The present invention relates to a drive device for moving a barrier, such as a garage door, between a closed and an open position and vice versa. The device is intended primarily for use with doors of a sectional or one piece design and combined with a counterbalance assembly comprised of a drive shaft connecting cable drums to the door through a flexible linkage. Notwithstanding, other combinations and uses are also contemplated.
Jackshaft garage door openers that lift the door by turning the counterbalance shaft have been known by those skilled in the art for quite some time. Jackshaft garage door openers are primarily used on sectional doors with lift clearance, or full vertical, style track configurations since a portion, or all, of the door remains in the vertical orientation when the door is open. When closing, the jackshaft opener turns the counterbalance assembly and winds the counterbalance springs while paying out cable. The door is lowered by the weight of the portion of the door in the generally vertical position, relative to the ground, applying a downward force to the remainder of the door that is in the generally horizontal position, relative to the ground. This downward force also keeps the cables tensioned as the door is closed.
Sectional doors are moveable barriers used to secure an opening in a wall or structure. The opening is usually comprised of a header which is parallel, relative to the ground, spanning the very top of the opening, a floor at the very bottom of the opening which is parallel relative to the ground, and side jambs which are normal, relative to the ground, and span the left and right side of the opening from the floor to the header. The sectional door is in the closed position when the bottom section of the door is in contact with the floor and the entire opening is secured by the sectional door blocking the opening. The sectional door is considered to be in the open position when the very lowest portion, relative to the ground, of the bottom section is near the header of the opening allowing entry and exit through the opening.
On standard lift sectional doors near, or in, the open position, very little of the door, if any, is in the vertical position relative to the ground. Turning the counterbalance assembly to close a standard lift door from near, or at, the open position where insufficient door weight is in the vertical orientation, relative to the ground, leads to a situation where the cables could become un-tensioned and unwrap from the cable drums. Cables which become unwrapped from a cable drum result in an unsafe condition in which the door could drop uncontrollably. A further complication of cables coming unwrapped is the inability to lift the door without binding cables around the counterbalance shaft and potentially breaking the cable and allowing the door to drop to the ground uncontrollably. Cables can also lose tension and unwrap from cable drums in the event a door binds or encounters an obstruction while it is closing. This could occur not only on standard lift doors, but also on lift clearance and full vertical sectional doors.
Over the years slack cable sensors of various designs have been used to detect a loss of cable tension on sectional doors. These sensors include mechanical and electrical versions all with the same intended purpose, to stop the door from closing when the lift cables are un-tensioned and could potentially unwrap from the cable drums. Electrical versions are connected to inputs on motorized operators to alert the motorized operator that cables are un-tensioned and to stop. Slack cable sensors complicate the installation of a jackshaft opener by requiring additional equipment and installation time. They also cannot prevent the cables from slacking, but rather only detect it.
Standard lift doors can sometimes be modified to increase the amount of force acting in the vertical position when the door is in the open position. Those skilled in the art should be familiar with modifying the horizontal tracks of standard lift doors to provide some vertical lift and/or installing pusher springs on the back of the horizontal tracks to push the door closed for brief amount of travel from the open position. Both of these modifications require additional time and equipment, and should be done only by a highly trained individual. Another method of attempting to provide a closing force to standard lift doors when closing via a jackshaft opener has been the addition of one or more cable drums to the door itself on the counterbalance shaft to take up cables attached to the top section of the door to pull it closed. The problem with this method is that as sectional door is closing from the open to close position the top of the door transitions from the horizontal to the vertical position and the top edge of the door moves closer to and then further away from the cable drums. This creates a situation where the cable drums pulling the door closed take up cable and then have to pay out cable during the closing operation. The counterbalance shaft rotates in only one direction as the door closes and thus does not allow for a cable attached to the top of the door to be taken up and then paid out as the top of the door transitions from the horizontal to the vertical orientation. Several devices have been previously proposed to address this. One such prior art device is disclosed in U.S. Pat. No. 4,191,237 which describes an operator used to rotate a counterbalance assembly with cable drums to take up cable thereby lifting the door and another cable drum on the counterbalance assembly that is used to pull the door closed. In order to address the transitioning of the top section from horizontal to vertical the '237 patent discloses a fixed pulley mounted below the counterbalance assembly and an additional pulley attached to a bracket mounted to the top of the door. These inconvenient modifications require additional cost of equipment and time to install and add undesirable complexity to the door system.
Another mechanism disclosed in U.S. Pat. No. 6,883,579 also includes a cable to pull the door closed. The cable is connected to the top section of the door through an arm bracket at one end and to a cable drum on the counterbalance shaft at the opposite end. The point of attachment of the cable to the arm bracket remains in the horizontal position throughout the opening/closing operation. The modification of the door to add the arm bracket and the need for a longer horizontal length of door track is costly, time consuming to install and, therefore, undesirable.
U.S. Pat. No. 6,326,751 also describes a cable that spans between and connects the top of the door to a cable drum mounted on the door counterbalance shaft. The '751 patent describes attachment of the upper cable to the door utilizing a tension member such as an extension spring. While closing, the top section of the door starts transitioning from a generally horizontal to generally vertical orientation, relative to the ground, at which point the top section of the door begins to move away from the cable drum thereby stretching the extension spring while the door continues to close. The problem with this device is the spring, while flexible enough to allow it to wrap on the drum, is actually trying to pull the door open, not closed once the top section of the door has transitioned from horizontal to vertical. In order for the spring to be flexible enough to wrap on the drum it also cannot provide any significant tensile force to the top of the door when pulling it closed from the open position rendering the application of this device impractical in reality.
Consequently, there is a long felt need in the art for a jackshaft opener that not only opens a door by rotating the counterbalance shaft and cable drums to take up lift cables attached to the bottom of the door, but will also provide a force applied to the door so as to positively drive a door closed without relying on the weight of a portion of the door hanging in the vertical position, relative to the ground, and without relying on the addition of costly equipment or time consuming modification of the door. There is also a long felt need in the art for a jackshaft opener that can directly sense the position of the door so as to determine whether or not the door is moving while the counterbalance assembly is turned so as to detect slack cables without additional equipment or modification of the door. Finally, there is a long felt need in the art for a jackshaft opener that accomplishes all of the forgoing objectives, and that is relatively inexpensive to manufacture and safe and easy to use.
The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed innovation. This summary is not an extensive overview, and it is not intended to identify key/critical elements or to delineate the scope thereof. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is presented later.
The subject matter disclosed herein, in one aspect thereof, is a jackshaft opener that: (i) positively drives a barrier such as a sectional door closed without relying on the weight of a portion of the barrier hanging in the vertical position, relative to the ground, and without relying on the addition of costly equipment or time consuming modification of the barrier; (ii) provides the user with a jackshaft opener that can directly sense the position of the barrier so as to determine whether or not the barrier is moving while the counterbalance assembly is turned so as to detect slack cables without additional equipment or modification of the barrier; and (iii) secures the barrier from being manual forced opened without additional equipment or modification of the barrier.
The object of this invention is to provide for a new type of jackshaft garage door opener that could be installed on new or existing standard lift doors. In addition to turning the counterbalance assembly to open the door through the doors lift cables this new opener includes an integrated cable drum with an upper cable attached to the top section of the door for pulling the door closed, for at least a portion of the door travel, most critically near the open position where little or no door weight may be hanging in the vertical position. Those skilled in the art will also appreciate the benefits from the ability to apply a downward force to the door in the open position by the jackshaft operator itself without the necessary addition of pusher springs on the door, or modification of the track assembly. A clutch connects the integrated cable drum of the operator to the motor of the operator. A means for engaging and disengaging the clutch is also provided. The operator may engage the clutch allowing the motor to rotate the integrated cable drum pulling the door closed for at least a portion of the door travel and then the clutch may be disengaged allowing the integrated cable drum to be disconnected from the motor of the operator. The clutch may be a wrap spring clutch which is comprised of a helical wound spring that is mounted circumferentially overtop of an input hub on one end and circumferentially overtop of an output hub on the opposite end of the helical wound spring.
A wrap spring clutch transmits torque via an interference fit between the internal diameter of the helical spring and the outside diameter of the input and output hubs it is mounted circumferentially overtop of. A wrap spring also only transmits torque in one direction and acts as an overrunning clutch in the opposite direction. The direction the helical spring is wound determines which way the wrap spring clutch will rotate and engage. Those skilled in the art will also appreciate a tensioning device included as part of the operator, ideally a power spring, which will bias the upper cable to spool onto the integrated cable drum when the clutch is disengaged. This will spool the upper cable onto the integrated cable drum of the operator when the clutch is disengaged, allowing the upper cable to be taken up or paid out from the integrated cable drum as needed as the top section goes from horizontal to vertical and vice versa, in reference to the ground.
Still a further objective of this invention is to provide for two separate sensors utilized to monitor the rotation of both the counterbalance rotation on the door system as well as the rotation of the operator cable drum. While closing, the operator controls can monitor the rotation of the operator cable drum and compare it to the rotation of the counterbalance shaft, which the operator is drivingly connected to, and determine whether or not the door has been hung up or is jammed. This will allow the operator to stop further rotation of the counterbalance shaft thereby un-tensioning the door lift cables and possibly unwrapping them from the doors cable drums. When the door is being opened the operator controls can utilize the feedback from the sensors to determine what type and diameter lift cable drum is being used on the door. This is possible because different types of lift cable drums take up different amounts of cable per rotation. The amount of cable taken up or paid out per rotation of the opener cable drum is fixed and when compared to the rotation of the counterbalance the size and type of lift cable drums can be calculated.
Still a further objective of this invention is to provide for a way to secure the barrier from being manual forced opened without additional equipment or modification of the barrier. With the door in, or near, the closed position a flexible linkage attached to the top of the door and to the jackshaft opener or operator applies a force to the top of the door thereby preventing it from being forced open.
In a preferred embodiment of the present invention is a drive system for moving a sectional door between an open and closed position comprised of a jackshaft opener or operator drivingly connected to a counterbalance shaft comprised of a counterbalance cable drum. Said operator opens said sectional door by rotating said counterbalance cable drum thereby taking up and spooling a lift cable onto said counterbalance cable drum. Said operator closes said sectional door by rotating said counterbalance shaft in the opposite direction thereby paying out and unspooling said lift cable from said counterbalance cable drum allowing the weight of said sectional door to keep said lift cables tensioned. For at least a portion of travel while said operator closes said barrier an upper cable attached to said barrier is taken up and spooled onto an operator cable drum which is drivingly connected through a clutch that is engaged to a motor thereby applying a force along said upper cable to the top section of said sectional door moving said sectional door toward the closed position. While continuing to close, but prior to said sectional door reaching the close position, said clutch is disengaged freeing said operator cable drum from said motor thereby allowing said operator cable drum to pay out and unspool said upper cable from said operator cable drum while said sectional door continues to the closed position. The jackshaft opener of the present invention accomplishes all of the forgoing objectives, as well as others, and is relatively inexpensive to manufacture and safe and easy to use.
To the accomplishment of the foregoing and related ends, certain illustrative aspects of the disclosed innovation are described herein in connection with the following description and the annexed drawings. These aspects are indicative, however, of but a few of the various ways in which the principles disclosed herein can be employed and is intended to include all such aspects and their equivalents. Other advantages and novel features will become apparent from the following detailed description when considered in conjunction with the drawings.
The innovation is now described with reference to the drawings, wherein like reference numerals are used to refer to like elements throughout. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding thereof. It may be evident, however, that the innovation can be practiced without these specific details.
Referring initially to the drawings,
Door frame 56 is comprised of an opening 58 which is formed by a header 60 spanning the top of the opening 58, a jamb 64 positioned on both the left and right side of opening 58, and a floor 62 which spans the bottom of opening 58. Typically wood, or other acceptable construction materials, are used to rigidly construct header 60 and jambs 64.
Sectional door 12 is comprised of an upper door section 18a, a lower door section 18b, and one or more of a center door section 18c connected to one another by at least one or more of a center hinge 26 and an end hinge 20 positioned at each end of said sectional door 12. An upper bracket 82 is attached to upper door section 18a near the left and right side and a bottom bracket 84 is attached to said lower door section 18b near the left and right side.
Track assembly 30 is comprised of a vertical track 30a, a horizontal track 30b, and a curved track 30c mounted to the left and right side of opening 58. A flag bracket 36 is used in multiple locations to attach the vertical tracks 30a to the jamb. Each flag bracket 36 is comprised of a jamb leg 36a, attached to the jambs 64, and a track leg 36b extending perpendicularly to the jamb 64 to which the vertical track 30a is attached. Curved track 30c extends from the vertical track 30a up, relative to the floor 62, and around a curved path into a horizontal orientation, generally parallel to floor 62, and is then connected to the horizontal track 30b.
Referring to
Counterbalance assembly 40 is comprised of a counterbalance shaft or door shaft 42 which is mounted to header 60 by way of an end bearing bracket 48 on both ends. A counterbalance flexible linkage storage unit or counterbalance cable drum 44 is supported by, and rotatably coupled to, door shaft 42 at each end. Counterbalance cable drum 44 is positioned in close proximity to the inside of each end bearing bracket 48 relative to the opening 58 as best shown in
Mounted proximate to the door shaft 42 is an operator or motorized operator 100 as seen in
A reversible motor 310 is mounted to operator frame 110 as shown in
With slider 410 engaged, driving sprocket 350 is rotatably connected to motor 310 and can turn driven sprocket 370 by way of a roller chain 380. Driven sprocket 370 is rotatably coupled to a drive shaft 330 which is rotatably coupled to drive gear 340 that turns driven gear 320 mounted on door shaft 42 for transmitting power to counterbalance cable drums 44 to take up or payout lift cables 54 thereby lifting or lowering sectional door 12.
An operator flexible linkage storage unit or operator cable drum 510, as shown in
Wrap spring 610a is comprised of a bent up tab 612a and wrap spring 610b is comprised of a bent up tab 612b both of said bent up tabs 612a and 612b are located within a keyway slot 622a in a stop collar 620a, and a keyway slot 622b in stop collar 620b respectively. Stop collar 620a and 620b are located over the outside diameter of wrap spring 610a and 610b respectively. Referring to
A solenoid coil 670 is mounted proximate to clutch 600. Solenoid coil 670 has an armature 672 which is pulled in longitudinally through solenoid coil 670 against a compression spring 680 and a clevis pin 678 connects armature 672 to pivot arm 674 through a slotted hole which rotates pivot arm 674 about a pin 676 and thereby moves blocking tab 674a out of connection with slots in stop collar 620a and 620b.
In
Having described the general structure of a first embodiment of a new jackshaft opener, and the environment in which it operates, its function will now be described in general terms.
Once motorized operator 100 is mounted to the counterbalance assembly 40 and connected to sectional door 12 the opening and closing limits can be set in logic controller 222. When control circuit 220 is first powered up there are no limits set in the logic controller 222. With sectional door 12 in the closed position a cal button 226 is used to prompt logic controller 222 to record the current position of counterbalance shaft sensor 236 as the down limit. Sectional door 12 is then moved to its desired open position and logic controller 222 is prompted to record the new position as the up limit using cal button 226.
Normal operation of motorized operator 100 is initiated through either a wall button 228 or a remote 230 input to logic controller 222. If sectional door 12 is in, or near, the closed position logic controller 222 receives an open input from either wall button 228 or remote 230, logic controller 222 will leave solenoid coil 670 de-energized and thereby keep pivot arm 674 and blocking tab 674a engaged in slots in stop collars 620a and 620b thereby preventing stop collars 620a and 620b from rotating. Logic controller 222 then energizes motor 310 in the open direction which turns slider 410 which is engaged in driving sprocket 350 and turns driven sprocket 370 mounted to drive shaft 330 by way of a roller chain 380. The rotation of drive shaft 330 causes drive gear 340 to turn driven gear 320 and door shaft 42 in the open direction which transmits power to counterbalance cable drums 44 to take up lift cables 54 thereby lifting sectional door 12 to the open position. As motorized operator 100 opens sectional door 12 a bent up tab 612b on wrap spring 610b contacts the wall of keyway slot 622b in stop collar 620b. Blocking tab 674a on pivot arm 674 is engaged in slots 624 preventing stop collar 620b, and thereby wrap spring 610b, from rotating thereby keeping wrap spring 610b loose on the hex shaft 470, and thereby keeping operator cable drum 510 rotatably free from motor 310. Rotatably free means, without limitation, two bodies are free to independently rotate relative to one another about a common axis. During the opening of sectional door 12, power spring 530 keeps upper cable 520 tensioned and spooled on operator cable drum 510. At a pre-determined time or position, which may be determined by counterbalance shaft sensor 236, logic controller 222 de-energizes motor 310 to stop sectional door 12 in the open position.
As sectional door 12 starts to close from the open position, upper cable 520 is taken up on operator cable drum 510 as shown in
If sectional door 12 is in or near the open position as shown in
While sectional door 12 continues to close operator cable drum 510 is drivingly disconnected from motor 310 by disengaging clutch 600 prior to sectional door 12 reaching the position of minimum length of unspooled upper cable 520 shown in
To drivingly disconnect operator cable drum 510 from motor 310 clutch 600 is disengaged. Clutch 600 is disengaged by logic controller 222 de-energizing solenoid coil 670 which allows pivot arm 674 and blocking tab 674a to re-engage the slots in stop collars 620a and 620b thereby preventing stop collars 620a and 620b from rotating. As motor 310 and hex shaft 470 continue to rotate in the closed direction a bent up tab 612a on wrap spring 610a contacts the wall of keyway slot 622a in stop collar 620a thereby loosening wrap spring 610a, de-coupling hex shaft 470 from center hub 608 and thereby rotatably freeing operator cable drum 510 from motor 310. Power spring 530 continues to apply a torque to drum shaft 550 and connected operator cable drum 510 keeping upper cable 520 tensioned and spooled around operator cable drum 510.
Sectional door 12 continues to close until logic controller 222 determines through counterbalance shaft sensor 236 that the down limit has been reached at which time logic controller 222 de-energizes motor 310, thereby stopping sectional door 12 from further closing. During the closing of sectional door 12 from the open position, logic controller 222 compares pulses received from a operator cable drum sensor 238 to rotations of door shaft 42 through counterbalance shaft sensor 236. If logic controller 222 determines the pulses from operator cable drum sensor 238 have slowed, or stopped, compared to the rotations of door shaft 42 being reported by counterbalance shaft sensor 236 the most likely cause is sectional door 12 is hung up and prevented from closing while motorized operator 100 continues to turn counterbalance assembly 40 paying out lift cables 54 from counterbalance cable drums 44 creating an unsafe condition. If this condition is encountered, then logic controller 222 may de-energize motor 310 thereby stopping sectional door 12 from closing any further, and possibly energize motor 310 in the opposite rotation to reverse sectional door 12 to the open limit, depending on where sectional door 12 stopped in relation to the floor.
With sectional door 12 stopped at the down limit, logic controller 222 could also monitor operator cable drum sensor 238 to determine if sectional door 12 is being forcibly lifted manually without using disconnect mechanism 400. When pulses are detected from operator cable drum sensor 238 without rotation of counterbalance shaft sensor 236, logic controller 222 is able to determine operator cable drum 510 is rotating when door shaft 42 is not. Rotation of operator cable drum 510 without rotation of door shaft 42 is most likely caused by someone trying to forcibly lift sectional door 12 from the closed limit without using disconnect mechanism 400. When motor 310 is not energized and logic controller 222 determines that operator cable drum 510 is rotating while counterbalance shaft sensor 236 is not rotating, logic controller 222 can energize solenoid coil 670 thereby pulling in armature 672 against compression spring 680 pulling pivot arm 674 and blocking tab 674a out of slots in stop collars 620a and 620b thereby rotatably connecting operator cable drum 510 to motor 310 which is non-energized and is non-backdrivable preventing operator cable drum 510 from paying out any additional cable thereby locking sectional door 12 from being forcibly opened further.
An alternate construction of the drive system utilizes an electromagnetic clutch 640 to connect motor 310 to the operator cable drum 510. Referring to
Further alternative constructions of the drive system may utilize a single wrap spring like a wrap spring 1556 as shown in
Not illustrated with figures but none the less envisioned as an alternative to the clutch 600, or electromagnetic clutch 640, are different types of mechanical and electro-mechanical clutches which could include a dentil tooth or friction clutch with a mechanical disengagement, a viscous fluid clutch, and roller style one direction overrunning clutches which include some method of engaging and disengaging during the operation of motorized operator 100. Also envisioned are alternative methods to engage and disengage clutch 600. To engage and disengage clutch 600 a motor with a four bar linkage attached to a crank, or a motor with a worm gear and a follower member attached to the driven gear, or an air cylinder may be utilized in place of a solenoid.
Referring to
Mounted proximate to door shaft 42 and to the left hand side of sectional door 12 is motorized operator 1100 as seen in
Referring to
Referring to
Referring back to
Referring to
Referring to
Solenoid assembly 1563 is mounted to frame 1110 by way of a screw 1582 in several locations as shown in
Referring to
Referring to
In
Having described the general structure of a second embodiment of the jackshaft opener of the present invention, its function will now be described in general terms.
Referring to
Referring to
Operator cable drum 1502 on motorized operator 1100 sits below the door shaft 42 vertically, relative to the floor. The relative position of operator cable drum 1502 below door shaft 42 and the upper connection point for attaching tensile member 1720 to cable bracket 1710 allows for the unspooled length of upper cable 1504 from operator cable drum 1502 to be at its shortest length when sectional door 12 is in the closed position as shown in
Once operator 1110 is mounted to the counterbalance assembly 40 and to door frame 56 the opening and closing limits can be set in logic controller 1222. When control circuit 1220 is first powered up there are no limits set in the logic controller 1222. With sectional door 12 in the closed position a cal button 1226 is used to prompt logic controller 1222 to record the current position of the counterbalance shaft sensor 1236 as the down limit. Sectional door 12 is then moved to its desired open position and logic controller 1222 is prompted to record the new position as the up limit using cal button 1226.
Normal operation of motorized operator 1100 is initiated through either a wall button 1228 or a remote 1230 input to logic controller 1222. If sectional door 12 is in, or near, the closed position and logic controller 1222 receives an opening input request from either wall button 1228 or remote 1230 logic controller 1222 will energize motor 1160 in the open direction which turns driving sprocket 1190 and thereby transfers power through roller chain 1180 to driven sprocket 1370 causing driven sprocket 1370 to rotate. As driven sprocket 1370 is rotated dentil teeth 1370b contact slider dentil teeth 1314b on slider 1314 causing it to rotate. Slider 1314 has a hex bore through its center that turns hex drive sleeve 1318 which through a spring pin 1312 connection thereby rotates drive tube 1310, drive coupler 1390, and door shaft 42 in the open direction which transmits power to counterbalance cable drums 44 to take up lift cables 54 thereby lifting sectional door 12 to the open position.
During the opening of sectional door 12 power spring 1506 keeps upper cable 1504 tensioned and spooled on operator cable drum 1502 by overrunning wrap spring 1556 in one direction. Hex drive sleeve 1318 rotates driving sprocket 1350 which moves roller chain 1352 which is connected to and thereby rotates driven sprocket 1518 on operator cable drum shaft assembly 1500. In this embodiment, driving sprocket 1350 is approximately twice as large as the driven sprocket 1518 which causes the drum shaft 1512, and thereby operator cable drum 1502, to rotate approximately twice as fast as door shaft 42. Operator cable drum 1502 has a functional diameter for spooling upper cable 1504 that is approximately half the functional diameter of counterbalance cable drums 44 which spools lift cables 54. This combined with approximately twice the rotational speed, results in operator cable drum 1502 paying out in the open direction, and taking up in the closed direction, upper cable 1504 at nearly the same rate as counterbalance cable drums 44 take up in the open direction, or pay out in the close direction, lift cables 54. This allows operator cable drum 1502 to be of a smaller overall diameter than counterbalance cable drums 44 so as to make a smaller envelope when included as part of motorized operator 1100.
As driven sprocket 1518 is rotated in the open direction it turns wrap spring 1556 in a direction which unwraps the wrap spring 1556 from connection to the hub of driven sprocket 1518. As sectional door 12 is being opened, upper cable 1504 is paid out from operator cable drum 1502 while still being tensioned by power spring 1506. At a pre-determined time or position, as determined from counterbalance shaft sensor 1236, logic controller 1222 de-energizes motor 1160 to stop sectional door 12 at the open position.
If sectional door 12 is in, or near, the open position and logic controller 1222 receives a closing input request from either wall button 1228 or remote 1230, logic controller 1222 will energize motor 1160 in the close direction which turns driving sprocket 1190 and thereby transfers power through roller chain 1180 connected to driven sprocket 1370 causing driven sprocket 1370 to rotate. As driven sprocket 1370 is rotated dentil teeth 1370b contact slider dentil teeth 1314b on slider 1314 causing it to rotate in the closed direction. Slider 1314 has a hex bore through its center that turns hex drive sleeve 1318 which through a spring pin 1312 connection thereby rotates drive tube 1310, drive coupler 1390, and door shaft 42 in the close direction which transmits power to counterbalance cable drums 44 to pay out lift cables 54 thereby lowering sectional door 12 to the closed position.
During the closing of sectional door 12, hex drive sleeve 1318 rotates driving sprocket 1350 which moves roller chain 1352 which is connected to, and thereby rotates, driven sprocket 1518 on operator cable drum shaft assembly 1500. As driven sprocket 1518 is rotated in the close direction it causes wrap spring 1556 to wrap down on, and rotatably connect to, the hub of driven sprocket 1518. Wrap spring 1556 which is now rotatably connected to driven sprocket 1518 also wraps tight around and rotates hub 1552 which rotates drum shaft 1512 by way of key 1562. Drum shaft 1512 rotates operator cable drum 1502 also by way of key 1562. As operator cable drum 1502 rotates in the close direction it takes up and spools upper cable 1504 thereby applying a force in the closing direction to upper door section 18a of sectional door 12 by way of tensile member 1720 connected to upper cable bracket 1710 mounted on upper door section 18a.
Sectional door 12 continues to close until logic controller 1222 determines through counterbalance shaft sensor 1236 that the down limit has been reached at which time logic controller 1222 de-energizes motor 1160 thereby stopping sectional door 12 from further closing.
Solenoid assembly 1563 may be used to disengage wrap spring 1556 during motorized operation of sectional door 12. While sectional door 12 is closing from at, or near, the open position after a pre-determined amount of time, or movement in the closed direction, solenoid coil 1564 may be energized which pulls in armature 1566 and thereby stop bracket 1568 and forces the top edge of stop bracket 1568 to contact stop collar 1560 thereby preventing stop collar 1560 from rotating. Referring to
During the closing of sectional door 12 from the open position, logic controller 1222 compares pulses received from operator cable drum sensor 1238 to rotations of door shaft 42 through counterbalance shaft sensor 1236. If logic controller 1222 determines the pulses from operator cable drum sensor 1238 have slowed or stopped, compared to the rotations of door shaft 42 being reported by counterbalance shaft sensor 1236, then the logic controller 1222 may de-energize motor 1160 thereby stopping sectional door 12 from closing any further, and possibly reverse directional movement of sectional door 12 to the open limit depending on where sectional door 12 stopped in relation to the floor.
Someone trying to manually force sectional door 12 open will cause upper door section 18a to apply a force on upper cable 1504 which thereby attempts to rotate operator cable drum 1502. When motor 1160 is stopped it is non-backdrivable and thereby prevents operator cable drum 1502, and upper cable 1504, from moving which secures sectional door 12 from being manually forced open. If someone needs to open sectional door 12 manually, a disconnect assembly 1400 is provided. A disconnect cable 1440, accessible from the secured side of the door, can be pulled manually which causes fork bracket 1430 to rotate about pin 1420 and then contact, and move, slider 1314 along hex drive sleeve 1318 to compress disconnect spring 1316. Slider 1314 moves out of rotatable connection with driven sprocket 1370 when slider dentil teeth 1314b are no longer contacting dentil teeth 1370b of driven sprocket 1370. Sectional door 12 can then be manually opened or closed as needed. Once sectional door 12 has been manually positioned where desired, the disconnect cable 1440 can be released thereby allowing disconnect spring 1316 to force slider 1314 back into rotatable connection with driven sprocket 1370.
Other variations are also within the spirit of the present invention. Thus, while the invention is susceptible to various modifications and alternative constructions, certain illustrated embodiments thereof are shown in the drawings and have been described above in detail. It should be understood, however, that there is no intention to limit the invention to the specific form or forms disclosed, but on the contrary, the intention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the invention, as defined in the appended claims.
The use of the terms “a” and “an” and “the” and similar referents in the context of describing the invention (especially in the context of the following claims) are to be construed to cover both the singular and the plural, unless otherwise indicated herein or clearly contradicted by context. The terms “comprising,” “having,” “including,” and “containing” are to be construed as open-ended terms (i.e., meaning “including, but not limited to,”) unless otherwise noted. The term “connected” is to be construed as partly or wholly contained within, attached to, or joined together, even if there is something intervening. Recitation of ranges of values herein are merely intended to serve as a shorthand method of referring individually to each separate value falling within the range, unless otherwise indicated herein, and each separate value is incorporated into the specification as if it were individually recited herein. All methods described herein can be performed in any suitable order unless otherwise indicated herein or otherwise clearly contradicted by context. The use of any and all examples, or exemplary language (e.g., “such as”) provided herein, is intended merely to better illuminate embodiments of the invention and does not pose a limitation on the scope of the invention unless otherwise claimed. No language in the specification should be construed as indicating any non-claimed element as essential to the practice of the invention.
Several embodiments of this invention are described herein. Variations of those embodiments may become apparent to those of ordinary skill in the art upon reading the foregoing description. The inventor expects skilled artisans to employ such variations as appropriate, and the inventor intends for the invention to be practiced otherwise than as specifically described herein. Accordingly, this invention includes all modifications and equivalents of the subject matter recited in the claims appended hereto as permitted by applicable law. Moreover, any combination of the above-described elements in all possible variations thereof is encompassed by the invention unless otherwise indicated herein or otherwise clearly contradicted by context.
This application claims priority from Provisional Patent Application Ser. No. 62/200,893 filed on Aug. 4, 2015 which is incorporated herein by reference in its entirety.
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Entry |
---|
Blaine R. Copenheaver, ISA Written Opinion of PCT International Application PCT/US2016/044936, pp. 1-17. |
Number | Date | Country | |
---|---|---|---|
20170037671 A1 | Feb 2017 | US |
Number | Date | Country | |
---|---|---|---|
62200893 | Aug 2015 | US |