DE3150148A1 - Internal-combustion engine for driving a compressor of a heat pump - Google Patents

Abstract

In a heat pump whose compressor is driven by an internal-combustion engine, a simple structural unit is created by the present invention which acts as a front silencer, a silencing section and a rear silencer for the exhaust gas system, allows the overpressure in the exhaust gas system to be reduced, extracts usable heat from the exhaust gases and supplies the said heat to the heating system, condenses out the water content from the exhaust gases and cleans said gases of harmful substances. This structural unit consists essentially of an external container in which a container through which the exhaust gas flows, is arranged concentrically and which has an immersion pipe which leads below the water level of a water reservoir. In order to prevent condensate formation after leaving this structural unit, the exhaust gas is once again guided along the outer wall of the container, as a result of which the exhaust gas is reheated. This reheating of the exhaust gas dries said exhaust gas and allows the exhaust gas line leaving the structural unit to be connected to a conventional building chimney.

Description

Internal combustion engine zitil drive a compressor of a heat pump

The invention relates to an internal combustion engine for propulsion a compressor of a heat pump, wherein the exhaust gases of the internal combustion engine a Flow through the silencer and a heat exchanger, which are arranged in the exhaust pipe are to dampen the noise of the internal combustion engine on the one hand and to on the other hand to condense the condensable components in the exhaust gases and to wash out pollutants as well as the recovery of exhaust gas heat.

In such known systems, the exhaust noise is a or several mufflers reduced. A recovery of exhaust heat is here problematic, especially in diesel engines, because of the relatively heavy soot deposits occurs and in diesel and gasoline engines aggressive condensate from the nitrogen oxides and sulfur dioxide is formed in conjunction with the condensing water vapor.

The pollutants produced have so far either been discharged with the exhaust gas or more or less retained and neutralized by exhaust gas condensation. It is known from DE-AS 2 744 615 to pass the combustion gases through a heat exchanger to conduct, which must have the lowest possible temperature in order to keep as much condensate as possible and to hold back pollutants.

The disadvantage of this construction is that for the heat exchanger a low cooling temperature is required, so that a heat sink with accordingly low temperature and the heat exchanger must be very large is because the heat transfer between gas and metal is relatively low.

To discharge the exhaust gases one to drive a compressor one Heat pump used internal combustion engine, it is known the exhaust gases to lead directly to the open air via an exhaust pipe. Due to the low exhaust gas temperatures in the case of exhaust gas heat utilization and in particular in the case of exhaust gas condensation, this occurs Installation in some cases considerable amounts of condensate and acids. An introduction the exhaust gases in the building chimney is not easily possible for this reason; In addition, it is imperative that when the exhaust gases are introduced into the building chimney these are fed to the chimney without pressure.

The object of the present invention is to overcome the disadvantages of the known Avoid constructions and provide a device for the discharge of the exhaust gases internal combustion engine provided for driving a compressor of a heat pump create, which avoids the above-described, known problems. Included should the device in the simplest possible way a good soundproofing and a Allow pressure reduction in the exhaust system and a heat exchanger to recirculate the Have the amount of heat contained in the hot exhaust gases. In addition, the exhaust gas should cleaned and a condensation of aggressive liquids after leaving the device be avoided. Particular importance is attached to the fact that the device is simple in structure st and enables problem-free installation in the heating system.

This object is achieved according to the invention in that to reduce noise and to reduce the pressure of the silencers and heat exchangers form a structural unit, wherein a water seal is arranged, from the exhaust gases is flowed through. These features create a unit that has a Sound attenuation achieved in the exhaust system, a pressure reduction causes5 a heat recovery and allows the exhaust gases to be cleaned of pollutants. The structural unit is also very compact and easy to install in the heating system.

According to a further feature of the invention, the exhaust line opens into a container, at the end of which is opposite the exhaust gas inlet, a dip tube is arranged, which ends in the water reservoir, and in the water reservoir Heat exchanger is arranged, which the amount of heat absorbed the heating system feeds. The container serves as a pre-silencer, while the one below the Water level of the water reservoir Immersion tube as a result of direct contact of the exhaust gas with the water ensures good heat and mass transfer causes a high proportion of the water content of the exhaust gases to condense and at the same time pollutants such as sulfur dioxide and nitrogen oxides go into solution and soot is washed out. At the same time, the exhaust gas cools down in the water seal Heat is withdrawn and this amount of heat is fed to the heating system via the heat exchanger.

A drying of the exhaust gases before leaving the structural unit is easy Way achieved in that, according to the characteristics, the exhaust gas flowed through the water seal from the hot outer surface of the container and then to an exhaust gas outlet got.

In this way, the container forms a gas heat exchanger, which thus formed in a simple manner according to a further feature of the invention is that the container is surrounded by a jacket, which is the water seal exhaust gas flowed through between the outer wall of the container and the inner wall of the jacket reaches the exhaust outlet. By reheating the exhaust gas before leaving the unit a drying is achieved, so that in the subsequent continuation of the exhaust gas no condensation occurs.

For discharging the condensate and the accumulating in the water reservoir According to the invention, pollutants are the water reservoir with a siphon as an overflow provided, which is arranged in the outer container receiving the water seal. This siphon creates a drainage option that can only be used with Increasing the level of the water reserve allows liquid to escape while the gas cannot escape through this opening, not even a slight one Overpressure in the outer container. The external container is used to renew the water reserve it is provided according to the invention with a fresh water supply.

Since the pressure in the exhaust system is reduced by the structural unit is, it is possible according to the invention that the exhaust gas outlet with the OebAudeschornstein connected is.

The invention is explained in more detail below with reference to the drawing: the Figure shows the structural unit according to the invention in longitudinal section in a schematic representation. It consists essentially of the outer container 1, the lid of which the container 2, the container 2 being arranged concentrically in the outer container 1.

The exhaust gas inlet nozzle 3 opens into the container 2, while at the bottom of the container the dip tube 6 is attached and below the liquid level of the water reservoir 7 ends. The container 2 is also surrounded by a jacket 5 and forms between the outer wall of the container 2 and the inner wall of the shell 5 an annular space, the is connected to the exhaust gas outlet nozzle 4. In the water reserve 7 is located a heat exchanger 8 belonging to the heating system Siphon 9 is with the water gate 7 in liquid-conducting connection, while a fresh water supply 10 opens into the interior of the container 1.

The exhaust gas from the internal combustion engine (not shown) passes over the exhaust gas inlet supports 3 into the container 2, this container 2 as a pre-silencer works. The hot dip tube 6 passes through the dip tube 6 at the bottom of the container 2 Exhaust gas in the water seal 7 of the outer container 1. By direct contact with the Exhaust gas with the water takes place a very good heat and material exchange, whereby a high proportion of the water content of the exhaust gases condenses out and at the same time the Pollutants like sulfur dioxide and nitrogen oxides go into solution and the soot is washed out will. The heat released in the water seal 7 when the exhaust gas cools down Delivered to the heating system via the heat exchanger 8. After the exhaust gas the water reserve 7 has passed, it gets through the free interior space, which acts as a rear silencer of the outer container 1 into that of the outer wall of the container 2 and the inner wall of the jacket 5 formed annular space, by the hot wall of the container 2 is here the exhaust gas is heated up again, which once causes exhaust gas drying and for others for the one necessary when connecting to a conventional building chimney Buoyancy is taken care of.

The exhaust gas leaves this structural unit via the exhaust gas outlet nozzle 4, the exhaust gas outlet nozzle 4 in a building chimney, not shown flows out. The container 2 thus acts as a gas heat exchanger, with part of the amount of heat of the entering Gas for exhaust gas reheating of the exiting Gas is used. When flowing through and cleaning the exhaust gas in the water reservoir 7 the volume of the water reserve becomes due to the formation of condensation and washing out of the pollutants 7 enlarged, the drainage of the condensate there and that in the water reservoir 7 accumulating pollutants via the siphon 9 takes place. The growing concentration of acids and soot becomes constant due to simultaneous water condensation weakened, so that one of further external parameters such as cooling water temperature and exhaust gas adjusts to the state-dependent state of equilibrium. A renewal the water reservoir 7 can be fed into the external container 1 via the fresh water supply 10 take place.

The structural unit described above is in a simple manner a good sound absorption is achieved, since the container 2 serves as a pre-silencer, while the outer container 1 represents the rear muffler. Another D damping route is achieved by the water seal 7. The water gate 7 causes a good exhaust gas cleaning and condensing the water vapor contained in the exhaust gas. The depressurization of the Exhaust gas also takes place in this unit and through the exhaust gas reheater Acting container 2 is a drying of the structural unit through the exhaust gas outlet 4 leaving gas achieved. The finished unit is despite the above, multiple functions, easy to assemble and allows easy installation in the Heating system.

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Claims (7)

P A T E N T A N S P R Ü .c. H E internal combustion engine to drive a Compressor of a heat pump, whereby the exhaust gases of the internal combustion engine have a silencer and flow through a heat exchanger, which are arranged in the exhaust pipe, on the one hand to dampen the noise of the internal combustion engine and on the other hand the To condense condensable components in the exhaust gases and to wash out pollutants and to achieve a recovery of the waste heat, dad gek * that to reduce noise and a structural unit for reducing the pressure of the muffler and the heat exchanger form wherein a water reservoir (7) is arranged through which the exhaust gases flow will. 2. Internal combustion engine according to claim 1, dad. gek. that the exhaust pipe (Exhaust gas inlet nozzle 3) opens into a container (2) at whose exhaust gas inlet opposite end a dip tube (6) is arranged, which in the water reservoir (7) ends, and a heat exchanger (8) is arranged in the water reservoir (7) supplies the absorbed amount of heat to the heating system a 3. Internal combustion engine after claims 1 and 2, dad. gek. That the water seal (7) flowed through the exhaust gas is heated by the hot outer surface of the container (2) and then to an exhaust gas outlet (Exhaust outlet nozzle 4) arrives. 4, internal combustion engine according to claims 1 to 3, dad. gek. that the container (2) is surrounded by a jacket (5), which is the water seal (7) exhaust gas flowed through between the outer wall of the container (2) and the inner wall of the jacket (5) reaches the exhaust gas outlet (exhaust gas outlet nozzle 4). 5. Internal combustion engine according to claims 1 to 4, dad. gek. that the water seal (7) has a siphon (9) as an overflow, the in which the water seal (7) receiving the outer container (1) is arranged. 6. Internal combustion engine according to claims 1 to 5, dad. gek. that the outer container (1) is provided with a splash water supply (10). 7. Internal combustion engine according to claims 1 to 6, dad. gek. that the exhaust gas outlet (exhaust gas outlet nozzle 4) is connected to a building chimney is.