Deadbolts are typically operated by a user (e.g., with a key on an outside of the door or a thumbturn on the inside of the door) to secure a door against unwanted intrusions. At least some known deadbolts are motorized, but it can often be difficult to install these systems within doors, as well as deliver reliable power.
In an aspect, the technology relates to an electronic deadbolt including: a face plate; a housing including a first end and an opposite second end, wherein the first end is releasably coupled to the face plate, wherein the housing further includes a bolt compartment defining a bolt axis and a battery compartment defining a battery axis, and wherein the bolt axis is substantially parallel to and offset from the battery axis, and the bolt compartment is separated from the battery compartment proximate the second end of the housing; and a bolt module disposed within the bolt compartment, wherein the bolt module includes a motor and a deadbolt, and wherein the deadbolt is configured to be selectively linearly extended from the face plate along the bolt axis.
In an example, both of the bolt compartment and the battery compartment are substantially cylindrical. In another example, the bolt compartment has a first outer diameter and the battery compartment has a second outer diameter, and the first outer diameter is approximately equal to the second outer diameter. In yet another example, the bolt compartment and the battery compartment are approximately 1¼ inches in diameter. In still another example, the housing further includes a spacer disposed at least partially between the bolt compartment and the battery compartment at the first end. In an example, the bolt module further includes a lead screw configured to be rotated by the motor about the bolt axis, and the deadbolt is coupled to the lead screw.
In another example, the bolt module further includes a support coupled to an inside surface of the bolt compartment, wherein the support is engaged with the deadbolt such that upon rotation of the lead screw, rotation of the deadbolt is prevented so that rotational movement of the lead screw is transferred into linear movement of the deadbolt. In yet another example, the support at least partially supports the motor and the deadbolt within the bolt compartment. In still another example, a substantially cylindrical cover is threadably coupled to the face plate adjacent the battery compartment.
In another aspect, the technology relates to an electronic deadbolt including: a bolt compartment having a bolt axis and configured to house a bolt module, wherein the bolt module includes: a motor; a lead screw configured to be rotated by the motor about the bolt axis; and a deadbolt coupled to the lead screw and upon rotation of the lead screw, is linearly extendable from the bolt compartment along the bolt axis; a battery compartment having a battery axis and configured to house a battery module, wherein the bolt axis is substantially parallel to and offset from the battery axis; and a face plate releasably coupled to the bolt compartment and the battery compartment.
In an example, the bolt compartment and the battery compartment are coupled together to form a single housing. In another example, at least a portion of the bolt compartment and the battery compartment are separated by a gap. In yet another example, both of the bolt compartment and the battery compartment are substantially cylindrical. In still another example, the bolt compartment has a first outer diameter and the battery compartment has a second outer diameter, and the first outer diameter is approximately equal to the second outer diameter. In an example, the bolt compartment is independent from the battery compartment.
In another example, the face plate includes a shoulder extending therefrom and the compartments include a lip, and when the compartments are coupled to the face plate the shoulder engages with the lip. In yet another example, the bolt compartment and the battery compartment are coupled to the face plate with a snap-fit connection. In still another example, the bolt module further includes a position sensor.
In another aspect, the technology relates to a method of installing an electronic deadbolt on a door, the method including: boring two substantially cylindrical holes adjacent to one another on the door; inserting at least a portion of the electronic deadbolt into the two cylindrical holes, wherein the electronic deadbolt includes a face plate and a housing including a bolt compartment and a battery compartment, wherein each compartment is inserted within a respective hole, and wherein a bolt module is disposed within the bolt compartment and a battery module is disposed within the battery compartment; and securing the face plate to the door.
In an example, the method further includes inserting a power source into the battery compartment.
There are shown in the drawings, examples that are presently preferred, it being understood, however, that the technology is not limited to the precise arrangements and instrumentalities shown.
In the example, the door panel 104 is a pivoting door; however, the electronic deadbolt systems described herein can be utilized in entry doors, sliding doors, pivoting patio doors, and any other door as required or desired. In sliding patio doors, the electronic deadbolts 102 have linearly extending locking elements that may extend from the head 108 or the sill 110 of the sliding door. If utilized on the locking edge 112 of a sliding door, the electronic deadbolt 102 would require a hook-shaped locking element that would hook about a keeper so as to prevent retraction of the door.
In the example, each electronic deadbolt system 102 is positioned to as to extend into a keeper 114. The keepers 114 may be standard keepers or electronic keepers as described in U.S. patent application Ser. No. 15/239,714, filed Aug. 17, 2016, entitled “Locking System Having an Electronic Keeper” the disclosure of which is herein incorporated by reference in its entirety. The system 100 also includes an electronic keeper 116 configured to receive a standard (e.g., manually-actuated) deadbolt 118, as typically available on an entry or patio door.
In one example, once the deadbolt 118 is manually actuated into the locking position, the electronic keeper 116 detects a position of the deadbolt 118 therein. A signal may be sent to the remotely located electronic deadbolt systems 102, thus causing actuation thereof. At this point, the door 104 is now locked at multiple points. Unlocking of the manual deadbolt 118 is detected by the electronic keeper 116 (that is, the keeper 116 no longer detects the presence of the deadbolt 118 therein) and a signal is sent to the remote electronic deadbolts 102 causing retraction thereof, thus allowing the door 104 to be opened. Thus, the electronic deadbolts described herein may be utilized to create a robust multi-point locking system for a door and to improve the security thereof.
In another example, the system 100 may include a controller/monitoring system, which may be a remote panel 120, which may be used to extend or retract the electronic deadbolt systems 102, or which may be used for communication between the various electronic keepers 114 and deadbolts 102. Alternatively or additionally, an application on a remote computer or smartphone 122 may take the place of, or supplement, the remote panel 120. By utilizing a remote panel 120 and/or a smartphone 122, the electronic deadbolt systems 102 may be locked or unlocked remotely, thus providing multi-point locking ability without the requirement for manual actuation of the deadbolt 118. Additionally, any or all of the components (electronic deadbolt system 102, keeper 116, panel 120, and smartphone 122) may communicate either directly or indirectly with a home monitoring or security system 124. The communication between components may be wireless, as depicted, or may be via wired systems.
The electronic deadbolts described herein are configured to be more easily installed within the door 104 and/or frame 106. Some known electronic deadbolts have a non-cylindrical shapes that require complex cavities to be formed in the door and/or frame. This increases the difficulty of installation of the electronic deadbolt. In one example, the electronic deadbolts described herein include a bolt module and a separate battery module that are each disposed within cylindrical housings. These cylindrical housings enable typical boring tools (e.g., a drill and a bit) to be used to install the electronic deadbolts on the edge of the door. For example, the cylindrical housings may correspond in shape and size of the manual deadbolt so that the tools utilized to install the manual deadbolt can be used to install the electronic deadbolts. Accordingly, a more efficient installation of the remote electronic deadbolts is enabled, even by untrained purchasers. Furthermore, the electronic deadbolt described herein is constructed and configured in a manner that reduces overall space and limits end-user access to internal components.
The housing 202 is releasably coupled to the face plate 204 and disposed on one side thereof. The housing 202 includes a first end 209 that is configured to couple to the face plate 204 and an opposite second end 211. The housing 202 also includes a bolt compartment 210 configured to house a bolt module 212 therein, and a battery compartment 214 configured to house a battery module 216 therein. In the example, the bolt compartment 210 is separated from the battery compartment 214 proximate the second end 211 of the housing 202 such that a gap 218 is formed therebetween.
As illustrated, both the bolt compartment 210 and the battery compartment 214 are substantially cylindrical in shape and extend substantially orthogonally to the longitudinal axis 206. In the example, the bolt compartment 210 and the battery compartment 214 have approximately equal outer diameters so that a single boring tool, such as a drill, may be utilized for installation of both compartments of the electronic deadbolt 200. For example, the outer diameter may be approximately 1¼ inches in diameter. In other examples, the outer diameter may be between, and include, ½ inches and 2 inches as required or desired. In an aspect the outer diameter may correspond to standard spade drill bits (e.g., ⅞ inches, 1 inch, 1⅛ inches, etc.). In other examples, the compartments 210, 214 may have different outside diameters as required or desired. For example, the bolt compartment 210 may have an outside diameter that is smaller than, or greater than, the battery compartment 214 (e.g., for a larger power source).
The bolt compartment 210 is separated by the gap 218 extending along the longitudinal axis 206 from the battery compartment 214, such that each part of the housing 202 may be received within a corresponding and discrete bore in the door and/or frame. As described above, this enables a more efficient installation of the electronic deadbolt 200. For example, two boreholes can be drilled out from the door and/or frame by a common drill and bit so that the electronic deadbolt 200 can be installed. This reduces the need to form complex cavities (e.g., irregular shapes) in the door and/or frame for the deadbolt assembly.
In other examples, both the bolt compartment 210 and the battery compartment 214 may be combined in to a single compartment, for example, a substantially oval-shaped housing 202, with both the bolt module 212 and the battery module 216 in the same compartment space. In this example, the bolt module 212 and the battery module 216 are still stacked on top of one another. Additionally, the oval-shaped housing 202 can still increase installation efficiencies because it is easier to form an oval shape than a square housing shape in a door and/or frame.
In the example, the housing 202 may be removably coupled to the face plate 204 such that the bolt module 212 and the battery module 216 are accessible. For example, the housing 202 may be coupled to the face plate 204 by one or more snap locks 220 (e.g., a protrusion extending from the face plate and a corresponding opening defined in the housing that can be press fit together and retain the housing to the face plate). As illustrated, the bolt compartment 210 and the battery compartment 214 each has a pair of opposing snap locks 220. In other examples, the housing 202 may be coupled to the face plate 204 via any other connection method as required or desired.
In the example, the bolt compartment 210 defines a bolt axis 234 and at least partially houses the bolt module 212. The bolt module 212 includes a motor 224 that is configured to drive a rotating shaft based on power provided from the battery module 216. In the example, the motor 224 may be an off-the-shelf unit that includes an integral gear set 226 surrounded by a chassis 228 and is communicatively coupled to a circuit board 227 (shown in
The support 230 is sized and shaped to engage within the bolt compartment 210 and includes an outer surface having slots 229 that correspond to protruding channels 231 within the bolt compartment 210 such that the bolt module 212 can be circumferentially aligned within the bolt compartment 210 during assembly. Additionally, the support 230 being engaged with the bolt compartment 210 prevents the bolt module 212 from rotating within the compartment during operation (e.g., rotational movement induced by the motor 224). As described above, the bolt compartment 210 is similarly sized to the battery compartment 214 to facilitate easier installation in the door/frame, and thus, the bolt compartment 210 may be sized larger than needed for the bolt module 212. Accordingly, the support 230 also acts as a spacer to radially align the motor 224 and other components within the bolt compartment 210 and along the bolt axis 234.
The bolt module 212 also includes a lead screw 232 that is connected to the motor 224, via the gear set 226 and shaft, and is configured to be rotated about the bolt axis 234 by the motor 224. The lead screw 232 includes a nut 236 that connects the lead screw 232 to a deadbolt 238, such that rotation of the lead screw 232 around the bolt axis 234 translates into linear movement of the deadbolt 238 along the bolt axis 234. Thus, rotation of the lead screw 232 driven by the motor 224 can selectively extend and retract the deadbolt 238 from the bolt compartment 210 and the face plate 204.
The deadbolt 238 includes a first extension end 235 that is tapered for extension into a corresponding keeper to lock the door. A second end 237 of the deadbolt 238 includes a recess for securing the nut 236 to the deadbolt 238. An internal bore 239 extends from the second end 237 of the deadbolt 238 towards the first end 235 such that a portion of the lead screw 232 can extend within the deadbolt 238 during the retraction operations. In other examples, the nut 236 may be integral with the deadbolt 238. Additionally, a pair of projections 241 extend from the second end 237 of the deadbolt 238. The projections 241 are sized and shaped to be received within corresponding recesses 243 extending longitudinally within the support 230. By slidingly engaging the deadbolt 238 with the support 230, upon rotation of the lead screw 232, rotation of the deadbolt 238 is prevented so that rotational movement of the lead screw 232 is transferred into linear movement of the deadbolt 238.
The bolt module 212 also includes an O-ring 240 that is positionable between the support 230 and the face plate 204 and restricts dust and debris from accumulating within the bolt compartment 210. In the example, the face plate 204 defines a bolt opening 242 that is sized and shaped to enable the deadbolt 238 to extend and retract with respect to the face plate 204. On one side of the face plate 204, the face plate 204 includes a housing extension 244 that is shaped and sized to receive the first end 209 of the housing 202 and secure the electronic deadbolt assembly 200 together. For example, the snap locks 220 can be positioned on the housing extension 244.
In some examples, the bolt module 212 may further include a position sensor 245 (shown in
Accordingly, to at least partially absorb the loads generated by the hard stops and the motor drive, the position sensor 245 may be used to detect the position of the deadbolt 238 and stop, slow, and/or reverse the motor 224 before the hard stop is reached. This increases the life span of the bolt module 212 and the motor 224. The sensor 245 may be any type of switch, sensor, transducer/transformer, encoder, etc. that enables the function of the bolt module 212 as described herein. Additionally or alternatively, a flexible coupling (not shown) may be used between the motor shaft and the leadscrew so as to absorb loads before the loads reach the gear set 226 and the motor 224.
In the example, the battery compartment 214 defines a battery axis 254 and at least partially houses the battery model 216. The battery model 216 includes a power source 246 (e.g., a battery) and electrical contacts (not shown) that enable power to be extracted from the power source 246. The electrical contacts may be at least partially recessed within the battery compartment 214 such that the power source 246 may easily slide within the battery compartment 214. In the example, power source 246 may be a “D” size battery and as such, the battery compartment 214 is sized and shaped to receive one “D” battery. Although other battery types, arrangements, and power sources may be utilized as required or desired. Additionally or alternatively, the electronic deadbolt 200 may be connectable to the structure's line power that it is placed within.
The face plate 204 defines a battery opening 248 that is sized and shaped to enable the power source 246 to be inserted and removed through the face plate 204. The battery opening 248 has a removable cover 250 that provides access to the battery compartment 214 so that the bolt compartment 210 does not have to be disturbed while replacing the power source 246. The cover 250 may be cylindrically-shaped to correspond to the shape of the power source 246 and securable to the face plate 204 via a threaded connection or any other connection as required or desired. In other examples, cover 250 may have any other shape (e.g., rectangular, oval, etc.) as required or desired, and may or may not correspond to the shape of the power source 246. The cover 250 may include a slot 252 on the face of the cover 250 that enables a screwdriver or a coin to be utilized to rotate the cover 250. The cover 250 is configured to secure flush to the surface of the face plate 204 so that it does not interfere with the opening and closing of the door.
The battery compartment 214 defines the battery axis 254 along which the power source 246 is positioned along. The battery axis 254 is substantially parallel, but offset, from the bolt axis 234. Additionally, both the battery axis 254 and the bolt axis 234 are substantially orthogonal to the longitudinal axis 206 of the face plate 204. This configuration enables access to the power source 246 and extension/retraction of the deadbolt 238 via the face plate 204. Also, installation of the electronic deadbolt assembly 200 in the door is easier because the housing 202 that contains the components is shaped and size to only require two bore holes. Overall, the electronic deadbolt 200 is constructed and configured in a manner that reduces overall space, eases installation (even by untrained purchasers), for example, through use of a standard size drill bit, and limits end-user access to critical internal components (e.g., the motor and circuit board).
The bolt compartment 210 includes one or more protruding channels 231 such that the support 230 (shown in
Around a perimeter of the first end 209 of the housing 202, a lip 262 is defined so that the housing 202 may be secured around the housing extension 244 of the face plate 204 (shown in
In addition, the housing extension 244 extends from one side and includes a shoulder 268 that is configured to be received at least partially within the lip 262 of the housing 202 (shown in
The materials utilized in the manufacture of the lock described herein may be those typically utilized for lock manufacture, e.g., zinc, steel, aluminum, brass, stainless steel, etc. Molded plastics, such as PVC, polyethylene, etc., may be utilized for the various components. Material selection for most of the components may be based on the proposed use of the locking system. Appropriate materials may be selected for mounting systems used on particularly heavy panels, as well as on hinges subject to certain environmental conditions (e.g., moisture, corrosive atmospheres, etc.).
While there have been described herein what are to be considered exemplary and preferred examples of the present technology, other modifications of the technology will become apparent to those skilled in the art from the teachings herein. The particular methods of manufacture and geometries disclosed herein are exemplary in nature and are not to be considered limiting. It is therefore desired to be secured in the appended claims all such modifications as fall within the spirit and scope of the technology. Accordingly, what is desired to be secured by Letters Patent is the technology as defined and differentiated in the following claims, and all equivalents.
This application claims priority to and the benefit of U.S. Provisional Patent Application No. 62/641,511, filed on Mar. 12, 2018, the disclosure of which is hereby incorporated herein by reference in its entirety.
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Number | Date | Country | |
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62641511 | Mar 2018 | US |