality of heat exchange tubes contacting the heat exchange medium and extending into the first air supply line to transfer the exhaust heat recovered through the heat exchange medium to outdoor air supplied through the first air supply line; It characterized in that it comprises a; blower for forcibly sucking the outdoor air introduced through the heat exchange tube direction.

The primary air supply pipe is installed above the exhaust flue, and the exhaust heat of the exhaust flue is transmitted to the primary air supply by natural convection.

The heat exchange part is installed side by side in a state where airtightness is maintained along the inside of the first air supply line, a part of the exhaust flue, the exhaust heat of the exhaust gas discharged through the exhaust air supply is supplied through the first air supply line Characterized in that made to be delivered to the outdoor air.

A temperature sensor provided on a passage of the heat exchanger to sense a temperature inside the heat exchanger; and when the temperature of the heat exchanger sensed by the temperature sensor exceeds an indoor air temperature, the first damper is opened and the first sensor is opened. Blocks the damper to control the outdoor air to be supplied through the first air supply line, and if the temperature of the heat exchanger detected by the temperature sensor is less than the indoor air temperature, the first damper is blocked and the second damper is blocked. And a control unit which opens to control outdoor air to be supplied through the second air supply line.

If the indoor air temperature exceeds the outdoor air temperature, the controller opens the first damper and blocks the second damper so that outdoor air is supplied through the first air supply line, and the indoor air temperature is If the outdoor air temperature is less than the first damper and the second damper by opening the outdoor air is characterized in that the air supply through the second air supply line is controlled.

According to the exhaust heat recovery type ventilation system according to the present invention, by recovering the exhaust heat discharged through the exhaust flue of the boiler to heat the low-temperature outdoor air supplied to the ventilation system over a predetermined temperature to supply a separate temperature compensation heater Even without installation, not only can condensation problems caused by winter ventilation system can be solved, but also the cost of indoor heating can be reduced, and outdoor air heated to a temperature similar to that of indoor air is supplied to the room, which causes inpatients to receive cold air. There is an advantage that can prevent the rejection of time.

In addition, according to the present invention by configuring the air supply line of the ventilation system in a double and configured to select the flow path of the air supply line in one direction according to the operation of the damper, when the heat exchange is not possible, such as when the boiler is not used or when repairing or hot water of the boiler in summer When heat exchange is unnecessary as in use, the ventilation system can be variably operated to suit the environmental conditions by inducing the outdoor air flowing into the air supply side of the ventilation system to be directly supplied to the ventilation system without passing through the heat exchange unit.

Hereinafter, the configuration and operation of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a boiler exhaust heat recovery type ventilation system according to an embodiment of the present invention, Figure 2 is a configuration diagram showing an embodiment having a double air supply line in the boiler exhaust heat recovery type ventilation system of Figure 1, Figure 3 FIG. 2 is a state diagram illustrating an air supply path when outdoor air is directly supplied to a ventilation device without heat exchange in the boiler exhaust heat recovery type ventilation system of FIG. 2.

In the boiler exhaust heat recovery type ventilation system according to an embodiment of the present invention, the indoor air is discharged to the outside and the outdoor air is purified and supplied to the room, and the exhaust heat of the indoor air is discharged to the outdoor air supplied to the room. One end is in communication with the heat exchange type ventilator 100 having the heat exchanger 150 built therein, and the outdoor air inlet 200 into which the outdoor air is introduced, and the other end is communicated with the heat exchange type ventilator 100 to supply the outdoor air. The first air supply line 210 to which the gas is moved, the exhaust flue 20 in which the exhaust gas combusted by the boiler 10 is discharged, and the exhaust heat of the exhaust gas discharged through the exhaust flue 20 is recovered to the first air line. It includes a heat exchange unit 300 for transmitting the exhaust heat to the outdoor air supplied to the heat exchange type ventilator 100 through the air supply line 210.

The heat exchange type ventilation device 100 includes a first air supply chamber 110 through which outdoor air introduced from the outdoor air inlet unit 200 flows through the first outdoor air intake port 111, and the first air supply chamber 110. The second outdoor air inlet 120 is introduced through the heat exchanger 150 and supplied to the room through the outdoor air outlet 122 in a purified state while the introduced outdoor air passes through the filter 115, and an indoor air intake port ( The first exhaust chamber 130 and the indoor air introduced into the first exhaust chamber 130 through which the indoor air is sucked through the heat exchanger 150 are discharged to the outside through the indoor air outlet 142. The second exhaust chamber 140 is configured.

In addition, an air supply blower 125 for forcibly sucking outdoor air supplied in the direction of the outdoor air outlet 122 is provided in the second air supply chamber 120, and indoor air is provided in the second exhaust chamber 140. An exhaust blower 145 may be provided to forcibly suck the indoor air exhausted toward the outlet 142.

1 illustrates an embodiment in which the air supply side passage of the outdoor air is configured as the first air supply line 210 having a unitary structure, and FIGS. 2 and 3 show the first air supply in addition to the first air supply line 210 of the air supply side passage of the outdoor air. The second air supply line 220 branched from the line 210 and connected to the second outdoor air inlet 112 of the heat exchange type ventilator 100 is additionally provided in the form of a bypass pipe.

First, the configuration of the heat exchanger 300 common to the above embodiments will be described.

The heat exchanger 300 is for heating outdoor air supplied to the heat exchange type ventilator 100 through the first air supply line 220 by using the exhaust heat of the exhaust gas combusted by the boiler 10. Since the exhaust gas is discharged at a temperature of about 40 to 70 ° C. in the condensing boiler at 130 to 150 ° C., the exhaust heat of the exhaust gas is recovered to heat the outdoor air to the indoor air temperature level.

The heat transfer method in the heat exchange unit 300 may be configured as a water-cooled or air-cooled, the embodiment of the heat exchange unit 300 shown in FIG. 1 is in contact with the exhaust flue 20 surrounding the main body 311 The lower end is in contact with the heat exchange medium 340 through the heat exchange medium 340 filled in the lower portion and the partition 312 horizontally installed in the main body 311 and the upper end of the first air supply line 210. It includes a plurality of heat exchange tubes 310, heat pipes formed to extend into the inner space, one side of the main body 311 of the heat exchange unit 300 is introduced into the external air inlet 200 is guided to the first-class engine 210 A blower 320 for forcibly sucking outdoor air in a direction toward the heat exchange tube 310 is installed. As the heat exchange medium 340, various heat transfer materials including water or air may be used.

In addition, the first air supply pipe 210 is installed to be positioned above the exhaust flue 20 so that the air heated by the exhaust heat of the exhaust flue 20 in the heat exchange part 300 rises in a natural convection manner. It is preferably configured to transfer more heat to the outdoor air supplied through the first air supply 210.

In addition, a temperature sensor 330 for detecting a temperature of the heat exchanger 300 is installed inside the main body 311.

2 and 3, in the structure in which the second air supply line 220 is branched in addition to the first air supply line 210, the flow of air supplied to a point on the first air supply line 210 is opened and closed. The first damper 205 is provided, and at one point on the second air supply line 220, the second damper 215 is controlled to open and close in a state opposite to the open / close state of the first damper 205. Is installed.

As described above, in the embodiment in which the passage in which the outdoor air is supplied to the heat exchange type ventilator 100 is divided into the first air supply line 210 and the second air supply line 220, the outdoor air may be firstly provided in a situation where heat exchange is required. While guided to the air supply line 210 and configured to supply air to the heat exchange type ventilator 100 via the heat exchange unit 300, the temperature difference between the indoor air and the outdoor air according to the season or the operation / non-operation of the boiler 10 is performed. In a situation where heat exchange is unnecessary or impossible depending on the operating state, outdoor air is bypassed through the second air supply line 220 to induce direct supply of air to the heat exchange type ventilator 100.

The operation of the air supply line of the outdoor air variably applied according to the surrounding environment will be described later.

Figure 4 is a block diagram of a boiler exhaust heat recovery type ventilation system according to another embodiment of the present invention, Figure 5 is a block diagram showing an embodiment having a double air supply line in the boiler exhaust heat recovery type ventilation system of Figure 4, Figure 6 5 is a state diagram illustrating an air supply path when outdoor air is directly supplied to a ventilation device without heat exchange in the boiler exhaust heat recovery type ventilation system of FIG. 5.

Boiler recovery type ventilation system according to another embodiment of the present invention, the first embodiment and the other components can be configured in the same, and is characterized in that consisting of a heat exchange unit 300a of the double pipe form, Detailed description of the overlapping components will be omitted, and the description will be given based on the configuration of the heat exchange unit 300a.

The heat exchange part 300a is a part of the exhaust flue 20a is installed side by side in a state where airtightness is maintained along the inside of the first air supply line 210a, and the exhaust flue (without a separate heat exchanger tube) 20 is characterized in that the exhaust heat is discharged from the first air supply line 210a is configured to be directly transmitted to the outdoor air supplied to the inside.

Here, the heat exchanger 300a is defined as a portion in which the exhaust flue 20 is impregnated in the first air supply line 210a, and the temperature sensor 330a for detecting the temperature of the heat exchanger 300a is provided in the first air supply line 210a. It is installed on the inner side of the air supply line 210a.

7 is a flowchart illustrating the operation of the boiler exhaust heat recovery type ventilation system according to the present invention.

The operation of the boiler exhaust heat recovery type ventilation system described below is commonly applied to the above two embodiments.

In general, when the indoor air temperature exceeds the outdoor air temperature, such as in winter, the first damper 205 is opened and the second damper 215 is opened in the controller (not shown) as shown in FIGS. 2 and 5. Is blocked so that the outdoor air introduced into the outdoor air inlet 200 is supplied to the heat exchange type ventilator 100 via the heat exchange parts 300 and 300a through the first air supply lines 210 and 210a.

On the contrary, if the indoor air temperature is less than the outdoor air temperature, such as in summer, the first damper 205 is blocked and the second damper 215 is opened in the control unit as shown in FIG. The outdoor air introduced into 200 is controlled to be directly supplied to the heat exchange type ventilator 100 without heat exchange through the second air supply lines 220 and 220a. Here, although not shown in the drawings, it is assumed that the indoor air temperature and the outdoor air temperature can be detected by separate temperature sensing means.

If the indoor air temperature is lower than the outdoor air temperature, such as in summer, when the boiler is used with hot water, the indoor air temperature is unnecessarily increased when the boiler exhaust heat is recovered and the outdoor air is supplied to the room. In this case, the outdoor air is supplied through the second air supply lines 220 and 220a to prevent heat exchange.

When the indoor air temperature exceeds the outdoor air temperature, such as in winter, when the temperature signal of the heat exchangers 300 and 300a sensed by the temperature sensors 330 and 330a is sent to the controller, the controller may control the temperature of the heat exchangers 300 and 300a. The indoor air temperature will be compared.

If the temperature of the heat exchange parts 300 and 300a exceeds the indoor air temperature, it is determined that the boiler 10 is in a normal operating state, and thus the control unit first damper 205 as shown in FIG. 2 or 5. ) Is opened and the second damper 215 is blocked so that the outdoor air introduced into the outside air inlet unit 200 passes through the heat exchange units 300 and 300a through the first air supply lines 210 and 210a. It is controlled to supply to the air.

On the contrary, when the temperature of the heat exchange parts 300 and 300a is equal to or lower than the indoor air temperature, the boiler 10 is determined to be in an inoperative state or under repair, and therefore, the control unit first damper as shown in FIG. 3 or 6. 205 is blocked and the second damper 215 is opened to control the outdoor air introduced into the outside air inlet 200 to be supplied directly to the ventilation device 100 without heat exchange through the second air supply lines 220 and 220a. .

As described above, the boiler exhaust heat recovery type ventilation system according to the present invention recovers the exhaust heat of the boiler 10 and heats the outdoor air supplied to the heat exchange type ventilator 100 to a temperature similar to the temperature of the room air. In addition to preventing condensation in the ventilation system and reducing the heating load in the room, energy efficiency can be improved, as well as the inflow of outdoor air in situations where heat exchange is not necessary or impossible, such as in summer, when the boiler is not running or when the boiler is being repaired. By changing the path and controlling the outdoor air to be directly supplied to the heat exchange type ventilator, the ventilation system can be variably operated to suit the environmental conditions.

In addition, the boiler exhaust heat recovery type ventilation system according to the present invention by using a heat exchange type ventilator having a heat exchanger in the ventilator itself by using the exhaust heat of the indoor air to discharge the outdoor air supplied even when the boiler is inactive As it can be heated, it can not only supply the warm air to the room regardless of the operating time of the boiler, but also in the condition where the outdoor air temperature is higher than the indoor air temperature such as in summer, the outdoor air to be supplied is bypassed and can be directly heated without heat exchange. By supplying air to the heat exchange type ventilation device, it can be a complementary option to select the air supply method to suit the surrounding environment.

It is apparent to those skilled in the art that the present invention is not limited to the above embodiments and can be practiced in various ways without departing from the technical spirit of the present invention. will be.

1 is a block diagram of a boiler exhaust heat recovery type ventilation system according to an embodiment of the present invention,

2 is a configuration diagram showing an embodiment having a double air supply line in the boiler exhaust heat recovery type ventilation system of FIG.

3 is a state diagram showing an air supply path when outdoor air is directly supplied to a ventilation device without heat exchange in the boiler exhaust heat recovery type ventilation system of FIG. 2;

4 is a configuration diagram of a boiler exhaust heat recovery type ventilation system according to another embodiment of the present invention;

5 is a configuration diagram showing an embodiment having a double air supply line in the boiler exhaust heat recovery type ventilation system of FIG.

FIG. 6 is a state diagram illustrating an air supply path when outdoor air is directly supplied to a ventilation device without heat exchange in the boiler exhaust heat recovery type ventilation system of FIG. 5;

7 is a flowchart illustrating the operation of the boiler exhaust heat recovery type ventilation system according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10: boiler 20,20a: exhaust flue

100: heat exchange type ventilator 110: primary air supply chamber

111: first outdoor air intake 112: second outdoor air intake

115: filter 120: secondary air supply chamber

122: outdoor air outlet 130: first exhaust chamber

132: indoor air intake 140: second exhaust chamber

142: indoor air outlet 150: heat exchanger

200: outside air inlet 205: first damper

210,210a: Primary air supply line 215: Second damper

220,220a: second air supply line 300,300a: heat exchanger

310: heat exchanger tube 320: blower

330,330a: Temperature sensor 340: Heat exchange medium

Claims (7)

A heat exchange ventilator having a heat exchanger configured to discharge indoor air to the outside and purify the outdoor air to supply the indoor air, and to transfer the exhaust heat of the indoor air discharged to the outdoor air supplied to the indoor air; A first air supply line having one end communicating with an outdoor air inlet through which outdoor air is introduced and the other end being connected to a first outdoor air inlet of the heat exchange type ventilator to move outdoor air to be supplied; Exhaust flue exhausted from the boilers; And a heat exchanger for recovering exhaust heat of the exhaust gas discharged through the exhaust flue and transferring exhaust heat to outdoor air supplied to the heat exchange type ventilator through the first air supply line. Type ventilation system. The method of claim 1, A first damper is provided on the first air supply line to open and close the flow of air, and branched to one side in the middle of the first air supply line to communicate with a second outdoor air inlet of the heat exchange type ventilator, and to a point on an internal passage. Boiler exhaust heat recovery type ventilation system, characterized in that the second air supply line is provided with a second damper for opening and closing the flow of air. The method according to claim 1 or 2, The heat exchange unit, A heat exchange medium surrounding and filling the exhaust flue to recover exhaust heat from the exhaust flue; A plurality of heat exchange tubes contacting the heat exchange medium and extending into the first air supply line to transfer the exhaust heat recovered through the heat exchange medium to the outdoor air supplied through the first air supply line; and And a blower forcibly drawing outdoor air introduced through the outside air inlet toward the heat exchange tube. The method of claim 3, The first grade engine is installed above the exhaust flue, the exhaust heat of the exhaust flue exhaust heat recovery type ventilation system, characterized in that the natural convection transfer to the first flue. The method according to claim 1 or 2, The heat exchange unit, A part of the exhaust flue is installed side by side in a state in which airtightness is maintained along the inside of the first air supply line, so that the exhaust heat of exhaust gas discharged through the exhaust flue is supplied to the outdoor air supplied through the first air supply line. Exhaust heat recovery type ventilation system, characterized in that the transmission is made. The method of claim 2, A temperature sensor provided on a passage of the heat exchanger to sense a temperature inside the heat exchanger; and when the temperature of the heat exchanger sensed by the temperature sensor exceeds an indoor air temperature, the first damper is opened and the first sensor is opened. Blocks the damper to control the outdoor air to be supplied through the first air supply line, and if the temperature of the heat exchanger detected by the temperature sensor is less than the indoor air temperature, the first damper is blocked and the second damper is blocked. And a control unit which opens to control the outdoor air to be supplied through the second air supply line. 2. The method of claim 6, If the indoor air temperature exceeds the outdoor air temperature, the controller opens the first damper and blocks the second damper so that outdoor air is supplied through the first air supply line, and the indoor air temperature is If the outdoor air temperature is less than the first exhaust damper and the second damper to open the exhaust air heat recovery type ventilation system, characterized in that for controlling the outdoor air to be supplied through the second air supply line.

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