The present invention relates to strike mechanisms for electrically locking or unlocking a door in a frame; more particularly, to such strike mechanisms wherein a keeper support bracket is moveable between blocking and unblocking positions to selectively allow a keeper to be placed from a locked position and an unlocked position to allow a latch to be released from the strike; and most particularly, to a biasing mechanism including dual opposing springs that impose approximately a zero net force on the keeper support bracket when in the locked position.
As is known in the art of door latching, typically an electrically-controlled strike is mounted in a frame portion of a door and engages a lockset disposed on or in an edge portion of the door. Typically, the lockset includes a latch, and possibly a dead latch. In the case of a mortise-type lockset, the dead latch is linearly spaced-apart from the latch along the edge portion of the door. In either lockset type, the latch is reciprocally moveable between an engaged position so that it can engage an entry chamber in the strike, thereby to secure the door in a closed state, and a released position, wherein the latch is permitted to exit the entry chamber and to release the door from the closed state and is free to open. Similarly, if included, the dead latch is reciprocally moveable between an enabling position (extended) that permits movement of the latch from its engaged position to the released position and a disabling position (depressed) that prohibits movement of the latch from its engaged position to its release position. Typically, the latch is resiliently biased into the engaged position and the dead latch is resiliently biased into the enabled position.
U.S. Pat. No. 6,581,991 B2, the relevant disclosure of which is incorporated herein by reference, discloses an electrically-controlled strike comprising a housing adapted to be mounted in a frame portion of a door and having a cavity with a forwardly disposed opening that is sized and adapted to receive a spring latch and a dead latch when the door is in the closed state. The invention provides a single electrically actuated door latch structure that can be customized to a variety of spring latch and dead latch arrangements.
U.S. Pat. No. 9,183,976, assigned to Hanchett Entry Systems, Inc., discloses a springless electromagnet actuator having a mode selectable magnetic armature that may be used in door latching applications. A standard solenoid body and coils are combined with a non-magnetic armature tube containing a permanent magnet, preferably neodymium. The magnet is located in one of three positions within the armature. When biased toward the stop end of the solenoid, it may be configured to act as a push solenoid. When biased toward the collar end of the solenoid, it may be configured to act as a pull solenoid. In either case, no spring is required to return the armature to its de-energized position. Positioning the magnet in the middle of the armature defines a dual-latching solenoid requiring no power to hold it in a given state. In one aspect, positive coil pulse may move the armature toward a stop end, whereas a negative coil pulse moves the armature toward a collar end. The armature will remain at the end to which it was directed until another pulse of opposite polarity is supplied to the actuator.
International Patent Publication No. WO 2014/152187, the relevant disclosure of which is incorporated herein by reference, discloses a circuit, apparatus and method for improving energy efficiency, reducing cost and/or improving quality of electronic locks. The electronic lock controller circuit includes an input for receiving a legacy pulse, a power circuit for extracting power from the legacy pulse to power the electronic lock controller circuit, a detector circuit for detecting a polarity of the legacy pulse and a microcontroller having an output for connection to a lock actuator. The microcontroller sends an output pulse via the output to control the lock actuator and the output pulse having reduced power as compared to the legacy pulse at the input. The power may be reduced by reducing voltage and/or reducing the duration of the voltage pulse.
What is needed in the art is an interchangeable actuator module wherein each module may include a user-selected and/or condition-dependent actuator, such as, for example, a standard solenoid, a low power springless solenoid or a motor such as a low power stepper motor actuator. Such modules may further be configured to reside within strike housings having different depths depending upon the size/type of latch assembly being used.
It is an aspect of the present invention to reduce the cost and complexity of an electrically-controlled strike for a door with a mortise lockset and to improve reliability of operation. Another aspect of the present invention is to decrease the time in which a stepper motor-controlled electric strike is moved from a locked state to an unlocked state to allow a door to be moved to an opened state in a timely manner.
Briefly described, one aspect of the present invention is directed to an interchangeable, unitized actuator module for an actuator-controlled electric strike, for operating in conjunction with a latch of a mortise-type or cylindrical-type lockset, wherein the latch has an engaged position so as to selectively secure a door in a dosed state. The electric strike may comprise a housing including a back wall and opposing side walls defining an entry chamber therein. A keeper is rotatably disposed in the entry chamber about an axis for rotation between a locked position and an unlocked position. The interchangeable actuator module may include a body, at least one keeper release and an actuator selectively movable between a first actuator position and a second actuator position. The actuator is unitized in that the actuator is contained within the body and at least a portion of the keeper release is contained within the body. The actuator may in turn include an actuating device, which may be a solenoid or a motor, and a keeper support bracket and a keeper support. The keeper release engages the keeper support which extends downwardly from the keeper support bracket. The support bracket may include an actuator extension that is configured to mount onto or otherwise engage a plunger of the activating device. In the case of a pull type solenoid operating in a fail secure mode, actuation of the solenoid upon receiving power via leads extending out of the module causes the plunger to be pulled into the body of the solenoid. As the keeper support bracket is engageable with the plunger via an actuator extension, the inward travel of the plunger pulls with it the keeper support bracket. The keeper support is likewise displaced by travel of the keeper support bracket such that the keeper support is no longer operatively coupled to the keeper release. Thus, with the solenoid plunger retracted, any load on the keeper (such as an authorized attempt to withdraw a latch from the entry chamber of the housing) pivots the keeper so that the keeper drives the keeper release toward a back wall of the housing against a biasing member. Once any load on the keeper is removed, the keeper is returned to its locked position by its own biasing member while the keeper release is returned to the extended position via its biasing member. In this manner, once power to the solenoid has been cut off, the plunger returns to its original extended position, such as via a plunger return spring. In turn, the keeper support bracket and keeper support return to their original positions so as to lock the keeper.
In accordance with another aspect of the invention, a unitized, interchangeable actuator module is provided as described above, so that an existing electric strike may be readily retrofitted with a replacement actuator module.
In accordance with a further aspect of the invention, the unitized actuator module is configured to interchangeably reside within housings having entry chambers of differing depth.
In accordance with another aspect of the present invention, the keeper release and the keeper support are configured such that a load placed on the keeper when the latch is in the engaged position and the keeper is in the locked position is transferred from the keeper through the keeper release and keeper support to the back wall of the housing.
In accordance with a further aspect of the present invention, the actuating device may comprise a spring return solenoid and a plunger, wherein the keeper release is operatively coupled to the plunger and configured for sliding movement when the actuating device moves between a first and second actuator positions.
In accordance with yet another aspect of the invention, the actuating device may comprise a stepper motor including a shaft. The keeper release is coupled to the shaft and configured for sliding movement when the stepper motor moves between a first and second actuator positions. The actuator module may also include a microcontroller configured to sense a voltage having a first polarity supplied to the stepper motor wherein, upon sensing the voltage having the first polarity the microcontroller drives the stepper motor from the first to the second actuator position. The actuator module may further include a constant-current, constant-voltage (CCCV) charger and a super capacitor, the microcontroller controlling the CCCV charger to charge the super capacitor after the stepper motor has been driven to the second actuator position, the super capacitor being used to provide a second voltage having a polarity opposite the first polarity to selectively drive the stepper motor from the second actuator position to the first actuator position.
In accordance with another aspect of the invention, the actuating device may comprise a springless electromagnet actuator, wherein the keeper release is coupled to the plunger and configured for sliding movement when the actuating device moves between the first and second actuator positions. The actuator module may also include a microcontroller configured to sense a voltage having a first polarity supplied to the actuating device wherein, upon sensing the voltage having the first polarity the microcontroller drives the springless electromagnet actuator from the first to the second actuator position. The actuator module may further include a constant-current, constant-voltage (CCCV) charger and a super capacitor, the microcontroller controlling the CCCV charger to charge the super capacitor after the springless electromagnet actuator has been driven to the second actuator position, the super capacitor being used to provide a second voltage having a polarity opposite the first polarity to selectively drive the springless electromagnet actuator from the second actuator position to the first actuator position.
In accordance with another aspect of the present invention, the housing is configured to receive one of a plurality of strike plates, wherein each of the plurality of strike plates are configured to accommodate different types of locksets.
In accordance with another aspect of the present invention, the keeper includes an extendable face portion in communication with the entry chamber, the extendable face portion being adjustable to define a width of the entry chamber. The extendable face portion may be adjusted to an infinite number of positions using a set screw.
In accordance with a further aspect and non-limiting exemplary embodiment of the present invention, an actuator-controlled electric strike may be provided for operating in conjunction with a latch and deadbolt of a lockset, wherein the latch has an engaged position so as to secure a door in a closed state and a released position. The strike may comprise a housing including a longitudinal length, a back wall extending along the housing longitudinal length, and upstanding side walls defining an entry chamber therein. The strike may further comprise a keeper disposed in the entry chamber about an axis of rotation parallel with the back wall, wherein the keeper is rotatable about the axis of rotation between a locked position and an unlocked position. The back wall is disposed opposite the keeper when the keeper is in the locked position. The strike may further comprise a deadbolt bracket adjustably positioned in the entry chamber along the housing longitudinal length. The deadbolt bracket includes a first wall, a second wall, and a bracket side wall connecting the first wall and the second wall, wherein the deadbolt bracket defines at least a portion of a deadbolt receiving chamber for the deadbolt.
In another exemplary, non-limiting embodiment, the first wall includes a first distal end, and the second wall includes a second distal end, and the first and second distal ends are disposed against one of the side walls of the housing, and wherein the deadbolt bracket and the one of the side walls define the deadbolt receiving chamber for the deadbolt. Further, the deadbolt bracket may include a tab extending from at least one of the first and second distal ends, and one of the side walls of the housing has a slot defined therein configured to receive the tab.
In yet another exemplary, non-limiting embodiment, the first wall includes a first distal end, the second wall includes a second distal end, and the first and second distal ends are disposed against the back wall of the housing, wherein the deadbolt bracket and the back wall define the deadbolt receiving chamber for the deadbolt. Further, the deadbolt bracket may include a tab extending from at least one of the first and second distal ends, wherein the back wall of the housing has a slot defined therein configured to receive the tab.
In accordance with yet a further aspect of the present invention, the housing is configured to receive a latch bolt monitor, wherein the housing is configured to receive the latch bolt monitor in the entry chamber. The housing may include a back wall, wherein the latch bolt monitor is mounted to the back wall.
In accordance with another aspect of the invention, the strike may further include a trim plate disposed around the keeper, wherein the trim plate is mounted to one of the housing of the strike or a door frame.
In accordance with yet another aspect of the invention, a lip extension may be fitted to the electric strike in order to for the electric strike to be used with a wider, non-standard door frame. The lip extension may include a bottom panel, a first side wing, and a second side wing, wherein the first side wing extends from a first end of the bottom panel, wherein the second side wing extends from a second end of the bottom panel, and wherein the lip extension is mounted to the housing. The lip extension may include a rib disposed on the bottom panel that extends between the first side wing and the second side wing, wherein the rib is disposed adjacent to a notch formed in the housing. At least one of the first side wing and the second side wing may include a notch defined in a distal end that is configured for being disposed adjacent to a strike plate mounted to the housing. The bottom panel of the lip extension may be positioned adjacent to a bottom panel of the housing. Further, the lip extension may be U-shaped.
In accordance with another aspect of the invention, the housing may include a back panel, a bottom panel and opposing side walls to define the entry chamber, and at least one of the sidewalls includes an edge. The keeper may include a keeper base and a ramp element, wherein the ramp element includes a surface that is contactable by the latch, and wherein the surface of the ramp element extends beyond the edge of the at least one of the side walls when the keeper is in the locked position to prevent the latch from contacting the edge of the at least one of the side walls. A profile of the surface of the ramp element may be configured to match a profile of the edge of the at least one of the side wads. For example, the surface of the ramp element includes a rounded profile.
In another aspect, the surface of the ramp element may include an extension flange that covers the edge of the at least one of the side wads when the keeper is in the locked position.
In another aspect of the invention, the ramp element may include a surface contactable by the latch wherein the surface extends beyond a front profile of the housing to prevent the latch from contacting an edge of a side wall of the housing.
In another aspect, the housing may include a front profile, and the keeper may include a keeper base and a ramp element. The ramp element includes a surface that is contactable by the latch, and the surface of the ramp element extends beyond the front profile of the housing when the keeper is in the locked position to prevent the latch from contacting the edge of the at least one of the side walls. In still a further aspect of the present invention, a method is provided for locking or unlocking a door having an actuator-controlled electric strike for operating in conjunction with a latch of a lockset is included, wherein the latch has an engaged position so as to secure a door in a closed state and a released position, and wherein the strike includes a housing including a back wall and opposing side walls and defining an entry chamber therein; a keeper rotatably disposed in the entry chamber about an axis for rotation between a locked position and a unlocked position; and an actuator module including a keeper release configured to engage the keeper and an actuator selectively movable between a first actuator position and a second actuator position, wherein when the actuator is in one of the first or second actuator positions the keeper release is coupled to the keeper to secure the keeper in the locked position, and wherein when the actuator is selectively moved to the other of the first or second actuator positions the keeper release is decoupled from the keeper and the keeper is rotatable to the unlocked position, the method for unlatching comprising the steps of: providing an input voltage to drive the actuator from the first actuator position to the second actuator position; after driving the actuator to the second actuator position, using the input voltage to charge a capacitor; removing the input voltage; and providing a return voltage via the capacitor to drive the actuator from the second actuator position to the first actuator position.
In yet a further aspect of the invention, a method for changing a unitized actuator module of a strike assembly is provided wherein the actuator module is a first actuating module including a body, an actuator and a keeper release, the method comprising the steps of:
a) providing the strike assembly having a housing, wherein the first actuator module is disposed in the housing, and a keeper movably disposed in the housing. The first actuator module includes a first body, a first actuating device comprising one of a solenoid or a motor, and a first keeper release operatively engageable with said movable keeper to selectively release said keeper from a locked position to a released position;
b) allowing for the removal of the first actuator module from the housing; and
c) allowing for the installation of a second actuator module in place of the first removable actuator module wherein the second actuator module includes a second actuating device comprising one of a solenoid or a motor, and further comprising a second keeper release operatively engageable with the movable keeper to selectively release the keeper from the locked position to the released position.
In a further aspect of the present invention, a method may include having the actuator module include a microcontroller, wherein the microcontroller senses an input polarity of the input voltage and drives the actuator from the first actuator position to the second actuator position. Further, the capacitor may be a super capacitor, and the actuator module may further include a constant-current, constant-voltage (CCCV) charger. The microcontroller controls the CCCV charger to charge the super capacitor after the actuator has been driven to the second actuator position, wherein the super capacitor provides a second voltage having a polarity opposite the input polarity to drive the actuator from the second actuator position to the first actuator position.
In a further aspect of the present invention, an actuator-controlled electric strike for operating in conjunction with a latch of a lockset is provided. The latch has an engaged position so as to secure a door in a closed state and a released position. The strike comprises a housing defining an entry chamber therein, a keeper disposed in the entry chamber about an axis of rotation wherein the keeper is rotatable between a locked position and an unlocked position, and a keeper support bracket movable between a blocking position and an unblocking position. When the keeper support bracket is in the blocking position, the keeper is held in the locked position, and wherein when the keeper support bracket is in the unblocking position the keeper is able to be moved to the unlocked position. The strike further comprises a motor operatively connected to the keeper support bracket and actionable in a first direction to move the keeper support bracket toward the blocking position, and actionable in a second direction to move the keeper support bracket toward the unblocking position, wherein the second direction is opposite of the first direction. The strike further includes a biasing member applying a net force to the keeper support bracket, wherein the biasing member comprises a first spring and a second spring. A first spring constant of the first spring is different than a second spring constant of the second spring. The first spring applies a first force to the keeper support bracket in the first direction, and the second spring applies a second force to the keeper support bracket in the second direction, wherein when the keeper support bracket is in the blocking position, the net force of the biasing member applied to the keeper support bracket is approximately zero.
In a further aspect, the keeper support bracket may include an actuator extension that is operatively coupled to the motor, wherein the keeper support bracket is selectively moveable by the motor between the blocking position and the unblocking position. The motor may be a stepper motor, and a keeper release may be operatively coupled between the keeper support bracket and the keeper. The strike may further include a motor carrier operatively connected between the motor and the keeper support bracket, wherein the motor carrier may be formed of a polyether ether ketone polymer. Furthermore, the stepper motor may include a lead screw having a screw thread, and the motor carrier may include a carrier thread mateable with the screw thread, wherein when the stepper motor is actionable in either the first direction or the second direction, the motor carrier acts upon the keeper support bracket to move the keeper support bracket between the blocking position and the unblocking position.
In another aspect, the present invention includes a method of improving the performance of an electric strike. The electric strike includes a keeper movable between a locked position and an unlocked position, and a support bracket movable by a stepper motor actuator between a blocking position and an unblocking position. When the support bracket is in the blocking position the keeper is in the locked position, and wherein when the support bracket is in the unblocking position the keeper is in the unlocked position. The method comprises the steps of: a) providing a first spring operatively coupled to the support bracket to apply a first force in a first direction to move the support bracket toward the blocking position, wherein the first spring includes a first spring constant; b) providing a second spring operatively coupled to the support bracket to apply a second force in a second direction opposite the first direction to move the support bracket toward the unblocking position, wherein the second spring includes a second spring constant that is different than the first spring constant; and c) selecting the first and second spring constants so that a net force exerted on the support bracket by the first and second springs is approximately zero when the support bracket is in the blocking position, whereby the performance of the electric strike is improved by increasing an acceleration of the support bracket upon an initial movement of the support bracket toward the unblocking position by the stepper motor actuator.
The method may further comprise the step of selecting the first and second spring constants so that a net force exerted on the support bracket by the first and second springs is positive in the first direction applied in the unblocking direction when the support bracket is in the unblocking position.
Numerous applications, some of which are exemplarily described below, may be implemented using the present invention.
The present invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Corresponding reference characters indicate corresponding parts throughout the several views. The exemplifications set out herein illustrate currently preferred embodiments of the present invention, and such exemplifications are not to be construed as limiting the scope of the invention in any manner.
Referring now to
Turning again to
Referring now to
As further shown in
As further shown in
An alternate embodiment of the actuator is shown in
Actuation of stepper motor 274 by supplying a voltage having a first polarity causes rotation of lead screw 280 so as to advance motor carrier 275 (and actuator extension 270 of keeper support bracket 268 that is in touching contact with motor carrier 275) in a first, keeper unlocking direction shown as arrow 276 in
Supplying stepper motor 274 a voltage having the opposite polarity reverses rotation of lead screw 280 to move motor carrier 275 in a second keeper locking direction opposite the first keeper unlocking direction. Upon movement of motor carrier 275 in the second keeper locking direction shown as arrow 282 in
As best shown in
In the presently described embodiment, the spring constants of springs 277 and 279 are different and configured with respect to keeper support bracket 268 to provide equal but opposing forces on support bracket 268 so that when keeper support bracket 268 is in the position shown in
As best shown in
Importantly, the net lateral force exerted on support bracket 268 by biasing member 278 is zero in keeper locked position L. This provides for an increase in acceleration of support bracket 268 when actuator 274 is commanded to move the support bracket 268 in the unlocking direction to quickly release the latch from the keeper.
Over time, it is further noted that the internal threads 283 of motor carrier 275 may wear causing the force needed by stepper motor 274 to rotate lead screw 280 and to move support bracket 268 away from position L to increase. The resulting sluggishness of movement of support bracket 268 to in the unlocking direction would counter the advantages bestowed by the embodiment including the dual springs 277, 279 discussed above. To reduce wear of the internal threads, motor carrier 285 may be molded of a wear resistant, high performance engineering plastic such as a polyether ether ketone polymer (PEEK).
In accordance with the embodiment shown in
In accordance with an aspect of the present invention, actuator module 26″ may be configured to operate stepper motor 74″ as a low power actuator. To that end, and with additional reference to
As can be noted from the above, actuator module 26″ may be selected to operate in either a fail safe mode or a fail secure mode depending on whether the first position has keeper support 64, 64″ coupled to keeper release 62, 62″ (fail secure) or whether the first position has members 62/64, 62″/64″ decoupled from one another (fail safe). To ensure that the actuator drive operation completes when a pre-load condition is present, a position sensor 95″ may be used to supply the microcontroller with actuator position data. In one embodiment, position sensor 95″ may be a contactless linear position Hall sensor in conjunction with a magnet. It should be understood that the position sensor may incorporate any suitable sensor system capable of sensing the actuator drive position, such as, but not limited to, a photo sensor, a pressure sensor, a micro switch, a passive infrared sensor, a radio frequency (RF) sensor, a reed switch, or the like. If microcontroller 84″ determines the actuator drive was not successfully completed after receiving actuator position data from position sensor, microcontroller 84″ will continue to drive the actuator until the desired position is successfully reached. To conserve power, position sensor 95″ may be switched to a power down state when it is not being used.
In accordance with a further aspect of the present invention, the actuating device may be a springless electromagnet actuator having a non-magnetic armature containing a permanent magnet combined with a solenoid body and coils similar to that disclosed within US Patent Application, Ser. No. 13/833,671. When using such a springless electromagnet actuator, microcontroller 84″ can use input power 90″ to provide a first pulse having a first polarity to drive the armature to the second position. Input voltage 90″ may then charge super capacitor(s) 88″ through CCCV regulator 86″ under microcontroller 84″ control as described above. Once input power is removed, super capacitor(s) 88″ may then provide the power needed for a second pulse having a second polarity to return the armature to the first position.
While the actuating device has been described as either a solenoid, a stepping motor or a springless electromagnet actuator, it is understood the actuating device in accordance with the invention may include other types of motors, including a DC motor, or other types of powered actuating devices, including piezo electric and shape memory devices.
Turning now to
In accordance with this aspect, keeper 24 may include a groove 102 adapted to received face portion 54. One or more set screws 104 may be threadably inserted within corresponding threaded apertures 106 within face portion 54. Set screws 104 may be selectively advanced until the desire width is created, i.e., width W2. Groove 102 may include respective recesses 108 configured to receive a respective set screw 104. A fastener, such as hex screw 110 is then threaded through face portion 54 and into keeper 24 to secure face portion 54 to the keeper. Width W2 may be selected such there is little movement of the door latch, and subsequently the door, when the latch is locked within strike 20. Reduced movement minimizes unnecessary wear and tear on the latch and the strike, as well as reduces door movement and subsequent noise. In addition, when used in conjunction with a cylindrical-type lockset, and when extendable face portion 54 is adjusted outward and keeper 24 is in its locked position as shown in
As seen in both
As shown in
Deadbolt bracket 124 in accordance with the invention may be mounted within housing 22 by a pair of screws 126 passing through holes 114 define within back wall 28 of the housing and threaded into corresponding holes 127 defined in rear wall 128 of deadbolt bracket 124. Side wall 34 may include a slot 130 configured to receive a tab 132 extending from an end 135 of front wall 134 of deadbolt bracket 124. In this manner, deadbolt bracket 124 is rigidly secured along two faces of housing 22 such that any load placed on the deadbolt latch (not shown) impacts the deadbolt bracket and housing 22 and not keeper 24.
Thus, the deadbolt receiving chamber 123 of open-sided deadbolt bracket 124 provides more room and greater vertical clearance for the associated deadbolt and, if keeper 24 were to be compromised or otherwise fail, the door would remain secure due to the deadbolt securely residing within receiving chamber 123 of deadbolt bracket 124. In addition, deadbolt bracket 124 may also be made to be interchangeable across a multitude of electric strike models. While deadbolt bracket is shown as being U-shaped in
Referring to
Referring now again to
In yet another aspect of the invention, keeper 24′ may optionally include at least one extension flange 29′ that projects from an end of ramp element 23′ that extend beyond at least one of side edges 25′ of keeper base 27′. When keeper 24′ is in a locked position ((
Several aspects of this invention have been disclosed as being desirably interchangeable across a multiple of electric strike models, thereby demonstrating the versatility of the disclosed electric strike and its ability to meet various strike needs. In another aspect of the invention, a strike lip extension can be used with the disclosed electric strike in order to make the electric strike adaptable to fit a variety of door frames that might exist in the field. Referring to
Referring to
Referring now to
In accordance with a further aspect of the present invention, a method for locking or unlocking a door having an actuator-controlled electric strike for operating in conjunction with a latch of a lockset is included, wherein the latch has an engaged position so as to secure a door in a dosed state and a released position, and wherein the strike includes a housing including a back wall and opposing side walls and defining an entry chamber therein; a keeper rotatably disposed in the entry chamber about an axis for rotation between a locked position and a unlocked position; and an actuator module , including a keeper release configured to engage the keeper, and an actuator selectively movable between a first actuator position and a second actuator position, wherein when the actuator is in one of the first or second actuator positions the keeper release is coupled to the keeper and the keeper is secured in the locked position, and wherein when the actuator is selectively moved to the other of the first or second actuator positions the keeper release is decoupled from the keeper and the keeper is rotatable to the unlocked position, the method for unlatching comprising the steps of providing an input voltage to drive the actuator from a first position to a second position; after driving the actuator, using the input voltage to charge a capacitor; removing the input voltage; and providing a return voltage via the capacitor to drive the actuator from the second position to the first position.
The method may further include the actuator module having a microcontroller wherein the microcontroller senses an input polarity of the input voltage and drives the actuator from the first actuator position to the second actuator position. Further, the capacitor may be a super capacitor wherein the actuator module further includes a constant-current, constant-voltage (CCCV) charger, the microcontroller controlling the CCCV charger to charge the super capacitor after the actuator has been driven to the second actuator position, the super capacitor then providing a second voltage having a polarity opposite the input polarity to drive the actuator from the second actuator position to the first actuator position.
A method for changing an actuator module of a strike assembly is provided wherein said actuator module is a first actuating module including an actuator and a keeper release, comprising the steps of:
1) providing said strike assembly having said first actuator module disposed in a strike assembly housing wherein said housing includes a movable keeper, wherein the first actuator module includes a first actuating device comprising one of a solenoid or a motor, and further comprising a first keeper release operatively engageable with said movable keeper to selectively release said keeper from a locked position to a released position;
2) allowing for the removal of said first removable actuator module from said housing; and
3) allowing for the installation of a second removable actuator module in place of said first removable actuator module wherein the second actuator module includes a second actuating device comprising one of a solenoid or a motor, and further comprising a second keeper release operatively engageable with said movable keeper to selectively release said keeper from a locked position to a released position.
While the invention has been described by reference to various specific embodiments, it should be understood that numerous changes may be made within the spirit and scope of the inventive concepts described. Accordingly, it is intended that the invention not be limited to the described embodiments, but will have full scope defined by the language of the following claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 17/161,149, filed Jan. 28, 2021, which in turn is a continuation of U.S. patent application Ser. No. 15/098,041, filed Apr. 13, 2016, now U.S. Pat. No. 10,934,744, which in turn claims the benefit of U.S. Patent Application No. 62/147,468, filed Apr. 14, 2015, the contents of which are hereby incorporated by reference in their entirety.
Number | Date | Country | |
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62147468 | Apr 2015 | US |
Number | Date | Country | |
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Parent | 15098041 | Apr 2016 | US |
Child | 17161149 | US |
Number | Date | Country | |
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Parent | 17161149 | Jan 2021 | US |
Child | 17222399 | US |