KR101313192B1 - Total heat exchanger having fire mode - Google Patents

Abstract

PURPOSE: An electric heat exchanger capable of operating a fire mode is provided to minimize the number of casualties due to suffocation by discharging poisonous gases in the event of fire and preventing the fire from spreading by blocking the inflow of outside air. CONSTITUTION: An electric heat exchanger capable of operating a fire mode includes a housing (110), an exhaust fan (140), a supply fan (160), a sensor (12), a common power source, an emergency power source, a remote control (20), and a master controller (10). The exhaust fan is installed inside the housing and inhales or discharges inside air. The supply fan is installed inside the housing and inhales or discharges outside air. The sensor detects the occurrence of fire and includes a no-power contact point. The common power source and the emergency power source are electrically connected to the exhaust fan and the supply fan. The remote control is inputted with a predetermined value for the operation of the exhaust fan and the supply fan and transmits an electric signal depending on the predetermined value. The master controller is installed inside the housing to be electrically connected to the exhaust fan and the supply fan and controls the operation of the supply fan. The master controller is connected to the no-power contact point to be changed into a normal mode or a fire mode. [Reference numerals] (10) Main control unit; (12) Sensing unit; (AA) Common power; (BB) Emergency power

Description

Heat exchanger that can operate in fire mode {TOTAL HEAT EXCHANGER HAVING FIRE MODE}

The present invention relates to a total heat exchange apparatus, and more particularly to a total heat exchange apparatus operable in the normal mode and the fire mode.

Recently, the quality of the residential environment has been improved by improving the indoor environment of the living space due to the development of various air-conditioning and mechanical devices. However, as the air-conditioning facilities are spreading, it is difficult to ventilate the living space, and inadequate ventilation in the indoor space threatens the health of the residents.

Installation of building ventilation equipment is mandated by the Building Standards Act, and the improvement of indoor air in buildings is becoming an important issue, such as adding ventilation to home air conditioning and heating devices.

However, if the ventilation of the building is active, the heat loss is increased even after heating and cooling, the energy consumption is too large. Accordingly, attention has been paid to a total heat exchange device that minimizes the emission of heat or cold while ventilating to suppress energy consumption.

The total heat exchange device has a structure in which a spacer is disposed between each liner and a liner stacked in a vertical direction with a predetermined space therebetween. The liner functions as a heat exchange medium between the air flowing above and below the spacer, and the spacer has a corrugated plate shape to form an air passage for the flow of air. The air flow path has a structure that intersects each other, one of which is a flow path through which indoor air passes to the outside, and the other is a flow path through which outdoor air flows into the inside. Therefore, during ventilation, indoor air and outdoor air are exchanged with each other while passing through each air passage with a liner interposed therebetween, and the latent heat or sensible heat of the discharged indoor air is absorbed by the outdoor air.

Korean Registered Patent Publication No. 1149815 2012.05.24.

It is an object of the present invention to provide a total heat exchange device capable of ventilating the interior of a building.

Another object of the present invention to provide a total heat exchange device that can discharge the harmful gas in the fire.

Still another object of the present invention is to provide a total heat exchanger capable of preventing the spread of fire by blocking the inflow of external air during a fire.

Still other objects of the present invention will become more apparent from the following detailed description and the accompanying drawings.

According to an embodiment of the present invention, an electrothermal heat exchanger installed inside the building to supply external air to the inside and discharge the internal air to the outside is installed inside the building, and the external air and the internal air A housing in which heat exchange is performed; A discharge fan installed inside the housing and positioned at one side of an internal air discharge port formed at one side of the housing to suck and discharge the internal air; A supply fan installed inside the housing and positioned at one side of an internal air supply port formed on the other side of the housing to suck and discharge the external air; A detector for detecting a fire and having a non-power contact; A remote controller for inputting a setting value for an operation state of the discharge fan and the supply fan by a user and transmitting an electrical signal according to the setting value; And a main controller electrically connected to the discharge fan and the supply fan to control the operation of the discharge fan and the supply fan, and connected to the non-power contact and switchable to a normal mode and a fire mode. In the normal mode, the operation of the discharge fan and the supply fan is controlled according to the set value, and the rotation speed of the discharge fan is increased while disregarding the set value in the fire mode.

The main controller may stop the supply fan in the fire mode.

The total heat exchange device further comprises a commercial power source electrically connected to the discharge fan and the supply fan, wherein the main controller increases the current value of the commercial power applied to the discharge fan in the fire mode and is applied to the supply fan. The commercial power source can be cut off.

The total heat exchange device further includes a commercial power source and an emergency power source electrically connected to the discharge fan and the supply fan, wherein the main controller replaces the commercial power source with the discharge fan and the supply fan when the commercial power source is normal in the fire mode. The emergency power may be supplied to the discharge fan and the supply fan when the commercial power is cut off.

According to an embodiment of the present invention it is possible to ventilate the interior of the building through the total heat exchange device. In addition, it is possible to minimize the damage to life due to asphyxiation by releasing harmful gases in the fire, and to prevent the spread of fire by blocking the inflow of external air. In particular, it is possible to effectively discharge harmful gases by preventing the operation is stopped in the event of a power failure due to fire.

1 is a view schematically showing a total heat exchange apparatus according to an embodiment of the present invention.
2 and 3 are views showing an operating state of the total heat exchange device shown in FIG.
4 is a flowchart showing the operation procedure of the electrothermal heat exchanger shown in FIG.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to FIGS. 1 to 4. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described below. The embodiments are provided to explain the present invention to a person having ordinary skill in the art to which the present invention belongs. Accordingly, the shape of each element shown in the drawings may be exaggerated to emphasize a clearer description.

1 is a view schematically showing a total heat exchange apparatus according to an embodiment of the present invention. As shown in FIG. 1, the total heat exchange apparatus 100 has a housing 110 having a rectangular cross section. The total heat exchange device 100 is installed inside the building, and heat exchange between the outside air and the inside air is performed in the housing 110.

The external air suction port 210 and the internal air discharge port 230 are formed at one side of the housing 110, and the internal air supply port 250 and the internal air suction port 260 are formed at the other side of the housing 110. . The external air is introduced into the housing 110 through the external air intake 210 and then supplied to the inside of the building through the internal air supply port 250, and the internal air is supplied to the housing 110 through the internal air intake 260. After being introduced into the inside is discharged to the outside of the building through the internal air outlet 230. The external air and the internal air pass through a heat exchange element (not shown) installed inside the housing 110, and simultaneously exchange sensible and latent heat in a state in which they are not mixed with each other in the heat exchange element.

The discharge fan 140 is installed at one side of the internal air discharge port 230 and discharges through the internal air discharge port 230 after suctioning the internal air introduced into the housing 110. The supply fan 160 is installed at one side of the internal air supply port 250, and discharges the external air introduced into the housing 110 through the internal air supply port 250. Through this method, the outside air is supplied to the inside of the building through the air supply duct 270 in heat exchange with the inside air, and the inside air flows into the inside of the housing 110 through the exhaust duct 280 and then outside. Exhausted outside the building in heat exchange with air.

The main controller 10 is connected to the discharge fan 140 and the supply fan 160, respectively, and controls the operation of the discharge fan 140 and the supply fan 160. The remote controller 20 transmits a setting value to the main controller 10, and as will be described later, the main controller 10 operates the discharge fan 140 and the supply fan 160 according to the setting value in the normal mode. Control or control the operation of the discharge fan 140 and the supply fan 160 in accordance with a predetermined fire mode. The preset fire mode may be stored in a memory provided inside the main controller 10.

The remote controller 20 may include an input button 21 for inputting a setting value and a display 22 showing the setting value to the user. The user inputs a setting value through the input button 21, and the input setting value is not only displayed on the display 22 but also transmitted to the main controller 10 through wireless or wired communication. Since the remote controller 20 is connected to the main controller 10, as will be described later, even if the remote controller 20 is damaged or damaged due to a fire, the discharge fan 140 and the supply fan 160 is the main controller 10 Can be operated by The remote controller 20 may be fixed to the interior wall of the building, and may be connected to the main controller 10 by wireless or wired.

The commercial power source and the emergency power source are connected to the main controller 10, and the main controller 10 supplies the current supplied from any one of the commercial power source and the emergency power source to the discharge fan 140 and the supply fan 160. Commercial power refers to AC power supplied to each household from the power transmission line connected to the power plant. Emergency power means power generation inside or around the assembly building when commercial power is interrupted by power failure or breakage of the power transmission line. Refers to the power supplied from the facility. Typically, in a building such as an apartment, a townhouse, or an officetel, when commercial power is cut off, emergency power is supplied to each household so that emergency lights are turned on. When disconnected, emergency power must be provided to essential loads such as emergency lights. For example, the emergency power source may be a self-generator, a storage battery facility, or an emergency power receiving power facility that stores or generates power by receiving energy such as thermal power, wind power, and solar power.

The main controller 10 cuts off the power supply of the emergency power in the normal mode and supplies current through the commercial power, and the electrothermal heat exchanger 100 does not operate when the commercial power is out of power. On the other hand, the main controller 10 cuts off the power supply of the emergency power in the fire mode and supplies the current through the commercial power, but supplies the current after switching the power to the emergency power when the commercial power is out of power. That is, in the event of a power failure due to a short circuit or breakage of wires in a fire, the main controller 10 supplies a current from an emergency power source to operate the total heat exchange device 100. At this time, the main controller 10 prevents the emergency power and the commercial power from being supplied at the same time by cutting off the power supply of the commercial power.

In addition, the main controller 10 may control the operation state of the discharge fan 140 and the supply fan 160 by adjusting the current value according to the set value received from the remote controller 20 in the normal mode, It is possible to control the operation state of the discharge fan 140 and the supply fan 160 by adjusting the current value in accordance with the fire mode.

On the other hand, the detector 12 is installed on the ceiling or wall inside the building, and detects the heat or gas generated by the fire to detect whether the fire. The detector 12 has a no-power contact, which is connected to the main controller 10. When the room temperature is out of a predetermined range or the combustion gas is detected, the detector 12 may transmit an electrical signal to the main controller 10 connected to the non-powered contact to notify the fire occurrence, the main controller 10 May be converted from the normal mode to the fire mode through a signal transmitted from the no-power contact of the detector 12.

2 and 3 are views showing an operating state of the electrothermal heat exchanger shown in FIG. 1, and FIG. 4 is a flowchart showing an operation procedure of the electrothermal heat exchanger shown in FIG. Hereinafter, the operation of the total heat exchanger will be described with reference to FIGS. 2 to 4.

First, as shown in Figure 1, the main controller 10 receives the set value from the remote controller 20 in the normal mode (S10), the discharge fan 140 and the supply fan 160 in accordance with the received set value Control the operating state of the (S20). The outside air is sucked into the housing 110 by the supply fan 160 and introduced into the air supply duct 270, and the inside air of the housing 110 is discharged by the exhaust fan 140 through the exhaust duct 280. It is sucked into the inside and discharged. The main controller 10 adjusts the current value supplied from the commercial power supply to supply to the discharge fan 140 and the supply fan 160, the rotational speed of the discharge fan 140 and the supply fan 160 in accordance with the current value I can regulate it. At this time, the power supply of the emergency power is cut off.

Next, as shown in Figure 2, the main controller 10 is connected to the no-power contact of the detector 12, when the room temperature is out of a predetermined range or the combustion gas is detected, the detector 12 is a no-power contact By transmitting an electrical signal to the main controller 10 through the fire to inform the facts. The main controller 10 receives the signal from the detector 12 and then switches from the normal mode to the fire mode (S30).

The main controller 10 disregards the setting value received from the remote controller 20 in the fire mode, operates in a preset fire mode stored in the memory to discharge the smoke inside the building to the outside, and the external air flows into the building. Can be blocked.

The main controller 10 increases the current value applied to the discharge fan 140 to increase the rotational speed of the discharge fan 140 (S40). The discharge fan 140 rotates at the highest speed to discharge the smoke inside the building to the outside, thereby minimizing the damage to life due to harmful gases such as smoke.

In addition, the main controller 10 stops the power supplied to the supply fan 160 to stop the operation of the supply fan 160 (S50). When the outside air is introduced into the building due to the operation of the supply fan 160, the fire zone may be spread due to the oxygen supply.

On the other hand, due to the fire may be a power failure due to a short circuit or breakage of the wiring, the operation of the total heat exchange device 100 can be stopped during the power failure of the commercial power. Therefore, as shown in FIG. 3, when the current supply is cut off due to the power failure of the commercial power source, the main controller 10 switches the commercial power source to the emergency power source (S60) and releases the power supply of the emergency power source. Power supply to the discharge fan 140 and the supply fan 160 may be continued. At this time, the main controller 10 prevents the emergency power and the commercial power from being supplied at the same time by cutting off the power supply of the commercial power.

Although the present invention has been described in detail by way of preferred embodiments thereof, other forms of embodiment are possible. Therefore, the technical idea and scope of the claims set forth below are not limited to the preferred embodiments.

10: main controller 12: detector
20: remote controller 100: electric heat exchanger
110 housing 140 exhaust fan
160: supply fan 210: external air intake
230: internal air outlet 250: internal air supply
260: internal air intake 270: air supply duct
280: exhaust duct

Claims (4)

In the heat exchange device installed inside the building to supply the outside air to the inside and discharge the inside air to the outside,
A housing installed inside the building and configured to exchange heat with the outside air and the inside air;
A discharge fan installed inside the housing and positioned at one side of an internal air discharge port formed at one side of the housing to suck and discharge the internal air;
A supply fan installed inside the housing and positioned at one side of an internal air supply port formed on the other side of the housing to suck and discharge the external air;
A detector for detecting a fire and having a non-power contact;
Commercial power and emergency power electrically connected to the discharge fan and the supply fan;
A remote controller installed spaced apart from the housing to input a setting value for an operation state of the discharge fan and the supply fan through a user and to transmit an electrical signal according to the setting value; And
Is installed inside the housing and electrically connected to the discharge fan and the supply fan and controls the operation of the discharge fan and the supply fan, and includes a main controller that is connected to the non-powered contact can be switched to the normal mode and the fire mode, ,
The main controller,
Controlling the operation of the discharge fan and the supply fan according to the signal transmitted from the remote controller in the normal mode,
In the fire mode,
Ignore the signal transmitted from the remote controller, increase the rotational speed of the discharge fan and stop the supply fan,
And supply the commercial power to the discharge fan and the supply fan when the commercial power is normal, and supply the emergency power to the discharge fan and the supply fan when the commercial power is interrupted. delete The method of claim 1,
The total heat exchange device further comprises a commercial power source electrically connected to the discharge fan and the supply fan,
The main controller increases the current value of the commercial power applied to the discharge fan in the fire mode and cuts off the commercial power applied to the supply fan. delete

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