The present invention relates to filing cabinets, and more particularly to mechanisms adapted to prevent one or more of the drawers in the filing cabinet from being opened. It has been known in the past to include interlock mechanisms on filing cabinets that prevent more than one drawer in the cabinet from being opened at a single time. These interlock mechanisms are generally provided as safety features that are intended to prevent the filing cabinet from accidentally falling over, a condition that may be more likely to occur when more than one drawer in the cabinet is open. By being able to open only a single drawer at a given time, the ability to change the weight distribution of the cabinet and its contents is reduced, thereby diminishing the likelihood that the cabinet will fall over.
In addition to such interlocks, past filing cabinets have also included locks that prevent any drawers from being opened when the lock is moved to a locking position. These locks are provided to address security issues, rather than safety issues. These locks override the interlocking system so that if the lock is activated, no drawers may be opened at all. If the lock is not activated, the interlock system functions to prevent more than one drawer from being opened at the same time. Oftentimes the system that locks all of the drawers and the interlock system that locks all but one of the drawers are at least partially combined. The combination of the locking system with the interlocking system can provide cost reductions by utilizing common parts.
Past locking and interlocking mechanisms, however, have suffered from a number of disadvantages. One disadvantage is the difficulty of changing the drawer configurations within a cabinet. Many filing cabinets are designed to allow different numbers of drawers to be housed within the cabinet. For example, in the cabinet depicted in
In the past, such reconfiguring of the drawers in a cabinet has been a difficult task because the interlocking and/or locking system for the drawers could not easily be adjusted to match the newly configured filing cabinet. For example, U.S. Pat. No. 6,238,024 issued to Sawatzky discloses an interlock system that utilizes a series of rigid rods that are vertically positioned between each drawer in the cabinet. The height of these rods must be chosen to match the vertical spacing between each of the drawers in the system. If the cabinet is to be reconfigured, then new rods will have to be installed that match the height of the new drawers being installed in the cabinet. Not only does this add additional cost to the process of reconfiguring the cabinet, it complicates the reconfiguring process by requiring new parts of precise dimensions to be ordered. Finding these precisely dimensioned parts may involve extensive searching and/or measuring, especially where the manufacturer of the rods is not the same entity that produced the new drawers being installed, or the manufacturer of the rods has ceased producing the parts, or has gone out of business.
Another difficulty with systems like that disclosed in the Sawatzky patent is the precise manufacturing that may be required to create these rigid rods. These interlock systems only work if the rods have heights that fall within a certain tolerance range. This tolerance range, however, decreases as more interlocks are installed in a given cabinet. In other words, the tolerance of the heights of these rods is additive. In order to function properly, a cabinet with ten drawers will therefore require smaller tolerances in the rods than a two drawer cabinet. In order to create rods that can be universally used on different cabinets, it is therefore necessary to manufacture the rods within the tight tolerances required by the cabinet having the greatest expected number of drawers. These tight tolerances tend to increase the cost of the manufacturing process.
Another difficulty with past interlock and lock systems for file cabinets has been the expense involved in creating a locking system that will withstand high forces exerted on the drawers. The Business and Institutional Furniture Manufacturer's Association (BIFMA) recommends that lock systems for file cabinets be able to withstand 50 pounds of pressure on a drawer. Thus, if a file cabinet does not exceed this standard, thieves can gain access to the contents of a lock drawer by pulling the drawer outwardly with more than fifty pounds of force. Many users of file cabinets, however, desire their locking system to be able to withstand much greater forces than this before failure. Increasing the durability of the locking system often adds undesired expense to the cost of building the system.
A number of prior art interlock systems have used cables or straps as part of the interlocking system. Such systems, however, have suffered from other disadvantages. For example, U.S. Pat. No. 5,199,774 issued to Hedinger et al. discloses an interlock and lock system that uses a cable. The slack in the cable is decreased when a drawer is opened. The amount of slack of the cable is carefully chosen during the installation of the drawer lock so that there is just enough slack in the system to allow only one drawer to be opened at a time. The interlock on whatever drawer is opened takes up this available slack in the cable, which prevents other drawers from being opened at the same time. A similar system is disclosed in U.S. Pat. No. 5,062,678 issued to Westwinkel. This system uses a strap instead of a cable. Both systems suffer from the fact that excessive amounts of force may be easily transferred to either the cable or the strap. In other words, the cable or the strap itself are what resist the pulling force that a person might exert on a closed drawer when either the lock is activated, or another drawer is opened. The tensile strength of the cable or strap therefore determines how much force must be exerted to overcome the interlock or lock. In fact, in the interlock of Westwinkel, the system appears to be constructed so that the pulling force exerted by a person on a locked drawer will be amplified before being applied to the strap. The strap must therefore have a greater tensile strength than the highest rated pulling force that the lock or interlock system can resist. Increasing the strength of the cables or straps typically tends to increase their cost, which is desirably avoided.
In light of the foregoing, the desirability of an interlock and lock system that overcomes these and other disadvantages can be seen.
Accordingly, the present invention provides an interlock and lock that reduces the aforementioned difficulties, as well as other difficulties. The interlock and lock of the present invention allow relatively low-tensile strength cables or flexible members to be used in systems which provide high resistance to theft and breakdown. The system of the present invention further allows changes to cabinet configurations to be easily implemented with little or no additional work required to integrate the new cabinet configuration into the interlock or lock system. The present invention provides a simple construction for locks and interlocks that can be easily manufactured without excessively restrictive tolerances, and which can be easily installed in cabinets.
According to one aspect of the present invention, an interlock for a cabinet drawer is provided. The drawer is movable in the cabinet is a first direction toward an open position and in a second, opposite direction toward a closed position. The interlock includes an elongated, flexible member, a rotatable lever, an engagement member, and a biasing member. The lever is adapted to alter the amount of slack in the elongated, flexible member. The lever is rotatable between a first position and a second position. The first position creates a low amount of slack in the elongated, flexible member, and the second position allows a high amount of slack to be present in the elongated, flexible member. The engagement member is attached to the drawer and positioned to cause the rotatable lever to rotate toward the first position when the drawer is initially moved from the closed position in the first direction. The biasing member is positioned adjacent the lever and adapted exert a force that tends to prevent the lever from rotating from the first position to the second position until the drawer is moved in the second direction to the closed position.
According to another aspect of the present invention, an interlock is provided that includes a cable, a slack take-up mechanism, a cam, and a biasing member. The slack take-up mechanism is engage able with the cable and movable between a high-tension position and a low-tension position. The high-tension position creates a greater amount of tension than the low-tension position in the cable. The cam is operatively coupled to the slack take-up mechanism and to the drawer. The cam is adapted to switch the slack take-up mechanism from the low-tension position to the high-tension position when the drawer is moved in the first direction toward the open position. The biasing member is adapted to exert a force against the take-up mechanism that urges the slack take-up mechanism toward the high-tension position. The force of the biasing member has a magnitude that is independent of the magnitude of the force exerted on the drawer in the first direction.
According to still another aspect of the present invention, an interlock is provided. The interlock includes a cable, a rotatable lever, an engagement member, and a retainer. The lever is adapted to change the cable between high and low slack conditions. The engagement member is attached to the drawer and positioned to cause the lever to rotate to a first position that changes the cable to a low slack condition when the drawer is initially moved in the first direction from the closed position. The engagement member is also positioned such that a first force exerted on the drawer in the first direction is translated by the lever to a second force on the cable, which is less than the first force. The retainer is adapted to retain the rotatable lever in the first position while the drawer is moved to the open position.
According to still another aspect of the present invention, a locking and interlocking system for a cabinet is provided. The system includes a lock, a first cable, a second cable, a first interlock, and a second interlock. The first cable extends between at least a first and second drawer. The first cable is changeable from a high slack to a low slack condition. The second cable extends between the lock and the first drawer. The lock is adapted to change the second cable from a high slack to a low slack condition. The first interlock is in communication with the first and second cables and adapted to change both said first and said second cables from the high slack to the low slack condition whenever the first drawer is opened. The first interlock is further adapted to prevent the first drawer from opening whenever the first or second cables are in the low slack condition. The second interlock is in communication with the first cable and adapted to change the first cable from the high slack to the low slack condition whenever the second drawer is opened. The second interlock is further adapted to prevent the second drawer from opening whenever the first cable is in the low slack condition.
According to yet another aspect of the present invention, a cabinet is provided that includes at least one drawer movable within the cabinet in a first direction toward an open position and in a second, opposite direction toward a closed position. The cabinet further includes a frame adapted to support the drawer, an elongated, flexible member, an interlock, and a slack take up mechanism. The elongated, flexible member is positioned within the cabinet and changeable between a lower slack condition and a higher slack condition. The interlock is positioned within the frame and in operative engagement with the elongated, flexible member. The interlock is adapted to prevent the drawer from moving to the open position when the elongated, flexible member is in the lower slack condition and to allow the drawer to move to the open position when the elongated, flexible member is in the hither slack condition. The slack take up mechanism is adapted to change the elongated, flexible member from the high slack condition to the lower slack condition when the drawer is moved from the closed position to the open position. The slack take up mechanism is further adapted to translate a first force exerted on the drawer in the first direction to a second force exerted on the elongated, flexible member which is less than the first force.
According to still other aspects of the present invention, the interlock may be in communication with a lock that is adapted to selectively alter the condition of the cable. The interlocks may be secured to drawer slides that are removable from the cabinet. A cable guide may be included as part of the interlock to snap fittingly receive the cable and retain it in engagement with the interlock.
The various aspects of the present invention provides an interlock and lock system that is versatile, resistant to high forces, and easily installed. These and other benefits of the present invention will be apparent to one skilled in the art in light of the following written description when read in conjunction with the accompanying drawings. The interlock may be in communication with a lock that is adapted to selectively alter the tension in the cable.
The interlocks may be secured to drawer slides that are removable from the cabinet. A cable guide may be included as part of the interlock to snap-fittingly receive the cable and retain it in engagement with the interlock.
The various aspect of the present invention provides an interlock and lock system that is versatile, resistant to high forces, and easily installed. These and other benefits of the present invention will be apparent to one skilled in the art in light of the following written description when read in conjunction with the accompanying drawings.
The present invention will now be described with reference to the accompanying drawings wherein the reference numerals in the following written description correspond to like numbered elements in the several drawings. The present invention relates to locks and interlocks that may be used with file cabinets, such as the file cabinet 60 depicted in
The interlocks of the present invention may be advantageously combined or attached to the drawer slides in which drawers 62 slidingly move between their open and closed position. An example of one of these drawer slides 70 is depicted in
An interlock 72 according to a first embodiment of the present invention is depicted in
As illustrated in
Attachment plate 76 includes a plurality of fastener holes 92 which may be used to receive rivets, screws, or other fasteners to secure attachment plate 76 to stationary portion 90 of drawer slide 70. Attachment plate 76 is depicted in detail in FIGS. 6 and 8-10. Attachment plate 76 further includes a rivet hole 94 which receives rivet 88. Rivet 88 secures cam 80 to attachment plate 76 in a rotatable fashion. Stated alternatively, cam 80 is attached to attachment plate 76 in such a manner that it can rotate about the axis generally defined by rivet 88. Attachment plate 76 further includes a spring attachment nub 96 to which one end of spring 82 is attached. Attachment plate 76 also includes a pair of bent flanges 98. Bent flanges 98 are received inside of cable guide 84 and used to secure cable guide 84 to attachment plate 76. Each flange 98 includes a shoulder 100 that retains cable guide 84 on attachment plate 76 after they have been attached, as will be explained in more detail below.
Sliding plate 78, which is depicted in detail in FIGS. 6 and 11-13, is positioned between attachment plate 76 and cam 80. Sliding plate 78 slides linearly in a direction parallel to first and second directions 64 and 66. When a drawer 62 is initially opened, sliding plate 78 slides linearly in first direction 64. As the drawer fully closes, sliding plate 78 slides back to its original position in second direction 66. Sliding plate 78 includes an elongated aperture 102 that receives rivet 88. Because elongated aperture 102 has a length much greater than the diameter of rivet 88, sliding plate 78 can slide along rivet 88 while still being supported by rivet 88. Sliding plate 78 includes an engagement lug 104 positioned at an end generally opposite to elongated aperture 102. Engagement lug 104 engages cable 74 generally along its side that faces toward elongated aperture 102. The side of sliding plate 78 adjacent engagement lug 104 is supported in a channel 106 defined by cable guide 84. When sliding plate 78 slides in first direction 64, engagement lug 104, which is in engagement with cable 74, decreases the slack in cable 74. Thus, when a drawer is open, sliding plate 78 and engagement lug 104 remove the slack from cable 74. This will be described in more detail below.
Sliding plate 78 further includes a spring attachment nub 108. Spring attachment nub 108 is used to attach the other end of spring 82 to sliding plate 78. When spring 82 is connected between attachment nubs 108 and 96, spring 82 exerts a force that tends to urge attachment nubs 96 and 108 toward each other in a direction generally parallel to first direction 64. The movement of sliding plate 78 toward spring attachment nub 96 of attachment plate 76 is limited by an interior surface 110 of elongated aperture 102. When interior surface 110 contacts rivet 88, sliding plate 78 can no hanger be moved any further in first direction 64. As will be described in more detail herein, spring 82 exerts the tensioning force on cable 74, by way of engagement lug 104 when a drawer is opened. Depending on the physical construction of interlock 72, as well as the type of cable 74 chosen, spring 82 may be desirably chosen to exert a force against sliding plate 78 of one to two pounds in a first direction 64 when a drawer is open. Other amounts of force can also be used within the scope of the present invention. The amount of this force should be sufficient to retain cable 74 in a taut condition whenever any other drawers are attempted to be opened.
Sliding plate 78 further includes an embossment 112 on a side 114 that faces cam 80. Embossment 112 is positioned between elongated aperture 102 and engagement lug 104. Embossment 112 interacts with cam 80 in a manner that will be described in more detail herein. In general, cam 80 acts as a switch for moving sliding plate 78 between a tensioning position, in which tension is exerted on cable 74, and a non-tensioning position, in which no tension, or very little tension, is exerted on cable 74. This switching occurs when the drawer associated with interlock 72 is opened or closed. This switching utilized embossment 112, as explained more below.
Cam 80, which is depicted in more detail in FIGS. 6 and 14-16, includes a central aperture 116 which receives rivet 88. As mentioned previously, cam 88 is rotatable about rivet 88. Cam 80 includes a pair of spaced flanges 118 that define a channel 120 therebetween. Channel 120 selectively receives engagement member 86. Engagement member 86 is attached to the drawer 62 such that it will move linearly in first direction 64 when the drawer is open, and in second direction 66 when the drawer is closed. Cam 80 translates this linear motion into a rotational motion. Cam 80 includes a first surface 122 that engages embossment 112 whenever the associated drawer is fully closed. Raised shoulders 124a and b are defined adjacent each end of first surface 122. Raised shoulders 124a and b tend to maintain embossment 112 on first surface 112 and thereby resist inadvertent rotation of cam 80.
From the position illustrated in
After embossment 112 has overcome raised shoulder 124a, the force of spring 82 tends to pull sliding plate 78 in first direction 64. If cable 74 is in a taut condition, however, sliding plate 78 will not be able to move in first direction 64 because engagement lug 104 will be prevented from moving in first direction 64 by the taut cable. If the cable is taut, further rotation of cam 80 in direction 126 will only be able to continue until a stop surface 128 on cam 80 abuts against embossment 112. This condition is illustrated in
If cable 74 is not in a taut condition when cam 80 rotates in direction 126, then sliding plate 78 will be free to move in first direction 64 after embossment 112 has cleared raised shoulder 124a. This movement of sliding plate 78 in first direction 64 will cause embossment 112 to also move in first direction 64. This movement of embossment 112 will allow it to fit into a channel 130 defined on cam 80. Channel 130 is suitably dimensioned to allow cam 80 to continue to rotate until channel 120 is angled enough to, allow engagement member 86 to exit channel 120. Thus, the drawer can be opened. The movement of embossment 117 into channel 130, which is caused by the biasing force of spring 82, will also cause engagement lug 104 to move in first direction 64. The movement of engagement lug 104 in first direction 64 will increase the tension in cable 74 to a taut condition. No other drawers will therefore be able to be opened simultaneously.
When the associated drawer is closed, engagement member will cause cam 80 to rotate in a direction opposite to the direction of its rotation when the drawer is opened. This closing rotation will cause a surface 131 on cam 80 to engage embossment 112. This engagement pushes embossment 112, and consequently sliding plate 74 in second direction 66. In order to avoid requiring excessive force to close the drawer, surface 131 may be angled at about 45 degrees when it contacts embossment 112. This allows sliding plate 78 to be pushed in second direction 66 without excessive forces.
Engagement member 86, which is depicted in more detail in
Cable guide 84, which is depicted in more detail in
Apertures 140 are spaced apart in a vertical direction a distance that is slightly smaller than the vertical distance between shoulders 100 on flanges 98 of attachment plate 76. Thus, when flanges 98 are inserted into apertures 140, shoulders 100 contact and press against inner surfaces 142 of apertures 140. The dimensions of shoulders 100 force inner surfaces 142 to flex inwardly towards each other. When flanges 98 have been completely inserted into apertures 140, shoulders 100 have moved past inner surfaces 142, allowing them to flexibly snap back to their unstressed position. Shoulders 100 contact surfaces 144 of cable guide 84. Shoulders 100 thus prevent flanges 98 from being retracted out of apertures 140 without flexing inner surfaces 142 towards each other. Because shoulders 100 do not have a cam surface that facilitates removal of flanges 98 from apertures 140, cable guide 84 is securely retained on flanges 98 of attachment plate 76.
Cable 74 is easily threaded into cable guide 84 by moving cable 74 in direction 146 into channel 106 (
FIGS. 3 and 24-27 illustrate interlock 72 in its various positions according to different drawer conditions.
An interlock 72′ according to a second embodiment of the present invention is depicted, either partially or wholly, in
Interlock 72′ operates according to the same general principal as interlock 72 and is operatively coupled to a cable 74 that runs vertically inside of cabinet 60. Specifically, cable 74 is installed within the cabinet with a certain amount of slack. In general, interlock 72′ operates according to the amount of slack in cable 74. When the first drawer of the cabinet is opened, the associated interlock 72′ removes the slack from cable 74. As long as this drawer remains open, cable 74 remains in a low slack condition. The low slack condition of cable 74 prevents any other drawers from simultaneously being opened. When the one drawer is closed, cable 74 returns to its slack condition. In other words, cable 74 has two different basic levels of slack. When a single drawer is opened, interlock 72′ takes up most of or all the slack in the cable 74 and creates a second, lower level of slack in cable 74. The lower level of slack in cable 74 is such that no other drawers in the cabinet can be opened. This lower level of slack may be zero, or may be a small amount of slack. When the drawer is closed, more slack in the cable returns. At that point, any other single drawer may be opened, or the same drawer may be opened again. If a lock is included, the lock is adapted to alter the slack in cable 74 when the lock is activated. In this activated state, no drawers may be opened in the cabinet. When in the unlocked condition, the lock allows cable 74 to have sufficient slack so that a single drawer may be opened. Interlocks 72′ are thus designed to only allow their associated or attached drawer to be opened when cable 74 has sufficient slack. Further, they are designed to remove substantially all of the slack in cable 74, if their associated drawer is opened. The detailed construction and operation of interlock 72′ will now be described.
For purposes of description, components of interlock 72′ that are similar to components in interlock 72 will be described with the same reference numeral followed by the prime (C) symbol. Components of interlock 72′ that are substantially different from components of interlock 72 will be described with a completely new reference numeral. As can be easily seen in
Lever 156, which is illustrated in more detail in
Lever 156 includes an inner surface portion 180 and a crest 182. When a drawer is initially opened, cam 160 abuts against crest 182 and exerts a rotational force on lever 156. If cable 74 is not in a low slack condition, cam 160 pushes against crest 182 until lever 156 is rotated sufficiently to put cam 160 in contact with inner surface portion 180. This will be described in more detail below.
Cam 160, which is depicted in detail in FIGS. 32 and 36-39, is rotationally secured to stationary portion 90′ of drawer slide 70′ by way of second rivet 158. Cam 160 includes a recess 184 into which engagement member 86′ fits when the associated drawer is in the closed position. Recess 184 includes a contact surface 186 that contacts engagement member 86′ when the associated drawer is pulled in the first direction 64. When a drawer is pulled in first direction 64, engagement member 86′ engages contact surface 186 and imparts a rotational force on cam 160. This rotational force is generally in the direction 188 (
The rotation of cam 160 in direction 188 causes lever 156 to rotate in direction 178 (
When cable 74 is changed to a low slack condition by another interlock or lock, cam 160 cannot rotate further than the position depicted in
In addition, to maintain cam 160 in its proper rotational orientation when a drawer is opened, spring 82′ helps prevent the drawers from rebounding open, or partially open, after they are slammed shut. Without spring 82′, it might be possible for a drawer to be slammed shut with sufficient force such that the rebound of the drawer in first direction 64 might rotate earn 160 and allow the drawer to open up again. Spring 82′ helps prevent such rebounding of the drawers into the open position by biasing lever 156 in a direction that resists the rotation of cam 160. The amount of biasing is sufficient to generally overcome the amount of force typically present in a drawer rebound. The drawers therefore do not rebound open, but rather only open when a user applies sufficient force to overcome the biasing resistance that spring 82′ exerts.
Cam 160 includes a sloped surface 196 that helps ensure that engagement member 86′ is successfully guided back into recess 184 when a drawer is closed. If engagement member 86′ contacts sloped surface 196, it will exert a rotational force on cam 160 that tends to rotate cam 160 so that recess 184 is properly aligned for receiving engagement member 86′. Cam 160 further includes chamfered surfaces 198a and b. Chamfered surfaces 198a and 198b are designed to urge slidable portion 164 of drawer slide 70′ into proper axial alignment with cam 160. Stated alternatively, if slidably portion 164 of drawer slide 70′ is compressed toward stationary portion 90′, chamfered surface 198 will contact an end flange 200 on slidable portion 164 and urge it away from stationary portion 90′ (
Cam 160 further includes a slide surface 202 that contacts a respective slide surface 204 on lever 156 (
Cable guide 84′, which is depicted in detail in
Cable 74 is easily threaded into cable guide 84′ by moving cable 74 in direction 146 into channel 106 (
The head of rivet 158 preferably does not extend farther away from the stationary portion 90 than does slidable portion 164. Rivet 158, therefore, does not obstruct the drawer attached to slidable portion 164 and the back end of the drawer may extend all the way back to the back end of the drawer slide. Interlock 72, therefore, does not put any space limitations on the dimensions of the drawer other than those required by the drawer slide.
As mentioned previously, interlock 72′ is designed to transfer only a small fraction of a pulling force exerted on a drawer onto cable 74. This reduction in forces can best be understood with reference to
The force FC will be applied to moment arm 212 of lever 156 at a position C. Position C is located on moment arm 212 at a position that is relatively close to pivot point 214. Force FC will be transferred via lever 156 to cable 74 at a point T. Point T refers to the position where engagement lug 104′ engages cable 74. Because point T is substantially farther away from pivot point 214 along moment arm 212, the magnitude of force FT will be significantly less than the magnitude of force FC. Further, the spring 81′ will exert a force FS along lever 156 at a point S. This force FS acts in opposition to the force FT. Because point S is farther away from pivot point 214 along moment arm 212, a smaller amount of force FS is necessary to cancel out the force FT. The force FT that is exerted against cable 74 will therefore be greatly reduced as compared to the force FD that is exerted on the drawer. The tensioning force FT may be as little as 1/20th, or less, of the magnitude of the force FD. Cable 74 can therefore resist drawer-pulling forces that greatly exceed its maximum tensile strength.
In addition to transferring only a fraction of the force of FD to cable 74, the arrangement of cam 160 and lever 156 also magnifies the movement of engagement lug 104′ with respect to the rotation of cam 160. Stated alternatively, if the attached drawer is moved in first direction 64 a small distance A that causes cam 160 to partially rotate, the distance that engagement lug 104′ moves in first direction 64 will be greater than the distance A. For example, if the drawer is moved in first direction 64 for 0.05 inches, this may cause engagement lug 104′ to move 0.65 inches. This feature decreases the amount of movement in the locked drawers that might otherwise be present. A drawer that is locked will therefore only be able to be pulled a small distance before taut cable 74 prevents it from being opened. Interlock 72′ can thus prevent drawers from being opened even for the small distance that might otherwise easily allow an intruder to insert a screw driver, or other lever mechanism, between the drawer and the cabinet.
An example of a lock 216 that may be used in conjunction with the present invention is depicted in
Reciprocating member 224 includes a pair of apertures 236. Cable 74 may be secured to one of the apertures 236. When key cylinder 218 is rotated toward a locking condition, reciprocating member 224 moves vertically upward with respect to cover 226 (
Cable 74 may be secured to one of apertures 236 by threading the cable therethrough and tying it, such as is illustrated in
The opposite end of cable 74 may also be fastened within a cabinet by using a J-hook that fits through an aperture attached to the cabinet, although any other method of securing cable 74 can be used with the present invention. If it is desired to avoid having an end of cable 74 be attached to the frame of the cabinet, it could alternatively be held in place by interacting with cable guide 84′. Specifically, an enlarged ring or other structure could be affixed to the end of the cable. This enlarged structure would be dimensioned so that it was too large to pass through the cable passageway defined in cable guide 84. For securing the bottom of the cable, the enlarged structure would thus abut against a bottom surface 310 of the lower-most cable guide 84′ (
Lock 216 could be modified so that reciprocating member 224 utilized a spring or other structure that selectively increased or decreased the tension on cable 74. In other words, rather than having reciprocating member 224 absolutely move to is raised position when the key is rotated to the locked position, lock 216 could be modified to include a spring, or other biasing force, that urged member 224 towards its upper, locked position. If no drawers were open, this biasing force would be sufficient to raise member 224 to its locked position. If one drawer were open, this biasing force would be insufficient to move the member 224 to its upper position because the cable would be in its low slack condition, thereby preventing member 224 from moving upward while the drawer was opened. As soon as a drawer was closed, however, the biasing force would move member 224 to is locked position and remove the slack in the cable that was created by the drawer closing.
This arrangement allows the lock to be switched to the locked position while a drawer is still open. Once the drawer closed, it would immediately be locked and not able to be opened until the lock 216 was deactivated. The modified lock 216 thus would allow the cabinet to be locked while a drawer was still open, and as soon as the open drawer was closed, it would immediately lock. Thereafter, no drawers could be opened until the lock was deactivated. The biasing force exerted on reciprocating member 224 in modified lock 216 should be sufficient to remove the slack in cable 74 when all the drawers are closed and to maintain the cable in the locked, low slack condition when pulling forces are exerted against one or more locked drawers.
Lock 216 may be further modified to include a solenoid, or other electrically controlled switch, that controls the movement of reciprocating member 224 between its locked and unlocked position. The solenoid could be controlled remotely by a user using a hand-held device that transmitted wireless signals to a receiver in the cabinet that controlled the solenoid. The control could be carried out in a conventional manner, such as in the manner in which remote, keyless entry systems work on many current automobiles. Alternately, the cabinet could include a keypad, or other input device, in which the locking or unlocking of the cabinet was controlled by information, such as a code or password, input by a user.
A single interlock 72′ is all that is needed for each drawer in the cabinet. The opposite drawer slide can thus be a regular drawer slide with no interlock attached. Interlock 72, of course, can be attached directly to the cabinet, rather than integrated with the drawer slide. During the installation of the interlock system into a cabinet, the slack in the cable maybe easily set by securing one end of the cable, opening a single drawer, and then pulling the cable until substantially all of its slack is removed. The cable is then secured in that condition. When the drawer is thereafter closed, the cable will have sufficient slack to allow only a single drawer to be opened at a time. Alternatively, cables 74 could be manufactured at a preset length to fit different cabinet heights. The installer of the interlocks therefore could simply fasten the cable in the desired location and the length of the cable will create the appropriate slack to allow a single drawer to be opened. Once the appropriate length of a cable is determined for a given cabinet height, cables could be easily mass-produced by a manufacturer by simply cutting them to the appropriate lengths.
An interlock system 240 is depicted in
When either cable 74a or 74b is in the low slack condition, interlock 72 will prevent the associated drawers 62a or b from being opened. If both cables 74a and b are in the low slack condition, interlock 72 will also, of course, prevent the associated drawers 62a or b from being opened. Because cable 72a also runs through the interlock associated with the lowermost drawer 62c, only one drawer in the entire cabinet may be opened at a given time. Cable 74c, which runs through the interlock 72 of the lowermost drawer 62c, allows the lowermost drawer 62e to be selectively locked independently of the locking of the uppermost two drawers 62a and b. Cables 74a and c, which run through interlock 72 of the lowermost drawer 62c, may be run side by side through interlock 72 in the same manner that has been described above. Alternatively, an additional engagement lug 104 may be provided on all of the interlocks that extends outwardly in an opposite direction to engagement lug 104. Cable guide 84 may be modified to include a second channel to accommodate the second cable and align it with the added engagement lug. Other modifications may be made to accommodate the second cable. System 240 allows the two upper drawers to be locked independently of the lower-most drawer while only a single drawer may be opened at any time if either or both of the locks are not activated.
An interlock 472 according to yet another embodiment of the present invention is depicted in
Interlock 472 is adapted to be attached directly to a drawer slide 470. While interlock 472 is depicted attached to the back end of the drawer slide, it will be appreciated that it can be attached to a drawer slide at any desirable location along the drawer slide's length. Alternately, the interlock can be attached directly to the cabinet. Interlock 472 operates in conjunction with cable 74 so that only a single drawer can be open at a given time. As understood from
Spring 462 mounts on one end to the lever 456 at a stop 462a and on its other end to fixed rail 490 in a manner to urge lever 456 to move in a counter-clockwise direction about rivet 454 (as viewed in
Lever 456 is pivotable about a pivot axis generally defined by first rivet 454. Lever 456 includes an aperture for receiving first rivet 454, similar to the previous embodiments. As noted above, lever 456 includes a spring attachment tab or nub 462a to which one end of the spring is secured and an engagement lug 404 that engages cable 74. When lever 456 rotates about its pivot axis in a clockwise direction (as viewed in
Similar to the previous embodiments, lever 456 includes an inner surface portion 480, which optionally defines the range of motion of cam 460. When a drawer is initially opened, cam 460 rotates counterclockwise and exerts a rotational force on lever 456. If cable 74 is not in a low slack condition, surface portion 492 of cam 460 pushes against inner surface portion 480 until lever 456 is rotated sufficiently to remove the slack.
Cam 460 is rotationally secured to stationary portion 490 of drawer slide 470 by way of second rivet 458. Cam 460 includes an engagement surface 584, such as a pin 584a, with which engagement member 486 is engaged when the associated drawer is in the closed position. Pin 584a contacts engagement member 486 when the associated drawer is pulled in an extended or first direction. When a drawer is pulled in the extended direction, engagement member 486 engages pin 584a and imparts a rotational force on cam 460. The shape of aperture 486a is such that as the drawer is extended, pin 584a is urged downward (as viewed in
This rotation of lever 456 takes up any slack in cable 74 by way of engagement lug 404. However, if cable 74 is already in a low slack condition, lever 456 will be prevented from rotating sufficiently so that full rotation of cam 460 will therefore be prevented. Engagement member 486 of slidable portion 464 of drawer slide 470 wilt therefore not be able to disengage from pin 584a of cam 460. Drawer slide 470 will therefore not be able to slide, and the attached drawer will not be able to open.
When cable 74 is changed to the low slack condition by another interlock or lock, cam 460 cannot rotate further. If cable 74 is not already in a low slack condition, then cam 460 will be able to rotate sufficiently to allow engagement member 486 to disengage from pin 584a. Slide 470 is therefore free to slide and the attached drawer can be fully opened. When the drawer is fully open, the spring 462 exerts a force on lever 456 in a direction opposite its clockwise rotational direction, which tends to maintain the surface portion 492 of cam 460 in frictional contact with inner surface portion 480 of lever 456. This maintains cam 460 in the proper rotational attitude for pin 584a to be engaged by engagement member 486. When the drawer is being closed, engagement member 486 comes into contact with pin 584a on cam 460. As the drawer is fully closed, engagement member 486 pushes against pin 584a to thereby cause cam 460 to rotate in a clockwise direction (as viewed from
In addition to maintaining cam 460 in its proper rotational orientation when a drawer is opened, spring 462 helps prevent the drawers from rebounding open, or partially open, after they are slammed shut. Without the spring, it might be possible for a drawer to be slammed shut with sufficient force such that the rebound of the drawer might rotate the cam and allow the drawer to open up again. The spring helps prevent such rebounding of the drawers into the open position by biasing the lever in a direction that resists the rotation of the cam, as noted in reference to the previous embodiment.
Referring to
While other materials may be used, the interlocks described herein may be made primarily of metal. Specifically, the attachment plates, sliding plates, cams, and rivets may all be made of metal, such as steel, or any other suitable metal. The engagement members may be made of metal or any other suitable material. The cable guides may be all made from plastic. The drawer slides are preferably made of metal, such as steel, with the exception of the ball bearing cages for the ball bearings, which may be made of plastic. The levers, cams, and cable guides of interlock 72′ or interlock 472 may all be made of plastic. The first and second rivets, stationary portion, and slidable portion may also all be made of metal, such as steel. Spring 82 of interlock 72 may exert a force of 1.5 pounds. The springs of interlock 72′ and 472 may exert a force of approximately 0.5 pounds. Other spring strengths may, of course, be used. The cables may comprise steel cables each composed of seven strands, with each strand made of seven individual filaments and may have a tensile strength of 40 pounds. The cables may preferably be made of stainless steel and include a vinyl coating. For example, the diameter of the cable after coating may be 0.024 inches, although other dimensions can be used. To avoid kinking of the cables, surfaces that come in contact with the cable, such as the engagement lug, may be curved with a radius of at least 0.125 inches to help reduce the possibility of kinking. As several possible alternatives to steel, the cable could be a string, a plastic based line, such as those used as fishing lines, or any other elongated, flexible member with suitable tensile strength.
While the present invention has been described in terms of the preferred embodiments depicted in the drawings and discussed in the above specification, it will be understood by one skilled in the art that the present invention is not limited to these particular preferred embodiments, but includes any and all such modifications that are within the spirit and scope of the present invention as defined in the following claims.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US03/38001 | 11/26/2003 | WO | 00 | 12/13/2005 |
Publishing Document | Publishing Date | Country | Kind |
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WO2004/049864 | 6/17/2004 | WO | A |
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