JP3800834B2 - Water heater - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a water heater that heats a heat exchanger with a combustion flame from a burner to obtain hot water.
[0002]
[Prior art]
A conventional water heater has a configuration shown in FIG. 8, for example. Referring to FIG. 8, the water heater includes a main burner 4 disposed in the inner body 2, and a pilot burner 6 is provided adjacent to the main burner 4. The main burner 4 is connected to a gas supply source 10 such as a gas cylinder via a main gas flow path 8 formed by a gas pipe or the like, and the pilot burner 6 is connected to the main gas flow path 8 via a pilot gas flow path 12. It is connected. An electromagnetic open / close valve 14 and a flow control valve 16 are disposed in the main gas flow path 12. The electromagnetic on-off valve 14 controls the opening and closing of the main gas passage 8, and the flow rate control valve 16 controls the flow rate of the fuel gas flowing through the main gas passage 8. When the electromagnetic on-off valve 14 is in the open state, the fuel gas is allowed to be fed through the main gas passage 8, so that the fuel gas from the gas supply source 10 passes through the main gas passage 8 to the main burner 4. In addition to being fed, it is fed to the pilot burner 6 through the main gas passage 8 and the pilot gas passage 12. On the other hand, when the electromagnetic opening / closing valve 14 is in the closed state, the supply of fuel gas through the main gas flow path 8 is stopped, and the fuel gas is not supplied to the main burner 4 and the pilot burner 6. The pilot burner 6 is provided with a disappearing detection thermocouple 20, and a counter electromotive force generating thermocouple 22 is disposed above the main burner 4.
[0003]
Such a water heater is further configured as follows to prevent incomplete combustion of the fuel gas. Generally, a water heater is installed in a room such as a kitchen or a washroom. In this way, when used indoors, if the fuel gas from the main burner is burned continuously for a long time in a poorly ventilated state, the oxygen concentration in the room decreases and incomplete combustion occurs. Therefore, in the conventional water heater, a timer means is provided in relation to the electromagnetic on-off valve. This timer means forcibly closes the electromagnetic on-off valve 14 when a predetermined set time is counted from the time when the water heater is ignited (when the electromagnetic on-off valve is opened), and thus exceeds the predetermined set time. Prevents continuous combustion. The predetermined set time is a time sufficient for normal use in a kitchen, a washroom, etc., and is set to a time during which continuous combustion does not result in incomplete combustion, for example, about 20 minutes.
[0004]
[Problems to be solved by the invention]
However, in the conventional water heater, when reignition is performed after the combustion is forcibly stopped by the timer means, the timer means can continuously burn until the predetermined set time is counted again. By repeating the above, continuous use over a substantially long time becomes possible, and incomplete combustion may occur when used in this way for a long time.
[0005]
The objective of this invention is providing the water heater which can prevent generation | occurrence | production of incomplete combustion.
Moreover, the objective of this invention is providing the water heater which can prevent the continuous use over a long time.
[0006]
[Means for Solving the Problems]
In the present invention, a heat exchanger for generating hot water, a burner for heating the heat exchanger, a gas flow path for supplying fuel gas to the burner, and a gas flow path are provided. An electromagnetic on-off valve provided, and a control means for controlling the opening and closing of the electromagnetic on-off valve,
The control means includes a forced stop signal generating means for generating a forced stop signal for closing the electromagnetic on-off valve, and a counter means for counting the number of forced stops by the forced stop signal generating means. ,
The forced stop signal generating means generates the forced stop signal when burning for a predetermined allowable combustion time after the start of combustion of the burner, thereby stopping the combustion of the burner,
When reignition is performed within a predetermined reignition period after the forced stop, the counter means counts the number of forced stops, and the forced stop signal generating means generates the forced stop signal in a time shorter than the predetermined allowable combustion time. ,
The allowable combustion time until the forced stop signal is generated becomes shorter as the count value of the counter means increases.
[0007]
According to the present invention, the control means for controlling the opening / closing of the electromagnetic open / close valve includes a forced stop signal generating means and a counter means for counting the number of forced stops. At the time of the first combustion, the forced stop signal generating means generates a forced stop signal after the elapse of a predetermined allowable combustion time after the start of combustion, whereby the electromagnetic on-off valve is closed and the burner combustion is forcibly stopped. If reignition is performed within the predetermined reignition period after the forced stop, there is a risk of continuous use. Therefore, the counter means counts the number of forced stops as one, and during the second combustion, the forced stop signal generating means A forced stop signal is generated with an allowable combustion time shorter than the allowable combustion time, and the combustion of the second burner is forcibly stopped by this forced stop signal. Thus, as the count value of the counter means increases, the allowable combustion time until the forced stop signal is generated is shortened, thereby shortening the burner combustion time, thus preventing incomplete combustion due to continuous use. it can. When re-igniting after the predetermined re-ignition period has elapsed, a sufficient time has elapsed after the end of combustion, and the count value of the counter means is reset, assuming that the surroundings such as the room are sufficiently ventilated. Is burned.
[0008]
Further, in the present invention, the forced stop signal generating means generates the forced stop signal continuously for a predetermined stop period when the count value of the counter means reaches a predetermined value, and thereby the burner for the predetermined stop period. The combustion is forcibly stopped.
[0009]
According to the present invention, when the count value of the counter means becomes a predetermined value, in other words, when continuous combustion by reignition is performed a predetermined number of times, the forced stop signal generating means continuously generates the forced stop signal for a predetermined stop period. Therefore, during this predetermined stop period, the electromagnetic on-off valve is kept closed, the burner combustion is forcibly stopped, and continuous burner combustion due to re-ignition can be reliably prevented.
[0010]
In the present invention, detection means for detecting a combustion state is provided in association with the burner, and the control means sets an allowable time setting for setting an allowable combustion time until the forced stop signal is generated. The allowable time setting means sets a standard time when the detection means detects large combustion, and sets an extension time longer than the standard time when the detection means detects small combustion. Features.
[0011]
According to the present invention, detection means for detecting the combustion state is provided, and this detection means is constituted by, for example, a detection sensor for detecting a set position of a flow rate setting member for setting a gas flow rate. When this detection means detects large combustion, the allowable time setting means sets the standard time. Further, when the detection means detects that the combustion is small, the amount of oxygen used is less than that of the large combustion, so the allowable time setting means sets an extension time longer than the standard time. Therefore, in the small combustion state, the combustion time can be lengthened while preventing incomplete combustion.
[0012]
In the present invention, the control means includes timer means provided in association with the forced stop signal generating means, and allowable time setting means for setting an allowable combustion time until the forced stop signal is generated. The allowable time setting means sets a shortened time when re-ignited within the first period of the predetermined re-ignition period, and re-ignites within a second period after the first period of the predetermined re-ignition period. Then, a standard time longer than the shortening time is set.
[0013]
According to the present invention, timer means is provided in association with the forced stop signal generating means, and the timer means starts timing from the time when combustion of the burner is forcibly stopped. If the ignition is re-ignited within the first period after the timer counts, the permissible time setting means sets a shortened time because the room is not sufficiently ventilated, and the time after the timer counts the first period after the first period. When the ignition is re-ignited within the period of 2, the combustion time setting time is set to a standard time longer than the above shortened time, assuming that the room is ventilated to some extent. Therefore, the burner is shorter when re-ignited within the first period than when re-ignited within the second period, and by this configuration, the burner is incomplete during short-term continuous combustion. Generation of combustion can be prevented.
[0014]
Further, in the present invention, a heat exchanger for generating hot water, a burner for heating the heat exchanger, a gas flow path for supplying fuel gas to the burner, and the gas flow path Comprising an electromagnetic on-off valve disposed on the control means, and a control means for controlling the opening and closing of the electromagnetic on-off valve,
The control means includes a forced stop signal generating means for generating a forced stop signal for closing the electromagnetic on-off valve, and an allowable time setting means for setting an allowable combustion time until the forced stop signal is generated. With
In relation to the burner, a detecting means for detecting the combustion state of the burner is provided,
The allowable time setting means sets a standard time when the detection means detects large combustion, and sets an extension time longer than the standard time when the detection means detects small combustion.
[0015]
In the present invention, since the basic configuration is the same as described above, when the detection means detects large combustion, the allowable time setting means sets a standard time, and when the detection means detects small combustion, The allowable time setting means sets an extension time longer than the standard time. Therefore, the burner burns for a longer time in the small combustion state than in the large combustion state, and can extend the combustion time while preventing the occurrence of incomplete combustion.
[0016]
Furthermore, in the present invention, a heat exchanger for generating hot water, a burner for heating the heat exchanger, a gas flow path for supplying fuel gas to the burner, and the gas flow path Comprising an electromagnetic on-off valve disposed on the control means, and a control means for controlling the opening and closing of the electromagnetic on-off valve,
The control means includes a forced stop signal generating means for generating a forced stop signal for closing the electromagnetic on-off valve, timer means provided in association with the forced stop signal generating means, and the forced stop signal Is provided with an allowable time setting means for setting an allowable combustion time until generation of
The allowable time setting means sets a shortened time when reignited within the first period after the forced stop, and sets the shortened time when reignited during the second period after the first period after the forced stop. It is characterized by setting a long standard time.
[0017]
According to the present invention, since the basic configuration is the same as described above, when the ignition is re-ignited within the first period after the timer starts counting, the allowable time setting means sets a shortened time shorter than the standard time. Therefore, if the ignition is re-ignited within a short time after stopping the forced combustion, the allowable combustion time of the burner is shortened, and the occurrence of incomplete combustion due to a short-term continuous combustion can be prevented.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, with reference to FIGS. 1-7, embodiment of the water heater according to this invention is described. 1 to 3 show an embodiment of a water heater according to the present invention, FIG. 1 is a diagram schematically showing an embodiment of a water heater, and FIG. 2 is a water heater of FIG. 3 is a flowchart specifically showing a part of the control of the flowchart of FIG.
[0019]
Referring to FIG. 1, the illustrated water heater includes an inner cylinder 52 whose lower part is released, a main burner 54 is disposed at the lower part of the inner cylinder 52, and a pilot burner 56 adjacent to the main burner 54. Is provided. One end of a main gas flow path 58 formed by a gas pipe, a gas tube, or the like is connected to the main burner 54, and the other end is connected to a gas supply source 60 such as a gas tank or a gas cylinder. A pilot gas flow path 62 is branched from the main gas flow path 58, and the pilot gas flow path 62 is connected to the pilot burner 56.
[0020]
The main gas flow path 58 is provided with an electromagnetic on-off valve 64 for supplying and shutting off the fuel gas and a flow rate control valve 66 for controlling the flow rate of the fuel gas, and the electromagnetic on-off valve 64 and the flow rate control valve. 66 is provided on the upstream side of the branch portion of the main gas channel 58 with the pilot gas channel 60. When the energizing current is supplied, the electromagnetic opening / closing valve 64 is opened to release the main gas flow path 58 and allow the fuel gas to be supplied to the main burner 54 and the pilot burner 56. On the other hand, when the supply of the urging current is stopped, the electromagnetic opening / closing valve 64 is closed, the main gas passage 58 is shut off, and the supply of fuel gas to the main burner 54 and the pilot burner 56 is stopped. The flow control valve 66 controls the flow area of the main gas flow path 58 and controls the supply amount of the fuel gas to the main burner 54 and the pilot burner 56, mainly the supply amount to the main burner 54.
[0021]
Although not shown in the figure, a heat exchanger is provided in the inner cylinder 52, and the water inlet portion of the heat exchanger is connected to, for example, a water pipe, and the hot water outlet portion is connected to a gate pipe. Further, in order to prevent gas leakage due to extinction in relation to the pilot burner 56, a extinction detection sensor 68 is provided, and in addition to the main burner 54, in order to prevent incomplete combustion of fuel gas, An incomplete combustion detection sensor 70 is provided.
[0022]
In such a water heater, when an ignition switch (not shown) is pressed and ignited, an energizing current is supplied to the electromagnetic on-off valve 64 to be opened, and the fuel gas from the gas supply source 60 is discharged. In addition to being supplied to the main burner 54 through the main gas passage 58, it is supplied to the pilot burner 56 through the main gas passage 58 and the pilot gas passage 62. The combustion flame of the fuel gas from the pilot burner 56 is used as a fire type for the main burner 54. The combustion flame of fuel gas from the main burner 54 is used to heat a heat exchanger (not shown). Water such as tap water is introduced into the heat exchanger from the water inlet, and the inflowed water is heated by the combustion flame from the main burner 56 to become hot water and flows out from the hot water outlet, and is thus desired. Hot water of temperature is obtained.
[0023]
The extinction detection sensor 68 is composed of, for example, a thermocouple. When the combustion of the pilot burner 56 is extinguished, the temperature of the thermocouple rapidly decreases, the electromotive force is reduced, and the energizing current of the electromagnetic on-off valve 64 is reduced, whereby the electromagnetic on-off valve 64 is closed. Therefore, when the combustion of the pilot burner 56 is extinguished, the electromagnetic on-off valve 64 is automatically closed, and gas leakage due to extinction can be prevented. Moreover, the incomplete combustion detection sensor 70 is comprised, for example from the thermocouple for back electromotive force generation. In this embodiment, incomplete combustion is detected by combining the incomplete combustion detection sensor 70 and the extinction detection sensor 68. When incomplete combustion occurs, the combustion flame of the main burner 54 becomes longer, the temperature of the incomplete combustion detection sensor 70 rises and the back electromotive force increases, and as a result, the energizing current from the extinction detection sensor 68 decreases. Thus, the electromagnetic on-off valve 64 is closed when the ambient oxygen concentration in the room or the like is about 18%. Therefore, before the incomplete combustion occurs, the electromagnetic on-off valve 64 automatically closes, and the occurrence of incomplete combustion can be prevented in advance.
[0024]
This water heater is further configured as follows to prevent continuous combustion due to re-ignition. A control means 72 for controlling the electromagnetic opening / closing valve 64 is provided, and the control means 72 is constituted by, for example, a microprocessor (CPU). In this embodiment, the control means 72 includes a timer means 74, a counter means 76, a first memory 78, a second memory 80, a forced stop signal generating means 82, and an allowable time setting means 84. The timer means 74 starts timing from the time when the electromagnetic switch 64 is opened by pressing an ignition switch (not shown), and when the electromagnetic switch 64 is closed as will be described later. Start timing from. The counter means 76 counts the number of combustion times for continuous combustion. The first memory 78 stores the allowable combustion time. In this embodiment, the first predetermined allowable combustion time is, for example, 20 minutes, the second continuous combustion time is, for example, 10 minutes, and the continuous combustion is further performed. For example, 5 minutes is stored as the third allowable combustion time. Such permissible combustion time can be appropriately set depending on the model of the water heater. The second memory 80 stores a predetermined reignition period as to whether or not reignition by an ignition switch (not shown) is determined to be continuous combustion. The predetermined reignition period is set to, for example, about 7 to 15 minutes, for example, 10 minutes in this embodiment, and the ignition switch is pressed within the predetermined reignition period (10 minutes) from the time when the electromagnetic on-off valve 64 is closed. Then, the counter means 76 adds “1” to the number of combustions as continuous reignition. On the other hand, when the ignition switch is pressed after the predetermined reignition period has elapsed from the time when the electromagnetic opening / closing valve 64 is in the closed state, it is processed as normal ignition rather than continuous reignition. This predetermined reignition period can also be set as appropriate depending on the model of the water heater. Further, the forcible stop signal generating means 82 generates a forcible stop signal for closing the electromagnetic on-off valve 64. When this forcible stop signal is supplied to the electromagnetic on-off valve 64, the electromagnetic on-off valve 64 is closed. It becomes a state. Further, the permissible time setting means 84 sets a permissible combustion time corresponding to the count value of the counter means 74, and combustion can be continued for the set permissible combustion time.
[0025]
Next, the control by the control means 72 will be described with reference to FIGS. 2 and 3 together with FIG. First, the outline of the control of the water heater will be described with reference to FIG. 1 and FIG. 2. When the ignition switch (not shown) is pressed to ignite the water heater, the steps S-1 to S- In step 2, the counter means 76 of the control means 72 adds the count value, the count value of the counter means 72 becomes “1”, and the first combustion is processed as described later. Next, the process proceeds to step S-3, where an allowable combustion time corresponding to the count value of the counter means 76 is set, and combustion of the main burner 54 and the pilot burner 56 is allowed during the set allowable combustion time. The allowable combustion time corresponding to the count value of the counter means 76 and its combustion will be described later.
[0026]
In step S-3, if the allowable combustion time corresponding to the count value is continuously burned, the forced stop signal generating means 82 generates a forced stop signal (step S-4), and the forced stop signal is generated by the electromagnetic on-off valve 64. And the electromagnetic on-off valve 64 is closed by the forced stop signal, thereby forcibly stopping the continuous combustion of the main burner 54 and the pilot burner 56 (step S-5). When the electromagnetic on-off valve 64 is closed in this way, the process proceeds to step S-6, where the timer means 74 starts measuring time and continues counting until reignition is performed by the ignition switch.
[0027]
Thereafter, when the ignition switch is pressed and reignition is performed, the process proceeds from step S-7 to step S-8, and after the generation of the forced stop signal, that is, whether the predetermined reignition period has elapsed after the timer means 74 starts measuring time. Is judged. When the ignition switch is pressed for reignition, the control means 72 compares the time measured by the timer means 74 with a predetermined reignition period (10 minutes in this embodiment) stored in the second memory 80. When the time measured by the timer means 74 is shorter than the predetermined reignition period, the combustion is performed again within a short time, so that the control means 72 treats it as continuous combustion and returns from step S-8 to step S-2. . Therefore, in the case of continuous combustion, the count value is added in step S-2, the count value of the counter means 76 becomes “2”, and the control means 72 processes as the second continuous combustion. Steps S-2 to S-9 described above are repeatedly performed.
[0028]
On the other hand, when the time measured by the timer means 74 is longer than the predetermined reignition period, the control means 72 does not process as continuous combustion, proceeds from step S-8 to step S-9, and the count value of the counter means 76 is reset. Is done. In this case, since a certain amount of time has passed after the forced combustion stop of the main burner 54 and the pilot burner 56, the surrounding air is sufficiently ventilated, so that it is treated as a new ignition and the process returns to step S-2. Thus, the above-described operation is repeatedly performed.
[0029]
Next, referring to FIG. 3 together with FIG. 1, the allowable combustion time and the combustion according to the count value of the counter means 76 in step S-3 will be described. In step S-2, the count value of the counter means 76 is added. When step S3-1 is performed, it is determined in step S3-1 whether the count value of the counter means 76 is "3" or less. In the first combustion, the count value of the counter means 76 is “1”, in the second combustion, the count value of the counter means 76 is “2”, and in the third combustion, the count value of the counter means 76 is The count value is “3”, and the count value of the counter means 76 is “4” at the time of the fourth combustion. Accordingly, the process proceeds from step S3-1 to step S3-2 until the third continuous combustion. However, when the fourth continuous combustion is performed, the process proceeds from step S3-1 to step S-4, and the forced stop signal generating means 82 outputs the forced stop signal. , The electromagnetic on-off valve 64 is closed, and the combustion of the main burner 54 and the pilot burner 56 is forcibly stopped. Such combustion stop is continued until the timer means 74 counts the predetermined reignition period, in other words, the predetermined stop period. As described above, when the number of continuous combustions is a predetermined number of times, in this embodiment, three times, and the fourth time, the combustion of the main burner 54 and the pilot burner 56 is performed for a predetermined reignition period (10 in this embodiment). This forcibly stops the fuel gas and thus prevents incomplete combustion of the fuel gas. When the ignition is re-ignited after the predetermined stop period has elapsed, the counter means 76 is reset because the surrounding ventilation has been performed, and the first combustion of the main burner 54 and the pilot burner 56 is performed.
[0030]
In step S3-1, if the count value of the counter means 76 is "3" or less, the process proceeds to step S3-2. First, in step S3-2, it is determined whether or not the count value of the counter means 76 is "1". If this count value is "1", that is, in the case of the first combustion, step S3- 3, the electromagnetic on-off valve 64 is opened, and the fuel gas is supplied to the main burner 54 and the pilot burner 56, and the fuel gas is combusted in these burners 54 and 56. When the electromagnetic on-off valve 64 is opened and combustion of the fuel gas starts, the timer means 74 starts measuring time in step S3-4. In the first combustion, the control means 72 reads 20 minutes from the first memory 78, and the allowable time setting means 84 sets the read 20 minutes as the allowable combustion time. Next, in step S3-5, it is determined whether or not the timer means 74 has timed 20 minutes, in other words, whether or not combustion has been continued for 20 minutes. Then, the combustion of the main burner 54 and the pilot burner 56 is forcibly stopped as described above.
[0031]
If the count value of the counter means 76 is not “1” in step S3-2, then the process proceeds to step S3-6, where it is determined whether or not the count value of the counter means 76 is “2”. In the case of “2”, that is, in the case of the second combustion, the process proceeds to step S3-7, the electromagnetic on-off valve 64 is opened, and the fuel gas is supplied to the main burner 54 and the pilot burner 56. The fuel gas is combusted at 54 and 56, and the timer means 74 starts measuring time at step S3-8. In the second combustion, the control means 72 reads 10 minutes from the first memory 78, and the allowable time setting means 84 sets the read 10 minutes as the allowable combustion time. Next, in step S3-9, it is determined whether or not the timer means 74 has counted 10 minutes, in other words, whether or not combustion has been continued for 10 minutes. Then, the combustion of the main burner 54 and the pilot burner 56 is forcibly stopped as described above.
[0032]
If the count value of the counter means 76 is not “2” in step S3-6, then the process proceeds to step S3-10, where it is determined whether or not the count value of the counter means 76 is “3”. In the case of “3”, that is, in the case of the third combustion, the process proceeds to step S3-11 where the electromagnetic on-off valve 64 is opened and the fuel gas is burned in the main burner 54 and the pilot burner 56, and step S3 is performed. At -12, the timer means 74 starts measuring time. In the third combustion, the control means 72 reads 5 minutes from the first memory 78, and the allowable time setting means 84 sets this 5 minutes as the allowable combustion time. Next, in step S3-13, it is determined whether or not the timer means 74 has timed 5 minutes, in other words, whether or not combustion has been continued for 5 minutes. Then, the combustion of the main burner 54 and the pilot burner 56 is forcibly stopped as described above. In step S3-10, if the count value of the counter means 76 is not "3", it is determined that combustion has been performed three times in succession, and the process proceeds to step S-4, where the combustion of the main burner 54 and the pilot burner 56 is forced. During a predetermined stop period.
[0033]
In this water heater, the allowable combustion time is shortened as the count value of the counter means 76 increases, in other words, as the number of times of continuous combustion increases, so that the operator can recognize continuous combustion and allow By shortening the combustion time, incomplete combustion of the fuel gas can be prevented in advance.
[0034]
In this embodiment, continuous combustion can be performed up to 3 times by re-ignition, but continuous combustion is performed up to 2 times by re-ignition or a predetermined number of times of 4 or more in consideration of the model of the water heater, installation location, etc. In such a case, the allowable combustion time at each number of combustions can be set as appropriate depending on the model of the water heater.
[0035]
In the embodiment described above, the allowable combustion time is changed depending on the number of times of continuous combustion, but in addition to such a configuration, the combustion stop time, that is, the time until the ignition is stopped after forcibly stopping the combustion is related to. It is also possible to change the allowable combustion time. In this case, the configuration of the water heater may be substantially the same as the configuration shown in FIG. 1, and the control by the control means 72 may be performed as follows, for example.
[0036]
1 and 4, when an ignition switch (not shown) is ignited (step S-21), the count value of the counter means 76 is added (step S-22). And the combustion for the time according to the count value of the counter means 76 is performed (step S-23), and this combustion is performed according to the flowchart shown in FIG. 3 like step S-3, for example. When the combustion for the allowable combustion time is thus performed, the forced stop signal generating means 82 generates a forced stop signal (step S-24), and the electromagnetic on-off valve 64 is closed by the forced stop signal (step S-24). S-25), the combustion of the main burner 54 and the pilot burner 56 is forcibly stopped, and the timer means 74 starts measuring time (step S-26). The flow of operations from step S-21 to step S-26 is substantially the same as the contents of steps S-1 to S-6 in FIG.
[0037]
When combustion of the water heater is forcibly stopped and an ignition switch (not shown) is pressed and reignited, the process proceeds from step S-27 to step S-28, and this reignition is the first after the forced stop. In this embodiment, it is determined whether or not it is within 5 minutes. If it is within the first period, the process proceeds to step S-29 and the counter means 76 sets the count value “1”. The addition is performed, and then the process returns to step S-22. Accordingly, when the ignition is re-ignited within the first period after the first combustion, the count value of the counter means 76 is added in step S-29 and step S-22. The count value becomes “3”, and the allowable combustion time corresponding to this count value is read out in step S-23, and the allowable time setting means 84 sets the read time, in this case 5 minutes, as the combustible time. . Further, when the ignition is re-ignited within the first period after the second combustion, as easily understood, the count value of the counter means 76 in the third combustion becomes “4”, which is related to the third continuous combustion. The combustion of the main burner 54 and the pilot burner 56 is forcibly stopped. Note that the time for setting the first period, which is 5 minutes in this embodiment, is stored in the second memory 78, for example.
[0038]
On the other hand, if the re-ignition is not performed within the first period of the re-ignition period, the process proceeds from step S-28 to step S-30. In step S-30, the second re-ignition after the forced stop is performed. In this form, which is within the period, it is determined whether it is 5 to 10 minutes. If reignition is performed within the second period after the first period in the reignition period, the process returns from step S-30 to step S-22. In step S-22, the count value of the counter means 76 is returned. Is incremented by "1", and Steps S-22 to S-30 are repeatedly performed. Accordingly, as described above, when the ignition is re-ignited within the second period after the first combustion, the count value of the counter means 76 is added in step S-22, so that the counter means in the second combustion The count value of 76 becomes “2”. When the ignition is re-ignited within the second period after the second (or third) combustion, the count value of the counter means 76 in the third (or fourth) combustion is “ 3 "(or" 4 "), and in step S-23, an allowable combustion time corresponding to this count value is set.
[0039]
In step S-30, if the reignition is not performed within the second period of the reignition period, it means that reignition was not performed within the reignition period. Proceeding to S-31, the count value of the counter means 76 is reset, and returning to step S-22, this reignition is processed as the first combustion.
[0040]
As described above, in the above-described control, when re-ignition is performed within the second period of the re-ignition period, the count value of the counter means 76 is incremented by “1”. The standard time of 10 minutes is set, and at the time of the third combustion, the standard time is set to 5 minutes as the allowable combustion time. On the other hand, if reignition is performed within the first period of the reignition period, the time until the reignition is forced after the combustion is forcibly stopped is short, so that it is treated as continuous combustion with almost no stop period. Then, the count value of the counter means 76 is incremented by “2”, and at the time of the second combustion, the shortened time shorter than the standard time, 5 minutes in this embodiment, is set as the allowable combustion time, and at the time of the third combustion, Combustion is forcibly stopped. In this way, if ignition is forcibly stopped within a short period of time after the combustion is forcibly stopped, the shortened time shorter than the standard time is set as the allowable combustion time in the next combustion, so incomplete combustion of the fuel gas Can be further prevented.
[0041]
In the above-described embodiment, the added value of the counter means 76 is increased and, as a result, the allowable combustion time is shortened. Instead, for example, the first memory 78 has a shortened time shorter than the standard time. It can also be stored separately. In this case, for example, the allowable combustion time for the second combustion can be set, for example, 7 minutes, and the third allowable combustion time, for example, 3 minutes.
[0042]
Further, for example, in the above-described embodiment, the reignition period is divided into the first period and the second period, and a shortening time is set at the time of reignition within the first period, and the reignition period is within the second period. The standard time is set at the time of reignition, but the present invention is not limited to this, and the reignition period can be divided into three or more, and the allowable combustion time can be set corresponding to each period. .
[0043]
FIG. 5 is a diagram schematically showing another embodiment of the water heater, FIG. 6 is a flowchart showing an outline of control of the water heater according to another embodiment, and FIG. It is a flowchart which shows a part of flowchart specifically. In other embodiments, substantially the same members as those shown in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted.
[0044]
Referring to FIG. 5, in this other embodiment, detection sensor 90 is associated with a flow rate setting member (not shown) of flow rate control valve 66, for example, an operation dial for setting the temperature of hot water flowing out from the heat exchanger. Is provided. The flow rate setting member sets the flow rate of the fuel gas flowing through the main gas flow path 58, and controls the combustion state of the main burner 54 by controlling the gas flow rate by the flow rate control valve 66, thereby flowing out of the water heater. The temperature of the hot water is adjusted. The detection sensor 90 functions as a detection means for detecting the combustion state of the main burner 54, detects the set position of a flow rate setting means (not shown), and based on this set position, the combustion state of the main burner 54, In the embodiment, it is detected whether the combustion flame is in the large combustion state or the combustion flame is in the small combustion state. That is, when the gas flow rate is increased by the flow rate setting member, the combustion flame of the main burner 54 increases, and this detection sensor 90 detects large combustion based on the set position of the flow rate setting member. On the other hand, when the gas flow rate is reduced by the flow rate setting member, the combustion flame of the main burner 54 is reduced, and this detection sensor 90 detects small combustion based on the set position of the flow rate setting member.
[0045]
In this other embodiment, the first memory 78 further stores an extended time longer than the standard time in addition to the standard time as the allowable combustion time. That is, as described above, as the standard time as the combustible time in the continuous combustion, the first memory 78 includes, for example, the first allowable combustion time 20 minutes, the second allowable combustion time 10 minutes, and the third time. The 5th allowable combustion time is stored. Further, since the amount of oxygen used in the small combustion state is small, an extension time longer than the standard time is set as the occurrence of incomplete combustion is small, and, for example, the first allowable combustion is stored in the first memory 78. A time of 20 minutes, a second allowable combustion time of 15 minutes, and a third allowable combustion time of 7.5 minutes are stored. The other configuration of this embodiment is substantially the same as that of the embodiment shown in FIG.
[0046]
The outline of the control of the water heater will be described with reference to FIGS. 5 and 6 as follows. When an ignition switch (not shown) is ignited (step S-41), the count value of the counter means 76 is added (step S-42). Next, in step S-43, the state of the set combustion is detected by the detection sensor 90. When the set combustion is in the large combustion state, the process proceeds from step S-43 to step S-44. When the allowable combustion time corresponding to the combustion is set, and the combustion for the set allowable combustion time is performed, the process proceeds to step S-45. In step S-44, since the combustion is in the large combustion state, the control means 72 reads the standard time stored in the first memory 78, and the allowable time setting means 84 includes the counter means 76 of the standard time. Set the time corresponding to the count value. The setting of the allowable combustion time and the combustion during that period are performed according to the flowchart shown in FIG. 3, for example, similarly to step S-3 in the above-described embodiment.
[0047]
On the other hand, when the set combustion is in the small combustion state, the process proceeds from step S-43 to step S-46, where the count value of the counter means 76 and the allowable combustion time corresponding to the small combustion are set. When combustion is performed, the process proceeds to step S-45. In step S-46, since the combustion is in the small combustion state, the control means 72 reads the extended time stored in the first memory 78, and the allowable time setting means 84 includes the counter means 76 of the extended time. Set the time corresponding to the count value. The setting of the allowable combustion time and the combustion during that period will be described in detail later.
[0048]
When the process proceeds from step S-44 or step S-46 to step S-45, the forced stop signal generating means 82 generates a forced stop signal, and the electromagnetic stop valve 64 is closed by this forced stop signal (step S-). 47) Combustion of the main burner 54 and the pilot burner 56 is forcibly stopped, and the timer means 74 starts measuring time (step S-48).
[0049]
Thereafter, when the ignition switch is pressed and reignition is performed, the process proceeds from step S-49 to step S-50, and after the generation of the forced stop signal, that is, whether or not the predetermined reignition period has elapsed after the timer means 74 starts measuring time. Is judged. When the time measured by the timer means 74 is shorter than the predetermined reignition period, the control means 72 processes as continuous combustion and returns from step S-50 to step S-42. Therefore, in the case of continuous combustion, in step S-42, the counter means 76 adds “1” to give a count value of “2”, and the control means 72 processes as the second continuous combustion, and the above-described steps S-42 to S-42. Step S-50 is repeatedly performed. On the other hand, when the time measured by the timer means 74 is longer than the predetermined reignition period, the process proceeds from step S-50 to step S-51, and the count value of the counter means 76 is reset. In this case, the control means 72 does not process as continuous combustion, but processes as new ignition, returns to step S-42, and the control mentioned above is repeatedly performed. The operations in steps S-45 to S-51 are substantially the same as the contents in steps -4 to S-9 in the flowchart of FIG. 2 in the above-described embodiment.
[0050]
Next, referring to FIG. 7 together with FIG. 5, the contents of step S-46 will be specifically described. When the process proceeds from step S-43 to step S46-1, it is determined whether or not the count value of the counter means 76 is "3" or less. The count value of the counter means 76 is “1” (or “2”, “3”) at the first (or second or third) combustion, but at the fourth combustion, The count value is “4”. Therefore, the process proceeds from step S46-1 to step S46-2 until the third continuous combustion. However, when the fourth continuous combustion is performed, the process proceeds from step S46-1 to step S-45. The stop signal generating means 82 generates a forced stop signal, and the electromagnetic on-off valve 64 is closed.
[0051]
When the process proceeds from step S46-1 to step S46-2, it is determined whether or not the count value of the counter means 76 is “1”. If this count value is “1”, that is, in the case of the first combustion. In step S46-3, the electromagnetic on-off valve 64 is opened and the fuel gas is burned in the main burner 54 and the pilot burner 56 (step S46-3), and the timer means 74 starts measuring time ( Step S46-4). In the first combustion in the small combustion state, the control means 72 reads 20 minutes corresponding to the first time out of the delay times stored in the first memory 78, and the allowable time setting means 84 allows the read 20 minutes. Set as burning time. Next, in step S46-5, it is determined whether or not the combustion has been continued for 20 minutes. If the combustion has been continued for 20 minutes, the process proceeds to step S-45, and the combustion of the main burner 54 and the pilot burner 56 is described above. To stop it forcibly.
[0052]
If the count value of the counter means 76 is not “1”, the process proceeds from step S46-2 to step S46-6 to determine whether or not the count value of the counter means 76 is “2”. ”, That is, in the case of the second combustion, the process proceeds to step S46-7, the electromagnetic on-off valve 64 is opened, and the fuel gas is burned in the main burner 54 and the pilot burner 56 (step S46-7). In addition, the timer means 74 starts measuring time (step S46-8). In the second combustion in the small combustion state, the control means 72 reads 15 minutes corresponding to the second time out of the delay times stored in the first memory 78, and the allowable time setting means 84 allows the read 15 minutes. Set as burning time. Next, in step S46-9, it is determined whether or not the combustion is continued for 15 minutes. If the combustion is continued for 15 minutes, the process proceeds to step S-45, and the combustion of the main burner 54 and the pilot burner 56 is described above. To stop it forcibly.
[0053]
When the count value of the counter means 76 is not “2”, the process proceeds from step S46-6 to step S46-10, where it is determined whether or not the count value of the counter means 76 is “3”. ”, That is, in the case of the third combustion, the process proceeds to step S46-11, the electromagnetic on-off valve 64 is opened, and the fuel gas is burned in the main burner 54 and the pilot burner 56 (step S46-11). In addition, the timer means 74 starts measuring time (step S46-12). In the third combustion in the small combustion state, the control means 72 reads 7.5 minutes corresponding to the third time out of the delay times stored in the first memory 78, and the allowable time setting means 84 reads 7. 5 minutes is set as the allowable combustion time. Next, in step S46-13, it is determined whether or not the combustion is continued for 7.5 minutes. If the combustion is continued for 7.5 minutes, the process proceeds to step S-45, and the main burner 54 and the pilot burner 56 are processed. Is forcibly stopped as described above.
[0054]
Thus, by changing the allowable combustion time according to the combustion state, it is possible to lengthen the combustion time while preventing incomplete combustion of the fuel gas. In this embodiment, the permissible combustion time is changed by detecting whether the combustion state is large combustion or small combustion, but either one of three types of large combustion, medium combustion, small combustion, or 4 It is also possible to change the allowable combustion time by detecting any of the types or more.
[0055]
As mentioned above, although embodiment of the water heater according to this invention was described, this invention is not limited to this embodiment, A various deformation | transformation thru | or correction | amendment are possible without deviating from the scope of the present invention.
[0056]
For example, although not specifically described, the control shown in FIG. 4 can be combined with the control shown in FIGS. 6 and 7, and these controls (the allowable combustion time is shortened according to the count value of the counter means 76). The control, the control for changing the allowable combustion time depending on the time of reignition, and the control for changing the allowable combustion time depending on the combustion state) can be used alone.
[0057]
【The invention's effect】
According to the water heater of the first aspect of the present invention, as the count value of the counter means increases, the allowable combustion time until the forced stop signal is generated is shortened, whereby the burner combustion time is shortened and thus continuously. Incomplete combustion due to use can be prevented.
[0058]
According to the water heater of claim 2 of the present invention, when continuous combustion by reignition is performed a predetermined number of times, the forced stop signal generating means continuously generates the forced stop signal for a predetermined stop period. Therefore, during the predetermined stop period, the electromagnetic on-off valve is forcibly held in the closed state, and continuous combustion of the burner due to reignition can be reliably prevented.
[0059]
According to the water heater of claim 3 of the present invention, the standard time is set as the allowable combustion time for large combustion, and the extended time longer than the standard time is set as the allowable combustion time for small combustion. The combustion time can be lengthened while preventing incomplete combustion in a small combustion state.
[0060]
According to the water heater of claim 4 of the present invention, when the ignition is re-ignited within the first period, the shortened time is set as the allowable combustion time, and when the ignition is re-ignited within the second period, the allowable combustion time is set. As a standard time longer than the shortened time, the allowable combustion time can be shortened during reignition within the first period to prevent the occurrence of incomplete combustion.
[0061]
According to the water heater of claim 5 of the present invention, in the small combustion state, the extension time is set as the allowable combustion time, so that the combustion time can be lengthened while preventing the occurrence of incomplete combustion. it can.
[0062]
Further, according to the water heater of claim 6 of the present invention, when reignition is performed within the first period, the shortened time is set as the allowable combustion time, so that the occurrence of incomplete combustion at the time of reignition is prevented. can do.
[Brief description of the drawings]
FIG. 1 is a diagram schematically illustrating an embodiment of a water heater according to the present invention.
FIG. 2 is a flowchart showing an outline of control of the water heater in FIG. 1;
FIG. 3 is a flowchart specifically showing a part of the flowchart of FIG. 2;
FIG. 4 is a flowchart showing an outline of another control of the water heater.
FIG. 5 is a diagram schematically showing another embodiment of a water heater according to the present invention.
6 is a flowchart showing an outline of control of the water heater in FIG. 5;
FIG. 7 is a flowchart specifically showing a part of the flowchart of FIG. 6;
FIG. 8 is a diagram schematically illustrating an example of a conventional water heater.
[Explanation of symbols]
54 Main burner
56 Pilot burner
58 Main gas flow path
62 Pilot gas flow path
64 solenoid valve
66 Flow control valve
72 Control means
74 Timer means
76 Counter means
78 First memory
80 second memory
82 Forced stop signal generation means
84 Allowable time setting means
90 Detection sensor

Claims (6)

A heat exchanger for generating hot water, a burner for heating the heat exchanger, a gas flow path for supplying fuel gas to the burner, and an electromagnetic wave disposed in the gas flow path An on-off valve, and a control means for controlling opening and closing of the electromagnetic on-off valve,
The control means includes a forced stop signal generating means for generating a forced stop signal for closing the electromagnetic on-off valve, and a counter means for counting the number of forced stops by the forced stop signal generating means. ,
The forced stop signal generating means generates the forced stop signal when burning for a predetermined allowable combustion time after the start of combustion of the burner, thereby stopping the combustion of the burner,
When reignition is performed within a predetermined reignition period after the forced stop, the counter means counts the number of forced stops, and the forced stop signal generating means generates the forced stop signal in a time shorter than the predetermined allowable combustion time. ,
As the count value of the counter means increases, an allowable combustion time until the forced stop signal is generated becomes shorter. The forced stop signal generating means generates the forced stop signal continuously for a predetermined stop period when the count value of the counter means reaches a predetermined value, thereby forcibly burning the burner during the predetermined stop period. The water heater according to claim 1, wherein the water heater is stopped. Detection means for detecting a combustion state is provided in relation to the burner, and the control means includes an allowable time setting means for setting an allowable combustion time until the forced stop signal is generated, and the allowable The time setting means sets a standard time when the detection means detects large combustion, and sets an extension time longer than the standard time when the detection means detects small combustion. Or the water heater of 2 description. The control means includes timer means provided in association with the forced stop signal generating means, and allowable time setting means for setting an allowable combustion time until the forced stop signal is generated, and the allowable time setting means Sets a shortened time when re-ignited within the first period of the predetermined re-ignition period, and re-ignites within a second period after the first period of the predetermined re-ignition period. The water heater according to claim 1 or 2, wherein a long standard time is set. A heat exchanger for generating hot water, a burner for heating the heat exchanger, a gas flow path for supplying fuel gas to the burner, and an electromagnetic wave disposed in the gas flow path An on-off valve, and a control means for controlling opening and closing of the electromagnetic on-off valve,
The control means includes a forced stop signal generating means for generating a forced stop signal for closing the electromagnetic on-off valve, and an allowable time setting means for setting an allowable combustion time until the forced stop signal is generated. With
In relation to the burner, a detecting means for detecting the combustion state of the burner is provided,
The allowable time setting means sets a standard time when the detection means detects large combustion, and sets an extended time longer than the standard time when the detection means detects small combustion. Boiler. A heat exchanger for generating hot water, a burner for heating the heat exchanger, a gas flow path for supplying fuel gas to the burner, and an electromagnetic wave disposed in the gas flow path An on-off valve, and a control means for controlling opening and closing of the electromagnetic on-off valve,
The control means includes a forced stop signal generating means for generating a forced stop signal for closing the electromagnetic on-off valve, timer means provided in association with the forced stop signal generating means, and the forced stop signal Is provided with an allowable time setting means for setting an allowable combustion time until generation of
The allowable time setting means sets a shortened time when re-ignited within a first period after forced stop, and re-ignites within a second period after the first period after forced stop. A water heater characterized by setting a long standard time.

Images