Patent Grant
10932324
Embodiments of the present invention relate to a flange assembly for securing a heating device to a fluid container of an appliance accommodating the fluid to be heated, in particular a domestic appliance. Embodiments of the present invention further relate to a heating system including such flange assembly.
More specifically, the present invention relates to a flange assembly for holding a heating device to a fluid container of an appliance accommodating a fluid to be heated, in particular a domestic appliance, comprising a flange unit arranged for being mounted to an opening of the fluid container by at least one fixing unit and having a non-sealing and a sealing position and being reversibly movable from the non-sealing to the sealing position and vice versa by means of the fixing unit for being configured to engage the opening of the fluid container in the sealing position, wherein the flange unit comprises a sealing element and a tensioning element, wherein the sealing element and the tensioning element are moveable relative to each other in an axial direction by means of the fixing unit such that the sealing element and the tensioning element can be pressed against each other, wherein the sealing element and the tensioning element are, in the sealing position, arranged to provide a sealing in a sealing direction perpendicular to the axial direction.
A flange assembly for securing a heating device according to the state of the art is described with reference to
Upon mounting the preassembled flange assembly 1000 in the mounting or installation opening of the fluid container of the domestic appliance (not shown), such as for example a washing machine or a dishwashing machine, nut 1045 is tightened upon pin 1040. As a result, tensioning element 1030 experiences a relative movement with respect to sealing element 1020 and compresses sealing element 1020 which is disposed between cover unit 1010 and tensioning element 1030. That causes the cross-section of sealing element 1020 to enlarge and to therefore seal off the entire system against the fluid container, while at the same time flange assembly 1000 is fixed to the mounting opening.
Flange assembly 1000 according to the state of the art suffers from disadvantages such as the large number of individual components, namely at least five, which comprise different materials and which are each to be produced separately. In addition, it is necessary to apply a relatively high force upon mounting flange assembly 1000 in order to ensure that flange assembly 1000 be securely sealed in relation to the container. For this reason, tensioning element 1030 has to be made of a robust and rigid material, such as a metal. By compressing massive elastic sealing element 1020, an undefined and thus unfavorable deformation of elastic sealing element 1020 occurs, such that a high force of compression is needed to compensate for the undefined deformation in order to ensure a secure sealing of flange assembly 1000 in relation to the container.
Moreover, by providing a massive sealing element 1020 and a metallic tensioning element 1030, high material costs occur. As generally flange assemblies or heating systems of that kind are subject to a high level of cost pressure, the number of components involved, the choice of material and the number of handling steps in pre-assembly and assembly to the fluid container have a great influence on the economic viability of the flange assembly or the heating system, respectively.
It has thus been an object of the present invention to provide a flange assembly and a heating system which, while affording the same or better efficiency and reliability, permit a reduction in manufacturing costs and provide for a predefined sealing in comparison with the previously known flange assemblies or heating systems.
In one embodiment, the present invention relates to a flange assembly for holding a heating device to a fluid container of an appliance accommodating a fluid to be heated, in particular a domestic appliance, comprising a flange unit arranged for being mounted to an opening of the fluid container by at least one fixing unit and having a non-sealing and a sealing and attachment position and being reversibly movable from the non-sealing to the sealing and attachment position and vice versa by means of the fixing unit for being configured to engage the opening of the fluid container in the sealing and attachment position, wherein the flange unit comprises a sealing element and a tensioning element, wherein the sealing element and the tensioning element are moveable relative to each other in an axial direction by means of the fixing unit such that the sealing element and the tensioning element can be pressed against each other, wherein the sealing element and the tensioning element are, in the sealing and attachment position, arranged to provide a sealing in a sealing direction perpendicular to the axial direction, wherein the sealing element and/or the tensioning element of the flange unit comprise at least one tapered portion, wherein the tapered portion is arranged such that the relative movement of the sealing element and the tensioning element in the axial direction causes a predefined displacement of the tapered portion in the sealing direction.
Since the sealing element and/or the tensioning element of the flange unit comprise at least one tapered portion, upon relative movement of the sealing element and the tensioning element in the axial direction, the tapered portion can be displaced in a sealing direction, which is preferably perpendicular to the axial direction. In other words, based on the geometrical shape of the tapered portion, it is possible to realize a predefined displacement of the tapered portion in response to the relative movement between sealing element and tensioning element. In other words, depending on the angle, shape or form of the tapered portion with respect to the axial direction, a transition between the axial direction and the sealing direction concerning the displacement of the tapered portion in the sealing direction can be adjusted. Thereby, it is advantageously possible to define, in particular predefine, the displacement of the tapered portion and therefore the sealing of the sealing element in the sealing and attachment position (or sealing position for short) in advance.
In this context, the axial direction preferably corresponds to an insertion direction in which the flange unit is mounted to or inserted into the opening of the fluid container.
In a different development, the tapered portion can present any arbitrary shape that allows a transmission from the relative movement in the axial direction to a displacement in the sealing direction perpendicular to the axial direction.
Preferably, the sealing position of the flange unit corresponds to a state, in which more pressure is applied between the sealing element and the tensioning element than in a state corresponding to the non-sealing position. Thereby, it is thus possible to employ the pressure applied in the sealing position for displacing the tapered portion.
In a further development of the flange assembly according to the present invention, the flange unit is made of a non-metallic material, wherein the sealing element is made of the same or of a softer non-metallic material than the tensioning element.
By providing the flange unit of the non-metallic material, costs and manufacturing effort can be reduced. Further, by providing the sealing element of the same non-metallic material or a softer non-metallic material than the tensioning element, displacement in the sealing direction implied by relative movement of sealing element and tensioning element in the axial direction preferably occurs at the sealing element and not the tensioning element.
The non-metallic material is preferably a plastic material. Since the non-metallic material is preferably a plastic material, material properties such as elasticity and the like can readily be selected. It is further preferred that the flange unit be manufactured by means of injection molding or a different process of manufacturing known in the art. Particularly injection molding allows for relatively complex forms and shapes to be easily and cost efficiently manufactured.
In one embodiment, the sealing element and/or the tensioning element comprise hollow sections.
Hollow sections in this context are sections surrounded by the respective element in at least four out of six possible orthogonal directions. By providing hollow sections, the respective section is not provided with material and the sealing element and/or the tensioning element can thus be manufactured using less material. The respective element and therefore the flange assembly can thus be manufactured of less material and thus less expensively. It should be noted that providing hollow sections and at the same time ensuring the defined sealing deformation is feasible due to the tapered portions providing the defined deformation upon the application of pressure thereon.
In a further development of the flange assembly according to the present invention, at least a part of the surface of the sealing element facing the tensioning element comprises a tapered sealing portion and/or at least a corresponding part of the surface of the tensioning element comprises a corresponding tapered tensioning portion, wherein the tapered sealing portion and/or the tapered tensioning portion are arranged such that the relative movement of the sealing element and the tensioning element in the axial direction causes a defined displacement of the tapered sealing portion and/or the tapered tensioning portion in the sealing direction.
Since in this development the tapered portion is provided at the surface facing the sealing element or the tensioning element, and not, for instance, on an opposite side thereof, the tapered portion is directly contacted by the other of the sealing element and the tensioning element upon movement of the two elements relative to each other. Thus, predefined stress and load between the tensioning element and the sealing element at the tapered portion and eventually the sealing can be achieved in an advantageous manner.
Preferably, the tapered portion is provided on both a surface of the sealing element and the tensioning element, such that the tapered portion of the sealing element contacts the tapered portion of the tensioning element upon relative movement therebetween. Since in this development the contacting surfaces correspond to each other, it is advantageously possible to predefine the displacement and eventually the sealing more precisely.
In a further development of the flange assembly according to the present invention, the outer peripheral wall portion is provided at an outer circumferential edge of the sealing element and the tensioning element, respectively.
In this development, the tapered portion is preferably located at the outer peripheral wall portion provided on an outer circumferential edge of the sealing element and the tensioning element, the tapered portion and thus eventually the realized sealing can be provided between the flange assembly and the opening of the fluid container of the appliance. In particular, if the flange assembly is mounted within the opening of the fluid container, the wall of the sealing element can abut the opening of the fluid container from an inner side thereof such that the tapered sealing portion displaced radially outwardly provides for a tight sealing between the flange unit and the opening of the fluid container.
Preferably, the wall of the tensioning element has a smaller circumference then the wall of the sealing element and abuts the wall of the sealing element from an inner side thereof. The respective wall portions preferably protrude axially in the axial direction on the radially outward edge of the sealing element and the tensioning element. Thereby, the wall of the sealing element is preferably supported against the opening of the fluid container in the radial direction by a part of the wall of the tensioning element.
Yet, in order for the tapered tensioning portion to be in the position corresponding to the tapered sealing portion in the axial direction, i.e., to overlay the tapered sealing portion upon projection in the axial direction, the tapered tensioning portion is directed radially outward from the wall portion of the tensioning element, such as to overlay the tapered sealing portion in the axial direction. In other words, it is preferred that the tensioning wall portion comprise a portion, corresponding to the portion farthest from the base portion of the tensioning element, having the same circumference and same shape as the wall of the sealing element but being axially displaced in the axial direction.
In a preferred development, the wall portion is provided at the complete or entire outer peripheral circumferential edge of the base portion of the sealing element and the tensioning element, respectively. Thereby, a tight sealing of the fluid container can be achieved about the entire peripheral circumference of the opening of the fluid container.
In a further development of the flange assembly according to the present invention, the flange unit comprises at least one through opening extending through the sealing element and the tensioning element in the axial direction.
Since the at least one through opening extends through the sealing element and the tensioning element it is possible for elements to be inserted into the fluid container through the flange unit in the axial direction.
In a preferred development, the through opening is arranged and provided for receiving and holding a heating device or a temperature sensor therethrough.
By receiving and holding or in other words securing a heating device or a temperature sensor in the through opening of the flange unit it is possible to provide the inside of the fluid container with the heating device or a temperature sensor, respectively.
In a further development of the flange assembly according to the present invention, the sealing element comprises a tapered portion surrounding the through opening and being arranged such that, in the sealing position, the defined displacement of the tapered portion in the sealing direction holds the heating device or the temperature sensor within the through opening.
Since the sealing element comprises a tapered portion that surrounds the through opening and that displaces in the sealing direction towards the heating device or temperature sensor inserted within the through opening, the inserted element can be tightened and fastened at its position within the through opening.
Accordingly, it is thus possible to securely receive and hold the heating device or the temperature sensor within the through opening, without need for further manufacturing or assembly steps.
In a further development of the flange assembly according to the present invention, the tapered portion comprises a sealing lip, provided at the inner peripheral surface of the at least one through opening.
By providing a sealing lip at the inner peripheral surface of the at least one through opening in the tapered portion of the sealing element, the elements inserted through the through opening, such as the heating device or the temperature sensor, can be readily sealed such that no fluid from the inside of the fluid container can leak to the outside thereof. Advantageously, by providing the sealing lip, no use of glue, adhesive etc., which would require additional manufacturing or assembly steps, becomes necessary.
Preferably, the sealing lip is configured as an O-ring sealing lip. An O-ring sealing is widely recognized as a well-known and secure form of a sealing which provides a reliable seal. Moreover, the displacement of the tapered portion can account for an additional sealing in addition to the O-ring sealing in one development.
In a further development of the flange assembly according to the present invention, the sealing element comprises a fixing unit opening and the tensioning element comprises a blind hole at corresponding positions along the axial direction for receiving at least part of the fixing unit therein.
Since the blind hole is formed in the tensioning element, no liquid connection is created from the front surface of the sealing element through the fixing unit openings of the cover unit and the sealing element to the inside of the fluid container. In other words, the blind hole is provided such that no liquid from the inside of the fluid container can leak to the outside despite the provision of the fixing unit.
Preferably, the blind hole is configured as a tapped blind hole. As the blind hole is configured as a tapped blind hole, part of the fixing unit provided within the tapped blind hole can be provided with a corresponding thread such that the relative movement of sealing element and tensioning element and thus the transition from non-sealing to sealing position of the flange unit can easily be realized by means of the tapped blind hole cooperating with a corresponding part of the fixing unit.
In a further development of the flange assembly according to the present invention, the fixing unit is arranged to provide a sealing in a sealing direction parallel to the axial direction.
In a further development of the flange assembly according to the present invention, the sealing element comprises a tapered portion around the fixing unit opening which is arranged to displace radially to the inside of the fixing unit opening upon relative movement between the sealing element and the tensioning element.
By providing the tapered portion around the fixing unit opening, also the fixing unit provided within the fixing unit opening can be tightened in case the sealing element and the tensioning element are moved towards each other. In other words, the tapered portion around the fixing unit opening accounts for a secure retaining of the fixing unit in the sealing position of the flange unit.
Preferably, the tapered portion displaces radially to the inside of the fixing unit opening by pressure applied from a corresponding tapered portion of the tensioning element. By providing a corresponding tapered portion of the tensioning element, it is advantageously possible to precisely define the retaining force applied by the tapered portion radially to the inside of the fixing unit opening of the sealing element.
In a further development of the flange assembly according to the present invention, the tensioning element comprises at least one support wall portion that extends radially outward from the blind hole for transferring pressure applied by the fixing unit at the blind hole over the tensioning element.
Since the tensioning element comprises at least one support wall portion that extends from the blind hole radially outward and transfers or distributes pressure applied to the tensioning element by the fixing unit, more precisely pressure applied at the blind hole of the tensioning element, no massive tensioning element is needed. It is thus advantageously possible to save material, weight and thus cost of the entire flange assembly. In other words, the support wall portion allows for the base portion of the tensioning element to be provided with less thickness in the axial direction, as pressure induced by the relative movement between tensioning element and sealing element, which could bend the base portion without the provision of a support wall portion, gets transferred to the radially outward positions with reference to the blind hole, by means of the support wall portion without bending the base portion of the tensioning element. It is thus possible to efficiently spread and distribute the pressure applied by the fixing unit over a larger portion of the tensioning element, preferably the entire tensioning element.
In one development, the sealing element is formed as a single piece and the tensioning element is formed as a single piece. However, in other developments the sealing element and the tensioning element can be formed as a single piece integral flange unit or the tensioning element and/or the sealing element can be formed of multiple pieces, respectively.
In a further development, the flange assembly according to the present invention comprises a cover unit provided in front of the flange unit in the axial direction, such that the sealing element is located between the cover unit and the tensioning element.
By providing a cover unit, it is possible to tension the sealing element between the cover unit and the tensioning element. The cover unit can thus provide support for the sealing element for pressure applied on the sealing element by the fixing unit.
In a further development of the flange assembly according to the present invention, the cover unit comprises through openings at positions corresponding to any through holes or blind holes formed in the flange unit.
In this development, the cover unit is preferably placed on the outside of the fluid container on the sealing element and eventually on the tensioning element in the axial direction. By comprising through openings at positions corresponding to any through holes or blind holes formed in the flange unit, such as a heating device insertion opening, a temperature sensor insertion opening and a fixing unit through opening, the respective elements or devices can be readily provided and inserted without difficulties, even if the cover unit is provided on top of the flange unit.
In a further development of the flange assembly according to the present invention, the sealing element is arranged to be pressed against the cover unit in the sealing position.
Preferably, the sealing element comprises at least one tapered portion provided adjacent the cover unit.
By providing at least one tapered portion adjacent the cover unit, a defined displacement of the tapered portion in the sealing direction can also be employed at the contacting surface of sealing element and cover unit. Advantageously, an improved sealing connection thus results also between the sealing element and the cover unit.
In a further development of the flange assembly according to the present invention, the fixing unit comprises a ground connecting element for connecting the flange assembly with ground.
In a further development of the flange assembly according to the present invention, the cover unit comprises an outer circumferential side wall, having a larger diameter than the flange unit. In this development, the flange unit preferably comprises a supporting portion arranged for contacting the appliance in the axial direction when mounted.
In other words, the flange assembly is arranged for being mounted to the opening of the fluid container from the outside of the fluid container in the axial direction. Upon tensioning the tensioning element against the sealing element, a sealing between the flange assembly and the opening of the fluid container is formed in the sealing direction perpendicular to the axial direction. Upon mounting the flange assembly, before tensioning, the supporting portion formed in the sealing element contacts the opening of the fluid container or the like of the appliance in the axial direction. Accordingly, the supporting portion is formed radially outwardly protruding from the side wall of the supporting element, which is arranged for contacting the opening of the fluid container in the sealing direction. Since the cover unit has an outer circumferential side wall with a larger diameter than the flange unit, the supporting portion can easily be formed in the space between the side wall of the flange unit, respectively the sealing element thereof, and the side wall of the cover unit.
In a further development of the flange assembly according to the present invention, the fixing unit is resilient, and the fixing unit preferably comprises at least one of a self-tapping screw, a threaded screw, a threaded bolt and nut, a knee lever, a speed nut and a snap connector.
By providing a resilient fixing unit, it is easily possible to dismount and loosen the flange assembly from the fluid container, such as for maintenance purposes or the like. With the selection of the particular fixing unit, particular needs of the application, such as easy and fast mounting and dismounting, replacement, and the like, can be accounted for.
In a further development of the flange assembly according to the present invention, a protruded portion is provided at the sealing element to engage with the tensioning element. The protruded portion ensures that the sealing element engages with the appliance wall as well as the tensioning element in the sealing position even if the appliance wall is beveled to ease mounting of the assembly components. The protruded portion compensates the missing material of the appliance wall.
Preferably, the tensioning element comprises a corresponding grooved portion in which the protruded portion of the sealing element can engage in the attachment position. In this arrangement the sealing element is to be clamped onto the tensioning element during assembly.
In a different embodiment of the invention, a heating system is provided including at least one heating device for heating a fluid, in particular in a domestic appliance, a flange assembly according to the present invention for holding the heating device, and a fluid container for accommodating the fluid to be heated by the heating device, wherein the fluid container has at least one through opening for passing the heating device therethrough and for mounting the flange assembly.
Since the heating system according to this embodiment is provided including the flange assembly according to the present invention, all the advantages and benefits of the flange assembly described above are also present in the heating system of this embodiment. In particular, the heating system according to the present invention allows for a more cost-efficient heating system, since no metallic sealing and tensioning elements are needed. Further, the mounting and dismounting of the flange assembly to and from the heating system is improved with respect to the prior art heating systems, since no huge sealing force is to be applied to the fixing unit. Finally, also a more reliable sealing is achieved due to the predefined and predetermined displacements of the flange unit towards the fluid container providing the seal between inside and outside of the fluid container.
Further advantages and preferred embodiments of the present invention will be described in the following together with the drawings listed below.
In the drawings:
First, an exemplary flange assembly 10 for securing a heating device (not shown, except partially in
The exemplary flange assembly 10 comprises a flange unit 20, a fixing unit 30 and a cover unit 40. Flange unit 20 comprises a sealing element 50 and a tensioning element 60. In an axial or insertion direction A, which corresponds basically to an axial direction of fixing unit 30 from a surface side of cover unit 40 to the rear of flange assembly 10, cover unit 40 abuts sealing element 50, which abuts tensioning element 60, respectively.
Fixing unit 30 comprises in this example a screw 31 for linking and tensioning sealing element 50, tensioning element 60 and possibly cover unit 40 as will be detailed below. A ground connecting portion 34 is provided in proximity to screw 31 for connecting flange assembly 10 to ground.
On the front surface of cover unit 40, which is the surface side to be provided outside the fluid container of the appliance to which flange assembly 10 is arranged for being mounted, cover unit 40 comprises a substantially flat base plate 42 with a rounded rectangular shape. An outer peripheral side wall 45, which extends in axial direction A towards the rear of flange assembly 10, is linked to the outer circumference of base plate 42 via rounded edge 46. Cover unit 40 preferably comprises a plastic material, such as a thermosetting plastic or polymer, which can be manufactured, for instance, by injection molding or a different suitable process known in the art. However, also different materials, such as materials comprising or consisting of metal or thermoplastic components, are considered.
Behind and adjacent to cover unit 40 in axial direction A, sealing element 50 and tensioning element 60 are provided. In
As mentioned above, flange assembly 10 is shown in a non-sealing position. Therefore outer peripheral side wall 55 smoothly migrates to outer peripheral side wall 65, such that a substantially homogeneous outer peripheral surface of sealing element 50 and tensioning element 60 is formed.
Through openings 18, through which another component, such as the heating element or heating device which is to be secured or held to the fluid container of the appliance, can be inserted, are formed through flange assembly 10 in axial direction A. At the positions corresponding to through opening 18, two heating device mounting openings 48a for inserting a heating device (not shown) there through and a temperature sensor opening 48b, through which a temperature sensor (not shown) is insertable, are respectively provided in cover unit 40.
Flange unit 20 and thereby sealing element 50 and tensioning element 60 comprise openings or through holes at positions respectively corresponding to heating device openings 48a and temperature sensor opening 48b of cover unit 40 in axial direction A, such that the respective elements can readily be inserted through cover unit 40 and flange unit 20.
It should be noted that peripheral side wall 45, peripheral side wall 55, and peripheral side wall 65 are preferably provided about the entire circumferential edges of cover unit 40, sealing element 50 and tensioning element 60, respectively.
From a backside of tensioning element 60, which is the side opposite to the side adjacent to sealing element 50 in axial direction A, a fixing unit receptacle 63 can be seen, which is provided substantially in the center and spreading therefrom towards the outer circumferential side wall 65 there are provided four support wall portions 66. Screw 31 of fixing unit 30 is inserted from the front surface of base plate 42 into fixing unit receptacle 63. Support wall portions 66 stabilize tensioning element 60 and account for a transfer and distribution of any pressure applied by fixing unit 30 to fixing unit receptacle 63 over the entire tensioning element 60.
Further to the elements indicated and illustrated in
Surrounding screw 31, a thread 36 and a thread 38 is formed in sealing element 50 and tensioning element 60, respectively. Threads 36, 38 are in this example provided at the time of manufacturing into sealing element 50 and tensioning element 60, respectively.
It can be seen from
Outer peripheral side wall 55 includes a tapered portion 51 at or near the end thereof, which is the part of outer peripheral side wall 55 having the largest distance from cover unit 40 in axial direction A. The tapered direction is such arranged that tapered portion 51 becomes thinner from the radial inside to the radial outside towards the rear of flange assembly 10 that is with increased distance from cover unit 40.
Outer peripheral side wall 65 is formed parallel and abuts outer peripheral side wall 55 in a first section thereof, namely the foremost section of outer peripheral side wall 65. This first section parallel to outer peripheral side wall 55 of outer peripheral side wall 65 is approximately the same length as the outer peripheral side wall 55. However, outer peripheral side wall 65 is not planar over its entire extension, but presents outwardly directed tapered portion 61 at an axial position approximately corresponding to tapered portion 51 of sealing element 50. Further to the rear of flange assembly 10, there is provided a portion of peripheral side wall 65 protruding coaxially with outer peripheral side wall 55 in axial direction A.
Sealing element 50 comprises further tapered portions 57 and 59. Tapered portions 57 are provided in a front area of flange assembly 10, i.e., on the surface side of sealing element 50 contacting cover unit 40. Tapered portion 59 is provided surrounding fixing unit opening 54. Corresponding to tapered portion 59, there is also provided a tapered portion 69 in the tensioning element 60, surrounding blind hole 64 on the front side of tensioning element 60.
It can be seen from
More specifically, tapered portion 51 and tapered portion 61 are in this example provided on outer peripheral side wall 55 and outer peripheral side wall 65 and thus over the entire circumferential edge of sealing element 50 and tensioning element 60, respectively. By overlaying tapered portion 61 over tapered portion 51, outer peripheral side wall 55 and thus the circumference of sealing element 50 is widened and pressed against the surface of the opening of appliance 70 such that the sealing is formed, preferably a defined sealing over the entire circumference of sealing element 50.
Further, tapered portion 69 overlays tapered portion 59 and thus forces tapered portion 59 to displace and to apply a pressure. This pressure is applied in the sealing direction, radially inwards towards screw 31. Accordingly, tapered portion 59 provides a sealing between sealing element 50 and fixing unit 30 or screw 31, respectively. Thereby, also screw 31 is held in place, such that an unintended loosening of screw 31 can be prevented.
Furthermore, by tensioning screw 31, sealing element 50 is also tensioned against cover unit 40. Accordingly, by tensioning the tensioning element 60 against sealing element 50, tapered portions 57 are pressed against cover unit 40 and deform. In other words, tapered portions 57 provide a sealing between sealing element 50 and cover unit 40.
In this example, fixing unit 30 comprises exemplarily screw 31. However, as will be seen with reference to
Moreover, tapered portions of sealing element 50 and tensioning element 60 are shown to have substantially corresponding forms and shapes in this example. However, also different forms and shapes of tapered portions of sealing element 50 and tensioning element 60, respectively, are contemplated by the skilled person, as long as the relative movement of sealing element 50 and tensioning element 60 in axial direction A accounts for a defined displacement of said tapered portion in a sealing direction being substantially perpendicular to axial direction A.
In these figures, flange assembly 10 is shown mounted to appliance 70 and having heating device 80 inserted into through openings 18. Through openings 18 through which heating device 80 is inserted are formed by heating device openings 48a provided on base plate 42 of cover unit 40. Sealing element 50 and tensioning element 60 provide openings at positions corresponding to heating device openings 48a along axial direction A. Sealing element 50 comprises at the circumferential surface surrounding heating device 80 a tapered portion 59 and tensioning element 60 comprises at the position corresponding to tapered portion 59 of sealing element 50 a tapered portion 69. As can be seen from
Another through opening 18 is provided radially inward with respect to heating device openings 48a through which heating device 80 is inserted. This through opening 18 is formed by temperature sensor opening 48b on base plate 42 of cover unit 40. Sealing element 50 and tensioning element 60 provide openings at positions corresponding to the temperature sensor opening 48b along axial direction A. Similar to tapered portions 59 and 69, respectively provided at sealing element 50 and tensioning element 60 adjacent heating device opening 48a, there are provided tapered portions 59 and 69 about through opening 18 corresponding to temperature sensor opening 48b. Similar to heating device 80, a temperature sensor (not shown) can thus be securely received and sealed within temperature sensor opening 48b by the relative movement and force of tensioning element 60 applied against sealing element 50.
Although in this example a heating device and/or a temperature sensor is intended to be inserted through one or more of through openings 18, also different devices or elements can be inserted in different applications.
In this example, tapered portion 59 is provided in the shape of a partial dual cone, that is a tapered region is formed both on the front side, i.e., the side adjacent cover unit 40, and on the rear side, i.e., the side adjacent tensioning element 60.
In addition to the sealing force induced by tapered portion 59, in this example all openings surrounding through openings 18 formed in sealing element 50 for receiving heating device 80, a temperature sensor, or a different element, respectively, are provided with one or more sealing lip 58 at the inner circumferential surface of respective tapered portion 59. Sealing lip 58 is in this example formed as an O-ring and provides for a frictional seal between sealing element 50, more precisely tapered portion 59, and the respective elements inserted therein in addition to the seal provided by the radial displacement of tapered portion 59.
In this example, at least one sealing lip 58 formed as an O-ring is provided at each of the respective tapered portions 59. However, in other examples, sealing lips 58 are not necessarily provided, can be provided only at some of the respective openings, and/or can be formed by O-rings as in this example or by different sealing elements as known in the art.
In
In this example, tensioning element 60 is preferably formed of a plastics material. Further, sealing element 50 is preferably formed of an elastomeric material, such as a plastic elastomeric material. Preferably, both sealing element 50 and tensioning element 60 are manufactured by processing methods such as injection molding, as widely known in the art. However, also employing other materials and/or manufacturing processes are contemplated by the person skilled in the art.
Similar, another through opening 18 is formed closer to fixing unit 30 than heating device opening 48a, formed by temperature sensor opening 48b of cover unit 40 and corresponding openings in the lower sealing element 50 and tensioning element 60. The same sealing is formed as described with respect to heating device opening 48a, namely by tapered portions 69 applying force onto corresponding tapered portions 59 and by providing one or more sealing lips 58 at the inner circumferential surface of the opening in sealing element 50. Finally, blind temperature sensor opening 48c has no corresponding opening formed in base plate 42. The provision thereof is for reasons of symmetry of tensioning element 60, as described above.
On the rear side of flange assembly 10, which is the side tensioning element 60 is provided at, support wall portions 66 radially outwardly protruding from fixing unit receptacle 63 are shown. Fixing unit receptacle 63 forms the envelope of blind hole 64 for receiving fixing unit 30. Support wall portions 66 transfer the pressure and/or force applied by screw 31 of fixing unit 30 onto fixing unit receptacle 63 to outer peripheral side wall 65 of tensioning element 60. Thereby, support wall portions 66 equilibrate the tension among different portions of tensioning element 60. Further, due to support wall portions 66 the need for a massive tensioning element 60 is avoided. Accordingly, is possible to save material and thus cost of tensioning element 60 and the entire flange assembly 10.
In the first example described with reference to
Another embodiment of fixing unit 30 will be described with reference to
Although speed nut 300, snap connection 400 and screw 31 have been described as examples of the fixing unit for engaging sealing element 50 and tensioning element 60 at a predefined frictional pressure there between, also different fixing means or units are contemplated by the person skilled in the art.
In order to strengthen the positioning of the sealing element 50, the tensioning element 60 may be provided with more material wherever appropriate, in particular at the through openings 18 where the heating device is inserted. Furthermore, stiffening rips may be provided at the tensioning element 60.
The various embodiments described above can be combined to provide further embodiments. Aspects of the embodiments can be modified, if necessary to employ concepts of the various patents, applications and publications to provide yet further embodiments.
These and other changes can be made to the embodiments in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific embodiments disclosed in the specification and the claims, but should be construed to include all possible embodiments along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure.
| Number | Date | Country | Kind |
|---|---|---|---|
| 15179269 | Jul 2015 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2016/068288 | 8/1/2016 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2017/021351 | 2/9/2017 | WO | A |
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|---|---|---|---|
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| 4707590 | Lefebvre | Nov 1987 | A |
| 5033647 | Smith et al. | Jul 1991 | A |
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| 5892888 | Romero | Apr 1999 | A |
| 6192549 | Kasen | Feb 2001 | B1 |
| 6852963 | Jeong | Feb 2005 | B2 |
| Number | Date | Country |
|---|---|---|
| 100 62 539 | Sep 1960 | DE |
| 1 112 792 | Aug 1961 | DE |
| 1 851 911 | May 1962 | DE |
| 6 607 317 | Feb 1971 | DE |
| 1 952 282 | Apr 1971 | DE |
| 2 101 062 | Jul 1972 | DE |
| 26 10 512 | Nov 1976 | DE |
| 26 38 380 | Mar 1978 | DE |
| 36 21 295 | Jan 1988 | DE |
| 100 62 539 | Jun 2002 | DE |
| 0 086 465 | Aug 1983 | EP |
| 0 551 914 | Jul 1993 | EP |
| 1 111 962 | Jun 2001 | EP |
| 1111962 | Jun 2001 | EP |
| 1 278 121 | Jun 1972 | GB |
| Entry |
|---|
| Machine Translation EP1111962, 2001, performed Feb. 7, 2020 (Year: 2001). |
| Number | Date | Country | |
|---|---|---|---|
| 20180220492 A1 | Aug 2018 | US |
