[0001] The present invention refers to a key for a lock.
[0002] Different kinds of key have been present on the market for some time, of flat or
corrugated type that are reversible and not, having a bit that combines teeth, recesses,
ridges and movable elements configured and arranged to interact with the encryption
elements present in the lock.
[0003] Obviously, it is possible to make the key extremely secure with a suitable design
of the combination of the elements that make up the bit.
[0004] In some cases, the key bit elements are fixed crests protruding from the surface
of the key that may constitute an obstacle when the key is inserted into specific
types of cylinder lock, in which the base of the cylindrical rotor is covered by a
special protective disc.
[0005] A key with a simpler bit that is for example devoid of fixed elements protruding
from the plane of the key could eliminate the aforesaid drawback but could at the
same time be exposed to fraudulent duplication.
[0006] Keys also exist in which the bit has a movable element that for constructional reasons
is restricted to a very limited movement that is not always appropriate to ensuring
reliable and effective operation.
[0007] The technical task of the present invention is to realise a key for a lock which
enables the decried technical drawbacks of the prior art described above to be eliminated.
Within the context of this technical task, an object of the invention is to realize
a very secure key for a lock.
[0008] Another object of the invention is to realise a key for a lock that is practical
and convenient to use.
[0009] Another object of the invention is to realise a key for a lock that is difficult
to duplicate. Another object of the invention is to realise a key for a lock that
is reliable and resistant. The technical task, as well as these and other objects,
according to the present invention, are achieved by a key for a lock, comprising a
grip, a blade, at least one lever having a first movement receiving arm for receiving
the movement from a sensor formed by a fixed pin and a second actuating arm for actuating
an encryption element of the lock, said lever being pivoted on the blade with an axis
of oscillation thereof that is transverse to the longitudinal axis of the blade, said
lever being housed in a groove of a main face of the blade, said groove having a depth
dimension in the direction of the thickness of said blade that is less than the thickness
of said blade and extending longitudinally along said blade as far as the end of said
blade opposite said grip, said lever being positioned entirely inside said groove
in an inactive position to interact with said sensor, being characterized in that
a retaining spring of said lever is further provided in an inactive position, said
spring being configured and arranged to return said lever automatically to an inactive
position after each oscillation.
[0010] In a preferred embodiment of the invention said spring protrudes from a seat obtained
in said groove.
[0011] In a preferred embodiment of the invention said spring has a base with a form matching
said seat.
[0012] In a preferred embodiment of the invention, said seat is formed by a print in a bottom
of said groove.
[0013] In a preferred embodiment of the invention, said spring is interlocked between said
seat and said first arm of said lever
[0014] In one embodiment of the invention, said spring is helical.
[0015] In one embodiment of the invention, said helical spring is tapered.
[0016] In another embodiment of the invention, said spring is plate-shaped and has the base
and a tilted arm projecting from the base.
[0017] In a preferred embodiment of the invention, said spring is in a first compression
state between said seat and said first arm of said lever when said lever is in said
inactive position, and in a second state of greater compression between said seat
and said first arm of said lever when said lever is in an active position in which
said second arm protrudes outside said groove.
[0018] The key according to the invention, owing to the provision of the spring, has secure,
precise and reproducible lever movements that improve the performance of the key even
over the long term.
[0019] The spring can be advantageously returned by hand to position simply and easily during
the key assembly step without particular operations like welding, gluing, fixing with
screws, etc., that, during miniaturisation of the components, can be particularly
tricky. In practice, it is sufficient to position the spring between the spring seat
and the lever and only subsequently fit the rotation pin of the lever.
[0020] In addition to long-term operating reliability, the key thus has benefits from a
simplified manufacturing process.
[0021] In this connection, creating the seat for the spring requires a milling processing
that is moreover already envisaged for the realisation of the groove.
[0022] With a single milling processing, the groove can then be obtained in which the seat
of the spring is already arranged inside the groove.
[0023] In addition, the spring can be made of material, for example harmonic steel, which
is perfectly resistant to atmospheric agents without counting that the position thereof
proximal to the free end of the blade makes cleaning with a single jet of air possible
to remove a possible accumulation of powder.
[0024] The key according to the invention does not moreover have fixed elements protruding
from the plane of the key and is usable without prejudice in applications using cylinder
locks with the cylindrical rotor protected by a protective disk.
[0025] Providing an oscillating lever moreover makes fraudulent duplication of the key extremely
complicated.
[0026] The lever has a rocker movement that increases the stroke of the second lever arm
and thus the grip of the encryption element of the lock.
[0027] In this manner, the lever acts with extreme efficacy and reliability for actuating
the encryption element of the lock.
[0028] Further features and advantages of the invention will become more apparent from the
description of a preferred, but not exclusive, embodiment of the key for a lock according
to the invention, which is illustrated by way of approximate and non-limiting example
in the appended drawings, in which:
figure 1 shows a perspective view of a flat reversible key, according to a preferred
embodiment of the invention;
figure 2 shows the two levers provided on the two opposite main faces of the blade
of the flat key of figure 1;
figure 2A shows the key of figure 1 sectioned along a plane A-A that extends in the
longitudinal direction of the blade;
figure 3 shows an exploded view of the key of figure 1;
figure 4a shows the flat reversible key of figure 1 inserted into a cylinder lock;
figure 4b shows the cylinder lock of figure 4a with the key removed;
figure 5 shows a combination of a flat reversible key and a cylinder lock conforming
to a second embodiment of the invention;
figure 6 shows a corrugated key conforming to another manner of realising the invention;
figure 7 shows an exploded view of a key conforming to a second preferred embodiment
of the of the invention; and
figure 8 shows the blade of the key of figure 7 in a longitudinal section.
[0029] Equivalent parts in the following description will be indicated with the same numerical
reference.
[0030] With reference to the cited figures, a key 1 for a lock 2 is shown.
[0031] In figures 1 to 5, 7 and 8 we shall refer to a preferred solution that has a flat
reversible key and a cylinder lock.
[0032] The scope of the invention can however be extended to a key of a different type,
for example a corrugated key 1 illustrated in figure 6, or to a non-reversible key.
[0033] The key 1 comprises a grip 3 and a blade 4 bearing the bit of the key 1 adapted to
interact with the encryption elements present in the lock 2.
[0034] In the case of the flat key illustrated in figures 1 from 1 to 5, 7 and 8 the bit
of the key 1 comprises in a known manner on each of the two opposite main faces 5
of the blade 4 of the key 1 one or more rows of recesses 6 aligned according to the
longitudinal axis of the blade 4. Possibly, as shown, the bit can comprise in a known
manner also on each of the two opposite secondary side faces 7 of the blade 4 one
or more rows of recesses 8 aligned according to the longitudinal axis of the blade
4.
[0035] In the case of the corrugated key 1 illustrated in figure 6, the bit of the key 1
comprises in a known manner recesses 6 of various shape and depth along the lower
secondary face 7 of the blade 4 of the key 1.
[0036] Advantageously, on each main face 5 of the blade 4 of the flat reversible key illustrated
in figures 1 to 5, 7 and 8, and on a main face 5 of the blade 4 of the corrugated
key illustrated in figure 6, a lever 9 is fitted having a first movement receiving
arm 10 and a second arm 11 actuating an encryption element of the lock 2.
[0037] It remains understood that in any other case in which the key is not reversible,
there is just one lever 8 fitted selectively to one of the two main faces 5 of the
blade 4 of the key 1.
[0038] Alternatively, the lever 9, in a different embodiment of the invention, can be fitted
to a secondary face 7 of the blade 4 of the key 1.
[0039] Each lever 9 is pivoted by a pin 12 on the blade 4 of the key 1.
[0040] The axis of oscillation of the lever 9 is transverse to the longitudinal axis of
the blade 4 of the key 1.
[0041] The first lever arm 10 and the second lever arm 11 are exposed on the main face 5
of the blade 4 of the key 1.
[0042] The lever 9 is housed in a groove 13 of the main face 5 of the blade 4 of the key
1.
[0043] The groove 13 extends longitudinally along the blade 4 of the key 1.
[0044] In particular the groove 13 extends as far as the end 14 of the blade 4 of the key
1 opposite the grip 3 of the key 1.
[0045] The groove 13 has a width, length and depth that are such as to house entirely therein
the lever 9 when the latter adopts an inactive position illustrated for example in
figure 1.
[0046] The lever 9 also has an active position in which the second arm 11 thereof protrudes
outside the groove 13.
[0047] The key 1 has suitable releasable retaining means of the lever 9 in the inactive
position. The retaining means comprises a spring 15 configured and arranged to return
the lever 9 automatically to the inactive position after each oscillation.
[0048] The spring 15 protrudes from a seat 16 obtained in the groove 13.
[0049] The spring 15 has a base 15A with a form matching the seat 16.
[0050] The base 15A of the spring 15 is preferably flat.
[0051] The seat 16 is formed by a print 16A in the bottom 13A of the groove 13.
[0052] The spring 15 is interposed between the seat 16 and the lever 9, in particular between
the seat 16 and the first arm 10 of the lever 9.
[0053] The spring 15 is more precisely simply interlocked between the seat 16 and the first
arm 10 of the lever 9.
[0054] The spring 15 can be helical, and in particular tapered, as illustrated in figures
1 - 6, and be more precisely arranged with the axis M thereof orthogonal to the rotation
pin 12.
[0055] Alternatively, the spring 15 can be plate-shaped as illustrated in figures 7 and
8, and have in particular the base 15A and a tilted arm 15B projecting from the base
15A.
[0056] The tapered or plate-shaped conformation of the spring 15 results in a significant
saving in overall dimensions that is particularly useful for a construction in which
the groove 13 has the minimum possible dimensions in order not to weaken the blade
4 of the key 1 structurally.
[0057] The base 15A of the spring 15, the larger base 15A in the case of the tapered helical
spring 15 illustrated in figures 1 - 6, is positioned exactly in the seat 16.
[0058] The spring 15 is in a first compression state between the seat 16 and the first arm
10 of the lever 9 when the lever 9 is in the inactive position: in this inactive position
of the lever 9 the second lever arm 11 is intercepted by a limit stop 40 of the lever
9 formed by an inner step of the groove 13.
[0059] The spring 15 is in a second state of greater compression between the seat 16 and
the first arm 10 of the lever 9 when the lever 9, appropriately stressed by the sensor
21, is in the active position in which the second arm 11 protrudes outside the groove
13.
[0060] Advantageously, when the force acting on the first arm 10 is released, the lever
9 can return automatically and precisely to the inactive position by effect of the
strain of the spring 15 that terminates when the second lever arm 11 is intercepted
by the limit stop 40 of the lever 9.
[0061] Advantageously, the second arm 11 of the lever 9 has a greater length than the first
arm 10 of the lever 9 so as to increase the movement of the encryption element.
[0062] In other embodiments of the invention, the length of the two lever arms can be the
same or the second lever arm 11 can be of a shorter length than the first lever arm
10.
[0063] The key 1 works in combination with a cylinder lock having a stator 22 that houses
a cylindrical rotor 17 provided with a slot 23 for inserting the key 1.
[0064] The cylindrical rotor 17 of the lock 2 houses a series of encryption elements formed
by pins 18, 19, 19', 20 of different type and a sensor 21 adapted to interact with
the first lever arm 10.
[0065] The encryption pins 18, 19, 19', 20 and the sensor 21 are aligned along the axis
of the cylindrical rotor 17 and in particular they are positioned at the same diameter
plane as the cylindrical rotor 17 on the same side as the insertion slot 23 of the
key 1.
[0066] The encryption pins 18, 19, 19', 20 are movable along radial channels of the cylindrical
rotor 17 that on one end open onto the annular part 22a of the stator 22 and on the
other end open onto the slot 23 for the key 1.
[0067] The encryption pin 18 is a passive pin consisting of a single piece with frustoconical
ends.
[0068] When the key 1 is inserted into the slot 23 (figures 4a, 5), by effect of the interaction
of the pin 18 with the bit of the key 1, the pin 18 is free to translate and release
the end thereof from the relative engagement seat 29 provided on the inner side of
the annular part 22a of the stator 22. This condition thus enables the rotation of
the cylindrical rotor 17.
[0069] The encryption pin 19 comprises a male part 19a and a female part 19b engaged with
the male part 19a with interposition of an elastic element 19c. The female part 19b
has a frustoconical end adapted to interact with the bit of the key 1 and an insertion
end of the male part 19a. The male part 19a has an end inside the female part 19b
and a frustoconical end outside the female part 19b and engageable in a seat 24 of
matching shape present on the inner side of the annular part 22a of the stator 22.
The male part 19a moreover has a perimeter recess 19a'. When the key 1 is not inserted
into the slot 23 (figure 4b) the frustoconical end of the male part 19a is engaged
in the seat 24 thereof and the female part 19b by effect of the action of the elastic
element 19c is extended from the male part 19a and assumes a position in which the
insertion end thereof of the male part 19a is aligned with the recess 19a' of the
male part 19a. In this position, if an attempt is made to rotate the cylindrical rotor
17, the male part 19a is free to rotate angularly so as to wedge between the cylindrical
rotor 17 and the stator 22 and prevent rotation of the cylindrical rotor 17. On the
other hand, when the key 1 is inserted into the slot 23 (figures 4a, 5), the frustoconical
end of the male part 19a is engaged 24 in the seat thereof but the female part 19b
by effect of the interaction with the bit of the key 1 is retracted towards the male
part 19a, assuming a position in which the insertion end of the male part 19a is staggered
by the recess 19a' of the male part 19a. In this position, the female part 19b acts
as a translation guide for the male part 19a. Thus if an attempt is made to rotate
the cylindrical rotor 17, the male part 19a is guided to translate in the female part
19b until the frustoconical end of the male part 19a exits the seat 24 thereof and
is retracted into the radial channel of the cylindrical rotor 17. In this case, the
rotation of the cylindrical rotor 17 can take place.
[0070] The solution illustrated in figures 4a and 4b provides an encryption pin 20 consisting
of a single piece adapted to interact with a lock nut 25 movable in contrast and by
action of an elastic element 26 in a seat 27 obtained on the inner side of the annular
part 22a of the stator 22. When the key 1 is not inserted into the slot 23 (figure
4b) the lock nut 25 by effect of the action of the elastic element 26 is protracted
partially into the radial channel that houses the pin 20. In this position, if an
attempt is made to rotate the cylindrical rotor 17, the lock nut 25 arranged straddling
the cylindrical rotor 17 and the stator 22 prevents the rotation of the cylindrical
rotor 17. On the other hand, when the key 1 is inserted into the slot 23 (figure 4a),
by effect of the interaction of the pin 20 with the bit of the key 1 the point of
contact between the pin 20 and the lock pin 25 is positioned at the cylindrical interface
surface between the annular part 22a of the stator 22 and the cylindrical rotor 17.
In this case, the rotation of the cylindrical rotor 17 can take place.
[0071] The solution illustrated in figure 5 has on the other hand an encryption element
19' that is equivalent in operation to the encryption element 19 from which it differs
structurally in the flat rather than frustoconical shape of one end of the female
part.
[0072] Encryption of the lock can comprise encryption elements that are also different in
arrangement, number and type from those that have just been disclosed.
[0073] In the lock illustrated in figures 4a and 4b the sensor 21 is formed by a fixed pin
positioned above the last encryption element on the side of the cylindrical rotor
17 opposite the side from which the key 1 is inserted.
[0074] In this case, the lever 9 has the first lever arm 10 in a position proximal to the
end 14 of the blade 4 of the key 1 and the second lever arm in a position distal from
the end 14 of the blade 4 of the key 1.
[0075] Also the sensor 21 can however be different in arrangement and type and the key 1
has to be anyway conformed in a congruent manner.
[0076] With reference on the other hand to the solution illustrated in figure 5, the lever
9 has the first lever arm 10 in a position that is distal from the end 14 of the blade
4 of the key 1 and the second lever arm in a position that is proximal 14 to the blade
4 of the key 1, because the sensor 21 is now positioned before the last encryption
element 19'.
[0077] In the solution illustrated in figure 5, also the structure of the sensor 21 is different.
The sensor 21 has in this case a pin 21a that is movable in a radial channel 30 of
the cylindrical rotor 17 in contrast and by action of an elastic element 21b interposed
between the movable pin 21a and a housing 21c fixed in said radial channel 30.
[0078] The lever 9 operates in the following manner.
[0079] Before the key 1 is inserted into the slot 23 of the cylindrical rotor 17 the spring
15 retains the lever 9 in an inactive position completely inside the groove 13.
[0080] When the key 1 is inserted into the slot 23 of the cylindrical rotor 17, the first
lever arm 10 interacts with the sensor 21 from which it receives a force that overcomes
the elastic force exerted by the spring 15 to retain the lever 9 in an inactive position
and generates on the lever 9 a rotation moment owing to which the lever 9 moves to
the active position.
[0081] By effect of the rotation of the lever 9 the second lever arm 11 actuates an encryption
element, in particular, the encryption element 20 in the solution illustrated in figures
4a and 4b and the encryption element 19' in the solution illustrated in figure 5.
[0082] The encryption element actuated by the lever 9 moves from the rotation locking position
of the cylindrical rotor 17 to the position that enables the rotation of the cylindrical
rotor 17.
[0083] More in general, by effect of the interaction with the bit of the key 1, also all
the other encryption elements move to the position that enables the rotation of the
cylindrical rotor 17.
[0084] The encryption pin actuated by the lever 9 can naturally also be a pin with the structure
of the pin 19, or yet another pin.
[0085] The key for a lock thus conceived is susceptible to numerous modifications and variations,
all falling within the scope of the inventive concept, as defined by the claims.
[0086] In practice, the materials used, as well as the dimensions, can be any depending
on the needs and the state of the art.
1. A key (1) for a lock (2), comprising a grip (3), a blade (4), at least one oscillating
lever (9) having a first movement receiving arm (10) for receiving the movement from
a sensor (21) formed by a fixed pin and a second actuating arm (11) for actuating
an encryption element of the lock (2), said lever (9) being pivoted on said blade
(4) with an axis of oscillation thereof that is transverse to the longitudinal axis
of said blade (4), said lever (9) being housed in a groove (13) of a main face (5)
of the blade (4), said groove (13) having a depth dimension in the direction of the
thickness of said blade (4) that is less than the thickness of said blade (4) and
extending longitudinally along said blade (4) as far as the end (14) of said blade
(4) opposite said grip (3), said lever (9) being positioned entirely inside said groove
(13) in an inactive position to interact with said sensor (21), a retaining spring
(15) of said lever (9) being further provided in an inactive position, said spring
(15) being configured and arranged to return said lever (9) automatically to an inactive
position after each oscillation.
2. The key (1) for a lock (2) according to claim 1, characterised in that said spring (15) protrudes from a seat (16) obtained in said groove (13).
3. The key (1) for a lock (2) according to the preceding claim, characterised in that said spring (15) has a base (15A) with a form matching said seat (16).
4. The key (1) for a lock (2) according to the preceding claim, characterised in that said base (15A) is flat.
5. The key (1) for a lock (2) according to any one of claims 2 to 4, characterised in that said seat (16) is formed by a print (16A) in a bottom (13A) of said groove (13).
6. The key (1) for a lock (2) according to any one of claims 2 to 5, characterised in that said spring (15) is interposed between said seat (16) and said first arm (10) of
said lever (9).
7. The key (1) for a lock (2) according to any one of claims 2 to 6, characterised in that said spring (15) is interlocked between said seat (16) and said first arm (10) of
said lever (9).
8. The key (1) for a lock (2) according to any one of claims 2 to 7, characterised in that said spring (15) is helical.
9. The key (1) for a lock (2) according to the preceding claim, characterised in that said helical spring (15) is tapered.
10. The key (1) for a lock (2) according to any one of claims 2 to 7, characterised in that said spring (15) is plate-shaped.
11. The key (1) for a lock (2) according to any one of claims 6 to 10, characterised in that said spring (15) is in a first compression state between said seat (16) and said
first arm (10) of said lever (9) when said lever (9) is in said inactive position,
and in a second state of greater compression between said seat (16) and said first
arm (10) of said lever (9) when said lever (9) is in an active position in which said
second arm (11) protrudes outside said groove (13).
12. A combination of a cylinder lock (2) and a key (1) compliant with any preceding claim,
wherein said encryption element is an encryption pin placed in the cylindrical rotor
(17) of the lock (2).