The present invention relates to a device for urging a door into a closed or first position.
Devices for urging doors or the like into either closed or open positions are well-known in the art. It is frequently desired that a door should be kept in a closed position for safety, security or other reasons, and this is particularly true in elevator systems with respect to the landing doors.
In elevator systems, sliding doors are placed at each landing to secure the elevator hoistway during periods when the elevator car is not present at the landing. In this particular application, the mechanism for causing both the landing and car doors to open is mounted on the elevator car and moves vertically therewith. Upon arrival at a landing to be served, the elevator car doors and landing doors are engaged, and the opening mechanism drives both into the open position. Although this same mechanism also causes the doors to return to their closed positions upon completion of the loading and unloading of passengers, it is desirable that the landing doors include independent means or urging the doors into a closed position.
For space and other considerations, it is common to use a cable mechanism for driving the landing doors. One such mechanism known in the art utilizes a winding drum upon which the drive cable is wound and unwound as the door is slid closed and opened. A torsional spring, connected to the winding drum, provides an increasing torque on the drum as the cable, which is connected at one end to the landing door, is pulled off during opening. When the landing door is released, the spring winds the cable back on the drum, thereby pulling the landing door into the closed position.
One problem, however, with this prior art arrangement is that the torsional spring does not provide a uniform torque to the drum over the range of travel of the door. As will be apparent to those skilled in the art, a torsional spring will deliver the least torque when the door is in the closed or first position, and the most torque when the door is in the open or second position and the cable has been fully unwound from the winding drum. This variation in torque produces a similar variation in the restoring force imparted by the cable to the door. In order to open hoistway doors equipped with the torsional spring and cable apparatus of the prior art, it is necessary to provide a door opening mechanism with sufficient strength to overcome the highest force generated by the door closing apparatus. This results in a door opening mechanism which is much more powerful, heavier, and costly than desirable.
What is needed is a door closing device which provides a uniform closing force over the length of travel of the moving door, but which also retains the space and flexibility advantages of the prior art winding drum and cable device.
According to the present invention, an apparatus for driving a door to a first, closed position from a second, open position includes a cable, attached at one end to the door and at the other end to a spring apparatus for pulling the door toward the first position. The spring apparatus includes a winding drum with a conical outer peripheral surface, whereby the cable is wound up on a progressively decreasing diameter surface as the door is pulled to the first position. A torsional spring drives the winding drum, imparting the greatest torsional force when the cable is fully unwound, and the least torsional force when the cable is fully wound and the door is in the first, closed position.
By matching the increasing diameter of the cable winding point on the winding drum with the correspondingly increasing torque imparted by the torsional spring, the apparatus according to the present invention provides a consistent linear urging force to the cable and door in the direction of the first position.
This arrangement is particularly useful for horizontally sliding landing doors in an elevator application, wherein it is desirable to provide a closing bias to the landing doors independent of the door opening and closing mechanism mounted on the elevator car. The apparatus according to the present invention achieves the flexibility and compactness of the prior art spring driven cable systems, but without requiring increased power to open the landing doors against an increasing spring resistance.
Referring to the drawing figures, and in particular to
According to the present invention, a spring apparatus 16 is secured to the door header 11 for pulling a cable 23 attached to the hanger bracket 14 at 23b. The spring apparatus 16 includes a winding drum 22 for winding and unwinding the cable 23 as the landing door 13 is moved laterally.
Referring now to
Referring to
Also shown in
The operation of the apparatus according to the present invention should now be apparent. The apparatus operates to urge a bidirectional moving door, such as an elevator landing door 13 in a first direction toward a first position by imparting a tension force on a cable 23 connected at a first end 23b to the door 13 and at the second end to a spring apparatus 16. The spring apparatus 16 imparts a constant tension force on the cable 23 by means of the interaction between the spiral spring 24 and the conical outer peripheral surface 27 as described above. As will be apparent to those skilled in the art, when the cable 23 is fully wound on the winding drum 22, the cable is positioned at the smaller or minimum diameter end 26. Simultaneously, the spiral spring 24 is in its least deformed configuration, whereby it exerts a minimum torsional force on the winding drum 22.
As the cable 23 is pulled from the drum 22 by the motion of the door 13 from the first position to a second position, the drum 22 rotates, whereby spiral spring 24 is deformed. Thus, as the cable is pulled from the increasing diameter portions of the outer peripheral surface 27, the torsional force exerted on the winding drum 22 by the spiral spring 24 likewise increases. As is most clearly shown in
Thus, for the door 13 in the first position whereby the maximum quantity of cable 23 is wound on the winding drum 22, the force F1 is determined by the torque T1 divided by the radius R1. As has been noted above, both T1 and R1 are at their minimum values, and both T and R increase as the cable 23 is unwound from the drum 22. Thus, in the second or fully open position of the door 13, the cable 23 is fully unwound from the drum 22 and T2 and R2 are at their maximum values. By judiciously sizing the spring 24 and the shape of the conical outer peripheral surface 27 of the winding drum 22, the force exerted on the cable 23 can be kept relatively constant.
It will be readily apparent to those skilled in the art that there are a number of equivalent embodiments or arrangements which although not directly illustrated here are within the scope of the invention. For example, although the apparatus according to the present invention has been shown in an elevator arrangement with one or more sliding doors, the invention may be equally applicable to swinging or lifting doors. Likewise, although shown here as functioning to urge the subject door or doors into a closed position, the invention may be used to bias or urge a door into an open position if so desired.
Number | Date | Country | Kind |
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2002-139424 | May 2002 | JP | national |
Number | Name | Date | Kind |
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3756585 | Mihalcheon | Sep 1973 | A |
6142260 | Shin | Nov 2000 | A |
6164014 | McDowell et al. | Dec 2000 | A |
6321489 | Murofushi et al. | Nov 2001 | B1 |
6401793 | Martin | Jun 2002 | B1 |
Number | Date | Country | |
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20030221370 A1 | Dec 2003 | US |