This invention relates to a mechanical door closure for double-acting doors and more particularly to a door in combination with a mechanical door closure.
Mechanical door closure devices that automatically return a double-acting door to a preferred center position are well known and are exemplified by the mechanisms illustrated and described in U.S. Pat. No. 4,951,351, issued Aug. 28, 1990 to A. Eckel; U.S. Pat. No. 4,945,606, issued Aug. 7, 1990 to A. Eckel; U.S. Pat. No. 4,124,955, issued Nov. 14, 1978 to A. J. Kochis; and U.S. Pat. No. 3,263,365, issued Aug. 2, 1966 to O. C. Eckel. Such devices are generally satisfactory, but have limitations. For one thing, they are lacking aesthetically. For another thing they comprise a cam and cam follower, and the latter requires a roller in engagement with the cam in order to allow the door to pivot freely between open and closed positions. The roller is subject to breakdown. A further limitation of the foregoing type of closure device is that return motion to center position tends to be uneven due to the contour of the cam.
The primary object of the invention is to provide a new and improved cam/cam follower type mechanical door closure device.
A further object is to provide new cam-type door-closing hardware that is strong, durable, and reliable.
Another object is to provide a cam/cam follower type of door closure that is adjustable to assure that the attached door will close automatically to a determinate position.
Another object is to provide a gravitationally-operated door-closing mechanism that has simplicity of construction, can be installed with minimum skill, and can be substituted for other prior art cam/cam follower door closure devices.
The foregoing objects are achieved by providing a door closing system that comprises first and second members each having a central axially-extending bore for receiving a door post and a helical end surface extending transversely of its center axis. The first member is adapted to be secured in spaced relation to a side of a door frame with its central bore extending parallel to that door frame side. The second member is adapted to be mounted on and secured to a door post that extends through and is rotatable in the central bore of the first member, with the helical end surface of the second member facing and engaging the helical end surface of the first member. The helical end surfaces coact with one another to gravitationally return a door attached to the door post to a closed position automatically after the door has been pushed opened and then released. Other features and advantages of the invention are described in or rendered obvious by the following detailed description of a preferred embodiment of the invention and the accompanying drawings.
In the several views like components are designated by like numerals.
Referring to
Referring to
The upper door mount also includes new cam-type door closure hardware comprising a first U-shaped metal bracket 42 and a second L-shaped metal bracket 44. The first bracket 42 fits in the upper corner formed by inner jamb 14 and lintel 16 and is fixed to those members by screw bolts 46. The second bracket is fixed to inner jamb 14 by additional screw bolts 50 and its horizontal arm 54 is spot welded to the horizontal arm 52 of bracket 42. Brackets 42 and 44 have holes, e.g., as shown at 43 in
Seated on lower arm 52 of bracket 42 is a first cam member 60A having at one end a flat surface 62 and at its other end an inclined helical cam surface 64 as hereinafter described in greater detail. The outer surface of cam member 60A is cylindrical. Cam member 60A is secured to bracket 42 by means of three screw bolts 66 that pass through aligned holes 53 and slots 55 in arms 52 and 54 and are screwed into tapped holes formed in the bottom end of the cam member. Cam member 60A has an axial bore 68 and a coaxial counterbore 70. The outer diameter of door member 40 is sized so that it makes a close but rotatable fit in bore 68. Counterbore 70 and the outer diameter of cam member 60A are sized so that the radial dimension of cam surface 64, measured between its inner and outer edges, is sufficient to assure a bearing surface that is adequate for supporting the weight of the door. By way of example but not limitation, cam member 60A has an outer diameter of about 2.375 inch, a diameter for bore 68 of about 1.250 to about 1.321 inch, a diameter for counterbore 70 of 1.500 inch, and a height of 2.500 inch measured between bottom surface 62 and the highest point of surface 64.
The upper door mount also includes a second cam member 60B that is mounted on the upper end of door post 40 and functions as a cam follower. Except as otherwise described hereinafter, cam member 60B is identical to cam member 60A, but is oriented so that its helically curved end face 64 faces counterpart surface 64 of cam member 60A. The upper end of door post 40 is formed with an exterior screw thread 41 and the surface defining the axial bore 68 of cam member 60B has a slightly smaller diameter than axial bore 68 of cam member 60A, but is formed with a screw thread whereby it can be screwed onto the upper end of the door post. The rotational orientation of cam member 60B on door post 40 is fixed by means of a set screw 78 that is screwed into a tapped, radially-extending hole in the cam member. The set screw may engage the door post thread directly. However, that entails the risk that the set screw will deform the thread and make it difficult thereafter to unscrew the cam member of to alter its rotational position on the door post. Therefore, a preferred practice is to lock the cam member 60B to the door post by the combination of a set screw 78 and a brass plug 79 (
Referring to FIGS. 2 and 4–6, the surfaces 64 of cam members 60A and 60B have a helical curvature and are flat between their inner and outer edges, with all co-radius points between those edges being equidistant from the corresponding flat end surfaces 62. As used herein with reference to surfaces 64, the term “helical curvature” denotes a helical curvature in relation to the longitudinal axis of the corresponding cam member, similar to the relationship of a screw thread to the axis of the shaft on which it is formed. As seen in
Referring now to FIGS. 1 and 8–10, the bottom mount comprises a U-shaped bracket 80 having two oppositely and outwardly extending side flanges 82 and bottom flanges 84 (only one each of flanges 82 and 84 is visible in the drawings) that are secured to inner jamb 14 and sill 18 by screw bolts 86. Welded to the upper end of bracket 80 is a top plate 88. Fixed in a hole in plate 88 is a tubular bearing 90 having peripheral flange 91 that engages plate 88. The latter rotatably accommodates a door post 92 that is a fixed extension of a U-shaped metal door bracket 94 that is similar to door bracket 30. Bracket 94 embraces opposite sides of door 20. The bracket is attached to door 20 by means of bolts 96 that extend through the door and are secured by nuts 98. The upper and lower door mounts are attached to the door so that door post 92 is axially aligned with door post 40.
Mounting the door is facilitated by the slots 56 and 58 in bracket arms 52 and 54. The door installation involves first attaching mounting brackets 42 and 44 and bracket 80 to the door frame as shown in the drawings. Then with brackets 30 and 94 attached to door 20, the bottom door post 92 is inserted in bearing 90 and door post 40 is moved into the slots 56 and 58 of brackets 42 and 44 respectively. Cam member 60A is then slipped onto upper door post 40 and attached to brackets 42 and 44 by means of screws 66. Alternatively and preferably, the rear screw 66 (the screw to the right in
If the door is not exactly in fully closed position when at rest, i.e., when the cam members are as shown in
The two cam members may be made of various materials, e.g., a metal such as steel or aluminum or a plastic or fiber-reinforced plastic. A primary requirement of the cam members is that they be strong enough to carry the weight of the door. Preferably the bottom cam member 60A is made of Delrin®, a product of E.I. DuPont de Nemeurs Company, while the upper cam member is made of Teflon®-impregnated hardcote anodized aluminum. The Teflon® impregnation reduces the coefficient of friction of the aluminum and the tendency of dirt or other materials to adhere to the cam member, thereby assuring satisfactory operation of the door closure hardware. As a second preference, the upper cam member is also made of Delrin®.
The invention is susceptible of other modifications. Thus, for example, the two short door posts may be replaced with a single door post that extends for substantially the full length of the door, e.g., in the manner disclosed in U.S. Pat. No. 4,951,351, cited supra. Also the invention may be practiced by using other means for attaching the cam hardware components to the door frame and the door post, and the number and type of screws or other fasteners used in connection with the cam hardware may be varied. The arm 54 of bracket 44 need not be spot welded to arm 52 of bracket 42. Another modification is to replace U-shaped bracket 42 with an L-shaped bracket that is attached to the side door jamb but not to the lintel. A further modification comprises installing the door closure hardware as part of the bottom mount instead of as part of the top door mount. Alternatively two sets of the same cam hardware may be used for a single door, one set as part of the top door mount and the other set as part of the bottom door mount. Also, although the illustrated embodiment comprises a single door in a door frame, the door closure hardware provide by this invention may be used in installations comprising double doors, i.e., two swinging doors mounted side by side in a single door frame. In this connection it should be noted that an important advantage of the cam hardware described herein is that it may be used for relatively heavy duty doors, e.g., doors in a warehouse. A further advantage is that it eliminates the need for the roller that is necessary in all “V” cam door closure hardware used on double acting traffic doors, e.g., the hardware shown in U.S. Pat. Nos. 4,951,351, 4,945,606, 4,124,955, and 3,263,365, all cited supra. Still other modifications and advantages will be obvious to persons skilled in the art from the foregoing description and the related drawings.
Number | Name | Date | Kind |
---|---|---|---|
424088 | Booraem | Mar 1890 | A |
454343 | Gibson | Jun 1891 | A |
1845477 | Bommer | Feb 1932 | A |
2840848 | Hickey | Jul 1958 | A |
3107758 | Benham | Oct 1963 | A |
3113649 | Wargo | Dec 1963 | A |
3134134 | Keator | May 1964 | A |
3147831 | Tansey | Sep 1964 | A |
3263365 | Eckel | Aug 1966 | A |
3384996 | Gilchrist et al. | May 1968 | A |
3545032 | Dielman | Dec 1970 | A |
3546736 | Booth | Dec 1970 | A |
4078334 | Lambias | Mar 1978 | A |
4124955 | Kochis | Nov 1978 | A |
4292764 | Kochis | Oct 1981 | A |
4570384 | Eckel | Feb 1986 | A |
4881353 | Braendel et al. | Nov 1989 | A |
4951351 | Eckel | Aug 1990 | A |
Number | Date | Country | |
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20040244293 A1 | Dec 2004 | US |