The present invention relates to door hinge. More particularly this invention concerns such a hinge that is recessable and adjustable.
A typical recessed hinge has two hinge parts adapted to be recessed, one in a door frame and one in an edge of a door panel. A link assembly extending between the hinge parts allows the door to pivot in the frame about a vertical axis, frequently through an angle of up to 180°. When the door is closed, such a hinge is normally completely concealed.
At least one of the hinge parts is provided with a mechanism that allows the hinge to be adjusted in three mutually perpendicular directions, that is front-to-back horizontally perpendicular to the vertical plane of the door frame, horizontally side-to-side parallel to this plane and perpendicular to the vertical pivot axis of the hinge, and vertically parallel to the hinge pivot axis. This way the door can be perfectly centered in the frame and, with the front-to-back adjustment, the amount of compression of a seal in the frame can be controlled. When at least two such hinges are provided with their pivot axes coaxial, it is also possible to ensure that the door is perfectly vertical or, if a closing or opening movement is desired, at a slight angle to the vertical.
Such a hinge that is fully concealed between the frame and the door when the door is closed and not visible on the outside of the door is typically used for doors for residential and office spaces as well as interior and exterior building doors. The doors may have considerable weight, and therefore the door hinges and their components must meet stringent requirements for dimensional stability and continual load. In principle, the hinge system is also usable for windows and other building closures.
Normally one of the hinge parts of this invention allows vertical adjustment of the door relative to the frame and also a front-to-back compression adjustment of the door whereas the other can be responsible for the other horizontal adjustment parallel to the door plane. The vertical adjustment as well as the compression adjustment of the door are of crucial importance for doors equipped with a recessed door hinge. For design reasons, recessed door hinges are frequently used in doors whose doors end in flush alignment with the door frame, with a reveal remaining between the door and the door frame. The door must be adjusted in such a way that the reveal has constant dimensions over the entire periphery of the door in the closed state. Even minor deviations are perceived as having an extremely unattractive appearance. The compression adjustment of the door as well as the vertical adjustment of the door must therefore work with high precision. During adjustment, the entire weight of the door must be borne by the hinge structure in order to precisely adjust the door position. After adjustment, all mutually movable parts must be fixed connectable to one another so that the door does not shift, even under continual load.
A hinge part for a recessed door hinge for doors is known from WO 2015/149495. It has a housing for fastening to a frame or door, a support body adjustably mounted in a cavity of the body, and a bearing block for connecting links of the link assembly. The bearing block has a rotatable pinion meshing with teeth on the support body, thus allowing a horizontal adjustment of the bearing block. Vertical adjustment of the door hinge is provided on another separate hinge part.
A recessed-mount door hinge between a door frame and a door is also known from U.S. Pat. No. 6,829,808. This door hinge also has a first hinge part and a second hinge part joined together by a link assembly. The two hinge parts are insertable into mortises in the door frame and in an edge of the door. Each of the two hinge parts has a housing for fastening to a frame or a door and bearing blocks for connecting links of the link assembly. Each of the bearing blocks of the first hinge part is vertically adjustable in a guide recess in the respective housing. The bearing blocks of the other hinge part are horizontally adjustably mounted in the respective housing. Adjusting eccentrics are provided for the horizontal adjustment as well as for the vertical adjustment. It is disadvantageous that the vertical adjustment and the lateral adjustment of the door must be carried out on different hinge parts. In addition, the precision of the adjustment, in particular the compression adjustment of the door, is still in need of improvement.
It is therefore an object of the present invention to provide an improved door hinge.
Another object is the provision of such an improved door hinge that overcomes the above-given disadvantages, in particular that allows biaxial adjustment for vertical adjustment of the door and for compression adjustment. In addition the hinge part according to the invention should allow precise compression adjustment of the door or window leaf, and must be suited in particular for heavy doors.
Another aspect is the combination with a device for vertical adjustment of the door to allow precise vertical adjustment while accommodating heavy loads.
A hinge according to the invention has two housings adapted to be recessed in a door frame and a door edge and a link assembly extending between the housings and having ends pivoted in the housings. A support body is vertically shiftable in one of the housings and has a row of teeth extending horizontally in a first direction, and a bearing block supported in the housing on the support body forms a pivot for the respective end of the link assembly and is formed with a seat open toward the row of teeth and with a throughgoing block hole extending in a second horizontal direction transverse to the first horizontal direction. A screw threaded into the support body extends through the block hole and is tightenable to bear on and fix the bearing block on the support body. A gear captured in the seat of the bearing block meshes with the row of teeth and is rotatable to shift the bearing block on the support body in the first horizontal direction in a loosened condition of the screw.
The bearing block is advantageously linearly movably guided on guide surfaces of the housing. Stepped surfaces or grooves that cooperate with a countersurface or a projection are suitable as guide surfaces. Within the scope of the invention, however, the screw connection may also be used to horizontally guide the bearing block on the support body. According to one preferred embodiment of the invention, the screw connection between the bearing block and the support body has two screws passing through horizontally oriented elongated holes in the bearing block. The screw connection allows a fixed, permanent connection between the bearing block and the support body. After the screw connection is loosened, the described arrangement may be used to linearly move the bearing block along the housing and adjust it. The pinion on its freely accessible end-face side has an externally accessible connecting formation for a rotary tool. Rotation of the pinion meshing with the teeth adjust the bearing block precisely in the horizontal direction for compression adjustment of the door.
The support body is preferably designed as a die-cast part, and advantageously has a projection formed with the row of teeth. According to one particularly preferred embodiment of the invention, a rear side of the projection facing away from the teeth has a wedge face acted on by a vertical adjustment device. The pinion for the compression adjustment of the bearing block and the wedge face for vertically adjusting the support body are integrated into the hinge housing in a space-saving manner. The arrangement is characterized by high dimensional stability.
According to the invention, vertical adjustment is effected by a wedge having a pressure face complementary to the wedge face of the projection integrally formed on the support body, and that may be pressed against the support body by an adjustment screw. The wedge face and the complementary pressure face advantageously have an inclination angle of approximately 45°. The actuating movement of the adjustment screw horizontally relatively shifts the wedge and the wedge-shaped projection formed onto the support body. The angled faces convert the horizontal movement into a vertical adjustment of the support body. The wedge is slides on a surface of the housing. As a result, the arrangement is able to carry out the vertical adjustment under load and accommodate the weight of a door which acts on the arrangement.
The support body is fixable to the body by a screw connection. The screw connection has at least one adjustment screw passing through a vertically oriented elongated hole in the support body. The vertical adjustment described above may be carried out after the screw connection is loosened. After the desired position is set, the support body and the body may be fixedly joined together by tightening of the screw connection.
The bearing block is preferably a die-cast part, and has a gear seat for the pinion gear. The gear seat surrounds the pinion by more than 180°. As a result of this arrangement, the pinion is supported in the correct position in the support body, using simple technical means. The pinion may have a collar engaging behind a countersurface of the bearing block and axially securing the pinion in the gear seat against horizontal movement perpendicular to a horizontal rotation axis of the pinion gear.
The bearing block is coordinated with the structural design of the link assembly. One advantageous embodiment of the invention provides that the bearing block has a groove for longitudinally guiding a first link, and a bearing hole for rotationally supporting a second link of the link assembly.
The housing may be a die-cast part, and preferably has the shape of a housing which has an installation space, open on the end-face side, for the support body and the bearing block.
A further aspect of the invention relates to a recessed-mount door hinge between a door frame and a door, having a first hinge part and a second hinge part joined together in an articulated manner by a link assembly. The two hinge parts are insertable into mortises in the door frame and into an edge of the door. The first hinge part, which is preferably mounted in a mortise in the door frame, has a hinge housing on its upper end and on its lower end which has the design described above. The links of the link assembly are supported on the bearing blocks of the two hinge parts.
According to one advantageous embodiment, the bearing blocks of the two hinge parts are situated on respective housings. The housings the two hinge parts situated therein form separate assemblies which are not connected to the middle part. This middle part may in particular be designed as a thin-walled shell having a base and at least one side wall, the side wall bridging the distance between the bearing blocks and having a height that corresponds to the depth of the mortise.
Within the scope of the invention, however, the first hinge part may also have a housing insertable into an associated mortise in the door frame or into the edge of the door, and the housings of the two hinge parts may be integral parts of the housing.
The second hinge part may have an adjustment device via which a bearing arrangement of the links of the link assembly is horizontally adjustable in the depth direction of the respective mortise. The door hinge may be adjusted in a second horizontal direction by using this adjustment device of the second hinge part. In addition to the above-described adjustment in the vertical direction and the horizontal direction for compression adjustment of the door, the adjustment device of the second hinge part also allows a so-called lateral adjustment of the door in order to laterally adjust the door.
The above and other objects, features, and advantages will become more readily apparent from the following description, reference being made to the accompanying drawing in which:
As seen in
The hinge housings 4 illustrated in
Each bearing block 8 is horizontally shiftable on the respective support body 6 in the x direction and can be fixed to the support body 6 by a screw connection 9. In this embodiment, the screw connection 9 is formed by two parallel and horizontal screws 10 extending in a horizontal y direction through the bearing block 8 and threaded into the support body 6, passing through respective horizontally elongated holes 11 in the bearing block 8. When loosened, the screw connection 9 allows horizontal movement of the bearing block 8 along the support body 6 in a horizontal direction x in order to adjust the contact pressure of the door against a door seal, the so-called compression setting.
As shown in
Movement of the adjustment screw 18 in the y direction exerts a vertical force vector in the z direction on the support body 6. The adjustment screw 18 passes through the hole 19 in the wedge face 14 of the projection 12 that is vertically elongated as a slot to permit relative movement between the wedge 16 and the support body 6 as is necessary for the vertical adjustment of the support body 6. The wedge 16 is supported on a flat horizontal face 20 of the housing 4. Vertical adjustment of the support body 6 is possible under load in that the wedge 16 can accommodate the weight of the door that is transmitted via the articulated joint connection of the link assembly 3.
The support body 6 can be fixed to the mounting flange 5 by a screw connection 21. The screw connection 21 has at least one adjustment screw 22 passing through a vertically elongated throughgoing hole 23 in the support body 6 and threaded into the housing 4. In this embodiment and according to one preferred design, two such adjustment screws 22 and respective holes 23 are provided.
The bearing block 8 has a rotatably mounted pinion gear 24 meshing with the teeth 13 of the short rack fixed on the support body 6, and can horizontally shift the bearing block 8 on the support body 6 if the screw connection 9 is loosened. The bearing block 8 has a part-cylindrical seat 25 complementarily holding the pinion 24, and may be economically manufactured as a die-cast part. The gear seat 25 extends mostly around the pinion 24 through preferably more than 180°. The pinion 24 has a collar 26 engaging behind a countersurface of the bearing block 8 and axially securing the pinion 24 in the gear seat 25.
The bearing block 8 has a groove 27 for longitudinally guiding a first link, and a bearing hole 28 for bearing a second link in a rotatably movable manner.
The first hinge part 1 of the door hinge illustrated in
The second hinge part 2 of the door hinge illustrated in
Number | Date | Country | Kind |
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10 2015 116 192 | Sep 2015 | DE | national |
Number | Name | Date | Kind |
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5694665 | Strickland | Dec 1997 | A |
5701636 | Jahnke | Dec 1997 | A |
6829808 | Neukoetter | Dec 2004 | B2 |
7334293 | Erickson | Feb 2008 | B2 |
7552511 | Campbell | Jun 2009 | B2 |
7676887 | Chung | Mar 2010 | B2 |
8429794 | Tagtow | Apr 2013 | B2 |
20110296652 | Zhang | Dec 2011 | A1 |
Number | Date | Country |
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2015149495 | Oct 2015 | WO |
Number | Date | Country | |
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20170089108 A1 | Mar 2017 | US |