Any and all applications, if any, for which a foreign or domestic priority claim is identified in the Application Data Sheet of the present application are hereby incorporated by reference under 37 CFR 1.57.
Electronic locks have a number of advantages over normal mechanical locks. For example, electronic locks may be encrypted so that only a key carrying the correct code will operate the lock. In addition, an electronic lock may contain a microprocessor so that, for example, a record can be kept of who has operated the lock during a certain time period or so that the lock is only operable at certain times. An electronic lock may also have the advantage that, if a key is lost, the lock may be reprogrammed to prevent the risk of a security breach and to avoid the expense associated with replacement of the entire lock.
Described herein are example fluid guards that can be used with locking devices. Various aspects may be particularly applicable to electrical locks, but they may also be applicable to mechanical locks.
For purposes of summarizing the disclosure, certain aspects, advantages and novel features are discussed herein. It is to be understood that not necessarily all such aspects, advantages or features will be embodied in any particular embodiment disclosed herein, and a myriad of combinations of such aspects, advantages, or features may be implemented.
A locking device guard can include a guard head, a guard body, and a hinge. The guard head may include a fluid absorber, a frame that is shaped to receive the fluid absorber, and a fastening mechanism. The guard body can be coupled with an electronic lock. The guard body can include an aperture that is configured to expose a face of the electronic lock. The aperture may also receive the fluid absorber. The fluid absorber may contact the face of the electronic lock and to thereby absorb fluid off of the face of the electronic lock. The guard body may further include a fastening receiver that is configured to mate with the fastening mechanism. The hinge can connect the guard head and the guard body and be configured to define an open position and a closed position of the locking device guard.
A locking device guard head can include a fluid absorber. The fluid absorber can be inserted into a cup of a face of a lock. The fluid absorber may also absorb fluid from the face of the lock. The guard head can also include a frame that is shaped to receive the fluid absorber. The guard head can include a fastening mechanism. The locking device guard head can prevent a flow of fluid from an exterior of the guard head to the face of the lock.
A locking device guard can be used on an access panel of an access box. The locking device guard can include a latch of the access panel. The locking device guard may include a guard door, a guard body, and a hinge. The guard door may be attached to the latch of the access panel. The guard door can include a fluid absorber. The guard base may be attached to the access panel of the access box. The guard base can include an aperture and a flange. The aperture may be configured to expose a face of an electronic lock that is disposed within the access panel. The aperture may also be configured to receive the fluid absorber, for example, so as to permit the fluid absorber to contact the face of the electronic lock and to thereby permit absorption of fluid off of the face of the electronic lock. The flange may be disposed at least partially about the aperture. The hinge can connect the guard base and the guard door and be configured to define an open position and a closed position of the locking device guard.
The following drawings and the associated descriptions are provided to illustrate embodiments of the present disclosure and do not limit the scope of the claims.
Various structures can be used to cover a lock body. For example, locking devices may include weatherproofing features. Some designs may include providing one or more seals on a padlock body and/or on a key. However, many shortcomings of the prior art exist for which this application provides beneficial and novel solutions.
Described herein are example fluid guards that can be used with locking devices. Various aspects may be particularly applicable to electrical locks, but they may also be applicable to mechanical locks. Electrical or mechanical locks can be used in secure boxes, cabinets, and the like. These locks may be susceptible to problems cause by fluids, such as water, oils, solvents, acids, bases, salts, alcohols, and other fluids containing ketones, salts, glycols, or esters. For example, electronic locking devices may be damaged and/or rendered less effective in the presence of fluids, which can cause short circuits or otherwise disrupt communications. To protect a lock from fluids or other harmful substances, a fluid guard may be used.
A lock can be outfitted with a fluid guard described herein. The fluid guard can prevent fluids or dust from coming in contact with certain parts of the lock, such as a face of the lock. Some parts of a lock may be particularly sensitive to changes in physical dimensions, such as at a lock face, where a key may be inserted. Repeated exposure to fluid can be accompanied with an accumulation of rust, debris, microorganisms, and/or a variety of other undesirable effects.
Fluid guards described herein may also improve the functionality of the lock itself. Some electronic locking mechanisms may operate on a principle of inductance or capacitance, and fluid between lock and key components could change the distance between those components and therefore negatively affect communications. For example, an electronic lock may include a partial capacitor comprising a capacitive metal plate in communication with a processor. The capacitive metal plate of the partial capacitor can form a capacitor with a corresponding capacitive metal plate of a key when brought into proximity with the metal plate of the lock, thereby allowing for capacitive data or power transfer between the lock and key. Some examples of such locking mechanisms are disclosed in U.S. Pat. No. 9,710,981, titled “Capacitive Data Transfer in An Electronic Lock and Key Assembly,” filed May 5, 2015 (“the '981 patent”), which is incorporated by reference herein in its entirety for all purposes.
Any fluid between these capacitive plates may change the distance between the plates and hence the capacitance, which can limit the ability of the key and lock to communicate effectively or at all. Thus, the fluid guard can be used to prevent or reduce the incidence of fluids covering the capacitive plate of the lock. Further, the fluid guard can include a fluid-absorbent material that can wipe or wick away fluid from the face of the capacitive plate of the lock.
Although the included figures and following description focus on a fluid guard for an example padlock, it should be understood that the fluid guard can be adapted to protect an electronic or mechanical lock included in a cabinet or in another enclosure or other type of lock.
Example Padlock with Fluid Guard
In certain embodiments, when the electronic key 650 engages the lock assembly 600 there are two transfers that occur. The first transfer can be a transfer of power and the second transfer can be a transfer of data. The electronic key 650 may include a partial capacitor comprising a capacitive metal plate in communication with a processor. The capacitive metal plate of the partial capacitor can form a capacitor with a corresponding capacitive metal plate of a lock when brought into proximity with the metal plate of the lock, thereby allowing for capacitive data or power transfer between the key and lock (see
As discussed above, however, fluid can interfere with the capacitive functionality described. For example, fluid that interferes with an electronic communication between the lock and the key may hinder the functionality of the key, for example, by altering a capacitance formed between the lock and the key capacitive plates. The fluid guard 400 and fluid absorber 500 can ameliorate this type of problem, among others.
As shown, the fluid guard 400 is in an open position. The fluid guard 400 can include a guard body 404 and a corresponding guard head 408. As shown, for example, the fluid guard 400 may be generally elongate such that a length of the guard body 404 is greater than a width of the guard body 404. In this way, the length may be measured along a major axis and/or the width be measured along a minor axis of the guard body 404. However, the guard body 404 and guard head 408 may be square, oval, round, or otherwise differently shaped than shown here.
One or more sides of the guard body 404 may be rounded, as shown in
To close the fluid guard 400, a fastening mechanism 428 on the guard head 408 can mate with (for example, be inserted into, snap fit with, friction fit with, or the like) a corresponding fastening receiver 440. The fastening mechanism 428 can include a cantilevered portion or other ledge (for example, sloped ledge), as shown. The fastening mechanism 428 may be an extension of another portion of the guard head 408, such as a fastening body 448, as shown. The fastening mechanism 428 can have a snap fit with the fastening receiver 440. The fastening receiver 440 can include a cantilevered portion or other type of ledge. In some embodiments, the fastening receiver 440 may include a slot in a portion of the guard body 404. The fastening receiver 440 may be attached to an extension from a surface of the guard body 404, as shown.
Other mechanisms can be used to close the fluid guard 400. For instance, the guard head 408 may be closed using a friction fit. Additionally or alternatively, a latch mechanism may be used to close the guard head 408. In some embodiments, a magnet may be inserted into the fluid absorber 500 and/or the guard head 408. A magnetic element (for example, a magnet) may be inserted in the guard body 404 to which the magnet may be attracted. This configuration can be used to encourage the guard head 408 to remain in a closed position.
One or more components of the fluid guard 400 may include a resilient material. The resilient material may include, for example, a synthetic material such as a synthetic polymer (for example, a synthetic elastomer, a synthetic plastic, etc.). For example, the resilient material of the fluid guard 400 may comprise silicone. Additionally or alternatively, the resilient material may include a natural material, such as a polymer of organic compound(s). The material of the fluid guard 400 can have a durometer of between about 10 and 50. In some embodiments, the durometer may be between about 20 and 40. Preferably, the durometer may be between about 25 and 35. For example, the durometer may be about 30 in certain embodiments. A durometer in one of these ranges may be soft enough to enable an interference fit or friction fit between the guard head and the guard body so as to further resist fluid entry.
The fastening mechanism 428 may be disposed near a distal end of the guard head 408. Distal and proximal may refer to relationships to the hinge 412. Similarly, the fastening receiver 440 may be located at or near a distal end of the guard body 404, as shown. The fastening body 448 may include a protrusion from the guard head 408. A corresponding slot 452 may be in the guard body 404. The slot 452 may be configured to receive the fastening body 448 and/or the fastening mechanism 428. The slot 452 may include an opening within the guard body 404.
In some embodiments, such as the one shown in
The guard head 408 may include one or more sidewalls 456. The sidewalls 456 can create a fluid seal along one or more sides of the fluid guard 400. The one or more sidewalls 456 can wick fluid away from the aperture 416 and/or guide fluid along a length of the sidewalls 456. This wicking or guiding action may help fluid to avoid entering between the guard body 404 and the guard head 408. The sidewalls 456 may be disposed approximately parallel to a major axis of the fluid guard 400. In some embodiments, the sidewalls 456 may be curved (for example, to align with the guard body 404). Other orientations and shapes are possible. For example, the sidewalls 456 may be disposed on the guard body 404 in some embodiments.
The example guard body 404 shown includes an aperture 416. The aperture 416 may allow insertion of a key (for example, the electronic key 650) therethrough. The aperture 416 can be aligned approximately centrally within the guard body 404 (for example, at an intersection of the major and minor axes of the guard body 404). In some embodiments, the aperture 416 is approximately circular, though other shapes (for example, rectangular, elliptical, etc.) are possible. The aperture 416 may be surrounded at least in part or in full by a rim 444, as shown. The rim 444 may be a raised portion relative to a surface of the guard body 404, thereby further protecting a lock face 612 (see
The rim 444 may be configured to receive a connector frame 432 disposed on the guard head 408. The connector frame 432 can be a raised portion relative to a surface of the guard head 408. For example, the connector frame 432 may include a raised rim that fits within the rim 444 and/or the aperture 416. The raised rim of the frame 432 may have a circular perimeter or circular cross section, although other shapes are possible (such as oval, square, and rectangular). The raised rim may have an internal perimeter that is circular or some other shape. The internal perimeter may be a portion of the frame 432 that contacts the fluid absorber 500 and that at least partially holds the fluid absorber 500 in place. The connector frame 432 may have a friction fit with the rim 444 to further protect the lock face 612 (see
The connector frame 432 can house the fluid absorber 500. The fluid absorber 500 can advantageously absorb or otherwise wick away fluids from the lock face 612 (see
The proximal surface 512 of the protruding portion 510 may be spaced less than an inch from the proximal surface 506 of the annular portion 504. In some embodiments, the distance between the proximal surfaces 506, 512 may be about ¼ inch. The annular portion 504 may have a height of between about 1/32 inch and ½ inch. In some embodiments, the height of the annular portion 504 is about ⅛ inch. The protruding portion 510 may have a height of between about 1/16 inch and ¾ inch. In some embodiments, the height of the protruding portion 510 is about ¼ inch. The
The annular portion 504 and the protruding portion 510 may be two separate elements, as shown. However, in some embodiments, the annular portion 504 and the protruding portion 510 together form a single element. In embodiments, where they are separate elements, the protruding portion 510 may be inserted into the annular portion 504 using one or more types of interfaces. For example, the interface may be a friction fit and/or an adhesive attachment.
When the guard head 408 is brought into contact with or proximity to the guard body 404, the protruding portion 510 of the fluid absorber 500 can mate with (for example, be inserted into, snap fit with, friction fit with, or the like) a receptacle (for example, an interior cup) of a portion of the lock core, such as the lock face 612, while the annular portion 504 can contact and/or protect an exterior annulus of a portion of the lock core (for example, the lock face 612). For example, with respect to
Because the example fluid absorber 500 is shaped to enter the interior cup of the lock face and/or contact or come into proximity to the exterior of the lock face, the fluid absorber 500 can contact and/or protect a significant portion of the surface are of the lock face. As a result, the fluid absorber 500 can be very effective at wicking away or absorbing water from many or all surfaces of the lock face.
In other embodiments, the fluid absorber may be shaped differently. The shape of the fluid absorber may conform more fully to the lock face, including by having any ridges, valleys, or protrusions needed to conform to the shape of the lock face. Other example fluid absorbers may not have the protrusion 510 but instead may be a flat or substantially flat disk. For example, with some electronic locks that use electrical contacts instead of capacitive or inductive coupling, a flatter surface fluid absorber may be used.
The fluid absorber 500 can include an antibacterial element. For example, the fluid absorber 500 can include an antimicrobial agent that is configured to destroy microbes that may be present in the fluid. This benefit may further prolong the life of the lock assembly 600 and/or the electronic key 650. For example, the fluid absorber 500 can include a compound including silver or another antimicrobial element or compound.
The material of the fluid absorber 500 can be a foam or foam-like material for fluid absorption purposes. For example, the material may comprise polyvinyl alcohol (PVA) and/or polyurethane (PUR). The material may include small (for example, on the order of microns) pockets of air configured to promote absorption of liquid. For example, the material may be a closed-celled foam or open-celled foam, but a closed-cell foam is preferable in some embodiments because it may draw water away from the lock face 612 without retaining water like an open-celled foam. The material may be configured to absorb between about 5 and 15 times its weight in fluid. In some embodiments, the material can absorb between about 9 and 13 times its weight in fluid. For example, the material may be configured to absorb about 12 times its weight in fluid. In some embodiments, the material is configured to absorb at least 3 times its weight in fluid.
The key 1300 includes an elongate main body portion 1302 that is generally rectangular in cross-sectional shape. The illustrated key 1300 also includes a mating portion 1312 of smaller external dimensions than the body portion 1302. The body portion 1302 can house the internal electronics of the key 1300 as well as other components. The mating portion 1312 can engage a lock described below with respect to
The electronic lock core 1400 includes a body portion 1404 and a mating portion 1408. The body portion 1404 may at least partly house one of the coil assemblies described above. The diameter of the mating portion 1408 is larger than the diameter of the body portion 1404. The mating portion 1408 includes a cylinder 1446 and a raised cylindrical portion 1460 disposed within the cylinder 1446. An annular groove 1448 or key recess is formed between the cylinder 1446 and the raised cylindrical portion 1460. The annular groove 1448 is capable of receiving the tabs 1314 of the key 1300. A cup 1452 is disposed within the raised cylindrical portion 1460, which is capable of receiving the power coil 1320 of the key 1300 as well as the protruding portion of the fluid absorber described above.
In certain implementations, the key 1300 may mate with the electronic lock core 1400 by placement of the tabs 1314 in the annular groove 1442, by placement of the power coil 1320 in the cup 1452. The key 1300 may provide data to the electronic lock core 1400, optionally after a user presses a certain button sequence on the key 1300, allowing a locking mechanism of the electronic lock core 1400 to be actuated. The key 1300 may then be turned by an operator of the key to unlock the lock. Locking may proceed, for example, by turning the key 1300 in a reverse motion.
As described above, fluid that accumulates between the partial capacitors can change the capacitance undesirably. Thus, the fluid absorber 500 may be inserted into the cup assembly 3101. In this way, the fluid absorber 500 can wick away and/or absorb fluid therein to reduce or eliminate changes to the capacitance of the capacitor 3672.
The storage container or lock box may also be mounted in a clinical facility or emergency vehicle (such as an ambulance) in order to store controlled substances. Moreover, the lock box may be used in any suitable application where security and tracking access to the lock box is useful, including, for example, as evidence lockers in police stations or police vehicles. The box may additionally or alternatively hold critical medical supplies or other equipment for saving lives.
Because time is often of the essence in many lock box applications, including emergencies, emergency personnel need confidence that the locking mechanism in the lock box can be reliably trusted. An electronic lock can be used to provide greater security and audit tracking ability with a lock box, such as the electronic lock described above. For electronic locks, as described above, water may interfere with the signal generated between the key and the locking mechanism. Advantageously, for at least this reason, the lock box can be outfitted with a fluid guard as described herein.
The fluid guard 702 can have a guard base 707 and a guard door 708 connected by a hinge 713. The guard door 708 can include a fluid absorber 500, as described in more detail herein. The guard base 707 and/or the guard door 708 may be substantially flat. For example, in some lock boxes, the fluid guard 702 may need to be adhered to a flat surface. The guard base 707 can have a front surface 744 and a back surface 752 (not shown in
The guard base 707 includes an aperture 740. When the fluid guard 702 is in the closed position, the fluid absorber 500 may be disposed at least partially within the aperture 740. The aperture 740 can allow access to the locking mechanism (for example, at a face of the lock). The aperture 740 may allow insertion of a key (for example, the electronic key 650) therethrough. The aperture 740 can be aligned approximately centrally within the guard base 707. In some embodiments, the aperture 740 is approximately circular, though other shapes (for example, rectangular, elliptical, etc.) are possible. The aperture 740 may be surrounded at least in part or in full by a base flange 724, as shown. As shown, the base flange 724 forms a convex profile with respect to the aperture 740. Other profile shapes are possible. The base flange 724 can be referred to as a collar, an ear, a rim, or any other name signifying a raised portion. The base flange 724 can be disposed on the front surface 744 of the guard base 707. The base flange 724 can be configured to come into contact with the guard door 708 and/or create a fluid seal therebetween when the fluid guard 702 is in the closed position.
The base flange 724 can include one or more base flange vents 728. For example, a base flange vent 728 can be disposed near a “bottom” (after assembly or attachment to the lock box) of the base flange 724. This configuration may allow fluid to drain or drip away from the lock face. The base flange vent 728 can be referred to as a guide vent. The base flange vent 728 can be configured to allow air to enter the lock area and therefore promote drying (for example, evaporation) of any fluid that may have accumulated on or near the lock face. For example, the base flange vent 728 can provide fluid communication between the lock face and an exterior of the fluid guard 702, even when the fluid guard 702 is in the closed position. The guard base 707 may also include one or more contours 736 configured to fit to the underlying lock box. For example, as shown the contours 736 can be formed to allow for underlying attachment devices (for example, bolts, screws, nails, etc.) that may be formed in the underlying lock box.
The guard door 708 can have a fluid absorber 500 and/or a door flange 718 configured to guide fluid away from the fluid absorber 500. The door flange 718 may be formed similarly to the base flange 724. For example, the door flange 718 may be curved outward with respect to the fluid absorber 500 to better wick fluid away from the fluid absorber 500. The door flange 718 can be disposed at least partially about the fluid absorber 500 as shown. For example, the door flange 718 may be disposed on the guard door 708 along a curved path (for example, circular). The door flange 718 can include a door flange vent 720 that may have one or more characteristics in common with the base flange vent 728. The base flange vent 728 can be sized to at least partially fit within the aperture 740. In some embodiments, the door flange vent 720 is disposed in substantially the same orientation as the base flange vent 728 when the fluid guard 702 is in the open position. The door flange vent 720 may be disposed in the door flange 718 such that when the fluid guard 702 is in the closed position, the door flange 718 and the base flange vent 728 are not completely or substantially aligned. This configuration of the combination of vents can help provide a greater scope (for example, 360°) of fluid protection from entering the lock face while the fluid guard 702 is in a closed position. In some embodiments, in the closed position the door flange 718 and the base flange vent 728 are not aligned at all, for example as shown in
The fluid guard 702 can include one or more fluid guides 732 that are configured to further guide fluid away from the locking device and/or the fluid absorber 500. The one or more fluid guides 732 may be disposed on the guard door 708. The fluid guides 732 may be disposed along one or more edges of the guard base 707 and/or guard door 708. The fluid guides 732 may include a flange, a lip, a rim, or other structure configured to restrict the flow of fluid in a certain direction. In some embodiments, the fluid guides 732 are configured to contact and/or create a fluid seal with a corresponding portion of the fluid guard 702. For example, as shown the fluid guides 732 may be disposed on the guard door 708 and be configured to come in contact with the guard door 708.
The guard door 708 may be closed using a friction fit. Additionally or alternatively, a latch mechanism may be used to close the guard door 708. In some embodiments, a magnet may be inserted into the fluid absorber 500 and/or the guard door 708. A magnetic element (for example, a magnet) may be inserted in the guard body 404 to which the magnet may be attracted. This configuration can be used to encourage the guard door 708 to remain in a closed position.
One or more components of the fluid guard 702 may include a resilient material. The resilient material may include, for example, a synthetic material such as a synthetic polymer (for example, a synthetic elastomer, a synthetic plastic, etc.). For example, the resilient material of the fluid guard 702 may include silicone (for example, silicone rubber). Additionally or alternatively, the resilient material may include a natural material, such as a polymer of organic compound(s). The material of the fluid guard 702 can have a durometer of between about 10 and 50. In some embodiments, the durometer may be between about 20 and 40. Preferably, the durometer may be between about 25 and 35. For example, the durometer may be about 30 in certain embodiments. The durometer may be of Type A (for example, 20 A, 30 A, 35 A, etc.). A durometer in one of these ranges may be soft enough to enable an interference fit or friction fit between the guard head and the guard body so as to further resist fluid entry. The fluid guard 702 may be molded as a single piece. Such a soft material can help promote easier opening/closing of the guard door 708.
Because of the advanced engineering of the fluid guard 702, it may be able to operate in a wide range of temperatures. For example, it may operate down to very cold temperatures (for example, −55° F.) and/or up to very hot temperatures (for example, 450° F.). The material may be resistant to deterioration from UV rays and/or corrosion. In some embodiments, the fluid guard 702 can be configured to be opened/closed more than 100,000 times before needing to be replaced or repaired. In some embodiments, the fluid guard 702 can be sized and shaped to fit a plurality of different types of lock boxes and/or locking mechanisms. For example, the fluid guard 702 or one or more components thereof can be configured to fit a “Roman Bracket.” For example, the fluid guard 702 can include a groove to align over a magnet alignment ring of the Roman Bracket. Additionally or alternatively, the fluid guard 702 can include clearance pockets to align over rivets on early brackets.
A KNOX® Gate and Key Switch device can allow firefighters to access an interior of a parking structure or garage. The device can allow firefighters to open a physical barrier, such as an electronic gate, rolling gate, an arm gate, etc. The key can keep a gate in an open position. Using the KNOX® Gate and Key Switch device, firefighters can prevent the spread of fire to other property (for example, vehicles) and/or to people.
In some prior cabinets that do not have the recess 710, the cabinets are ordered by customers with specific requests for mounting hole and/or cable hole locations. Cable holes in these prior cabinets could be drilled in the sides of the cabinet, the top, or the rear of the cabinet and may be used to conduct power cable and antenna and other cables or wires out of the cabinet. A power cable can supply power to the cabinet to control circuitry including the processor and associated circuitry and sensors described above as well as the motor. (Although the cabinet can be battery operated, it may be more secure for the cabinet to be powered by an external power source which may be supplied from the wall outlet or from a vehicle that the cabinet is installed in.)
Because cabinets may be installed in different vehicles or buildings which have different mounting configurations, it can be desirable to make the cabinet so that it can go in multiple different mounting locations without requiring holes to be drilled specifically for each cabinet in different locations. A problem has occurred where cabinets would be ordered without specifying the correct cable holes (for example, holes would be drilled where cables could not go, such as against a wall), causing a customer to have to return a cabinet. With the recess 710, cables can be snaked out of the back of the recess to the side, directly to the back, or over the top of the cabinet to the other side of the cabinet—thus addressing this problem at least in part.
As shown in
The recess 710 is defined in one embodiment by a wall 712, a shelf 716, and a wall 714. The shelf 716 and the wall 712 are of a sufficient width to enable cables to be snaked out of the cabinet without the cables being pinched against the wall to which the rear of the cabinet is mounted. For instance, in one embodiment the shelf 716 has a depth of about 1.5 inches (about 3.8 cm). The size of the shelf 716 can be driven by the size of the cables and/or antenna used to connect to the back of the cabinet 700. If smaller cables and/or antenna are used, the shelf 716 may be narrower in depth. Likewise, the height of the wall 714 may be smaller or larger depending on the size of the cables and/or antenna used.
Additional details about such lock boxes or cabinets, such as drug boxes or home boxes, that may be used in conjunction with the fluid guard can be found in U.S. application Ser. No. 15/852,326, titled “ELECTRONIC STORAGE CABINET,” filed Dec. 22, 2017 (“the '326 application”), which is incorporated by reference herein in its entirety for all purposes.
In other embodiments, the guard head 408 and/or guard body 404 may be made of the same foam material as the fluid absorber 500. In such an embodiment, the guard head 408 and/or body 404 may be integrally formed with the fluid absorber 500 as a single foam piece. A guard head can also be used without using a guard body, such that the guard head covers a lock face.
A cap with a fluid absorber may also be provided for the key 650 shown in
As shown, the fluid absorber 500 can be configured to fit within and/or contact a surface of the lock face 816.
The following examples are meant by way of example only and are not limiting to the number of other available alternatives.
In a 1st example, a locking device guard comprises: a guard head comprising: a fluid absorber; a frame shaped to receive the fluid absorber; and a fastening mechanism; a guard body coupled with an electronic lock, the guard body comprising: an aperture configured to: expose a face of the electronic lock, and receive the fluid absorber; and a fastening receiver configured to mate with the fastening mechanism; a hinge connecting the guard head and the guard body and configured to define an open position and a closed position of the locking device guard.
In a 2nd example, the locking device guard of example 1, wherein the fluid absorber is configured to absorb at least 3 times its weight in fluid.
In a 3rd example, the locking device guard of any of examples 1-2, wherein the fluid absorber comprises a synthetic polymer.
In a 4th example, the locking device guard of any of examples 1-3, wherein the fluid absorber comprises polyvinyl alcohol.
In a 5th example, the locking device guard of any of examples 1-4, wherein the fluid absorber comprises an antimicrobial agent.
In a 6th example, the locking device guard of example 5, wherein the antimicrobial agent comprises silver.
In a 7th example, the locking device guard of any of examples 1-6, wherein the locking device guard comprises a resilient material.
In a 8th example, the locking device guard of any of examples 1-7, wherein the locking device guard comprises silicone.
In a 9th example, the locking device guard of any of examples 1-8, wherein the guard body further comprises a rim surrounding at least a portion of the aperture.
In a 10th example, the locking device guard of any of examples 1-9, wherein the guard head further comprises a fastening body that defines an air outlet, the air outlet providing fluid communication between an exterior of the locking device guard in a closed position and a locking device.
In a 11th example, the locking device guard of any of examples 1-10, wherein the locking device guard has a length and a width, the length being greater than the width.
In a 12th example, a locking device guard head comprising: a fluid absorber configured to: be inserted into a cup of a face of a lock, and absorb fluid from the face of the lock; a frame shaped to receive the fluid absorber; and a fastening mechanism; wherein the locking device guard head is configure to prevent a flow of fluid from an exterior of the guard head to the face of the lock.
In a 13th example, the locking device guard head of example 12, further comprising a hinge configured to connect to a guard body, the guard head configured to define an open position and a closed position.
In a 14th example, the locking device guard head of example 13, wherein fluid absorber is configured to fit into an aperture of the guard body.
In a 15th example, the locking device guard head of example 12, wherein the lock comprises an electronic lock.
In a 16th example, the locking device guard head of any of examples 12-15, wherein the fluid absorber comprises a synthetic polymer.
In a 17th example, the locking device guard head of any of examples 12-16, wherein the fluid absorber comprises polyvinyl alcohol.
In a 18th example, the locking device guard head of any of examples 12-17, wherein the fluid absorber comprises an antimicrobial agent.
In a 19th example, the locking device guard head of example 18, wherein the antimicrobial agent comprises silver.
In a 20th example, the locking device guard head of any of examples 12-19, wherein the locking device guard head comprises silicone.
In a 21st example, the locking device guard for use on an access panel of an access box, the locking device guard comprising: a latch of the access panel; a guard door attached to the latch of the access panel, the guard door comprising a fluid absorber; a guard base attached to the access panel of the access box, the guard base comprising: an aperture configured to: expose a face of an electronic lock disposed within the access panel; and receive the fluid absorber so as to permit the fluid absorber to contact the face of the electronic lock and to thereby permit absorption of fluid off of the face of the electronic lock; and a flange disposed at least partially about the aperture; and a hinge connecting the guard base and the guard door and configured to define an open position and a closed position of the locking device guard.
In a 22nd example, the locking device guard of example 21, wherein the guard door further comprises a door flange disposed at least partially about the fluid absorber.
In a 23rd example, the locking device guard of example 22, wherein the door flange is configured to guide fluid away from the fluid absorber.
In a 24th example, the locking device guard of any of examples 22-23, wherein the door flange is configured to fit at least partially within the aperture.
In a 25th example, the locking device guard of any of examples 22-24, wherein the door flange comprises a vent configured to allow, in the closed position, fluid communication between the fluid absorber and an exterior of the locking device guard.
In a 26th example, the locking device guard of any of examples 21-25, wherein the base flange comprises a vent configured to allow, in the closed position, fluid communication between the fluid absorber and an exterior of the locking device guard.
In a 27th example, the locking device guard of any of examples 21-26, wherein the guard door further comprises one or more fluid guides disposed at least partially along one or more edges of the guard door.
In a 28th example, the locking device guard of example 27, wherein the one or more fluid guides are configured to contact the guard base in the closed position.
In a 29th example, the locking device guard of any of examples 21-28, wherein the guard base further comprises a gasket configured to create a seal between the locking device guard and the face of the electronic lock.
In a 30th example, the locking device guard of example 29, wherein the gasket is disposed on a side opposite the base flange through the aperture.
In a 31st example, the locking device guard of any of examples 21-30, further comprising an adhesive.
In a 32nd example, the locking device guard of example 31, wherein the adhesive is disposed on a back surface of the locking device guard, the back surface being opposite a surface on which one or more of the fluid absorber or flange are disposed.
In a 33rd example, the locking device guard of any of examples 21-32, wherein the locking device guard comprises silicone.
In a 34th example, the locking device guard of any of examples 21-33, wherein the locking device guard comprises a material having a durometer of type A of between 25 and 35.
In a 35th example, the locking device guard of any of examples 21-34, wherein the fluid absorber comprises polyvinyl alcohol.
In a 36th example, the locking device guard of any of examples 21-35, wherein the fluid absorber comprises an antimicrobial agent.
In a 37th example, the locking device guard of example 36, wherein the antimicrobial agent comprises silver.
In a 38th example, the locking device guard of any of examples 21-37, wherein the locking device guard comprises a resilient material.
In a 39th example, the locking device guard of any of examples 21-38, wherein the base has a length and a width, the length being less than 50% greater than the width.
In a 40th example, the locking device guard of any of examples 21-39, wherein one or both of the flange or door flange comprise a curved profile forming an ear configured to guide fluid flow therein.
In a 41st example, the locking device guard of any of examples 21-40, wherein the access box comprises a storage container configured to secure supplies usable by first responders.
In a 42nd example, the locking device guard of any of examples 21-40, wherein the access box comprises a key access port for control of a gate.
In a 43rd example, the locking device guard of any of examples 1-11, wherein the locking device guard is configured for attachment to a padlock.
In a 44th example, the locking device guard of any of examples 1-11 or 43, wherein the locking device guard is configured for attachment to a lock box.
In a 45th example, the locking device guard of any of examples 1-11 or 43-44, wherein the fluid absorber is axially symmetric about an absorber axis.
In a 46th example, the locking device guard of any of examples 1-10 or 43-45, wherein the fluid absorber is shaped to conform to the face of the electronic lock.
In a 47th example, the locking device guard of any of examples 1-10 or 43-46, wherein a shape of the fluid absorber comprises a disk.
In a 48th example, the locking device guard of any of examples 1-10 or 43-47, wherein the fluid absorber is configured to enter an interior cup of the electronic lock.
In a 49th example, the locking device guard of any of examples 1-10 or 43-48, wherein the fastening mechanism comprises a ledge configured to mate with a corresponding ledge of the guard body.
In a 50th example, the locking device guard of any of examples 1-10 or 43-49, wherein the fastening mechanism is disposed near a distal end of the guard head in relation to the hinge.
In a 51st example, the locking device guard of any of examples 1-10 or 43-50, wherein the aperture is configured to receive the fluid absorber so as to permit the fluid absorber to contact the face of the electronic lock and to thereby permit absorption of fluid off of the face of the electronic lock.
Although certain embodiments and examples are disclosed herein, inventive subject matter extends beyond the specifically disclosed embodiments to other alternative embodiments and/or uses and to modifications and equivalents thereof. Thus, the scope of the claims appended hereto is not limited by any of the particular embodiments described below. For example, in any method or process disclosed herein, the acts or operations of the method or process may be performed in any suitable sequence and are not necessarily limited to any particular disclosed sequence. Various operations may be described as multiple discrete operations in turn, in a manner that may be helpful in understanding certain embodiments; however, the order of description should not be construed to imply that these operations are order dependent.
Additionally, the structures, systems, and/or devices described herein may be embodied as integrated components or as separate components. For purposes of comparing various embodiments, certain aspects and advantages of these embodiments are described. Not necessarily all such aspects or advantages are achieved by any particular embodiment. Thus, for example, various embodiments may be carried out in a manner that achieves or optimizes one advantage or group of advantages as taught herein without necessarily achieving other aspects or advantages as may also be taught or suggested herein. Furthermore, the particular features, structures or characteristics may be combined in any suitable manner, as would be apparent to one of ordinary skill in the art from this disclosure, in one or more embodiments.
As used in this application, the terms “comprising,” “including,” “having,” and the like are synonymous and are used inclusively, in an open-ended fashion, and do not exclude additional elements, features, acts, operations, and so forth. Also, the term “or” is used in its inclusive sense (and not in its exclusive sense) so that when used, for example, to connect a list of elements, the term “or” means one, some, or all of the elements in the list.
Similarly, it should be appreciated that in the above description of embodiments, various features are sometimes grouped together in a single embodiment, figure, or description thereof for the purpose of streamlining the disclosure and aiding in the understanding of one or more of the various inventive aspects. This method of disclosure, however, is not to be interpreted as reflecting an intention that any claim require more features than are expressly recited in that claim. Rather, inventive aspects lie in a combination of fewer than all features of any single foregoing disclosed embodiment. Accordingly, no feature or group of features is necessary or indispensable to each embodiment.
A number of applications, publications, and external documents may be incorporated by reference herein. Any conflict or contradiction between a statement in the body text of this specification and a statement in any of the incorporated documents is to be resolved in favor of the statement in the body text.
Although described in the illustrative context of certain preferred embodiments and examples, it will be understood by those skilled in the art that the disclosure extends beyond the specifically described embodiments to other alternative embodiments and/or uses and obvious modifications and equivalents. Thus, it is intended that the scope of any claims which follow should not be limited by the particular embodiments described above.
Number | Date | Country | |
---|---|---|---|
62651965 | Apr 2018 | US | |
62678960 | May 2018 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 16056192 | Aug 2018 | US |
Child | 17031632 | US |