NL1015308C1 - Underfloor heating and cooling system for building, uses geothermal heat pump techniques to extract heat energy from ground around foundation piles - Google Patents

Abstract

The system uses geothermal heat pump techniques which exploit the temperature difference between the soil and the air outside the building (3). Heat exchanges are associated with the foundation piles (4) of the building (2). Pumps and heat exchangers are used to heat or cool a medium which flows through underfloor pipes (30) in an underfloor temperature control system (40).

Description

Heating / cooling system for a building.

The present invention relates to a heating / cooling system for a building, comprising heating / cooling bodies 5 arranged in the building, connected via an inner pipe system to a heat exchanger part of a heat pump, which heat pump is on the other hand provided with a pipe system extending in the ground connected to a number of heat exchangers for extracting / releasing heat from the ground.

Such a system is generally known in the prior art. By using heat pumps it is possible to upgrade heat from the ground (relative to the outside air) to heat that is suitable for heating purposes.

It is also known to cool buildings in the summer months using relatively cool medium from the soil. To date, 15 such systems have been used mainly in relatively large buildings where the costs of complex installations outweigh the reduction in energy consumption. Complex, special parts were used for such installations.

The object of the present invention is to considerably simplify the construction of a heating / cooling system and to enable the use of existing parts used in large series. More particularly, the use of the heat pump is, of course, aimed at using standard components which are currently well known in the market.

This object is achieved in a heating / cooling system 25 described above in that the bottom pipe system in the circulation direction of the heating / cooling medium upstream of that heat pump is provided with a heat exchanger, which is on the other hand connected to the inner pipe system, in which valves are arranged in the inner pipe system. bringing the medium circulating therein into contact with either that heat exchanger or that heat exchanger part of said heat pump.

A special simplification can be obtained by placing the heat exchanger which is arranged upstream of the building for cooling purposes upstream. Using the shut-off valves, the 1015308 2 heat / cold transfer medium can be passed either through the heat exchanger for cooling or through the heat pump's heat exchanger. According to an advantageous embodiment of the invention, the heating / cooling bodies comprise a pipe network arranged in the floor, wall or ceiling of the building 5. This means that a relatively large heating surface is present, so that the temperature increase in relation to the desired room temperature in the building can remain relatively limited. This can be further promoted by optimal insulation of the building. Therefore, it is possible to limit the temperature of such a pipe network 10 to about 28 ° C.

In such an embodiment it may be desirable to control the temperature in different rooms or floors separately. In such a case, each heat exchanger or group of heat exchangers per floor or the like can be controlled by means of a thermostat-controlled shut-off valve, ie the supply of heating / cooling medium to the respective heat exchanger can be controlled.

According to a further advantageous embodiment of the invention, a thermostat-controlled valve is present in the pipe network of the heat exchanger in order to prevent temperatures that are too low therein. This prevents condensation in particular.

According to a further advantageous embodiment of the invention, constant circulation of medium takes place in the pipe network of the heat exchanger and more heat or cold is supplied through the inner pipe system in a dosed manner depending on the need.

Further optimization of the energy consumption can be achieved if the air ventilation system of the building system is arranged in such a way that not only air is extracted mechanically but also mechanically supplied.

It has been found that the air flow can thereby be accurately controlled, so that during normal occupancy of a building, in particular only about 0.4 x the content of the building per hour need to be ventilated. As a result, losses can be further limited.

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The invention will be explained in more detail below with reference to an exemplary embodiment schematically shown in the drawing.

The only figure shows very schematically the heating / cooling system according to the present invention.

In the only figure, the heating / cooling system according to the invention is indicated in its entirety by I. Dashed lines indicate the separation between what is inside a building 2 and what is outside. The latter is indicated by 3.

In this example, the building in question stands on a number of piles 4. These 10 piles 4 have considerable length and are provided with a number of pipes 8 which extend over the entire length of the piles concerned and near the lower end thereof in the heat-exchanging contact with the groundwater located there. As an example, such piles are about 16 meters long and have a cross-sectional dimension (square) of 30 x 30 cm. The pipes 15 in question have an internal diameter of 16 mm. and are flowed through with a heat exchanging medium at 20 cm / s. Preferably, water with additives is used for the heat exchanging medium to avoid freezing. The distance from the heat exchanging piles is important. After all, if this distance is too small, insufficient heat can be extracted from the soil. According to the present invention, the distance from the posts is preferably 3-5 meters and more particularly about 4 meters.

The various posts 4 are connected by means of pipes 5 and 6 indicates a supply pipe and 7 a return pipe to and from a heat pump 12. Circulation of the medium is achieved with the aid of pump 9. A (plate) heat exchanger 20 is arranged in the circulation direction upstream of heat pump 12. This serves for possible cooling of the medium that flows into the inner pipe system.

The line between heat exchanger 20 and heat pump 12 is indicated by 11.

The inner pipe system consists of a supply line 16 and a return line 30 17. Supply line 16 can be connected to heat exchanger 20 via valve 18. Supply valve 16 can be connected to heat pump 12 via valve 19. All this is controlled by a central control 13. This is inter alia connected to a temperature sensor 14, which can for instance be arranged on the roof of the building. Depending on the outside temperature, it is determined whether there is a need for heating the building, cooling or neither.

The supply line 16 or return line 17 can be connected to one or more heat exchangers for delivering heat or cold, respectively.

In the example given here, only the connection to an underfloor heating 40 is shown. It will be understood that in practice several such heat exchangers will be present. In the inner pipe system consisting of the pipes 16 and 17, the medium is also circulated by pump 15.

Underfloor heating 40 consists of a number of heating bodies 30 which are coupled together. Such a system has a relatively high resistance and therefore a separate pump 22 is provided. The supply line of such a network is indicated by 21 while the return line is indicated by 23. In principle, the pipes 21 and 23 form a closed chain and a valve 29 is provided which determines the flow of this closed chain. This is controlled by means of auxiliary control 24. A valve 28 is present which can completely block the supply of medium from line 16 to line 21. However, the amount of heat or cold transferred from line 16 to line 21 is determined by the thermostatically operated control valve 29. Valve 28 is modulated by means of auxiliary control 24. Auxiliary control 24 is controlled by means of a heat sensor 25 located in the relevant room.

A control valve 26 is provided which maximizes the supply of heat / cold from line 16. This is particularly important if different heat exchanging bodies 40 are connected.

In the building shown schematically here, a ventilation system (not shown in more detail) is also present. Both the incoming and outgoing air are moved mechanically and in this way refreshment can suffice with 0.4 x the content of the building per hour. Obviously, the incoming air is heated with the outgoing air, i.e. no heated air enters the environment.

It has been found that considerable energy savings can be obtained with such a system. Moreover, such a system is constructed in such a simple manner and with standard components that it can also be used in relatively small buildings.

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Those skilled in the art will immediately see variants after reading the above description which variants are obvious and within the scope of the appended claims.

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Claims (7)

A heating / cooling system (1) for a building (2), comprising heating / cooling bodies (30) arranged in building 5 connected via an inner pipe system to a heat exchanger part of a heat pump (12), which heat pump is on the other hand provided with a the bottom piping system connected to a number of heat exchangers (8) for extracting / releasing heat from the bottom, characterized in that the bottom piping system is provided in the circulation direction of the heating / cooling medium upstream of said heat pump (12). heat exchanger (20), which is on the other hand connected to the inner pipe system, wherein in the inner pipe system valves (18, 19) are arranged, which bring the medium circulating therein into contact with either that heat exchanger (20) or that heat exchanger part of that heat pump. Heating / cooling system according to claim 1, wherein said heating / cooling bodies comprise a pipe network arranged in the floor, wall or ceiling of the building. Heating / cooling system according to one of the preceding claims, wherein a thermostat-controlled valve (28) is arranged between said pipe network and said inner pipe system. Heating / cooling system according to claim 3, wherein said thermostat-controlled valve (28) is designed to determine the lowest temperature in said pipe network during cooling. A heating / cooling system according to any one of the preceding claims in combination with claim 2, wherein said pipe network comprises a closed circuit comprising a pump (22) with supply and discharge connections for connection to said inner pipe system, a supply and discharge connection being provided between said supply and discharge connection. the ratio between fed / discharged and recirculating medium regulating thermostatically operated valve (29) is provided. FI015308 i A heating / cooling system according to any one of the preceding claims, comprising an air exchange system in which both the introduced and exhausted amount of air is determined mechanically. 7. Heating / cooling system according to claim 6, wherein 0.4 x the content of that building is refreshed per hour. 101 5308