JPH02130247A - Cogeneration system - Google Patents

Abstract

PURPOSE:To improve the thermal efficiency by connecting the cooling water side of a reciprocating engine and the low temperature regenerator of a single/ double combined type absorption type refrigerator by a low temperature circulation circuit and connecting an exhaust gas boiler and a high temperature regenerator by a high temperature circulation circuit. CONSTITUTION:A cogeneration system generates electric power by driving a power generator 20 by a reciprocating engine 22, and takes out the saturated steam by installing an exhaust gas boiler 34 in an exhaust system 24, and drives a single/double combined type absorption type refrigerator 48 by utilizing waste heat. The engine cooling heat in the water jacket 26 of the reciprocating engine is sent into the low temperature regenerator 49 of the refrigerator 48 through a low temperature recirculation circuit 25 and the saturated steam supplied from the exhaust gas boiler 34 is sent into a high temperature regenerator 51 of the refrigerator 48 through a high temperature recirculation circuit 35. Therefore, two kinds of engine exhaust heat having different temperature potential can be converted to the cold heat efficiently and economically by one unit of absorption type refrigerator.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a cogeneration system, and in particular,
This relates to an improvement to a cogeneration system that makes it possible to effectively recover exhaust gas and engine cooling heat.

[Conventional technology]

A cogeneration system generally involves installing an engine on-site at a building or factory to drive a generator, refrigerator, etc., and at the same time recover exhaust gas and engine cooling heat.
By using it as a heat source for air conditioning, hot water supply, or processes, the energy contained in the fuel is utilized in stages, greatly improving the overall energy use efficiency and reducing energy costs. recognized as a system.

FIG. 4 shows the conceptual configuration of a conventional cogeneration system, where 1 is a generator.

A reciprocating engine 3 is connected to the departure machine 1 via a drive shaft 2. Furthermore, an exhaust gas boiler 5 is attached to the exhaust system 4 of the reciprocating engine 3 for recovering thermal energy of exhaust gas. A hot water circulation pipe 7 is connected to the exhaust gas boiler 5 and the water jacket 6 of the reciprocating engine 3.

This hot water circulation pipe 7 is provided with a circulation pump 8 . Furthermore, this hot water circulation pipe 7 is connected to a − type dynamic absorption refrigerator 9 . A cold water pipe 10 for taking out cold water is connected to this - type dynamic absorption refrigerator 9.

According to this conventional cogeneration system, the reciprocating engine 3 is driven to start the generator 1 and generate electricity. At this time, the circulation pump 8 is driven in the hot water circulation pipe 7 to circulate hot water. In the water jacket 6 in the reciprocating engine 3, the temperature of the cooling water increases as the engine is driven, and the temperature of the hot water in the hot water circulation pipe 7 located in the water jacket 6 increases. For example, hot water that has been moved at 83°C becomes 87°C when it leaves the water jacket 6 and is sent to the exhaust gas boiler 5, where it is heated to 90°C and heated to 87°C. It is sent to refrigerator 9. In this - type dynamic absorption refrigerator 9,
Water flowing in through the cold water pipe 10 is turned into cold water and sent out. Then, the hot water whose heat has been radiated by the - type dynamic absorption refrigerator 9 is sent out again to the water jacket 6 of the reciprocating engine 3 by the circulation pump 8 via the hot water circulation pipe 7.

[Problem to be solved by the invention]

However, in such conventional cogeneration systems,
Since the hot water circulation pipe 7 is shared between the water jacket 6 of the reciprocating engine 3 and the exhaust gas boiler 5, it had to be used after unifying the temperature level to the lower temperature potential. As a result, only the -type dynamic absorption chiller 9 can be used, and the heat exchange efficiency is low (60
%) was obtained.

Furthermore, if the balance between electric power and cooling load deviates from the rated value, engine cooling heat and exhaust gas temperature decrease, making economical operation difficult.

The present invention was made to solve these conventional problems, and provides a cogeneration system that can utilize the temperature potential of the cooling heat of the reciprocating engine and the exhaust gas heat without reducing it. There is a particular thing.

[Means to solve the problem]

The cogeneration system according to the present invention includes a generator, a reciprocating engine that drives the generator, an exhaust gas boiler installed in the exhaust system of the reciprocating engine, a single/double combination absorption chiller, and a reciprocating engine that drives the generator. A low-temperature circulation circuit that is thermally connected to and circulates between the cooling water side of the engine and the low-temperature regenerator of the single/double type absorption chiller, and the exhaust gas boiler installed in the exhaust system of the reciprocating engine and the single/double type absorption chiller. It is composed of a high-temperature circulation circuit that is thermally connected to a high-temperature regenerator of a combination type absorption refrigerator.

[For production]

In the cogeneration system according to the present invention, the engine cooling heat in the water jacket of the reciprocating engine is directly sent to the low temperature regenerator of the single/double type absorption refrigerator via the low temperature circulation circuit, and The exhaust gas energy of the reciprocating engine is extracted as desired saturated steam by the exhaust gas boiler installed in the exhaust system of the reciprocating engine, and is sent to the high-temperature regenerator of the single-double absorption refrigerator through the high-temperature circulation circuit. Therefore, two types of engine exhaust heat having different temperature potentials can be converted into cold heat with high efficiency and economically using one absorption chiller.

〔Example〕

Embodiments of the present invention will be described below based on the drawings.

FIG. 1 shows a first embodiment of a cogeneration system according to the present invention, and 20 is a generator.

A reciprocating engine 22 is connected to the generator 20 via a drive shaft 21 .

The water jacket 23 of the reciprocating engine 22 has a built-in heat absorption section 26 for the low-temperature wt ring road 5. Further, the exhaust system 24 of the reciprocating engine 22 is provided with an exhaust gas boiler 34 for recovering thermal energy of exhaust gas.

Low′/! The JLWi ring circuit 25 is a reciprocating engine 22
The water jacket (cooling water side) 23 and the low temperature regenerator 49 of the single/double type absorption chiller 48 are thermally connected and circulated.
The heat dissipation section 27 is inserted into the low temperature regenerator 49 of No. 8. The hot water inside can be circulated by a circulation pump 28. Further, the low temperature circulation circuit 25 is provided with a bypass passage 30 that thermally communicates with a heat exchanger 62 provided in the exhaust system 24. This bypass path 30 is provided with valves 31 and 32, which are configured to switch the bypass path 30 in conjunction with a solenoid valve 29 provided at a branch portion of the bypass path 30. Furthermore, an expansion tank 33 is connected to the low temperature circulation circuit 25 .

A saturated steam outlet 36 and a hot water outlet 37 of a high temperature circulation circuit 35 are attached to the exhaust gas boiler 34 . As this exhaust gas boiler 34, a steam generator capable of generating saturated steam is used.

The high-temperature circulation circuit 35 is thermally connected to the exhaust gas boiler 34 and the high-temperature regenerator 51 of the single/double type absorption refrigerator A48 for circulation.
A heat dissipation section 38 is inserted into the high temperature regenerator 51 .

A pipe line 40 communicating with the saturated steam outlet 36 in this high temperature circulation circuit 35 branches in the middle, and a solenoid valve 41 is provided at the branch part 39, and a silencer 42 is provided on the downstream side of this solenoid valve 41. It is being Furthermore, this conduit 40 is provided with a solenoid valve 43. In addition, a trap 45. A hot well tank 46 and a circulation pump 47 are provided.

In addition, the low temperature regenerator 4 of the single/double type absorption refrigerator 48
9, a heat dissipation section 5 of a pipe line 52 communicating with the high temperature regenerator 51;
3 has been inserted. This low-temperature regenerator 49 is formed inside the condenser 50. The condenser 50 includes a cooling water pipe 58 that circulates between the absorber 55 and the cooling tower 57.
is installed. A circulation pump 59 is provided in this cooling water pipe 58 . Note that the absorber 55 and the evaporator 56 are built into the tank 54. Further, a cold water pipe 60 is connected to the evaporator 56 . A circulation pump 61 is provided in this cold water pipe 60.

Next, the operation of this embodiment configured in this manner will be explained.

Drive the reciprocating engine 22 to start the generator 20,
Generate electricity. At this time, in the low temperature circulation pipe 25, the solenoid valve 29 is closed, the valves 31 and 32 are opened, and the bypass pipe 3
0 is opened, and the W-ring pump 28 is driven to circulate hot water. In the water jacket 23 in the reciprocating engine 22, the temperature of the cooling water increases as the reciprocating engine 22 operates, and the temperature of the hot water in the low-temperature circulation pipe 25 located in the water jacket 23 increases. At this time, the hot water that has been transferred at, for example, 83° C. is heated to 87° C. by the heat exchanger 62 using the thermal energy of the exhaust gas. Then, thermal energy of 87° C. can be supplied to the heat radiating section 27 in the low temperature regenerator 49 of the single/double type absorption refrigerator 48. The heat-radiated hot water in the low-temperature circulation pipe 25 is sent out again to the heat absorption section 26 in the water jacket 23 of the reciprocating engine 22 by the circulation pump 28. In addition, heat exchanger 6
The exhaust gas whose heat has been dissipated by No. 2 is discharged at approximately 200°C.

On the other hand, in the high temperature circulation circuit 35, the solenoid valve 41 is closed and the solenoid valve 43 is opened so that saturated steam can be sent to the high temperature regenerator 51 of the single/double type absorption refrigerator 48. In this state, exhaust gas at approximately 500°C is being discharged into the exhaust system, so the exhaust gas boiler 34 installed in the exhaust system 24 pumps hot water in the high temperature circulation circuit 35 at a rate of 7 kg/c+f.
The medium pressure steam can be about tG (approximately 170"C). Then, this medium pressure steam is sent to the heat radiation section 38 in the high temperature regenerator 51 of the single/double type absorption refrigerator 48. ,
The refrigerant in the high-temperature regenerator 51 is turned into vapor and sent to the low-temperature regenerator 49 via the pipe 52. The hot water (condensed water) that has passed through the heat radiation section 38 in the high-temperature regenerator 51 of the single-duplex absorption refrigerator 48 is sent to the hot well tank 46 through the pipe line 44, and from there is sent to the hot well tank 46 by the circulation pump 47. , and is again sent into the exhaust gas boiler 34 from the hot water discharge port 37.

In addition, cooling water at 32°C is supplied from the cooling tower 57 to the circulation pump 5.
9 to the absorber 55, and in the tank 54, the cold water supplied by the cold water pipe 60 can be supplied at 7°C. The cooling water leaving the absorber 55 is
After being sent to the condenser 50, it returns to the cooling tower 57.

In addition, the temperature of the cooling water in the water jacket 23 of the reciprocating engine 22 rises, and the hot water in the low temperature circulation circuit 25 rises.
When the temperature can be raised to 5° C., the solenoid valve 29 can be opened, the valves 31 and 32 can be closed, and the bypass path 30 can be closed.

Furthermore, when the power load is extremely reduced and the exhaust gas temperature drops, the function of the exhaust gas boiler 34 will decrease, but the low-temperature circulation circuit 25 can form a circuit similar to the conventional system.・Double combination type absorption refrigerator 48
can function as a single-effect absorption refrigerator.

Furthermore, when the cooling load decreases, by opening the solenoid valve 41 and closing the solenoid valve 43, surplus steam can be safely released to the atmosphere via the silencer 42.

As described above, according to this embodiment, the reciprocating engine 22
A hot water circuit that communicates between the exhaust gas boiler 34 and the absorption chiller is connected to the water jacket 23 of the reciprocating engine 22.
Since the circulation circuit that thermally communicates with the exhaust gas boiler 34 and the circulation circuit that thermally communicates with the exhaust gas boiler 34 are separated, it is possible to use them without reducing their respective temperature potentials, and it can also be used as an absorption chiller. It has become possible to use a combination single and double absorption refrigerator 48. As a result, it was possible to improve the heat exchange efficiency to nearly 80%.

FIG. 2 shows a second embodiment of the invention. In this example,
A heat exchanger 63 is interposed when connecting the reciprocating engine 22 in the low temperature circulation circuit 25.

According to this embodiment, the same effects as those of the above-mentioned embodiments are achieved, and the single-double absorption refrigerator 48 can be installed at a desired location.

FIG. 3 shows a third embodiment of the invention. Exhaust gas boiler 34
A bypass pipe 64 is provided.

In each of the above embodiments, the exhaust gas boiler 34 is directly attached to the exhaust system 24, but a bypass pipe 64 is provided in the exhaust gas boiler 34, and the exhaust gas boiler 34 is used or not used by opening and closing valves 65 and 66. You can also adjust the ability.

〔Effect of the invention〕

As described above, according to the present invention, there is provided a generator, a reciprocating engine that drives the generator, an exhaust gas boiler provided in the exhaust system of the reciprocating engine, and a combination single and double absorption refrigerating machine. Single layer with the cooling water side of the reciprocating engine.
The low-temperature circulation circuit is thermally connected to the low-temperature regenerator of the double absorption chiller, and the exhaust gas boiler installed in the exhaust system of the reciprocating engine and the high temperature of the single/double absorption chiller. Since it is composed of a high-temperature circulation circuit that is thermally connected to the regenerator and circulates, it is possible to efficiently convert exhaust gas and water jacket cooling heat, which have different temperature potentials, into cold heat without reducing their respective temperature potentials. Can be done.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram showing a cogeneration system according to a first embodiment of the present invention. FIG. 2 is an explanatory diagram showing a cogeneration system according to a second embodiment of the present invention. FIG. 3 is an explanatory diagram showing a cogeneration system according to a third embodiment of the present invention. FIG. 4 is a conceptual diagram showing a conventional cogeneration system. [Explanation of symbols of main parts] 20... Generator 22... Reciprocating engine 25... Low temperature circulation circuit 34... Exhaust gas boiler 35... High temperature circulation circuit 48... Single/double combination Type absorption refrigerator 49...low temperature regenerator 51...high temperature regenerator.

Claims (1)

[Claims] (1) A generator, a reciprocating engine that drives this generator, an exhaust gas boiler installed in the exhaust system of this reciprocating engine, a single/double absorption refrigerator, and a cooling water side of the reciprocating engine. A low-temperature circulation circuit that is thermally connected to the low-temperature regenerator of the single/double type absorption chiller, and an exhaust gas boiler installed in the exhaust system of the reciprocating engine and the single/double type absorption chiller. A cogeneration system comprising a high-temperature regenerator and a high-temperature circulation circuit that circulates while being thermally connected to the high-temperature regenerator.