DE19834432A1 - Device for the selective transmission of energy between two transmission units - Google Patents

Abstract

The device according to the invention has two transmission units (10, 20) arranged in a respective carrier element (1, 2), the second transmission unit (20) being arranged in the vicinity of a consumer (5). The second transmission unit (20) actuates at least one contact pin (K) via a switching cam (N) and thus brings this into one of two stable final states depending on the actuation.

Description

The present invention relates to an optional device Transferring energy between two transmission units. Such Devices are known for example in connection with doors.

These known devices are found for example in such Doors use, the so-called security locks with branches shared trigger nuts, and in which the two handles Nut parts electrically, preferably electromagnetically with one another can be coupled. The coupling used is part of the Castle and thus trained in the door. Such a sure thing Unit lock is known from DE-C 44 07 244.

In the case of doors with such security locks, it is naturally necessary to give the door leaf the current or the voltage required to actuate the coupling (in general terms:
to be able to supply the energy required for actuation). So far this has been the case with doors (for example called) from the door frame to the so-called hinge side of the door, ie, to the side of the door where it is attached to the door frame.

Disadvantage of this type of energy transfer is that ver turned contacts on the side of the door facing away from the lock tes are arranged so that when you close the door in the Contact other door contacts arranged. This is the half disadvantage because the electromagnetically operated dome tion is part of the lock and thus the clutch pre gear-producing coil also part of the lock  is. Therefore, electrical cables must be routed in the door are from the one side where the contacts are ("Hinge side"), up to the other side of the door ("Opposite hinge side") where the lock is located.

The object of the present invention is a device to selectively transfer energy so that the the installation effort required for this is kept as low as possible can be.

This object is achieved by means of the features according to the patent Claim 1. It is provided that the device two Has transmission units, each in a carrier element are arranged. One carrier element is related of the other support element arranged movably. The one Transmission unit has contacts. The other transfer unit then effects the desired energy transfer active when both carrier elements are in a given bottom sition to each other (with door: closed state). That will be a carrier element from this given position moved out, the other transmission unit interrupts the Energy transfer active due to this movement.

The advantages of the device according to the invention are in particular:

• - when retrofitting existing lock units with locks, to which energy is to be supplied are on the door (for example) leaf changes only necessary in the area of the castle,
• - With an electric door opener that is already available only minimal changes to the existing electri necessary installation,
• - for the second support element (for the door example: for the door sheet) are also minimal in the case of retrofitting Work necessary.

A particular advantage of the device according to the invention is that it (also) applicable to support elements  is that perform shear movements in the case of actuation.

The invention is based on the drawing he he purifies. Show:

Figs. 1 and 2, various arrangements of the Übertra supply units with respect to the support elements and
FIGS. 3 and 4, a transfer unit in its two states.

Fig. 1 shows as a first support member 1 a door frame and as the second carrier element 2 a door leaf. The door leaf is assumed to be rotatable with respect to the door frame. However, the invention is also applicable to a door frame / door leaf combination designed as a sliding door or to pivot doors. Instead of the selected combination of door frame / door leaf, it is of course also possible, for example, to combine a gate leaf and gate frame or counterpart, and such a combination can also be designed to be rotatable and slidable.

In Fig. 1, a first transmission unit 10 is arranged in the door frame acting as the first support element 1 . Accordingly, a second transmission unit 20 is arranged in a second carrier element 2 designed as a door leaf. According to the invention, the second transmission unit 20 is arranged in the vicinity of a consumer, advantageously an energy-operated door lock 5 , in order to be able to keep the installation effort required in the door leaf as low as possible.

It is assumed that the first transmission unit has 10 contacts or is a contact plate. In the case of a transmission of energy in electrical form, it is also conceivable that the door leaf itself by means of its door cone represents at least two electrically necessary connections for the door lock (for example in the case of a metal door), and thus it is also possible that the first transmission unit contains only a single contact. Contact is generally understood to mean any conceivable geometric design, such as a contact pin (solid or hollow), contact surface or contact hole.

Fig. 2 differs from Fig. 1 only in the arrangement of the transmission units 10 , 20 with respect to the carrier elements 1 , 2 : While in Fig. 1 the first transmission unit 10 is arranged in the first carrier element 1 and the second transmission unit 20 in the second 2 , it is exactly the opposite in the arrangement according to FIG. 2: In FIG. 2, the first transmission unit 10 is arranged in the second carrier element 2 and, accordingly, the second transmission unit 20 is arranged in the first carrier element 1 .

The arrangements of the devices according to the invention according to FIGS. 1 and 2 offer the advantage that the supply of the lock 5 with energy requires minimal installation effort. The cable routing in the door leaf is simplified since the transmission units 20 ( FIG. 1) or 10 ( FIG. 2) can be arranged close to the lock 5 .

When converting a lock that interacts with an electric door opener to a security lock with a two-part, coupled lever follower, there is the following advantage: Since the electric door opener is not required in such a case, the existing electrical installation for its power supply can be used , ie their line (reference number 15 in FIGS. 1 and 2) with minimal effort to the first transmission unit 10 ( FIG. 1) or the second transmission unit 20 ( FIG. 2) are ruled out.

According to the invention it is now further provided that the second transmission unit 20 causes the energy transfer ac tively in the case in which the two support elements 1 , 2 (in the example: door and door frame) are in a predetermined position to each other, namely when the Door (or gate) is closed. This applies both to a hinged door leaf hinged on one side (shear actuation of the contacts) and to a sliding door. This is still the case even for a revolving door. If the door is now opened, ie the door leaf is moved out of its given position, the second transmission unit 20 actively interrupts the energy transmission.

The second transmission unit 20 is shown in more detail in FIGS. 3 and 4. Fig. 3 shows the second transmission unit 20 with the door open, that is, the second carrier element 20 is rotated or pushed onto its position relative to the first carrier element 1 (corresponds here to the door frame). Fig. 4 shows the second transfer unit 20 in its predetermined position.

The second transmission unit 20 has a switching cam N, which is articulated, for example, on one side to the second transmission unit 20 via a pin 24 , and at least one longitudinally displaceably mounted contact pin K, which can be bolt-like or hollow. The direction of movement of the contact pin K and the pivoting direction of the switching cam N are the same. Both are coupled with each other in such a way that they execute their movements in opposite directions and that they flip-flop-like each occupy two stable end positions, which are shown in FIGS. 4 and 5.

The switching cam N is supported against a spring-loaded, longitudinally displaceably mounted pin 21 which runs parallel to the contact pin K. The contact pin K is operatively connected to the spring-loaded pin 21 using a rigid web 22 , which is articulated to the contact pin K, and a leaf spring 23 , which in turn is connected on the one hand at its base to the web 22 and on the other hand with the spring-loaded pin 21 (a spring spring S is shown in FIGS. 3 and 4 as a spring load for the pin 21 ).

The articulation of the web 22 on the contact pin K takes place in the example shown via an annular groove 25 on the contact pin K, in which the fork-shaped free end of the web 22 engages. The other end of the web 22 is fixed in a housing and articulated bearing 26 and articulated. The web 22 forms a pivot lever which is deflected by the contact pin K. With this deflection, a base point 27 of the leaf spring 23 , which is arranged as close as possible to the free end of the web 22 , is also deflected and changed relative to the position of the other base point 28 on the control pin 21 .

The relative positions of the two base points 27 , 28 change in the same way when the control pin 21 is moved and the associated base point 28 follows the movement.

The leaf spring 23 passes through such a position change a dead center at which its direction of action changes. In the end points shown in FIG. 3, the leaf spring 23 is directed in the same way as the spiral spring S. The leaf spring 23 presses the control pin 21 completely in its extended position and holds it there together with the switching cam N. At the same time it presses the contact pin K into its retracted position and holds it there.

If the switch cam N is pressed from this extended position together with the control pin 21 against the force of the spiral spring S inwards, the associated foot point 28 of the leaf spring 23 passes through its dead center and the reversal of the spring force causes the contact pin to move into its extended position Position is pushed and held there, as shown in Fig. 4.

If the pressure on the switching cam N is removed, the spiral spring S pushes the switching pin 21 outwards again, the associated base point 28 passes through the dead center and the entire arrangement assumes the position according to FIG. 3.

With an arrangement of the second transmission unit 20 in the second carrier element 2 , ie with an arrangement according to FIG. 1, the spiral spring S presses the switching cam N in the direction outside the second transmission unit 20 when the door is open, ie the second carrier element 2 . The spring force P of the spring 23 thus presses the web 22 in Rich direction interior of the second transmission unit 20 , whereby the contact pin K is held inside the second transmission unit 20 ; it does not protrude (or at least hardly worth mentioning) from the second transmission unit 20 . If the door is now closed, the switching cam N first presses against the door frame, ie against the first carrier element 1 (arrangement of the transmission units 10 , 20 according to FIG. 1). As the closing continues, the back pressure exerted by the door frame, ie the door frame, on the switching cam N is greater than the spring force of the spiral spring S, so that the switching cam N is pressed in the direction of the interior of the second transmission unit 20 . This takes the Kraftkompo component of the spring in the direction of the connection to the web 22 due to the articulation of the web 22 on the contact pin K and the housing and the connection of the spring 23 to the web 22 on the one hand and the pin 21 on the other hand, and then changes their direction with renewed increase, so that the contact pin K is moved in the direction of the second transmission unit 20 . This then has the consequence that when the door is now closed, the contact pin K presses stably against the first transmission unit 10 and thus establishes an electrical connection with the latter. For example, the above mentioned coupling of two parts of the follower of a lock can be effected electrically.

If the door is now opened again, the Schaltnoc ke N slides away from the door frame, whereby it is pressed by means of the spiral spring S outside of the second transmission unit 20 . With regard to the spring force P of the spring 23 and its action on the web 22 (and thus on the contact pin K), the reverse effect occurs as described above: from a certain position of the switching cam N, the contact pin K becomes towards the inside of the second transmission unit 20 pulled, which interrupts the energy transfer again. Depending on the positions of the two carrier elements 1 , 2 relative to one another, actuation of the switching cam N causes the contact pin K to be extended and retracted and thus a transmission of the energy or an interruption of this transmission insofar as the first transmission unit 10 supplies energy is (arrangement of the transmission units 10 , 20 corresponding to FIG. 1).

When the door is closed, the control cam N is sunk in wesentli chen in the door, apart from a small part that protrudes into the distance between the door and door frame due to the action of the spiral spring S. Accordingly, the contact pin K is extended by the spring force P. as far as the first transmission unit 10 permits. When the door is open, however, the contact pin K is at least substantially sunk in the second transmission device 20 , while the switching cam N is extended with respect to the second transmission unit 20 , insofar as the mechanical construction of the switching cam N in connection with its articulation on the second transmission unit 20 allows it. Seen overall, the second transmission device 20 is a bistable element with regard to the contact pin K, ie an element with two stable end states.

Even if it was previously assumed that the contact pin K has a single contact, it lies in the Scope of the invention that it has multiple contacts can, which is at least partially electrically iso against each other  are. Furthermore, it is also in the area of ing invention that by means of a single switching cam N a plurality of contact pins K can be actuated simultaneously. There one appropriate construction for the specialist based on the message ten is easy to implement, is from a more detailed Description apart.

The invention has been described in terms of the transmission of electrical energy. However, it is also possible with the device according to the invention other energies to transmit types, in particular optical energy ("Light waves").

Claims (11)

1. Device for the selective transmission of energy between two transmission units ( 10 , 20 ),

• - in which a consumer ( 5 ) can be actuated by means of the transmitted energy,
• - in which the transmission units ( 10 , 20 ) are arranged in a first carrier element ( 1 ) and in a second carrier element ( 2 ),
• - in which the second carrier element ( 2 ) is arranged movably with respect to the first carrier element ( 1 ),
• - In which the first transmission unit ( 10 ) has at least one contact and that it ( 10 ) is preferably a contact plate,
• - In which the second transmission unit ( 20 ) actively causes the energy transmission between the two transmission units ( 10 , 20 ) when the two carrier elements ( 1 , 2 ) are in a given position to one another and which otherwise actively interrupts the energy transmission, and
• - In which the second transmission unit ( 20 ) is arranged in the vicinity of the consumer ( 5 ).

2. Device according to claim 1, characterized in that the consumer ( 5 ) is a lock which can be actuated by means of energy to be supplied. 3. Apparatus according to claim 1 or 2, characterized in that the first carrier element ( 1 ) is a door frame or a counterpart for a gate. 4. Apparatus according to claim 1 or 2, characterized in that the second carrier element ( 2 ) is a door or a gate. 5. Device according to one of claims 1 to 4, characterized, that it serves to transmit electrical energy. 6. Device according to one of claims 1 to 4, characterized characterized that they are a transmission of opti energy. 7. Device according to one of the preceding claims, characterized in that

• - That the second transmission unit ( 20 ) has a switching cam (N) and at least one actuatable contact pin (K),
• - That the contact pin (K) is arranged in an unactuated state substantially within the second transmission unit ( 20 ),
• - That the contact pin (K) protrudes from the second transmission unit ( 20 ) in an actuated state and
• - That the contact pin (K) can be actuated by means of the switching cam (N).

8. The device according to claim 7, characterized in that the switching cam (N) in a state of the least least a contact pin (K), in which it is not actuated, partially protrudes from the second transmission unit ( 20 ), and that it in a state of the at least one contact pin (K), in which it is actuated, is substantially lowered within the second transmission device ( 20 ). 9. Apparatus according to claim 7 or 8, characterized in that the at least one contact pin (K) is pressed in its actuated state by means of spring force (P) in the direction from the second transmission device ( 20 ). 10. Device according to one of claims 7 to 9, characterized in that the at least one contact pin (K) is pressed in its unactuated state by means of spring force (P) in the direction of the second transmission device ( 20 ). 11. The device according to one of claims 7 to 10, characterized characterized in that the contact pin (K) at least has a contact.