LT5321B - Arrangement in electromechanical cylinder lock - Google Patents

Abstract

The present invention relates to an arrangement in an electromechanical cylinder lock that comprises a cylinder housing (1) enclosing a turnable inner cylinder (2) and locking means (3, 4) which normally prevent the turning of the inner cylinder (2)relative to the cylinder housing (1) and which may be moved by the key of the lock to a releasing position allowing the turning of the inner cylinder (2), a lock pin (5) or the like which is operatively connected to the inner cylinder (2) so that it in its locking position prevents the turning of the cylinder (2), and a bolt member (8) which is electrically turnable from a first position allowing the locking position of the lock pin (5) to a second position where it prevents the lock pin (5) from moving to its locking position. The arrangement comprises a securing element (11, 11',11'') which, in response to a shock, vibration or other mechanical impulse exerted on the lock, is arranged to bounce from the counter surface (13,13', 13'') included in the lo

Description

The present invention relates to an electromechanical cylindrical locking mechanism as claimed in the first claim.

Electromechanical cylindrical locks and similar locking devices typically have a key that controls the locking mechanism and additional electrical protection in the form of an electronic code or other signal. Electrical protection may be applied to means independent of the key controlling the locking mechanism and to separately control the transmission of force from the key to a particular locking latch or similar element.

A locking mechanism known in the prior art, described in US6363762 JV, incorporates a sophisticated electronics-controlled security element that blocks rotor movement.

The present invention seeks to provide electrical control using small and thin cells, so that the amount of energy required to move the cells is also low. Nevertheless, it is an object of the invention to make this locking reliable. For this purpose, a lock is provided with a latch member or similar element which is pushed, and in particular rotated, by an electric drive or solenoid where the latch member does not necessarily directly provide the mechanical security required by the electric lock but has a warning or authorization effect on the individual locking member or allows the movement required for opening the shutter, that is to say, in the case of a cylindrical lock, specific rotary movement of the cylinder. In this type of structure, it is advantageous from an energy point of view that the power is applied only when the lock is opened electromechanically, the movement or rotation of such a latch member does not require too much force and movement can be caused, for example, by the lock and / mounted on it under impact or vibration.

The object of the present invention is to provide a mechanism for the simple but effective elimination of the movement of the latch or similar element described above in relation to electrical protection to a position allowing the lock to be opened by external forces, i.e. specifically, shocks, vibrations, or similar effects or impulses without activating the appropriate electrical code device.

These objects of the invention are achieved in the manner described in the first and subsequent claims.

The mechanism according to the present invention consists of a security element, which, in order to respond to a lock's impact, vibration or other mechanical action, is mounted by bouncing against the surface facing the lock in the latch member. In this way, the pulses acting in the opposite direction of the latch member prevent the latch member from moving to a position which prevents the locking head from moving to a position preventing the inner cylinder from rotating.

It is desirable that the security element is shaped and mounted such that it is generally pressed against the surface facing it. Alternatively, the security element may be spring-springed to said opposite surface, this solution may also be applicable when the opposite surface in the embodiment is not vertically oriented.

Preferably, the security member is pivotally connected to the latch member so that its axis of rotation is parallel to, and preferably aligned with, the latch member. However, it is useful for the reliability of operation that each element has its own physical axis.

Preferably, the locking head has a guide surface which is mounted to operate the security element so that it is returned to the opposite surface when the inner cylinder is rotated to unlock the lock. In this way, the safety element can be protected even if it is left in the wrong position due to dirt, freezing, oil or similar. In addition, it is desirable that the locking head also has a guide surface mounted to return the latch member to its first position. Thus, it can be guaranteed that the locking head will also move to its initial position, thereby allowing the head to move to the locking position.

In an embodiment of the invention, said opposite surface is mounted in a cylindrical housing. In this case, it is desirable that the cylindrical body has a guide surface at a certain distance from the opposite surface so that said surfaces together determine the rotational freedom of the protection element.

In a second embodiment of the invention, said opposite surface is mounted on a locking head. Thus, the security element may have a projection which is sufficiently thin in the direction of its rotational movement and which is arranged to interact with both the opposite surface and the latch element so that together they determine the freedom of rotation of the security element. In addition, this opposite surface may be on a separate impact surface.

of an element that has a rigid contact with

In a third embodiment of the invention, said opposite surface is mounted on a separate guide element resting on the lock body. This guide member includes, preferably, a shortened shaft resting on the latch member when a security member is pivotally mounted on the shortened shaft. In this case, said opposite surface is disposed on a projection mounted in the guide element parallel to the truncated shaft. The mechanism also has, preferably, a cushioning surface for inhibiting possible shaking of the latch member. In this way, the shaking of the latch member can be prevented. Said cushioning surface is preferably mounted on a projection. In addition, the cushioning surface may be mounted so as to also inhibit the movement of the protection element after a shaking effect on the protection element.

The invention will now be described by way of example with reference to the accompanying drawings, in which:

- FIG. 1-4 are perspective views of a partial embodiment of a lock according to the invention in various working positions;

- FIG. 5 and 6 show the lock according to Figs. 1 - 4 distracted working position;

- FIG. 7 and 8 are enlarged and partial views of some of the mechanisms of the invention, respectively;

- FIG. 9 is a partial view of an alternative embodiment of the invention; and

- FIG. 10 and 11 show a view of another alternative embodiment of the invention.

In the drawings, reference numeral 1 shows a cylindrical body in an electromechanical cylindrical lock which encloses a rotatable inner cylinder 2, in the embodiments described having a plurality of locking discs 3 rotated by a lock key (not shown). The locking discs are known to some extent as interacting with the locking latch 4 such that in the locked position according to FIG. The locking latches 1 and 4 prevent the inner cylinder 2 from rotating relative to the cylindrical body 1. When the locking discs 3 are disposed in their correct rotation position with the locking key, they allow the locking catch 4 to move to the opening position of the locking mechanism shown in Figs. 2 and 3, the inner cylinder 2 can thus be rotated relative to the cylindrical body 1. The mechanism is generally known, especially from the ABLOY lock, and is therefore neither shown nor described in this context.

In addition, the lock comprises a locking head 5 or the like, which is functionally connected to the inner cylinder 2 so as to prevent the inner cylinder 2 from rotating in its locking position. 3 as shown. The stop surface 10 is located in the locking head against the surface 9 of the inner cylinder 2 (see Fig. 5), thereby preventing rotation of the inner cylinder 2, although the locking mechanism itself may be opened by a locking key. The lock also has a latch member 8 which is rotated electrically (in the drawings with an electric actuator 7) from the first position (Figs. 1 and 3) determining the closing position of the locking head 5 to the second position (Fig. 2). to the position where the inner cylinder is locked 2.

In the situation according to FIG. 1 both mechanical and electrical locking is in the locked position. As shown in Figs. 1, the locking head 5 is accelerated by its spring 6 towards its locked position (for simplicity, the opposite surface of the spring is not shown in the drawings), but the locking catch 4 prevents the locking head 5 from moving when locked. FIG. In the situation shown in Fig. 2, the correct electronic code has been entered into the lock, and therefore the electric actuator 7 turns the latch element 8 to Fig. 2. In this way, it prevents the locking head 5 from moving to a position which prevents rotation of the inner cylinder 2, so that the inner cylinder 2 can be rotated with the lock key relative to the cylindrical body 1, and the entire lock can be opened.

FIG. In the situation shown in Fig. 3, the mechanical locking was opened by a locking key (not shown), whereby the locking catch 4 moves to the off position, thereby allowing the inner cylinder 2 to rotate. In this position, the locking catch 4 also allows the locking head to move.

5. The electronic code entered in this case was incorrect, so that the latch element 8 is not turned to its upper Fig. 2. Thus, the latch member 8 does not obstruct the locking head 5 which moves to the position of the locking member 6 in an accelerated manner. 3, wherein the inner cylinder 2 is prevented from rotating independently of the mechanical locking means 3 and 4 of the locking mechanism in operation.

In the described lock design, opening the locking mechanism using a mechanical key alone is not sufficient to open the lock unless the entered electronic code is correct or other electronic permission is obtained to move the latch member 8 to FIG. 2. For this reason, anyone may attempt to impact the latch member with 8 strokes or vibration to the lock and / or stationary structures around it. When the power supply to the electric actuator 7 is interrupted, no substantial force is exerted on the latch element 8, but it is possible to push the latch element 8 into Figs. 2, where it will prevent the locking head 5 from moving into a position that locks the inner cylinder 2, thereby allowing the lock to be opened with a locking key without any electronic code or other protection. To prevent this, the lock according to the present invention has a security element which, in order to respond to a lock impact, vibration or other mechanical action, is mounted to bounce against the surface facing the lock into the latch member 8 and thereby prevent the latch member from moving into FIG. 2.

In an embodiment according to FIG. 1 to 4 is disposed on the cylindrical body 10 in response to a shock or vibration transmitted to the latch, and bounces against the latch member 8, which is pushed toward the latch member 8 in response to the shock or vibration transmitted to the lock. top position as shown in Figs. 4, thereby preventing the latch member 8 from moving from its position according to FIG. 1 and 3 to Figs. 2. The cylindrical body 1 also has a guide surface 14 at a certain distance from the opposite surface 13 such that said surfaces 13 and 14 together determine the freedom of rotation of the security element 11.

FIG. 5 illustrates a possible situation in which the protection element 11 remains in a position returning the latch element 8 due to dirt, oil, frost or the like. 6 shows how these error conditions are normalized. The procedure is as follows. While the inner cylinder 2 is rotated, the spring 6 pushes the locking head 5 into the notch in the inner cylinder (see Fig. 6), the guide surface 17 in the locking head presses the protection element 11 into its initial position by means of the opposite face 11b. In the next attempt to open, the latch member 8 is allowed to rotate to the position shown in FIG. 1 allowing the lock to be opened without the security element 11 interfering with it due to the aforementioned error conditions. For clarity, the cylindrical body is not shown in Figs. 5 and 6.

The locking head 5 also has a guide surface 15 which acts on the latch member 8 and pivots it back to its original position according to FIG. 1. This occurs so that in the position according to FIG. The inner cylinder 2 is further rotated by a key, thereby engaging the inner cylinder surface 16 against the projection 18 of the locking head 5 (see Fig. 5) and causing the locking head 5 to rotate slightly, thereby guiding the latch member 15 while rotating. 8 away from the position of FIG. 2 to the position according to FIG. 1. Therefore, after the latch element 8 is returned to the position according to FIG. 1, where it does not impede the movement of the locking head 5, the inner cylinder 2 is rotated backward, the spring 6 presses the locking head 5 into the recess in the inner cylinder whose guide surface 19 raises it to the position according to FIG. 1, where it lies on the lock latch 4. Thus, in practice, the latch latch 4 in this case is unbearable. Instead, at the same time as the inner cylinder 2 is rotated backward, the projection 4a on the locking latch 4 also rotates the locking head 5 to its original position.

FIG. 7 and 8 show the mounting of the support for the latch member 8 and the security member 11 related to the invention. Preferably, the security member 11 has a support such that its pivot axis 12 is parallel to the pivot axis of the latch member 8; in addition, it has its own separate shaft. To this end, the mechanism has a guide member 20 resting on the cylindrical body 1 and the guide member having a shortened shaft 20a for the security member 11. The shortened shaft 20a may be an extension of the pivot axis of the latch member 8 but is completely independent of the latch member.

The security element 11 is formed such that it is generally pressed against the opposite face 13. 1 - 3 as shown. FIG. 8 illustrates a case with a spring 21 which can be provided if it is thus determined that the protection element 11 is in its normal position against the surface 13 in front of it. In this way, this solution can be applied even if the surface 13 is opposite. non-vertical in the embodiment under consideration.

FIG. 9 shows an alternative embodiment of the invention, wherein the front face 13 of the security element 11 'is mounted on the locking head 5. Also, in this embodiment the security element IT is formed so that it is generally pressed against the opposite face 13'. 9 as shown. In this embodiment, the security element IT has a projection 11a 'which is arranged to interact with both the opposite surface 13' and the latch element 8 so that they together define the freedom of rotation of the security element IT. In this case, the security element IT bounces off the opposite face 13 ', thereby the projection 11a' strikes the latch member 8 and prevents it from moving to the upper position where it would interfere with the movement of the locking head 5 to the locking position.

The opposite surface may also be mounted on a separate element which has a rigid contact with the impact surface. One such embodiment of the invention is disclosed in Figs. 10 and 11. In this solution, the guide member 20, supported by the cylindrical body 1, has a shortened shaft 20a for the protection member 11. The protection member 11 has a projection 11a.

In this case, the opposite surface 13 is mounted on the projection 22 in the guide member 20, the projection being parallel to the shortened shaft 20a. In practice, the guide member includes, for example, riveting to the cylindrical body 1, thereby transmitting external vibrations from the guide surface 13 to the guard member 11 (not shown in the drawings). Further, the projection 22 has a cushioning surface 23 which inhibits movement of the latch member 8. This can prevent the latch member 8 from bouncing off. The cushioning surface 23 may at the same time inhibit the movement of the protection element 11 after it has been initially exposed to the bounce. In this case, the return of the protection element 11 against the guide surface 13 can be done either by means of gravity or by a spring-loaded acceleration. In practice, the cushioning surface may be a discrete member made of a suitable cushioning material fixed to the projection 22, but there are also several other possible ways of providing cushioning.

The solution according to the invention is independent of the type of mechanical locking used, i.e. the invention is not limited to a cylindrical lock having rotatable locking discs, but the invention can also be applied to other mechanisms such as toggle mechanisms. Usually in such cases the support provided with the locking latch for the locking head needs to be replaced by another mechanism.

The solution according to the invention, apart from being used for cylindrical locks, can be used for other objects where shock and vibration can cause similar types of problems, for example, lockable locks that are inserted into doors or other similar objects.

Thus, the invention is not limited to the uses described above, and several other modifications are possible within the scope of the appended claims.

Claims (13)

1. Mechanism in an electromechanical cylindrical lock consisting of a cylindrical housing 5 (1) comprising a pivotable inner cylinder (2) and locking means (3, 4) which generally prevent rotation of the inner cylinder (2) relative to the cylindrical body (1) and which can be moved with a locking key to release position of the inner cylinder (2) pivoting, a locking head (5) or a similar member functionally coupled to the inner cylinder (2) such that, in the locked position, prevents the inner cylinder (2) from rotating, and a latch A member (8) which is electrically rotated from a first position providing for a locking position of the locking head (5) to a second position wherein the locking head (5) is prevented from moving into the locking position; , 11), which is adapted to bounce against the surface facing the lock (13, 13 ') in response to a shock, vibration or other mechanical action on the lock. 13) into the latch member (8) so as to prevent the latch member (8) from moving from said first position to said second position. 2. A mechanism according to claim 1, characterized in that the security element (11,11 ', 11) is shaped and mounted such that it is generally pressed against the opposite one. 20 surfaces (13,13 ', 13). 3. A mechanism according to claim 1 or 2, characterized in that the protection element (11,1Γ, 11) is spring-springed to the opposite surface (13, 13 ′, 13). 25th 4. Mechanism according to any one of the preceding claims, characterized in that the protection element (11 ', 11) is pivotally connected to the latch element (8) such that its axis of rotation (12) is parallel to the axis of rotation of the latch element (8). to coincide with it. 5. The mechanism according to any one of the preceding claims, characterized in that the locking head (5) has a guide surface (17) which is mounted to act on the security element (11) so as to return it to the opposite surface (13) when the barrel (12) is rotated to unlock the lock. 9 EN 5321 B 6. A mechanism according to claim 5, characterized in that the locking head (5) also has a guide surface (15) arranged to return the latch member (8) to the first position. 7. Mechanism according to any one of the preceding claims, characterized in that said opposite surface (13) is mounted in a cylindrical body (1). 8. Mechanism according to claim 7, characterized in that the cylindrical body (1) has a guide surface (14) at a distance from the opposite surface (13) such that The surfaces (13, 14) 10 together define the rotational freedom of the protection element (11). A mechanism according to any one of the preceding claims 1 to 6, characterized in that said opposite surface (13 ') is mounted on the locking head (5). 15th 10. The mechanism of claim 9, wherein the security element ( 11 ') has a projection (Ha') thin enough in its direction of rotation and mounted to interact with both the opposite surface (13 ') and the latch member (8) so that the latter together define the rotational freedom of the protection member (1Γ) 11. A mechanism according to any one of the preceding claims 1-4, characterized in that the opposite surface (13) is mounted on a separate guide element (20) resting on the lock body (1). 12. The mechanism of claim 11, wherein the guide member 25 (20) includes, preferably, a shortened shaft (20a) resting on the latch member (8) and a security member (11) rotatably mounted on the shortened shaft. 13. Mechanism according to claim 11 or 12, characterized in that the opposite surface (13) is arranged on a projection (22) mounted in the guide element (20). 30 parallel to the shortened shaft (20a). 14. A mechanism according to any one of the preceding claims 11 to 13, characterized in that it also has a cushioning surface (23) for damping possible shaking of the latch member (8) and that said cushioning surface (23) is preferably mounted on a projection. 35 (22). 15. A mechanism according to claim 14, characterized in that the cushioning surface (23) is arranged to inhibit the movement of the protection element (11) after the impact of the jitter on the protection element (11).