DE102004052638A1 - Solar heat pump for heating e.g. walls during winter has heat pump pipe, which is corrosion resistant whereby heat pump pipe and solar pipe are connected, by pipe joint and rain water nozzle is fastened with heat transfer grid - Google Patents

Abstract

The solar heat pump has a heat pump pipe (2), which is corrosion resistant. The heat pump pipe and solar pipe (1) are connected by pipe joint (10). The rainwater nozzle is fastened with the heat transfer grid. It is installed in the building structure (5) or in the pipe trench (6) and over the assembly pit with the solar cycle. The heat pump cycle and the rainwater extraction device (19) and the rainwater intake box are connected by rainwater pressure pipe. The moisture meter and temperature sensor is equipped with control unit.

Description

For the heat extraction (Anergy) in heat pumps are the usual today Flächenerdkollektoren Made of plastic pipes laid approx. 1.20 m deep. To the Heat extraction over the Ensure throughout the winter months to be able to is the double earth surface across from required to be heated living room floor areas.

at Today's compact design, the available Soil areas mostly do not look to the heat supply (Anergy) of heat pumps for building heating to make sure.

There no additional heat sources in the winter months exist, falls the temperature in the heat pump anergy circuit below -5 ° C, so the capacity figure drops to 2-3 at the end of the heating season. Larger soil movements and large quantities stone-free soil material must be procured so that the economics of a geothermal heat pump system in most cases is not given.

 function Description

The solar heat pump soil double-tube heat and cold storage S consists of a double pipe system wherein the outer heat pump cycle pipe ( 2 ) and the inner solar circuit pipe ( 1 ) over the connection ( 10 ) with the inner transfer surfaces for the heat pump cycle ( 2 ) and the solar circuit ( 1 ) for temperature compensation and with the rainwater nozzle tube ( 3 ) on the heat transfer grid ( 4 ) is connected to a unit and into the building pit ( 5 ) or in a separate trench ( 6 ) and built with the solar cycle ( 8th ) and the heat pump cycle ( 9 ) and the rainwater pressure line ( 41 ) is used for heat absorption or heat output for heating and cooling purposes via a heat pump.

By the merge of solar, earth, rainwater heat and humidification to the storage unit S is a permanent mix of solar, earth, Rainwater heat given to smallest storage masses S.

By the continuous merger of sun, earth and rain water 1 In about half of the otherwise normal soil surface is required.

The solar heat pump soil-double-tube heat and cooling storage S mentioned in claim 2 is the separate pipe circuit for the heat pump ( 11 ) and the solar circuit pipe ( 12 ) as well as the rainwater nozzle tube ( 3 ). These are equipped with corrosion-resistant heat transfer plates ( 4.1 ) with and without profiled injection by stainless steel screws connected to a prefabricated heat transfer unit. These are as in claim 1 in the building pit ( 5 ) or in the trench ( 6 ) and filled with water-permeable, stone-free soil to the storage unit S.

In claim 3 is a double pipe system as in claim 2, but here are pulled apart tube bundles for the solar cycle ( 12 ) and the heat pump cycle tube bundle ( 11 ) with the rain pipe nozzle tube ( 3 ) on a common heat transfer mat ( 4 ) and in the building pit ( 5 ) or in the trench ( 6 ) and filled with water-permeable stone-free soil to the storage unit S.

In the 4 is the heat pump circulation pipe ( 11 ) and the solar circuit pipe ( 12 ) as well as dda rainwater nozzle pipe ( 3 ) are introduced into a wellbore and filled with heat transfer material.

In the 5 be the heat pump cycle pipe ( 11 ) and the solar circuit pipe ( 12 ) and the rainwater nozzle pipe inserted into a tube sleeve shot into the ground and potted with heat transfer material.

The 6 includes the side by side laying of the heat pump cycle pipe ( 11 ) and the solar circuit pipe ( 12 ) in a soil collector. For humidification, the rainwater nozzle tube ( 3 ) and filled with stone-free soil.

Under 7 Prefabricated two-chamber and three-chamber pipe systems are provided which are installed in a building 5 ) or in a surface collector can be laid. In the three-chamber piping system, it is possible to cool rainwater collected in a reservoir in the circulation system and to extract the heat.

In order to be able to use the solar heat pump soil double-tube heat and cooling tank S sensibly, in a reversible heat pump ( 22 ) 8th , a heating operation in winter and a cooling operation in summer for the building system ( 35 ).

In heating mode, the reversible heat pump ( 22 ) the heat from the solar heat pump soil double-tube heat and cold storage S via the circulation pump ( 27 ) used as anergy source. With the circulating pump ( 28 ), the feed water of the heat pump ( 22 ) via the solar heat exchanger ( 23 ) and over the Überströmmischzylinder ( 13 ) to the three-way mixing valve ( 32 ), the circulation pump ( 34 ) to the consumer ( 35 ) and back over the Überströmmischzylinder ( 13 ) and the engine door ( 31 ) led to the return of the heat pump.

In cooling mode, via the circulating pump ( 27 ) heated the solar heat pump soil double-tube heat and cold storage S for winter operation, so that the heat stored there in winter as a heating source is available. Due to the evaporator-capacitor switching, the refrigeration cycle is controlled by the circulating pump ( 29 ) the Überströmmischzylinder ( 13 ) to the cold consumer ( 35 ) and via the circulating pump ( 33 ) the three-way valve ( 32 ), the non-operating heat exchanger ( 23 ) and the engine throttle ( 30 ) led to the return of the heat pump.

The solar heat from the collector ( 25 ) is depending on the sunlight via the circulation pump ( 26 ) for hot water preparation via the engine throttle valve ( 14 ), for reheating heating via the engine flap ( 15 ) and the heat exchanger ( 23 ) and for heating the solar heat pump soil-double tube heat and cold storage S on the engine door ( 16 ) up to + 10 ° C brine temperature exploited.

About the rainwater nozzle tube ( 3 ) which via the rainwater inlet box ( 17 ) and the rainwater sampling device ( 19 ) with the rainwater pressure line ( 41 ), the solar heat pump soil double tube heat and cold storage S via the humidity sensor ( 18 ) moistened for good temperature transfer.

The 9 includes the use of a commercial heat pump ( 21 ) with the requisite circulating pumps, engine flaps and heat exchangers including overflow ( 13 ).

When installing a commercially available heat pump ( 21 ) 9 , the solar heat pump soil double-tube heat and cold storage S as in 8th in summer via the circulation pump ( 28 ), the engine door ( 45 ) and the heat exchanger ( 42 ) are used for heat pump heat dissipation with simultaneous heating of the solar heat pump soil double-tube heat and cooling tank S. At the evaporator of the heat pump ( 21 ) is the cold on the circulation pump ( 27 ) and the engine door ( 48 ), the heat exchanger ( 23 ) via the circulating pump ( 36 ), the engine door ( 37 ), the Überströmmischzylinder ( 13 ) to the cold consumer ( 35 ) and via the circulating pump ( 33 ), the three-way valve ( 32 ) over the mixing cylinder ( 13 ) back to the heat exchanger ( 23 ) guided.

The solar entry via the solar collectors ( 25 ) and the circulation pump ( 26 ) takes place as in 8th via the temperature difference control and the engine flaps ( 14 ) 15 ) and ( 16 ). The temperature is controlled by the necessary temperature sensors as well as by the memory S - sensor ( 40 ).

To Claim (9) are all parts such as circulation pumps, engine valves, heat exchangers in a tubular frame to a unit, including piping, with control and connection plug and connection fitting, prefabricated.

Claims (9)

Solar heat pump soil double pipe heat and cooling storage S (1) characterized in that the corrosion resistant heat pump cycle tube ( 2 ) and in the same a solar circuit pipe ( 1 ) via the pipe connection ( 10 ) and the rainwater nozzle tube ( 3 ) on the heat transfer grid ( 4 ) is prefabricated and in the building pit ( 5 ) or in the trench ( 6 ) and via the mounting shaft ( 7 ) with the solar cycle ( 8th ) and the heat pump cycle ( 9 ) and the rainwater sampling device ( 19 ) and the rainwater inlet box ( 17 ) via the rainwater pressure line ( 41 ) and filled with water-permeable, stone-free soil to a storage unit S and with the humidity sensor ( 18 ) and the temperature sensor ( 40 ) is equipped with control unit. Solar heat pump soil double pipe heat and cooling storage S (2) according to claim (1), characterized in that the separate heat pump cycle tube ( 11 ) and the solar circuit pipe ( 12 ) and the rainwater nozzle tube ( 3 ) between 2 st corrosion-resistant heat transfer plates ( 4.1 ) with or without profile impressions, with stainless steel screws is connected to a prefabricated unit in a contact-tight manner and in the building pit ( 5 ) or in the trench ( 6 ) vertically or horizontally mounted on larger surfaces and to the heat pump circuit ( 9 ) and the solar circuit ( 8th ) as well as the rainwater extraction line ( 41 ) and the rainwater collection device with filter ( 19 ) (8th) connected and filled with water-permeable, stone-free soil S is filled. Solar heat pump soil double pipe heating and cooling storage 3 according to claim (2) but from exploded tube bundles for the solar circuit ( 12 ) and pulled apart heat pump circuit tube bundles ( 11 ) together with the rain nozzle tube ( 3 ) on the heat transfer mat ( 4 ) as a complete prefabricated double-pipe combination system into the excavation ( 5 ) or in the trench ( 6 ) mounted vertically or horizontally and to the heat pump circuit ( 9 ) and the solar circuit ( 8th ) and to the rain pipe circuit ( 41 ) connected. Solar heat pump soil double pipe heating and cooling storage 4 according to claim (2) or (3), however, that the solar circuit pipe ( 12 ) and the heat pump cycle pipe ( 11 ) and the rainwater nozzle tube ( 3 ) is laid vertically in a wellbore or the solar heat pump soil double tube, 5 , the solar circuit tube ( 12 ) and the heat pump cycle pipe ( 11 ) as well as the rainwater nozzle tube ( 3 ) pushed into a star-shaped injected into the soil casings and filled with a heat transfer material and the connection shaft ( 7 ) to the heat pump circuit ( 9 ) and the solar circuit ( 8th ) connected. Solar heat pump soil double pipe heating and cooling storage 6 according to claim (2), (3) and 4, but in the surface-ground collector, the heat pump cycle pipe ( 11 ) and the solar circuit pipe ( 12 ) parallel to each other in a horizontal arrangement and laid in about 1.2 m depth and above the rainwater nozzle tube ( 3 ) laid in about 1.0 m depth and the entire earth collector S is filled with stone-free soil. Solar heat pump soil double pipe heating and cooling storage 7 according to claim (2), (3), (4) and (5), but in a juxtaposed machined double tube for the solar cycle ( 12 ) and the heat pump cycle ( 11 ) in round or square shape or as a triple tube for the solar circuit ( 12 ), the heat pump cycle ( 11 ) and the rainwater circle ( 3.1 ) in the building pit ( 5 ) or in the tube shaft ( 6 ), or in-ground surface collector (S) is laid and to the solar circuit ( 9 ), the heat pump cycle ( 8th ) and the rainwater pipe ( 41 ) connected. Solar heat pump soil double pipe heat and cooling storage, 8th , according to claim (1), (2), (3), (4), (5) and (6) and the individual circuits to the reversible heat pump ( 22 ) are connected. About the circulation pump ( 27 ) is the heat pump ( 22 ) via the connecting cable ( 9 ) Connected to the solar heat pump soil-double tube heat and cold storage S and this works in cooling mode for waste heat emission and heating to heat absorption. Via the connecting cable ( 8th ) is the solar heat pump soil double-tube heat and cold storage S with the solar panels ( 25 ) of the circulation pump ( 26 ) and the engine door ( 16 ) and the engine door ( 14 ), with the water heater ( 24 ) and the engine door ( 15 ) with the heat exchanger ( 23 ) connected. For heating operation, the heat pump flow ( 22 ) via the circulating pump ( 28 ), the heat exchanger ( 23 ) and the mixing overflow cylinder ( 13 ) with the engine three-way valve ( 32 ) of the heating circulation pump ( 34 ) with the building pipe system ( 35 ) via the multipurpose supercharger cylinder ( 13 ) and the engine door ( 31 ) connected to the return of the heat pumps. For cooling operation, the heat pump flow ( 22 ) via the circulating pump ( 29 ), the Überströmmischzylinder ( 13 ) to the building ear system ( 35 ) for circulation reversal and via the circulating pump ( 33 ), the engine three-way valve ( 32 ) via the Mischüberströmzylinder ( 13 ) the heat exchanger ( 23 ) and the engine door ( 30 ) with the return of the heat pump ( 22 ) connected via pipeline. Solar heat pump soil double pipe heat and cooling storage S, 9 , according to claim (1), (2), (3), (4), (5) and (6), characterized in that with a commercial heat pump ( 21 ) is converted from heat to cold operation via an automatic control system. In heating mode, the solar heat pump soil double-tube heat and cooling tank S via the circulating pump ( 27 ), the engine door ( 47 ) and ( 46 ) for heat absorption and via the circulating pump ( 28 ), the engine door ( 38 ) and ( 39 ) with the return, via the heat exchanger ( 23 ), the Überströmmischzylinder ( 13 ), the three-way motor mixer ( 32 ), the circulation pump ( 34 ) to the building system ( 35 ) in the flow and over the Überströmmischzylinder ( 13 ), the engine door ( 39 ) with the heat pump ( 21 ) connected. In cooling mode, the solar heat pump soil double-tube heat and cold storage S for heat transfer through the circulation pump ( 28 ), the engine flaps ( 43 ) and ( 45 ) and the circulation pump ( 44 ) and the heat exchanger ( 42 ) with the heat pump ( 21 ) and the circulating pump ( 27 ), the engine door ( 48 ) with the heat exchanger ( 23 ) via the circulating pump ( 36 ) and the engine door ( 37 ) the Überströmmischzylinder ( 13 ) with the building system ( 35 ) via the circulating pump ( 33 ) in the circuit reversal via the piping system with the three-way valve ( 32 ), to the heat exchanger ( 23 ). Solar heat pump soil double pipe heat and cooling storage, 8th and 9 , according to claim (1), (2), (3), (4), (5), (6), (7) and (8) characterized in that the 9 or 8th Designated equipment in a tubular frame including the complete piping and the required control parts are mounted as well as electrical connection plugs and all necessary compression fittings are prefabricated.