JP3848726B2 - Water heater - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a so-called single-can double water channel type hot water supply apparatus.
[0002]
[Prior art]
The single-can double-water channel hot-water supply device has been developed to reduce the size. A simple explanation will be given by taking, as an example, a one-can / two-channel hot-water supply device with a memorial function, and a common heat exchanger and a common burner are accommodated in one can. Two heat receiving pipes penetrate this heat exchange section. One heat receiving pipe is provided as part of the hot water supply system, and the other heat receiving pipe is provided as part of the memory system. The hot water supply system has, in addition to the heat receiving pipe, a water supply pipe and a hot water supply pipe connected to both ends of the heat receiving pipe. A hot water tap is provided at the end of the hot water supply pipe.
[0003]
In the hot water supply apparatus having the above configuration, at the time of chasing, a pump provided in the chasing system is driven to circulate the bath water, and the common burner is combusted. When the hot water tap is opened, water flows through the hot water supply system. At this time, the common burner is burned to supply hot water.
[0004]
In the hot water supply apparatus having the above-described configuration, the heat receiving pipes of the reheating system and the hot water supply system pass through a common heat exchanging section, and the water staying in the heat receiving pipe of the hot water supply system is common when the reheating is performed. It is heated by the combustion heat of the burner. Therefore, when hot water supply is started by opening the hot-water tap in the middle of the remedy or immediately after the completion of the remedy, there is a risk that high hot water that causes pain to the user at the initial stage of hot water supply may be discharged.
[0005]
In order to prevent the above inconvenience, the hot water supply system of the hot water supply apparatus disclosed in Japanese Utility Model Publication No. 61-7458 is provided with a bypass pipe connected in parallel to the heat receiving pipe and the hot water supply pipe, and a bypass pipe connected to the hot water supply pipe. It is equipped with a bypass valve consisting of a solenoid valve. Then, the bypass valve is opened at the initial stage of hot water supply, and the temperature of the discharged hot water is lowered by mixing the low temperature water from the water supply pipe through the bypass pipe with the high temperature hot water retained in the heat receiving pipe.
[0006]
[Problems to be solved by the invention]
In the above-described one-can / two-water-type hot water supply device with a remedy function, particularly when the bypass valve is in a closed state, the hot water cannot be supplied to the hot water supply pipe through the bypass pipe at the initial stage of hot water supply. High hot water that causes pain may be discharged.
[0007]
[Means for Solving the Problems]
  The invention of claim 1A common heat exchanger that receives combustion heat from a common burner is inserted with a heat receiving pipe of a hot water supply system and a heat receiving pipe of another system, and this hot water supply system includes the heat receiving pipe and water supply pipes connected to both ends thereof. And a hot water supply pipe, a water supply pipe, a bypass pipe connected between the hot water supply pipe and in parallel with the heat receiving pipe, and a bypass valve provided in the bypass pipe, water is supplied to the hot water supply system. When there is a request for burner combustion in a state where water does not flow and water flows to the other system, burner combustion is temporarily started, and in parallel with this, the bypass valve is operated to determine whether the operation is normal. It is characterized by comprising control means for confirming that burner combustion is continued when judged to be normal, and forcibly terminating burner combustion being executed when judged to be abnormal.
[0009]
  Claim2The invention of claim1In the hot water supply apparatus according to claim 1, a temperature sensor is provided at or near the heat receiving pipe of the hot water supply system, and the control means performs burner combustion in an initial mode in parallel with the operation check of the bypass valve. When it is determined that there is an abnormality, the burner combustion is forcibly terminated, and when it is determined that it is normal, burner combustion is executed in the full-scale mode, and in the initial mode, the temperature detected by the temperature sensor is set to the first set temperature. Combustion control is performed, and in the full-scale mode, combustion control is performed so that the temperature detected by the temperature sensor becomes a second set temperature higher than the first set temperature.
  Claim3The invention of claim1In the hot water supply apparatus described in 1), a temperature sensor is provided at or near the heat receiving pipe of the hot water supply system, and the control means starts combustion based on the temperature detected by the temperature sensor when receiving a request for burner combustion. When the combustion start time is determined, the time width from the combustion start time to the expected operation confirmation end time is detected as the detected temperature is lower. It is characterized by determining so that it may become so small that temperature is high.
  Claim4The invention of claim 1 to claim 13In the hot water supply apparatus described in (1), the bypass valve is driven by a gear motor, and a movable portion of the gear motor is provided with position detection means, and the control means operates the bypass valve based on position information from the position detection means. It is characterized by confirming.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS. FIG. 3 shows a one-can two-water channel type hot water supply apparatus having two functions of hot water supply and retreat. This hot water supply apparatus is configured by storing a common burner 2 in the lower part of one can 1 and storing a common heat exchanging unit 3 in the upper part. A fan 4 for supplying combustion air is provided at the bottom of the can 1. The means 5 for supplying gas to the burner 2 has a main electromagnetic on-off valve 5a and an electromagnetic proportional valve 5b. An ignition mechanism (not shown) is disposed in the vicinity of the burner 2.
[0011]
The heat exchanging section 3 has a large number of thin fin plates 3a, and the heat receiving pipe 11 of the hot water supply system 10 and the heat receiving pipe 21 of the tracking system 20 penetrate through the fin plate 3a.
[0012]
The hot water supply system 10 will be described in detail. A water supply pipe 12 is connected to the inlet end of the heat receiving pipe 11, and a hot water supply pipe 13 is connected to the outlet end. An open / close plug 14 is provided at the end of the hot water supply pipe 13. A water amount control valve 15 is provided in the water supply pipe 12. A bypass pipe 16 that is in parallel with the heat receiving pipe 11 is connected between the water supply pipe 12 and the hot water supply pipe 13, and a bypass valve 17 is provided in the bypass pipe 16.
[0013]
The memorial system 20 will be described in detail. A return pipe 22 is connected between the inlet end of the heat receiving pipe 21 and the circulation fitting 6a of the bathtub 6, and an outgoing pipe 23 is connected between the outlet end of the heat receiving pipe 21 and the circulation fitting 6a. The return pipe 22 is provided with a pump 24.
[0014]
Furthermore, the hot water supply apparatus has a control unit 30 (control means). The control unit 30 controls the main electromagnetic on-off valve 5a, the electromagnetic proportional valve 5b, the ignition mechanism, the fan 4, the water amount control valve 15, the bypass valve 17, and the pump 24 of the gas supply means 5. . The control unit 30 receives detection signals from various detection means. As detection means, the water flow switch 31 provided in the water supply pipe 13, the temperature sensor 32 provided in the U bend portion of the heat receiving pipe 11 located outside the can 1, and the hot water supply pipe 13 are provided upstream of the bypass pipe 16. Temperature sensor 33, temperature sensor 34 provided on the downstream side, water flow switch 35 and temperature sensor 36 provided on the return pipe 22, and the like.
[0015]
As the bypass valve 17, a gear motor driven type as shown in FIG. 4 is used. More specifically, the valve port 50 provided in the bypass pipe 16 is opened and closed by a valve body 51 that is movable in the axial direction. The valve body 51 is connected to a motor 53 via a gear train 52 and moves in the axial direction as the motor 53 rotates. The shaft (movable part) of one gear in the gear train 52 is provided with a potentiometer 55 (position detecting means), and a detection signal of the potentiometer 55 is also sent to the control unit 30.
[0016]
  Next, the operation of the hot water supply apparatus configured as described above will be described. In order to simplify the description, a general operation not including the features of the present invention will be described first. When the hot-water tap 14 is opened, water flows in the order of the water supply pipe 12, the heat receiving pipe 11, and the hot water supply pipe 13. Water flow switch provided in the water supply pipe 1231Is detected, and in response to the detection signal, the control unit 30 opens the main electromagnetic on-off valve 5a and performs an ignition operation, whereby combustion in the burner 2 is started. As a result, the fin plate 3a is heated, and as a result, the water passing through the heat receiving pipe 11 is heated and discharged from the hot water tap 14 as hot water. Note that, based on the signals from the temperature sensors 33 and 34, the opening degrees of the electromagnetic proportional valve 5b and the water amount control valve 15 are controlled so that the hot water temperature becomes the user set temperature.
[0017]
When tracking is performed, a tracking button on the control unit 30 or a remote controller (not shown) is pressed. In response to this, the control unit 30 drives the pump 24 to circulate the water in the bathtub 6 through the return pipe 22, the heat receiving pipe 21, and the forward pipe 23. Further, the combustion in the burner 2 is started by opening the main electromagnetic on-off valve 5a and performing an ignition operation. As a result, the fin plate 3a is heated, and as a result, the water from the bathtub 6 passing through the heat receiving pipe 21 is heated, and the memory is executed. When the hot water temperature of the bathtub 6 detected by the temperature sensor 36 reaches the user set temperature, the memorial process is terminated. In order to prevent idling, the start of the additional combustion is executed after confirming the ON state of the water flow switch 35.
[0018]
When performing the above-mentioned memorial alone, the combustion heat of the burner 2 is also given to the water staying in the heat receiving pipe 11 of the hot water supply system 10. For this reason, the accumulated water in the heat receiving pipe 11 becomes high temperature. In this regard, the following control devices have been devised. That is, the additional combustion is controlled based on the temperature detected by the temperature sensor 32 provided in the U bend portion of the heat receiving pipe 11 (that is, the temperature of the accumulated water in the heat receiving pipe 11). More specifically, the combustion of the burner 2 is interrupted when the detected temperature increases and reaches 75 ° C., and is restarted when the detected temperature decreases and reaches 70 ° C. By such hysteresis control, the memorization can be completed in a short time while preventing boiling of the accumulated water in the heat receiving pipe 11.
[0019]
As described above, during the execution of the remedy alone, the temperature of the accumulated water in the heat receiving pipe 11 of the hot water supply system 10 is in the range of 70 ° C. to 75 ° C., and immediately after the completion of the remedy. In the case of the residual heat, the temperature of the staying water rises to about 80 ° C. Therefore, if hot water supply is started during the remedy or immediately after the completion of the remedy, high-temperature staying water in the heat receiving pipe 11 is discharged from the hot-water tap 14 at the initial stage. In order to prevent this, the control unit 30 drives the motor 53 of the bypass valve 17 to open the bypass valve 17 in the initial stage of hot water supply. Then, the water from the water supply pipe 12 is supplied to the hot water supply pipe 13 through the bypass pipe 16, and the staying water in the heat receiving pipe 11 is mixed with the water from the bypass pipe 16 to become an appropriate temperature or low temperature, and the hot water tap 14. It is discharged from. This bypass valve 17 is opened only in the initial stage of hot water supply and then closed.
[0020]
In the initial stage of hot water supply, whether or not to open the bypass valve 17 may be selected based on the temperature detected by the temperature sensor 32 of the U-bend portion of the heat receiving pipe 11. That is, when the temperature is not painful to the user, the opening operation of the bypass valve 17 is not performed, and only when the temperature is painful to the user, the opening operation of the bypass valve 17 is performed.
Further, the opening degree of the bypass valve 17 may be adjusted in the initial stage of hot water supply according to the temperature detected by the temperature sensor 32. That is, as the detected temperature is higher, the opening degree of the bypass valve 17 is increased.
[0021]
If the bypass valve 17 does not normally open at the initial stage of hot water supply and remains closed, as described above, the hot accumulated water in the heat receiving pipe 11 may be discharged from the hot water tap 14 as it is at the initial stage of hot water supply. In order to prevent this, it is forbidden to carry out the remedy alone, which causes the temperature of the accumulated water in the heat receiving pipe 11 to rise. This is a feature of the present invention.
[0022]
Next, the memory control routine of the first aspect will be described with reference to FIG. First, when the chasing button is turned on in a state where hot water supply is not being executed, it is determined whether or not an error flag described later is set (step 100). When a negative determination is made, the pump 24 is driven (step 101) and the operation of the bypass valve 17 is confirmed. More specifically, the motor 53 of the bypass valve 17 in the fully closed state is driven to make it fully open (step 102). Next, based on the signal from the potentiometer 55, it is determined whether or not the bypass valve 17 has been fully opened (step 103). When the determination is affirmative, the motor 53 is reversely rotated to fully close the bypass valve 17 (step 104), and based on the signal from the potentiometer 55, it is determined whether or not the bypass valve 17 is fully closed (step). 105). This operation check requires about 10 seconds.
[0023]
When an affirmative determination is made in steps 103 and 105 described above, that is, when it is determined that the bypass valve 17 is normal, it is determined whether or not the water flow switch 35 is on (step 106). When the pump 24 is driven in a state where there is water in the bathtub 6, the water in the bathtub 6 circulates through the memory system 20, so that the water flow switch 35 is turned on. Therefore, when an affirmative determination is made in step 106, the burner 2 is ignited to start additional combustion, and continues as described above until the temperature of the hot water in the bathtub 6 reaches the user set temperature (step 107). If a negative determination is made in step 106, there is a risk of airing, so this routine is terminated without performing additional combustion.
[0024]
If there is an abnormal operation in the bypass valve 17, a negative determination is made in either step 103 or 105, an error flag is set (step 108), and an error display (alarm display) is displayed on the display unit such as the control unit 30 or the remote controller. (Step 109), and this routine is finished.
When the tracking button is pressed again after setting the error flag, a negative determination is made at step 100, so this routine is immediately terminated. The error flag is reset by pressing the reset button of the control unit 30.
[0025]
The single tracking control routine is shown in FIG. 2 as a time chart. That is, when the memory button is pressed, the pump 24 is driven and the operation check of the bypass valve 17 is executed. Then, when it is determined in this operation check that the bypass valve 17 is normal, the combustion of the burner 2 (additional combustion) is started for the first time. When the bypass valve 17 is abnormal, additional combustion is not executed. Therefore, the staying water in the heat receiving pipe 11 of the hot water supply system 10 is not heated prior to the hot water supply operation, and it is possible to prevent the inconvenience that the high temperature staying water in the heat receiving pipe 11 is discharged from the hot water tap 14 at the initial stage of hot water supply. it can.
[0026]
Next, a second mode independent tracking control routine executed by the control unit 30 of the hot water supply apparatus will be described with reference to FIGS. In the second mode, the combustion combustion can be started earlier than the first mode. As shown in FIG. 5, in response to turning on the memorial button, it is determined whether or not the error flag is set (step 200), and when the negative determination is made, the pump 24 is driven (step 201). This is the same as the routine of the first aspect. Next, a start command for a bypass valve operation confirmation routine is issued (step 202). Thereby, execution of the same steps as steps 102 to 105 in FIG. 1 is started in another routine. Then t₁After waiting (for example, about 2 seconds) (step 203), it is determined whether or not the water flow switch 35 is on (step 204). Note that t₁Is sufficient time for the water in the bathtub 6 to actually circulate from the on of the pump 24.
[0027]
When an affirmative determination is made in step 204, additional combustion in the initial mode is started (step 205). In this initial mode, combustion of the burner 2 is interrupted when the temperature detected by the temperature sensor 32 rises and reaches 55 ° C., and restarts when the temperature detected decreases and reaches 50 ° C. The set temperatures of 50 ° C. and 55 ° C., which are the basis for such hysteresis control, are referred to as the first set temperature. The first set temperature may be a unique temperature value. Moreover, the temperature (for example, about 42 ° C.) set by the user with a remote controller or the like may be used.
[0028]
Next, it is determined whether or not the operation check of the bypass valve 17 in the separate routine has been completed (step 206). When the determination is negative, the follow-up combustion control in the initial mode in step 205 is continued. When the determination is affirmative, the determination result in the other routine, that is, whether the bypass valve 17 is normal is checked (step 207). When it is determined that the bypass valve 17 is normal, additional combustion in the full-scale mode is executed (step 208). In this full-scale mode, the combustion of the burner 2 is interrupted when the temperature detected by the temperature sensor 32 increases and reaches 75 ° C., and restarts when the temperature detected decreases and reaches 70 ° C. The set temperatures of 70 ° C. and 75 ° C., which serve as a reference for such hysteresis control, are referred to as second set temperatures. The second set temperature is higher than the first set temperature in the initial mode. The second set temperature may be a unique temperature value.
[0029]
When it is determined in step 207 that the bypass valve 17 is abnormal, the above-described initial mode additional combustion is not finished, but the full-scale additional combustion is not executed, and an error flag is set (step 209), an error display (alarm display) is displayed on the display unit of the control unit 30 (step 210), and this routine is terminated. Note that these steps 209 and 210 may be executed by the separate routine.
[0030]
The chasing control routine of the second aspect is shown in a time chart as shown in FIG. That is, when the memory button is pressed, the pump 24 is driven and the operation check of the bypass valve 17 is executed. In parallel with this operation confirmation, combustion of the burner 2 in the initial mode (additional combustion) is performed. In other words, the combustion in the initial mode is executed before the judgment result indicating whether the bypass valve 17 is normal is obtained. Therefore, the memorial start time can be advanced, and as a result, the hot water temperature of the bathtub 6 can be quickly brought to the user set temperature.
[0031]
When the additional combustion in the initial mode is executed, the accumulated water in the heat receiving pipe 11 of the hot water supply system 10 is heated. The temperature of the accumulated water is compared by feedback control based on the temperature detected by the temperature sensor 32. The first set temperature (50 to 55 ° C.) can be kept low. Therefore, if the hot water supply operation is started during the chasing in the initial mode or immediately after the chasing in the initial mode, the water from the bypass pipe 16 is mixed even if the bypass valve 17 fails and does not open. Even if it cannot be performed, the temperature of the hot water from the hot water tap 14 is low, so that it does not hurt the user.
[0032]
The combustion control in the initial mode ends when the confirmation of the operation of the bypass valve 17 is completed. Since the combustion in the full-scale mode is not performed when the bypass valve 17 is abnormal, the accumulated water in the heat receiving pipe 11 of the hot water supply system 10 is not heated to a relatively high second set temperature prior to the hot water supply operation. In addition, it is possible to prevent the inconvenience that high-temperature staying water is discharged from the hot-water tap 14.
Further, when the bypass valve 17 is normal, additional combustion is performed in the full-scale mode, so that the hot water temperature of the bathtub 6 can be quickly brought to the user set temperature in combination with the additional combustion in the initial mode. .
[0033]
Next, a third embodiment of the single tracking control routine executed by the control unit 30 of the hot water supply apparatus will be described with reference to FIGS. Even in the third mode, the combustion combustion can be executed earlier than the first mode. In FIG. 7, steps 200 to 204 are the same as those in the second mode of FIG. When an affirmative determination is made in step 204, the start time of additional combustion (usually earlier than the end of the operation confirmation of the bypass valve 17) is calculated (step 250).
[0034]
A method for calculating the start time of the additional combustion will be described in detail. First, the temperature (residual water temperature) of the heat receiving pipe 11 of the hot water supply system 10 is read from the temperature sensor 32. Then, the difference between this detected temperature and the temperature that the user can withstand (for example, the first set temperature in the initial mode in the control routine of the second aspect) is calculated. Then, the additional combustion time Δt (see FIG. 8) necessary for applying the amount of heat corresponding to this temperature difference is calculated based on the map. By subtracting the calculated additional combustion time Δt from the expected end point of the operation check of the bypass valve 17, the additional start time is calculated.
As apparent from the above description, the additional combustion time Δt means the time width from the ignition for additional combustion to the expected end point of the operation confirmation of the bypass valve 17 and is shorter as the detected temperature is higher. The lower the detection temperature, the longer.
[0035]
Next, after waiting until the calculated start time (step 251), additional combustion is started (step 252). This additional combustion is controlled in the same manner as the additional combustion control in the first mode routine and the full-scale mode control in the second mode routine. This additional combustion is performed until the confirmation of the operation of the bypass valve 17 is completed (step 206). When it is determined that the bypass valve 17 is normal at the completion of the operation confirmation, the additional combustion is continued (step). 207, 253). When a negative determination is made in step 207, the combustion combustion is stopped, and steps 209 and 210 similar to the routine of the second mode are executed.
[0036]
FIG. 8 is a time chart showing the memory control routine of the third aspect. That is, when the remedy button is pressed, the pump 24 is driven and the operation of the bypass valve 17 is confirmed. And before completion | finish of this operation | movement confirmation, the combustion (burning combustion) of the burner 2 is performed.
[0037]
When the confirmation of the operation of the bypass valve 17 is completed and it is determined that the operation is normal, this additional combustion is continued. In addition, when there is an abnormality, additional combustion is stopped. As described above, the temperature at the time of stopping can be suppressed to a relatively low temperature by adjusting the start point of the additional combustion according to the temperature detected by the temperature sensor 32. Therefore, even if hot water supply is started during the chasing or immediately after the chasing is stopped, it is possible to prevent high-temperature staying water from being discharged from the hot water tap 14 at the initial stage of hot water feeding.
[0038]
In the above-described embodiment, the bypass valve 17 is provided in the middle of the bypass pipe 16, but as shown in FIGS. 9 and 10, the bypass valve 17 is bypassed at the end of the bypass pipe 16, that is, at the intersection of the bypass pipe 16 and the hot water supply pipe 13. A valve 17 'may be arranged. Since the configuration of the bypass valve 17 ′ is basically similar to the bypass valve 17 of the above-described embodiment, the corresponding components are denoted by the same reference numerals and description thereof is omitted. This bypass valve 17 ′ has a valve port 50 a disposed between the bypass pipe 16 and the downstream side of the hot water supply pipe 13, and a valve port 50 b disposed between the upstream side and the downstream side of the hot water supply pipe 13. It has two valve bodies 51a and 51b corresponding to these valve openings 50a and 50b. In the bypass valve 17 ′, the upstream and downstream sides of the hot water supply pipe 13 are blocked when the valve bodies 51 a and 51 b are leftmost, and the bypass pipe 16 and the downstream side of the hot water supply pipe 13 are communicated. Moreover, when approaching to the rightmost, the bypass pipe 16 is interrupted | blocked and the upstream and downstream sides of the hot water supply pipe 13 are connected. Note that both passages are open at an intermediate position of the bypass valve 17 '. In the initial stage of hot water supply, the bypass valve 17 'is set to the intermediate position.
[0039]
The present invention is not limited to the above embodiment, and various forms can be adopted. For example, if a bypass motor is used as the bypass valve as in the above embodiment, the operation can be easily confirmed by detecting the position of the movable part, but the actual opening / closing operation can be detected. If possible, other types of bypass valves may be used.
The operation of the bypass valve may be confirmed only by confirming whether the operation from the closed state to the open state is normal. That is, when it is confirmed that the opening operation is normal, additional combustion may be started, or the transition from the initial mode to the full-scale mode may be performed.
[0040]
In the above-described embodiment, when there is a memorial request during hot water supply, the confirmation of the bypass valve operation is omitted and the memorialization is performed, but in this case, the operation confirmation may be performed.
In addition, when hot water supply is completed after simultaneously performing hot water supply and hot water supply, similar to the control routine described above (routines of the first to third modes) in response to the hot water supply end (requirement of additional combustion alone). Control may be performed. That is, when a routine similar to the routine of the first mode is adopted, the chasing is temporarily suspended, the operation of the bypass valve is confirmed during that time, chasing is resumed when normal, and when abnormal, Forbid memorial. When a routine similar to the routine of the second mode is adopted, the combustion combustion is temporarily shifted to the initial mode control, is returned to the full-scale mode control when normal, and the combustion combustion ends when abnormal. . When a routine similar to the routine of the third aspect is employed, the tracking is temporarily suspended, the tracking restart time is calculated, and the combustion combustion is executed after waiting for the restarting time. The rest is the same as the routine of the third aspect.
[0041]
The hot water supply apparatus of the present invention may have a hot water filling function. The hot water supply system may have a bypass pipe having no valve in addition to the bypass pipe provided with the bypass valve.
The hot water supply apparatus of the present invention may be provided with a heating system or a circulating hot water supply system instead of the memory system.
The bypass pipe of the present invention should be interpreted in a broad concept and includes a passage formed in the block.
When it is determined that the operation is abnormal, the combustion may not be stopped and only the alarm operation including the alarm display may be performed.
When a sufficiently long time has elapsed from the end of the memorial service, the bypass valve does not have to open.
[0042]
【The invention's effect】
  As explained above,According to the invention of claim 1,When there is a heating request for a system different from the hot water supply system, the operation of the bypass valve is checked. When the bypass valve is abnormal, burner combustion is prohibited.For,It is possible to prevent the inconvenience that high temperature accumulated water in the heat receiving pipe is discharged in the initial stage of hot water supply. And since burner combustion is started in parallel with the said operation check, the role of the system different from the said hot-water supply system can be played at an early stage.
  Claim2According to the invention, the burner combustion performed in parallel with the operation check of the bypass valve is controlled in the initial mode based on the detected temperature of the hot water supply heat receiving pipe and the relatively low first set temperature. Even if hot water supply is started during the middle or immediately after the burner combustion is stopped due to an abnormality, the temperature of the hot water can be surely kept low.
  Claim3According to this invention, the start point of burner combustion before the end point of the operation check is adjusted according to the detected temperature of the hot water supply heat receiving pipe. Even if hot water supply is started immediately after it is stopped, the hot water temperature can be reliably kept low.
  Claim4According to the invention, since a bypass motor driven type is used for the bypass valve, it is possible to easily confirm the operation by detecting the position of the movable part.
[Brief description of the drawings]
FIG. 1 is a flowchart showing a first aspect of a chasing control routine executed by a hot water supply device having a chasing function of a single can and two water channel type according to an embodiment of the present invention.
FIG. 2 is a time chart of control executed by the memory control routine of the first embodiment.
FIG. 3 is a schematic view showing an overall configuration of the hot water supply apparatus.
FIG. 4 is a schematic view showing a configuration of a bypass valve incorporated in the hot water supply apparatus.
FIG. 5 is a flowchart showing a second mode of a chasing control routine executed by the hot water supply apparatus.
FIG. 6 is a time chart of control executed by the memory control routine of the second mode.
FIG. 7 is a flowchart showing a third mode of a memory control routine executed by the hot water supply apparatus.
FIG. 8 is a time chart of control executed by the memory control routine of the third aspect.
FIG. 9 is a schematic view showing a configuration of a hot water supply system according to another embodiment.
FIG. 10 is a schematic view showing a configuration of a bypass valve used in the hot water supply system.
[Explanation of symbols]
1 can
2 Burner
3 Heat exchange section
10 Hot water supply system
11 Heat receiving pipe
12 Water supply pipe
13 Hot water supply pipe
16 Bypass pipe
17 Bypass valve
20 memorial system
21 Heat receiving pipe
30 Control unit (control means)
32 Temperature sensor

Claims (4)

A common heat exchanger that receives combustion heat from a common burner is inserted with a heat receiving pipe of a hot water supply system and a heat receiving pipe of another system, and this hot water supply system includes the heat receiving pipe and water supply pipes connected to both ends thereof. In a hot water supply apparatus including a hot water supply pipe, a bypass pipe connected between the water supply pipe and the hot water supply pipe and in parallel with the heat receiving pipe, and a bypass valve provided in the bypass pipe,
When there is a request for burner combustion when water does not flow to the hot water supply system and water flows to the other system, burner combustion is temporarily started, and the bypass valve is operated in parallel to this operation. A hot water supply apparatus comprising: control means for confirming whether or not the fuel is normal and continuing burner combustion when determined to be normal, and forcibly terminating burner combustion being performed when determined to be abnormal. A temperature sensor is provided at or near the heat receiving pipe of the hot water supply system, and the control means performs burner combustion in the initial mode in parallel with the operation check of the bypass valve, and when it is determined abnormal by this operation check, Burner combustion is forcibly terminated, and when it is determined to be normal, burner combustion is performed in full-scale mode.
In the initial mode, combustion control is performed so that the temperature detected by the temperature sensor becomes the first set temperature, and in the full-scale mode, the temperature detected by the temperature sensor becomes a second set temperature that is higher than the first set temperature. water heater according to claim 1, characterized in that the combustion control to. A temperature sensor is provided in or near the heat receiving pipe of the hot water supply system, and the control means determines a combustion start time based on a temperature detected by the temperature sensor when receiving a request for burner combustion, Burner combustion is executed from the start point, and when determining the combustion start point, the time width from the start point of combustion to the expected end point of the operation confirmation is increased as the detection temperature is lower and is decreased as the detection temperature is higher. The hot water supply apparatus according to claim 1 , wherein the hot water supply apparatus is determined as follows. The bypass valve is driven by a gear motor, and a movable portion of the gear motor is provided with position detection means, and the control means confirms the operation of the bypass valve based on position information from the position detection means. The hot-water supply apparatus of Claims 1-3 .

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