SE0900745A1 - Clutch function for a lock function - Google Patents

Description

attacks the rotary function, this effect is pre-energized via the rotary shaft to the locking function, which also breaks down.

Document GB 2189860 A has a rotary function, the rotary shaft of which can be disengaged via a solenoid, so that the rotary function does not affect the locking function. This construction is complicated and has many parts, where a movement in the rotary function affects a device radially and which in turn affects a plate to be connected to another plate axially, only if a solenoid has moved on a part stopping against one plate . This construction requires a large axial distance. The construction is easy to sabotage, by mechanically attacking the rotary function, which then ceases to function. Furthermore, this construction cannot be mounted on the outside of existing lockable units, since the coupling device must be arranged inside the lockable unit and is therefore only suitable for a limited area of use.

The object of the present invention is to solve the problems which exist with known constructions, by arranging the coupling device, within a limited axial space, enclosed by a protective housing, intended for mounting on a number of different lockable units. The coupling function takes up little space containing a few constituent disc-shaped parts laid on top of each other, supported against the inside of the outer wall of the housing axially surrounded by a shell surface with tooth formations which are locked by a locking element axially from a solenoid electronically operated from the outside without using a locking cylinder. to a second axis of rotation to lock or unlock the locking function.

Thanks to the invention, a simple inexpensive, well-functioning and easily assembled coupling device has been provided, which takes up little space inside an enclosing housing, and has few integral parts, which connect two rotary shafts, to transmit a torque from a rotary function such as a knob or a handle for a locking function, having a locking element e.g. a locking piston for externally locking / unlocking a lockable unit such as a door, a gate, a window, etc. to lock a space or a fence. A pivot axis passes through the outer wall of the housing and through a hole in the center of a circular disk unit, which rotates freely about the axis of rotation. The circular disc unit is flatly rotatably arranged towards the inside of the outer wall. The periphery of the circular disc unit is connected to the inside of this annular mantle surface, the outside of which has tooth formations, which. points radially out from the outside of the mantle surface. A solenoid locking element either locks the gear formations or moves freely from them, controlled by an external one of an electronic handset, which activates the coupling device with a preselected lock code, the locking element entering between the gear formations, so that it can not rotate about the axis of rotation. The second side surface of the circular disc unit has at least one elevation projecting in a direction away from the inside.

The pivot shaft terminates at a first end at the second side surface, after passing through the hole. A coupling lens element is resiliently connected at one end to the first end of the rotary shaft, where it passes through the second side surface a bit. The coupling element then continues to abut radially against the second side surface, as the locking element moves freely from the tooth formations and is angled up by the elevation, which is arranged below the coupling element from the second side surface, when the tooth formations are held by the locking element during further rotation. Then the coupling element grips a radially directed gripping element, which is connected to a second end of a second axis of rotation, extending in the extension of the axis of rotation, projecting from the lockable unit, the rotation function transmitting torque to the second axis of rotation, to rotate around it one way to lock and the other way to unlock the lock function. Coupling element then springs back down from one of the elevations and the gripping element, when the locking element is disconnected from the gear formations by a resilient steel spring arranged on the first end of the rotary shaft. The coupling device itself transmits the torque within a small limited axial space and thus has a place at the circular disc unit inside the mantle surface which has an axial length of less than 20 mm.

The diameter of the circular disc unit is about 2- 5 cm.

A good function and a simple way of assembling the parts included in the coupling device, which also requires small axial space, is obtained against the coupling element is connected and laid directly to the coupling plate, which is laid on the circular unit resting against the outside wall of the housing.

The coupling plate and the coupling element are made of flat punched metal sheet pieces, which are a few mm thick connected with joints. The coupling plate is then substantially rectangular, having an I-shaped hole in its center, which encloses the axis of rotation, which is also I-shaped for transmitting the driving force to the coupling plate. In a preferred embodiment of the invention, the inside of the mantle surface encloses a friction surface, which is fixedly arranged at the periphery and which forms part of the outside of the elevation following the periphery, which faces radially towards the inside. The second side surface then continues between the elevations as a flat part, where the coupling element has its lowest position before it is angled up, resting against the other side of the non-circular disc unit between the elevations, before the rotation to be connected to the gripping element. An elevation then begins with an angled inclined surface along the periphery from the planar portion and then flattens out at the top of the elevation as a planar surface, which in turn ends with a stop surface extending across the second side surface, against which the coupling element locks, for to continue rotation of the circular disc unit, when the casing surface is locked by the locking element. In this way, the coupling element is supported from below when it grips the gripping element and follows in this position as long as you turn the rotary function in this position until the locking / unlocking is completed.

The invention is described in more detail below with the aid of some embodiments of the invention, in which Fig. 1 shows a vertical section through the coupling device, when the locking element is inserted into the gear formations during rotation, Fig. 2 shows a vertical detail section through a detail of coupling device when the tooth formations move freely from the locking element Fig. 3 shows a translucent view straight towards a coupling device seen against the inside of the outer wall of the housing.

As can be seen from Figs. 1-3, a coupling device 1 is shown, arranged at a rotary shaft 3 for transmitting a torque from a rotary function 2, e.g. a knob, for a locking function, for locking or unlocking a lockable unit 4, such as e.g. a door about a space / fenced 5. The coupling device 1 is arranged on the outside of the lockable unit 4 and is enclosed by a housing 6.

The pivot shaft 3 extends from the outside through the outer wall 7 of the housing 6 and in through a hole 8 in the center of a circular disc unit 9, which radially runs freely around the pivot axis 3. One side surface 10 of the circular disc unit 9 is guided up towards the inside 11 of the outer wall 7 and slides towards one inside 11, to reduce the friction between one side surface 10 and the inside 11 and to minimize wear of one side surface 10. The plastic sheet 44 is made. of one. low friction materials such as e.g. nylon, so that one side surface slides easily towards it when twisting. The periphery 12 of the circular disk unit 9 is connected to the inside 14 of an annular shell surface 13, the outside 15 of which has tooth formations 16, pointing radially therefrom, to be held or released by a locking element 17 controlled by a solenoid which is electronically activated from the outside to move in and out of the tooth formations 16. The second side surface 18 of the disc unit 9 has, in a direction 19 away from the inside 11 projecting elevations 20. The axis of rotation 3 terminates axially a bit after passing through the hole 8 in a first end 22, where it is connected to two coupling element 24, to resiliently abut against the second side surface 18 between the elevations 20 when the locking element 17 moves freely from the tooth formations 16. When the tooth formations 16 are held by the locking element 11 when rotating on the axis of rotation 3, the coupling elements are angled up against the elevations 20 in the direction 19 gripping a radially directed gripping element 26, which is connected to a second end 27 of a second pivot shaft 38, the distance in the extension of the rotary shaft 3, in order to be able to turn the second rotary shaft 38 in one direction to lock and in the other direction to unlock the locking function.

In a preferred embodiment of the invention, the elevation 20 has a stop surface 25. When the rotation of the rotation shaft 3 proceeds when the locking element 17 has locked against the tooth formations 1 and when the movable coupling lens element 24 is angled up in the direction 19, it is stopped against the stop surface 25 extending in the direction 19. The stop surface 25 then follows the rotation, when the torsional force exceeds one, between the inside 14 of the mantle surface 13 and the circular disc unit 9 at the periphery 12 and the elevations 20, where established. friction, when the circular disc unit 9 and the mantle surface 13 are two different parts connected with friction between them. Then the inside 14 of the jacket surface 13 encloses at least one friction surface 28, which is arranged in the outside 29 of the elevation 20, which follows the periphery 12, which faces radially towards the inside 14. The friction then exists between the inside 14 and the friction surface 28. The friction surface 28 is made as a box-shaped loose part 41, which is resiliently fitted in a hole 37 in the outside 29, arranged to spring therefrom therefrom. The friction surface 28 presses on towards the inside 14 with resilient elements 40, which are arranged behind the loose part 41. The second side surface 18 continues between the two elevations 20 as a flat part 36, where the coupling element 24 has its lowest position before the rotation. The elevation 20 then begins with an angled inclined surface 30 along the periphery 12, which flattens out at the top of the elevation 20 as a flat surface 31, which is parallel to the second side surface 18 and which in turn ends with the stop surface 25 and which extends transversely. the second side surface 18, while continuing to rotate the circular disc unit 9, when the casing surface 13 is locked by the locking element 17. Two coupling elements 24 are connected to a coupling plate 21, which are made of flat sheet metal pieces. The coupling plate 21 is slightly rectangular and has an I-shaped hole 32 in its center, which encloses the pivot shaft 3, which is also I-shaped, for transmitting the driving force to the coupling plate 21, which is flat against the circular disc unit 9 on the other side of the side surface 18, which in the middle of its two opposite short sides each have their own edge area 33, which has two opposite folds 34 constituting two half joints 23 per short side, formed by a piece of the edge area 33. These folds 34 are connected to corresponding two other semiconductor joints 23 also formed as folds 33 at coupling elements 24, formed as two semicircular segments, at its straight side, where the torque is transmitted.

The semicircular segments together with the joints 23 and the coupling plate are a torsionally rigid transmission structure which is not deformed by the torsional force.

The other ends of the coupling elements 24 each have their projection 43, which also has a fold 33 constituting a stop plate 45 to stop against the stop surface 25 in the center of the periphery of the semicircular segment. Near this, along this periphery, there is yet another fold 34 in the form of a hook function 42, intended to grip the gripping element 26 and transmit the torque to it.

Two opposite mirror-resilient resilient stop surfaces 25, flat surfaces 31 and inclined surfaces 30 with an intermediate flat part are arranged at the periphery 12 on the second side surface 18, whereby when locking the locking function, the rotary shaft 3 is rotated in one direction towards one of the stop surfaces 25 and when unlocking turn the rotary shaft 3 in the other direction. against the second stop surface 25. The first end 22 has a steel spring 35 which springs back against the coupling elements 24, which press against it in a direction towards the second side surface 18 and at the same time presses the coupling plate 21 and the circular disc unit 9 towards the inside 11 with a resilient spring pressure. . The hook function 42 can randomly touch the gripping element 26 when the locking element 17 has just locked the tooth formations 16. The gripping element 26 is a flat piece of sheet metal, extending radially from the other end 27, one side of which faces the hook function 42, which can then be hit without gripping grip the gripping element 26 in a position when the hook function 42 is located at the top of the flat surface 31. Gripping element 26 is resiliently radially connected to the other end 27, which then springs back from the hook function 42, which then instead grips the gripping element 26 when continued. rotation during the next turn. The stop surface 25 resiliently in a direction of rotation. The rotation of the coupling element 24 is then gently stopped against the stop surface 25, so that it does not flip over the stop if the rotation takes place too quickly and gets stuck there. During the rotation, the stop surface is moved along the stretch of the flat surface 31 until it stops in a stop position 39 and rotates the circular disc unit 9 further. After the rotation, when the locking element 17 goes free again from the tooth formations 16, the stop surface 25 pushes back stop plate 45, which then slides down for the inclined surface 3 to the flat part 36. Then the rotation function 2 raps and the second rotation shaft 38 goes free and thus comes not to unlock the lock function.

Claims (10)

10 Claims 1. Coupling device (1) arranged at at least one rotary shaft (3) for transmitting a torque from a rotary function (2), e.g. a knob, a handle for a locking function, having at least one locking element e.g. a locking piston, to lock / unlock a lockable unit (4) from the outside, such as a door, a gate, a window etc. about a space / fence (5), characterized in that coupling device (1) is arranged at the lockable unit (4). ) enclosed by at least one housing (6), preferably a steel housing, which pivot shaft (3) from the outside passes through the outer wall (7) of the housing (4) and through a hole (8): in at least the center of a circular disc unit (9), which radially moves freely around the axis of rotation (3), which side surface (10) of the disc unit (9) is guided up radially, via the inside (11) of the outer wall (7), which periphery (12) of the circular disc unit (9) is radially connected to an annular shell surface ( 13), inside (14), the outside of which (15) has tooth formations (16), pointing radially out therefrom, to be held / released by / from at least one locking element (17), which second side surface (18) of disc unit (9) has at least one elevation (20) projecting in a direction (19) away from the inside (11), which pivot axis (3) terminates after the hole (8) in the direction (19) in a first direction. end (22) and is directly or indirectly connected to at least one coupling lens element (24), which is resiliently arranged to abut at least to some extent against the second side surface (18) when the locking element (17) moves freely, whereby, when the tooth formations (16 ) is held by the locking element (11) during rotation, coupling element (24) is rotated and at least to some extent moved in the direction (19) towards the elevation (20), to grip at least one, radially directed gripping element (26), which is connected at a second end (27) of a second rotary shaft (38), extending in the extension of the rotary shaft (3) to rotate the second rotary shaft (38) in one direction to lock and in the other direction to unlock the locking function and which coupling element (24) springs back down from the ridge (20) and the gripping element (7), when the locking element (11) has been disconnected from the gear formations (16). Coupling device (1) according to claim 1, characterized in that, when the rotation of the rotation shaft (3) proceeds, when the locking element (17) has locked against the gear formations (16) and when the movable coupling element (24) is angled up in the direction (19) , it is stopped against at least one stopping surface (25) extending in the direction (19), arranged at the second side surface (18) of the elevation (20), which then accompanies the rotation, when the torsional force exceeds one inside the jacket surface (13) (14) ) and the circular disc unit (9) at the periphery (12) and the elevations (20) a friction established there, when the circular disc unit (9) and the mantle surface (13) are two different parts connected with friction between them. Coupling device (1) according to claim 2, characterized in that the inside (14) of the jacket surface (13) encloses at least one friction surface (28), which is fixedly arranged at the periphery (12), which forms at least a part of the outside of the elevation (20). (29) following the periphery (12) facing radially towards the inside (14), which friction is present between the inside (14) and the friction surface (28), which second side surface (18) 12 continues between the two elevations (20) as a plane part (36), where the coupling element (24) has its lowest position before rotation, which elevation (20) begins with an angled inclined surface (30) along the periphery (12), which flattens out at the top of the elevation (20) as a plane surface (31) substantially parallel to the second side surface (18), which in turn ends with the stop surface (25) extending across the second side surface (18), against which the coupling element (24) locks, to continue to rotate the the circular disc unit (9) must be made when the casing surface (13) is locked by the locking element (17). Coupling device (1) according to claim 3, characterized in that the coupling element (24) is connected to a coupling plate (21), both of which are made of flat sheet metal pieces, which coupling plate (21) is substantially rectangular in shape and abuts against the other side (18), having an I-shaped hole (32) in its center, which encloses the axis of rotation (3), which is also I-shaped for transmitting the driving force to the coupling plate (21), flat-laid. towards the other side side surface (18), which in the middle of its two opposite short sides each has its own edge area (33), which has at least half a joint (23) in the form of a fold (34) in a piece of the edge area (33) , which is coupled to the corresponding second half of the joint (23) there to transmit the torque to the coupling element (24), formed as a semicircular segment, one end of which is a straight side, which has at least one corresponding fold (34), which coupling element ( 24) other end consists of the periphery of the semicircle segment having at least one fold (34) in the form of a hook function (42), 13 to hook the gripping element (26) and transmit the torque to it and to stop against the stop surface (25). Coupling device (1) according to claim 4, characterized in that the friction surface (28) is arranged on a box-shaped loose part (41), which is resiliently fitted in a hole (37) arranged in the outside (29), that in the hole (37) ) spring out from it, which friction surface (28) presses on towards the inside (14) with at least one resilient element (40) behind the loose part (41). Coupling device (1) according to claim 4, characterized in that the first end (22) has a steel spring (35) which springs back against the coupling element (24) to press it in a direction towards the second side surface (18) and at the same time press the coupling plate (21) and the circular disc unit (9) against the inside (11) with a resilient spring pressure. Coupling device (1) according to claim 4, characterized in that the hook function (42) randomly touches the gripping element (26), which is a flat piece of sheet metal, extending radially out from the other end (27), one side of which faces the hook function (42). ) then strikes it without gripping it in a position when the hook function (42) is located on the flat surface (31), which gripping element (26) is resiliently radially connected to the other end (27), which flat piece of sheet metal then springs back and which hook function (42) instead grips the gripping element (26) during continued rotation during the next turn. 9. Coupling device (1) according to claim 4, characterized in that the stop surface (25) is a resilient stop surface (25), wherein. when the projection (43) is rotated towards the stop surface (34) (25), having one (45), at least a part of (31) (39) another fold (25) is moved along the flat surface in the form of a stop plate stop surface stretching until it stops in a circular (25), stop position and rotates (9) back the projection disc unit against the stop surface (43) which presses by springing back, when the rotating function (2) is released, when the locking element (17) moves freely from the tooth formations ( 16) and which projection (43) then slides down for the inclined surface (30) to the flat part (36), Coupling device (1) that one side surface according to claim (10) (9) arranged plastic disc 4, Jcänrxeteackxaad av 'vid the disc unit (11) the rotation of the circular slides towards at least one towards the inside (44), which is made of a material with low friction such as e.g. nylon. Coupling device (1) in that two opposite mirror faces (25), (31) according to claim 8, käzzneizeclcnaci and resilient stop surfaces (30) flat surfaces inclined surfaces with an intermediate flat part are arranged at the periphery (12) on the second side surface (18) , the rotary shaft (25) and in the other direction counterclockwise, whereby when locking the locking function, rotating in one direction towards one of the stop surfaces (3) unlocking, the rotary shaft is rotated the other stop surface (25).