DE19541325A1 - Locking cylinder - Google Patents

Abstract

The lock cylinder (10) has a cylinder housing (12) with a bore (14) which accommodates a rotating core (18), and which has at least one bearing surface (16). A group of tumblers (20,22,24,26,28) prevents the core from rotating about its axis (A) in a locked position, and can be freed by a control element, which is especially a key. Each tumbler has a core pin (30,32) in a hole (34,36) in the core, and a housing pin (38,40) in a hole (42,44) in the housing, and the latter pin is spring- loaded towards the former. One end of each core pin is engaged by the key, and in the locked position, this end of one core pin is offset from the others, while all of the core pins have their opposite ends inside their core pin holes.

Description

The present invention relates to a locking cylinder, comprising a cylinder housing with at least one a core bearing receiving core, one in the rotate at least one core receiving bore around a core axis bar cylinder core, locking device, which the cylinder core in the core receiving bore in a locked position against rotation block the core axis and which in one by together act with a in a receiving channel of the cylinder core insertable control unit, in particular key feasible release position the cylinder core for rotation around the Release the core axis, the locking devices being a group of Pin tumblers include, each with a core pin in one provided in the cylinder core core pin bore and a housing pin in a housing pin provided in the cylinder housing bore, which housing pin is spring-loaded towards the core pin is biased, the core pins each a controller attack surface at a first end point and a housing pin contact surface on a second End.

In one of the German Patent No. 15 53 535 be Known lock cylinder is one in an axial direction of the Cylinder core extending locking pin provided on the core pin in a direction of insertion of the key the rearmost pin tumbler attacks. The locking pin presses by spring bias against a substantially cone-like trained key attack surface of this core pin rearmost tumbler so that if no key in the cylinder core is inserted (locked position), this in is a state in which, on the one hand, the control organ connection Grip surface of the associated core pin in the direction of the Core storage area is set back and on the other hand the casing pin contact surface of this core pin into the housing pin hole immersed in the cylinder housing. Through this lock cylinder design should open the locking cylinder an unauthorized person will be hampered by the idea it is assumed that this unauthorized person uses the method of  "Scanning" the locking cylinder, so try to the locking coding of the tumblers with a suitable one Tools to determine to the rest of the values to make a duplicate key. There is a consideration that the determination of the measure for the control position of the Duplicate key, which is the core acted upon by the locking pin pin corresponds, is difficult because this core pin at a scanning attempt in a falsified by the locking pin Position.

For the concept of scanning, reference is made to the German one Standard DIN 18252 lock cylinder for door locks, point 2.10 Safe to scan.

Another method frequently used by unauthorized persons for unauthorized use The opening of a locking cylinder is the so-called method called "picking" or "picking". This method is in the the following figure descriptions in detail explained. Here it is sufficient to point out that the unauthorized person is with a Picking instrument, such as a needle, into the receiving channel for retracts the key and tries the radial movement To influence core pins in their position so that the housings emerge from the core pin holes one after the other and to release a twist of the cylinder core.

This method of picking up poses a special danger as they are used for equipment by a trained unauthorized person frequently sophisticated instruments for quick opening of a locking cylinder.

The invention particularly aims to open a Lock cylinder according to the picking method with unite difficult means to complicate.

To solve this problem, a lock cylinder is featured beat, comprising a cylinder housing with at least one a core receiving bore having a core bearing surface, one in  the at least one core receiving bore around a core axis rotatable cylinder core, locking device, which the cylinder core In the core mounting hole in a locked position against rotation block around the core axis and which in one by together act with a in a receiving channel of the cylinder core insertable control unit, in particular keys feasible release position the cylinder core for rotation around the Release the core axis. The locking devices include one Group of pin tumblers, each with a core pin in a core pin bore provided in the cylinder core and one Housing pin in a housing provided in the cylinder housing pin hole. The housing pin is in the direction of spring force biased to the core pin. The core pins each have a controller attack surface at a first end and a housing pin engagement surface at a second end. In the locking position are the housing pin attack surfaces Core pins within the respective core pin holes and in the blocking position is the control surface of at least one core pin towards the governing body Grip surfaces of the other core pins towards the core storage space set back.

The advantages of this solution are detailed below ing figure description explained. The first is sufficient here Finding that access to the core pin is back set control organ attack surface by a picking-in is difficult without a spring-loaded, axially movable locking pin is required. Other characteristics result itself from the subclaims.

The lock cylinder according to the invention is referred to below described in detail on the accompanying drawings. It demonstrate:

Figure 1 is a schematic longitudinal section through an inventive locking cylinder.

Fig. 2 is a side view of a key suitable for actuating the inventive lock cylinder.

Fig. 1 shows a schematic axis-containing longitudinal section through a lock cylinder 10 of the invention. The lock cylinder 10 is a single lock cylinder Darge, as it can be used for example in cabinet doors or the like. However, it is also possible to form the lock cylinder according to the invention as a double lock cylinder, as is used, for example, in house or apartment doors accessible from both sides.

The locking cylinder 10 comprises a cylinder housing 12 with a core receiving bore 14 . The plug receiving bore 14 has a core bearing surface 16 and in the plug receiving bore 14 a mounted on the core bearing surface 16 cylinder core 18 is inserted.

The locking cylinder 10 has a plurality of pin tumblers 20 , 22 , 24 , 26 , 28 , by means of which the cylinder core 18 is blocked in a locking position shown in FIG. 1 against rotation about the core axis A within the cylinder housing 12 in a manner known per se. When inserting a key into a receiving channel 31 formed in the cylinder core 18 , the Stiftzu attitudes 20 , 22 , 24 , 26 , 28 are each moved into a release position, so that the cylinder core 18 is rotatable about the axis A.

Since the pin tumblers 20 , 22 , 24 , 26 , 28 are constructed essentially identically to one another, only the pin tumblers 26 and 28 will be described in detail below to illustrate the essential features of the present invention. The pin tumblers 26 and 28 each have core pins 30 , 32 which are inserted into corresponding core pin bores 34 , 36 in the cylinder core 18 . Furthermore, the pin tumblers 26 , 28 have respective housing pins 38 , 40 which are inserted into respective housing pin bores 42 , 44 in the cylinder housing 12 . Each of the core pins 30 , 32 has a control organ engagement surface 46 , 48 at one end and a housing pin engagement surface 50 , 52 at an opposite end. In the locking position shown in FIG. 1, the respective housing pin engagement surface 50 , 52 of the core pins 30 , 32 lies within the core pin bores 34 , 36 , so that the corresponding housing pins 38 , 40 are partially in the core pin bores due to the force of respective springs 54 , 56 34 , 36 protrude.

As can also be seen in FIG. 1, a bore depth B1 of the core pin bore 36 of the pin tumbler 28 is shorter than a corresponding bore depth B2 of the pin tumbler 26 and the pin tumblers 20 , 22 , 24 . The hole depth here generally denotes the length of the cylindrical sections of the respective core pin holes without the conical section formed at the end of the respective holes. The hole depth could also indicate the maximum depth of the respective holes in the area of the cone tip.

This has the consequence that, as shown in Fig. 1, the control organ engagement surface 48 of the pin tumbler 28 with respect to the control organ engagement surface 46 of the pin tumbler 26 and the corresponding control organ engagement surfaces of the Stiftzu attitudes 20 , 22 , 24 in the direction of the Core bearing surface 16 of the cylinder core 12 is set back. The bore depth B1 or B2 of the core pin bores 36 , 34 is therefore decisive for the positions of the core pins 32 and 30 shown in FIG. 1, since the diameter of the bores 36 , 34 is thus matched to the width of the receiving channel 31 perpendicular to the plane of the drawing, that at the inner ends of the bores 36 , 34 through the intersection of the bores 36 , 34 contact shoulders 25 in the cylinder core 18 are formed. When trying to hold the pin tumblers 20 , 22 , 24 , 26 , 28 by means of a picking needle 56 shown schematically in FIG. 1 in the sense of a change in position of the pin core 20 , 22 , 24 , 26 , 28 that allows the cylinder core 18 to rotate , The control organ engagement surface 48 of the pin tumbler 28 , as explained in detail below, is difficult for the picking needle 56 to reach.

The picking needle 56 can, for example, be a needle of a picking device, in which the needle 56 can be moved back and forth in the direction of arrows P1 and P2 and in this case strikes the control element engagement surfaces of the core pins 30 , 32 of the pin tumblers. The needle 56 can either perform single strokes or it can be operated periodically. When picking by means of a picking device, a torque is additionally applied to the cylinder core 18 about the core axis A. If the core pins of the respective Stiftzu attitudes are struck, this pulse is transmitted to the respective housing pins, so that they move against the spring force (e.g. 54 , 56 ) out of the core pin holes 34 , 36 downwards. Due to the torque applied around the core axis A, a small offset between the core pin bores 34 , 36 and the housing pin bores 42 , 44 is formed in the area of the core bearing surface 16 due to an inevitable manufacturing inaccuracy. Moving the housing pins 38, 40 after emersion from the Kernstiftboh stanchions 34, 36 again in the direction of the core pin bores 34, 36, so now is the one housing pin, which a result of the occurring tolerances in its housing pin bore the slightest game has, at hang in the area of the core bearing surface due to the offset between core pin bores and housing pin bores formed by an outer peripheral surface of the cylinder core 18 shoulder. This is because the housing pin with the least play in its bore this ter formed by the outer peripheral surface, the core school can not avoid. However, since essentially this housing pin previously blocked the Zylin derkern in the circumferential direction against rotation and this pin is no longer immersed in the core hole assigned to it, the cylinder core can continue to rotate slightly due to the torque applied to it. If the process is repeated subsequently, the individual housing pins of the pin tumblers are successively caught on the shoulders formed in the region of the peripheral surface of the cylinder core. When all housing pins are caught, the core is free to rotate within the core mounting hole.

As can be seen in FIG. 1, however, the control organ engagement surface of the pin tumbler 48 is set back in the direction of the core bearing surface 16 in relation to the other control organ engagement surfaces lying at the same height. As a result, when the individual pin tumblers are struck by the needle 56, this control element engagement surface 48 can only be reached by the needle 56 if the needle 56 has previously pushed the core pins of the pin tumblers 20 , 22 , 24 , 26 downward by an amount which corresponds to a difference between the hole depths B1 and B2. Only then does the needle 56 come into contact with the control member surface 48 and can also strike the core pin 32 . However, this means that the needle 56 must perform a relatively large stroke in the receiving channel 31 . However, since the receiving channel 31 generally has an irregular cross-sectional profile, for example a serpentine line, it is difficult to carry out such a large stroke within the receiving channel with such a needle 56 without bumping into respective profile projections in the receiving channel. It is thus made significantly more difficult, by repositioning the control element engagement surface 48 of the pin tumbler 28 , to pick up the locking cylinder according to the invention, for example by means of a picking device.

As can also be seen in FIG. 1, the length of the core pin 30 of the pin tumbler 26 is greater than the distance of the control member engagement surface 48 of the pin tumbler 28 from the core bearing surface 16 in the locked state shown in FIG. 1. The result of this is that when the needle 56 performs such a large stroke that it can also strike the core pin 32 , the core pin 30 of the pin tumbler 26 is pushed out of its core pin bore 34 so far down that it partially enters the housing pin bore 42 of the housing pin 38 assigned to it dips. This means that the moment the core pin 30 is struck and the housing pin 40 assigned to it emerges from the core pin bore 36 , the core pin 30 of the pin tumbler 26 secures the cylinder core 18 against incremental further rotation in the core receiving bore 14 . This effect can be further enhanced by the fact that a cross-sectional dimension, ie the diameter, of the core pin 30 of the pin tumbler 26 is larger than the corresponding cross-sectional dimension of the housing pin 38 assigned to it. Then, when the pin tumbler of the pin tumbler inserted upon abutment of the core pin 32 28, the core pin 30 26 through the needle 56 into the housing pin bore 42, that is by the core pin 30 and housing pin bore 42 approved rotational play for the cylinder core about the core axis A less than that of the corresponding housing pin 38 and the housing pin bore 42 or the core pin bore 34 approved rotational play. This means that the core pin 30 restricts the cylinder core 18 even more from being rotatable than the housing pin 38 assigned to it. Due to the still further limited rotatability of the cylinder core 18 is the probability that the housing pin 40 of the pin tumbler 28, which is swapped out by striking the core pin 32 out of the core pin bore 36 , subsequently gets stuck in the core pin bore 36 on a shoulder formed on the peripheral surface of the cylinder core 18 , very little. In other words, the intention underlying the picking to catch all housing pins in the area of the bearing surface 16 one after the other and to prevent them from entering the associated core pin bores is in any case difficult to achieve in the case of the pin tumbler 28 . The locking cylinder according to the invention thus provides a high level of security against picking up the pin tumblers, for example by means of a picking needle.

Regardless of the increase in cross-section of the core pin 30 made it difficult to catch the housing pin 40 returning in the direction of the cylinder core 18 , the length requirement:

Length of the core pin 30 is greater than the distance B1 of the set back control organ engagement surface 48 from the core bearing surface 16 in the locked position

A further increase in security against picking is achieved, in particular when this length requirement is met for several or all of the other pin tumblers 20, 22, 24, 26 .

For an exemplary explanation it is assumed that the above-mentioned rule for all other tumblers 20 , 22 , 24 , 26 is met. Assuming the worst case is that it has already been possible to move the associated housing pins to below the core bearing surface 16 by picking the pin tumblers 20 , 22 , 24 , 26 , and that the housing pins of the pin tumblers 20 have also succeeded , 22 , 24 , 26 in the area of the core bearing surface 16 by applying torque to the cylinder core 18 while the pin position 28 is still in the locked position according to FIG. 1, the breaker would only have to act on the core pin 32 of the pin tumbler 28 whose housing pin 40 move below the core bearing surface 16 . However, he still encounters an aggravation because the control element engagement surface 48 is then still set back downward with respect to the control element engagement surfaces of the other pin tumblers 20 , 22 , 24 , 26 , although this is at most as far as possible compared to the position according to FIG. 1 are offset below that the associated housing pin engagement surfaces 50 are flush with the core bearing surface.

Regardless of compliance with the above length specification could one of the regulation according to the invention

• In the locked position, the housing pin attack surfaces 50 , 52 of the core pins, preferably all core pins, lie within the respective core pin bores, and in addition, in the locked position, the control member attack surface 48 of at least one, and preferably only one, core pin 32 relative to the Controller attack surfaces 46 of the other core pins 30 set back in the direction of the core bearing surface 16 .

obeying the locking cylinder in its security against picking attempts to break open can also be further improved in that at least one, preferably several and best all pin tumblers 20-26 in the locked position according to FIG. 1 allow a greater rotational play when applying torque to the cylinder 18 than that Pin tumbler 28 . Then it is ensured that the housing pin 40 of the pin tumbler 28 must never be caught last in the area of the bearing surface 16 (namely on the way back from a pin hole 36 dipped out of the position towards the cylinder core 18 ), but always at least one of the Housing pins of the remaining tumblers 20-26 must be caught as the last. Then, at any point in the process of progressively catching housing pins, it always applies that the control element engagement surface 48 of the pin tumbler 28 is set back in the direction of the core bearing surface 16 with respect to the control element engagement surface at least one other pin tumbler 20-26 . This can be achieved, for example, by drilling one, preferably several, most preferably all housing pins of the pin tumblers 20-26 with greater movement play with respect to the associated housing pin bore than in the case of the pin tumbler 28 .

Fig. 2 shows a schematic side view of a key sels 60, which can be, for example, used to actuate the lock cylinder proper 10 Invent. This key has a key profile 61 , which corresponds to the profile of the receiving channel 31 already mentioned above.

As can be seen in particular in FIG. 2, the key 60 has a level-varied control track 62 with respective control positions 64 , 66 , 68 , 70 , 72 for the pin tumblers 20 , 22 , 24 , 26 and 28 , respectively. The respective control positions have different level distances from the core bearing surface 16 shown schematically in FIG. 2 when the key 60 is inserted into the receiving channel 30 .

As can be seen in particular in FIG. 2, a level distance C1 of the control position 72 for the pin tumbler 28 with the set-back control element engagement surface 48 is smaller than a level distance C2 of the control position 70 for the pin tumbler 26 with the long core pin 30 . This is a consequence of the fact that the core pin 30 has a length which is greater than the distance of the control member attack surface 48 of the core pin 32 from the bearing surface 16 in the locked state. This would apply even if the core pin 32 were extended downward in FIG. 1 without any other changes, so that its housing pin engagement surface 52 is only a short distance above the core bearing surface 16 .

Although in the figures, the locking cylinder according to the invention is shown in such a way that the pin tumbler with a set control organ attack surface is the rearmost pin tumbler when viewed from a control organ introducer of the receiving channel, it is also possible, however, that one of the other pin tumblers has a reset control element - Has attack surface. Advantageously, however, the foremost pin tumbler (pin tumbler 20 in Fig. 1) is equipped with a corresponding set-back control organ attack surface, since this would lead to the fact that when looking at the pin tumblers from the controller organ introducer it could be recognized that the foremost pin tumbler has a set-back control organ attack surface.

In addition, it is possible that the core pin bores of the other pin tumblers (pin tumblers 20-26 in Fig. 1) do not have the same hole depth, but that holes are provided at different depths. In order to achieve a safety-fulfilling effect, it is only necessary to set the control organ engagement surface of at least one pin tumbler back towards the core bearing surface in relation to the control organ engagement surface at least one other pin tumbler.

The invention can be implemented in a technically simple manner in that the core pin ( 32 ) with a recessed control element engagement surface ( 48 ) receiving the core pin bore ( 36 ) is shorter than the core pin bores ( 34 ) of the other core pins ( 30 ). In this way, the locking cylinder according to the invention can be produced in a particularly simple and cost-effective manner by differentiated drilling of the core pin bores. Alternatively, however, it is also possible to insert a pin element into a pin element receiving hole that intersects the corresponding core pin hole and to reset the core pin.

It is a further safety-increasing feature that the pin tumbler ( 28 ), whose control organ engagement surface ( 48 ) is set back, is matched in such a way to the other pin tumblers ( 20 , 22 , 24 , 26 ) that after the pin tumbler has emerged ( 28 ) with the set back control organ attack surface ( 48 ) assigned housing pin ( 40 ) from the associated core pin bore ( 36 ) as a result of exposure to the set back control organ attack surface ( 48 ), this housing pin ( 40 ) again under the action of the spring force can return to the associated core pin bore ( 36 ) when a torque is applied to the cylinder core ( 18 ). For this purpose, it can be provided, for example, that the length of at least one of the other core pins ( 30 ), hereinafter referred to as the long core pin, is greater than the distance of the set-back control element engagement surface ( 48 ) from the core bearing surface ( 16 ) in the locked position. It can thus be achieved that when a picking needle performs such a stroke that it can strike the core pin with the control element attack surface set back, the long core pin in any case plunges into the associated pin housing bore and thus the cylinder core ( 18 ) secures against rotation. In this case, further, the long core pin (30) in its cross-sectional dimension in such a way on the Querschnittsabmes the associated housing pin bore (42) sung matched be that upon immersion of the long core pin (30) in the Zugehör strength housing pin bore (42) a for torque application to the cylinder core ( 18 ) possible rotational play of the cylinder core ( 18 ) about the core axis (A) by the interaction of the long core pin ( 30 ) with the associated housing pin bore ( 42 ) is restricted to an extent that the sticking out of the core pin bore ( 36 ) once stuck Housing pin ( 40 ) of the tumbler ( 28 ) with recessed Steuer organ attack surface ( 48 ) in the area of the bearing surface ( 16 ) prevented when this housing pin ( 40 ) under the effect of its spring preload ( 56 ) back on the cylinder core ( 18th ) too moved. For this purpose, for example, the long core pin ( 30 ) can have a larger cross-sectional dimension than the housing pin ( 38 ) assigned to it.

The inventive concept can be implemented in such a way that at least three and preferably at least five pin positions ( 20 , 22 , 24 , 26 , 28 ) are provided, the control organ attack surfaces ( 46 ) of the other core pins ( 30 ) being in the locked state lie on a straight connecting line, and wherein the set-back control organ attack surface ( 48 ) is set back behind this connecting line. Regardless of whether the connecting line between the control element attack surfaces ( 46 ) of the other core pins ( 30 ) runs parallel to the core axis (A) or inclined with respect to it, it should always be ensured that the control element attack surface ( 48 ) of the core pin ( 32 ) with the control element attack surface set back does not lie on this connecting line and can therefore only be struck with difficulty when a picking needle is inserted obliquely.

Based on the fact that the pin tumblers ( 20 , 22 , 24 , 26 , 28 ) in the cylinder core ( 18 ) along the core axis (A) are arranged consecutively, the pin tumbler ( 28 ) with the set-back control element engagement surface ( 48 ) at Be from a control organ introducer of the receiving channel ( 31 ) is not the first pin tumbler. It can thereby be ensured that when looking at the locking cylinder according to the invention from the introducer of the receiving channel ( 31 ) it cannot be recognized which of the pin positions has the set-back control element attack surface. The pin tumbler ( 28 ) with the set-back control organ engagement surface ( 48 ) is preferably the last pin tumbler when viewed from the control organ introducer of the receiving channel ( 31 ).

According to a further aspect of the present invention, the key ( 60 ), which has a level-varied control path ( 62 ) with control positions ( 64 , 66 , 68 , 70 , 72 ) distributed along the control path ( 62 ), has different level distances from the core bearing surface ( 16 ), the level distance (C1) for the pin tumbler ( 28 ) with a recessed control organ engagement surface ( 48 ) is smaller than the level distance (C2) of the pin tumbler ( 26 ) with the long core pin ( 30 ).

According to another view, the invention provides a locking cylinder with core tumblers ( 26 , 28 ) comprising core pins ( 30 , 32 ) and housing pins ( 40 , 42 ), in which the core pins ( 30 , 32 ) are inserted into core pin bores ( 34 , 36 ) Cylinder core ( 18 ) are slidably received and the bore depth of at least one core pin bore ( 36 ) is less than the bore depth of the other Kernstiftbohrun conditions ( 34 ).

According to a further aspect of the invention, this relates to a method for producing a lock cylinder according to the invention and its associated key with the process feature that in the lock cylinder core ( 18 ) Kernstiftboh stanchions ( 34 , 36 ) provides, of which at least one (36) one Has core pin stop surface, which is set back compared to core pin stop surfaces of other core pin bores ( 34 ), that a core pin ( 32 ) is inserted into the at least one core pin bore with the set back stop surface, which within its housing pin contact surface ( 52 ) when the key is not inserted the core pin bore ( 36 ) lies in that a key blank with the profile of a key receiving channel ( 31 ) of the cylinder core ( 18 ) profile-matched blank shank is provided, notches are incorporated into the blank shank as control positions and one set back for the pin tumbler r control organ attack surface ( 48 ) certain recess (control position 72 ) with a distance to the core bearing surface ( 16 ) which is smaller than the corresponding distance in the case of at least one other pin tumbler.

Claims (14)

Locking cylinder ( 10 ), comprising a cylinder housing ( 12 ) with at least one core receiving bore ( 14 ) having a core bearing surface ( 16 ), a cylinder core ( 18 ) rotatable in the at least one core receiving bore ( 14 ) about a core axis (A), locking means ( 20 , 22 , 24 , 26 , 28 ), which block the cylinder core ( 18 ) in the core receiving bore ( 14 ) in a blocking position against rotation about the core axis (A) and which in one by interacting with one in a receiving channel ( 31 ) of the cylinder core ( 18 ) insertable control member ( 60 ), in particular key ( 60 ), releasable release position to release the cylinder core ( 18 ) for rotation about the core axis (A), the locking means ( 20 , 22 , 24 , 26 , 28 ) a group of tumblers ( 20 , 22 , 24 , 26 , 28 ), each with a core pin ( 30 , 32 ) in a provided in the cylinder core ( 18 ) core pin bore ( 34 , 36 ) and a housing pin ( 38 , 40 ) in e in the cylinder housing ( 12 ) provided housing pin bore ( 42 , 44 ), which housing pin is biased by spring force in the direction of the core pin ( 30 , 32 ), the core pins ( 30 , 32 ) each having a control element engagement surface ( 46 , 48 ) have a first end and have a housing pin engagement surface ( 50 , 52 ) at a second end, wherein in the locked position the housing pin engagement surfaces ( 50 , 52 ) of the core pins ( 30 , 32 ) within the respective core pin bores ( 34 , 36 ) lie and wherein in the locked position, the control organ engagement surface ( 48 ) of at least one core pin ( 32 ) relative to the control organ engagement surfaces ( 46 ) of the other core pins ( 30 ) is set back in the direction of the core bearing surface ( 16 ). 2. Lock cylinder according to claim 1, characterized in that the core pin ( 32 ) with set back control organ attack surface ( 48 ) receiving core pin bore ( 36 ) is shorter than the core pin bores ( 34 ) of the other core pins ( 30 ). 3. Lock cylinder according to claim 1 or 2, characterized in that the pin tumbler ( 28 ), whose control member-engaging surface ( 48 ) is set back, in such a way to the other Stiftzuhaltun gene ( 20 , 22 , 24 , 26 ) is matched that after diving out of the pin tumbler ( 28 ) with the set back control element engagement surface ( 48 ) to orderly housing pin ( 40 ) from the associated core pin bore ( 36 ) as a result of exposure to the set back control element engagement surface ( 48 ), this housing pin ( 40 ) also then can return under the action of the spring force in the associated core pin bore ( 36 ) when a torque is present on the cylinder core ( 18 ). 4. Lock cylinder according to one of claims 1-3, characterized in that the length of at least one of the other core pins ( 30 ), hereinafter referred to as the long core pin, is greater than the distance of the set-back control element engagement surface ( 48 ) from the core bearing surface ( 16 ) in the locked position. 5. Lock cylinder according to claim 4, characterized in that the long core pin ( 30 ) in its cross-sectional dimension is matched to the cross-sectional dimension of the associated housing pin bore ( 42 ) that when immersing the long core pin ( 30 ) in the associated housing pin bore ( 42 ) a possible torque application to the cylinder core ( 18 ) rotational play of the cylinder core ( 18 ) about the core axis (A) by the interaction of the long core pin ( 30 ) with the associated housing pin bore ( 42 ) is restricted to an extent that a The stuck once from the core pin bore ( 36 ) immersed housing pin ( 40 ) of the pin tumbler ( 28 ) with set back control organ-engaging surface ( 48 ) in the area of the bearing surface ( 16 ) prevented when this housing pin ( 40 ) under the effect of it Spring preload ( 56 ) moves back to the cylinder core ( 18 ). 6. Lock cylinder according to claim 5, characterized in that the long core pin ( 30 ) has a larger cross-sectional dimension than the housing pin assigned to it ( 38 ). 7. Lock cylinder according to one of the preceding claims, characterized in that at least three and preferably at least five pin tumblers ( 20 , 22 , 24 , 26 , 28 ) are provided, the control member engagement surfaces ( 46 ) of the other core pins ( 30 ) in Locked state lie on a straight connecting line, and wherein the set back control organ attack surface ( 48 ) is set back behind this connecting line. 8. Lock cylinder according to claim 7, characterized records that the connecting line is axially parallel. 9. Lock cylinder according to claim 7, characterized indicates that the connecting line with respect to the Core axis (A) is arranged inclined. 10. Lock cylinder according to one of the preceding claims, characterized in that the pin tumbler lines ( 20 , 22 , 24 , 26 , 28 ) in the cylinder core ( 18 ) along the core axis (A) are successively arranged and that the pin tumbler ( 28 ) with the set-back control organ engagement surface ( 48 ) when viewed from a control organ insertion end of the receiving channel ( 31 ) is not the first pin tumbler. 11. Lock cylinder according to claim 10, characterized in that the pin tumbler ( 28 ) with the control organ attack surface to be reset ( 48 ) when viewed from the control organ introducer of the receiving channel ( 31 ) ago the last pin closing device. 12. Lock cylinder according to claim 5 and if desired according to one of claims 6-11, wherein the key ( 60 ) a level-varied control path ( 62 ) with along the control path ( 62 ) distributed control positions ( 64 , 66 , 68 , 70 , 72 ) different Level distance from the core bearing surface ( 16 ), characterized in that the level stand (C1) for the pin tumbler ( 28 ) with a recessed control element engagement surface ( 48 ) is smaller than the level distance (C2) of the pin tumbler ( 26 ) with the long core pin ( 30 ). 13. Lock cylinder with core pins ( 30 , 32 ) and housing pins ( 40 , 42 ) comprising tumblers ( 26 , 28 ), the core pins ( 30 , 32 ) in core pin bores ( 34 , 36 ) of a cylinder core ( 18 ) displaceably added bar are characterized in that the bore depth of at least one core pin bore ( 36 ) is less than the bore depth of the other, preferably equally deep, core pin bores ( 34 ), if desired with at least one further feature according to one of claims 1-12. 14. A method for producing a lock cylinder with key according to one of claims 1-13, characterized in that in the lock cylinder core ( 18 ) core pin bores ( 34 , 36 ) provides, of which at least one ( 36 ) has a core pin stop surface, which is set back compared to core pin stop surfaces of other core pin bores ( 34 ), that a core pin ( 32 ) is inserted into the at least one core pin bore with the set back stop surface, which, when the key is not inserted, with its housing pin engagement surface ( 52 ) inside the core pin bore ( 36 ) is that you provide a key blank with the profile of a key receiving channel ( 31 ) of the cylinder core ( 18 ) profilange matching blank shank, in this raw shank as control positions notches worked and thereby one for the pin tumbler with set back control organ attack surface ( 48 ) determined Recess (tax tion position 72 ) with a distance to the core bearing surface ( 16 ) which is smaller than the corresponding distance in the case of at least one other pin tumbler.