CH707892B1 - Clothes dryer with wastewater pump. - Google Patents

Abstract

The tumble dryer has a catch basin (7) for condensed water in the base area. A pump (12) in a two-part pump housing unit (11) protrudes from above into the catch basin (7). The pump housing unit (11) forms a siphon (13), which prevents the intake of outside air via the collecting basin (7). For this purpose, a first riser (18) is formed in the lower part (27) of the pump housing unit (11) and a second riser (21) is formed in the upper part (26). The two riser pipes communicate via a connecting channel (20), which is formed between the upper part (26) and the lower part (27). This results in a compact construction, and the siphon (13) can be easily manufactured.

Description

Description Field of the Invention The invention relates to a tumble dryer according to the preamble of claim 1.

Background [0002] Dryer with at least partially closed process air cycle have a drum for receiving laundry and a process air duct, wherein the process air from the drum for processing through the process air duct and via a blower arranged in the process air duct back into the drum. In the intake area of the pump, i. in the negative pressure area of the same, a cooling unit for extracting water from the process air is provided. Below the cooling unit is a catch basin for collecting the condensed water. So that the fan does not suck in uncontrolled ambient air via the catch basin, the catch basin is sealed airtight with respect to the ambient air.

For pumping out water from the catch a pump is provided. This is a siphon downstream, i. The pumped by the pump water passes through the siphon after the pump. The task of this siphon is to avoid sucking in ambient air through the pump when the pump is off and the fan is on.

The corresponding embodiment of such a device is relatively complex, which makes the production time-consuming and expensive.

It is an object to provide a device of the type mentioned, which is simple in design.

This object is achieved by the device according to claim 1. Accordingly, the pump and the siphon are arranged together in a pump housing unit. In this way, the pump and siphon can be mounted in one step in the form of the pump housing unit in the device.

Advantageously, the pump housing unit has an upper part and a lower part, which are connected to each other airtight and shaped such that they form the siphon between them.

In particular, while the pump housing unit may have a first riser extending from the output area (ie overpressure area) of the pump up against a first riser mouth, and further a second riser extending from the outlet of the pump housing unit down to a second riser mouth , To form the siphon, the first riser mouth is arranged higher than the second riser mouth.

In the context of the present text and the claims are terms such as "up", "down", "above", "below", "deeper" etc. in terms of the intended installation of the tumble dryer to understand in which the base of the device is located below the drum.

BRIEF DESCRIPTION OF THE DRAWINGS Further embodiments, advantages and applications of the invention will become apparent from the dependent claims and from the following description with reference to the figures. Showing:

1 is a schematic section through some components of a tumble dryer (not to scale),

2 shows a first partial section through a pump housing unit,

3 is a second partial section through the pump housing unit of FIG. 1,

Fig. 4 is a third partial section through the pump housing unit of FIG. 1 and

Fig. 5 is a schematic representation of an embodiment of the level electrodes.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT FIG. 1 shows the most important components of a clothes dryer, wherein the size ratios are reproduced in a distorted manner for better understanding. In particular, the components in the base of the machine are drawn enlarged. Water filled areas are shown horizontally hatched.

The device has in a known manner a drum 1 for receiving the laundry. From the drum 1, a first section 2a of a process air duct via a filter unit (not shown) leads to an air treatment unit 3 in the device base. This is located in a second section 2b of the process air duct. From there, the air passes through a third section 2c of the process air duct and a blower 4 back into the drum. 1

In the air treatment unit, a cooling unit 5 and a heating unit 6 are arranged. The air first passes through the cooling unit 5, where it is cooled, so that at least a part of the water dissolved in the water condenses out. Then the air passes through the heating unit 6, where it is reheated so that it can absorb new water.

The cooling unit 5 and the heating unit 6 may be configured in known per se as evaporator or condenser of a heat pump cycle. Alternatively or additionally, at least part of the cooling unit can be cooled with ambient air, or the heating unit can be heated by a resistive electric heater.

The auskondensierende on the cooling unit 5 water drips from this and arrives at a catch basin 7, which is lower than the cooling unit 5. The portion 2b of the process air duct, in which the refrigeration unit 5 is located, and the catch basin 7 communicate with each other, i. in both there is about the same air pressure. Since the cooling unit is located in the intake of the fan 4, this air pressure is slightly below the ambient pressure during operation of the device. In order to prevent uncontrolled ambient air from being sucked in via the catch basin 7, the catch basin 7 is arranged in a basin housing 8 which is hermetically sealed to the outside.

Advantageously, the portion 2b of the air duct, in which the cooling unit 5 and the heating unit 6 are arranged, and the collecting basin 7 formed by a common structural unit, which is arranged in the base of the device.

As can be seen from Fig. 1, the pelvic housing 8 is closed from above with a ceiling 8a. In this ceiling, an opening 9 is recessed, in which the aforementioned pump housing unit 11 is inserted. The opening 9 is closed airtight by the pump housing unit 11. The pump housing unit 11 protrudes from above into the catch basin 7.

Fig. 1 shows the pump housing unit 11 in a schematic section. As mentioned, a pump 12 and a downstream siphon 13 are housed in the pump housing unit 11. These are described in more detail below.

In the embodiment shown, the pump 12 a radially promotional impeller 14 and above the same a the impeller 14 driving motor 15.

The impeller 14 has a vertical axis of rotation and is located in a pumping chamber 16 at the bottom of the pump unit, resulting in a space-saving design.

Coaxial with the axis of rotation of the impeller 14, a suction port 17 is arranged in the pumping chamber 16, via which water from the catch basin 7 can be sucked. Radially outward on the pumping chamber 16, in the exit region (i.e., overpressure region) of the pump 12, includes a first riser 18 which extends upwardly to a first riser mouth 18a. The first riser mouth 18a is arranged in a connecting channel 20, which again leads downwards. In a lower part of the connection channel 20 is a second riser mouth 21 a of a second riser 21, which extends between the second riser mouth 21 a and an outlet 22 of the pump housing unit 11. The first riser mouth 18 a and the second riser mouth 21 a are connected to one another via the connecting channel 20.

The outlet 22 forms a nozzle to which a hose 23 or the like is connected, which leads to a condensate collection container (or drain) of the device. This condensate collector, which is not shown in Fig. 1, is ventilated, i. he is in contact with the environment, so that there is ambient pressure in the condensate collecting tank.

As shown in Fig. 1, the pump housing unit 11 has an upper part 26 and a lower part 27. The lower part 27 forms the pumping chamber 16, the first riser 18, the housing for the motor 15 and a side collar 29, with which the Pump housing unit 11 rests on the ceiling 8a of the pelvic housing 8. Further, the lower part 27 forms a trough 30 under the second orifice 21a. The upper part 26 forms the second riser 21 and a dome 31 above the first orifice 18a.

The connecting channel 20 is formed between the upper part 26 and the lower part 27, in particular between the dome 31 and the trough 30th

The upper part 26 and the lower part 27 are connected to each other via a suitable seal, so that the connecting channel 20 is sealed from the environment.

In operation, water accumulates in the catch basin 7 (reference numeral 35). Once the level of this water reaches a certain level, the pump 12 is put into operation and delivers the water through the pump chamber 16, the first riser 18, the connecting channel 20 and the second riser 21 to the hose 23rd

If the pump 12 is not in operation, so collects in the cathedral 31 air. In the region of the connecting channel 20 and the second riser 21, however, remains a certain amount of residual water, since these parts form a siphon.

If the blower 4 is turned off, then the air pressure in the catch basin 7 corresponds approximately to the ambient pressure, so that the water level in the connecting channel 20 is about the same as that in the second riser 21. If, however, blower 4 is turned on, then arises Sump 7 a suppression, so that the water level in the connecting channel 20 is higher than that in the second riser 21, as shown in Fig. 1 in the drawing. Since the

Claims (12)

Repression in the catch basin 7, however, is relatively small, suffice a few inches of water column to compensate for it and to prevent suction of outside air through the hose 23. Figs. 2-4 show a concrete embodiment of the pump housing unit. Here, the upper part 26 and the lower part 27 are each made as an injection-molded part made of plastic, so that the device can be manufactured in a simple manner. Between the upper part 26 and the lower part 27, a seal 40 is provided, which seals the connecting channel 20 from the outside. Can be seen in Fig. 2-4, the first riser 18 and the subsequent thereto subsequent pumping chamber 16, which are both formed by the lower part 27. Also visible are the second riser 21 and the dome 31, which are formed by the upper part 26. The lateral collar 29 of the lower part 27 carries a circumferential sealing lip 41, with which it can be sealed against the ceiling 8a. The pump housing unit shown in Fig. 2-4 is designed so that the dynamic overshoot of the water level in the siphon with changes in pressure in the sump 7 is minimal. The siphon is designed so that the movements of the water in the risers 18 and 21 are damped. For this purpose, the connecting channel 20 forms in each case at the first and the second orifice 18a or 21a the aforementioned dome 31 or the aforementioned trough 30 (compare Fig. 4). In addition, the wall 31a or 30a of the dome 31 or of the trough 30 opposite the respective riser mouth 18a or 21a is in each case substantially perpendicular to the riser pipe 18 or 21. (By "substantially perpendicularly" is to be understood that the Angle of the longitudinal axis of the respective riser to the wall in the range of 70 ° -110 °, in particular 80 ° to 100 °.) This leads, for example, with a drop in pressure in the catch basin 7 that through the second riser 21 into the chamber 20b entering water hits the wall 20d and is braked there by the impact. As a result, an excessive lowering of the water level in the riser 21 is prevented and the risk that the riser 21 completely emptied and thus opens the siphon reduced. Thanks to the achieved damping of the water movement, the length of the risers 18, 20 are kept relatively short. Further visible in Fig. 2-4 holding devices 43, which serve to receive fill level electrodes (not shown). Fig. 5 again shows the pump housing unit 11 corresponding to the schematic representation of Fig. 1. In particular, the upper part 26 and the lower part 27 are visible. In the present embodiment, the lower part 27 carries in two of the holders 43 a first and a second level electrode 44a, 44b, which project from above into the catch basin 7. Further, the base 27 of the present embodiment also carries a third level electrode 44c which also projects downwardly but less deeply than the first and second level electrodes 44a, 44b. With these three electrodes, two different water levels 45a, 45b can be detected. The pump 12 may be turned on when the water reaches the higher level 45b and turned off when it drops to the lower level 45a. If the water after switching on the pump 12 does not drop in a certain time to the lower level 45a, the device control can close to a pump failure, a clogging or a faulty installation and issue a warning. In the embodiment according to FIG. 5, a fourth electrode 44d is also provided, which forms an overflow detector with which stagnant water can be detected in a collecting trough 47 at the top of the pump housing unit 11. This drip pan 47 is formed by laterally encircling upwardly directed walls 48 which project upwards at the edges of the collar 29 (see also FIG. 2). The overflow detector serves to detect water, e.g. occurs between the upper part 26 and the lower part 27, or between the second riser 21 and the hose 23. If water is detected in the drip pan 47, the device control outputs an error message. The pump housing unit 11 forms an integral, i. in a coherent component which can be installed as a whole in the tumble dryer and this can be removed if necessary, whereby the assembly and disassembly is simplified. While preferred embodiments of the invention have been described in the present specification, it is to be understood that the invention is not limited thereto and may be embodied otherwise within the scope of the following claims. claims 1. Dryer with a drum (1) for receiving laundry, a process air duct (2a, 2b, 2c) through which process air from the drum (1) and back into the drum (1) can be guided, one in the process air duct (2a , 2b, 2c) arranged fan (4) for conveying process air through the process air duct (2a, 2b, 2c), a cooling unit (5) arranged in the intake of the blower (4) for removing water from the process air, a deeper than that Cooling unit (5) arranged catchment basin (7) for collecting water, wherein the catch basin (7) is sealed airtight to ambient air, a pump (12) for pumping water from the catch basin (7) and one of the pump (12) downstream siphon (13), characterized in that the pump (12) and the siphon (13) in a pump housing unit (11) are arranged. 2. A tumble dryer according to claim 1, wherein the pump housing unit (11) has an upper part (26) and a lower part (27), which are connected to each other airtight, wherein the siphon (13) between the upper part (26) and the lower part (27). is trained. 3. A tumble dryer according to claim 2, wherein the pump housing unit (11) has a first riser (18) extending from an exit region of the pump (12) up to a first riser mouth (18 a), and wherein the pump housing unit (11) a second riser (21) extending from an outlet (22) of the pump housing unit (11) down to a second riser mouth (21a), wherein the first riser mouth (18a) is higher than the second riser mouth (21a). 4. The tumble dryer according to claim 3, wherein the first and the second riser mouth (18a, 21a) in a between the upper part (26) and the lower part (27) formed connecting channel (20) are arranged and connected to each other via the connecting channel. 5. Dryer according to claim 4, wherein the upper part (26) above the first riser mouth (18 a) a dome (31) and / or the lower part (27) under the second riser mouth (21 a) forms a trough (30). 6. A tumble dryer according to claim 5, wherein one of the first riser mouth (18a) opposite wall (31a) of the dome (31) substantially perpendicular to the first riser (18a) and / or one of the second riser mouth (21a) opposite wall (30a ) of the trough (30) is arranged substantially perpendicular to the second riser (21). 7. Dryer according to one of claims 3 to 6, wherein the first riser (18) from the lower part (27) and the second riser (21) from the upper part (26) is formed. 8. Dryer according to one of claims 2 to 7, wherein the upper part (26) and / or the lower part (27) is each a one-piece injection molded part, and in particular wherein between the upper part (26) and the lower part (27) has a seal (40 ) is arranged. 9. A tumble dryer according to one of the preceding claims, wherein the collecting basin (7) is arranged in a basin housing (8) which has a ceiling (8a) with an opening (9), wherein the pump housing unit (11) in the opening (9). is used and this seals airtight. 10. Dryer according to one of the preceding claims, wherein on the pump housing unit (11) a level sensor (44a-44d) is arranged, which projects from above into the catch basin (7). The clothes dryer of claim 10, wherein the level sensor (44a-44d) includes first and second level electrodes (44a, 44b), wherein the level electrodes (44a, 44b) are disposed on the pump housing unit (11) and from above into the catch basin (7), and in particular wherein a third level electrode (44c) is arranged on the pump housing unit (11) which also projects from above into the catch basin (7) but less deeply than the first and the second level electrode (44a, 44b). , 12. Tumble dryer according to one of the preceding claims, wherein on the pump housing unit (11) an overflow detector (44d) is arranged, with which stagnant water at an upper side of the pump housing unit (11), in particular in a collecting trough (47) at the top of the pump housing unit ( 11), is detectable.