EP2822442A2 - Household appliance - Google Patents

Abstract

The present invention relates to a household appliance (1), particularly a dishwasher, comprising a door (3), a thermal actuator (6) for the opening or unlocking of the door (3) and a device (11) that is designed to uncouple a closing or locking of the door (3) from the thermal actuator (6).

Description

 household appliance

The present invention relates to a household appliance, in particular a dishwasher. By unlocking and opening the door of a conventional dishwasher, such as a dishwasher with a pull-lock, a certain amount of force on the part of the operator is connected, which is sometimes perceived as uncomfortable. Further, in the past, it has been found to be beneficial to be energy efficient and, in view of complete drying, to partially open the door of a dishwasher during the drying process.

Accordingly, in recent years, dishwashers having a device for automatically opening the door have been developed. Such a dishwasher is described, for example, in EP 2 394 561 A2.

An object of the present invention is to provide a household appliance which is equipped with a particularly cost-effective mechanism for opening the door. Therefore, a household appliance, in particular a dishwasher, is provided with a door, an actuator, in particular a thermoactuator, for opening or unlocking the door and a device. The device is configured to decouple closing or locking of the door from the actuator. A "thermoactuator" in the present case is an actuator in which a movement results as a function of a temperature change. "Movement" includes, for example, moving a working element, eg a working piston, between a starting position and an opening position, wherein the movement in the open position causes the door to open or unlock. The temperature change can be effected, for example, electrically, which can be easily implemented in terms of control engineering. Thermo-actuators usually comprise a wax (for example, oil, wax, hard paraffin or metal) caused by a change in temperature undergoes a phase transition and thus a significant volume change, resulting in a movement from the home position to the open position. The distance traveled is usually proportional to the volume change of the wax. If the expansion material cools down again, the working element, in particular the working piston, is typically pushed back by a spring into the corresponding housing of the thermal actuator and in this way is moved back into its starting position. Examples of such thermoactuators are wax motors, bimetals or shape memory alloys (memory metals). Thermoactuators, in particular the mentioned wax engines, are characterized by the fact that they are particularly cost-effective. However, such thermal actuators typically have the property that they are capable of only relatively slow actuation. In particular, the return movement of the working element from the open position to the starting position takes a relatively long period of several seconds to a few minutes to complete. This is explained below by way of example with reference to a wax motor: The wax of the wax motor can be heated relatively quickly by means of an electrical heating device so that a relatively fast movement of the working piston relative to the return movement can be achieved from the starting position to the opening position due to the expanding wax. The cooling of the wax, however, takes place more slowly than the heating, so that the return movement of the working piston from the opening position to the starting position takes place correspondingly slower.

Because of this feature, the thermoactuator can be used to easily open or unlock the door, especially when the speed of movement of the actuator from the starting position to the opening position for the desired function is not critical, such as at a desired opening or unlocking the door at the end a drying program of a dishwasher. However, if the door is to be closed or locked again immediately after opening or unlocking, the thermoactuator itself, in particular the working element itself, prevents such closing or closing from the opening position to the starting position due to the only slow movement speed of the working element, in particular working piston. unless additional measures are envisaged. This problem basically exists with any actuator whose speed of movement during the return movement of the working element from the opening position to the starting position falls below a predefinable minimum speed, or in other words, at each Actuator in which the return movement exceeds a predefinable period of time. Such a delayed return movement can be due to the system, as in the case of a thermoactuator, but can also result from a special arrangement, for example an electric motor with a complicated downstream gear mechanism. In the present case, a corresponding additional measure is to decouple the closing or locking of the door from the actuator, in particular thermoactuator. This kinematic decoupling causes the door can be closed or locked, although the working element, in particular the working piston, at least partially extended due to its slow movement speed in the direction from the open position to the starting position. Closing or locking the door immediately after opening or unlocking the door is thus possible.

The application of the invention is particularly useful if the return movement of the working element from the open position to the starting position lasts at least one second, in particular at least five seconds. If, in fact, the door can not be closed again for such a period of time, this represents a condition restricting the operation of the household appliance, which is perceived as disturbing or at least undesirable by an operator.

In the present case, a distinction is made between opening / closing and unlocking / locking as follows: opening / closing means a movement of the door to release (open) or close (close) access to a room behind the door. Unlocking / locking the door means an actuation of a locking element which releases an opening of the door (unlocking) or blocking such an opening (locking). The opening and unlocking can also take place simultaneously, just as the closing and locking can take place simultaneously. This is the case, for example, with a door lock in which the unlocking of the door with an opening thereof and / or the locking of the door associated with a closing thereof.

According to one embodiment, the device is designed to couple the actuator with the door for opening the same or with a door lock for unlocking the door.

The coupling creates a kinematic operative connection between the actuator and the door or the door lock. This kinematic operative connection is then through the decoupling is lifted to close or lock the door immediately after opening or unlocking the same.

According to a further embodiment, the device has a first and a second actuating element, which can be brought into contact with one another for coupling and for decoupling.

Typically, the first actuator acts in a first direction against the second actuator while in abutment with each other. If the first actuating element is moved in a second direction substantially perpendicular to the first direction, then the first and second actuating element are out of engagement. The first actuating element may be formed, for example, as a plunger. The second actuating element can be designed, for example, as a lever.

Preferably, the first and second actuating element are each adjustable between a first and second position, wherein the first layer corresponds to a closed or locked state of the door and the second layer each corresponding to an open or unlocked state of the door, wherein the first and second actuating element, if these are each in their second position, can be brought out of abutment for the decoupling, whereby a return part of the second actuating element is released from its second position in its position.

The first and second actuating element are thus provided in such a way that they move partly on the same path (first and second actuating element in contact) and partly on different tracks (first and second actuating element apart from the system). Thereby, the rear portion of the second operating member can be easily accomplished independently of a movement of the first operating member.

According to a further embodiment, the disengagement comprises a displacement of the first actuating element transversely to the feed axis of the actuator.

The feed axis means the axis along which the working element, in particular the working piston, of the actuator is movable. As far as present of "transverse", "parallel" or "Perpendicular" is spoken, so are preferably deviations from the transverse direction, the parallels and the perpendicular from 0 to 45 °, preferably 0 to 20 °, more preferably 0 to 10 ° or even more preferably 0 to 5 °.

According to a further embodiment, the device has a spring for the displacement of the actuating element.

In principle, instead of the spring (this applies to each of the presently described springs, in particular the first and second spring), a different kind of actuator, such as a permanent magnet or solenoid may be used.

According to a further embodiment, the first actuating element has a bevel against which the spring acts at least indirectly.

"Indirectly" here means indirectly and directly. "Indirect" means that the spring can act on the first actuating element, for example, by means of an intermediate plunger. However, a direct action of the spring - without intermediate element - on the first actuator is possible. The slope causes the spring to be increasingly tensioned as the first actuator is moved along the feed axis. In addition, the slope causes the force applied by the spring to have a component in the direction transverse to the feed axis.

According to a further embodiment, the first actuating element for the insertion and dislocation is movably provided on a closed path.

The closed path may be, for example, circular, oval, rectangular, square or oblong-shaped. Thus, the mentioned different paths of the first and second actuating element can be easily accomplished. According to a further embodiment, the device has a link, which cooperates with a link element of the first actuating element to define the closed path. The backdrop may be formed, for example, in the form of a slot-shaped elevation. The link element may be formed, for example in the form of a pin, which is moved along the outer contour of the slot-shaped elevation.

According to a further embodiment, the closed path has a first and a second path section, along which the first actuating element can be adjusted by means of the actuator, in particular thermoactuator.

The first and second track sections are preferably formed parallel to one another. The first web section typically corresponds to the extension of the working element, e.g. in the form of a working piston, the actuator, while the second path section corresponds to the retraction of the working piston.

According to a further embodiment, the closed track has a third and a fourth track section, which connect the first and second track sections to one another and along which the first actuating element can be adjusted by means of one or more springs.

For example, the third and fourth track sections may each be semicircular. In this case, the third track section preferably connects the first and second track sections at their respective one ends, while the fourth track section preferably connects the first and second track sections at their respective other ends.

According to a further embodiment, the first actuating element is adjustable by means of the actuator along the first path section from the first in its second position in the feed direction of the actuator, wherein the first actuating element at least indirectly comes into contact with a first spring and the second actuating element and thereby the compressed first spring and the second actuator between its first and second position adjusted.

In the feed direction of the actuator, the direction from the starting position of the working element, eg of the working piston, in its opening position preferably means "in the feed direction of the thermoactuator", preferably the direction along which expands the expansion of the thermal actuator. In the feed direction, the actuator, in particular the thermal actuator, or its working piston has a relatively high movement speed in comparison to the return direction (counter to the feed direction). The door can thereby be opened or unlocked quickly, for example within 45 to 60 seconds.

According to a further embodiment, the first spring adjusts the first actuating element, if this is in its second position, along the third path section in the transverse direction to the feed axis from its second position to a third position, wherein the first actuating element comes out of engagement with the second actuating element.

This results in the decoupling of the first and second actuating element from each other in a simple manner. According to a further embodiment, the first actuating element is adjustable by means of the actuator along the second path section from its third position into a fourth position counter to the feed direction, wherein the first actuating element at least indirectly comes into contact with a spring and thereby compresses the second spring. "Contrary to the feed direction" means a movement along the direction of the

Opening position to the starting position of the working element. For thermoactuators, this is the direction along which the expansion material of the thermal actuator typically contracts, so that the corresponding speed of movement of the thermal actuator or the working piston thereof is low.

According to a further embodiment, the second spring displaces the first actuating element, when this is in its fourth position, along the fourth track section from its fourth position into the first position counter to the transverse direction. This results in a simple way, the closed path along which the first actuator is moved. According to a further embodiment, the device has a stop against which the first spring abuts when the first actuating element is in its third position.

The stop prevents the first spring from counteracting the second spring as the second spring moves the first actuating member along the fourth track portion.

According to a further embodiment, the first actuating element is mounted transversely to the feed direction movable on a working piston of the actuator. For this purpose, the working piston may have an engagement element which engages in a corresponding receiving element in the actuating element displaceable. Alternatively, the first actuating element, the engagement element and the working piston having the receiving element. The engaging and receiving element may be formed according to the tongue and groove principle. According to a further embodiment, a return spring is provided, which resets the second actuating element from its second position in its first position.

As soon as the first actuating element releases a return part of the second actuating element, the second actuating element is reset by means of the return spring. As a result, the second actuating element and optionally associated with this, further actuating elements are positioned such that the door can be easily closed or locked.

According to a further embodiment, the first and second actuation elements for bringing in place have mutually corresponding bevels.

As a result, it can be achieved by a minimum offset of the first and second actuating elements relative to one another that they can be moved past each other for the rear part of the second actuating element.

According to a further embodiment, the first spring acts by means of a plunger on the first actuating element, which has a slope which corresponds to the slope of the first actuating element. Thereby, the movement of the first actuating element in the feed direction of the actuator can be easily converted into a movement for compressing the first spring. The springs, in particular the first and / or second spring, may be formed as compression springs, in particular spiral compression springs. Furthermore, the springs may be formed as leaf springs.

According to a further embodiment, the second actuating element is designed as a reversing lever. As a result, the device takes up little space. Alternatively, the second actuating element can also be designed as an eccentric.

According to a further embodiment, the second actuating element acts on a door-opening ram or a locking element of the door lock.

A "door-open pestle" is a pestle that is moved substantially perpendicular to the door so as to push it in. A "door-latch locking element" is one such element which engages a recess in the door or in a door-opening-bounding frame of a housing Domestic appliance engages to lock the door, or can be disengaged with this recess to unlock the door and thus release it for opening.

According to a further embodiment, the door lock on a striker and a lever. The striker is by means of the actuator, in particular Thermoaktua- sector, from a locking position in which it engages positively in the door, adjustable against a force acting in the closing direction of the door spring in an unlocked position in which he releases the door for opening the same and against a return part is positively secured by the spring. When the door is closed, the lever releases the positive lock, which causes the spring to move the striker to the locking position and pull the door in the closing direction. In this door lock unlocking the door with a slight opening of the same and the locking of the door with a slight closing of the same goes hand in hand. This type of door lock can also be referred to as a "pull-lock".

According to one embodiment, the door is formed without handles. In this case, the actuator according to the invention, in particular thermoactuator, causes any opening of the door. Such an embodiment is particularly useful when the feed rate, that is, the speed of movement of the working element from the starting position to the open position is sufficiently large. According to another embodiment, the door is formed with a handle or a recessed grip. The actuator causes the opening of the door only when it is provided by the sequence program of the household appliance, for example, the washing program of a dishwasher. Preferably, the opening of the door takes place during or after a drying program of a dishwasher.

The opening or unlocking of the door may be triggered by a sensor connected to the actuator, e.g. the Thermoaktuator, is connected by signal technology. For example, the sensor may be in the form of a pushbutton, touch sensor, proximity sensor or optical sensor. Alternatively, the opening or unlocking of the door can be triggered by a control device.

Further advantageous embodiments and aspects of the invention are the subject of the dependent claims and the embodiments of the invention described below. Furthermore, the invention will be explained in more detail with reference to preferred embodiments with reference to the accompanying figures.

It shows:

FIG. 1 shows a schematic side view of a dishwasher;

FIG. 2 shows an enlarged view II from FIG. 1 in a partially broken-away illustration, wherein an actuator tappet is in a first position; FIG. 3 is a perspective view of an actuator tappet from FIG. 2;

Figure 4: a section IV-IV of Figure 2;

FIG. 5 shows a section V-V from FIG. 4;

FIG. 6 shows the view from FIG. 2, wherein the actuator tappet is in a second position;

FIG. 7 shows the view from FIG. 5 when the actuator ram is in the second position shown in FIG. 6;

FIG. 8 shows the view from FIG. 6, wherein the actuator ram is in a third position; FIG. 9 shows the view from FIG. 8, wherein the actuator ram is in a fourth position;

FIG. 10 shows schematically a closed path on which the actuator tappet is moved; and

Figure 1 1: the view of Figure 5 with active overload protection.

In the figures, the same or functionally identical elements have been given the same reference numerals, unless stated otherwise.

FIG. 1 shows a schematic side view of a domestic appliance in the form of a dishwasher 1. This has a washing container 2 for receiving items to be washed. A door 3 is pivotably connected to a body 4 forming the washing container 2 by means of a joint 5. In this case, the closed position and in dashed line the open position of the door 3 is illustrated in a solid line. The dishwasher 1 further comprises an actuator in the form of a Thermoaktua- sector 6 (see Figure 2), a door lock 7 and a device 1 1, which are each arranged below an upper cover 12 of the body 4.

The door lock 7 comprises a locking element 13 (see FIG. 4) and a recess 14 (see FIG. 1) into which the locking element 13 engages in the closed position of the door 3 and this in the direction of the washing compartment 2 against a one shown in FIG Seal 15 pulls. As a result, a gas- and liquid-tight closure of the washing compartment 2 in the closed position of the door 3 is achieved. The dishwasher 1 also has a touch sensor 16, which is signal-technically coupled to a control device 17 of the dishwasher 1. If an operator presses the touch sensor 16 during operation of the dishwasher 1, that is to say while it is processing a rinse program, for example to place a forgotten cup in a dish rack (not shown) in the rinse tank 2, the controller 17 interrupts the rinse operation and controls the thermoactuator 6 Unlocking the door 3. In this state, the device 1 1 couples the thermo-actuator 6 to the door lock 7. Thereafter, the thermo-actuator 6 actuates the locking element 13 from its locking position shown in FIG. 4 in a solid line into the unlocking position shown there in dashed line. After this, the operator person pulls the door 3 into its open position, for example by means of a recessed grip 21, as shown in FIG. 1, or the door 3 falls into its open position due to its own weight. The touch sensor 16 may also be integrated into the recessed grip 21, so that a grasping by hand already leads into the recessed grip 21 for unlocking the door 3. In the open position of the door 3, for example, the forgotten cup can now be placed in the dish rack. Subsequently, the operator closes the door 3 again. With the pushing of the door 3, the locking element 13 (see Figure 4) jumps again from its unlocked position into its locking position, whereby the door 3 is locked and pressed in the direction of the washing compartment 2 against the seal 15. The opening and closing of the door 3 together with the corresponding unlocking and locking of the locking element 13 takes only a short time. As a rule, this time span is not sufficient for the thermo-actuator 6 to be able to restructure. In order that now the return of the locking element 13 from its unlocking position in its locking Position is possible despite not yet restored Thermoaktuator 6, the device 1 1 decouples the locking element 13 of the thermo-actuator. 6

Figure 2 shows an enlarged view II of Figure 1, wherein the cover 12 is shown in broken-away view.

The thermoactuator 6 is formed, for example, as a wax engine. The thermal actuator 6 comprises a housing 22 which is filled with wax 23 which drives a working piston 24. The device 1 1 has a first, stationary carrier part 28, on which the housing 22 is attached. Furthermore, a coil 25 is provided, which heats the wax 23 as soon as the control device 17 (see FIG. 1) supplies the coil 25 with current. The wax 23 then expands relatively quickly, wherein the working piston 24 is extended along the feed axis 26 in the feed direction V. For a retraction of the working piston 24 against the feed direction V, the thermo-actuator 6 may have a spring, not shown. The working piston 24 is along the feed axis 26 in positive connection with a first actuating element in the form of an actuator tappet 27th

FIG. 3 shows the actuator ram 27 in a perspective view. The actuator ram 27 has a T-slot 31, into which the working piston 24 at its free end, which is formed in the form of a Ts (not shown), engages positively along the feed axis 26 and along a transverse axis 32 transversely to the feed direction 26. Furthermore, the actuator ram 27 has a link element in the form of a pin 33. The pin 33 extends perpendicular to the plane defined by the feed axis 26 and the transverse axis 32 level E.

Returning now to FIG. 2, it can be seen that the device 1 1 furthermore has a link in the form of a slot-shaped elevation 34. The elevation 34 is formed on a second, stationary carrier part 29 of the device 11. The support member 29 is shown in Figure 2 transparent. The actuator ram 27 or the pin 33 is guided in a manner described in more detail below on a closed path 35 (see FIG. 10) around the elevation 34 along its outer contour. The device 1 1 further comprises a first spring plunger 36, which is biased by a first spring 37 in the form of a helical compression spring in the transverse direction Q along the transverse axis 32. The first spring 37 is supported on the one hand on the first support member 28 and on the other hand on the first spring plunger 36 from. The spring plunger 36 has a bevel 41, which corresponds to a bevel 42 (see FIG. 3) of the actuator pusher 27, ie, the slopes 41, 42 have the same pitch and face each other. In the first position L1 shown in FIG. 2 (see FIG. 10) of the actuator pusher 27, the first spring pusher 36 bears against a stop 40 in the transverse direction Q. According to the embodiment, the actuator plunger 27 and the first spring plunger 36 in the first position L1 of the actuator pusher 27 are spaced from each other by a gap.

If the control device 17 now energizes the coil 25, the working piston 24 displaces the actuator plunger 27 from its first position L1 along a path section 43 (see FIG. 10) in the feed direction V, whereby the actuator plunger 27 is in abutment with the bevel 41 of FIG first spring plunger 36 passes and thereafter the first spring plunger 36 against the transverse direction Q shifts and thereby compresses the first spring 37. An adjustment of the actuator pusher 27 in the transverse direction Q is prevented by the pin 33 in cooperation with the elevation 34. Subsequently, the actuator ram 27 comes into abutment with a second actuating element of the device 11 in the form of a deflection lever 44. The deflection lever 44 is initially located in its first position L1. The deflection lever 44 extends in its first position L1 along the transverse axis 32. "Along" in the present case comprises co-linear and parallel, unless indicated otherwise The deflection lever 44 has a first and a second end 45, 46 and is located between the Ends 45, 46 are pivotally mounted on the second carrier part 29 at an articulation point 47. The first end 45 comprises a bevel 51, which preferably has the same pitch as the slopes 41, 42.

If the actuator ram 27 is now actuated further in the feed direction V, the bevel 42 of the actuator pusher 27 acts against the bevel 51 of the deflection lever 44, as a result of which the deflection lever 44 pivots out of its first position L1 into its second position L2 (see FIG. 6). Seen in Figure 2, the lever pivots thus clockwise about the pivot point 47. This finally also enters the actuator plunger 27 in its second position L2, as shown in Figure 10. The second end 46 of the reversing lever 1 1 is formed with an example semi-circular backdrop, which acts on an example T-shaped end 54 of a plunger 53. The plunger 53 passes through the first support part 28. Between the T-shaped end 54 and the first support part 28, a return spring 55 is arranged in the form of a helical compression spring. As soon as the deflection lever 44 actuates the tappet 53 counter to the feed direction V, the return spring 55 is compressed.

FIG. 5 shows a section V-V on FIG. 4.

The plunger 53 engages against the feed direction V positively a U-shaped bracket 56 which engages behind a pressure plate 61 at its free ends 57. Between the bracket 56 and the pressure plate 61, an overload spring 62 is arranged in the form of a spiral compression spring, which may be provided with a bias of, for example, 50 Newton. The deflection lever 44 thus acts on the pressure plate 61 by means of the plunger 53 and the overload spring 62.

The initially mentioned locking element 13 of the door lock 7 is presently designed as a striker. The striker 13 comprises two legs 63, which engage behind a spring 64 at its one end 65. The spring 64 is designed as a spiral compression spring. At its other end 66, the spring 64 is supported on a housing 67 of the door lock 7. An upper part of the housing 67 is not shown in Figure 5 to release the view of the underlying components. The striker 13 has opposite to the legs 63 a hook 71 which extends in a direction perpendicular to the plane E. FIG. 4 shows a section IV-IV from FIG. 2.

The hook 71 engages in its locking position in the recess 14 (see Figure 1). If now the deflection lever 44 acts on the legs 63 by means of the pressure plate 61, the striker 13 is actuated from its locking position (see FIG. 5) into its unlocking position (see FIG. 7). The hook 71 is moved on the one hand against the feed direction V and on the other hand in a direction R perpendicular to the plane E. The movement in the direction R is accomplished by the door lock 7 having a step 72. In the unlocked position (shown in dashed lines in Figure 4) of the Striker 13, the hook 71 locks in a form-fitting manner behind the step 72. The unlocking position of the striker 13 is also shown in FIG.

The recess 14 is released in the unlocked position of the striker 13, so that the door 3 can be opened manually by the operator. Alternatively, the door 3 can also be automatically opened by a further device of the dishwasher 1. Although such a device is not shown in detail in the figures, it can be easily realized on the basis of the same principle of operation as shown above. In this case, the pressure plate 61 would not act on the door lock 7, but on a door-opening plunger 73, which is shown by way of example in FIG. The door opening plunger 73 would push the unlocked door 3 from its closed position to the open position. Furthermore, a differently functioning device for opening the door 3 could be used.

FIG. 6 shows the view from FIG. 2, wherein the actuator pusher 27 and the deflecting lever 44 are each in their second position L2. The second layer L2 now lacks the support of the pin 33 in the transverse direction Q, so that the first spring plunger 36 presses the actuator pusher 27 in the transverse direction Q from the second ply along a semicircular track portion 74 into a third ply L3 (see FIG. 8) , As soon as the actuator pusher 27 reaches its position L3, or shortly before, the first spring plunger 36 abuts against the stop 40. As the actuator pusher 27 moves from its second position L2, see FIG. 6, into its third position L3, see FIG. 8, it releases a return part of the reversing lever 44 from its second position L2 in its first position L1 by means of the return spring 55. When the deflecting lever 44 is then in its first position L1, as shown in FIG. 8, the pressure plate 61 is arranged at a distance from the legs 63 of the striker 13.

Closes now the operator, for example, after a few seconds again the door 3 manually, so actuates an unspecified door section a lever 75 of the door lock 7, which is shown in Figure 4. The operation of the lever 75 causes the hook 71 lifted out of its unlocked position, that is highlighted behind the stage 72, and placed on the step 72. Characterized the hitherto existing positive connection between the hook 71 and the step 72 is released, whereby the hook 71 is pulled by means of the spring 64 in its locking position. The in Figure 8 With 76 designated distance is consumed. A feedback of the movement of the striker 13 on the Aktuatorstößel 27 does not take place.

According to a further embodiment, the first spring tappet 36, the first spring 37 and the stop 40 can be dispensed with. In this case, the bevel 51 of the reversing lever 44 acts on the slope 42 of the Aktuatorstößels 27 that the Aktuatorstößel 27 is moved to the end of its movement in the feed direction V in the third layer L3.

From the third position L3 (see FIG. 8), the actuator tappet 27 is pulled along a web section 77 (see FIG. 10) by means of the working piston 24 of the thermal actuator 6 slowly counter to the feed direction V and thereby moved into its fourth position L4. The track section 77 is provided parallel to the track section 43. Therefore, the movement along the path portion 77 is slower than the opposite movement along the path portion 43 because the wax 23 cools and contracts more slowly as it heats and expands.

The device 1 1 further comprises a second spring tappet 81 which is supported on the second carrier part 29 via a second spring 82 in the form of a helical compression spring. As the actuator tappet 27 moves from its third L3 to its fourth position L4, it comes into abutment with a bevel 83 of the spring tappet 81 and presses it against the action of the second spring 82 in the transverse direction Q.

Once the support of the pin 33 is missing by the elevation 34 against the transverse direction Q, the second spring plunger 81 presses the actuator plunger 27 by means of the slope 83 against the transverse direction Q along a track section 84 (see Figure 10) back into its first position L1. Thus, now the thermo-actuator 6 and the device 1 1 and the door lock 7 are back in the starting position, whereupon the above-described sequence of Entriegeins and opening the door 3 can be repeated. According to a further embodiment, the second spring tappet 81 and the second spring 37 can be dispensed with. In this case, a bevel, not shown, arranged on the second carrier part 29 acts on the actuator tappet 27 in such a way that the actuator torrent 27 is moved towards the end of its movement counter to the feed direction V in the first position L1.

Figure 1 1 shows the view of Figure 5 and illustrates an integrated overload protection. For example, if a child safety device is activated or an opening of the door 3 is otherwise prevented, for example, if a heavy object is in front of the door 3, the striker 13 can not move from its locking position shown in Figure 1 1, as in the present construction also always requires a certain opening movement of the door 3. In order to avoid damage to the device 1 1 and the door lock 7, the overload spring 62 is provided. This is compressed when the striker 13 can not move from its locking position to its unlocked position and at the same time the lever 44 is actuated by means of the Aktuatorstößels 27 in its second position L2.

Although the present invention has been described with reference to embodiments, it is variously modifiable.

For example, the control device 17 may be configured to unlock the door 3 during or after a drying program of the dishwasher 1 by correspondingly activating the thermoactuator 6. The touch sensor 16 is optional in this embodiment.

Likewise, it is also conceivable to replace the thermoactuator by another actuator which, in particular, similar to a thermoactuator, only allows a slow return movement of the working element.

Used reference signs:

1 dishwasher

2 rinse tanks

 3 door

 4 corpus

 5 joint

 6 actuator

 7 door lock

 1 1 facility

 12 cover

 13 locking element

14 recess

 15 seal

 16 sensor

 17 control device

21 recessed grip

 22 housing

 23 wax

 24 working pistons

25 coil

 26 feed axis

27 Actuator plunger

28 carrier part

 29 carrier part

 31 T-slot

 32 transverse axis

 33 cones

 34 survey

 35 closed track

36 first spring tappet

37 first spring

 40 stop

41 slope 42 slope

 43 railway section

44 lever

45 first end

46 second end

47 articulation point

51 slope

 52 scenery

 53 pestles

 54 end

 55 return spring

56 stirrups

 57 end

 61 pressure plate

 62 Overload spring

63 thighs

 64 spring

 65 end

 66 end

 67 housing

 71 hooks

 72 level

 73 door opening ram

74 railway section

75 levers

 76 distance

 77 railway section

81 second spring plunger

82 second spring

83 slope

 84 track section

Claims

Domestic appliance (1), in particular a dishwasher, with a door (3), an actuator (6), in particular a thermoactuator, for unlocking the door (3) and a device (1 1) which is designed to lock the door (3 ) from the actuator (6) to decouple.

Domestic appliance according to claim 1, characterized in that the device (1 1) is adapted to couple the actuator (6) with a door lock (7) for unlocking the door (3).

Domestic appliance according to claim 1 or 2, characterized in that the actuator (6) comprises a movable between an initial position and an open position working element (24), in particular a working piston (24 '), wherein a movement in the open position unlocking the door ( 3) and wherein a return movement from the opening position to the starting position lasts at least one second, in particular at least five seconds.

Domestic appliance according to claim 2 or 3, characterized in that the device (1 1) has a first and a second actuating element (27, 44), which are for conditioning against each other in conditioning and for decoupling out of engagement, preferably the first and second actuating element (27, 44) each between a first and second layer (L1, L2) are adjustable, wherein the first layer (L1) each a locked state of the door (3) and the second layer (L2) each in an unlocked state corresponds to the door (3), wherein the first and second actuating element (27, 44), when these are in each case in their second position (L2) for disengaging can be brought out of abutment, whereby a rear portion of the second actuating element (44) whose second layer (L2) is released in its first position (L1).

Domestic appliance according to claim 4, characterized in that the disengagement bring a displacement of the first actuating element (27) transversely to the feed axis (26) of the actuator (6), wherein preferably the device (1 1) a spring (37, 82) for the displacement of the first actuating element (27), wherein more preferably, the first actuating element (27) has a bevel (42) against which the spring (37) acts at least indirectly.

Domestic appliance according to claim 4 or 5, characterized in that the first actuating element (27) for insertion and dislocation on a closed path (35) is provided movably.

Domestic appliance according to claim 6, characterized in that the device (1 1) has a link (34) which cooperates with a link element (33) of the first actuating element (27) to define the closed path (35).

Domestic appliance according to claim 6 or 7, characterized in that the closed track (35) has a first and second track section (43, 77) along which the first actuating element (27) is adjustable by means of the thermal actuator (6), preferably the closed track (35) has third and fourth track portions (74, 84) interconnecting the first and second track portions (43, 77) and along which the first actuator (27) is adjustable by means of one or more springs (37, 82).

Domestic appliance according to claim 8, characterized in that the first actuating element (27) by means of the actuator (6) along the first web portion (43) from the first layer (L1) in the second layer (L2) in the feed direction (V) of the actuator ( 6) is adjustable, wherein the first actuating element (27) at least indirectly comes into abutment with a first spring (37) and the second actuating element (44) and thereby compresses the first spring (37) and the second actuating element (44) between the first and the second layer (L1, L2), wherein preferably the first spring (37), when the latter is in its second position (L2) along the third track portion (74) in the transverse direction (Q) Feed direction (V) of the second layer (L2) in a third position (L3) adjusted, wherein the first actuating element (27) out of engagement with the second actuating element (44) passes, wherein more preferably the first Betätigungsele ment (27) by means of the actuator (6) along the second path portion (77) from the third layer (L3) in a fourth position (L4) against the feed direction (V) is adjustable, wherein preferably the first actuating element (27) at least indirectly comes into contact with a second spring (82) and thereby compresses the second spring (82), wherein more preferably the second spring (82), the first actuating element (27 ), when this is in its fourth position (L4), adjusted along the fourth track portion (84) from its fourth position (L4) in the first layer (L1) against the transverse direction (Q).

10. Household appliance according to claim 9, characterized in that the device (1 1) has a stop (40) against which the first spring (37) abuts when the first actuating element (27) in its third position (L3) is located ,

1 1. Household appliance according to one of claims 4 - 10, characterized in that the first actuating element (27) is mounted transversely to the feed direction (V) movable on a working piston (24) of the actuator (6).

12. Household appliance according to one of claims 4 - 1 1, characterized in that a return spring (55) is provided which resets the second actuating element (44) from its second position (L2) in its first position (L1).

13. Household appliance according to one of claims 4 - 12, characterized in that the first and second actuating element (27, 44) for the investment bring each other corresponding bevels (42, 52).

14. Household appliance according to claim 13, characterized in that the first spring (37) by means of a plunger (36) acts on the first actuating element (27), which has a bevel (41), the bevel (42) of the first actuating element

(27).

15. Household appliance according to one of claims 4-14, characterized in that the second actuating element (44) is designed as a reversing lever and / or the second actuating element (44), in particular by means of an overload spring (62) on a locking element (13) of Door lock (6) acts.

16. Household appliance according to one of claims 2-15, characterized in that the door lock (7) has a striker (13), which by means of the actuator (6) from a locking position in which it engages positively in the door (3), against a spring (64) acting in the closing direction of the door (3) is adjustable into an unlocking position, in which it releases the door (3) for opening it and is positively secured against being reset by the spring (64), and Lever (75) which reverses the positive locking when closing the door (3), whereby the spring (64) actuates the striker (13) in the locking position and pulls the door (3) in the closing direction.