RU2354797C2 - Split spindel - Google Patents

Abstract

FIELD: building industry. ^ SUBSTANCE: invention refers to hardware items, particularly to split spindle of lock consisting of first part of spindle, of second part of spindle and of connecting pin uniting part of spindle; also both parts have openings for connecting pin. The split spindle contains a flexible element designed to be inserted in the opening in the first part of the spindle so, that the flexible element envelopes the connecting pin inserted in it and in the first part of the spindle; also the flexible element remains in space left between one end of the connecting pin and the first part of the spindle. ^ EFFECT: eliminating unwanted effect of external force applied to split spindle. ^ 15 cl, 8 dwg

Description

The invention relates to lock spindles, cut into two parts and connected by a connecting pin, also to locks with a split spindle, in particular to solenoid types of locks and the corresponding mechanical types of locks.

Figure 1 shows a split spindle, consisting of two parts 4, 5 of the spindle, and a connecting pin connecting these two parts. In the embodiment of FIG. 1, the connecting pin is a solid bolt that is screwed into a hole in one of the parts of the spindle 4 by a screw thread, so that the engaging end 15 of the bolt 6 remains in the expanded part of the hole passing through the other part 5 of the spindle. The coupling end 15 may be screwed into the hole in the spindle part 15 by means of a universal wrench, for example, depending on the type of tool for which the coupling end has been machined. Parts 4, 5 of the spindle of the split spindle can be rotated independently of each other.

The handle of the desired type can be mounted on each of the spindle parts. In the example of FIG. 1, spindle parts 5, 4 are mounted with lever arms 3, 2. Butt pad locks are not shown in figure 1. In some embodiments, the handles are not secured to the spindle, but are mounted on the butt pads of the lock using, for example, bearings and a snap ring.

In the embodiment of FIG. 1, a solenoidal lock (or a corresponding mechanical type of lock) is installed in the door 1, and a split spindle is installed therein. Only parts of the castle needed for this description are illustrated. The housing 8 of the lock is installed with a pusher 9 and leads 10, 11 for both parts 5, 4 of the spindle. When the handle 3 is rotated to open the door 1, the spindle part 5 is rotated while turning the leash 10 related to the spindle part. The leash 10 transfers the torsional force applied to the spindle to the push rod 9, which is connected to the lock bolt, and opens the lock. Accordingly, when the handle 2 is rotated to open the door 1 on the opposite side of the door, the spindle part 4 is rotated while turning the leash 11 related to the spindle part. The leash transmits torsional force to the follower 9.

In addition, a separate washer 7 is located between the spindle parts 5 and 4. A separate washer is not required in some embodiments when the pusher 9 is installed with a sealing ring that is located in the gap between the spindle parts.

In figure 1, the handle 3 and the spindle part 5 are located on the inside of the door, on the so-called output side. This means that the door can always be opened if necessary using the handle 3. In this example, no locking device is disclosed. In other words, there is always a connection from the spindle part 5 through the leash 10 to the push rod 9.

The handle 2 and part 4 of the spindle are located on the outside of the door, on the so-called control side. This means that the transmission of torsional force exerted on the handle 2 and part 4 of the spindle to the lock pusher can be prevented. In this case, the handle 2 rotates idle, and the door can only be opened if the lock is opened with a mechanical key, for example, the transmission of torsional force is prevented on the control side using a solenoid, which leads to blocking of the door.

The disadvantage of the embodiment shown in FIG. 1 is that the locked door can nevertheless be opened from the outside if sufficient force is applied to the spindle to the handle 2 and part 4 of the spindle, especially in the longitudinal direction of the spindle when turning the handle. The force 12 can be either pushing force, traction force or lateral force.

For example, if the handle 2 is pushed with force, then the spindle part 4 will move to the inside of the door, while simultaneously pushing the lead 11 to the pusher 9. Sufficient friction surfaces 13 are formed when the surfaces contact between the pusher 9 and the lead 11, which creates a connection from the handle 2 to pusher 9. The simultaneous strong pushing and rotation of the handle cause unwanted opening of the lock.

If the handle is pulled with force, a friction surface 14 is formed between the inner part 5 of the spindle and the engaging end 15 of the bolt. As a result of the large pulling force, the friction surface is sufficient to transmit the torque of the simultaneous turning force to the handle 2 through the inner part 5 of the spindle to the leash 10 and the pusher 9. The simultaneous large pulling force and the turning force exerted on the handle 2 cause an undesirable opening of the lock through it inner leash 10.

It is also possible that in some types of locks and / or handles, the force exerted on the spindle that contains the transverse element will lead to one of the cases of undesired opening of the lock described above.

The objective of the present invention is to remedy this drawback by using a split lock spindle, as presented in the claims.

The present invention eliminates the effect of an external force (especially a longitudinal force) applied to the split spindle on the spindle with opposite sides and other parts of the lock. The split spindle comprises at least one flexible member, depending on the embodiment. In addition, some embodiments of the split spindle have a separate widened part of the hole also in the second part of the spindle. This prevents the formation of a sufficiently large friction surface as a result of pushing or lateral tension / pushing.

In a preferred embodiment of the present invention, the split spindle comprises a flexible member 25 that can be installed in the hole 29 in the first part of the spindle. A flexible element surrounds the connecting pin 23 installed therein and the first spindle part 21, and remains in the space left between one end 24 of the connecting pin and the first spindle part. In addition, the hole 210 in the second spindle part 22 has an expanded part 27 at the end of the second spindle part 22, which can be placed against the first spindle part 21. A less preferred embodiment is otherwise similar to the embodiment described above, except that in the second part of the spindle there is no expanded part 27 of the hole 210.

In another embodiment of the present invention, the split spindle comprises, in addition to these structures, another flexible member 211 that can be installed in the expanded portion 27 of the hole in the second portion of the spindle. In this case, the second flexible element surrounds the connecting pin 23 installed in it and in the second part of the spindle. Thus, in its main embodiment, the split lock spindle in accordance with the present invention comprises a first spindle part 21, a second spindle part 22 and a connecting pin 23 connecting the spindle parts, both parts containing holes 29, 210 for the connecting pin 23, and flexible element 25 in the first part of the spindle. In addition, in other embodiments of the present invention, the second spindle portion comprises an expanded hole portion 27 or an expanded hole portion 27 and a second flexible member 211.

In yet another embodiment of the present invention, which comprises two flexible members and an expanded part of the hole in the second spindle part, the second spindle part comprises an intermediate spindle 22A in addition to the main spindle part 22. In this embodiment, the second flexible member 211 is installed in the expanded portion 27 of the opening of the main spindle portion 22 and the corresponding expanded portion 212 of the intermediate spindle 22A. The intermediate spindle has an opening for the connecting pin. Thus, the main spindle part 22 and the intermediate spindle 22A can be arranged relative to each other at the ends of the expanded spindle bore parts 27, 212. The first flexible member 25 may be mounted in the first spindle part 21 in such a way that it surrounds the connecting pin 23 installed therein and the first spindle part, and remains in the space left between the first end (engaging end) of the connecting pin and the first spindle part as in other embodiments. The second flexible member 211 may be installed in the expanded hole portions 27, 212 in the intermediate spindle 22A and the main spindle 22C in the second spindle part 22. Any of these flexible elements will stretch in the longitudinal direction of the split spindle when external force is applied, especially in the longitudinal direction, to the split spindle.

The invention is described in more detail below with reference to the accompanying drawings, in which:

figure 1 shows an example of a split spindle of the prior art;

figure 2 shows an example embodiment of the present invention;

figure 3 shows an example of another embodiment of the present invention;

figure 4 shows an example of figure 3 from a different angle;

figure 5 shows an example of another embodiment of the present invention;

figure 6 shows an example of figure 5 from a different angle;

7 depicts an example implementation of an intermediate spindle in one embodiment of the present invention; and

on Fig depicts an example implementation of the real part of the spindle in one of the embodiments of the present invention.

Figure 2 shows an example embodiment of the present invention, in which the connecting pin 23 is installed through the hole 29 in the first part 21 of the spindle into the hole 210 in the second part 22 of the spindle. The connecting pin is screwed into the second part of the spindle by means of its thread 26. The end 24 of the connecting pin remains in the hole 29 in the first spindle part 21, while the flexible element (first flexible element) 25 in the opening of the first spindle part remains in the space between the end 24 of the connecting pin and the housing of the first spindle part. The gap 28 remains between the first spindle part 21 and the second spindle part 22.

When the spindle of FIG. 2 is inserted into the lock, the flexible member 25 and the expanded hole part 27 in the second spindle part prevent undesired effects of the force exerted on the handle mounted, for example, in the second spindle part 22. For example, if the handle is pressed or pulled laterally in comparison with the spindle, then the expanded part 27 of the hole and the flexible element 25 will prevent the occurrence of too much undesirable friction due to this external force on the spindle and / or lock, making it impossible to open lock in an undesirable way. If, on the other hand, an external force essentially acting in the longitudinal direction of the spindle is applied to the spindle, then the flexible member 25 will stretch when pulled by the handle, preventing any undesired frictional force. If the specified handle is pushed with force, and the handle has a sliding connection with the spindle part 22, then sliding prevents any undesired frictional force caused by pushing. Therefore, the embodiment of FIG. 2 is optimal for applications in which the handle is mounted on the butt of the lock and can slide in the longitudinal direction of the spindle part.

However, it is possible to implement the embodiment in accordance with FIG. 2 without the expanded hole portion 27 in the second spindle portion. The bold designation of the expanded portion 27 illustrates this feature in FIG. In this basic embodiment, however, it is necessary that the handle connected to the second spindle part 22 be inserted into the butt plate in such a way as to ensure sufficient movement of the handle relative to the second spindle part. This can be difficult to implement.

Figure 3 shows an example of another embodiment of the present invention. The construction of this embodiment is similar to that shown in FIG. 2, but furthermore, it comprises a second flexible member 211 mounted in the expanded portion 27 of the opening of the second spindle portion 22. In this embodiment, the handle can be fixed directly to the spindle parts by means of screws, for example, so that the handle cannot slide in the longitudinal direction of the spindle. The second flexible member 211 prevents any undesired frictional force, for example, when the second spindle part 22 or the handle attached thereto is pushed with force toward the first spindle part. Of course, this embodiment also takes into account the forces exerted on the spindle in other directions in accordance with what has been described above. FIG. 4 is a cross-sectional view of the example of FIG. 3.

In the embodiment of FIG. 3, in which two flexible members are used, the first flexible member 25 is preferably less flexible than the corresponding flexible member 25 in the embodiment of FIG. 2. This creates optimal functionality in both embodiments. Since in all practical embodiments of the present invention it is preferred that the flexible members 25, 211 are springs, greater flexibility in the embodiment of FIG. 2 can be achieved by using a spring that is longer but otherwise similar to the spring in the embodiment of FIG. 3 .

When installing the split spindle, shown in figure 3, in the lock - the end of the second flexible element, which is closer to the first part 21 of the spindle - is installed against the lock.

Figure 5 shows an example of another embodiment of the present invention. FIG. 6 is a cross-sectional view of the embodiment of FIG. 5 from a different angle. Assume that the first spindle part 21 is the inner part of the spindle, and the second spindle part 22 is the outer part of the spindle. Figure 5 shows the spindle in its installation configuration (similar to the previous figures 2-4), in which the connecting pin 23 is screwed into the second part 22 of the spindle by a screw thread 26, more specifically, into the hole 210 in the second part of the spindle. The engaging end 24 of the connecting pin remains in the expanded part of the hole 29 in the first spindle part 21. The first flexible element 25 is installed in the hole 29 in the first part of the spindle and remains between the engaging end 24 of the connecting pin and the first part 21 of the spindle. The first flexible element 25 provides the flexibility of the spindle, especially in the longitudinal direction, if the second spindle part 22 is pulled from the first spindle part 21, which in practice means installation from the door. The gap 28 remains between the parts of the spindle. Spindle parts 21, 22 can be rotated independently of each other in the same way as in previous embodiments.

In addition to the main spindle part, the second spindle part 22 comprises an intermediate spindle 22A. The intermediate spindle and part of the main spindle contain holes for the connecting pin 23. The hole passes through the intermediate spindle. These openings comprise widened portions 27, 212. Thus, the second spindle portion 22 forms a single unit 22S together with an intermediate spindle. Part 22 of the main spindle and the intermediate spindle 22A can be mounted relative to each other at the ends of the expanded parts 27, 212 of the holes in the spindles. The second flexible member 211 is installed in the expanded hole portions 27, 212 in the main spindle and the intermediate spindle, leaving a gap 213 between the main spindle part and the intermediate spindle. The gap 213 and the second flexible element 211 provide flexibility of the spindle, especially in the longitudinal direction, if the second spindle part 22 is pushed towards the first spindle part 21, which in practice when installed means towards the door.

In addition, in the embodiment of FIG. 5, the gap 213 between the main spindle part 22 and the intermediate spindle 22A is closed by a separate ring 22B that provides support, connects the intermediate spindle to the main spindle in its housing and protects the second flexible element 211. A part of the main spindle, intermediate spindle, or both, can move inside ring 22B. The ring does not have to be a separate element. It can also be made in one piece or with an intermediate spindle, or with the main spindle. Fig. 7 shows an embodiment of an intermediate spindle 22A in which the ring 41 is integral with it. In this embodiment, a portion of the main spindle can be moved in the expanded portion 41 of the ring. On Fig shows an embodiment of part 22 of the main spindle, in which the ring 51 is made in one piece with him. In this embodiment, the intermediate spindle can move in the expanded portion 51 of the ring.

Thus, the examples in FIGS. 2-6 are based on the assumption that the first spindle part 21 is the inner part of the spindle, and the second spindle part 22 is the outer part of the spindle. Then, suppose that the spindles in accordance with the drawings are installed in a solenoidal lock or mechanical lock, performing the corresponding function, as shown in figure 1. If a force, especially in the longitudinal direction of the spindle, is applied to the outer part 22 of the spindle, then the flexible elements 25 or 211 (pay attention to the embodiment of FIG. 2 separately) prevent the transmission of force to the follower 9. The described examples also take into account undesired gear forces on the pusher due to shear force exerted on the spindle part.

In the embodiments of FIGS. 3-6, for example, if the second spindle part 22 is pulled and rotated at the same time, then the first flexible member 25 will stretch, preventing the transmission of force through the inner leash 10 to the lock pusher 9. On the other hand, if the second spindle part 22 is pushed and rotated at the same time, then the second flexible member 211 will stretch, preventing the transmission of force to the outer leash 11 and through it to the pusher.

As described, the present invention can be implemented in several different embodiments. Flexible elements 25, 211 may be springs, for example. It is also optimal for the operation of the spindle so that the flexible member 25 (such as a spring) installed in the first spindle part 21 is a less flexible member and the flexible member 211 (such as a spring) installed in the second spindle part 22 is a more flexible member. Both flexible elements 25 and 211 can be stretched by 1-4 mm, for example, providing an exact distance depending on the requirements of the embodiment. In the example of FIG. 5, the width of the gap 213 remaining between the spindle parts of the second flexible member 211 determines the maximum stretch.

Although the second spindle part 22 in the examples of FIGS. 2-6 is the outer part of the spindle, the split spindle can be mounted in the lock so that the second spindle part becomes the inner part of the spindle and the first spindle part becomes the outer part of the spindle.

Preferably, the split spindle in accordance with the present invention was made so that when you try to open the lock by force, the handle first breaks, then the spindle, and finally the lock.

The connecting pin can be made in various ways. For example, it may be a threaded bolt that can be screwed into the main spindle of the second part of the spindle, with the coupling end remaining in the hole of the first part of the spindle when the split spindle is installed.

From the examples presented above, it is understood that an embodiment of the present invention can be implemented using many different solutions. It is also understood that the present invention is not limited to the examples illustrated in this description, and can be implemented in many other embodiments within the scope of the idea of the present invention.

Claims (15)

1. A split lock spindle comprising a first spindle part, a second spindle part and a connecting pin connecting the spindle parts, both parts having holes for the connecting pin, characterized in that the split spindle comprises a flexible element adapted to be placed in the hole in the first part the spindle so that the flexible element surrounds the connecting pin installed therein and in the first part of the spindle, the flexible element remaining in the space left between one end of the connector pin and the first part of the spindle. 2. The spindle according to claim 1, characterized in that the hole in the second part of the spindle contains an expanded part at the end of the second part of the spindle, made with the possibility of placement against the first spindle. 3. The spindle according to claim 2, characterized in that the split spindle contains a second flexible element, configured to be placed in the expanded part of the second part of the spindle so that the second flexible element surrounds the connecting pin installed in it and in the second part of the spindle. 4. The spindle according to claim 3, characterized in that the first flexible element is less flexible than the flexible element in the spindle according to claim 1. 5. The spindle according to claim 3, characterized in that when placing the split spindle in the lock, the end of the second flexible element, which is closer to the first part of the spindle, is located against the lock. 6. The spindle according to claim 3, characterized in that the second part of the spindle further comprises an intermediate spindle with an opening therein for a connecting pin, said hole having an expanded part at one of the ends of the intermediate spindle, and said intermediate spindle ensures its location against the second part the main spindle at the end of the expanded part of the hole in the intermediate spindle, in this case, the end of the second flexible element, which is closer to the first part of the spindle, is placed in the expanded part of the hole I'm in the intermediate spindle. 7. The spindle according to claim 6, characterized in that the intermediate spindle of the second part of the spindle contains an extended part of the ring. 8. The spindle according to claim 6, characterized in that the second part of the main spindle contains an expanded part of the ring into which the intermediate spindle can be installed and into which the second part of the main spindle can be installed. 9. The spindle according to claim 6, characterized in that it comprises a ring adapted to be placed above the expanded parts of the holes in the intermediate spindle of the second spindle part and the second part of the main spindle, thereby connecting the intermediate spindle and the main spindle. 10. The spindle according to any one of paragraphs.7, 8 or 9, characterized in that the intermediate spindle, the second part of the main spindle or both are made with the possibility of movement inside the ring. 11. The spindle according to any one of claims 1 to 9, characterized in that the flexible elements are springs. 12. The spindle according to any one of claims 3 to 9, characterized in that the flexible element installed in the first part of the spindle is less flexible, and the flexible element installed in the second part of the spindle is more flexible. 13. The spindle according to any one of claims 1 to 9, characterized in that the second part of the spindle is an outer spindle. 14. The spindle according to any one of claims 1 to 9, characterized in that the connecting pin is a bolt, the thread of which can be screwed into the main spindle of the second part of the spindle, and the coupling end of which will remain in the hole in the first part of the spindle when installing the split spindle. 15. The spindle according to any one of claims 1 to 9, characterized in that the hole in the first part of the spindle contains an expanded part.

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