DE924811C - Shaft adjustment mechanism of the pawl type with pawls that can be operated selectively with the aid of a dial - Google Patents

Description

Shaft adjustment mechanism of the pawl type with the help of a selector part, selectively operated pawls For setting shafts in predetermined positions, especially in remote control radios, e.g. B. Aircraft transmitters., one uses ratchet-type shaft adjustment mechanisms. Such a mechanism has a number of adjustable stop parts on the shaft to be adjusted those arranged next to the shaft selective pawls for locking the shaft be able to work together in a predetermined position. Usually these will Mechanisms provided with an adjustable pawl selector through which the pawls successively brought into the effective position in which they are matched with a corresponding Stop part working together on the shaft. The invention relates to a shaft adjustment mechanism of the latter type and aims at a type in which it is, among other things, very simple Way is possible to set the wave by hand or in any other way To bring location without being hindered by the pawls, and where there is also the possibility, if a mechanism is assumed, at where the positions to be set are within a setting range of 36o °, i.e. H. one revolution of the shaft to be adjusted, a mechanism must be chosen to create in which the positions to be set are distributed over an area as desired can be more than a turn the wave to be set includes. The latter is particularly important when setting tuning coils Sliding contact that have more than one turn.

A shaft adjustment mechanism according to the invention has the feature on that he has a separately movable, with all. Cooperating clinics Part (hereinafter referred to as the pawl lifting part) contains the for each pawl with such a profile is provided that in one of: two end positions, which can be given to the pawl lifting part by external means, all pawls : must be kept lifted by the profiling of the pawl lifting part, while in the other end position .des pawl lifting part any pawl from Selector element can be brought into its effective position without .d doing this from the latch lifting part to be hindered, and in the movement of the pawl lifting part of the second in the first position one possibly brought into the effective position by the selection organ The pawl guided by the profiling of the pawl lifting part in .die ineffective position will.

The presence of the pawl lifting part makes it possible in every position the shaft to be set and the ratchet selector all ratchets out of action to set by this pawl lifting part led from one to the other end position will. This creates a condition in which the wave to be set z. B. by hand can be rotated to any position without being hindered by the latch system to become. By resetting the pawl lifting part, the previous state is restored, and the shaft to be set can be returned to the predetermined one by means of the pawls Layers are locked.

The pawl lifting part can be associated with the adjustment mechanism Means are controlled in that after the selection of a certain pawl of the pawl lifting part so long in the position in which all the pawls are inevitably raised, held until a certain part .within a certain range of rotation of the wave to be set is reached. Then the pawl lifting part is in the other Brought so that the pawl selected by the ratchet dial with the corresponding Stop part cooperates and locks the shaft to be adjusted. That way it is possible to use the shaft adjustment mechanism for precise adjustment of the shaft in particular. Use layers that span a range of more than one turn the wave can be distributed arbitrarily.

With a shaft adjustment mechanism in which the pawls all around the shaft to be adjusted is arranged and each provided with a follow-up part, wherein the follower parts are rotatably supported by the shaft to be adjusted Work together ratchet and .davy controlled, is according to the invention the pawl lifting part expediently by a disc rotatable about the shaft to be adjusted formed, which is arranged next to the ratchet selecting part. This disc owns for each follow-up part has a recess with a beveled edge with which the Follow-up parts work together in such a way that when the disk rotates, the follow-up part has a possibly effective latch from the inclined edge of the corresponding recess is forced to perform a radial movement with which the pawl in question is lifted off the corresponding stop part.

The invention is explained in more detail with reference to a drawing in Fig. I an embodiment of a shaft adjustment mechanism partially in section .shows in which the shaft adjustment mechanism and an overload clutch, via which the shaft to be set is driven to form a structural unit are assembled.

Figures 2, 3, 4 and 5 relate to an embodiment of a Shaft adjustment mechanism according to the invention, which consists of a structural unit accordingly Fig. I and a second structural unit consists of a second ratchet mechanism contains the combination with which the shaft to be set can be locked in positions can, which can be anywhere in a range that is more than one revolution of the Includes shaft to be set.

Fig. 2 is a plan view; Fig. 3 is also a top plan view of the Mechanism made up of two units, in which: the various parts are omitted are; Fig. 4 is a side view of the structural unit with the additional ratchet mechanism; FIG. 5 is a cross section taken along line V-V in FIG. 3.

Figures 6, 7, 8 and 9 relate to an embodiment of one Shaft adjustment mechanism according to the invention, in which the latch system of a manually operated sliding shaft can be operated by means of the pawl lifting part.

Fig. 6 shows partially in section a sliding shaft device: g for Rotation of the pawl lifting part of a shaft adjustment mechanism according to FIG only some parts are shown; Figs. 7, 8 and 9 respectively show that shown in Fig. 6 Sliding shaft mechanism in the normal position in which the pawl lifting part the Pawls not affected, in the effective position in which the pawl lifting part all Has put pawls out of action, and in an intermediate position in which the pawl lifting part must be brought from the last to the first position.

The shaft adjustment mechanism shown in Fig. I includes between the two-part frame plates connected to one another by cross members 3, 4, 5 and 6 I and 2 in the lower part an overload clutch, of which the various. Parts are carried by a shaft 7 mounted in the frame plates mentioned. Between the upper parts of the frame plates are equipped with a latch system that connects with. Stop parts on the shaft to be locked 8 cooperates, which is also in the two frame plates i and 2 are stored. The output of the overload clutch and the one to be set wave 8 are coupled in the manner described below.

The overload clutch corresponds to the type according to the French patent specification 975 152 and contains, in Fig. I from left to right, the following parts: an input gear 9 which is firmly connected to a ratchet Io; a shell-shaped output wheel ii, which has a ring gear 12 on the edge; an auxiliary element 13, which is connected by two springs 14, only one of which is visible, to pins 15 fastened in the output wheel II, and a shell-shaped housing I6 which surrounds the auxiliary element 13 and is provided with an arm 17. The parts g, II, 13 and 16 are all rotatably arranged on the shaft 7. A locking roller 18 carried by the locking arm I9 can cooperate with the ratchet wheel Io. This locking arm can be rotated about a pawl holder 2o which is firmly connected to the auxiliary member 13. The latter has two recesses 2, 1 in the outer edge, only one of which is visible and in each of which there is a pinch roller 22. The pinch rollers 22 form an overrunning clutch between the auxiliary part 13 and the housing 16; for this purpose, the bottoms of the recesses 2I are inclined.

The mode of operation of the overload clutch is as follows: in brief: When loading the output wheel II over a limit load, which is caused by the Springs 14 is due to the moment exerted, the auxiliary part 13 is together with the pawl I9 with respect to the output wheel II in the direction of rotation indicated by the arrow P. adjusted; as a result, the locking arm I9 is rotated in a manner not described in detail, the locking roller 18 both over the radially directed flank of the cooperating therewith The tooth of the ratchet wheel Io and also rolls over the side edges of the ratchet arm I9, whereby the role is finally released from the ratchet wheel Io. As a result, the Connection between the input and the output of the coupling interrupted. Since the Auxiliary part is then only subject to the action of the springs, it has the tendency to turn back, the overrunning clutch between the auxiliary part 13 and the Housing 16 is active, so that the housing 16 is moved back. The case but can only make a limited movement because the arm 17 is in a recess 23 is located in an immovable bracket part 24, which is adjacent to the shaft adjustment mechanism is arranged. In addition, one of a movable part is attached to this mounting part Contact 25 and an immovable contact 26 existing electrical contact device attached. The arm 17 cooperates with the movable contact 25 so that due to the limited movement that the housing 16 together with that of the entrance The auxiliary part exposed by the overload clutch executes the contact device is opened. The means with which the locking arm I9 and the roller 18 existing The pawl is controlled, are set up in such a way that regardless of the after lifting of the Pawl brought about by movement of the housing 16 reduction in the relative Rotation between the auxiliary part 13 and the output wheel II, the pawl is still lifted remain. The pawl engages again in the ratchet wheel Io, if by reducing the Load on the output wheel II of the latter due to the tension of the springs 14 in the original direction of movement is moved. The connection between input and output the clutch is then produced automatically. The auxiliary part is then on new taken in the original direction of rotation, whereby the overrunning clutch between this part and the housing 16 is ineffective, so that the housing with the Arm 17 can return to its original position. The contact facility with contacts 25 and 26 are closed again. This contact device can e.g. B. used for signaling; but it is very useful to have this Device to be included as a switch in the circuit of an electric motor, which is the input wheel 9 drives the clutch.

The actual shaft adjustment mechanism, which is in the top half of the space between the frame plates I and 2 is arranged, consists of the partial hollow shaft 8 with which a part to be adjusted, e.g. B. a tuning capacitor a Radio device, can be coupled. On this wave there is one set alternating arranged friction disks 35 and stop parts 36; the latter consist of one Ring which is provided with a recess 37 on the outer edge. The friction disks 35, of which two are shown in Fig. I, are firmly connected to the shaft 8, because they are pressed firmly on the ribbed shaft surface. They also have one such strength and made of such a material that they are pliable, whereby the outer parts can be moved a little in the axial direction. the Stop rings 36, of which only two are shown in the drawing, are each freely rotatable around an intermediate ring 38. That of the friction disks and The set formed by the stop rings can be axially positioned between one on the shaft 8 attached pressure part 39 and a pressure part 40 movable in the axial direction be squeezed. With this compression, the stop rings become like this wedged between the friction disks that they are in the with respect to the shaft 8 assumed position can be held. The pressure part 40 is pressed on by means of an axial screw 41 screwed into the hollow end of the shaft will. By means of a push rod 43 adjustable in this shaft and one across is guided by the shaft, movable in the axial direction bridge part 43 the pressure part 40 adjustable in the axial direction by means of the screw 41. Rings around the shaft 8 are a number, e.g. B. arranged twelve pawl shafts 45, each a pawl 46 and an arm 47 carry. The jack shafts, only one of which is whole is visible, are rotatably mounted with the ends in two mounting plates 48 and 49, both of which are rotatably seated on the shaft $. The mounting plate 48 is provided with a number of elongated openings 33 through which pins 5o reach, which are each connected to an arm 47 of a pawl shaft 45. The end of everyone Pin 5o works together with a ratchet selector, which consists of one around the shaft 8 rotatable circular cam 5I, the locally a recess 52 with Has beveled edges. The cam 5I is connected to the gear 53, on further two pins 54 and 55 are located. The two pins are through one curved wire spring 56 connected, the middle part of which is above the recess 52 extends. The gear 53 of the ratchet selection part is coupled to a gear 3o, which is freely rotatable about the shaft 7, which is also the various parts of the overload clutch wearing. Between the mounting plate 48 and the cam 51 is freely rotatable on the shaft 8 a pawl lifting part 57, which is formed by a thin toothed washer which is provided with a recess 58 for each pin 50. Every recess has a beveled edge 49, which extends through the recess in question with the Pin 5o can work together.

In each selected position of the ratchet selection part, the indentation 52 is below guided one of the pins 5o, the spring 56 acting on this in the radial direction Pin presses. As a result, the corresponding pawl works together with the edge of the corresponding stop ring on shaft B. The pawls 46 are one below the other so arranged offset in the axial direction that each pawl with a certain Stoppring can work together. To drive the shaft 8 sits on this shaft the gear 34, which is in the ring gear 12, of the output part II of the overload clutch intervenes.

Is now through mediation of the overload clutch and the gear 34 to be set shaft 8 rotated in the direction of arrow R, so in a given moment the recess 37 the end of the operated by the ratchet dial Reach pawl 46 so that the pawl snaps into place and the shaft 8 locks. Consequently the overload clutch will disengage itself. The location of the wave 8 is blocked, is due to the angular position of the recess 37 of the relevant stop ring with respect to the shaft 8 is determined. This angular position can be used for every stop ring separately, after releasing the axial pressure on the friction disks 35 and set the set formed as desired.

To lock the shaft 8 in one of the other stop rings Position the ratchet dial is rotated so that now the stop ring with this cooperating pawl is selected, since the indentation 52 of the selector cam 51 is brought under the relevant pin 5o. Only the already effective The pawl lifted because the pin 5o assigned to this pawl differs from the beveled Edge of the indentation 52 is moved radially outward. The cam 5I stops in each In the selected position, the not selected pawls are raised, and it can: only the pawl, whose arm is located above the indentation 52, with a stop ring .auf: the Wave 8 working together.

In the illustrated position of the pawl lifting part 57 are all Pins 5o at a point in the recesses 58 where these recesses are sufficient are far so as not to cause movement of these pins by the ratchet selector hinder. By turning the pawl lifting part in the direction of rotation R of the shaft 8 but this is different, and all pins get into a narrowed part the recesses, which is so far from the center line of the shaft 8 that the pawl, which is assigned to a pin located in this narrowed part, cannot cooperate with its stop ring on shaft 8. As a result of the beveled Edge 59 of the recesses becomes one of the ratchet selection part during this rotation of the disk 57 lifted into the effective position, because the pin in question is beveled Runs along edge 59. In the new position of the pawl lifting part, it is possible to use the Bring shaft 8 in any position without being hindered by the pawls to become. By turning back the pawl lifting part 57, the original state is restored restored so that the shaft 8 again from any pawl to be selected can be locked.

The impact on the pawl when locking the shaft 8 is as follows caught: The two mounting plates 48 and 49 have a protruding one Part 63 and 64, in which the ends of a parallel to the shaft 8 extending multi-part leaf spring 65 are set. With the middle of this leaf spring acts the edge of an eccentric cam 66, which is attached to the cross member 5 is. Due to the tension of the leaf spring 65, the two mounting plates held against the cross member 5 with a stop 6I or 62. When locking the shaft 8 by means of one of the pawls 46, the impact is resiliently absorbed, since the from the mounting plates 48 and 49 with the shafts of the pawls mounted therein The frame formed is entrained in the direction of rotation R against the force of the leaf spring 55 will. The overload clutch is disengaged as a result of the load that occurs. As soon as the shaft 8 has come to a standstill, the aforementioned frame is put together rotated back with the shaft 8 and the organs coupled to it by -the leaf spring, until the two stops 61 and 62 rest on the cross member 5 again. The spring tension the leaf spring 65 is adjustable by rotating the cross member 5.

On the shaft, the gear 6-7 is rotatably arranged, which is in engagement with the input gear 9 of the overload clutch. The coupled wheels 9 and 67 and 53 and 30 make it possible that the drive means of the overload clutch and the ratchet dial can be arranged on any side of the structural unit described.

The figure also shows a scale 68 arranged on the shaft 8, with which a gear 69 is connected is. This gear can be used for Manual adjustment of the shaft 8 is a pinion 7I connected to a precision control knob 70 may be brought into engagement by axially displacing this knob.

A shaft adjustment mechanism is described with reference to FIGS. with which the shaft to be set can be locked in predetermined positions, which can be set arbitrarily over a setting range that is more than one rotation of the Wave embraces, can be widespread. The mechanism consists of a structural unit A constructed, which corresponds to the mechanism shown in Fig. I, with the one second structural unit B is coupled, which also has a ratchet mechanism contains. The latter has essentially the same parts as that in Fig. I Mechanism shown and corresponds to unit A. These parts are therefore in unit B with those used for the corresponding parts in FIG Reference numerals denoted, with an accent added to the necessary distinction is.

The unit B has a shaft 8 ', which is in two parallel frame plates Ioo and IoI is stored and the shaft 8 of the unit A corresponds. On wave 8 ' is a set of alternating friction washers 35 'and adjustable stop rings 36 'arranged. The shaft 8 'with its set of friction washers and stop rings is referred to below as the auxiliary rotor. With these stop jumping you can under control of a ratchet selection cam 5 i 'selectively cooperate with the pawls 46' that each carried by a pawl shaft 45 ': The shafts 45' of the pawls are in a circle around the shaft 8 'mounted in the two rotatable around the shaft 8' Support plates 48 'and 49'. The two plates each have a protruding part Io2, which has a toothing on the edge. These teeth mesh in two with each other connected gears 103, which in two with the rack plates Ioo and IoI connected socket-shaped bearings Io5 or Io6 mounted spindle 104 are rotatable. The bearing bush 105 (Fig. 5) carries a rotatable gear 107 which is in the ring gear of the pawl lifting part 57 of the unit A engages. The gears 103 and 107 are through a coil spring Io8 is coupled to one another, which is attached to a pin Io9 on the wheel Io7 and at an animal bent, connected to the gear 103 and by a tangential one Slot i i i in gear 107 engages arm i i o which extends through it.

The unit B further includes a gear 113 which revolves around one in the plate Ioo attached shaft 114 is rotatable and that in a freely rotatable about the shaft 8 ' Gear 67 'engages. On the other hand, the mutual arrangement of the Units A and B put gear 114 into gear 67 on the shaft to be adjusted 8 of unit A.

The bottom plate carries a fixed IOI in a terminal i 1 6 i15 shaft which carries a gear 1 17 on the one hand in the Klinkenwählrad 53 'of the unit B on the other hand engages the Klinkenwählrad 53 of the unit A. The two pawl selection parts are thus coupled in such a way that both of them select one pawl of their unit at the same time. Since the two units have the same number of pawls to be selected, each pawl of one unit corresponds to a corresponding pawl of the other unit, which pawls are always selected at the same time.

The shafts 8 and 8 'are coupled in their movement in such a way that that after a certain number of revolutions they simultaneously return to their original position Assume an angular position. In the exemplary embodiment, this coupling is effected by means of a gear wheel i 18 with two ring gears i 19 and I2o; this gear is on the socket Io6, in which the upper end of the shaft 104 is also held. The ring gear i i9 meshes with the gear 34 ', and the ring gear I2o meshes with the gear attached to the shaft 8 of the unit A. 34.

By choosing the ratio of the number of teeth of the rims II9 and I2o can be achieved that after a certain number of revolutions the shafts 8 and 8 'assume their original angular position at the same time. If you want this z. B. to achieve fourteen revolutions of the shaft 8, the transmission ratio between waves 8 and 8 'be 13:14, 15:14 or 14: i. Usually will choose one of the first three ratios.

The whole mechanism works as follows: As a result of the Drive of one of the ratchet dials 53 and 53 'is both in the unit A as well as in the unit B selected a certain pawl. In unit B, the Selected pawl to work with the corresponding stop ring on the shaft 8 'brought. This is not the case with the unit A, since the pawl lifting part 57 through the coupling via the gears 107 and 103 with the mounting plates 48 ' and 49 'of unit B held in that position under the influence of spring 121 is, in which none of the pawls 46 around the shaft to be adjusted 8 with a Stoppring can work together on this wave. The spring 121, the one hand engages on the pin 114 and on the other hand on a pin 122, the two protruding Joining parts Io2 of plates 48 'and 49' holds what is formed by these plates Frame in an end position which is opposite to the direction of rotation of the shaft 8 ' and. .by the possibility of movement of the arm i Io in a recess 123 of the Gestellpfatte ioi is conditional.

If now when driving the coupled shafts 8 and 8 'via the overload clutch Unit A is the recess in the stop ring with which the unit B selected Pawl 46 'works together, reaches this pawl, snaps this pawl into place, and as the two shafts continue to rotate, this is achieved by: the shafts 45 'of the pawls and the plates 48 'and 49' formed in the direction of rotation of the shaft 8 'in taken in a manner which corresponds to that in the case of the in Fig. i described device the shock when locking the shaft 8 is absorbed. The one from the Spring I2I induced load should be here does not lead to the disengagement of the overload clutch in unit A. The adjustment of the said frame has the consequence that by mediating the elastically coupled Gears 103 and 107 of the pawl lifting part 57 of the unit A: is thus rotated (in Fig. 3 in clockwise direction) that the pawl selected in unit A is now with their corresponding stop ring can work together and thus lock the shaft 8 is when the recess of this stop ring reaches the end of the pawl.

If the shaft 8 is not locked soon, the frame with the The pawl shafts of the unit B taken so far that as a result of the adjustment of the the selected pawl associated pin 50 'over the indentation 52 of the cam 51 'of the ratchet selecting part of the unit B, the ratchet is also raised, whereby the coupling between the frame and the shaft 8 'is disengaged. The frame then moves back to its original position under the influence of the fields r21, whereby also the pawl lifting part 57 of the unit A in its original position, in so that none of the pawls of unit A can be active, is returned. the The shaft 8 is only locked when the pawl selected in unit B. engages in the recess of their corresponding stop ring and at the same time the recess in the stop ring with which the then active, selected pawl of unit A works together, reached the end of this latch. By this type of coupling of the two shafts 8 and 8 ', this state occurs only once in a range of a certain number Revolutions; this number is determined by the gear ratio between the shafts 8 and 8 'conditional.

The elastic coupling between the gears 103 and 107 by means of the spring Io8 and the driver IIo in the slot i i i allows the frame with the pawls of the unit B can be taken further from the shaft 8 'than is required to enable the pawl lifting portion of unit A to be in which the pawls 46 are not further hindered. The auxiliary rotor must continue to run can to lift the pawl effective in unit B if the one in the unit A selected pawl does not move from the recess in the corresponding stop ring in time is achieved.

The position in which the shaft 8 is locked by means of a pawl 46, is through, the angular position of the stop ring that matches this pawl of the shaft 8 and due to the angular position of the stop ring on the auxiliary rotor, with which the latch selected at the same time in unit B works together. the previous setting, this position takes place in that both of: the stop ring set on the shaft 8 as well as that on the shaft 8 ', the axial pressure is lifted which the stop rings in the occupied by them with respect to their shaft Determines position and the two pawls selected at the same time in the recess of the corresponding Drops stop rings. For this purpose it is necessary that the frame with the pawls of unit B by external means, e.g. B. by hand, so far opposite the force of the spring 121 is pivoted out that the pawl lifting part 57 of the unit A reaches the position in which none of the pawls 46 is hindered any longer. Are the If both pawls are snapped into place, the shaft 8 will automatically turn into the desired one later Brought to be set position of this shaft, after which by applying an axial pressure the stop rings cooperating with the selected pawls in the then in relation be determined on the shafts assumed angular position. This is for the stop rings, assigned to each pair of pawls of units A and B to be selected at the same time can be carried out separately.

The gear 67 ', which via the gear 113 with the gear 67 of the unit A is coupled, serves that the drive means for the shaft to be adjusted can also be coupled to the side of the unit B without the need for additional transmission means to the. Input of the overload clutch of unit A are required.

Corresponding to the unit A, the unit B has a pawl lifting part equipped in the form of a toothed disk 57 'provided with recesses 58', with the a gear 124 rotatable about shaft 115 is engaged. As a result of Rotation of the pawl lifting part 57 'from the normal position in which the pawls 36' of unit B cannot be influenced by this part, in the effective position in the all pawls 46 'are inevitably raised, a state is created in which the shaft 8 to be adjusted can be brought into any position without doing so from. the pawls 46 of the unit A to be obstructed.

The mechanism described with reference to FIGS. 2 to 5 is special Suitable for setting coils with sliding contact that have more than one turn to have. You can use the arm with the sliding contact or the coil itself through the Drive shaft 8. permit. The shape of the recesses in the stop rings 36; the formation of the frame carrying the ratchet shafts of the unit B and: the Formation of the overload clutch, the shaft 8 can only 'continuously in one direction to be turned around. In the embodiment described, it is therefore desirable that between the shaft 8 and the movable member of the sliding coil a movement of the movable part arranged periodically reversing reversing mechanism or else the coil is designed such that when it reaches its end the sliding contact is automatically returned to the beginning of the coil.

6, 7, 8 and 9 will now be used. described "as by means of a Snieibewellensystems in a simple way the pawl lifting part of a unit, as shown in Fig. i, from the effective position to the inactive position and vice versa can be performed. The sliding shaft system consists of a structural unit, which as a whole besides that in Fig: g. i mechanism shown is arranged. Fig. 6 shows the structure of this unit and their working together with a mechanism according to Fig. I, of the latter mechanism only the parts that are important for understanding the following description are shown schematically are. 7, 8 and 9 are different to explain the mode of operation Positions of the sliding shaft system shown.

In addition to the shaft adjustment mechanism according to FIG. 1, there is a hollow foot 301 arranged to which a cylindrical guide 302 for a sliding shaft 303 with a Button 305 to be pressed in by hand is connected. Around the lower end of the guide 302 the bush 3o6, which sits between a collar 307 and a ring 308, is rotatable. A transverse pin 3o9 is fastened in the sliding shaft 3o3, which is connected by two diametrical, Slot-shaped openings 310 of the guide 3o2 extending in the axial direction reaches through. The socket 3o6 also has slot-shaped openings 3II for the pin 309; however, these openings follow a helical line. A movement of the Sliding shaft 303 in the axial direction therefore has the consequence that the bush 3o6 rotates will.; A pinion attached to the bushing 3o6 also takes part in this rotary movement 312 part, which is in the ring gear of the pawl lifting part 57 of the actual shaft adjustment mechanism engages and that transmits this movement to the ratchet lifting part. The sliding shaft is pushed away from the foot 301 by means of a coil spring 313; this spring sits between the underside of the head 305 and a ring 3I4 on the end of the Guide bush 3o2 is at rest. The part of the sliding shaft located within the guide 3o2 has a transverse opening in which a ball 315 is located, which is held by a spring 316 is pushed outwards. A bushing 317 is displaceable around the end of the bushing 3o2 and rotatable, which is on the inside with a cylindrical. Well 3I8 with beveled Edge 3I9 is provided and a head 32o and a ring gear 321 on the outside owns. The bushing 317 is subjected to two opposing spring forces, from one of which is exerted by a coil spring 322 between a collar 323 of the socket 3I7 and the ring 3o8. sits while the other by a coil spring 324 is effected between the underside of the head 305 and a ring 325 which rests on the inside on socket 3I7. In the one shown in FIGS The state shown outweighs the tension of the spring 322, whereby the bushing 317 is pressed with a collar 326 against the ring 3I4.

In the foot 301 there is an electrical switch, which consists of two approximately semi-cylindrical solid. Contacts 327 and 328 and a moving contact 33I consists of a coil spring 332 against the fixed contacts 327 and 328 is pressed and this electrically connects. With the contact 33I the tapered End 333 of sliding shaft 303 work together.

The mode of operation of the device described is as follows: Normal the sliding shaft 303 is in the position shown in FIGS. 6 and 7. This increases the socket 306 was in such a position that the pawl lifting part 57 ate in the actual Shaft adjustment mechanism is rotated so that the pawls 46 not from the part 57 be disabled. The shaft 8 can thus by means of the pawls 46 in predetermined Layers are locked. By pressing the button 305, the sliding shaft is adjusted in the longitudinal direction, the pinion 3I2 is rotated. The pawl lifting part 57 is then brought into the effective position in which all pawls of the adjustment mechanism are inevitably lifted so that the shaft 8 is brought into any position by hand can be. The sliding shaft is locked in the pushed-in position because the ball 315 snaps into an opening 334 of the guide 302 and onto the wall of the recess 318 comes to rest in socket 317. As a result, the ball ends up with the Center approximately in the middle of the opening 334, whereby the sliding shaft is not can move back. When the button 305 was pushed in, the spring 324 was also activated additionally tensioned, as a result of which this spring overcomes the counterforce of spring 322 can. As a result, the bushing 317 is moved with the sliding shaft 303 until it abuts against a collar 335 of the guide 302. By this displacement of the socket 317, the ring gear 32I has come into engagement with that with the shaft 8 of the actual Adjustment mechanism connected gear 69, so that the knob 320 is now used as a fine control knob can act for this wave. By pressing in the sliding shaft 303, from whose tapered end 333 also has the movable contact 331 of the switch in the base 301 pushed away from the fixed contacts 327 and 328, making the electrical connection between the conductors 329 and 330 connected to these contacts is interrupted. This position is shown in FIG. The switch in the foot 301 is in series with the Contact device 23, 24 from the arm I7 of the overload clutch of the actual Adjustment mechanism (Fig. I) is operated in: the electrical circuit of the driving force Electric motor (not shown) added to the whole mechanism. Through the Switch is prevented that when pressing the sliding shaft, in which case the with a pawl trained blocking of the shaft 8 canceled and the overload clutch is automatically engaged, the drive motor is operated.

In order to bring the mechanism back into the position in which the shaft 8 is locked in a predetermined position by means of a pawl to be selected by the pawl selection part, the bushing 317 is brought into its original position by pulling the button 320 , the spring 313 being strongly tensioned and also due to the beveled edge 319 of the recess 318, the ball 1315 is pushed inward. In the process, the ring gear 32i is also free from the gear 69 on the shaft B. The position then obtained is shown in FIG. This is a transition position, because by: the pressing in of the ball 315 comes this against the edge of the opening 334 to the plant that now from. there is no longer any question of a real blocking of the sliding shaft 303, so that the spring 3I3 pushes the sliding shaft back into its original position in the axial direction. The socket 3o6 is rotated back, as a result of which the pawl lifting part 57 is also rotated back into the position in which the arms 5o, which are assigned to the pawls in the actual adjustment mechanism, are located in the large parts of the recesses 58 of this part. The original position is hereby restored. Since during the return movement of the sliding shaft the movable contact 331 restores the electrical connection between the conductors 329 and 330 , the drive motor is actuated and the shaft 8 to be adjusted is rotated until the pawl selected with the pawl selection part blocks this shaft, after which the overload clutch is disengaged.

It should be noted that in the case of the described with reference to FIGS Device a sliding shaft unit can be arranged next to unit B, to cooperate with the pawl lifting member 57 'in this latter unit. The advantage of the described design of the sliding shaft system is that that it is joined together to form a structural unit that can be joined to any one with a Associated with latch lifting part provided according to the invention shaft adjustment mechanism can be.

Claims (18)

PATENT CLAIMS: I. Ratchet-type shaft adjustment mechanism, in which the shaft to be adjusted has a number of separately adjustable stop parts carries, with which pawls located next to the shaft can selectively cooperate, which handles. one after the other into the effective position by means of a ratchet dial can be brought in with a corresponding stop part on the shaft work together to lock this shaft in a predetermined position, thereby characterized in that the mechanism is a separately movable, with all Contains pawls cooperating pawl lifting part, which for each pawl with a such profiling is provided that in one of two end positions, the .by external means can be given to the pawl lifting part., all pawls through the profiling of the pawl lifting part must be kept lifted and in the other end position brought any pawl from the selector into its effective position can be without being hindered by the pawl lifting part, and in the movement of the pawl lifting part from the last to the first end position with one if necessary a stop part cooperating pawl through the profiling of the pawl lifting part is brought into the ineffective position. 2. Mechanism according to claim I, in which the Pawls arranged around the shaft to be adjusted and each with a follower part are provided, which follow-up parts of a running around the shaft to be set Cams of the ratchet selector rotatably supported by this shaft are controlled, characterized in that the pawl lifting part of one to be adjusted Shaft rotatable disc is formed immediately next to the cam of the ratchet dial is arranged and for each of the following parts mentioned with a recess is provided with a beveled edge, from which edge the following part is an effective one Pawl when moving the pawl lifting part in .the position in which all pawls be held inevitably lifted by this part, moved in the radial direction is, whereby the pawl in question is made free of the stop part. 3. Shaft adjustment mechanism according to claim 1 or 2, characterized in that the pawl lifting part has means is coupled, which corresponds to the position of the ratchet dial and an organ can be controlled with the wave to be set via such a transmission is coupled that each after a certain number of revolutions to be set Shaft and this organ both assume the original position at the same time, the one and the other such that the pawl selected by the pawl selector part from the pawl Lifting part to lock the shaft to be adjusted is released when the to be adjusted Shaft and said organ simultaneously occupies a predetermined position. 4th Shaft adjusting mechanism according to claim 3, characterized in that the means to control the ratchet lifting part with an additional ratchet mechanism a shaft (auxiliary shaft) are formed with an equal number separately adjustable stop parts such as the shaft to be adjusted is provided with which Stop parts under the control of a pawl selector part an equal number of pawls can selectively cooperate which auxiliary shaft through one of i: i different Translation is coupled to the shaft to be set, and the ratchet dial such with the pawl selection part assigned to the pawls of the shaft to be adjusted is coupled in its movement that in each dial position of the two axes a pawl is selected, and then the pawls of the additional ratchet mechanism are carried in parts that are selected upon engagement in this ratchet mechanism The pawl with its corresponding stop part on the auxiliary shaft counteracts this a spring force exerted on the parts mentioned is taken along, with means are provided which couple these parts in their movement with the pawl lifting part of the pawls associated with the shaft to be adjusted, whereby when moving the mentioned parts of the ratchet lifting part from the position in which it is all of the pawls assigned to the shaft to be adjusted ineffective, in: .die Position is performed in which the last-mentioned pawls no further from the pawl lifting part be hindered. 5. shaft adjustment mechanism according to claim 4, wherein the to be adjusted Shaft is driven via an automatically operating overload clutch, thereby characterized in that the spring force against which the auxiliary shaft is associated with it Adjusted pawls bearing parts, is such that for this adjustment with The shaft to be set coupled to the auxiliary shaft is not above the limit load the overload clutch is loaded. 6. shaft adjustment mechanism according to claim 4. or 5, characterized in that the parts to be moved by the auxiliary shaft, which carry the pawls assigned to this shaft, with the pawl lifting part an elastic coupling are coupled, which allows the mentioned parts an adjustment allows the adjustment required to move the pawl lifting part goes out. 7. shaft adjustment mechanism according to claim 4, 5 or 6, characterized in that that the pawls associated with the auxiliary shaft are arranged around this shaft and made selectively operative by means of a rotatably mounted on the auxiliary shaft Ratchet selection part, which in its movement with the ratchet selector for the to be set Shaft associated with the pawl is coupled. B. Shaft adjustment mechanism according to claim 7, characterized in that the pawls associated with the auxiliary shaft are rotatably supported are arranged in two parallel plates, which are rotatable on the auxiliary shaft and means a spring to a torque acting opposite to the direction of rotation of this shaft are subject. G. Shaft adjustment mechanism according to one of claims 4 to 8, characterized in that also for the pawls associated with the auxiliary shaft a pawl lifting part is attached, with which these pawls all at the same time in the ineffective position can be brought. Io. Shaft adjustment mechanism after a or more of claims 4 to 9, characterized in that the additional Ratchet mechanism and the means with which Ankupplun: g to that of the to be adjusted Wave and all means to block this wave system formed, are combined in a separate structural unit, which as a whole in addition to the above System is arranged. i i. Shaft adjustment mechanism according to claim I or 2, thereby characterized in that the movement of the ratchet lifting part from the movement of a in The longitudinal direction to be adjusted sliding shaft is derived. 12. Shaft adjustment mechanism according to claim g, characterized in that the pawl lifting part for that of the auxiliary shaft associated pawls by means of a sliding shaft that can be adjusted in the longitudinal direction is moved. 13. Shaft adjustment mechanism according to claim I I or 12, characterized in that that the ratchet lifting part to be moved by the sliding shaft is designed as a gear is and is in engagement with a pinion which is concentric to the sliding shaft, rotatable socket is connected, in which the sliding shaft is adjustable in the longitudinal direction which socket is provided with a 'slot following a helical line, in which a pin carried by the sliding shaft engages. I4. Mechanism according to Claim 13, characterized in that the sliding shaft has a radial cavity is provided in which a ball subjected to radial pressure by a spring is arranged, which in an end position of the sliding shaft by the spring pressure in an opening in the side wall of a fixed hollow guide in: which the sliding shaft is stored, penetrates about halfway and thereby locks the sliding shaft. 15th Adjustment mechanism according to claim I4, characterized in that all around the hollow guide an adjustable bushing is arranged with an inner recess for partial Receipt of the penetrated into the opening in the wall of the guide ball provided is which recess has such a beveled bottom part that upon adjustment this socket with respect to the guide the penetrated ball from said bottom part is pushed back, whereby the blocking of the sliding shaft is released. 16. shaft adjustment mechanism according to claim 15, characterized in that the The sliding shaft and the adjustable bushing are coupled to one another by a compression spring are, which as a result of the movement of the sliding shaft in the position in which this of the exiting ball is locked, is additionally tensioned, whereby the socket in the direction of movement of the sliding shaft is taken along, with a gear on this Socket brought into engagement with a gear mounted on the shaft to be adjusted will. 17. Shaft adjustment mechanism according to one of claims 12 to 16, characterized characterized, @ that the sliding shaft with an electrical contact device cooperates, which is actuated by the sliding shaft during its longitudinal movement. 18. Shaft adjustment mechanism according to claim 17, in which the shaft to be adjusted is driven by an electric motor via an automatically operating overload clutch, the overload clutch being a control part which moves when the same is switched off. contains an electrical contact device which is included in the motor circuit, characterized in that the contact device actuated by the sliding shaft is included in series with the contact device actuated by the control part of the clutch in the motor circuit and the first-mentioned contact device in that position of the sliding shaft in which the so that the pawl lifting part to be moved keeps all associated pawls lifted, is open. I9. Shaft adjusting mechanism according to one or more of Claims II to 18, characterized in that the sliding shaft and the parts cooperating with it, with which the movement of the pawl lifting part is obtained, are combined in one structural unit which, as a whole, in addition to the system of the shaft to be adjusted and the Means for adjusting this shaft is arranged in certain positions. Referred publications: German Patent No. 725 94i-