NO332872B1 - Shaft Shaft - Google Patents

Abstract

This invention relates to lock spindles divided into two parts and connected by a connecting pin. The invention particularly relates to solenoid locks. The invention eliminates the unwanted effect of an external force applied on the divided spindle. The divided spindle includes at least one flexible element and, in some embodiment, a bore extension that prevents unwanted frictional forces caused by an external force applied to the spindle.

Description

The area of technology

This invention relates to locking shafts divided into two parts and connected with a connecting pin. The invention also relates to locks with a split square pin. The invention relates in particular to electromagnetic lock types and corresponding mechanical lock types.

Known technique

Figure 1 shows a known split square pin formed by two square pin parts 4, 5 and a connecting pin 6 which connects these. In the embodiment in Figure 1, the connecting pin is a one-piece bolt that is screwed into a bore in one of the square pin parts 4 by bolt threads so that the drive end 15 of the bolt 6 remains in the extension of the bore that passes through the other square pin part 5. The drive end 15 can be turned through the bore in the square pin part 5 with an Allen key, for example depending on the type of tool the drive end is machined for. The square pin parts 4, 5 of the split square pin can rotate independently of each other.

A handle of the desired type can be attached to each of the square pin sections. In the example in figure 1, the square pin parts 5, 4 are arranged with door turners 3,2. The lock's cover plates are not shown in figure 1.1 In some versions, the handles are not attached to the square pin but to the lock's cover plates by using, for example, carriers and a locking ring.

In the embodiment in Figure 1, an electromagnetic lock (or a corresponding mechanical lock type) is arranged in the door 1, and the split square pin is mounted in this. Only the parts necessary for this description are shown. The locking body 8 is provided with a drop tube 9 and jacket pins 10, 11 for both square pin parts 5, 4. When the door turner 3 is turned to open the door 1, the square pin part 5 turns to simultaneously turn the jacket pin 10 specifically for that square pin part. The mantel pin 10 transfers torsional force applied to the square pin to the drop tube 9 which is connected to the rail, and opens the lock. Similarly, when the door turner 2 is turned to open the door 1 from the opposite side of the door, the square pin part 4 turns and simultaneously turns the mantle pin 11 especially for the square pin part. The casing pin must transmit torsional force to the downpipe 9.

Furthermore, there is a separate disc 7 between the square pin parts 5 and 4. A separate disc is not required in some designs since the downpipe 9 is provided with a sleeve which is installed in the space between the square pin parts.

In Figure 1, the door twister 3 and the square pin part 5 are on the inside of the door on the so-called exit side. This means that the door can always be opened by using the door turner 3 if necessary. This example will not apply to any locking arrangement. In other words, there is always a connection from the square pin part 5 through the jacket pin 10 to the downpipe 9.

The door knob 2 and the square pin part 4 are on the outside of the door on the so-called control side. This means that the transmission of torsional force applied to the door twister 2 and the square pin part 4 to the downpipe of the lock can be prevented. In this case, the handle 2 performs a "dead twist" and the door can only be opened if the lock is opened by, for example, a mechanical key. Transmission of torsional force is prevented on the control side by using an electromagnet which results in the door being locked.

Furthermore, a split square pin composed of two square pin parts is known from DE

203 15 688 U. Also EP 1004728 describes split square pins for a lock.

The problem with the embodiment in Figure 1 lies in the fact that a locked door can still be opened from the outside if a sufficient force affecting the square pin is applied to the door twister 2 and the square pin part 4, especially in the longitudinal direction of the square pin when the door twister is turned. The force 12 can either be a pushing force, a pulling force or a lateral force.

For example, if the door turner 2 is pushed with force, the square pin part 4 moves towards the inside of the door at the same time as it pushes the casing pin 11 towards the downpipe 9. Sufficient friction surfaces 13 are formed at the contact surfaces between the downpipe 9 and the casing pin 11 which forms a connection from the door turner 2 to the downpipe 9. Simultaneous forceful pushing and turning of the handle causes unwanted opening of the lock.

If the door twister 2 is pulled with force, a friction surface 14 is formed between the inside square pin part 5 and the drive end 15 of the rail. Due to the strong pulling force, the friction surface is sufficient to transmit torsion of the simultaneous turning force on the door turner 2 through the inside square pin part 5 to the jacket pin 10 and the downpipe 9. Simultaneous strong pulling and turning force on the door turner 2 causes unwanted opening of the lock through its inside jacket pin 10.

It is also possible that in some types of locks and/or door twisters force is applied to the square pin which includes a lateral component which results in one of the cases of unwanted opening of the lock described above.

The purpose of the invention is to remove the described problem. The purpose is achieved as presented in the requirements.

Brief description of the invention

The invention removes the effect of external force (especially the longitudinal force) applied to a split square pin on the opposite side square pin and other parts of the lock. The split square pin has at least one flexible element, depending on the design. Furthermore, some designs of the split square pin have a separate bore extension part which is also in the second square pin part. This prevents the formation of a sufficiently large friction surface due to pushing or lateral pulling/pushing.

In a preferred embodiment of the invention, the split square pin comprises a flexible element 25 which can be placed in a bore 29 in the first square pin part. The flexible element encloses the connecting pin 23 fitted through this and the first square pin part 21 and remains in the space between an end 24 of the connecting pin and the first square pin part. Furthermore, the bore 210 in the second square pin part 22 has an extension part 27 at the end of the second square pin part 22 which can be placed against the first square pin part 21. A less preferred embodiment is otherwise similar to the one described above, but there is no extension part 27 in the bore 210 in the other square pin part.

In another embodiment of the invention, the split square pin comprises, in addition to the elements described above, another flexible element 211 which can be placed in the extension part 27 of the bore in the second square pin part. In this case, the second flexible member encloses the connecting pin 23 mounted through this and the second square pin part. Thus, in its basic embodiment, a split square pin according to the invention has a first square pin part 21, a second square pin part 22 and a coupling pin 23 connecting the square pin parts, both parts comprising a bore 29, 210 for the coupling pin 23, as well as a flexible element 25 in the first square peg. Furthermore, in other embodiments of the invention, the second square pin part has a bore extension part 27 or a bore extension part and a second flexible member 211.

In yet another embodiment of the invention comprising two flexible elements and a bore extension part in the second square pin, the second square pin comprises an intermediate square pin 22A in addition to the actual square pin part 22.1 this embodiment, the second flexible element 211 is arranged in the bore extension part 27 to the actual the square pin part 22 and the corresponding extension part 212 of the intermediate square pin 22A. The intermediate square pin has a bore through it for the connecting pin. Thus, the actual four edge pin part 22 and the intermediate square pin 22A can be placed against each other at the ends of the bore extension parts 27,212 in the square pins. The first flexible member 25 can be placed in the first square pin part 21, causing the flexible member to enclose the connecting pin 23 mounted through it and the first square pin part causing the flexible member to remain in the space left between an end (drive end) of the connecting pin and the first square pin part , just like in the other embodiments. The second flexible member 27 can be placed in the bore extension parts 27, 212 of the intermediate square pin 27A and the actual square pin 22C of the second square pin part 22. Each of the flexible members will act in the longitudinal direction of the split square pin when an external force especially in the longitudinal direction , is applied to the split square pin.

Figure list

In the following, the invention will be described in more detail with reference to the attached figures, where:

Figure 1 shows an example of a previously known split square pin.

Figure 2 shows an example of an embodiment of the invention.

Figure 3 shows an example of another embodiment of the invention.

Figure 4 shows the example in Figure 3 from another angle.

Figure 5 shows an example of a further embodiment of the invention.

Figure 6 shows the example in Figure 5 from another angle.

Figure 7 shows an example of an embodiment of an intermediate square pin in one of the embodiments of the invention. Figure 8 shows an example of an embodiment of an actual square pin in one of the embodiments of the invention.

Description of the invention

Figure 2 shows an example of an embodiment of the invention where a connecting pin 23 is mounted through a bore 29 in the first square pin part 21 to a bore 210 in the second square pin part 22. The connecting pin is screwed by its threads 26 to the second pin part. The connecting pin end 24 remains in the bore 29 of the first square pin part 21 so that the flexible element (the first flexible element) 25 in the bore of the first square pin part remains in the space between the connecting pin end 24 and the body of the first square pin part. A space 28 remains between the first square pin part 21 and the second square pin part 22.

When the square pin shown in Figure 2 is mounted in a lock, the flexible member 25 and the bore extension part 27 of the second square pin part prevent the unwanted action of a force applied to the door twister mounted, for example, on the second square pin part 22. For example, if this door twister is pushed or pulled in a longitudinal direction compared to the square pin, the extension part 27 and the flexible element 25 will prevent the negative frictional force applied by the external force on the square pin and/or the lock fira from becoming too great, making it impossible to open the lock in an unwanted way. If, on the other hand, a substantially longitudinal external force on the square pin is applied to the square pin, the flexible member 25 will act when the door handle is pulled, preventing any negative frictional force. If the door handle is pushed with force and the door handle has a sliding connection with the square pin part 22, the sliding movement of the door handle prevents any negative frictional force exerted by pushing. Therefore, the embodiment in Figure 2 is advantageous for applications where the door twister is attached to the lock's cover plate and can slide in the longitudinal direction of the square pin part.

However, it is also possible to create an embodiment according to Figure 2 without the extension part 27 in the second square pin part. The designation in bold type for the extension part 27 shows this possibility in figure 2.1 this basic design, however, it is required that the door turner connected to the second square pin part 22 is mounted to the cover plate in a way that allows sufficient movement of the door turner in relation to the second square pin part. This can be difficult to implement in practice.

Figure 3 shows an example of another embodiment of the invention. The composition in this embodiment is similar to that shown in figure 2, but in addition it comprises a second flexible element 211 placed in the bore extension part 27 to the second square pin part 22.1 this version, the door twisters can be mounted directly on the square pin part by, for example, screws, so that the door twister cannot slide in the longitudinal direction of the square pin. The second flexible element 27 prevents any negative frictional force, for example when the second square pin 22 or the door twister attached to it is pushed forcefully against the first square pin part. Naturally, this design also takes forces applied to the square pin from other directions into the calculation, corresponding to what is described above. Figure 4 shows a cross-sectional view of the example in Figure 3.

In the embodiment in Figure 3, where two flexible elements are used, the first flexible element 25 is preferably less flexible than the corresponding flexible element 25 in the embodiment in Figure 2. This provides the desired functionality in both embodiments. Because it is preferred in all practical embodiments of the invention that the flexible elements 25, 211 are springs, greater flexibility in the embodiment in Figure 2 can be achieved by using a spring which is longer but in other respects similar to that in the embodiment in Figure 3 .

When the split square pin shown in figure 3 is mounted in a lock, the end of the second flexible element 211 closer to the first square pin part 21 will be stabilized against the lock.

Figure 5 shows an example of a further embodiment of the invention. Figure 6 shows a cross-sectional view of the embodiment in Figure 5 from another angle. Let us assume that the first square pin part 21 is the inside square pin part and the second square pin part 22 is the outside square pin part. Figure 5 shows the square pin in its mounting configuration (corresponding to previous figures 2 to 4), where the connecting pin 23 is screwed into the second square pin part 22 by bolt threads 26, more precisely in the bore 210 in the second square pin part. The drive end 24 of the coupling pin remains in the extension part of the bore 29 of the first square pin part 21. The first flexible element 25 is placed in the bore 29 of the first square pin part and remains between the drive end 24 of the coupling pin and the first square pin part 21. The first flexible element 25 guarantees the flexibility to the square pin, especially in the longitudinal direction, if the second square pin 22 is pulled away from the first square pin 21, which in a practical installation means away from the door. A space 28 remains between the square pin parts. The square pin parts 21,22 can rotate independently of each other, just as in previous designs.

In addition to the actual square pin part, the second square pin part 22 comprises an intermediate square pin 22A. The intermediate square pin and the actual square pin part comprise a bore for the connecting pin 23. The bore in the intermediate square pin passes through the intermediate square pin. These bores comprise the extension parts 27, 212. Thus, the second square pin part 22 forms a unit 22S together with the intermediate square pin. The actual square pin part 22 and the intermediate square pin 22A can be placed against each other at the ends of the extension parts 27, 212 of the square pins. The second flexible member 211 is placed in the bore extension parts 27, 212 of the actual square pin and the intermediate square pin, leaving a space 213 between the actual square pin part and the intermediate square pin. The gap 213 and the flexible element 211 guarantee the flexibility of the square pin, especially in the longitudinal direction, if the second square pin 22 is pushed against the first square pin 21, which in practical installation means towards the door.

Furthermore, in the embodiment of Figure 5, the space 213 between the actual square pin portion 22 and the intermediate square pin 22A is covered by a separate collar 22B which provides support, connects the intermediate square pin to the actual square pin through its body and protects the second flexible member 211. the actual square pin portion, the intermediate square pin, or both, is allowed to move in the collar 22B. The collar is not required to be a separate component. It can also be an integral part of either the intermediate square pin or the actual square pin. Figure 7 shows an embodiment of the intermediate square pin 22A where the collar 41 is an integral part. In this embodiment, the actual square pin part can move in the collar extension 41. Figure 8 shows an embodiment of the actual square pin 22 where the collar 51 is an integral part. In this embodiment, the intermediate square pin can move in the collar extension 51.

Thus, the examples in Figures 2 to 6 are based on the assumption that the first square pin part 21 is the inside square pin part and the second square pin part 22 is the outside square pin part. Let us further assume that the square pins in the figures are mounted in an electromagnetic lock or a mechanical lock using a corresponding function as shown in Figure 1. If a force 12 especially in the longitudinal direction of the square pin is applied to the outer square pin 22, the flexible element 25 prevents or 211 (note the embodiment in figure 2 separately) the force from being transferred to the downpipe 9. The described examples also take into account the unwanted transfer of force to the downpipe due to a lateral force applied to the square pin part.

In the embodiment in, for example, Figures 3 to 6, and if the second square pin part 22 is pulled and turned simultaneously, the first flexible element 25 will act to prevent the transfer of force through the inside square pin 10 to the lock's downtube 9. On the other hand, if the second square pin part 22 is pushed and turned at the same time, the second flexible element 211 will act to prevent the transfer of force to the outer casing pin 1 log through the corresponding tube.

As described, the invention can be used in a number of different embodiments. The flexible elements 25,211 can be, for example, springs. It is also advantageous for the operation of the square pin that the flexible element 25 (such as a spring) is arranged in the first square pin part 21 which is a less flexible element, and the flexible element 211 (such as a spring) is arranged in the second square pin part 22 which is a more flexible element. Both the flexible elements 25 and 211 can act at, for example, 1 to 4 mm with the exact distance depending on the requirements of the execution. In the example in Figure 5, the width of the space 213 left between the square pin parts at the second flexible element 211 will determine the maximum performance.

Although the second square pin part 22 in the examples of Figures 2 to 6 are outside square pin parts, a split square pin can also be arranged in a lock such that the second square pin part is the inside square pin part and the first square pin part is the outside square pin part.

It is preferred that the split square pin according to the invention is designed so that when an attempt is made to open the lock by force, the door twister will break, first followed by the square pin and finally the lock.

The connecting pin can be implemented in different ways. For example, it may be a threaded bolt which can be screwed into the actual square pin of the second square pin part with the drive end remaining in the bore of the first square pin part when fitting the split square pin.

It is obvious from the examples presented above that an embodiment of the invention can be carried out by using a range of different solutions. It is also obvious that the invention is not limited to the mentioned examples in this text, but can be used in many other different embodiments within the scope of the inventive idea, as defined by the attached claims.

Claims (14)

Claim 1. Split square pin for a lock comprising a first square pin part (21), a second square pin part (22) and a connecting pin (23) connecting the square pin parts, both parts comprising a bore (29, 210) for the connecting pin, characterized in that the split square pin comprises a flexible element (25) which can be placed in a bore (29) in the first square pin part (21), whereby the flexible element (25) encloses the connecting pin (23) which is mounted through it and the first square pin part (21) and makes that the flexible element (25) remains in the space left between an end (24) of the connecting pin and the first square pin part (21). 2. Square pin according to claim 1, characterized in that the bore (210) in the second square pin part (22) comprises an extension part (27) at the end of the second square pin part (22) which can be placed against the first square pin part (21). 3. Square pin according to claim 2, characterized in that the split square pin comprises a second flexible element (211) which can be placed in the extension part (27) of the second square pin part (22), whereby the second flexible element (211) encloses the connecting pin (23) which is fitted through it and the other square pin part (22). 4. Square pin according to claim 3, characterized in that when the split square pin is mounted in a lock, the end of the second flexible element (211) which is closest to the first square pin part is placed against the lock. 5. Square pin according to one of claims 3 to 4, characterized in that the second square pin part (22) additionally comprises an intermediate square pin (22A) with a bore through it for a connecting pin (23), the bore has an extension part at one of the ends of the the intermediate square pin (22A) and the intermediate square pin (22A) allows its placement against the actual second square pin part (22) at the end of the extension part of the intermediate square part, in which case the end of the second flexible member (211) which is closer to the first square pin part (21) is placed in the extension part of the intermediate square pin (22A). 6. Square pin according to claim 5, characterized in that the intermediate square pin of the second square pin part (22) comprises a collar extension (41). 7. Square pin according to claim 5, characterized in that the actual second square pin part (22) comprises a collar extension (51) in which the intermediate square pin (22A) can be arranged. 8. Square pin according to claim 5, characterized in that it comprises a collar (22B) which can be placed over the extension parts of the intermediate square pin (22A) to the second square pin part (22) and the actual second square pin part to thereby connect the intermediate square pin (22A) and the actual square pin part (22). 9. Square pin according to one of claims 6, 7 or 8, characterized in that the intermediate square pin (22A), the actual second square pin part (22), or both, are allowed to move in a collar. 10. Square pin according to one of claims 1 to 9, characterized in that the flexible elements (25, 211) are springs. 11. Square pin according to one of claims 3 to 10, characterized in that the flexible part (25) placed in the first square pin part (21) is less flexible, and the flexible part (211) arranged in the second square pin part (22) is more flexible, relative to each other. 12. Square pin according to one of claims 1 to 11, characterized in that the second square pin part (22) is an outside square pin. 13. Square pin according to one of claims 1 to 12, characterized in that the connecting pin (23) is a bolt, the threads of which can be screwed into the actual square pin of the second square pin part (22), and the drive end of this will remain in a bore in the first square pin part (21) when installing the split square pin. 14. Square pin according to one of claims 1 to 13, characterized in that the bore in the first square pin part (21) comprises an extension part.