KR20100029551A - Co generation and control method of the same - Google Patents

Abstract

PURPOSE: A co-generation and a control method of the same are provided to always allow a water tank to supply a hot water by connecting a water tank through a radiation unit. CONSTITUTION: A co-generator includes a co-generation unit(1), a water heating tank(30), and a radiating unit(50). The co-generation unit generates power and heat. The co-generation unit transmits generated power to an electric apparatus and transfer the generated heat to a hot water heat exchanger. A water heating tank is connected to the hot water heat exchanger through a hot water circulating path.

Description

 Cogeneration generator and its operation method {Co generation and Control method of the same}

 BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cogeneration generator and a method of operating the same, and more particularly, to a cogeneration generator in which heat of an engine is recovered in a storage tank and a method of operating the same.

 In general, a cogeneration generator includes a generator and a drive source such as an engine for operating the generator, supplies power generated from the generator to a power source, and supplies heat generated from a drive source such as an engine to a heat source such as a heat storage tank.

 The cogeneration generator according to the prior art includes a heat recovery unit for recovering heat from a drive source such as an engine, a hot water heat exchanger connected to a heat recovery unit and a heat medium circulation passage so that a heat medium that has recovered heat while passing through the heat recovery unit, and a hot water heat exchanger And a hot water tank connected to the hot water circulation circulation passage.

In the cogeneration generator as described above, the heat medium transfers heat of the engine to the hot water supply heat exchanger while circulating the heat recovery unit and the hot water heat exchanger, and the water is heated by the heat transferred to the hot water heat exchanger while circulating the hot water tank and the hot water heat exchanger.

The cogeneration generator further includes a heat radiation heat exchanger for radiating heat recovered to the heat recovery unit to the outside, and the heat radiation heat exchanger is connected to a heat medium circulation passage and a heat radiation passage connecting the heat recovery unit and the hot water heat exchanger.

The heat medium circulation passage is provided with a heat medium control valve for switching the flow of the heat medium such that the heat medium that has recovered heat from the driving source such as an engine passes through one of the hot water supply heat exchanger and the heat dissipation heat exchanger and then is recovered to the heat recovery unit.

The heat medium control valve guides the heat medium to the heat dissipation heat exchanger during the heat dissipation operation so that the heat medium is dissipated in the heat dissipation heat exchanger, and guides the heat medium to the hot water heat exchanger during the hot water operation to heat the hot water heat exchanger.

However, in the cogeneration generator according to the prior art, the heat medium flow to the heat radiating heat exchanger is not smooth when switching from the hot water operation to the heat radiating operation temporarily, the heat dissipation amount is weak temporarily, the temperature of the heat medium is the highest, this temperature rise to be considered At this time, there is a problem in that it is difficult to form the temperature of the storage bath at a high temperature.

The present invention has been made to solve the above-mentioned problems of the prior art, the heat cogeneration can be recovered to all the heat for hot water supply and heat dissipation in the water storage tank and the heat dissipation in the heat dissipation unit connected to the water storage tank to enable the water storage tank to supply hot water of higher temperature The purpose is to provide a generator.

 It is another object of the present invention to provide a method of operating a cogeneration generator in which the heat dissipation mode and the non-heat dissipation mode of the heat dissipation unit are performed according to the temperature of the water storage tank or the temperature of the water circulation passage.

The cogeneration generator according to the present invention for solving the above problems is a cogeneration unit for generating power and heat, transferring the generated power to the power consumer, and transfers the generated heat to the hot water heat exchanger; A storage tank connected to the hot water supply heat exchanger and the hot water circulation circulation passage; And a heat dissipation unit connected to the water storage tank and the heat dissipation passage.

The heat dissipation unit may include: a heat dissipation heat exchanger connected to the heat dissipation flow path and having a water flow path through which water of the water storage tank passes; It includes a heat radiating fan for flowing outdoor air to the heat radiating heat exchanger.

The heat dissipation unit further includes a heat dissipation case in which the heat dissipation heat exchanger and the heat dissipation fan are installed, and the heat dissipation case includes an outdoor air intake port through which outdoor air is sucked in and an outdoor air discharge port through which the outdoor air heat exchanged with the heat dissipation heat exchanger is discharged.

The heat dissipation flow path includes a water outlet pipe connecting the water storage tank and the water flow path of the heat dissipation heat exchanger so that the water of the water storage tank flows into the water flow path of the heat dissipation heat exchanger, and the water of the water flow path of the heat dissipation heat exchanger flows into the water storage tank. It includes a water inlet pipe connecting the water flow path of the reservoir and the heat exchanger heat exchanger if possible.

It further includes a heat dissipation pump installed in one of the water outlet pipe and the water inlet pipe.

A temperature sensor configured to detect at least one temperature of the hot water circulation circulation path and the water storage tank; And a control unit for controlling the heat dissipation pump and the heat dissipation fan according to the temperature sensed by the temperature detection unit.

A method of operating a cogeneration generator according to the present invention includes a load sensing step of sensing a load; A cogeneration unit operating step of operating a cogeneration unit when a load is detected in the load sensing step; If the temperature of the hot water circulation circulation passage or the temperature of the water storage tank is disposed between the heat generation generator unit and the water storage tank during the operation of the cogeneration unit unit operation step or the temperature of the water storage tank is more than the heat radiation setting temperature is installed in the heat dissipation passage connecting the heat exchanger and the water storage tank installed in the heat dissipation unit. A heat dissipation step of driving a heat dissipation pump and rotating a heat dissipation fan for flowing air to the heat dissipation heat exchanger; And a heat dissipation stop step of stopping the heat dissipation pump and stopping the heat dissipation fan when the temperature of the hot water circulation circulation channel or the temperature of the water dissipation tank installed between the cogeneration generator unit and the water storage tank is lower than the heat dissipation set temperature during the heat dissipation step.

In the cogeneration generator according to the present invention configured as described above, both the heat used for the hot water supply and the heat radiating heat are recovered to the water storage tank, and the heat dissipation unit is connected to the water storage tank and the heat dissipation passage to heat the water in the water storage tank, thereby driving the cogeneration unit. The municipal reservoir has the advantage of always supplying hot water.

In addition, the cogeneration generator according to the present invention, the heat dissipation unit is made separately from the cogeneration unit, heat dissipation of the water supplied from the water tank to the outdoor air, the cogeneration unit does not need to be installed outdoors together with the heat dissipation unit, cogeneration unit There is an advantage of easy installation.

In addition, the cogeneration generator according to the present invention, since the heat dissipation heat exchanger and the heat dissipation fan are installed in the heat dissipation case, there is an advantage that the heat dissipation heat exchanger and the heat dissipation fan can be protected by the heat dissipation case.

In addition, the cogeneration generator according to the present invention has an advantage that the construction of the heat dissipation passage is made of a heat dissipation passage is composed of a water outlet pipe and a water inlet pipe connecting the water passage of the reservoir and the heat exchanger heat exchanger.

In addition, the cogeneration generator according to the present invention has an advantage of easily switching between the heat dissipation mode and the non-heat dissipation mode since the heat dissipation pump and the heat dissipation fan are controlled in accordance with at least one of the hot water circulation circulation path and the water storage tank.

In addition, the operating method of the cogeneration generator according to the present invention, while the heat dissipation step and the non-heat dissipation step are carried out in accordance with the temperature of the hot water circulation circulation passage or the temperature of the water tank, there is an advantage that the efficient heat dissipation.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic configuration diagram of an embodiment of a cogeneration generator according to the present invention, Figure 2 is a control block diagram of an embodiment of a cogeneration generator according to the present invention.

 The cogeneration generator according to the present invention, as shown in FIG. 1, includes a cogeneration unit 1 and a storage tank 30.

The cogeneration unit 1 generates power and heat, supplies the generated power to a lighting or home appliance, which is a power consumption device, and transfers the generated heat to a storage tank 30, which is a heat demander.

The cogeneration unit 1 includes a chassis 2 which forms an exterior thereof; An engine 3 installed inside the chassis 2; A generator 8 installed inside the chassis 2 and connected to the engine 3 to generate electric power; The hot water supply heat exchanger (14) installed inside the chassis (2) and connected to the water storage tank (30) and the hot water circulation circulation flow path (32), and the engine (3) and the generator (8) installed inside the chassis (2). And a heat transfer part 20 for recovering at least one heat and transferring it to the hot water heat exchanger 14.

The engine 3 is driven by a fossil fuel such as gas or petroleum to drive the generator 8. (5) and the exhaust pipe 6 through which the exhaust gas exhausted from the engine 3 pass are connected.

The engine 3 is connected to a battery 9, which is an electric component for storing power generated by the generator 8, by a power line, and is started by the power of the battery 9.

The generator 8 is connected to the rotor of the output shaft of the engine 3 to produce electric power when the output shaft rotates, and supplies the generated power to power consumption devices such as lighting or home appliances in buildings where cogeneration generators are installed through the power line. .

The power produced by the generator 8 is supplied directly to the power consumer via a power line, or is stored in a battery 9 connected to the generator 8 and then supplied from the battery 9 to the power consumer and the engine 3. do.

A power load detector 10 is installed between the generator 8 and the power consuming device to detect the power load of the power consuming device.

The hot water heat exchanger 14 is formed with a heat medium flow path 16 through which a heat medium transferring heat recovered by the engine 3 passes, and a water flow path 18 through which water supplied from the water storage tank 30 passes.

The heat transfer part 20 transfers heat generated by the engine 3 or the generator 8 to the hot water supply heat exchanger 14. The heat medium 20 directly passes the engine 3 while the heat medium directly passes through the engine 3. It is also possible to recover the heat of the fuselage, including a separate engine cooling heat exchanger, the coolant circulates the engine 3 and the engine cooling heat exchanger while transferring the heat of the engine to the engine cooling heat exchanger, and the heat medium passes through the engine cooling heat exchanger. It is also possible to recover the heat transferred to the engine cooling heat exchanger, which is explained below as the heat medium passes directly through the engine 3. In addition, the heat transfer unit 20 will be described as the heat medium recovers the heat of the exhaust gas of the engine 3 and delivers the heat to the hot water heat exchanger 14.

The heat transfer part 20 is a heat medium circulation path 22 which connects the heat recovery part 21 to which the heat medium recovers heat of the engine 3, and the heat medium flow path 16 of the heat recovery part 21 and the hot water heat exchanger 14. ) .

The heat recovery unit 21 includes an exhaust gas heat exchanger 24 having an exhaust gas heat recovery flow path 23 for recovering exhaust gas heat, and an engine heat recovery formed in the engine 3 so that a fluid passes directly through the engine 3. And an exhaust gas heat exchanger-engine connection passage 26 for connecting the flow passage 25, the exhaust gas heat recovery passage 23, and the engine heat recovery passage 25.

That is, the heat transfer part 20 recovers the heat of the exhaust gas while the fluid passes through the exhaust gas heat recovery flow path 23, and passes the engine heat recovery flow path 25 through the exhaust gas heat exchanger-engine connection flow path 26. Recover heat from the engine fuselage.

The heat medium circulation flow path 22 is a heat medium supply pipe 27 connected to the engine 3 and the hot water heat exchanger 14 so that the heat medium passing through the engine heat recovery flow path 25 flows into the heat medium flow path 16 of the hot water heat exchanger 14. ) And the heat medium recovery pipe connecting the hot water supply heat exchanger 14 and the exhaust gas heat exchanger 24 so that the heat medium passing through the heat medium flow path 16 of the hot water heat exchanger 14 flows into the exhaust gas heat recovery flow path 23. (28).

The heat medium circulation passage 22 includes a heat medium circulation pump 29 for pumping the heat medium so that the heat medium circulates through the heat recovery unit 21 and the hot water heat exchanger 14, and at least one of the heat medium supply pipe 27 and the heat medium recovery pipe 28. It is installed on one.

That is, the heat medium of the heat medium recovery pipe 26 when the heat medium circulation pump 29 is driven recovers heat while passing through the exhaust gas heat recovery flow path 23 and the engine heat recovery flow path 25 of the exhaust gas heat exchanger 24. After passing through the supply pipe 25 is introduced into the heat medium flow path 16 of the hot water supply heat exchanger 14 to transfer heat to the hot water heat exchanger 14, and then circulated to the heat medium recovery pipe (26).

On the other hand, when a plurality of exhaust gas heat exchanger 24 is installed in the exhaust port 6 of the engine 3, the exhaust gas heat recovery flow path 23 formed in each of the exhaust gas heat exchanger 24 is an exhaust gas heat exchanger connection flow path. Connected.

The storage tank 30 is installed outside the cogeneration generator, is connected to a water pipe or a heating pipe in a building, and contains water used for hot water supply.

 The water storage tank 30 has a water flow path 18 and a hot water circulation circulation flow path 32 of the hot water heat exchanger 14 so that the water therein circulates through the water flow path 18 and the water storage tank 30 of the hot water heat exchanger 14. ).

The hot water supply circulation passage 32 connects the water heater tank 30 and the water flow path 18 of the hot water supply heat exchanger 14 so that the water of the water storage tank 30 flows into the water flow path 18 of the hot water heat exchanger 14. The water flow path 18 and the water storage tank 30 of the hot water heat exchanger 14 so that the water passing through the water supply pipe 33 and the water flow path 18 of the hot water heat exchanger 14 flows into the water storage tank 30. It includes a water recovery pipe 34 for connecting).

In the hot water supply circulation channel 32, a heat recovery hot water pump 36 for pumping water in the hot water tank 30 to circulate the hot water heat exchanger 14 and the hot water tank 30 is provided with a water supply pipe 33 and a water recovery pipe 34. ) Is installed in at least one.

That is, when the hot water pump 36 is driven, the water of the water storage tank 30 passes through the water supply pipe 33 and then flows into the water flow path 18 of the hot water heat exchanger 14 to be heated from the hot water heat exchanger 14. Received, and is then recovered to the storage tank 30 through the water recovery pipe 34.

On the other hand, the cogeneration generator according to the present embodiment is a temperature sensing unit 42 for detecting at least one of the temperature of the water storage tank 30 and the temperature of the water supply pipe 33, the user, etc. of the water storage tank 30 It has the temperature setting part 44 which sets a temperature.

If the temperature of the water storage tank 30 sensed by the temperature detection unit 42 is lower than the lower limit value (eg, 50 ° C.) of the hot water temperature set by the temperature setting unit 44, it is detected that there is a hot water load, and the temperature When the temperature of the water storage tank 30 sensed by the detector 42 is equal to or higher than an upper limit (eg, 60 ° C.) of the hot water temperature set by the temperature setting unit 44, it is detected that there is no hot water load.

On the other hand, the cogeneration generator according to the present embodiment generates heat together with the power during the operation of the cogeneration unit 1, and the cogeneration power generation when the hot water load from the water tank 30 and the power load of the power consumer equipment together Most preferably, the unit 1 is operated, but the cogeneration unit 1 can be operated even if there is only one of the power load and the hot water load, and there is a power load, no hot water load, or the water temperature in the water tank 30 When excessively high, it is necessary to recover heat from the engine 3 to heat the outside through the heat dissipation unit 50 in order to protect the engine 3 and not to make the water in the water tank 30 too hot.

The heat dissipation unit 50 may be installed inside the cogeneration unit 1 and may be connected to the heat medium circulation passage 22 by a heat dissipation passage. The heat dissipation unit 50 may be installed outside the cogeneration unit 1, It is also possible to connect with a heat dissipation flow path.

In the cogeneration unit 1, when the heat dissipation unit 50 is connected to the heat medium circulation passage 22 and the heat dissipation passage, the heat medium circulates one of the heat dissipation unit 50 and the hot water supply heat exchanger 14 and the heat recovery unit 21. It further includes a heat medium control valve (not shown) to adjust the flow path of the heat medium as possible, the heat medium control valve is a hot water supply mode for supplying the heat medium to the hot water heat exchanger (14) and a heat dissipation mode for supplying the heat medium to the heat dissipation unit (50) In this case, the instant when the temperature of the heat medium is the highest (that is, the maximum temperature of the heat medium) is when the heat medium control valve is switched from the hot water mode to the heat dissipation mode, and the hot water mode while managing the maximum temperature of the heat medium circulation flow path 22. Considering the temperature rise at the moment of switching to the heat dissipation mode at, to form a hot water of the hot water tank 30 in order to manage the heat medium temperature of the heat medium circulation passage 22 is not excessively high Becomes difficult.

On the other hand, when the heat dissipation unit 50 is installed outside the cogeneration unit 1 and connected to the water storage tank 30 and the heat dissipation passage 52, the heat dissipation unit 50 may occur when the cogeneration unit 1, in particular, the engine 3 is driven. The supplied heat is always transferred to the water in the water storage tank 30 through the hot water supply heat exchanger 14, and heats the water in the water storage tank 30 in the heat dissipation unit 50 only when the temperature of the water storage tank 30 is high. In this case, the temperature of the heat medium does not increase rapidly, and the water storage tank 30 can always supply hot water of high temperature to the water pipe or the bottom pipe.

That is, all the heat for hot water supply / heat dissipation is recovered to the low temperature tank 30, and the cogeneration generator does not need to consider the temperature rise at the moment of switching to the heat dissipation mode, and thus it is always in a state capable of supplying hot water of high temperature.

Hereinafter, the heat dissipation unit 50 will be described in detail.

The heat dissipation unit 50 is connected to the water storage tank 30 by a heat dissipation path 52 to discharge heat generated in the cogeneration unit 1 and transferred to the water storage tank 30 to the outside. And a heat dissipation heat exchanger (56) having a water flow passage (54) through which water in the water storage tank (30) passes, and a heat dissipation fan (58) for flowing air to the heat dissipation heat exchanger (56).

The heat dissipation unit 50 further includes a heat dissipation case 60 in which a heat dissipation heat exchanger 56 and a heat dissipation fan 58 are installed and an outdoor air passage through which outdoor air passes.

The heat dissipation case 60 is formed with an outdoor air inlet 62 through which outdoor air is sucked, and an outdoor air outlet 64 through which outdoor air heat exchanged with the heat dissipation heat exchanger 56 is discharged to the outside.

On the other hand, the heat dissipation passage 52 is provided with a heat dissipation pump 66 for circulating the water in the storage tank 30 passes through the heat dissipation passage 52 of the heat dissipation heat exchanger 56 and then circulated to the storage tank 30.

The heat dissipation flow path 52 connects the water flow path 54 of the heat dissipation tank 30 and the heat dissipation heat exchanger 56 so that the water of the water storage tank 30 flows out into the water flow path 54 of the heat dissipation heat exchanger 56. The water outflow pipe 68 and the water flow path 54 of the heat dissipation tank 30 and the heat dissipation heat exchanger 56 are introduced so that the water of the water flow path 54 of the heat dissipation heat exchanger 56 flows into the storage tank 30. It comprises a water inlet pipe 70 for connecting.

The heat dissipation pump 66 is installed in one of the water outlet pipe 68 and the water inlet pipe 70.

The heat dissipation pump 66 may be installed at a portion located between the heat dissipation tube 68 and the water inflow tube 70 between the heat dissipation case 60 and the water storage tank 30. It is also possible to install in a portion located, it is preferable to be installed inside the heat dissipation case 60 to be protected by the heat dissipation case 60 to configure the heat dissipation unit 50.

When the heat dissipation pump 66 is driven, the water of the water storage tank 30 passes through the water outlet pipe 68 and then flows into the water flow path 54 of the heat dissipation heat exchanger 56 to heat the heat to the heat dissipation heat exchanger 56. After the transfer, the water inlet pipe 70 is recovered to the storage tank 30.

The heat dissipation unit 50 cools the heat dissipation heat exchanger 56 with outdoor air, and is installed outdoors so that outdoor air is directly sucked into the heat dissipation case 60 and then discharged to the outdoor.

On the other hand, the air conditioner according to the present embodiment controls the engine 3, the heat medium circulation pump 29 and the hot water pump 36 in accordance with the detection result of the power load detector 10 or the temperature detector 42, The controller 80 further controls the heat dissipation pump 66 and the heat dissipation fan 58 according to the temperature sensed by the temperature detection unit 42.

  3 is a flowchart illustrating an embodiment of a method of operating a cogeneration generator according to the present invention.

As shown in FIG. 3, the method of operating the cogeneration generator according to the present embodiment includes a load sensing step S1 and a cogeneration unit operating step S2.

The load detection step S1 is a step of detecting a load of the cogeneration generator, and the power load detector 4 detects the power load and outputs it to the controller 80, and the temperature detector 42 detects the temperature to control the controller. Output to (80).

The controller 80 detects a load according to the detection result of the power load detector 4 and the temperature detector 42, and if it is detected that there is a load, operates the cogeneration unit 1 and drives the cogeneration unit. Step S2 is carried out.

 The controller 80 drives the engine 3 during the cogeneration unit operation step S2, and drives the heat medium circulation pump 29 and the hot water pump 36.

When the engine 3 is driven, the generator 8 generates electric power and supplies it to the power consuming device, and the engine 3 and the exhaust gas heat exchanger 24, which are the heat recovery unit 21, are heated.

When the heat medium circulation pump 29 is driven, the heat medium of the heat medium recovery pipe 26 recovers heat while passing through the exhaust gas heat recovery flow path 23 and the engine heat recovery flow path 25 of the exhaust gas heat exchanger 24 and heat transfer supply pipe. After passing through 25, the heat medium flows into the hot water heat exchanger 14, thereby transferring heat to the hot water heat exchanger 14.

When the hot water supply pump 36 is driven, the water of the water storage tank 30 passes through the water supply pipe 33 and then flows into the water flow path 18 of the hot water supply heat exchanger 14 to heat heat from the hot water supply heat exchanger 14. Received, and then recovered to the storage tank 30 through the water recovery pipe 34 to heat the water in the storage tank (30).

That is, all of the heat generated from the engine 3 is transferred to the inside of the water storage tank 30 through the hot water supply heat exchanger 14.

On the other hand, during the operation of the cogeneration unit as described above, the heat dissipation unit 50 performs the heat dissipation step (S3) (S4) and the non-heat dissipation step (S5) (S6).

The heat dissipation step S3, S4 and the non-heat dissipation step S5 and S6 are the hot water circulation circulation flow path 32 installed between the cogeneration generator unit 1 and the storage tank 30 during the cogeneration unit operation step S2. Is a kind of hot water supply unit adjustment step of operating / stopping the hot water supply unit 50 according to the temperature of the hot water storage tank 30 or the temperature of the hot water storage tank 30. Compared with the heat radiation set temperature, the hot water supply unit 50 is operated / stopped according to the size.

Here, the heat radiation set temperature may be set equal to the upper limit of the hot water temperature for determining the hot water load, and may be set higher than the upper limit of the hot water temperature.

The heat dissipation step (S3) (S4) is heat dissipation if the temperature of the hot water circulation circulation channel 32 or the temperature of the water storage tank (30) is higher than the heat dissipation set temperature (for example, 60 ° C) during the cogeneration unit operation step (S2). The heat dissipation pump 66 provided in the flow path 52 is driven, and the heat dissipation fan 58 which flows outdoor air to the heat dissipation heat exchanger 56 is rotated.

During the operation of the heat dissipation pump 66 as described above, the water of the water storage tank 30 passes through the water outlet pipe 68 and then flows into the water flow path 54 of the heat dissipation heat exchanger 56 to dissipate the heat dissipation heat exchanger 56. Heat is transferred to the), and then recovered to the water storage tank 30 through the water inlet pipe 70 to circulate the water flow path 54 and the water storage tank 30 of the heat radiation heat exchanger (56). During the rotation of the heat radiating fan 58, the water passing through the water flow path 54 of the heat radiating heat exchanger 56 is radiated by the outdoor air.

That is, when the heat dissipation pump 66 is driven and the heat dissipation fan 58 is rotated, the heat recovered from the engine 3 and stored in the water storage tank 30 through the hot water heat exchanger 14 causes the heat dissipation heat exchanger 56 to flow. Is released to the outdoors through, the water temperature in the reservoir 30 is gradually lowered.

Non-heat-dissipating step (S5) (S6) is stopped during the heat dissipation step (S3) (S4) when the temperature of the hot water supply circulation flow path 32 or the temperature of the water storage tank (30) is less than the set heat dissipation temperature to stop the heat dissipation pump (66) Stop the heat radiating fan 58.

If the driving of the heat dissipation pump 66 and the heat dissipation fan 58 continue to rotate in the heat dissipation step (S3) (S4), the temperature of the hot water circulation circulation passage 32 or the temperature of the water storage tank 30 is less than the heat dissipation set temperature. When the heat dissipation pump 66 and the heat dissipation fan 58 are stopped, the temperature of the hot water circulation circulation channel 32 or the temperature of the water storage tank 30 is increased again and the water in the water storage tank 30 is not too low. Will not.

On the other hand, the present invention is not limited to the above embodiment, and the heat dissipation step is performed when the temperature of the hot water circulation circulation channel 32 or the temperature of the water storage tank 30 is equal to or higher than the heat dissipation upper limit set temperature, and the heat dissipation pump 66 is operated. In addition to driving, the heat dissipation fan 58 is rotated, and if the temperature of the hot water circulation circulation channel 32 or the temperature of the water storage tank 30 is lower than the heat dissipation lower limit set temperature lower than the heat dissipation upper limit set temperature, a non-heat dissipation step is performed. It is also possible to stop the heat dissipation pump 66 and the heat dissipation fan 58, and various implementations are possible within the technical scope of the present invention.

1 is a schematic configuration diagram of an embodiment of a cogeneration generator according to the present invention,

2 is a control block diagram of an embodiment of a cogeneration generator according to the present invention;

  3 is a flowchart illustrating an embodiment of a method of operating a cogeneration generator according to the present invention.

<Explanation of symbols on main parts of the drawings>

  1: Cogeneration Unit 2: Chassis

3: engine 8: generator

14: hot water supply heat exchanger 20: heat transfer unit

21: heat recovery portion 22: heat medium circulation flow path

29: heat medium circulation pump 30: reservoir

32: hot water circulation passage 36: hot water pump

42: temperature sensing unit 50: heat dissipation unit

54; Water Euro 56: Heat Resistant Heat Exchanger

58: heat dissipation fan 60: heat dissipation case

62: outdoor air inlet 64: outdoor air outlet

66: heat dissipation pump

Claims (7)

A cogeneration unit for generating power and heat, transferring the generated power to a power consumer, and transferring the generated heat to a hot water heat exchanger; A storage tank connected to the hot water supply heat exchanger and the hot water circulation circulation passage; A cogeneration generator comprising a heat dissipation unit connected to the water storage tank and a heat dissipation passage. The method of claim 1, The heat dissipation unit may include: a heat dissipation heat exchanger connected to the heat dissipation flow path and having a water flow path through which water of the water storage tank passes; A cogeneration generator comprising a heat radiating fan for flowing outdoor air to the heat radiating heat exchanger. The method of claim 2, The heat dissipation unit further includes a heat dissipation case in which the heat dissipation heat exchanger and the heat dissipation fan are installed. The heat dissipation case is a combined heat generator having an outdoor air inlet through which the outdoor air is sucked and an outdoor air outlet through which the outdoor air heat exchanged with the heat exchanger is discharged. The method of claim 2 or 3, The heat dissipation flow path includes a water outlet pipe connecting the water storage tank and the water flow path of the heat dissipation heat exchanger so that the water of the water storage tank flows into the water flow path of the heat dissipation heat exchanger, and the water of the water flow path of the heat dissipation heat exchanger flows into the water storage tank. A cogeneration generator comprising a water inlet pipe connecting the water flow path of the reservoir and the heat dissipating heat exchanger. The method of claim 4, wherein A cogeneration generator further comprising a heat dissipation pump installed in one of the water outlet pipe and the water inlet pipe. The method of claim 5, wherein A temperature sensor configured to detect at least one temperature of the hot water circulation circulation path and the water storage tank; And a control unit for controlling the heat dissipation pump and the heat dissipation fan according to the temperature sensed by the temperature detection unit. A load sensing step of sensing a load; A cogeneration unit operating step of operating a cogeneration unit when a load is detected in the load sensing step; If the temperature of the hot water circulation circulation passage or the temperature of the water storage tank is disposed between the heat generator unit and the storage tank during the operation of the cogeneration unit unit operation step or the temperature of the water storage tank is higher than the heat radiation setting temperature is installed in the heat radiation passage connecting the heat exchanger and the storage tank installed in the heat dissipation unit. A heat dissipation step of driving a heat dissipation pump and rotating a heat dissipation fan for flowing air to the heat dissipation heat exchanger; And a heat dissipation stop step of stopping the heat dissipation pump and stopping the heat dissipation fan when the temperature of the hot water circulation circulation passage or the temperature of the water dissipation tank installed between the cogeneration generator unit and the water storage tank is lower than the heat dissipation setting temperature during the heat dissipation step. How to drive a generator.

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