CA1298862C - Sliding door lock - Google Patents
Sliding door lockInfo
- Publication number
- CA1298862C CA1298862C CA000541764A CA541764A CA1298862C CA 1298862 C CA1298862 C CA 1298862C CA 000541764 A CA000541764 A CA 000541764A CA 541764 A CA541764 A CA 541764A CA 1298862 C CA1298862 C CA 1298862C
- Authority
- CA
- Canada
- Prior art keywords
- lock
- door
- lock bolt
- slide member
- keeper
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
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- 230000003993 interaction Effects 0.000 description 3
- 229910000831 Steel Inorganic materials 0.000 description 2
- 230000000712 assembly Effects 0.000 description 2
- 238000000429 assembly Methods 0.000 description 2
- 238000005452 bending Methods 0.000 description 2
- 238000010276 construction Methods 0.000 description 2
- 238000009434 installation Methods 0.000 description 2
- 238000000034 method Methods 0.000 description 2
- 230000000717 retained effect Effects 0.000 description 2
- 239000010959 steel Substances 0.000 description 2
- 101100230376 Acetivibrio thermocellus (strain ATCC 27405 / DSM 1237 / JCM 9322 / NBRC 103400 / NCIMB 10682 / NRRL B-4536 / VPI 7372) celI gene Proteins 0.000 description 1
- 101100072702 Drosophila melanogaster defl gene Proteins 0.000 description 1
- HOKDBMAJZXIPGC-UHFFFAOYSA-N Mequitazine Chemical compound C12=CC=CC=C2SC2=CC=CC=C2N1CC1C(CC2)CCN2C1 HOKDBMAJZXIPGC-UHFFFAOYSA-N 0.000 description 1
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- 239000000463 material Substances 0.000 description 1
- 230000009528 severe injury Effects 0.000 description 1
Landscapes
- Lock And Its Accessories (AREA)
Abstract
ABSTRACT OF THE INVENTION
The lock assembly of the present invention is mounted in a lock frame. A slide member is disposed for translation within the lock frame. A lock bolt is pivotally mounted within the lock frame and extends through it for engagement with a door keeper in a door frame. A lock bolt detent is pivotally mounted to the slide member for maintaining the lock bolt in a secure position when the door is closed. Actuation of movement of the slide member results in movement of the lock bolt detent away from the lock bolt followed by pivotal motion of the lock bolt as a pin on the slide member engages the lock bolt and lifts clear of the door keeper. The door is sprung open by a spring loaded plunger which extends out of the lock frame.
The lock assembly of the present invention is mounted in a lock frame. A slide member is disposed for translation within the lock frame. A lock bolt is pivotally mounted within the lock frame and extends through it for engagement with a door keeper in a door frame. A lock bolt detent is pivotally mounted to the slide member for maintaining the lock bolt in a secure position when the door is closed. Actuation of movement of the slide member results in movement of the lock bolt detent away from the lock bolt followed by pivotal motion of the lock bolt as a pin on the slide member engages the lock bolt and lifts clear of the door keeper. The door is sprung open by a spring loaded plunger which extends out of the lock frame.
Description
~L~9~ 2 APPLICATION FOR PATENT
TITLE: SLIDING DoaR LOCK
INVENTORS: EUGENE F. DAUGHERTY AND
C~ARLES E. HOLYCROSS
Field of the Invention The present invention relates to locks and secur~ty devices such as are used in prison security doors and the like. The disclosed lock assembly is particularly suited for use in a door locking system and may be operated remotely or locally adjacent to the door.
Bac~ of the Invention Penal institutions frequently house inmates in dormitory-like cells or rooms which open to a common hall or corridor. In a prison environment it is, of course, mandatory that access to the celIs by the inmates be controlled. It is desirable that such control be achieved either locall~ at each door or remotely from a secured central control room.
While previously known systems have attempted to provide such features, they have failed to achieve wide-spread acceptance due to a number of shortcomings such as technical complexity, functional inade~uacy and high cost. For example, light weight electric solenoid bolt control `devices have been previousIy proposed, such as the device disclosed in U.S. Patent No. 3,893,723, wherein a bolt was actuated by a slide member 10 which moved between upper and lower solenoids. The device was unsatisfactory for high security installations since it ~..
- ,' ' ' was easily damaged by any substantial force applied to the bolt in its extended position. Any such force created a bending force on the solenoids and typically resulted in severe damage or destruction of the locking mechanism.
The inmates' well known propensity for vandalism in penal institutions therefore rendered the device of this patent totally unsatisfactory for penal institution use.
Other penal door locking systems were not usable with conventional steel door jambs and door assemblies. The cost of custom door installations made such systems too expensive to be practical for use in government built penal institutions.
Other device~ such as that sho~m in U.S. P tent No.
1,946,384 have employed solenoid operated bolt members actuated by a pin and slot camming arrangement of complex construction suitable only for light duty in window sashes or the like.
U.S. Patent No. 4,099,752 disclosed a lock in which an actuating solenoid for the bolt was mounted so that its plunger had an axis o movement perpendicular to the axis of movement of the lock bolt. The lock bolt also included a detent switch which energized a solenoid to lock the bolt when the door was closed.
Therefore, it is the object of the present invention to provide a new and improved door locking system for penal or similar institutions that is secure and relatively inexpensive to install.
It is yet another object of the present invention to provide a new and improved door locking system that can be operable from a remote site and from a position adjacent the door.
5ummary of_the Invention The lock assembly L of the present invention is mounted in a lock frame. The lock assembly L includes slide member for actuating the lock mechanism disposed for translation within the lock frame by manual actuatiOn with a key or i.n response to a control signal. A lock bolt is pivotally mounted within the lock frame and extends through it for engagement with a door keeper in a door frame. A lock bolt detent is pivotally mounted to the slide member for maintaining the lock bolt in a secured position when the door is closed. Actuation of the slide member results in movement of the lock bolt detent away from the lock bolt followed by pivotal motion of the lock bolt as a pin on the slide member engages the lock bolt and lifts it clear of the door keeper. Once the lock bolt has been disengaged from the doar keeper, the door is sprung open by a spring loaded plunger which extends out of the lock frame.
Description of th~ Drawings Fig. l is a side elevational view of the lock lS assembly of the present invention with the lock bolt in the deadlocked position.
Fig. 2 is an end view of the invention taken along lines 2-2 of Fig. 1.
Fig. 3 is a side elevational view of the lock assembly of the present invention with the lock bolt in the open position as the door is being opened.
Fig. 4 is a side elevational view of the lock assembly of the present invention with the lock bolt in the open position as the door is being closed.
Fig. 5 is a sectional elevational view of an alternative embodiment of the lock assembly.
Fig. 6 is a detailed sectional elevational view of the alternative embodiment of the lock assembly shown in Fig. 5.
Detailed DescriPtion of the Preferred Embodiment As best seen in Fig. 1, the lock assembly L is built around a lock frame 10. The lock frame 10 is deSigned to be fitted into a door frame or wall (not shown) and attached thereto by well known means. The lock frame 10 interacts with door 12 which is schematically illustrated in Figs. l and 3. Door 1~ further includes a door keeper 14. The above-described arrangement can be reversed .
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without departing from the spirit of the invention. As can readily been seen, when the door is closed a lock bolt ~o travels over door keeper 14 and into receptacle 16, in the manner more fully described hereinbelow. In order to S protect against vandalism, lock frame 10 is fabricated from 3/16 inch thick plate 18, for example. Lock frame 10 is formed having several openings to accommodate various elements of the lock assembly. Opening 20 allows lock bolt 30 to project from within lock frame 10 for engagement with door kèeper 14. Opening 22 allows plunger 40 to project from lock frame 10 and contact the door 12 when it is closed.
Mounted with1n lock frame 10 are: a slids member 50;
lock bolt 30; a lock bolt detent means D; a disabling means G and a drive means R. The function and operation of each of these elements is described in more detail hereinbelow.
Slide member 50 is mounted to lock frame 10 in a manner which allows slide member 50 to translate in a direction parallel to the longitudinal axis of lock assembly L. To facilitate such translation, slide member 50 has a plurality of mounting slots 52 (see Figs. 1 and 3). Each slot 52 has a bolt 54 extending therethrough and which is threaded into or otherwise secured to lock frame 10 (see Fig. 2). Slide member 50 further includes a lower flange 56 which is disposed in a plane perpendicular to the remainder of slide member 50 for operative engagement by drive means R (Fig. 2).
Drive means R includes a mechanical lock 70 which may be actuated by an attendant standing near the door.
Mechanical lock 70 includes a lock cylinder 72 which when rotated through the use of a key forces a deadbolt 74 to extend from the mechanical lock 70 and bear on flange 56 of slide member 50. In this manner slide member 50 is displaced vertically in response to keyed operation of lock 70 in order to open the door. Reversed rotation of a key in lock cylinder 72 results in the retraction of r deadbolt 74 back into mechanical lock 70. As a result, slide member ~0 drops down vertically due to its own w~ight. The manual mechanical lock 70 is of a type known in the art such as that currently manufactu~ed by 50uthern Steel Company of San Antonio, Texas under Mod01 No. 1010.
A~ illustrated in Fig. 1, slide member 50 i9 in the locked position. As illustrated in Fig. 3, slide member 50 is in the unlocked position. While the illustrated embodiment relies upon the weight of slide member 50 to return it from the unlocked to the locked position, it sh~uld be understood that the lock assembly of the present invention may also include a biasing means, such as a spring or the like, to positivelv bias slide member 50 from the unlocked to the locked position.
Referring now to Fig. 2, lock bolt 30 is pivotally mounted to lock frame 10 and extends through opening 20 out of lock frame 10. A hook shaped segment 32 of lock bolt 30 extends from lock frame 10 to engage door keeper 14 when the door is closed. Lock bolt 30 is pivotally mounted to lock frame 10 on pin 34 (see Fig. 2). In order to facilitate engagement between hook shaped segment 32 and door keeper 14, lock bolt 30 further includes a leading beveled edge 36. As the door is pushed from the open to the closed position, leading beveled edge 36 first contacts the door keeper 14 thereby pivoting lock bolt 30 around pin 34. As shown in Fig. 1, lock bolt 30 is in the secured position. As shown in Fig. 3, due to the interaction between leading beveled edge 36 and door keeper 14, lock bolt 30 has been rotated from the secured position toward the open position. Fig. 4 shows the lock bolt in the fully open position. Upon further movement of the door 12 toward the door frame leading beveled edge 36 is moved further into door keeper 14 and as a result, spring 38 biases lock bolt 30 toward the secured position.
The action of spring 38 results in engagement between the hook shaped segment 32 and the door keeper 14, thereby locking the door. It should be noted that lock bolt 30 .
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can be designed with su~ficient weight in the hook shaped segment 32 so that spring 38 would not be necessary and lock bolt 30 wlll, by gravity, rotate counterclockwlse toward the secured position after the le~ding beveled edge 36 has passed into door keeper 14. However, spring ~8 ~s a desirable featl~re and is specifically included in specifications for locks by penal institutions in the United States.
It is desirable, that the design of the lock assemblies for penal institutions prevent inmates from using tools to rotate the lock bolt 30 from the secured position shown in Fig. 1 to the open position shown in Fig~ 3 when the Aoor is closed. In order t~ prevent rotation of lock bolt 30 ~hen the door is closed, lock bolt detent means D engages detent tang 39 when the door is closed. Lock bolt detent means D comprises a generally L-shaped pivotally mounted link 60. Link 60 is pivotally connected to slide member 50 via pin 61 (see Fig. 2).
Link 60 includes a horizontal component 62 and a vertical component 64. As shown in Fig. 1, the horizontal component 62 further includes an engagement means E to prevent rotation of lock bolt 30 about pin 34 when the door is closed and locked. In the illustrated embodiment, means E comprises a depression 66 adapted to engage detent tang 39 to prevent the lock bolt 30 from rotating about pin 34 when the door is closed and locked. It should be noted that alternative designs of the engagement means E
of the horizontal component 62 of link 60 may be used without departing from the spirit of the invention. For example, the horizontal component 62 may have a slot therethrough or may in other ways interfere with the rotation of lock bolt 30 when the lock bolt is in the secured position.
As previously stated, the slide member S0 may be manually actuated by mechanical lock 70. However, drive means R also includes an alternative method of ~ctuating slide member S0 from a secured remote location such as a ., , ;
- ~z~
central control room for pxison guards. Drive means R
includes a motor 76 operably connected to eccentric cam 78 through gearing or other methods known in the art.
Eccentric cam 78 is connected through a linkage formed by the connecticn of rigid link 80 to slide member 50 via pin 82 (see Fig. 2). Pin ~2 extends through a slot 84 in link 80. As can readily be seen from Fig. 2, the purpose of slot 84 is to allow actuation of slide member 50 via mechanical lock 70 without interfering with or effecting link 80.
When slide member 50 is raised via operation of motor 76 or mechanical lock 70, and the door is closed, pin 61 which is fixed to slide member 50 causes the horizontal component 62 of l1nk 60 to rise. Pin 61 thus forms a part of disabling means G, as will be more fully described hereinbelow. As slide member 50 initially moves from the locked to the unlocked position, the vertical translation of pin 61 disengages depression 66 from detent tang 39.
In this position, lock bolt 30 is free to rotate about pin 34. As slide member 50 is raised further, pin 58 engages lock bolt 30 to initiate its rotation about pin 34. It should be noted that at the time pin 58 contacts lock bolt 30, the depression 66 on horizontal component 62 of link 60 has already begun to move away from detent tang 39.
Therefore, further vertical movement of slide member 50 from the locked to the unlocked position causes lock bolt 30 to pivot until hooked shaped segment 32 is in the position shown in Fig. 3 allowing it to be withdrawn from the door keeper 14. In the preferred embodiment, a slight initial movement of slide 50, i.e. 5/32", moves depression 66 away from detent tang 39. Further movement of slide 50, i.e. 7/16", moves lock bolt 30 to the open poSition.
The details of disabling means G are illustrated in Fig. 3. When lock bolt 30 is raised to the open position, disabling means G acts to force the door open by withdrawing hook shaped segment 32 from door keeper 14 and forcing the door to slide open. A plunger 40 is guifled 6:2 within lock frame 10 by guides 42 and 44. Nut 45 attached to plunger 40 acts as a travel stop when it contacts guide 42. Plunger 40 serves to spring the door open as loc~
bolt 30 is pivoted from the secured to the open position via the action of a biasing means B secured to plunger 40.
Biasing means B includes release spring 46 and return spring 47. The vertical component 64 of pivotally mounted link 60 is operably connected to plunger 40. As best seen in Fig. 2, the vertical component 64 is U-shaped with plunger 40 passing through it. Release spring 46 is mounted over plunger 40 and is secured to guide 42 on one end and pin 48 extending from plunger 40 at the other end.
Return spring 47 is secured to plunger 40 vi~ ~in 49 at one end. The opposite end of return spring 47 bears against vertical component 64 by pressing against washer 41. Washer 41 is not essential and it should be understood that return spring 47 may bear directly again~t vertical component 64 without departing from the spirit of the invention.
When the door is closed and slide member 50 is actuated to raise lock bolt 30 from the secured to the open position (Fig. 3), biasing means B causes plunger 40 which bears against door 12 to force the door open as soon as hook shaped segment 32 has been positioned to be retracted from door keeper 14. Release spring 46 acting against pin 48 propels plunger 40 outwardly against door 12 thereby sliding the door open. In the preferred embodiment, release spring 46 has a higher spring rate or exerts more force per inch of compression than spring 47 so that as long as the door remains open (Fig. 4) release spring 46 overcomes the opposite force exerted by return spring 47. It should also be noted that by reason of release spring 46 overcoming the opposing force produced by return spring 47, pivotally mounted link 60 is rotated counterclockwise to the position ~hown in Fi~. 4. As can readily be seen from Figs. 1 and 4, the pin 48 acting against washer 43 which bears against vertical component g 64 results in rotation of vertical component 64 about pin 61. Due to the higher spring rate o~ releas~ spring 46 as compared to return spring 47, as long as the door remains open, the pivotally mounted link 60 remains in the position shown in Fig. 4. In the preferred embodiment, pivotally mounted link 6C is forced to rotate approximately 10 to 15, although other degrees of rotation may be used without departing from the spirit of the invention.
As previously mentioned, rotation of link 60 results in depression 66 moving away from detent tang 39. It is necessary to maintain depression 66 away from detent tang 39 while the door is open so that lock bolt 3p is free to pivot ahout pin 34 as long as the door is left open (Fig.
4). This feature is desirable so that the door may automatically lock when slammed shut. By way of further explanation, whether slide member 50 is actuated to move from the locked to the unlocked position via motor 76 or mechanical lock 70, slide member 50 moves in one complete cycle from locked to unlocked and back to the locked position. In motor driven embodiments, a limit switch 90 is provided which causes motor 76 to be actuated through one complete revolution whenever the guard at a remote location actuates motor 76. A second limit switch, not shown can be used to stop the motor 76 after half a revolution thereby keeping the lock in the unlocked position as long as desired. As motor 76 completes one revolution, slide member 50 will move in one smooth motion from the locked to the unlocked and back to the locked position. Similarly, when the lock assembly L is operated via a mechanical lock 70, the guard may use a key to extend deadbolt 74 to open the door and then withdraw the key thereby retracting deadbolt 74 back into mechanical lock 70 after the door has sprung open. Thus, after the door has been pushed open due to the action of plunger 40 biased by release spring 46, the components within lock frame 10 come to rest in the position sho~n in Fig. 4, 36;~
with link 60 defl~cted 10 to 15 countexclockwise from its position in Yig. 1 and retained in that position due to the spring rat~ of release spring ~6 exceeding the spring rate o~ return spring 47.
When it is desired to close the door 12, (~ig. 4), the door is sliA toward the door frame containing the lock assembly L. Since the llook shaped segment 32 of lock bolt 30 extends from lock frame 10 further than plunger 40, initial contact is first made between leading beveled edge 36 and door keeper 1~. The net result is that lock bolt 30 is pivoted from the locked position toward the unlocked position in a clockwise direction until leading beveled edge 36 clears the door keeper 14 whereupon.spring 38 biases lock bolt 30 in a counterclockwise direction resulting in engagement of the hook shaped segment 32 within door keeper 14. Just as the leading beveled edge 36 clears the door keeper 14, plunger 40 contacts door 12.
Further inward movement of the doox 12 toward the door frame results in compression of release spring 46. In essence, release spring 46 is compressed by movement of pin 48 toward guide 42. As a result, return spring 47, which has previously been compressed when the door was opened, bears against washer 41 and causes pivotally mounted link 60 to rotate clockwise about pin 61 until link 60 is in the position shown in Fig. 1. Therefore, it is preferred that the extension of plunger 40 when the door is opened be preset such that rotation of link 60 commences with rotation of lock bolt 30 toward the secured position when leading beveled edge 36 clears door keeper 14. In that circumstance, as soon as lock bolt 30 has completed its travel from the open to the secured position, depression 66 formed in horizontal com~onent 62 is in position for engagement with detent tang 39. The net result ls that upon engagement of hook shaped segment 32 into door keeper 14, the interaction between depression 66 and detent tang 39 prevents rotation of lock bolt 30 out of the secured position.
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As shown in Fig. 1, plunger 40 is guided by guides 42 and 44 and further has spring forces from release spring 46 and return spring 47 acting on it. As indic~ted in Fig. 1, when the doGr is closed, the normal position for plunger 40 is in the deadlocked position. However, it is possible that inmates may attempt to vandal,ze plunger 40 by attaching foreign objects to door 12 with the intent of damaging lock assembly L by overtravel of plunger 40.
Alternatively, inmates may attempt to damage the lock by jamming lock bolt 30 in the locked position and slamming the door 12 into it. The lock assembly of the present invention compensates for such attempts at vandalism by providing freedom for plunger 40 to move into the overtravel position (see Fig. 1). Additionally, the lock bolt 30 can be resiliently mounted to frame 10 (Figs. 5 and 6). Accordingly, none of the internal components will be damaged if an inmate maliciously attaches a foreign object to door frame 12 at the point of contact with plunger 40. The indirect link between pivotally mounted 20 link 60 and plunger 40 also serves to prevent vandalism to the lock assembly L. As shown in Fig. 1, plunger 40 and link 60 are not rigidly connected. Instead, any force applied to plunger 40 as might occur in an inmate's attempt to damage the lock assembly will be transmitted to 25 release spring 46 and return spring 47 rather than directly to link 60.
K Due to the propensity of inmates to vandalize locks, it is desirable to be able to determine the position of lock bolt 30 from a remote location such as a control room 30 monitored by prison guards. To this end, pin 59 acting in conjunction with lock bolt limit switch 92 provide a signal to a remote location that the lock bolt ~0 is in the secured position. Similarly, pin 68 acting in conjunction with lock bolt detent limit switch 94 provide 35 a signal that pivotally mounted link 60 has achieved the position shown in Fig. l wherein it effectively precludes 8~6~
rotation of lock bolt 30 clockwise out of the secured position to the opened position.
An alternative embodiment is disclosed in Figs. 5 ar,d 6. The operation of this embod1ment is in many respects identical to the lock assembly as prèviously discussed in Figs~ 1 through 4. However, there are a few differences as will be discussed hereinbelow. The principal area of difference lies ln engagement means E'. As seen in Fig.
6, lock bolt 30' has a depression defined by surfaces 100, 102 and 104. As before, rigid link 80' is in contact with slide member 50' to urge slide member 50' to selectively move upwardly or downwardly. ~ suitably connected motor (not shown) can actuate rigid link 80'. Alt~rnatively, slide member 50' can be manually actuated with a key lock assembly 70' (Fig. 5).
It should be noted that link 60' is pivoted around pin 61'. Pin 61' is connected to carriage 106 which supports not only link 60' but also lock bolt 30' via pivot pin 34'.
Lock bolt 30' further includes an internal opening 108. Pin 110 extends from slide member 50' through carriage 106 and opening 108. Link 60' has a curved surface 112 thereon. Upward movement of slide 50' causes pin 110 to engage curved surface 112 thereby rotating link 60~ ~ clockwise about pin 61'. The clockwise rotation of link 60' moves engagement means E' which comprises of a tab 114. In the position as shown in Fig.
6, tab 114 is disposed over surface 116 of lock bolt 30'.
Thus, in the position shown in Fig. 6, engagement means E
is enabled thereby preventing lock bolt 30' from pivoting about pin 34' due to the interaction of tab 114 with surface 116. However, when pin 108 engages curve,d surface 112 as a result of upward movement of slide 50', link 60' is rotated clockwise along with tab 114. Thus tab 114 is juxtaposed against the depression defined by surfaces 100, 102 and 104 on lock bolt 30'. Subsequently, after pin 110 causes link 60' to rotate clockwise, further elevation of .
.
slide member 50' results in pin 110 raising lock bolt 30' by engagement with internal opening 108. It should be noted that clockwise displacement of link 60' results in compression of spring 47' as a result of tab 114 pressing against washer 120. As in the embodi~ents of Figs. 1-4, when lock bolt 30' clears the door keeper 14, spring 46' overcomes the fcrce of spring 47' and propels plunger 40' outwardly from lock assembly L'. Spring 46' acts against washer 43' which is retained by pin 48' to plunger 40'.
Thus, as long as the door remains opened, spring 46 overcomes the force of spring 47'thus retaining the engagement means in the disabled position wherein tab 114 is juxtaposed opposite the depression in lock bolt 30' as defined by surfaces 100, 102 and 104.
Since the lock bolt 30' extends further than plunger 40', upon closing the door, inclined surface 36' engages the door keeper 14 (See Fig. 1) whereupon lock bolt 30' is caused to rotate counterclockwise. The forward end of lock bolt 30' clears door keeper 14 and enters receptacle 16 (see Fig. l). Due to the extension of plunger 40' from lock assembly L, the engagement means E' remains disabled as the lock bolt 30' rotates counterclockwise and its leading edge enters receptacle 16 behind doorkeeper 14.
Further movement of the door causes plunger 40' to engage the door with a resultant inward displacement of plunger 40' into lock assembly L'. This inward displacement causes spring 46' to be compressed as a result of pin 48' pushing against washer 43'. Simultaneously, forces acting to compress spring 47' are relieved thereby causing washer 120 to displace tab 114. Displacement of tab 114 results in counterclockwise rotation of link 60' to the position shown in Fig. 6. Thus, when the door is fully cl,osed, tab 114 will be in the position shown in Fig. 6. The door will then be locked due to the lock bolt 30' being in position within receptacle 16 and engagement means E' being placed in the enabled position as a result of the forces exerted by spring 47' on tab 114. It should be _ l4 _ noted that no movement of slide member 50~ is necessary in order to close and lock the door. The door merely needs to be slammed shut.
Another beneficial feature of the invention is illustrated in Fig. 5. Carriage 106 support lock bolt 30' via pin 34'. Additionally, as shown in Fig. 6, plunger 40' is supported off of carriage 106 by extending through the carriage at a point marked 118 on one end and via support of a strut 120 at the opposite end. Carriage 106 is resiliently mounted to lock frame 10' through the use of a plurality of springs 122 straddling bolts 124 or any other equivalent means.
Thus, as seen in Fig. 5, if an inmate attempts to vandalize the lock assembly L of the present invention by somehow mannually holding lock bolt 30' in the deadlock position shown in Fig. 6 and slamming the door shut against it, springs 122 provide sufficient resiliency in the mounting of the lock bolt 30' to the lock assembly L' to avoid doing damage to the lock bold 30'. Thus slamming the door against lock bolt 30' in the deadlock position merely results in displacement of carriage 106 which is guided by bolts 124. Springs 122 resist forces applied to lock bolt 30' and keep carriage 106 abutting lock frame 10'. In order to allow for lateral movement of carriage 106, link 80' is mounted to pin 82' as to allow lateral movement of pin 82' without corresponding movement to link 80'. Thus, carriage 106 can be laterally displaced without any bending moments applied to link 80'. Similarly, of a manual lock 70' is employed, the deadbolt 74' is so positioned below slide member 50' to allow relative displacement of slide member 50' with respect to deadbolt 74'. Thus, when vandals apply forces against lock bolt 30', and such forces are transmitted to slide member 50' via carriage 106, there is no resulting damage to either carriage 106 or slide member 50' due to the resilient mounting of carriage 106 via springS 122 mounte~ over bolts 124. A
similar carriage mounting of plunger 40 and lock bolt 30 can be employed in the embodiment of Figure 1.
The foregoing disclosure and description of the invention are illustrative and explanatory thereof, and various changes in the size, shape and materials, as well as in the details of the illustrated construction may be made without departing from the spirit of the invention.
. . .
TITLE: SLIDING DoaR LOCK
INVENTORS: EUGENE F. DAUGHERTY AND
C~ARLES E. HOLYCROSS
Field of the Invention The present invention relates to locks and secur~ty devices such as are used in prison security doors and the like. The disclosed lock assembly is particularly suited for use in a door locking system and may be operated remotely or locally adjacent to the door.
Bac~ of the Invention Penal institutions frequently house inmates in dormitory-like cells or rooms which open to a common hall or corridor. In a prison environment it is, of course, mandatory that access to the celIs by the inmates be controlled. It is desirable that such control be achieved either locall~ at each door or remotely from a secured central control room.
While previously known systems have attempted to provide such features, they have failed to achieve wide-spread acceptance due to a number of shortcomings such as technical complexity, functional inade~uacy and high cost. For example, light weight electric solenoid bolt control `devices have been previousIy proposed, such as the device disclosed in U.S. Patent No. 3,893,723, wherein a bolt was actuated by a slide member 10 which moved between upper and lower solenoids. The device was unsatisfactory for high security installations since it ~..
- ,' ' ' was easily damaged by any substantial force applied to the bolt in its extended position. Any such force created a bending force on the solenoids and typically resulted in severe damage or destruction of the locking mechanism.
The inmates' well known propensity for vandalism in penal institutions therefore rendered the device of this patent totally unsatisfactory for penal institution use.
Other penal door locking systems were not usable with conventional steel door jambs and door assemblies. The cost of custom door installations made such systems too expensive to be practical for use in government built penal institutions.
Other device~ such as that sho~m in U.S. P tent No.
1,946,384 have employed solenoid operated bolt members actuated by a pin and slot camming arrangement of complex construction suitable only for light duty in window sashes or the like.
U.S. Patent No. 4,099,752 disclosed a lock in which an actuating solenoid for the bolt was mounted so that its plunger had an axis o movement perpendicular to the axis of movement of the lock bolt. The lock bolt also included a detent switch which energized a solenoid to lock the bolt when the door was closed.
Therefore, it is the object of the present invention to provide a new and improved door locking system for penal or similar institutions that is secure and relatively inexpensive to install.
It is yet another object of the present invention to provide a new and improved door locking system that can be operable from a remote site and from a position adjacent the door.
5ummary of_the Invention The lock assembly L of the present invention is mounted in a lock frame. The lock assembly L includes slide member for actuating the lock mechanism disposed for translation within the lock frame by manual actuatiOn with a key or i.n response to a control signal. A lock bolt is pivotally mounted within the lock frame and extends through it for engagement with a door keeper in a door frame. A lock bolt detent is pivotally mounted to the slide member for maintaining the lock bolt in a secured position when the door is closed. Actuation of the slide member results in movement of the lock bolt detent away from the lock bolt followed by pivotal motion of the lock bolt as a pin on the slide member engages the lock bolt and lifts it clear of the door keeper. Once the lock bolt has been disengaged from the doar keeper, the door is sprung open by a spring loaded plunger which extends out of the lock frame.
Description of th~ Drawings Fig. l is a side elevational view of the lock lS assembly of the present invention with the lock bolt in the deadlocked position.
Fig. 2 is an end view of the invention taken along lines 2-2 of Fig. 1.
Fig. 3 is a side elevational view of the lock assembly of the present invention with the lock bolt in the open position as the door is being opened.
Fig. 4 is a side elevational view of the lock assembly of the present invention with the lock bolt in the open position as the door is being closed.
Fig. 5 is a sectional elevational view of an alternative embodiment of the lock assembly.
Fig. 6 is a detailed sectional elevational view of the alternative embodiment of the lock assembly shown in Fig. 5.
Detailed DescriPtion of the Preferred Embodiment As best seen in Fig. 1, the lock assembly L is built around a lock frame 10. The lock frame 10 is deSigned to be fitted into a door frame or wall (not shown) and attached thereto by well known means. The lock frame 10 interacts with door 12 which is schematically illustrated in Figs. l and 3. Door 1~ further includes a door keeper 14. The above-described arrangement can be reversed .
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without departing from the spirit of the invention. As can readily been seen, when the door is closed a lock bolt ~o travels over door keeper 14 and into receptacle 16, in the manner more fully described hereinbelow. In order to S protect against vandalism, lock frame 10 is fabricated from 3/16 inch thick plate 18, for example. Lock frame 10 is formed having several openings to accommodate various elements of the lock assembly. Opening 20 allows lock bolt 30 to project from within lock frame 10 for engagement with door kèeper 14. Opening 22 allows plunger 40 to project from lock frame 10 and contact the door 12 when it is closed.
Mounted with1n lock frame 10 are: a slids member 50;
lock bolt 30; a lock bolt detent means D; a disabling means G and a drive means R. The function and operation of each of these elements is described in more detail hereinbelow.
Slide member 50 is mounted to lock frame 10 in a manner which allows slide member 50 to translate in a direction parallel to the longitudinal axis of lock assembly L. To facilitate such translation, slide member 50 has a plurality of mounting slots 52 (see Figs. 1 and 3). Each slot 52 has a bolt 54 extending therethrough and which is threaded into or otherwise secured to lock frame 10 (see Fig. 2). Slide member 50 further includes a lower flange 56 which is disposed in a plane perpendicular to the remainder of slide member 50 for operative engagement by drive means R (Fig. 2).
Drive means R includes a mechanical lock 70 which may be actuated by an attendant standing near the door.
Mechanical lock 70 includes a lock cylinder 72 which when rotated through the use of a key forces a deadbolt 74 to extend from the mechanical lock 70 and bear on flange 56 of slide member 50. In this manner slide member 50 is displaced vertically in response to keyed operation of lock 70 in order to open the door. Reversed rotation of a key in lock cylinder 72 results in the retraction of r deadbolt 74 back into mechanical lock 70. As a result, slide member ~0 drops down vertically due to its own w~ight. The manual mechanical lock 70 is of a type known in the art such as that currently manufactu~ed by 50uthern Steel Company of San Antonio, Texas under Mod01 No. 1010.
A~ illustrated in Fig. 1, slide member 50 i9 in the locked position. As illustrated in Fig. 3, slide member 50 is in the unlocked position. While the illustrated embodiment relies upon the weight of slide member 50 to return it from the unlocked to the locked position, it sh~uld be understood that the lock assembly of the present invention may also include a biasing means, such as a spring or the like, to positivelv bias slide member 50 from the unlocked to the locked position.
Referring now to Fig. 2, lock bolt 30 is pivotally mounted to lock frame 10 and extends through opening 20 out of lock frame 10. A hook shaped segment 32 of lock bolt 30 extends from lock frame 10 to engage door keeper 14 when the door is closed. Lock bolt 30 is pivotally mounted to lock frame 10 on pin 34 (see Fig. 2). In order to facilitate engagement between hook shaped segment 32 and door keeper 14, lock bolt 30 further includes a leading beveled edge 36. As the door is pushed from the open to the closed position, leading beveled edge 36 first contacts the door keeper 14 thereby pivoting lock bolt 30 around pin 34. As shown in Fig. 1, lock bolt 30 is in the secured position. As shown in Fig. 3, due to the interaction between leading beveled edge 36 and door keeper 14, lock bolt 30 has been rotated from the secured position toward the open position. Fig. 4 shows the lock bolt in the fully open position. Upon further movement of the door 12 toward the door frame leading beveled edge 36 is moved further into door keeper 14 and as a result, spring 38 biases lock bolt 30 toward the secured position.
The action of spring 38 results in engagement between the hook shaped segment 32 and the door keeper 14, thereby locking the door. It should be noted that lock bolt 30 .
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can be designed with su~ficient weight in the hook shaped segment 32 so that spring 38 would not be necessary and lock bolt 30 wlll, by gravity, rotate counterclockwlse toward the secured position after the le~ding beveled edge 36 has passed into door keeper 14. However, spring ~8 ~s a desirable featl~re and is specifically included in specifications for locks by penal institutions in the United States.
It is desirable, that the design of the lock assemblies for penal institutions prevent inmates from using tools to rotate the lock bolt 30 from the secured position shown in Fig. 1 to the open position shown in Fig~ 3 when the Aoor is closed. In order t~ prevent rotation of lock bolt 30 ~hen the door is closed, lock bolt detent means D engages detent tang 39 when the door is closed. Lock bolt detent means D comprises a generally L-shaped pivotally mounted link 60. Link 60 is pivotally connected to slide member 50 via pin 61 (see Fig. 2).
Link 60 includes a horizontal component 62 and a vertical component 64. As shown in Fig. 1, the horizontal component 62 further includes an engagement means E to prevent rotation of lock bolt 30 about pin 34 when the door is closed and locked. In the illustrated embodiment, means E comprises a depression 66 adapted to engage detent tang 39 to prevent the lock bolt 30 from rotating about pin 34 when the door is closed and locked. It should be noted that alternative designs of the engagement means E
of the horizontal component 62 of link 60 may be used without departing from the spirit of the invention. For example, the horizontal component 62 may have a slot therethrough or may in other ways interfere with the rotation of lock bolt 30 when the lock bolt is in the secured position.
As previously stated, the slide member S0 may be manually actuated by mechanical lock 70. However, drive means R also includes an alternative method of ~ctuating slide member S0 from a secured remote location such as a ., , ;
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central control room for pxison guards. Drive means R
includes a motor 76 operably connected to eccentric cam 78 through gearing or other methods known in the art.
Eccentric cam 78 is connected through a linkage formed by the connecticn of rigid link 80 to slide member 50 via pin 82 (see Fig. 2). Pin ~2 extends through a slot 84 in link 80. As can readily be seen from Fig. 2, the purpose of slot 84 is to allow actuation of slide member 50 via mechanical lock 70 without interfering with or effecting link 80.
When slide member 50 is raised via operation of motor 76 or mechanical lock 70, and the door is closed, pin 61 which is fixed to slide member 50 causes the horizontal component 62 of l1nk 60 to rise. Pin 61 thus forms a part of disabling means G, as will be more fully described hereinbelow. As slide member 50 initially moves from the locked to the unlocked position, the vertical translation of pin 61 disengages depression 66 from detent tang 39.
In this position, lock bolt 30 is free to rotate about pin 34. As slide member 50 is raised further, pin 58 engages lock bolt 30 to initiate its rotation about pin 34. It should be noted that at the time pin 58 contacts lock bolt 30, the depression 66 on horizontal component 62 of link 60 has already begun to move away from detent tang 39.
Therefore, further vertical movement of slide member 50 from the locked to the unlocked position causes lock bolt 30 to pivot until hooked shaped segment 32 is in the position shown in Fig. 3 allowing it to be withdrawn from the door keeper 14. In the preferred embodiment, a slight initial movement of slide 50, i.e. 5/32", moves depression 66 away from detent tang 39. Further movement of slide 50, i.e. 7/16", moves lock bolt 30 to the open poSition.
The details of disabling means G are illustrated in Fig. 3. When lock bolt 30 is raised to the open position, disabling means G acts to force the door open by withdrawing hook shaped segment 32 from door keeper 14 and forcing the door to slide open. A plunger 40 is guifled 6:2 within lock frame 10 by guides 42 and 44. Nut 45 attached to plunger 40 acts as a travel stop when it contacts guide 42. Plunger 40 serves to spring the door open as loc~
bolt 30 is pivoted from the secured to the open position via the action of a biasing means B secured to plunger 40.
Biasing means B includes release spring 46 and return spring 47. The vertical component 64 of pivotally mounted link 60 is operably connected to plunger 40. As best seen in Fig. 2, the vertical component 64 is U-shaped with plunger 40 passing through it. Release spring 46 is mounted over plunger 40 and is secured to guide 42 on one end and pin 48 extending from plunger 40 at the other end.
Return spring 47 is secured to plunger 40 vi~ ~in 49 at one end. The opposite end of return spring 47 bears against vertical component 64 by pressing against washer 41. Washer 41 is not essential and it should be understood that return spring 47 may bear directly again~t vertical component 64 without departing from the spirit of the invention.
When the door is closed and slide member 50 is actuated to raise lock bolt 30 from the secured to the open position (Fig. 3), biasing means B causes plunger 40 which bears against door 12 to force the door open as soon as hook shaped segment 32 has been positioned to be retracted from door keeper 14. Release spring 46 acting against pin 48 propels plunger 40 outwardly against door 12 thereby sliding the door open. In the preferred embodiment, release spring 46 has a higher spring rate or exerts more force per inch of compression than spring 47 so that as long as the door remains open (Fig. 4) release spring 46 overcomes the opposite force exerted by return spring 47. It should also be noted that by reason of release spring 46 overcoming the opposing force produced by return spring 47, pivotally mounted link 60 is rotated counterclockwise to the position ~hown in Fi~. 4. As can readily be seen from Figs. 1 and 4, the pin 48 acting against washer 43 which bears against vertical component g 64 results in rotation of vertical component 64 about pin 61. Due to the higher spring rate o~ releas~ spring 46 as compared to return spring 47, as long as the door remains open, the pivotally mounted link 60 remains in the position shown in Fig. 4. In the preferred embodiment, pivotally mounted link 6C is forced to rotate approximately 10 to 15, although other degrees of rotation may be used without departing from the spirit of the invention.
As previously mentioned, rotation of link 60 results in depression 66 moving away from detent tang 39. It is necessary to maintain depression 66 away from detent tang 39 while the door is open so that lock bolt 3p is free to pivot ahout pin 34 as long as the door is left open (Fig.
4). This feature is desirable so that the door may automatically lock when slammed shut. By way of further explanation, whether slide member 50 is actuated to move from the locked to the unlocked position via motor 76 or mechanical lock 70, slide member 50 moves in one complete cycle from locked to unlocked and back to the locked position. In motor driven embodiments, a limit switch 90 is provided which causes motor 76 to be actuated through one complete revolution whenever the guard at a remote location actuates motor 76. A second limit switch, not shown can be used to stop the motor 76 after half a revolution thereby keeping the lock in the unlocked position as long as desired. As motor 76 completes one revolution, slide member 50 will move in one smooth motion from the locked to the unlocked and back to the locked position. Similarly, when the lock assembly L is operated via a mechanical lock 70, the guard may use a key to extend deadbolt 74 to open the door and then withdraw the key thereby retracting deadbolt 74 back into mechanical lock 70 after the door has sprung open. Thus, after the door has been pushed open due to the action of plunger 40 biased by release spring 46, the components within lock frame 10 come to rest in the position sho~n in Fig. 4, 36;~
with link 60 defl~cted 10 to 15 countexclockwise from its position in Yig. 1 and retained in that position due to the spring rat~ of release spring ~6 exceeding the spring rate o~ return spring 47.
When it is desired to close the door 12, (~ig. 4), the door is sliA toward the door frame containing the lock assembly L. Since the llook shaped segment 32 of lock bolt 30 extends from lock frame 10 further than plunger 40, initial contact is first made between leading beveled edge 36 and door keeper 1~. The net result is that lock bolt 30 is pivoted from the locked position toward the unlocked position in a clockwise direction until leading beveled edge 36 clears the door keeper 14 whereupon.spring 38 biases lock bolt 30 in a counterclockwise direction resulting in engagement of the hook shaped segment 32 within door keeper 14. Just as the leading beveled edge 36 clears the door keeper 14, plunger 40 contacts door 12.
Further inward movement of the doox 12 toward the door frame results in compression of release spring 46. In essence, release spring 46 is compressed by movement of pin 48 toward guide 42. As a result, return spring 47, which has previously been compressed when the door was opened, bears against washer 41 and causes pivotally mounted link 60 to rotate clockwise about pin 61 until link 60 is in the position shown in Fig. 1. Therefore, it is preferred that the extension of plunger 40 when the door is opened be preset such that rotation of link 60 commences with rotation of lock bolt 30 toward the secured position when leading beveled edge 36 clears door keeper 14. In that circumstance, as soon as lock bolt 30 has completed its travel from the open to the secured position, depression 66 formed in horizontal com~onent 62 is in position for engagement with detent tang 39. The net result ls that upon engagement of hook shaped segment 32 into door keeper 14, the interaction between depression 66 and detent tang 39 prevents rotation of lock bolt 30 out of the secured position.
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As shown in Fig. 1, plunger 40 is guided by guides 42 and 44 and further has spring forces from release spring 46 and return spring 47 acting on it. As indic~ted in Fig. 1, when the doGr is closed, the normal position for plunger 40 is in the deadlocked position. However, it is possible that inmates may attempt to vandal,ze plunger 40 by attaching foreign objects to door 12 with the intent of damaging lock assembly L by overtravel of plunger 40.
Alternatively, inmates may attempt to damage the lock by jamming lock bolt 30 in the locked position and slamming the door 12 into it. The lock assembly of the present invention compensates for such attempts at vandalism by providing freedom for plunger 40 to move into the overtravel position (see Fig. 1). Additionally, the lock bolt 30 can be resiliently mounted to frame 10 (Figs. 5 and 6). Accordingly, none of the internal components will be damaged if an inmate maliciously attaches a foreign object to door frame 12 at the point of contact with plunger 40. The indirect link between pivotally mounted 20 link 60 and plunger 40 also serves to prevent vandalism to the lock assembly L. As shown in Fig. 1, plunger 40 and link 60 are not rigidly connected. Instead, any force applied to plunger 40 as might occur in an inmate's attempt to damage the lock assembly will be transmitted to 25 release spring 46 and return spring 47 rather than directly to link 60.
K Due to the propensity of inmates to vandalize locks, it is desirable to be able to determine the position of lock bolt 30 from a remote location such as a control room 30 monitored by prison guards. To this end, pin 59 acting in conjunction with lock bolt limit switch 92 provide a signal to a remote location that the lock bolt ~0 is in the secured position. Similarly, pin 68 acting in conjunction with lock bolt detent limit switch 94 provide 35 a signal that pivotally mounted link 60 has achieved the position shown in Fig. l wherein it effectively precludes 8~6~
rotation of lock bolt 30 clockwise out of the secured position to the opened position.
An alternative embodiment is disclosed in Figs. 5 ar,d 6. The operation of this embod1ment is in many respects identical to the lock assembly as prèviously discussed in Figs~ 1 through 4. However, there are a few differences as will be discussed hereinbelow. The principal area of difference lies ln engagement means E'. As seen in Fig.
6, lock bolt 30' has a depression defined by surfaces 100, 102 and 104. As before, rigid link 80' is in contact with slide member 50' to urge slide member 50' to selectively move upwardly or downwardly. ~ suitably connected motor (not shown) can actuate rigid link 80'. Alt~rnatively, slide member 50' can be manually actuated with a key lock assembly 70' (Fig. 5).
It should be noted that link 60' is pivoted around pin 61'. Pin 61' is connected to carriage 106 which supports not only link 60' but also lock bolt 30' via pivot pin 34'.
Lock bolt 30' further includes an internal opening 108. Pin 110 extends from slide member 50' through carriage 106 and opening 108. Link 60' has a curved surface 112 thereon. Upward movement of slide 50' causes pin 110 to engage curved surface 112 thereby rotating link 60~ ~ clockwise about pin 61'. The clockwise rotation of link 60' moves engagement means E' which comprises of a tab 114. In the position as shown in Fig.
6, tab 114 is disposed over surface 116 of lock bolt 30'.
Thus, in the position shown in Fig. 6, engagement means E
is enabled thereby preventing lock bolt 30' from pivoting about pin 34' due to the interaction of tab 114 with surface 116. However, when pin 108 engages curve,d surface 112 as a result of upward movement of slide 50', link 60' is rotated clockwise along with tab 114. Thus tab 114 is juxtaposed against the depression defined by surfaces 100, 102 and 104 on lock bolt 30'. Subsequently, after pin 110 causes link 60' to rotate clockwise, further elevation of .
.
slide member 50' results in pin 110 raising lock bolt 30' by engagement with internal opening 108. It should be noted that clockwise displacement of link 60' results in compression of spring 47' as a result of tab 114 pressing against washer 120. As in the embodi~ents of Figs. 1-4, when lock bolt 30' clears the door keeper 14, spring 46' overcomes the fcrce of spring 47' and propels plunger 40' outwardly from lock assembly L'. Spring 46' acts against washer 43' which is retained by pin 48' to plunger 40'.
Thus, as long as the door remains opened, spring 46 overcomes the force of spring 47'thus retaining the engagement means in the disabled position wherein tab 114 is juxtaposed opposite the depression in lock bolt 30' as defined by surfaces 100, 102 and 104.
Since the lock bolt 30' extends further than plunger 40', upon closing the door, inclined surface 36' engages the door keeper 14 (See Fig. 1) whereupon lock bolt 30' is caused to rotate counterclockwise. The forward end of lock bolt 30' clears door keeper 14 and enters receptacle 16 (see Fig. l). Due to the extension of plunger 40' from lock assembly L, the engagement means E' remains disabled as the lock bolt 30' rotates counterclockwise and its leading edge enters receptacle 16 behind doorkeeper 14.
Further movement of the door causes plunger 40' to engage the door with a resultant inward displacement of plunger 40' into lock assembly L'. This inward displacement causes spring 46' to be compressed as a result of pin 48' pushing against washer 43'. Simultaneously, forces acting to compress spring 47' are relieved thereby causing washer 120 to displace tab 114. Displacement of tab 114 results in counterclockwise rotation of link 60' to the position shown in Fig. 6. Thus, when the door is fully cl,osed, tab 114 will be in the position shown in Fig. 6. The door will then be locked due to the lock bolt 30' being in position within receptacle 16 and engagement means E' being placed in the enabled position as a result of the forces exerted by spring 47' on tab 114. It should be _ l4 _ noted that no movement of slide member 50~ is necessary in order to close and lock the door. The door merely needs to be slammed shut.
Another beneficial feature of the invention is illustrated in Fig. 5. Carriage 106 support lock bolt 30' via pin 34'. Additionally, as shown in Fig. 6, plunger 40' is supported off of carriage 106 by extending through the carriage at a point marked 118 on one end and via support of a strut 120 at the opposite end. Carriage 106 is resiliently mounted to lock frame 10' through the use of a plurality of springs 122 straddling bolts 124 or any other equivalent means.
Thus, as seen in Fig. 5, if an inmate attempts to vandalize the lock assembly L of the present invention by somehow mannually holding lock bolt 30' in the deadlock position shown in Fig. 6 and slamming the door shut against it, springs 122 provide sufficient resiliency in the mounting of the lock bolt 30' to the lock assembly L' to avoid doing damage to the lock bold 30'. Thus slamming the door against lock bolt 30' in the deadlock position merely results in displacement of carriage 106 which is guided by bolts 124. Springs 122 resist forces applied to lock bolt 30' and keep carriage 106 abutting lock frame 10'. In order to allow for lateral movement of carriage 106, link 80' is mounted to pin 82' as to allow lateral movement of pin 82' without corresponding movement to link 80'. Thus, carriage 106 can be laterally displaced without any bending moments applied to link 80'. Similarly, of a manual lock 70' is employed, the deadbolt 74' is so positioned below slide member 50' to allow relative displacement of slide member 50' with respect to deadbolt 74'. Thus, when vandals apply forces against lock bolt 30', and such forces are transmitted to slide member 50' via carriage 106, there is no resulting damage to either carriage 106 or slide member 50' due to the resilient mounting of carriage 106 via springS 122 mounte~ over bolts 124. A
similar carriage mounting of plunger 40 and lock bolt 30 can be employed in the embodiment of Figure 1.
The foregoing disclosure and description of the invention are illustrative and explanatory thereof, and various changes in the size, shape and materials, as well as in the details of the illustrated construction may be made without departing from the spirit of the invention.
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Claims (24)
1. A lock assembly for use with a door assembly that includes a door frame, a door keeper, and a sliding door movably mounted in the door frame, comprising:
a lock frame supported by the door assembly, positioned to about the door keeper when the sliding door is closed and positioned away from the door keeper when the sliding door is opened;
a slide member mounted within the lock frame between a first "locked" position and a second "locked"
position;
a lock bolt mounted within the lock frame and positioned to travel with the slide member between "locked"
and "unlocked" positions, the lock bolt including connecting means partially extending from the lock frame for forming a connection with the door keeper that locks the door when the slide member is in the first "locked" position, and the slide member disengages the connecting means and door keeper when the slide member moves to a second, "unlocked" position;
lock bolt detent means for preventing movement of the lock bolt to the "unlocked" position when the slide member is in the first "locked" position;
disabling means for spacing the lock bolt and the detent means a part responsive to movement of the slide member from the first "locked" position to the second "unlocked" position, and means for holding the detent means in a spaced position from the lock bolt and independently of slide member travel so that the door can slam lock when said lock bolt engages the door keeper.
a lock frame supported by the door assembly, positioned to about the door keeper when the sliding door is closed and positioned away from the door keeper when the sliding door is opened;
a slide member mounted within the lock frame between a first "locked" position and a second "locked"
position;
a lock bolt mounted within the lock frame and positioned to travel with the slide member between "locked"
and "unlocked" positions, the lock bolt including connecting means partially extending from the lock frame for forming a connection with the door keeper that locks the door when the slide member is in the first "locked" position, and the slide member disengages the connecting means and door keeper when the slide member moves to a second, "unlocked" position;
lock bolt detent means for preventing movement of the lock bolt to the "unlocked" position when the slide member is in the first "locked" position;
disabling means for spacing the lock bolt and the detent means a part responsive to movement of the slide member from the first "locked" position to the second "unlocked" position, and means for holding the detent means in a spaced position from the lock bolt and independently of slide member travel so that the door can slam lock when said lock bolt engages the door keeper.
2. The lock assembly of claim 1 wherein:
said lock bolt detent means is pivotally mounted to said slide member.
said lock bolt detent means is pivotally mounted to said slide member.
3. The lock assembly of claim 2 wherein:
said lock bolt member is pivotally mounted within said lock frame.
said lock bolt member is pivotally mounted within said lock frame.
4. The lock assembly of claim 1 wherein:
said lock bolt member is further formed having a depression thereon;
said lock bolt detent means is a pivotally mounted link having an engagement means thereon for selectively allowing said lock bolt member to pivot;
whereupon initial movement of said slide member causes movement of said link disabling said engagement means by aligning said engagement means adjacent said depression on said lock bolt member.
said lock bolt member is further formed having a depression thereon;
said lock bolt detent means is a pivotally mounted link having an engagement means thereon for selectively allowing said lock bolt member to pivot;
whereupon initial movement of said slide member causes movement of said link disabling said engagement means by aligning said engagement means adjacent said depression on said lock bolt member.
5. The lock assembly of claim 4 wherein:
said slide member further includes a pin positioned on said slide member to engage said lock bolt member after said engagement means on said pivotally mounted link has been disabled as a result of initial slide member movement from said locked to said unlocked position.
said slide member further includes a pin positioned on said slide member to engage said lock bolt member after said engagement means on said pivotally mounted link has been disabled as a result of initial slide member movement from said locked to said unlocked position.
6. The lock assembly of claim 5 wherein said portion of said lock bolt member extending from said lock frame further comprises:
a hook shaped segment for engaging a door keeper;
and said pin on said slide member selectively pivots said lock bolt member to allow the hook shaped segment of said lock bolt member to be withdrawn and inserted into the door keeper.
a hook shaped segment for engaging a door keeper;
and said pin on said slide member selectively pivots said lock bolt member to allow the hook shaped segment of said lock bolt member to be withdrawn and inserted into the door keeper.
7. The lock assembly of claim 6 wherein said lock bolt member further comprises:
a leading beveled edge in said hook shape segment, said leading beveled edge engaging the door keeper as the door is closed thereby forcing said lock bolt member to pivot toward the open position and allowing said hook shaped segment of said lock bolt member to enter the door keeper and pivot toward said secured positioned.
a leading beveled edge in said hook shape segment, said leading beveled edge engaging the door keeper as the door is closed thereby forcing said lock bolt member to pivot toward the open position and allowing said hook shaped segment of said lock bolt member to enter the door keeper and pivot toward said secured positioned.
8. The lock assembly of claim 7 wherein said disabling means comprises in part:
a slidably mounted plunger mounted transversely to said lock frame and adapted to partially extend therefrom, said plunger adapted to bear against the door when the door is closed; and said pivotally mounted link is operably connected to said plunger so that the link can pivot when the plunger slides with respect to the housing.
a slidably mounted plunger mounted transversely to said lock frame and adapted to partially extend therefrom, said plunger adapted to bear against the door when the door is closed; and said pivotally mounted link is operably connected to said plunger so that the link can pivot when the plunger slides with respect to the housing.
9. The lock assembly of claim 8 wherein:
said lock bolt and said plunger are mounted on a common carriage;
said carriage is resiliently mounted to said lock frame.
said lock bolt and said plunger are mounted on a common carriage;
said carriage is resiliently mounted to said lock frame.
10. The lock assembly of claim 8 further including:
biasing means operably connected to said plunger for selectively enabling and disabling said engagement means on said link as said plunger moves into and out of contact with the door.
biasing means operably connected to said plunger for selectively enabling and disabling said engagement means on said link as said plunger moves into and out of contact with the door.
11. The lock assembly of claim 10 wherein:
said biasing means further comprises a release spring, biasing said plunger from said lock frame when said slide member is moved from said locked to said unlocked position and said pin thereon pivots said hook shaped segment of said lock bolt member into said open position, whereupon said plunger pushes the door open.
said biasing means further comprises a release spring, biasing said plunger from said lock frame when said slide member is moved from said locked to said unlocked position and said pin thereon pivots said hook shaped segment of said lock bolt member into said open position, whereupon said plunger pushes the door open.
12. A lock assembly for use with a door assembly that includes a door frame, a sliding door movably mounted in the door frame, and a door keeper, comprising:
a lock frame supported by the door assembly, positioned to abut the door keeper when the sliding door is closed, and positioned away from the door keeper when the sliding door is opened;
a slide member movably mounted within the lock frame between a first lower and a second higher position along a generally vertical path;
a horizontally extending lock bolt mounted within the lock frame and having means, partially extending therefrom for engaging the door keeper to lock the door, the lock bolt being positioned to engage the slide member for movement therewith between "locked" and unlocked" positions corresponding respectively to the first and second portions of the slide member;
lock bolt detent means, mounted upon the slide member for travel therewith, for maintaining the lock bolt in the locked position when the slide member is in the first position;
means for disabling the lock bolt detent means, responsive to movement of the slide member from the first lower position toward the second upper position thereby allowing the door to open; and the disabling means including holding means for keeping the detent means and lock bolt in spaced apart positions and independently of slide member movement after the sliding door is opened.
a lock frame supported by the door assembly, positioned to abut the door keeper when the sliding door is closed, and positioned away from the door keeper when the sliding door is opened;
a slide member movably mounted within the lock frame between a first lower and a second higher position along a generally vertical path;
a horizontally extending lock bolt mounted within the lock frame and having means, partially extending therefrom for engaging the door keeper to lock the door, the lock bolt being positioned to engage the slide member for movement therewith between "locked" and unlocked" positions corresponding respectively to the first and second portions of the slide member;
lock bolt detent means, mounted upon the slide member for travel therewith, for maintaining the lock bolt in the locked position when the slide member is in the first position;
means for disabling the lock bolt detent means, responsive to movement of the slide member from the first lower position toward the second upper position thereby allowing the door to open; and the disabling means including holding means for keeping the detent means and lock bolt in spaced apart positions and independently of slide member movement after the sliding door is opened.
13. A locking assembly for locking a door assembly that includes a door frame, a lock keeper, and a sliding door movably mounted in the door frame and with respect to the lock keeper, comprising:
a lock housing mounted on the door assembly in a position spaced from the lock keeper so that the lock keeper and lock housing can move relative to each other when the sliding door opens and closes;
a key-operated drive member movably mounted within the housing between first and second positions;
a lock bolt movably mounted upon the housing for movement independently of the drive member but positioned to travel with the drive member at least when the drive member moves from the first to the second position, which moves the lock bolt from a "locked" position to an "unlocked" position;
the lock bolt including means extending from the lock housing for perfecting a tensile connection with lock keeper that prevents opening of the sliding door;
powered plunger means for thrusting the door open when the lock bolt opens;
detent means carried by the drive member for preventing movement of the lock bolt when the drive member is in the first position; and disabling means for holding the detent means in a position spaced from the lock bolt when the sliding door and lock keeper are disengaged so that the lock bolt is free to move between "locked" and "unlocked" position when the sliding door is open and comprising in part a member that forms a connection with the powered plunger means.
a lock housing mounted on the door assembly in a position spaced from the lock keeper so that the lock keeper and lock housing can move relative to each other when the sliding door opens and closes;
a key-operated drive member movably mounted within the housing between first and second positions;
a lock bolt movably mounted upon the housing for movement independently of the drive member but positioned to travel with the drive member at least when the drive member moves from the first to the second position, which moves the lock bolt from a "locked" position to an "unlocked" position;
the lock bolt including means extending from the lock housing for perfecting a tensile connection with lock keeper that prevents opening of the sliding door;
powered plunger means for thrusting the door open when the lock bolt opens;
detent means carried by the drive member for preventing movement of the lock bolt when the drive member is in the first position; and disabling means for holding the detent means in a position spaced from the lock bolt when the sliding door and lock keeper are disengaged so that the lock bolt is free to move between "locked" and "unlocked" position when the sliding door is open and comprising in part a member that forms a connection with the powered plunger means.
14. The lock assembly of claim 12 or 13 wherein:
said beveled edge of said lock bolt member extends further out of said lock frame than said plunger when the door is open; and whereupon closure of the door, said beveled edge engages the door keeper and pivots said lock bolt member from said secured toward said open position, whereupon when said leading beveled edge has cleared the door keeper, said hook shaped segment has moved into said secured position before said plunger is moved inwardly into said lock frame to enable said engagement means.
said beveled edge of said lock bolt member extends further out of said lock frame than said plunger when the door is open; and whereupon closure of the door, said beveled edge engages the door keeper and pivots said lock bolt member from said secured toward said open position, whereupon when said leading beveled edge has cleared the door keeper, said hook shaped segment has moved into said secured position before said plunger is moved inwardly into said lock frame to enable said engagement means.
15. The lock assembly of claim 14 wherein the weight of said hook shaped segment of said lock bolt member is sufficient to pivot said lock bolt so that said hook shaped segment falls into engagement with the door keeper after said beveled edge enters the door keeper.
16. The lock assembly of claim 15 further including:
biasing means mounted to said lock frame for urging said hook shaped segment of said lock bolt member toward said secured position after said beveled edge enters and clears the door keeper.
biasing means mounted to said lock frame for urging said hook shaped segment of said lock bolt member toward said secured position after said beveled edge enters and clears the door keeper.
17. The lock assembly of claim 16 further comprising:
drive means within said lock frame for actuating movement of said slide member between said locked and said unlocked positions, thereby allowing the door to be opened.
drive means within said lock frame for actuating movement of said slide member between said locked and said unlocked positions, thereby allowing the door to be opened.
18. The lock assembly of claim 17 wherein said drive means further comprises:
a motor;
an eccentric cam driven by said motor;
a linkage comprising a rigid link formed having a slot thereon connecting said cam to said slide member; and whereupon revolution of the motor said slide member is driven from said locked position to said unlocked position, whereupon said plunger pushes the door open.
a motor;
an eccentric cam driven by said motor;
a linkage comprising a rigid link formed having a slot thereon connecting said cam to said slide member; and whereupon revolution of the motor said slide member is driven from said locked position to said unlocked position, whereupon said plunger pushes the door open.
19. The lock assembly of claim 18 further including:
a motor limit switch to selectively stop said motor after said motor has made said slide member cycle from said locked position to said unlocked position and to selectively stop said motor after movement of the slide member back to said locked position.
a motor limit switch to selectively stop said motor after said motor has made said slide member cycle from said locked position to said unlocked position and to selectively stop said motor after movement of the slide member back to said locked position.
20. The lock assembly of claim 19 wherein said motor is actuable from a location remote from the door.
21. The lock assembly of claim 18 wherein said drive means further includes:
a lock cylinder mounted in said lock frame;
a dead bolt driven by said lock cylinder for movement of said slide member from said locked to said unlocked position; and said deadbolt selectively moving said slide member without moving said rigid link due to said slot therein, thereby allowing the lock assembly to be either remotely actuated or locally actuated.
a lock cylinder mounted in said lock frame;
a dead bolt driven by said lock cylinder for movement of said slide member from said locked to said unlocked position; and said deadbolt selectively moving said slide member without moving said rigid link due to said slot therein, thereby allowing the lock assembly to be either remotely actuated or locally actuated.
22. The lock assembly of claim 21 further including:
a lock bolt limit switch mounted in said lock frame for remotely signaling the position of said lock bolt as being in said secured position; and an engagement means switch for remotely signaling the enablement of said engagement means.
a lock bolt limit switch mounted in said lock frame for remotely signaling the position of said lock bolt as being in said secured position; and an engagement means switch for remotely signaling the enablement of said engagement means.
23. The lock assembly of claim 22 further including:
a guide for said plunger, said guide defining the maximum outward movement of said plunger when the door is opened and said plunger is outwardly driven by said release spring;
said plunger adapted for displacement to a deadlocked position through said guide when the door is closed and one end of said plunger extends from the lock frame into contact with the door; and said plunger adapted for further displacement into said lock frame beyond said deadlocked position into an over travel position.
a guide for said plunger, said guide defining the maximum outward movement of said plunger when the door is opened and said plunger is outwardly driven by said release spring;
said plunger adapted for displacement to a deadlocked position through said guide when the door is closed and one end of said plunger extends from the lock frame into contact with the door; and said plunger adapted for further displacement into said lock frame beyond said deadlocked position into an over travel position.
24. The lock assembly of claim 23 wherein:
said lock bolt and said plunger are mounted on a common carriage;
said carriage is resiliently mounted to said lock frame.
8634b DND July 8, 1987
said lock bolt and said plunger are mounted on a common carriage;
said carriage is resiliently mounted to said lock frame.
8634b DND July 8, 1987
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA000541764A CA1298862C (en) | 1987-07-10 | 1987-07-10 | Sliding door lock |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CA000541764A CA1298862C (en) | 1987-07-10 | 1987-07-10 | Sliding door lock |
Publications (1)
Publication Number | Publication Date |
---|---|
CA1298862C true CA1298862C (en) | 1992-04-14 |
Family
ID=4136062
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA000541764A Expired - Lifetime CA1298862C (en) | 1987-07-10 | 1987-07-10 | Sliding door lock |
Country Status (1)
Country | Link |
---|---|
CA (1) | CA1298862C (en) |
-
1987
- 1987-07-10 CA CA000541764A patent/CA1298862C/en not_active Expired - Lifetime
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Date | Code | Title | Description |
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MKEX | Expiry |