DE3021824A1 - HEATING SYSTEM WITH HEAT PUMP - Google Patents

Description

Heating system with heat pump

The invention relates to a heating system with a Heat pump, the compressor of which is driven by an internal combustion engine, whereby the heat loss from the internal combustion engine is over at least one heat exchanger is transferred to the heat transfer medium in the heating network of the system.

In known systems of this type, the heat exchanger is arranged as an independent, separate component and over exposed Lines connected to the heating network and the housing part of the internal combustion engine, from which the heat loss is removed will. Since heating systems are often switched on and off automatically several times an hour, between Internal combustion engine and heat exchanger known expansion compensators (e.g. elastic corrugated pipes) to allow multiple changes between thermal expansion and cooling in the pipe system enable. In addition, a large number of connection points are required in the lines between the internal combustion engine and the heating network.

Such systems are therefore very disadvantageous. First of all, the expansion compensators are expensive to purchase and theirs Limited service life. In addition, the many connection points must be sealed very carefully so that the system receiving them Surrounding rooms, mostly house basements, not contaminated by media escaping from the heating network or the internal combustion engine will. Finally, there is also maintenance and cleaning

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Sheet 4- to the letter dated 06/10/80 _to DPA

the heat exchanger itself is very cumbersome and expensive, because many lines are removed and reconnected Need to become.

It is the object of the present invention to eliminate these disadvantages of the known systems. This object is achieved according to the invention solved in that that part of the housing of the internal combustion engine, at which the heat loss is removed, in the way is designed so that it also serves as a receptacle for the heat exchanger. This design according to the invention enables the construction a heating system that requires a minimum of exposed lines between the heating network and the internal combustion engine. The on Heat loss occurring in a housing part of the internal combustion engine is transferred to the heat exchanger housed in the same housing part supplied practically in full, so that there is a high efficiency of the heat exchange. Neither are they exposed Connection points or expansion compensators between the internal combustion engine and heat exchangers required, so that an economical structure and an environmentally friendly operation results.

In heating systems, the exhaust gas heat from the internal combustion engine is often used used as heat loss and transferred to the heat transfer medium in the heating network via the heat exchanger. Here it is advantageous according to a further feature of the present invention, the cylinder head of the internal combustion engine having the exhaust gas duct and to shape the receptacle for the heat exchanger into a single housing piece in such a way that the exhaust gases from the internal combustion engine from the exhaust duct directly to the in the same

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Sheet V for the letter from ¹ "· ^ · ⁰ " to

May 10th, 1980 _to DFA IHATZ

heat exchanger mounted on the housing and only after it Flow through leaving the cylinder head.

A simple embodiment of this invention results when at least one channel surrounding the heat exchanger is provided in the cylinder head of the internal combustion engine, through which the heat transfer medium is passed from the heating network and in the process flows around the heat exchanger through which exhaust gases flow. Such an embodiment can be used regardless of the type of medium used as the heat transfer medium in the heating network and also of the type of internal combustion engine used to drive it. An air-cooled internal combustion engine can consequently also be used here. \ -_.

Another, particularly advantageous embodiment of the invention is possible in systems with water as the heat transfer medium and with Water-cooled internal combustion engines. In such a case, there is at least one heat exchanger in the cylinder head of the internal combustion engine Provide surrounding channel through which the water is passed and thereby the heat exchanger through which exhaust gases flow flushed around, the water heated after flushing around the heat exchanger being fed to the heating network.

An expedient structural development of the invention is that the heat exchanger as a self-contained unit formed and exchangeable from the outside in the receptacle in the The cylinder head of the internal combustion engine is arranged. In this embodiment, one is necessary for cleaning or maintenance purposes Removal and installation of the heat exchanger can be carried out very easily «

Sheet 6 to the letter _to the 10.06.8C

In the following description, exemplary embodiments of the Invention explained with reference to drawings. Show it:

Fig. 1 the heat pump with compressor and driving it Internal combustion engine in a schematic representation,

2 shows the cylinder and cylinder head of the internal combustion engine in partial vertical longitudinal section,

Fig. 3 is a horizontal cross section through the cylinder head along line A-A of Fig.2, and

Fig. 4 shows a vertical cross section through the cylinder head Line B-B of Figure 3.

The heat pump shown schematically in Figure 1 comprises a two-cylinder compressor 10 for the refrigerant in its circuit, the drive shaft 10a of the compressor 10 being driven by the output shaft, ie the crankshaft 12a of a water-cooled internal combustion engine 12 of a known type, e.g. a single-cylinder injection internal combustion engine. In an evaporator 14 upstream of the compressor 10, the liquid refrigerant is made to evaporate at a temperature of about 2 ° G and, as indicated by arrow E, absorbs the heat from the medium surrounding it, for example groundwater or air, and evaporates in the process. The refrigerant vapor is then conducted to the compressor 10 in a suction line 16. During the compression phase, the refrigerant vapor is compressed and heated in the process, so that it is then passed through a line 18 to a condenser 20. ^{The refrigerant vapor, which is heated to approximately 60 °} C. in the compressor 10, flows through the condenser 20 in a line 20a, gives off most of its heat and becomes liquid again. The liquefied, cooled refrigerant is passed through an expansion valve 26, expands and assumes its original temperature of approximately 2 ^° C. again. It then flows

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HATZ

Sheet 7 of the letter dated 10.06.80 to DPA

back to the evaporator 14 to start a new cycle in the Start the heat pump.

Through the capacitor 20 in a separate line 22 the Used, cooled heating water from a heating system, e.g. a house heating system 24, and takes it from the refrigerant given off heat. The heating water heated after passing through the condenser 20 becomes a connection point 12b on the internal combustion engine 12 and entered for the purpose of cooling this machine in its only dash-dotted line cooling system. At the end of this cooling cycle, the heated water is poured over a additional heat exchanger 28 passed and with the help of from the Heat loss resulting from combustion exhaust gases is heated even further. The heated water is then sent to another connection point 12c passed to the machine 12 in order to supply the cooling line system here leaving. In a line 30, the highly heated water is passed into the domestic heating system 24, which has most of the obtained heat in the direction indicated by arrow H for house heating purposes gives away.

The details of the cooling line system, indicated only schematically in FIG. 1, of the machine 12 and of the additional heat exchanger 28 emerge from the following description and the other figures. Here, the cylinder and cylinder head arrangement of the engine 12 is shown in section. The cylinder 32 receives a vertical cylinder liner 34 in which a piston 36 is guided. The connecting rod 38 coupled to the piston engages the crankshaft 12a of the engine 12 in a known manner. The cylinder 32 is by means of four bolts 40, a cylinder head 42 bef ^it * ÄSTk 'n jfl, Y ^ ^ -Wfc P ^e * ⁿ ^ intake ^"a training

8 to the letter dated June 10th, 1980 _to DPA

release valve 46 and a fuel injector 48 in known Way are arranged. Each valve is actuated via an associated rocker arm 50, which is also actuated by a push rod 52 in is controlled in a known manner by a control drive, not shown. A cylinder head cover 54 closes the two rocker arms 50 from the outside. The combustion air is in a duct 42a to the suction valve 44, while the exhaust gases flowing out via the outlet valve are discharged through the outlet channel 42b.

The operation of a four-stroke injection internal combustion engine from described type is known and is therefore not intended here in detail explained.

Between the housing parts 32 and 34, a narrow annular space is provided which is connected in terms of lines to the aforementioned water connection point 12a, which is arranged in the lower region of the housing parts 32,34. Two transverse bores 58 represent the line connection between the annular space 56 and two bores 60, each of which is seated in a lateral flange 32f of the housing part 32. In order to cool the cylinder 32,34 and the cylinder head 42, the water in the spaces 56-60 goes upwards and passes through two passage openings 42d of the head 42 from the bores 60 into the cooling channels 42k inside the cylinder head 42.

The cylinder head 42 is designed such that it is at the same time as

perpendicular / recording for the heat exchanger 28 is used. A to the cylinder axis' upright and horizontally elongated channel 42t is delimited by the tubular walls 42w of the head 42 and Shaped via partition walls 42z with the head 42 to form a single housing unit. A connection channel 42v is between the

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Sheet 9 to the letter of 1 Ö. 06 .80 to DPA

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Walls 42w and 42z are formed and run parallel to the channel 42t. The channel 42v is connected to the cooling channel via a channel-shaped opening 42s extending below the outlet channel 42b 42k in pipe connection, so that the water from the cooling pipe system in the cylinder head 42 in the connecting channel 42v and above whose mouth opening 42w can flow further into the bing channel 42t.

The tubular wall 52w of the head 42 is on both sides formed into annular receiving flanges 42f in which the heat exchanger 28 is arranged. It consists of a multitude of thin tubes 28a, which are held together at their ends in two holding plates 28b. The heat exchanger 28 can access this Way as a self-contained unit in the receptacles 42f be introduced through a lateral opening 42o in the cylinder head 42, which can be closed by a cover 62. The exhaust outlet duct 42b of the head 42 opens into a chamber 42bb between the receptacle 42f and the cover 62, so that the Exhaust valve 46 discharges hot combustion gases from chamber 42bb through the interior of the thin heat exchanger tubes 28a flow through and exit again on the other side, and then via an outlet pipe 64 to a suitable outlet point to be forwarded.

When flowing through the heat exchanger 28, ie its tubes 28a, the ^{exhaust gases flowing out of the cylinder at a temperature of about 40O 0} C give off a large part of their heat, which is generated as heat loss during the combustion process, to the water surrounding the tubes 28a, so that the Exhaust gases at the outlet pipe still have a heat of about 150 ^° C. That through the exhaust

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Sheet 10 of the letter dated June 10, 1980 to DPA

hot water exits channel 42t through an opening 42tt and is connected to the house heating system via the connecting pipe 12c 2A- conducted to its heat to house heating in well-known Way to deliver

The advantages resulting from the design of the cylinder head 42 result as a simultaneous recording for the heat exchanger 28, are already mentioned in detail in the introduction. It should therefore only be added that - in contrast to the embodiment described - a common housing unit for the cylinder head and Heat exchanger would also be applicable if the heat transfer medium in the heating system and the coolant for the internal combustion engine are not of the same kind (water). Also, the additional Heat exchanger (28) formed into a single unit in a similar manner with a housing part other than just the cylinder head If it appears in the case of certain internal combustion engines, the heat loss is somewhere other than in the cylinder head take off and enter there in the additional heat exchanger. It would be conceivable, for example, the crankcase of the internal combustion engine at the same time as a heat exchanger receptacle if the heat loss from the lift stored there Lubricating oil should be fed to the heating water or another medium in the house heating system via the heat exchanger.

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Claims (6)

Godfather ή ta η s ρ r ü c h e: (1.iHeating system with a heat pump, the compressor of which is from an internal combustion engine is driven, the heat loss the internal combustion engine is transferred to the heat transfer medium in the heating network of the system via at least one heat exchanger, thereby characterized in that that housing part (42) of the internal combustion engine (12) y at which the heat loss is removed, is designed in such a way that it also serves as a receptacle for the heat exchanger (28). 2. Installation according to claim 1 with an internal combustion engine whose Exhaust heat via the heat exchanger to the heat transfer medium in the heating system is added, characterized in that the exhaust duct (42b) having cylinder head (42) of the internal combustion engine (12) and the receptacle (42f) for the heat exchanger (28) in this way a single housing piece are formed that the exhaust gases of the internal combustion engine from the exhaust duct directly to the im heat exchanger mounted on the same housing part and only leave the cylinder head after it has flowed through. 3. Plant according to claim 2, characterized in that im Cylinder head> (42) of the internal combustion engine (12) at least one the channel (42t) surrounding the heat exchanger ί28) is provided, through which the heat transfer medium from the heating network (24) is passed and the heat exchanger through which exhaust gases flow washed around, 130051/0251 Sheet ² to the letter of 10.06.80 "" ■ DPA 4-, plant according to claim 2, with water as the heat transfer medium Heating network and with a water-cooled internal combustion engine, characterized in that in the cylinder head (4-2) of the internal combustion engine (12) at least one duct (42t) surrounding the heat exchanger (28) is provided through which the Water is passed and in the process washes around the heat exchanger through which the exhaust gases flow, this being done after the heat exchanger has been washed around heated water is fed to the heating network (24-). 5. Plant according to claim 2, characterized in that the heat exchanger (28) is designed as a self-contained unit and exchangeable from the outside in the receptacle (4-2f) in the Cylinder head (4-2) of the internal combustion engine (12) is arranged. 6. Plant according to claim 6 with a heat exchanger, which consists of a There is a multitude of parallel tubes that are openly combined at their ends in round holders, characterized in that that for each holder (28b) in the receptacle (4-2f) formed in the cylinder head (42) of the internal combustion engine (12) one Bearing bore is provided in which the holder is sealing sits. 130051/0251