WO2009080431A1 - Household appliance for the care of laundry, and method for operating such a household appliance - Google Patents

Abstract

The invention relates to a household appliance for the care of laundry, comprising a drum (3) for receiving laundry and a process air guide (2), by means of which process air may be guided to and through the drum (3), and a heating unit (16) that is thermodynamically coupled to the process air guided in the process air guide (2) and that is disposed upstream of the drum (3), wherein the process air guide (2) has a main channel (19) and a secondary channel (20) branching off of the same downstream of the drum (3), and the secondary channel (20) ends in the heating unit (16) or upstream of the heating unit (16) in the process air guide (2). The invention further relates to a method for operating a household appliance for the care of laundry.

Description

 Domestic appliance for the care of laundry items and method for

Operating such a household appliance

The invention relates to a domestic appliance for the care of items of laundry, in particular a dryer, with a drum for receiving laundry items and a process air duct through which process air can be conducted to and through the drum, and a heater which is thermodynamically coupled to the process air guided in the process air duct and is arranged upstream of the drum. Furthermore, the invention relates to a method for operating a domestic appliance for the care of laundry items, in particular a dryer.

In general, a tumble dryer is operated as a vented dryer or as a condensation dryer. An exhaust air dryer passes heated air once through the laundry to be dried and carries this moisture-laden air through an exhaust hose from the exhaust air dryer from the room in which it is placed. A condensation dryer, the operation of which is based on the condensation of moisture evaporated by means of warm process air from the laundry, requires no exhaust hose and allows energy recovery from the heated process air, for example by using a heat pump.

By contrast, in the case of an exhaust air dryer, the air laden with moisture after passing through a laundry drum is generally passed out of the dryer. Compared to a condensation dryer, an exhaust air dryer can be constructed simpler and thus more cost-effective. An exhaust air dryer draws air from its environment during operation and uses it directly for drying. Such ambient air is usually relatively dry with a relative humidity of significantly less than 100%, and therefore can absorb a relatively large amount of moisture. By comparison, the circulating process air in a condensation dryer can generally only be dehumidified to 100% relative humidity at the lowest temperature present in the process air cycle, which limits its absorption capacity for moisture from the objects to be dried and thus imposes some restriction in the drying process. Heat recovery is also possible in an exhaust air dryer. For this purpose, from DE 30 00 865 A1 a tumble dryer with heat recovery designed as a vented dryer. The tumble dryer comprises a movable and the laundry items receiving drum into which a heated by a heating supply air flows, while the moist hot air is conducted as exhaust air through an outlet. In the supply air flow, a heat exchanger is arranged in front of the heating element, which is flowed through by the hot-humid exhaust air from the drum.

Exhaust air dryers may be designed as systems sucking or tumbling into the drum, depending on whether a blower is placed in the process air duct before or after the drum for conveying the process air flow. In this connection, the heating device, which is usually arranged upstream of the drum, can also be flowed through in an oppressive or suction manner. To protect the heater from overheating at greatly reduced flow rate, a temperature limiter may be provided which can turn off the heater, this temperature limiter is placed in the flow direction.

In unfavorable installation or inappropriate operation of the dryer on exhaust air systems, it may happen that in the operating phase of the dryer, the flow direction in the process air duct, for example, due to a strong back pressure reversed. It may then happen that the heater overheats.

It is an object of the present invention to provide a domestic appliance for the care of items of laundry and a method for operating such a domestic appliance, in which such overheating of a heater can be prevented at unfavorable for the flow of process air operating phases.

This object is achieved by a domestic appliance having the features of claim 1, and a method having the features of claim 1 1.

An inventive domestic appliance for the care of items of laundry comprises a drum for receiving the laundry items and a process air duct through which process air can be conducted to and through the drum. Furthermore, the household appliance includes a Heating device which is thermodynamically coupled with the guided in the process air duct process air and upstream of the drum. Downstream of the drum, the process air duct is branched into a main duct and into a side duct branching off from it, and the auxiliary duct opens into the heating device or upstream of the heating device into the process air duct. By such an embodiment, a circulation of the process air in the main flow direction can be achieved even in unfavorable operating phases. Even with strong back pressure can be prevented by the fact that the flow direction in the process air flow reverses and a heater is no longer sufficiently flows around and thus overheated. By suitable measures in the domestic appliance, the air duct can thus be improved to avoid overheating of the heater.

Preferably, a first temperature limiter for situation-specific shutdown of the heater or the heater between this heater and the drum in the process air guide is arranged. It is thus ensured a temperature monitoring of the heater on the basis of the flow direction in normal operation, which is arranged after the heater.

It is preferably provided that a second temperature limiter for situation-specific shutdown of the heating device is arranged upstream of the heating device in the process air duct. As a result of this arrangement, when the process air flows under normal process conditions, a temperature control can also take place in front of the heating device so that overheating can also be detected here and, if necessary, the heating device can be switched off in good time.

Preferably, the secondary channel opens downstream of a second temperature limiter and upstream of the heater in the process air duct. The junction of the secondary channel in the process air duct is thus formed between the second temperature limiter and the heater.

As already mentioned above, the junction of the secondary channel can also be done directly in the heater. The time duration of the return of the process air via the auxiliary channel to the heating device is preferably dependent on the temperature of the heating device and / or the flow velocity of the process air in the process air duct in the area of the heating device. Depending on at least one of said parameters, the time duration can thus preferably be automatically controlled by a control unit and thus adjusted as needed, so that the return of the process air is also time-optimized. This also with regard to an efficient and effective overall concept, in which the optimal implementation of the care process of the laundry items on the one hand and the energy-efficient and safety-relevant operation of the components on the other hand is possible.

Preferably, the time of the return of the process air via the auxiliary channel to the heating device is dependent on the temperature of the heating device and / or the flow velocity of the process air in the process air duct in the region of the heating device. Not only the time period, but in addition or instead of this, the specific time at which the return of the process air is to take place via the secondary channel can be determined individually and situation-specific. Here, too, the respective temperature detection and / or the flow velocity of the process air and / or the flow direction of the process air can be detected and output to a control unit via an appropriate sensor so that it controls the feedback of the process air via the auxiliary channel depending on this information ,

The proportion of the process air recirculated via the secondary channel to the heating device preferably depends on the temperature of the heating device and / or the flow velocity of the process air in the process air duct in the area of the heating device. By this configuration, the dosage of the process air amount, which is to be performed on the secondary channel, are set very precise and demand-dependent. This too can be electronically controlled and thus automatically adjusted. It may be provided that an element for reducing the flow cross-section, for example a flap or the like, is arranged at the branch of the secondary channel from the main channel, which element can be electronically controlled via a control unit. This can thus be set situation-specific in its position so that the time and / or the time and / or the proportion of over the secondary channel recirculated process air can be made very accurate. As a result, a highly effective and highly efficient system can be made possible, which detects a possible overheating of the heater early and initiates appropriate countermeasures.

The invention provides measures which satisfy the highest safety requirements with regard to overheating of the heating device in the air duct of the domestic appliance. The design of the domestic appliance with preferably one or two temperature limiters can be made much more robust by this safety concept, or it can even be provided that the temperature limiter can be omitted upstream of the heater. This is achieved in that at least partially process air is passed through the secondary channel, which emerges from the drum and is returned to the heater. Optionally, although this raises the air temperature in front of the heater slightly, but by the significantly increased air flow through the heater, the temperature can then be significantly lowered. This higher volume flow makes the system basically less susceptible to increased air resistance and to the reversal of air flow due to, for example, a back pressure. The proportion of recirculated air via the secondary duct ensures in all cases that the air flow through the heating device in the main flow direction is maintained at larger boundary locations.

The second temperature limiter in front of the heating device can preferably be dispensed with completely or designed to be significantly weaker than it would have to be designed without such a return of the process air via the auxiliary channel for the purpose of reducing the temperature of the heating device.

In particular, this safety concept is provided in exhaust air dryers, in which preferably components for heat recovery from the process air are arranged.

In particular, it is thus provided that the domestic appliance also comprises a heat exchange device, which is preferably associated with a heat pump. If the domestic appliance is designed as an exhaust air dryer, it has an open process air duct. However, this is not to be understood that the Process air can not be performed at least partially in a circuit in the household appliance. In principle, however, the process air in such an exhaust air dryer is sucked in through a supply air opening and pushed out of the household appliance via an exhaust air opening.

In the method according to the invention for operating a domestic appliance for the care of laundry items, process air guided in a process air duct is thermally coupled to a heating unit arranged upstream of a drum for receiving laundry items and passed through the drum. Downstream of the drum, the process air duct is branched into a main duct and a side duct branching off from it, and the process air is fed back to the heating unit at least proportionally in terms of operating phase. This procedure can prevent overheating of the heating device during unfavorable operating phases of the domestic appliance, in particular when the flow velocity of the process air in the region of the heating device is greatly reduced or flows in the opposite direction to the main flow direction due to a counterpressure.

The time duration of the return of the process air via the auxiliary channel to the heating device is preferably determined as a function of the temperature of the heating device and / or as a function of the flow rate of the process air in the process air duct in the region of the heating device. In particular, the time of the return of the process air via the auxiliary channel to the heating device is determined as a function of the temperature of the heating device and / or the flow velocity of the process air in the process air duct in the region of the heating device. The proportion of process air conducted via the auxiliary channel to the heating device is also preferably determined as a function of the temperature of the heating device and / or the flow rate of the process air in the process air duct in the region of the heating device.

The time duration and / or the time and / or the proportions of the process air conducted via the auxiliary channel can additionally or instead also be determined depending on the parameter of the flow direction of the process air in the process air duct in the region of the heating device. Advantageous embodiments of the domestic appliance according to the invention are also to be regarded as advantageous embodiments of the method according to the invention.

An embodiment of the invention will be explained in more detail with reference to a schematic drawing. The single FIGURE shows a sketchy representation of a designed as exhaust air dryer domestic appliance.

FIG. 1 shows in a sketch a domestic appliance designed as a vented dryer 1 for the care of laundry items, which comprises a process air duct with a process duct 2, which is designed as an open process air duct. The dryer 1 also has a drum 3 for receiving items of laundry, which is rotatably mounted about an axis 4.

Process air guided in the process air duct is guided by means of a blower 5 through the drum 3 and laundry items (not shown) located therein. In the exemplary embodiment, the blower 5 is coupled in the main flow direction of the process air in front of the drum 3 and thus upstream of the drum 3 with the process air guide. Behind the drum 3 and thus in the direction of flow after the drum 3, the process air passes through a lint filter 6, which in the simplest case is a lattice-shaped sieve to lint, d. H. small fibers, which entrains the process air by the rotation of the drum 3 against each other moving laundry pieces and entrains to catch. This is important for a sufficiently long trouble-free function of the downstream of the process air flow components of the dryer 1, since it prevents lint from settling on these components. The process air is drawn through a supply air opening 7 in the process air duct 2 and pushed out through an exhaust port 8. In the supply air opening 7 air passes directly from the environment of the dryer 1. To the exhaust port 8 is connected an exhaust hose 9, with which the exhaust air from the dryer 1 away and from a building in which it is placed, is discharged.

In addition, the dryer 1 comprises a heat exchange device 10, 11. The heat exchange device 10 and 11 is associated with a heat pump 15. In this context, the heat pump 15 comprises a first heat exchanger, which is designed as an evaporator 10, and a second heat exchanger, which as Condenser 11 is formed. In the condenser 1 1, the process air drawn in through the supply air opening is heated. This heated process air is passed into the drum 3, where it comes into contact with the laundry to be dried and then flows to the lint filter 6. Then the moist, warm and freed of any fluff process air is cooled in the evaporator 10. The heat withdrawn from the process air heat is in a heat pump circuit 10 to 14, to the components of the evaporator 10 and the condenser 1 1 includes, led to the condenser 1 1 and fed there the freshly flowed process air.

The heat pump circuit 10 to 14 and thus the heat pump 15 is formed in addition to the evaporator 10 and the condenser 1 1 by a throttle 12 and a compressor 13, said components via a closed line system

14 are connected to a circuit with each other. In the circuit circulates, driven by the compressor 13, a cyclically to be evaporated, to be compressed, to be liquefied and to be relaxed working fluid, in particular a refrigerant. Gaseous the evaporator 10 leaving refrigerant is from

Compressor 13 is compressed and heated. It then passes to the condenser 11, where it liquefies with the release of heat to the process air. Then it flows in

Line system 14 through the throttle 12, where it is expanded to a lower pressure, and passes to the evaporator 10, where it evaporates while absorbing heat from the process air. From the evaporator 10, it flows in the pipe system 14 to

Compressor 13 so that the circuit closes.

However, the heat exchange device 10, 1 1 can also be considered as a heat pump 15 associated with it, but be designed as a countercurrent or cross-flow heat exchanger.

In the exemplary embodiment, the fan 5, as already mentioned, arranged in front of the drum 3 and is thus designed as a pressing system. It can also be provided that the fan 5 is arranged in the main flow direction of the process air in the process air duct after the drum 3, so that this system is then designed as a sucking system. The dryer 1 further comprises a heating device 16, which is arranged in the main flow direction in front of the drum 3. The heating device 16 is positioned so that it is thermodynamically coupled to the process air guided in the process air duct 2. As a result, the process air can be heated before it enters the drum 3.

In addition, a first temperature limiter 17 is arranged or coupled between the heating device 16 and the inlet of the drum 3 in the process air duct. A second temperature limiter 18 is arranged in the main flow direction between the fan 5 and the heater 16 in the process air guide or coupled thereto.

The process air guide is branched after the drum 3 into a main channel 19 and into a secondary channel 20. In the exemplary embodiment, the secondary channel 20 branches off at the branch 21 from the main channel 19 and ends at the junction 22 in the process air duct. The junction 22 is thus formed upstream of the heater 16. It can also be provided that, according to the dashed representation, the junction takes place directly into the heating device 16. In the exemplary embodiment, the junction 22 is formed in the process air duct before the heater 16 and after the second temperature limiter 18. It can also be provided that the junction 22 upstream and thus in the main flow direction before the second temperature limiter 18 is formed.

Preferably, a flap 23 is arranged as an element for reducing the flow cross section of the process air channel 2 at the branch 21. The flap 23 is electrically connected to the exemplified control unit 24, so that its adjustment is controlled by the control unit 24. In addition, the heater 16 is controlled by the control unit 24. The two temperature limiter 17 and 18 are connected to the control unit 24. The control unit 24 may also be designed to control further components of the dryer 1 beyond.

Depending on the situation, during the operation of the dryer 1 in the process air duct guided process air is at least partially passed through the secondary channel 20. By this procedure, under specific operating conditions, in particular at Conditions in which conditions occur in which the flow direction reverses in the operating phase due to strong back pressure and thus runs counter to the symbolized by the arrow representation main flow direction can be prevented. Since overheating of the heating device 16 can occur precisely in such specific operating phases, the flow in the main flow direction can be maintained by the at least proportional conduction of the process air via the auxiliary channel 20, thereby preventing overheating of the heating device 16. Although an increase in the air temperature may possibly occur in the main flow direction in front of the heating device 16, the temperature there and then lowered by the significantly increased air volume flow via the heating device 16. This increased volume flow for maintaining the main flow direction of the process air makes the system more resistant to increased air resistance in the flow direction against the main flow direction and against the reversal of the air flow in general. This volume of recirculated air generated via the secondary duct 20 also ensures that the air flow through the heating device 16 in the main flow direction is maintained at larger boundary positions.

By this procedure can also be made possible that the temperature limiter 18 may possibly be completely eliminated or can be designed significantly weaker than this must be the case if the described procedure with the process air line via the secondary channel 20 would not exist.

The time duration and / or the time of the return of the process air via the secondary channel 20 and / or the portion of the process air which is recycled via the secondary channel 20 is preferably automatically controlled as a function of the temperature limiters 17 and 18 by the control unit 24. In this context, the duration of the return of the process air via the secondary channel 20 and / or the time of returning the process air via the secondary channel 20 and / or the proportion of recirculated process air via the secondary channel 20 depending on the temperature of the heater 16 and / or the Flow rate of the process air in the process air in the range of the heater 16 and / or the flow direction of the process air in the process air in the range of the heater 16 done. Especially in exhaust air dryers, in particular with a heat recovery, in the form of a heat exchanger assembly 10, 1 1 or in particular in the form of a heat pump 15, can by this concept with the recirculated air through the secondary channel 20 is a much improved safety concept with regard to avoiding possible overheating of the heater 16 in specific operating phases of the dryer 1, in particular when an occurrence of a back pressure, which can form, for example, via the exhaust hose 9 and the exhaust port 8 in the process air, are made possible. For example, such a back pressure may result in unfavorable wind conditions outside the dryer 1.

Claims

claims

1. Domestic appliance for the care of laundry, with a drum (3) for receiving laundry items and a process air guide (2), through which process air to and through the drum (3) can be conducted, and a heater (16), which with the in the process air duct (2) guided process air thermodynamically coupled and upstream of the drum (3) is arranged, characterized in that downstream of the drum (3) the process air guide (2) has a main channel (19) and a branching off secondary channel (20) and the Side channel (20) in the heater (16) or upstream of the heater (16) opens into the process air duct (2).

2. domestic appliance according to claim 1, characterized in that a first temperature limiter (17) for situation-specific shutdown of the heater (16) between the heater (16) and the drum (3) in the process air guide (2) is arranged.

3. Domestic appliance according to claim 1 or 2, characterized in that a second temperature limiter (18) for situation-specific shutdown of the heater (16) upstream of the heater (16) in the process air guide (2) is arranged.

4. Domestic appliance according to one of the preceding claims, characterized in that the secondary channel (20) opens downstream or upstream of a second temperature limiter (18) and upstream of the heating device (16) in the process air duct (2).

5. Domestic appliance according to one of the preceding claims, characterized in that the time duration of the return of the process air via the auxiliary channel (20) to the heater (16) depends on the temperature of the heating device (16) and / or the flow rate of the process air in the process air duct ( 2) im

Area of the heating device (16) and / or the flow direction of the process air in the process air duct (2) in the region of the heating device (16).

6. domestic appliance according to one of the preceding claims, characterized in that the time of recycling the process air via the secondary channel (20) to the heater (16) depending on the temperature of the heater (16) and / or the flow rate of the process air in the region of the heater (16) and / or the flow direction of the process air in the process air duct (2) in

Range of the heater (16).

7. domestic appliance according to one of the preceding claims, characterized in that the proportion of the secondary duct (20) for Heinzeinrichtung (16) recirculated process air depends on the temperature of the heater (16) and / or the flow rate of the process air in the heating device ( 16) and / or the flow direction of the process air in the process air duct (2) in the region of the heating device (16).

8. Domestic appliance according to one of the preceding claims, characterized in that it comprises a heat exchange device (10, 11).

9. domestic appliance according to claim 8, characterized in that the heat exchange device (10, 11) is associated with a heat pump (15).

10. Domestic appliance according to one of the preceding claims, which is designed as a vented dryer (1) with an open process air guide (2).

1 1. A method for operating a domestic appliance for the care of laundry, wherein in a process air duct (2) guided process air with an upstream of a

Drum (3) arranged to receive items of laundry heating device (16) thermally coupled and passed through the drum (3), characterized in that downstream of the drum (3), the process air guide (2) in a main channel (19) and one of them branching Sub-channel (20) is branched off and the process air via the secondary channel (20) operating phase specific at least proportionally to the heater (16) is returned.

12. The method according to claim 11, characterized in that the time duration of the return of the process air via the auxiliary channel (20) to the heating device (16) depends on the temperature of the heating device (16) and / or the flow rate of the process air in the region of the heating device (16 ) and / or the flow direction of the process air in the process air duct (2) in the region of the heating device (16) is determined.

13. The method according to claim 10 or 11, characterized in that the timing of the return of the process air via the secondary channel (20) to the heater (16) depends on the temperature of the heater (16) and / or the flow rate of the process air in the region of the heater (16) and / or the flow direction of the process air in the process air duct (2) in the region of the heating device (16) is determined.

14. The method according to any one of claims 10 to 13, characterized in that the proportion of the secondary passage (20) for Heinzeinrichtung (16) recirculated

Process air is determined as a function of the temperature of the heating device (16) and / or the flow rate of the process air in the region of the heating device (16) and / or the flow direction of the process air in the process air duct (2) in the region of the heating device (16).