1. Field of the Invention
The present invention relates to door lock devices, and more particularly, to a manually driven electronic deadbolt assembly with a fixed turnpiece, such that but for a ratcheting effect provided by a clutch assembly, an exterior turnpiece is rotatably fixed to a torque blade that in turn is rotatably fixed to a deadbolt mechanism.
2. Description of the Related Art
A keyed deadbolt assembly is used to supplement the level of security provided by a simple keyed lock configured integral with a doorknob. A traditional deadbolt assembly includes an exterior keyed lock cylinder and a cylinder body that projects away from the surface of a standard door. The lock cylinder has a tail piece that is operably connected to a deadbolt actuation mechanism to facilitate retraction and extension of the deadbolt. An interior turnpiece is provided on the interior side of the door, and also is operably connected to the deadbolt actuation mechanism.
Some attempts have been made to provide an electronic door latch, which may utilize motorized retraction of the latch bolt. Also, such electronic door latches may require door modification to accommodate the electronic door latch.
The present invention provides a manually driven electronic deadbolt assembly with a fixed turnpiece, such that but for a ratcheting effect provided by a clutch assembly, the exterior turnpiece is rotatably fixed to a torque blade that in turn is rotatably fixed to a deadbolt mechanism.
The invention, in one form thereof, is directed to an exterior actuator assembly for a manually driven electronic deadbolt assembly and configured to operate a deadbolt mechanism from an exterior space via a torque blade. The exterior actuator assembly has a locked condition and an unlocked condition. The exterior actuator assembly includes an exterior turnpiece rotatably mounted to a cylinder body. A torque blade driver is coupled to the torque blade. The torque blade driver has a perimetrical lock recess. The torque blade driver is rotatable about a first rotational axis. A clutch assembly is drivably interposed between the exterior turnpiece and the torque blade driver. A motor has a motor shaft arranged to rotate about a second rotational axis that is non-coaxial with the first rotational axis. A locking shifter is mounted to the cylinder body and is configured for axial translation along the second rotational axis. The locking shifter has a blocking tab portion configured for selective engagement with the perimetrical lock recess of the torque blade driver. A rotational-to-linear motion converter is drivably interposed between the motor shaft and the locking shifter and is configured such that a rotation of the motor shaft in a first rotational direction about the second rotational axis results in an axial displacement of the locking shifter in a first longitudinal direction to a locked position corresponding to the locked condition wherein the blocking tab portion of the locking shifter is engaged with the perimetrical lock recess of the torque blade driver to prohibit rotation of the torque blade via the exterior turnpiece, and a rotation of the motor shaft in a second rotational direction about the second rotational axis results in an axial displacement of the locking shifter in a second longitudinal direction to an unlocked position corresponding to the unlocked condition wherein the blocking tab portion of the locking shifter is disengaged from the perimetrical lock recess of the torque blade driver to permit rotation of the torque blade via the exterior turnpiece.
The invention, in another form thereof, is directed to a manually driven electronic deadbolt assembly for use on a door separating an exterior space from a secured space. The manually driven electronic deadbolt assembly includes an interior actuator assembly, an exterior actuator assembly, a deadbolt mechanism, and a torque blade. The deadbolt mechanism has a spindle drive opening. The torque blade is configured to be drivably received in the spindle drive opening of the deadbolt mechanism. The torque blade has a first end, a second end, and a first rotational axis. The interior actuator assembly is configured to operate the deadbolt mechanism from the secured space. The interior actuator is mechanically connected to the first end of the torque blade. An exterior actuator assembly is configured to operate the deadbolt mechanism from the exterior space. The exterior actuator assembly has a locked condition and an unlocked condition. The exterior actuator assembly includes a cylinder body, and an exterior turnpiece rotatably mounted to the cylinder body. A torque blade driver is coupled to the second end of the torque blade, with the torque blade driver having a perimetrical lock recess. A clutch mechanism is drivably interposed between the exterior turnpiece and the torque blade driver. A motor has a motor shaft arranged to rotate about a second rotational axis that is non-coaxial with the first rotational axis. A locking shifter is mounted to the cylinder body and is configured for axial translation along the second rotational axis. The locking shifter has a blocking tab portion configured for selective engagement with the perimetrical lock recess of the torque blade driver. A rotational-to-linear motion converter is drivably interposed between the motor shaft and the locking shifter and is configured such that a rotation of the motor shaft in a first rotational direction about the second rotational axis results in an axial displacement of the locking shifter in a first longitudinal direction to a locked position corresponding to the locked condition wherein the blocking tab portion of the locking shifter is engaged with the perimetrical lock recess of the torque blade driver to prohibit rotation of the torque blade via the exterior turnpiece. A rotation of the motor shaft in a second rotational direction about the second rotational axis results in an axial displacement of the locking shifter in a second longitudinal direction to an unlocked position corresponding to the unlocked condition wherein the blocking tab portion of the locking shifter is disengaged from the perimetrical lock recess of the torque blade driver to permit rotation of the torque blade via the exterior turnpiece.
The invention, in another form thereof, is directed to a method for operating a deadbolt mechanism mounted on a door that separates an exterior space from a secured space, the deadbolt mechanism having a spindle drive opening, the method including: providing a torque blade configured to be drivably received in the spindle drive opening of the deadbolt mechanism, the torque blade having a first end, a second end, and a first rotational axis; providing an interior actuator assembly for operating the deadbolt mechanism from the secured space, the interior actuator being mechanically connected to the first end of the torque blade; and providing an exterior actuator assembly for operating the deadbolt mechanism from the exterior space, the exterior actuator assembly having a locked condition and an unlocked condition, the exterior actuator assembly including: a cylinder body; an exterior turnpiece rotatably mounted to the cylinder body; a torque blade driver coupled to the second end of the torque blade, the torque blade driver having a perimetrical lock recess; a clutch mechanism drivably interposed between the exterior turnpiece and the torque blade driver; a motor having a motor shaft arranged to rotate about a second rotational axis that is non-coaxial with the first rotational axis; a locking shifter mounted to the cylinder body and configured for axial translation along the second rotational axis, the locking shifter having a blocking tab portion configured for selective engagement with the perimetrical lock recess of the torque blade driver; and a rotational-to-linear motion converter drivably interposed between the motor shaft and the locking shifter and configured such that a rotation of the motor shaft in a first rotational direction about the second rotational axis results in an axial displacement of the locking shifter in a first longitudinal direction to a locked position corresponding to the locked condition wherein the blocking tab portion of the locking shifter is engaged with the perimetrical lock recess of the torque blade driver to prohibit rotation of the torque blade via the exterior turnpiece, and a rotation of the motor shaft in a second rotational direction about the second rotational axis results in an axial displacement of the locking shifter in a second longitudinal direction to an unlocked position corresponding to the unlocked condition wherein the blocking tab portion of the locking shifter is disengaged from the perimetrical lock recess of the torque blade driver to permit rotation of the torque blade via the exterior turnpiece.
The above-mentioned and other features and advantages of this invention, and the manner of attaining them, will become more apparent and the invention will be better understood by reference to the following description of an embodiment of the invention taken in conjunction with the accompanying drawings, wherein:
Corresponding reference characters indicate corresponding parts throughout the several views. The exemplifications set out herein illustrate an embodiment of the invention, in one form, and such exemplifications are not to be construed as limiting the scope of the invention in any manner.
Referring now to the drawings, and more particularly to
Deadbolt mechanism 18 includes a housing 26 that carries a retractable deadbolt 28, and is configured as is well known in the art. Deadbolt mechanism 18 includes a deadbolt drive mechanism 30 having a spindle drive 30-1 that has a spindle drive opening 30-2. Spindle drive opening 30-2 is non-circular, e.g., having a square or D-shaped cross-section, so as to receive a rotational driving force from torque blade 111 having a similarly shaped profile.
Torque blade 111 extends between interior actuator assembly 200 and exterior actuator assembly 100, and is slidably received through spindle drive opening 30-2 of deadbolt drive mechanism 30. Torque blade 111 has a first end 111-1 that is received by a portion of interior actuator assembly 200 and has a second end 111-2 that is received by a portion of exterior actuator assembly 100.
Torque blade 111 is configured to drive deadbolt drive mechanism 30 of deadbolt mechanism 18 by a rotation of torque blade 111 about first rotational axis 130. Thus, torque blade 111 is configured to be drivably received in spindle drive opening 30-2 of deadbolt mechanism 18, and in this regard torque blade 111 has a cross-section shape, e.g., square or D-shaped, that corresponds to the shape of spindle drive opening 30-2 so as to convey a rotational force to deadbolt drive mechanism 30 of deadbolt mechanism 18.
Referring also to
Interior actuator assembly 200 is configured to operate deadbolt mechanism 18 from the secured space 16 via interior turnpiece 208. More particularly, interior actuator assembly 200 is configured in a fail-safe manner to provide a continuous drive via interior turnpiece 208 through torque blade 111 to selectively retract and extend retractable deadbolt 28 of deadbolt mechanism 18 by a rotation of interior turnpiece 208. In other words, interior turnpiece 208 is always drivably connected to deadbolt mechanism 18 to operate retractable deadbolt 28.
Referring to FIGS. 1 and 4-8, the exterior actuator assembly 100 includes a cylinder guard cover 101, a cylinder body 102, a printed circuit board box 103, a printed circuit board 104, a keypad 105, a keypad cap 106, a locking shifter 107, a motor 108, a torque blade driver 109, a collar 110, a torque blade 111, a retainer clip 112, a pin follower 113, a motor spring 114, a torsion spring 115, a turnpiece clutch shaft 116, a clutch spring 117, a turnpiece clutch driver 118, an exterior turnpiece 119, a retaining ring 120, and a turnpiece spring 121.
In general, cylinder body 102 is a non-rotatable chassis that is used to mount exterior actuator assembly 100 to an exterior of door 12. Turnpiece 119 is rotatably mounted to cylinder body 102, and is rotatably coupled to torque blade 111 for operation of deadbolt mechanism 18 via a clutch assembly 124 and the torque blade driver 109. Thus, but for a ratcheting effect provided by clutch assembly 124, turnpiece 119 is rotatably fixed to torque blade 111, and in turn is rotatably fixed to deadbolt mechanism 18. The locking of the manually driven electronic deadbolt lock unit to prevent actuation of deadbolt mechanism 18 by the exterior actuator assembly 100 is effected by an off-axis blocking of the rotation of the torque blade driver 109, as described in more detail below.
Clutch assembly 124 includes turnpiece clutch shaft 116, clutch spring 117, turnpiece clutch driver 118 and retaining ring 120. Turnpiece clutch shaft 116 includes a proximal end 116-1 and a distal end 116-2. Intermediate of the proximal end 116-1 and the distal end 116-2 is an annular groove 116-3. Spaced toward distal end 116-2 from the annular groove 116-3 is a pair of opposed V-shaped ramps 116-4, 116-5.
Referring to
Referring also to
Referring also to
Referring also to
The proximal end 116-1 of turnpiece clutch shaft 116 includes an end bore 116-6 defining a sidewall 116-7 in which there is formed a pair of diametrically opposed axially extending slots 116-8. The turnpiece spring 121 is inserted into the end bore 116-6, and a bore 119-1 in turnpiece 119 is fitted over the proximal end 116-1 of the turnpiece clutch shaft 116. A turnpiece connecting pin 126 is then inserted radially through a radial hole 119-2 in the turnpiece 119 and into and through the pair of diametrically opposed axially extending slots 116-8 on the sidewall 116-7 of the turnpiece clutch shaft 116 so as to mount the turnpiece 119 to turnpiece clutch shaft 116. The turnpiece spring 121 thus is interposed in a state of compression between the floor of the end bore 116-6 in the turnpiece clutch shaft 116 and the turnpiece 119, so as to bias the turnpiece 119 axially outwardly in direction D2.
Torque blade driver 109 is configured for driving engagement with torque blade 111, and torque blade 111 is configured, e.g., with a profiled perimeter (square, D-shaped, etc.) for driving engagement with the deadbolt mechanism 18. Torque blade driver 109 is further configured with a perimetrical, e.g., circumferential, lock recess 109-1 for selectively receiving a blocking tab portion 107-1 of locking shifter 107. Torque blade driver 109 is axially and rotatably mounted to torque blade 111, with torque blade driver 109 and torque blade 111 being held in driving engagement by an inwardly facing tab 112-1 of retainer clip 112. Torque blade driver 109 further includes an inner hub 109-2 having one or more circumferential slot(s) 109-3 for respectively receiving a corresponding circumferential tab 118-3 of turnpiece clutch driver 118.
Collar 110 includes a bore 110-1 serving as a bearing support for an outer annular surface 109-4 of torque blade driver 109, and with torque blade driver 109 being axially restrained in the distal direction D1 by collar 110. The collar 110 is mounted to cylinder body 102 via fasteners, e.g., screws, to close the interior side of cylinder body 102.
Torsion spring 115 has two protruding ends 115-1, 115-2 that are arranged to respectively engage a portion of torque blade driver 109 and a portion of cylinder body 102, so as to rotationally bias the torque blade driver to its home position 115-3 (see
Cylinder body 102 includes a second axial opening 102-2 for mounting motor 108. Motor 108 has a motor shaft 108-1 that is drivably coupled to motor spring (coil spring) 114, with motor shaft 108-1 and motor spring 114 being arranged to rotate about a second rotational axis 132. Second rotational axis 132 is arranged to be parallel to, and thus non-coaxial with, first rotational axis 130. Locking shifter 107 has an axial opening 107-2 positioned axially relative to second rotational axis 132. The axial opening 107-2 of locking shifter 107 is sized to loosely accommodate the circumferential perimeter of motor spring 114, such that motor spring 114 is moveable within the axial opening 107-2. Locking shifter 107 includes the blocking tab portion 107-1, which is configured to selectively engage the circumferential lock recess 109-1 of torque blade driver 109.
A proximal portion 113-1 of the pin follower 113 is radially received into a hole in an annular portion of locking shifter 107. A distal portion 113-2 of the pin follower 113 radially projects inwardly toward second rotational axis 132 from the annular portion of locking shifter 107, with the distal portion 113-2 of pin follower 113 being received between adjacent coils of motor spring 114 to form a rotational-to-linear motion converter. Locking shifter 107 includes one or more winged protrusions 107-3 configured to engage a corresponding slot or ledge in cylinder body 102 to prevent rotation of locking shifter 107 about second rotational axis 132 relative to motor spring 114 when motor spring 114 is rotated by motor 108 about second rotational axis 132.
With the distal portion 113-2 of pin follower 113 drivably received between the coils of motor spring 114, rotation of motor spring 114 by motor shaft 108-1 of motor 108 in a first rotational direction about rotational axis 132 results in an axial displacement of locking shifter 107 in a first longitudinal direction, e.g., in direction D1, to a locked position (see
When the blocking tab portion 107-1 of locking shifter 107 is engaged with circumferential lock recess 109-1 of torque blade driver 109, the manually driven electronic deadbolt lock unit is in the locked condition as illustrated in
Conversely, when blocking tab portion 107-1 of locking shifter 107 is disengaged from circumferential lock recess 109-1 of torque blade driver 109, the manually driven electronic deadbolt lock unit is in the unlocked condition, as illustrated in
Referring again to
In operation, a user will enter a pre-programmed access code via keypad 105, which in turn is converted into a command to shift locking shifter 107 in direction D2 to an unlocked position (see
Thus, when turnpiece 119 is rotated (see
Referring to
Referring to
Interior actuator assembly 200 is configured to operate deadbolt mechanism 18 from the secured space 16 via interior turnpiece 208. More particularly, cover 206 has an opening for mounting interior turnpiece 208 via a ring retainer 210 to thus be rotatably mounted to interior cover 206. Interior torque blade driver 212 is drivably attached to interior turnpiece 208. Interior actuator assembly 200 is configured in a fail-safe manner to provide a continuous drive via interior turnpiece 208 through torque blade 111 to selectively retract and extend retractable deadbolt 28 of deadbolt mechanism 18 by a rotation of interior turnpiece 208. In other words, interior turnpiece 208 is always drivably connected to deadbolt mechanism 18 to operate retractable deadbolt 28.
As shown in
Interior chassis 214 includes a switch 218 having a protruding actuator 220, a wiring connector 222, and a programming button 224. Actuator 220 of switch 218 is positioned to be selectively actuated by a camming action caused by a rotation of interior torque blade driver 212. Interior rose (base) 202 has a wiring channel 202-1 for receiving a wiring harness from exterior actuator assembly 100, described above, which in turn is electrically coupled to wiring connector 222. Interior rose (base) 202 has a single post 202-2 for mounting the cover 206 via a screw.
In
Programming button 224 is provided to allow the programming of the memory 104-5 of printed circuit board 104 of the exterior actuator assembly 100 with a plurality of unique user access codes.
During operation, a valid access code is entered on the keypad 105 to permit the unlocking of the deadbolt mechanism 18 via exterior turnpiece 119. When the access code is entered, the user has a period of time, e.g., 5 to 10 seconds, in which to rotate exterior turnpiece 119 to unlock the deadbolt mechanism 18. After the period of time, the motor 108/locking shifter 107 is returned back to the locked condition, as illustrated in
While this invention has been described with respect to embodiments of the invention, the present invention may be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the invention using its general principles. Further, this application is intended to cover such departures from the present disclosure as come within known or customary practice in the art to which this invention pertains and which fall within the limits of the appended claims.
This is a non-provisional application based upon U.S. provisional patent application Ser. No. 61/514,192, filed Aug. 2, 2011.
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