DE2754065A1 - Automatic calendar switching mechanism - has month rotation shaft turned by can member and has month min. length rotation switch - Google Patents

Abstract

The calendar switching mechanism has a cam member which is displaced axially by one or more axial curved tracks according to the month class in question. The cam member may be turned on by the month rotation shaft in the ratio 1:1. The setting part may be turned on by the month rotation shaft in the ratio 1:1/12 or 1:13/12 and thus has 1/12 revolution of lag or 1/12 revolution of advance per revolution of the cam member. The axial centre position of the cam member may be its 31-day month class position.

Description

CalendarUp

is the subject of the invention with fully automatic the main gear of a calendar mechanism with monthly rotating shaft and mechanical Month-end gearbox in accordance with P 27 37 754.4.

This main transmission is shown in FIGS. 1 to 6. Figure 1 represents the longitudinal section without shift lever shaft 47 and Figure 2 the section A-A in semi-schematic Depiction.

Figure 3 shows the upper half of section B-B and Figure 4 the section C-C. FIG. 5 shows the development of parts 13 and 17 and FIG 6 shows a part of the development of parts 24 and 25. In FIG. 7, the ele'.trische Circuit diagram shown, This main gear consists of the monthly rotating shaft 2, the worm via its worm wheel 3 from the thread 4 of the daily rotating shaft 1 during the daily running time (at night at midnight) by one increment (1/31 of a revolution) is rotated further and thus continues to rotate by 1/31 of a revolution per revolution of shaft 1 (counterclockwise as seen in direction A) The shaft 1 is driven by a not shown Electric motor driven by reduction gear. This exists in other parts Main gear from the rotatable or fixed parts on the shaft 2 and the month end gear 5 and the rotary switch adjustment gear 6. The month end gear 5 consists of the Kettsnrräder 7 and 8, which the shaft 9 via a not shown Continue turning the chain in a ratio of 1: 1 and the sprockets 10 and 11, which are the main part Turn 12 further in a ratio of 1: 11/12, so that the main part 12 per revolution of the Shaft 9 overturns 1/12 of a turn. The sprockets 7 and 10 are fixed on the wave 2 and the sprocket 8 fixed on the shaft 9.

In other parts, the month end gear 5 consists of the axially slidably arranged on the shaft 9 cam body 13, the guide pins 14 engage in corresponding bores in flange 1 of shaft 9. This flange 1 can also be a fixed additional part of the shaft 9.

The cam body 13 is provided with two fixed cams b and c provided and with the axial curve path d and is through the compression spring 15 over the disk 16 shifted to the right and by the cam e of the main part 12 to the left.

Gravel main part 12 consists of the sprocket 11 and parts 17 and 18, which are firmly connected to each other. Part 19 is a solid on the shaft 2 arranged flange, the drive body 20 of the weekday display drive via a locking coupling rotates, which consists of the socket 21 and the double ratchet 22 with hub and the sprocket 23 with hub and the passive drive disk 24 consists of feet are connected to each other. The double ratchet 22 is with 31 ratchet teeth provided and the driving disc 24 with 31 locking creams. Part 25 is the active drive pulley, which is arranged axially displaceable and via 2 pins 26 to the flange 19 is rotatably coupled, which are fixedly arranged on the flange 19. Part 27 is the drive sprocket of the day of the month display drive, which is firmly connected to shaft 2 via its hub is. Part 28 is the drive pulley of the month display mechanism, which is via its hub is fixedly connected to the shaft 2 and is provided with a cam f, which the The intermediate lever of the month display mechanism is moved to its second end position and again snap back. Part 29 is the circulating unit of the monthly minimum length circulating switch 52, which is also arranged on the shaft 2 in a torsion-proof manner. Part 62 is the swivel body of this month's minimum-length rotary switch, which can be rotated on the pin h of the shaft 2 is mounted and is provided with the bearing pin 31 on which the contact bracket 32 is pivotably arranged, which pivots to the left under the action of a spring stands. Part 30 is the contact ring of the circulating body 29, which is connected to the contact bridge 33 is electrically connected and part 34 - the sliding bridge of this University running body. Part 35 is the lead contact bracket of the contact bracket 32 and Part 36 of the X, uleittu.gs contact clip of the contact ring 30.

The rotary switch adjusting gear 6 consists of the gear 37, which is fixedly arranged on the shaft 9 and the double gears 38, 39, 40 zld 41, of which the double gears 39 and 41 are rotatably arranged on the shaft 9 and the double gears 38 and 40 are rotatably arranged on the bearing pin 42 are. Part 43 is the final gear of this rotary switch adjustment gear 6, which is also rotatably mounted on the bearing pin 42 and provided with the cam i is, which pivots the adjusting body 62 to the left against the action of the spring 63 moves and makes one revolution in 4 years. The end of month switch 44 is through the lever 46 is actuated, which is fixedly arranged on the rotatably mounted axle 47. The axle 47 is also provided with the lever 48, which is also fixedly arranged on it is and over which the axis 47 counter to the action of the spring 49 by the cams b and c of the cam body 13 is moved into its right-hand pivot end position in which the switch 44 is in its on position. The frame consists of parts 64a to 64c; The stops on this frame have part numbers 65 to 68. The drive plate 25 also has 31 ratchet teeth like the drive plate 24.

The electrical system of this calendar mechanism consists of the following parts (Scheme Figure 7): 1 daily circulating wave 2 monthly circulating wave 44 month end switch Monthly minimum length cycle switch 53 Day cycle switch (day cycle switch j (Switch-on angle: 90 to 360 degrees) 54 Drive motor (AC drive motor) 55 Weekday display operation blocking magnet 56 Relay switch of the drive motor 54 57 Relay switch of the day of the week display operation blocking magnet 55 58 Rectifier 59 24-hour switch (Switch-on time: approx. 5 seconds) 59 b Hand switch 60 Relay switch 61 II Die This calendar switching mechanism works as follows: On normal days of the month the shaft 2 via its worm wheel 3 of the thread worm 4 of the daily rotating shaft 1 further rotated counterclockwise by 1 sub-step (1/31 turn) viewed in direction A. and thereby also the drive body 20 of the weekday display mechanism by a partial step rotated because the drive plate 25 by springs, not shown, against the Driving disk 24 is pressed and the locking lever of the toothed locking disk 22 is not is swiveled into its locked position. This is when the shaft continues to rotate 2 by 1/31 of a turn also the weekday display drive by the chain wheel 23 by one Sub-step rotated further and the day of the month display drive by the sprocket 27 rotated one step further. At the end of the month and the day transition additionally by the cam f of the cam disk 28 via a not shown Movement transmission lever with feed pawl of the month display drive by a partial step turned further. At the end-of-day transitions between the 30-day months, after further rotation the monthly circulation shaft 2 by 0.5 sub-steps of the switch 44 by the cam c des Cam body 13 switched on via lever 48, axis 47 and lever 46 and thus the Relay after-switch 56 switched on via its third current path, which is via the holding current relay switch 61 leads. At the same time, the relay switch 57 is switched on by the switch 44, by which the day of the week display drive lock magnet 55 is turned on. Through this third current path via the End of month switch 44 is thus the Relay switch 57 switched on and the gap in the second current path (daily circulation switch 53), which only closes its current path from 90 to 360 degrees. So is now also the turnstile of the weekday-knob drive drive body 20 is switched on (a locking lever swiveled in electromagnetically), so that the drive body 20 can only turn one increment (1/31 turn) further. After about 1.5 days of the shafts 2 and 9 then the axle 47 snaps with its levers 48 and 46 again back into the position shown in Figure 2 and the relay switch 57 remains of the blocking magnet 55 is switched on via the holding current pelais switch 61. In the last The relay switches 56 and are half a partial step of these two daily partial steps 57 therefore only switched on via the daily circulation so holder 53, which is in the angular position 360 degrees, or earlier by the outlet angle, its Stromwe; interrupts and thus also switches off the relay switch 60. At the end of February day transition will be after further turning the monthly rotating shaft 2 by 0.5 Tjil steps of the switch 44 closed by the cam b of the cam body 13 via lever 48, axis 47 and lever 46 and thus relay switches 57 and 61 two days earlier than a 30-day month switched on. In the further course of the February month end, the activation gap will be of the daily circulation switch 53 three; al bridged by the switch 44. After approx 3.5 daily steps of the shafts 2 and 9 then snaps the axis 47 with its levers 48 and 46 back into the rotational position shown in Figure 2 and remains the Relay switch 57 of the locking magnet 55 on the holding current relay switch 61 turned on. In the last half sub-step, the February end day run is the same as the month end day run a 30-day month.

On normal days of the month, the shaft 2 turns with the fixed their arranged parts and seen with the main part 20 in direction A counterclockwise by one increment and the weekday display mode is thus activated by the Chain wheel 23 rotated one step further and the day of the month Display drive rotated further by the chain wheel 27 by a partial step. On the 31-day months The monthly cycle wave 2 also only rotates by one partial step at the end of the day continues and in this last sub-step of monthly circulation wave 2 also becomes the Day of the week and day of the month display mode each turned one step further and also the month display drive by the cam f via an intermediate lever with feed pawl also by a partial step. In months with less than 31 Days, the main part 20 via its locking toothed disk is at the end of the month day run 22 electromagnetically blocked after the first partial step at the end of the month and thus the day of the week display mode is turned one step further and the day of the month display mode rotated by the remaining number of partial steps up to day number 1 or 01. At the The last sub-step of wave 2 is also the month display mode the cam f further rotated by a partial step.

At the end of February of the leap years, the cam i of the gear is located 43 in the position shown in FIG. 4 and thus becomes the swivel body 62 pivoted to the left in the position shown in FIG. This got through the bearing pin 31 of the swivel body 62 in the position shown in FIGS. 3 and 4 and thus the minimum month length is extended to 29 days (29 daily increments) and thus postponed the end of February by one day. After one year the cam i has turned clockwise by 90 degrees and the cam comes b normal to effect again. The switch 44 only comes into effect when the current path of the monthly minimum length circulation switch 52 is closed, so when the contact bracket 32 rests with its free end on the contact bridge 33. Of the The contact bracket swivels to the left, also under the action of a spring.

By arranging a third NocKens a between the cams b and c, the Moljatsumlaufwelle 2 can be designed for 32 sub-steps. Through this the advantage is achieved that wave 2 occurs on a 31-day-end-of-day transition rotates further by 2 sub-steps and thus a more favorable design of the cam f (Part 28) achieved. The monthly wave 2 rotates at a 31-day end of the month thus 2 sub-steps further. With this type B, this month-end rotation is then continued 3 sub-steps at the end of a 30-day month and 5 sub-steps at the end of a 28-day month.

The cam a here has the length of the cam c (Figure 2) and the Cams b and c have a length (arc length) greater by a partial step. The relative small pitch difference is not taken into account here.

With types A2 and B2, the leil 13 is provided with 2 curved tracks, which are arranged offset to one another by 180 degrees and arranged n 2 radius areas are. Corresponding to these cam tracks, which are offset by 180 degrees from one another, is here the part 12 (17) is provided with 2 cams e, which are in 2 different radius areas are arranged offset from one another by 180 degrees.

In the case of type A3, 2 levers 43 are arranged and the cams D and c arranged close together. The distance between levers 48a and 48b corresponds here del width of cams b and c. The approaches of the curved path d are here depressions and deepening 2-3 an approach.

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Claims (4)

Claims 1) Calendar switch mechanism with monthly rotating shaft and monthly minimum length rotating switch, characterized in that the further rotation of this monthly rotating shaft (2) by a cam body (13) is controlled by one or more axial cam tracks is shifted axially according to the respective month class. 2) calendar switching mechanism according to claim 1, characterized in that the cam body (13) rotated further in a ratio of 1: 1 by the monthly rotating shaft (2) and the adjustment part (12) in the ratio 1: 11/12 or 1: 13/12 of the monthly circulation shaft 2 is turned further and thus 1/12 turn per turn of the cam body (13) Has lag or 1/12 turn lead. 3) calendar switching mechanism according to claim 1 and 2, characterized in that that the axial center position of the cam body (13) is its 31-day monthly class position is. 4) calendar switching mechanism according to claim 1 and 2, characterized in that that the monthly circulation wave (2) of type B has 32 sub-steps and thus the minimum month-end rotation is 2 sub-steps.