[0001] The present invention relates to a closure mechanism for members hinged to structures
as defined in the preamble of claim 1.
[0002] The closure mechanism defined in the preamble of claim 1 comprises more particularly
a first and a second part, each one of them substantially rigid and pivotally attachable
to one of the hinged member or structure, guided relative to each other in a linear
translational motion between a first and a second position and urged towards a first
position wherein the closure member is closed by a resilient element interposed between
them. The closure mechanism is of the type wherein the distance between the attachment
points of the first and the second parts to the hinged member and the structure varies
upon opening or closing of the hinged member not by a relative rotational motion of
both parts with respect to one another but by a translational motion.
[0003] Such linearly extendable and contractible closure mechanisms are generally known
in the art and are used especially for outdoor applications such as for garden gates
and doors. Usually, to avoid slamming, these closure mechanisms also comprise a hydraulic
damper. However, this solution has the drawback that such hydraulic components are
delicate and badly suited for outdoors use. They are more particularly quite sensitive
to temperature variations and are also often subjected to leakage problems.
[0004] US-A-4 872 239 tries to remedy these problems by converting the relative linear translational motion
of the first and second parts into a rotational motion and braking it by using a rotary
braking device instead of the previous hydraulic dampers. However, the rotary braking
device of this prior art is a friction brake of the type that generates a constant
braking torque, irrespective of the rotational speed of its input and thus of the
closing speed of the hinged closure member. Since the force generated by the resilient
element increases linearly with the displacement from said first position, following
Hooke's Law, and thus nearly linearly with the opening angle of the door, this has
the drawback that an element resilient enough to still overcome the braking torque
of the friction brake at small door opening angles may push the door too hard at large
door opening angles, and makes the door difficult to properly open especially for
children or older people. Furthermore, the hinged member will be accelerated during
the whole closing movement, reaching its peak speed just as it closes, potentially
leading to painful and dangerous injuries or material damage.
[0005] On the other hand, without an element resilient enough, the mechanism may stick,
especially in an outdoors environment with significant temperature changes, dirt,
rain, freezing weather and so on, leaving the door ajar, with potentially very negative
consequences in security- or safety-critical applications, such as doors of enclosures
of airports, swimming pools, etc.
US-A-4 872 239 tries to avoid these drawbacks by decoupling the friction brake at small opening
angles, which in turn generates additional problems, such as a lack of damping at
those small opening angles, without solving the problem of the hinged member's high
final closing speed.
[0006] An object of the present invention is therefore that of providing a closure mechanism
with a safe closing speed at and from all opening angles and a high degree of reliability,
even for outdoor applications.
[0007] To this end, the closure mechanism according to the invention is characterised in
that the rotary braking device is of the type that, when in use, brakes its input
element with a variable braking torque which increases and decreases with the rotational
speed of the input element of the rotary braking device, the rotary braking device
preferably comprising a centrifugal brake.
[0008] In the closure mechanism according to the invention, the braking torque of the closure
mechanism increases with the closing speed of the hinged member until braking torque
and driving force of the resilient element reach a state of equilibrium and the closing
speed stabilises. In this way, the invention ensures a safe closing speed at and from
all opening angles without compromising the closing performance.
[0009] In other types of closure mechanisms it has also been proposed to use centrifugal
brakes to provide a variable braking torque, for instance in
US-A-5 048 151 and in
US-A-4 912 806. These prior art mechanisms comprise also two parts which are respectively attached
to the hinged member and to the structure onto which the hinged member is mounted
but the two parts are pivotally connected to one another so that a varying distance
between their attachment points to the hinged member and the structure is obtained
by a relative rotational motion. One part is more particularly a lever arm so that
the rotation of the closure member is converted in a corresponding rotation of the
first gear wheel of the closure mechanism. In this way, when opening the closure member
over an angle of 90°, the first gear wheel of the closure mechanism is also rotated
only over a fraction of one rotation. A drawback of such mechanisms is that, since
compact centrifugal brakes are only effective at high rotational speeds (for example
above 1000 rpm), they need gear trains of considerable complexity to multiply the
rotational motion of the door hinge within a limited amount of space. This is in direct
conflict with the need to keep the mechanism compact. The closure mechanisms disclosed
in
US-A-5 048 151 and in
US-A-4 912 806 both use, in the last stage of their gear trains, a worm shaft to achieve the necessary
high speed-up ratio in a compact mechanism. Such worm shafts are, however, prone to
blocking under heavy load, and thus not advisable for security-or safety-critical
applications. This is especially the case for outdoor applications wherein the closure
mechanism is subjected to various temperature and humidity conditions and wherein
ice may even be formed within the mechanism.
[0010] British patent
GB 190002775 also proposed a centrifugal brake for a door check, however without such a high speed-up
ratio. Due to the low speed-up ratio or in other words due to the small centrifugal
force, it appears that this door check would not work satisfactorily, despite special
measures having been taken to try to achieve the required braking force. First of
all it is clear that the frictional coefficient between the braking pads (weighted
arms) and the braking surface has to be quite high to be able to produce the required
braking torque. In
GB 190002775 this is attempted by the use of leather. An essential feature of the door check disclosed
in
GB 190002775 is further that it comprises means for urging the braking pads away from the braking
surface. The braking pads are in particular mounted on pivots that are inclined so
that gravity tends to swing the braking pads away from the braking surface. It is
clear that adjusting the weight of the braking pads, the inclination of their pivots
and the frictional coefficient between the braking pads and the braking surface is
quite delicate to achieve the desired braking effect. Moreover, the door check may
become quite easily disordered when the frictional coefficient changes for example
due to wear or to varying weather conditions (humidity, ice formation, temperature
changes, etc.). It must also be noted that
GB 190002775 concerns a door check that merely brakes external forces acting on the door, not
a closure mechanism with a driving actuator.
[0011] In contrast to the mechanisms disclosed in
US-A-5 048 151, in
US-A-4 912 806 and in
GB 190002775, an important additional speed-up stage is already achieved in the closure mechanism
according to the present invention wherein the angular motion of the hinged member
is first converted into a translational motion between the two parts of the closure
mechanism, and then into a rotational motion of the rotary output element of the motion
converting means. In this way, a smaller speed-up ratio has to be provided between
this rotary output element and the rotary input element of the rotary braking device
whilst maintaining the reliability and advantages of a centrifugal brake. It is more
particularly possible to replace, in a closure mechanism as disclosed in
US-A-4 872 239 the disadvantageous friction brake by a centrifugal brake without having to add a
lot of additional gear wheels and in particular without having to use a worm wheel
transmission to keep the mechanism sufficiently compact.
[0012] Advantageously, the closure mechanism of the invention further comprises a transmission
gearing comprising one or more stages increasing the rotational speed between the
output element of the motion converting means and the input element of the rotary
braking device. Increasing the rotational speed and reducing the torque at the rotary
braking device, facilitates a progressive action of the rotary braking device while
keeping it light and compact.
[0013] Advantageously, the closure mechanism of the invention further comprises a one-way
clutch, preferably comprising a ratchet wheel, so as to enable rotation of said rotary
output element of the motion converting means without rotating said rotary input element
of the rotary braking device when the first part is moved towards the second position.
The advantage of such an embodiment of the invention is to enable the user to open
the hinged member without having to act against the rotary braking device of the closure
mechanism.
[0014] In a particularly advantageous embodiment, at least one speed-up stage of the transmission
gearing is placed between the one-way clutch and the input element of the rotary braking
device. The advantage of this embodiment is to reduce the rotational speed of the
one-way clutch so that it is less subjected to wear and produces less noise.
[0015] Also advantageously, the closure mechanism of the invention further comprises a torque
limiter, preferably comprising a friction clutch set to slip at a predetermined torque,
so as to limit the maximum torque transmitted between said rotary output element of
the motion converting means and said rotary input element of the rotary braking device.
The advantage of such an embodiment of the invention is to protect the closure mechanism
from overloading if external forces are exerted on the hinged member to close it.
[0016] In a particularly advantageous embodiment, the torque limiter is contained within
one gearwheel of the transmission gearing. This has the advantage of improved compactness.
[0017] In a particularly advantageous embodiment, at least one speed-up stage of the transmission
gearing is placed between the output element of the motion converting means and the
torque limiter. The advantage of such an embodiment is to reduce the torque at the
torque limiter, thus enabling the use of smaller, lighter torque limiter.
[0018] Advantageously, the motion converting means comprises a rack-and-pinion gear. This
has the advantage of cheapness and simplicity whilst being very reliable. Preferably,
the rack is formed on or attached to the first part.
[0019] Advantageously, the resilient element is a coil spring, which provides strength and
reliability.
[0020] Advantageously, the closure mechanism of the invention also comprises a pivot device
mounted on a base member of the first or second part for pivotally attaching said
first or second part to the hinged member or structure, the pivot device being mounted
so that it can rotate on the base member around a first axis substantially different
to a second axis on which it is pivotally attachable to the hinged member or structure,
the first axis being preferably substantially perpendicular to the second axis. In
this way, the closure mechanism adapts itself to various angles of attachment to the
hinged member or structure and is protected from potential damage resulting from misalignment
of the pivots.
[0021] The invention will be described in detail and non-limitingly with reference to the
accompanying figures, in which:
Figs. 1 and 2 represent a hinged door with a closure mechanism according to the invention;
Fig. 3 represents an embodiment of the closure mechanism according to the invention
during a normal closing operation in which the first part moves away from the second
part, i.e. towards its first position;
Fig. 4 is an exploded, perspective view of the one-way clutch of said embodiment;
Fig. 5 is an exploded, perspective view of the torque limiter of said embodiment;
Fig. 6 is an exploded, perspective view of a centrifugal brake of said embodiment;
Fig. 7 represents the same embodiment of the closure mechanism during an opening operation;
Figs. 8 and 9 are detail views of the one-way clutch of said embodiment, as the output
element of the motion converting means is rotated in opposite directions;
Fig. 10 represents the same embodiment during a closing operation accelerated by an
external force;
Fig. 11 is a detail view of the torque limiter during the same operation and
Fig. 12 is an exploded, perspective view of the pivot device of said embodiment.
[0022] Figs. 1 and 2 depict a closure member D, in this example a door leaf or garden gate,
hinged to a structure F, in this example a post. Between the door leaf D and the post
F, a compact closure mechanism C according to the invention, is installed which comprises
a first part 1 which is pivotally attached to the hinged door leaf D, and a second
part 2 which is pivotally attached to the door frame F. In Fig. 2 the door leaf D
and closure mechanism C are represented both in the open and closed position. When
the door is opened, the first part 1 and second part 2 move towards each other in
a relative translational motion. To close the door, the first part 1 and second part
2 are urged apart, thus pushing the door leaf D back towards the closed position wherein
the first part 1 is in its first or extended position with respect to the second part
2.
[0023] Referring now to Fig. 3, the closure mechanism C is illustrated more into detail.
The first part 1 comprises a sleeve 1' which is telescopically slidable over a corresponding
sleeve 2' of the second part 2, so as to guide the first part 1 between its first
position, wherein the door is closed, and a second position in a linear translational
motion relative to the second part 2. The closure mechanism C is mounted preferably
in such a manner on the closure member D and on the structure f that, when opening
the closure member D over an angle of 90°, the first part 1 moves over a distance
of at least 100 mm, preferably over a distance of at least 120 mm with respect to
the second part 2. In the example illustrated in the figures, the first part moves
over a distance of about 140 mm with respect to the second part. In addition to the
first 1 and the second part 2, the closure mechanism C also comprises means, including,
for example, a plastic sliding bearing 3, for holding the first part 1 and the second
part 2 together.
[0024] The closure mechanism C also comprises a resilient element 4 placed between the first
and second parts 1, 2 so as to urge the first part 1 in the direction 5 of the linear
translational motion towards its first position, i.e. towards the position wherein
the closure member is closed. In order to be able to control the closing speed, the
closure mechanism C further comprises a motion converting device 6 for converting
the linear translational motion of said first part 1 relative to said second part
2 into a rotational motion of an output element 6o of said converting means 6, and
a rotary braking device 7 which comprises an input element 7i coupled directly or
indirectly to the output element 6o of the motion converting device 6 and arranged
to be braked at least when the first part 1 moves towards its first position, i.e.
when the closure member is closed by means of the resilient element 4.
[0025] In the illustrated embodiment, the first part 1 comprises a base member 8, in the
form of a cylindrical rod, and a pivot device 9 which can pivot with respect to this
rod. The second part 2 has the form of a housing containing i.a. the motion converting
device 6 and the rotary braking device 7. The resilient element 4 is embodied in a
coil spring, which surrounds the base member 8 and is itself housed in the two telescoping
sleeves 1' and 2', so as to be guided therein and protected from the outside environment.
In the illustrated embodiment, the converting means 6 comprises a rack-and-pinion
gear, with the rack 10 formed on the base member 8 of the first part 1 and a 12-teeth
pinion 11 on the output element 6o of the motion converting means 6. When opening
the closure member over 90°, the rack is displaced over about 140 mm and the pinion
11 makes about 4 rotations. The motion converting means 6 could be of a different
type, such as a ball screw, but the depicted rack-and-pinion gear has the advantages
of cheapness, simplicity and reliability. There are also alternatives to the coil
spring as the resilient element 4, such as air and elastomeric springs, but the coil
spring also appears to be particularly advantageous for this invention.
[0026] In the illustrated embodiment, the rotary output element 6o of the motion converting
means 6 is coupled, in the depicted normal closing operation, to the input element
7i of the rotary braking device 7 through a transmission gearing 12 comprising three
stages increasing the rotational speed between the output element 6o of the motion
converting means 6 and the input element 7i of the rotary braking device 7. In the
depicted embodiment, the transmission gearing 12 is a gearwheel train.
[0027] A significant advantage of the invention is that, since it does not require a high
speed-up ratio between the output element 6o of the motion converting means 6 and
the input element 7i of the rotary braking device 7, it allows the use of a simple
transmission gearing 12, having at most four speed-up stages, and preferably at most
three, as in this example wherein the transmission gearing 12 comprises three speed-up
stages, each stage having individual speed-up ratios under 6 and preferably under
5 and gearwheels smaller than 8 cm in diameter, and preferably under 6 cm, so that
the mechanism can be kept quite compact. The total speed-up ratio of the transmission
gearing 12 can be less than 80, preferably less than 60. However, it would be advantageous
to have a speed-up ratio of more than 15, and preferably more than 25. As will appear
from the following description, the total speed-up ratio of the transmission gearing
illustrated in the figures is about 43.7.
[0028] In the depicted embodiment, a one way-clutch 13 is placed between the output element
6o of the motion converting means 6 and the transmission gearing 12. This one-way
clutch 13, as can be seen in Fig. 4, essentially consists in a ratchet-wheel 14 formed
on the inside of a first gearwheel 15 of the transmission gearing 12, and two pawls
16, resiliently mounted on the output element 6o of the motion converting means 6,
so as to engage with the ratchet wheel 14 only when the output element 6o rotates
in one direction.
[0029] Turning back to Fig. 3, the first gearwheel 15, having 40 teeth, engages a second
pinion (not illustrated but having 12 teeth), formed on the same axle as a second
gearwheel 17, which has 52 teeth and engages a third pinion 18 having 14 teeth.
[0030] In the depicted embodiment, this third pinion 18 is coupled to a torque limiter 19
in the form of a friction clutch interposed between the third pinion 18 and a third
gearwheel 20 (which has 46 teeth).
[0031] As can be seen in Fig. 5, the torque limiter 19 comprises a first friction disc 21,
mounted so as to rotate with the third pinion 18, and a second friction disc 22, mounted
so as to rotate with the third gearwheel 20. The first and second friction discs 21,
22 are pushed together by a clutch spring 23 with a force that can be calibrated with
a calibrating screw 24. The maximum torque of the torque limiter 19 will depend on
that force and the friction coefficient between the two friction discs 21, 22. In
the illustrated embodiment, one of the friction discs 21 or 22 is made of stainless
steel, whereas the other friction disc 21 or 22 is made of a friction material of
the type used in brake pads, so that the friction coefficient between the two friction
discs 21, 22 remains substantially constant, regardless of temperature or humidity.
A friction coefficient of at least 0.3 and preferably at least 0.35 allows the use
of a small clutch spring 23, thus contributing to the compactness of the closure mechanism
C. In the illustrated embodiment, the torque limiter 19 is contained within the third
gearwheel 20, in an arrangement particularly advantageous for the purpose of obtaining
a compact closure mechanism C.
[0032] Finally, the third gearwheel 20 engages a fourth pinion 25 (not illustrated in Fig.
3 but having 13 teeth) formed on the rotary input element 7i of the rotary braking
device 7. As can be seen in Fig. 6, the rotary braking device 7 of this embodiment
comprises essentially two braking pads 26 eccentrically hinged to the input element
7i of the rotary braking device 7, so as to be urged against a braking surface 27
(not illustrated in Fig. 6) surrounding them, with a centrifugal force proportional
to the square of the rotational speed of the input element 7i of the rotary braking
device 7.
[0033] Alternatives to the centrifugal brake of this embodiment, such as a rotary hydrodynamic
brake, can be considered, as long as they also generate a variable braking torque
which increases and decreases with the rotational speed of the input element 7i of
the rotary braking device 7.
[0034] Turning back to Fig. 3, during the normal closing operation, the first part 1 moves,
urged by the resilient element 4, in the direction 5 towards its first position in
which the hinged member D will be closed. The linear translational motion of the first
part 1 relative to the second part 2 is converted by the motion converting means 6
into a rotational motion of the output element 6o of said motion converting means
6. In the illustrated embodiment, an angular motion of 90° by the hinged member D
will be converted, through the linear translational motion of the first part 1 relative
to the second part 2 and the motion converting means 6, into about four full revolutions
of the output element 6o of said motion converting means 6. This rotational motion
is transmitted through the speed-up stages of the transmission gearing 12 to the input
element 7i of the rotary braking device 7. As the first part 1 is accelerated by the
driving force of the resilient element 7 towards the first position, the rotational
speed of the input element 7i of the rotary braking device 7 also increases. As the
rotational speed of the input element 7i increases, so will the braking torque generated
by the centrifugal brake in the rotary braking device 7, until it compensates the
driving force of the resilient element 4. As the braking torque balances out the driving
force of the resilient element 4, the first part 1 and therefore the hinged member
will cease to accelerate. A state of equilibrium will be reached in which the braking
torque and the driving force cancel each other until the first part 1 reaches first
position is reached and/or the hinged member closes. In practice, the closure member
may close in about 4 seconds. With the motion converting means 6 and the transmission
gearing 12 illustrated in the figures, this corresponds to a rotational speed of the
input element 7i of the centrifugal brake 7 of about 2600 rpm, thus enabling an effective
braking action even when the centrifugal brake 7 has limited dimensions (inner diameter
of the braking surface smaller than 7 cm and preferably smaller than 5 cm) to fit
in a compact closure mechanism.
[0035] Turning now to Figs. 7 to 9, the operation of this closure mechanism C during an
opening motion of the hinged member will be explained. Should the first part 1 remain
coupled to the rotary braking device 7 during this opening motion, a braking torque
would be generated which would add to the resistance of the resilient member 4 to
the opening motion. The one-way clutch 13 therefore has the purpose of letting the
output element 6o of the motion converting means 6 freewheel during this opening motion,
as depicted in Figs. 7 and 8, so that its rotational motion is not transmitted to
the gearwheel 15. On the other hand, during a closing motion, the pawls 16 engage
the ratchet wheel 14, and the one-way clutch 13 transmits the rotational motion of
the output element 6o to the gearwheel 15, as depicted in Fig. 9.
[0036] Coupling the one-way clutch 13 directly to the output element 6o of the motion converting
means has the advantage that, before the speed-up stages of the transmission gearing
12, the rotational speed is still moderate, and such one-way clutches perform more
reliably at moderate rotational speeds. Other arrangements of ratchet wheels, as well
as alternative types of one-way clutches, as known by the skilled person, could alternatively
be used.
[0037] Turning now to Figs. 10 and 11, the operation of this closure mechanism C during
an accelerated closing motion of the hinged member in which the driving force of the
resilient element 4 is significantly reinforced by external forces, such as those
exerted by a user, the wind, etc. will be illustrated. During such a motion, the braking
torque generated by the rotary braking device 7 and the rotational speed of the input
element 7i of the rotary braking device 7 could increase so much that the closure
mechanism could be overloaded and damaged. The torque limiter 19 therefore has the
purpose of limiting the maximum torque that can be transmitted between the motion
converting means 6 and the rotary braking device 7 in such a situation to prevent
an overload. As can be seen in Figs. 10 and 11, if the maximum torque is reached,
the friction discs 21, 22 will slip. Placing the torque limiter 19 behind one or several
speed-up stages of the transmission gearing 12, as in this embodiment, has the advantage
that there the torques are lower, so that the torque limiter 19 does not need to be
dimensioned for heavy loads.
[0038] Turning now to Fig. 12, the pivot device 9 of the first part 1 is illustrated in
detail. The pivot device 9 is mounted on the base member 8, i.e. onto the rod, so
that it can rotate on said base member 8 around a first axis 28 perpendicular to a
second axis 29 on which the pivot device 9 is pivotally attached to the hinged member
D. In this case the first axis 28 is the axis of the linear translational motion of
the first part 1 relative to the second part 2. The purpose of the rotational mounting
of the pivot device 9 is to enable the closure mechanism C to be adapted to various
angles of attachment to the hinged member D or structure F, while ensuring that the
rack-and-pinion motion converting means 6 is not submitted to damaging torsion loads.
[0039] For this purpose, the cylindrical rod forming the first part 1 comprises a circumferential
notch 30 near the end of the first part distal to the second part 2. The pivot device
9 in turn comprises at least one pin 31, preferably two, slotting into said circumferential
notch 30 so as to restrain the pivot device 9 axially, while allowing its rotation
around base member 8.
[0040] Although the present invention has been described with reference to specific exemplary
embodiments, it will be evident that various modifications and changes may be made
to these embodiments without departing from the broader scope of the invention as
set forth in the claims. Accordingly, the description and drawings are to be regarded
in an illustrative sense rather than a restrictive sense.
[0041] It is for example possible to amend the illustrated embodiment in such a manner that
it can be mounted on the hinged closure member and on the structure in a same way
as in
US-A-4 872 239, i.e. in such a manner that the closure mechanism is in its extended state when the
closure member is open and in its retracted state when the closure member is closed.
1. A closure mechanism (C) for a member (D) hinged to a structure (F), comprising
- a first part (1), substantially rigid and pivotally attachable to one of said hinged
member (D) or structure (F);
- a second part (2), substantially rigid and pivotally attachable to the other one
of said hinged member (D) or structure (F), the first part (1) and the second part
(2) being assembled to each other so that said first part (1) is guided in a translational
motion relative to the second part (2) between a first and a second position;
- a resilient element (4) placed between said first and second parts (1, 2) so as
to urge the first part (1) towards said first position;
- a motion converting means (6), comprising a rotary output element (6o), for converting
the translational motion of said first part (1) relative to said second part (2) into
a rotational motion of said rotary output element (6o); and
- a rotary braking device (7) comprising a rotary input element (7i) directly or indirectly
coupled to said rotary output element (6o) at least during movement of the first part
(1) towards said first position, so as to be rotated thereby;
the closure mechanism (C) being
characterised in that the rotary braking device (7) is of the type that, when in operation, brakes its
rotary input element (7i) with a variable braking torque which increases and decreases
with the rotational speed of said rotary input element (7i).
2. A closure mechanism (C) according to claim 1, wherein the rotary braking device (7)
comprises a centrifugal brake, so as to generate said variable braking torque.
3. A closure mechanism (C) according to claim 1 or 2, further comprising a speed increasing
transmission gearing (12) interposed between the rotary output element (6o) of the
motion converting means (6) and the rotary input element (7i) of the rotary braking
device (7), which transmission gearing (12) comprises one or more speed-increasing
stages increasing the rotational speed between the output element (6o) of the motion
converting means (6) and the input element (7i) of the rotary braking means (7).
4. A closure mechanism (C) according to claim 3, wherein said transmission gearing (12)
comprises at most 4, preferably at most 3 speed-increasing stages.
5. A closure mechanism (C) according to claims 3 or 4, wherein each speed-increasing
stage of the transmission gearing (12) has a speed-up ratio of less than 6, preferably
less than 5.
6. A closure mechanism (C) according to any one of the claims 3 to 5, wherein the transmission
gearing (12) is a gear wheel train composed of gear wheels (15,17,20), all of which
have an outer diameter of less than 8 cm, preferably less than 6 cm.
7. A closure mechanism (C) according to any of claims 3 to 6, wherein the speed-up ratio
between the output element (6o) of the motion converting means (6) and the input element
(7i) of the rotary braking device (7) is less than 80 and preferably less than 60.
8. A closure mechanism (C) according to any of claims 3 to 7, wherein the speed-up ratio
between the output element (6o) of the motion converting means (6) and the input element
(7i) of the rotary braking device (7) is more than 15 and preferably more than 25.
9. A closure mechanism (C) according to any of the claims 3 to 8, further comprising
a one-way clutch (13), preferably comprising a ratchet wheel (14), which one-way clutch
(13) is interposed between the rotary output element (6o) of the motion converting
means (6) and the rotary input element (7i) of the rotary braking device (7) to enable
rotation of said rotary output element (6o) without rotating said rotary input element
(7i) when the first part (1) is moved towards the second position, at least one speed-increasing
stage of said speed-increasing transmission gearing (12) being placed between the
one-way clutch (13) and the input element (7i) of the rotary braking device (7).
10. A closure mechanism (C) according to any of claims 3 to 9, further comprising a torque
limiter (19) interposed between the rotary output element (6o) of the motion converting
means (6) and the rotary input element (7i) of the rotary braking device (7), so as
to limit the maximum torque transmitted between said rotary output element (6o) and
said rotary input element (7i), which torque limiter (19) preferably comprises a friction
clutch set to slip at a predetermined torque, wherein at least one speed-increasing
stage of the transmission gearing (12) is placed between the output element (6o) of
the motion converting means (6) and the torque limiter (19).
11. A closure mechanism (C) according to any of claims 3 to 9, further comprising a torque
limiter (19) interposed between the rotary output element (6o) of the motion converting
means (6) and the rotary input element (7i) of the rotary braking device (7), so as
to limit the maximum torque transmitted between said rotary output element (6o) and
said rotary input element (7i), which torque limiter (19) is contained within a gearwheel
(20) of the transmission gearing (12), and preferably comprises a friction clutch
comprising two opposed friction discs (21,22) set to slip at a predetermined torque.
12. A closure mechanism (C) according to any one of the claims 1 to 8, further comprising
a torque limiter (19) interposed between the rotary output element (6o) of the motion
converting means (6) and the rotary input element (7i) of the rotary braking device
(7), so as to limit the maximum torque transmitted between said rotary output element
(6o) and said rotary input element (7i), which torque limiter (19) preferably comprises
a friction clutch set to slip at a predetermined torque.
13. A closure mechanism (C) according to claim 12 or any one of the claims 1 to 8, further
comprising a one-way clutch (13), preferably comprising a ratchet wheel (14), which
one-way clutch (13) is interposed between the rotary output element (6o) of the motion
converting means (6) and the rotary input element (7i) of the rotary braking device
(7) to enable rotation of said rotary output element (6o) without rotating said rotary
input element (7i) when the first part (1) is moved towards said second position.
14. A closure mechanism (C) according to any one of the claims 1 to 13, wherein the motion
converting means (6) comprises a rack-and-pinion gear, wherein the rack is preferably
formed on or attached to the first part (1).
15. A closure mechanism (C) according to any one of the previous claims, wherein the first
part (1) comprises a sleeve (1') and the second part (2) comprises another sleeve
(2') and one of the sleeves (1', 2') is telescopically slidable over the other sleeve
(1', 2') during the translational movement of the first part (1) relative to the second
part (2).
16. A closure mechanism (C) according to claim 15, wherein at least one of the two sleeves
(1', 2') surrounds the resilient element (4).
17. A closure mechanism (C) according to any one of the claims 1 to 16, wherein the resilient
element (4) comprises a coil spring.
18. A closure mechanism according to any one of the previous claims, wherein the distance
between said first position and said second position is at least 100 mm, preferably
at least 120 mm.
19. A closure mechanism (C) according to any one of the previous claims, comprising a
pivot device (9) mounted on a base member (8) of the first or second part (1, 2) for
pivotally attaching said first or second part (1, 2) to the hinged member (D) or structure
(F), wherein the pivot device (9) is mounted so that it can rotate on the base member
(8) around a first axis (28) substantially different to a second axis (29) on which
it is pivotally attachable to the hinged member (D) or structure (F), the first axis
(28) being in particular substantially perpendicular to the second axis (29).
20. A hinged closure member, in particular a hinged door, gate or window, which closure
member is provided with a closure mechanism (C) according to any one of the previous
claims.