WO2020153574A1

WO2020153574A1 - Boiler control system using carbon monoxide detectors

Info

Publication number: WO2020153574A1
Application number: PCT/KR2019/013164
Authority: WO
Inventors: 강수철
Original assignee: 강수철
Priority date: 2019-01-22
Filing date: 2019-10-08
Publication date: 2020-07-30
Also published as: KR102017450B1

Abstract

The present invention relates to a boiler control system using carbon monoxide detectors, and provides a boiler control system using carbon monoxide detectors, the boiler control system detecting, in real time, the concentration of carbon monoxide in a boiler room and indoors so as to stop the operation of a boiler when the concentration is higher than a reference value, warning indoor residents of same so as to enable rapid ventilation and the like to be induced, and being simply installed without changing or replacing a boiler and a room switch such as that of an indoor temperature controller having been preinstalled, thereby enabling the minimization of costs required for boiler control by using carbon monoxide detection.

Description

Boiler control system using carbon monoxide detector

The present invention relates to a boiler control system using a carbon monoxide detector, and more particularly, to a system for monitoring a carbon monoxide concentration using a carbon monoxide detector installed in a boiler room and a room, and stopping the operation of the boiler when the reference value is exceeded.

In general, the boiler has various types of gas boilers, oil boilers, and the like depending on the fuel used. As an example, a gas boiler uses gas as a fuel and heats water using combustion heat generated when combusting the gas, and is a heating pipe installed indoors by a circulation pump that circulates the heated and stored water forcibly. It is a device that circulates to heat the room and supplies warm water to the bathroom and kitchen as hot water.

At this time, the exhaust gas emitted due to the use of the boiler includes carbon monoxide (CO), and these carbon monoxides have three characteristics: colorless, odorless, and tasteless. When carbon monoxide enters the lungs, it combines with hemoglobin in the blood to form carbon monoxide hemoglobin. As a result, the ability to carry blood oxygen is lost and the person is in an internal suffocation condition. This phenomenon is called carbon monoxide poisoning.

More specifically, the higher the concentration of carbon monoxide in the air, the more serious it can be. If the concentration in the air is 0.02%, a mild headache occurs within 2-3 hours, and if it is more than 0.08%, symptoms of headache, nausea, and vomiting appear after 45 minutes, and fainting occurs within 2 hours, and if it is 0.16% or more, about 20 minutes There are reports of exposure, headache, nausea, and vomiting and death within 2 hours, and death of between 1 and 3 minutes at 1.28%.

Therefore, in order to avoid exposure to carbon monoxide, it is necessary to regularly check gas leaks of boilers and the like.

On the other hand, Patent Publication No. 10-2005-004810 (reference) has been proposed in this regard. This relates to the indoor temperature controller of a boiler equipped with an indoor pollution alarm function, in an indoor temperature controller including a microprocessor to remotely operate the function of the boiler body, measuring the degree of indoor air pollution at the input end of the microprocessor To detect dust contained in the air in the room, a dust sensor for detecting the amount of carbon monoxide, a carbon monoxide sensor for detecting the amount of carbon dioxide, a carbon dioxide sensor for detecting the amount of carbon dioxide, a temperature sensor for detecting the indoor temperature, and a humidity sensor A humidity sensor is included and connected, and an output unit of the microprocessor is connected to a display unit for displaying the measured air pollution level and an alarm unit for notifying the user when the measured air pollution level exceeds a preset reference value, and the microprocessor There has been proposed a room temperature controller of a boiler equipped with an indoor pollution alarm function, in which a storage unit in which reference data capable of determining the degree of contamination is stored is connected based on the data measured from the sensors.

However, the indoor temperature controller of the reference is simply to monitor the air pollution level of the room to display or alert the user to cope, and in this case, if the user does not live in the room, the boiler operates as it is.

In addition, for reference, for example, carbon monoxide is leaked from the boiler room where the boiler is installed, and it is impossible to monitor immediately before entering the room. In addition, when the indoor temperature controller malfunctions, there is also a problem that it is impossible to display or alarm the air pollution level in the room.

In addition, there is a problem in that the indoor temperature controller of the reference cannot be used as it is, and the indoor temperature controller must be replaced with a newly added indoor temperature controller.

Therefore, to solve the problems of the prior art, the present invention is to provide a boiler control system that stops the operation of the boiler when the reference value is exceeded by monitoring the concentration of carbon monoxide by using a carbon monoxide detector individually installed in the boiler room and the room. There is this.

In addition, the present invention also has an object to provide a boiler control system using a carbon monoxide detector that warns residents of the room to induce rapid ventilation when the concentration of carbon monoxide in a boiler room or room exceeds a reference value.

In addition, the present invention also has an object to provide a boiler control system using a carbon monoxide detector that can be applied without changing or replacing basic facilities such as a room temperature controller connected to a pre-installed boiler.

The present invention to solve this technical problem; The boiler is provided in the boiler room and is equipped with a boiler driving unit that is controlled by the boiler controller, and is supplied with driving power through a power line from the boiler controller, but is installed indoors to receive boiler monitoring information from the boiler controller and receive the boiler. A room switch that transmits boiler control information for control to the boiler controller, and when the carbon monoxide concentration value installed in the boiler room and detected in the boiler room exceeds a reference value, the power line is turned off to drive the boiler controller. With a carbon monoxide detector for the boiler room to cut off the power, and an indoor carbon monoxide detector to cut off the driving power supplied from the boiler controller to the room switch by turning off the power line when the carbon monoxide concentration value installed in the room exceeds the standard value. Composed; The boiler controller generates boiler monitoring information including a driving state of the boiler driving unit and controls the boiler driving unit, and transmits the boiler monitoring information to a room switch installed in the room and receives boiler control information from the room switch. A first interface unit for receiving; The room switch operates a second interface unit for receiving boiler monitoring information of the boiler controller, an operation unit for indoor occupants to operate or stop the boiler, and to start or stop the boiler according to an operation signal of the operation unit And a room control unit for generating boiler control information for transmission to the boiler controller through the second interface unit; The carbon monoxide detector for the boiler room includes a first carbon monoxide sensor for detecting the carbon monoxide concentration in the boiler room, a first control unit for outputting a power-off control signal when the carbon monoxide concentration value detected by the first carbon monoxide sensor exceeds a reference value, and the first A first opening/closing switch for turning off the power line according to the power-off control signal of the first control unit; The indoor carbon monoxide detector includes a second carbon monoxide sensor that detects the indoor carbon monoxide concentration, a second control unit that outputs a power-off control signal when the carbon monoxide concentration value detected by the second carbon monoxide sensor exceeds a reference value, and the second And a second opening/closing switch for turning off the power line according to a power-off control signal of the control unit; The boiler control unit of the boiler controller determines that the room switch is turned off or the driving power is turned off when the room switch data is not received by the first interface unit due to switch-off of the room switch or blocking of driving power, thereby stopping the boiler driving unit. It is characterized by controlling.

According to the present invention, when the boiler installed in the boiler room is continuously operated, the concentration of carbon monoxide in the boiler room and the room is continuously detected, and when the carbon monoxide allowance is exceeded, the operation of the boiler can be quickly stopped to ensure the safety of indoor residents.

In particular, the present invention has the advantage of being equipped with a carbon monoxide sensor in the boiler room and the room to monitor the concentration of carbon monoxide, and the carbon monoxide introduced into the room as well as the concentration of carbon monoxide generated or leaked during the fuel combustion process and the indoor inflow can be blocked. .

In addition, according to the present invention, there is no effect of minimizing the cost required to configure the boiler control through the detection of carbon monoxide because it is simple to install because there is no need to change or replace the room switch such as a pre-installed room temperature controller and the boiler.

1 is an overall configuration diagram of a boiler control system using a carbon monoxide detector according to the present invention.

2 is a detailed configuration diagram of a boiler control system using a carbon monoxide detector according to the present invention.

Hereinafter, the characteristics of the boiler control system using the carbon monoxide detector according to the present invention may be understood by the embodiments described in detail with reference to the accompanying drawings.

1 and 2, the boiler control system using the carbon monoxide detector according to the present invention is the concentration of carbon monoxide in the boiler room (1) or indoor (2) when the boiler 100 installed in the boiler room (1) is driven If it is monitored in real time and exceeds the reference value, the operation of the boiler 100 may be stopped, and an indoor occupant may be alerted to promptly ventilate.

At this time, the boiler 100 is mainly applicable to gas boilers, but includes various types of boilers such as oil boilers using oil as fuel.

The boiler system is installed in the boiler room 1, the boiler 100 is provided with a boiler controller 120 for controlling the boiler driving unit 110, and installed in the room 2, the boiler monitoring from the boiler controller 120 It consists of a room switch 200 such as an indoor temperature controller (or room cone) that receives information and transmits boiler control information for controlling the boiler 100 to the boiler controller 120.

At this time, the boiler controller 120 that controls the driving of the boiler 100 supplies driving power to the room switch 200 through the power line L.

The boiler controller 120 receives AC 220V household power and converts it into DC power, such as DC 12V, through a transformer and rectification process, and supplies it to the driving power of the room switch 200 through a power line (L). do. Therefore, the power supply line L is installed to extend from the boiler room 1 to the room 2 such as a living room or a master room.

At this time, the room switch 200 performs data communication with the boiler controller 120 in a wired or wireless manner. Accordingly, when the power supply to the room switch 200 is cut off, the boiler controller 120 is blocked from transmitting and receiving data from the room switch 200. Through this, the boiler controller 120 stops driving the room switch 200. It is determined that the boiler driving unit 110 is stopped control.

In this case, the boiler controller 120 monitors the input power of the power line L or determines that the operation of the room switch 200 is stopped in various situations, such as in the case of communication loss, thereby stopping the boiler driving unit 110 Can be controlled.

The boiler control system using the carbon monoxide detector according to the present invention using the boiler control system made of the room switch 200 connected to the boiler 100 and the power line L as it is is provided in the boiler room 1 The boiler 100 is provided with a boiler driving unit 110 that is controlled by the controller 120, and is supplied with driving power from the boiler controller 120 through a power line L, but is installed in the room 2 above. A room switch 200 that receives boiler monitoring information from the boiler controller 120 and transmits boiler control information for controlling the boiler 100 to the boiler controller 120, and is installed in the boiler room 1 When the carbon monoxide concentration value detected in the boiler room 1 exceeds a reference value, the carbon monoxide detector 300 for turning off the power line L and the carbon monoxide concentration value installed in the room 2 and detected in the room are the reference value When exceeding, it consists of an indoor carbon monoxide detector 400 that turns off the power line L.

At this time, the

carbon monoxide detectors

300 and 400 for the boiler room and the interior are made of the same structure, and it is determined by itself whether the carbon monoxide concentration values detected in the boiler room 1 and the room 2 respectively exceed a reference value, and through this, the boiler room (1) Or, if the carbon monoxide concentration value detected in the room (2) exceeds the reference value, the power line (L) on the side of the boiler room (1) is turned off or the power line (L) on the side of the room (1) is turned off. The driving power supplied from the controller 120 to the room switch 200 is cut off.

When the driving power of the room switch 200 is cut off, the boiler controller 120 determines that the room switch 200 is off or malfunctions, and stops and controls the boiler driving unit 110.

Hereinafter, the configuration of each part of the present invention will be described in detail.

First, the boiler 100 provided in the boiler room 1 is heated indoors by using combustion heat generated when combusting fuel such as gas, and is heated indoors by a circulation pump that forcibly circulates the heated and stored water. It adopts the normal structure provided with the boiler driving unit 110 which circulates through the installed heating pipe to heat the room or supplies hot water to the bathroom and kitchen.

The boiler 100 is provided with a boiler controller 120 to drive or stop the boiler driving unit 110.

The boiler controller 120 generates boiler monitoring information including a driving state of the boiler driving unit 110 and controls the boiler driving unit 110, the boiler control unit 122, and a room switch installed in the room 2 ( 200) and a first interface unit 124 for transmitting the boiler monitoring information and receiving boiler control information from the room switch 200.

At this time, the first interface unit 124 is composed of a wired/wireless communication module that performs data communication with the room switch 200. Through this, it is possible to determine whether the room switch 200 is turned on or off. This is, for example, when the switch of the room switch 200 is turned off or the communication is lost due to the driving power cut, the data of the room switch 200 such as boiler control information is transmitted to the first interface unit 124 of the boiler controller 120. If is not received, the boiler control unit 122 determines that the room switch 200 is switched off or shuts off the driving power, thereby stopping the boiler driving unit 110 to stop driving the boiler 100. Using this principle, it is possible to stop the operation of the boiler 100 by determining that the room switch 200 is off or malfunction without changing the design of the boiler 100 and the room switch 200.

In addition, the room switch 200 includes a second interface unit 202 for receiving boiler monitoring information of the boiler controller 120, and an operation unit 204 for indoor occupants to operate or stop the boiler 100. ), a room control unit that generates boiler control information for driving or stopping the boiler 100 according to an operation signal of the operation unit 204 and transmits it to the boiler controller 120 through the second interface unit 202. 206.

At this time, the first interface unit 202 is composed of a wired and wireless communication module that performs data communication with the boiler controller 120, the driving power of the room control unit 206 is a boiler controller 120 through a power line (L) ).

According to this configuration, the room control unit 206 may control the boiler control information including the boiler operation control signal or the boiler stop control signal for starting or stopping the boiler 100 according to the operation signal of the operation unit 204 in the second interface. It is transmitted to the boiler controller 120 through the unit 202.

At this time, the operation unit 204 includes a power switch and is equipped with a knob or a button capable of adjusting the temperature so that the temperature can be adjusted when the boiler is driven, so that proper temperature control is possible. Of course, the temperature control data of the operation unit 204 is also included in the boiler control information, and the temperature control data is transmitted to the boiler controller 120 through the second interface unit 204 to control the boiler driving unit 110 Adjust the heating temperature.

On the other hand, the

carbon monoxide detectors

300 and 400 for the boiler room and for the room are installed in the boiler room 1 and the room 2, respectively, but have the same configuration only in differences in installation positions and operate independently of each other. In this case, the carbon monoxide detector 300 for the boiler room is attached to one side of the boiler 100, and the indoor carbon monoxide detector 400 is preferably installed to one side of the room switch 200.

First, the carbon monoxide detector 300 for the boiler room is installed in the boiler room 1 and is detected by the first carbon monoxide sensor 310 and the first carbon monoxide sensor 310 that detect the concentration of carbon monoxide in the boiler room 1. A first control unit 320 for outputting a power-off control signal when the carbon monoxide concentration value exceeds a reference value, and a first opening/closing for turning off the power line L according to a power-off control signal of the first control unit 320 It includes a switch 330.

In this case, the first opening/closing switch 330 is for turning off the power line L, and various switches such as a relay type switch and a semiconductor switch that can be turned on or off according to a control signal may be used. The first opening/closing switch 330 is preferably configured such that the power line L is turned ON so that the driving power can be returned to be supplied to the room switch 200.

Of course, the carbon monoxide detector 300 for the boiler room is a place that can be operated by having a power source, and such a power source is made of batteries or is composed of an internal battery that charges power supplied through a power line (L). ), it is preferable to enable independent driving.

In addition, the carbon monoxide detector 300 for the boiler room is further provided with a first speaker 340 for audio output of a warning sound, and a first warning lamp 350 for warning display. In this configuration, when the concentration of the carbon monoxide detected by the first carbon monoxide sensor 310 in the first control unit 320 exceeds a reference value, the power cutoff signal is output to control the first opening/closing switch 330 to control the power line L ) Off and simultaneously controlling the first speaker 340 to output a warning sound and to light or flash the first warning lamp 350.

In this case, the first speaker 340 is a concept including a buzzer light, and the first warning light 350 uses a LED having a longer life than a conventional lamp, and is composed of a red LED to control blinking red light. desirable.

Next, the indoor carbon monoxide detector 400 is installed in the room 2 and is detected by the second carbon monoxide sensor 410 and the second carbon monoxide sensor 410 to detect the carbon monoxide concentration in the room 2. When the carbon monoxide concentration value exceeds the reference value, the second control unit 420 outputs a power-off control signal, and a second open/close switch that turns off the power line L according to the power-off control signal of the second control unit 420 430.

At this time, the second opening/closing switch 430 is for turning off the power line L, and various switches such as a relay type switch and a semiconductor switch that can be turned on or off according to a control signal may be used. The second opening/closing switch 430 is preferably configured such that the power line L is turned ON so that the driving power can be returned to be supplied to the room switch 200.

Of course, the indoor carbon monoxide detector 400 is a place that can be operated by having a power supply unit, and the power supply unit is made of batteries or consists of an internal battery that charges power supplied through the power supply line L. ), it is preferable to enable independent driving.

In addition, the indoor carbon monoxide detector 400 is further provided with a second speaker 440 for audio output of a warning sound, and a second warning lamp 450 for warning display. In this configuration, when the concentration of the carbon monoxide detected by the first carbon monoxide sensor 310 in the second control unit 420 exceeds a reference value, the power cutoff signal is output to control the first open/close switch 430 to control the power line L ) Off and simultaneously controlling the second speaker 440 to output a warning sound and to light or flash the second warning light 450.

In this case, the second speaker 440 is a concept including a buzzer light, and the second warning light 450 uses a LED having a longer life than a conventional lamp, and is composed of a red LED to control blinking red light. desirable.

Hereinafter, an example of driving the boiler control system using the carbon monoxide detector according to the present invention will be described with reference to FIGS. 1 and 2.

Residents who usually live in the room 2 may drive the boiler 100 provided in the boiler room 1 when heating is cold or when hot water is desired.

At this time, the indoor occupant can operate the operation unit 204 of the room switch 200 installed in the living room or master room of the indoor 2, for example. Accordingly, the room control unit 206 receives the boiler control information including the boiler operation control signal for the operation of the boiler 100 according to the operation signal of the operation unit 204 through the second interface unit 202, the boiler controller 120 Transfer to.

Accordingly, the boiler controller 120 of the boiler 100 connected to the room switch 200 in a wired or wireless manner receives the boiler control information including the boiler operation control signal through the first interface unit 124, thereby driving the boiler 110 ) Is started.

During such boiler operation, the boiler room and the indoor

carbon monoxide detectors

300 and 400 respectively installed in the boiler room 1 and the room 2 are equipped with the boiler room 1 and the room through the first and second

carbon monoxide sensors

310 and 410. Detect the carbon monoxide concentration in 2).

Accordingly, the first and

second control units

320 and 420 of the

carbon monoxide detectors

300 and 400 for the boiler room and the indoor units receive and compare the carbon monoxide concentration values detected by the first and second

carbon monoxide sensors

310 and 410 to determine whether the reference value is exceeded. In this case, the carbon monoxide reference value can be set to 10 PPM, for example. Therefore, the first and

second control units

320 and 420 determine that the carbon monoxide concentration values measured by the first or second

carbon monoxide sensors

310 and 410 are less than or equal to the reference value of 10 PPM, and determine that they are abnormal when they exceed 10 PPM.

At this time, the first and second

carbon monoxide sensors

320 and 420 can detect the concentration of carbon monoxide in real time, and if necessary, receive the concentration of carbon monoxide in a set cycle (for example, in 5 seconds to 1 minute increments) to exceed the reference value. The computational overload of the first and

second control units

320 and 420 may be reduced by reducing the computational amount of the.

The first and

second control units

320 and 420 of the boiler room and indoor

carbon monoxide detectors

300 and 400 determine that the concentrations of carbon monoxide measured by the first and second

carbon monoxide sensors

310 and 410 exceed the reference value of 10 PPM and are abnormal. When the power-off control signal is output, the first and second open/

close switches

330 and 430 are turned off to block the driving power of the boiler controller 120 from being supplied to the room switch 200 through the power line L.

Accordingly, since the boiler controller 120 does not transmit and receive data such as control information of the room switch 200 through the first interface 124, it is determined that the state is the room switch 200 off or failure, and the boiler drive unit ( 110) to stop fuel combustion.

At the same time, the first and

second control units

320 and 420 of the

carbon monoxide detectors

300 and 400 for the boiler room and the indoor use the first and

second speakers

340 and 440 in order to notify the abnormal state that the carbon monoxide concentration value exceeds the reference value of 10 PPM. It outputs a warning sound by controlling and lights or flashes the first and

second warning lights

350 and 450 so that indoor residents can ventilate or check and cope with the operation of the boiler.

Of course, the

carbon monoxide detectors

300 and 400 for the boiler room and the room are individually operated, and carbon monoxide can be detected or simultaneously detected only in the boiler room 1 or room 2, and the same power line (L) is used. Even if one of the on/off

switches

330 or 430 of the practical carbon monoxide detector 300 and the indoor carbon monoxide detector 400 is operated, the power line L is cut off, so that it is supplied from the boiler controller 120 to the room switch 200. The driving power is cut off.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains can be modified and modified in various ways without departing from the essential characteristics of the present invention. The protection scope of should be interpreted by the claims below, and all technical spirits within the equivalent scope should be interpreted as being included in the scope of the present invention.

Claims

Boiler 100 which is provided in the boiler room 1 and equipped with a boiler driving unit 110 whose driving is controlled by the boiler controller 120 and a driving power supply from the boiler controller 120 through a power line L Room switch 200 which is installed in the room (2), receives boiler monitoring information from the boiler controller (120) and transmits boiler control information for controlling the boiler (100) to the boiler controller (120), When the carbon monoxide concentration value installed in the boiler room 1 and detected in the boiler room 1 exceeds a reference value, the power line L is turned off to drive power supplied from the boiler controller 120 to the room switch 200. When the carbon monoxide detector 300 for the boiler room to be blocked and the concentration of carbon monoxide detected in the room installed in the room 2 exceeds a reference value, the power line L is turned off to turn off the room switch 200 in the boiler controller 120 It consists of an indoor carbon monoxide detector 400 to cut off the driving power supplied to;

The boiler controller 120 generates boiler monitoring information including a driving state of the boiler driving unit 110 and controls the boiler driving unit 110, the boiler control unit 122, and a room switch installed in the room 2 ( 200) includes a first interface unit 124 for transmitting the boiler monitoring information and receiving boiler control information from the room switch 200;

The room switch 200 includes a second interface unit 202 for receiving boiler monitoring information of the boiler controller 120, and an operation unit 204 for indoor occupants to operate or stop the boiler 100. And, a room control unit for generating the boiler control information for driving or stopping the boiler 100 according to the operation signal of the operation unit 204 and transmits it to the boiler controller 120 through the second interface unit 202 ( 206);

The carbon monoxide detector 300 for the boiler room includes a first carbon monoxide sensor 310 that detects the carbon monoxide concentration in the boiler room 1 and cuts off power when the carbon monoxide concentration value detected by the first carbon monoxide sensor 310 exceeds a reference value. It includes a first control unit 320 for outputting a control signal, and a first opening/closing switch 330 for turning off the power line L according to a power-off control signal of the first control unit 320;

The indoor carbon monoxide detector 400 controls the power off when the second carbon monoxide sensor 410 for detecting the carbon monoxide concentration in the room 2 and the carbon monoxide concentration value detected by the second carbon monoxide sensor 410 exceeds a reference value. It includes a second control unit 420 for outputting a signal, and a second opening and closing switch 430 to turn off the power line (L) according to the power off control signal of the second control unit 420;

If the boiler control unit 122 of the boiler controller 120 does not receive the data of the room switch 200 to the first interface unit 124 due to the switch-off of the room switch 200 or the driving power off, the Boiler control system using a carbon monoxide detector, characterized in that the control of the boiler driving unit 110 is stopped by determining that the room switch 200 is turned off or the driving power is off.
The carbon monoxide detector 300 for the boiler room is further provided with a first speaker 340 for outputting a warning sound and a first warning lamp 350 for warning display, the first carbon monoxide sensor 310 in the first control unit 320 ) If the detected carbon monoxide concentration value exceeds the reference value, the first speaker 340 is controlled to output a warning sound and light or flash the first warning lamp 350;

The indoor carbon monoxide detector 400 is further provided with a second speaker 440 for outputting a warning sound and a second warning lamp 450 for warning display, the second carbon monoxide sensor 410 in the second control unit 420 Boiler control system using a carbon monoxide detector characterized in that when the carbon monoxide concentration detected in) exceeds the reference value, the second speaker 440 is controlled to output a warning sound and light or flash the second warning lamp 450. .