KR100685767B1 - System and method for operating defrost of energy recovery ventilation - Google Patents

Abstract

A system and a method for defrosting operation of a waste heat recovering ventilator are provided to drive a defrosting heater according to data detected by a temperature sensor and a pressure detecting element, thereby preventing unnecessary defrosting operation from being carried out in spite of low atmospheric air temperature. A system and a method for defrosting operation of a waste heat recovering ventilator includes a temperature sensor(140) for detecting a temperature of atmospheric air inhaled into an air supply duct(110), and pressure detecting elements(160) such as differential pressure gauges or pressure sensors mounted in an air exhaust duct(120) for detecting a pressure difference between room air introduced into the heat exchanger and room air discharged from the heat exchanger. A defrosting heater(150) is mounted in the air supply duct and is driven to heat the atmospheric air introduced into the air supply duct by a control part according to signals output from the temperature sensor and the pressure detecting element.

Description

System and method for operating defrost of energy recovery ventilation

1 is a schematic view showing a waste heat recovery ventilator according to the prior art.

Figure 2 is a schematic diagram showing a waste heat recovery ventilator according to the present invention.

Figure 3 is a block diagram showing a first embodiment of the defrosting operation system of the waste heat recovery ventilator according to the present invention.

Figure 4 is a block diagram showing a second embodiment of the defrosting operation system of the waste heat recovery ventilator according to the present invention.

5 is a flowchart illustrating a defrosting operation method of a waste heat recovery ventilator according to the present invention.

-Explanation of symbols for the main parts of the drawings-

101: duct 103: bulkhead

110: air supply duct 111: air supply intake

113: air supply outlet 115: air supply fan

120: exhaust duct 121: exhaust inlet

123: exhaust outlet 125: exhaust fan

130: heat exchanger 137: air supply passage

139: exhaust passage 140: temperature sensor

150: defrost heater 160: pressure detection means

170: differential pressure gauge 181: first pressure sensor

182: second pressure sensor 200: control unit

The present invention relates to a defrosting operation system and method of a waste heat recovery ventilator, and more particularly, by driving the defrost heater through the information detected by the temperature sensor and pressure detection means, the temperature of the outdoor air is lowered to the heat exchanger If this is not done, the present invention relates to a defrosting operation system and method of a waste heat recovery ventilator that can prevent unnecessary defrost heaters.

In general, air in an enclosed space increases the carbon dioxide content as time passes by the breathing of the living organisms, which interferes with the breathing of the living creatures. Therefore, when many people, such as an office or a vehicle, stay in a confined space, the indoor polluted air should be replaced with fresh air from time to time.

At this time, a commonly used ventilation device. Most known ventilation apparatuses adopt a method of forcibly discharging only indoor air to the outside using a single blower.

However, when forced to discharge only indoor air by using one blower, the indoor air is discharged to the outside without filtration and the outdoor air is introduced without heat exchange through the door or window gap, thereby heating and cooling the room. The expense required to do so was unnecessarily high.

In addition, due to the sudden inflow of cold air and heat from inside to outside people suddenly change the temperature of the interior people there is unpleasant feelings, especially in the state that the indoor window or door frame closed to discharge only the indoor air to the outside In this case, the inflow of fresh air is blocked and oxygen deficiency may occur, and the humidity of the indoor air is not controlled at all, and there is a problem in that a pleasant indoor environment is not maintained even though a ventilation device is provided. .

In order to solve such a conventional problem, a waste heat recovery ventilator for exchanging outdoor air with indoor air discharged to the outside first and then supplying the indoor air has been proposed.

As illustrated in FIG. 1, the waste heat recovery ventilator includes an air supply duct 10 into which outdoor air flows into a room in a duct 1 having a box shape, and the air supply duct 10 and a predetermined air supply duct 10. An exhaust duct 20 is provided which intersects at the position and guides indoor air to the outside.

A heat exchanger 30 is provided to exchange heat between the outdoor air that is supplied at the point where the air supply duct 10 and the exhaust duct 20 intersect and the indoor air that is exhausted.

At this time, the air supply duct 10 and the exhaust duct 20 are not interfered with each other by the partition wall 3 partitioning the inside of the duct 1 up and down.

An air supply suction opening 11 is formed at one end of the air supply duct 10 to communicate with the outside, and an air supply outlet 13 is formed at the other end of the air supply duct 10 to communicate with the room at one end of the exhaust duct 20. An exhaust inlet 21 is formed, and at the other end, an exhaust outlet 23 communicating with the outdoors is formed.

An air supply fan 15 is provided at the air supply outlet 13 side of the air supply duct 10 to forcibly suck outdoor air to discharge the heat-exchanged air into the room, and the air exhaust port 23 side of the exhaust duct 20 is provided. The exhaust fan 25 for forcibly discharging the indoor air is provided.

Meanwhile, the heat exchanger 30 has a hexahedron shape in which upper and lower edges are supported by the duct 1, and left and right edges are supported by the partition wall 3, and a plurality of air supply passages communicating with the air supply duct 10 therein ( 37 and a plurality of exhaust passages 39 adjacent to the air supply passages 37 and in communication with the exhaust ducts 20 are provided.

Although not separately shown in the drawing, a heat exchange plate having excellent heat conduction efficiency is provided at the boundary between the air supply passage 37 and the exhaust passage 39.

At this time, the portion shown by the solid line is the air supply passage 37, and the portion shown by the dotted line is the exhaust passage 39.

Referring to the operation of the waste heat recovery ventilator having such a configuration as follows.

First, when indoor air is contaminated to some extent, power is supplied to the exhaust fan 25 so that indoor air flows into the exhaust duct 20 through the exhaust inlet 21, and then the exhaust passage 39 of the heat exchanger 30. ) Is discharged to the outside through the exhaust outlet (23).

At the same time, while supplying power to the air supply fan 15, fresh outdoor air flows into the air supply duct 10 through the air supply intake port 11, and then passes through the air supply passage 37 of the heat exchanger 30, and then supplies the air supply outlet. It is introduced into the room through (13).

At this time, the indoor air and the outdoor air passing through the heat exchanger 30 will exchange heat through the heat exchange plate. Specifically, the heat exchange occurring in the heat exchanger 30 includes sensible heat exchange between the supplied outdoor air and the exhausted indoor air, and high temperature air in the indoor or outdoor air is below the dew point temp. It is made of latent heat exchange by the condensate produced in the state of.

In the case of the heat exchange type ventilation device, the outdoor air supplied when the room is cooled or heated is primarily heat-exchanged with the indoor air and then introduced into the room, thereby preventing a rapid rise or fall of the room temperature.

However, in the waste heat recovery ventilator as described above, when the temperature of the outdoor air drops to below zero during winter operation, the indoor air that heat-exchanges with the outdoor air drops locally to 0 ° C or below, and condensed after condensation of moisture from the indoor side. Part of the heat exchanger 30 is blocked by being accumulated on the heat exchanger (30). In order to prevent this, a separate defrost heater 40 and a temperature sensor 50 are mounted on the air supply duct 10 through which the outdoor air is sucked, and when the outdoor temperature detected by the temperature sensor 50 is below the set temperature, the defrost heater. The 40 is operated to heat the outdoor air sucked into the air supply duct 10.

However, the waste heat recovery ventilator according to the prior art, which uses a heater such as a defrost heater for winter defrosting operation, is operated when the temperature detected by the temperature sensor is lower than the set temperature, so that no dropping occurs in the actual heat exchanger. Even when the outdoor air introduced into the exhaust duct is below the set temperature, the defrost heater is operated, thereby increasing the power consumption, thereby increasing the operating cost unnecessarily.

The present invention has been made to solve the above problems, the pressure detection means by detecting the pressure difference between the indoor air flowing into the heat exchanger in the exhaust duct and the indoor air flowing out of the heat exchanger only when a pressure difference occurs It is an object of the present invention to provide a defrosting operation system and method of a waste heat recovery ventilator that can operate a defrost heater to prevent unnecessary use of the defrost heater.

The present invention is divided into an air supply duct for introducing outdoor air into the room by an air supply fan and an exhaust duct intersecting the air supply duct, and the air duct flowing out to the outdoor air by the exhaust fan, and the air supply duct and the exhaust duct intersect. A plurality of air supply passages provided at a point to communicate with the air supply duct and a plurality of air exhaust passages communicating with the exhaust duct are adjacent to each other, and include a heat exchanger configured to heat exchange the air in the air supply passage and the air passages with each other. A defrosting operation system of a waste heat recovery ventilator, comprising: a temperature sensor detecting a temperature of outdoor air introduced into the air supply duct; Pressure detecting means for detecting a pressure difference between indoor air flowing into the heat exchanger and the indoor air flowing out of the heat exchanger in the exhaust duct; Defrost heater for heating the outdoor air introduced into the air supply duct; And a controller configured to control the operation of the defrost heater by receiving the signal detected from the temperature sensor and the pressure detecting means.

Preferably, the pressure detecting means is characterized in that the differential pressure gauge for detecting a pressure difference by detecting a change in the flow rate of the indoor air inflow side and the indoor air outflow side of the heat exchanger, the pressure detection means is It is characterized in that the first and second pressure sensing sensors respectively installed on the side where the indoor air flows in and the indoor air flows out of the heat exchanger.

In addition, the present invention comprises the steps of: a) detecting the temperature of the outdoor air introduced into the air supply duct temperature sensor; b) comparing, by the controller, the temperature detected by the temperature sensor with a preset temperature for determining the stock image; c) the control unit outputting a driving signal of a defrost heater when the detected temperature is less than or equal to a preset temperature determination temperature; d) detecting, by the pressure detecting means, a pressure difference between a side into which indoor air of the heat exchanger flows in and a side into which indoor air flows out; e) comparing, by the control unit, the pressure difference value detected by the pressure detecting means with a preset accumulation determination reference value; And f) defrosting the waste heat recovery ventilator including outputting a stop signal of the defrost heater when the detected pressure difference value does not exceed a preset drip determination reference value. How to drive

Therefore, the present invention drives the defrost heater through the information detected through the temperature sensor and the pressure detecting means, thereby preventing unnecessary defrost heater driving when the temperature of the outdoor air is low even if the heat exchanger is not made, effectively consumed There is an effect that can reduce the power.

Hereinafter, a preferred embodiment of a defrosting operation system and method of a waste heat recovery ventilator according to the present invention will be described with reference to the accompanying drawings.

First, Figure 2 is a schematic view showing the waste heat recovery ventilator according to the present invention, as shown, the air supply duct 110 is provided with the outdoor air flows into the interior of the box-shaped duct 101 is provided In addition, the air supply duct () is provided with an exhaust duct 120 that crosses at a predetermined position and indoor air is guided to the outside.

A heat exchanger 130 is provided to exchange heat between the outdoor air that is supplied at the point where the air supply duct 110 and the exhaust duct 120 intersect with the indoor air that is exhausted.

At this time, the air supply duct 110 and the exhaust duct 120 is not interfered with each other by the partition 103 partitioning the inside of the duct 101 up and down.

An air supply suction port 111 is formed at one end of the air supply duct 110 to communicate with the outside, and an air supply outlet 113 is formed at the other end to communicate with the room, and is connected to the room at one end of the exhaust duct 120. An exhaust suction opening 121 is formed, and an exhaust discharge opening 123 communicating with the outdoors is formed at the other end.

An air supply fan 115 is provided on the air supply outlet 113 side of the air supply duct 110 to forcibly suck outdoor air to discharge the heat-exchanged air into the room, and the exhaust outlet 123 side of the exhaust duct 120 is provided. Exhaust fan 125 for forcibly discharging the indoor air is provided.

The heat exchanger 130 has a hexahedron shape whose upper and lower edges are supported by the duct 101, and the left and right edges are supported by the partition 103, and a plurality of air supply passages 137 communicating with the air supply duct 110 therein. And a plurality of exhaust passages 139 adjacent to the air supply passage 137 and communicating with the exhaust duct 120.

Although not separately shown in the drawings, a heat exchange plate having excellent heat conduction efficiency is provided at the boundary between the air supply passage 137 and the exhaust passage 139. The portion shown by the solid line is the air supply passage 137, and the portion shown by the dotted line is the exhaust passage 139.

On the other hand, the temperature sensor 140 for detecting the temperature of the outdoor air flowing into the air supply duct 110 in the portion adjacent to the air supply inlet 111 of the air supply duct 137 and the outdoor air introduced into the air supply duct 110 Defrost heater 150 is provided for.

In addition, the indoor air and the heat exchanger introduced into the heat exchanger 130 on the side into which the outdoor air of the heat exchanger 130 flows and the indoor air of the heat exchanger 130 flows into the exhaust duct 120. Pressure detection means 160 for detecting the pressure difference of the indoor air flowing out from 130 is provided.

In this case, the pressure detecting means 160 may use a differential pressure gauge 170 for detecting a pressure difference by detecting a change in the flow rate of the side where the indoor air of the heat exchanger 130 is introduced and the side where the indoor air flows. First and second pressure detection sensors 181 and 182 may be installed on the side where the indoor air flows in and the side air flows through the heat exchanger 130, respectively.

Hereinafter, the operation of the waste heat recovery ventilator according to the present invention will be described in detail.

First, when indoor air is contaminated to some extent, power is supplied to the exhaust fan 125 so that indoor air flows into the exhaust duct 120 through the exhaust suction opening 121, and then the exhaust passage 139 of the heat exchanger 130. ) Is discharged to the outside through the exhaust outlet 123.

At the same time, the fresh outdoor air flows into the air supply duct 110 through the air supply inlet 111 while power is supplied to the air supply fan 115, and then passes through the air supply passage 137 of the heat exchanger 130. 113 is introduced into the room.

In addition, the indoor air and the outdoor air passing through the heat exchanger 130 will exchange heat through the heat exchange plate. In detail, the heat exchange in the heat exchanger 130 includes sensible heat exchange between the supplied outdoor air and the exhausted indoor air, and the hot air in the indoor air or the outdoor air is below the dew point temp. It is made of latent heat exchange by the condensate produced in the state of.

On the other hand, during the winter operation, defrosting operation is performed in order to prevent a drop in the heat exchanger 130, Figure 3 is a block diagram showing a first embodiment of the defrosting operation system of the waste heat recovery ventilator according to the present invention, As shown, if it is determined that the outdoor temperature detected by the temperature sensor 140 is the temperature causing the build-up of the heat exchanger 130, the control unit 200 drives the defrost heater 150 to heat the outdoor temperature. . In addition, when the pressure difference between the indoor air flowing into the heat exchanger 130 and the indoor air flowing out through the differential pressure gauge 170 is detected and the pressure difference is determined as the pressure difference value due to the accumulation of the heat exchanger 130, When the heater 150 is continuously driven, and the pressure difference is determined not to be the pressure difference value due to the buildup of the heat exchanger 130, the driving of the defrost heater 150 is stopped. At this time, the differential pressure gauge 170 operates by measuring the flow rate of the indoor air flowing into the heat exchanger 130 and the flow rate of the indoor air flowing out of the heat exchanger 130 to calculate the pressure difference between the two points.

Figure 4 is a block diagram showing a second embodiment of the defrosting operation system of the waste heat recovery ventilator according to the present invention, in which the indoor air of the heat exchanger 130 is introduced instead of the differential pressure gauge 170 of the first embodiment and the room The defrost heater 150 is provided with a first pressure sensor 181 and a second pressure sensor 182 on the side from which air flows, respectively, to detect the respective pressures and to compare the difference, thereby calculating the pressure difference. Control whether or not

5 is a flowchart illustrating a defrosting operation method of a waste heat recovery ventilator according to the present invention. As shown in the drawing, first, a temperature sensor 140 detects a temperature of outdoor air introduced into an air supply duct 110. In operation S100, the control unit 200 compares the temperature detected by the temperature sensor 140 with a preset drop determination temperature to determine whether or not the heat exchanger 130 is loaded (S200).

As a result of comparing the temperature detected in the step S200 and the temperature of the stock determination, when the detected temperature is less than or equal to the preset temperature of the stock determination, the controller 200 of the defrost heater 150 operates the defrost heater 150. The driving signal is output (S300). That is, the controller 200 compares the detected temperature with the temperature for determining the stock removal, and when it is determined that the heat is generated in the heat exchanger 130, the defrost heater 150 is driven to perform the defrosting operation.

Then, the pressure difference between the side of the indoor air of the heat exchanger 130 and the side of the indoor air flows through the differential pressure gauge 170 or the first and second pressure detection sensors 181 and 182 that are the pressure detecting means 160. (S400), and the control unit 200 compares the pressure difference value detected by the pressure detecting unit 160 with a preset drop determination reference value set in order to break whether the heat exchanger 130 is loaded. (S500).

If it is determined that the pressure difference value detected in the step S500 is not greater than the predetermined drop determination reference value, the controller 200 determines that the drop of the heat exchanger 130 is removed, and the defrost heater 150 is stopped. The stop signal of the heater 150 is output (S600).

In addition, when it is determined that the pressure difference value detected in the step S500 is greater than the preset drop determination reference value, the control unit 200 determines that the drop is not yet resolved in the heat exchanger 130, the pressure detecting means again ( 160 to detect the pressure difference between the side in which the indoor air of the heat exchanger 130 flows in and the side in which the indoor air flows out.

The defrosting operation system and control method of the waste heat recovery ventilator according to the present invention, as described above, by driving the defrost heater through the information detected through the temperature sensor and the pressure detection means, even if the temperature of the outdoor air is low It is a useful invention that can prevent the drive of the defrost heater undesirably, and can effectively reduce the power consumption.

Claims (5)

At the point where the air supply duct is divided into an air supply duct that introduces outdoor air into the room by the air supply fan and the air exhaust duct that crosses the air supply duct, and the air is discharged to the outside by the air exhaust fan, and the air supply duct and the exhaust duct intersect. And a plurality of supply passages communicating with the air supply duct and a plurality of exhaust passages communicating with the exhaust duct are adjacent to each other, and a heat recovery ventilator including a heat exchanger for exchanging heat in the air supply passage and the air in the exhaust passage. As the defrosting system of the device, A temperature sensor detecting a temperature of outdoor air introduced into the air supply duct; Pressure detecting means for detecting a pressure difference between indoor air flowing into the heat exchanger and the indoor air flowing out of the heat exchanger in the exhaust duct; Defrost heater for heating the outdoor air introduced into the air supply duct; And And a control unit for controlling the operation of the defrost heater by receiving the signal detected from the temperature sensor and the pressure detecting means. The method of claim 1, The pressure detecting means is a defrosting operation system of the waste heat recovery ventilator, characterized in that for detecting the pressure difference by detecting a change in the flow rate of the indoor air inflow side and the indoor air outflow side of the heat exchanger. The method of claim 1, The pressure detecting means is a defrosting operation system of the waste heat recovery ventilator, characterized in that the first and second pressure sensing sensors installed on the side of the indoor air inflow and the indoor air outflow side of the heat exchanger, respectively. As a defrosting operation method of the waste heat recovery ventilator, a) detecting a temperature of outdoor air introduced into the air supply duct by a temperature sensor; b) comparing, by the controller, the temperature detected by the temperature sensor with a preset temperature for determining the stock image; c) the control unit outputting a driving signal of a defrost heater when the detected temperature is less than or equal to a preset temperature determination temperature; d) detecting, by the pressure detecting means, a pressure difference between a side into which indoor air of the heat exchanger flows in and a side into which indoor air flows out; e) comparing, by the control unit, the pressure difference value detected by the pressure detecting means with a preset accumulation determination reference value; And f) defrosting operation of the waste heat recovery ventilator including the step of outputting a stop signal of the defrost heater when the detected pressure difference value does not exceed a preset drop determination reference value; Way. The method of claim 4, wherein If it is determined that the pressure difference value detected in step e is greater than the preset drop determination reference value, the control unit performs step d again, the defrosting operation method of the waste heat recovery ventilator.

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