The invention relates to a door closing mechanism for a hinged door arranged in a door frame which mechanism comprises a door fitting disposed on, or in, the door panel, a frame fitting arranged in, or on, the door frame, a final door closing movement arrangement which is disposed in the door fitting or in the frame fitting and a final door closing movement counterpart which is mounted to the frame fitting or, respectively, the door fitting.
In a brochure concerning folding door closers of Gretsch-Unitas GmbH, 71254 Ditzingen, dated Oct. 17, 2005, a door closer is described which is accommodated in the door panel area. To this end, a fitting including a closing spring acting on a lever drive is installed in a cut-out of the door panel. The lever drive output is a lever end to which a coupling rod is pivotally connected. The coupling rod is connected at its free end cardanically to a fixed point of the door frame. For closing the door, the lever pivots into the fitting while pulling the door into a closed position. However, a full closing of the door is not always ensured since the force of the closing spring is smallest specifically at the end of the closing path. Also, simple unhinging of the door is no longer possible.
It is the object of the present invention to provide a final closing mechanism for a hinged door which starts to pull the door to its closed position as soon as a fitting part of the door comes into contact with a fitting part of the door frame or a fitting part of the wall supporting the door.
This object is solved by the features of the main claim. To this end, the final door closing mechanism includes a closing catcher to which a closing pull element is connected or linked. The closing catcher is supported in a fitting and is moved along the fitting to a forward position in which it is held. The closing mechanism counterpart includes at least a tripping element which comes directly or indirectly into contact with the closing pull element when the door is being closed in order to fully close the door by a push movement of the closing catcher in combination with the closing pull element.
The closing catcher may be provided with at least one braking surface for damping the closing movement. The final closing pull mechanism includes to this end a pneumatic or hydraulic damping member which is arranged between the closing catcher and the fitting. The trip element has at least one contact flank which comes directly or indirectly into contact with the braking surface when the door is closed in order to slow down the movement of the door panel by an activation of the damping member.
This final closing mechanism is only activated when the slowed-down door is almost closed. As soon as the lock fitting of the door panel comes into contact with the door frame, the final closing pull mechanism is activated. Then the front edge of the lock fitting is—depending on the wall thickness of the door panel—at a distance from the door frame seal of only about 10-25 millimeters as shown in
In various embodiments, the final closing pull arrangement is integrated into a lock box which is installed in a door panel. But it may also be integrated into the fitting of a door frame. In that case, the trigger elements are mounted in, or on, the door panel.
The door closing mechanism closes any door whose movement is initiated for example by the type of the door mount. For initiating the closing movement, the pivot axis of the door panel may be slightly inclined with respect to the frame. Also, the facing front surfaces of the door hinges may extend helically around the post. Furthermore, the door panel may be supported on the door frame by way of a lifting rod arranged near the door pivot axis. In all three cases, the weight force of the door panel is used for closing the door. Alternatively, a floor door closer, an automatic door closer or a spiral spring accommodated in the door hinge in a tightened state may be used. These variants provide for the closing movement by way of pre-tensioned mechanical springs.
Further particulars of the invention are apparent from the sub-claims and the following description of schematically shown embodiments:
The
In this embodiment, a closing pull catcher (50), a nut (103) and a chain spring (108) with its support (109) are arranged in the lock box. The closing pull catcher (50), which is shown in the upper part of the lock box (40) is positioned above the pivot nut (103). The nut (103) is moved by a handle (100), (see
The closing pull catcher (50) can be divided into three sections. The first section is the head section (61). The latter is accommodated with play in, for example, the rectangular catcher opening (32) of the cover plate (31). The front area of the head section (61) is for example wedge-shaped. Its front surface (55) extends at an angle with respect to the lock bottom side (53) of, for example, 45°. A normal line on the front surface (55) extends opposite to the direction (9) of the door closing movement, that is, the front face (55) faces the overlap (11) of the door panel (10), see
The head section (61) has near the front surface (55), for example, two groove-like recesses (65, 66). In each case, one of the recesses (65, 66) ends at the upper side (51) and the lower side (52) of the closing pull catcher (50). Each recess (65, 66) has a wall (67, 68) extending with respect to the lock bottom side (53) at an angle of for example, 45°. In the embodiment according to
The head section (61) is provided at the lock bottom side (53) of the closing pull catcher (50) with an engagement ledge (69), see
The second section is the center section (71). It has, at least in the rear area near the pivot unit (103), a cutout (72) with two flanks (73, 83) of partial cylindrical shape, see
The center section (71) furthermore includes an elongated damper opening (74) which includes foam lock bottom side (53)—see
Between the elongated cam opening (76) and the head section (61), there is in the center section (71) on the lock bottom side (53) a dead end bore (78) in which a compression coil spring is disposed so as to form a front engagement spring (86). The front engagement spring (86), which is supported on the lock bottom (41), biases the closing pull catcher (50) toward the edge of the catcher opening (25), see
The foot section (81) is provided near the rear flank (83), at the cover side thereof, see
In place of the coil compression springs (86, 87) also flat leaf springs may be used which, dependent on their installation position, slide along the lock bottom (41), the lock cover (42) or the closing pull catcher (50).
From the foot section (81), for example, a central dead end bore (88) extends up to the head section (61). Within, the spring element (99) is disposed. It is supported between the base of the dead end bore (88) and a guide web (43) of the lock box. If expedient, several springs arranged in parallel are installed in the head section (61).
The lock box (40), which is for example an oblong thin-walled sheet metal box, a closing pull catcher (50) is supported so as to be longitudinally movable. The extended closing pull catcher (50) see
In
Spatially below the cut-out (72) of the closing pull catcher (50) the pivot nut (103) is disposed in a bore (48) of the lock bottom (41). Near the pivot nut (103), see
By way of the cover plate (31), that is, the front wall of the lock box (40), the lock box (40) is inserted into a cut-out (13) of the door panel (10) and is mounted therein, see
In
The recess (115) comprises mainly narrow parallel grooves (116, 117). Both grooves extend at an angle of 45° with respect to the front face (113) of the angled locking metal sheet (111). The flanks of the two grooves (116, 117) extend for example at least approximately parallel to the front face (55) of the closing pull catcher (50), see
The groove (117) has at the catcher side additionally a cut-out (118) of triangular cross-section, see
In accordance with
When now, upon closing of the door, the lock box disposed in the door panel moves with the closing pull catcher (50) retracted toward the angled locking sheet (111) and the catcher engagement element (112) of the door frame (20) in the door closing direction (9), first, in accordance with
By the contact, the closing pull catcher (50) is pivoted around the engagement edge (47) forming a fictive pivot axis counter to the pivot movement of the closing door, for example by an angle of 1 degree. By the pivot movement, the engagement ledge (69) is moved off the cover plate edge (33). The locking of the closing pull catcher (50) is eliminated. Via the spring element (99), the front section of the closing pull catcher (50) is moved out of the lock box in a damped manner. The closing flank (79) which is part of the closing-pull element (160) abuts the support flank (153). Both flanks (79, 153) are in the shown exemplary embodiment wedge surface which slide along one another as parts of a wedge drive. The closing pull flanks (79) and/or support flanks (153) can be coated with slip-coatings which have low friction coefficients.
When a door closes slowly, the outward movement of the closing pull catcher (50) provides a force which pulls the door panel (10) fully into the lock. In this process, the lock bottom side (53) of the closing pull catcher (50) slides along the engagement edge (47) of the stop (45) until the rear end surface (56) is disposed in front of the blocking flank (46) of the stop (45), see
If the door panel (10) is closed at a larger speed, for example if the door is rapidly closed with an impulse, the braking webs (63, 64) with braking surfaces (67, 68) slide along the contact flanks (123) of the trigger elements (121, 122) for braking the door. The movement is damped by the damper (90). In this case, the closing flanks (79) abut the support flanks (153) only when the movement of the door has been largely braked down.
The damper (90) may also be a pure friction damper. If desired, also several different damper operating principles may be realized in the damper (90).
The braking surfaces (67, 68) and/or the contact flanks (123) can be provided with special braking pads on brake pad coatings.
With the aid of rolling bodies, the slide movements between the slide friction pairings lock box (40)/closing pull catcher (50), closing pull flank (79)/support flank (153) and/or front surface (55)/support flank (154) can be converted to roller friction. Expediently in each of the pairings closing flank (79)/support flank (153) and/or front side (55) support flank (154) at least one flank is rounded spherically curved.
In order to again open the door, the handle (100) must be pushed down. Upon operating the handle (100), the nut cam (104) is pivoted clockwise in the elongated cam opening (76) see
In the door frame (20), the frame fixture (24) of the arrangement (30) is disposed in a recess (23). This frame fixture (24) is, in this case, a lock box (40). In the lock box (40) the closing pull catcher (50) is supported and guided between a lock box bottom (41) and a lock box cover (42).
The closing pull catcher (50) has a head section (61) which corresponds to a large extent to the variant as shown in
The angled locking sheet (111) is disposed in a recess (13) of the door panel (10). It includes a closing pull catcher opening (115) which is at least essentially in the form of the closing pull catcher opening of the variant shown in
Upon closing of the door, the door panel (10) moves in the direction (9) toward the door frame (20). The release element (121) projecting beyond the flange surface of the locking sheet (111) comes into contact with the braking web (63) of the closing pull catcher (50) as shown in
The spring element (99), that is a coil compression spring, moves the closing pull catcher toward the lock sheet, see
For opening the door, the closing pull catcher (50) is moved back to its locked original position, see
In the
Between the rear surface of the pull to closing pull trap (250) and the lock box (40), a spring element in the form of compression spring (99) is arranged.
The push lever (270) has a load arm (271) which in the shown embodiment has a length of about a quart of the length of the lever arm (273). The engagement spring (87) acts on the end of the lever which is disposed in the elongated groove (251). The other lever end has a joint eye (274), via which the push lever (270) is linked to the closing pull lever (260).
The closing pull lever (260), see also
The closing pull lever (260) according to
The closing pull lever (260) is pivotally and slidably supported in the lock box (40) with its joint bore (266) disposed on a bolt (249), see
In the
In accordance with
For opening the door, the operating handle (100) is pivoted down, see
In accordance with the
If the closing pull trap (250) is triggered while the door is open, that is, the closing pull lever (260) is in the closed position, the door can be closed in accordance with the
The
Of course instead of two- or multi-part mounting hinge structures also chisel mount hinges, screw-on hinges combination hinges or similar may be used.
The lower hinge part (301) consists of a stepped pivot pin (302), which is attached to the door frame for example via two smooth mounting bolts (313, 314). The bolts (313, 314) extend parallel to each other. The stepped pivot pin (302) is divided into a support part (303) and a support bolt (310). The mounting bolts (313, 314) extend from the support part (303) at a right angle. From the upper front face (305) of the support part (303), the cylindrical support bolt (312) projects centrally. The annular front face (305) of the support part (303) is wave-shaped.
The upper connecter part (321) comprises a pivot tube (323) and a mounting bolt (333). The pivot tube (323) which is provided with an end wall is disposed on the support bolt (312)—when the door panel is installed. The cylindrical inner wall of the pivot tube (323) forms together with the cylindrical outer wall of the support bolt (312) a friction pivot joint.
It is also possible to provide between the support bolt (312) and the pivot tube (323) roller bearings.
The lower axially loaded annular front face (305) has for example a shape corresponding to the wave-shape of the front face (325). If the cylindrical outer wall of the support part (304) is developed, the edge of the generated surface has a wave shape in which over 360 angular degrees two raised areas and two low areas are alternately formed. In each case, a raised area and a low area form a 180° section. The two 1800 sections are for example congruent. The raised area comprises two ramps (307, 308) with different inclinations. The long ramp (307) has an inclination of 15 angular degrees whereas the short ramp (308) has an inclination of 70 angular degrees. Depending on the type of door, these inclinations may be varied by +/−10 angular degrees. The long ramp 307 serves for lifting the door panel. It extends in the shown embodiment for example over 90 angular degrees of the opening pivot movement of the door panel.
The low area is in this case, a plane (309) or, respectively, a line of the developed annular wall. The line (309) extends normal to the pivot axis (2) of the door connector. The transitions between the ramps (307, 308) with respect to one another and with respect to the line (309) are rounded.
When the door is closed, see
If the door is pivoted open by an additional 45 angular degrees, see
Number | Date | Country | Kind |
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10 2006 002 952.6 | Jan 2006 | DE | national |
Number | Date | Country | |
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Parent | PCT/DE2007/000130 | Jan 2007 | US |
Child | 12220066 | US |