DE19642164A1 - Laundry dryer - Google Patents

Abstract

A laundry dryer features a fan (7) which is located between the laundry drying space (1) and the evaporator (5) in the process air circuit. The suction side of the fan (7) succeeds the laundry drying space (1) while the evaporator (5) succeeds the pressure side of the fan.

Description

The invention relates to a tumble dryer a process air circuit, the laundry drying room, a Process air circulating fan and means for precipitating Has moisture from the process air stream, the Means for the precipitation of moisture as a heat pump circuit with an evaporator, a compressor, a condenser and a throttle are formed and the evaporator for Cool down the process sucked out of the laundry drying room air and the condenser to heat the previously cooled process air.

Such heat pump tumble dryers have become due their operational reliability and their high us proven in practice. The temperature difference between the process air cooled by the evaporator and the Process heated by the condenser to the set temperature air can be kept essentially constant, so that the heat pump is operated in an optimal performance range can be.

In known heat pump dryers of the beginning mentioned type (DE-OS 34 07 439 and 40 23 000) is the Ge blower arranged in the process air circuit behind the condenser and draws hot process air from the condenser. The Ge The blower is therefore exposed to the highest temperature loads. In the Ab between evaporator and condenser cut of the process air circuit creates a negative pressure, because the process air blower from the condenser section the evaporator. Due to the negative pressure, the Sam collecting and removing condensate in the bottom area of the ver steam room adversely affected.

The invention has for its object the heat pump pen tumble dryer so that its operational Properties are improved.  

Starting from a tumble dryer of the type mentioned ten kind is the solution of this problem according to the invention characterized in that the blower between the Laundry drying room and the evaporator in the process air circuit is ordered that the blower suction side dry the laundry space and the evaporator on the blower pressure side are.

These measures according to the invention lead to considerable operational advantages:
The space between the evaporator and the condenser is under a slight overpressure due to the accumulation effect of the condenser, so that the condensed water can flow off unhindered below the evaporator. The blower itself is no longer directly exposed to the process air heated up in the area of the condenser; instead, the blower draws in moist and less warm air from the laundry drying room. The lower operating temperature with otherwise the same process conditions favors the lifespan of the blower and thus the reliability of the heat pump washer dryer. Another advantage of the subject of the invention, in particular the relocation of the blower from the hot supply air duct into the section downstream of the laundry drying space, consists in the simpler design of the air duct between the condenser and the laundry drying space. In the drum-shaped laundry drying room, which is usually in the form of a drum, a vacuum is built up by the action of the downstream fan, which reduces the release of moist air into the environment. Low moisture air entering the drum improves the drying process.

In a preferred embodiment of the invention the blower is located in the door of the tumble dryer. This arrangement ensures a particularly compact and effective fan design. In further education of the Er The invention provides that the blower be used as radial veins tilator is formed and process air approximately axially from a sucks off the laundry drum serving as a laundry drying room. Before  preferably the process air flow in the interior of the door of the Tumble dryer deflected approximately radially to the drum axis.

According to a development of the invention, that a condensate pump on the suction side with the evaporator and on the pressure side with a device cooling the compressor is connected and that a condensate tank of the compressor Cooling device is arranged downstream, so that the condensate pump the condensed water via the compressor cooling device for Conveys condensate tank.

This training has the particular advantage that the already featured in tumble dryers of conventional design see condensate pump not only for removing the condensate sats, but in addition to cooling the compressor on permissible temperature level is made available. With that ent the additional cooling units that would otherwise be necessary especially an additional fan.

In a preferred development of this embodiment the compressor cooling device is a heat exchanger, in particular another, a cooling coil or rib, which is caused by the oil sump of the compressor.

The condensate pump can be used to optimize the cooling effect depending on the process air temperature controlled who the. This makes a particularly simple two-point control characterized in that the condensate pump depending on a temperature threshold in the process air circuit on and off is switchable.

Further advantageous developments of the invention are characterized in the subclaims.

In the following the invention is based on one in the Drawing shown embodiment compared to a conventional heat pump dryer explain tert. The drawing shows:

Fig. 1 is a schematic representation of the wesentli Chen components of a heat pump laundry dryer of conventional design; and

Fig. 2 shows a corresponding schematic representation of an embodiment of the invention.

The conventional heat pump dryer shown schematically in FIG. 1 contains a laundry drum 1 forming the laundry drying room and a process air duct closed via the laundry drum 1 , through which process air is conveyed in the direction of the arrows. The process air duct has a duct section 2 for heated dry air, a duct section 3 for the moist and somewhat cooler air leaving the drum 1 and a duct section 4 for the cool, dry air. The duct section 4 lies between an evaporator 5 , on the heat exchanger surfaces of which the moist, warm air from the duct section 3 is cooled, and a condenser 6 , the heat exchanger surfaces of which heat the dry and cool air from the duct section 4 to approximately the intended drying temperature. Between the condenser 6 and the laundry drum 1 , an electric motor-driven blower 7 is arranged, which extracts hot air from the condenser 6 and presses section 2 into the washing drum 1 through the channel. The process air flow indicated by the arrows arises.

The evaporator 5 and the condenser 6 are components of a heat pump circuit, which also include a compressor 8 and a throttle 9 . Training and function of these heat pump components are known; Also known is the influence of the evaporator or condenser as a cooling or heating unit on the process air flow.

Below the heat exchanger surfaces of the evaporator 5 , a collector 10 is arranged to collect the condensate deposited on the cool heat exchanger surfaces of the evaporator. The condensate collected is sucked off with the aid of a condensate pump 12 and conveyed to a condensate drain.

The process air circuit of the known clothes dryer shown in FIG. 1 is closed over the laundry drum 1 , but not free of leakage air flows. The resulting leakage air flows due to the design of the known dryer are shown mathematically by curved arrows A and Z, where A denotes exhaust air flows and Z supply air flows. (A louver assembly for controlling the air exchange between the process air circuit and the surrounding area, as is known from DE-OS 40 23 000 was does not Darge.) Due to the suction effect of which is arranged in the channel section 2 the fan 7 is formed in the inflow-side Ka nalabschnitten 2 a and 4 a negative pressure, so that from the surrounding air supply air Z can penetrate into the corresponding process air duct sections. The negative pressure, especially in the channel section 4 hinders the outflow of the formed on the Wärmetauschflä surfaces of the evaporator 5 and dripping condensate; because a portion of the condensate drops is sucked into the channel section 4 and only reaches the collector 10 via detours. In the drum 1 , the pressure side of the blower 7 corresponds to a positive pressure which leads to an unavoidable exhaust air flow of the heated and moist process air. The moist leakage currents A in the drum area lead to undesired formation of condensate in the vicinity of the dryer.

In contrast, in the heat pump tumble dryer according to the invention shown schematically in FIG. 2, the blower 7 is arranged in the channel section 3 , the Ge bläsesaugseite 7 a of the laundry drum 1 is immediately switched on and sucks moist, warm air out of the laundry drum 1 . The blower 7 generates a certain negative pressure on the suction side 7 a in the drum 1 , thereby preventing moist, warm air from the drum 1 from escaping into the ambient atmosphere of the clothes dryer. The channel section 3 , the evaporator 5 and the channel section 4 are pressurized via the pressure side 7 b of the blower. The condenser 6 develops a certain throttling effect and supports the build-up of excess pressure in the channel section 4 . This has the favorable effect that the condensate formed in the evaporator drips undisturbed into the collector 10 and can be removed from there via the condensate pump 12 .

As can be seen, the blower 7 does not take up any additional space since it is integrated in the tumble dryer door 11 . The fan is formed as a radial fan 7 , sucks process air approximately axially from the drum 1 and presses the moist and warm air through the pressure side 7 b approximately radially to the drum axis in the channel section 3rd The dry, hot air from the condenser 6 can be conveyed directly into the washing drum 1 without contact with moving parts. The channel formation and guidance along the rear wall of the dryer can thereby be simplified.

In the described embodiment according to Fig. 2, the condensate is not di conveyed by the condensate pump 12 rectly into the condensate flow, but also serves to cool the compressor. 8 For this purpose, the pressure side of the condensate pump 12 is connected via a line 13 to a cooling coil 15 or rib, which is guided through the oil sump of the compressor 8 . With the help of the condensate cooled in the evaporator, effective cooling of the oil sump of the compressor and thus of the compressor itself can be achieved in a very simple manner and without an additional drive.

The condensate pump is controllable in a preferred embodiment of the invention, depending on the temperature of the process air at any suitable point in the process air duct. A particularly simple way of controlling the condensate pump is a two-point control, in which the condensate pump is switched on and off as a function of reaching a temperature threshold in the process air circuit. If necessary. the condensate and coolant flow passed through the oil cooler via the cooling coil 15 can be interrupted and can be conducted directly into the condensate drain via a bypass 14 .

The tumble dryer arrangement explained with reference to FIG. 2 can have suitable supply air openings and associated flap arrangements, as are known from the gatings-forming documents mentioned at the beginning. There are also numerous modifications with regard to the formation of the components involved in the extraction of the condensate from the collector 10 and the condensate cooling of the compressor 8 . For example, the condensate pump 12 can be arranged in an old native design between the compressor cooling coil 15 and the condensate drain. In this arrangement, the condensate is conveyed from the pump suction side through the cooling coil 15 in the oil cooler of the compressor.

Claims (9)

1. tumble dryer with a process air circuit, which has a laundry drying room ( 1 ), a process air circulating fan ( 7 ) and means ( 5 ) for precipitating moisture from the process air flow, the means for precipitating moisture as a heat pump circuit with an evaporator ( 5 ), a compressor ( 8 ), a condenser ( 6 ) and a throttle sel ( 9 ) are formed and the evaporator ( 5 ) for cooling the process air extracted from the laundry drying room and the condenser ( 6 ) for heating the previously cooled process air serves, characterized in that the blower ( 7 ) is arranged in such a way between the laundry drying room ( 1 ) and the evaporator ( 5 ) in the process air circuit that the blower suction side ( 7 a) the laundry drying room ( 1 ) and the evaporator ( 5 ) downstream of the blower pressure side ( 7 b). 2. Clothes dryer according to claim 1, characterized in that the fan ( 7 ) in the door ( 11 ) of the clothes dryer is arranged. 3. Tumble dryer according to claim 1 or 2, characterized in that the fan ( 7 ) is formed as a radial fan and process air is extracted approximately axially from a laundry drum serving as a laundry drum ( 1 ). 4. Clothes dryer according to claim 3, characterized in that the process air flow in the interior of the door ( 11 ) of the clothes dryer is deflected approximately radially to the drum axis. 5. Clothes dryer according to one of claims 1 to 4, characterized in that a condensate pump ( 12 ) on the suction side with the evaporator ( 5 ) and on the pressure side with a compressor ( 8 ) cooling device is connected and that a condensate container is arranged downstream of the compressor cooling device , so that the condensate pump conveys the condensed water to the condensate container via the cooling device. 6. Tumble dryer according to claim 5, characterized in that the compressor cooling device is a heat exchanger, in particular a cooling coil or rib, which is guided through the oil sump of the compressor ( 8 ). 7. Clothes dryer according to claim 5 or 6, characterized in that the condensate pump ( 12 ) is controllable as a function of the process air temperature, in particular the temperature in the laundry drying room. 8. tumble dryer according to claim 7, characterized in that the condensate pump ( 12 ) depending on a temperature threshold in the process air circuit on and off bar. 9. Clothes dryer according to claim 7 or 8, characterized in that the compressor cooling device can be bridged by a bypass ( 14 ).