FR3040415A1 - SYSTEM FOR OPENING AND CLOSING ACCESS - Google Patents

Abstract

The invention relates to a system for opening and closing an access (1) comprising a gate (4) rotatably mounted between an open position and a closed position, and a post (3) with respect to which the gate (4) ) is rotatably mounted. According to the invention, a synchronization system enables synchronization of the rotational movement of the gate (4) with the translational movement of the pole (3), the synchronization system (10) comprises a synchronization link (10) directly connecting the gate (4) to a fixed element, and the synchronization link (10) is formed, on the one hand, by a fixed vertical synchronization element (51) arranged, when the gate (4) is in the closed position, close a vertical edge (22) delimiting the portal (4) on the side of the post (3), and, secondly, by a horizontal synchronizing element (52) arranged along a horizontal edge of the portal (4). ) and along which the vertical synchronizing element (51) is mounted in translation and in rotation.

Description

OPENING SYSTEM AND PE CLOSING ACCESS

The present invention relates to a system for opening and closing access "including access to a field. In general, the area of available land is becoming smaller and smaller. However, the known access opening and closing systems comprise mobile gates which, during their movement, occupy an important place.

In addition 'since a portal must not open on the public road' there are additional constraints on the kinematics of the gateways of the access opening and closing systems when the gates 'in the closed position' are near the public road.

A first known type of access opening and closing system comprises a gate rotatably mounted along a vertical axis relative to a fixed pole. Because of the quarter-circle movement of the gate, there is around the fixed post a large occupancy space corresponding to a quarter disc centered on the fixed post and whose radius is equal to the length of the gate. A second known type of access opening and closing system comprises a gate mounted in horizontal translation along a fixed guide rail. Because of the translational movement of the gate between its open position and its closed position, only a gate whose length is less than half the width of the ground at the guide rail can be implemented.

A third known type of land access opening and closing system is an accordion system whose gate comprises two parts: a first portion rotatably mounted along a first vertical axis relative to a fixed pole, and a second rotatably mounted portion to the first portion according to a second vertical axis. The space occupied by such a portal is less important than that of a first-type system, but it is already at least equal to the quarter-disc centered on the fixed post and whose radius equal to the length of the first part of the portal. And in this space of occupation of the first part of portal "we must add the occupation space of the second part. Finally "the problem of space occupation is added the fact that" the portal is divided into two parts "the choice of its design is limited.

A fourth known type of land access opening and closing system is a fan system whose gate comprises several parts (generally at least six), all mounted in rotation relative to a fixed pole along an axis. horizontal oriented in the direction of the access to the ground. If this fourth type of system does not pose a problem of occupation "it raises problems related to the technical difficulty of their implementation, to their high cost" and to the very limited choice of the design of their portal which is cut in one significant number of parties.

The present invention aims to provide a system for opening and closing an access generating a very limited occupation of the ground during the movement of its portal, having no technical difficulty of implementation, and allowing a choice of design as important as the first two known types of access opening and closing systems. The invention relates to a system for opening and closing an access, the system comprising a gate rotatably mounted between an open position releasing access and a closed position obstructing access, and a post relative to which the gate is mounted in rotation, characterized in that it comprises a fixed guide rail which extends in a guide direction, the post being slidably mounted relative to the guide rail between an open position and a position of closure, the system for opening and closing an access comprising a synchronization system for synchronizing the rotational movement of the gate with the translational movement of the pole so that when the gate is in the open position. the post is in the open position, and when the gate is in the closed position, the post is in the closed position.

According to the invention, the occupation of the ground during the displacement of the gate substantially corresponds, in a square of which two perpendicular sides are defined, on the one hand, by the gate in the closed position, and, on the other hand, by the gate in the open position, to the space which, on the one hand, is centered on the first corner situated at the intersection of the two aforementioned sides, and, on the other hand, is complementary to a quarter disc centered on a second corner diagonally opposite the first corner and whose radius is equal to the length of the gate. Thus, the ground occupation during the entire movement of the gate is particularly low.

Depending on the position of the gate during its movement, the most important occupation is when the post is halfway between its open and closed positions, the gate then being at 45 ° relative to the guide rail and access. This peculiarity of geometry of the ground occupation is particularly advantageous since, taken in the direction of the guiding direction, the occupation of the gate on the ground is weaker as this gate moves away from its median position. 45 °, either towards its open position or toward its closed position.

In addition, the portal can be in one piece, the choice of design is as important as for those of the first two known types.

Preferably, the gate is delimited, on the one hand, by a first vertical edge which is adjacent to the post and, on the other hand, by a second vertical edge which follows a line defined by the location of the gate in the closed position when the pole moves.

As a result, such an access opening and closing system can be used at the edge of a field with the public domain.

The opening and closing system according to the present invention comprises several parameters, in particular the nature of the synchronization system, the support of the gate, the nature of the system performing the rotation of the gate, the guiding in rotation of the gate, the shape of the gate. portal at the level of its connection with the post, the support of the post, the nature of the system carrying out the translation of the post, the guidance in translation of the post, the orientation of the guide rail with respect to the horizontal plane and the system for setting the pole and gate movement,

A first parameter concerns the nature of the synchronization system.

According to a first embodiment of the first parameter, the synchronization system comprises an activation arm which is connected to the gate and which comprises, in a fixed manner, a synchronization member mounted in horizontal translation on the post in a synchronization direction. perpendicular to the guide direction, so that when the pole moves along the guide rail, the synchronizing member moves in the synchronization direction and causes the gate to rotate.

According to an advantageous embodiment of the first embodiment, the synchronization system comprises, on the one hand, a fixed drive rail which extends in a vertical drive plane at an angle to the vertical plane in which extends the guide rail, and, secondly, a drive member carried fixed by the activation arm and slidably mounted along the drive rail, so that when the pole moves along the rail 1, the driving member moves along the drive rail and causes the synchronization member to move in the synchronization direction,

According to a preferred mode of the advantageous mode, the synchronization system comprises a horizontal motion transformation plate which is integral with the pole and which comprises, on the one hand, a synchronization slot oriented in the direction of synchronization and in which the body synchronizer is slidably mounted, and, secondly, a non-secant motion transformation slot and making a non-zero angle with the synchronization slot, a motion transformation member carried fixed by the activation arm being slidably mounted. in the transformation slot, motion so sue, when, the drive member moves along the drive rail, the motion transformation member moves along the transformation slot, motion and causes movement of the activation arm relative to the motion transformation plate,

The motion transformation slot may not be rectilinear and have a more or less pronounced curve in order to modify the speed of movement of the gate for a translational speed. · Constant of the post. Advantageously, the curved shapes may be located at one or the other of the two ends of the motion transformation slot (or at both ends) in order to accelerate or slow down the rotation of the gate.

Particularly, the angle between the synchronization slot and the general direction of the motion transformation slot is about 45 °.

According to a variant of the first embodiment, the connection of the activation arm with the gate is carried out by a vertical linkage finger carried fixed by the activation arm and housed in a vertical connection orifice made in the remote gate of the axis of rotation of the gate.

According to a second embodiment of the first parameter, the synchronization system is formed by an alignment of fixed projecting members which extends parallel to the guide rail, and by a contactor which is mounted movably relative to the post between, on the one hand, an activation position in which it is located in line with a projecting member and causes the gate to be rotated and, on the other hand, a deactivation position in which it is located between two adjacent projecting members and causes the rotation of the gate to stop.

According to a first advantageous embodiment of the second embodiment, the switch is biased in its disengaged position by a return member.

According to one. preferential mode of the first advantageous mode, the return member is formed by a spring.

According to a second advantageous embodiment of the second embodiment, the contactor controls, according to whether it is in the activation position or in the deactivated position, the displacement of a toothed wheel carried by the post in an engaged position or a disengaged position. with a mechanism for rotating the gate.

According to a third advantageous embodiment of the second embodiment, the contactor comprises a drive roller adapted to roll only on the projecting members.

When the second embodiment comprises the second and third advantageous modes, the drive roller is integral with the toothed wheel.

According to a third embodiment of the first parameter, the synchronization system is formed by a closed belt fixed to the post and mounted in connection with, on the one hand, two transmission rollers whose vertical axes of rotation are fixed and arranged at each end of the guide rail, and, secondly, a gate roller whose vertical axis is connected to the axis of rotation of the gate.

According to an advantageous embodiment of the third embodiment, the belt is adapted to be tensioned by a tension roller which is movably mounted on the pole between a tensioning position in which the belt is tensioned and allows the movement of the post and the gate. , and a release position in which the belt is relaxed and does not allow movement of the post and the gate.

According to a fourth embodiment, of the first parameter, the synchronization system is formed by a gear system disposed in the pole and connecting a first gear for translating the pole to a second gear wheel for rotation of the gate.

According to a fifth embodiment of the first parameter, the synchronization system comprises a synchronization link directly connecting the portal to a fixed element.

According to a first variant of the fifth embodiment, the synchronization link is formed by a synchronization bar rotatably mounted to the gate according to a first vertical shaft and to the fixed element according to a second vertical shaft.

According to a second variant of the fifth embodiment, the synchronization link is formed, on the one hand, by a fixed vertical synchronization element arranged, when the gate is in the closed position, close to a vertical edge delimiting the gate of the side of the post, and, secondly, by a horizontal synchronizing element disposed along a horizontal edge of the gate and along which the vertical synchronizing element is mounted in translation and in rotation.

According to a third variant of the fifth embodiment, the synchronization link is formed, on the one hand, by a fixed support rail extending under the gate in the closed position and, on the other hand, by a wheel of support which is mounted to roll on the support rail and is pivotally supported by the gate along a vertical axis located near the vertical limit of the portal remote from the post.

A second parameter concerns the support of the portal.

According to a first variant of the second parameter, the gate is worn only by the pole.

According to a second variant of the second parameter, the gate is carried by a support wheel which is pivotally mounted to the gate along a vertical axis.

According to an advantageous aspect of the second variant, the support wheel is rolled up on a fixed support rail extending under the gate in the closed position and is disposed near the vertical limit of the portal remote from the pole.

A third parameter concerns the nature of the system performing the rotation of the portal.

According to a first embodiment of the third parameter, the gate is rotated by a toothed wheel carried by the pole and meshing with a toothed pinion carried by the gate.

According to a second embodiment of the third parameter, the rotation of the gate is performed by a jack connecting the post and the gate remote from the axis of rotation of the gate.

According to a first aspect of the second embodiment, the jack is rotatably connected to the post by means of a projecting member fixed to the post and oriented in the guiding direction.

According to a second aspect of the second embodiment, the jack is connected in rotation to the gate via an offset arm which shifts the axis of rotation between the jack and the gate out of the plane of the gate.

A fourth parameter relates to the rotational guidance of the portal.

According to an embodiment of the fourth parameter, the guide in rotation of the gate is made by a vertical rotating shaft which is carried by one of the two elements taken from the post and the gate and which is rotatably mounted in an opening. vertical rotation performed in the other of the two elements.

According to an advantageous aspect of the embodiment, the rotation guidance is achieved by two coaxial vertical rotation shafts housed in two vertical rotation apertures, each vertical rotation shaft and each vertical rotation aperture being located at the vertical end of the pole. and the portal.

A fifth parameter concerns the shape of the portal at its link with the post.

According to an embodiment of the fifth parameter, the gate comprises, in a fixed manner, a rotation member which forms a vertical extension of the post.

According to an advantageous aspect of the embodiment, the outer shape of the rotation member is 1a. same as that of the post, at least when the gate is in one of its open or closed positions.

A sixth parameter concerns the support of the post.

According to a first variant of the sixth parameter, the pole was carried only by the guide rail.

According to a second variant of the sixth parameter, the post is carried by a support wheel which is rotatably mounted on a fixed support rail and parallel to the guide direction.

A seventh parameter concerns the nature of the system carrying out the translation of the post.

According to a first embodiment of the seventh parameter, the translation of the pole on the guide rail is performed by a toothed wheel rotatably mounted on the pole and meshing with a rack which extends along the guide rail.

According to a second embodiment of the seventh parameter, the translation of the post on the guide rail is performed by a guide nut carried by the post and engaged around a guide screw which extends along the guide rail.

According to an advantageous embodiment of the second embodiment, the guide screw is rotatably mounted about its longitudinal axis.

According to a third embodiment of the seventh parameter, the translation of the post on the guide rail is performed by a closed belt fixed to the post and driven in displacement by two transmission rollers whose vertical axes of rotation are fixed and arranged at each end. of the guide rail.

An eighth parameter concerns the translation guidance of the post.

According to an embodiment of the eighth parameter, the translational guidance of the post is formed, on the one hand, by a fixed anti-tilt rail and parallel to the guide direction, and, on the other hand, by an anti-tilt element. -Bascule carried by the pole and at least partially surrounding the anti-tip rail.

According to a first variant of the embodiment, the anti-tipping element has, in cross section, a dovetail profile corresponding to the cross section of the anti-tip rail.

According to a second variant of the embodiment, the antitipper element is a ball cage mounted in translation around the anti-tip rail.

According to an advantageous aspect of the embodiment, the anti-tip rail is formed by the guide rail.

A ninth parameter relates to the orientation of the guide rail relative to the horizontal plane.

According to an embodiment of the ninth parameter, the guide rail extends along a plane of displacement which makes an angle of inclination with the horizontal plane so as to take account of the inclination of the ground.

According to an advantageous embodiment of the embodiment, connecting members ensuring the connection of the post with the guide rail are fixed to the post being inclined, relative to the horizontal plane, by an angle equal to the angle of inclination of the post. guide rail.

A tenth parameter concerns the system for moving the post and the gate.

According to a first embodiment of the tenth parameter, the access opening and closing system comprises a manual system for moving the post and the gate.

According to a second embodiment of the tenth parameter, the access opening and closing system includes a motor adapted to drive either the translation movement of the pole or the rotational movement of the gate.

According to a first variant of the second embodiment, the access opening and closing system comprises only one motor.

According to a first version of the first variant, the motor is adapted to drive the translational movement of the pole.

According to a first option of the first version, the motor is secured to the guide rail.

According to a second option of the first version, the motor is secured to the post.

According to a second version of the first variant, the motor is adapted to drive the rotational movement of the gate.

According to a first option of the second version, the motor is secured to the pole.

According to a second option of the second version, the motor is secured to the gate.

According to a second variant of the second embodiment, the access opening and closing system comprises a complementary motor adapted to drive either the translational movement of the pole if the motor is adapted to cause the rotational movement of the gate, or the rotational movement of the gate if the motor is adapted to cause the translational movement of the pole, the complementary motor being synchronized to the motor.

According to a first option of the second variant, the motor is secured to the guide rail and the complementary motor is secured to the gate.

According to mue second option of the second variant, the motor is secured to the guide rail and the complementary motor is secured to the post.

According to a third option of the second variant, the motor is secured to the pole and the complementary motor is secured to the gate.

According to a fourth option of the second variant, the motor and the complementary motor are integral with the post. Other features and advantages of the present invention will appear in the embodiments of the invention given as non-limiting examples and illustrated in the drawings in which: - Figure 1 is a top view of a system of opening and closing access according to a first embodiment of the present invention, the gate being in the closed position; - Figure 2 is a view similar to Figure 1, the gate being between its closed position and its open position; - Figure 3 is a view similar to Figures 1 and 2, the gate being in the open position; - Figure 4 is a side view of an access opening and closing system according to a second embodiment of the present invention and installed in a terrain, having a slope, the gate being in the open position; FIG. 5 is a view from above of an access opening and closing system according to a third embodiment of the present invention, the gate being between its closed position and its open position; Fig. 6 is a top view of the timing system used in the access opening and closing system shown in Fig. 5; FIG. 7 is a perspective view from above and from the side of an activation arm of the synchronization system of FIG. 6; FIG. 8 is a perspective view from above and from the side of the horizontal motion transformation plate of the synchronization system of FIG. 6; FIG. 9 is a perspective view from above and from the side illustrating the cooperation between a drive rail, an activation arm and a horizontal motion transformation plate of the synchronization system of FIG. 6, the non-illustrated gate being in the closed position y - Figure 10 is a view similar to Figure 9, the non-illustrated gate being between its closed position and its open position; - Figure 11 is a view similar to Figures 9 and 10, the non-illustrated portal being in the open position; - Figure 12 is a view similar to Figure 9 (gate in the open position) illustrating the cooperation of the synchronization system with the guide rail and the post; - Figure 13 is a view similar to Figure 12 illustrating the cooperation of the synchronization system with the guide rail, the post and the gate; FIG. 14 is a side view of the cooperation of a pole, a guide rail and a synchronization system of an access opening and closing system according to a fourth embodiment. of the present invention; - Figure 15 is a similar view of Figure 14, the drive roller being in its disengaged position; FIG. 16 is a top view of an access opening and closing system according to a fifth embodiment of the present invention, the synchronization system being formed by a belt; FIG. 17 is a top view of an access opening and closing system according to a sixth embodiment of the present invention, the synchronization system being formed by a gear system; FIG. 18 is a view from above of an access opening and closing system according to a seventh embodiment of the present invention, the synchronization system being formed by a synchronization bar; FIG. 19 is a view from above of an access opening and closing system according to an eighth embodiment of the present invention, the synchronization system being formed by the cooperation of a fixed element of synchronization, with an element extending along the portal; FIG. 20 is a view from above of an access opening and closing system according to a ninth embodiment of the present invention, the synchronization system being formed by the cooperation of a support rail. and a wheel carried by the gate j - Figure 21 is a top view of an access opening and closing system according to a tenth embodiment of the present invention, the rotation of the gate being realized by the actuation of a jack; FIG. 22 is a front view of the connection of the gate with the post of an access opening and closing system according to an eleventh embodiment of the present invention, two parts of the gate extending the post vertically. ; FIG. 23 is a front view of the connection of the post with the guide rail of an access opening and closing system according to a twelfth embodiment of the present invention, the post being not worn; by the guide rail; FIG. 24 is a front view of the connection of the post with the guide rail of an access opening and closing system according to a thirteenth embodiment of the present invention, the post being carried by a support wheel; FIG. 25 is a vertical sectional view perpendicular to the guide direction of the pole connection with the guide rail of an access opening and closing system according to a fourteenth embodiment of the present invention. The connection being made by a system of nut and screw # - Figure 26 is a schematic top view illustrating the floor occupation of the gate during its movement; and - Figure 27 is a view similar to Figure 8 * the motion transformation slot having a curved shape.

As illustrated in the various figures, 1'invention relates to a system for opening and closing an access 1 to control access to land.

The system for opening and closing an access 1 object of the present invention comprises a guide rail 2 »a pole 3, a gate 4 and a synchronization system 5, 6, 7, 8, 9, 10, 11 .

The guide rail 2 is fixed and extends in a guide direction 12 defining a vertical guide plane. The system may also have a plurality of parallel guide rails 2 (as shown in FIGS. 14 and 23 to 25).

Among the possible modes of attachment, the guide rail 2 can be fixed to a wall (as illustrated in FIGS. 1 to 3) or carried by vertical uprights 13 fixed to the ground (as illustrated in FIGS. 4, 5, 9, 11, 12 and 23).

Preferably, when the part of the ground where the guide rail 2 extends has a vertical inclination in the guide direction 12, the guide rail 2 is arranged to extend in a plane of displacement which makes an angle inclination 14 with the horizontal plane so as to take account of the inclination of the ground (as shown in Figure 4).

The post 3 is slidably mounted relative to the guide rail 2 between "open position and a closed position,

The post 3 can be worn only by the guide rail 2 (as shown in Figure 23) or be carried by a support wheel 15 (as shown in Figure 24), In the case where the post 3 is worn by a support wheel 15, this support wheel 15 is preferably rotatably mounted, according to its horizontal axis, on a support rail 16 which is fixed to the ground parallel to the guide direction 12,

In the case where the guide rail 2 makes an angle of inclination 14 with the horizontal plane, connecting members ensuring the connection of the post 3 to the guide rail 2 are fixed to the post 3 by being inclined with respect to the horizontal plane d An angle equal to the angle of inclination 14. In this way, the post 3 remains oriented vertically regardless of its position, (as shown in Figure 4).

In order to prevent tilting of the post 3 with respect to the guide rail 2, the post 3 is guided in translation along the guide rail 2 by a fixed anti-tilt rail and parallel to the guide direction 12 and by an element anti-tipper carried by the post 3 and at least partially surrounding the anti-tip rail. The antitipper element may have, in cross-section (perpendicular to the guide direction 12), a dovetail profile corresponding to the cross-section of the anti-tip rail. The antitipper element may also be formed by a cylinder (for example a ball cage) mounted in translation around the anti-tip rail. Preferably, the anti-tip rail is formed by the guide rail 2.

The translation of the post 3 on the guide rail 2 can be achieved by different means. It is thus possible to use a toothed wheel rotatably mounted on the post 3 and engaged with a rack which extends along the guide rail 2. It is also possible to use a closed belt 17, the belt 17 being fixed to the post 3 and driven by two transmission rollers 18 whose vertical axes of rotation are fixed and arranged at each end of the guide rail 2 (as shown in Figure 16), It is still possible to use a nut guide 19 carried by the pole 3 and engaged around a guide screw 20 which extends along the guide rail 2 (as shown in Figure 25), the guide screw 20 being rotated about its longitudinal axis (which is parallel to the guide direction 12).

The gate 4 is rotatably mounted relative to the post 3 between an open position releasing access and a closed position obstructing access. Preferably, the gate 4 in the open position is parallel to the vertical guide plane. Preferably, the axis of rotation 21 of the gate 4 to the post 3 extends in a vertical direction.

The gate 4 is delimited vertically by two vertical edges 22 "23: a first vertical edge 22 which is adjacent to the post 3, and a second vertical edge 23 opposite the first vertical edge 22.

Preferably "for aesthetic reasons and to limit the masonry operations * the gate 4 is worn only by the post 3. It is also possible that the gate 4 is carried by a support wheel which is mounted at the gate 4 pivotably along a vertical pivot axis 24 and which is adapted to ride on the ground. Preferably * when the gate 4 is carried by a support wheel * the latter is mounted on a rolling rolling support rail 25 which extends under the gate 4 in the closed position (as shown in Figure 20). Also preferably * in order to distribute the weight of the gate 4 * the support wheel is disposed near the second vertical edge 23 of the gate 4.

In order to stabilize the rotation of the gate 4 with respect to the post 3 *, the rotational guidance of the gate 4 is preferably made on the one hand by a vertical rotation shaft which is carried by the post 3 or by the gate 4 and * on the other hand "by an opening of vertical rotation which is carried out either in the gate 4 if the vertical rotation shaft is carried by the pole. 3, or in the post 3 if the vertical rotating shaft is carried by the gate 4 # the vertical rotation shaft being rotatably mounted in .the vertical rotation opening. Preferably, the rotation guidance is achieved by two coaxial vertical rotation shafts housed in two vertical rotation apertures, the vertical rotation shafts, and the vertical rotation apertures being located at both vertical ends of the post 3 and the portal 4.

The rotation of the gate 4 with respect to the post 3 can be achieved by different means. It is thus possible to use a jack 26 connecting the post 3 and the gate 4 at a distance from the axis of rotation 21 of the gate 4 (as shown in FIG. 21). When a jack 26 is used, it is connected to the post 3 along a first vertical axis 27 (preferably via a projecting member 28 secured to the post 3 and oriented in the guide direction 12), and the gate 4 along a second vertical axis 29 (preferably by a intermediate of an offset arm 30 which shifts the second vertical axis 29 out of the plane of the portal 4).

For aesthetic reasons and in order to hide the mechanical connections between the post 3 and the gate 4, the gate 4 may comprise, in a fixed manner, a rotation member. 31 which forms a vertical extension of the post 3 (as shown in Figure 2.2 where the gate comprises two rotational members 31). Preferably, the outer shape of the rotation member 31 is the same as that of the post 3, at least when the gate 4 is in one of its open or closed positions (and preferably when the gate 4 is in its position). closed position).

The synchronization system 5, 6, 7, 8, 9, 10, 11 allows synchronization of the rotational movement of the gate 4 with the translation movement of the post. 3 so that when the gate 4 is in the open position, the pole 3 is in the open position, and when the gate 4 is in the closed position, the pole 3 is in the closed position (as shown in FIGS. )

Preferably, the synchronization system 5, 6, 7, 8, 9, 10, 11 allows the second vertical edge 23 of the gate 4 to follow a line 32 defined by the location of the gate 4 in the closed position when the pole 3 and portal 4 are moving. The support rail 25, when it exists, is arranged along this line 32.

FIGS. 5 to 13 illustrate a first example of synchronization system 5,

The first example of synchronization system 5 comprises an activation arm 33 (as illustrated in FIG. 7). This activation arm 33 is connected to the gate 4 and has, in a fixed manner, a synchronizing member 34 which is mounted in translation on the pole. 3 according to a synchronization direction 35 horizontal and perpendicular to the guide direction 12. As a result, when the post 3 moves along the guide rail 2, the synchronizing member 34 moves relative to the post 3 according to the synchronization direction 35 (perpendicular to the guide direction 12) and causes the gate 4 to rotate.

In the first example of synchronization system 5, the activation arm 33 also comprises, in a fixed manner, a drive member 36 which is slidably mounted along a fixed drive rail 37. The drive rail 37 extends in a vertical drive plane which is at an angle to the vertical guide plane. As a result, when the post 3 moves along the guide rail 2 (and therefore at the surface of the vertical guide plane), the driving member 36 moves along the driving rail 37 (and thus at the surface of the vertical driving plane) and causes the synchronizing member 34 to move in the synchronization direction 35.

The first example of synchronization system 5 also comprises a horizontal motion transformation plate 38 which is integral with the post 3 and which comprises two slots 39, 40 of different orientations and non-intersecting. A first of these two slots 39, 40 is a synchronization slot 39 which is oriented in the synchronization direction 35 and in which the synchronizing member 34 is slidably mounted. The second slot is a motion transformation slot 40 in which is slidably mounted a motion transformation member 41 carried fixedly by the activation arm 33. As a result, when the driver 36 moves the along the drive rail 37, the motion transformation member 41 moves along the motion transformation slot 40 and causes the activation arm 33 to move relative to the motion transformation plate 38.

In the embodiment illustrated in FIG. 8, the motion transformation slot 40 is rectilinear and oriented at approximately 45 ° with respect to the synchronization slot 39. In the embodiment illustrated in FIG. the motion transformation slot 40 is curved and its overall orientation with respect to the synchronization slot 39 is about 40 ° (in this embodiment, since the entire motion transformation slot 40 is curved, The general orientation is determined by the line connecting the two ends of the motion transformation slot 40).

The shape of the motion transformation slot 40 makes it possible to have a rotation speed of the variable gate 4 as a function of the position of the gate 4 for a constant translation speed of the post 3. The curvature of the motion transformation slot 40 may not be uniform throughout its length. The motion transformation slot 40 may have a curvature only in certain places, for example, only one or the other of its two ends or both ends could be bent in order to accelerate or slow down the rotation of the portal 4.

As illustrated in FIGS. 7 and 13, the connection of the activation arm 33 with the gate 4 is made by a vertical connecting finger 42 which is fixedly supported by the activation arm 33 and which is housed in a vertical connection orifice made in the gate 4 at a distance from the axis of rotation 21 of the gate 4 to the post 3. Thus "when the activation arm 33 moves relative to the motion transformation plate 38" the gate 4 moves around its axis of rotation 21.

This first example of synchronization system 5 is particularly simple to implement since it only requires a fixed drive rail 37 extending in a vertical drive plane which is at an angle to the vertical guide plane. A horizontal motion transformation plate 38 fixed to the post 3 and carrying two slits 39 "40 of different non-secant orientations" and an activation arm 33 connected to the drive rail 37 by an armature member. "drive 36" to the horizontal motion transformation plate 38 by a synchronization member 34 and a transformation member, movement 41, and the gate 4 by a vertical connecting finger 42.

Figures 14 and 15 illustrate a second example of synchronization system 6.

The second example of synchronization system 6 is formed "on the one hand" by an alignment of fixed projecting members 43 which extends parallel to the guide rail 2 "and" on the other hand "by a contactor 44 which is worn by the pole 3 and which is adapted to cooperate with this alignment. For this purpose, the contactor 44 is movably mounted with respect to the pole 3 between "on the one hand" an activation position in which it is located in line with a projecting member 43 and causes the gate 4 to rotate "On the other hand" a deactivation position in which it is located between two adjacent projecting members 43 and causes the stop of the rotation of the gate 4.

According to a first option »the contactor 44 is biased in its deactivation position by a return member 45 such as a spring 45. Thus the rotation of the gate 4 is only when the contactor 44 is in contact with a protruding member 43. It is thus possible, by adjusting the position and the length of each projecting member 43, to determine the speed of rotation of the gate 4.

According to a second option that can be associated with the first option, the switch 44 controls, according to whether it is in the activation position or in the deactivated position, the movement of a toothed wheel carried by the post 3 between an engaged position and a disengaged position with a mechanism for rotating the gate 4.

According to a third option that can be associated with at least one of the two previous options, the switch 44 comprises a drive roller 46 which is mounted vertically movable relative to the pole 3 and which is adapted to roll only on the projecting members 43. When the second option is associated with the third option, it is preferable that the drive roller 46 is integral in rotation and in translation movement of the toothed wheel. The drive roller 46 and the toothed wheel may in particular be part of a single piece forming the contactor 44.

FIG. 16 illustrates a third example of synchronization system 7.

The third example of synchronization system 7 is formed by a closed belt 17 which is fixed to the pole 3 and which is mounted in connection with rollers 18, 47. These rollers 18, 47 comprise, in addition to the two transmission rollers 18 whose vertical axes of rotation are fixed and arranged at each end of the guide rail 2, a gate roller 47 whose vertical axis is connected to the axis of rotation 21 of the gate 4. As a result, the translation of the post 3 drives the rotation of the gate 4. The gate roller 47 can be carried by the gate 4 or by the pole 3.

According to one variant, the belt 17 is stretched by at least one tension roller 48 which is mounted to move on the pole 3 between a tensioning position in which the belt 17 is stretched and allows the displacements of the post 3 and the gate 4, and a release position in which the belt 17 is relaxed and does not allow the movements of the post 3 and the gate 4. In Figure 16, the synchronization system comprises two tension rollers 48.

FIG. 17 illustrates a fourth example of synchronization system 8.

The fourth example of a synchronization system 8 is formed by a gear system disposed in the post 3 and connecting a first gear wheel enabling the translation of the post 3 to a second gear wheel enabling the gate 4 to rotate.

FIGS. 18, 19 and 20 illustrate three examples of synchronization system 9, 10, 11 in which the synchronization systems 9, 10, 11 are formed by a synchronization link 9, 10, 11 directly connecting the gate 4 to an element fixed.

FIG. 18 illustrates a fifth example of a synchronization system 9. The synchronization link 9 is formed by a synchronization bar 9 which is rotatably mounted on the one hand to the gate 4 along the first vertical shaft 49, and, d on the other hand, to the ground according to a second fixed vertical shaft 50.

FIG. 19 illustrates a sixth example of a synchronization system 10. The synchronization link 10 is formed by a fixed synchronization vertical element 51 mounted in translation and in rotation with a horizontal synchronization element 52 carried by the gate 4. The element vertical synchronization 51 is disposed, when the gate 4 is in the closed position, near the first vertical edge 22 of the gate 4, and the horizontal synchronization element 52 is disposed along a horizontal edge of the gate 4 .

FIG. 20 illustrates a seventh example of a synchronization system 11. The synchronization link 11 is formed, on the one hand, by a support rail 25 fixed to the ground and extending under the gate 4 in the closed position and, d on the other hand, by a support wheel which is mounted to roll on the support rail 25 and is pivotably carried by the gate 4 along a vertical axis 24 near a second vertical edge 23 of the gate 4.

Finally, the system for opening and closing an access 1 object of the present invention also comprises a system for moving the post 3 and the gate 4.

This movement system can be a manual movement system. It can also be a motorized system that is preferably # -controllable to allow manual movement.

The motorized system may comprise only one motor adapted to directly drive the movement of the post 3 or the gate 4 # the synchronization system 5 # 6, 7, 8 # 9, 10 # 11 ensuring the connection between the gate 4 and the post 3. If the motor directly drives the translation of the post 3, it can be either fixed (integral with the guide rail 2) or integral with the post 3. If the motor directly drives the rotation of the gate 4, it can be either secured to the post 3, is secured to the portal 4.

The motorized system may also include two motors: a first motor adapted to directly drive the movement of the pole 3, and a second motor adapted to directly drive the movement of the gate 4, the synchronization system ensuring the synchronization of the two motors. The first motor can be fixed or integral with the post 3, and the second motor can be secured to the post 3 or the gate 4. The use of a single fixed motor is preferable because the electric supply son are also fixed . Such an engine can be used to drive the rotation of a guide screw 20 or a transmission roller 18.

The control of the access can be realized both by a single opening and closing system 1 according to the present invention, as by two opening and closing systems 1 according to the present invention.

In the case where two opening and closing systems 1 are used, the two gates 4 are arranged so that their two second vertical edges 23 are adjacent to each other. Preferably, the movements of the gates 4 and 3 of the posts. two systems are synchronized. Typically, the two gates 4 rotate in opposite directions while the posts 3 move in the same direction.

As illustrated in FIG. 26, the occupation of the ground during the displacement of the gate 4 corresponds substantially, in a square whose two perpendicular sides are defined, on the one hand, by the gate 4 in the closed position, and, on the other hand by the gate in the open position 4 (or by the guide rail 2), to a space 53 which is complementary to the quarter disc whose radius is equal to the length of the gate and whose center is at the corner diagonally opposite to the corner located at the intersection of the two aforementioned sides. The corresponding circular arc 54 forms the limit of the ground occupation of the opening and closing system 1.

Claims (2)

1. System <3'opening and closing an access (1), the system (1) comprising a gate (4) rotatably mounted between an open position releasing access and a closed position obstructing access, and a post (3) with respect to which the gate (4) is rotatably mounted, the CD system comprising a fixed guide rail (2) extending in a guide direction (12), the post (3) being mounted sliding relative to the guide rail (2) between an open position and a closed position, the opening and closing system of an access (1) comprising a synchronization system (10) allowing the synchronization of the movement of rotation of the gate (4) with the translation movement of the post (3) so that, when the gate (4) is in the open position, the post (3) is in the open position, and when the gate (4) ) is in the closed position, the post (3) is in the closed position, characterized in that the synchronization system (10) comprises a synchronization link (10) directly connecting the gate (4) to a fixed element, and in that the synchronization link (10) is formed, on the one hand, by a fixed vertical synchronization element (51) arranged when the gate (4) is in the closed position, near a vertical edge (22) delimiting the portal (4) on the side of the pole (3), and, secondly, by a horizontal synchronizing element ( 52) disposed along a horizontal edge of the gate (4) and along which the vertical synchronizing element (51) is mounted in translation and in rotation. 2. System (1) according to claim 1, characterized in that the gate (4) is delimited, on the one hand, by a first vertical edge (22) adjacent to the post (3) and, on the other hand, by a second vertical edge (23) which, when the post (3) moves, follows a line (32) defined by the location of the gate (4) in the closed position.