KR100614583B1 - Heating pump for controlling operation in according to temperature and water level and method thereof - Google Patents

Abstract

The present invention relates to a boiler and a method for detecting the heating water temperature and the heating water level in the water tank and to operate more accurately and safely. The boiler according to an aspect of the present invention detects the water level of the heating water in the water tank. A water level detection sensor, a temperature sensor detecting a heating water temperature, a heating water temperature value input from the temperature sensor and a water level detection signal input from the water level detection sensor to determine whether to be frozen, and an operation control signal corresponding thereto. It includes a freezing state processing unit for outputting a; and a solenoid valve driving unit for driving the electronic valve in accordance with the operation control signal input from the freezing state processing unit, by first detecting the heating water temperature and the heating water level in the water tank more accurate and safe Operation control is possible.

Boiler, Operation Control, Freezing, Circulating Pump

Description

Heating pump for controlling operation in accordance with temperature and water level and method

1 is a block diagram showing the overall configuration of a conventional boiler.

Figure 2 is a block diagram schematically showing the configuration of a boiler according to an embodiment of the present invention.

3A and 3B are flowcharts illustrating operations of a boiler according to an embodiment of the present invention.

The present invention relates to a boiler, and more particularly, to a boiler and a method for controlling a boiler operation more accurately and safely by sensing a heating water temperature and a heating water level in a water tank.

Typically, a boiler is a device used to supply hot water and heating water to a home or an office. 1 is a block diagram showing the overall configuration of a conventional boiler. The illustrated boiler illustrates a gas boiler, and the gas boiler 1 includes a combustor 10 for burning gas for hot water supply, a water tank 20 for storing heating water, and a circulation of hot water and cold water. Secondary heat exchanger 30 having different paths is included.

In the casing 11 of the combustor 10, a burner group 12 composed of a plurality of burners, a blower fan 13 for supplying combustion air, a primary heat exchanger 14, and the burner group 12 The ignition plug 15 for igniting), the frame rod 16 for detecting the ignition of the burner group, and the exhaust portion 18 for discharging the exhaust are formed on the upper surface of the combustor casing 11. In addition, a gas pipe 50 for supplying gas is provided below the burner group 12, and the gas pipe 50 has two electron valves 51 and 52 for passing gas at the time of energization, and to adjust the gas supply amount. Proportional valve 53 is installed.

The water tank 20 is provided in the water level detection sensor 21 for detecting the high and low water level of the heating water in the water tank, the overflow pipe 22 for discharging excess water, and the heating return pipe 24. A circulation pump 26 is installed in the water separator 23 and the water supply pipe 25 for supplying water to the primary heat exchanger 14 to circulate the heating water.

In addition, between the heating return pipe 24 and the direct water inlet pipe 34, the water supply valve 35 for replenishing the water when the water tank 20 is insufficient, clogging of the heating filter, blockage of the heating distributor. And a bypass pipe 38 for preventing the pressure from rising inside the gas boiler when the heating distribution pipe is blocked, and for circulating the flow of water by making an internal closed circuit of the gas boiler.

In addition, three sides 36 are installed in the water supply pipe 25 and the heating water supply pipe 37. The heating water heated by the first heat exchanger 14 by the three-sided valve 36 is circulated to the heating water supply pipe 37 through the water supply pipe 25, and the second heat exchanger through the water supply pipe 25. Through the water 30, the water separator 23 and the circulation pump 26 may be circulated back to the first heat exchanger 14 through the water supply pipe 25.

In addition, the first heat exchanger 14 detects the temperature of the heating water discharged as the heating water having a specific temperature by the first heat exchanger 14 through the water supply pipe 25. And, a temperature sensor (TH2) for detecting the overheating temperature of the heating water flowing into the first heat exchanger 14 through the water supply pipe 25 is installed.

On the other hand, the boiler control unit (not shown) when the user drives the hot water valve (not shown) to use hot water in the heating mode, the external cold water supplied from the direct inlet pipe 34 is made of the water flow switch 33 and 2 becomes hot water while passing through the heat exchanger 30 is discharged to the outside through the hot water supply pipe (37). In addition, the boiler controller (not shown) is recognized as a hot water mode when a hot water button pressing signal is input by the user, the heating water heated by the first heat exchanger 14 through the water supply pipe 25 to the second heat exchanger ( To control the three-sided 36 to flow in 30). Accordingly, when the user drives the hot water valve (not shown), the external cold water supplied from the direct water inflow pipe 34 becomes hot water while passing through the water flow switch 33 and the second heat exchanger 30 to supply the hot water supply pipe ( 37) continuously discharged to the outside.

The conventional boiler control unit is implemented to stop the operation of the boiler by determining that the heating water circulated in the boiler is completely frozen when the temperature input from the temperature sensor is below a certain temperature. This is to prevent the parts from being damaged or exhausting gas when the boiler is operated while the heating water is frozen.

By the way, the conventional boiler, for example, when the ambient temperature is very low during the initial installation in winter, the temperature sensor may detect a temperature lower than the temperature set as a reference of the frozen state. In other words, when the boiler builder initially installs the boiler and before the boiler is supplied with water, if the ambient temperature where the boiler is installed is too low, the heating water temperature normally input from the temperature sensor mounted on the first heat exchanger 14 is increased. It may be a temperature below the frozen state.

In this case, in general, the temperature of the water supplied to the boiler in winter is above the freezing point (about 4 ℃), so if water is supplied to the boiler's heating pipe, the boiler temperature sensor's detection temperature is also higher than the threshold temperature at which it can be frozen. However, the boiler control unit judges that the heating water is completely frozen in the state that water is not replenished in the heating pipe of the boiler, and the boiler does not operate even if there is no breakdown or problem in the boiler. There was a problem of thinking that there is a product and requesting a return of the product or an AS.

In order to eliminate the above-mentioned phenomenon when installing a boiler, a boiler installer contacts a heat source such as a dryer near the temperature sensor to heat the temperature sensor to a temperature at which the boiler can operate and to operate the boiler in a water replenishing manner. Even though it is, there is also a problem that comes with the inconvenience in construction.

Accordingly, the present invention has been proposed to solve the above problems, the present invention is to provide a boiler and a method capable of controlling the boiler operation more accurately and safely by detecting the heating water temperature and the heating water level in the water tank.

Boiler according to an aspect of the present invention for achieving the above object, the water level detection sensor for detecting the water level of the heating water in the water tank, the temperature sensor for detecting the heating water temperature, and the heating input from the temperature sensor A freeze state processor for determining whether to freeze according to a combination of a water temperature value and a water level detection signal input from the water level detection sensor and outputting an operation control signal corresponding thereto; It characterized in that it comprises a solenoid valve drive unit for driving the electromagnetic valve.

According to this aspect, the boiler first detects the heating water temperature and the heating water level in the water tank, thereby enabling more accurate and safe operation control.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce the present invention.

Figure 2 is a block diagram schematically showing the configuration of a boiler according to an embodiment of the present invention. As shown, the boiler 100 according to the present embodiment is the user interface 110, the temperature sensor 120, the water level detection sensor 130, the display unit 140, the solenoid valve drive unit 150 And a combustor driver 160 and a controller 170.

The user interface 110 is a conventional means for receiving various user operation commands such as boiler temperature and operation time setting, and may be implemented as a key button and a volume.

The temperature sensor 120 is a means for detecting a heating water temperature, and may be implemented as a thermistor. The water level detection sensor 130 is a means for detecting the water level of the heating water in the water tank. The level sensor 130 may also use a well-known before this application.

The display unit 140 is a means for externally displaying a boiler set temperature and an operating state according to a user operation input, and may be implemented as an LED display device or a liquid crystal display device.

The solenoid valve driving unit 150 drives various solenoid valves installed in the boiler, for example, a three-way valve, a receiver valve, and the like according to an operation control signal input from the controller 170.

The combustor drive unit 160 is a burner group (reference numeral 12 of FIG. 1) installed in the boiler according to the operation control signal input from the control unit 170, and a blowing fan for supplying combustion air (reference numeral 13 of FIG. 1). And a primary heat exchanger (reference numeral 14 in FIG. 1), an ignition plug (reference numeral 15 in FIG. 1), etc. for igniting the burner group 12.

The controller 170 controls the entire system, and may be implemented as a microprocessor including a ROM, a RAM, and a peripheral device. According to a characteristic aspect of the present invention, the control unit 170 determines whether to freeze according to the heating water temperature value input from the temperature sensor 120 and the water level detection signal input from the water level detection sensor to determine the operation control signal corresponding thereto. It includes a frozen state processing unit 171 to output.

According to this aspect, the boiler of the present invention can detect the heating water temperature and the heating water level in the water tank first during the operation after the initial installation to enable more accurate and safe operation control.

In one embodiment, if the heating water temperature value is lower than the threshold temperature and the level of the heating water in the water tank is not detected, the frozen state processing unit 171 stops the operation of the power receiver valve 35 so that the water tank is replenished. To control. That is, the frozen state processing unit 171 recognizes the complete frozen state only when the heating water temperature is lower than the threshold and the heating water level in the water tank is detected.

In another embodiment, the freezing state processing unit 171 has a heating water temperature lower than the threshold temperature and the level of the heating water in the water tank is not detected, or the heating water temperature is higher than the threshold temperature and the level of the heating water in the water tank is higher than the threshold temperature. If not detected, the solenoid valve driving unit 150 outputs the receiving valve driving control signal.

According to this embodiment, if the heating water is not present in the water tank even if the temperature of the heating water is below the threshold temperature set as a reference of the freezing state, the water tank is replenished so that the water tank is operated for a predetermined time. Control will cause the heating water to be forced into the boiler.

In another embodiment, the frozen state processing unit 171 controls the boiler to operate normally according to the set boiler temperature when the heating water temperature value is higher than the threshold temperature and the level of the heating water in the water tank is detected.

3A and 3B are flowcharts illustrating operations of a boiler according to an embodiment of the present invention.

First, referring to FIG. 3A, the boiler controller 170 receives a heating water temperature value T _P input from a temperature sensor and a water level detection signal of heating water in a water tank from a water level detection sensor (S801). Thereafter, the controller 170 compares the input heating water temperature value T _P with a threshold temperature T _C set based on the freezing state (S802). In one embodiment, the threshold temperature T _C may be −6 ° C.

As a result of comparison, the controller 170 checks whether the level of the heating water in the water tank is detected when the heating water temperature value T _P is lower than the threshold temperature T _C (S803). As a result of the check, if the level of the heating water in the water tank is not detected, the controller 170 controls the receiver side 35 to be driven for a predetermined time (S804). If it is determined that there is no level detection for the programmed time (S805), the control unit 170 proceeds to step S806 and performs the post-processing operation according to the complete freezing state.

On the other hand, if it is determined in step S802 that the heating water temperature value T _P is higher than the threshold temperature T _C , the controller 170 proceeds to FIG. 3B and checks whether the water level of the heating water in the water tank is detected (S807). As a result, when the water level of the heating water in the water tank is not detected, the controller 170 controls the power receiver valve 35 to be driven (S808), while in step S807, when the water level of the heating water in the water tank is detected, the controller ( 170 is controlled to operate the boiler in accordance with the set boiler temperature (S809).

As described in detail above, the boiler according to the present invention has a useful effect of enabling the more precise and safe operation control by first detecting the heating water temperature and the heating water level in the water tank.

Although the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the invention from this description. Therefore, it should be interpreted by the claims described to include many such variations.

Claims (3)

In the boiler capable of safe operation control by detecting the heating water temperature value and the heating water level in the water tank, the boiler is: A water level detection sensor detecting a water level of the heating water in the water tank; A temperature sensor detecting a heating water temperature value; A freezing state processor for determining whether to freeze according to a combination of a heating water temperature value input from the temperature sensor and a water level detection signal input from the water level detection sensor and outputting an operation control signal corresponding thereto; A solenoid valve driver for driving the receiving valve in accordance with an operation control signal input from the freezing state processor; Boiler comprising a. The method of claim 1, wherein the frozen state processing unit: If the heating water temperature is higher than the threshold temperature and the heating water level in the water tank is detected, operate the boiler normally according to the set boiler temperature. If the heating water temperature value is lower than the threshold temperature and the heating water level in the water tank is not detected, a hydroelectric drive control signal for water replenishment is output.If the water level is not detected for a certain time, it is treated as a freezing error state. If the heating water detection temperature is higher than the threshold temperature and the water level of the heating water in the water tank is not detected, the boiler characterized in that to output the electromagnetic control drive control signal to the solenoid valve drive unit. Water level detection sensor for detecting the level of heating water in the water tank, temperature sensor for detecting the temperature of the heating water, a control unit for controlling the entire system, and an solenoid valve for driving the receiving valve in accordance with the operation control signal input from the control unit In an operation control method executable in a control unit of a boiler including a driving unit, the method includes: Receiving a heating water temperature value input from the temperature sensor and a water level detection signal of the heating water in the water tank from the water level detection sensor; Comparing the input heating water temperature value with a threshold; As a result of the comparison, when the heating water temperature value is higher than the threshold temperature and the level of the heating water in the water tank is detected, operating the boiler normally according to the set boiler temperature; As a result of the comparison, if the heating water temperature value is lower than the threshold value and the level of the heating water in the water tank is not detected, outputting a hydro-electric drive control signal for water replenishment, but if the water level is not detected for a predetermined time, treating the freezing error state; ; And outputting a manual valve driving control signal to the solenoid valve driving unit when the heating water temperature value is lower than a threshold temperature and the level of the heating water in the water tank is not detected.

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