The present disclosure relates to a fitting for a door, and especially to an arrangement related to the functional components of the fitting.
In the area of fittings for doors, a common configuration of the fitting comprises a first part fastened to a door frame and a body fastened on a door.
In this type of construction, it is sometimes desirable to minimize the penetration of air, gas, or other substance between the door and door's frame. A common way to minimize the penetration of air or other substance is by the body part abutting the door, pressing towards the door frame when the door is in closed position. Another way to minimize the penetration of air is by using a distance element such as that disclosed in EP0754831 A1.
A particular problem with this type of construction is the need for different fittings for different doors and frames with different offsets.
Therefore, there is a need for an improved fitting which can be used to minimize the penetration of air or other substance despite the offset between the door and frame.
It is an object of the present invention to provide an improved solution that alleviates the mentioned drawbacks with present devices.
The invention is defined by the appended independent claims, with embodiments being set forth in the dependent claims, in the following description and in the attached drawings.
According to a first aspect of the invention, there is provided a fitting for arrangement to a door and a door frame, the fitting comprising a body, a first part configured to be arranged on a door frame, wherein the body is rotatably arranged to the first part, and a support plate arranged at a door facing side of the body and configured to abut the door when the fitting is arranged thereto. The fitting further comprises a distance element arranged in-between the support plate and the body and is moveable between at least a first position and a second position. The distance element provides, in the second position, an increased offset between the body and the support plate than in first position.
With this arrangement, the penetration of air or other substance can be minimized and one type fitting can be adapted to different types of doors with different offsets.
The support plate may abut the door and the force with which the door is pushed against the frame may be determined by the position of the distance element setting an offset between the support plate and the body. This may provide an offset between the fitting's attachment to the door and its attachment to the door frame. When closing the door, such offset may provide an increased pressure and tighter sealing between the door and the door frame compared to a fitting without offset.
The offset needed to achieve the desired pressure and sealing between the door and the door frame may vary and the distance element's position may be used to achieve this. As the distance element is moveable between the different portions the offset may be easily adjusted.
The present invention may be used in different kinds of fittings for doors, such as hinges, latches, handles and catches. In such embodiments, the body may be engageable with the first part by e.g. being rotatably arranged to the first part, lockable to the first part or otherwise engageable with the first part. The first part may further in such embodiments be e.g. a hinge part (such as a hinge pin part) or a striker engageable with the body of a latch, handle or catch.
In one embodiment, the distance element may be configured to offset the support plate and the body by setting a distance between the support plate and the body. The distance between the body and the support plate may be adjusted by moving the distance element between the first and second position. The offset and thereby the compression of the door to the door frame may be adjusted.
In another embodiment, the distance element may comprise at least a first and a second portion having different thickness, wherein the thickness of the first portion may set the distance between the support plate and the body when the distance element is in the first position, and the thickness of the second portion may set said distance when the distance element is in the second position. When less offset between the support plate and body is desired, a less thick portion of the distance element may be used and when a larger offset between the support plate and body is desired, a thicker portion of the distance element may be used. By moving the distance element between the first and the second position, different portions of the distance element may affect the offset between the body and the support plate.
In one embodiment, the distance element may further comprise a means for moving the distance element between the at least first and second positions. The moving means may protrude through the body such as to be accessible despite the distance element location in-between the support plate and the body. The different positions of the distance element may be used to adjust the distance between the support plate and the body. A thicker thickness of the distance element may push the support element away from the body towards a door and thus adjusting the fitting to allow it to be used on any door with different offsets between the door and door frame.
In one embodiment, the distance element may be movable by rotation. The distance element may be of a circle sectional shape and rotation of the distance element may allow for the distance element to be rotated from one position to another. Alternatively, the distance element may take rectangular shape or other shape suitable for thickness variation. The movement of the distance element between its different positions may be performed by moving the distance element for example by a linear movement.
The distance element may in a further embodiment be rotatable around the means for moving. Rotation of the distance element may be around the means for moving and may facilitate the action of shifting position of the distance element. A through hole for an axis of rotation may also occupy a limited amount of space on the body. The means for moving may comprise an adjustment screw. The distance element may be rotatable around the rotational axis of the adjustment screw. The adjustment screw may comprise a socket head cap screw, a screw head, a nut, or other means for rotation. The adjustment screw may be an integrated part of the distance element. Alternatively, the distance element may be linearly moveable and the means for moving may provide such linear movement.
In one embodiment, the distance element may be fixed by fastening means to the body and the support plate in any of the at least first or second position. Fixation of the distance element into a position may assure that the distance element does not move out of position and thereby changes the offset of the support plate relative the body unintentionally. The fastening means may be loosened such as to rotate the distance element to another position, for example to adjust to a different offset between a door and door frame, and the distance element may then be fixed in the new position.
The fastening means fixating the distance element into a first or second position may in one embodiment comprise a screw. The fastening means may be fixed from the body, through the distance element and into the support plate to secure the position of the distance element relative the support plate and/or the body. Alternatively, the fastening means may be fixed through the body, distance element, support plate, and into the door.
In one embodiment, the support plate may comprise a contacting part configured to protrude from the support plate and to abut the distance element in any of the at least first and second portions. The contacting part may serve as a point of contact between the support plate and the distance element to allow for a stable construction. The contacting part may abut the distance element in any position of the distance element. The contacting part may have a shape at least partly corresponding to the shape of the portions of the distance element. Such correspondence may provide a rigid contact between the two parts. The contacting part may be of a circle sectional shape and the angle of the sides of the shape may correspond to the angle of at least one of the sides of the portions of the distance element.
Further, in one embodiment, the support plate may comprise a first area and a second area, wherein the distance element is arranged in-between the body and the support plate at the first area of the support plate, wherein the second area of the support plate is in contact with the body. One area of the support plate in contact with the body may allow for the body and support element to be fixed to each other to enhance stability of the construction. The first area of the support plate in contact with the distance element, and the distance element being located in-between the body and the support plate may allow for the support plate, the distance element, and the body to be fixed to each other by using only one means of fixation, such as a screw. Additional fixation means may be provided in the second area of the support plate. The first area of the support plate may be fixed to the door directly or jointly fixed to the door and the body and/or the distance element. The second area of the support plate may be fixed to the door directly or jointly fixed to the door and the body. The first area of the support plate may be located closer to a door frame portion of the fitting than the second area, the door frame portion configured to be arranged to a door frame.
In one embodiment, a protruding surface configured to maximize the contact region between the body and the second area of the support plate may be arranged on the body or on the support plate.
As the distance element is moved to a position with a larger thickness, the support element is offset from the body, a protruding surface may serve to assure contact is maintained between the support plate and the body. The protruding surface may be located either on the support plate facing side of the body or on the body facing side of the support plate. The protruding surface may be located at the second area of the support plate. Fastening means may be configured to be arranged through the protruding surface to attach the body to the support plate.
In one embodiment, the protruding surface may have a cross-sectional form of a circle segment extending above the surface of the body or the support plate. A circle segmental form of the protruding surface may maximize the area of contact between the support plate and the body for any offset of the support plate relative the body. The offset of the support plate as the thickness elements distance increases may be a rotational movement. The axis of rotation may be around the highest point of the circle segment of the protruding surface. Due to the protruding surface's extension above the surface of the body or the support element, the axis of rotation is moved from an end edge of the support plate to a surface of the protruding surface. The area of contact between the support plate and the body is thereby maximized regardless of the distance between the support plate and the body set by the distance element.
In one embodiment, the body and the support plate may be configured to be fastened by use of fastening means to each other and/or a door. The support plate may be fastened to the body via the distance element and additionally the body and support plate may be fastened to each other by for example screws. The body and/or the support plate may further be fasted to a door by for example screws to assure a fixed position on the door.
In one embodiment, at least one fastening means is intended to extend through the protruding surface. The support plate may be fixed to the body by a fastening means such as a screw to assure that these are fixed to one another and no relative movement between these affect the support element's abutment of the door. The location for fastening may be through the protruding surface.
In one embodiment, a door facing side of the body may comprises a plane A wherein the support plate comprises a lower surface placed in plane A in at least one of the positions of the distance element and wherein the lower surface of the support plate is offset from said plane in at least one other position of the distance element. The offset of the support plate in relation to the body may be used to adjust the fitting to be compatible to different doors with different offsets between the door and the door frame. As the support plate is offset and extends through the plane A, the support plate abuts the door and further presses it against the door frame to minimize the flow of air or gas through the door and door frame. The first part of the fitting, configured to be attached to the door frame, may be coupled to the body. An offset of the support plate relative to the body may thereby provide an offset of the support plate relative to the first part and an offset of the fitting's attachment to the door relative to its attachment to the door frame.
In one embodiment, the fitting may be a hinge, the first part may be a hinge part configured to be arranged on a door frame, and the body may be rotatably arranged to the first part.
In one embodiment, the hinge may be a latching hinge and the latching hinge may comprise a handle which is rotatably arranged to the body such that the body may be released from the hinge part when the handle is in an unlatched position.
This and other aspects of the present invention now be described more in detail, with reference to the appended drawings showing a currently preferred embodiment of the invention.
The present invention will be described more fully hereinafter with reference to the accompanying drawings. In the drawings, like numbers refer to like elements.
The present invention is defined by the appended independent claim, and is in the following description and figures illustrated and described with reference to a latching hinge 1 according to an embodiment of the invention.
The latching hinge 1 according to an embodiment of the invention is illustrated in
In
An example of a body facing side of a distance element 5 according to the invention is shown in
The thickness t varies across the distance element 5, with a first portion p1 having a thickness t1 which may be less than a thickness t2 of a second portion p2. The thickness t2 is further smaller than a thickness t3 of a third portion p3 of the distance element 5.
The distance element 5 further comprises a setting screw head 52 for moving the distance element 5 between different positions of the distance element. The setting screw head 52 may be a socket head cap screw, a screw head, a nut, or other means for rotation. The setting screw head 52 protrudes through the body 3 such that the distance element 5 can be moved or rotated without exposing the body facing side of the distance element 5, as illustrated in
The different thicknesses t1, t2, t3 set the distance between the support plate 6 and the body 3. The distance element 5 may be moved between the positions by rotation or by a linear motion. The distance element is in the illustrated embodiment moved by rotation around the setting screw head 52. The position of the distance element may alternatively be shifted by for example linear vertical or horizontal movement of the distance element.
The distance element 5 may further be of a circular or circle sectional shape or of any other shape, such as a rectangular shape comprising different thicknesses in different portions of the element.
In
The protruding part 31 has a longitudinal extension and is positioned either on the support plate 6 or as illustrated on the body 3. The protruding part 31 has a circle segment profile to maximize the contact area as the support plate 6 and body 3 are rotated away from each other. The distance element 5 is positioned in a cavity 34 of the body 3 such that when the distance element 5 is positioned in a position with the thinnest portion p1 in contact with the support plate 6, the support plate 6 is in contact with the body 3 at the area next of the distance element. In such situation, the distance element 5 has no effect on the positioning of the support plate 6 relative to the body 3.
The support plate 6 is illustrated in
The distance element 5 has a protrusion 53 (see
Further, the support plate 6 comprises holes 61 screws 32 to attach to the body 3 and a hole 61′ for fixation to the body 3 via the distance element 5. The support plate 6 comprises a first area 6a and a second area 6b. The first area 6a may be in contact with the body 3 for a certain thickness of the distance element 5 and tilted away from the body 3 when the thickness t of the distance element 5 increases. The second area 6b of the support plate 6 is always in contact with the body 3.
A cross-section of the latching hinge 1 is illustrated in
In
The latching hinge 1 may be produced from plastics, metal, a combination of these of other suitable material and may be produced in separate parts for example by injection molding.
In the drawings and specification, there have been disclosed preferred embodiments and examples of the invention and, although specific terms are employed, they are used in a generic and descriptive sense only and not for the purpose of limitation, the scope of the invention being set forth in the following claims.
Number | Date | Country | Kind |
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16188882.1 | Sep 2016 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/073085 | 9/14/2017 | WO | 00 |