DE4203491A1 - Heating circuit for building or swimming pool - has combustion engine with exhaust gases and emergent cooling water heating up boiler water via heat exchangers - Google Patents

Abstract

The heating circuit has a combustion engine coupled to a generator, and a boiler which is heated both by the exhaust gas of the engine and its outgoing cooling water using heat exchangers. The generated electricity can be used partially or totally for the heating of the boiler. The remanent heat in the exhaust gases is extracted from another heat exchanger circuit with an engine driven-pump and this heat is also added to the boiler's thermal storage. The catalytically-cleaned and spent exhaust gases pass to the atmosphere. ADVANTAGE - Improved overall cycle efficiency.

Description

The present invention relates to an energy ver Care unit according to the generic term of claim 1.

Such power supply units can be found, for example Application to both in a building or a swimming pool To provide thermal energy as well as electrical energy. In many cases, however, the electrical energy generated is not in fully needed and the feed of the excess Energy in the public grid is either not possible or with difficulties.

It is therefore the object of the present invention To design energy supply unit in such a way optimal energy utilization is made possible.

This problem is solved according to the characteristic ones Features of claim 1. Further advantageous Ausge events of the power supply unit according to the invention the dependent claims.

Based on the single figure of the accompanying drawing following an embodiment of an inventive  Power supply unit are described in more detail.

With the drive shaft of a combustion or heat engine M. an electrical generator G coupled, which preferably as Asynchronous generator is designed and therefore also easier Be operated as a motor with electrical control which can then be used as a supply from the public network Starter for the internal combustion engine M is used. Exhaust gases from the engine M are over a catalyst Kat and a probe LS (e.g. Lambda probe) fed to a heat exchanger C3 in a boiler B.

Furthermore, the cooling water of the engine M after heat exchange in a heat exchanger C1 in the engine M by a cooling circuit pump P1 pumped to a heat exchanger C2 in boiler B to put his To give off heat to the water in boiler B.

After the exhaust gases of the engine in the heat exchanger C3 their heat have largely given up to the water in boiler B, they will a heat exchanger H supplied to the residual heat in this to deliver a heat pump circuit which is a compressor pump P2 has the compressed heat medium to a heat exchanger C4 in boiler B. The cooled and cleaned exhaust gases are from the heat exchanger H, possibly via a fan F to the outside guided.  

Both the cooling water pump P1 and the heat pump P2 are seated on the drive shaft of the motor M and are thus by this driven.

The boiler B is heated by two heat exchangers C5 and C6 removed, the heat exchanger C5 via a circulation pump P3 is connected to a heating circuit and the heat exchanger C6 via a process water charging pump P4 to the process water circuit run is connected. The pumps P3 and P4 are also seated on the drive shaft of the motor M. Um even in the event of a failure or a break in operation of the motor M to operate the heating and being able to provide service water are further Pumps P5 and P6 are provided electrically from the network can be controlled.

A thyristor bridge TB1 controls the start of the motor / Generator G, its synchronization and performance distribution. Another thyristor bridge TB2 is used for Control of the electric boiler heater EH. This electrical Boiler heater EH can also be used to prevent uneven phases load on generator G if the public grid fails to compensate. Interrupt circuits are CB1 and CB2 provided for a controlled shutdown of the various make electrical circuits of the supplied device or in the event of a power failure, the public network cut off.  

The entire power supply unit and its components are controlled by an electrical control CC, whereby this on the engine, the generator, the catalyst, the Temperature, power distribution, interruption switching circles etc.

Claims (7)

1. Power supply unit with a combustion or heat engine and an electric generator driven by it and a boiler which is heated by heat exchangers from the cooling water and the exhaust gases of the engine, characterized in that the electrical energy generated by the generator (G) in whole or in part is used in addition to the electrical heating of the boiler (B). 2. Power supply unit according to claim 1, characterized characterized in that with the wave of Internal combustion engine (M) one working on the boiler (B) Heat pump (P2) is coupled, the circuit via a Heat exchanger (H) with the residual heat of the exhaust gases in Heat exchange stands. 3. Power supply unit according to claim 2, characterized characterized that with the shaft of the engine (M) a cooling water pump (P1) is also coupled. 4. Power supply unit according to claim 3, characterized characterized that a heating circuit circulation pump (P3) and a domestic water charge pump (P4) to the shaft of the Internal combustion engine (M) can be coupled. 5. Power supply unit according to claim 1, characterized characterized in that as a generator  asynchronous generator (G) which can also be operated as a motor is arranged. 6. Power supply unit according to claim 5, characterized characterized in that the exhaust gases from the Motors (M) a catalyst (Kat) is arranged. 7. Power supply unit according to claim 1, characterized characterized that the electrical Boiler heating (EH) is usable to uneven phases to compensate for the load on the generator (G).