SE531216C2 - Heating system, heat pump and heater - Google Patents

Description

531 216 2 re-examination of the cycle. Common heat transfer media are halogenated hydrocarbons, such as Freon®.

Since the heat pump principle is generally known, the above summary account of this should be sufficient in this context.

When a building is heated by an air-to-air heat pump, it is normal for the heat-emitting medium to consist of the outdoor air. This has the advantage that it is available in unlimited quantities but the disadvantage that it is relatively cold, especially during the periods when the need for heating is greatest, ie, during the winter months and during nights.

It is also known that the heat-emitting medium is the building's exhaust air.

It has the advantage that the energy in this relatively warm air is recovered. The disadvantage is that it is not sufficient for the heating demand, which is why the heating demand must be supplemented with additional heating units, e.g. wood or fossil-fired boiler, immersion heater or another heat pump. This increases the investment costs for the system by requiring more than one unit. Against this background, the object of the present invention is to provide a heating system which utilizes the advantages of known systems but eliminates the disadvantages thereof.

Disclosure of the structure According to the first aspect of the invention, the stated object is achieved in that a heating system of the type stated in the preamble of claim 1 comprises the special features stated in the characterizing part of claim 1.

Because the heat pump utilizes both hot exhaust air and outdoor air, the energy contained in the exhaust air is recovered at the same time as the required volume is obtained by also utilizing the outdoor air. This provides optimal heating economy.

By doing this in a single unit, investment costs for the heating system are saved. All in all, this leads to a total economy for heating that is more favorable than what has been achieved so far. 10 20 25 531 215 3 A basic space of this kind utilized i.a. for the building's heating is described in SE 468 441. The building foundation described in the said patent is an invention that involves a radical innovation in terms of heating and other service needs of a building where a holistic perspective has created opportunities for an optimized construction economy. By supplying the air heated by the heat pump to such a basic space, a further improvement is achieved. The advantages of a heating system according to the present invention become particularly valuable when it is used in connection with a house foundation of the type specified in the said patent.

Another advantage that is gained is that you reduce the risk of freezing at the heat-absorbing side of the heat pump compared to a heat pump where only outdoor air is used.

According to a preferred embodiment of the invented heating system, all exhaust air is led from the exhaust air line to the heat-absorbing side of the heat pump and control means are arranged to regulate the amount of supplied outdoor air in dependence on the amount of supplied exhaust air.

This ensures that the energy in the exhaust air is fully utilized regardless of the size of the heating demand. When reduced air volume is required to meet the heating need, this design means that it is primarily the volume of outdoor air that is reduced while the exhaust air volume is fully utilized. Thus, an optimization of the heating is achieved independent of heating needs.

According to a further preferred embodiment, a heat exchanger is arranged to absorb heat from the exhaust air before it is supplied to the heat pump.

This can be advantageous as the exhaust air has a high moisture content. By lowering its temperature in the heat exchanger, the absolute moisture content of the exhaust air is reduced and thus the risk of condensation is reduced when it is supplied to the heat pump.

According to a further preferred embodiment, a mixing chamber is arranged for mixing exhaust air from the building and outdoor air, wherein the heat-absorbing side of the heat pump is arranged to receive the mixed air. The above-mentioned preferred embodiments of the invented heating system are set out in the claims dependent on claim 1.

The object set out is achieved from the second aspect of the invention in that a method of the kind stated in the preamble of claim 6 comprises the special measures specified in the characterizing part of the claim.

The invention is further elucidated by the following detailed description of advantageous embodiments thereof with reference to the accompanying figures.

Brief description of the figures Fig. 1 is a diagram illustrating an embodiment of a heating system according to the invention.

Fig. 2 is a schematic section through the lower part of a building provided with a heating system according to the invention.

Fig. 3 is a schematic view from above of the base part of the building in fig.

Fig. 4 is a diagram illustrating an alternative embodiment of a heating system according to the invention.

Fig. 5 is a schematic illustration of an alternative embodiment of the outdoor unit of the heat exchanger.

Fig. 1 is a schematic section through an example of a heating system according to the invention. The system comprises an air-to-air heat pump 1, 2 with an outdoor unit 1 which is the heat-absorbing side of the heat pump, i.e. its evaporator and an inner part 2 which is the heat dissipating side of the heat pump, i.e. its condenser. The air part 1 of the air pump is heated partly with outdoor air A, partly with exhaust air B which is led out to the outdoor part 1 via a pipeline 3, e.g. from a bathroom outlet valve 4. Optionally, a blow-out spout 5 can be arranged in the pipeline 3.

The heat carrier medium is led via a line 6 from the heat pump's outer part 1 to its inner part 2. The inner part 2 heats the outdoor air which is supplied via a pipeline 7 20 25 30 531 2'l6 5 and by means of a fl genuine 8. directly towards the inner part 2 of the heat exchanger. Thus, in principle, all incoming outdoor air will pass the inner part 2 and be heated by this before it is spread in the basic space 9. Heated air C is then delivered to the building's interior, in the example shown a basic space 9. heated by the inner part 2 of the heat pump, its relative moisture content is lowered so that condensation does not occur. The base space 9 is then secured against moisture and mold.

The building with its basic space is illustrated in fig. 2. The base space is insulated against the ground with an insulating layer 10 covered by a radon cloth 16 and enclosed by a so-called croft ground 11. The term floor closest to the ground floor is denoted by 12. Between the floor 12 and the walls 13 there is a circumferential gap 14. The floor 12 is heated by the warm hat on its underside. Hot air also flows up through the mentioned gap 14 and into the other rooms of the building to heat these.

At the same time, a fundamental overpressure occurs in that the air C which is supplied is throttled as it is passed on through the gap 14 between the floor 12 and the walls 13. This further prevents radon from penetrating into the ground space 9.

The velocity of the heated air through the gap 14 is a fraction of the air velocity that the air has in traditional ventilation systems in which the dirt, despite the high velocity, still settles to the bottom of the pipes. Due to the thus lower speed, the dirt is sedimented more efficiently. The purification of the air thus takes place by sedimentation instead of in a filter. The base radon cloth is easier to keep clean are spiral pipes with bends and bends. It is also not advisable to pass relatively clean air through a filter that starts to get dirty on day one.

I fi g. 3, the basic space described is illustrated in a view from above.

I fi g. 4 illustrates an alternative embodiment of the invented heating system. In this case, the exhaust air in the exhaust air line 3 is forced to pass a heat exchanger 15 before it is led on to the outside part of the heat pump. In the heat exchanger 15, the exhaust air is cooled by the supply air from the line 7. A fl shaft is arranged in the inlet of the exhaust air line 3 in the heat exchanger 15. The exhaust air line 7 is also 531 216 6 provided with a fl shaft 21 at the inlet in the heat exchanger 15. Both of these speed regulated. Otherwise, the system is structured as in fi g. 1.

The inner part 2 of the heat pump and the heat exchanger 15 are advantageously built together into a unit.

In the embodiment according to Fig. 5, the exhaust air B from the exhaust air line and the outdoor air A is led into a mixing chamber 18, which may be designed as a cover in connection with the heat pump's outdoor unit 1. The mixture of exhaust air and outdoor air is then introduced towards the outdoor section 1. 19 be arranged which streamlines the mixing before the air flow enters the outdoor unit 1. A damper 17 regulates the amount of supplied outdoor air A. The damper can be automatically controlled depending on the amount of incoming exhaust air B.

Claims (10)

20 25 30 53'l 215 NEW PATENT CLAIMS A heating system for heating a building, which system comprises a basic space (9) below the floor (12) of the building, which basic space (9) communicates via gaps (14) between the floor (12) and walls (13) with above the floor ( 12) located spaces characterized in that the system comprises an air-to-air heat pump (1, 2) with a heat-emitting side (2) located in said basic space (9) and with a heat-absorbing side (1) arranged to receive both exhaust air as heat-emitting medium (B) from the building and outdoor air 2. (A) and wherein an exhaust air line is arranged to direct exhaust air from the building to the heat-absorbing side of the heat pump (1). Heating system according to claim 1, characterized in that a line (7) is arranged for supplying outdoor air to the basic space (9), which line (9) is arranged to direct the outdoor air towards the heat-emitting side (2) of the heat pump for absorbing heat therefrom. . Heating system according to claim 2, characterized in that the heat-absorbing side (1) of the heat pump is arranged to receive all exhaust air (B) from the exhaust air line (3) and that control means (17) are arranged to control the amount of supplied outdoor air (A) depending on the amount supplied exhaust air (B). Heating system according to one of Claims 1 to 3, characterized in that a heat exchanger (15) is arranged to absorb heat from the exhaust air before it is supplied to the heat-absorbing side (1) of the heat pump. Heating system according to one of Claims 1 to 4, characterized in that a mixing chamber is arranged for mixing exhaust air (B) from the building and outdoor air (A) and in that the heat-absorbing side (1) of the heat pump is arranged to receive the mixed air. A method for heating a building, which building comprises a basic space (9) below the lower floor (12) of the building, which basic space (9) communicates via gaps (14) between the floor and walls (13) with 531 215 Spaces located above the floor (12), characterized in that the building is provided with an air-to-air heat pump (1, 2), with a heat-emitting side (2) arranged in said basic space and with a heat-absorbing side (1) to which exhaust air from the building and outdoor air, whereby an exhaust air line is arranged to direct exhaust air from the building to the heat-absorbing side of the heat pump (1). Method according to Claim 6, characterized in that outdoor air is supplied to the basic space and is directed towards the heat-emitting side (2) of the heat pump. Method according to claim 6 or 7, characterized by the amount of supplied outdoor air is regulated depending on the amount of supplied exhaust air. Method according to one of Claims 6 to 8, characterized in that a heat exchanger (15) is arranged to absorb heat from the exhaust air before it is supplied to the heat-absorbing side (1) of the heat pump. The exhaust air from the building is mixed with outdoor air in a mixing chamber, after which Method according to one of Claims 6 to 9, characterized in that the heat-absorbing side (1) of the air mixture is supplied to the heat pump.