JP4050722B2 - 1 fan type combined heat source machine - Google Patents

Description

  The present invention relates to first and second combustion chambers, a first heat exchanger for hot water heated by a first burner housed in the first combustion chamber, and a second burner housed in the second combustion chamber. And a second heat exchanger for purposes other than hot water supply such as heating for heating and reheating a bath, and supplying combustion air from a single combustion fan to both the first and second combustion chambers It relates to the 1 fan type combined heat source machine.

  In this type of single fan type combined heat source machine, combustion air is supplied to both the first and second combustion chambers by the operation of the combustion fan. When hot water is supplied by the operation on the first heat exchanger side, the inside of the first heat exchanger is filled with hot water even after the operation on the first heat exchanger side is stopped by stopping the hot water supply. When the operation on the second heat exchanger side is performed in this state, only the air supplied to the first combustion chamber flows through the first heat exchanger, and the hot water in the first heat exchanger is cooled. As a result, a so-called cold water sandwich phenomenon occurs in which cold water cooled in the first heat exchanger flows out of the hot water tap and the hot water temperature temporarily decreases during reheating. In addition, when the temperature is low, the water in the first heat exchanger may freeze during the single operation on the second heat exchanger side.

  Conventionally, in order to solve such a problem, there is known a one-fan type combined heat source apparatus provided with a supply air heating means for heating air sucked into a combustion fan by exhaust heat on the second heat exchanger side (for example, patents) Reference 1). According to this, since the air heated by the supply air heating means is supplied from the combustion fan during the single operation on the second heat exchanger side, the cooling of the first heat exchanger is suppressed.

However, this structure is complicated and expensive due to the provision of the air supply heating means. Also, during simultaneous operation on the first heat exchanger side and the second heat exchanger side (air heating is performed by the supply air heating means) and during single operation on the first heat exchanger side (air supply by the supply air heating means) In this case, there is a difference in the temperature of the air supplied to the first combustion chamber and a difference in the actual supply of combustion air due to the difference in the air density due to this temperature difference. When the first heat exchanger side and the second heat exchanger side are operated simultaneously, the air temperature changes due to the change in the combustion amount of the second burner, and the hot water supply temperature becomes unstable. This causes problems such as
JP-A-6-201190 (paragraph 0014, FIG. 1)

  In view of the above points, the present invention causes the above-described problems such as the cold water sandwich phenomenon due to the cooling of the first heat exchanger and the freezing of water in the first heat exchanger during the single operation on the second heat exchanger side. It is an object of the present invention to provide a one-fan type composite heat source machine that can be prevented without any problem and that is simple and inexpensive.

In order to solve the above-described problems, the present invention provides first and second combustion chambers, a first heat exchanger for hot water heated by a first burner housed in the first combustion chamber, and a second A second heat exchanger for use other than hot water heated by a second burner housed in the combustion chamber, and supplying combustion air from a single combustion fan to both the first and second combustion chambers The one-fan type combined heat source apparatus includes control means for controlling the operation of the first burner during the single operation on the second heat exchanger side, and this control means is a predetermined after the operation stop on the first heat exchanger side. The first burner is configured to burn at a time , and the predetermined time includes a time condition that an elapsed time from the operation stop on the first heat exchanger side is a predetermined time or more, and a hot water temperature of the first heat exchanger. Satisfied with the temperature condition that the detection temperature of the hot water temperature sensor that detects the temperature has fallen below the predetermined temperature A second predetermined time longer than the predetermined time and a second predetermined temperature lower than the predetermined temperature are determined, and the control means stops the operation on the first heat exchanger side. When the elapsed time from the time reaches the second predetermined time or more, the first burner is configured to burn only when the detected temperature of the hot water temperature sensor becomes the second predetermined temperature or lower. Features.

According to the present invention, the first burner can be burned so that the hot water temperature of the first heat exchanger is maintained at a predetermined temperature during the single operation on the second heat exchanger side. Therefore, it is possible to prevent the cold water sandwich phenomenon from occurring due to the cooling of the first heat exchanger and the freezing of water in the first heat exchanger during the single operation on the second heat exchanger side. In the present invention, hardware means such as the conventional air supply heating means is unnecessary, the structure is simplified, and the cost can be reduced. In addition, since the air is not heated by exhaust heat on the second heat exchanger side, the simultaneous operation on the first heat exchanger side and the second heat exchanger side and the single operation on the first heat exchanger side Therefore, there is no problem that a difference occurs in the actual supply amount of combustion air, which adversely affects the combustibility, and a problem that the hot water supply temperature fluctuates due to a change in the combustion amount of the second burner during simultaneous operation.

By the way, when the hot water temperature sensor is out of order, there is a possibility of erroneous detection that the hot water temperature of the first heat exchanger is actually high but low, and when the first burner is burned in this state, There is a risk of overheating (boiling) of the heat exchanger. Here, in the present invention, the predetermined time is set such that the elapsed time from the operation stop on the first heat exchanger side becomes a predetermined time or more, and the detected temperature of the hot water temperature sensor becomes a predetermined temperature or less. because it is when the temperature condition is satisfied together that, until the first heat exchanger water temperature and passed some time from the stop of the operation of the first heat exchanger side is decreased, hot water in deviation of water temperature sensor Even if the temperature is erroneously detected as being equal to or lower than the predetermined temperature, the first burner is not burned, and overheating of the first heat exchanger is prevented.

  When the operation on the first heat exchanger side is stopped, the hot water remaining in the tapping pipe on the downstream side of the first heat exchanger gradually cools by natural heat dissipation, and the elapsed time from the operation stop on the first heat exchanger side When it gets longer, the hot water remaining in the tapping pipe cools down and becomes cold water. In this state, a cold water sandwich phenomenon occurs due to the cold water in the hot water discharge pipe when reheating hot water, and therefore it is useless even if the hot water in the first heat exchanger is kept at an appropriate temperature.

Here, according to the present invention, after the elapsed time from shutdown of the first heat exchanger side becomes a second predetermined time, taken cold water remaining in the hot water pipe, a first heat exchanger Rather than keeping the hot water in the chamber at an appropriate temperature (predetermined temperature), the first burner is burned so that the water temperature in the first heat exchanger does not fall below the temperature required for freezing prevention (second predetermined temperature). Can be made. As a result, energy consumption can be minimized.

  The combustion of the first burner may be stopped when the hot water temperature of the first heat exchanger rises to a combustion stop temperature set for stopping combustion (for example, a temperature higher than the predetermined temperature by a predetermined hysteresis). However, even if the hot water temperature of the first heat exchanger rises to the combustion stop temperature, it is erroneously detected that the hot water temperature remains low due to a malfunction of the hot water temperature sensor, and the combustion of the first burner is continued and the first heat exchanger May cause overheating. In this case, the combustion of the first burner is stopped when the detected temperature of the hot water temperature sensor becomes equal to or higher than the combustion stop temperature, and even if the detected temperature of the hot water temperature sensor does not become higher than the combustion stop temperature, If it is configured to stop the combustion of the first burner when a predetermined fixed time has elapsed from the start of combustion, overheating of the first heat exchanger due to erroneous detection can be prevented.

  In the embodiment described later, the control means corresponds to the control program shown in FIG. 2, wherein the predetermined temperature is TH1, the second predetermined temperature is TH2, the predetermined time is TM1, and the second The predetermined time is TM2, the combustion stop temperature is THe1, THe2, and the predetermined fixed time is TMe1, TMe2.

  FIG. 1 shows a combined heat source machine that performs hot water supply and heating. This heat source machine includes a first combustion chamber 1 and a second combustion chamber 2, and a first heat exchanger 4 for hot water supply disposed above the first burner 3 accommodated in the first combustion chamber 1. The second heat exchanger 6 for heating is arranged to be heated by the second burner 5 that is heated and accommodated in the second combustion chamber 2. Combustion air is supplied to the first and second combustion chambers 1 and 2 from a single combustion fan 7. Thus, a 1-fan type combined heat source machine is configured.

  The first heat exchanger 4 is connected to an upstream water supply pipe 4a and a downstream hot water discharge pipe 4b. The first heat exchanger 4 is opened by opening a hot water tap (not shown) at the downstream end of the hot water discharge pipe 4b. When the water is passed through, the first burner 3 is ignited, and hot water having a set temperature set by a remote controller or the like is discharged from the tap. In this embodiment, a bypass pipe 4c for connecting the water supply pipe 4a and the hot water discharge pipe 4b is provided, and the hot water temperature is adjusted by a bypass mixing system. The second heat exchanger 6 is connected to a heating circuit (not shown) such as floor heating via the forward pipe 6a and the return pipe 6b, and hot water is supplied to the heating circuit via the second heat exchanger 6. Circulate and heat.

  Gas is supplied to the first and second burners 3 and 5 via the electromagnetic on-off valves 31 and 51 and the electromagnetic proportional valves 32 and 52, respectively. Combustion is started and stopped, and the combustion amounts of the burners 3 and 5 are adjusted by the electromagnetic proportional valves 32 and 52. The electromagnetic on-off valves 31 and 51, the electromagnetic proportional valves 32 and 52, and the combustion fan 7 are controlled by a controller 8 serving as control means. During the operation on the first heat exchanger 4 side (at the time of hot water supply operation) or the operation on the second heat exchanger 6 side (at the time of heating operation), the combustion of the burners 3 and 5 corresponding to the hot water supply load and the heating load is performed. The amount is calculated, the opening degree of the electromagnetic proportional valves 32 and 52 is controlled in accordance with the amount of combustion, and the rotational speed of the combustion fan 7 is controlled so that the amount of combustion air corresponding to the amount of combustion is supplied. To do. In addition, a signal from a hot water temperature sensor 9 that detects the hot water temperature of the first heat exchanger 4 is input to the controller 8, and the first burner 3 based on the temperature detected by the hot water temperature sensor 9 is used during a hot water supply operation. Performs feedback control of the combustion amount.

  By the way, at the time of heating independent operation which operates only the 2nd heat exchanger 6 side, since the air from the combustion fan 7 is supplied also to the 1st combustion chamber 1 and flows into the 1st heat exchanger 4, the 1st heat exchanger 4 is air-cooled, and the hot water in the first heat exchanger 4 is cooled. As a result, a so-called cold water sandwich phenomenon occurs in which cold water cooled in the first heat exchanger 4 flows out of the hot water tap and the hot water temperature temporarily decreases during reheating. In addition, when the temperature is low, the water in the first heat exchanger 4 may freeze during heating single operation.

  Therefore, in the present embodiment, the first burner 3 is controlled for the purpose of keeping the temperature of the first heat exchanger 4 during heating single operation. This control is executed at the time of heating independent operation, and the details will be described with reference to FIG. First, the various determination reference values shown in FIG. 2 will be described. TM1 and TM2 are determination reference times related to an elapsed time TM after the operation on the first heat exchanger 4 side, that is, the hot water supply operation is stopped, and TM1 is a hot water supply operation temperature of the first heat exchanger 4 For example, TM2 is set to about 5 minutes in accordance with the time during which the temperature is maintained at a certain level or more after the stop of the water. For example, it is set to about 10 minutes in accordance with the time taken to lower the temperature to feel cold. TH1, TH2, THe1, and THe2 are determination reference temperatures related to the detected temperature TH of the hot water temperature sensor 9, and TH1 is set to, for example, about 40 ° C. according to the temperature that a person feels warm. The temperature is set to about 1 ° C., for example, in accordance with the temperature necessary to prevent the residual water in the heat exchanger 4 from freezing. THe1 and THe2 are determination reference temperatures for stopping combustion, and are set higher by a predetermined hysteresis (for example, about 3 ° C.) than TH1 and TH2, respectively. TMe1 and TMe2 are determination reference times for stopping combustion based on the elapsed time TMe from the start of combustion of the first burner 3, and are adjusted to a time that does not cause overheating (boiling) of the first heat exchanger 4. For example, it is set to about 5 seconds.

  At the time of heating independent operation, first, it is determined whether or not the elapsed time TM after stopping the hot water supply operation in step S1 is equal to or greater than TM2, and if TM <TM2, the hot water supply operation is stopped in step S2. It is determined whether or not the elapsed time TM has been equal to or greater than TM1. When TM ≧ TM1, the process proceeds to step S3, and it is determined whether or not the detected temperature TH of the hot water temperature sensor 9 is equal to or lower than TH1. If T ≦ TH1, the first burner 3 is burned in step S4. If the hot water temperature sensor 9 is out of order, it may be erroneously detected that the hot water temperature of the first heat exchanger 4 is actually high but low immediately after the hot water supply operation is stopped. In this state, the first burner may be erroneously detected. When 3 is burned, the first heat exchanger 4 may be overheated. However, in the present embodiment, until TM1 elapses after the hot water supply operation is stopped, even if the detected temperature TH of the hot water temperature sensor 9 becomes equal to or lower than TH1, the first burner 3 is not burned, and the first heat exchanger 4 Overheating is effectively prevented.

  If the 1st burner 3 is burned, it will progress to the step of S5 next and it will be discriminate | determined whether the detected temperature TH of the hot water temperature sensor 9 became more than THe1. When TH ≧ THe1, the combustion of the first burner 3 is stopped in step S7. If TH <THe1, it is determined in step S6 whether the elapsed time TMe from the start of combustion of the first burner 3 is equal to or greater than TMe1, and when TMe ≧ TMe1, the step S7 is also performed. The combustion of the first burner 3 is stopped. Accordingly, even if the detected temperature TH of the hot water temperature sensor 9 does not become equal to or higher than THe1, if the elapsed time TMe from the start of combustion of the first burner 3 becomes equal to or higher than TMe1, the combustion of the first burner 3 is stopped. Become. Therefore, it can be reliably prevented that the hot water temperature sensor 9 is erroneously detected that the hot water temperature remains low, and the combustion of the first burner 3 is continued and the first heat exchanger 4 is overheated.

  The above process is repeated until the elapsed time TM from the stop of the hot water supply operation becomes equal to or greater than TM2, and the hot water temperature of the first heat exchanger 4 is maintained at a temperature close to TH1. Accordingly, it is possible to prevent the occurrence of a cold water sandwich phenomenon in which cold water cooled in the first heat exchanger 4 is discharged during reheating.

  When the elapsed time TM from the stop of the hot water supply operation becomes TM2 or more, the residual water in the tapping pipe 4b becomes considerably low temperature, and a cold water sandwich phenomenon due to this residual water occurs, so the hot water temperature of the first heat exchanger 4 Is wasted even if maintained at TH1. Therefore, in the present embodiment, when the elapsed time TM after stopping the hot water supply operation becomes equal to or greater than TM2, it is determined whether or not the detected temperature TH of the hot water temperature sensor 9 is equal to or less than TH2 in step S8. When TH ≦ TH2, the first burner 3 is burned in step S9. Since TM2 is a temperature set to prevent freezing, the first burner 3 is burned to the minimum necessary to prevent the first heat exchanger 4 from freezing, which reduces energy consumption. Is advantageous.

  When the first burner 3 is combusted in step S9, the process proceeds to step S10, and it is determined whether or not the detected temperature TH of the hot water temperature sensor 9 is equal to or higher than THe2. When TH ≧ THe2, the combustion of the first burner 3 is stopped in step S7. If TH <THe2, it is determined in step S11 whether or not the elapsed time TMe from the start of combustion of the first burner 3 is equal to or greater than TMe2, and when TMe ≧ TMe2, the step S7 is also performed. The combustion of the first burner 3 is stopped. Therefore, even if the detected temperature TH of the hot water temperature sensor 9 does not become equal to or higher than THe2, if the elapsed time TMe from the start of combustion of the first burner 3 becomes equal to or higher than TMe2, the combustion of the first burner 3 is stopped. Become. Therefore, also in this case, it can be reliably prevented that the hot water temperature sensor 9 is erroneously detected that the hot water temperature remains low, and the combustion of the first burner 3 is continued and the first heat exchanger 4 is overheated.

  As mentioned above, although embodiment which applied this invention to the 1 fan type | mold composite heat source machine which has the 1st heat exchanger 4 for hot-water supply and the 2nd heat exchanger 6 for heating was described, the 2nd heat exchanger 6 is The present invention can be similarly applied to the case of a heat exchanger for bath reheating or the case of a heat exchanger for heating and bath reheating.

The figure which shows the structure of embodiment of this invention heat source machine. The flowchart which shows control of the 1st burner at the time of the independent operation by the 2nd heat exchanger side (at the time of heating independent operation).

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... 1st combustion chamber, 2 ... 2nd combustion chamber, 3 ... 1st burner, 4 ... 1st heat exchanger, 5 ... 2nd burner, 6 ... 2nd heat exchanger, 7 ... Combustion fan, 8 ... Controller , 9 ... Hot water temperature sensor, TH1 ... predetermined temperature, TH2 ... second predetermined temperature, THE1, THe2 ... combustion stop temperature, TM1 ... predetermined time, TM2 ... second predetermined time, TMe1, TMe2 ... predetermined constant time.

Claims (2)

Heated by the first and second combustion chambers, the first heat exchanger for hot water heated by the first burner housed in the first combustion chamber, and the second burner housed in the second combustion chamber In the 1-fan type combined heat source apparatus comprising a second heat exchanger for applications other than hot water supply, and supplying combustion air from a single combustion fan to both the first and second combustion chambers,
Control means for controlling the operation of the first burner during the single operation on the second heat exchanger side is provided, and this control means burns the first burner at a predetermined time after the operation stop on the first heat exchanger side. Composed of
In the predetermined time, the time condition that the elapsed time from the operation stop on the first heat exchanger side is equal to or longer than the predetermined time, and the detected temperature of the hot water temperature sensor that detects the hot water temperature of the first heat exchanger is equal to or lower than the predetermined temperature. When the temperature condition of
Furthermore, a second predetermined time longer than the predetermined time and a second predetermined temperature lower than the predetermined temperature are determined, and the control means sets the elapsed time from the operation stop on the first heat exchanger side for the first time. 1 fan type, wherein the first burner is configured to burn only when the detected temperature of the hot water temperature sensor becomes equal to or lower than a second predetermined temperature when the predetermined time exceeds 2 Combined heat source machine. The control means stops the combustion of the first burner when the detected temperature of the hot water temperature sensor becomes equal to or higher than the combustion stop temperature set for stopping the combustion, and the detected temperature of the hot water temperature sensor stops the combustion. without go more temperature, 1-fan system according to claim 1, characterized in that it is configured to stop the combustion of the first burner upon lapse of a predetermined fixed time from the combustion start of the first burner Combined heat source machine.

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