HON lateral files deliver commercial office quality on a home-office budget. This four-drawer, 30"W model has a tamper-resistant enclosed base. Cabinet accepts letter or legal hanging file folders. Molded polymer handle is standard. Finish color is Black. SMALL BUSINESS OR HOME OFFICE: This compact filing cabinet frees up space in your office and helps organize your workspace. SMOOTH GLIDE: No loud bangs and crashes, these office file cabinets have four vertical reinforcements that keep the cabinet sturdy and ball-bearing full-suspension drawers that open and close quietly and easily. EAS. HON F26 File Cabinet Lock - Push-to-Lock Vertical File Cabinet Replacement Lock Kit. Comes with: * Plastic Sleeve * Sleeve Clip * Metal Fastener * Replacement Lock Cylinder * Bell Crank Actuator * Compression Spring **Quantity of two or more will ship keyed alike. Product information.  Wrong. Now the cabinet is permanently locked because the keyed part is disengaged from the locking mechanism. My accountant is unable to get to the files within. I'm going to have to find some long, skinny pliers to try and reach inside and operate the locking mechanism long enough to get the drawer open and take out this junk lock. Do not buy if you need to open your filing cabinet successfully more than three times. Picture attached. HON file cabinets use a cam lock to secure the drawers. The cam lock engages a mechanism on the inside of the cabinet that locks the lower drawers, while a lock bolt on the cam secures the top drawer. When keys get lost or you want to rekey the cabinet, it is necessary to change the lock.  His work has appeared in both print and online publications, including "The American Chronicle." Crawford holds an associate degree in business administration from Commonwealth College. HON file cabinets use a cam lock to secure the drawers. The cam lock engages a mechanism on the inside of the cabinet that locks the lower drawers, while a lock bolt on the cam secures the top drawer. When keys get lost or you want to rekey the cabinet, it is necessary to change the lock. Flexible arm includes a shoulder that retains reciprocating member to cover when the two are snap fit together. Once the appropriate lockinng 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. The present invention will now hon file cabinet locking mechanism pdf 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. When cable 74 is changed to the low slack condition by another interlock or lock, cam cannot rotate further than the mevhanism depicted in FIG. The interlocks of the hon file cabinet locking mechanism pdf invention may be advantageously combined or attached to the drawer slides in which drawers 62 slidingly move between their open and closed position. This lower level of slack may be zero, or may lockkng a small amount of slack. Spring 82 may exert a force of approximately 0.

To ensure you are ordering the correct caster for your chair, please locate the serial number on the sticker located on the underside of the seat and contact the original purchasing dealer.. Silver is a highly effective, natural agent. Silver ion technology is already present in everyday products cell phones, touch screens, textiles, clothing, etc.

Silver ion technology resists and inhibits the growth of microorganisms by forming a protective surface against microbes, pathogens, and bacteria, such as E. It also suppresses the growth of harmful mold, mildew, and fungus. In helping prevent the growth of stain and odor causing microorganisms, this protection provides stain and odor control. Additionally, tests have shown that on unprotected surfaces, bacteria can double in number every 20 minutes.

Mitigating the effects of this rapid escalation, Silver ion technology inhibits bacterial growth by For the core graded in line any of the vinyls would be resistant to fluid permeation and have more stain resistance than other fabrics.

CF Stinson is high durability, high performance textile solutions made with healthcare applications often in mind. Nanotex delivers permanent textile protection from soil and stains, while maintaining breathability and comfort. Nanotex bonds with the fabric, allowing lighter colored and delicate fabrics to repel liquids and stains, while preserving their natural beauty.

There is no difference, they are the same. A double-rub is the ability of fabric to resist surface wear caused by flat rubbing contact with another material. In the Wyzembeek abrasion test, fabrics are rubbed along the warp and weft of the fabric, with one back and forth motion equaling a double rub. The abrasion rating is determined by the number of double rubs made before two yarn breaks occur. The Signal fabric is extremely durable exceeds , double rubs and is Solution Dyed Nylon which is bleach cleanable.

Crypton is a treatment for textiles used to prevent stain, moisture, mold, mildew, bacteria, and odor-resisting protection. Several of our textiles feature this treatment. Polyurethane PU is a compound fabric made by laminating a cloth fabric to a thin film of polyurethane.

Yes, HON does allow for customer provided fabrics to be used on its chairs, provided it passes a manufacturing feasibility test. A fabric grade is a designator assigned to a certain fabric pattern which determines the associated pricing upcharge. Yes, touch-up pens are available as a Finished Goods order and model information can be found in the Pricer.

Additionally, 0. Frequently Asked Questions. What should I do if my chair is not moving up and down smoothly? What can I do to prevent my office chair from sinking whenever I sit in it? How do I fix my office chair if it is frozen and I cannot raise or lower it? What can I do if my chair wobbles when I am seated in it? What should I do if washers have fallen from the bottom of the chair base?

What should I do if the cylinder on the chair touches the floor? What does it mean if there is leaking oil or grease under my chair? How do I disassemble or take apart my chair? Where can I find chair functionality instructions? How do I adjust the hinges on my HON office furniture? My overhead unit was attached to the desk with double-sided sticky tape.

How do I move or remove the overhead unit without damaging the laminate surface? I have many HON desks and files in my office and would like them to use the same key. Can this be done? How do I remove the drawer on my laminate series desk? Where can I find the Hardware Pack for my product? How do I disassemble or Hon File Cabinet Locking Mechanism Google take apart my desk? What should I do if the lock on my HON lateral, credenza or pedestal cabinet spins when I turn the key, or if it makes a grinding noise when I open it?

Where should I start? What is the proper way to level my HON lateral file? The drawer on my HON lateral file does not seem aligned and it will not close all the way. How do I fix it? What should I do if the drawer on my HON lateral file will not properly open all the way?

How do I replace a thumb button that has come loose or is missing from a vertical filing cabinet? If the thumb button has fallen off, how can I access the drawer? What can I do if the lock on my vertical file spins or does not work? If you need to replace the Lock you can watch the below video to learn more.

I have many HON vertical and lateral files in my office and would like them to use the same key. Where can I find information on hangrails?

How do I disassemble or take apart my filing cabinet? What are the caster dimensions for steel chairs? Do we have caster recommendations for specific types of flooring? What are our casters made out of? What is the difference between hard casters and soft casters—and how can I get different casters for my chair? How do I fix this problem? What is Silver Ion Technology?

Do we have any fabric that is resistant to fluid permeation? Do we have any fabrics that use Nanotex? What is the difference between cycles and double rubs?

Why does the Signal fabric have a ten year warranty? Where can I find our fabrics that meet Healthcare standards? What is Crypton? What is Polyurethane? Can I provide my own fabric for chairs instead of choosing fabric offered by HON? What is Fabric Grade? While interlock 72 is depicted attached to the back ends of drawer slides 70 , it will be appreciated that it can be attached to the drawer slides at any desirable location along the drawer slides' length, or they can be attached directly to the cabinet.

Interlock 72 operates in conjunction with cable 74 so that only a single drawer can be open at a given time. If a lock is included in the cabinet, the lock is in communication with cable 74 and can change the amount of slack in cable If the lock is activated, cable 74 has little or no slack, and none of the drawers may be opened.

Interlock 72 allows a small portion of the pulling force exerted on a drawer in first direction 64 to be transmitted to cable Nevertheless, the amount of force transmitted is so small that a cable 74 having a relatively low tensile strength can still be used in a cabinet which provides strong resistance to its locking system being overcome.

As can be easily seen in FIG. Stationary portion 90 is fixedly secured to the interior of cabinet Stationary portion 90 includes an upper aperture and a lower aperture Upper aperture receives a first rivet that pivotally secures a lever to stationary portion Lower aperture receives a second rivet that pivotally secures a cam to stationary portion Interlock 72 further includes a cable guide 84 that is mounted to a pair of flanges 98 on stationary portion 90 Interlock 72 further includes a spring 82 and an engagement member Engagement member 86 comprises a flange that extends off of a slidable portion of drawer slide Slidable portion is slidable with respect to stationary portion 90 by way of a plurality of ball bearing cages that house a plurality of ball bearings in contact with both slidable portion and stationary portion 90 of drawer slide 70 FIGS.

Slidable portion is adapted to be secured to a drawer. Slidable portion may include a plurality of attachment flanges used to releasably secure slidable portion to the drawer. Similarly, stationary portion 90 may also include a plurality of attachment flanges used to releasably secure stationary portion 90 to the interior of the cabinet.

Lever , which is illustrated in more detail in FIGS. Lever includes an aperture for receiving first rivet Lever includes a spring attachment nub over which one end of spring 82 is secured. Lever further includes an engagement lug that engages cable When lever rotates about its pivot axis in a direction FIG. Spring 82 exerts a force on lever that tends to resist rotation in direction Lever includes an inner surface portion and a crest When a drawer is initially opened, cam abuts against crest and exerts a rotational force on lever If cable 74 is not in a low slack condition, cam pushes against crest until lever is rotated sufficiently to put cam in contact with inner surface portion This will be described in more detail below.

Cam , which is depicted in detail in FIGS. Cam includes a recess into which engagement member 86 fits when the associated drawer is in the closed position.

Recess includes a contact surface which contacts engagement member 86 when the associated drawer is pulled in the first direction When a drawer is pulled in first direction 64 , engagement member 86 engages contact surface and imparts a rotational force on cam This rotational force is generally in the direction FIG.

Rotational direction is the opposite of rotational direction The rotation of cam in direction causes an edge of cam to press against crest of lever If sufficient rotational force is exerted on cam , edge will push against lever sufficiently to allow edge to pass by the crest on lever Crest may have an arced or radial surface that allows edge to overcome it without an excessive force spike.

The rotation of cam in direction causes lever to rotate in direction FIG. The rotation of lever takes up any slack in cable 74 by way of engagement member If cable 74 is already in a low slack condition, lever will be prevented from rotating sufficiently far enough to allow edge of cam to reach inner surface portion of lever The full rotation of cam will therefore be prevented.

Engagement member 86 of slidable portion of drawer slide 70 will therefore not be able to disengage from recess in cam Drawer slide 70 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 cannot rotate further than the position depicted in FIG.

If cable 74 is not already in a low slack condition, then cam will be able to rotate sufficiently far so that edge contacts inner surface portion When edge is in contact with inner surface , cam has rotated sufficiently far to allow engagement member 86 to disengage out of recess Slide 70 is therefore free to slide and the attached drawer can be fully opened. When the drawer is fully open, spring 82 exerts a force on lever in a direction opposite to rotational direction This rotational force tends to maintain edge in frictional contact with inner surface portion This prevents edge from sliding back to contact with crest before the drawer is fully closed, and this maintains cam in the proper rotational attitude for recess to accept engagement member When the drawer is being closed, engagement member 86 eventually comes into contact with a contact surface defined on cam As the drawer is fully closed, engagement member 86 pushes against contact surface to thereby cause cam to rotate in a rotational direction that is opposite to direction This rotation causes edge to move out of contact with surface portion and into contact with crest This, in turn, allows lever to rotate in a direction opposite to direction This rotation causes engagement lug to decrease the force on cable The closing of the drawer therefore decreases any tension in cable 74 and increases its slack.

In addition to maintaining cam 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 cam and allow the drawer to open up again. Spring 82 helps prevent such rebounding of the drawers into the open position by biasing lever in a direction that resists the rotation of cam 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 includes a sloped surface that helps ensure that engagement member 86 is successfully guided back into recess when a drawer is closed.

If engagement member 86 contacts sloped surface , it will exert a rotational force on cam that tends to rotate cam so that recess is properly aligned for receiving engagement member Cam further includes chamfered surfaces a and b. Chamfered surfaces are designed to urge slidable portion of drawer slide 70 into proper axial alignment with cam Stated alternatively, if slidably portion of drawer slide 70 is compressed toward stationary portion 90 , chamfered surface will contact an end flange on slidable portion and urge it away from stationary portion 90 FIG.

Second chamfered surface b will continue to urge slidable portion away from stationary portion 90 as the drawer is completely closed. Chamfered surfaces a and b therefore serve to help maintain the proper spacing of stationary portion 90 with respect to slidable portion Cam further includes a slide surface that overlays a respective slide surface on lever FIGS. Slide surfaces and help ensure that cam and lever maintain the proper axial position with respect to each other as they are rotated.

Edge of cam may preferably be arced with a radius of 0. Crest may also be arced with a radius of 0. Other values may, of course, be used. Rounding edge and crest reduces the amount of force necessary to open the drawer.

However, rounding these surfaces excessively will cause more of the force exerted on a locked drawer to be transferred to the cable Cable guide 84 , which is depicted in more detail in FIGS. Cable guide 74 may be manufactured of molded plastic.

Cable guide 84 preferably snap-fittingly receives cable 84 so that cable 74 may be easily threaded into guide 84 with little danger of cable 74 becoming unthreaded.

Cable guide 84 includes an upper and lower portion a and b. A channel is defined between upper and lower portions a and b. Cable 74 is easily threaded into cable guide 84 by moving cable 74 in direction into channel FIG. Movement of cable 74 in this direction causes the cable 74 to come in contact with two flexible arms As cable 74 is further pushed against flexible arms , flexible arms begin to flex out of the way until sufficient clearance is provided for cable 74 to pass by flexible arms As soon as cable 74 passes by arms , they snap back to their unflexed condition.

In this unflexed condition, cable 74 is prevented from being retracted out of cable guide 74 in a direction opposite the direction by flexible arms If an interlock 72 is to be removed from the inside of a cabinet, cable 74 can be easily removed from cable guide 84 by manually pressing flexible arms in direction Flexible arms are pressed until sufficient clearance is provided for cable 74 to be retracted out of guide 84 in a direction generally opposite to direction Cable guide 84 includes a spring attachment nub that holds an end of spring 82 opposite spring attachment nub on lever Cable guide 84 includes recesses not shown that receive flanges 98 and that interact with the shoulders to secure guide 84 to stationary portion These recesses are defined on the bottom of cable guide 84 and do not extend all the way through cable guide Shoulders abut against surfaces when cable guide 84 is attached to stationary member 90 FIG.

Second rivet includes a sloped undersurface FIG. If the drawer is subjected to pulling forces, or other types of forces, that tend to cause the drawer to rack or twist especially if made out of thin sheet metal , these forces may move the back end of slideable portion away from stationary portion In such instances, end flange will come into contact with sloped undersurface of rivet as the drawer is closed.

The sloped nature of surface will create a force on end flange of slideable portion that pushes the back end of slideable portion toward stationary portion 90 in a direction generally parallel to pivot axis This helps maintain the proper alignment of the drawer when it is closed. End flange may be chamfered to correspond to the angle of undersurface in order to more easily force the drawer into the proper alignment. Undersurface also helps to ensure that engagement member 86 stays aligned with cam so that engagement member 86 properly engages cam Without rivet and undersurface , it might be possible for a drawer to become excessively racked such that engagement member 86 no longer contacted cam when the drawer was opened and closed.

Undersurface prevents this possibility. The head of rivet preferably does not extend farther away from the stationary portion 90 than does slideable portion Rivet therefore does not obstruct the drawer attached to slideable portion 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 This reduction in forces can best be understood with reference to FIG. The tautness of cable 74 prevents interlock 70 from allowing the drawer to be opened.

Line represents the moment arm of cam as it pivots about its pivot point corresponding to the center of rivet Line represents the moment arm of lever as it pivots about its pivot point corresponding to the center of rivet For purposes of discussing the forces applied to interlock 72 , it will be assumed that the cable 74 depicted in FIG.

Interlock 72 depicted in FIG. If a person exerts a strong pulling force on the drawer attached to interlock 72 of FIG. The pulling force exerted on the drawer in first direction 64 is transmitted to cam by engagement member Engagement member 86 engages cam generally in recess The pulling force exerted on the drawer, which is illustrated by the arrow F D , acts on moment arm at a point D.

This point corresponds to the location where engagement member 86 contacts first surface of recess Force F D will cause cam to rotate generally in a counter clockwise direction, as depicted in FIG.

This rotation will cause edge of cam to push against crest of lever with a force of F C. F C refers to the amount of force exerted by cam on lever Because force F C will be applied by cam at a location that is farther away from pivot point on moment arm , force F C will be less than force F D. The force F C will be applied to moment arm of lever at a position C. Position C is located on moment arm at a position that is relatively close to pivot point Force F C will be transferred via lever to cable 74 at a point T.

Point T refers to the position where engagement lug engages cable Because point T is substantially farther away from pivot point along moment arm , the magnitude of force F T will be significantly less than the magnitude of force F C.

Further, the spring 81 will exert a force F S along lever at a point S. This force F S acts in opposition to the force F T. Because point S is farther away from pivot point along moment arm , a smaller amount of force F S is necessary to cancel out the force F T.

The force F T that is exerted against cable 74 will therefore be greatly reduced as compared to the force F D that is exerted on the drawer. 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 F D to cable 74 , the arrangement of cam and lever also magnifies the movement of engagement lug with respect to the rotation of cam Stated alternatively, if the attached drawer is moved in first direction 64 a small distance A that causes cam to partially rotate, the distance that engagement lug 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. 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.

In FIG. The cable 74 would therefore prevent cam in lever of interlock 72 from rotating further than that depicted in FIG. When two drawers are trying to be opened simultaneously, lever can rotate more than it can in FIG. However, the rotation of lever is insufficient to allow edge of cam to travel past crest Cam therefore does not rotate sufficiently to allow engagement lever 86 to disengage from recess Therefore, neither drawer being simultaneously pulled will allow it to be opened.

Engagement member 86 has moved to a greater extent than in FIGS. This greater movement creates a sufficient force against cable 74 not shown to put the cable in a low slack condition, thereby preventing other drawers from being opened simultaneously.

With surface in contact with surface , lever is prevented from rotating back, thereby maintaining cable 74 in the lower slack state when another drawer is attempted to be opened. An example of a lock that may be used in conjunction with the present invention is depicted in FIGS.

Lock selectively changes the condition of cable 74 from a high slack condition to a low slack condition. Lock includes a hole , which may be a keyhole, into which a key may be inserted, or which may receive a bar that is coupled to a conventional lock cylinder.

If hole is a keyhole, insertion of the proper key therein allows a key cylinder to be rotated by the key. If hole receives a bar, which may be desirable where lock is positioned at the back end of the cabinet, the bar is coupled to any conventional lock in a manner that causes the bar to be able to rotate about its longitudinal axis when the proper key is inserted into the conventional lock.

In either situation, key cylinder therefore will rotate when a proper key is used. Key cylinder includes a pin that moves in a cam track defined in a reciprocating member Reciprocating member is snap-fittingly attached to a cover by way of a flexible arm Flexible arm fits into an aperture defined in cover Flexible arm includes a shoulder that retains reciprocating member to cover when the two are snap fit together.

The snap fitting occurs when flexible arm initially contacts cover A cam surface causes flexible arm to flex as reciprocating member is initially pushed toward cover After the two are completely secured together, flexible arm snaps back to its unflexed condition in which shoulder prevents the two members from being separated.

Reciprocating member includes a pair of apertures Cable 74 may be secured to one of the apertures When key cylinder is rotated toward a locking condition, reciprocating member moves vertically upward with respect to cover FIGS. This vertical movement decreases the slack in cable 74 such that no drawers in the cabinet may be opened.

When lock is unlocked, the unlocking rotation of key cylinder moves reciprocating member vertically downward with respect to cover FIGS. This creates sufficient slack in cable 74 for a single drawer to be opened. Cover may be securely fastened inside of cabinet 60 in any suitable manner. Cable 74 may be secured to one of apertures by threading the cable therethrough and tying it, such as is illustrated in FIGS.

Alternatively, a more preferred method of securing cable 74 to apertures is accomplished by way of a J-hook FIG.

J-hook is crimped onto an end of cable 74 in a conventional manner. J-hook includes a lower vertical section , a middle horizontal section , and an upper vertical section Upper vertical section , along with a portion of horizontal section , is inserted through one of apertures and manipulated until upper vertical section contacts one side of the wall in which apertures are defined and is oriented vertically.

In this position, horizontal section passes horizontally through the aperture and lower vertical section abuts against a side of the wall in which aperture is defined that is opposite the side contacting upper section In this position, J-hook is maintained in aperture and can only be released by manually twisting J-hook appropriately to allow upper section to be backed out of aperture J-hook thus provides a convenient way for installing and removing cable 74 from lock 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 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 For securing the bottom of the cable, the enlarged structure would thus abut against a bottom surface of the lower-most cable guide 84 FIGS.

If it were desired to secure the top end of the cable in a like manner to a cable guide 84 , rather than to a lock , an enlarged structure could also be attached to the top end of cable In this situation, the enlarged structure would abut against a top surface of the uppermost cable guide The enlarged structure may preferably be shaped to snap onto, or otherwise be secured to, cable guide If an enlarged structure were used on both ends of the cable to secure it in the cabinet, the proper cable slack could be set by manufacturing the cable to the specific length that created the desired amount of slack.

Lock could be modified so that reciprocating member utilized a spring or other structure that selectively increased or decreased the tension on cable In other words, rather than having reciprocating member absolutely move to is raised position when the key is rotated to the locked position, lock could be modified to include a spring, or other biasing force, that urged member towards its upper, locked position.

If no drawers were open, this biasing force would be sufficient to raise member to its locked position. If one drawer were open, this biasing force would be insufficient to move the member to its upper position because the cable would be in its low slack condition, thereby preventing member from moving upward while the drawer was opened.

As soon as a drawer was closed, however, the biasing force would move member 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 was deactivated.

The modified lock 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 in modified lock 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 may be further modified to include a solenoid, or other electrically controlled switch, that controls the movement of reciprocating member 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. While other materials may be used, interlock 72 may be made primarily of plastic.

Specifically, lever , cam , and cable guide 84 may all be made of plastic. Drawer slide 70 is 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.

First and second rivets and , stationary portion 90 , and slidable portion may also all be made of metal, such as steel.

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