DE19909885A1 - Heat pump arrangement for single-family house; has condenser for gaseous coolant operated by internal combustion engine, where movable units are formed of same movement type - Google Patents

Abstract

The arrangement has a condenser for gaseous coolant and an internal combustion engine for the condenser. Movable condenser units for the engine and the condenser are formed in the same movement type. The movement of the condenser unit of the condenser and the engine are coupled by a common undivided transfer arrangement. An Independent claim is included for a heating system incorporating the heat pump arrangement.

Description

Smaller heating systems are used to save fossil fuels such as single-family houses and increasingly also heat pumps used which the ambient air or the ground as a heat source use. The heat pump assemblies typically include one Piston compressor for the refrigerant and an electric motor to drive the Compressor.

The object of the present invention is to provide a heat pump arrangement high efficiency and simple and therefore inexpensive construction as well specify a heating system with such a heat pump arrangement.

Solutions according to the invention are in the independent claims described. The dependent claims contain advantageous ones Refinements and training.

It is essential in the heat pump arrangement according to the invention that the in conventional heat pump arrangements, the usual separation of Drive unit, briefly referred to as drive, and the compressor unit Heat pump is canceled and the two functions in closer structural Unit are realized, wherein the drive is designed as an internal combustion engine. In particular, the movements or moving Compression devices of the two different functional components Refrigerant compressor on the one hand and internal combustion engine on the other  a common undivided mediation means be coupled. Preferably are the compression spaces of the internal combustion engine and the refrigerant compressor formed in a common support block. Even if the Internal combustion engine in its work cycle a compression process includes, with compressor in the following, the refrigerant compressor the heat pump.

In a preferred embodiment, the compression devices are as Reciprocating piston and a common undivided crankshaft in coupled with their movements. The cylinders as compression spaces are included preferably realized in a common support block, in itself known manner, the cylinder treads also in holes of the Carrier blocks inserted cylinder liners can be realized.

The preferred embodiment is one in its structure common multi-cylinder internal combustion engine similar, in which at least one cylinder in a conventional manner as a motor drive and at least one other cylinder is used as a compressor for the refrigerant. On the extensive and varied experiences and insights from the Development of reciprocating internal combustion engines can be advantageous be used and built up.

The design with a high compression is particularly advantageous Reciprocating piston arrangements which, on the one hand, Immunity to interference and longevity particularly cheap diesel engine Drive principle (self-ignition engine) enables and on the other hand for the Heat pump operation is an advantage. The beneficial effects of high Compression both in the drive principle and in the refrigerant Compression complement each other in a particularly advantageous manner.  

In contrast to the drive with the typical four-stroke cycle Suction, compression, combustion with expansion and ejection is the Cycle of the compressor with suction and compressed discharge per se only two-stroke. During a drive cycle, the preferred one Embodiment are run through two compressor cycles. The control the inlet and outlet valves of the compression chambers is for the Compressors different than for the drive. In particular, at Compression chamber of the compressor the forced control of one or more Valves via camshafts or the like are omitted and by executing such Valves to be replaced as check valves.

However, the compressor can also be four-stroke in the sequence - suction - compression without ejection - expanding - compressing with ejection.

Due to the similarity of the preferred embodiment of the Heat pump arrangement with a conventional multi-cylinder According to a development of the invention, the internal combustion engine can also be a such a common motor with little effort to one heat pump assembly according to the invention to be rebuilt, in addition to the separation of the gas streams in particular the aforementioned differences of Valves are to be considered as a design change. Since at Compressor building a high pressure of the refrigerant is not primarily in the Cylinder space, but also afterwards to the condenser is important, that can Remaining volume of the cylinder space (with the piston at top dead center) be reduced compared to the cylinder space of an engine cylinder, for which purpose in a low-effort version simple, reducing the free gas volume Inserts can be introduced into the cylinder space.  

For a heat pump arrangement with an internal combustion engine as drive is particularly advantageous to use a motor, which by its constructive structure for the combustion of fuels from renewable Raw materials, especially fuels from vegetable oils such as For example, so-called bio-diesel fuel is provided. It is advantageous also an all-substance engine, which also used with fats, for example household oils and fats can be operated.

The speed of the drive and the compressor output are advantageous controllable via the fuel supply to the internal combustion engine, whereby a Adaptation to a varying heating power requirement in particular Seasonal variation is quick and easy.

Advantageously, the combustion gases in the Combustion engine contained energy in heat exchanger devices for Exhaust gas cooling also used in a heating system, with the Exhaust gas cooling by falling below the dew point for the in the exhaust gas contained water vapor also used its high heat of condensation can be.

Drive and compressor advantageously have a common cooling system with a uniform coolant supply and a common one Coolant drain, which in turn is advantageous that the heat output to be dissipated over the walls of the compression rooms The compressor and drive are of the same order of magnitude. The coolant is advantageously the refrigerant from the Heat pump circuit itself used, being in the form of the so-called Suction gas cooling the cooling system between the outlet of the condenser and Input of the compressor, especially between the output of the condenser  and expansion valve of the evaporator is arranged in the refrigerant circuit. Advantageously, a heat exchanger device is used Heat transfer from the refrigerant heated in the cooling system at the outlet of the Cooling system to the refrigerant cooled in the evaporator at the inlet of the Compressor.

A collector system used to extract heat from the environment is preferably via a heat exchanger device with the evaporator Heat pump arrangement connected and has its own closed Pipe system with a heat transfer medium different from the refrigerant on, especially with water as a heat carrier, which by adding salt or another anti-freeze to prevent the collector system from freezing is secured. The collector system preferably comprises a buried one Soil collector. Especially when using a ground collector a heating system connected to the heat pump arrangement in summer also advantageously suitable for cooling rooms, in which case the Soil collector is used as a heat sink.

With the arrangement according to the invention in particular also with additional Utilization of the exhaust gas heat achievable high utilization of the Combustion engine supplied primary energy and through the simple Power control can be required in almost any heating system Performance range monovalent via the heat pump arrangement and one appropriately designed collector arrangement, in particular an earth Collector arrangement are operated.

In particular in the form of exhaust gases from the internal combustion engine Temperatures are available, which also include heating domestic water  to high hygiene regulations, such as the so-called Legionella regulation allow satisfactory temperatures of 90 ° C, for example.

The simple and compact structure of the arrangement enables the structure a heating system for both space heating and domestic water Warming at low purchase costs, which in connection with the high energy utilization too short and therefore especially Private households leads to interesting economic payback periods. The simple performance variation means that it can be used in almost any and in particular, integration into existing heating systems is also possible.

The invention is based on a preferred embodiment with reference to the figure, which schematically shows the structure of a Heating system with a heat pump arrangement shows.

The heat pump arrangement outlined includes a closed one Refrigerant circuit with a refrigerant compressor KV, a refrigerant Condenser KK, a cooling system KS, an expansion valve EV, a Refrigerant evaporator KD and an additional refrigerant heat exchanger WTK.

As a heat sink, a heating circuit H is provided, which via a Heater heat exchanger WTH thermally with the refrigerant condenser KK is coupled. The refrigerant evaporator KD is WTQ heat exchanger and a collector line system with a collector, in particular an earth collector as a heat source Q thermal coupled.  

The principle of operation of the heating system is known per se. That in Compressor heated to high temperature T9 by high compression gaseous refrigerant flows through the condenser part of the heating Heat exchanger WTH, in which heating fluid is made in countercurrent the heating circuit via a return line RL with the return temperature TO flows in. The heating fluid is changed to one in the heating heat exchanger higher flow temperature T10 heats up and leaves the heat exchanger a flow line VL. At the same time, the refrigerant in the counterflow Capacitor to a low temperature T1, which is approximately equal to T0, cooled and liquefied.

The liquefied refrigerant under high pressure is an expansion valve EV fed and evaporated there by depressurization. The refrigerant cools strongly from, for example to a temperature T4 of -5 ° C, and flows through the evaporator KD via the source heat exchanger is thermally coupled to the collector system of the heat source. The Heat transfer medium of the collector system, for example a brine, flows through the Source heat exchanger in counterflow to the flow of the evaporated refrigerant and is determined by the source temperature T6, which is, for example, approx. 0 ° C amount, cooled to a lower temperature T5, which is approximately equal to T4. In return, the gaseous refrigerant is upgraded to a higher one Output temperature T7 heated, which is approximately equal to T6. The gaseous Refrigerant, which is under low pressure, becomes the again Refrigerant compressor KV supplied and compressed and heated there.

The compressor KV is like a drive motor AM after Reciprocating principle constructed and has at least one moving compressor HKV piston in a refrigerant compression chamber W. The Drive motor AM has at least one in an engine compression chamber  VM moving engine reciprocating piston HKM. The compression spaces W des The refrigerant compressor and VM of the drive motor are in one Carrier block MB trained. The movements of the HKV piston The compressor and HKM of the drive motor are common undivided crankshaft KW coupled. The movement of the piston from Drive on the one hand and compressor on the other hand is preferably carried out opposite phase. The piston arrangement is preferably in the so-called boxing position executed.

The compressor and drive advantageously have a common cooling system KS with a uniform input connection KE and output connection KA. The cooling system is preferred with the cooled and liquefied Refrigerant is fed from the refrigerant condenser, which is thereby on a higher temperature T2 of, for example, between 20 ° C and 60 ° C heated becomes. The heated, high-pressure refrigerant is removed from the Cooling system output connection to a refrigerant heat exchanger WTK fed, on the other hand from the heated in the evaporator, but on low temperature T7 of, for example, approx. 0 ° C gaseous Refrigerant flows through at low pressure. In the refrigerant heat exchanger WTK will also use the high-pressure refrigerant on one temperature T4 further reduced compared to T1 in front of the expansion valve EV cooled and at the same time the gaseous refrigerant before being sucked into the Compressor preheated to a higher temperature T8.

The drive motor is fuel KR from a reservoir VB in over one controllable regulating valve RV fed variable amount. Abgase AG of the drive motor are advantageously a further heat sink, in particular via an exhaust gas cooler AK, a hot water tank SP supplied from which hot water consumers WV are fed. Through the  low temperature of a cold water inlet KW of the store SP can in addition to cooling the exhaust gas, the heat of condensation of im Water vapor containing exhaust gas can be obtained as heating energy.

The features indicated above and in the claims are both can be realized individually as well as in various combinations. The The invention is not limited to the exemplary embodiments described, but in various ways within the framework of professional skill changeable. In particular, other forms of drive such as Rotary piston motors can be used. The exhaust heat can be anywhere a heating or process water system can be used by exhaust gas cooling.

Claims (15)

1. Heat pump arrangement with a compressor for gaseous refrigerant and a drive for the compressor, characterized in that the drive is an internal combustion engine, that moving compression devices of the drive and compressor are designed according to the same type of movement and that the movements of compression devices of the compressor and drive via a common undivided mediation means are coupled. 2. Arrangement according to claim 1, characterized in that the Compression areas of drive and compressor in one Carrier block are formed. 3. Arrangement according to claim 2, characterized in that drive and Compressors are designed as reciprocating piston devices. 4. Arrangement according to one of claims 1 to 3, characterized in that that drive and compressor over an undivided common crankshaft are connected. 5. Arrangement according to one of claims 1 to 4, characterized in that the drive can be controlled at variable speeds. 6. Arrangement in particular according to one of claims 1 to 5, characterized characterized in that the internal combustion engine for fuel renewable raw materials.   7. Arrangement according to one of claims 1 to 6, characterized in that the internal combustion engine is a diesel engine. 8. Arrangement according to one of claims 1-7, characterized in that the internal combustion engine is designed as an all-substance engine. 9. Arrangement according to one of claims 1 to 8, characterized by a common cooling system for drive and compressor. 10. Arrangement according to one of claims 1 to 9, characterized in that suction side refrigerant for cooling the drive and compressor is inserted. 11. The arrangement according to claim 10, characterized in that refrigerant from the cooling system outlet to the evaporator expansion valve is supplied and the line section between the cooling system and Expansion valve via a refrigerant heat exchanger arrangement in There is thermal contact with the refrigerant supply to the compression room of the compressor. 12. Heating system with a heat pump arrangement according to one of the Claims 1 to 11, characterized in that the exhaust gases from the Internal combustion engine passed through an exhaust gas heat exchanger arrangement are. 13. Heating system with a heat pump arrangement according to one of the Claims 1 to 11 or according to claim 12, characterized in that a ground collector is connected as a heat source.   14. Heating system with a heat pump arrangement according to one of the Claims 1 to 11 or according to claim 12 or 13, characterized through monovalent heat pump operation. 15. Heating system with a heat pump arrangement according to one of the Claims 1 to 11 or according to one of claims 12 to 14, characterized by the switchable operating mode as a cooling system with the collector as a heat sink.