KR100285882B1 - System control method and device when gas boiler is completely frozen - Google Patents

Abstract

The present invention relates to a method and apparatus for controlling a system at the time of complete freezing. More particularly, the present invention relates to a system in a gas boiler in which two thermistors are used to determine complete freezing and thus prevent freezing of the heating water to the maximum. It relates to a method and an apparatus for controlling. Conventionally, when the power supply and the operation switch is turned on in the completely frozen state can not detect the complete freezing state, when the system is operated in the fully frozen state, there is a problem that the system is damaged by the restraint of various loads, The present invention provides a method for detecting a low temperature sensing thermistor below freezing point, driving a circulating pump for a predetermined time, and maintaining a constant temperature change in a state where there is almost no temperature difference between the tapping-side thermistor and the return-side thermistor after driving the circulating pump. Detecting the absence of time, switching the trilateral direction to the hot water side and the heating side for a predetermined time after the detection, outputting an answer signal confirming the driving of the trilateral direction to the trilateral side, and If there is no response, it is determined that the system is completely frozen and the system goes to error mode without starting the system. There is action by including the steps of: characterized in that there are.

Description

System control method and device when gas boiler is completely frozen

The present invention relates to a method and apparatus for controlling a system at the time of complete freezing. More particularly, the present invention relates to a system in a gas boiler in which two thermistors are used to determine complete freezing and thus prevent freezing of the heating water to the maximum. It relates to a method and an apparatus for controlling.

In the conventional gas boiler, when the temperature outside the boiler is detected by the bimetal mounted on the water pipe, the temperature outside the boiler is lowered to a predetermined temperature or less, the bimetal is turned on, and the circulation pump is driven.

And because the water is circulated by the pump, but the three sides are always fixed only in the heating direction, the water is not circulated in the hot water system, and the residual water accumulated in the hot water system remains at a standstill, so when the external temperature drops below zero, it freezes. There was a problem.

In order to solve this problem, the external temperature is sensed through a low temperature sensing thermistor, and if the temperature lasts for a predetermined time or less, the circulation pump is operated with the low water level detection float switch turned on, and at the same time, the direction of the three directions is changed. In addition, the present invention proposed a method of preventing the freezing of the hot water system and the heating system by alternating between the heating direction and the hot water direction alternately.

However, the above-described method also cannot detect a complete freeze when the power and operation switch are completely frozen, and thus, when the system is driven in the fully frozen state, damage to the system may be caused by restraint of various loads. There was a problem.

The present invention has been made to solve the problems of the prior art operating as described above, the object of the present invention is to determine the complete freezing using two thermistors mounted on the tapping and returning side and in response to the system It is to protect the system by stopping the operation and processing in error mode.

1 is a view showing the entire system of a gas boiler according to the present invention,

2 is a flowchart illustrating a process of controlling a system during complete freezing according to the present invention;

3 is a circuit diagram showing a microcomputer for controlling an answer signal in order to control the system in the complete freezing of the present invention.

<Explanation of symbols for main parts of drawing>

10: combustor 30: secondary heat exchanger

33: water flow switch 26: circulation pump

TH1: tapping side thermistor TH2: return side thermistor

TH3: Low Temperature Sensing Thermistor

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be more apparent from the following detailed description based on the accompanying drawings in order to achieve the above object.

That is, Figure 1 shows a gas boiler (1) to which the method of the present invention is applied, which is installed in the casing (2) of the gas boiler (1) to combust the gas to heat the hot water for heating or hot water supply ( 10), the water tank 20 for storing the heating circulation water, and the secondary heat exchanger 30 having different paths for circulation of hot water and cold water are configured by mutually coupling.

At this time, a burner group 12 including a plurality of burners is formed in the casing 11 of the combustor 10, and a primary heat exchanger 14 is installed in the upper direction thereof to prevent overheating and the water passing therethrough. The burner group 12 is heated, and a blower 13 for supplying combustion air is installed at the bottom of the combustor casing 11, and the burner group 12 is provided near the burner group 12. The spark coupler 15 for ignition and the frame rod 16 for detecting the ignition of the burner group are installed, and an exhaust unit 18 for discharging combustion air is provided on the upper surface of the combustor casing 11. It is formed through the casing 2 of (1).

In addition, a gas pipe 50 for supplying gas is installed below the burner group 12, wherein two electron valves 51 and 52 for passing the gas at the time of energization and a proportional valve for adjusting the gas supply amount are provided. 53 is provided upstream of the gas pipe 50 with respect to the gas supply path.

The water tank 20 includes an electrode rod 21 for detecting a quantity of water in the water tank, an overflow tube 22 for discharging excess water, and a water separator 23 for recovering heating water rotated on an underfloor. ) Is installed in the heating return pipe 24 and the water supply pipe 25 for supplying water to the primary heat exchanger 14 is provided with a circulation pump 26 for adjusting the circulation of the water downward.

At this time, the water supply pipe 25 passing through the primary heat exchanger 14 has a return side thermistor TH2 for detecting the return side temperature and a tapping side thermistor TH1 for detecting the tapping temperature. The return side thermistor (TH2) is installed on the outer side of the primary heat exchanger (14), and the tapping side thermistor (TH1) is the primary heat exchanger (14) and the bypass pipe. It is provided between 38.

On the other hand, the secondary heat exchanger 30 is a water flow switch for detecting the presence of water flow by injecting cold water from the outside of the hot water discharge pipe 31, the gas boiler to supply hot water to the user by discharging water through the tap water (33), a direct water inlet pipe 34 is provided with a mechanical automatic quantity control device for passing a certain amount according to the direct water temperature to obtain a stable temperature characteristics, the water supply pipe 25 is a three-way (36) It is connected to the heating hot water supply pipe 37 through which the water for heating is passed through.

In addition, between the heating return pipe 24 and the direct inflow pipe 34 is provided with a tap water supply side 35 for replenishing water when the water tank 20 is insufficient, clogging of the heating filter, heating The bypass pipe 38 is installed to prevent the pressure from rising inside the gas boiler 1 when the distributor and the heating distribution pipe are blocked, and to circulate the flow of water by making an internal closed circuit of the gas boiler 1. The low temperature sensing thermistor (TH3) for detecting when the temperature inside the gas boiler (1) falls below the freezing point is installed at an appropriate position inside the gas boiler (1), but slightly in the blower (13) Mounted at intervals.

The control method of the present invention will be described with reference to the accompanying drawings.

In the present invention, a method of controlling the system at the time of complete freezing of the gas boiler is to operate the circulation pump 26 for a predetermined time after detecting that the low temperature sensing thermistor TH3 is below the freezing point, and the tapping side after the circulation pump 26 is driven. When there is little temperature difference between the thermistor TH1 and the return side thermistor TH2, it detects that there is no change in temperature.

After the detection of the temperature change, the three-sided valve 36 is driven to the hot water side and the heating side for a predetermined time, and an answer signal confirming the driving of the three-sided valve 36 is output to the three-sided valve 36. If there is no response from the signal, it is determined that the system is completely frozen and processed in error mode without starting the system.

The tapping side thermistor TH1 is located at the tapping side, and the return side thermistor TH2 is located at the returning side.

In addition, the set temperature of the tapping-side thermistor TH1 and the return-side thermistor TH2 is detected by detecting that there is no temperature change in a state where there is almost no temperature difference between the tapping-side thermistor TH1 and the return-side thermistor TH2. Is set higher than the set temperature of the low temperature sensing thermistor (TH3), which means that the set temperature of the tapping side thermistor (TH1) and the return side thermistor (TH2) is set lower than the set temperature of the low temperature sensing thermistor (TH3) If there is a problem that the function of the thermistor (TH1) (TH2) is performed only in the state that the hot water and heating, which is a function of the gas boiler (1) at all, the thermistor (TH1) (TH2) should be set above the freezing point temperature do.

The answer signal is controlled by a low or high signal from the MICOM in the system.

The system controller of the present invention when the gas boiler is completely frozen, the low temperature detection thermistor (TH3) for detecting below the freezing point, the tapping-side thermistor (TH1) for sensing the temperature of the tapping side, and for detecting the temperature of the return side A return side thermistor TH2 and a microcomputer MICOM for recognizing the detected temperatures of the thermistors TH1, TH2, and TH3 and controlling an anther signal for driving the triangulation 36 are connected to each other. will be.

The operation of the present invention having such a configuration will be described with reference to FIGS. 1 and 2 as follows.

In a preferred embodiment of the present invention, when the external temperature is generally lowered to a low enough temperature to freeze, the freezing is started from the direct inflow pipe 34 supplied from the outside and gradually propagates into the casing 2.

Accordingly, when the inside of the gas boiler 1 has a freezing point, the low temperature detection thermistor TH3 detects that the freezing point is below freezing point (S10), and transmits this signal to the MICOM. 26) is driven for a predetermined time (S20).

After driving of the circulation pump 26, the microcomputer MICOM detects that there is no temperature change in a state where there is almost no temperature difference after the signal of the temperature detected by the tapping-side thermistor TH1 and the return-side thermistor TH2. (S30).

At this time, the temperature of the tapping side thermistor TH1 and the return side thermistor TH2 is set higher than that of the low temperature sensing thermistor TH3.

In addition, the MICOM outputs an Answer Signal to the three-sided 36 in order to check whether the three-sided 36 is transferred to the hot water side for a predetermined time (S40) and then driven properly. )

In addition, the MICOM outputs an answer signal for confirming the driving of the three-sided 36 to the heating side again by switching the three-sided 36 to the heating side for a predetermined time.

If there is no response to the answer signal, the MICOM determines that the system of the gas boiler 1 is completely frozen and is processed in an error mode (S60) without operating the system.

FIG. 3 is a circuit diagram illustrating a connection between a microcomputer MICOM and three thermistors TH1, TH2, and TH3 that control the system of the gas boiler when fully frozen. The low temperature sensing thermistor TH3 is a gas boiler. (1) It is installed inside and detects when the internal temperature of the gas boiler 1 is below the freezing point and delivers it to the MICOM.

At this time, if an abnormality (error) such as short circuit or disconnection of the low temperature sensing thermistor TH3 is detected, the process is performed in an error mode. If the error is not detected, the low temperature state of the low temperature sensing thermistor TH3 is a predetermined time (e.g., 10 seconds), and the signal of the detected temperature of the tapping side thermistor TH1 for sensing the temperature of the tapping side and the return side thermistor TH2 for sensing the temperature of the returning side In addition, the low temperature sensing thermistor TH3 is transmitted to the MICOM together with the detected temperature signal.

In addition, the microcomputer MICOM compares and determines the temperature values detected by the low temperature sensing thermistor TH3, the tapping side thermistor TH1, and the return side thermistor TH2, and transfers the trigonal 36 to an answer signal. If no response is sent, it is determined as complete freeze and processed in error mode.

The present invention can be variously modified and can take various forms and only the specific embodiments thereof are described in the detailed description of the invention.

It is to be understood, however, that the present invention is not limited to the specific forms mentioned in the detailed description of the invention, but rather includes all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. It should be understood to do.

As described above, the present invention is to determine the complete freezing in the frozen state, and to treat the gas boiler system in error mode without forcibly driving the system, thereby preventing components and devices installed inside the gas boiler from fatal damage. It is obvious that the invention is useful.

Claims (5)

In a gas boiler having a control method for stopping the operation of a functional part and notifying freezing when a freezing temperature lower than an antifreezing operation temperature is detected through a low temperature sensing thermistor, the low temperature sensing thermistor (TH1) ) Is less than the freezing point, driving the circulation pump 26 for a predetermined time, and the temperature difference between the tapping side thermistor (TH1) and the return side thermistor (TH2) after driving the circulation pump 26 is almost Detecting that there is no temperature change for a predetermined time in the absence state, transferring the three-sided valve 36 to the hot water side and the heating side for a predetermined time after the detection, and answering the operation of the three-sided valve 36. Outputting an answer signal to the three-sided 36; and if there is no response of the answer signal, it is determined that the system is completely frozen. The step of operating as, the method of controlling the system at the time of complete freezing of the gas boiler comprising a. The method according to claim 1, wherein the tapping-side thermistor (TH1) is located on the tapping side, and the return side thermistor (TH2) is located on the returning side. The method of claim 1, wherein the tapping-side thermistor (TH1) and the return-side thermistor in the step of detecting that there is almost no temperature change in a state where there is almost no temperature difference between the tapping-side thermistor (TH1) and the return-side thermistor (TH2) The set temperature of the TH2 is higher than the set temperature of the low temperature sensing thermistor TH3. The method of claim 1, wherein the answer signal is controlled at a MICOM in the system. In case of detecting the freezing temperature lower than the freezing prevention operation temperature through the freezing temperature recognition thermistor, the operation switch stops the operation of the functional parts regardless of the operating state and provides a freezing device. Low temperature detection thermistor (TH3), tapping-side thermistor (TH1) for sensing the temperature of the tapping side, return-side thermistor (TH2) for sensing the temperature of the return side, the thermistor (TH1) (TH2) (TH3) And a microcomputer (MICOM) for recognizing the detected temperature of the plurality of sensors and controlling the answer signal for driving the three-sided valve (36).