DE10065155A1 - Coupling arrangement in lock cylinder comprises coupling elements for first rotating part which engage in coupling openings of second rotating part - Google Patents

Abstract

A coupling arrangement in a lock cylinder (1) comprises coupling elements (12) for a first rotating part (6) which engage in coupling openings (15) of a second rotating part and are held there as a result of a radial rear support by a control element (9) displaceable from a first operating position corresponding to a coupled position into a second operating position corresponding to an uncoupled position. The control element is a bolt displaceable in an axial direction of the rotating parts. The coupling openings are arranged directly adjacent to each other in the peripheral direction under the formation of roof-like edges (16). Preferred Features: The coupling elements are pins or balls.

Description

The invention relates to a clutch arrangement in one Lock cylinder between a first and a second Turned part, with the first rotating part assigned dome tion elements in a clutch engagement position in Engage clutch openings of the second rotating part and there according to a radial back support by a from a position corresponding to the coupled position Most operating position in one of the uncoupled positions corresponding second operating position shiftable Control element are held.

A clutch assembly of the type in question is known from GB 2 259 737 A, the control member designed as an eccentric that can be rotated by a motor is. By rotating the same by means of a in an electric motor housed who the spherical coupling elements radially outwards in groove-shaped coupling openings of the second rotating part relocated.

The object of the invention is based on the task de, a generic clutch assembly from herstel technically simple, reliable working opening to specify construction.

This task is solved initially and essentially in a clutch arrangement with the features of Claim 1, which is based on that Control element shifted in the axial direction of the turned parts bar is slider, the coupling openings under Forming roof-like abutting flanks in The circumferential direction lie directly next to each other.  

Due to such a design, a clutch is order of the type in question, which is essentially through a simple structure and secondly through reliable operation distinguished. The simple structure results from that the control member now turns in the axial direction parts displaceable slide is. Preferably one can regarding the drive of an electromagnet operate that works according to the submersible anchor principle. The plunger will then be in the uncoupled position held by a spring while the coupled stel tion is maintained by magnetic force. He takes Sliding in its relocated position, the Coupling elements taken the radial support. That means that then the second operating position is present, in which the first rotating part opposite the second rotating part is displaceable without a generate kung. The slide is controlled in the clutch position, so through the slide the coupling elements are pressed radially outwards under Establish the coupling connection between the first and second rotating part. Because of the special design of the clutch openings is realized that the coupling elements always in case of slide displacement find the clutch position clutch openings what Avoids locking problems. Over the roof together the abutting flanks of the circumferential direction immediately side by side clutch openings becomes a produces certain centering effect, so that the clutch always securely into the coupling openings be moved. Another way of inventing To solve the task is that the tax judge a shiftable in the axial direction of the turned parts Slider is, the coupling elements in the decoupling pelt operating position due to radial spring force in  immerse the clutch openings and at torque surcharge due to a slope control radi al are evasive. In this variant, the Coupling elements before the slide is moved in the coupling position in the coupling openings into it. The slide is then in the engagement position brought, so he provides support for the Coupling elements so that these in their entry position to the coupling openings remain and at a drive shift via the slope control tion the slewing ring between the first and second Manufacture turned part.

According to the invention it is provided that the slide Coupling elements emerging from the engagement position due to a wedge effect in the coupling openings repressed. The wedge action can either be out of shape the coupling elements or the shape of the end of the shoot result. However, it is also possible that both the coupling elements and the slide too contribute to the wedge effect. There is also a partial feature of the invention in that the number the coupling elements is smaller than the number of Coupling openings. It is possible that the Coupling elements designed as pins or balls are. A variant is characterized in that the Coupling openings have a crescent-shaped cross section to have. The sickle course can be the circumferential course be adapted to the coupling elements. This recommends especially when the coupling elements have a spherical shape. Another issue design is characterized in that the circumferential length ge of the coupling openings is larger than the circumferential Wei te of the coupling elements. That way realize a certain game. Only after Durchlau  The corresponding shooting game is started impact of the coupling elements against spring action through the slope control. To achieve that the spring-loaded coupling elements in succession Effect, lies are essentially diame tral opposite roof ridge lines slightly in Circumferential direction offset to that in the diametral provided coupling elements arranged. In the second version it is possible to have a rotational symmetry use slider, which benefits the position of the lock cylinder brings, in the sense a cost saving. Finally, it should be emphasized ensure that the coupling openings are concentric with the Have axis of rotation running floor. As long as the dome Support elements are supported on this floor do not move axially. Only then does this take place instead if the coupling elements on the roof-like colliding flanks.

Below are two embodiments of the invention tion explained using the drawings. It shows:

Fig. 1 is a view of an inventive lock cylinder designed, on the first approximate shape exporting,

Fig. 2 shows the section along the line II-II in Fig. 1, in an enlarged representation, Subject Author fend the engaged position of the control of the Glienicke or slide,

Fig. 3 shows a sequence view of FIG. 2, and that upon rotation of the first rotary member with respect to the second rotating member, wherein a the two coupling elements runs on an oblique flank,

Wherein the slider is moved back in the clutch disengagement position and the clutch elements upon rotation of the first rotating part, the return displacement against spring force, Fig. 4 is also a sectional view similar enabled,

Fig. 5 shows a longitudinal section through a lock cylinder according to the second embodiment with the slide and pilot-controlled in the coupling position

FIG. 6 is an illustration like FIG. 5, but with the slide displaced back and with the first rotating part displaced with respect to the second rotating part.

The locking cylinder 1 shown is designed as a Profilzylin. It has a cylinder housing 2 with a central cutout 3 for receiving a closing member 4th This is in constant coupling connection with a door 5 arranged inside the door. For this purpose, the knob 5 and the closing member 4 are rotatably connected with a cylinder part 2 encompassed by the most rotating part 6 . This engages in a second rotating part 7 which is arranged concentrically to it and which is rotatably coupled to an outer knob 8 . The latter can include the batteries of a power supply, for example. The inside door knob 5 is used to accommodate an electronic access control circuit, not shown. Through this, a signal entered from the outside of the door is read. If the signal is correctly recognized by the access control circuit, an electromagnetic, not illustrated, displacement of a control element 9 takes place , which is designed according to the first embodiment according to FIGS. 1 to 4 as a rotationally symmetrical slide. It is guided in an inner sleeve 10 arranged in a rotationally fixed manner in the first rotating part 6 .

The first rotating part 6 with the inner sleeve 10 has in diame tral opposite two graded holes 11 for receiving a stepped coupling element 12 , which is designed as a spring-loaded in the radial outward direction. In detail, each coupling pin 12 is composed of a larger-diameter head 12 'and a stepped shaft 12 ". A compression spring 13 sits on the latter, which loads the coupling pin 12 in the radial outward direction. The rounded-shaped head 12 ' is supported. on the bottom 14 of a coupling opening 15 of the second rotating part 7. In the supporting position, the inner end of the shaft 12 "projects into the inner sleeve 10 , see FIG. 2. In the exemplary embodiment, four such coupling openings 15 are provided with the same circumferential distribution. Mutually neighbored coupling openings 15 go over inclined flanks 16 into a ridge line 17 which extends to the surface of the first rotating part 6 and accordingly brings this radial support. As illustrated in FIG. 4 in particular, there are essentially diametrically opposed ridge lines 17 offset slightly in the circumferential direction from the coupling elements 12 arranged in the diametra DD. This is clear from the fact that the one obliquely downward te coupling element 12 is on the ridge line 17 , while the opposite coupling element 12 acts on the facing oblique flank 16 .

Since the circumferential length of the coupling openings 15 is greater than the circumferential width of the coupling elements 12 , there is a rotational play of the rotating parts 6 , 7 in both directions to each other according to FIG. 2.

The following mode of action occurs:

An actuation of the closing member 4 is possible at any time from the inside of the door by means of the knob 5 . With such a displacement, the first rotating part 6 rotates relative to the second rotating part 7 . This state is illustrated in Fig. 4. The control member 9 or the slide is in a moved back position and does not protrude into the area between the mutually facing ends of the coupling elements 12 . If the rotating part 6 is now rotated, this leads to a collision of the coupling elements 12 on the corresponding inclined flanks 16 . FIG. 4 is a case where a coupling pin 12 has explained may the ridge line 17, while the opposite coupling pin 12 bears on an inclined flank 16 yet. This means that the coupling pins 12 come into effect one after the other and accordingly the torque applied here is relatively low.

If, on the other hand, there is a closing operation from the outside of the door 8 , only the outer knob 8 can be rotated without access authorization, and with it the second rotating part 2 with respect to the first rotating part 6 . There is then only Lich an evasive movement of the coupling elements without establishing a coupling connection to the first rotating part 6 and thus to the locking member 4 .

Rather, the entrainment of the locking member 4 requires the input of a signal, for example by means of an electronic transmitter, etc. If the locking authorization is recognized by the electronic access control circuit, this leads to a displacement of the rotationally symmetrically designed slide 9 into the position according to FIGS . 2 and 3. Since, as shown in FIG. 3, there is no evasive displacement of the coupling elements 12 due to the then present backing, the coupling elements 12 can only shift slightly in the radial direction in the radial direction after running through the play, and then one over the inclined flanks 16 Generate entrainment effect. The first and second rotary parts 6 , 7 are thus coupled to one another and thus the rotational displacement of the outer knob 8 is also transmitted to the locking member 4 .

According to the second embodiment shown in FIGS . 5 and 6, the same components have the same reference numerals. The second rotating part 7 also has in the circumferential direction immediately adjacent, in a ridge line 17 abutting flanks. Regarding the same, there are the ends of the coupling openings 18 , which in turn have a crescent-shaped cross section. In the exemplary embodiment, eight such coupling openings 18 are provided such that two coupling openings 18 are opposite each other in a diametral manner. The roof opening lines 17 formed by the coupling openings 18 protrude up to the outer circumference of the first rotating part 6 . As in the first embodiment, this can also be in constant coupling connection with the closing element 4 . The first rotating part 6 is sleeve-shaped and has a diametral bore 19 for receiving coupling elements 20 arranged in the diametral. The same are designed as balls, the Kugelra diaus corresponds to the radius of the crescent-shaped coupling openings 18 .

Between the spherical coupling elements 20 is in the axis of rotation of the rotating parts 6 , 7 axially displaceable slide 21 out. The elements 20 which can be controlled between the coupling elements 20, the end of the slide 21 , as illustrated in FIG. 6, can form in a ridge meeting sloping flanks 22 which serve to control the balls 20 in the radial outward direction. The thickness of the slider 21 is chosen so large that in the engaged state, the radially outwardly displaced spherical coupling elements 20 are completely into the coupling openings 18 opposite them.

In contrast to the first embodiment, the balls 20 , since they are not spring-loaded, can shift radially inwards when the slide 21 is uncoupled, the position according to FIG. 6 being established, for example. The first rotating part 6 is permanently connected to the closing member, while the second rotating part 7 rotates empty to the inner rotating part 6 when the outer knob is rotated.

In order to be able to close the lock cylinder from the outside of the door, the front entry signal must be entered from the outside of the door. After detection, this leads to a displacement of the slide valve 21 into the coupling position, in which the coupling elements 20 are urged in the radial outward direction via the inclined flanks 22 and spherical curves. The crescent-shaped coupling openings 18 cause a centering effect. After the coupling elements 20 are in their coupling position, can by means of the outer knob 8 via the second and first rotary member entrainment of the closing member. 4

All features disclosed are (by themselves) fiction sentlich. In the disclosure of the registration is hereby also the disclosure content of the associated / attached Priority documents (copy of pre-registration) full included in content, also for the purpose of characteristics of these documents in claims of the present application to include.

Claims (10)

1. Coupling arrangement in a lock cylinder ( 1 ) between a first ( 6 ) and a second rotating part ( 7 ), the first rotating part ( 6 ) being associated with coupling elements ( 12 , 20 ) in a coupling engagement position in coupling openings ( 15 , 18 ) of the Intervene second rotary part ( 7 ) and there, according to a radial backing, are held by a control element ( 9 , 21 ) which can be displaced from a first operating position corresponding to the coupled position into a second operating position corresponding to the uncoupled position, characterized in that the control element ( 9 , 21 ) is a slide ( 9 , 21 ) which can be displaced in the axial direction of the rotating parts ( 6 , 7 ), the coupling openings ( 15 , 18 ) lying directly next to one another in the circumferential direction, forming roof-like abutting flanks ( 16 ). 2. Coupling arrangement in a lock cylinder ( 1 ) between a first ( 6 ) and a second rotating part ( 7 ), with the first rotating part ( 6 ) associated coupling elements ( 12 ) engaging in a clutch engagement position in clutch openings ( 15 ) and there according to a radial Support by a control element ( 9 ) which can be displaced from a first operating position corresponding to the coupled position to a second operating position corresponding to the uncoupled position, characterized in that the control member ( 9 ) has a slide which can be displaced in the axial direction of the rotary parts ( 6 , 7 ) ( 9 ), with the clutch elements ( 12 ) being immersed in the uncoupled operating position due to radial spring force into the clutch openings ( 15 ) and radially evasive when subjected to torque due to a slope control. 3. Coupling arrangement according to claim 1 or in particular according thereto, characterized in that the slide ( 21 ) displaces the coupling elements ( 20 ) emerging from the engagement position as a result of a wedge effect in the coupling openings ( 18 ). 4. Coupling arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the number of coupling elements ( 12 , 20 ) is smaller than the number of coupling openings ( 15 or 18 ). 5. Coupling arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the coupling elements ( 12 , 20 ) are designed as pins or balls. 6. Coupling arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the coupling openings ( 18 ) have a crescent-shaped cross section. 7. Coupling arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the circumferential length of the coupling openings ( 15 ) is greater than the circumferential width of the coupling elements ( 12 ). 8. Coupling arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that substantially diametrically opposed ridge lines ( 17 ) are arranged slightly offset in the circumferential direction from the coupling elements ( 12 ) provided in the diametrals (DD). 9. Coupling arrangement according to one or more of the preceding claims or in particular according thereto, characterized by a rotationally symmetrical slide ber ( 21 ). 10. Coupling arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the coupling openings ( 15 ) have a bottom ( 14 ) running concentrically to the axis of rotation.