KR970006475Y1 - Circulation pump driving control circuit of a boiler - Google Patents

Abstract

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Description

Circulating pump drive control circuit of boiler

1 is a conventional circulation pump drive control circuit diagram

2 is a circulation pump driving control circuit diagram of the present invention

Explanation of symbols on the main parts of the drawings

1: heating water temperature detection unit 2: driving temperature setting unit

3: circulating pump driving signal output unit 4: circulating pump driving unit

5: burner drive signal output unit 6: burner drive unit

21: second circulation pump drive signal output unit

The present invention is a boiler for heating a room while burning fuel such as petroleum, diesel, gas, etc., when the heating water temperature is higher than the previously raised heating temperature by forcibly driving the circulating pump to increase the heating efficiency It relates to a circulation pump drive control circuit of the.

In the conventional boiler, the burner operates to burn fuel when the room temperature is lower than the set temperature, and the circulating pump is driven when the temperature of the heating water heated by the combustion of the fuel is higher than the set temperature. It has a temperature deviation of 10 ° C.

An example of such a conventional circulation pump drive control circuit will be described with reference to the drawings of FIG.

1 is a conventional circulation pump drive control circuit diagram, as shown therein, a heating water temperature detection unit _{1 comprising} resistors R ₁ and R ₂ and a temperature sensor TH for detecting a temperature of heating water, and a hot water supply. Transistors (Q ₁ , Q ₂ ), resistors (R _3- R ₆ ), and variable outputting the circulating pump and burner operating temperature preset at the time of output, and the circulating pump and burner operating temperature set according to the user's operation during heating. A comparator for determining whether the driving temperature setting unit 2 made of the resistor VR and the heating water temperature of the heating water temperature detecting unit 1 are equal to or higher than the circulating pump driving temperature output from the driving temperature setting unit 2 ( CP ₁ ) and circulating pump drive signal output section 3 composed of resistors R ₇ and R ₈ and the output signal of circulating pump drive signal output section 3 when the heating water temperature is equal to or higher than the circulating pump drive temperature. Diodes (D ₁ , D ₂ ), resistors (R ₉ ), transistors (Q) which drive the circulation pump ₃ ) and when the heating water temperature of the circulation pump driving unit 4 including the circulation pump driving relay RY and the heating water temperature detecting unit 1 is lower than the burner driving temperature output from the driving temperature setting unit 2. A burner drive signal output section 5 comprising comparators CP ₂ and CP ₃ , resistors R ₁₀ -R ₁₆ and transistors Q _{4 for} outputting burner drive signals to the burner drive signal output section 5; Burner driver 6 for driving the burner according to the output signal of the "

In the above, when the circulation pump driving relay RY is driven, the circulation pump is driven, and reference numeral B + in the drawing description of FIG. 1 is a power source.

In the conventional boiler circulation pump driving control circuit configured as described above, the temperature sensor TH of the heating water temperature detection unit 1 detects the temperature of the heating water while the power B + is applied and is inversely proportional to the heating water temperature voltage. Outputs

That is, the temperature sensor TH has a negative resistance characteristic. When the temperature of the heating water is low, when the temperature of the heating water is high, the temperature of the heating water output voltage is high, and when the temperature of the heating water is high. Since the resistance value of the temperature sensor TH is low, the output water temperature voltage is low.

In this state, when the hot water is set and the heating / hot water driving signal is input at a high potential, the transistor Q ₁ of the driving temperature setting unit 2 is turned on, and the power source B + is a resistor R ₃ -R ₅ . The circulating pump driving voltage and burner driving temperature voltage are respectively input to the circulating pump driving signal output unit 3 and the burner driving signal output unit 5.

When the heating / hot water supply driving signal is input at a low potential by setting heating, the transistor Q ₂ of the driving temperature setting unit ₂ is turned on, and the power source B ⁺ is a resistor (R ₃ , R ₄ ), and variable. The resistance VR is divided by the non-resistance R ₆ to input the circulating pump driving temperature voltage and the burner driving temperature voltage to the circulation pump driving arc output unit 3 and the burner driving signal output unit 5, respectively. The circulation pump drive temperature is set to about 10 ° C lower than the burner drive temperature.

In this state, when the temperature of the heating water is low and the heating water temperature voltage output from the heating water temperature detection unit 1 is higher than the burner driving temperature voltage output from the driving temperature setting unit 2, the burner driving signal output unit 5 The comparator CP ₂ outputs a low potential, the comparator CP ₃ outputs a low potential, and the transistor Q ₄ is turned on, so that the power supply B ⁺ is supplied to the burner driver 6 through the transistor Q ₄ . The burner drive unit 6 is inputted to drive the burner and heat the heating water.

As such, the temperature of the heating water gradually increases while the burner is driven, and thus the heating water temperature voltage output from the heating water temperature detection unit 1 gradually decreases, and the circulation pump driving temperature output from the driving temperature setting unit 2. When the voltage is lower than the voltage, the comparator CP ₁ of the circulating pump driving signal output unit 3 outputs a high potential, and the transistor Q ₃ of the circulating pump driving unit 4 is turned on by the output high potential. RY) is driven so that the circulation pump circulates the driving and heating water.

As described above, when the temperature of the heating water continues to rise while the burner and the circulation pump are driven and the heating water temperature voltage output from the heating water temperature detection unit 1 is lower than the burner driving temperature voltage, the burner driving signal is output in the opposite manner to the above. The comparator CP ₂ of the negative portion 5 outputs a high potential, the comparator CP ₃ outputs a high potential, and the transistor Q ₄ is turned off, so that a low potential in the burner driver 6 is burner driver 6. Will stop the burner.

As such, when the burner is stopped and the temperature of the heating water continues to decrease while only the circulation pump is driven, the heating water temperature voltage output from the heating water temperature detection unit 1 becomes lower than the circulation pump driving temperature voltage. In contrast, since the comparator CP ₁ of the circulation pump drive signal output unit 3 outputs a low potential and the transistor Q ₃ is turned off, the relay RY is stopped and the circulation pump is stopped.

Here, when the hot water is set, the circulating pump drive signal is output when the heating water temperature voltage output from the heating water temperature detection unit 1 is lower than the circulating pump driving temperature voltage output from the driving temperature setting unit 2 as in the heating setting. The unit 3 outputs a high potential, and the relay RY of the circulation pump driving unit 4 is driven to output a driving signal of the circulation pump, but to the rear circulation pump control circuit (not shown). This prevents the circulation pump from running during hot water supply.

However, the conventional drive control circuit as described above stops the driving of the circulating pump even though the temperature of the heating water is sufficient to heat the room when the burner and the circulating pump drive temperature are set high to increase the room temperature. There was a problem that the heating water is not circulated.

That is, assuming that the burner and circulation pump driving temperatures are set to 70 ° C. and 60 ° C., respectively, the circulation pump is operated only when the temperature of the heating water is 60 ° C. or higher, and the temperature is high enough to heat the room. At 59 ° C, the circulation pump is not driven.

Therefore, the driving frequency of the boiler is increased, and as a result, the service life of the boiler is shortened, and as a result, many fuels are consumed without necessity, and heating efficiency is lowered.

The present invention has been made to solve the above-mentioned conventional problems, the temperature of the heating water is sufficient to heat the room, for example, when the temperature of the heating water is about 40 ℃ or more the circulating pump drive signal The purpose of the present invention is to provide a circulating pump driving control circuit of a boiler having a simple configuration for controlling the driving of the circulating pump by outputting a second circulation pump driving signal output unit, which will be described in detail with reference to the accompanying drawings. The same code | symbol was attached | subjected to the same site | part as the past.

2 is a circulating pump drive control circuit diagram of the present invention, as shown in the present invention is a conventional circulating pump drive control circuit of the boiler, the temperature of the heating water output from the heating water temperature detection unit 1 is fixed in advance It is determined that the temperature can be heated and the resistance (R _21- R ₂₄ ), a comparator (CP ₂₁ ) and a diode (D ₂₁ ) to output a circulating pump drive signal when the temperature is higher than the temperature to heat the room. It consisted of two circulation pump drive signal output parts 21.

The circulation pump driving control circuit of the present invention configured as described above includes a circulation pump and a burner in which the heating water temperature output from the heating water temperature detection unit 1 is output from the driving temperature setting unit 2 while the power source B ⁺ is applied. When the temperature is higher than the driving temperature, the circulation pump driving unit 4 and the burner driving unit 6 operate the circulation pump and the burner according to the output signals of the circulation pump driving signal output unit 3 and the burner driving signal output unit 5 as in the prior art. When the heating water temperature is lower than the circulation pump and burner driving temperature, the circulation pump driving unit 4 and the burner according to the output signals of the circulation pump driving signal output unit 3 and the burner driving signal output unit 5 are respectively driven. The driving unit 6 stops driving the circulation pump and the burner.

Here, when setting the hot water supply, when the heating water temperature voltage output from the heating water temperature detection unit 1 is lower than the circulation pump driving temperature voltage output from the driving temperature setting unit 2 as in the prior art, the circulation pump driving signal output unit 3 ) Outputs a high potential, and the relay RY of the circulation pump driving unit 4 is driven to output a drive signal of the circulation pump, but the circulation pump is not driven at the time of hot water supply by the circulation pump control circuit of the rear stage.

In this operation, the present invention divides the power source B ⁺ by the resistors R ₂₁ and R ₂₂ of the second circulation pump driving signal output unit ₂₁ so that the non-inverting input terminal (+) of the comparator CP _{21 is} provided. ), And the heating water temperature voltage output from the heating water temperature detection unit 1 is applied to the inverting input terminal (-) of the comparator CP ₂₁ through the resistor R ₂₃ .

Here, when the temperature of the heating water is set to the resistances R ₂₁ and R ₂₂ , for example, 40 ° C. or less, the heating water temperature voltage output from the heating water temperature detection unit 1 resists the power source B ⁺ . Since the comparator CP ₂₁ outputs a low potential because the voltage is higher than the voltage divided by R ₂₁ and R ₂₂ , the transistor RY is not driven because the transistor Q ₃ of the circulation pump driving unit 4 is turned off. The circulation pump does not run.

When the temperature of the heating water is higher than the temperature set by the resistors R ₂₁ and R ₂₂ , the heating water temperature voltage output from the heating water temperature detection unit 1 divides the power supply B + into the resistors R ₂₁ and R ₂₂ . Since the comparator CP ₂₁ outputs a high potential circulating pump driving signal because the voltage is lower than one voltage, the relay RY is driven because the transistor Q ₃ of the circulating pump driving unit 4 is temperatured. Driven to circulate the heating water.

As described in detail above, the present invention determines whether the temperature of the heating water is sufficient to heat the room, and when the temperature is sufficient to heat the room, drives the circulation pump to circulate the heating water and heat the room. The driving frequency of the boiler is reduced, thereby extending the service life of the boiler, reducing fuel consumption, and improving heating efficiency.

Claims (1)

A heating water temperature detection unit 1 for detecting a heating water temperature, and a driving temperature setting unit for outputting a circulating pump and burner driving temperature which are fixed at the time of hot water and outputting a circulating pump and burner driving temperature according to a user's operation during heating ( 2), a circulating pump driving signal output unit 3 for outputting a circulating pump driving signal when the heating water temperature is equal to or higher than the circulating pump driving temperature, and a circulating pump driving unit driving the circulating pump according to the circulating pump driving signal (4), a burner drive signal output unit 5 for outputting a burner drive signal when the heating water temperature is equal to or lower than the burner drive temperature, a burner driver 6 for driving a burner in accordance with the burner drive signal; It is determined whether the temperature of the heating water is a temperature capable of heating a preset room, and when the temperature of the heating water is higher than a temperature capable of heating the room, the circulation pump is driven to the circulation pump driving unit 4. Second circulation pump driving signal output unit 21 to a circulation pump drive control of the boiler, characterized in the configured circuit for outputting the same signal.