Information
-
Patent Grant
-
6595561
-
Patent Number
6,595,561
-
Date Filed
Tuesday, November 28, 200024 years ago
-
Date Issued
Tuesday, July 22, 200321 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Knight; Anthony
- Walsh; John B
Agents
-
CPC
-
US Classifications
Field of Search
US
- 292 202
- 292 207
- 292 209
- 292 330
- 292 336
- 292 34115
- 292 34116
- 292 34117
- 292 304
- 296 224
-
International Classifications
-
Abstract
The invention relates to a closure comprising a closing head (20) and a lock (10) which rest on the immobile or mobile part of a door, flap or such like. The closing head (20) has an undercut axial shoulder (26) which during coupling is engaged by a radially mobile blocking member (11) in the lock (10). The lock (10) further comprises a sensing member (12) and a restoring member (13) for the blocking member (11). To make the lock less prone to malfunctions the invention provides for the axially spring-loaded sensing member (12) to be used as a locking means for the radially spring-loaded blocking member (11). When the locking effect is actuated the blocking member (11) is held in a release position in relation to the closing head (20). When the closing head (20) is engaged the sensing member (12) carries out an axial movement which releases the lock so that the radial spring-loading can move the blocking member (11) into its blocked position. Actuation of the restoring member (13) results in a radial reverse movement of the blocking member (11), which activates the locking of the sensing member (12) and locks the blocking member (11) in its release position.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to a closure between the movable and the stationary part of a door, a flap or the like, especially for vehicles, such as a hinged rear window of a motor vehicle, comprising a lock on one, especially the stationary, part of the flap and with a closing head movable axially relative thereto on the other, especially the movable, part of the flap, wherein the closing head comprises an undercut axial shoulder for a radially movable locking member of the lock which is spring-mounted in a direction of its movement axis, and the locking member in the coupling situation of the closing head engages behind the axial shoulder and is then in a locked position, and the lock, in addition to the locking member, has an axially spring-mounted sensing member and a return member for the locking member, wherein the sensing member projects into the axial movement path of the closing head and is actuated by the closing head, while the return member moves the locking member into a release position relative to the closing head, in which the closing head can be decoupled.
2. Description of the Related Art
In the case of vehicles the closure can be used, for example, on the hinged rear window. The closure comprises a closing head and a lock which are coupled with one another upon closing the rear window. In the coupling situation, the spring-action locking member engages behind an axial shoulder of the closing head which characterizes the locked position of the closure. For decoupling the closing head, the locking member is transferred by a return member into a release position where the closing head can again be decoupled from the lock and the rear window can be transferred into the open position.
In the known closure, the closing head comprises on its free end portion a control surface which extends at a slant to the axial movement direction and has the task to push away the locking member against its spring force during coupling of the closing head. The locking member was subjected to axial loads. The pushing away action of the locking member by the closing head resulted in friction and thus in wear. After extended use disturbances caused by wear resulted which could be remedied only in a cumbersome way by after-adjustment. Moreover, the closure also had an axially spring-loaded sensing member which had the task to cooperate with a sensor. The sensor had the task to initiate further functions within the vehicle, for example, activation of the theft alarm. The sensing member therefore had its own function relative to the locking member. Both components had no functional connection with one another.
SUMMARY OF THE INVENTION
The invention has the object to develop an inexpensive, space-saving closure of the aforementioned kind which is characterized by high reliability and minimal failure liability. This is achieved according to the invention by the sensing member being a locking means for the locking member and the locking member being secured by it in a release position until the closing head is decoupled, wherein the axial movement of the sensing member resulting during coupling of the closing head releases the locking action so that the radial spring load transfers the locking member into its locking position, and wherein the radial return movement of the locking member resulting from actuation of the return member activates the locking action of the sensing member and locks the locking member in its release position.
According to the invention, the sensing member takes on the new function to realize a locking means for the locking member. As long as the closing head is decoupled, the sensing member blocks the release position of the locking member. This allows for a wear-free coupling and decoupling of the closing head without the locking member having to be moved by the closing head. The movement of the locking member occurs instead only when the full coupling position of the closing head in the lock is reached. This is realized automatically. Upon insertion, the closing head impacts on the sensing member which, because of its axial spring action, follows this axial movement of the closing head. The moved sensing member releases the locking action so that the locking member is transferred by its radial spring loading into its locking position in which it engages behind the closing head. The locking of the locking member by the sensing member occurs automatically again once the locking member is returned into its release position upon actuation of the return member. This establishes again the initial state.
BRIEF DESCRIPTION OF THE DRAWINGS
Further measures and advantages of the invention result from the further claims, the following description, and the drawings. In the drawings, the invention is illustrated by one embodiment. It is shown in:
FIG.
1
—in the coupling situation—a section of the lock of the closure according to the invention along the section line II—II of
FIG. 3
or
FIG. 4
;
FIG. 2
an axial section of the closing head belonging to the closure according to the invention, which is fastened on a hinged part, i.e., the rear window of a vehicle;
FIG. 3
a plan view onto the lock in the viewing direction III of
FIG. 1
;
FIG. 4
a plan view onto the lock which corresponds to that of
FIG. 3
but after the upper cover plate of the lock housing has been removed;
FIG. 5
a further section of the lock along a section line V—V, perpendicular to
FIG. 1
, of
FIG. 3
or
FIG. 4
after the closing head of the closure has been coupled; and
FIG. 6
in a section illustration corresponding to
FIG. 1
the coupling situation of the closing head in the lock according to
FIG. 5
, for which purpose the corresponding section line VI—VI has been indicated in FIG.
5
.
DESCRIPTION OF PREFERRED EMBODIMENTS
The closure
10
,
20
according to the invention is used in the embodiment for a hinged rear window
30
, which is illustrated in
FIG. 6
, of a motor vehicle. The rear window
30
is pivotable along the arc-shaped path illustrated at
31
in FIG.
6
. The closure is comprised of a lock
10
—relative to the rear window movement
31
which is arranged on the stationary part
40
of the motor vehicle, i.e., on the rear part
40
of the motor vehicle indicated in dashed lines in FIG.
6
. The closure further comprises a closing head
20
which is connected to the window
30
and is guided together with it along the hinged movement path
31
. In the last phase of the hinged movement
31
, the closing head
20
carries out the movement which is determined by the tangent according to arrow
32
of
FIG. 6
which, for a simpler description of the other movements, is referred to in the following as the “axial movement direction” or the “axial decoupling movement” of the closing head
20
. The drawing plane of
FIG. 6
is the plane of the pivot movement
31
of the window
30
with closing head
20
connected thereto.
The movable component
20
referred to as “closing head” can be formed in the shape of an axial projection with non-round radial profile. In the present situation this component
20
is, however, designed with radial symmetry to an axis
33
extending in the direction of movement
32
. The closing head
20
, as illustrated in
FIG. 2
, can be divided into four portions
21
to
24
. They include a forward end portion
21
which is conically shaped in this embodiment. The end portion
31
tapers toward the front end face
25
of the closing head
20
. The end face
25
is spherical. The conical end portion
21
provides a slanted control surface
27
which, because of the aforementioned radial-symmetrical embodiment of the closing head
20
, is provided on all sides.
A constriction
22
in the closing head
20
adjoins this end portion
31
and produces an undercut axial shoulder
26
at the transition to the end portion
21
. Behind the constriction
22
a cylindrical portion
23
is arranged which, in the direction toward the constriction, has a gliding slant
28
pointing in the movement direction
32
of the closing head
20
. This gliding slant
28
, because of the radial-symmetrical embodiment of the closing head
20
already mentioned several times, extends circumferentially about the closing head axis
33
.
At the opposite end of the closing head
20
an axial mounting pin
24
is provided which is fastened in a receptacle
34
of the rear window
30
. This attachment in the receptacle
34
is realized indirectly by a bushing
36
which is comprised of elastomer material
35
and has an integrated threaded sleeve
37
. The mounting pin
24
provided with an outer thread
44
can be screwed into the inner thread of this threaded sleeve
37
. The bushing
36
is seated in a window button
38
which is seated by means of a seal
43
in the window receptacle
34
. The window button
38
is supported by means of one flange surface on one side of the rear window
30
and is fastened on the window
30
by a securing ring
39
which is supported at the opposite window side. The attachment of the securing ring
39
is realized on the circumference of a hollow shaft of the window button
38
which receives the bushing
36
and which, with interposition of the seal
43
is seated in the window receptacle
34
.
The screw connection
37
,
44
of the closing head
20
makes it possible to precisely adjust the closing head
20
with respect to its axial length
42
, illustrated in
FIG. 2
, relative to the window
30
. For this purpose, the closing head
20
has a non-round plug receptacle
29
at its front end face
25
for a rotational tool
50
shown in FIG.
6
and to be described infra.
The lock
10
comprises, as can be seen best in
FIG. 4
, a locking member
11
, a sensing member
12
, a return member
13
, and a motoric actuator
14
for the return member
13
. These members
11
to
14
are positioned in the interior of a two-part housing
19
,
49
. The housing comprises, as best illustrated in
FIG. 1
, a housing half
19
which is closed by a housing cover
49
. The housing cover comprises a coupling opening
41
. This coupling opening
41
, as illustrated in the plan view of
FIG. 3
, is circular and, in particular, coaxial to the axis
33
illustrated also in
FIG. 1
which, as mentioned, determines the axial movement direction
32
of the closing head
20
. The coupling opening
41
is surrounded by a tubular guide
45
, illustrated in
FIGS. 1 and 3
, whose inner width is matched to the cross-section
46
of a cylindrical portion
23
of the closing head
20
. The cross-section
46
is somewhat greater than the maximum cross-section
47
of the conical end portion
21
of the closing head
20
, illustrated in FIG.
2
.
Upon insertion of the closing head
20
into the coupling opening
41
of the lock
10
in the direction of arrow
32
, an alignment movement relative to the lock
10
can already take place on the conical end portion
21
. The described slanted control surfaces
27
of the conical shape cooperate with the tubular projection
45
surrounding the coupling opening
41
. A centering of the closing head
20
is realized especially by the gliding slant
28
on the adjoining cylindrical portion
23
of the closing head
20
. The tubular projection
45
acts as a guide receptacle for the cylinder portion
23
and secures its coaxial position in the coupling situation that can be seen in FIG.
6
. The cylinder portion
23
rests with its circumference on the inner surface of the guide receptacle
45
of the housing
10
. The bushing
36
has a coaxial annular projection
48
which can be seen in FIG.
2
and which, in the coupling situation of
FIG. 6
, elastically surrounds the tubular projection
45
of the lock. In the coupling situation of
FIG. 6
, the interior of the lock is sealed at
45
,
48
relative to the surroundings against penetration of water and dirt.
The elastomer material
35
of the bushing
36
provides primarily a radially elastic securing action of the closing head
20
on the window
30
. After extended use of the vehicle, the hinge for the aforementioned pivot movement
31
of the window
30
can result in a change of the pivot movement path
31
as a result of wear. In order for the aforementioned radial alignment movement on the control surfaces
27
or the gliding slants
28
to take place during coupling, the mounting pin
24
of the closing head
20
should carry out an alignment movement in the bushing
36
which is illustrated by the radial double arrow
58
in FIG.
2
. This is so because the mounting pin
24
is radially elastically secured in the bushing
36
because of the resilience of the bushing material
35
.
The locking member
11
, as illustrated in
FIG. 4
, is formed as a two-arm lever
51
,
52
. This lever is seated on a pivot axle
53
which is positioned parallel to the axis
33
and which makes the lever arms
51
,
52
radially movable relative to the axis
33
. A two-legged locking spring
56
engages the locking member
11
and exerts onto the lever arm
51
a spring force which is illustrated by the arrow
54
in FIG.
4
. The lever arm
51
thus has substantially a spring action in the direction of the axis
33
. In the decoupling situation of the closing head
20
illustrated in
FIGS. 1 through 4
, however, the spring force
54
is not able to act because the lever arm
51
is secured by locking means
61
,
62
in the pivot position of FIG.
4
. This position is the “release position” of the locking member
11
.
This is possible because the sensing member
12
according to the invention acts as a locking means for the locking member
11
. The sensing member
12
is formed as a one-arm lever whose pivot axis
55
is positioned perpendicularly to the pivot axis
53
of the locking member
11
. While the sensing member
12
is pivotable in the plane of the drawing
FIG. 1
in the direction of the arrow
60
, the pivot movement of the locking member
11
, indicated by the arrow
57
in
FIG. 4
, is positioned perpendicularly thereto, i.e., in the drawing plane of FIG.
4
. This means that the sensing member
12
is axially pivotable, i.e., parallel to the axis
33
of
FIG. 1
, but the locking member
11
is radially pivotable relative to the axis
33
. The sensing member
12
is also spring-loaded, in particular, by a spring force illustrated by arrow
63
of
FIG. 1
which acts substantially axially. For this purpose, a pressure spring
64
is provided which is supported with one end on the bottom of the housing half
19
and with the other end on the sensing member
12
. The sensing member
12
is provided with a securing element embodied as a cam
62
which, as a result of the spring-load
63
of the sensing member
12
, as illustrated in
FIG. 1
, is spring-loaded in a direction toward the locking member
11
and, in its release position, engages a cutout
61
which is a counter securing element for the cam
62
. The cam
62
has a shoulder with which it contacts a counter shoulder
65
in the interior of the cutout
61
. In this release position of the locking member
11
, illustrated in
FIGS. 1 and 4
, the closing head
20
can be coupled in the direction of arrow
32
in the lock
10
or decoupled in the direction of the counter arrow
32
′ of FIG.
1
. However, in the last phase of the coupling movement
32
a release of the locking means
61
,
62
results for the following reasons.
Upon coupling
32
of the closing head
20
it impacts against the sensing member
12
. This results in an axial pivoting away in the direction of the aforementioned pivot movement arrow
60
of
FIG. 1
counter to the spring load
63
of the sensing member
12
. Accordingly, the cam
62
is pulled out of the cutout
61
in the locking member
11
. Now the locking member
11
is free and can be moved radially against the axis
33
in the direction of the force arrow
54
of
FIG. 4
acting on it in accordance with the arrow
57
shown there. This results, as is illustrated in
FIG. 5
, in the lever arm
51
moving into the constriction
22
of the closing head
20
. The lever arm
51
engages behind the axial shoulder
26
of the closing head
20
. The closing head
20
is secured in its coupling position in the lock
10
. The pivot position of the locking member
11
that can be seen in
FIGS. 5 and 6
is the “locked position”. A decoupling in the direction of the arrow
32
′ illustrated in
FIG. 6
is initially not possible. For this to happen, the aforementioned return member
13
must be activated which is realized here by a motoric actuator
14
.
As can be seen in
FIGS. 4 and 5
, the return member
13
is comprised of a control pin
15
which is seated on a worm wheel
16
. The worm wheel
16
is rotatably supported with its worm wheel axle
66
in the housing
19
,
49
and is subjected to the effect of a worm wheel spring
67
. With suitable rotational stops the worm wheel
16
is secured in the initial rotational position illustrated in
FIG. 4
where, when the release position of the locking member
11
is present, normally a radial spacing to the second arm
52
of the locking member
11
is realized. However, when the locking position of the locking member
11
, illustrated in
FIGS. 5 and 6
, is present where the first mentioned working arm
51
of the locking member
11
secures the coupling position of the closing head
20
, the second lever arm
52
has pivoted in a direction toward the control pin
15
. If needed, the control pin
15
can also serve as a stop for the pivot movement
57
of the locking member
11
. In
FIGS. 5 and 6
, the window
30
is closed.
In the closed position of the rear window
30
a theft alarm can be activated. The inquiry of the theft alarm can be realized by means of the microswitch
70
whose switching actuation is realized by a switch button
71
which is actuated by a switching leaf spring
72
or the like. This microswitch
70
cooperates with the second lever arm
52
of the locking member
11
which acts as a control arm. If it is desired to decouple the closing head
20
, the actuator
14
must be activated.
The actuator
14
for the return member
13
is comprised of an actuating member, i.e., a preferably electrically driven motor
18
with a worm
17
which engages the worm wheel
16
of the return member
13
. The actuator
14
also includes an actuating switch with suitable control electronics which is connected within the electrical circuit of the motor
18
. When the motor
18
is switched on, the worm wheel
16
is rotated by the worm about an angular spacing counter to the spring load
63
of the worm wheel spring
67
acting on the worm wheel
16
. This rotational movement is illustrated in
FIG. 4
by the rotational arrow
68
. In the final rotational position of the worm wheel
16
, the control pin
15
reaches the rotational position
15
′ illustrated in dash-dotted line in FIG.
4
. By entraining the control arm
52
, the locking member
11
is returned in the direction of arrow
57
′ of
FIG. 4
counter to the acting spring force
54
. The locking member
11
reaches thus the release position of FIG.
4
. Upon return pivot movement
57
′ of the working arm
51
, the cutout
61
provided thereat again reaches axial alignment with the cam
62
seated on the sensing member
12
so that these elements
61
,
62
again engage one another as illustrated in
FIGS. 1 and 4
. The engagement of the cam
62
in the cutout
61
functions like a snap connection. The sensing members
12
is pivoted back in the direction of arrow
60
′ of
FIG. 1
by its springload
63
. Accordingly, the sensing members
12
has activated the locking action for the locking member
11
in its release position. The closing head
20
can be decoupled in the direction of arrow
32
′ of FIG.
6
.
As soon as the control pin has reached its rotational end position
15
′, the actuator
14
is switched off. This can be carried out automatically via the automatic control. The motor
18
is no longer supplied with current. Now the rotational return force provided by the worm wheel spring
67
exerted in the direction of arrow
69
of
FIG. 4
is sufficient to return the worm wheel
16
again into its initial rotational position where the control pin is in the position shown in solid lines in FIG.
4
. The provided engagement between the worm wheel
16
and the worm
17
cannot prevent this rotational return movement
68
′; the engagement between
16
,
17
is not self-locking.
As can be seen in
FIGS. 1 and 4
, the sensing member
12
has a penetration
73
which is partially engaged by the closing head
20
with its front end
21
. The penetration
73
is comprised in the present situation of a slotted hole whose large slotted hole axis
74
expediently is aligned with the plane of the pivot movement
31
(see
FIG. 6
) of the window
30
. This plane of the pivot movement is identical to the section line II—II of FIG.
3
. Upon coupling, the closing head
20
is inserted to a partial height
75
of its conical front portion
21
as illustrated in FIG.
6
. The insertion depth is determined by the conical shape of the front portion
21
and by the small slotted hole width
76
, illustrated in
FIG. 3
, of the penetration
73
. The insertion of the closing head
20
into the penetrations
73
, illustrated in
FIGS. 5 and 6
, allows a reduction of the construction height of the closure housing
10
,
49
. The aforementioned orientation of the large slotted hole axis
74
takes into consideration the curvature of the pivot movement
31
illustrated in
FIG. 6
of the closing head
20
fastened on the window
30
. Its forward end
21
can be radially displaced within the slotted hole
73
in the last phase of the coupling action when contacting the sensing member
12
. Because the aforementioned pivot movement
60
,
60
′ of the sensing member
12
is carried out in the same plane of the hinged pivot movement, the slotted hole
73
also takes into consideration the corresponding radial displacement between the sensing member
12
and the front end of the closing head
21
resulting from pivoting
60
,
60
′.
The invention furthermore is characterized in that the closed position of the rear window
30
relative to the stationary rear part
40
of the motor vehicle can be adjusted very precisely. This adjustment can be realized in the coupling situation of the closing head
20
through the lock
10
. For this purpose, the housing half
19
of the lock
10
has a penetration
77
for a suitable rotational tool
50
. The penetration extends also through possible further lock members on the path to the closing head
20
. The slotted hole
73
provided in the sensing member
12
can also serve as a passage. With the tool
50
the axial spacing
42
, described above and illustrated in
FIG. 2
, of the end face
25
of the closing head
20
can be adjusted relative to the window
30
. The tool
50
has a plug-in end
59
whose contour profile matches the aforementioned receptacle
29
at the front end face
25
of the closing head
21
. By the illustrated plug connection of
FIG. 6
of the two connecting halves
29
,
59
, a torque can be exerted via the rotational tool
50
which results in a defined screwing of the closing head
20
in the threaded receptacle
37
of the bushing
36
.
List of Reference Numerals
10
first part of closure, lock
11
locking member, two-arm lever
12
sensing member, one-arm lever
13
return member for
11
14
actuator for
13
15
control pin of
13
(initial position)
15
′ rotational end position of
15
(
FIG. 4
16
worm wheel of
13
17
worm of
14
18
motor of
14
19
first part of housing, housing half
20
second part of closure, closing head
21
forward end portion of
20
, conical front end
22
constriction on
20
23
cylindrical portion of
20
24
axial mounting pin of
20
25
front end face of
20
26
axial shoulder on
21
27
slanted control surface on
21
28
gliding slant on
23
29
plug receptacle in
25
, first half of plug connection
30
hinged rear window
31
pivot movement path of
30
32
arrow of axial coupling movement of
20
in
10
32
′ counter arrow for the decoupling movement of
20
from
10
(
FIG. 1
)
33
axis of
20
34
receptacle in
30
for
24
35
elastomeric material of
36
36
bushing for
24
37
threaded sleeve in
36
, first part of screw connection of
20
relative to
30
38
window button on
30
39
securing ring for
38
40
stationary part of the motor vehicle, the rear part
41
coupling opening for
20
in
49
42
axial spacing between
25
and
30
43
seal between
38
,
34
44
outer thread on
24
, second part of the screw connection between
20
,
30
45
tubular projection, the guide receptacle on
41
46
cross-section of
23
47
maximum cross-section of
21
48
annular projection on
36
for
45
49
second part of housing on
10
, housing cover
50
rotational tool for
20
51
first lever arm of
11
, working arm
52
second lever arm on
11
, control arm
53
pivot axis on
11
54
arrows of spring force of
51
55
pivot axis of
12
56
locking member spring on
11
(
FIG. 4
)
57
arrow of pivot movement of
11
(
FIG. 4
)
58
arrow of alignment movement of
24
in
36
(
FIG. 2
)
59
plug on
50
, second half of a plug connection (
FIG. 6
)
60
arrow of pivot movement of
12
(
FIG. 1
)
60
′ counter arrow of return pivot movement of
12
(
FIG. 1
)
61
locking means, cutout in
11
for
62
, counter securing element
62
locking means, cam on
12
for
61
, securing element
63
arrow of spring-load of
12
(
FIG. 1
)
64
pressure spring for
12
65
counter shoulder of
61
for
62
66
worm wheel axle
67
worm wheel spring for
66
68
arrow of rotation of movement of
15
in
15
′
68
′ counter arrow of rotational return movement of
15
′ on
15
69
arrow of rotation or return force on
16
70
microswitch for
52
71
switch button on
70
72
switching leaf spring of
70
73
penetration in
12
for
20
, slotted hole
74
large slotted hole axis of
73
75
partial height of
21
(
FIG. 6
)
76
small slotted hole width of
73
77
penetration in
19
for
50
(
FIG. 6
)
Claims
- 1. A closure between a movable part and a stationary part of a door or a flap of vehicles,the closure comprising a lock (10) on the stationary part (40) or the moveable part and further comprising a closing head (20) configured to cooperate with the lock (10) and provided on the moveable part or the stationary part, respectively, and movable axially (32) relative to the lock (10), wherein the closing head (20) comprises an undercut axial shoulder (26) and the lock (10) comprises a radially movable (57, 57′) locking member (11) which is spring-mounted in a direction of a movement axis (33) of the locking member (11), wherein the locking member (11) in a coupling situation of the closing head (20) with the locking member (11) engages behind the axial shoulder (26) and is in a locked position, wherein the lock (10) further comprises an axially spring-mounted (63) sensing member (12) and a return member (13) acting on the locking member (11), wherein the sensing member (12) projects into an axial movement path (32) of the closing head (20) and is actuated by the closing head (20), wherein the return member (13) is configured to move the locking member (11) into a release position relative to the closing head (20), in which release position the closing head (20) is configured to be decoupled, wherein the sensing member (12) is a locking means for the locking member (11) and the locking member (11) is secured by the sensing member (12) in the release position until the closing head (20) is decoupled, wherein an axial movement (60) of the sensing member (12) resulting during coupling (32) of the closing head (20) releases a locking action (61, 62) so that a radial spring load (54) acting on the locking member (11) transfers the locking member (11) into the locked position, and wherein the radial return movement (57′) of the locking member (11) resulting from actuation of the return member (13) activates the locking action of the sensing member (12) and locks the locking member (11) in the release position; wherein the sensing member (12) and the locking member (11) are pivotably supported levers having a pivot movement direction (60, 60′; 57, 57′), respectively, wherein the pivot movement directions extend perpendicular to one another.
- 2. The closure according to claim 1, wherein the closing head (20) conically tapers toward a front end face (25) of the closing head (20)and wherein the sensing member (12) comprises a penetration (73) receiving a partial height (75) of the closing head (20) in the coupling situation.
- 3. The closure according to claim 2, wherein the penetration (73) is formed as a slotted hole (73) having a long slotted hole axis (74) positioned in a plane of a pivot movement (31) of the movable part (30).
- 4. The closure according to claim 1, wherein the closing head (20) comprises an axial mounting pin (24) fastened in a receptacle (34) of the moveable part or the stationary part correlated therewithand wherein the mounting pin (24) is secured in the receptacle in a radially elastic way (35, 58).
- 5. The closure according to claim 4, wherein the mounting pin (24) is supported in a bushing (36) comprised of elastomeric material (35)and wherein the bushing (36) is fastened in the receptacle (34).
- 6. The closure according to claim 1, wherein the closing head (20) is fastened by an axial screw connection (44, 37) on the moveable part or the stationary part correlated therewith,and wherein the lock (10) has a penetration (77) for a rotational tool (50) in order to, with the closing head (20) in the coupled position, be able to axially adjust a mounting position (42) of the closing head (20) on the moveable part or the stationary part.
- 7. The closure according to claim 6, wherein the penetration (77) in the lock (10) penetrates the lock housing (19) and all parts of the lock which are positioned in a path of the rotational tool (50) in the direction to the coupled closing head (20).
- 8. The closure according to claim 6, further comprising a plug connection comprising a first plug connection half (29) arranged on a front end face (25) of the closing head (20) and a complementary second plug connection half (59) arranged on the rotational tool (50),wherein the plug connection, in the insertion position of the first and second plug connection halves (29, 59), transmits onto the closing head (20) a torque exerted by the rotational tool (50), and the first plug connection half (29) is axially aligned with the penetration (77).
- 9. The closure according to claim 1, wherein the lock (10) has a housing with an axial guide receptacle (45) and wherein the closing head (20) has a cylindrical portion (23) received in the axial guide receptacle (45).
- 10. The closure according to claim 9, wherein, for centering the closing head (20) during insertion into the guide receptacle (45) of the lock, the cylindrical portion has a gliding slant (28) oriented in an axial movement direction (32) of the closing head (20).
- 11. The closure according to claim 9, wherein the axial guide receptacle (45) is tubular.
- 12. The closure according to claim 1, wherein the sensing member (12) comprises a securing element (62) and the locking member (11) comprises a counter securing element (61),wherein the securing element (62) and the counter securing element (61) are engaged with one another when the closing head (20) is decoupled and secure the locking member (11) counter to the radial spring load (54) in the release position, and wherein during coupling (32) of the closing head (20) the securing element (62) of the sensing member (12) axially moves at least to such an extent away from the locking member (11) until the securing element (62) leaves the counter securing element (61) and releases the locking member (11).
Priority Claims (1)
Number |
Date |
Country |
Kind |
198 28 289 |
Jun 1998 |
DE |
|
PCT Information
Filing Document |
Filing Date |
Country |
Kind |
PCT/EP99/03789 |
|
WO |
00 |
Publishing Document |
Publishing Date |
Country |
Kind |
WO99/67490 |
12/29/1999 |
WO |
A |
US Referenced Citations (12)
Foreign Referenced Citations (1)
Number |
Date |
Country |
0361679 |
Apr 1990 |
EP |