JPH023108B2 - - Google Patents

Description

[Detailed description of the invention] (Industrial application field) The present invention relates to a gas instantaneous water heater.

(Prior Art) Conventionally, there have been various structures as gas instantaneous water heaters, but in recent years so-called gas proportional water heaters, which control the temperature of hot water by the amount of gas, have become mainstream.

However, due to the structure of the burner in the gas proportional water heater, the lower limit combustion amount (minimum number) that can be controlled proportionally is limited, and the minimum number is usually the maximum combustion amount (maximum number). It is 1/4 to 1/5 of that.

Therefore, for example, in a gas proportional water heater with a maximum size of No. 16, the combustion amount can only be reduced to a minimum of No. 4 depending on the combustion limit of the burner, and it is used at a capacity of No. 4 or less. In some cases, it will not burn.

Also, if the maximum number is not large, the minimum number will naturally be correspondingly large.

Therefore, even if you try to use a small amount of hot water in the summer with a No. 16 water heater, it will not be possible to use the hot water. Water has to flow.

In order to solve this problem, the applicant of this application has developed a first burner (proportional control burner) that controls the amount of heat by changing the amount of gas for one heat exchanger, and a burner that repeatedly burns and extinguishes the heat. A gas instantaneous hot water heater that is equipped with a second burner (intermittent combustion control burner) that controls the amount of heat by changing the ratio of time and extinguishing time, and burns both burners selectively or simultaneously depending on the required heat load. (Japanese Patent Application No. 59-208688) and two proportionally controlled burners for one heat exchanger, the maximum combustion amount of one burner is equal to or higher than the lower limit combustion amount of the other burner. Gas instantaneous water heaters (1985
The application was filed on May 23, 2017).

However, in the former case, the lower combustion limit can be reduced to a value close to 0, but intermittent combustion control burners are often used, and the solenoid valve that opens and closes the gas supply pipe to the burner may be damaged. intense.

On the other hand, although the latter causes less damage to the solenoid valve, it is not possible to reduce the lower limit combustion amount to near No. 0.

(Problems to be Solved by the Invention) The problems to be solved by the present invention are that although the maximum combustion quantity is large, the lower limit combustion quantity can be reduced to close to 0, and the solenoid valve is not damaged. The goal is to reduce

(Means for Solving the Problem) The technical means taken by the present invention to solve the above problem is that a first burner is provided in one heat exchanger together with the first burner, and the maximum combustion amount is set as the first burner. A second burner set to be equal to or slightly higher than the lower limit combustion amount of the first burner,
Based on the data input from each of the above-mentioned detection means and temperature setting means, a controller having a water amount detection means, an inlet water temperature detection means, an outlet hot water temperature detection means, and a temperature setting means provided in each of the water supply pipes passing through the heat exchanger. calculation means for calculating the required heat load;
burner selection means for selecting a burner to be used based on the required heat load calculated by the calculation means; control method selection for determining the heat amount control method for the second burner based on the required heat load by selecting a second burner by the burner selection means; The extinguishing signal, the second burner intermittent combustion signal, the second burner proportional combustion signal, the first burner proportional combustion signal, the first burner, and the second Means for selectively generating a burner proportional combustion signal, first and second electromagnetic valves provided in the gas piping of each of the first and second burners, and driven by the signal to open and close the gas piping, and a means for controlling the gas amount. comprising first and second proportional control valves that control continuously, and the second burner intermittent combustion signal is
Occurs when the required heat load is equal to or less than a predetermined reference value, and the second proportional control valve is fixed at a predetermined opening degree, and the second solenoid valve is intermittently opened at a period and an opening/closing time ratio according to the required heat load. 2nd burner proportional combustion, 1st burner proportional combustion, 1st, 2nd burner
Each signal of burner proportional combustion is generated when the required heat load corresponds to the above-mentioned predetermined reference value or more, and is responded by opening one or both of the first and second solenoid valves depending on the required heat load. This is to open the proportional control valve to an opening degree that corresponds to the required heat load.

(Operation) According to the above means of the present invention, when the required heat load is within the capacity range of the second burner, the second burner
When only the burner is within the capacity range of the 1st burner, only the 1st burner is operated, and when the capacity range of the 11th burner is exceeded, both the 1st and 2nd burners are operated according to the required heat load. The amount of combustion is controlled, and when the required heat load is less than the lower limit combustion amount of the second burner, the second burner performs intermittent combustion with the required cycle and the required ratio of ignition time and extinguishing time.

(Example) In FIG. 1, a is a water heater main body, b is a controller, and the water heater main body a has two burners, a first burner 2 and a second burner 3, for one heat exchanger 1. The gas supplied through the gas pipe 13 is burned in the first burner 2 and/or the second burner 3, and the water flowing through the water supply pipe 4 is heated in the heat exchanger 1. .

The gas pipe 13 branches at a midpoint into a first gas pipe 13a that communicates with the first burner 2 and a second gas pipe 13b that communicates with the second burner 3. Original solenoid valve 1
It has 8.

The first gas pipe 13a is provided with a first electromagnetic valve 14 and a first proportional control valve 16, and the second gas pipe 13b is provided with a second electromagnetic valve 15 and a second proportional control valve 17, respectively.

Therefore, the first burner 2 and the second burner 3 are
In either case, if the first and second solenoid valves 14 and 15 are opened, respectively, while the original solenoid valve 18 is open, the first and second solenoid valves 14 and 15 are opened.
The amount of gas corresponding to the opening degree of the second proportional control valves 16, 17 is supplied, and by changing the opening degrees of the first and second proportional control valves 16, 17 and changing the amount of gas supplied, the first , the amount of heat can be changed within the range that can be controlled by the second proportional control valves 16 and 17. (Hereinafter, such a heat amount control method will be referred to as proportional control.) In addition, since both burners 2 and 3 can be intermittently burned by repeatedly opening and closing the first and second solenoid valves 14 and 15, proportional control is possible. valve 16,1
If the opening degree of valve 7 is kept constant and the solenoid valves 14 and 15 are repeatedly opened and closed, by changing the length of the opening/closing cycle and the ratio of the valve opening time to the valve closing time, the proportionality kept constant can be maintained. In the range from the amount of heat when continuous combustion is performed with the opening degrees of the control valves 16 and 17 to the amount of heat when the valve closing time is extremely short compared to the opening time of the solenoid valves 14 and 15, that is, the amount of heat close to 0. You can change the amount of heat. (Hereinafter, such a heat amount control method will be referred to as intermittent combustion control.) The first burner 2 and the second burner 3 are configured such that the maximum combustion amount of the second burner 3 is equal to or less than the lower limit fuel amount of the first burner 2. Set it to be slightly larger.

In the case of this embodiment, the first burner 2 is constituted by five individual burners 2' to form a unit in which the minimum number is 4 and the maximum number is 15, and the second burner 3 is composed of 2 burners. A single book burner 3' constitutes a unit with a minimum size of 1.6 and a maximum size of 6.

Therefore, if water heater a uses only the second burner 3 and proportionally controls it, it will be in the range of No. 1.6 to No. 6, and if only the first burner 2 is used and it is proportionally controlled, it will be in the range of No. 4 to No. 4. The combustion amount can be varied within the range of No. 15, and if the first burner 2 and the second burner 3 are used simultaneously and proportionally controlled, the combustion amount can be varied within the range of No. 15 to No. 21.

In addition, the water heater a uses only the second burner 3, and the second proportional control valve 17 is adjusted to an appropriate opening degree, for example, 3.
By repeating the opening of the second solenoid valve 15) while maintaining the opening corresponding to No. 0, and by controlling the intermittent combustion by varying the cycle and the ratio of opening/closing time,
The amount of heat can be controlled within the range of No. 1.6.

Therefore, this water heater a can control the amount of heat in the range of No. 0 to No. 21 by appropriately combining and switching the first and second burners 2 and 3 and switching between proportional control and intermittent combustion control. .

On the other hand, in the water supply pipe 4, a water flow rate sensor 5 and an incoming water temperature sensor 6 are installed upstream of the heat exchanger 1, and an outlet water temperature sensor 7 is installed downstream of the heat exchanger 1. It is provided close to the exchanger 1 outlet.

The first and second solenoid valves 14 and 15, the first and second
The proportional control valves 16 and 17, the water flow sensor 5, the incoming water temperature sensor 6, and the outgoing water temperature sensor 7 are electrically connected to a microprocessor 19, which will be described later.

The water amount sensor 5 detects the amount of water flowing through the water supply pipe 4, that is, the flow rate Q, and generates a pulse signal.

The above-mentioned flow rate Q varies depending on the opening degree of the faucet at the end of the water supply pipe 4 and fluctuations in water pressure.

The incoming water temperature sensor 6 measures the incoming water temperature to the heat exchanger 1.
The output _temperature sensor 7 detects the output temperature T _H from the heat exchanger 1 and sends it as a voltage to the A/D converter, which outputs T _C , T _H
Convert to data.

The controller b is equipped with a power switch 20 and a temperature setting means 8, and the set temperature T _S set by the temperature setting means 8 is sent to the microprocessor 19 as a voltage, but on the way, the T S is set by an A/D converter. Converted to _S data.

The microprocessor 19 is disposed in the water heater body a, and includes a calculation means 9 for calculating the required heat load F ₁ and a burner for selecting the burner to be used based on the required heat load calculated by the calculation means 9. a selection means 10; a control method selection means 11 for selecting a heat amount control method for the second burner 3 when the burner selection means 10 selects the second burner 3; and burner and control method selection means 10, 11. The electromagnetic valve opening/closing and proportional valve opening signal generating means 12 generates signals necessary for the first and second electromagnetic valves 14 and 15 and the second proportional control valves 16 and 17 based on the selection.

The calculation means 9 is activated by the water amount detection by the water amount sensor 5, converts the pulse signal from the water amount sensor 5 into water amount Q data and takes in it, and also inputs the A/D from the temperature setting means 8, the incoming water temperature sensor 6, and the outgoing water temperature sensor 7. T _S , T _C transferred through the converter,
Take in the T _H data and calculate the required heat load F ₁ based on these data.

The burner selection means 10 makes four selections regarding the use of the burner depending on the required heat load calculated by the calculation means 9.

The first option is not to use both the first and second burners, which is selected when the required heat load is less than or equal to the first reference value.

The second option is the use of the second burner 3, which is selected when the required heat load is within the range of the first reference value and the second reference value.

The third option is the use of the first burner 2,
This is selected when the required heat load is within the range of the second reference value to the third reference value.

A fourth option is the simultaneous use of both the first and second burners 2, 3, which is selected when the required heat load exceeds a third reference value.

The above reference values are, for example, the first reference value of 0.1,
The second reference value is set to No. 6, which corresponds to the maximum combustion amount of the second burner 3, and the third reference value is set to No. 15, which corresponds to the maximum combustion amount of the first burner 2.

The control method selection means 11 operates only when the burner selection means 10 makes the second selection, that is, when the use of the second burner 3 is selected, and selects the heat amount control method of the second burner 3.

The control method to be selected is either intermittent fuel control or proportional control, and the control method selection means 11 is selected when the required heat load is below a fourth reference value set between the first reference value and the second reference value. When , intermittent combustion control is selected, and when the fourth reference value is exceeded, proportional control is selected.

The fourth reference value is set, for example, to No. 1.6, which corresponds to the lower limit combustion amount of the second burner 3. The electromagnetic valve opening/closing and proportional valve opening signal generation means 12 selectively generates five signals in accordance with the selections made by the burner selection means 10 and the control method selection means 11.

The above five signals are the extinguishing signal, the second burner intermittent combustion signal, the second burner proportional combustion signal, the first burner proportional combustion signal, and the first and second burner proportional combustion signals.

The extinguishing signal is generated when the burner selection means 10 selects non-use of both the first and second burners,
The first and second solenoid valves 14 and 15 and the first and second proportional control valves 16 and 17 are all closed.

Therefore, when this extinguishing signal occurs, the first and second
Burners 2 and 3 are both extinguished.

The second burner intermittent combustion signal is generated when the burner selection means 10 selects the use of the second burner 3 and the control method selection means 11 selects intermittent combustion control, and the second burner intermittent combustion signal is generated when the first solenoid valve 14 and the first proportional combustion control are selected. control valve 1
6 is closed, and the second solenoid valve 15 is intermittently opened and closed at a cycle and opening/closing time ratio according to the required heat load, and the second proportional control valve 17 is set to a predetermined opening, for example, an opening equivalent to No. 3. Open the valve.

Therefore, when this signal is generated, the second burner 3 burns intermittently at a period corresponding to the required heat load and at a ratio of ignition and extinguishing times.

The second burner proportional combustion signal is generated when the burner selection means 10 selects the second burner 3 and the control method selection means 11 selects proportional control,
Close the first solenoid valve 14 and the first proportional control valve 16,
The second electromagnetic valve 15 is opened, and the second proportional control valve 17 is operated proportionally according to the required heat load.

Therefore, when this signal is generated, the second burner 3 continuously burns the gas with an amount corresponding to the required heat load.

The first burner proportional combustion signal is generated when the burner selection means 10 selects the use of the first burner 2, opens the first solenoid valve 14, and controls the first proportional control valve 16 according to the required heat load. Proportional operation, first
The solenoid valve 15 and the second proportional control valve 17 are closed.

Therefore, when this signal is generated, the first burner 2 continuously burns the gas amount according to the required heat load.

The first and second burner proportional combustion signals are generated when the burner selection means 10 selects joint use of the first and second burners 2 and 3, and the first and second solenoid valves 14 and 15 are opened. , first and second proportional control valves 1
6 and 17 are both operated proportionally according to the required heat load.

Therefore, when this signal is generated, the first and second burners 2 and 3 jointly perform continuous combustion with an amount of gas corresponding to the required heat load.

In the above explanation, the lower limit combustion amount of the first burner 2 is set to 4, and the maximum combustion amount of the second burner 3 is set to 6.
Therefore, the range from No. 4 to No. 6 can be controlled using either the first burner 2 or the second burner 3. Also, the required heat load is
Even if it is equivalent to No. 1.6 or higher, it can be handled by intermittent combustion control of the second burner 3 depending on the intermittent combustion cycle and the ignition and extinguishing time ratio.

Therefore, the reference values for burner selection and control method selection need not be limited to the above-mentioned exemplary reference values, and may be determined depending on the convenience of control, and may vary depending on whether the required heat load changes in the direction of increasing or decreasing. It is also possible to use different reference values for selection depending on the case where the change occurs in the direction of change.

The solenoid valve 18 of the gas pipe 13 is opened and closed by turning on and off the power switch 20 of the controller b.

Although not shown in the drawings, igniters are provided near each of the burners 2 and 3, and these igniters generate ignition in synchronization with the opening of the electromagnetic valve of the corresponding burner.

(Effects) Since the present invention has the above configuration, it has the following advantages.

(1) By using two burners at the same time and controlling them proportionally, the maximum number of water heaters will be equivalent to the sum of the maximum numbers of both burners, so the maximum number of water heaters can be increased. On the other hand, by using only the small-capacity burner and controlling its combustion intermittently by opening and closing its solenoid valve, the minimum number of water heaters can be reduced to almost zero.

(2) When the maximum size of the first burner is the same as or slightly higher than the minimum number of the first burner, and the required heat load is equal to or higher than the lower limit combustion amount of the second burner, Either one of the two burners is selected depending on the required heat load, or they are used simultaneously for proportional control, and when the required heat load corresponds to the lower limit combustion amount or less, the second burner is switched on and off by opening and closing the solenoid valve of the second burner. By controlling the amount of heat by intermittent combustion of the burner, it is possible to control the amount of heat continuously from almost 0 to the maximum number without any break, making the water heater easy to use.

(3) The solenoid valve of the second burner was opened and closed to control the amount of heat only when the required heat load was equal to or less than the lower limit combustion amount of the second burner, but the above cases are not so frequent. Since the solenoid valve does not have to open or close excessively, it has excellent durability.

[Brief explanation of drawings]

FIG. 1 is a schematic diagram of a gas instantaneous water heater showing an embodiment of the present invention, FIG. 2 is a block diagram, and FIG. 3 is a flowchart. a: water heater main body, b: controller, 1: heat exchanger, 2: first burner, 3: second burner,
4: Water supply pipe, 5: Water amount detection means (water amount sensor), 6: Inlet water temperature detection means (inlet water temperature sensor),
7: Hot water temperature detection means (hot water temperature sensor), 8:
temperature setting means, 9: calculation means, 10: burner selection means, 11: control method selection means, 12: solenoid valve opening/closing, proportional valve opening signal generation means, 13a: first gas piping, 13b: second gas piping, 14: first solenoid valve, 15: second solenoid valve, 16: first proportional control valve,
17: Second proportional control valve.

Claims (1)

[Scope of Claims] 1 (1) a first burner; (2) provided for one heat exchanger together with the first burner;
a second burner set to be equal to or slightly above the lower limit combustion amount; (3) water amount detection means, inlet water temperature detection means, and hot water temperature detection means provided in each of the water supply pipes passing through the heat exchanger; , (4) a controller having a temperature setting means, (5) a calculation means for calculating the required heat load based on the data input from each of the above-mentioned detection means and the temperature setting means, (6) the required heat load calculated by the calculation means. burner selection means for selecting a burner to be used based on (7) control method selection means for determining a heat amount control method for the second burner based on the required heat load by selecting a second burner by the burner selection means; Depending on the selection of the burner and control method by the burner selection means and the control method selection means, an extinguishing signal, a second burner intermittent combustion signal, a second burner proportional combustion signal, a first burner proportional combustion signal,
means for selectively generating a proportional combustion signal for the first and second burners; (9) a first means for selectively generating a proportional combustion signal for the first and second burners; a second electromagnetic valve and first and second proportional control valves that continuously control the gas amount, and the second burner intermittent combustion signal is generated when the required heat load is equal to or less than a predetermined reference value. , the second proportional control valve is fixed at a predetermined opening degree, and the second electromagnetic valve is intermittently opened and closed at a period and opening/closing time ratio according to the required heat load, and the second burner proportional combustion and the first burner proportional combustion are performed. , the first and second burner proportional combustion signals are generated when the required heat load corresponds to the above-mentioned predetermined reference value or more, and either or both of the first and second solenoid valves are activated depending on the required heat load. A gas instantaneous water heater characterized in that a valve is opened and a corresponding proportional control valve is opened to an opening degree corresponding to a required heat load.