1. Field of the Invention
The present invention is directed to a door closer which provides even pressure to a door throughout the range of the door swing.
2. Description of Related Art
In the door closer/operator industry today there is the need for the user to feel a constant force when opening the door, especially on doors needing to meet ADA requirements. According to the prior art, one solution is double lever arm which changes the vector angle between the arm and the door as the torque increases on the door closer/operator due to a linear spring. Another solution is the cam and roller design where the cam profile changes with the spring compression to provide a constant torque output. Prior art door closers include those of U.S. Pat. No. 4,653,227; U.S. Patent Publication No. 2013/0081227; U.S. Pat. No. 4,763,385; and U.S. Pat. No. 8,732,904. Each of these designs has disadvantages. Each has mechanical losses due to friction, the rack and pinion setup on the double lever arm closers and the cam roller on the cam/roller design. Additionally, they each require very strict tolerances for proper functionality.
Bearing in mind the problems and deficiencies of the prior art, it is therefore an object of the present invention to provide an apparatus and method for providing a constant torque to open and close a door.
It is another object of the present invention to provide a door closer and/or operator that provides a desired torque profile during the opening and closing of a door.
A further object of the invention is to provide a door closer and/or operator with constant torque output and improved maintenance and wear characteristics.
Still other objects and advantages of the invention will in part be obvious and will in part be apparent from the specification.
The above and other objects, which will be apparent to those skilled in the art, are achieved in the present invention which is directed to a door closer or operator comprising a door closer or operator housing adapted to be mounted to one of a door frame or a door and a pivoting pinion on the door closer housing for transmitting door motion between the door closer housing and the other of the door or door frame. A cam is connected to the pinion and rotatable therewith about an axis of rotation, the cam having a peripheral edge about the axis of rotation. The door closer further includes a spring having two ends, with a first end secured to the door closer housing, and a connecting member secured to the spring adjacent a second end thereof to compress the spring. The connecting member extends along the spring from the spring second end to a position beyond the spring first end where the connecting member is tangential to and engages the peripheral edge of the cam. Rotation of the cam causes a change in length of the portion of the connecting member between the position tangent to the cam peripheral edge and the spring second end to expand or compress the spring, resulting in a force transmitted along a longitudinal axis of the connecting member as a result of spring deflection. The cam peripheral edge has a profile with a varying radial distance between the cam axis and the connecting member at the position tangent to the cam peripheral edge such that the radial distance is changed as the spring expands or compresses to maintain a desired torque about the axis of the cam and the connected pinion.
The profile of the cam peripheral edge may be circular or non-circular, and have a radial distance between the cam axis and the connecting member at the position tangent to the cam peripheral edge such that the radial distance is reduced as the spring compresses or expands to provide a desired torque profile about the axis of the cam and the connected pivoting member, such as maintaining a constant torque about the axis of the cam and the connected pivoting member.
The cam may have a groove disposed along the peripheral edge of the cam and the connecting member may be a cable. The cable has a first end secured to the cam and a second end secured adjacent the spring second end, with the cable wrapping around the cam in the groove as the cam rotates to compress or expand the spring. The cam may include teeth about the peripheral edge and the connecting member may include teeth engaging the cam teeth. The cam may comprise a pinion with teeth about the peripheral edge and the connecting member may comprise a rack with teeth engaging the pinion teeth.
The spring may comprise a coil spring with a central opening and the connecting member may extend through the spring central opening from the spring second end to the cam.
The door closer or operator may have a linkage arm for pivoting the door between open and closed positions, the linkage arm having a first end attached to and sliding with respect to a track mounted to the other of the door frame or the door surface and a second end secured to the pinion and rotatable therewith. Alternatively, the door closer or operator may have a double lever arm for pivoting the door between open and closed position, the double lever arm having a first end mounted to the other of the door frame or the door surface and a second end secured to the pinion and rotatable therewith. The door closer or operator may employ no linkage arms, and the door may be secured to the pinion such that the axis of rotation of the door becomes the axis of rotation of the pinion.
In a related aspect, the present invention is directed to a method of controlling operation of a swing door. The method includes providing a door in an open or closed position interposed in a door frame and secured to the door frame by at least one hinge, and providing a door closer mounted to one of the door frame or the door surface and having the structure and features described above. The method includes urging the door into the other of the open or closed position and rotating the pinion and connected cam about the cam axis as the door moves. The rotation of the cam causes a change in length of the portion of the connecting member between the position tangent to the cam peripheral edge and the spring second end to expand or compress the spring and transmitting a force along a longitudinal axis of the connecting member as a result of degree of compression of the spring. The method includes maintaining a desired torque about the axis of the cam and the connected pinion as the door moves to the other of the open or closed position as a result of the changing radial distance of the cam axis to the cam peripheral edge at the position tangent to the connecting member as the spring expands or compresses.
The features of the invention believed to be novel and the elements characteristic of the invention are set forth with particularity in the appended claims. The figures are for illustration purposes only and are not drawn to scale. The invention itself, however, both as to organization and method of operation, may best be understood by reference to the detailed description which follows taken in conjunction with the accompanying drawings in which:
In describing the preferred embodiment of the present invention, reference will be made herein to
The present invention is particularly directed to a door closer or operator which provides a constant force on a door regardless of the door position. Unless otherwise indicated, the term door operator includes door closer, and vice versa. One embodiment of the closer includes a pinion, a spring, a cable attaching spring to pinion, and a variable radius pulley wherein the cable rides on a variable radius at the point where the spring force is acting as the pinion rotates during opening or closing of the door. The closer may also include a damping component that dampens the force from the user applied in the opening direction of the door, momentum of the door, backcheck, and the force from the spring or momentum of the door in closing, sweep and latch, and can be done through hydraulic control, electrical control, or other conventional methods. Certain terminology is used herein for convenience only and is not to be taken as a limitation on the embodiments described. For example, words such as “top”, “bottom”, “upper,” “lower,” “left,” “right,” “horizontal,” “vertical,” “upward,” “downward,” “clockwise” and “counterclockwise” merely describe the configuration shown in the figures. Indeed, the referenced components 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 degrees from the closed position.
The attached drawings include
During the door opening, the door closer has an otherwise conventional mechanical spring to store potential energy to provide a bias to swing the door closed. This is shown in the interior view of door closer 10 in
In order to compensate for the spring force variation, the configuration of periphery 32 of cam 30 is non-circular, and is designed to vary according to the force imparted by spring 40 in any position of the spring. In the embodiment shown, the present invention provides a constant output torque from door closer/operator 10 which uses linear spring force to provide an output torque on pinion 20. Door closer 10 has a rigid attachment from the door to the door closer pinion 20 that causes a rotational motion on the pinion from a rotation of the door, and a linear spring 40 that is responsible for the force felt when opening the door due to the spring compression. In particular, the present invention changes the vector displacement on the pinion from the spring force as the pinion rotates and the spring compresses.
A modification of the cam is shown in
A constant force value for opening and closing the door may be predetermined by the user and/or the door requirements. The constant force value is typically measured from a predetermined distance from the pivot point of the door. The desired constant force value determines a specific torque on the pivot point of the door a user wishes to achieve.
Without the changing the cam radius, door closers using a single lever arm are subject to increasing door opening and closing force as the angle of door opening increases. A door closer comprised of a spring having a linear increase in spring force and a circular groove periphery 32 of a fixed radius about pinion 20 results in a linear increase in torque on the pinion as well, as shown in
After selecting the desired output torque, one can then determine the radius at each degree for any selected spring stiffness. To calculate the pulley profile necessary to keep the torque constant, first determine with the spring constant or K value of the spring, the desired output torque T and an initial radius or radial distance value between the cam axis and the connecting member at the position tangent to the cam peripheral edge, which is a limit due to design. The desired tangential force f acting on the pulley at the initial radius is then calculated. With a known K value the preload necessary to acquire this initial force is known. The profile calculation method assumes that the radius remains the same between each degree of rotation. From this assumption the distance of spring displacement may be found from the distance traveled around the cam periphery at a constant radius between degrees of cam rotation. The spring force at each degree of rotation may be determined by adding the perimeter distance traveled per degree with the preload multiplying by the K value. Once the force at each degree is known, the radius necessary at each degree to provide a constant output torque may be found, as follows:
Radius of pulley at 1° rotation:
R1=T/f1
f1 is measured by spring displacement calculated from radial distance traveled by pulley between 0° and 1°, which is approximate since the radial distance changes slightly between 0° and 1°
Radius of pulley at 2° rotation:
R2=T/f2
f2 is measured by spring displacement calculated from radial distance traveled by pulley between 1° and 2°
Radius of pulley at n° rotation:
Rn=T/fn
fn is measured by spring displacement calculated from radial distance traveled by pulley between n° and (n+1)°
Calculation of force in a spring:
F=K(X−X0),
Using the decreasing radius or radial distance from the cam axis to the cable tangential point as the cam rotates as determined above, the torque on the pinion, or force felt opening the door, is constant across the angle on the door opening as shown in
Instead of using a cable as the connecting member secured to the spring, another embodiment of the closer of the present invention includes a geared pinion, a damping component, and a geared rack. The pinion diameter and rack thickness change as the pinion gear teeth engages the rack teeth during compression of the spring. In such embodiment shown in
Operation of cam 30″ is similar to that of the preceding cam embodiments, except for the meshing of the gears between the pinion gear and the rack and the inflexibility of the rack portion. In
While the rack acts as a piston for hydraulic damping in this embodiment damping components may alternately or further include an electric motor attached to the pinion, whereby the motor controls the motion and movement of the door to act as a door operator. All components attached to the pinion, such as an electric motor, experience a constant load during operation of the door closer/operator for better control and longer life. The constant output torque can further be adjusted to meet the application by pre-compression of the linear spring.
Included in the aforementioned embodiment of the pinion and connecting member is an eccentric sprocket and flexible chain arrangement, where the cam is a sprocket with the configuration of the pinion with peripheral teeth, and the chain has rollers which serve and function as the teeth of the rack. Instead of being rigid like the rack, the connecting member chain is flexible and non-stretchable, similar to the cable. As the spring compresses, and the spring force increases, the pitch diameter on the sprocket pinion would decrease as with the aforedescribed cam configurations to maintain a constant torque on the cam and pinion.
Instead of a non-circular peripheral edge, the cam may have a circular profile with the axis of rotation offset from the center of the circle, particularly if approximating a constant torque for less than the full degree of swing of the door. As an alternative to the constant force described above, the cam profile in the door closer of the present invention may be configured to provide a varying force during the opening or closing of the door at any or all positions. One skilled in the art will appreciate that the teachings herein would enable the cam profile to be modified to provide more or less than a constant force at any position of the door movement by changing the profile to increase or decrease the torque on the door closer pinion at a desired point or range of spring position.
In operation of the door closer or operator of the present invention, any of the aforedescribed cam and connecting member embodiments may be employed. With such a door closer or operator, when starting in either the closed or open position, the user urges the door into the other of the open or closed position, whereupon the pinion and connected cam about the cam axis rotate as the door moves. The rotation of the cam causes a change in length of the portion of the connecting member between the position tangent to the cam peripheral edge and the spring second end to expand or compress the spring and transmitting a force along a longitudinal axis of the connecting member as a result of degree of compression of the spring. The result is that a desired torque is maintained about the axis of the cam and the connected pinion as the door moves to the other of the open or closed position.
The present invention can be used on any door within the limits of the closer/operator design. The shape of the cam may be determined by variables such as spring linearity, pivot locations, door resistance, desired movement of the door, and track forces whether or not the arm is connected directly to the door or doorframe.
Instead of having one linkage arm with sliding track configuration, the door closer of the present invention may be used in door closing systems which include a two linkage arms connected in series (also known as a double lever arm) from the door closer to the door or frame, depending where the door closer is mounted.
With a constant torque output, the rigid arm and track assembly can be used on ADA required doors giving the clean look of a track setup with the performance of a double lever arm. This design can also be useful in applications where a double lever arm cannot be used due to safety issues (mental health facilities, prisons, etc.) but the user has the need for a constant force on the door. The benefits of the cable cam design over the standard roller/cam design are the less strict tolerances and the elimination of wear components such as bearings in the roller.
While the present invention has been particularly described, in conjunction with a specific preferred embodiment, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the foregoing description. It is therefore contemplated that the appended claims will embrace any such alternatives, modifications and variations as falling within the true scope and spirit of the present invention.
Filing Document | Filing Date | Country | Kind |
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PCT/US14/61040 | 10/17/2014 | WO | 00 |
Number | Date | Country | |
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61892674 | Oct 2013 | US |