KR950012161B1 - Ignition and extinguish time control method - Google Patents

Abstract

When the differential temp. between water supply temp.(ΔT) and setting temp.(T0). is small under the condition hot water is supplied near an ignition flow rate(Q2) and if the water supply temp.(T0) detected by a noise sensor(11) is slightly changed, an extinction flow rate(Q1) will be markedly fluctuated so that a gas burner(15) may be forcibly put out. However, under the condition as described above, a specified computation must be made to increase a differential(Q0), thereby increasing the differential between the ignition flow rate(Q2) and extinction flow rate(Q1). This increased differential serves to prevent the generation of a troublesome chattering phenomenon that the gas burner(15) repeats a series of ignition and extinction at a short interval. When the differential temp.(ΔT) approaches or when the water supply temp. and the setting temp. approach each other relatively, the differential(Q0) will be increased.

Description

Adjustment method of ignition and fire extinguishing in hot water heater

1 is a flowchart illustrating the control of the hot water heater according to the present invention.

2 is an explanatory diagram of the configuration of the hot water heater.

3 is a diagram illustrating the relationship between the extinguishing flow rate Q ₁ and the ignition flow rate Q ₂ .

* Explanation of symbols for main parts of the drawings

1: water circuit 2: solar water heater

The present invention relates to a hot water heater of a type in which a gas burner is forcibly fired when the hot water tap is opened to a certain degree of opening and forced to extinguish when it is narrowed down to a certain degree of opening, in particular, a method for adjusting the ignition and extinguishing time of the gas burner.

As a hot water heater of the type which forcibly extinguishes a gas burner when the hot water tap is narrowed to a certain opening degree and the amount of hot water supply decreases, for example, there is one shown in FIG.

This uses hot water pre-heated in the solar water heater (2), and in the water flow circuit (1), the solar water heater (2), the flow meter (10), the temperature sensor (11), the heat exchanger (12), and cold from the upstream side thereof. Hot water mixing type mixing valves 14 are arranged downstream in this order, and a cold water circuit 20 is connected to the mixing valves 14. In addition, a proportional valve 16 and a main valve 17 upstream thereof are inserted into the gas circuit 19 to the gas burner 15 that heats the heat exchanger 12. 10) is electrically connected to the control device 3. Then, when the mixing valve 14 is opened, the flowmeter 10 detects the flow of water flowing into the water passage circuit 1, and the hot water at the set temperature T (for example, 80 ° C.) is exchanged with the heat exchanger 12. The amount of combustion of the gas burner 15 is controlled while the feed opening of the proportional valve 16 is controlled to be boiled at the b). Then, the supply cold water of the cold water circuit 20 is mixed with the hot water boiled in the heat exchanger 12, and the hot water of the desired temperature is taken out from the mixing valve 14.

In this kind of hot water heater, even if the opening degree of the mixing valve 14 is small, even if the gas burner 15 is burned to the maximum capacity, hot water above the set temperature T (for example, 80 ° C.) is heated and generated in the heat exchanger 12. In the case (for example, when hot water is already generated in the solar water heater 2, etc.), the gas valve 15 is kept in a completely extinguished state by keeping the main valve 17 closed from the viewpoint of stability and the like. It will be described in more detail below.

The flow rate Q measured by the flowmeter 10 and the timing of ignition and extinguishing have the same relationship as in FIG. 3, and the flow rate Q measured by the flowmeter 10 and the timing of ignition and extinguishment have the same relationship as in FIG. 3. If the flow rate Q measured by the flowmeter 10 is less than the ignition flow rate Q ₂ , the gas burner 15 is kept in a fire extinguishing state, and the flow rate Q is increased to the ignition flow rate Q ₂ . At this point, the gas burner 15 is brought into an ignition state and control of the combustion amount is started appropriately. Further, when the mixing valve 14 in the open state is gradually narrowed so that the flow rate Q measured by the flow meter 10 decreases to the extinguishing flow rate Q ₁ , the heat exchanger may be burned even if the gas burner 15 is burned to the maximum capacity. In 12), the hot water over the set temperature may be generated by heating, so the main valve 17 is closed to keep the gas burner 15 in a fired state. As shown in FIG. 3, the flow rate difference (hereinafter referred to as the difference Q ₀ ) between the ignition flow rate Q ₂ and the extinguishing flow rate Q ₁ is tapped and operated near the flow rate. In this case, it is for preventing the so-called chattering phenomenon in which the gas burner 15 repeats ignition and extinguishing little by little with a natural flow rate number (e.g., caused by an instantaneous hydraulic pressure fluctuation on the upstream side). The difference Q ₀ is usually set to about 0.7 liters / minute.

However, in the conventional hot water heater, when the water supply temperature T ₀ from the solar water heater 2 or the like approaches the set temperature T, the gas burner 15 little by little even though the difference Q ₀ is provided. There existed a problem that the said chattering phenomenon which repeats ignition and extinguishing generate | occur | produces.

This problem will be described in more detail.

The ignition flow rate Q ₂ and the extinguishing flow rate Q ₁ are set to be changed by the water supply temperature T ₀ detected by the temperature sensor 11, and the normal extinguishing flow rate Q ₁ is determined by the following equation. do.

Extinguishing flow rate (Q ₁ ) ≤ minimum calorific value (R) (Kcal / min) / [set temperature (T) -water supply temperature (T ₀ )]. (A)

However, when the water supply temperature T ₀ approaches the set temperature T, the temperature difference ΔT (set temperature T-water supply temperature T ₀ ), that is, the denominator of formula (A) is not limited. Approaching "0", even if the water supply temperature (T ₀ ) changes slightly, the extinguishing flow rate (Q ₁ ) changes significantly. Therefore, when converted to a digital signal in the microcomputer of the water temperature (T ₀₎ is the set temperature water temperature (T ₀₎ the control device (3) for the temperature sensor 11 detects the state in which access to the (T) The conversion error of squeezes into the denominator of equation (A) and greatly changes the extinguishing flow rate (Q ₁ ). The influence of the conversion error on the digital signal on the extinguishing flow rate Q ₁ becomes larger as the water supply temperature T ₀ approaches the set temperature T, and the flow rate error of the extinguishing flow rate Q ₁ ( DELTA Q ₁ may be greater than or _{equal to the difference} Q ₀ described. When the flow rate error ΔQ ₁ increases or decreases by a width greater than or equal to the difference Q ₀ during the hot water operation (during combustion of the gas burner 15), the so-called gas burner 15 repeats ignition and extinguishing little by little. Chattering occurs.

Moreover, although from the above prior art are subject to digestion flow (Q ₁₎ the difference (Q ₀₎ of the fixed thereto by calculation by the formula (A) is added to determine the ignition flow rate (Q _2), the ignition flow rate (Q ₂ ) May be set to a value obtained by adding a predetermined value to the value calculated by the above formula, and subtracting the fixed difference Q ₀ from this may be employed as the extinguishing flow rate Q ₁ .

The present invention has been made in view of the above-mentioned point, and the " flow meter 10 for measuring the flow rate of the water flowing through the heat exchanger 12 and the temperature of the supply water to the heat exchanger 12 is measured. An ignition flow rate Q ₂ or an extinguishing flow rate Q ₁ having a temperature sensor 11 and inversely proportional to the temperature difference ΔT between the set temperature T and the water supply temperature T ₀ detected by the temperature sensor 11. ), And the difference Q _{0 which} is the flow rate difference between these ignition / digestion flow rates Q ₂ and Q ₁ is provided, and the flow rate Q measured by the flow meter 10 is the ignition flow rate. When the gas burner 15 for the heat exchanger 12 is ignited at the time of (Q ₂ ) or more, and the flow rate Q is equal to or less than the extinguishing flow rate Q ₁ , the gas burner 15 is used. in the adjusting method "in which the ignition timing to maintain a digestion, digestion conditions, to approach the water temperature (T ₀₎ is set, the temperature (T) of the temperature sensor 11 detects also the And to ensure that the burner 15 is frequently inhibit the chattering repeating lighting, digested with the task.

The technical means of the present invention for solving the above problems is to "set the difference (Q ₀ ) to increase or decrease, while the difference (Q ₀ ) is set to increase and decrease the opposite direction of the temperature difference (△ T)" will be.

The technical means act as follows.

According to the above technical means, since the increase / decrease direction of the temperature difference ΔT between the set temperature T and the water supply temperature T ₀ and the increase / decrease direction of the difference Q ₀ are set in a reverse relationship, the temperature difference ΔT When the water supply becomes small (T ₀ ) and the set temperature (T) is relatively close, the difference (Q ₀ ) becomes large.

That is, based on the detection error when the water supply temperature (T ₀ ) and the set temperature (T) approaches and detect the water supply temperature, and the conversion error of the microcomputer, the error of the extinguishing flow rate (Q ₁ ) or the ignition flow rate (Q ₂ ) is reduced. If the there is significant concern, it will be a difference between the flow rate difference (Q ₀₎ of both large.

The present invention has the following unique effects.

Due to the detection error when the water supply temperature (T ₀ ) and the set temperature (T) approaches and detect the water supply temperature, and the conversion error of the microcomputer, the error of the extinguishing flow rate (Q ₁ ) or the ignition flow rate (Q ₂ ) may become large. When there is a concern, since the difference Q ₀ , which is the flow rate difference between them, becomes large, the ignition flow rate Q ₂ and the extinguishing flow rate Q ₁ can be clearly distinguished, and the gas burner 15 burns and extinguishes little by little. It is possible to prevent the drawback of repeating.

Next, the embodiment of the present invention described above will be described.

The water circuit of the water heater according to the present invention has the same configuration as that of FIG.

In the microcomputer stored in the control device 3 for controlling the main valve 17 and the proportional valve 16 for the gas burner 15, a control program as shown in FIG. 1 is stored. The operation of the hot water heater, which has been performed, will be described with reference to FIG.

(a). First, it is determined whether the flow meter 10 is in the flow measurement state, and when the flow meter is in the flow measurement state, that is, when the layer flow rate exceeds "0", it is determined that the mixing valve 14 is opened and the tapping operation is performed. Q ₀ ) (see steps 70 and 71).

The difference Q ₀ is set such that the water supply temperature T ₀ becomes larger as the set temperature T approaches (in this embodiment is set to 80 ° C.), and in this embodiment,

Difference (Q ₀ ) = 100 liters / {[set temperature (T) -water supply temperature (T ₀ )]}... … … … … … … … … … (B)

Use the expression of. As a result, the increase or decrease direction of the set temperature (T) and the water temperature (T ₀₎ the temperature difference (△ T) is a significant and these temperature differences more be less difference (Q ₀₎ (△ T) between the difference (Q ₀₎ station Becomes a relationship.

Furthermore, the denominator is the expression of the difference (Q ₀₎ - is one with the square of [predetermined temperature (T) water temperature (T _0)], reviewed from the above equation (A) for calculating a digest flow (Q ₁₎ This is because the change amount of the extinguishing flow rate Q ₁ is inversely proportional to the square of the [set temperature (T) -water supply temperature (T ₀ )].

In other words,

To be the extinguishing flow (Q ₁₎ the formula (C) is a right-hand side of the denominator representing the amount of change - of [predetermined temperature (T) water temperature (T _0)] the digestion flow (Q ₁₎ because it is the square of In order to increase or decrease the difference Q ₀ in accordance with the change, that is, the square of the denominator (set temperature (T) -water supply temperature (T ₀ )) on the right side of the equation (B).

(b). Next, when the difference Q ₀ is smaller than 0.7 liters / minute, the difference Q ₀ is set to 0.7 liter (reference numerals 72 and 73).

(c). Next, calculation of the ignition flow rate Q ₂ is executed (see step 74). That is, similarly to the conventional one described above, the extinguishing flow rate Q ₁ is calculated using the formula (A), and the difference Q ₀ obtained in the step 71 is obtained from the calculation result [the difference ( If Q ₀ ) is less than 0.7, it is set to 0.7.] Is added to obtain the ignition flow rate Q ₂ .

(d). Next, when the flow rate Q measured by the flowmeter 10 is smaller than the ignition flow rate Q ₂ , even if the gas burner 15 is burned to its maximum capacity, the set temperature T (in this embodiment, 80 ° C.) or more is exceeded. Since the hot water boils in the heat exchanger 12, the control operation returns to the step 70 with no ignition of the gas burner 15. On the contrary, when the flow rate Q measured by the flow meter 10 is equal to or higher than the ignition flow rate Q ₂ , the main valve 17 is opened to supply gas to the gas burner 15, and at the same time, the gas burner 15 is ignited. This is taken as a combustion state (refer to the step of reference numeral 76).

(e). The set temperature (T) from the flow rate (Q) measured by the flow meter (10), the water supply temperature (T ₀ ) detected by the temperature sensor (11), the set temperature (T), and the heat exchange efficiency of the heat exchanger (12). The opening degree of the proportional valve 16 is controlled while calculating the amount of combustion of the gas burner 15 necessary to boil hot water. In other words, the hot water supply operation is continued while the feed forward control is performed (see step 77). During the hot water supply operation, the extinguishing flow rate Q ₁ is calculated by substituting the detected water temperature (water supply temperature T ₀ ) of the temperature sensor 11 that changes over time by the above formula (A). The flow rate Q is monitored to be less than the extinguishing flow rate Q ₁ (see steps 78 and 79).

In this case, under the condition of tapping operation in the vicinity of the ignition flow rate Q ₂ , when the temperature difference ΔT between the water supply temperature T ₀ and the set temperature T is small as described above, the temperature sensor 11 When the temperature difference (ΔT) between the water supply temperature (T ₀ ) and the set temperature (T) is small, if the water supply temperature (T ₀ ) by the temperature sensor 11 changes slightly, the extinguishing flow rate (Q ₁ ) is large. There is a possibility that the gas burner 15 is forced to extinguish due to fluctuation, but under such conditions, the calculation is performed in the step 71 as the difference Q ₀ becomes large, so that the ignition flow rate Q ₂ and the extinguishing flow rate Q ₁ ) Difference is large, and there is little fear that a chattering phenomenon in which the gas burner 15 repeatedly ignites and extinguishes little by little.

(f). Next, if the flow rate Q measured by the flow meter 10 is smaller than the extinguishing flow rate Q ₁ when the step 79 is executed, the gas burner 15 may be burned to the maximum capacity. Since hot water exceeding the set temperature T is heated and generated in the heat exchanger 12 to become a dangerous state, the main valve 17 is opened (see step 80 of the reference numeral), and the control operation is Return to step

Further, in the above embodiment, the extinguishing flow rate Q ₁ is calculated using equation (A), and the ignition flow rate Q is obtained by adding the difference Q ₀ obtained in the step 71 to the calculation result. ), But the ignition flow rate Q may be obtained using equation (A), and the extinguishing flow rate Q ₁ may be obtained by subtracting the difference Q ₀ therefrom.

That is, for example, the ignition flow rate Q ₂ ? K {(minimum calorific value R (Kcal / min) / [set temperature T-water supply temperature T ₀ )]} (where K is a constant greater than 1). The ignition flow rate may be obtained by the following equation, and the extinguishing flow rate Q ₁ may be obtained by subtracting the difference Q ₀ obtained from the reference numeral 71.

Claims (1)

The flow meter 10 which measures the flow volume of the flow through the heat exchanger 12, and the temperature sensor 11 which measures the temperature of the supply water to the heat exchanger 12, and set temperature (T) ) And one of the ignition flow rate Q ₂ or the extinguishing flow rate Q ₁ is set so as to be inversely proportional to the temperature difference ΔT between the water supply temperature T ₀ detected by the temperature sensor 11). The difference Q ₀ , which is the flow rate difference between the extinguishing flow rates Q ₂ and Q ₁ , is provided, and the heat exchanger 12 when the flow rate 10 and the flow rate Q to be measured are equal to or greater than the ignition flow rate Q ₂ . Adjusting the ignition / extinguishing timing to keep the gas burner 15 in a fire extinguishing state when the gas burner 15 for ignition is ignited and the flow rate Q is equal to or less than the extinguishing flow rate Q ₁ . in the method, it referred to increasing or decreasing changes in the difference (Q ₀₎ and at the same time, the difference in the increase or decrease direction of the (Q ₀₎ for increasing or decreasing direction, as opposed to a hot water supply device of the set temperature difference (△ T) How to adjust the ignition and extinguishing timing of fire.