SE433880B - VERMEPUMPANLEGGNING - Google Patents

Description

15 20 25 30 800lf0lf8-8 A heat pump system of the type mentioned in the introduction normally comprises a relatively large number of evaporators with associated channels. When defrosting, the fan in the relevant duct is closed. However, due to the air flow in adjacent ducts and / or wind conditions, a flow usually occurs, ie drafts of heat-emitting, but relatively cold gas, which make defrosting more difficult. Attempts have been made to eliminate this disadvantage, for example by providing the fans with dampers, ie flaps, which close over the fan surface when the fan is switched off, but this has not proved to be a really effective solution to the problem, and in addition an unnecessary cryekfaii is obtained.

According to the present invention, a heat pump system is provided, which allows a safe defrosting in a simple manner, and which in addition in a preferred embodiment provides good heat economy, in that a first opening is arranged between each overpressure chamber and the compressor chamber, so that in heat extraction from gas in a channel, in which the fan is running, a gas flow flows through the corresponding opening to the compressor chamber and from there on to the space between an evaporator which is under defrosting and its stationary fan, via the associated opening.

In a preferred embodiment of the invention, wherein it is provided with an intake chamber formed before the fan, seen in the direction of flow of the gas, a second opening is arranged between the compressor chamber and the intake chamber, so that a gas flow is enabled from the overpressure chamber through the compressor chamber, and the second opening to the intake chamber, bringing available heat to the compressor chamber.

In a further preferred embodiment of the heat pump system, the first openings are provided with valve means, which are arranged to allow only gas flow from the overpressure chamber to the compressor chamber, and at each evaporator a third opening is provided, provided with valve means, only allowing one gas flow through the compressor chamber gas flow paths, when the respective fan is switched off.

According to a further suitable embodiment, a vessel is arranged below the respective evaporator for collecting water leaving during defrosting, the third opening being arranged such that a gas flow is led through the vessel to the gas flow paths of the evaporator. 15 '20 .25 30 35 0-00110118-8 This has the advantage that drops falling from the evaporator cannot freeze to ice and possibly block the outlet. The invention will be described in more detail below with reference to the accompanying drawing, in which Figure 1 schematically shows a vertical section through a heat pump system according to the invention and Figure 2 shows a detail of the same with a suitable embodiment of the first and third openings. .

Figure 1 shows only one circuit, but it is understood that the heat pump system comprises a plurality of circuits with associated evaporators and corresponding fans. Such a circuit comprises a compressor 1, an evaporator 2, an expansion valve 3 and a condenser 4, all connected to a circuit by means of a line S. Heat is extracted from the condenser U through a circuit, of which only a part 6 is shown. The compressor 1 is arranged in a compressor chamber 7, on the outside of which a suction chamber 8 is mounted, which is terminated by a transverse wall 9, 1 in which a fan 10 is mounted. The fan opens into an overpressure chamber 11, in one end of which the evaporator 2 is mounted. After the evaporator, an exhaust shaft 12 is arranged. The overpressure chamber 11 is built in direct connection with the compressor chamber 7, and a first opening 13 is arranged between the overpressure chamber 11 and the compressor chamber 7. A second opening ïü is arranged between the suction chamber 8 and the compressor chamber 7.

The heat-emitting gas flows in a channel formed by the intake chamber 8, the overpressure chamber 11 and the exhaust shaft 12 and thereby passes through the gas flow paths of the evaporator 2, when the fan 10 is running. The gas is cooled and the extracted heat exits from the condenser 4 through the circuit 6. Heat emitting to the environment from the compressor 1 accompanies a gas flow from the overpressure chamber 11 through the first opening 13 in the direction of the arrow 15 to the compressor chamber 7 and further out through the second opening 14 to the suction chamber 8, where the heat in question is absorbed by the heat-emitting gas and thus is transferred to the evaporator 2 so that it is utilized.

When an evaporator is to be defrosted, gaseous, hot refrigerant is led into the evaporator through a system not shown in the figure, so that frost formed on its surface melts. In this case, the fan 10 is stationary, and a heated gas flow flows in the direction of the arrow 16 from the compressor chamber 7, to which gas flows from the overpressure chambers which are under overpressure by the respective fan being running, thus avoiding cold drafts through the evaporator 2. Figure 2 shows a detail of an improved heat pump system. Details corresponding to Figure 1 have the same reference numerals. The evaporator 2 is provided at the bottom with a vessel 17 for collecting water emerging during defrosting, which is diverted through a drain 18. In the vessel 17 a third opening 19 is arranged, to which leads a chamber 20, provided with a valve, or a damper 21 , which only allows a gas flow in the direction of the arrow 23, i.e. from the compressor space T, through the opening 19, the vessel 17 and up through the bottom 22 of the evaporator 2, further through its gas flow paths in the direction of the arrows 23 and PH. To the opening 13 between the compressor chamber 7 and the overpressure chamber 11 is connected a duct 25, which is provided with a valve means or a damper 26, which only allows a gas flow in the direction of the arrow 27, ie from the overpressure chamber 11 to the compressor chamber 7.

During heat absorption, when the fan 10, which is not shown in this figure, is running, the heat-emitting gas flows through the evaporator's external gas flow paths from the overpressure chamber 11 to the exhaust shaft 12. A gas flow also flows through the opening 13 and further through the damper 26 into 1 compressor. the room and further through the opening 1ü not shown in figure 2 in the same way as described in figure 1. The damper 21 is then closed.

When the evaporator 2 is defrosted, the fan 10 is closed, and a gas flow flows through the damper 21 through the vessel 17 in the direction of the arrows 23 and 2N, so that the evaporator 2 is surrounded by hot gas. Water drips into the vessel 17 and is prevented from freezing by the hot gas flowing through it. It may be appropriate to arrange flow-distributing articulated plates, indicated by the reference numeral 27, in the vessel 17 so that the gas coming from the compressor chamber 7 is suitably distributed at the evaporator 2.

Claims (3)

80040148-8 NW PATENT REQUIREMENTS A heat pump system having a number of closed circuits, each comprising a compressor (1), a condenser (Ä), an expansion valve (3) and an evaporator (2), a compressor being common to several such circuits, which contain refrigerant, and wherein at least the compressor (1) in each circuit is arranged in a compressor chamber (7) and each evaporator (2), provided with flow paths for a heat-emitting gas, is arranged to cool one in an associated duct (8). , 11) flowing such heat-emitting gas, a fan (10) being arranged in each channel before the respective evaporator (2) seen in the direction of flow of the gas, so that an overpressure chamber (11) is formed in each channel between the fan (10) and evaporator (2), characterized in that a first opening (13) is arranged between each overpressure chamber (11) and the compressor chamber (7), so that when heat is removed from the heat-emitting gas 1 a channel (8, 11) in which the fan (10) is running, a gas flow flows through a corresponding one opening (13) to the compressor chamber (7) in a circuit and from there on to the space between an evaporator (2) which is under defrosting and its stationary fan (10) in one of the other circuits via the associated opening (13). Heat pump system according to claim 1, with an intake chamber (8) formed before each fan (10) seen in the direction of flow of the gas, characterized in that a second opening (13) is arranged between compressor chambers (7). ) and its intake chamber (8), so that a gas flow is enabled from the overpressure chamber (11) through the compressor chamber (7) and the second opening (14) to the intake chamber (8), bringing available heat into the compressor chamber (7). Heat pump system according to claim 1 or 2, characterized in that the first openings (13) are provided with valve means (26), which are arranged to allow only gas flow from each overpressure chamber (11) to the compressor chamber (7), and that at each evaporator (2) a third opening (19) is provided, provided with valve means (21), only allowing a gas flow from the compressor chamber (7) through the flow paths of heat-emitting gas of the evaporator (2), when the respective fan (10) is off. Heat pump system according to claim 3, characterized in that a vessel (17) is arranged below the respective evaporator (2), for collecting water leaving defrosting, the third opening (19) being so arranged , that a gas flow is conducted through the vessel (17) to the flow paths of the heat-emitting gas of the evaporator (2).