DE1062039B - Revolution counter with continuous ten circuit - Google Patents

Description

GERMAN

The staggered, d. H. successive ten circuit, as in most cases with the revolution counters is common in calculating machines, has the disadvantage that the angle of rotation 5 and thus the number of digits over which the ten circuit works are limited. Also requires Such a ten circuit requires greater mechanical effort and greater manufacturing accuracy.

The subject of the invention is a revolution counter with a continuous ten circuit for calculating machines or similar machines, in which the actual ten circuit is made by a switching bridge and their overall control is carried out by a crankshaft and the ten circuit synchronously, i.e. closed can be done at the same time across all positions and the structure is much simpler and clearer. Similar tens transmission devices are known. So are with revolution counters with parallel axes Digit rollers longitudinally displaceable camshafts have been applied, which have a common Can make tens transmission in all places, the camshaft in a known case for Carrying out the ten circuit shifted by a control element into one of the two effective end positions will. This known device is very cumbersome to set up. A camshaft for scanning the The number of digits also limits the number of digits due to the sector disks.

The switching bridge used in the subject matter of the invention, however, consists of a pawl carrier, the is set in a known embodiment by a crank in a reciprocating motion and the the first digit roller constantly takes with it, while the other digit rollers each after reaching the transfer point taken by the latches falling into the gaps at these points will. The pawls of the known switching bridges are mounted in a rail in individual pivot points, so that the bearing play must be taken into account when adjusting the bridges; however, this can Change the setting through wear and tear and mechanical stress. Since also the well-known Switching bridge is firmly connected to the crank mechanism, the one actuated by it must not be for everyone Types of invoices required by the revolution counter. However, it is desirable if necessary to be able to switch off the revolution counter.

According to the invention, the switching bridge formed from individual sensing and switching elements is connected to a control shaft which is driven by the machine and is axially displaceable so that, depending on its setting, it switches the Zehnerschaltvor-revolution counter
with continuous ten circuit

Applicant:

Math. Bäuerle G. mb H.,
St. Georgen (Black Forest)

Hermann Raible, St. Georgen (Black and White),
has been named as the inventor

can be made synchronously across all points via the switching bridge. The control shaft fulfills three various functions. It controls the plus or minus movement of the number disks by means of axial displacement via the switching elements of the switching bridge, whereby their central position corresponds to the neutral position, in which a circuit cannot take place. This gives the opportunity to use the revolution counter completely off, and finally it causes a shift of the switching bridge in both directions in the sense of the ten circuit as well as a perpendicular movement of the switching elements. All Control functions are therefore combined in one wave.

The switching bridge, as used in the subject matter of the invention, preferably consists of a closed unit that can be attached to the rear derailleur as such. Tn a z. B. off A bent sheet-metal frame is mounted on a different axis, the links designed as ratchets the bridge carries, which are inevitably connected to each other in a known manner in such a way that at corresponding position of the digit roller, so when the sensing levers of the pawls engage in them, all Ten circuits are carried out simultaneously. The function of relaying and sensing in each place there are in each case a link that spans from one place to the next Switching bridge summarized, which consists of a sensing

909 578/221

lever and a shift lever connected to it by a bearing bushing. That is useful first shift lever designed as a clutch and control member for "connection with the control shaft, so that

Switching bridge 10 consists of one in the longitudinal direction displaceable shaft 14, on which in addition to the switching and control pawl 9 more, each in pairs Sockets 17 connected switching pawls 19 and sensing

the movements carried out by this are mounted tiltably via the 5 lever 18. The pawl 9 sits for The first shift lever on the shift bridge is transmitted solely to a bushing 15 that is connected to the shaft 14 will'. This arrangement is simple and overview-pinned. The other sockets 17, each of which borrowed and reliable. More details of a feeler lever 18 at one end and a feeler lever 18 at the other end Revolution counter with a pawl 19 carries according to the invention, are freely tiltable on the formed control shaft for. a Zehnerschaltvorrich- io shaft 14 is arranged. They form with the worship the pawls and levers attached to the drawing are the links in the circuit diagrams. · ■ bridge. Each pawl 9 or 19 is the feeler lever 18 Fig. 1 shows the control shaft in its basic position of the next link adjacent. Each feeler lever as well their connection with the switching bridge; sits at the rear end of a bent sideways Fig. La is a 90 ° rotated partial view of the 15 tabs 16 on the pawl of the prevailing control shaft; rests on the limb. Since each link is replaced by an am

The circumference of its socket engaging tension spring 20 is connected to the frame 12 and the train of this Springs in the sense of the tilting movement of the pawl 9 acts, the contact of the tabs 16 remains on the previous one Pawls 19 per se obtained with each tilting movement. A tilting of the pawl 9 by one of the two eccentrics 7 or 8 therefore also causes a tilting rotational movement of the entire Switching bridge 10 against the tension of the spring 13.

The rotary movements of these bushings with the

Fig. Ib is a horizontal section through the shaft above the switching bridge;

Fig, .l.c. shows the control shaft and switching bridge in Oblique view;

Fig. 2 shows the switching bridge in its overall arrangement and its coupling with the stem in the basic position;

3 shows the number wheels to be controlled by the switching bridge;

Fig. 3a explains the ten switching process for and -;

Fig. 4 is a section of a calculating machine with a revolution counter.

riveted feeler levers and ratchets proceed as follows:

If one of the sensing levers 18 (Fig. 2) against the

One in FIGS. 1, 1 a, 1 b and 1 c is enlarged in a clockwise direction (FIG. 1), moved or held, so Asked control shaft 1 is moved by a shaft 2 so all following members 17 with their driven that they are in a machine game, that is sockets, feeler levers and ratchets that, from the one revolution of the machine main shaft, also seen from a pawl 9, lie behind it, with or remain Revolution. The control shaft 1 has a slot 3 when the pawl 9 is tilted. It. will • on, "in which a pin 4 engages. Through this slot 35, therefore, always still the ones held immediately in front of the a .Longitudinal displacement of the AVelle 1 is made possible. Feeler lever lying pawl 19 and all in front of it in the clock -for this a lever 5 is used with a clockwise tilted into an annular groove 6 when the pawl 9 is described-_ Control shaft 1 gripping pin, through which it executes in bene tilting movement.

the basic position is held in a central position. The number disks 30 (Fig. 3) carry the scanning

Depending on the control from the machine side in 40 disks 40 and the transport wheels 41. In the last known way, the. Control shaft 1 through th dial 31 is a scanning disc no longer <the ^; Lifter5 can be moved up or down.
'■' The control shaft 1 also has two 180 °
'Eccentric 7 and 8 offset from one another. on
them grinds depending on the setting of the control shaft 1 45
through the lever 5 an approach 9 a of a pawl 9,
■ by which these are in the cycle of the shaft rotation of one
the eccentric 7 or 8 is tilted clockwise about its bearing axis 14. This axis is also one
Longitudinal axis of the still to be described
bridge 10.

^: The control shaft 1 always only rotates clockwise, as indicated by the arrow in FIG. ^: The middle part 11 of the control shaft between the annular groove 6 and the eccentrics 7, 8 is eccentric to its axis of rotation and is enclosed by a bracket 9 b of the pawl 9. Since the pawl 9 is a member of the entire switching bridge 10, it is moved by the eccentric part 11 when the control shaft 1 rotates in

In the direction of the longitudinal axis of the bridge back and forth, and these are determined by the eccentric part 11 pushed, so that the switching bridge has two reverse movements of the switching bridge 10 gene, namely a tilting movement and a pushing forwarded by a division. However, this is movement, executes at the same time. only with a tens transfer in all digits

The basic position of the control shaft 1 and thus the possible at the same time, d. H. if all dials Switching bridge 10 is shown in Fig. 2. The jumper and 65 to nine and the corresponding gaps in the scan if necessary The control shaft 1 are also in a washer above the feeler levers. All frame-like Frame 12 arranged; a disk 30 on it are rotated from 9 to 0., has a fixed spring 13 that engages the 'pawl 9'

. the task, the Klinke'9 and thus the switching bridge of the relevant feeler lever through the scanning disc 10 always in the in Fig; ! '' to pull the length shown. The 70 is recorded, and all subsequent transport bikes can

necessary. The remaining scanning disks 40 have cutouts 50, which have a certain position to the dials in relation to the Nuü.

If a movement in the positive direction of rotation is to be carried out on the dials in a known manner, so first the control shaft 1 is raised by the lever 5 so far that the pawl 9 of the eccentric 7 can be detected. By rotating the switching 50 shaft 1, the switching bridge 10 is initially through the crank-like acting eccentric part 11 shifted to the left (Fig.2 and 3a). The amount of shift to the left corresponds to a division of the transport wheels of the dials.

If the switching bridge 10 has arrived in the left end position, the eccentric 7 begins to work and tilts the entire jumper 10 clockwise. The switching bridge 10 engages with its pawls in the Teeth of the transport wheels 41 of the dial 30

Claims (7)

NEN do not participate in the switching movement until this dial has reached nine through the pawl of the preceding, not held member and the associated feeler lever can fall into the scanning disc under the action of the spring 20. With a negative rotation, however, the control shaft 1 is adjusted downwards by the lever 5. The switching pawl 9 with its tab 9 α thus comes into the area of the eccentric 8. When the control shaft 1 continues to rotate, the switching bridge 10 is now first tilted clockwise (FIG. 1) and then shifted longitudinally. The pawl 9 accordingly engages in the tooth gap of the associated transport wheel 41 of the dial 30 and transports it back by the longitudinal movement of the switching bridge 10 by one division and thus the dial 30 by one number. In order to achieve the opposite direction of rotation of the number wheels, the movement process takes place in the reverse order, as schematically indicated in FIG. 3a. If the dial 30 has now been transported by plus or minus steps of the switching bridge 10 until a gap 50 of a sensing disk 40 comes into the area of the sensing lever 18, which is always the case at zero, the sensing lever can. 18 fall into the gap 50 ^ while the pawl 19 of the same link 17 falls into the gap of the next transport wheel 41 of the next dial 30. This transport wheel with its dial then performs the same switching movement in the same way. In Fig. 3, the pawl 9 and the first two pawls 19 are shown in engagement with the transport wheels 41. However, since the feeler lever 18 of the next link rests on the edge of the scanning disc of the associated number wheel, its pawl cannot intervene on the next transport wheel, and consequently all following links are held back in their ineffective position by the coupling connections 16. It is still possible to switch off the revolution counter completely. This is done in that the control shaft 1 remains in the middle position. When the machine rotates, regardless of whether it is + or -, the switching bridge then only makes the axial shift, but has no effect, since it cannot be tilted; consequently, the transport wheels on the dials can no longer be detected. The interaction of the individual parts of a calculating machine with the revolution counter according to the invention is shown in Fig. 4. 51 is the housing, 52 the keyboard, 53 the counter, 54 a handle for pulling the counter to the right, 55 denotes the switching shaft through which the control shaft 1 is raised, 56 denotes the number of revolutions, 57 the result mechanism, 58 the setting buttons, 59 the delete handles and 60 a cover plate. The connection between the control shaft 1 and the pawl 9 controlling the switching bridge 10 is designed differently in this arrangement in that, instead of the pawl attachment 9a, a lever 29 mounted on the frame 12 rests on the control shaft or on its eccentrics 7 and 8. This lever arm 29 engages under a shoulder 39 of the pawl, as a result of which it is tilted by the eccentrics 7 and 8 in the same way as is described for FIG. 1. Pa τ η ν τ λ ν s ρ r π c η ε: 1. Revolution counter with a 'made of pawls, back and forth from a crank moved switching bridge effected continuous ten circuit, characterized in that the switching bridge (10) is driven by an axially displaceable control shaft (1), which in its two end positions the switching bridge (10) in a positive or negative switching sense to the effect brings, but makes ineffective in the intermediate position. 2. Reverse counter according to claim 1, characterized in that the control shaft (1) and the coupling member (9) of the switching bridge (10) acting on it are designed so that by their rotation besides a movement of the switching bridge in both longitudinal directions is also one of them vertical movement of the switching bridge takes place. 3. speed mechanism according to claims 1 and 2, characterized in that the pawls (19) of the switching bridge are arranged on a displaceable axis (14) mounted in a frame (12) to be fastened to the switching mechanism and each pawl consists of a sensing lever (18 ) for scanning and a switching lever (19) connected to it by a bearing bushing for switching the dial (30), while the first switching lever (9) is designed as the coupling member (9 a, 9 b) connected to the control shaft and is firmly connected to the axis (14). 4. Revolution counter according to claims 1 to 3, characterized in that the control shaft (1) carries two eccentrics (7, 8) which are offset from one another by 180 ° and the tilting movement of the switching bridge (10) in the event of an axial displacement of the shaft the direction perpendicular to the longitudinal axis. 5. Revolution counter according to claims 1 to 4, characterized in that the control shaft (1) designed as a crankshaft with its eccentric part (11) in the control and coupling member (9 b) of the switching bridge, in particular the first pawl (9), engages and that this pawl also has an approach (9 a) with which it is controlled by the eccentrics (7, 8) of the control shaft. 6. Revolution counter according to claims 1 to 5, characterized in that the control shaft (1) is connected to a drive shaft (2) by a slot guide (3) which the axial displacement of the control shaft permitted. 7. Revolution counter according to claims 1 to 6, characterized in that the axial Displacement of the control shaft (1) controlled by a reversing shaft (55) via a lever (5) which engages in an annular groove (6) of the control shaft. Considered publications:
German patent specifications No. 471755, 606 991. For this purpose 2 sheets of drawings © 909 578/221 7.