DE924739C - Electric drive and control device for setting or adjusting an output component - Google Patents

Description

Electrical .drive and control device for setting or Adjusting an output component The invention relates to selective electrical Signal systems. More generally, the invention relates to providing improved electrical drive and control devices for setting or adjusting a Output component, for example a shaft or an endless chain or a Band, from a normal or rest position after any, by a key signal determined among a plurality of stop positions. Preferably the relates Invention to an improved electrically powered change display device which serves to provide information (e.g. numbers or letters) which are transmitted by key signals is determined to be identified. In the electric drive according to the invention and control device for adjusting an output component from a normal position out into a stop position according to a key signal, a control circuit, which controls the drive of the output component, per key element of the related Key to a key branch. In the following this key branch of the control circuit with the control circuit code branch will. The drive and control device according to the invention is such that in every stop position before the desired stop position (during the adjustment of the drive component from its normal position into one by a key signal fixed Stop position takes place), the switching state is such that one or several control circuit key branches are effective to drive the output component to let it persist. In contrast, the switching state is at the desired stop position such that no control circuit key branch is effective to drive the To let the output component continue, so that the output component in this stop position is stopped. A key control unit, which is driven by the output component has a control switch in each control circuit key branch. In relation affects every control circuit key branch. the key controller in such Way out that this branch is opened while the output component is in one or more stop positions and that it is closed while the output component is in the other stop position or positions. everyone Control circuit key branch is only switched on to make the branch effective for those To make stop positions of the output component, in which the branch through the Key switch mechanism is closed when the signal element, which branch is assigned, in the case of the relevant key signal applied in each case a has a certain character (e.g. a work impulse, in contrast to a rest pulse, is). The arrangement allows the use of a key, in which some of the key signals used are such that only one the signal elements has the aforementioned special character character, while otherwise the key signals used are such that two or more of the Signal elements have the aforementioned special character. As a result of providence a control circuit key branch per key element can through the output component a decryption operation without the aid of a decryption arrangement or a decoding tree of relay contacts.

According to a main feature of the invention, there is the key switch mechanism from a rotor and stationary contact arms, which are set up electrical To make contacts with electrically conductive key washers of this rotor, with a Conductive key washer per control circuit key branch (and thus per key element of the key) is provided. With every electrically conductive key disc there are Sections cut away so that a continuous circuit between this disc and the associated stationary contact arm is only present when the runner is certain Occupies positions, the electrically conductive discs with each other in permanent electrical connection are.

According to a further feature of the invention is the drive and control device such that the adjustment of the output component from its normal position out to a stop position, which is determined by a key signal, takes place with a continuous or continuous adjustment movement, this continuous adjustment movement due to the uninterrupted excitation of the electromagnet an electromagnetic clutch over the required period of time will. The electromagnetic clutch is used to connect the output component with a To couple the primary drive device.

According to a further feature of the invention is the drive and control device such that the adjustment of the output component from a normal position in a stop position determined by a key signal with a continuous Movement takes place and that the key switch with .dem output component over a coupling device is connected, which causes each effective switching movement of the key switch mechanism takes place faster than .this would be the case if the switch mechanism would be operated with a continuous movement, which is equal to the continuous Movement of the output component is or corresponds to it. This feature makes an impermissible spark formation on the key switch is avoided. Such an impermissible Otherwise sparks could be caused by the fact that the device is inductive has to open electrical circuits. A particularly useful coupling device, which can easily be provided to the desired discontinuous movement of the key switch mechanism as a result of a continuous adjustment movement of the output component cause is a Maltese cross gear or a control unit in which a cam actuates the pawl of a ratchet mechanism.

In the embodiments of the invention that are particularly considered the output component forms part of an electrically operated change display device, and it is, for example, an endless chain containing a series of display surfaces carries, which are to be brought to the display alternately individually.

The key signals need not necessarily be or signals To correspond to signals received in key form from a remote station will; they can also be generated locally only for the purpose of the output component to bring into the respective desired of the various display positions.

For example, we now consider an embodiment of the invention Hand drawing to be described. This embodiment of the invention eats an electrically operated change indicator in which an endless chain has a Series of display surfaces carries, each to be brought to the display. The display device is designed so that it is to the side as well as above and below Similar display devices can be provided to make up a large composite display device to form, through which a complex changing information is displayed can be. The display device is .by a primary drive device, for example an electric drive motor associated with a plurality of display devices be can, powered. The display device consists of a main frame, a coupling, a control device and the endless chain, which the row of display surfaces wearing.

Figure i is a side view of the display device showing how the main frame, coupling, control device and an endless chain carrying fourteen display surfaces are interconnected. In order to simplify the drawing, most of the coupling device and the control devices and various other details have been omitted. 2 and 3 are a side view and a plan view of the coupling, while FIGS. 4 and 5 show a side and plan view (from below) of the control device. The main frame is designed so that an endless chain can be used, which is twice the length of the chain shown in FIG. i has the endless chain shown and thus carries twenty-four display areas instead of the fourteen that are used here. FIG. 6 reproduces a circuit arrangement for an endless chain and the display surfaces on which FIG. 1 is based, and shows the shapes which in this case the key disks and certain other disks which are provided in the control device . Fig. 7 shows a modified circuit arrangement which corresponds to the case in which the endless chain carries twenty-four display areas. The purpose of this structure is to be able to use the shorter endless chain and the disks corresponding to it if the display device is to display the digits 1, 2, 3 ... 9, o while the longer endless chain and the disks assigned to it are used if the display device is to display the letters of a twenty-six letter alphabet.

As can be seen from Fig. i results in the main frame i of the display device roughly the shape of an angle when viewed from the front or back of the Display device is viewed here. If you look at it from the side (i.e. from the left in If you look at Fig. I), it can be seen that the main frame i has a vertical part, which is to the left of the coupling and the control device, as well as a horizontal one Part 2, which is arranged below this control device. Just the edge of the horizontal part 2 can be seen in FIG. The horizontal part 2 is used to to provide an alignment and protective base part for the display device, if the Display device is brought into the working position, so as a unitary part of a large composite display device to serve. About a small part of its length on the The main frame i is not horizontal Part on. A hole 3 in the vertical part of the main frame near the rear Edge of this frame serves as a finger grip when inserting the display device into the Working position when it serves as a unitary component of a large composite display device should, as well as to be able to move it out of this position. A main support plate 4 of the coupling is on the vertical part of the main frame i by means of four screws attached, which sit in four threaded sockets 5, which in one Piece with the support plate 4 are formed. The coupling is from the carrier plate 4 held, and it consists of a sprocket 6, soft with the endless chain 7 cooperates. As shown, the endless chain 7 consists of seventy links, and it carries fourteen display surfaces B. The endless chain 7 takes, as shown, a display (stop) position, in which the respective display surface 9 to Display is brought. When viewed from the front of the display device, represents the display area 9 is a rectangular area, which is the desired Inscription or information display. The sprocket 6 has fifteen teeth on, and there are five teeth of the endless chain 7 assigned to each of the display surfaces it must make a third of a turn to display one I switch to the next one. A cam wheel io with three equally spaced cams provided from one another move the sprocket 6 and serve as in the following is described to ensure that the endless chain 7 only in a certain Holding position is stopped.

A main support plate i i of the control device is on the vertical Part of the main frame i attached by means of four screws that are threaded in four provided sockets 12, which are formed in one part with the carrier plate i i are. The four screws lead through four slots 13, which in four finger-shaped parts 14 of the vertical section of the main frame i formed are. The slots are used to align or tension the endless chain 7, this chain runs with its rear end over a sprocket 15, the one Forms part of the control device and is held by the carrier plate i i. That Chain wheel 15 has fifteen teeth, and there five teeth of the endless chain 7 assigned to a display area: it rotates a third of a revolution when changing the display from one display area to the next. The finger-shaped Parts 14 enable the control device to be aligned on the main frame i. The total length of the from the front to the back of the Main frame i is not shown in the figure. The part not shown on the Break point 16 has four finger-shaped parts 14, which in corresponding Way (relative to the sprocket 6) are arranged in an analogous manner to the carrier plate i i to be able to attach in the event that the endless chain used is twice the length of the endless chain 7 shown here (i.e. if the endless chain consisting of one hundred and forty instead of seventy links and twenty-eight instead of fourteen display areas).

As can be seen from Fig. 2 and 3, Fig. 2 shows, as already mentioned, a side view of the coupling, while FIG. 3 is a corresponding plan view reproduces. The main support plate 4 of the unit, the threaded bushings 5, the sprocket 6 and the cam wheel io have already been mentioned with reference to FIG. Fixed with the carrier-5, for example by means of welding, is a secondary metal carrier plate 17 connected, which forms a board-like support 18. The support 18 has a part 19 bent downwards and carries a latch electromagnet: zo. Of the The latch electromagnet is attached to the support by means of two screws: 2i, which sit in threaded holes in the yoke 22 of the pawl electromagnet. A metal plate 23, which is attached to the yoke 22, holds the bearing 24 for the armature 25 of the pawl electromagnet and also carries a contact spring 26. The contact spring 26 is isolated on the Plate 23 and is biased so that it is against another, stronger spring 27 sets when the pawl electromagnet is not energized. The spring 27 is also isolated from the plate 23. The armature 25 is in its normal rest position shown, in which it is always moved back by the return spring 28. The one The end of the spring 28 is guided around a hook-shaped part 31 of this anchor 25, while the other end sits in a slot in a screw 32, which through the part i9 of the support 18 is screwed through. The anchor 25 has a shoulder (shown partially broken away in FIG. 3) which forms a pawl 29. The pawl 29 is used in its interaction with the cam wheel io to this wheel to bring into the various stop positions and to hold on to what the endless chain is held in the various display positions. The handle 29 also serves in their interaction with the cam wheel io to the armature 25 mechanically in its working position, while the endless chain a Receives feed movement between the various display positions.

The armature 25 has a further approach 3o, which is a contact carries, which comes into contact contact with the contact on .der contact spring 26 when the armature 25 assumes its working position. A connector 33, which by the Nut 34 is held, which holds the yoke 22 on the core of the ratchet electromagnet, serves as a connection terminal or solder tail for the approach 30. A good electrical Connection between connector 33 and approach 3o is through a circuit the yoke 22 and the bearing 24 created therethrough. The fitting 35 is the end fitting the contact spring 26. The connecting pieces 36 provide the connections for the latch electromagnet represent.

The clutch is an electromagnetic clutch of known type. This clutch serves to connect the sprocket 6 and the cam wheel io with a gear 37 to connect. When the display device is in the working position as a unitary component of a large composite display device. is, then the gear 37 meshes with a pinion on a shaft, which is continuously driven by the common primary drive device is set in rotation during the periods during which the setting of the display device. The electromagnetic clutch is not The subject of the present invention, and therefore it is needless to go into detail to depict and describe their structure. It is composed of one Drive component, which consists of a pot magnet 38 which is attached to the gear 37 is, and from an output component, which consists of a magnet armature 39, the is connected to the chain wheel 6 and the cam wheel io. The armature 39 is on the sprocket 6 and held on the cam wheel io by means of the spring components, which: serve to the Armature 39 out of (frictional) engagement with pot magnet 38 during the periods to hold, in which this electromagnet is de-excited. During the periods in where the pot magnet 38 is excited, the armature 3: 9 is in drive connection with this electromagnet. The axis 40, on which both the structural unit, which consists of the gear 37 and the pot magnet 38, as well as the structural unit, which consists of the chain wheel 6 and the cam wheel io and the armature 39; one Carry out rotation is a stationary axis, one end of which is firmly attached to: the main.carrier plate 4 sits. The two aforementioned structural units are in the working position held on the axis 4o by a clamping ring or an annular clamp 41. Excited the pot magnet 38 is via two contact arms 42, which are associated with slip rings. cooperate, which sit isolated on that end face of the gear 37, which faces away from the pot magnet. The contact arms 42 are isolated on the Support plate 4 and have connecting pieces 43, which serve as connections for the pot magnet 38 serve.

As can be seen from Fig. 4 and 5, Fig. 4 shows, as already mentioned, a side view of the control device, while FIG. 5 is a corresponding plan view, seen from below, reproduces. The main support plate i i of the unit, the threaded bushings 12 and the chain wheel 15 have already been explained with reference to FIG. Fixed on the sprocket 15, so that it rotates with him, sits a gear 44, which meshes with a pinion 45 (see. Fig. 5). The axis 46 on which the structural Unit consisting of sprocket 15 with gear 44 rotates, is a stationary axle, one end of which is firmly seated on the main support plate i i. The structural unit is in the working position on the axis 46 _ by a bracket 47 held. The gear ratio between gear 44 and pinion 45 is such that one third of a revolution of the gear 44 one revolution of the pinion 45 causes. Fixed to the pinion 45 so that it rotates with it, sits the drive or pin wheel 48 (see. Fig. 5) .a Geneva gear. The pencil of the Stiftrade 48 is at 49 in FinG. 5 shown. The output gear 5o of the Maltese cross has seven slots 51 so that one revolution of the pin wheel 48 causes a seventh of a revolution of the wheel 5. Firmly on the wheel 5o so that it is rotates with this, sits a pinion 52 (see. FIG. 5), which with a gear 53 combs. The structural unit, which consists of the gear 5o and the pinion 52, rotates on a fixed axis, one end of which is fixed to the main carrier plate i i sitting. The rotor 54 is seated firmly on the gearwheel 53 so that it rotates with it a key switch. The axis 55, on which both the structural unit, which consists of the pinion 45 and the pin wheel 4: 8 of the Geneva gear, as well the structural unit, which consists of the gear 53 and the rotor 54, itself Rotate is a stationary axle, one end of which is fixed to the main support plate i i sitting.

The two aforementioned structural units are in their working position on, the axis 55 held by a ring bracket 56. The gear ratio between pinion 52 and gear 53 is such that one revolution of the pinion 52 causes a quarter turn of the gear 53. As can be seen from the foregoing results in transmission ratios, calls a third of a revolution of the gear 44 (that means the movement of the gear 44 corresponding to a change in the Display between the display of a specific display area and the display the following display area), one twenty-eighth of a rotation of the rotor 54 emerges.

The rotor consists of six conductive disks 57, 58, 59, 6o, 61 and 62, which are permanently connected to one another via five conductive spacer disks 63 are in electrical connection (see. Fig. 5). The six electrically conductive key washers and the five conductive spacers 63 are pressed together and are of the support plate i i kept isolated. The gear 53 and the rotor 54 are at a standstill with each other via an inner bearing component in a clamping connection, which is an outer Has nut-shaped portion 64. In those operating cases where the endless Chain has seventy links and has fourteen display surfaces, the six have current-remaining disks of the rotor have the shapes shown in Fig. 6, the disks 59, 6o, 61 and 62 are key disks, while disk 57 is a reset disk and disk 58 is a feed disk. In the other operational case where the endless chain has one hundred and forty links and twenty-eight display faces carries, the six current-conducting disks of the rotor have those shown in FIG Shapes, with the disks 58, 59, 6o, 61 and 62 being key disks, while the disk 57 is a combined return and supply disk. In the same Wise-formed stationary contact arms 65, 66, 67, 68, 69 and 70 are respectively associated with the conductive disks 57, 58, 59, 6o, 61 and 62.

Each contact arm is a slot arm consisting of two parts which are arranged to cooperate with the two surfaces of the associated electrically conductive disc. The contact arm assembly sits on the main carrier plate i 1 and is held there by several screws, such as 71 (see Fig. 5). It itself has adjusting screws 72 and 73 and clamping screws 74. The stationary contact arms 65 to 70 are isolated from one another and from the carrier plate ii. In the case of operation where the endless chain has one hundred and forty links and carries twenty-eight display surfaces and the disk 57 has a combined return and. If the feeder disk is, the disk 57, as can be seen from FIG. 4, is assigned a stationary feeder contact arm 75 in addition to the contact arm 65. This supply contact arm 75 is sufficiently wide at its contact end to bridge the individual cutouts which the disk 57 has in this case. If the supply contact arm 75 is provided, it forms part of the same contact arm arrangement as the other contact arms, and it is isolated from these other contact arms and from the carrier plate ii. The contact arms have connecting pieces 76.

As can be seen from FIG. 6, this shows, as already mentioned, a circuit arrangement; which corresponds to that operating case in which the endless chain carries fourteen display surfaces. For the description of the operation of the display device in this operating case, it should be assumed that the display area which is displayed when the endless chain is in its normal position corresponds to a space, while the display areas which are displayed when the endless chain is in its first, second, third ... ninth and tenth stop position out of the zero display position, the digits 1, 2, 3 ... 9 and o reproduce and that the remaining display areas correspond to further spaces. In the circuit arrangement, the six current-conducting disks 57, 58, 59, 6o, 61 and 62 of the rotor of the key switch mechanism are shown in such a way that they assume their normal position relative to the stationary contact arms 65, 66, 67, 68, 69 and 7o. A movement of the endless chain, regardless of whether it is done to adjust the chain so that a certain number is displayed, or to return the chain to its normal position, always takes place in the direction in which the clockwise rotation ( 4 and 6) of the rotor of the key switch mechanism.

In the operational case that is now being dealt with, the endless chain only calls having fourteen stop positions including the normal position and since the movement the chain from one stop point to the next stop point is only one twenty-eighth corresponds to one revolution of the rotor of the key switch mechanism, a closed one Movement of the endless chain from its normal position over the various Display positions, back to their normal position only half a turn of Runner of the key. Therefore, the rotor has the key switch mechanism two normal positions that are offset by half a turn to each other, and he is; as can be seen in particular from Figure 6, set up so that he the same sequence of switching operations for each movement over: half a turn away from any of these positions. One complete revolution or Movement of the runner from one of his normal positions to the other normal position corresponds to fourteen switching steps of the rotor, these switching steps of course be brought about by means of the Geneva gear.

In the circuit arrangement, the pawl electromagnet 2o is provided between the negative battery and the stationary contact arm 66, while the pot magnet 38 of the electromagnetic clutch and the normally open contact LMC of the pawl electromagnet are arranged in series between the negative battery and the positive battery. The normally open contact LMC is the contact which is formed by the shoulder 30 (see FIG. 2) of the armature of the ratchet electromagnet and by: the contact spring 26 (see FIG. 2). Contact R is a contact which is closed to return the endless chain to its normal position, while contacts W, X, Y and 'Z are key contacts which are closed in various combinations to adjust the endless chain so that it shows the various digits. The various combinations that are used here are shown in the table below Table I. Associated Re-closed Position from the keys to be given Digit normal position contact (s) out z first ........... W - - - 2 second ......... - X - - 3 third .......... WX - - q. fourth. . . . . . . . . . - - Y - 5 fifth .......... W - Y - 6 sixth ......... - X- Y - 7 seventh .... .... WXY - 8 eighth .......... - - - Z 9 ninth ......... W - - Z o tenth .......... - X - 7th A key signal which causes a certain digit to be displayed is a four-element signal, the first character element determining whether the key contact W is closed or open, the second element determining whether the key contact X is closed or open, the third element determining whether the key contact Y is closed or open and the fourth element determines whether the key contact Z is closed or open. All electrically conductive disks 57, 59, 6o, 61 and 62 have, as shown, cutouts so that a continuous circuit between the disks. and the associated contact arms are only present when the rotor of the switching mechanism assumes certain positions. The electrically conductive disks, which are in electrical contact with the associated stationary contact arms when the rotor assumes its various positions, are listed in the table below. Table 1I Position of the conductive discs in elec- Runner's tric contact with associated K ak stationary ont t a n rme normal ...., ........ - 58 59 6o 61 62 first (from normal). . 57 58 - 6o 61 62 second ............ 57 58 59 - 61 62 third ............ 57 58 - - 61 62 fourth ............ 57 58 59 6o - 62 fifth. _. .... .... 57 58 - 6o - 62 sixth ............ 57 58 59 - - 62 seventh .......... 57 58 - - - 62 eighth ............. 57 58 59 6o 61 - ninth ........... 57 58 - 6o 61 - tenth ............ 57 58 59 - 61 - eleventh. . . . . . . . . . . . 57 58 - - 6 = - twelfth ........... 57 58 59 60 - - thirteenth ........ 57 58 - 6o - - In considering the operation of the display device, one must remember that the conductive disks 57, 58, 59, 60, 61 and 62 are all in permanent electrical communication with one another through the five conductive spacers 63 (see FIG. 5). The ratchet electromagnet 2o has a control circuit which has a key branch for each element of the key used. The control circuit key branch for the first element of the key consists of the key disk 59, the stationary contact arm 67 and the key contact W. The control circuit base key branch for the second element of the key consists of the key disk 60, the stationary contact arm 68 and the key contact X. The The control circuit key branch for the third element of the key consists of the key disc 61, the stationary contact arm 69 and the key contact Y. The control circuit key branch for the fourth element of the key consists of the key disc 62, the stationary contact arm 7o and the key contact Z.

After closing one or more of the key contacts W, X, Y and Z to move the endless chain from its normal position to the stop position in which it shows the relevant number, which one here corresponding key signal in question, the latch electromagnet 2o excited via one or more of the control circuit key branches. When the Pawl electromagnet ao becomes the pawl 2c9 (see. Fig. 2) brought out of operative connection with the cam wheel ro, during the ratchet electromagnetic contact LZIC (see. Fig. 6) is closed. By closing contact L3IC, the circuit for the pot magnet 38 of the electromagnetic clutch established with the result that the sprocket 6 (see. Fig. 2) and the cam wheel ro with the common Primary drive: ebsvorrichtung is coupled and driven by this. The order is such that the excitation of the pot magnet 38 is maintained for so long until the sprocket 6 moves the endless chain into the required stop position brought. During the periods in which the endless chain is between stop positions moved, the contact LJIC is independent of the energized state of the pawl electromagnet 2o held in that the pawl 29 (see. Fig. 2) then not in a cam recess can come up.

The Maltesergetri.ebe (see. Fig. 4. and 5) is set up so that the step-by-step advancement of the key switch rotor takes place, while the contact LMC, as described above, regardless of the switching state of the latch electromagnet 2o is kept closed. At every stop position that is reached before the desired stop position has been reached, the switching conditions are such, that one or more of the four control part key branches are effective to .den ratchet electromagnet 20 to excite. On the other hand, the switching conditions are at the respectively desired stop position such that none of the four control circuit key branches is effective to the ratchet electromagnet to excite.

As a first example it is assumed that by a key signal it is indicated that the number z is indicated by the indicator in the operating case according to FIG should be displayed. Then (see Table I) the key contact W closed while the endless chain is in its normal position. The latch electromagnet 2o is excited via the control circuit key branch with the key washer 69, the stationary contact arm 67 and the key contact g '. The LMC contact is closed, so that the endless chain starts moving. While the chain is coming out of her Normal position moved to the next position in which the number z is displayed the Malteserg-etriebe brings the runner of the key-operated mechanism step by step from the normal position to the first switch position. When the rotor of the key switch mechanism has moved to its first switch position (from normal), then that is the last mentioned control circuit key branch in the key switch device open (cf. Table II). Hence, `if the endless chain is the first display position has reached the switching conditions such that none of the four control circuit key branches is effective to excite the pawl electromagnet 2o, so that the pawl 29 (cf. Fig. 2) falls into the opposite groove or cam recess in the toothed wheel ro and thereby the contact LMC 'is opened. The endless chain becomes as a result brought to a standstill in the stop position in which the number r is displayed will.

As a further example it is assumed that it has been determined by a key signal that the number 7 is to be displayed. Then (see. Table I) the key contacts W, X and Y are closed, while the endless bed is in its normal position. As a result, the ratchet electromagnet 2o is initially excited via the three control circuit key branches which the three key disks 59, 6o and 61 have. When the endless chain has moved into the first display position (from normal), then the two control circuit key branches with the two key disks 6o and 61 in the key switch device are closed (see Table II), and they become effective to excite the pawl electromagnet 2o so that the contact LAIC is kept closed and the movement of the endless chain continues. In the second display position, the two control circuit key branches with the two key disks 59 and 61 are effective; In the third display position, the star circle key branch with the key washer 61 becomes effective; In the fourth display position, the two control circuit keys with the two key disks 59 and 6o are effective; In the fifth display position, the control circuit key branch with the key disc 6o becomes effective; In the sixth display position, the control circuit key branch with the key washer 59 becomes effective. In the seventh display position, however, the three control circuit key branches with the three key disks 59, 6o and 61 are all open in the key switching device, so that the switching condition is that none of the four control circuit key branches is effective to excite the pawl electromagnet 2o. As a result, the endless chain is stopped in the stop position in which the number 7 is displayed.

It should be noted that when the display device is set has been to indicate a digit, the subsequent opening of the key contacts, which have been closed to effect such an adjustment do not by itself cause a change in attitude. To convert the display device into to reset the normal position, the contact R; with all key contacts in the open position, closed with the result that an excitation circuit for the The pawl electromagnet 2o is closed via the reset disk 57 and the stationary contact arm 65 until the endless chain is in its normal position approaching. The exact alignment x of the chain into its normal position takes place then under the action of the pawl 2.9 (see. Fig. 2).

As can be seen from FIG. 7, this relates, as already mentioned, to a circuit arrangement for i the operating case in which the endless chain has twice the length of the endless chain shown in FIG. Z and carries twenty-eight display areas. For the description of the mode of operation of the display device in this operating case it is assumed that the display area which is displayed when the endless chain assumes its normal position corresponds to a space and that the display areas which are displayed when the endless chain are in their first, second, third ... twenty-fifth and twenty-sixth display positions, the letters A, B; C. . . Display Y and Z respectively and that the further display area also corresponds to a space.

In the circuit are the six electrically conductive discs 57, 58, 59, 6o, 61 and 62 des-runner of the key switch mechanism shown so that they their normal position relative to the stationary contact arms 65, 66, 67, 68, 69 and Take 7o. A movement of the endless chain, regardless of whether it is takes place in order to bring a certain letter to the display, or whether it takes place, to bring the chain back to its normal position always plays in the same direction from which a clockwise rotary movement (see. Fig. 7) of the rotor of the key switch mechanism is equivalent to. In the operational case now to be considered, the endless chain calls having twenty-eight stop positions including the normal position and there the movement of the chain from one stop position to the next stop position corresponds to the twenty-eighth of a turn of the rotor of the key casing, a closed movement of the endless chain from its normal position over the different display positions back to their normal position one turn of the rotor of the key switch mechanism. Therefore, in this operating case, the The rotor of the key switch mechanism only has a normal position.

In the switching arrangement, the pawl electromagnet 2o is provided between the negative battery and the stationary feed line contact arm 75 (cf. FIG. Q.), Which is assigned to the combined return and feed line disk 57. As has already been stated, the stationary supply contact arm 75 is sufficiently wide at its contact end to bridge the only cut-away part of the disk 57, so that this contact arm is always in contact with the disk 57. The pot magnet 38 of the electromagnetic clutch and the normally open contact LMC of the pawl electromagnet are switched in the same way as in the case of FIG. 6 described operating case. Contact R is a contact which is closed to return the endless chain to its normal position, while contacts P, Q, R, S and T are key contacts which are closed in various combinations - "" ground to set the endless chain that it displays the various letters. The various combinations selected for this can be seen in the table below: Table III Anzu- each closed showing corresponding key Letter display position contact (s) A first ........... P - - - - B second ......... - Q - - - C third ......... PQ - - - D fourth .......... - - R - - E fifth .......... P - R - - F sixth ......... - QR - - G seventh ........ PQR - - Eighth .......... - - - S - I ninth ......... P - - S - J tenth ......... - Q - S - K elft ............ PQ - S - L twelfth. . . . . . . . . - - RS - M thirteenth ...... P - RS - N fourteenth ...... - QRS - O fifteenth ...... PQ RS - P sixteenth ..... - - - - T seventeenth ...... P - - - T R eighteenth ..... - Q - - T S nineteenth ..... PQ - - T T twentieth ..... - - R - T U twenty-first P - R - T V two and twentieth QR - T W three twentieth ... PQR - T X four and four twentieth ST Y five and five twentieth ... P - - ST Z six and twentieth Q - ST A key signal, which prescribes that a certain letter is to be displayed, is this time a five-element signal, whereby the first element determines whether the key contact P is closed or open, the second element determines whether the key contact is closed or open, the third element determines whether the key contact R is closed or open, the fourth element determines whether the key contact S is closed or open, and the fifth element determines whether the key contact T is closed or open. Each of the electrically conductive disks 57, 58, 59, 6o, 61 and 62 has, as shown, cutouts, so that a continuous circuit between the Seheibe and the associated stationary contact arm 65, 66, 67, 68, 69 and 70 is only present when the rotor of the rear derailleur assumes certain positions. The electrically conductive disks, which are in electrical contact with the associated one of the contact arms 65, 66; 67, 68, 69 and 70 are, when the runner assumes his different positions, are to be taken from the following table Table IV Conductive disks in elec- Position of the tric contact with the Runner meeting the contact arms 65, 66, 67, 68, 69 and 70. normal ............ - 58 59 6o 61 62 first (off normal). . 57 - 59 6o 61 62 second ............ 57 58 - 6o 61 62 third ............ 57 - - 6o 61 62 fourth ............ 57 58 59 - 61 62 fifth ............ 57 - 59 - 61 62 sixth ............ 57 58 - - 61 62 seventh .......... 57 - - - 61 62 eighth ............. 57 58 59 6o - 62 ninth ........... 57 - 59 6o - 62 tenth ............ 57 58 - 6o - 62 eleventh. . . . . . . . . . . . :. 57 - - 6o - 62 twelfth ........... 57 58 59 - - 62 thirteenth ........ 57 - 59 - - 62 fourteenth ........ 57 58 - - - 62 fifteenth ........ 57 - - - - 62 sixteenth ......... 57 58 59 6o 61 - seventeenth ........ 57 - 59 6o 61 - eighteenth ........ 57 58 - 6o 61 - nineteenth ....... 57 - - 6o 61 - twentieth ......... 57 58 59 - 61 - twenty-first .. 57 - 59 - 61 - twenty-second. 57 58 - - 61 - twenty third. 57 - - - 61 - twenty fourth. 57 58 59 6o - - twenty-fifth. 57 - 59 6o - - twenty sixth. 57 58 - 6o - - twenty seventh 57 - - 6o - - The ratchet electromagnet 2o has a control circuit which has a key branch for each element of the key used here. The control circuit key branch for, the first element of the key consists of the key disc 58, the stationary Konfiaktarrn 66 and the key contact B. The control circuit key branch for the second element of the key consists of the key disc 59, the fixed contact arm 67 and the key contact Q. The control circuit key branch for The third element of the key consists of the key washer 6o, the stationary contact arm 6-8 and the key contact R. The control circuit key branch for the fourth element of the key consists of the key disk 61, the stationary contact arm 69 and the key contact S. The control circuit key branch for the The fifth element of the key consists of the key washer 62, the stationary contact arm 70 and the key contact 7 '.

When closing one or more of the key contacts. P, Q, R, S and Z 'for the purpose of setting and adjusting the endless chain from its normal position to the stop position in which it displays the desired letter, which is determined by the relevant key signal; speaks, the ratchet electromagnet 2o on one or more of the control circuit key branches. The latch solenoid contact therefore closes with the result that the circuit of the pot magnet 38 of the electromagnetic clutch is closed. The display device is controlled in a manner which corresponds to that which has been explained above with reference to FIG has brought the desired stop position. At each previous stop position, the switching state is such that one or more of the five control circuit key branches are effective to excite the pawl electromagnet 2o, while at the desired stop position the switching state is such that none of the five control circuit key branches are effective to close the pawl electromagnet irritate.

For example, it is assumed that it has been determined by a key signal that the letter W is to be displayed by the display device in the operating case according to FIG. Then (see. Table III) the key contacts P, Q, R and T are closed while the endless chain is in its normal position. Under these circumstances, in every stop position between the normal position and the fifteenth display position, the control circuit key branch, which has the key washer 62, the stationary contact arm 70 and the key contact P, is effective to excite the pawl electromagnet (see Table IV), regardless of this whether the other control circuit key branches are open or closed. In the sixteenth, seventeenth, eighteenth and nineteenth stop positions, at least the control circuit key branch with the key washer 6o, the stationary contact arm 68 and the key contact R is effective in order to excite the pawl electromagnet. In the twentieth and twenty-first stop positions, at least the control circuit key branch with the key washer 59, the stationary contact arm 67 and the key contact Q is effective in order to excite the pawl electromagnet. In the twenty-second stop position, the control circuit key branch with the key disc 58, the stationary contact arm 66 and the key contact P is effective in order to excite the pawl electromagnet. In the twenty-third stop position, on the other hand, none of the control circuit key branches are effective to operate the ratchet electromagnet, and the endless chain is stopped to display the letter W. By closing the contact R for all key contacts in the open position, the display device is reset to the normal position, as can be seen from the description of the reset process which has been explained above with reference to FIG.

Even if a common primary drive device was mentioned at the beginning has been, it goes without saying that a display device with one him each individually assigned drive electric motor, if desired, can be provided.

To ensure correct adjustment of the display device according to the invention Sometimes it may be necessary to use a different key :, the display elements in a non-numerical and / or non-alphabetical order on the endless one Chain to be provided.

The display device according to the invention can be controlled by key signals which can be recorded or stored beforehand in a perforated tape.

Claims (8)

PATENT CLAIMS: i. Electric drive and control device for Setting or adjusting an output component from a normal position in a stop position according to a key signal indicating a selection of a meets certain of a series of stop positions in which a control circuit, which controls the drive of the output component, has a key branch, which corresponds to each key element of the key used, the various control circuit key branches being designed and set up in this way -are that in each stop position, which is before the selected stop position, the switching state is such that @ that one or more control circuit keyszw eige are effective to let the drive of the output component continue, thereby characterized in that a key switch mechanism with a rotor, which by the Output component is driven, one stationary for each control circuit key branch Has contact arm and a conductive key washer, which is part of the Runner is swept over by the fixed contact arm, in permanent electrical Connection with the other conductive key washers of the rotor is off which parts are cut out so that a continuous circuit between you and the stationary contact arm is only available if the runner determined Takes positions according to the key element to which the branch is assigned and which, together with the stationary contact arm, has a control switch in the key branch forms. 2. Device according to claim i, characterized in that the control circuit is set up in such a way that a continuous adjustment movement through it of the output component from the normal position into the desired stop position is caused by the fact that an uninterrupted excitation of the electromagnet an electromagnetic clutch is maintained, which is used to To couple the output component with a primary drive device. 3. Establishment according to claim i, characterized in that the adjustment of the output component from the normal position to the desired stop position by a continuous Movement of the output component is effected and that the rotor of the key switch mechanism is driven by the output component via a clutch device, which causes every effective switching movement of the key switch mechanism to take place faster, than is the case when the rear derailleur equals one continuous movement or according to the continuous movement of the output-B, auteils moved will. q .. Device according to Claim 3, characterized in that the key switch is driven by the output component via a Maltese cross gear. 5. Establishment for display devices in which an output component has a normal position and a Number of stop positions', in which different display areas for Display are brought, characterized in that an electric drive and control device according to claim i, 3 or q. is provided to the output component from the normal position to any desired stop position accordingly to move a key signal, 6. Device according to claim 2 for an electrically actuated change display device in which an output component has a normal position and has a plurality of stop positions in which different display areas are brought to the display, characterized in that the output component from the normal position out to the desired stop position according to a key signal is moved. 7. Device according to claim 5, characterized in that the control circuit one key branch per element of the key used and the excitation the electromagnet of an electromagnetic clutch causes which to couple of the output biological part is used with a primary drive device. 8. Establishment according to claim 5 or 6, characterized in that the control circuit ate a key branch has per key element of the key applied and the control by means of makes a latch electromagnet, which controls a latch, which by her Penetration into a groove or recess in a cam wheel, which is connected to the output component is coupled, the output component stops in a stop position. G. Facility according to claim 5, characterized in that the control circuit, which has a key branch has per key element of the related key, its control by means of a pawl electromagnet with an armature, which is de-energized Pawl electromagnets insert a pawl into a groove or recess in a cam wheel get an idea leaves, which is coupled to the output component and thereby the output component brings to rest in a stop position, which when the electromagnet is excited keeps the pawl out of engagement with the grooves or cams in the cam wheel, and which, when actuated, actuates a latch solenoid contact, which the excitation of the electromagnet of an electromagnetic clutch causes the couples the output component to a primary drive device. ok Facility according to claim 9, characterized in that during the movement of the output component between the stop positions of the armature of the latch electromagnet in its working position is held by the action of the pawl on the cam wheel. i i. Facility according to claim 5 or 6, characterized in that the rotor of the key switch mechanism has an electrically conductive disk, which in addition to the electrically conductive key disks is provided and serves as a combined return and supply disk, and that a stationary contact arm is assigned to this disk and as a supply contact arm serves, which is sufficiently wide at its contact end to form a gap or slot to be bridged in the disk, which causes the reset of the output component.