EP3029226B1 - Electro locking unit - Google Patents

Description

The present invention relates to an electric locking unit according to the preamble of claim 1 and a cabinet according to claim 13.
Various devices are known from the prior art, lock the doors of cabinets and release for opening. For example, mechanical locks or electrically operated locks are known. Disadvantage of the known devices is that the motor-operated electric locks and locking units of the prior art in the de-energized state block the lock or the lock and the door of a cabinet can not be closed. This leads in particular to jewelery cabinets to an increased security risk and facilitates burglars and unauthorized persons access to the stored in the cabinets valuables. An electric locking unit according to the preamble of claim 1, for example, in US 2006/267349 A1 shown. It is therefore an object of the present invention to provide an electric locking unit of the type mentioned, which is easy to control and on the one hand allows reliable opening and closing of a cabinet and on the other hand automatically secures the closed door of the cabinet in the de-energized state and a closure also reliably enabled in the de-energized state.

This object is solved by the characterizing features of claim 1.

By providing the free state, the introduction of the closing part in the closing opening is made possible even in the de-energized state, since the locking bolt is still displaced.
Particularly advantageous embodiments of the electric locking unit are defined by the features of the dependent claims:

To bring the locking pin automatically into the recess of the closing part is provided that the locking pin has a tapered to the closing part bevel, wherein the electric locking unit has an engaging the locking pin spring, wherein the locking pin can be pressed or pulled by the spring in the recess of the locking bolt and wherein upon insertion of the closing part in the displacement path of the locking bolt, the bevel of the locking bolt by the closing member is pressurizable and the locking pin against the force of the spring in the open state is displaced.
The closing part can also be held in the open state in the displacement of the locking bolt when the electric locking unit comprises a magnet, wherein the magnet is arranged on the locking pin and wherein the closing part consists of a magnetic or ferromagnetic material and by the magnet in the open state of Locking bolt in the closed state, in particular in the displacement of the locking pin, is durable.

A preferred embodiment of the invention is provided when the crank disc is arranged eccentrically on the shaft of the electric motor.
The locking bolt can be easily adjusted when the cam track is formed as a recess, in particular as a closed groove or groove track, in the link disk, wherein the cam track in particular has an elliptical shape.
A preferred embodiment of the invention is provided in that the curved path has two points (A, B), which preferably have the greatest distance to one another on the curved path, wherein the extension and thus the locking bolt can be adjusted linearly and brought into the three states along the curved path , Wherein when covering the extension with one of the points (A, B) of the cam track of the locking pin is in the closed state and, preferably maximally, protrudes into the recess of the closing part, wherein when covering the extension with the other of the Points (A, B) of the locking pin is in the open state and out of the recess of the closing part, preferably maximum, is extended.

The electric locking unit can be particularly easily brought into the free state when the cam track of the link plate in the direction of the open position of the locking pin has a freewheel recess, wherein the freewheel recess between the two points (A, B) and in a third Point (C) protrudes into the curved path, wherein the extension of the locking bolt in the free state with the third point (C) is brought into coincidence and the freewheel recess along the axis of the locking bolt extends and wherein the extension in the freewheel recess along the axis of the locking bolt with the locking pin in a displacement of the locking pin is mitverschiebbar.

It is advantageously provided that the third point (C) is adjustable in the free state in the displacement of the extension upon rotation of the link plate.

For automatic locking of the electric Verrieglungseinheit is provided that the electric locking unit comprises a switch, wherein the switch in the free state upon movement of the locking bolt in the direction of the open state is switchable, and wherein the locking pin upon actuation of the switch by the drive in the closed state is slidable or adjustable.

A rotation of the locking bolt can be easily prevented if the locking pin has an anti-rotation device to prevent the rotation of the locking bolt about its axis, wherein the rotation is designed in particular as a guided in a guide pin.

A preferred embodiment provides that the closing part is designed as an L-shaped or T-shaped profile.

It is a further object of the invention to provide a cabinet with an electric locking unit according to the invention.

This object is solved by the features of claim 13. It is envisaged that the cabinet at least one door and an inner space bounded by the door , wherein the cabinet has an electric locking unit according to one of claims 1 to 12.

• Fig. 1 zeigt eine erfindungsgemäße Elektro-Verriegelungseinheit in einer Explosionsdarstellung.
• Fig. 1 a zeigt eine weitere Ausführungsform in perspektivischer Ansicht.
• Fig. 2 bis 4 zeigen Grund-, Auf- und Kreuzriss einer erfindungsgemäßen Elektro-Verriegelungseinheit.
• Fig. 5 bis 7 zeigen einen Grund-, Auf- und Kreuzriss einer Ausführungsform der Elektro-Verriegelungseinheit.
• Fig. 8 und 9 zeigen eine Schnittansicht der Elektro-Verriegelungseinheit im geschlossenen Zustand.
• Fig. 10 und 11 zeigen eine Schnittansicht der Elektro-Verriegelungseinheit im offenen Zustand.
• Fig. 12 und 13 zeigen eine Schnittansicht der Elektro-Verriegelungseinheit im freien Zustand.
• Fig. 14 bis 18 zeigen Ansichten einer Ausführungsform einer Kulissenscheibe.
• Fig. 19 zeigt eine weitere Ausführungsform einer erfindungsgemäßen Elektro-Verriegelungseinheit.
• Fig. 20 und 21 zeigen eine Schnittansicht einer weiteren Ausführungsform der Elektro-Verriegelungseinheit im geschlossenen Zustand.
• Fig. 22 und 23 zeigen eine Schnittansicht einer weiteren Ausführungsform der Elektro-Verriegelungseinheit im offenen Zustand.
• Fig. 24 und 25 zeigen eine Schnittansicht einer weiteren Ausführungsform der Elektro-Verriegelungseinheit im freien Zustand.

Unauthorized opening of the cabinet can be easily prevented when the electric locking unit is arranged in the interior of the cabinet and the closing part is arranged on the door of the cabinet, wherein in the open state of the electric locking unit, the closing part of the electric locking unit can be brought out and the door is openable.
A preferred embodiment of the cabinet provides that the cabinet has a detector, in particular proximity switch, wherein the detector with the closed state of the door is detectable, the detector in particular a magnet attached to the door and a in the interior of the cabinet, in particular in the Electric locking unit, arranged magnetic detector has.
Further advantages and embodiments of the invention will become apparent from the description and the accompanying drawings.
The invention is illustrated schematically below with reference to particularly advantageous, but not limiting exemplary embodiments in the drawings and is described by way of example with reference to the drawings:

• Fig. 1 shows an inventive electric locking unit in an exploded view.
• Fig. 1 a shows a further embodiment in perspective view.
• Fig. 2 to 4 show basic, top and bottom elevation of an electric locking unit according to the invention.
• Fig. 5 to 7 show a bottom, top and bottom elevation of an embodiment of the electric locking unit.
• 8 and 9 show a sectional view of the electric locking unit in the closed state.
• 10 and 11 show a sectional view of the electric locking unit in the open state.
• FIGS. 12 and 13 show a sectional view of the electric locking unit in the free state.
• FIGS. 14 to 18 show views of an embodiment of a link plate.
• Fig. 19 shows a further embodiment of an electric locking unit according to the invention.
• FIGS. 20 and 21 show a sectional view of another embodiment of the electric locking unit in the closed state.
• FIGS. 22 and 23 show a sectional view of another embodiment of the electric locking unit in the open state.
• FIGS. 24 and 25 show a sectional view of another embodiment of the electric locking unit in the free state.

Fig. 1 shows an exploded view of an embodiment of the inventive electric locking unit 10 for locking cabinets, such as jewelery cabinets, in a perspective view and Fig. 1a a perspective view of the electric locking unit 10. The electric locking unit 10 includes a housing 22 and a closing part 3, which is formed in this embodiment as an L-shaped profile part. The closing part 3 has at its short end a centrally arranged recess 5. The housing 22 is cuboid and has a rectangular closing recess 23 on one of its long sides. The housing 22 is further penetrated by an inserted on a narrow side through hole 24. The through hole 24 extends from this narrow side of the housing 22 to the closing recess 23 and opens vertically into the closing recess 23. In the through hole 24, a cylindrical locking pin 1 is inserted ( Fig. 1a ). The locking pin 1 has an anti-rotation, which prevents rotation of the locking pin 1 in the through hole 24. The rotation in this embodiment has a formed on the locking pin 1 pin 18 and designed as a slot in the housing of the electric locking unit 10 guide 17. The pin 18 protrudes when inserted locking pin 1 in the guide 17 and is guided in this ( Fig. 9, 11, 13th ).

The electric locking unit 10 further comprises a drive, that is, in this embodiment, an electric motor 2 and an adjusting unit. The adjusting unit is used as a link disc 4 ( FIGS. 14 to 18 ) and is seated on the shaft 25 of the electric motor 2. The link plate 4 is arranged eccentrically on the shaft 25 of the electric motor 2 and is formed as a circular disc. On the link plate 4, a curved path 12 is formed ( Fig. 8, 10, 12th and 14 ). The cam track 12 is formed as a recess and forms a closed and elliptical groove path. The curved path 12 is in the Fig. 8, 10, 12th and 14 shown in more detail. Upon rotation of the crank plate 4 by the drive, the cam track 23 allows the adjustment of the locking pin. 1 along its axis 21. The locking pin 1 comprises on the circumference of an extension 11 which projects into the cam groove 12 formed as a recess. The diameter of the extension 11 is slightly smaller than the width of the cam track 12, so that the extension 11 can slide in the cam track 12. The shape of the cam track 12 allows the adjustment of the locking pin 1 by the rotation of the crank plate 4 in three states, ie in an open ( 10 and 11 ), a closed ( 8 and 9 ) and a free state ( FIGS. 12 and 13 ). The extension 11 is thereby along the curved path 23 with three arranged on the curved path 23 points A, B and C ( Fig. 14 ). The points A and B have the greatest distance on the cam track 12 and mark the maximum opening and the maximum closed state of the locking bolt 1 and the electro-Verrieglungseinheit 10th

8 and 9 show the electric locking unit 10 in the closed state in sectional views. The locking pin 1 is in the front position and is fully extended. The locking bolt 1 is introduced into the recess 5 of the closing part 3 and blocks it, so that leakage of the closing part 3 from the electric locking unit 10 is prevented ( Fig. 9 ). The extension 11 of the locking pin 1 is brought into coincidence with the point A. The extension 11 of the locking pin 1 is held by the link plate 4 in the extended position, since the cam track 12 fixes the extension 11 in this position by a support on the wall of the cam track 12 of the crank plate 4.

10 and 11 show sectional views of the electric locking unit 10 in the open state. The locking pin 1 is in the open, retracted, rear state and is maximally extended from the recess 5 of the closing part 3. The extension 11 blocks a further displacement of the locking bolt 1 along its axis 21 by the support of the extension 11 on the wall of the cam track 12 of the crank plate 4. The closing part 3 is released and can be discharged from the closing recess 23. The locking pin 1 has a magnet 8, which is arranged on the closing part 3 facing the end of the locking bolt 1. The magnet 8 holds the existing of a magnetic or ferromagnetic material closing part 3 within the closing recess 23 and prevents falling out or accidental leakage of the closing part 3 from the Schließausnehmung 23. The magnet 8 is so matched to the closing part 3, that an automatic opening the closing part 3 is not possible, but by the action of a tensile force on the closing part 3 in the direction of the closing recess 23, For example, by a user, the closing part 3 can be opened, that is, discharged from the closing recess 23 or led out.

FIGS. 12 and 13 show sectional views of the electric locking unit 10 in the free state of the extension 11 is with the point C in coverage. The link plate 4 has in this position a along the axis 21 of the latch bolt 1 extending freewheel recess 13. The freewheel recess 13 extends from the point C parallel to the axis 21 of the locking pin 1 in the direction of the pivot point or center of the crank plate 4. The width of the freewheel recess 13 corresponds at least to the width of the cam track 12, so that the extension 11 in the freewheel Can slide recess 13 along and the locking pin 1 can be moved freely. The length of the freewheel recess 13 corresponds at least to the minimum displacement of the locking bolt 1, ie the displacement of the locking bolt along its axis 21 is required to extend completely out of the recess 5 of the closing part 3. In the free state of the locking pin 1 is thus independent of the rotational movement of the crank plate 4 along its axis 21 freely adjustable.

The locking pin 1 has at one of its ends a tapered bevel 7. The chamfer 7, in the inserted state of the locking bolt 1 in the direction of the outside of the electric locking unit 10, ie the closing part 3 out. At the opposite end of the bevel 7 of the locking bolt 1, the locking pin 1 is hollow and has a spring opening 26. In the spring opening 26, a spring 6 is inserted in this embodiment, which is supported at one end in the locking bolt 1 and at the other end to a housing cover 27 of the housing 22. The spring 6 is a spiral compression spring. The closing part 3 can be introduced again in the free state of the locking bolt 1, for example, after previous removal from the closing recess 23 in this. The closing part 3 strikes the bevel 7 of the locking bolt 1 and exerts a compressive force on it, as a result of which the locking bolt 1 is moved counter to the spring force of the spring 6 and tensions the spring 6. The extension 11 of the locking pin 1 dips into the freewheel recess 13 and the locking pin 1 gives the closing part 3 the way into the closing recess 23 free. Once the recess 5 of the closing part 3 in the adjustment of the locking pin 1, the locking pin 1 is extended by the spring force of the spring 6 again and pressed into the recess 5 of the closing part 3 and held in this state, the closed state. The closing part 3 can thus not be deployed again from the electric lock 10 or the closing recess 23 and the electric locking unit 10 is automatically closed again and the locking bolt 1 is in free condition. By the spring 6, the electric locking unit 10 is thus without actuation of the crank plate 4, for example in a power failure or a manipulation of the lock, closed and can only be reopened again when the control and the adjustment to the open state.
In Fig. 1 and 2 the electric locking unit 10 further includes a board 28 and a cable 29 connected to the board 28. The board 28 controls the electric motor 2 and is powered by the cable 29 with power. On the board 28, a switch 14 is disposed in the region close to the locking bolt. The switch 14 is actuated upon displacement of the locking pin 1 in the open state and outputs to the board 28, an electrical signal. In this embodiment, the switch 14 is mechanically actuated by a control pin 30 which is fixed to the locking pin 1, as the control pin 30 slides past the switch 14.
The electric locking unit 10 is used according to the invention for locking and locking cabinets. The installation of jewelery cabinets has proven to be particularly advantageous. The housing 22 of the electric locking unit 10 is mounted in the interior of the cabinet. The closing part 3 is fixed to the door of the cabinet and bolted to the holes 31 on the door. The closing part 3 is fastened to the door in such a way that when closing the door, the closing part 3 is introduced into the closing recess 23 of the electric locking unit 10 and can be brought into the adjusting path of the locking bolt 1.
In one embodiment of the electric locking unit 10, this has a magnetic detector 32 ( Fig. 1 and 2 ). On the door of the cabinet, a magnet is attached in the effective range of the magnetic detector. When the door is closed, the magnetic detector 32 indicates the closed state of the door. Thus, unauthorized opening of the door or breakage can be detected and a signal, such as an alarm, issued. Alternatively, a mechanical sensor pin can report the condition of the door.
Fig. 19 shows a further embodiment of the electric locking unit 10 according to the invention, the closing part 3, instead of the magnet 8 described above, held in this embodiment by a spring 31 in the closing recess 23. The spring 31 is designed as a pair of pliers with two opposing tong arms 35. The pliers arms 35 have spiral shape and consist of a Spring wire. The pliers arms 35 comprise the closing part 3 at the end inserted into the closing recess 23 and clamp it, whereby the closing part 3 is held in the closing recess.

Fig. 20 to 25 show a further embodiment of the electric locking unit 10 according to the invention. The locking pin 1 has a recess 33. The recess 33 is arranged on the cam plate 4 facing peripheral portion. The link plate 4, in this embodiment, an eccentric pin 34, which projects into the recess 33 of the locking pin 1. In FIGS. 20 and 21 the electric lock unit 10 is shown in the closed state. The eccentric pin 34 lies in the axis of the locking bolt 1 and has the maximum smallest distance to the closing opening 5. The locking pin 1 is pressed by the spring 8 in the recess 5 of the closing part 3, wherein the extension path is limited by the eccentric pin 34 and the size of the recess 33 of the locking bolt 1.

FIGS. 22 and 23 shows the electric lock unit 10 in the open state. The link disc is rotated in relation to the closed state by 180 ° about its own axis. The eccentric pin 34 is located at a maximum distance from the recess 5 of the closing part. 3

FIGS. 24 and 25 show the electric lock unit 10 in the free state. The link plate 4 is rotated by 90 ° degrees to the open or closed state, the eccentric pin 34 is in an intermediate position.

Alternatively, the closing part 3 may also be T-shaped and thus achieve better load distribution.

Hereinafter, the operation of the electric lock unit 10 will be described by way of example with reference to the drawings.

The electric locking unit 10 is located as in 8 and 9 shown in the closed state. The extension 11 is in coincidence with the point A and the extension 11 is locked by the wall of the cam track 12, whereby the locking pin 1 is not adjustable. The locking pin 1 is in the maximum extended state and is introduced into the recess 5 of the closing part 3. If an attempt is then made to open the door, an attempt is made to remove the closing part 3 from the door Apply locking recess 23, this blocks the locking pin 1, thus preventing the door from opening.
If a signal is transmitted to the board 28 by the user via a switch or a remote control, this controls the electric motor 2 in the open state ( 10 and 11 ). The electric motor 3 rotates the link plate 4, in this embodiment, in a clockwise direction until the extension 11 is brought into coincidence with the point B. The extension 11 is adjusted parallel to the axis 21 of the locking bolt 1 and the locking pin 1 is guided in the rear open position, the open state, and is then in the open state. The locking pin 1 is fully extended from the recess 5 of the closing part 3 and the spring 6 stretched. The magnet 8, alternatively the spring ( Fig. 19 ), keeps the closing part 3 still in the closed state. If now the door with the closing part 3 attached thereto is opened against the holding force of the magnet 8, the closing part 3 exits the closing opening 23 and the door is open. Now, a signal is output, for example, from the magnetic detector 32 to the board 28, which carries a switching unit. Since the magnet attached to the door is no longer detected and adjusted the electric motor 2, the crank plate 4 in the free state. The extension 11 is brought into coincidence with the point C and the locking pin 1 is pushed by the spring 6 in the closed state.

If now the closing part 3 is again introduced into the closing recess 23, ie the door is closed, the closing part 3 strikes the bevel 7, presses the locking bolt against the spring force into the open position and the locking bolt 1 gives the closing part 3 the way into the closing recess 23 completely free. As soon as the closing part 3 is introduced into the closing recess 23, the recess 5 is brought into the displacement of the locking bolt 1 and this moves off again. In this case, the spring 6 moves the locking pin 1 in the recess 5 and blocks a renewed escape of the closing part 3 from the electric lock 10. The magnetic detector 32 again signals the presence of the magnet on the door and the switching unit of the board 28 gives a control command to the Electric engine 2 off. The electric motor 2 rotates the link plate 4 again in the closed state, the extension 11 is brought into coincidence with the point A and the locking pin 1 blocks and fixes the closing part 3 until the board 28 again gives the signal to open.

Alternatively to the described detection of the open and closed state by means of a magnet on the door and a magnetic detector 32, the board 28 and the electric motor 2 can also be actuated by a signal of the switch 14. If the locking pin 1 is moved from the closed to the open state, actuates the Control pin 30 when driving past the switch 14, which then transmits a signal to the board 28 and adjusted after a time delay, the locking pin 1 in the free state. If the locking bolt 1 is adjusted again by inserting the closing part 3 into the closing opening 23, the switch 14 again outputs a signal and the board 28 gives the command to move the locking bolt 1 into the closed state.

Claims (15)

1. An electric locking unit, in particular for locking of jewelry cabinets, comprising a locking bolt (1) that is insertable into a recess (5) of a closing part (3), an electric drive and an adjustment unit that engages the locking bolt (1), wherein the locking bolt (1) is linearly adjustable by the drive via the adjustment unit along the axis (21) of the locking bolt (1) into at least three states, a closed, an open and a free state, wherein the locking bolt (1) in the closed state protrudes into the recess (5) of the closing part (3) at least partially, wherein the locking bolt (1) in the open state is extended out of the recess (5) of the closing part (3) and wherein the locking bolt (1) in the free state, at least partially independently of the adjustment unit, is freely displaceable or adjustable for the re-introduction of the closing part (3) into the electric locking unit (10), and wherein the electric drive is an electric motor (2), characterized in that
   the adjustment unit is designed as a link disc (4), wherein the link disc (4) is arranged on the shaft of the electric motor (2), wherein the locking bolt (1) comprises an extension (11) that projects into a cam track (12) formed on the link disk (4) and wherein the locking bolt (1) is adjustable by means of an adjustment of the extension (11) along the cam track (12) of the link disc (4) during rotation of the link disc (4) along said locking bolt's axis (21) and that in the closed position the extension (11) of the locking bolt (1) is held in the extended position by the link disc (4).
2. The electric locking unit according to claim 1, characterized in that the locking bolt (1) has a chamfer (7) point-tapering toward the locking part (3), wherein the electric locking unit (10) comprises a spring (6) that engages the locking bolt (1), wherein the locking bolt (1) can be pushed or pulled into the recess (5) of the locking bolt (1) by the spring (6) and wherein, through the introduction of the locking part (3) into the displacement path of the locking bolt (1), pressure can be applied to the chamfer (7) of the locking bolt (1) by the locking part (3) and the locking bolt (1) can be slid into the open position state counter to the force of the spring (6).
3. The electric locking unit according to any one of claims 1 or 2, characterized in that the electric locking unit (10) comprises a magnet (8), wherein the magnet (8) is disposed on the locking bolt (1) and wherein the locking part (3) is made of a magnetic or ferromagnetic material and is holdable in the closed state, in particular in the displacement path of the locking bolt (1), by the magnet (8) in the open state of the locking bolt (1).
4. The electric locking unit according to any one of the previous claims, characterized in that the link disc (4) is disposed eccentrically on the shaft of the electric motor (2).
5. The electric locking unit according to claim 4, characterized in that the cam track (12) is designed as a depression, in particular as a closed groove or groove track, in the link disc (4), wherein the cam track (12) has in particular an elliptical shape.
6. The electric locking unit according to claim 4 or 5, characterized in that the cam track (12) comprises two points (A, B) that preferably are separated relative to one another by the greatest distance on the cam track (12), wherein the extension (11) and therefore the locking bolt (1) is linearly adjustable along the cam track (12) and is placable into the three states, wherein, if the extension (11) is aligned with one of the points (A, B) of the cam track (12), the locking bolt (1) is in the closed state and protrudes, preferably maximally, into the recess (5) of the locking part (3), and wherein, if the extension (11) is aligned with the other of the points (A, B), the locking bolt (1) is in the open state and is extended from the recess (5) of the locking part (3), preferably maximally.
7. The electric locking unit according to claim 6, characterized in that the cam track (12) of the link disc (4) comprises a free-run recess (13) in the direction of the open position of the locking bolt, wherein the free-run recess (13) is positioned between the two points (A, B) and protrudes at a third point (C) into the cam tracks (12), wherein the extension (11) of the locking bolt (1) is brought into alignment with the third point (C) in the free state and the free-run recess (13) extends along the axis (21) of the locking bolt (1), and wherein the extension (11) in the free-run recess (13) is slidable along the axis (21) of the locking bolt (1) with the locking bolt (1) during the displacement of the locking bolt (1).
8. The electric locking unit according to claim 7, characterized in that the third point (C) is adjustable into the displacement path of the extension (11) during the during rotation of the link disc (4) into the free state.
9. The electric locking unit according to any one of the previous claims, wherein the electric locking unit (10) comprises a switch (14), wherein the switch (14) in the free state is switchable in the direction of the open state during the movement of the locking bolt (1), wherein the electric locking unit (1) is slidable of adjustable into the closed position by the drive during activation of the switch (14).
10. The electric locking unit according to any one of the previous claims, characterized in that the locking bolt (1) has a twist protection for protection against the rotation of the locking bolt (1) about its axis (21), wherein the twist protection is designed in particular as a pin (18) guided in a guide (17).
11. The electric locking unit according to any one of the previous claims, characterized in that the locking part (3) is designed in an L-shaped or T-shaped profile.
12. The electric locking unit according to any one of the previous claims, characterized in that the link disc (4) comprises an eccentric bolt (34) that is disposed eccentrically toward or relative to the rotation axis of the drive, wherein the locking bolt (1) comprises a recess (33), wherein the eccentric bolt (34) protrudes into the recess (33) of the locking bolt (1) and wherein the locking bolt (1) is adjustable during the rotation of the link disc (4) along its axis (21) through the adjustment of the eccentric bolt (34) in the recess (34) of the locking bolt (1).
13. A case, in particular a safe case, with at least one door and an interior space delimited from the door, characterized in that the case comprises an electric locking unit (10) according to any of the claims 1 to 12.
14. The case according to claim 13, characterized in that the electric locking unit (10) is disposed in the interior space of the case and the locking part (3) is disposed on the door of the case, wherein in the open state of the electric locking unit (10) the locking part (3) is removable from the electric locking unit (10) and the door is openable
15. The case according to claim 13 or 14, characterized in that the case comprises a detector, in particular a proximity switch, wherein the closed state of the door is detectable with the detector, wherein the detector comprises a magnet attached in particular to the door and a magnet detector (32) disposed in the interior space of the case (20), in particular in the electric locking unit (10).

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