The present disclosure relates to a tumble dryer comprising a housing, a rotatable drum in the housing being accessible from a front side of the housing, a fan arrangement for producing a flow of process air passing through the drum, and a heat pump for drying the process air before entering the drum, wherein the heat pump comprises a condenser, a compressor, and an evaporator.
Such a tumble dryer is shown for instance in EP-3118365-A1, describing a tumble dryer with a heat pump. Although such tumble dryers are usually more energy efficient than tumble dryers with simple electric heating elements that recirculate less of the heat energy of process air leaving the drum, one problem with such tumble dryers is how to improve their energy efficiency further.
One object of the present disclosure is therefore to provide a tumble dryer with improved energy efficiency. This object is achieved by means of a tumble dryer as defined in claim 1. More specifically, in a tumble dryer of the initially mentioned kind, the compressor is located in the flow of process air, between the evaporator and the condenser. This means that heat dissipated by the compressor and the motor driving the compressor will contribute with heating the relatively cold process air leaving the evaporator. This improves the energy efficiency of the tumble dryer even further, and at the same time accomplishes efficient forced cooling of the compressor and the associated motor.
The condenser may be located behind the tumble dryer drum as seen from the housing front side, and above the compressor. This makes good use of the available space in the tumble dryer housing.
The condenser may be carried by a support arrangement forming a common frame which takes up the load of the condenser on either or both sides of the compressor as seen from the housing front side. This means that the load of the condenser need not be taken up by the tumble dryer housing behind the drum, which facilitates providing the heat pump as a separate, replaceable unit. The support arrangement may comprise a top frame carried by a plurality of legs, and the compressor may be located in between the legs. The condenser may be supported by a top frame supporting the condenser at the edges of the condenser bottom surface, such that process air may pass through said bottom surface at inner parts thereof.
The evaporator may be located in front of the compressor as seen from the housing front side, such that it can reach into the space under the tumble dryer drum which may not be completely occupied by fan arrangements and the like.
The evaporator, the compressor and the condenser may be arranged as components making up a heat pump unit, which may be removed from the tumble dryer without separating the components from each other. The heat pump unit may form a complete closed refrigerant loop and further include an expansion valve.
The components of the heat pump unit may be enclosed in an insulating shell, for instance made of expanded polypropylene, EPP. The shell may comprise an air inlet and an air outlet, as well as a drain tube for leading water out of the shell.
The present disclosure relates generally to a tumble dryer which is provided with a heat pump in order to achieve energy-efficient drying of laundry. An example of a tumble dryer 1 is illustrated in
In a heat pump tumble dryer, process air drying the laundry can circulate within the outer enclosure of the tumble dryer.
The tumble dryer includes a heat pump arrangement with an evaporator 15, a compressor 17, a condenser 19, and an expansion valve 16 (cf.
As illustrated in
The process air flow 21, which is now cooler and contains less water, is passed to the rear section of the tumble dryer and subsequently passes the condenser 19, which heats the air again. Then the heated, dry air is reintroduced into the drum 11 where it is again capable of absorbing water from the laundry therein.
In the tumble dryer of the present disclosure, the compressor 17 is located in the flow of process air 21, between the evaporator 15 and the condenser 19. This means that heat dissipated from the compressor, which heat would otherwise become more or less wasted, is used to pre-heat the flow of process air 21 before it reaches the condenser 19. At the same time, the compressor 17 becomes cooled by the process air flow 21, which to a great extent renders other cooling arrangements, used to avoid overheating of the compressor 17, unnecessary. This allows for a more energy efficient tumble dryer 1, that can be produced at a lower cost.
As shown in
The condenser 19 is carried by a support arrangement 25, 27 of this framework. The support arrangement may comprise a top frame 25 on which the condenser 19 rests. This top frame 25 may be rectangular to carry the condenser 19 at the outer edges of the condenser bottom surface, but may provide a large opening at the inner parts of this bottom surface to allow process air to flow through the condenser to be heated. The top frame 25 may be supported by a plurality of legs 27, in the illustrated case four legs 27, each located at a corner of the top frame 25. The compressor 17 may be located in between the legs 27, and the legs may be attached to a bottom frame 29. The condenser 19 is supported by the top frame 25 at the edges of the condenser bottom surface, such that process air may pass through this bottom surface 24 at inner parts thereof, as shown in
The framework may be produced as sheet metal parts, such as aluminum or steel. Other framework configurations are possible. In order to allow the heat pump to be provided as a unit that can be installed or removed as a whole, it is preferred to provide a framework which takes up the load of the condenser 19 on either or both sides of the compressor 17 as seen from the housing front side 3, rather than for instance letting the condenser be suspended from an inner wall in the tumble dryer.
It is advantageous to keep the heat pump as a unit where the evaporator 15, the compressor 17 and the condenser 19 are included as components together with an expansion valve, and where the unit may be removed from or mounted in the tumble dryer without separating the components from each other, and instead handling them as a whole unit. The closed refrigerant medium loop in the heat pump is preferably filled and sealed in a central location, before being assembled in the tumble dryer. This also makes it simpler to replace a heat pump in an existing tumble dryer in the field. It is even possible to replace e.g. a gas heating unit in an existing tumble dryer with a heat pump.
The provision of the heat pump as a complete unit also makes it possible to enclose the heat pump as a whole in an insulating shell 23 as shown in
The heat pump unit together with the insulating shell 23 may be provided with wheels 41 that facilitate moving the heat pump unit on a floor, for instance when replacing a heat pump unit in the field.
As shown in
The present disclosure is not restricted to the above-described embodiment, and may be varied and altered in different ways within the scope of the appended claims.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/070161 | 8/9/2017 | WO | 00 |