JP2005147663A - Hot water supply device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent an increase in the size of a hot water supply combined device, such as a hot water supply heating bath device, to improve hot water temperature control performance when heating or reheating of a bath are effected, and to reduce running cost, concerning a combustion device. <P>SOLUTION: A pressure resisting pump 20 serving as a conveying means is arranged on a first circulation circuit 19 for circulating hot water, a first double-pipe heat exchanger 23 serving as a forced convection type heat exchanger for heating is arranged on a spot situated upper stream, and a second double-pipe heat exchanger 24 serving as a forced convection type heat exchanger for reheating the bath is arranged on a spot situated downstream. Thus, since the route of the first circulation circuit 19 is shortened, the size of the pressure resisting pump 20 is reduced, and the sizes of the first and second double-pipe heat exchangers 23, 24 are reduced, to thereby remarkably miniaturize this device. Further, when high-temperature water is circulated, the effect that a heat loss can be suppressed and the running cost can be lowered is produced. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a hot water supply apparatus having heating and bathing functions.

  Some conventional hot water supply apparatuses are described below (see, for example, Patent Document 1). In this type of hot water supply apparatus shown in FIG. 9, heating and reheating of the bath are performed in a configuration that realizes an immediate hot water function when hot water is supplied.

  That is, as shown in FIG. 9, the heat exchanger 1, the tapping pipe 2, the mixing valve 3 at the tip of the tapping pipe 2, the return pipe 4 provided immediately before the mixing valve 3, and the outlet of the heat exchanger 1 A bypass pipe 5 provided, an indirect heat exchanger 7 provided between the bypass pipe 5 and the water supply pipe 6, a bath reheating circuit 8, a heating circuit 9 and a water supply pipe 6 provided in the indirect heat exchanger 7. The bypass pipe 5, the water supply pipe 6, and the return pipe 4 form a circulation circuit 10, and includes a circulation pump 11 provided in the circulation circuit 10.

With the above configuration, when hot water is not supplied, hot water heated to a high temperature by the heat exchanger 1 is circulated by the circulation pump 11 via the return pipe 4 so that the hot water can be immediately supplied. Furthermore, by flowing hot water through the bypass pipe 5, the single indirect heat exchanger 7 reheats the bath via the bath reheating circuit 8 and heats it via the heating circuit 9.
No. 7-14758

  However, since the above-described conventional hot water supply system uses an immediate hot water system, high-temperature hot water must be circulated until just before reaching the indoor mixing valve 3, so that the running cost is high and mixing is always necessary to obtain high-temperature hot water. There was a problem that the valve 3 had to be provided. Furthermore, there is only one indirect heat exchanger 7, which is a coil shell type liquid hot water type water-water heat exchanger. Since the flow paths are parallel to each other, the heat exchange efficiency is low and hot water must be once stored in the shell. Therefore, a large and heavy heat exchanger is required, and there is a problem that it is difficult to control the hot water temperature required for heating and the hot water temperature required for bathing.

  In order to solve the above-mentioned problems, the present invention provides a burner, a heat exchanger heated by the burner, a water supply pipe provided at the inlet of the heat exchanger, and a hot water supply provided at the outlet in the casing of the hot water supply device. A pipe, a first circulation circuit forming a closed circuit at the inlet and the outlet, a conveying means for circulating hot water in the first circulation circuit, and forced convection heat provided in the first circulation circuit A second circulation circuit that forms a circulation circuit between the forced convection heat exchanger and the load device, a circulation pump for the second circulation circuit that circulates the hot water in the second circulation circuit, When the load device is not operated, the hot water supply device that stops the operation of the circulation pump for the second circulation circuit and operates the conveying means and the burner is provided.

  According to the above invention, it is possible to achieve downsizing of a combined hot water heater such as a hot water bath apparatus having a hot water heater and a bath reheating function, and a hot water heater having a hot water heater and a heating function, and a forced convection heat exchanger. Therefore, the heat exchange efficiency is high, and the path through which the hot water is circulated is short, so that the heat loss can be minimized. In addition, when the load device is not operated, the operation of the circulation pump for the second circulation circuit is stopped and the conveying means and the burner are operated, thereby improving the efficiency when using only the hot water.

  As described above, the hot water supply apparatus according to the present invention can realize downsizing of a combined hot water supply apparatus such as a hot water supply bath apparatus having a hot water heater and a bath reheating function or a hot water heater having a hot water heater and a heating function. The forced convection type heat exchanger has high heat exchange efficiency and has a short path for circulating high-temperature hot water, so that heat loss can be minimized. In addition, when the load device is not operated, the operation of the circulation pump for the second circulation circuit is stopped and the conveying means and the burner are operated, thereby improving the efficiency when using only the hot water.

  The first invention includes a burner, a heat exchanger heated by the burner, a water supply pipe provided at the inlet of the heat exchanger, a hot water pipe provided at the outlet, and an inlet and outlet in the casing of the hot water supply device. A first circulation circuit forming a closed circuit; a conveying means for circulating hot water in the first circulation circuit; a forced convection heat exchanger provided in the first circulation circuit; and a forced convection heat exchanger A load device that uses the heat obtained in step 2, a second circulation circuit that forms a circulation circuit between the forced convection heat exchanger and the load device, and a second circulation that circulates hot water in the second circulation circuit When the circuit circulating pump is arranged and the load device is not operated, the operation of the conveying means and the burner is performed by stopping the operation of the second circulating circuit circulating pump.

  And, by providing a forced convection heat exchanger in the first circulation circuit and operating the load device, it is possible to provide a small hot water supply complex machine having a hot water heater and a heating function or a bath function, etc. The running path of the hot water that circulates is short, and the heat loss is low, so the running cost is low. Further, when the load device is not operated, the efficiency when using only the hot water can be improved by stopping the operation of the circulation pump for the second circulation circuit and operating the conveying means and the burner.

  Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1)
FIG. 1 is a configuration diagram showing a combustion apparatus according to Embodiment 1 of the present invention. 1 and 2, reference numeral 12 denotes a casing of the main body, reference numeral 13 denotes a burner, a heat exchanger 14 that receives exhaust heat generated by combustion in the burner 13, and a water supply pipe 16 provided at an inlet 15 of the heat exchanger 14. And a hot water pipe 18 provided at the outlet 17, a first circulation circuit 19 that forms a closed circuit inside the casing 12 at the inlet 15 and the outlet 17, and hot water provided in the first circulation circuit 19 are circulated. The pressure in the piping provided on the upstream side of the first check valve 21 and the pressure pump 20 that prevents the back flow of water provided between the pressure pump 20 that is the conveying means, the pressure pump 20 and the inlet 15 is a certain value. The pressure relief valve 22 that releases the pressure when the pressure exceeds the first double-tube heat exchanger 23 that is the first forced convection heat exchanger and the second double tube that is the second forced convection heat exchanger Heat exchanger 24, first double tube heat exchanger 23 and negative A second circulation circuit 26 provided between a heating device 25 which is one of the devices, a second circulation circuit circulation pump 27 for circulating hot water provided in the second circulation circuit 26, and an expansion tank 28. The third circulation circuit 30 provided between the second double-tube heat exchanger 24 and the bathtub 29 which is one of the load devices, and the bathtub water provided in the third circulation circuit 30 are circulated. And a third circulation circuit circulation pump 31.

  Next, the operation and action will be described. First, when the hot water tap 32 is opened, the water passes through the water supply pipe 16 and enters the heat exchanger 14 through the inlet 15 and is heated by the combustion heat of the burner 13. The hot water is discharged from the street hot water tap 32.

  Next, at the time of heating operation, the circulation pump 27 for the second circulation circuit is driven by the operation command of the heating device 25, and the pressure-resistant pump 20 is driven in conjunction with it to ignite the burner 13. In the first circulation circuit 19, when hot water is circulated by the pressure-resistant pump 20, it is heated by the combustion heat of the burner 13, and is transferred to the second circulation circuit 26 side by the first double pipe heat exchanger 23. . In the second circulation circuit 26, the hot water circulates through the second circulation circuit 26 by the second circulation circuit circulation pump 27, and the heat received by the first double pipe heat exchanger 23 is radiated by the heating device 25. And blow out warm air.

  Next, at the time of reheating the bath, the circulation pump 31 for the third circulation circuit is driven by the reheating operation command for the bathtub 29, and the pressure pump 20 is driven in conjunction with the operation to ignite the burner 13. In the first circulation circuit 19, when hot water is circulated by the pressure pump 20, the hot water is heated by the combustion heat of the burner 13, and is transferred to the third circulation circuit 30 side by the second double pipe heat exchanger 24. . In the third circulation circuit 30, the bathtub water circulates in the third circulation circuit 30 by the third circulation circuit circulation pump 31, and the heat received by the second double pipe heat exchanger 24 is radiated in the bathtub 29. Retreat the bath.

  In the above operation, since the first circulation circuit 19 is provided inside the casing 12, the piping length is extremely short, so that the pressure loss is small and it can be circulated by the small pressure pump 20. That is, the running cost can be suppressed with little heat loss.

  Further, since the hot water temperature necessary for the heating device 25 is about 80 ° C. and the supply temperature to the bathtub 29 necessary for bathing is about 60 ° C., the heat exchanger 14 of the first circulation circuit 19 is used. By providing the second circulation circuit 26 on the outlet 17 side, the efficiency of the hot water temperature gradient in the first circulation circuit is improved. That is, sufficient heating operation capability can be secured, and bath reheating operation control becomes easy. The third circulation circuit 30 may be provided in the vicinity of the outlet 17 if the bath reheating ability may be reduced to some extent. Moreover, although the forced convection type heat exchanger is a double-pipe heat exchanger, the same effect can be achieved as a plate heat exchanger.

  Furthermore, in conjunction with the heating operation or the bath reheating operation, since the operation moves to the operation of heating the heat exchanger 14 after the hot water in the first circulation circuit 19 circulates, the air heating of the heat exchanger 14 does not occur. Durability is improved.

  In addition, although the structure which supplies a combustion heat to the heat exchanger 14 with the burner 13 was demonstrated, the combustion heat of the burner 13 is directly supplied to the 1st forced convection type heat exchanger 23 or the 2nd forced convection type heat exchanger 24. If supplied, the device can be further reduced in size.

  In addition, although an example in which two forced convection heat exchangers are shown is shown here, as shown in FIG. 2A, only one forced convection heat exchanger is naturally provided in the first circulation circuit, Each function can be satisfied similarly as a bath apparatus or as a hot water supply / heating apparatus as shown in FIG.

(Embodiment 2)
FIG. 3 is a bath configuration diagram showing the combustion apparatus according to Embodiment 2 of the present invention. The second embodiment is different from the first embodiment in that the first circulation circuit 20 includes three second forced convection heat exchangers 24, a third circulation circuit 30, and a third circulation circuit circulation pump. 31.

  In addition, the thing of the same code | symbol as Embodiment 1 has the same structure, and abbreviate | omits description.

  Next, the operation and action will be described. Since the three forced convection heat exchangers 24 are provided in the first circulation circuit 19, it is possible to replenish the three-room bathtub 29 at the same time. Here, a configuration has been shown in which three bathtubs 29 can be chased simultaneously, but the same effect can be exhibited even if there are two or three or more.

(Embodiment 3)
FIG. 4 is a configuration diagram showing a second double-pipe heat exchanger 24 according to Embodiment 3 of the present invention. The third embodiment is different from the second embodiment in that the second double-tube heat exchanger 24, which is the second forced convection heat exchanger, is configured to be inclined, and the third circulation circuit circulation pump. In this configuration, 31 does not exist.

  In addition, the thing of the same code | symbol as Embodiment 2 has the same structure, and abbreviate | omits description.

  Next, the operation and action will be described. When hot hot water passes through the first circulation circuit 19, it passes through the outer pipe 33 of the second double pipe heat exchanger 24 and passes through the inner pipe 34. Heat. The heated bathtub water moves upward and circulates naturally to the bathtub 29. Therefore, there is no need for the third circulation circuit circulation pump 31 for transporting the hot water for reheating to the bathtub 29, so that the apparatus can be miniaturized.

  In addition, the same effect is exhibited even if the first circulation circuit 19 is circulated through the inner pipe 34 of the second double pipe heat exchanger 24 and the bathtub water is circulated through the outer pipe 33.

(Embodiment 4)
FIG. 5 is a block diagram showing a combustion apparatus according to Embodiment 4 of the present invention. The fourth embodiment is different from the first embodiment in that a mixing circuit 35 is provided in the water supply pipe 16 and the hot water supply pipe 18, and the thermistor 36 provided between the heat exchanger 14 and the outlet 17 is provided in the mixing circuit 35. And a thermistor 37 provided in the water absorption pipe 16, and a water amount control valve 38, which is a flow rate control device that adjusts the mixing amount so as to achieve a set water temperature.

  In addition, the thing of the same code | symbol as Embodiment 1 has the same structure, and abbreviate | omits description.

  Next, the operation and action will be described. When bathing or heating operation is performed, hot water circulates in the first circulation circuit 19. At this time, the temperature of the hot water circulating through the first circulation circuit 19 is detected by the thermistor 36, the feed water temperature is detected by the thermistor 37, and the opening of the water amount control valve 38 is adjusted. When the hot-water tap 32 is opened, hot hot water is discharged. To avoid this, water is bypassed from the mixing circuit 35 to the hot water discharge pipe 18, and hot water at a desired temperature can be discharged. That is, the hot water tap 32 can use all kinds of valves, and may be a hot water tap other than the mixing valve.

  In the above embodiment, the flow rate control device is a water amount control valve. However, the same effect can be obtained even if a plurality of mixing circuits and a plurality of electromagnetic valves are provided and the amount of water to be bypassed is adjusted by the number of opening and closing of the electromagnetic valves. be able to.

(Embodiment 5)
FIG. 6 is a block diagram showing a laminated heat exchanger according to Embodiment 5 of the present invention. The fifth embodiment is different from the first embodiment in that the first forced convection heat exchanger is composed of a laminated heat exchanger. The plate of the laminated heat exchanger has a first circulation circuit inlet 39 and an outlet 40, a holding plate 43 provided with a second circulation circuit inlet 41 and an outlet 42, and a first circulation circuit 19 cut off. Plate A44, a partition plate B45, and a plate C46 in which the second circulation circuit 26 is cut. Furthermore, when the plates are stacked and integrated, through holes 47 and 48 that form header portions of the circulation circuits are provided.

  In addition, the plate 45 used for heat exchange is provided with through holes 49 and 50 that form header portions of the circulation circuits when the plates are stacked and integrated.

  Further, the flow path 52 of the plate C46 is provided at a position facing the flow path 51 of the plate A44 via the plate B45.

  The plate A44, plate B45, plate C46, and plate B45 are sequentially stacked to form one set, and a plurality of sets are stacked and integrated to form a stacked heat exchanger.

  In addition, the thing of the same code | symbol as Embodiment 1 has the same structure, and abbreviate | omits description.

  Next, the operation and action will be described. During the heating operation, hot water circulates in the first circulation circuit 19. At this time, the hot water entering from the first circulation circuit inlet 39 flows from the through hole 47 through the flow path 51 of the plate A 44 and exits from the first circulation circuit outlet 40. On the other hand, in the flow path 52 of the plate C46 which opposes, heat is transferred to the warm water of the second circulation circuit 26 via the plate B45 and supplied for heating. By using a laminated heat exchanger in this way, a compact and efficient forced convection heat exchanger can be realized, and the apparatus can be downsized.

  For example, diffusion welding or brazing is used as a method for integrally joining the plates. In diffusion welding, the temperature is raised to a temperature slightly lower than the melting point of the base material of the plate in a vacuum and is pressed, and is integrated by diffusion of the plate material. Brazing is performed by attaching a brazing material having a melting point lower than that of the base material of the plate to all the joining surfaces, raising the temperature to the melting point of the brazing material in a vacuum or in an inert atmosphere, and melting and integrating only the brazing material. Is.

(Embodiment 6)
7 and 8 are configuration diagrams showing a laminated heat exchanger and a filter according to Embodiment 6 of the present invention. The sixth embodiment is different from the first and fifth embodiments in that the second forced convection heat exchanger is configured by a laminated heat exchanger, and the third circulation circuit of the laminated heat exchanger is This is that a filter is provided on the inlet side. The plate of the laminated heat exchanger has a first circulation circuit inlet 39 and an outlet 40, a holding plate 43 provided with a third circulation circuit inlet 53 and an outlet 54, and a first circulation circuit 19 cut off. Plate A44, a partition plate B45, and a plate D55 in which the third circulation circuit 30 is cut. Furthermore, when the plates are stacked and integrated, a through hole 47 and a through hole 48 that form a header portion of each circulation circuit are provided. Further, the plate B45 when performing heat exchange is provided with a through hole 49 and a through hole 50 that form a header portion of each circulation circuit when the plates are stacked and integrated. Further, the flow path 56 of the plate D55 is provided at a position facing the flow path 51 of the plate A44 via the plate B45. The plate A44, plate B45, plate D55, and plate B45 are sequentially stacked to form one set, and a plurality of sets are stacked and integrated to form a stacked heat exchanger.

  Further, a detachable filter 57 is provided in the front stage of the third circulation circuit inlet 53.

  In addition, the thing of the same code | symbol as Embodiment 1 has the same structure, and abbreviate | omits description.

  Next, the operation and action will be described. When the bath reheating operation is performed, hot water circulates in the first circulation circuit 19. At this time, the hot water entering from the first circulation circuit inlet 39 flows through the flow path 51 from the through hole 47 and exits from the outlet 40 of the first circulation circuit. On the other hand, the channel 56 of the opposing plate D55 is transferred to the hot water of the bathtub 29 of the third circulation circuit 30 through the plate B45 and supplied with heat for bathing. By using a laminated heat exchanger in this way, a compact and efficient forced convection heat exchanger can be realized, and the apparatus can be downsized.

  In addition, the filter 57 can be attached and removed to trap dust such as hair and scale circulating from the bathtub 29 so that it does not enter the flow path 56 of the laminated heat exchanger, so that stable thermal efficiency can be secured and the filter can be replaced. Thus, heat exchange clogging can be prevented and an increase in pressure loss of the third circulation circuit 30 can also be prevented.

  As described above, the hot water supply apparatus according to the present invention can reduce the size of a combined hot water supply apparatus such as a hot water bath apparatus having a hot water heater and a bath reheating function or a hot water heater having a heating function and a heating function, and immediate hot water. Since it can be realized, it can be applied to uses such as domestic and commercial hot water supply devices.

Configuration diagram of hot water supply apparatus in Embodiment 1 of the present invention (A) The block diagram of the hot-water supply heating apparatus in Embodiment 1 (b) The block diagram of the hot-water bath apparatus in Embodiment 1 The block diagram of the hot-water supply apparatus in Embodiment 2 of this invention The expanded block diagram of the double pipe heat exchanger in Embodiment 3 of this invention The block diagram of the hot-water supply apparatus in Embodiment 4 of this invention The exploded perspective view of the lamination heat exchanger in Embodiment 5 of the present invention The exploded perspective view of the lamination heat exchanger in Embodiment 5 of the present invention Configuration diagram of the filter according to the sixth embodiment of the present invention Configuration diagram of conventional hot water supply equipment

Explanation of symbols

DESCRIPTION OF SYMBOLS 12 Casing 13 Burner 14 Heat exchanger 15 Inlet 16 Water supply pipe 17 Outlet 18 Hot water supply pipe 19 1st circulation circuit 20 Conveyance means 23 1st double pipe heat exchanger (1st forced convection type heat exchanger)
24 Second double-tube heat exchanger (second forced convection heat exchanger)
25 Heating device (load device)
26 Second circulation circuit 27 Circulation pump for second circulation circuit 29 Bathtub (load device)
30 Third Circulation Circuit 31 Third Circulation Circuit Circulation Pump 35 Mixing Circuit 38 Flow Control Device 44 Plate A
45 Plate B
46 Plate C
55 Plate D
57 Filter

Claims (1)

In the casing of the hot water supply apparatus, a burner, a heat exchanger heated by the burner, a water supply pipe provided at the inlet of the heat exchanger, a hot water supply pipe provided at the outlet, and a closed circuit at the inlet and the outlet A first circulation circuit for forming a hot water, a conveying means for circulating hot water in the first circulation circuit, a forced convection heat exchanger provided in the first circulation circuit, and the forced convection heat exchanger When a second circulation circuit that forms a circulation circuit between the first circulation circuit and the load device and a circulation pump for the second circulation circuit that circulates hot water in the second circulation circuit are disposed and the load device is not operated Is a hot water supply apparatus that stops the operation of the circulation pump for the second circulation circuit and operates the conveying means and the burner.

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