This application claims the benefit of German application DE 102009025993.7 filed Jun. 18, 2009 which is incorporated by reference herein.
The invention also relates to a key for a locking device.
DE 298 18 143 U1 describes a safety key and the tumbler pin of an associated locking cylinder. The broad side face of the flat key shank of the safety key has a multiplicity of cup-shaped coding recesses. Each coding recess has a supporting flank, which is formed by the bottom of the cup and on which the blunt end of a tumbler pin beveled at the tip can be supported. The supporting surface merges into a concavely rounded sliding surface. This rounding merges into a more inclined sloping flank. The latter merges into a concavely rounded sliding surface with a smaller slope. The concavely rounded sliding surface runs out in a broad side face of the key shank. This produces a shape of a sliding flank without any points of inflection and with portions inclined to differing degrees with respect to the direction of insertion of the key into the key channel of the locking cylinder.
A coding recess with a sliding flank of a shape without any points of inflection and with portions sloping to differing degrees is also described by DE 20 2006 005 188 U1. Here, the wall of the coding recess is formed by an arcuate portion produced by the use of a circular milling cutter with a constant milling radius.
DE 10 2004 021 580 B3 describes a flat key with coding recesses with straight sliding flanks. The flanks of adjacent coding recesses merge into one another while forming an acute angle. The apex angle of the two sliding flanks forming a coding recess is approximately 106°. The apex angle is preferably greater than 90°, in order to keep down the force component acting in the horizontal direction during the withdrawal of the key from the key channel. The shallower the angle of the sliding flank, the smaller the forces in the horizontal direction that are required to move the tumbler pins in the axial direction. Shallow sliding flanks have the disadvantage, however, that directly adjacent coding recesses can only have a relatively small difference in their depth of incision. The coding of a flat key is achieved by sliding flanks cut to different depths. The sliding flanks may meet at a point of intersection, as is the case for example in DE 10 2004 021 580 B3. The sliding flanks may, however, also merge into a supporting flank, as is the case with DE 298 18 143 U1. When the key is pushed into the key channel of a locking cylinder, a tumbler pin is made to enter an allocated coding recess. The tumbler pins are of different lengths, the depth of insertion of the associated coding recess being adapted to the length of the respective tumbler pin in such a way that, when the key is completely pushed in, the tumbler pins do not protrude beyond the shear line of the locking cylinder into a driver pin hole and driver pins mounted in the driver pin hole do not protrude into the core pin hole.
In order to increase the variety of permutations, the maximum differences in the depths to which adjacent coding recesses are cut must be as great as possible. With shallow sliding flanks, this requires adjacent tumbler pins to be spaced far apart in the direction of extent of the key channel. This would increase the overall length of the locking cylinder, which is undesired. If, for example, the slope of the sliding flanks is increased to 90°, the force component acting in the direction in which the key is withdrawn, that is to say in the direction of extent of the key channel, at the same time becomes greater. This may lead to a tumbler pin jamming within the pin hole.
It is an object of the invention to increase the variety of permutations while maintaining an overall length of the locking cylinder that is as short as possible.
The invention relates to a locking device comprising a locking cylinder and a matching key, the locking cylinder having a cylinder core with a key channel for inserting the key and with pin holes opening out into the key channel, in which pin holes tumbler pins are mounted, the pins forming a head with a tip and a conical surface which follows on from the tip, the head engaging in a coding recess of the key and being supported there by the tip on a portion of the wall of the coding recess, the wall forming a first sliding flank, on which the head of the tumbler pin lies in an abutting position before the axial displacement of the tumbler pin in the pin hole that is brought about by withdrawing the key from the key channel and along which it slides in a first phase of movement during the withdrawal of the key, and the wall forming a second sliding flank, which follows on from the first sliding flank in a transitional region, which second sliding flank slopes more steeply than the first sliding flank with respect to the direction of extent of the key and on which the head slides along in a second phase of movement during the withdrawal of the key.
The object is achieved by the invention specified in the claims.
First and foremost, it is proposed that the dimensions of the conical surface following on from the rounding of the tip and of the first sliding flank are made to match one another in such a way that the transitional region is covered by the conical surface in the abutting position. The two sliding flanks, intersecting at a real or imaginary point, on which the head of the tumbler pin slides along in a first phase of movement during the withdrawal of the key from the key channel may have an apex angle which is relatively great, for example is 106°, as in the prior art. The rounded tip of the tumbler pin slides along on this first sliding flank when the tumbler pin is set in motion from a rest position by accelerations. This accelerating flank is followed by a second sliding flank, which is steeper. The two second sliding flanks, respectively associated with a coding recess, may have an apex angle which is much smaller, for example 90°. The shallow first sliding flank merely has the task of overcoming the static friction when the tumbler pin is set in motion. The sliding friction, of a lower value, causes a smaller force component in the direction of withdrawal, so that the relevant sliding flank slope can be greater. The region of the first, less inclined sliding flank is consequently restricted to the region in which the core pin is accelerated. This region may be smaller than the radius or the diameter of the core pin. With the configuration of the two sliding surfaces according to the invention, a “gentle launch” of the core pins is consequently achieved. The transitional region of the two sliding flanks, which can merge one into the other there while forming a point of intersection, that is to say a point of inflection, lies in the region of the conical surface. This covers the transitional region. The sliding flanks are substantially straight. As a result, space is optimally utilized. The cone angle lies in the region of the apex angle of the second sliding flanks and is preferably slightly smaller than this apex angle. The coding recesses may be produced using a side and face-milling cutter. The side and face-milling cutter has a V-shaped disk profile, the two V legs having portions that slope to differing degrees. The coding recesses cut in to different depths with a side and face-milling cutter of this type are consequently of substantially the same configuration. The first sliding flanks always extend over the same portion of extent of the key shank.
In a development of the invention, it is provided that at least one tumbler pin has a conical surface, the cone angle of which is greater than the apex angle of the second sliding flank. This tumbler pin does not lie with its rounded tip against a supporting flank or a first sliding flank. Rather, the head of this tumbler pin lies, against the second sliding flank, with a transitional region between a second conical surface, which has a smaller apex angle, and the conical surface following on from the tip. This is indeed in keeping with greater forces of acceleration. The different cone angles, however, increase protection from picking by lock bumping. The key may be a flat key with a coding recess cut in on the front side, as described by DE 10 2004 021 580 B3. However, the key may also be a flat key with coding recesses milled into the broad side face using an end-milling cutter, as described in principle in DE 298 18 143 U1. In both cases, it is possible for the rounding at the tip of the tumbler pin to be supported on a supporting flank running parallel to the direction of extent of the key shank.
A development of the invention relates to a locking device with a locking cylinder which can be coupled with a locking element by means of a coupling, and to a key relating to the locking cylinder. DE 103 04 152 A1 describes a locking cylinder of this type with an associated key. The key has a tip portion which is flanked by two flank portions and enters the slit of a coupling element in order to couple the cylinder core to the locking element. A locking cylinder with an associated key in which the key tip performs a coupling function is also known from DE 41 12 564 A1. The flank portion forming the key tip is inclined with respect to the direction of insertion of the key shank into the key channel. A portion of this flank that is remote from the key tip forms a sliding slope which acts upon the heads of the tumbler pins when the key is pushed into the key channel, in order to move the tumbler pins into their pin holes in the axial direction.
According to the invention, it is provided that the sliding slope is shallower than the flank portion of the key tip directly following on from it. The angle of the sliding slope and the cone angle of the tumbler pin are made to match one another in such a way that the conical surface is acted upon by the sliding slope over substantially its entire axial length. The sliding slope therefore does not act upon the head of the tumbler pin only in the region of its tip or only in the region of the transitional region of the conical surface to the cylindrical shank portion of the tumbler pin, but more or less over the entire length of the cone. Instead of point contact, there is linear contact. The cone angle and the angle of the sliding slope do not have to match 100%, since a certain tilting of the tumbler pin can be accepted. However, this tilting must not be so much that the tumbler pin becomes misaligned in its pin hole. In addition, this sliding slope may also have steeper or shallower portions. What is important is that, in its acceleration phase, that is to say in the first phase of movement, the tumbler pin is acted upon by a portion of the sliding slope against which the conical surface can come to lie in a linearly abutting manner.
Exemplary embodiments of the invention are explained below with reference to appended drawings, in which:
The prior-art key 2 represented in
The development according to the invention of the key represented in
The coding recesses 10 have a first pair of sliding flanks 12, which intersect at an apex point 12′. It is important that the first sliding flanks 12 are straight. In the exemplary embodiment, there is a real point of intersection 12′. The first sliding flanks 12 may, however, also intersect at an imaginary point of intersection, if for example they first merge into a supporting flank running parallel to the extent of the key shank. In the exemplary embodiment, the rounded tip 8 of the head 7 of the core pin 6 is supported on the two first sliding flanks 12. In a variant that is not represented, the rounding of the tip 8 may, however, also be supported on a supporting flank.
The reference numeral 13 designates a point of inflection. Here, this is a transitional region in which the first sliding flank 12 merges into a second sliding flank 14, which has a greater slope with respect to the direction of extent of the key shank 21. The transitional region 13 is covered by the conical surface 9 of the head 7.
With respect to the direction of displacement of the core pin 6, the axial spacing of the transitional region 13 from the tip 8 of the core pin 6 which is held in position in the coding recess 10 is less than the axial length of the head 7 that is made up of the axial length of the tip 8 and the axial length of the conical surface. The spacing of the transitional region 13 from the center axis, passing through the tip 8, of the core pin 6 positioned in the coding recess 10 is less than the radius of the cylindrical shank portion of the core pin 6. As a result of this, the extent of the spacing between two opposing transitional regions 13 of a coding recess 10 in which the tip 8 is supported simultaneously on two first sliding flanks 12 is also less than the diameter of the core pin 6.
In the exemplary embodiment, the apex angle α of the two first sliding flanks 12 is approximately 106°. The apex angle of the second sliding flanks 14 is approximately 90°. The cone angle γ of the conical surface 9 in the exemplary embodiment is approximately 86°. The cone is configured in such a way that the diameter of its base area, with which the cone portion 9 follows on from the cylindrical shank portion of the core pin 6, is at least four times the diameter of the head of the cone portion 9 that is followed by the rounding of the tip 8. In the exemplary embodiment, the diameter ratio is approximately six. The dimensions are in any case chosen such that the rounding of the tip 8 is supported on the first sliding surface 12 and the transitional region 13 lies in the region of the conical surface 9.
The operating principle is as follows: if the key 2 is withdrawn from the key channel to the left from the position of rest that is represented in
A graduated adaptation of the core pin angles γ to the incision angles α, β achieves the effect that the core pins are gently raised with different accelerations. The alternating use of core pins with continuous and graduated conical surfaces 19, 20 leads to different acceleration models. The graduated form of the incisions in the key in combination with the angles of the pins provides increased ease of operation when the key is inserted and withdrawn. The different acceleration variants provide increased protection from picking by lock bumping.
As can be gathered from
The first inner conical surface merges into a second inner conical surface. The second inner conical surface forms two opposing second sliding flanks 14. The inner cone angle β of the second inner conical surface is approximately 90°, so that a transitional zone 13 is created in the form of a bent line. The transitional region 13 has with respect to the supporting flank 11 a spacing in the axial direction of the core pin 6 that is less than the spacing between the tip 8 and the base area of the cone 9 of the head 7.
The second sliding flank 14, formed by the second inner cone, merges into a broad side face of the key shank 21.
Here, too, the cone angle of the conical surface 9 is approximately 86°. The diameter here of the base area of the cone 9 is more than twice the diameter of the transitional region of the conical surface into the tip 8.
If, as shown in
The sliding slope 27 is followed by a flank portion 29 of the key tip 28 that is inclined by an angle δ of approximately 37° with respect to the direction of movement S of the core pin 6. This leads to a shortened key tip, which however is nevertheless capable of coupling the key to a locking element by entering a coupling slit.
The exemplary embodiment represented in the drawings shows a cylinder 31.5 mm long with six pins. Alternatives to this are 27.5 mm long and have five pins or are longer and have seven or more pins.
All features disclosed are (in themselves) pertinent to the invention. The disclosure content of the associated/accompanying priority documents (copy of the prior patent application) is also hereby incorporated in full in the disclosure of the application, including for the purpose of incorporating features of these documents in claims of the present application. In the optionally dependent way in which they are worded, the subclaims characterize independent inventive developments of the prior art, in particular in order for divisional applications to be filed on the basis of these claims.
Number | Date | Country | Kind |
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102009025993.7 | Jun 2009 | DE | national |