This invention relates generally to a door closer, and more particularly to a door closer for automatically moving a door from an open position to a closed position.
A conventional automatic door closer operates by storing energy in a spring mechanism during opening of a door and releasing the stored energy to close the door. Automatic door closers are provided with means for controlling the movement of the door, usually involving hydraulic resistance within the door closer. When the door approaches a fully open or the closed position, a fluid medium within the door closer is caused to flow through restrictive passages which determine the speed of door movement.
A typical automatic door closer generally comprises an elongated housing which may be mounted above the door, in the transom or lintel, or in the floor. A rotating spindle is disposed adjacent one end of the housing such that an end of the spindle extends from the housing for connecting to the door. The portion of the spindle within the housing is connected for rotation with a cam mechanism. During movement of the door from the closed position to an open position, the cam mechanism acts against at least one adjacent roller fixed to a slide assembly for moving the slide assembly longitudinally in the housing. The slide assembly is connected to a piston in a hydraulic dampening arrangement. The piston divides at least a portion of the interior of the housing into two pressure spaces which are connected to each other by one or more passages for the restricted flow of the fluid medium from one space to the other.
In operation, the spindle and the cam mechanism rotate with the door. When the door moves from the closed position to an open position, the cam mechanism abuts against the roller and moves the slide assembly and the piston from a first position towards one end of the housing. This compresses the spring mechanism and the piston forces fluid to flow from one pressure space to the other. The spring mechanism also provides some resistance to the opening of the door to prevent the door from sudden movement. When the door is released, the stored energy of the compressed spring mechanism supplies energy for closing the door. As the door moves back to the closed position, the extending spring mechanism urges the piston and slide assembly to return to the first position causing the roller to act against the cam for rotating the cam mechanism and spindle and moving the door to the closed position. The speed of closing movement is controlled by the passage of fluid from one pressure space to the other caused by the piston.
A problem with door closers of this type includes the immersion of the operative elements of the door closer in hydraulic fluid. The necessary use of fluid seals and other components lend themselves to possible leakage, which constitutes a safety hazard and can have a damaging effect on the door and floor below.
For the foregoing reasons, there is a need for an automatic door closer which minimizes the number of door closer elements immersed in fluid medium and thereby reduces the problem of preventing possible leakage.
According to the present invention, a door closer is provided for automatically moving a door in a closing direction. The door closer comprises an elongated housing having a first closed end and an open second end and defining an interior cavity including a cylindrical recess spaced from the first end of the housing. A spindle is journaled in the housing adjacent the first end of the housing for rotation about an axis. At least a portion of the spindle extends from the housing and is adapted to be connected to turn with the door. A cam is carried by the spindle for rotation with the spindle about the axis through an arc in a first direction from a first angular orientation corresponding to the closed position of the door to a second angular orientation corresponding to an open position of the door and about the axis through an arc in an opposite direction from the second angular orientation to the first angular orientation. Rotation of the cam from the first angular orientation to the second angular orientation corresponds to movement of the door in the opening direction and rotation of the cam from the second angular orientation to the first angular orientation corresponds to movement of the door in the closing direction. A slide assembly includes a cam following roller for cooperating with the cam for converting rotation of the cam into linear movement of the slide assembly relative to the housing. A piston is slidably disposed in the cylindrical recess and a piston rod is connected at one end to the piston and at the other end to the slide assembly. Spring means disposed outside of the housing urge the piston and slide assembly in the door closing direction. The spring means includes a spring rod connected at one end to the second end of the piston. First and second annular plugs are disposed in the housing adjacent the ends of the cylindrical recess for slidably sealingly receiving the piston rod and the spring rod, respectively. The first and second annular plugs and piston divide the cylindrical recess into a first chamber between the first annular plug and the end of the piston and a second chamber between the second annular plug and the other end of the piston. Passage means defined in the housing permit flow of fluid between the cylindrical recess and the cavity between the first annular plug and the closed end of the housing in response to movement of the piston. Upon rotation of the spindle and cam in the door opening direction, the cam operates against the cam following roller for moving the slide assembly toward the first closed end of the housing and the piston toward the first end of the cylindrical recess thereby compressing the spring means for storing energy. The spring means urges the piston toward the second end of the cylindrical recess for moving the slide assembly toward the second end of the housing and the cam following roller against the cam to rotate the cam and the spindle in the door closing direction.
For a more complete understanding of the present invention, reference should now be had to the embodiments shown in the accompanying drawings and described below. In the drawings:
Certain terminology is used herein for convenience only and is not to be taken as a limitation on the invention. For example, words such as “upper,” “lower,” “left,” “right,” “horizontal,” “vertical, ” “upward,” and “downward” merely describe the configuration shown in the FIGs. Indeed, the components of the door closer may be oriented in any direction and the terminology, therefore, should be understood as encompassing such variations unless specified otherwise.
As used herein, the term “open position” for a door means a door position other than a closed position, including any position between the closed position and a fully open position as limited only by structure around the door frame, which can be up to 180° from the closed position.
Referring now to the drawings, wherein like reference numerals designate corresponding or similar elements throughout the several views, a door closer according to the present invention is shown in
The mechanical end portion 14 defines an interior cavity 15 and has openings into the cavity 15 in a major face and at one end of the mechanical end portion 14. The cavity 15 in the mechanical end portion 14 accommodates a spindle 20, a cam assembly 22, and a slide assembly 24. The spindle 20 is rotatably mounted in the cavity 15 and extends normal to the longitudinal axis of the housing 12. An inner cylindrical end of the shaft of the spindle 20 is supported in an annular bore in the housing 12 by an inner roller bearing 26. The opening in the major surface of the mechanical end portion 14 is internally threaded for receiving an externally threaded spindle cap 28. The spindle 20 has an intermediate cylindrical shaft portion journaled in an outer roller bearing 30 held within a rim in the spindle cap 28 for rotatably supporting the spindle 20. The outer end of the shaft of the spindle 20 extends through an opening in the spindle cap 28 outwardly of the housing 12. The spindle 20 and spindle cap 28 are sealed by o-rings 32, 34 which prevent leakage of a hydraulic working fluid from the interior cavity 15 of the housing 12.
The cam assembly 22 comprises an eccentric cam 36. The cam 36 includes a first cam plate 38 and a second cam plate 40 mounted together in fixed spaced relation to the spindle 20 for rotation with the spindle 20. Each of the cam plates 38, 40 has a peripheral camming surface. As best seen in
Referring to
As seen in
The dampening end portion 16 of the housing 12 is secured to the mechanical end portion 14 using threaded fasteners received in axial threaded openings in the corners of the dampening end portion 16 (
A hollow spool-shaped piston 60 is slidably disposed within the cylinder 17 for reciprocal movement relative to the housing 12. The annular ends of the piston 60 seal against the wall of the dampening end portion 16 defining the cylinder 17 to establish a fluid tight relation between the ends of the piston 60 and the housing 12. One end of the piston 60 is connected to the draw bar rod 44 by means of a pin 62.
A pressure relief valve 64 is disposed in each end of the piston 60. Each pressure relief valve 64 has two axial valves 66, 68. One set of valves 66 includes a ball and a spring combination disposed in an inner larger diameter portion of the one set of passages. The diameter of the balls are larger than a smaller outer diameter portion of the passages. The springs bias the balls against the smaller diameter passage such that the passages are normally closed. The other set of valves 68 is one-way ball check valves which prevent the flow of fluid in a direction into the piston 60. As seen in
An annular check disc 82 is sealingly secured in the distal end of the cylinder 17 of the dampening end portion 16 adjacent the spring assembly 18. The check disc 82 is fixed with respect to the cylinder 17 and is sealed to the walls of the dampening end portion 16 with an o-ring 84 disposed in a circumferential groove on the periphery of the check disc 82. The check disc 82 thus effectively seals the distal end of the dampening end portion 16 of the housing 12. As shown in the
The spring assembly 18 comprises a spring rod 80 and coil compression springs 88 supported between a spring bar 90 and a spring retainer plate 92. The spring bar 90 is secured to the damping end portion 16 of the housing 12 using threaded fasteners received in axial threaded openings in the dampening end portion 16 adjacent the check disc 82 (
A fluid medium, such as hydraulic oil, is provided in the cavity 15 in the housing 12 to cooperate with the piston 60, and the dampening end portion 16 of the housing 12 is provided with passages though which fluid is transferred from one side of the piston 60 to the other during reciprocal movement of the piston 60 in the cylinder for regulating movement of the door. Referring to
Three throttle devices 116, 118, 120 comprising needle valves in threaded bores are longitudinally arranged along the main fluid passage 100. The threaded bores are in fluid communication with the main fluid passage 100. As seen in
In keeping with the present invention, the door closer 10 is mounted in the door frame above the door, preferably in a concealed position in the header, or overhead portion of the frame. The end portion of the spindle 20 is noncircular and extends from the housing 12 for being received in a complementary recess in the upper end of the door so that the door and spindle 20 turn together. The door is supported in the door frame for pivoting about the axis of rotation of the spindle 20 for movement between the closed position and an open position. In this arrangement, movement of the door causes the spindle 20 to turn in one direction and subsequent moving from an open position to the closed position causes the spindle 20 to turn in the opposite direction.
In operation, the components of the door closer 10 according to the present invention are as shown in
As the piston 60 moves toward the left end of the cylinder 17, the fluid inside the left end of the cylinder flows primarily through the two large diameter radial passages 106, 108 between the back check valve 116 and the stroke valve 118 and into the main fluid passage 100. The fluid passes through the opening 102 into the cavity 15 in the mechanical end portion 14 of the housing 12. Some of the fluid will also flow through the rightmost radial passage 108, into the piston 60 between the pressure relief valves 64, and out the end of the piston 60 through the ball check valve 68 thus filling the right end of the cylinder 17. As described above, if the pressure in the fluid flow path becomes excessive, the pressure may force the ball in the valve 66 in the leading end of the piston 60 to retract into the larger diameter portion of the passage so as to open the passage allowing fluid flow through the piston 60 with relatively little hydraulic resistance.
As the door continues to open and the piston 60 moves further to the left in the cylinder 17, the piston 60 gradually closes off the two passages 106, 108. This occurs at a certain opening angle of the door, for example, at about 70 degrees. Fluid can now flow out of the cylinder 17 only from the leftmost passage 104. Fluid entering this passage 104 is directed through a passage 122 to the back check valve 116 and out to the main fluid passage 100. As described above, the back check valve 116 regulates the flow of fluid leaving the cylinder 17. Therefore, resistance to door opening begins as the fluid becomes a damper to hinder the movement of the piston 60 which slows down rotation of the spindle 60 and the door. When the door reaches a fully open position, the piston 60 is adjacent the left end of the cylinder 17 and the springs 88 are compressed.
It is understood that the cam 36 is easily adapted for either 90-degree or 105-degree door swing. The cam 36 may be provided with opposed radius notches (not shown) which can be entered by a roller 50 when the door reaches an open position. The roller 50 drops into the notch where the resistance is enough to overcome the closing force of the spring assembly 18 for maintaining the door in an open position. If the door is held open, the door is easily closed by swinging it manually to clear the roller 50 out of the notch whereupon the energy stored in the springs 88 during opening of the door is released to move the door to the closed position.
Movement of the door from an open position to the closed position is effected by expansion of the spring assembly 18 acting to move the piston 60 and the slide assembly 24 to the right as seen in
During the first portion of the closing movement of the door, the piston 60 forces the fluid in the right end of the cylinder 17 through the two passages 110, 112 between the stroke check valve 118 and the latch check valve 120. The speed of movement of the closing door will be regulated by the flow of fluid past the stroke valve 118. As the door continues to move toward the closed position, the leading end of the piston closes off these fluid passages 110, 112. Typically this occurs as the door nearly reaches the closed position, for example, from about 5 degrees to about 7 degrees from the closed position. The only available passage for fluid to exit the cylinder 17 is the passage 114 at the same axial location as the latch check valve 120 (
The back check disc 54 also cooperates during door closing to permit fluid in the mechanical end portion 14 of the housing 12 to flow into the cylinder between the piston 60 and the back check disc 54. This occurs because the fluid pressure is on the opposite side of the piston 60 thereby freeing the balls from the passages in the ball check valves 56 in the back check disc 54 allowing fluid to pass. It is understood that during door opening the flow of fluid from the cylinder to the cavity in the mechanical end portion 14 is prevented by the one-way check valves 56. Accordingly all of the fluid expelled from the cylinder must flow through the main fluid passage 100.
When the door reaches the closed position, the components of the door closer 10 are again as shown in
Although the present invention has been shown and described in considerable detail with respect to only a few exemplary embodiments thereof, it should be understood by those skilled in the art that we do not intend to limit the invention to the embodiments since various modifications, omissions and additions may be made to the disclosed embodiments without materially departing from the novel teachings and advantages of the invention, particularly in light of the foregoing teachings. For example, some of the novel features of the present invention could be used with any type of automatic door closer. Accordingly, we intend to cover all such modifications, omission, additions and equivalents as may be included within the spirit and scope of the invention as defined by the following claims. In the claims, means-plus-function clauses are intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Thus, although a nail and a screw may not be structural equivalents in that a nail employs a cylindrical surface to secure wooden parts together, whereas a screw employs a helical surface, in the environment of fastening wooden parts, a nail and a crew may be equivalent structures.
This application is a continuation application of U.S. patent application Ser. No. 10/710,739, filed Jul. 30, 2004, the contents of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | 10710739 | Jul 2004 | US |
Child | 11534885 | Sep 2006 | US |