KR100211103B1 - Gas exhaust - Google Patents

Abstract

The present invention relates to a reverse wind protection circuit of a gas discharge device for a gas boiler.

The reverse wind protection circuit of the gas exhaust device according to the present invention is to prevent the gas leakage accident caused when the back wind phenomenon caused by the typhoon is generated and the damper installed at the exhaust fan outlet is closed.

For this purpose, the present invention is a reverse wind detection unit for detecting the blockage state of the damper due to the reverse wind, and a rotation speed variable unit for generating a signal forcibly opening the damper by increasing the rotational speed of the fan motor when the reverse wind is detected Is done.

Therefore, the reverse wind protection circuit of the gas discharge device according to the present invention by increasing the rotation speed of the fan motor during the reverse wind can prevent the damper is not closed at all to prevent frequent stopping of the gas boiler.

Description

Reverse Wind Protection Circuit of Gas Discharge Device

1 is a view schematically showing a gas discharge device and a damper mounted on a gas boiler.

2 is a block diagram of a gas exhaust device provided with a reverse wind protection circuit according to the present invention.

3 is a detailed view of the reverse wind protection circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

10 gas boiler 12 gas discharge device

160: damper 100: fan motor

200: Hall sensor 300: frequency / voltage converter

400: reverse wind detection unit 403: comparator

500: number of revolutions 502: relay coil

503: relay contact for 2000 rpm 504: relay contact for 3000 rpm

505: 2000 rpm Resistor 506: 3000 rpm Resistor

600: pulse width modulated signal generator

Vref: reference voltage Va: voltage at reverse wind

Vn: Normal voltage

The present invention relates to a reverse wind protection circuit of a gas discharge device for a gas boiler, and more particularly, the rotation speed of the exhaust fan is increased when the damper installed in the communication of the gas boiler is closed by a back wind caused by typhoons or strong winds. The present invention relates to a reverse wind protection circuit of a gas discharge device for preventing indoor leakage of exhaust gas.

The gas boiler used for heating in a single house or apartment is equipped with a gas discharge device having a fan motor, which will be described in more detail with reference to FIG.

1 is a view schematically showing a gas discharge device and a damper attached to a conventional gas boiler.

In FIG. 1, a gas exhaust device 12 having an exhaust fan 11 and a control circuit (not shown) is mounted above the gas boiler 10. In addition, an auxiliary communication 16 for inserting a communication 14 connected to the outside of the building is provided at the exhaust port side of the gas discharge device 12, and the opening and closing of the auxiliary communication 16 is opened and closed by a spring (not shown). Possible semicircular dampers 160 are provided. The damper 160 is opened as indicated by the dashed line in FIG. 1 by the wind pressure by the fan when the exhaust fan 11 is operated when the gas boiler 10 is operated.

On the other hand, when the operation of the gas boiler 10 is stopped, the operation of the exhaust fan 11 is also stopped, so there is no wind pressure of the exhaust fan, and the damper 160 is closed by restoring force of a spring (not shown).

Therefore, when the gas boiler 10 is not driven, the damper 160 is closed so that the wind backflowing from the outside through the communication 14 or the substance does not enter the gas boiler 10.

In FIG. 1, the micro switch 162 located behind the damper 160 is operated when the damper 160 is opened by the wind pressure of the exhaust fan of the gas exhaust device 12 when the gas boiler 10 is operated. When the damper 160 is closed due to a reverse wind or the like, it is a reverse wind protection switch for stopping the operation of the gas boiler 10.

However, although the damper and the micro switch are attached to the exhaust fan outlet in the related art as described above, when the damper is closed due to a typhoon or strong wind from the gas boiler, the exhaust gas is not easily discharged to the outside. Most of the gas was introduced into the room, which could cause asphyxiation of exhaust gas. In addition, when the micro switch which operates the gas boiler by the interlocking operation with the damper during the reverse wind is corroded by the exhaust gas and the contact point is poor, the micro switch is operated even when the back wind phenomenon occurs due to the typhoon. The operation continued to cause a choking accident caused by the exhaust gas.

The present invention is to solve the above problems, an object of the present invention is to open the damper completely by increasing the rotational speed of the exhaust fan when the damper is gradually closed due to the back wind due to typhoons or strong winds during operation of the gas boiler It is to provide a reverse wind protection circuit of the gas exhaust device that can prevent the exhaust gas leakage accident in advance.

Characteristic of the reverse wind protection circuit of the gas discharge device according to the present invention for achieving the above object is the blockage of the damper according to the reverse wind by comparing the output voltage and the predetermined reference voltage of the frequency / voltage converter which is variable during the rotation of the fan motor It consists of a reverse wind detection unit for generating a signal indicating a state, and a rotation speed variable unit for receiving a signal output from the reverse wind detection unit to increase the rotation speed of the fan motor when the reverse wind occurs.

Hereinafter, a preferred embodiment of the reverse wind protection circuit of the gas exhaust device according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a gas discharge device provided with a reverse wind protection circuit according to the present invention, the Hall sensor (200) for detecting the rotation state of the fan motor 100 when the gas boiler is operating frequency / voltage Is connected to the transducer 300. The frequency / voltage converter 300 converts the frequency signal generated by the hall sensor 200 into a voltage signal and outputs the voltage signal.

The reverse wind detection unit 400, which is essential for the present invention, is connected to the frequency / voltage converter 300. The reverse wind detection unit 400 outputs a voltage signal output from the frequency / voltage converter 300 and a predetermined reference voltage signal. In comparison, a signal indicating a blocked state of the damper 160 (refer to FIG. 1) due to the reverse wind is generated.

In addition, the reverse wind detection unit 400 is connected to a rotation speed variable unit 500 for varying the rotation speed of the fan motor 100 when the reverse wind occurs, the signal generated from the rotation speed variable unit 500 is a pulse connected thereto It is input to the width modulated signal generator 600. The triangular wave signal generator 700 is connected to the pulse width modulated signal generator 600, and an output terminal of the pulse width modulated signal generator 600 is connected to a drive logic 800 configured as a logic circuit. The drive logic 800 is connected to supply a signal to the inverter unit 900 for driving the fan motor 100.

Considering the operation state of the gas discharge device configured as described above, first, when the power is applied, the fan motor 100 rotates, and the frequency signal detected by the hall sensor 200 during the rotation of the fan motor 100 is frequency / The voltage converter 300 converts the voltage signal according to the rotation of the fan motor 100. The voltage signal generated by the frequency / voltage converter 300 is input to the reverse wind detector 400 and compared with the reference voltage Vref required for the normal rotation of the fan motor 100. The rotational speed (rpm) and the output voltage (Vn; normal) (Va; reverse wind) of the frequency / voltage converter 300 are assumed as shown in Table 1 below.

In Tables 1 and 2 above, the reference voltage Vref set in the reverse wind detection unit 400 is

, The rotation speed of the fan motor 100 according to the reference voltage Vref is set between 2000 rpm and 2500 rpm, for example, 2300 rpm.

Therefore, in the normal rotation, as shown in Table 1 and Formula (I), the reverse wind detector 400 compares the output Vn of the frequency / voltage converter 300 with the reference voltage Vref in a first state. A signal, for example, a high state signal is generated and provided to the rotational speed variable part 500.

In such a reverse wind, as shown in Table 1 and formula (I), the reverse wind detection unit 400 generates a second signal, for example, a low signal, and inputs it to the rotation speed variable unit 500.

At this time, the rotation speed variable unit 500 provides a pulse width modulated signal generator 600 with a signal for varying the rotation speed of the fan motor 100 according to the output state (H or L) of the reverse wind detection unit 400. For example, the reverse wind detection unit 400 and the rotation speed variable unit 500 will be described in detail later with reference to FIG. 3.

The pulse width modulation signal generator 600 generates and drives a modulation signal for varying the rotational speed of the fan motor according to a signal input from the rotation speed variable unit 500 and a signal input from the triangular wave signal generator 700. To the logic 800. The drive logic 800 may be configured such as an AND gate, and logically combines the output of the hall sensor 200 and the pulse width modulated signal to provide an inverter unit 900 that may be configured as a transistor. The inverter unit 900 controls the driving of the fan motor 100 according to the output signal of the drive logic 800.

FIG. 3 is a detailed view of the reverse wind detection unit 400 and the rotation speed variable unit 500 shown in FIG. 2, and the reverse wind detection unit 400 is a reference voltage (Vref) required for normal rotation of the exhaust fan motor 100. ), And a comparator 403 for comparing the voltage divider resistors 401 and 402 for setting?) And the reference voltage Vref due to the voltage divider resistor and the output voltage Vn or Va of the frequency / voltage converter 300. Here, the inverting input terminal of the comparator 403 is connected to the output terminal of the frequency / voltage converter 300, and the rotation speed (2300 rpm) necessary for the normal rotation of the fan motor 100 to the non-inverting input terminal of the comparator 403. The reference voltage Vref corresponding thereto is applied. In FIG. 3, 404 and 405 represent a feedback resistor and a pullup resistor, respectively.

The output terminal of the comparator 403 is connected to the base of the transistor 501 is turned on / off in accordance with the output voltage of the comparator 403, the collector of the transistor 501 is a relay coil (excited when the transistor 501 is turned on) 502 is connected. The relay contact 503 is on when the relay coil 502 is excited, and the relay contact 504 is configured to maintain an off state. However, when the relay coil 502 is not excited, the relay contact 503 is turned off, and the relay contact 504 remains on. Resistors 505 and 506 are connected in series to these relay contacts 503 and 504, respectively, to transmit a signal for varying the rotational speed of the fan motor when the relay contacts 503 and 504 are turned on / off to the pulse width modulation signal generator 600. It is supposed to provide.

The operation of the reverse wind protection circuit of the gas discharge device according to the present invention configured as described above will be described in detail.

First, as shown in Table 1 and formula (I) during normal rotation, the rotation speed of the fan motor 100 is 2000 rpm or less, and the reference set rotation speed is 2300 rpm, in which case the reference voltage (Vref) is normal rotation. Since it is larger than the voltage Vn (that is, VnVref), the output of the comparator 403 is turned high to turn on the transistor 501. When the transistor 501 is turned on, a current flows in the relay coil 502. At this time, the relay contact 503 is turned on, and the relay contact 504 is turned off. In this case, the voltage signal by the resistor 505 may be provided to the pulse width modulated signal generator 600. In other words, the fan motor 100 may be operated at 2000 rpm or less depending on the voltage determined by the relay contact 503 and the resistor 505.

On the other hand, when the reverse wind coming through the communication 14 shown in FIG. 1 by typhoons or strong winds, the damper 160 installed in the auxiliary communication 16 is gradually closed by the reverse wind, in which case the gas is discharged. Since the degree of vacuum inside the fan of the apparatus 12 is increased and the pressure is lowered, the rotation speed of the fan motor is increased to about 2500 rpm. However, since the exhaust gas cannot be normally discharged only by the amount of bulge at that time, it is necessary to further increase the rotation speed of the fan motor (for example, 3000 rpm or more).

Therefore, when the fan motor 100 is rotated at 2300 rpm or more due to the increase in the degree of vacuum in the fan, the reference voltage Vref is smaller than the output voltage Va of the frequency / voltage converter 300 due to the counterwind. The comparator 403 outputs a low state signal. At this time, since the transistor 501 is off, no current flows in the relay coil 502. Accordingly, the relay contact 503 is turned off, and the relay contact 504 is turned on. Therefore, in this case, the signal for causing the fan motor 100 to rotate at about 3000 rpm by the resistor 506 is provided to the pulse width modulated signal generator 600. When the fan motor 100 is rotated at about 3000 rpm, the damper 160 is forcibly opened more, so that there is no accident of exhaust gas leaking into the room even if a reverse wind blows.

As a result, the comparator 403 compares the output voltage Vn or Va and the reference voltage Vref of the frequency / voltage converter 300 to generate a signal for adjusting the rotational speed of the fan, and relay coil 502 and By operating the relay with the contacts 503 and 504, the fan motor 100 can be rotated at about 2000 rpm in normal, or less than 3000 rpm in reverse wind.

As described above, according to the reverse wind protection circuit of the gas discharge device according to the present invention, if the damper is closed during the inflow of the wind due to typhoons or strong winds during the operation of the gas boiler, the rotation speed of the fan is increased considerably to exhaust the damper by forcibly opening the damper. Unlike conventional technology in which a gas switch is frequently stopped due to a micro switch off by a damper whenever a reverse wind phenomenon occurs, and a gas boiler is frequently stopped, it detects this when the damper is gradually closed due to the reverse wind. It is possible to prevent the frequent stoppage of the boiler by opening the damper as much as possible by increasing the rotation speed rapidly.

Although the present invention has been described with respect to a gas boiler, the present invention is not limited to this, but may also be applied to a large ventilation device used in a place such as a restaurant.

Claims (1)

In the reverse wind protection circuit of a gas exhaust device having a damper which is opened when the fan motor is rotated and discharges exhaust gas to the outside, the divided pressure resistors for setting the reference voltage required for the normal rotation of the exhaust fan motor and the exhaust fan motor. Comparator that compares the output voltage of the variable frequency / voltage converter during normal rotation and reverse wind to generate a signal indicating the blocked state of the damper, the variable output voltage of the variable frequency / voltage converter during the rotation of the fan motor and predetermined A reverse wind detection unit for generating a signal indicating a blocked state of the damper according to the reverse wind by comparing a reference voltage, a transistor turned on / off by an output signal of the reverse wind detection unit, a relay coil excited when the transistor is turned on, and A relay of at least two relay contacts selectively on / off by a relay coil of the relay coil and the relay contacts It is composed of resistors connected in series to each of the relay contacts to change the rotational speed of the fan motor on / off, the rotational speed to increase the rotational speed of the fan motor in the reverse wind by receiving the signal output from the reverse wind detection unit Reverse wind protection circuit of a gas discharge device comprising a variable portion.