JP2003194404A - Flow type water heater - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a flow type water heater with a heat exchanger having improved heat efficiency when limiting the temperature of hot water supplied from the heat exchanger for drain prevention. <P>SOLUTION: A controller 80 determines a target burning quantity (Qa) of a hot water burner 11 so that a temperature detected by a hot water temperature sensor 32 becomes a target hot water temperature set by a remote controller 81 and controls the rotating speed of a hot water burner fan 15 and the opening of a water heating gas proportion valve 22 so that the burning quantity of the hot water burner 11 becomes the target burning quantity (Qa). The controller 80 determines a drain preventive temperature Td by applying the target burning quantity Qa to a Qa/Td map previously stored in a memory and controls the flow rate of water to be supplied to a water heat exchanger 10 by adjusting the opening of a bypath servo valve 3 so that a temperature detected by a water heat exchanger temperature sensor 16 becomes the drain preventive temperature Td. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flow-type water heating apparatus for preventing drainage from occurring in a heat exchanger by maintaining the temperature of hot water discharged from the heat exchanger at a predetermined temperature or higher.

[0002]

2. Description of the Related Art Conventionally, as a flow type water heating device,
For example, there is known a gas hot water supply device which has a heat exchanger heated by a burner, and heats water supplied from a water supply pipe by the heat exchanger to discharge hot water having a predetermined target hot water supply temperature to the hot water supply pipe. Has been.

In such a gas hot water supply apparatus, when the temperature of hot water discharged from the heat exchanger becomes low and the temperature of the combustion exhaust gas of the burner becomes low around the heat exchanger, the steam of the combustion exhaust gas becomes a drain and becomes a drain of the heat exchanger. It comes to adhere to the surface. If the drain adheres in this way, there is a disadvantage that the heat exchanger is corroded and the heat exchanger is deteriorated.

Therefore, the ratio of the flow rate of water supplied to the bypass pipe to the flow rate of water supplied to the heat exchanger, and the bypass pipe that bypasses the heat exchanger and connects the water supply pipe to the hot water supply pipe (bypass ratio). A bypass servo valve for adjusting the heat exchanger is provided, and the bypass ratio is adjusted so that the temperature of the hot water discharged from the heat exchanger reaches a predetermined drain prevention temperature so that drain does not occur. There has been proposed a gas hot water supply apparatus that controls the flow rate of water supplied to the water.

In the conventional gas water heater,
The drain prevention temperature was set to a constant value. However, when the inventors of the present application control the flow rate of water supplied to the heat exchanger so that the hot water outlet temperature of the heat exchanger has a constant drain prevention temperature, the thermal efficiency of the heat exchanger is We have found that it is not always good.

[0006]

DISCLOSURE OF THE INVENTION The present invention provides a flow type water heating apparatus in which the heat efficiency of the heat exchanger is improved when the temperature of the hot water discharged from the heat exchanger is limited in order to prevent the generation of drainage. The purpose is to do.

[0007]

The present invention has been made in order to achieve the above object, and comprises a heat exchanger for heating supplied water to discharge hot water, and a burner for heating the heat exchanger. A combustion amount adjusting means for adjusting the combustion amount of the burner, a target combustion amount determining means for determining a target combustion amount of the burner according to a predetermined condition, and a combustion amount of the burner by the combustion amount adjusting means for the target combustion amount. Amount control means for controlling the amount of heat, a heat exchange temperature sensor for detecting the temperature of hot water discharged from the heat exchanger, and a heat exchange amount adjusting means for adjusting the flow rate of water supplied to the heat exchanger. A flow including a heat exchange amount control means for adjusting the flow rate of water supplied to the heat exchanger by the heat exchange amount adjustment means so that the temperature detected by the heat exchange temperature sensor becomes a predetermined drain prevention temperature. The present invention relates to improvement of a water heater.

Details of the flow type water heating apparatus will be described later, but when the burner has a constant combustion amount,
The higher the flow rate of water supplied to the heat exchanger and the lower the hot water outlet temperature of the heat exchanger, the higher the heat efficiency of the heat exchanger. Further, the smaller the combustion amount of the burner, the lower the temperature around the heat exchanger and the more likely drain is generated in the heat exchanger, the higher the lower limit temperature at which no drain is generated in the heat exchanger.

Therefore, when the drain prevention temperature is set to a constant value, it is necessary to set the drain prevention temperature to a temperature at which no drain is generated in the heat exchanger when the combustion amount of the burner is set to the minimum value. is there. However, in this case, when the combustion amount of the burner is larger than the minimum setting, the heat exchange amount control is performed so that the hot water outlet temperature of the heat exchanger is higher than the lower limit temperature at which drain does not actually occur. The means controls the flow rate of water supplied to the heat exchanger. As a result, the flow rate of water supplied to the heat exchanger is
The thermal efficiency of the heat exchanger will not be optimal as it is less than the minimum flow rate actually required to prevent drainage.

Therefore, according to the present invention, the storage means for storing beforehand the correlation data between the burner combustion amount and the lower limit temperature at which the drainage does not occur in the heat exchanger, and the target combustion amount based on the correlation data And a drain prevention temperature setting means for setting the drain prevention temperature near the corresponding lower limit temperature.

According to the present invention, the drain prevention temperature setting means sets the drain prevention temperature near the lower limit temperature corresponding to the target combustion amount based on the correlation data. Then, the flow rate of water supplied to the heat exchanger is adjusted by the heat exchange amount control means so that the temperature detected by the heat exchange temperature sensor becomes the drain prevention temperature set in this way. Therefore, control is performed so that the flow rate of water supplied to the heat exchanger is maximized within a range where drainage does not occur in the heat exchanger, and thereby the thermal efficiency of the heat exchanger can be increased.

The heat exchanger heats the water supplied from the water supply pipe and discharges the hot water to the hot water supply pipe, bypasses the heat exchanger and bypasses the water supply pipe and the hot water supply pipe.
By-pass ratio adjusting means for adjusting the bypass ratio, which is the ratio of the flow rate of water flowing through the heat exchanger and the flow rate of water flowing through the bypass pipe, the hot-water supply pipe and the bypass pipe And a hot water supply temperature sensor for detecting the temperature of hot water supplied to the downstream side of the confluence point, the target combustion amount determining means, as the predetermined condition, the detected temperature of the hot water supply temperature sensor is a predetermined target hot water supply temperature. The target combustion amount is determined so as to match, and the thermal AC amount control means adjusts the flow rate of water supplied to the heat exchanger by changing the bypass ratio by the bypass ratio adjusting means. Is characterized by.

According to the present invention, the hot water having the target hot water supply temperature is provided at the downstream of the confluence of the hot water supply pipe and the bypass pipe without changing the flow rate of the water supplied from the water supply pipe. When controlling the combustion amount of the burner to be supplied, the heat exchange amount control unit changes the bypass ratio to adjust the flow rate of water supplied to the heat exchanger, By setting the hot water outlet temperature to the drain preventive temperature set by the drain preventive temperature setting means, it is possible to enhance the thermal efficiency of the heat exchanger when hot water is supplied at the target hot water supply temperature.

Further, the heat exchanger communicates with a bath via a circulation circuit, and a pump for circulating water in the bath via the circulation circuit and the heat exchanger, and a temperature of hot water in the bath are controlled. The target combustion is equipped with a bath temperature sensor for detecting, and a circulation flow rate adjusting means for adjusting the flow rate of water circulating in the circulation circuit by changing the flow rate of the pump water, which is the heat exchange amount adjusting means. The amount determining means determines the target combustion amount according to a difference between a predetermined target heating temperature and a temperature detected by the bath temperature sensor as the predetermined condition, and the thermal AC amount control means controls the circulation flow rate. By changing the flow rate of water circulating in the circulation circuit by means, the flow rate of water supplied to the heat exchanger is adjusted.

According to the present invention, the hot water in the bathtub is reheated by circulating it through the heat exchanger, and the hot water in the bathtub is heated according to the difference between the temperature detected by the bath temperature sensor and the target hot water supply temperature. When controlling the combustion amount of the burner, the heat exchange amount control means adjusts the flow rate of water supplied to the heat exchanger by the circulation flow rate adjusting means,
By setting the hot water outlet temperature of the heat exchanger to the drain prevention temperature set by the drain prevention temperature setting means,
The heat efficiency of the heat exchanger when reheating the hot water in the bathtub can be improved.

Further, the heat exchanger communicates with a heating terminal via a circulation circuit, supplies water heated by the heat exchanger to the heating terminal via the circulation circuit, and radiates heat at the heating terminal. A pump for recovering the recovered water to the heat exchanger, a bypass pipe for bypassing the heat exchanger to connect the upstream side and the downstream side of the circulation circuit, and the heat exchange amount adjusting means for the heat exchange. Ratio adjusting means for adjusting a bypass ratio, which is the ratio of the flow rate of water flowing through the bypass pipe to the flow rate of water flowing through the bypass pipe, and hot water supplied to the downstream side of the confluence of the circulation circuit and the bypass pipe. The target combustion amount determining means determines the target combustion amount so that the temperature detected by the hot water supply temperature sensor matches the predetermined target hot water supply temperature as the predetermined condition. , The heat Flow control means, and adjusting the flow rate of water supplied to the heat exchanger by changing the bypass ratio by the bypass ratio adjustment means.

According to the present invention, in the case of controlling the combustion amount of the burner so that hot water having the target hot water supply temperature is supplied to the heating terminal, the heat exchange amount control means is the circulation flow rate adjusting means. By adjusting the flow rate of the water supplied to the heat exchanger by setting the hot water outlet temperature of the heat exchanger to the drain prevention temperature set by the drain prevention temperature setting means, heat is radiated from the heating terminal. The heat efficiency of the heat exchanger when heating can be improved.

The burner is composed of a plurality of burner blocks, and the storage means stores, for each combination of burner blocks to be burned, a burned amount of the burner and a lower limit temperature at which drainage does not occur in the heat exchanger. Correlation data is stored, the drain prevention temperature setting means selects the correlation data according to a combination of burner blocks during combustion, and sets the drain prevention temperature based on the selected correlation data. And

According to the present invention, the burner is composed of a plurality of burner blocks, and the amount and path of the combustion exhaust gas flowing around the heat exchanger changes depending on the combination of the burner blocks to be burned. Therefore, depending on the combination of burner blocks to be burned, the lower limit temperature at which drainage does not occur in the heat exchanger also changes depending on the combustion amount of the burners.

Therefore, for each combination of burner blocks to be burned, correlation data between the burned amount of the burner and the lower limit temperature at which drainage does not occur in the heat exchanger is stored in the storage means, and the burner during burning is stored. By selecting the correlation data according to the combination of the blocks, the drain prevention temperature corresponding to the combination of the burner blocks to be burned can be appropriately set.

Further, the drain prevention temperature setting means sets the drain prevention temperature higher than the lower limit temperature by a predetermined temperature or more within a predetermined time after the burner is ignited.

According to the present invention, the drain prevention temperature is set higher than the lower limit temperature by the drain prevention temperature setting means within the predetermined time after the burner is ignited. As a result, the heat exchange amount control means controls to reduce the flow rate of water supplied to the heat exchanger in order to raise the temperature of the hot water discharged from the heat exchanger, and the water is supplied to the heat exchanger. The amount of heat absorbed by water is reduced and the heat exchanger can be heated quickly. Therefore, immediately after the burner is ignited, it is possible to shorten the time in which the temperature of the heat exchanger is low and a state where drainage is likely to occur is shortened.

[0023]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described with reference to FIGS. 1 is an overall configuration diagram of a hot water supply apparatus with a reheating function according to the first embodiment of the present invention, FIGS. 2 to 3 are operation flowcharts of the hot water supply apparatus shown in FIG. 1, and FIG. 4 is a hot water supply apparatus shown in FIG. FIG. 5 is a graph showing the relationship between the burner combustion amount and the heat efficiency of the heat exchanger in the apparatus, and a diagram showing a correlation map for determining the drain prevention temperature from the burner combustion amount. FIG. 5 shows the second embodiment of the present invention. It is a whole block diagram of the heating heat source device in a form.

First, a first embodiment will be described with reference to FIGS. With reference to FIG. 1, a hot water supply device 1 which is a flow-type water heating device of the present invention includes a hot water supply unit 4 that heats water supplied from a water supply pipe 2 and supplies it to a hot water supply pipe 3, and water in a bathtub 5. And a reheating section 7 for reheating through a reheating circulation circuit 6 (a reheating forward pipe 6a and a reheating return pipe 6b, which correspond to the circulation circuit of the present invention).

In the hot water supply unit 4, a hot water supply heat exchanger 10 (corresponding to the heat exchanger of the present invention) communicating with the hot water supply pipes 2 and 3 and a hot water supply burner 11 (the present invention) for heating the hot water supply heat exchanger 10 are provided. Hot water supply burner 11), a hot water supply spark plug 12 for igniting the hot water supply burner 11, an igniter 13 that applies a high voltage to the hot water supply spark plug 12, a hot water supply frame rod 14 that detects the presence or absence of combustion flames in the hot water supply burner 11, and a hot water supply. Hot water supply combustion fan 15 (corresponding to the combustion amount adjusting means of the present invention) for supplying combustion air to the burner 11, and the hot water supply heat exchanger 1
A hot water supply heat exchange temperature sensor 16 (corresponding to the heat exchange temperature sensor of the present invention) for detecting the temperature of hot water discharged from 0 is provided.

The hot water supply burner 11 is composed of a first burner block 11a (corresponding to the burner block of the present invention) and a second burner block 11b (corresponding to the burner block of the present invention).

The water supply pipe 2 is provided with a water supply flow rate sensor 20 for detecting the water supply flow rate, a water supply temperature sensor 21 for detecting the water supply temperature, and a water supply servo valve 22 for adjusting the water supply flow rate. Further, a bypass servo valve 31 (corresponding to a bypass ratio adjusting means of the present invention) that adjusts the opening degree of the bypass pipe 30 is connected to the bypass pipe 30 that bypasses the hot water heat exchanger 10 and connects the hot water pipe 2 and the hot water pipe 3. ) Is provided, and a hot water supply temperature sensor 32 that detects the hot water supply temperature is provided downstream of the confluence of the hot water supply pipe 3 and the bypass pipe 30.

Further, in the hot water supply unit 4, a source solenoid valve 41 for opening and closing the gas supply pipe 40 to which the fuel gas is supplied, and a hot water supply gas proportional valve for adjusting the opening degree of the hot water supply gas pipe 42 branched from the gas supply pipe 40. 43 (corresponding to the combustion amount adjusting means of the present invention), a first switching solenoid valve 44 for switching supply / cutoff of fuel gas from the hot water supply gas pipe 42 to the first burner block 11a.
a, and the hot water supply gas pipe 42 to the second burner block 11b
Second switching solenoid valve 4 for switching the supply / cutoff of fuel gas to / from
4b is provided.

On the other hand, the reheating section 7 includes a reheating circulation circuit 6
A reheating heat exchanger 50 (corresponding to the heat exchanger of the present invention) communicating with the reheating burner 51 (corresponding to the burner of the present invention) for heating the reheating heat exchanger 50, and a reheating burner 51.
-Fired flame plug 5 for igniting the flame, and flame-fired frame rod 5 for detecting the presence or absence of combustion flame in the flame-burner 51
3, a reheating combustion fan 54 for supplying combustion air to the reheating burner 51, a reheating heat exchange temperature sensor 55 (heat exchange temperature sensor of the present invention for detecting the temperature of hot water discharged from the reheating heat exchanger 50) Reheating pump 56 (corresponding to the pump of the present invention) for circulating the hot water in the bathtub 5 into the reheating circulation circuit 6, and circulation for detecting the presence or absence of water in the reheating circulation circuit 6 Water flow switch 57, bath temperature sensor 58 for detecting the temperature of the hot water in bath 5 flowing in reheating return pipe 6b, and reheating gas for adjusting the opening of reheating gas pipe 60 branched from gas supply pipe 40 A proportional valve 61 is provided.

Further, a hot water filling relay pipe 70 for communicating the hot water supply pipe 3 with the circulation circuit 6 is provided, and a hot water filling relay valve 71 for opening and closing the hot water filling relay pipe 70 is provided at an intermediate position of the hot water filling pipe 70. A water filling flow rate sensor 72 for detecting the flow rate of the hot water flowing through the water filling relay pipe 70 is provided.

The controller 80 (including the functions of the target combustion amount determining means, the combustion amount controlling means, the heat AC amount controlling means, the storing means, and the drain prevention temperature setting means of the present invention) constituted by a microcomputer or the like is used. The operation of the hot water supply device 1 is controlled.

The controller 80 is connected to a remote controller 81 for instructing to start / stop the hot water supply device 1, setting operating conditions, and displaying the operating status of the hot water supply device 1 and various instruction signals from the remote controller 81. , Hot water supply frame rod 14, hot water supply heat exchange temperature sensor 16, water supply flow rate sensor 2
0, the water supply temperature sensor 21, the hot water supply temperature sensor 32, the additional heating frame rod 53, the additional heating heat exchange temperature sensor 55, the circulating water flow switch 57, the bath temperature sensor 58, and the detection signals from the filling water flow sensor 72 are input. It

The igniter 13 and the hot water supply combustion fan 1 are controlled by the control signal output from the controller 80.
5, water supply servo valve 22, bypass servo valve 31, former solenoid valve 41, hot water supply gas proportional valve 43, first switching solenoid valve 44a,
The operations of the second switching electromagnetic valve 44b, the additional combustion fan 54, the additional pump 56, the additional gas proportional valve 61, and the hot water relay valve 71 are controlled.

Next, the procedure of executing the hot water supply operation by the controller 80 will be described with reference to the flow charts shown in FIGS. When the controller 80 detects that the water supply from the water supply pipe 2 is started by the detection signal of the water supply flow rate sensor 20, the controller 80 from STEP 1 to STEP 2 in FIG.
Then, the ignition process of the hot water supply burner 11 is performed. That is, in a state where the hot water supply combustion fan 15 is operated and a high voltage is applied to the hot water supply spark plug 12 by the igniter 13 to cause spark discharge, the original solenoid valve 41 and the hot water supply gas proportional valve 4 are provided.
3, first switching solenoid valve 44a, and second switching solenoid valve 44b
Is opened to supply fuel gas to the hot water supply burner 11 to ignite the hot water supply burner 11.

Then, the controller 80 uses STEP3
Starts the 1-minute timer. The 1-minute timer controls the flow rate of water supplied to the hot water supply heat exchanger 10 until 1 minute (corresponding to a predetermined time of the present invention) elapses after ignition of the hot water supply burner 11 by the processing of STEP 20 described later. This is for reducing the amount of water to quickly heat the hot water supply heat exchanger 10.

At the next STEP 4, the controller 80
According to the water supply temperature from the water supply pipe 2 detected by the water supply temperature sensor 21, the water supply flow rate from the water supply pipe 2 detected by the water supply flow rate sensor 20, and the target hot water supply temperature set by the remote controller 81, the target A target combustion amount (Qa) of hot water supply burner 11 that can obtain hot water at a hot water supply temperature is determined. Then, hot water supply burner 11 is adjusted so that the actual hot water supply temperature detected by hot water supply temperature sensor 32 matches the target hot water supply temperature.
The target combustion amount (Qa) of is finely adjusted.

At the subsequent STEP 5, the controller 80
The rotation speed of the hot water supply combustion fan 15 is adjusted to control the supply flow rate of the combustion air to the hot water supply burner 11 and the hot water supply gas proportional valve 43 so that the combustion amount of the hot water supply burner 11 becomes the target combustion amount (Qa). Thus, the opening of the hot water supply gas pipe 42 is adjusted to control the supply flow rate of the fuel gas to the hot water supply burner 11.

STEP 4 corresponds to the processing by the target combustion amount determining means of the present invention, and STEP 5 corresponds to the processing of the combustion control means of the present invention.

Then, in the next STEP 6, the controller 80 stores the target combustion amount (Qa) and the drain prevention shown in FIG. 4 (b), which are stored in advance in a memory (not shown, which corresponds to the storage means of the present invention). Correlation map showing the correlation with temperature (Td) (corresponding to the correlation data of the present invention.
/ Td map), the target combustion amount (Qa) determined in STEP 4 is applied to obtain the drain prevention temperature (Td) corresponding to the target combustion amount (Qa). Note that STEP 6 corresponds to the processing by the drain prevention temperature setting means of the present invention.

The Qa / Td map shown in FIG. 4 (b) shows the target combustion amount (Qa, abscissa) measured in advance by experiments and when the hot water supply burner 11 is burned at the target combustion amount (Qa). Is a map of the correlation data with the lower limit temperature of the hot water supply heat exchanger 10 required to prevent drainage from occurring in the hot water supply heat exchanger 10, and shows the solid-state difference of the hot water supply heat exchanger 10. In consideration of the above, the drain prevention temperature (Td) is set to a temperature slightly higher (for example, 2 ° C.) than the measured lower limit temperature.

The controller 80 controls the hot water supply heat so that the temperature detected by the hot water supply heat exchange temperature sensor 16 is equal to or higher than the drain prevention temperature (Td) obtained by applying the target combustion amount (Qa) to the Qa / Td map. By controlling the flow rate of the water supplied to the exchanger 10, it is possible to prevent drainage from occurring from the hot water supply heat exchanger 10 and deterioration of the hot water supply heat exchanger 10 due to adhesion of the drainage.

FIG. 4 (b) shows a correlation map when both the first hot water supply burner 11a and the second hot water supply burner 11b are burned (total combustion), and is the first hot water supply burner 11a only. The correlation map of the case (1/2 combustion) is shown. As shown in FIG. 2B, since the drain prevention temperature at the target combustion amount (Qa) is different between the case of 1/2 combustion and the case of full combustion, Q for 1/2 combustion is obtained.
By preparing the a / Td map () and the Qa / Td map () for all combustion, the drain prevention temperature (Td) can be set more accurately.

When the 1-minute timer has not timed up in STEP 7 (1 minute has not elapsed from the ignition of the hot water supply burner 11), the process branches to STEP 20, and the controller 80 causes the drain prevention temperature (Td). Is set higher by 5 ° C. As a result, the temperature of the hot water supply heat exchanger 10 is promptly raised at the start of hot water supply, and the time during which the temperature of the hot water supply heat exchanger 10 is low after the hot water supply is started and drainage easily occurs is shortened.

Further, FIG. 4 (a) shows that when the flow rate of water supplied to the hot water supply heat exchanger 10 is changed in a state in which the hot water supply burner 11 is burned with a certain amount of combustion, the water from the hot water supply heat exchanger 10 is changed. 5 is a graph showing a relationship between a hot water outlet temperature (Tout) and a thermal efficiency (α) of the hot water supply heat exchanger 10. As is clear from the graph of FIG. 4A, if the combustion amount of the hot water supply burner 11 is constant, the flow rate of water supplied to the hot water supply heat exchanger 10 is increased and the temperature of hot water discharged from the hot water supply heat exchanger 10 ( The lower the Tout), the higher the thermal efficiency (α) of the hot water supply heat exchanger 10.

Therefore, in STEP 8 of FIG. 3, the controller 80 controls the bypass servo valve 31 so that the temperature detected by the hot water supply heat exchange temperature sensor 16 becomes the drain prevention temperature (Td).
Adjust the bypass ratio by. As a result, the hot water supply heat exchanger 10 can be used with respect to the target combustion amount (Qa) of the hot water supply burner 11.
Is controlled so that the flow rate of water supplied to the hot water supply heat exchanger 10 is maximized within a range where drainage does not occur.
The heat efficiency of the hot water supply heat exchanger 10 can be improved. Note that STEP8 corresponds to the processing by the heat exchange amount control means of the present invention.

Then, in the subsequent STEP 9, when the water supply flow sensor 20 detects the water supply from the water supply pipe 2, the process returns to STEP 4 in FIG. 2 to continue the hot water supply operation, and when the water supply from the water supply pipe 2 is not detected, Proceeding to STEP 10, the combustion of the hot water supply burner 11 is stopped, the hot water supply operation is terminated, and the process returns to STEP 1 in FIG.

Next, the controller 80 has a remote controller 81.
When the instruction to fill the bathtub 5 is issued, the filling relay valve 71 is opened to start the filling operation.

When the hot water filling relay valve 71 is opened, water supply from the water supply pipe 2 is started, and as in the case of the hot water supply operation described above, the controller 80 causes the remote controller 81 to detect the temperature detected by the hot water supply temperature sensor 32. The target combustion amount (Qa) of the hot water supply burner 11 is determined so as to reach the set target filling temperature, and the detected temperature of the hot water supply heat exchange temperature sensor 16 applies the target combustion amount (Qa) to the Qa / Td map. The bypass servo valve 31 adjusts the bypass ratio so that the drain prevention temperature (Td) is set. As a result, the thermal efficiency of the hot water supply heat exchanger 10 during the filling operation is improved.

Then, the controller 80 calculates the cumulative amount of hot water supplied to the bathtub 5 from the detection signal of the hot water flow sensor 72, and when the cumulative amount reaches the target amount of hot water set by the remote controller 81. Then, the water filling relay valve 71 is closed to end the water filling operation.

Next, when an instruction for additional heating is given by the remote controller 81, the controller 80 starts the additional heating operation.

In the reheating operation, the controller 80
Operates the reheating pump 56 (corresponding to the pump of the present invention) to supply the water in the bathtub 5 to the reheating heat exchanger 50 via the circulation return pipe 6b, and the hot water heating exchanger 50 discharges hot water. By returning the hot water to be returned to the bathtub 5 through the circulation outflow pipe 6a, the water in the bathtub 5 is reheated.

The controller 80 includes the additional combustion fan 5
4 is operated and the spark ignition is generated in the reheating ignition plug 52 by the igniter 13, and the original solenoid valve 41 and the reheating gas proportional valve 61 are opened to supply the fuel gas to the reheating burner 51. The additional burner 51 is ignited.

Then, the controller 80 first controls the combustion amount of the additional heating burner 51 with the maximum capacity of the additional heating burner 51 as the target combustion amount (Qa), and the bath temperature sensor 58.
After the difference between the detected temperature of No. 1 and the target heating temperature set by the remote controller 81 becomes equal to or lower than the predetermined temperature, 1/2 of the maximum capacity of the additional heating burner 51 is set as the target combustion amount (Qa) and the additional heating burner 51. Control the combustion amount of.

When the temperature detected by the bath temperature sensor 58 reaches the target heating temperature, the controller 80
The original electromagnetic valve 41 and the additional heating gas proportional valve 61 are closed to stop the combustion of the additional heating burner 51, and the operations of the additional heating combustion fan 54 and the additional heating pump 56 are stopped to end the additional heating operation.

Here, the controller 80 sets the drain prevention temperature (Td) corresponding to the combustion amount at the maximum capacity of the reburning burner 51 and the drain prevention temperature (Td) corresponding to the combustion amount at half the maximum capacity. The data is stored in the memory in advance. The data of the drain prevention temperature (Td) corresponding to the combustion amount at the maximum capacity and the combustion amount at 1/2 of the maximum capacity correspond to the correlation data of the present invention, and the drain prevention temperature (Td) is the above-mentioned hot water supply. Similar to the case of the heat exchanger 10, it is determined in advance by experiments or the like.

During the reheating operation, the controller 80 causes the temperature detected by the reheating heat exchange temperature sensor 55 to be the drain prevention temperature (Td) corresponding to the target combustion amount (Qa) of the reheating burner 51. The amount of water supplied by the reheating pump 56 is adjusted to control the flow rate of water supplied to the reheating heat exchanger 50, thereby improving the thermal efficiency of the reheating heat exchanger 50.

Next, a second embodiment of the present invention will be described with reference to FIG. A heating heat source device 100 which is a flow-type water heating device of the present invention includes a heating circulation circuit 101.
The floor heating terminal 102 (corresponding to the heating terminal of the present invention) is connected via (the heating outflow pipe 101a, the heating return pipe 101b, and the circulation circuit of the present invention), and the heating circulation circuit 1
Hot water is supplied to the floor heating terminal 102 via 01. Then, as a result, the floor heating terminal 102 radiates heat.

The heating heat source device 100 includes the heating circulation circuit 1
Heating heat exchanger 110 and heating heat exchanger 11 communicating with 01
Heating burner 111 for heating 0, heating ignition plug 112 for igniting heating burner 111, heating ignition plug 1
Heating frame rod 1 for detecting the presence or absence of combustion flame of igniter 113 and heating burner 111 for applying a high voltage to 12
14, a heating combustion fan 115 that supplies combustion air to the heating burner 111, and a heating heat exchange temperature sensor 116 that detects the temperature of hot water discharged from the heating heat exchanger 110.

A bypass servo valve 121 for adjusting the opening of the bypass pipe 120 is provided in the bypass pipe 120 that bypasses the heating heat exchanger 110 and connects the heating outflow pipe 101a and the heating return pipe 101b. Outgoing pipe 10
A hot water supply temperature sensor 122 that detects the temperature of hot water supplied to the floor heating terminal 102 is provided downstream of the confluence of the 1a and the bypass pipe 120.

Further, the heating heat source device 100 has a heating pump 12 for circulating hot water in the heating circulation circuit 101.
3 (corresponding to the pump of the present invention), a source solenoid valve 131 for opening and closing the gas supply pipe 130 to which the fuel gas is supplied, and a heating gas proportional valve 132 for adjusting the opening of the gas supply pipe 130.

Then, a controller 140 (a target combustion amount determining means, a combustion amount controlling means, a heat AC amount controlling means, a storing means, and
The operation of the heating heat source device 100 is controlled by (including the function of the drain prevention temperature setting means).

The controller 140 includes the floor heating terminal 10
The remote controller 141 for instructing the operation / stop of 2 and setting the condition of the heating operation and displaying the operating status of the heating heat source device 100 is connected, and various instruction signals from the remote controller 141, the heating frame rod 114, and the heating heat. Exchange temperature sensor 116, hot water supply temperature sensor 122, and remote controller 141
And the detection signal of the room temperature sensor 142 provided in.

The control signals output from the controller 140 control the operations of the igniter 113, the heating combustion fan 115, the original electromagnetic valve 131, the heating gas proportional valve 132, the bypass servo valve 121, and the heating pump 123.

When the remote controller 141 instructs the controller 140 to start the heating operation, the controller 140 controls the heating pump 1
23 is operated to send the water heated by the heating heat exchanger 110 to the floor heating terminal 102 through the heating outflow pipe 101a, and the water radiated by the floor heating terminal is returned to the heating return pipe 101a.
The heating operation for recovering to the heating heat exchanger 110 via b is started.

The controller 140 first operates the heating combustion fan 115 to open the original solenoid valve 131 and the heating proportional valve 132 in the state where the ignition spark 113 is generated in the heating ignition plug 112, thereby opening the heating burner. 11
1, the fuel gas is supplied to ignite the heating burner 111.

Then, controller 140 determines the target combustion amount (Qa) of heating burner 111 so that the temperature detected by hot water supply temperature sensor 122 becomes a predetermined hot water supply target temperature (for example, 80 ° C.), and heating burner 111 is heated. The rotation speed of the heating combustion fan 115 is adjusted to control the supply flow rate of the combustion air to the heating burner 111 so that the combustion amount becomes the target combustion amount (Qa), and the heating gas proportional valve 132 supplies the gas. The flow rate of the fuel gas supplied to the heating burner 111 is controlled by adjusting the opening degree of the pipe 130.

Further, the controller 140 operates the heating pump 123 to supply the hot water heated by the heating heat exchanger 110 to the floor heating terminal 102 via the heating circulation circuit 101, and thereby the floor heating terminal 102. The room in which the floor heating device 102 is installed is heated by heat radiation from the room.

Here, in the memory (not shown) of the controller 140, the target combustion amount (Qa) to the target combustion amount (Qa) of the heating burner 111 is stored in the memory (not shown) as in the controller 80 of the first embodiment. The Qa / Td map for obtaining the drain prevention temperature (Td) corresponding to is stored in advance.

Then, the controller 140 applies the target combustion amount (Qa) to the Qa / Td map to determine the drain prevention temperature (Td) corresponding to the target combustion amount (Qa), and the heating heat exchange temperature sensor 116. The opening degree of the bypass servo valve 121 is adjusted to control the flow rate of the hot water supplied to the heating heat exchanger 110 so that the detected temperature of 1 is the drain prevention temperature (Td).

In this way, the heating operation is performed by controlling the flow rate of the water supplied to the heating heat exchanger 110 so that the temperature of the hot water discharged from the heating heat exchanger 110 becomes the drain prevention temperature (Td). The heat efficiency of the heating heat exchanger 110 at the time can be made better.

Further, the controller 140 interrupts the heating operation when the temperature detected by the room temperature sensor 142 exceeds the target room temperature set by the remote controller 141, and the room temperature sensor 1
The detected temperature of 42 is a predetermined temperature (for example, 2
By restarting the heating operation when it goes down,
The control is performed so that the temperature in the room becomes almost the target room temperature.

In the first and second embodiments, the target combustion quantity (Q
Map data (a) that maps the correspondence relationship between (a) and the drain prevention temperature (Td) set to a predetermined temperature higher than the lower limit temperature at which drain does not occur from the heat exchanger at the target combustion amount (Qa) determined by experiments or the like. Qa / Td map) was used, but the map data in which the correspondence relationship between the target combustion amount (Qa) and the lower limit temperature at which drainage does not occur from the heat exchanger at the target combustion amount (Qa) is mapped is used as the correlation of the present invention. The drain prevention temperature (Td) may be set as a temperature higher than the lower limit temperature obtained by applying the target combustion amount (Qa) to the correlation data.

In the first and second embodiments, the map data (Qa
/ Td map), the target combustion amount (Qa) is input and the drain prevention temperature (T) corresponding to the target combustion amount (Qa) is input.
You may use the mathematical formula data which outputs d).

In the hot water supply operation of the first embodiment, the drain prevention temperature (Td) is set high until the predetermined time elapses from the start of heating the heat exchanger, and the temperature of the heat exchanger is quickly increased. However, even if this process is not performed, the effect of the present invention can be obtained.

Further, as in the case of the hot water supply operation of the first embodiment, heat exchange is also performed in the hot water filling operation and the reheating operation of the first embodiment, and in the second embodiment. From the start of heating the vessel until a predetermined time has passed,
You may perform the process which raises the temperature of a heat exchanger rapidly by setting drain prevention temperature (Td) high.

Further, in the first embodiment, the hot water supply burner 11 composed of the two burner blocks of the first burner block 11a and the second burner block 11b is shown, but the hot water supply burner is composed of three or more burner blocks. May be configured. In this case, the correlation data between the target combustion amount (Qa) and the drain prevention temperature (Td) is prepared for each combination of burner blocks to be burned and stored in the memory in advance, and the burner blocks to be burned are combined. The drain prevention temperature may be determined based on the correlation data selected accordingly.

In addition, the reheating burner 51 and the heating burner 1
Similarly to hot water supply burner 11, 11 may be composed of a plurality of burner blocks.

[Brief description of drawings]

FIG. 1 is an overall configuration diagram of a hot water supply device with a reheating function according to a first embodiment of the present invention.

2 is an operation flowchart of the hot water supply device shown in FIG.

3 is an operation flowchart of the hot water supply device shown in FIG.

4 is a graph showing the relationship between the burner combustion amount and the heat efficiency of the heat exchanger in the hot water supply device shown in FIG. 1, and a diagram showing a correlation map for determining the drain prevention temperature from the burner combustion amount.

FIG. 5 is an overall configuration diagram of a heating heat source device according to a second embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Hot water supply device with a reheating function, 4 ... Hot water supply part, 7 ... Reheating part, 10 ... Hot water supply heat exchanger, 11 ... Hot water supply burner, 15 ... Hot water supply combustion fan, 16 ... Hot water supply heat exchange temperature sensor, 30 ... Bypass pipe , 31 ... Bypass servo valves 31, 50 ... Reheating heat exchanger, 51 ... Reheating burner, 54 ... Reheating combustion fan, 55 ... Reheating heat exchange temperature sensor, 56 ... Reheating circulation pump, 100 ... Heating heat source device , 103 ... Floor heating terminal, 1
10 ... Heating heat exchanger, 111 ... Heating burner, 115 ... Heating combustion fan, 116 ... Heating heat exchange temperature sensor, 120 ...
Bypass pipe, 121 ... Bypass servo, 123 ... Heating circulation pump, 140 ... Controller

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) F24D 3/00 F24D 3/00 S F24H 1/00 602 F24H 1/00 602G F term (reference) 3L024 CC25 DD13 DD14 DD17 DD22 DD27 DD28 GG03 GG04 GG05 GG24 HH13 HH14 HH15 HH17 HH26 3L034 CA04 DA02 DA05 DA06 3L070 AA02 BB02 BB03 BB18 DD02 DD08 DE09 DF06 DF07 DG02 DG05 DG07

Claims (6)

[Claims] 1. A heat exchanger for heating supplied water to discharge hot water, a burner for heating the heat exchanger, a combustion amount adjusting means for adjusting a combustion amount of the burner, and a burner for controlling a combustion amount according to a predetermined condition. Target combustion amount determining means for determining the target combustion amount of the burner, combustion amount control means for controlling the combustion amount of the burner to the target combustion amount by the combustion amount adjusting means, and hot water discharged from the heat exchanger. A heat exchange temperature sensor for detecting a temperature, a heat exchange amount adjusting means for adjusting a flow rate of water supplied to the heat exchanger, and the temperature detected by the heat exchange temperature sensor being a predetermined drain prevention temperature. In a flow-type water heating apparatus including a heat exchange amount control means for adjusting the flow rate of water supplied to a heat exchanger by the heat exchange amount adjustment means, a combustion amount of the burner and a drain are generated in the heat exchanger. No correlation data with lower limit temperature Flow-type water characterized in that the flow-type water is provided with storage means stored therein and drain prevention temperature setting means for setting the drain prevention temperature near the lower limit temperature corresponding to the target combustion amount based on the correlation data. Heating device. 2. The heat exchanger heats water supplied from a water supply pipe to discharge the water to a hot water supply pipe, bypasses the heat exchanger, and a bypass pipe communicating the water supply pipe with the hot water supply pipe. By-pass ratio adjusting means for adjusting the bypass ratio, which is the ratio of the flow rate of water flowing through the heat exchanger and the flow rate of water flowing through the bypass pipe, the hot-water supply pipe and the bypass pipe A hot water supply temperature sensor for detecting the temperature of hot water supplied to the downstream side of the confluence point with, the target combustion amount determining means, as the predetermined condition, the detected temperature of the hot water supply temperature sensor is a predetermined target hot water supply temperature. The target combustion amount is determined so as to match, and the heat exchange amount control unit adjusts the flow rate of water supplied to the heat exchanger by changing the bypass ratio by the bypass ratio adjustment unit. Characterized by Flow type water heating device according to claim 1. 3. The heat exchanger communicates with a bath via a circulation circuit, a pump for circulating water in the bath via the circulation circuit and the heat exchanger, and a temperature of hot water in the bath. The target combustion is provided with a bath temperature sensor for detecting, and a circulating flow rate adjusting means for adjusting the flow rate of water circulating in the circulation circuit by changing the water flow rate of the pump, which is the heat exchange amount adjusting means. The amount determining means determines the target combustion amount according to a difference between a predetermined target heating temperature and a temperature detected by the bath temperature sensor as the predetermined condition, and the thermal AC amount control means controls the circulation flow rate. The flow type water heating apparatus according to claim 1, wherein the flow rate of water supplied to the heat exchanger is adjusted by changing the flow rate of water circulating in the circulation circuit by means. 4. The heat exchanger communicates with a heating terminal via a circulation circuit, supplies water heated by the heat exchanger to the heating terminal via the circulation circuit, and radiates heat at the heating terminal. A pump for recovering the recovered water to the heat exchanger, a bypass pipe bypassing the heat exchanger and connecting the upstream side and the downstream side of the circulation circuit, and the heat exchange amount adjusting means for the heat exchange. Ratio adjusting means for adjusting a bypass ratio, which is the ratio of the flow rate of water flowing through the bypass pipe to the flow rate of water flowing through the bypass pipe, and hot water supplied to the downstream side of the confluence of the circulation circuit and the bypass pipe. The target combustion amount determination means determines the target combustion amount so that the temperature detected by the hot water supply temperature sensor matches a predetermined target hot water supply temperature as the predetermined condition. , The heat exchange The flow type water heating apparatus according to claim 1, wherein the amount control means adjusts a flow rate of water supplied to the heat exchanger by changing the bypass ratio by the bypass ratio adjusting means. 5. The burner is composed of a plurality of burner blocks, and the storage means stores, for each combination of burner blocks to be burned, a combustion amount of the burner and a lower limit temperature at which drainage does not occur in the heat exchanger. Correlation data is stored, the drain prevention temperature setting means selects the correlation data according to a combination of burner blocks during combustion, and sets the drain prevention temperature based on the selected correlation data. The flow-type water heating device according to claim 1, wherein 6. The drain prevention temperature setting means sets the drain prevention temperature higher than the lower limit temperature by a predetermined temperature or more within a predetermined time after the burner is ignited. To any one of claims 5 to 5
Flow type water heating apparatus according to the item.