The invention relates to a household appliance device according to the preamble of claim 1.
Induction ovens are known from the prior art for example, which have a planar induction heating unit, which is fixed in an immovable manner to a muffle by means of a rivet connection and/or screw connection. However during a heating operation such an immovable fixing of the induction heating unit leads to stresses in the induction heating unit, in particular as a result of a thermal deformation of the induction heating unit and the muffle, by means of which on the one hand material stress is increased and on the other heating performance is reduced as a result of a changed distance between the induction heating unit and the muffle.
The object of the invention is in particular to provide a generic device with improved properties in respect of efficiency. According to the invention, the problem is solved by the characterizing features of claim 1, while advantageous embodiments and developments of the invention can be derived from the subclaims.
The invention is based on a household appliance device, in particular a cooking appliance device, with a fixing unit, which is provided to fix a planar unit to a base unit at least partially and in particular at least for the most part.
It is recommended that in at least an assembled state the fixing unit allows restricted movement at least of a part, in particular at least of a major part of the planar unit relative to the base unit in a direction of movement at least essentially parallel to a main plane of extension of the planar unit. By means of this embodiment a household appliance device with improved properties in respect of efficiency, in particular assembly efficiency, maintenance efficiency, material efficiency, performance efficiency and/or cost efficiency, can be provided. In addition, advantageous flexibility, in particular assembly flexibility and/or a flexibility of fixing, can in particular be achieved. Furthermore, operating safety and/or reliability can advantageously be improved. In addition component deformations and/or component stresses, for example component tensions and/or component wear, can advantageously be avoided, by means of which in particular downtime and/or durability can be improved.
In this connection a “household appliance device” should in particular be understood to mean at least a part, in particular a subassembly, of a household appliance. The household appliance is here advantageously embodied as a cooking appliance, in particular as a cooktop, as a grill appliance, as a microwave oven and/or preferably as an oven. The household appliance is particularly advantageously embodied as an induction cooking appliance, in particular as an induction cooktop, as an induction grill appliance, as an induction microwave oven and/or particularly preferably as an induction oven. In particular the household appliance device can also comprise the base unit and/or the planar unit. The word “provided” should in particular be understood to mean specially designed and/or equipped. That an object is provided for a particular function should in particular be understood to mean that the object fulfills and/or performs this particular function in at least one usage and/or operating status. In addition a “major part of an object” should in particular be understood to mean a part of the object which embodies at least 55%, advantageously at least 65%, preferably at least 75%, particularly preferably at least 85% and particularly advantageously at least 95% of a volume and/or mass of the object. Furthermore the expression “at least for the major part” should in particular be understood to mean at least 55%, advantageously at least 65%, preferably at least 75%, particularly preferably at least 85% and particularly advantageously at least 95%.
A “base unit” should further in particular be understood to mean a unit which defines and/or embodies at least one part and preferably at least a major part of the household appliance. The base unit is here advantageously embodied as a support unit and in particular provided to support the planar unit and particularly advantageously further objects. Furthermore a “planar unit” should here in particular be understood to mean a unit separately embodied from the base unit, which in at least one operating status is provided to carry out at least one function, in particular associated with the household appliance. The function can here be any desired function, such as for example a storage function, an insulation function, a barrier function, a lighting function, a heat conduction function and/or heating function. Furthermore the term “planar” should in particular be understood to mean an object in the case of which a largest lateral surface of a smallest, in particular notional cuboid, which only just completely encloses the object, is at least 50%, advantageously at least 100%, preferably at least 200% and particularly preferably at least 500% larger than a lateral surface of the cuboid which is arranged perpendicularly to each largest lateral surface. In addition in this connection a “fixing unit” should in particular be understood to mean a unit, advantageously at least partially separately embodied from the planar unit and/or the base unit, which is provided to connect the base unit and the planar unit to each other, in particular in a force- and/or form-fitted manner and advantageously by means of at least one rivet connection, at least one bayonet connection, at least one snap-in connection, one plug-in connection and/or at least one screw connection. To this end the fixing unit advantageously has at least one fixing element and preferably a multiplicity of fixing elements, which in particular can interact for an at least partial fixing of the planar unit and the base unit.
A “restricted movement” should furthermore in particular be understood to mean a movement in at least one direction of movement, which is limited to a predetermined, advantageously rectilinear movement path, in the direction of movement. The movement path is advantageously predetermined by a shape, size, orientation and/or arrangement at least of a movement-restriction element and/or stop element. In addition, the “main plane of extension” of an object should in particular be understood to mean a plane which is parallel to a largest lateral face of a smallest, in particular notional, cuboid, which only just completely encloses the object, and which in particular runs through a central point, in particular a geometric central point, of the cuboid. Furthermore, “at least essentially parallel” should in particular be understood to mean an orientation of a direction relative to a reference plane and/or a reference direction, in particular in a plane wherein the direction has a variance relative to the reference plane and/or reference direction in particular of less than 8°, advantageously less than 4° and particularly advantageously less than 2°.
In particular in order to achieve great flexibility, in particular great flexibility of movement, and/or to minimize vibrations and/or in particular component tension caused by thermal expansion, it is recommended that a maximum movement path of the part of the planar unit relative to the base unit in the direction of movement amounts to at least 1 mm, preferably at least 2 mm and advantageously at least 3 mm, and/or at most 10 mm, preferably at most 7 mm and advantageously at most 5 mm. A “maximum movement path” should in particular be understood to mean a largest value of a movement path of the restricted movement allowed by the fixing unit.
It is further recommended that in the assembled state the fixing unit allows a restricted movement at least of a first further part, in particular at least of a first further major part of the planar unit relative to the base unit in a further direction of movement at least essentially parallel to the main plane of extension of the planar unit and different to the direction of movement. Flexibility, in particular flexibility of movement and/or movability, can thereby in particular be increased, and/or vibrations, component tension and/or component deformations reduced. In particular the first further part of the planar unit and the part of the planar unit can be identical. Preferably however, the first further part of the planar unit is at least partially different from the part of the planar unit. The further direction of movement is preferably arranged at least essentially perpendicularly to the direction of movement. In particular a maximum movement path of the first further part of the planar unit relative to the base unit in the further direction of movement amounts to at least 1 mm, preferably at least 2 mm and advantageously at least 3 mm, and/or at most 10 mm, preferably at most 7 mm and advantageously at most 5 mm. In this connection the expression “at least essentially perpendicular” should in particular define an orientation of a direction relative to a reference direction, wherein in particular viewed in a plane the direction and the reference direction enclose an angle in particular between 82° and 98°, advantageously between 85° and 95° and particularly preferably between 88° and 92°.
It is additionally recommended that in the assembled state the fixing unit at least essentially fixes a second further part of the planar unit relative to the base unit, in particular different from the part of the planar unit and the first further part of the planar unit, in particular in the direction of movement and/or the further direction of movement. A movement of the planar unit can hereby in particular advantageously be monitored. Here “at least essentially fixes” should in particular be understood to mean a fixing in at least one direction with a maximum movement path of at most 0.5 mm, advantageously at most 0.2 mm and particularly preferably at most 0.1 mm.
In a further embodiment of the invention it is recommended that the fixing unit is provided to fix the planar unit to the base unit in a fixing direction oriented perpendicularly to the main plane of extension of the planar unit. An advantageously efficient fixing, in particular independent of the restricted movement, can thereby in particular be achieved. In particular the fixing unit is provided to regulate, in particular to limit and advantageously at least essentially to keep constant a minimal gap of the planar unit to the base unit. In particular the fixing unit can fix the planar unit to the base unit in the fixing direction with play, in particular of at most 2 mm, preferably at most 1 mm, advantageously at most 0.5 mm and particularly preferably at most 0.25 mm. Advantageously however the fixing unit is provided to fix the planar unit to the base unit in a form-fitted manner in the fixing direction. In this connection an “at least essentially constant gap” should in particular be understood to mean that a maximum value of the minimum gap is greater than a minimum value of the minimum gap by at most 50%, in particular at most 25%, advantageously at most 10% and particularly preferably at most 5%.
In particular in order to increase operating safety, it is recommended that the fixing unit consists at least partially of an electrically insulating material, in particular a plastic and/or advantageously a mica material. Here at least one surface layer of the fixing unit preferably consists at least for the most part and preferably completely of the electrically insulating material. Furthermore the surface layer of the fixing unit can in particular consist at least partially of a material that reduces static friction and/or dynamic friction.
In addition it is recommended that the fixing unit is embodied at least partially in one piece with the base unit. In particular a high level of stability and/or an advantageous assembly efficiency can hereby be achieved. In this connection that an object is “embodied at least partially in one piece” with a further object should in particular be understood to mean that the objects have at least one common component and/or at least one component of the object and/or the object is connected and/or embodied in one piece with at least one component of the further object and/or the further object. Preferably however all components of the object are embodied in one piece with at least one component of the further object. In this connection “in one piece” should in particular be understood to mean at least connected in a bonded manner and/or embodied with each other. The bonding can for example be created by means of an adhesive process, a spray process, a welding process, a soldering process and/or another process. In one piece should advantageously be understood to mean formed from one piece and/or in one piece. This one piece is preferably produced from a single blank, a mass and/or a casting, for example in an extrusion procedure, in particular a single- and/or multi-component extrusion procedure, and/or an injection molding procedure, in particular a single- and/or multi-component injection molding procedure.
In particular to enable a high level of efficiency and/or security of restriction of movement, according to a further embodiment of the invention it is recommended that the planar unit has at least one first stop element, in particular a first movement-restriction element, and the fixing unit at least one second stop element assigned to the first stop element, in particular a second movement-restriction element, which interact to restrict the movement of the planar unit. In particular the first stop element and the second stop element interact to restrict movement of the part of the planar unit and/or of the first further part of the planar unit relative to the base unit in the direction of movement and/or the further direction of movement. An impact of the first stop element on the second stop element advantageously brings about the restriction of movement. The first stop element is preferably embodied as a recess in the planar unit and comprises at least one part of the planar unit delimiting the recess. The second stop element is preferably embodied in the form of a bolt and advantageously arranged in such a way that in at least one assembled state the second stop element penetrates the first stop element in the fixing direction. Advantageously at least one, in particular exactly one, first stop element and at least one, in particular exactly one, corresponding second stop element, surrounded in particular free of play and/or in a form-fitted manner by the first stop element, interact to at least essentially fix the second part of the planar unit relative to the base unit.
It is further recommended that the planar unit has a multiplicity of, in particular at least three, advantageously at least four, preferably at least five and particularly preferably at least six first stop elements, arranged at a distance from each other, in particular first movement-restriction elements, which are differently embodied as regards size, shape and/or orientation. A movement can hereby in particular be advantageously monitored and/or oriented. In this case, the fixing unit in particular has a multiplicity of, in particular at least three, advantageously at least four, preferably at least five and particularly preferably at least six second stop elements, in particular second movement-restriction elements, in particular assigned to the first stop elements, which are advantageously embodied at least essentially identical to each other as regards size, shape and/or orientation. In this case the first stop elements are preferably embodied as recesses in the planar unit and comprise at least one part of the planar unit delimiting the respective recess, so that a size, shape and/or orientation of the first stop elements is correlated with an orientation and/or a maximum movement path of the restricted movement of the planar unit relative to the base unit. In particular in order to enable uniform and/or reliable monitoring of the restricted movement, viewed in the fixing direction the first stop elements are advantageously arranged distributed over the entire planar unit. Furthermore viewed in the fixing direction the second stop elements are preferably arranged distributed over the entire base unit.
It is further recommended that the household appliance device has the base unit, which is embodied as a muffle wall, preferably an oven muffle wall and advantageously an induction oven muffle wall. An advantageously efficient and/or flexible household appliance with a cooking compartment can hereby in particular be realized.
It is additionally recommended that the household appliance device has the planar unit, which is embodied as a heating unit, in particular a heating conductor unit and advantageously an induction heating unit. Efficient heating can in particular advantageously be achieved hereby. In this case the planar unit can preferably have at least one heating element, advantageously wound into a spiral form, in particular a heating conductor and advantageously an inductor, and/or at least one insulation element, preferably connected to the heating element and in particular planar in form. The insulation element is here embodied in particular as a thermally insulating and/or advantageously electrically insulating insulation element.
In order to improve operating safety and/or operational monitoring, it is further recommended that the household appliance device has at least one temperature sensor, which is connected to the fixing unit. Advantageously the temperature sensor is thermally coupled with the base unit and advantageously arranged in the area of the second part of the planar unit. Advantageously the temperature sensor is provided to record, to measure and/or to determine a temperature of the base unit in at least one operating status.
Further advantages emerge from the following description of the drawing. The drawing shows five exemplary embodiments of the invention. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually, and put them together into sensible further combinations.
Wherein:
The household appliance 10a comprises a household appliance device. The household appliance device comprises a muffle 11a embodied as an oven muffle. The muffle 11a is embodied in a rectangular shape. The muffle 11a is provided to delimit a cooking compartment 13a. To this end the muffle 11a has a multiplicity of muffle walls. In addition, the household appliance 10a comprises an external housing (not shown) and an appliance closure element (not shown). In the present case the appliance closure element is embodied as an appliance flap. The appliance closure element is provided to close the cooking compartment 13a. Alternatively, a muffle could delimit a multiplicity of areas, for example cooking spaces and/or storage spaces. Furthermore an appliance closure element could also be embodied as an appliance door.
In addition the household appliance device has a base unit 16a. The base unit 16a is at least essentially embodied in planar form. The base unit 16a is embodied as one of the muffle walls. In the present case the base unit 16a is embodied as an induction oven muffle wall. The base unit 16a is further embodied as a support unit. In the present case the base unit 16a is arranged above the cooking compartment 13a and therefore, viewed in the gravitational direction, arranged above the cooking compartment 13a in particular in an assembled state. A main plane of extension of the base unit 16a is further arranged perpendicularly to the gravitational direction.
Alternatively, a base unit could be embodied as an in particular electrical and/or thermal insulation unit, as a barrier unit, as an in particular electrical and/or magnetic shield unit, as a storage unit, as a heating unit, as a lighting unit and/or as a housing unit. In addition, in an assembled state it is conceivable to arrange a base unit underneath and/or to the side of a cooking compartment in the gravitational direction. Furthermore a main plane of extension of a base unit could be oriented parallel or at an angle to the gravitational direction.
The household appliance device additionally comprises a planar unit 14a. The planar unit 14a is embodied as a heating unit, in the present case in particular an induction heating unit. The planar unit 14a has two insulation elements 15a, 17a. The insulation elements 15a, 17a are embodied in planar form. Furthermore the insulation elements 15a, 17a outwardly delimit the planar unit 14a. The insulation elements 15a, 17a are provided to furnish electrical insulation of the planar unit 14a. In addition the planar unit 14a has at least one inductor (not shown). The inductor is embodied in planar form. The inductor is arranged between the insulation elements 15a, 17a. In addition, the inductor is connected to the insulation elements 15a, 17a. In the assembled state the planar unit 14a is arranged on the base unit 16a.
The planar unit 14a has at least one first stop element 24a, 26a, 28a. In the present case the planar unit 14a comprises a multiplicity of, by way of example sixteen, first stop elements 24a, 26a, 28a, wherein in particular in
Alternatively, a planar unit could be embodied as a heating unit embodied differently from an induction heating unit, for example a resistance heating unit. In principle it is also conceivable that a planar unit is embodied as an in particular electrical and/or thermal, insulation unit, as a barrier unit, as an in particular electrical and/or magnetic shield unit, as a storage unit, as a support unit, as a lighting unit and/or as a housing unit. Furthermore the planar unit could have a number of insulation elements other than two.
It is also conceivable that a planar unit comprises a number of first stop elements other than sixteen. In addition, a planar unit could have first stop elements which surround recesses only for the most part.
Additionally, the household appliance device comprises a fixing unit 12a. The fixing unit 12a is embodied in multi-part form. The fixing unit 12a is embodied at least partially in one piece with the base unit 16a. The fixing unit 12a consists at least partially of an electrically insulating material. The fixing unit 12a is at least provided to fix the planar unit 14a to the base unit 16a. The fixing unit 12a is provided to fix the planar unit 14a to the base unit 16a in a fixing direction 22a. The fixing unit 12a is further provided at least essentially to keep a minimum gap of the planar unit 14a to the base unit 16a constant. In the present case the fixing unit 12a fixes the planar unit 14a to the base unit 16a in the fixing direction 22a in a form-fitted manner.
The fixing unit 12a comprises a multiplicity of, in the present case sixteen, fixing subunits 23a, 25a, 27a, wherein in particular for the sake of clarity only three of the fixing subunits 23a, 25a, 27a are provided with reference characters in
A fixing subunit 23a of the fixing subunits 23a, 25a, 27a and a first fixing element 38a of first fixing elements 38a, 40a, 42a are now described below in greater detail below with reference to the
The fixing subunit 23a has a first fixing element 38a. The first fixing element 38a is embodied as an element in the form of a bolt. In the assembled state a longitudinal extension of the first fixing element 38a is arranged parallel to the fixing direction 22a. The first fixing element 38a is connected in one piece with the base unit 16a. In the present case the first fixing element 38a is welded to the base unit 16a. The first fixing element 38a here has a head section 41a on an end facing towards the base unit 16a, which is welded to the base unit 16a. In addition the first fixing element 38a has an external thread 39a on an end facing away from a base unit 16a. Alternatively, a fixing unit. a fixing subunit and/or a first fixing element could be embodied separately from a base unit. Furthermore, the fixing unit could be partially glued and/or soldered onto the base unit. A fixing subunit could additionally have a multiplicity of first fixing elements. It is also conceivable that a first fixing element is embodied as a rivet, as a snap-in element, as a spring element, as a stop element and/or as an internal thread element.
The fixing subunit 23a further has a second fixing element 44a. The second fixing element 44a is embodied separately from the first fixing element 38a. The second fixing element 44a consists of the electrically insulating material. The second fixing element 44a is embodied as a disk element, in particular as a washer. In the assembled state, the second fixing element 44a completely surrounds the first fixing element 38a. In addition, in the assembled state the second fixing element 44a is in contact with the planar unit 14a. The second fixing element 44a is here in contact with the planar unit 14a on a contact surface which is arranged parallel to a main plane of extension of the second fixing element 44a and/or of the planar unit 14a. Alternatively or additionally a fixing unit, a fixing subunit and/or a second fixing element could consist of a thermally insulating material. Furthermore a second fixing element could be embodied in one piece with a first fixing element, in particular embodied in one piece with a base unit, or be identical to the first fixing element. In addition, a second fixing element could be embodied as a rivet, as a bolt element, as a snap-in element, as a spring element, as a stop element, and/or as a threaded element, advantageously internal thread element, for example nut, and/or external thread element, for example screw element. In principle it is also conceivable that a fixing unit, a fixing subunit and/or a second fixing element, in particular at least a surface layer of the second fixing element, at least on a part thereof which is in contact with a planar unit, consists of a further material which reduces static friction and/or dynamic friction.
In addition the fixing subunit 23a has a third fixing element 52a. The third fixing element 52a is in the present case separately embodied from the second fixing element 44a. Furthermore the third fixing element 52a is separately embodied from the first fixing element 38a. In the present case the third fixing element 52a is embodied as a nut. In the assembled state the third fixing element 52a is arranged on the first fixing element 38a, in particular the external thread 39a. The second fixing element 44a and the third fixing element 52a interact in the assembled state to fix the planar unit 14a to the base unit 16a in the fixing direction 22a. The third fixing element 52a is here provided to transmit a compression force to the second fixing element 44a in the fixing direction 22a. In addition, the second fixing element 44a is provided to transmit the compression force to the planar unit 14a. Alternatively, a third fixing element could be embodied as a rivet, as a snap-in element, as a spring element, as a stop element, and/or as a threaded element differing from a nut, for example a screw element. In addition, a second fixing element and/or a third fixing element could have a rectangular or oval contact surface.
In the present case the fixing unit 12a further has at least one second stop element 30a, 32a, 34a assigned to the first stop element 24a, 26a, 28a. In the present case the fixing unit 12a comprises a multiplicity of, by way of example sixteen, second stop elements 30a, 32a, 34a, wherein in particular in the figures only three of the second stop elements 30a, 32a, 34a are provided with reference characters. Viewed in the fixing direction 22a, the second stop elements 30a, 32a, 34a are arranged at a distance from each other. In the present case the second stop elements 30a, 32a, 34a are identically embodied as regards size, shape and orientation.
Furthermore, each of the fixing subunits 23a, 25a, 27a has precisely one second stop element 30a, so that the description that follows is once again limited to the fixing subunit 23a, but in principle can also be applied to the other fixing subunits 25a, 27a. The fixing subunit 23a has the second stop element 30a. The second stop element 30a and the first fixing element 38a are identical in the present case. The second stop element 30a is embodied as a movement-restriction element. Further, in the assembled state the second stop element 30a penetrates the first stop element 24a assigned to the second stop element 30a in the fixing direction 22a. Alternatively, at least one second stop element could be differently embodied from a first fixing element. Furthermore a fixing unit could have a number of second stop elements other than sixteen.
In addition in the assembled state the fixing unit 12a allows a restricted movement of the planar unit 14a relative to the base unit 16a in a direction of movement 18a at least essentially parallel to the main plane of extension of the planar unit 14a. Furthermore in the assembled state the fixing unit 12a allows a restricted movement of the planar unit 14a relative to the base unit 16a in a further direction of movement 20a at least essentially parallel to the main plane of extension of the planar unit 14a. The direction of movement 18a and the further direction of movement 20a are arranged perpendicularly to each other. In addition, the restricted movement is embodied as a movement on a linear movement path. In the present case a difference in the magnitude of the thermal expansion of the base unit 16a and of the planar unit 14a brings about a movement of the planar unit 14a and the base unit 16a relative to each other. Through the restricted movable mounting of the planar unit 14a relative to the base unit 16a tensions and/or deformations of the planar unit 14a can thus advantageously be avoided and at the same time a consistent arrangement of the planar unit 14a on the base unit 16a can be achieved. A maximum movement path of the planar unit 14a relative to the base unit 16a amounts in the present case to at least 2 mm and at most 7 mm in the direction of movement 18a and in the further direction of movement 20a.
In order to achieve this restriction of movement, in the present case the first stop elements 24a, 26a, 28a and the second stop elements 30a, 32, 34a interact with each other. Here in particular one of the first stop elements 24a, 26a, 28a interacts in each case with a corresponding second stop element 30a, 32, 34a assigned to the first stop element 24a, 26a, 28a. In the present case an impact of the first stop elements 24a, 26a, 28a on the second stop elements 30a, 32, 34a brings about the restriction of movement. Furthermore the restricted movement is predetermined by an arrangement, shape, size and orientation of the first stop elements 24a, 26a, 28a and the second stop elements 30a, 32a, 34a. Alternatively, a fixing unit could allow a restricted movement of a part of a planar unit relative to a base unit in one direction of movement only. In addition, a movement path could be embodied differently from a linear movement path, for example as a curvilinear movement path. In principle it is also conceivable that a cause other than thermal expansion, for example a mechanical force, brings about a movement of a planar unit relative to a base unit.
In the present case in at least one assembled state a fixing unit 12b allows restricted movement at least of a part of the planar unit 14b relative to a base unit 16b in a direction of movement 18b at least essentially parallel to a main plane of extension of the planar unit 14b and at least of a first further part of the planar unit 14b relative to the base unit 16b in a further direction of movement 20b different from the direction of movement 18b which is at least essentially parallel to the main plane of extension of the planar unit 14b. In addition in the assembled state the fixing unit 12b fixes a second further part of the planar unit 14b relative to the base unit 16b. In the assembled state the fixing unit 12b here fixes the second further part of the planar unit 14b relative to the base unit 16b in the direction of movement 18b and the further direction of movement 20b.
The planar unit 14b comprises, by way of example, nine first stop elements 24b, 26b, 28b. The first stop elements 24b, 26b, 28b are differently embodied as regards size, shape and orientation. Viewed in a fixing direction 22b, the first stop elements 24b, 26b, 28b are arranged distributed in a matrix-like manner over the planar unit 14b.
In addition, the fixing unit 12b comprises nine second stop elements 30b, 32b, 34b assigned to the first stop elements 24b, 26b, 28b. The second stop elements 30b, 32b, 34b are identically embodied as regards size, shape and orientation. Viewed in the fixing direction 22b, the second stop elements 30b, 32b, 34b are arranged distributed in a matrix-like manner over the base unit 16b. The second stop elements 30b, 32b, 34b are connected in one piece to the base unit 16b.
A first stop element 24b of the first stop elements 24b, 26b, 28b is mounted free of play on a corresponding second stop element 30b of the second stop elements 30b, 32b, 34b. The first stop element 24b is embodied in circular form. The first stop element 24b and the second stop element 30b interact to fix the second further part of the planar unit 14b relative to the base unit 16b in the direction of movement 18b and in particular additionally in the further direction of movement 20b.
In addition, further first stop elements 26b, 28b of the first stop elements 24b, 26b, 28b are mounted with play on assigned further second stop elements 32b, 34b of the second stop elements 30b, 32b, 34b. In the present case the further first stop elements 26b, 28b are embodied in an elongated or circular form, wherein in particular a diameter of the further first stop elements 26b, 28b is greater than a diameter of the further second stop elements 32b, 34b. The further first stop elements 26b, 28b are provided, together with the further second stop elements 32b, 34b, to allow to a restricted movement of the planar unit 14b, in particular of the part of the planar unit 14b and of the first further part of the planar unit 14b, relative to the base unit 16b.
In the present case one of the further first stop elements 26b is provided to allow a restricted movement of the planar unit 14b relative to the base unit 16b in the direction of movement 18b, while another of the further first stop elements 28b is provided to allow to a restricted movement of the planar unit 14b relative to the base unit 16b in the further direction of movement 20b.
In the present case the household appliance device has a temperature sensor 36c, which is connected to the fixing unit 12c. The temperature sensor 36c is embodied as an electronic temperature sensor. For example the temperature sensor 36c is embodied as a resistance temperature sensor. To this end the temperature sensor 36c has a resistance wire 56c. The resistance wire 56c has a temperature-dependent ohmic resistance. The resistance wire 56c is enclosed by an electrically insulating cable insulation 58c. Furthermore the resistance wire 56c is attached to a first fixing element 38c with two third fixing elements 52c, 53c. Advantageously the temperature sensor 36c is arranged in the area of a second further part of a planar unit 14c. Furthermore the temperature sensor 36c is in particular thermally coupled with the base unit 16c. The temperature sensor 36c is provided to record, measure and/or determine a temperature of the base unit 16c in at least one operating status. Alternatively, a temperature sensor could however also be embodied as any temperature sensor known per se and other than a resistance temperature sensor.
In the present case a fixing subunit 23d of the fixing unit 12d has a first fixing element 38d embodied as a threadless bolt element. The first fixing element 38d has a notch 64d. The notch 64d is arranged in a central part of the first fixing element 38d arranged between a first end and a second end.
Furthermore the fixing subunit 23d has a third fixing element 52d embodied as a snap-in element. The third fixing element 52d has two wings 60d, 62d. During assembly the wings 60d, 62d engage in the notch 64d. Furthermore the wings 60d, 62d fix the third fixing element 52d in a fixing direction 22d. A first wing end 61d of a first wing 60d of wings 60d, 62d faces away from is the first fixing element 38d. Furthermore a second wing end 63d of a second wing 62d of the wings 60d, 62d faces away from the first fixing element 38d. The wings 60d, 62d are provided to exert a compression force on a second fixing element 44d in the fixing direction 22d.
In the present case a fixing subunit 23e of the fixing unit 12e has a first fixing element 38e embodied as a threadless bolt element. The first fixing element 38e has a notch 64e. Furthermore the fixing subunit 23e has a third fixing element 52e embodied as a snap-in element. The third fixing element 52e has two wings 60e, 62e. During assembly, the wings 60e, 62e engage in the notch 64e. Furthermore the wings 60e, 62e fix the third fixing element 52e in a fixing direction 22e. The wings 60e, 62e are provided to exert a compression force on a second fixing element 44e in the fixing direction 22e.
The notch 64e embodies a part of the first fixing element 38e facing towards the planar unit 14e. A first wing end 61e of a first wing 60e of wings 60e, 62e faces towards the first fixing element 38e. In an assembled state the first wing end 61e of the first wing 60e engages in the notch 64e. Furthermore is a second wing end 63e of a second wing 62e of wings 60e, 62e faces towards the first fixing element 38e. In the assembled state the second wing end 63e of the second wing 62e engages in the notch 64e.
Number | Date | Country | Kind |
---|---|---|---|
P201730374 | Mar 2017 | ES | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/IB2018/051555 | 3/9/2018 | WO | 00 |