JP2010101583A - Water heater - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve a problem wherein in a combustion apparatus, although safety is secured by performing interlock processing for making combustion start operation ineffective to prohibit afterburning when a degree of blocking of an intake/exhaust air passage is progressed, even if cleaning of the intake/exhaust air passage etc. by a user makes the combustion apparatus return to the state enabling safe use, only a maintenance worker can release the interlock. <P>SOLUTION: Other than a combustion stop reference value for performing interlock, a combustion allowing reference value for releasing the interlock is stored. The combustion allowing reference value is a degree of blocking enabling safe combustion in a combustor, and the combustion stop reference value is a degree of blocking making safe combustion of the combustor impossible. Since the combustion allowing reference value is stored, it can be determined whether or not the combustor is returned to the state enabling safe operation by processing by a user, and when it can be confirmed that the combustor is returned to the state enabling safe operation, the interlock processing is released. Thus, this reasonably achieves safety and convenience. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a hot water supply apparatus.

  The hot water supply apparatus described in Patent Document 1 includes a combustor, an intake / exhaust passage communicating with the combustor, a fan that allows air to pass through the intake / exhaust passage, and heat installed in the exhaust passage of the intake / exhaust passage. An exchanger, a blockage degree detection means for detecting the blockage degree of the intake / exhaust passage, and an operation control means are provided. While passing through the heat exchanger, the water fed into the water heater is heated by the combustion heat and exhaust heat of the combustor to become hot water.

  If the intake / exhaust passage is blocked, the air necessary for combustion is not ensured, and the combustor cannot normally burn. Therefore, in the hot water supply apparatus of Patent Document 1, the blockage degree detecting means detects the blockage degree of the intake / exhaust passage during operation, and when the blockage degree becomes high (strongly blocked), the operation of the hot water supply apparatus is forcibly stopped. In addition, a process that does not start combustion even if the user performs a combustion start operation thereafter is executed. That is, when the blockage degree detected by the blockage degree detection means reaches a combustion stop reference value stored in advance, processing for invalidating the combustion start operation is executed. In this specification, a process that does not start combustion even if a combustion start operation is performed, that is, a process that invalidates the combustion start operation is referred to as an interlock process. Even if the operation for rotating the fan is started by the combustion start operation, if the operation for starting the combustion is not executed, this corresponds to an interlock process.

If the interlock process is performed when the blockage degree detected by the blockage degree detection means reaches the combustion stop reference value, the hot water supply apparatus is maintained until a maintenance person who has received specialized training checks the hot water supply apparatus. Can no longer be used. Therefore, combustion is not resumed in a state where the intake and exhaust passages are blocked. By performing the interlock process, the safety of the hot water supply device is ensured. On the other hand, if the interlock process is performed, the hot water supply device cannot be used until the maintenance staff inspects, and the convenience is impaired.
JP-A-8-261455

In the prior art, since safety must be prioritized, it has been considered that there is no other way to perform the interlock process when the degree of blockage reaches the combustion stop reference value.
However, even when the interlock process is performed because the blockage degree reaches the combustion stop reference value by the inventor's research, it is not always necessary for the maintenance staff to check the hot water supply device and release the interlock process. It has been found that the interlocking process may be canceled without waiting for the inspection of the maintenance staff in such a case that the hot water supply device may be returned to a state where it can be used safely by the person's process.
The present invention is based on the above-described knowledge. When it is confirmed that the user has returned to a state where the hot water supply device can be safely used by cleaning the intake and exhaust passages, the maintenance personnel can An object of the present invention is to provide a hot water supply device that releases an interlock process without waiting for a lock to be released. That is, an object of the present invention is to provide a hot water supply apparatus that achieves both safety and convenience at a more reasonable level.

  The hot water supply apparatus according to the present invention includes a combustor, an intake / exhaust passage, a fan, a heat exchanger, a blockage degree detection unit, a reference value storage unit, and an operation control unit. The intake / exhaust passage communicates with the combustor. The fan allows air to pass through the intake and exhaust passages. The heat exchanger is installed in the exhaust path of the intake and exhaust paths. The blockage degree detecting means detects the blockage degree of the intake / exhaust passage. The reference value storage means stores a combustion stop reference value related to the blockage degree and a combustion permission reference value related to the blockage degree. The blockage degree corresponding to the combustion stop reference value is a stronger blockage degree than the blockage degree corresponding to the combustion permission reference value. The operation control means executes a process of stopping the combustion and invalidating the combustion start operation when the degree of obstruction measured by the degree of obstruction detection means reaches the combustion stop reference value. The operation stop means further performs a combustion start operation when the degree of obstruction measured by the obstruction degree detection means after the combustion start operation is invalidated and has changed beyond the combustion permission reference value from the combustion stop reference value side. Also executes the process of enabling. The expression that the degree of obstruction exceeds the combustion permission reference value should be understood in a broad sense, and includes the case where the degree of obstruction becomes equal to the combustion permission reference value. The expression that the degree of obstruction reaches the combustion stop reference value should be understood in a broad sense, and includes the case where the degree of obstruction exceeds the combustion stop reference value.

Unlike a conventional hot water supply apparatus, this hot water supply apparatus stores a combustion permission reference value in addition to a combustion stop reference value. The blockage degree corresponding to the combustion stop reference value is a stronger blockage degree than the blockage degree corresponding to the combustion permission reference value. That is, the combustion permission reference value is a degree of blockage at which the combustor can burn safely, and the combustion stop reference value is a blockage degree at which the combustor cannot burn safely.
When the blockage progresses in the intake and exhaust passages, the blockage degree changes from the blockage level that is hardly blocked toward the combustion permission reference value, and further changes to reach the combustion stop reference value. When the blockage degree progresses to that point, the combustion is stopped and the interlock process is performed.
Even when the interlock process is performed, the blockage phenomenon may be solved if the user processes it appropriately. For example, when a small bird has nests in the intake and exhaust passages and is blocked, removing the nest will eliminate the blockage phenomenon. Alternatively, the blocking phenomenon may be solved because the filter is cleaned.
The conventional hot water supply apparatus attaches great importance to safety, and requires maintenance by a maintenance staff even when the clogging phenomenon is resolved and the hot water supply apparatus can be operated safely.
The hot water supply apparatus of the present invention determines whether or not it has returned to a state in which it can be safely operated by user processing. Therefore, the hot water supply apparatus of the present invention stores a combustion permission reference value. If the degree of blockage returns to the combustion permission reference value, it can be confirmed that the vehicle has returned to a safe driving state, so the interlock process is released.

  According to this apparatus, if the degree of blockage reaches the combustion stop reference value, the interlock process is performed, so that safety can be ensured. In addition, the convenience is improved because the interlock process is released when it is confirmed that the vehicle can be safely operated by the combustion permission reference value. Safety and convenience can be achieved at a more reasonable level.

The main features of the embodiments described below are listed first.
(Characteristic 1) The blockage degree detection means detects the blockage degree in a state where combustion is not performed in the combustor. For example, the amount of electric power required to rotate the fan at a constant rotational speed is measured. When the intake / exhaust passage is closed, the fan idles, so that the amount of power required to rotate the fan at a constant rotational speed decreases. The degree of blockage can be detected based on the amount of power required to rotate the fan at a constant rotation speed. Alternatively, the pressure on the downstream side of the fan may be detected. When the intake / exhaust passage is blocked, the pressure on the downstream side of the fan increases. Alternatively, the average flow velocity in the intake / exhaust passage may be detected. When the intake / exhaust passage is blocked, the average flow velocity decreases.
(Characteristic 2) The expression that the interlock process is performed when the blockage degree measured by the blockage degree detection means reaches the combustion stop reference value is as follows. When the number of times that the combustion stop reference value has been reached after the first ignition of the hot water supply device is reached for the second time, the interlock processing is performed (first ”Is the exception)”, the interlock process is performed when the number of times that the combustion stop reference value has been reached for the third time since the water heater was first ignited (the first two exceptions) ”)”. The number of exceptions is adjusted according to the inspection procedure before shipment from the factory.
(Characteristic 3) The expression that the interlock process is performed when the blockage degree measured by the blockage degree detection means reaches the combustion stop reference value is “the combustion stop reference value is reached only after the interlock process is released”. "When the interlock process is performed", the interlock process is performed when the number of times that the combustion stop reference value is reached after the interlock process is released is the second time (the exception is when the first is reached) The case includes the case where the interlock process is performed when the number of times the combustion stop reference value is reached after the release of the interlock process is the third time (with the first two exceptions).

  An embodiment of the present invention will be described with reference to FIGS. As shown in FIG. 1, the hot water supply apparatus A includes a hot water supply apparatus main body K installed outdoors and a remote control L installed in a kitchen or the like. The water heater main body K and the remote control L are connected by a two-wire N.

The hot water supply device main body K includes a combustor 2, an intake / exhaust passage 33, a fan 4, a water passage 1, a heat exchanger 121, and a control unit (operation control means) 5. As shown in FIG. 2, the control unit 5 includes a blockage degree detection unit 55 and a reference value storage unit 79.
The intake / exhaust passage 33 includes an air supply passage 35, a combustion housing 3, and an exhaust duct 32. A fan 4 is disposed at the inlet of the air supply path 35. The outlet of the supply passage 35 is connected to the combustion housing 3. The combustion housing 3 is connected to an exhaust duct 32 that discharges the combustion exhaust gas 31 to the outside of the water heater main body K. A combustor 2 is accommodated in the combustion housing 3. The intake / exhaust passage 33 communicates with the combustor 2. When the fan 4 rotates, air is sent from the air supply path 35 to the combustion housing 3 and pushed out from the combustion housing 3 to the exhaust duct 32. The fan 4 allows air to pass through the intake / exhaust passage 33.
The heat exchanger 121 is disposed downstream of the combustor 2 in the combustion rising 3. A portion of the combustion housing 3 downstream of the combustor 2 is an exhaust passage 34. The heat exchanger 121 is installed in the exhaust path 34 of the intake / exhaust path 33.

  The water channel 1 includes a water supply pipe 11, a heat exchanger pipe 12, a bypass pipe 13, and a hot water pipe 14. The water supply pipe 11 has an upstream side connected to the water supply and a downstream side connected to the inlet of the electric water amount control device 15. In the water supply pipe 11, a water filter / water drain plug 111, a water amount sensor 112, and a water supply thermistor 113 are arranged in this order from the upstream side.

  The heat exchanger pipe 12 has an upstream inlet side connected to one outlet of the electric water amount control device 15, an intermediate portion disposed above the combustor 2, and a downstream outlet side connected to the hot water outlet pipe 14. A portion of the heat exchanger tube 12 disposed above the combustor 2 constitutes a heat exchanger 121. The water flowing through the heat exchanger tube 12 is heated by the combustion heat and exhaust heat of the combustor 2 while passing through the heat exchanger 121. An overheat prevention device 122 is disposed on the outer wall of the heat exchanger tube 12, and a can body thermistor 123 is disposed on the downstream outlet side.

  The bypass pipe 13 has an upstream inlet side connected to the other outlet of the electric water amount control device 15, and a downstream end connected to the upstream side of the tapping pipe 14 (downstream end side of the heat exchanger pipe 12). Hot water heated by passing through the heat exchanger pipe 12 and cold water that has passed through the bypass pipe 13 flow into the hot water pipe 14, and hot water adjusted to an appropriate temperature by mixing both flows. The hot water discharge pipe 14 includes, in order from the upstream side to the downstream side, a freeze prevention heater 141 for preventing freezing, a hot water thermistor 142 for detecting the hot water temperature, an overpressure safety valve / water drain plug 143, and a hot water tap 144 for discharging hot water. Is arranged.

  The electric water amount control device 15 is energized and controlled by the actuator control unit 58 shown in FIG. 2 and controls the amount of water passing through the water supply pipe 11. The electric water amount control device 15 further controls the ratio between the amount of water passing through the heat exchanger pipe 12 and the amount of water flowing through the bypass pipe 13. When the amount of water passing through the water supply pipe 11 is equal to or greater than the predetermined amount of water, the amount of water passing through the heat exchanger pipe 12 is maintained at a constant amount, and only the amount of water flowing through the bypass pipe 13 is changed.

  By controlling the electric water amount control device 15 as follows, when the hot water supply device is operated intermittently, it is possible to prevent a phenomenon in which the temperature of the hot water delivered from the hot water discharge pipe 14 changes suddenly. That is, based on the elapsed time after stopping hot water supply and the incoming water temperature, the opening degree of the electric water amount control device 15 is changed so as to reduce the amount of bypass water every unit time. At the time of re-heating, the temperature of the hot water on the outlet side of the heat exchanger 121 is detected by the can body thermistor 123, and the opening degree of the electric water amount control device 15 is controlled based on the detected temperature. By controlling as described above, it is possible to suppress a change in hot water temperature during re-heating.

  The hot-water tap 144 is operated by the user to adjust the amount of hot water discharged from a faucet arranged in the kitchen or bathroom. The water amount sensor 112 is of an impeller type and sends out a pulse corresponding to the amount of water flowing through the water supply pipe 11. It can be seen from the output of the water amount sensor 112 that the user has opened the hot-water tap 144. When it is detected from the output of the water amount sensor 112 that the hot water tap 144 has been opened, the hot water supply device A starts combustion in the combustor 2. In this hot water supply apparatus A, the user opening the hot water tap 144 corresponds to the combustion start operation.

  The combustor 2 is disposed in the combustion housing 3 and forcibly burns the gas sent from the gas pipe 6 with the combustion air fed from the fan 4. The gas pipe 6 is provided with an original solenoid valve 61, a governor proportional solenoid valve 62, and capacity switching solenoid valves 63 and 64. In addition, 21 is an ignition electrode, 22 is an igniter, 23 is a flame rod for detecting a combustion flame, 24 is a thermal fuse, and 25 is a low temperature detection switch.

  The capacity switching electromagnetic valves 63 and 64 are energized and controlled by the actuator control unit 58 shown in FIG. 2, and the gas supply amount to the combustor 2 is switched in three stages by a combination of valve opening and valve closing. That is, one of “both solenoid valves 63 and 64 are opened”, “only solenoid valve 63 is opened”, and “only solenoid valve 64 is opened” is selected. The governor proportional solenoid valve 62 is energized and controlled by the actuator control unit 58, exhibits an opening according to the energization amount, and continuously varies the amount of gas flowing through the gas pipe 6. In this way, by combining the capacity switching solenoid valves 63 and 64 and the governor proportional solenoid valve 62, a wide control range of the combustion amount can be secured, and fine control is possible.

  The hot water thermistor 142 detects the hot water temperature, and the water supply thermistor 113 detects the water temperature. The can body thermistor 123 is disposed in order to detect boiling of water passing through the heat exchanger 121. The remote control L includes a push button switch for instructing to change the set temperature, an operation switch 71 for instructing start or stop of operation, a display 72, an operation lamp, a combustion lamp, and the like.

  As shown in FIG. 2, the control unit 5 having a microcomputer feeds back a fan current detection unit 51 that detects a fan current, a rotation number detection unit 52 that detects the rotation number of the fan 4, and the rotation number of the fan 4. A fan control unit 53 that controls, a correction value calculation unit 55 that calculates a rotational speed correction value corresponding to the closed state of the air supply / exhaust passage 33, and a restriction on ignition stop processing and hot water supply capability (combustion capability) corresponding to the blocked state A safe operation unit 56 that performs the above, a calorific value calculation unit 57, an actuator control unit 58 that controls the original electromagnetic valve 61 and the like, a correction value recording unit 59 that records a correction value when the operation is stopped, and a reference value storage unit 79. As will be described later, since the correction value calculated by the correction value calculation unit 55 indicates the degree of blockage of the intake and exhaust passage 33, it can be said to be a means for detecting the degree of blockage.

  The fan 4 is provided with a rotation speed sensor 42 and a current sensor 41. A hall element is used for the rotation speed sensor 42. The current sensor 41 detects the fan current value flowing in the motor that rotates the fan 4 every 0.5 seconds.

The fan control unit 53 stores the target rotational speed of the fan 4. The target rotational speed in the pre-purge process performed before ignition is 2700 rpm, the target rotational speed during the ignition process is 2250 rpm, and the target rotational speed corresponding to the required combustion amount calculated by the heat quantity calculation unit 57 is stored during hot water supply. is doing.
The fan control unit 53 feedback-controls the fan current based on the deviation between the actual rotation number detected by the rotation number detection unit 52 and the target rotation number. The fan control unit 53 controls the rotational speed of the fan 4 to the target rotational speed.

  When the intake / exhaust passage 33 is blocked, even if the rotational speed of the fan 4 is adjusted to the target rotational speed, a predetermined amount of combustion air is not sent into the combustor 2. Therefore, the target rotational speed of the fan 4 needs to be increased as the intake / exhaust passage 33 is blocked. In this embodiment, the degree of blockage of the intake / exhaust passage 33 is detected as follows.

The fan current value is higher as the fan speed is higher. If the fan speed is constant, the fan current value decreases as the intake / exhaust passage 33 is closed. When the intake / exhaust passage 33 is blocked, the fan 4 stops sending air and the fan 4 idles. When the fan 4 runs idle without sending air, the fan does not work and the fan rotates lightly.
In FIG. 3, reference numeral 81 denotes the relationship between the fan speed and the fan current value when the intake / exhaust passage 33 is not closed. Reference numeral 82 denotes a reference value line indicating the relationship between the fan rotation speed and the fan current value when the intake / exhaust passage 33 is in the design standard blockage degree. Reference numeral 83 denotes the relationship between the fan rotational speed and the fan current value when the intake / exhaust passage 33 is closed so that the amount of combustion heat needs to be reduced. Reference numeral 84 denotes the relationship between the fan speed and the fan current value when the intake / exhaust passage 33 is closed to the extent that it is necessary to stop the combustion of the combustor 2.
Reference numeral 85 denotes an auxiliary value line determined so that a value of 1.0 is obtained when the correction value H is obtained for the reference value line 82.

I ₁ is the fan current value in the auxiliary value line 85 when the fan speed is at a predetermined value. I ₂ is a fan current value in the reference value line 82 when the rotation speed is the same. I ₀ is the actually detected fan current value. a is I ₂ -I ₁ , and b is I ₀ -I ₁ .
The correction value calculation unit 55 obtains the correction value H by the equation {(a / b) −1} × α + 1. α is a constant of 1 or less.
If the intake / exhaust passage 33 is not closed and the relationship of 81 is obtained, b> a, and the correction value H is 1 or less. If the intake / exhaust passage 33 is in the design standard blockage degree and the relationship of 82 is obtained, b = a and the correction value H is 1. If the intake / exhaust passage 33 is blocked to reduce the amount of combustion heat and the relationship 83 is obtained, b <a and the correction value H is 1 or more. In this embodiment, if the relationship is 83, the correction value H is 1.1. The intake / exhaust passage 33 is blocked to the extent that it is necessary to stop the combustion of the combustor 2. If the relationship 84 is satisfied, b further decreases and the correction value H further increases. In this embodiment, if the relationship is 84, the correction value H is 1.2. The value of the correction value H increases as the intake / exhaust passage 33 is strongly blocked.

  In this embodiment, since the fan current value changes according to the degree of blockage of the intake / exhaust passage 33, the degree of blockage is detected by detecting the fan current value. Finally, the fan current value is converted into the correction value H. The converted correction value H indicates the degree of blockage of the intake / exhaust passage 33. If the correction value is 1.1 or less, the intake / exhaust passage 33 is not blocked and can be normally burned by the combustor 2. If the correction value is 1.1 to 1.2, the degree of blockage of the intake / exhaust passage 33 has progressed, and a necessary amount of combustion air cannot be obtained unless the amount of combustion heat of the combustor 2 is reduced. . In other words, this corresponds to a degree of blockage that can be safely combusted by the combustor 2 if the amount of combustion heat is reduced. If the correction value is 1.2 or more, the degree of blockage of the intake / exhaust passage 33 has progressed seriously, and the combustion of the combustor 2 needs to be stopped.

The combustion stop reference value storage unit 76 shown in FIG. 2 stores a value of 1.2, the combustion limit reference value storage unit 77 stores a value of 1.1, and the combustion permission reference value storage unit 78 stores a value of 1.0.
The correction value calculation unit 55 calculates the correction value H every 20 mS. The correction value storage unit 59 stores a correction value H at the end of the combustion operation.

  FIG. 4 shows the relationship between the correction value H and the blocking rate. A correction value H of 1.2 corresponds to a state where up to 80% of the cross-sectional area of the intake / exhaust passage 33 is closed. The hot water supply device has a high enough margin that it can be used until 80% of the intake and exhaust passages are blocked.

If the correction value is 1.1 or less, the combustor 2 can be burned normally. In this case, the target rotational speed of the fan 4 is multiplied by the correction value H to be corrected to the target rotational speed. The combustor 2 is normally controlled. If the target rotational speed of the fan 4 is corrected, the operation can be performed without restriction of the amount of combustion heat.
If the correction value is 1.1 to 1.2, the combustor 2 can be burned normally by multiplying the target rotational speed of the fan 4 by the correction value H to correct the target rotational speed. However, when the amount of combustion heat is high, the combustion air is insufficient even if the target rotational speed of the fan is corrected. Therefore, the amount of combustion heat is limited.
If the correction value is 1.2 or more, the combustion air is insufficient even if the target rotational speed of the fan 4 is corrected. The combustor 2 cannot be burned normally. In this case, the combustion of the combustor 2 is forcibly stopped. Moreover, even if a user performs combustion start operation after that, it measures so that a hot water supply apparatus may not start combustion. That is, an interlock is applied.

  The calorific value calculation unit 57 calculates the amount of combustion heat required for the hot water temperature detected by the hot water thermistor 142 to become the set temperature based on the detected water temperature detected by the water supply thermistor 113 and the detected water supply amount detected by the water amount sensor 112. To do.

  In the hot water supply apparatus A, the target rotational speed of the fan 4 is determined based on the necessary amount of combustion heat. Further, based on the actual rotational speed of the fan 4, the capacity switching solenoid valves 63 and 64 are switched to control the energization amount of the governor proportional solenoid valve 62. This is so-called fan-preceding control. When the target rotational speed is corrected with the correction value H, the rotational speed detected by the rotational speed detection unit 52 is divided by the correction value H to be returned to the combustion heat quantity dimension. The influence of the correction performed corresponding to the degree of blockage of the intake / exhaust passage 33 is removed. Further, if necessary, the electric water amount control device 15 is controlled to adjust the distribution ratio.

Next, the operation of the control unit 5 of the hot water supply apparatus A will be described based on the flowcharts shown in FIGS.
The control unit 5 starts the processing of FIGS. 5 and 6 when the user turns on the power (operating the operation switch 71) (step S2).
In step S4, a combustion start operation is awaited. In the case of the present embodiment, it is determined that the combustion start operation has not been performed when the water amount sensor 112 detects a flow rate of 2.7 liters or more per minute because the user has opened the hot-water tap 144. The above is an example of the combustion start operation, and the operation of putting hot water into the bathtub is also the combustion start operation.
When the combustion start operation is performed and step S4 becomes YES, the blockage degree stored at the time of the previous operation stop is read and compared with the combustion stop reference value (1.2). In this embodiment, the blockage degree is processed in units of the correction value H.

  When the combustion is forcibly stopped because the intake / exhaust passage 33 is blocked during the previous operation, the conventional technique performs the interlock process and does not perform the ignition process (S24 in this embodiment). The process does not proceed to the ignition process of S24 unless the maintenance staff checks and performs the process of releasing the interlock process. Also in this embodiment, when the combustion is forcibly stopped because the intake / exhaust passage 33 is blocked during the previous operation, step S6 becomes NO and, in principle, does not proceed to step S24. Perform interlock processing. However, the processing procedures of steps S12, 16, and 20 are prepared, and it is determined whether or not the state where the interlock process can be released is restored, and the state where the interlock state can be released is restored. If it is confirmed, the process proceeds to the ignition process in step S24. If it is confirmed that the interlock state can be released, the system of the hot water supply device releases the interlock state without waiting for the inspection work of the maintenance staff.

  When the combustion is forcibly stopped because the intake / exhaust passage 33 was blocked during the previous operation, the blockage degree (correction value) storage unit 59 stores a value of 1.2, and the determination result in step S6 is No. In this case, steps S12 and S16 are performed, and the degree of blockage is detected again. If the newly detected degree of blockage is smaller than the combustion permission reference value (1.0 in this case), step S20 becomes YES, and the process proceeds to step S24 where the ignition process is performed. In spite of the blockage degree at the time of the previous operation stop being 1.2 or more, the phenomenon that the current blockage degree is less than 1.0 is that the user carefully cleans the intake and exhaust passage 33, etc. This occurs when the intake / exhaust passage 33 is cleaned very cleanly. In this case, it is not necessary to continue the interlock process, and even if the interlock process is canceled on the system side, the safety is not impaired. If YES in step S20, the ignition process in step S24 does not proceed. Since the process proceeds from step S20 to steps S26 and S30 and does not proceed to step S24, the interlock process is not released when the interlock process needs to be continued.

Instead of step S20, when the current blockage degree becomes less than the combustion stop reference value (in this case 1.2), a process of releasing the interlock process and performing the ignition process of step S24 is also possible. Alternatively, it is also possible to perform a process of releasing the interlock process and performing the ignition process in step S24 when the current blockage degree is less than the combustion limit reference value (in this case 1.1). In this embodiment, instead, when the degree of blockage this time becomes less than the combustion permission reference value (1.0 in this case), a process of releasing the interlock process and performing the ignition process of step S24 is adopted. is doing.
According to the present embodiment, the interlock process is released only when it is confirmed that the phenomenon that triggered the interlock process has been removed by the user's hand. The interlock process is released only when it is reliably detected that the interlock process can be released without inadvertently releasing the interlock process. Safety and convenience can be rationally achieved.

Below, the procedure of a flowchart is demonstrated in order.
If it is determined in step S6 that the degree of blockage at the previous operation stop is less than the combustion stop reference value (1.2 in this case), steps S10 and S14 are performed, and the blockage degree is detected again. Thereafter, it is determined whether or not the blockage degree detected in step S14 is also less than the combustion stop reference value (1.2) (step S18). If it is less than 1.2 at the end of the previous operation but the newly detected degree of blockage is 1.2 or more, the process proceeds to step S22 and an error is displayed. The ignition process in step S24 does not proceed. In this case, in step S28, the degree of blockage (1.2 or more) detected again is stored in the storage unit 59, and the process is terminated. This phenomenon occurs when the intake / exhaust passage 33 is blocked during non-operation. This occurs when a small bird nests in the exhaust duct 32. When step S28 is executed, the next combustion start operation is performed (when step S4 is YES), step S6 is NO. Therefore, unless step S20 is YES, the process does not proceed to step S24. Unless canceled in step S20, this is equivalent to continuing the interlock process for invalidating the combustion start operation.

In this case, if the combustion start operation is performed after the intake and exhaust passages are cleaned, NO is determined in step S6, but YES is determined in step S20, so that the hot water supply apparatus A can be used again. This corresponds to the release of the interlock process.

  If the degree of obstruction at the time of the previous operation stop is also less than the combustion stop reference value (in this case 1.2), and the degree of obstruction detected this time is also less than the combustion stop reference value (in this case 1.2), step S18 becomes YES. In this case, the process proceeds to step S24 and the ignition process is performed. As a result, the hot water supply apparatus A starts burning and starts hot water supply. The subsequent processing will be described later with reference to FIG.

  If the degree of blockage at the time of the previous operation stop is equal to or greater than the combustion stop reference value (1.2 in this case), even if it is found that the combustion start operation is performed in step S4, step S6 becomes NO. If it is as it is, it does not advance toward step S24. In this case, in step S8, it is determined whether or not the previous operation was the first operation. The first operation is performed before factory shipment. In the manufacturing process, for example, the intake / exhaust passage 33 may be blocked due to forgetting to remove the masking tape at the time of painting. In this case, it is found in the first test operation that the degree of blockage is equal to or higher than the combustion stop reference value, and combustion is forcibly stopped. Since this type of product is thoroughly inspected thereafter, the processing after the inspection proceeds to the processing after step S10. In this case, even if the degree of blockage detected in step S14 is not less than the combustion permission reference value, the ignition process in step S24 is executed as long as it is less than the combustion stop reference value. For the first time only, even if the blockage degree reaches the combustion stop reference value, the interlock process is not performed.

  If the combustion stop reference value is reached in the second and subsequent operations, step S8 becomes NO. In this case, steps S12 and S16 are performed to detect the degree of blockage again. In step S20, the detected blockage degree is compared with a combustion permission reference value (1.0, which is lower than the combustion stop reference value (1.2)). If the blocking degree is 1.0 or more, the process proceeds to step S26 even if it is 1.2 or less. That is, an error is displayed, and the value of the combustion stop reference value is stored as the degree of blockage when the operation is stopped. As a result of the processing after step S20, even if the blockage degree is 1.2 or less, control is performed so that the ignition processing is not performed unless it becomes less than 1.0. The interlock state continues.

  Even if the combustion stop reference value is reached in the second and subsequent operations, if it is less than the combustion permission reference value by the subsequent recovery measures, step S20 becomes YES, and the process proceeds to step S24 and proceeds to the ignition process. Even if the interlock process is performed once, if the recovery is performed until the combustion permission reference value is reached, the interlock process is canceled and the ignition process is executed, so that the hot water supply device can be used.

  In the ignition processing in step S24, the ignition gas flow rate is adjusted, and the rotational speed of the fan is adjusted to 2250 × H (rpm). Since the target fan speed is corrected with the correction value H, combustion air corresponding to the ignition gas flow rate is sent regardless of the actual degree of blockage. A stable ignition process is performed.

When combustion starts in step S24 of FIG. 5, the process of step S32 of FIG. 6 is repeatedly executed, and the blockage degree is continuously detected at predetermined time intervals. In step S34, the fan rotation speed is adjusted according to the latest blockage degree. Specifically, the fan speed is adjusted by the following procedure.
(1) The required amount of combustion heat is calculated based on the detected feed water temperature detected by the feed water thermistor 113, the set temperature set in the remote control L, and the detected feed water amount detected by the water amount sensor 112.
(2) The fan speed corresponding to the required amount of combustion heat is calculated.
(3) The target rotational speed is corrected by multiplying the rotational speed of (2) by the blockage degree H.
(4) The fan control unit 53 feedback-controls the fan current so that the rotational speed detected by the rotational speed sensor 42 matches the target rotational speed corrected in the above (3). The fan rotation speed is corrected according to the degree of blockage by the above processing, and a necessary amount of combustion air is secured.

  During the combustion operation, the process of step S36 is repeatedly performed. In step S36, it is determined whether or not the blockage degree has increased to a combustion limit reference value (in this case, 1.1). When the combustion limit is reached, even if the fan rotation speed is corrected with the correction value H, the combustion air quantity becomes insufficient if the combustion heat quantity is large, so the combustion heat quantity is limited to a predetermined value or less (step S38). . For example, in the case of a hot water supply device having the capacity of No. 10, even when the combustion heat quantity of No. 10 is required from the relationship between the set temperature, the feed water temperature, and the amount of hot water, the blockage degree is 1.1 to 1.2. For example, the amount of combustion heat is limited to No. 8. In this case, hot water adjusted to the set temperature is discharged by limiting the amount of hot water supply by the electric water amount control device 15. If the blockage degree is less than the combustion limit reference value (1.1), step S38 is not performed.

During the combustion operation, the process of step S40 is repeated. In step S40, it is determined whether or not the blockage degree has increased to a combustion stop reference value (in this case, 1.2). If it has risen to the combustion stop reference value, step S40 becomes NO. In this case, the number of times that NO is continuously determined in step S40 is counted (step S44). While the number of continuous times is up to 5, the process waits for 15 seconds in step D52 and repeats the processes in and after step S32. When the number of times that NO is continuously determined in step S40 reaches six times, that is, when the state where the blockage degree is equal to or greater than the combustion stop reference value continues for 90 seconds, the combustion operation is forcibly stopped in step S49. In step S56, an error is displayed, and in step S58, the combustion stop reference value is stored in the blockage degree. If step S6 is executed after executing step S58, step S6 becomes NO, and the ignition process of step S24 is not executed unless YES is determined in step S20. That is, no ignition is performed even if the ignition operation is performed. Equivalent to setting the interlock state.
In the above embodiment, if step S48 is YES, step S58 is immediately executed. By executing step S58, the interlock process is started. Instead of this, a procedure may be adopted in which step S58 is performed when the number of consecutive times that have advanced to step S56 reaches a predetermined number. According to this, the interlock process is started only when the state where the intake / exhaust passage is blocked is stably detected. Interlocks are not unnecessarily interlocked due to temporary causes. Even if the interlock process is started with a delay, the processes in steps S10, S14 and S18 are prepared, so that the combustion is not started in a state inappropriate for combustion.

  If “YES” in the step S40, the continuous number counter is zero-cleared. In this case, it is checked whether or not an operation for stopping combustion (for example, an operation for closing the hot water tap 144) is performed in step S46 (step S46), and if the combustion stop operation is not performed, the operation after step S32 is repeated to perform the combustion operation. Continue. If the combustion stop operation is performed, step S50 is executed to store the blockage degree, and step S54 is executed to end the operation.

FIG. 7 shows the change in the degree of blockage and the operating state. As the degree of blockage increases, the case where the combustion is stopped from normal combustion through limited combustion is shown. After the combustion is stopped, it is switched to the interlock state. (A) shows the case where the degree of blockage detected when the combustion start operation is performed during the interlock is equal to or greater than the combustion permission reference value, and in this case, the interlock state is maintained. (B) shows a case where the degree of blockage detected when the combustion start operation is performed during the interlock is less than the combustion permission reference value, and in this case, normal combustion is resumed. The state of (a) is a state where it is not confirmed that the combustion operation can be safely performed by the recovery process after the interlock, and corresponds to the case where it is necessary to continue the interlock to ensure the safety. The state of (b) is a case where it is confirmed that the combustion operation can be safely performed by the recovery process after the interlock, and corresponds to the case where the operation can be permitted after the interlock is released.
According to this embodiment, convenience can be improved without sacrificing safety.

The present invention includes the following embodiments in addition to the above embodiments.
a. In the above embodiment, the remote controller L can change the set temperature, but it may be fixed (for example, 60 ° C., 75 ° C.).
b. You may employ | adopt for the hot-water supply apparatus without a bypass pipe, or a non-stop type hot-water supply apparatus.
c. In the above embodiment, the blockage degree is detected based on the correction value. However, the blockage degree may be detected based on the reduction rate of the fan current. Alternatively, the current value of the fan may be kept constant, and the degree of blockage may be detected by a change in the rotation speed of the fan.
d. In the above embodiment, the fan current is detected five times every 0.5 seconds, and the blockage degree is calculated therefrom. The number of times and the time can be changed as appropriate.
e. The present invention may be applied to a fan provided on the exhaust passage side.
f. In the above embodiment, the fan leading type is shown, but the proportional valve leading type that determines the rotation speed of the fan based on the current of the proportional solenoid valve or the parallel type that controls the proportional valve and the fan according to the target combustion amount. There may be.
g. In the condition determination step in the control procedure of FIG. 5 and FIG. 6, “whether less than or not” may be replaced with “whether or not” and “whether or not” may be replaced with “whether or not”. In the present specification, the following is not mathematically exact and may be less. Similarly, the above is not mathematically exact or may mean exceeding. Similarly, the expression to reach includes the case of exceeding, and the expression to exceed includes the case of reaching.

  The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology exemplified in this specification or the drawings achieves a plurality of objects at the same time, and has technical utility by achieving one of the objects.

It is the schematic of the hot water supply apparatus which concerns on the Example of this invention. It is a block diagram of the control unit of the hot water supply apparatus. It is a graph which shows the rotation speed-fan current characteristic of a fan. It is a graph which shows the relationship of the obstruction | occlusion rate-correction value. It is a flowchart explaining the action | operation of a hot-water supply apparatus. It is a flowchart explaining the action | operation of a hot-water supply apparatus. It is a time chart explaining the action | operation of a hot-water supply apparatus.

Explanation of symbols

A Hot-water supply device K Hot-water supply device main body L Remote control 1 Water path 2 Combustor 3 Combustion housing 4 Fan 32 Exhaust duct 33 Intake and exhaust path 51 Fan current detection part (fan current detection means)
52 Rotational speed detection unit (Rotational speed detection means)
53 Fan control unit (fan control means, rotation speed setting means)
55 Correction value calculation unit (blockage degree detection means, correction value calculation means)
56 Safe Driving Department (safe driving means)
59 Correction value recording unit (correction value recording means)
79 Reference value storage unit (reference value storage means)

Claims (1)

A water heater,
A combustor,
An intake and exhaust passage communicating with the combustor;
A fan that allows air to pass through the intake and exhaust passages;
A heat exchanger installed in the exhaust path of the intake and exhaust paths,
A blockage degree detecting means for detecting the blockage degree of the intake and exhaust passage;
A reference value storage means for storing a combustion stop reference value relating to the degree of obstruction, and a combustion permission reference value relating to the degree of obstruction;
Equipped with operation control means,
The degree of blockage corresponding to the combustion stop reference value is stronger than the degree of blockage corresponding to the combustion permission reference value,
The operation control means executes a process of stopping combustion and invalidating the combustion start operation when the degree of obstruction measured by the obstruction degree detection means reaches a combustion stop reference value. When the degree of blockage measured by the blockage degree detection means after invalidation changes from the combustion stop reference value side beyond the combustion permission reference value, a process for enabling the combustion start operation is performed. Hot water supply device.

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