JPH083387B2 - Water amount control device for an attached water heater - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a water quantity control device for a water heater with a plurality of heat exchangers, each of which heats water.

[Prior Art] For example, an attached water heater that heats water by two heat exchangers connected in parallel is often used when a large amount of hot water is required. In addition, an electromagnetic valve that stops the supply of water is provided in the water pipe to one heat exchanger, and when the amount of water used is small, the electromagnetic valve is closed and heating is performed only by the other heat exchanger. The solenoid valve is opened when a certain amount of water or more is used, and heating is performed by both heat exchangers, so that it can be used even when the required amount of hot water is small.

[Problems to be Solved by the Invention] However, when the amount of water used is small and the solenoid valve is not opened, heating is always performed only by the heat exchanger having no solenoid valve in the water pipe. The one side heat exchanger or heating device that is always used has a much higher degree of deterioration than the one side heat exchanger or heating device that is not used.

Therefore, even if the other heat exchanger, etc., which is used only when the amount of water used is large, is still fully usable,
When there is a limit to the durability of the heat exchanger on the side that is always used, it must be judged that the service life of the entire water heater has expired, so the life of the water heater tends to be shortened. .

It is an object of the present invention to provide a water quantity control device for a side-by-side water heater that suppresses deterioration of a heat exchanger and a heating device of the water heater itself and can use the water heater for a long period of time.

[Means for Solving the Problems] The present invention connects a plurality of heat exchangers in parallel in a water supply path for supplying water, and at the start of water supply, a part of the plurality of heat exchangers is connected. In the water quantity control device of the side-by-side water heater that supplies water and supplies water to the other of the plurality of heat exchangers when the supplied water quantity is equal to or greater than the reference water quantity, select the heat exchanger to which water is initially supplied. The technical means is to switch the heat exchanger to be selected each time the predetermined time is measured by the time measuring means.

Further, the technical means is that the selecting means does not switch the heat exchanger to be selected when it is in operation when the predetermined time is counted by the timing means.

In addition, a plurality of heat exchangers are connected in parallel in a water supply path for supplying water, and at the start of water supply, water is supplied to a part of the plurality of heat exchangers, and the amount of water supplied is standard. In the water quantity control device of the side-by-side water heater that also supplies water to the other of the plurality of heat exchangers when the amount of water is greater than or equal to, a selection means for selecting a heat exchanger to which water is initially supplied is provided, and the selection means is The technical means is to switch the selected heat exchanger for each operation.

[Operation and Effect of the Invention] In the combined water heater of the present invention, the heat exchanger to which water is initially supplied is alternately selected by the selection means. Therefore,
Even if the amount of water used is small and water is supplied to only some of the multiple heat exchangers in many cases, the heat exchangers used do not become fixed and Each heating means is used evenly. For this reason, the time when each heat exchanger or the like is used is reduced, and the deterioration rate can be suppressed, so that the heat exchanger can be used for a long period of time and the service life of the combined water heater can be extended.

[Embodiment] Next, the present invention will be described based on an embodiment shown in FIG.

The side-by-side gas water heater 1 splits the water supplied from the water supply pipe 2 connected to a water supply source (not shown) into the water pipes 10 and 20, and heats them by the heat exchangers 11 and 21, respectively, and then to the hot water supply pipe 2a. The hot water is supplied by merging the heat exchangers. In the water heater case 3, the heat exchangers 11 and 21 are housed in the combustors 30 and 40 having the same heating capacity. Each of the water passing through the inside is heated.

The water supply pipe 2 is provided with a water amount sensor 4 and an incoming water temperature thermistor 5, and after the water amount and water temperature of the supplied water are detected, a three-way valve 6 provided at a branch point to the water pipe 10 and the water pipe 20 is provided. Inflow.

The three-way valve 6 switches the water supplied from the water supply pipe 2 to only one of the water pipe 10 and the water pipe 20, and the water supply pipe 2 is always in communication with either the water pipe 10 or the water pipe 20. The supplied water is led to the heat exchanger 11 or the heat exchanger 21 connected to the water pipe 10 or the water pipe 20 communicating with the three-way valve 6, respectively.

Further, the water pipe 10 and the water pipe 20 are connected to each other by a bypass pipe 7a having a water solenoid valve 7, and the water supplied from the water supply pipe 2 to each of the water pipes 10 and 20 is connected to the water solenoid valve 7a.
When is open, it is also supplied to the other.

A water flow switch 1 that closes the contact points of the water pipes 10 and 20 upstream of the heat exchangers 11 and 21 when the amount of passing water exceeds a certain amount.
2, 22 and automatic water quantity control switching devices 13, 23 are provided, respectively. Here, the water flow switches 12 and 22 are 2.9 ± 0.5
The contact is closed by the amount of water per minute or more, and the amount of water is 2.2 ± 0.5.
The contact is opened at less than / minute.

The automatic water volume control switching devices 13 and 23 are automatic water volume control valves 14 and 24 that sense the temperature of water and automatically control the amount of water passing through.
And the water quantity switching valves 16 and 26 provided in the bypass pipes 15 and 25 that connect the upstream and downstream of the automatic water quantity control valves 14 and 24, respectively, to the respective heat exchangers 11 and 21. Adjust the inflow of water. The automatic water flow control valves 14 and 24 decrease the opening when the temperature of the supplied water is low, and increase the opening as the temperature rises. Therefore, the automatic water quantity control switching devices 13 and 23, for example, when the water quantity switching valves 16 and 26 are in the closed state, respond to changes in the water temperature of 5 ° C to 25 ° C by 6-10
Adjusted to supply water per minute, each water quantity switching valve 16, 26
When is open, the water is adjusted to supply 9 to 13 / min corresponding to the change in water temperature of 5 to 25 ° C.

Each water pipe 10, 20 downstream of each heat exchanger 11, 21 has a tap water temperature thermistor 17, for detecting the temperature of heated hot water,
27 are provided respectively, and the water pipes 10 and 20 are hot water supply pipes downstream thereof.
Merged into 2a.

Within each combustor 30, 40, multiple ribbon burners 31,
41 is provided, and the burners 31, 41 are provided with nozzle pipes 32, 42 each having an ejection port formed corresponding to each burner 31, 41. The nozzle pipes 32 and 42 are fuel pipes branched from a gas pipe 8 for supplying fuel gas from a fuel supply source (not shown).
Fuel gas is guided by 33 and 43. Each fuel pipe 33, 43 is provided with a source solenoid valve 34, 44, a main solenoid valve 35, 45, and a proportional valve 36, 46, respectively. Further, the combustors 30 and 40 are provided with blowers 37 and 47 for supplying combustion air to the burners 31 and 41, respectively.

Further, sparkers 38, 48 for ignition and flame rods 39, 49 for detecting flames are provided near the burners 31, 41 in the combustors 30, 40, respectively.

The combustors 30 and 40 are controlled by the control circuits 50 and 60, respectively, according to the temperature set by the controller 80.

The control circuit 50 and the control circuit 60 operate independently of each other,
It controls the combustor 30 and the combustor 40, respectively, and as shown in FIG. 3, it is composed of functional units of sequence control units 51 and 61 and combustion control units 52 and 62, respectively.

In the control circuit 50, when the water flow is detected by the water flow switch 12, the sequence control unit 51 performs ignition control in a predetermined sequence, operates the blower 37 to supply combustion air to the burner 31, and the blower 37. When the number of rotations reaches the specified number of rotations, the spark
34 and the main solenoid valve 35 are opened to supply the fuel gas to the burner 31.

Further, when flame is detected by the frame rod 39, the operation of the sparker 38 is stopped, and when flame is no longer detected by the frame rod 39, misfire is detected, and each electromagnetic provided in the fuel pipe 33 for ensuring safety. Close the valve.

The combustion control unit 52 is configured so that the temperature set by the controller 80 transmitted via the relay control circuit 70 and the hot water temperature thermistor 17 are set.
The blower 37 and the proportional valve 36 are respectively controlled on the basis of the hot water temperature detected by, and the combustion amount of the combustor 30 is adjusted.

The control circuit 60 controls the combustor 40 independently of the control circuit 50, and its control is exactly the same as that of the control circuit 50, and therefore its explanation is omitted.

The amount of water passing through the water pipes 10 and 20 is controlled by the relay control circuit 70 according to the operating state of the controller 80.

As shown in FIG. 1, the relay control circuit 70 is provided with three-way valve switching unit 71, a water solenoid valve control unit 72, and a water amount control unit 73, and each function unit causes the three-way valve 6 and the water control unit 73 to operate. The solenoid valve 7 and the water quantity switching valves 16 and 26 are controlled.

The three-way valve switching unit 71 includes the heat exchangers 11 and 21 and the combustors.
In order to make the usage states of 30 and 40 uniform, the three-way valve 6 is switched according to predetermined conditions to change the heat exchanger into which water flows at the initial stage of hot water supply. Here, the three-way valve switching unit 71 is provided with a timer unit 74, for example, the three-way valve 6 is switched every 24 hours at midnight, and when the three-way valve 6 is switched, water is directly supplied from the water supply pipe 2. The water pipes and heat exchangers are changed.

The water solenoid valve control unit 72 uses the heat exchanger 11 and the heat exchanger 21, and the combustor 30 and the combustor 40 together when a large amount of hot water is required. The water solenoid valve 7 is opened in response to the reference water amount L based on the incoming water temperature T _IN detected by the incoming water temperature thermistor 5 and the set temperature T _SET set by the controller 80. _{When 0} is determined and the detected water amount L is equal to or greater than the reference water amount L ₀ , the water solenoid valve 7 is opened.

When the set temperature L _{SET is} 55 ° C or higher, the reference water amount L ₀ is 7.0 ± 1.0 / min regardless of the water temperature T _IN .

When the set temperature T _SET is less than 55 ° C, as shown in Fig. 4, the reference water amount L ₀ for switching the water solenoid valve 7 is changed according to the water temperature T _IN .

When the input water temperature T _IN is less than 15 ° C, the reference water volume L ₀ is uniformly adjusted to 7.0.
± 1.0 / min. When the input water temperature T _IN is 15 ° C or more and less than 25 ° C, the reference water amount L ₀ is changed based on the input water temperature T _IN in a relation approximately represented by L ₀ = 0.16 × T _IN +4.6. It

If the input water temperature T _IN is 25 ° C or higher, set the standard water volume L ₀ to 8.6 ± 1.0 / min.

The opened water solenoid valve 7 is closed once the detected water amount L becomes 1.4 ± 0.8 / min less than the reference water amount L ₀ .

In the water amount control unit 73, the water amount switching valves 16 and 26 are controlled as follows, respectively.

When water flows in and is detected by the water amount sensor 4, the water amount switching valve 16 is opened, and a water passage is secured so that a water amount equal to or greater than the reference water amount L ₀ determined as described above can flow in.

Also, the set temperature T _SET by the controller 80 is high,
When the temperature is above ℃, in order to reliably raise the temperature of the water, the water quantity switching valves 16 and 26 are closed together and the water heat exchangers 11 and 21 are passed only when the water solenoid valve 7 is open. Reduce the amount of water used. At this time, if the water quantity switching valve 16 is closed before the water solenoid valve 7 is opened, the water quantity switching valve 16 restricts the passing water quantity and the water quantity does not increase. Therefore, the water quantity switching valve 16 opens after the water solenoid valve 7 is opened. The valve 16 is controlled to be closed.

Further, the relay control circuit 70 transmits the signal of the set temperature T _SET by the controller 80 to the control circuits 50 and 60.

The side-by-side gas water heater 1 having the above configuration operates as follows.

When the three-way valve 6 opens to the water pipe 10, for example, and the water supply pipe 2 and the water pipe 10 are in direct communication with each other, when the timer unit 74 measures a predetermined time, the three-way valve 6 is driven to drive the water pipe.
It opens to 20, and the water supply pipe 2 and the water pipe 10 directly communicate with each other.

On the contrary, the three-way valve 6 opens to the water pipe 20, and the water supply pipe 2 and the water pipe 20
In the case of direct communication with and, when a predetermined time is measured by the timer unit 74, the three-way valve 6 is driven to open to the water pipe 10, and the water supply pipe 2 and the water pipe 10 are in direct communication.

After that, similarly, when the timer unit 74 measures a predetermined time, the three-way valve 6 is switched, and the water pipe that directly communicates is changed.

When the water supply pipe 2 communicates with the water pipe 10 or the water pipe 20, when the user opens a water tap (not shown), water is supplied into the water supply pipe 2. At this time, the water solenoid valve 7 is closed, and the inflowing water flows only into the water pipe communicating with the water supply pipe 2.

If the inflow of water is detected, the amount of water switching valve 16 is opened, the incoming water temperature thermistor 5 and water sensor 4 is detected water quantity L and the incoming water temperature T _IN, respectively, the detected amount of water L entering water temperature T _IN According to the reference water volume L ₀ determined by, each operates as follows.

1) When the water amount L detected by the water amount sensor 4 is less than each of the reference water amounts L ₀ described above, the water solenoid valve 7 is not opened, and the water is only in one of the water pipes and the heat exchanger communicating with the water supply pipe 2. Is supplied to. Therefore, only one water flow switch is closed, only one control circuit is activated, and only one combustor burns. The inflowing water is heated by only one heat exchanger and flows out from the hot water supply pipe 2a.

2) When the detected water amount L is equal to or more than each of the reference water amounts L ₀ , the water solenoid valve 7 is opened, and at this time, the set temperature T _SET is 55.
When the temperature is lower than 0 ° C, the water quantity switching valve 26 is simultaneously opened, and the water supplied from the water supply pipe 2 is also supplied to the water pipe not directly communicating with the water supply pipe 2 through the bypass pipe 7a and the water pipe 10. Both are supplied to the water pipe 20.

If the set temperature T _SET is 55 ° C or higher, the water solenoid valve 7
When a predetermined time Δt elapses after the water is opened, the water quantity switching valve
16 is closed and the amount of water passing through each water pipe 10 and 20 is reduced, but the water can pass through the water pipe 10 and the water pipe 20, so the reference water amount
It is possible to secure a water amount of L ₀ or more.

Therefore, since both the water flow switch 12 and the water flow switch 22 are closed and the control circuits 50 and 60 are both operated, the supplied water is heated by the combustor 30 and the combustor 40, joins the hot water supply pipe 2a and flows out.

As described above, in the present embodiment, the water pipe to which water is supplied before the water solenoid valve is opened is switched by the three-way valve at every predetermined time, so even if the amount of water used is small in many cases,
Only one heat exchanger and combustor is not used and is used alternately with the other heat exchanger and combustor.
Therefore, only one heat exchanger and the combustor are not deteriorated, and both heat exchangers and the combustors are equally deteriorated. Therefore, the life of the water heater can be extended.

A second embodiment of the present invention is shown in FIGS. For simplification of description, the same parts and the same functions as those in the above embodiment are designated by the same reference numerals in the drawings.

In this embodiment, as shown in FIG. 5, the water supply pipe 2 is branched to directly communicate with the water pipe 10 and the water pipe 20, and the branched water pipes 10 and 20 are provided with water solenoid valves 9a and 9b, respectively. Has been.

These water solenoid valves 9a, 9b are controlled as follows by the relay control circuit 70a shown in FIGS. 6 and 7.

The water solenoid valve selection switching unit 75 alternately selects one of the water solenoid valves 9a and 9b in response to a time signal from the timer unit 74 every predetermined time, for example, 24 hours, and selects the selected water solenoid valve. To open.

In addition, the water solenoid valve selection switching unit 75 drives the non-selected water solenoid valve to open it in response to a control signal from the water solenoid valve control unit 72a described below.

The water solenoid valve control unit 72a determines the water solenoid valve that is not selected by the water solenoid valve selection switching unit 75 based on each signal from the controller 80, the incoming water temperature thermistor 5, and the water amount sensor 4, as described above. A control signal for controlling according to the reference water amount L ₀ is generated.

Also in this example, even if the amount of water used is small in many cases,
Since the heat exchanger and the combustor used are not fixed and used alternately, the life of the water heater can be extended.

In each of the above-described embodiments, the switching of the three-way valve or the selection of the water solenoid valve is performed after a predetermined time has passed. However, as shown by broken lines in FIG. 1 and FIG. Exclusive output only when driven
The OR circuit 76 may be provided so that the operating time of only one of the heat exchangers is settled by the timer unit, and the operating time is switched or selected every time a predetermined time, for example, 3 hours, elapses. Good. Further, as shown by the chain double-dashed lines in FIGS. 1 and 7, a signal indicating the operation of each combustor is transmitted from each control circuit 50, 60 to the three-way valve switching unit 71 or the water solenoid valve selection switching unit 75. Even if the timer unit counts a predetermined time, if the switching is not performed during operation, stable hot water supply can be performed.

Furthermore, switching or selection may be performed alternately each time it is used.

In this embodiment, the side-by-side water heater provided with the gas combustor has been described, but other fuel may be used or an electric heater may be used as a heating source.

[Brief description of drawings]

1 to 3 show a first embodiment of a water quantity control device for a combined type water heater according to the present invention. FIG. 1 is a block diagram showing a functional configuration of a relay control circuit, and FIG. 2 is a combined type. The block diagram which shows the outline of a gas water heater, FIG. 3 is a block diagram which shows the control system in a side-by-side gas water heater, and FIG. 4 is a control characteristic diagram which shows a part of control in the water solenoid valve control of a relay control circuit. FIGS. 5 to 7 show a second embodiment of the present invention, FIG. 5 is a schematic diagram of the combined gas water heater, and FIG. 6 shows a control system in the combined gas water heater. Block Diagram,
FIG. 7 is a block diagram showing the functional configuration of the relay control circuit. In the figure, 70 ... Relay control circuit (water amount control device), 71 ... Three-way valve switching unit (selection means).

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Akio Tanaka 2-26 Fukuzumi-cho, Nakagawa-ku, Nagoya, Aichi Linnai Co., Ltd. (72) Kenji Endo 2-26 Fukuzumi-cho, Nakagawa-ku, Nagoya, Aichi Within Linnai Co., Ltd. (56) Bibliography Sho 61-86644 (JP, U)

Claims (3)

[Claims] 1. A plurality of heat exchangers are connected in parallel in a water supply path for supplying water, and at the start of water supply, water is supplied to and supplied to a part of the plurality of heat exchangers. In the water quantity control device of the side-by-side water heater that supplies water to the other of the plurality of heat exchangers when the water quantity is equal to or greater than the reference water quantity, selection means for selecting the heat exchanger to which water is initially supplied, and timing means. The water quantity control device for an attached water heater, characterized in that the selection means switches the heat exchanger to be selected each time a predetermined time is measured by the time measurement means. 2. The selecting means, when the predetermined time is measured by the time measuring means, when the operation is in progress,
2. The water amount control device for an attached water heater according to claim 1, wherein the selected heat exchanger is not switched. 3. A plurality of heat exchangers are connected in parallel in a water supply path for supplying water, and at the start of water supply, water is supplied to and supplied to a part of the plurality of heat exchangers. In the water quantity control device of the side-by-side water heater that supplies water to the other of the plurality of heat exchangers when the water quantity is equal to or greater than the reference water quantity, a selection means for selecting the heat exchanger to which water is initially supplied is provided, and the selection is performed. The means switches the heat exchanger to be selected for each operation, and is a water amount control device for an attached water heater.