Information
-
Patent Grant
-
6374650
-
Patent Number
6,374,650
-
Date Filed
Thursday, October 7, 199925 years ago
-
Date Issued
Tuesday, April 23, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Lerner, David, Littenberg, Krumholz & Mentlik, LLP
-
CPC
-
US Classifications
Field of Search
US
- 010 129
- 010 131
- 010 142
- 010 102
- 010 134
- 292 140
- 292 DIG 41
-
International Classifications
-
Abstract
The invention is concerned with a lock mechanism of the kind having a deadbolt (9) which is operable by either an inside actuator or an outside actuator. The inside actuator usually includes a turn knob or the like, and the outside actuator usually includes a key operated lock. The lock mechanism includes a gear train (8) through which each of the two actuators is drivably connected to the deadbolt (9). The gear train includes two drive gears (13, 14) which are independently rotatable about a common axis of rotation, and each is connected to a respective one of the two actuators so as to rotate in response to operation of that actuator. The gear train (8) also includes two driven gear (17, 18) which are united to form a single piece composite gear (16), and each driven gear (17, 18) is cooperable with a respective one of the two drive gears (13, 14). The composite gear (16) is connected to the deadbolt (9) so that the deadbolt (9) moves between operative and inoperative positions in response to rotation of the composite gear (16). Each actuator adopts a rest position when the deadbolt (9) is in the inoperative position, and neither drive gear (13, 14) cooperatively engages with the composite gear (16) when the respective actuator is in the rest position. Furthermore, the gear arrangement is such that the outside actuator turns through 360° to cause the deadbolt (9) to move from one of its positions to the other, whereas 180° rotation of the inside actuator is sufficient to effect the same degree of deadbolt movement
Description
FIELD OF THE INVENTION
This invention relates to lock mechanisms of the kind used with deadbolt assemblies intended to secure a movable member, such as a door, in a closed position at which it prevents access to a space at one side (usually the inside) of the door or other member. It will be convenient to hereinafter describe the invention with particular reference to doors, but it is to be understood that the invention has wider application.
BACKGROUND OF THE INVENTION
Deadbolt assemblies of the foregoing kind generally have two rotatable actuators which are operable at the inside and the outside of the door respectively. The outside actuator is usually in the form of a key operated lock, whereas the inside actuator usually includes a manually operable turn knob. It is desirable that the key operated lock at the outside of the assembly be arranged to turn through 360° in moving the deadbolt between operative and inoperative positions. The inside actuator however, may require less movement (e.g., 180° rotation) to achieve the same result, and the lock mechanism needs to permit the different movement requirements of the two actuators.
Various means have been adopted to address the foregoing problem. One lock mechanism which has proven to be particularly satisfactory is that disclosed by Australian Patent 601098, but that mechanism is relatively complicated. The prior mechanism is expensive to manufacture because it requires a large number of parts and is difficult to assemble by automatic means.
It is an object of the present invention to provide a deadbolt lock mechanism of relatively simple form which requires a minimum number of parts and which is relatively easy to assemble.
SUMMARY OF THE INVENTION
A lock mechanism in accordance with the present invention is characterised in that it includes a gear train through which each of the two actuators is drivably connected to the deadbolt. The gear train includes two drive gears which are rotatable independent of one another, at least to some extent, and each of which is adapted to be caused to rotate by a respective one of each of the two actuators. Each of the two drive gears is cooperable with a composite gear which also forms part of the gear train and which is drivably connected to the deadbolt so as to move the deadbolt between its operative and inoperative positions.
The arrangement is preferably such that the composite gear rotates through 180° in moving the deadbolt between its operative and inoperative conditions, and such 180° movement occurs regardless of which of the two actuators is operated. In particular, the 180° composite gear movement occurs when driven by the drive gear connected to the outside actuator even though that drive gear may rotate through 360°.
In a preferred arrangement, the composite gear includes two gears interconnected for simultaneous rotation about a common axis. The two gears may be formed integral or otherwise secured together for that purpose. It is further preferred that a drive member, such as a pin, is connected to the composite gear and cooperates with the deadbolt in a manner such that the deadbolt moves linearly in response to rotation of the composite gear.
The gear train and the deadbolt may be housed within a hollow casing, and in one arrangement it is preferred that the deadbolt cooperates with the casing so as to be guided along a straight path when moving between the operative and inoperative positions. The gear train is preferably arranged to be loaded, in sub-assembly form, into the casing through an open side of the casing. The loading operation can be performed automatically and has the effect of placing the composite gear in drivable engagement with the deadbolt. A removable cover plate may be attached to the casing to extend over the aforementioned open side and thereby retain the gear train in place.
Reference to “gear” throughout this specification is to be understood as embracing a rotatable member having teeth extending around part only of its periphery. That is, the word “gear” embraces any rotatable member having a gear-like function during at least part of a complete revolution of movement of that member about its axis of rotation.
BRIEF DESCRIPTION OF THE DRAWINGS
Embodiments of the invention are described in detail in the following passages of the specification which refer to the accompanying drawings. The drawings, however, are merely illustrative of how the-invention might be put into effect, so that the specific form and arrangement of the various features as shown is not to be understood as limiting on the invention.
In the drawings:
FIG. 1
is a perspective view of an example deadbolt assembly to which the invention can be applied.
FIG. 2
is an exploded view of the assembly shown by FIG.
1
.
FIG. 3
is a perspective view of a gear train sub-assembly according to one embodiment of the invention.
FIG. 4
is a plan view of a lock mechanism in accordance with one embodiment of invention which incorporates the sub-assembly of FIG.
3
.
FIG. 5
is a cross-sectional view taken along line V—V of FIG.
4
.
FIG. 6
is an exploded view of the lock mechanism of FIGS.
4
and
5
.
DETAILED DESCRIPTION
FIG. 1
of the accompanying drawings shows one form of deadbolt assembly
1
to which the invention is applicable. The assembly
1
is shown secured to a door
2
and adapted to cooperate with a strike
3
secured to a door jamb
4
. A turn knob
5
is rotatably mounted on a housing
6
and forms an inside actuator of the assembly
1
.
FIG. 2
is an exploded view of the arrangement shown by FIG.
1
and shows a key operated lock
7
which forms an outside actuator of the assembly
1
. It is to be understood that the arrangement shown by
FIGS. 1 and 2
is an example only and that the invention can be applied to other deadbolt arrangements. Also, the inside and outside actuators need not be of the type shown by
FIGS. 1 and 2
.
A lock mechanism sub-assembly according to one embodiment of the invention is shown by FIG.
3
. That sub-assembly includes a gear train
8
and a deadbolt
9
of the kind used in the arrangement of
FIGS. 1 and 2
. The deadbolt
9
includes a plate
10
and two cylindrical locking members
11
, each of which is connected to the plate
10
through a respective connecting bar
12
. Such deadbolts are well known. The invention is applicable to other types of deadbolts.
The gear train
8
includes two drive gears
13
and
14
arranged for rotation about a common axis
15
, and each of those gears is capable of rotation relative to the other as hereinafter explained. The gear train
8
also includes a composite gear
16
which is cooperatively engageable with each of the drive gears
13
and
14
and includes two driven gear members
17
and
18
interconnected for rotation about a common axis
19
. It is preferred that the two gear members
17
and
18
are formed integral.
In the particular arrangement shown, each of the drive gears
13
and
14
and each of the driven gear members
17
and
18
is a partial gear in that it does not have a single series of gear teeth extending completely around its circumference. As will be evident from
FIG. 4
, the drive gear
13
has two groups of gear teeth which are arranged in diametrically opposed relationship and which are separated by spaces
20
and
21
. The drive gear
14
has a single group of teeth which extends partway around the periphery of the gear so that a gap exists between the opposite ends of that group of teeth. Each of the driven gear members
17
and
18
also has a single group of teeth extending partway around its periphery, and a blank or non-toothed section
22
and
23
respectively extends between the opposite ends of each of those groups of teeth. It is to be appreciated that arrangements other than that shown by
FIG. 4
could be adopted.
As best seen by
FIGS. 4 and 5
, both the deadbolt
9
and the gear train
8
are located within a hollow casing
6
. The casing
6
and deadbolt
9
cooperate in a manner such that the deadbolt
9
is guided for linear movement between its operative and inoperative positions. The gear train
8
is loaded, in subassembly form, into the casing
6
by way of an open side
24
of the casing. The gear train
8
, or part thereof, may be loaded into the casing
6
while attached to a cover plate
25
which closes the open side
24
of the casing
6
and which can be releasably secured to the casing
6
so as to thereby retain the gear train
8
in place.
A drive connection is made between the gear train
8
and the deadbolt
9
, and that preferably occurs during the process of loading the gear train
8
into the casing
6
. In the particular arrangement shown, the drive connection includes a pin
26
secured to the composite gear
16
at a location radially outwards of the axis of rotation of the composite gear
16
, and a cooperable recess
27
formed in the deadbolt plate
10
. As best seen in
FIG. 5
, the pin
26
projects beyond a face of the gear member
17
so as to locate within the recess
27
, and as best seen in
FIG. 4
the recess
27
is preferably in the form of a straight slot, which extends longitudinally in a direction transverse to the direction of movement of the deadbolt
9
.
In a completed form of the assembly
1
, the key operated lock
7
is drivably connected to the drive gear
14
and the turn knob
5
is mounted within the opening
28
(
FIGS. 4 and 5
) of the casing
6
so as to be drivably connected with the drive gear
13
. Each of the two drivable connections may be of a known kind. For example, as shown by
FIG. 2
, the key operator lock
7
may be connected to the gear
14
through a non-circular drive bar
29
which locates within a substantially complementary passage
30
formed in the gear
14
. A similar type of connection may be provided between the turn knob
5
and the gear
13
.
As will be evident from
FIG. 4
, neither of the drive gears
13
and
14
cooperatively engages with the composite gear
16
when the respective drive gear
13
or
14
has the rotational position shown by FIG.
4
. The relevant position of rotation of each of the gears
13
and
14
corresponds to a rest position of the respective actuator
5
or
7
, and also corresponds to the inoperative position of the deadbolt
9
.
When the turn knob
5
is rotated so as to move the gear
13
anti-clockwise from the position shown by
FIG. 4
, an end tooth
31
of the gear
13
engages against an abutment
32
at one end of the blank section
22
of the gear member
17
. Because of that engagement the gear member
17
is moved clockwise thereby swinging the drive pin
26
through an arc such that it presses against the upper side of the slot
27
. Because of the cooperation between the pin
26
and the slot
27
the deadbolt plate
10
is moved upwards so as to cause the deadbolt
9
to adopt the operative position. The teeth of the gear
13
and the gear member
17
respectively intermesh in the course of that movement, but those teeth become disengaged after approximately 180° rotation of the gear
13
because of the space
20
provided in the periphery of that gear. It will be apparent that reverse rotation of the gear
13
through 180° will restore the deadbolt
9
to the inoperative position as shown by FIG.
4
.
If the key operated lock
7
is operated instead of the turn knob
5
, anti-clockwise rotation of the drive gear
14
causes an end tooth
33
of that gear to engage an abutment
34
at one end of the blank section
23
of the driven gear member
18
. As will be apparent from
FIG. 4
, there will be some delay before that engagement occurs and the teeth of the gear
14
and the gear member
18
respectively cooperatively mesh following that engagement. Because of the aforementioned delay and the different diameters of the gear
14
and the gear member
18
respectively, the gear member
18
rotates through 180° in response to 360° rotation of the gear
14
. Movement of the deadbolt
9
occurs as in the case of operation of the turn knob
5
because the gear members
17
and
18
rotate in unison. That is, the pin
27
is swung through an arc of 180° regardless of whether the turn knob
5
or the key operated lock
7
is used to drive the composite gear
16
.
In either mode of operation as described above (i.e., turn knob operation or key operated lock operation), rotation of either gear
13
or
14
does not cause rotation of the other gear
14
or
13
respectively. That is in spite of the fact that the two gear members
17
and
18
rotate in unison. As will be apparent from
FIG. 4
, the gear member
18
can move through 180° without causing rotation of the gear
14
. Similarly, the gear member
17
can move through 180° without causing rotation of the gear
13
. It is relevant in that regard that rotation of the composite gear
16
is limited to 180° in both modes of operation.
Furthermore, regardless of whether the turn knob
5
or the key operated lock
7
is used to move the deadbolt
9
, the direction of rotation of the turn knob
5
or the lock
7
must be the reverse of that described above in order to transfer the deadbolt
9
from the operative position to the inoperative position.
FIG. 6
is an exploded view of the lock mechanism previously described. A mounting plate
35
as shown in that figure may be used to hold the gear
13
and the composite gear
16
in correct radial relationship and may form part of the sub-assembly initially loaded within the casing
6
.
It will be apparent from the foregoing description that a lock mechanism according to the present invention provides a very simple and effective means of operating a deadbolt. The mechanism involves use of a minimum number of parts and can be assembled by automatic means.
Various alterations, modifications and/or additions may be introduced into the constructions and arrangements of parts previously described without departing from the spirit or ambit of the invention as defined by the appended claims.
Claims
- 1. A lock mechanism including, a deadbolt which is movable between an operative position and an inoperative position, first and second independently operable rotatable actuators, a gear train through which each said actuator is drivably connected to said deadbolt and which includes first and second drive gears and first and second driven gears, said first and second drive gears being arranged for relative rotation about a common axis and being drivably connected to said first and second actuators respectively, said driven gears forming respective parts of a rotatable composite gear, said first and second drive gears cooperating with said first and said second driven gears respectively so that said composite gear rotates in response to rotation of either said drive gear, drive means drivably connecting said composite gear to said deadbolt so that the deadbolt moves between said operative and inoperative positions in response to rotation of said composite gear, and said first and second drive gears cooperate with their respective driven gears in a manner such that said deadbolt moves from one said position to the other in response to 360° rotation of said first actuator and moves from one said position to the other in response to substantially less than 360° rotation of said second actuator.
- 2. A lock mechanism according to claim 1, wherein said deadbolt moves from one said position to the other in response to 180° rotation of said second actuator.
- 3. A lock mechanism according to claim 1, wherein said first and second drive gears are formed integral with one another.
- 4. A lock mechanism according to claim 1, wherein each said actuator is in a rest position when said deadbolt is in said inoperative position, and neither said drive gear cooperatively engages with its respective driven gear when the respective said actuator is in said rest position.
- 5. A lock mechanism according to claim 1, wherein said first drive gear is a partial gear having a series of gear teeth extending around part only of the circumference thereof.
- 6. A lock mechanism according to claim 1, wherein said second drive gear is a partial gear having two series of gear teeth which are spaced apart around the circumference of the gear and each of which extends around a respective part of said circumference.
- 7. A lock mechanism according to claim 1, wherein each said driven gear is a partial gear having a series of gear teeth extending around part only of the circumference thereof and having a non-toothed portion extending around the remainder of said circumference.
- 8. A lock mechanism according to claim 1, wherein said drive means includes a drive pin connected to said composite gear at a location radially outwards of the axis of rotation of said composite gear, and said drive pin extends outwards from a surface of said composite gear in a direction substantially parallel to the axis of rotation of said composite gear and cooperatively engages with said deadbolt so as to cause linear movement of the deadbolt between said positions thereof in response to rotary movement of said composite gear.
- 9. A lock mechanism according to claim 8, wherein said drive pin is slidably located within a slot formed in said deadbolt and which extends longitudinally in a direction transverse to the direction of movement of said deadbolt between said positions thereof.
- 10. A lock mechanism according to claim 1, wherein each said actuator is connected directly to its respective said drive gear.
- 11. A lock mechanism according to claim 1, wherein said gear train is located within a hollow casing and forms part of a sub-assembly which is movable into and out of said casing through a side thereof.
- 12. A lock mechanism according to claim 11, wherein said gear train is connected to a mounting plate which also forms part of said sub-assembly and which retains said drive gears in correct radial relationship with said driven gears.
- 13. A lock mechanism according to claim 11, wherein said gear train is attached to a cover plate which is releasably connected to said casing so as to close said casing side and retain said gear train within the casing.
- 14. A lock mechanism according to any one of claims 11, wherein said deadbolt is located within said casing and is guided by that casing for linear movement between said operative and inoperative positions.
- 15. A lock mechanism comprising, a deadbolt movable between an operative position and an inoperative position, first and second independently operable rotatable actuators, a gear train through which each said actuator is drivably connected to said deadbolt, said gear train including first and second drive gears and first and second driven gears, said first and second drive gears arranged for relative rotation about a common axis and being drivably connected to said first and second actuators respectively so that each rotates in response to operation of a respective one of said actuators, said first and second driven gears forming respective parts of a rotatable composite gear, said first and second drive gears cooperating with said first and said second driven gears respectively so that said composite gear rotates in response to operation of either one of said actuators with consequent rotation of the drive gear connected to the operative actuator, drive means drivably connecting said composite gear to said deadbolt so that said deadbolt moves between said operative and inoperative positions in response to rotation of said composite gear, and said first and second drive gears cooperate with their respective driven gears in a manner such that said deadbolt moves from one said position to the other in response to 360° rotation of said first actuator and moves from one said position to the other in response to substantially less than 360° rotation of said second actuator.
- 16. The lock mechanism according to claim 15, wherein said first drive gear is a partial gear having a series of gear teeth extending around only part of the circumference thereof.
- 17. The lock mechanism according to claim 15, wherein each said driven gear is a partial gear having a series of gear teeth extending around only part of the circumference thereof and having a non-toothed portion extending around the remainder of said circumference.
- 18. The lock mechanism according to claim 15, wherein said drive means includes a drive pin connected to said composite gear at a location radially outwards of an axis of rotation of said composite gear, and said drive pin extending outwards from a surface of said composite gear in a direction substantially parallel to said axis of rotation of said composite gear and cooperatively engages with said deadbolt so as to cause linear movement of said deadbolt between said positions in response to rotary movement of said composite gear.
- 19. The lock mechanism according to claim 15, wherein said drive pin is slidably located within a slot formed in said deadbolt and which extends longitudinally in a direction transverse to the direction of movement of said deadbolt between said positions.
Priority Claims (1)
Number |
Date |
Country |
Kind |
P06042 |
Apr 1997 |
AU |
|
PCT Information
Filing Document |
Filing Date |
Country |
Kind |
PCT/AU98/00229 |
|
WO |
00 |
Publishing Document |
Publishing Date |
Country |
Kind |
WO98/45558 |
10/15/1998 |
WO |
A |
US Referenced Citations (4)
Foreign Referenced Citations (3)
Number |
Date |
Country |
0270425 |
Jun 1988 |
EP |
2551126 |
Mar 1985 |
FR |
2274306 |
Jul 1994 |
GB |