EP0377193A1 - Linen dryer - Google Patents

Abstract

A linen drier (tumbler) contains, in a machine housing (1), a rotating drum (2) which is surrounded by a jacket-like hot-air circulation space (3). Hot air flows continuously through the hot-air circulation space (3) and executes essentially a circular flow. All or some of this hot air repeatedly passes through a heating device (7), so that it is maintained at an essentially constant temperature. Moreover, the hot air passes through perforations in the drum (2) and the linen tumbled in the drum. As a result of the contact of the linen with the hot drum wall and the hot air passing through the drum wall, the water contained in the linen evaporates and is drawn off axially together with the hot air in the "moisture core". <IMAGE>

Description

The invention relates to a tumble dryer ("tumbler"), in particular for the commercial sector, with a machine housing, with a drum rotatably mounted in the machine housing and receiving the laundry to be dried, with a heating device, with a blower which carries air through the heating device and sucks off the exhaust air enriched with water vapor, the heat transfer from the hot air heated by the heating device to the laundry contributing to the drying of the laundry.

In known tumble dryers of this type, the hot air, which was previously heated in the heating device, is drawn across the perforated drum. That is, the hot air is introduced into the interior of the drum in a generally obliquely upward-pointing peripheral region of the drum wall; it is then sucked off together with the absorbed water vapor that has emerged from the laundry in the lower region of the drum wall. The hot air passes through the drum wall twice, a first time from the outside in and a second time from the inside out.

This design has very significant disadvantages. The drum and laundry pass through zones of different static pressures and different temperatures during their rotation. This significantly reduces the average temperature of the drying system and, consequently, the evaporation rate. The zones of different static pressure cannot be optimally sealed between the drum and the machine housing by baffles and sealing strips, so that considerable leakage losses occur due to the pressure differences. Only a small part the laundry surface has a brief contact with the hot drying air. The large flow resistances in the flow through the heating device, drum, laundry and other air passages not only lead to the mentioned, strongly increasing static negative pressure in the system in the flow direction and the resulting leakage flows inside the dryer; they also require high blower outputs. Cold outside air also enters the system through leaks in the housing and further reduces the average temperature.

The laundry in the drum is such that the air passage openings located in the lower region of the drum shell are laid in very different ways. This results in strong pulsations in the vacuum and air volume flow. These pulsations not only lead to considerable noise; they are also extremely stressful for the laundry which is sucked onto the air passage openings of the drum wall at high speed.

For the reasons mentioned, the efficiency of the known dryers in the commercial sector was relatively low. Higher dryer outputs could only be achieved by a disproportionate increase in energy consumption. The energy input affected both the heating output and the output of the blowers used.

The object of the present invention is to design a tumble dryer of the type mentioned at the outset in such a way that a good, gentle drying result is achieved with considerably lower energy consumption.

• a) ein Heißluft-Zirkulationsraum vorgesehen ist, der die Trommel mantelartig umgibt;
• b) ein Gebläse in dem Heißluft-Zirkulationsraum eine Kreis­strömung der erhitzten Luft aufrecht erhält,

wobei zumindest ein Teil der in dem Heißluft-Zirkulations­raum strömenden Luft durch die Heizeinrichtung geleitet werden kann.This object is achieved in that

• a) a hot air circulation space is provided, which surrounds the drum like a jacket;
• b) a fan in the hot air circulation space maintains a circulating flow of the heated air,

wherein at least a part of the air flowing in the hot air circulation space can be passed through the heating device.

In the configuration of the tumble dryer according to the invention, a relatively large circulation path for the hot air is therefore always kept open. The only significant flow resistance in this way is the heating device, which, however, can be dimensioned in a corresponding manner. The amount of energy required to maintain the circulation flow is relatively low. Because the air circulating in the circulation space passes through the heating device several times, it can be ensured that the average temperature of the hot air along the entire drum shell is constant and considerably higher than in known tumble dryers, where the temperature of the drum wall rapidly away from the hot air entry point falls off. According to the invention, the drum wall with which the laundry continuously comes into contact during the rotary movement of the drum is at a very high temperature. The heat given off by the heat transfer from the drum wall to the laundry and which leads to the evaporation of the water contained in the laundry can be replaced very quickly by the hot air in the circulation space. In the concept according to the invention, it is no longer important to suck a particularly large amount of hot air through the laundry itself. In extreme cases, it is sufficient if the hot air remains completely in the hot air circulation space, that is to say only flows around the drum, so that only the water vapor produced needs to be extracted from the drum. This can be done with a very low power blower. Another advantage is that the vapor extracted from the drum is of very high quality, ie is very strongly enriched with water vapor and has a high heat content. This will be discussed further below.

Significant static pressure differences no longer occur in the machine housing of a clothes dryer according to the invention; Leakages, as can not be avoided in practice between the drum and the machine housing, therefore no longer lead to as much heat loss and cold air as was the case with known tumble dryers. This also increases the efficiency of the machine according to the invention.

According to a feature of the invention, the interior of the drum should be extractable via an end wall in the area of the "moisture core". “Moisture core” is understood to mean that area which is radial within the path of movement of the laundry when the drum is rotating. This is the area that contains the humidest air. The front suction (instead of over the drum shell) has the additional advantage that the suction openings cannot be blocked by laundry lying on top. Pulsations in the pressure are thus avoided, as are stresses on the laundry caused thereby.

The suction opening in the front wall of the drum should be covered by a hood. This avoids the sucking in of laundry into the suction opening.

As already mentioned, the inventive concept does not necessarily require hot air to get into the interior of the drum. In a particular embodiment of the invention, however, it is provided that the drum is perforated in a manner known per se. In this case, the heated air circulating in the hot air circulation space can also enter the interior of the drum and interact with the moving laundry, as is also the case with conventional laundry Tumble dryers is the case.

A cross-flow fan is particularly suitable as a fan in the hot air circulation room.

The fan, which extracts the interior of the drum, should be speed-controlled. Depending on the operating phase (heating, drying or cooling phase), the speed and thus the output are adjusted differently (see below), within the drying phase to the lowest possible value.

As already mentioned, the vapors to be achieved with a clothes dryer according to the invention are of particularly high quality, that is to say they contain a particularly large amount of heat that can be recovered. It is therefore recommended that a heat exchanger is provided, via which the exhaust air sucked out of the interior of the drum and the fresh air supplied to the hot air circulation space are conducted. The thermal energy that is brought out of the tumble dryer with the vapor can thus be used in an optimal way to heat the fresh air supplied, which further reduces the heat requirement.

In a preferred embodiment of the invention, a flap is provided which can either release a direct path from the outside atmosphere for the fresh air or a path leading from the outside atmosphere to the hot air circulation space via the heat exchanger. In this way, fresh air can be introduced into the hot air circulation space, bypassing the heat exchanger, in particular during the cooling phase.

A further embodiment of the invention is that a flap is provided which divides the air flowing in the hot air circulation space into a first portion which flows through the heating device and a second portion which is on a by-pass path on the Heating flows past. This feature also contributes to the reduction of the heat requirement, since only as much air is passed through the heating device in the hot air circulation space as is necessary to maintain the required temperature.

In this context, a control circuit is expedient which comprises a temperature sensor located in the hot air circulation space and an actuator which actuates the flap, a constant temperature of the air in the hot air circulation space being maintained by varying the position of the flap.

The hood should advantageously be perforated. While such perforations on the actual suction opening in the drum wall have not proven themselves (here the perforations are quickly laid through the laundry items), they prove to be very useful in the hood. Since there is always a large path for the air extracted from the drum through the lower air inlet opening of the hood, accidental laying of individual perforation openings in the hood has no significant influence on the cross section that is effectively available for air extraction. In particular, there is no noticeable increase in the air speed in this case, which would result in an acceleration of the laying of the perforations in the case of perforations in the actual suction opening. Instead, items of laundry that happen to have accumulated on the perforations of the hood simply fall off again after a while.

The suction opening in the end wall of the drum, which is covered by the hood, is expediently higher than the air inlet opening in the hood. If items of laundry accidentally get into the hood from below through the air inlet opening during operation of the tumble dryer, they must counteract the effect of gravity Carry out an upward movement to the actual suction opening before you lay it or can be sucked into it. In general, however, the items of laundry fall back before crossing the corresponding height difference, so that sucking into the actual suction opening is practically impossible.

In a special embodiment of the invention, the fan and the heating device are arranged at a short distance from one another in the hot air circulation space. As a result, practically the entire hot air circulation space is at the same static pressure. This results in particularly defined conditions in the air movement through the perforations of the drum. In particular, it cannot happen that the static pressure in the interior of the drum is higher than in a partial area of the hot air circulation space. Such conditions would cause lint-laden air to change from the interior of the drum to the hot air circulation space.

It is useful if the heating device is arranged directly next to the suction opening of the blower. The hot air circulation space is then on the pressure side of the fan, i.e. it has a static pressure which is slightly higher than the atmospheric pressure prevailing outside. This means that at most air from the hot air circulation space can get to the outside, but that cold air from under no circumstances can penetrate into the hot air circulation space through cracks.

In general, the drum can be tilted for emptying in tumble dryers of the type of interest here. If this design is also used in a tumble dryer according to the invention, it is recommended that the hot air circulation space in the lower region be guided through a stationary, that is to say tiltable, base and that the heating device and the fan are in this lower area of the hot air circulation space. In this way, the entire tumble dryer is divided into two parts: an upper, relatively light, which essentially comprises only the drum and the larger area of the hot air circulation space and the loading and unloading flaps of the drum, and a lower part in which the heavy elements, in particular the heating device and the blower as well as all electrical and possibly elements requiring maintenance are combined.

A fluff filter is expediently arranged in the hot air circulation space.

Another special equipment feature of a tumble dryer according to the invention can consist in a device with which the ratio of fresh air to circulation air in the air conveyed by the blower can be adjusted. If one assumes that the performance of the blower, which sucks the vapor-laden air from the interior of the drum, and the blower, which circulates the air in the hot air circulation space, have a predetermined value, can be said by the device mentioned Set the static pressure in the hot air circulation room to a large extent.

The device mentioned is preferably a movable tube through which the fresh air is supplied and which can be brought at different distances from the inlet opening of the heating device. If the inner mouth of this pipe is very close to the inlet opening of the heater, where the suction effect of the fan is still large, then a correspondingly larger amount of fresh air is sucked in via the pipe than would be the case if the pipe were in a large one Distance from the inlet opening of the heater is withdrawn.

• Figur 1: einen senkrechten Schnitt durch ein erstes Ausfüh­rungsbeispiel eines Wäschetrockners;
• Figur 2: einen Teilschnitt gemäß Linie II-II von Figur 1;
• Figur 3: einen senkrechten Schnitt, ähnlich der Figur 1, durch ein zweites Ausführungsbeispiel der Erfin­dung;
• Figur 4: einen senkrechten Schnitt, ähnlich den Figuren 1 und 3, durch ein drittes Ausführungsbeispiel der Erfindung;
• Figur 5: schematisch die Seitenansicht des Ausführungsbei­spieles von Figur 4.

Embodiments of the invention are explained in more detail below with reference to the drawing; show it

• Figure 1: a vertical section through a first embodiment of a clothes dryer;
• Figure 2 shows a partial section along line II-II of Figure 1;
• Figure 3: a vertical section, similar to Figure 1, through a second embodiment of the invention;
• Figure 4: a vertical section, similar to Figures 1 and 3, through a third embodiment of the invention;
• Figure 5: schematically the side view of the embodiment of Figure 4.

The tumble dryer shown in FIGS. 1 and 2, which is intended for commercial use, comprises, in a manner known per se, a machine housing 1 in which a drum 2 is rotatably mounted. Details of the drum drive are omitted in the drawing for reasons of clarity and are not described in more detail here. They are of conventional construction.

As can be seen in particular from FIG. 1, the drum 2 is surrounded by a hot air circulation space 3, which extends parallel to the axis of the drum 2 over its entire width. In the hot air circulation space 3 there is a cross-flow fan 4, which maintains a circular flow in the hot air circulation space 3 in a manner to be described.

The hot air circulation space 3 is through a Insulation layer 5 protected from heat loss.

In the upper area of the hot air circulation space 3, a heating device 7 is provided in the form of an essentially conventional, steam-charged heating register, which also serves to heat the air flowing in the hot air circulation space 3 and the fresh air supplied in each case in a manner to be described. The latter optionally flows in via a duct 8 from an outer air inlet opening 9 or from a heat exchanger 10 which is attached to the side of the machine. The extent to which the fresh air flows directly through the duct 8 from the air inlet opening 9 or via the heat exchanger 10 into the hot air circulation space 3 depends on the position of a flap 11, which selectively block the flow through the duct 8 or the flow through a duct 12 can, which leads the air from the heat exchanger 10 to the heater 7.

The drum 2 is perforated in a manner known per se, so that hot air can reach the interior 13 of the drum 2 from the hot air circulation space 3.

The interior 13 of the drum 2 is suctioned off via an axial end wall, approximately in the middle. The suction opening itself is covered by a hood 14, which prevents items of laundry from being sucked into the suction opening.

The heat exchanger 10 contains, in a known manner, two plate systems which are flowed through at right angles to one another. Through the first plate system, which can be seen particularly clearly in FIG. 1, fresh air flows upwards from a second outer air inlet opening 15 to the duct 12 and from there, as already described, depending on the position of the flap 11 to the heating device 7 and in the hot air Circulation space 3. The second set of plates is, as can be seen better in FIG. 2, in the horizontal direction of flows through the air that was sucked out of the interior 13 of the drum 2. For this purpose, this extracted vapor is led via a corresponding line into a first, in reality vertically extending air space 16 shown in FIG. 2 below, then crosses the corresponding plate set of the heat exchanger 10 and arrives in a second air space 17. This, shown in FIG. 2 above , also extends perpendicularly along the plate sets of the heat exchanger 10; it communicates with an intake duct 18 of a blower 19, the speed of which can be regulated. On the pressure side, the blower 19 emits the vapors extracted from the interior 13 of the drum 2 via the heat exchanger 10 to the environment.

The tumble dryer described above works as follows:

If the drum 2 rotates, the laundry 20 located therein is taken along, as indicated in FIG. 1. It lies along a certain circumferential area on the drum wall, then detaches from it and falls, following a throwing parabola, downwards until it hits the drum wall again and is rotated by it again. At the same time, the hot air circulation space 3 is flowed through by a uniform, constant temperature hot air, which is kept in motion by the cross-flow fan 4. The cross-flow fan 4 can have a relatively low power, since the flow paths are relatively wide and only a slight throttling occurs.

A relatively small part of the hot air flowing in the hot air circulation space 3 also enters through the perforations of the drum 2 into its interior 13. It traverses the laundry 20 and arrives in the so-called "moisture core" around which the laundry 20 circulates. In this area there is also the suction opening covered by the hood 14, from where it is now strong Vapors saturated with water vapor reach the air space 16, from there via the second set of plates of the heat exchanger 10 into the second air space 17 and via the blower 19 into the outside atmosphere. The amount of air drawn out of the interior 13 of the drum 2 essentially depends on the speed, that is to say the power, of the fan 19. It can be reduced to such an extent that a high-quality vapors, that is to say vapors highly enriched with water vapor, can be sucked out of the interior 13 of the drum 2, the heat content of which is roughly comparable to that of vapors which are produced in deficiencies. It is therefore particularly suitable for heating the fresh air, which flows through the air inlet opening 15 into the second plate set of the heat exchanger 10, is heated there by the vapors and then flows into the hot air circulation space 3 via the heating device 7.

The heating device 7 therefore has essentially only the task in stationary operation to replace the heat given off by heat transfer to the laundry 20, and to heat the inflowing fresh air to the extent necessary after passing through the heat exchanger 10 to achieve the constant temperature in Hot air circulation space 3 is still required. The heating device 7 is used to a considerably lesser extent than is the case with conventional tumble dryers of the type of interest here.

The laundry 20 in the machine described is dried by two effects taking place simultaneously:

On the one hand, the wall of the drum 2 acts as a heating surface, which is practically at a constant temperature in its entire circumferential area. Direct heat transfer takes place here. The heat output on the drum wall is immediately replaced by the air flowing in the hot air circulation space 3. As a competing Effect, the proportion of which can be varied by the power of the blower 19, is the direct contact of the laundry 20 with air, which flows through the perforations of the drum 2 and then the laundry 20 itself and is ultimately released by the blower 19 into the outside atmosphere.

FIG. 3 shows a second exemplary embodiment of the invention, which largely corresponds to that according to FIGS. 1 and 2. Corresponding parts are therefore identified by the same reference number, plus 100.

The exemplary embodiment according to FIG. 3 differs from that according to FIGS. 1 and 2 by a geometrically somewhat different arrangement of the heating device 107, by the omission of the heat exchanger 10, which was present in the exemplary embodiment according to FIGS. 2 and 2, but of course also in the exemplary embodiment according to FIG 3 can be used, as well as by a flap control of the air flow in the hot air circulation space 103 which is of particular interest here.

As FIG. 3 makes clear, a flap 121 is pivotably articulated on the heating device 107 in such a way that it can send the air flowing in the hot air circulation space 103 either selectively or in different proportions through the heating device 107 or through a by-pass path 122 . The arrangement is obviously such that, depending on the pivoting position of the flap 121, more or less air is sent through the heating device 107. Accordingly, the air in the hot air circulation space 103 is more or less heated. The flap 121 is actuated by an actuator which is controlled so that the temperature in the hot air circulation space 103, measured by a suitable sensor, remains constant.

In channel 108, through which the fresh air from the outside Air inlet opening 109 is supplied, there is another flap 123 which is pivotable so that it regulates the supply of fresh air. The position of the flap 123 thus depends on the need for fresh air, in extreme cases it can be such that a supply of fresh air is completely prevented. Then essentially a pure circulation flow takes place in the hot air circulation space 103. Essentially pure water vapor is then sucked out of the interior 113 of the drum 102.

The above description has so far been limited to the actual drying phase, that is to say the part of the operating time in which the laundry 20 is dried. Here, the blower 19 is operated with an average volume flow, which must be sufficient for sufficient evacuation of the fumes which should be as high as possible from water vapor.

In the heating phase, on the other hand, until the desired constant temperature is reached within the hot air circulation space 3 or 103, the fan 19 or 119 is operated with no or very low volume flow. The position of the flap 11 in the embodiment of Figure 1 is as shown in the drawing; that is, supply air, insofar as it is drawn in at all, passes through the heat exchanger 10. In the exemplary embodiment according to FIG. 3, the flap 123 can be closed, so that essentially no fresh air is drawn in initially.

In the cooling phase, when the drying process is ended, the heating device 107 should normally be shut down (this means that the steam supply is switched off when a steam-operated heating register is used). In the exemplary embodiment according to FIGS. 1 and 2, the flap 11 now moves the path between the heat exchanger 10 and the heating device 7, ie gives the path for cold fresh air via the duct 8 in the hot air circulation room 3 free. This speeds up the cooling process. In the exemplary embodiment according to FIG. 3, the flap 123 is opened so that cold fresh air can reach the hot air circulation space 103 via the air inlet opening 109.

However, the following execution of the cooling process is particularly advantageous, in which the heating device 107 does not have to be shut down and therefore a quicker operational readiness for the next drying cycle can be achieved:

An insulated flap 124 (see FIG. 3), which connects the hot air circulation space 103 to the outside atmosphere, is located in the negative pressure area of the crossflow fan 104. To cool down, the flap 124 is opened; at the same time, the flap 121 is set so that all the air flows past the heater 107 via the by-pass path 122. The flap 123 is closed, so that the heater 107 is not flowed through by air at all. The fresh air flow now flowing in the hot air circulation space 103 ensures rapid cooling of the drum wall and the drum contents. After the laundry item has been removed and the drum 102 has been loaded again, the warm-up phase can be started without delay.

The exemplary embodiment of a clothes dryer shown in FIGS. 4 and 5 is similar to that of FIGS. 1 to 3; corresponding parts are therefore identified by the same reference numerals as in FIG. 1, but plus 200.

The tumble dryer shown in FIGS. 4 and 5 also comprises a machine housing 201 in which a perforated drum 202 is rotatably mounted. The drum 202 is surrounded by a hot air circulation space 203, in which a cross-flow fan 204 is arranged. The cross flow fan 204 is located in the lower region of the hot air circulation space 203, similar to the case in the exemplary embodiments described with reference to FIGS. 1 to 3. In the exemplary embodiments described at the outset, however, the heating device was provided approximately diametrically opposite at the top point of the hot air circulation space . Since the heating device is to be understood as the point in the hot air circulation space at which the pressure drop to be overcome by the cross-flow blower mainly takes place, the hot air circulation space was divided into two areas of different static pressure in these exemplary embodiments. If the area of the hot air circulation space located between the pressure side of the cross flow fan and the heating device is to be operated with a pressure which is only slightly above the external atmospheric pressure (in order to keep leakage losses small), then it can happen that that between the heating device and the The area of the hot air circulation space lying on the suction side of the crossflow fan is at a vacuum which is even lower than the pressure prevailing in the interior of the drum. This can then lead to the undesirable consequence that, in certain areas of the hot air circulation space, air reaches the hot air circulation space radially from the inside outward from the drum, that is, contrary to the direction actually desired. With this air, fluff gets from the interior of the drum into the hot air circulation space, which in particular sticks in the heating device and clog it over time.

If, on the other hand, as shown in FIG. 4, the heating device 207 is placed in the immediate vicinity of the cross-flow fan 204, practically the entire hot air circulation space 203 is at the same static pressure. In the illustrated embodiment, the heater 207 is attached to the suction side of the blower 204. This means that the hot air circulation space 203 is different is at the higher static pressure that exists on the pressure side of the cross flow fan 204. This makes it possible to ensure that at most air from the hot air circulation space 203 can escape to the outside atmosphere (cracks and gaps cannot be avoided at reasonable cost in the conventional design of such tumble dryers), but that cold air from the outside never enters the hot air Circulation space 203 can occur. This cold air would have to be heated in the heating device 207, which would lead to unnecessary heat consumption.

The fresh air is fed to the tumble dryer in FIG. 4 through a pipe 229 which is held so as to be axially displaceable. In this way, the inner opening 231 of the tube 229 can be brought at different distances from the inlet opening 230 of the heating device 207. It can be seen that the arrangement is such that a certain proportion of the total amount of air which the cross-flow fan 204 circulates in the hot air circulation space 203 is freshly supplied from the outside atmosphere via the pipe 229. This proportion is greater, the closer the mouth opening 231 of the tube 229 is brought to the inlet opening 230 of the heating device 207, because the more this mouth opening 231 is in the effective range of the blower 204 Distance between its mouth opening 231 and the inlet opening 230 increases, the suction effect of the fan 204 in the interior of the tube 229 decreases; the proportion of fresh air that is drawn in by the fan 204 and introduced into the circuit in the hot air circulation space 203 decreases.

The purpose of the measure is to be able to set the static pressure prevailing in the hot air circulation space 203. This results from the interaction of the amount of fresh air flowing through the pipe 229 in the hot air circulation space 203 is introduced, and the amount of air that is sucked off through the suction opening 225 in the front of the drum 203 and released into the outside atmosphere. The greater the amount of fresh air drawn in, the greater the pressure in the hot air circulation space 203. The aim is to bring this pressure in the hot air circulation space 203 as close as possible to the external atmospheric pressure, but slightly on the overpressure side. The tube 229 enables this pressure setting to be made individually for each tumble dryer delivered by the factory and for the cracks and crevices adhering to it, which are also individual and cannot be controlled by the factory.

Figure 4 also shows that the hood 214 is perforated. This perforation is very useful on the hood 214, although it would be unusable on a cover of the actual suction opening 225. In the latter case, a piece of laundry which happens to lay some of the perforation holes would reduce the residual cross section for the exhaust air so much that an increase in the air velocity would occur in the remaining open perforation holes. This in turn would have an increased suction effect for laundry items, so that the entire suction cross section would be laid with laundry items shortly. If, however, as shown in FIG. 4, the perforations on the hood 214 are used, items of laundry which are deposited thereon cannot significantly reduce the effective suction cross section. This is determined by the lower air inlet opening 226 of the hood 214. Negative self-reinforcing effects (laying some perforation holes increases the air speed in the other perforation holes and thus promotes the further laying of these remaining perforation holes) do not occur on the hood 214.

In the embodiment of Figure 4, the actual Liche suction opening 225 in the front of the drum 202 mounted higher than the air inlet opening 226 in the hood 214. In order to show this, the hood 214 has broken away in the upper region in Figure 4. If items of laundry with the extracted air penetrate into the hood 214 from below through the air inlet opening 226, they would have to overcome the height difference between the air inlet opening 226 and the suction opening 225 against the effect of gravity, so that they can be sucked into or into the actual suction opening 225 can relocate them. In practice, however, the items of laundry fall back into the drum beforehand.

In general, tumble dryers of the type of interest here are designed as so-called tilting dryers, in which the drum is tilted for emptying. This is shown schematically in FIG. 5, where the operating position of the drum (and the surrounding parts including the annular space) is drawn through and the tilted emptying position is shown in dash-dot lines. In Figure 5, the unloading flap 232 can also be seen, which can be pivoted via a hydraulic cylinder 233. The unloading flap 232 is brought into the open position shown in broken lines before the drum is tilted. The drum and the opened unloading flap are only tilted afterwards, so that the laundry can fall out between the opened unloading flap 232, which then runs approximately vertically, and the tilted part of the machine housing 201.

So that the mass to be tilted is as small as possible, both the heating device 207 and the blower 204 are located in a lower, non-tiltable base 227 of the clothes dryer. A small area of the hot air circulation space 203 is passed through this lower base 227. The displaceable tube 229 as well as any elements of the tumble dryer that may require maintenance are combined in this lower base 227, where they can be easily reached.

Claims (18)

1. Tumble dryer, in particular for the commercial sector, with a machine housing, with a drum rotatably mounted in the machine housing, which holds the laundry to be dried, with a heating device, with a blower, which air through the heating device and with Extracts exhaust air enriched with water vapor, the heat transfer from the hot air heated by the heating device to the laundry contributing to the drying of the laundry,
characterized in that
a) a hot air circulation space (3; 103) is provided which surrounds the drum (2; 102) like a jacket;
b) a fan (4; 104) in the hot air circulation space (3; 103) maintains a circular flow of the heated air;
wherein at least part of the air flowing in the hot air circulation space (3; 103) can be passed through the heating device (7; 107). 2. Clothes dryer according to claim 1, characterized in that the interior (13; 113) of the drum (2; 102) can be sucked off via an end wall in the region of the "wet core". 3. Tumble dryer according to claim 2, characterized in that the suction opening in an end wall of the drum is covered by a hood (14). 4. Tumble dryer according to one of the preceding claims, characterized in that the drum (2; 102) in is perforated in a manner known per se. 5. Clothes dryer according to one of the preceding claims, characterized in that the fan (4; 104) in the hot air circulation space (3; 103) is a cross-flow fan. 6. Clothes dryer according to claim or 3, characterized in that the fan (19; 119), which sucks the interior (13; 113) of the drum (2; 102), is speed-controlled. 7. Tumble dryer according to one of the preceding claims, characterized in that a heat exchanger (10) is provided, via which on the one hand the exhaust air sucked from the interior (13) of the drum (2) and on the other hand the fresh air supplied to the hot air circulation space (3) is directed. 8. Clothes dryer according to claim 7, characterized in that a flap (11) is provided, which either for the fresh air either a direct route (8, 9) from the outside atmosphere or via the heat exchanger (10) leading way to the hot air circulation space (3) can release. 9. Dryer according to one of the preceding claims, characterized in that a flap (121) is provided which divides the air flowing in the hot air circulation space (103) into a first portion which flows through the heating device (107), and one second portion which flows past the heating device (107) on a by-pass path (122). 10. A tumble dryer according to claim 9, characterized by a control circuit, the one in the hot air circulation space (103) temperature sensor and a the flap (121) actuating actuator, wherein a constant temperature of the air in the hot air circulation space (103) is maintained by varying the position of the flap (121). 11. Tumble dryer according to claim 3, characterized in that the hood (214) is perforated. 12. Clothes dryer according to claim 3 or 11, characterized in that the suction opening (225) in the end wall of the drum (202), which is covered by the hood (214), is higher than the air inlet opening (226) in the hood (214 ). 13. Clothes dryer according to one of the preceding claims, characterized in that the fan (204) and the heating device (207) are arranged at a short distance from one another in the hot air circulation space (203). 14. Clothes dryer according to claim 13, characterized in that the heating device (207) is arranged directly next to the suction opening of the blower (204). 15. A tumble dryer according to claim 13 or 14, in which the drum can be tilted for emptying, characterized in that the hot air circulation space (207) is guided in the lower region through a stationary, that is to say tiltable, base (227) and in that the heating device ( 207) and the fan (204) are in this lower area of the hot air circulation space (207). 16. Clothes dryer according to one of the preceding claims, characterized by a in the hot air circulation space (207) arranged lint filter (228). 17. Tumble dryer according to one of the preceding claims, characterized by a device (229) with which the ratio of fresh air to circulation air in the air conveyed by the blower (204) is adjustable. 18. Clothes dryer according to claim 17 when referring back to claim 14, characterized in that the device (229) is a movable tube (229) via which the fresh air is supplied and which is at different distances from the inlet opening (230) of the heating device (207) can be brought.

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