DE9454C - Clock that drives the movement, striking mechanism, alarm clockwork, repeater mechanism and a 4Go-year calendar mechanism with a single movement apparatus - Google Patents

Description

1879.

Class 83.

THEODOR WEISSER in FURTWANGEN.

Clock, which with a single movement apparatus movement, striking mechanism, alarm clockwork, Repetition mechanism and a 400 year old calendar mechanism drives.

Patented in the German Empire from i. May 1879.

The ordinary clocks for civil purposes are, if they have movement, striking mechanism, Repetition work and calendar work, as well as alarm clock work, are very complicated and very dear as a result.

In the case of the present watch, a single musculoskeletal system is operated by the tension spring or Weight can be operated, the whole clock, together with its ancillary components, is in motion set, but in such a way that striking, repeating, waking and calendar pushing are independent of the Movement happens.

The solution of this problem has only become possible because the individual groups the clock mechanisms was carried out in a manner not yet known, so that not only the entire arrangement of the clock, but also the individual groups of Mechanisms are new and peculiar.

However, not all mechanisms of the clock are necessarily linked to one another, but rather can also be used separately from walking, striking and repetition movements and associated with ordinary clocks.

On leaf I the movement with a barrel as the movement apparatus is in four different versions Views, Fig. 1, 2, 3 and 4, without alarm clock and calendar mechanism, and the release mechanism of the percussion, PIg. 5, 6, 7 and 8.

On sheet II the musculoskeletal system of the walking mechanism, Fig. 9, 10 and 11, is shown, as well the gears of the striking mechanism and the advancing device of the calendar mechanism. The former represents Figs. 12, 13 and 14, the the latter Figs. 15, 16, 17, 18 and 19 represent.

Sheet III shows the clock with a musculoskeletal system for weight and the arrangement of the Work. Figures 20 and 21 are two views of the entire watch and Figures 22, 23, 24 and 25 depict the alis release mechanisms and gear train, while FIGS. 26, 27 and 28 the movement apparatus of the movement and FIGS. 29, 30 and 31 the alarm clock setting device demonstrate.

Sheet IV shows the calendar work, with an advancement device, as in can be attached to any ordinary watch. Figures 32, 33 and 34 are three different Views of the calendar. Fig.

shows the guidance and arrangement of the belts. Figures 36 and 37 show the triggering device at the end and at the beginning of the month. 38 shows the advancement of the year numbers. Fig. 39, 40 and 41 show the advancement of the months and finally Fig. 42 shows that due to the leap year attached device.

I. Walking and striking mechanism, repetition mechanism, calendar advancement.

a) Movement.

9, 10, 11 and 13. A tension spring .S is attached to the shaft of the wheel M with its inner end. The outer end is hooked onto the pin t of the pawl s, FIGS. 9 and 10. A spring /, which, like the axis of rotation of the pawl, is attached to the ratchet wheel S _{1, presses on the pawl.} This ratchet wheel is pushed loosely onto the shaft of the wheel M; in the same engages a pawl S ₁ , which is mounted in the watch frame, Fig. 9 and 10, as well as Fig. 3. The arrangement is now made so that when the tension spring S, Fig. 9 and 10, pulled, ie on the The shaft of the wheel M is wound up, the tension of this spring turns the shaft together with the wheel B in the direction of arrow 1. The wheel M stands, as in every ordinary clock, by means of wheels. and drives with the climbing wheel S _{2 in connection, Fig. 1, 2, 3} and 4. In the arrangement shown on sheets I and II, the wheel M is the minute wheel, so it turns * once an hour. The minute wheel M engages in the drive of the center wheel M ₁ , and this again in the drive of the climbing wheel S ₂ . The anchor A engages in the climbing gear; The pendulum guide F is on the armature shaft. appropriate. With this arrangement, the tension of the tension spring S of the walking mechanism is transmitted to the pendulum and thus its movement is maintained.

b) Movement.

Since the minute wheel M turns once per hour, in the arrangement shown on sheet I, the quarter wheel V is pushed onto the extended shaft of the minute wheel, on which the hour wheel S ₃ sits. A change wheel W of the same size engages in quarter wheel V , the drive of which engages in hour wheel S ₃ , FIGS. 1, 2 and 3. The rest of the design is the same as for any other clock.

c) Winding up the mainspring of the movement.

The winding of the tension spring S, Fig. 9 and 10, happens regularly every hour when the clock strikes, each time only by one turn, so that the changes in the spring tension while the clock is running are extremely small and can be regarded as unchangeable whereby the rate of the clock becomes very regular.

Two springs act on the pawl s, Fig. 9: the tension spring on the pin t and the locking spring /! On the other end of the pawl ί! If the tension spring S is now fully wound up, FIG. 10, the tension exerted by this spring on the pin t is greater than the tension of the locking spring /, as a result of which the locking pawl s is lifted and no longer engages in the recess of the disk S _4; on the other hand, the tension spring S exhausted, so presses the locking spring f the pawl ί in the recess of the disc S _A, Figure 9. This disc S _A now consists of a single whole with the suppression degree -S ₅ with the case disk F ₁ and with the. Drive T ₁ . The axes of these parts are pierced, and the parts themselves are loosely pushed onto the shaft of the minute-wheel. Fig. 11 shows the minute wheel together with the pushed-on parts; Fig. 12 shows the firmly connected parts S _t , S ₅ , F ₁ and T ₁ without the minute wheel M, while the minute wheel M with its loosely pushed ratchet wheel S _{1 is shown} in FIG. When the clock is in motion, all parts pushed onto the shaft of the minute wheel stand still, the pin t on the pawl S thus holds the outer end of the tension spring S, Fig. 9, and the tension spring S, as it unwinds, turns the minute wheel M in the direction of the arrow. When the hour has elapsed, the minute wheel has turned once and the pawl s _{lies in the recess of the disk S 4} as a result of the pressure of the locking spring /, FIG. 9. If at the end of the hour the striking mechanism starts to move, that is, at the end of the hour the barrel JT, Fig. 1, 2, 3 and 4, the accessory wheel B and this the drive T ₁ together with the parts F ₁ S firmly connected to it turn ₁ and the disk .S ₄ , Fig. 12, 11 and 9, in the direction of the arrow 1, the tension spring S is _{wound onto the shaft of the minute wheel through the disk S 4} by means of the pawl ί, i.e. the spring is wound up. When striking, at the end of each hour, the whipping wheel .S _{5 and} disk S ₄ turn once, so that each time the tension spring S is only wound one turn. The pawl S ₁ - prevents any rotation of the ratchet wheel S ₁ in the direction of the arrow 2 (see FIGS. 9 and 10). From the entire arrangement and especially from FIGS. 9 and 10 it can be seen that the direction of rotation of the minute wheel M is the same in which the tension spring S is wound. When the mainspring is wound up, the clock does not stop, as is the case with the movable barrel of an ordinary movement. The winding of the mainspring of the movement can also be done by two interlocking wheels, and this version is a lighter one.

On sheet V is the clock with a musculoskeletal system for weight and arrangement of the alarm clock. 43, 44 and 45 show the movement apparatus of the walking mechanism and Fig. 46 shows the loose part pushed onto the shaft of the minute wheel, on which the tension spring is attached. Fig. 47 shows the gear train of the striking mechanism and / of a part of the movement, and Fig. 48, 49 and 50 the alarm clock device.

The winding of the mainspring S, sheet V, Fig. 43 and 44, happens regularly every hour when the clock strikes.

On the shaft of the minute wheel M is a wheel i? ₅ loosely pushed on, Fig. 45 and 46, and in this wheel i? ₅ is a pin / attached to which a tension spring 5 is attached at its one end.

The wheel i? ₅ engages another wheel Ji ₆ , which is loosely attached to the shaft of wheel .S ₅ between two steel disks .S ₁₃ .S ₁₄ , Fig. 45, in such a way that, when the tension spring S is wound up, the Wheel Ji ₅ holds wheel Ji _{6 in place by} means of the tension spring, Fig. 44.

When one hour has elapsed, when the clock strikes, the strike _{wheel .S 5} and with it the wheel Ji ₆ turns around once, whereby the tension spring .S is wound around one turn. From the whole arrangement it can also be seen that the direction of rotation of the wheel M is the same in which the tension spring is wound; the clock does not stop when the mainspring is wound, as described above. ·

d) Striking the clock.

A worm S _{6 is} firmly connected to the hour wheel S ₃ , FIGS. 1, 2 and 3, so that the axis of rotation of the worm coincides with that of the hour wheel.

h is a double-armed lever, the pivot axis of which is fixed on the front plate; w is the hammer shaft; Ji ₁ the hammer attached to it; / 1 is a spring, one end of which is attached to the hammer shaft w and the other end of which is attached to the watch frame (see Fig. 3). These

Spring J ₁ presses the hammer shaft w in the direction of the arrow 3 against one end of the lever A, the other end of which is _{pressed against the worm, S 6} (see FIG. 12). The impact wheel S ₅ , FIGS. 11, 12 and 14, has twelve impact pins of different lengths, the end points of which form a screw thread, the height of which is equal to the height of the screw thread of the screw S ₆ . However, the direction of inclination of both screw threads is opposite. Depending on the position of the worm .S ₆ , the distance of the hammer from the plane of the hammer S _{5 is} different, so that when the hammer S _{5 is} turned once at the end of an hour from the barrel H , only ι hammer pin or 2, or 3 .... or 12 striker pins trigger the striker A ₁ , whereby the number of strikes corresponding to the different hours are performed by the hammer H ₁ on the bell or gong.

e) Triggering the striking mechanism.
At the end of each hour, one revolution of the impact wheel S _{5 is} produced. The Viertelrad, Fig. S, 6, 7 and 8, carrying at right angles to its plane the tripping pin t ₂ which is 5 minutes before the expiration of a full hour the tripping lever ^ ₄ and this in turn by means of the pin t ₃ the lever A ₃ lifts which is firmly connected by the latch shaft W ₁ to the latch lever (or trap) A _2. The trap A ₂ is before lifting with its hook-shaped end in an incision in the trap washer F ₁ , Fig. 6. .S ₇ is the so-called. Jumping bike; it carries the spring pin i _A at right angles to its plane , which rests on a right-angled bend of the lever A ₃ , whereby the whole striking mechanism is blocked, ie it is prevented that the wheels of the striking mechanism can be set in motion from the spring housing H; the drive of the jumping wheel, S ₇ , is in engagement with the impact wheel S ₅ , Fig. 12, and is thus in connection with the spring house H. Now lifts the release pin /, on the quarter wheel the release lever A ₁ , and this the lever A ₃ , FIG. 6, finally there is a position in which the spring pin / ₄ on the lever A ₃ can fall off; the Springrad S ₇ is free and can rotate under the influence of the barrel in the direction of arrow 4, but only until the Spring pin t _t of the rectangular projection of the triggering lever A _t is applied (s. Fig. 7). The clock is now on a warning. When a full hour has elapsed, the release pin 4 of the quarter wheel V falls off the release lever A ₄ , the release lever A ₄ falls, the spring pin i? ₄ is free and the striking mechanism is triggered, the spring _{wheel S 7} rotates in the direction of the arrow 4. Before this wheel has now turned once, the latch disc F ₁ is rotated so far that it on its circumference the latch A ₂ and thus the Lever A ₃ is raised so far that when the spring wheel S _{7 is turned,} the spring _{pin / 4} does not touch anywhere (see Fig. 8).

Depending on the position of hammer A, Fig. 12, the clock strikes the number of strikes corresponding to the hour that has elapsed, which are executed _{during one revolution of the striking wheel ^ 5.} If the impact wheel S =, together with the latch disc F ₁ firmly connected to it, has turned once, the latch A ₁ falls back into the incision of the latch disc F ₁ , which prevents the further rotation of the percussion gear wheels by the spring pin t _A engaging the right-angled bend of the lever A ₃ applies; the striking mechanism is locked.

From this it can be seen how the winding of the mainspring of the movement is regularly possible every hour by one turn. The jumping wheel Si is designed as a worm wheel and engages in a worm, on the shaft of which a vestibule W is attached (see FIGS. 1 and 12).

f) Repeating the clock.
The repeating of the clock can be effected in the following very simple way. On the trap shaft W ₁ , Figs. 1 and 5, a lever A _{5 is} attached to which a cord .S _{8 is} attached. If you pull on this cord, the latch A ₂ and lever A _{3 are} raised, the spring pin t _A and thus the entire striking mechanism is triggered; The beat wheel .S ₅ can turn once, whereby the number of beats corresponding to the last hour that has elapsed is repeated.

g) The prevention of the overstretching of the

Mainspring of the movement.
Since with each revolution of _{the impact wheel S 5} all parts firmly connected to it also turn once and by means of the disk S ₄ and the pawl ί (see Fig. 9, 10, 11 and 12) the tension spring S of the walking mechanism each time by one turn is wound up, it could easily happen, if the clock is repeated more often, that the mainspring would be wound up more during an hour than it expands by the driving of the movement. The overstressing of the tension spring .S is now prevented in the following very simple manner (see FIGS. 9 and 10). The tension of the locking spring / is measured in such a way that it keeps the tension of the tension spring in equilibrium when it is wound one turn. The pawl then remains, as indicated in FIG. 9, in the recess of the disk, S ₄ ; but if the spring .S is wound only a little more than one turn, the tension it generates on the pin t of the pawl ί receives the excess weight over the spring /, and thereby lifts the pawl ί out of the recess in the disk .S ₄ ( see Fig. 10), so that with all further strikes resp. Turning the disk S _{4 the} same under the

The pawl ί goes away without being able to open the tension spring 5 ¹ any further. The pawl S ₁ prevents the ratchet wheel S _{1 from} rotating in the direction of the arrow 2.

It is not possible übermäfsiges tightening the mainspring, S ^1, how often you läfst repetiren the clock.

The over-tensioning of the mainspring is used in the modification, where the winding-up of the same caused by two interlocking wheels, prevented in the following way:

The tension of the wheel £ _e between the steel _disks S ₁₃ S iA, Fig. 45, is so dimensioned that the wheel i? _{6 of} the tension spring S just keeps its equilibrium when it is wound up by one turn.

If the tension spring .S is only wound a little more than one turn, does it receive i from the tension on the wheel? ₆ the overweight, so that with all further blows resp. Turning the impact wheel S ₅ the wheel i? ₀ stands still and the mainspring no longer pulls up.

From this it can be seen that how often one runs the clock repeating an excessive tension the tension spring 5 is not possible.

h) Calendar sliding.

A calendar mechanism should, as it is in the nature of things, be raised every night at 12 o'clock, but for this it is necessary that at this time a thread S ₀ or rod is suddenly raised by the actual clock mechanism and then dropped again. The mechanisms required to produce this movement are shown in FIGS. 1, 2, 4, 15, 16, 17 ,. 18 and 19 shown.

In addition to the release pin t ₂ , the quarter wheel V also carries a second pin t ₅ , which turns a 24-pointed star .S ₁₀ around a tooth for every revolution / every hour, i.e. once in 24 hours. The pin 4 is arranged in such a way that the star rotates about one tooth every time 15 minutes before the full hour.

Furthermore, the auxiliary wheel B is provided with lifting pins. The number of these pins must correspond to the number of hours in which the auxiliary wheel B turns once, whereby the arrangement of the gear train must of course be such that the auxiliary wheel is in a whole number of Turn around once for hours. With our arrangement, the accessory wheel turns once every 8 hours; it therefore has 8 lifting pins and turns around one pin every time the clock strikes at the end of the hour.

_{Furthermore, a shaft W 2 is} rotatably mounted in the frame of the watch and can be displaced by a certain amount in the axial direction. This shaft is pushed by the spring / ₂ to the front plate; so that the w to the shaft. ₂ mounted lever // ₆ B is not affected by the Hebstiften of Beisatzrades, rotates the same at the striking of the clock (see Fig. 18 ). Furthermore, a lever A _{5 is} firmly connected to the shaft w , to which the cord .S _{9 is} attached, which leads to the calendar.

On the star .S _10, Fig. 18 and 19, a pin 4 is attached so, that he night _^3/4 12 hours, when the pin 4 in Viertelrade V ₁₀ pushes the star .S around a tooth, in the axial direction against pushes the shaft ₂ and shifts it so much in the direction of the arrow 5 that the lever A ₆ comes to rest between two lifting pins of the auxiliary wheel B , Fig. 19. If the clock strikes at 12 o'clock at night, it rotates as stated above , the accessory wheel around a pin, whereby the levers A _& and A ₅ and thus the cord S _{a are} raised, and the advancement of the calendar mechanism is effected. If the clock has stopped, i.e. if a lever on lever A _{& has} fallen off, levers A _s and A _e will also fall down again.

_^3/4 ι clock is then the star S ₁₀ is again rotated by one tooth from the pin 4 in Viertelrade V, the pin t ₆ in the star S ₁₀ falls on the shaft w _2, and the spring / ₂ pushes this wave back to the front plate , and the lever / z _G comes out of the area of the lifting pins.

i) The walking and striking mechanism with repetition on a 24-hour weight watch.

The device described so far corresponds to a tension spring watch with an 8-day running time. On sheet III, however, the design of the new clock is given as a 24-hour weight clock. In this case, the chain roller K is still pushed loosely onto the shaft of the minute wheel M (see FIGS. 21 and 28). In addition, the mechanism of the movement is specified as under I a). In this case, the movement of the hands is arranged differently from that given under b), as here the change wheel W is pushed onto the extended shaft of the minute wheel M , which engages in an equally large quarter wheel V , which together with the hour wheel S ₃ on a pointer column is postponed, Figs. 20 and 21.

The manner of pulling of the tension spring S of the Gehwerkes happens here exactly as above in I c) is specified, only that here the disk S _4, which by means of the ratchet s winds the spring S direct to the chain roller K firmly connected is ( see Fig. 28).

The connection of the impact wheel S ₅ with the chain roller is exactly the same as the connection of the chain roller with the floor wheel on every watch. This chain roller is in fact firmly connected to a ratchet wheel, in which a pawl engages, the axis of rotation of which is attached to the hammer line S _b. The striking of the clock indicated under I d) is exactly the same here, only that the spring / ,, which pushes the hammer shaft in the direction of the arrow 3, is not a cylindrical one

Coil spring, but a rod spring (see Fig. 21).

The triggering of the striking mechanism indicated under I e) occurs here essentially in the same way, only, as shown in FIGS. 22, 23 and 24, the levers have a slightly different shape, and here the spring wheel .S _{7 has} two spring pins. In FIG. 22 the spring pin f ₄ rests on the lever h _z ; the striking mechanism is locked. If the release pin t ₂ on the quarter-wheel, by means of the lever h ^ , raises the lever A _{3 so far that the spring pin z * 4} on the lever h _{z can} fall off, the spring wheel S ₇ rotates until the second Spring pin t _% rests on lever h _z (see FIG. 23); the clock is then on warning.

If the release pin t ₂ falls off the lever h _A , the latch h ₂ remains raised by the latch disc F ₁ until this disc together with the strike line .S ₅ has turned once; while the clock strikes. When one rotation is complete, the latch A ₂ falls into the latch disc incision and the hammer mechanism is blocked by the lever A ₃ on the spring pin t _A.

Repeating and preventing overstretching is exactly the same as under I f) and I g) specified.

II. Alarm clock.

The alarm clock is shown here in connection with the 24-hour period shown on sheet III Clockwork described; but it is obvious from this that this alarm clock is being used can also be attached to the clockwork shown on sheets I and II. The essentially new This alarm clock consists in the fact that it does not need to be specially wound up, but from the one musculoskeletal system that winds the movement and the percussion in Movement sets, is driven.

a) Movement of the alarm clock hammer.

An ordinary alarm wheel .S _{1 t is} firmly attached to the shaft of the jumping wheel .S ₇ , Figs. 21, 25, 29 and 30.

If the jumping wheel is rotating together with the alarm wheel .S ₁₁ , and the alarm shaft W ₄ , FIGS. 21, 29 and 30, the embodiment of which is generally known, is raised, as shown in FIGS. 29 and 30, the pins of the alarm wheel S go ₁₁ past the bends in the alarm clock shaft W ₄ without causing the same to oscillate. This is always the case when the clock strikes without waking it up at the same time. The alarm clock _{shaft W 4} is kept raised by means of a lever A _a , which rests on a transverse pin of this shaft (see FIG. 30). Since the jumping wheel _{"S 7"} and the A-corner wheel "S""are stuck on a shaft, waking up is not possible other than for the clock to wake up and strike at the same time. A downward movement of the alarm clock shaft W ₄ through the lever A _s into the The position as shown in Fig. 29 must therefore be connected to the triggering of the striking mechanism at the same time; once this has happened, the alarm clock shaft W _{4 is set} in an oscillating motion when the alarm wheel .Si is turned by means of the pins attached to it, whereby the alarm hammer H ₁ strikes the bell.

Instead of the usual alarm wheel .S ₁ ', an escape wheel S ₁₁ , FIGS. 48, 49, 50, can also be used. If the jumping wheel rotates together with the escape wheel and the alarm clock shaft W ₄ , on which the armature A ₃ and the alarm hammer are firmly attached, is raised, as shown in FIG. 48, the teeth of the escape wheel .S ₁₁ pass when the The clock strikes without setting the alarm hammer in motion.

Here, too, it is not possible to do anything else than that the clock wakes and strikes at the same time.

b) Triggering the alarm clock.

The lever A _a , Fig. 20, 21, 29 and 30, is attached to a shaft w ₃ , which also carries a lever A _n . If this lever lies on the circumference of the alarm clock disc W ₁ , FIG. 30, then the lever A _s and likewise the alarm clock _{shaft W 4} are raised in such a way that, as mentioned above, the clock cannot wake up; On the other hand, if, as indicated in Fig. 29, the lever A ₇ falls into a recess in the alarm clock disc W ₁ , the lever A _s and with it the alarm clock shaft W _{4 also} fall down so far that the same falls through the pins of the alarm clock wheel S ₁ , can be moved. But by placing the lever Ji _n in an incision in the alarm clock disc. W ₁ occurs, a lever A ₉ attached to the shaft w _% presses against a lever h _i0 which is attached to the latch shaft w ₂ and thus triggers the striking mechanism, ie enables the alarm wheel to rotate .S ₁ 1. In this way the alarm shaft W _{4 is} effectively set and at the same time the alarm wheel S , ₍ moves, ie wakes the clock.

In FIGS. 48, 49 and 50 a modification of the alarm mechanism is shown, as it is used in the clock, in which the winding of the mainspring is effected by two intermeshing wheels. The lever A _s is firmly connected to the lever A ₁ and is rotatably mounted on the shaft W ₃ . If the lever / z ₇ lies on the circumference of the alarm clock disc W ₁ , Fig. 48, the shaft W ₄ and the lever A ₆ are raised as indicated above under a), and the clock cannot wake up. The spring / ₇ presses the lever A ₁ (see Figs. 48 and 49). against the alarm clock disc W ₁ . If the lever A ₇ , Fig. 49, falls into the recess of the alarm clock disc W ₁ , the lever / z _{8 is} thus also the shaft W ₄ with the armature A _{2 raised} so far that the armature enters the teeth of the wheel S , , engages, at the same time the lever h _s , Fig. 49, is raised, whereby the warning lever A _{3 is} pushed up and the striking mechanism is triggered.

This enables the escape wheel S ₁ to be rotated. In this way, the armature and the escape wheel also become effective and cause the hammer shaft to vibrate, ie the clock wakes up.

c) Waking up at a certain time.
The alarm clock disk W ₁ carries twelve small hollow cylinders C cut in half (see FIGS. 29 and 31), depending on the position of these cylinders, the lever h- slides over the circumference of the alarm clock disk or falls into the cavity at a certain time ; if the latter is the case, the clock wakes up at this time. Depending on whether the opening of the hollow cylinder is rotated more or less according to the circumference of the alarm clock disc, one is able to wake the clock every hour, or from quarter to quarter of an hour.

III. Calendar work.

a) Movement of the calendar.

Since the calendar not only works with the new watch, but also with any one Clock can be linked, so it is first to be explained in which way the calendar movement happens when the latter case takes place, because for the first case the calendar movement is already indicated under I a).

On sheet IV, Fig. 32, the movement of any clock is given. .S _{3 is} the hour wheel, V the quarter wheel, W the change wheel. , S ₁₀ a 24-pointed star, which by means of a pin ^ ₅ , which is fastened in a quarter-wheel, is turned around one point every hour and once every 24 hours. This asterisk * S, ₀ has a pin t ₆ , which is more suitable. Time lifts the lever A _s and drops it off at 12 o'clock at night. A cord S _{9 is} attached to this lever, and when it is lifted, the calendar movement is advanced. The shaft w _{2 of} the lever h _h has a second lever that can be moved by hand in order to set the calendar if the clock should have stood still for a long time.

b) Advancement of the day of the week.

The calendar mechanism shown on sheet IV initially has a main shaft W ₅ , Fig. 32, 33, 34, 35 and 36, on which a 7-tooth ratchet wheel S ₁₃ , Fig. 34, ■ is attached, and on which the day roll R _x , Fig 32, is pushed on loosely. A 7-tooth ratchet wheel -S _{12 is} firmly connected to this day roll R, Fig. 32. The two ratchet wheels are identical to one another. Connected to the cord S _{9 to be} lifted from the clockwork at a suitable time is a lever h _{91, FIGS} . 34 and 32, on which a pawl-like lever Zi ₁₀ . is rotatably mounted. This lever A ₁₀ carries a transverse pin t- ,, which, when the lever h _{9 is} lifted, engages the two ratchet wheels at the same time, and turns them around a tooth every day at 12 o'clock, so that the day roller R ₁ as well as the shaft w ₅ are rotated every day by the seventh part of their circumference, whereby the names corresponding to the individual days of the week are visible in a corresponding opening in the clock-case. The day roller R ₁ can be loosely rotated around the shaft W ₅ , so that the name of the day of the week can be easily set after the clock has not been used for a long time.

The spring / ₃ always holds the roller in the correct position so that it cannot adjust itself due to external vibrations and is always lifted by the cross pin Y ₇ at the same time as the shaft w _b.

c) advancement of the date.
On the shaft W ₅ a roller has meanwhile been attached to the plates of the work, FIGS. 32 and 35. One end of a band B is attached to this roller, on which the numbers 1 to 31 are located; the other end of the band is fixed on the roller r , Fig. 32, 33, 34 and 35. This roller has a pinion T ₁ which is in engagement with the toothed barrel H _%. The spring located in the barrel H ² tends to wind the tape B onto the roll r and thereby rotate the roller W together with the shaft W _5. On the shaft w 5, a drive T ₃ is also attached, which engages in the wheel Ji _3; 32 and 36. The drive T ₃ has 7 teeth and the wheel Ji ₃ has 35 teeth. In the wheel Ji ₃ a pawl ^ _2, FIG 32 33 35 3 ⁶ and 42 engages.,,, ·

If, as previously stated under b), the shaft W _{6 is} rotated around y, its circumference every day at 12 o'clock, a part of the band B is wound onto the roller W in such a way that it is wound up in a corresponding opening in the watch case The date of the day in question is visible on the band B. At the same time, however, the drive T ₃ rotates the wheel R ₃ around a tooth; the pawl S ₂ rises a little due to the tooth rotating in the direction of the arrow 6, and then falls behind the tooth into the tooth gap, whereby the date is determined and whereby the spring in the barrel IJ ₂ is prevented from winding the date band B onto the roll r.

It should also be noted that the wheel R ₃ , since it has 35 teeth and turns only one tooth every day, does not turn completely once in a month.

d) The date has moved forward from March 30th or 31st

on the 1st

. Above the pawl s _2, a lever A _11, which is provided with a slot through which a riveted in the pawl ^ ₂ t pin ₁₂ passes, Fig. 33, 36 and 4.2. With the advancement of the previously described under b)

At the date the pin t ₁₂ can move freely in the slot of the lever A _11. The lever / ^ ₁ , can not only rotate about its axis, but is also pressed by means of a spring in the direction of arrow 7, Fig. 32, outwards against pins «, which are in the monthly roll R ₂ , Figs. 32 and 38, are attached. Depending on the length of these pins, the distance of the lever A ₁₁ from the wheel R _{3 will be} different. In the wheel R ₃ there are 4 pins t _s t _s t ₁₀ tu, of which one always turns the lever A ₁₁ in the direction of the arrow 8, Fig. 33, 36 and 42 on the last day of the month _{, whereby the pin ^ 12} the pawl s ₂ is raised so far that a second pawl s _$ falls into the same and prevents it from engaging in a tooth gap of the wheel R ₃ . If this is done at 12 o'clock at night at the end of the last day, the spring in the spring house H ₂ , Fig. 35, can come into effect and wind the date band B onto the roll r in the direction of the arrow 9, until in the relevant opening of the clock case the number 1 becomes visible. The following arrangement has been made so that this always happens precisely. When the tape B is wound onto the roll, the wheel R ₃ rotates in the direction of arrow 10, FIGS. 36, 37 and 42, and resumes the position it had at the beginning of the month. During this return movement of the wheel, however, a high tooth located in the same hits the pawl S ₃ and triggers the same from the pawl S ₂ (see Fig. 37), so that the latter again fall into a tooth gap of the wheel R ₃ and thereby can prevent the action of the spring in the spring house ZT _2. The whole arrangement is now adjusted so that at the moment when the number 1 becomes visible in the opening of the watch-case during the return movement of the strap B , the above-mentioned engagement of the pawl S ₂ into the wheel R ₃ takes place at the same time.

The above-mentioned 4 pins t _s / ₉ t _la t _lt of wheel R ₃ have different lengths, and likewise the 12 pins in monthly roll R ₂ , FIGS. 32 and 38, are of different lengths, and the arrangement is such that if a month with 31 days is indicated in the relevant opening of the clock case, the lever A ₁₁ rests on a short pin α , and this is then so far removed from the wheel R ₃ that the longest pin t, _{1 of} this wheel the previously described position of the date from the 31st to the 1st causes. In a month with 30 days, the lever A _{11 is a} little closer to the wheel, as before, so that the pin _{10 can} turn the lever A ₁₁ and move it from the 31st to the 1st.

Of the 12 pins α , only 11 are used in the manner indicated.

e) the date has moved forward from the 28th or 29th

on the 1st
However, if the month of February is visible on the clock, the lever A _{11 is} not, as before, on one of the pins α riveted into the month roll, but, as shown in FIG. 42, on one of the 4 pins a, a. ₂ a ₃ a _{4 of} the asterisk A, Figs. 38 and 42. Of these 4 pins, 3 are of the same length, while the fourth is shorter. If the lever H _{11 is} now in contact with one of the pins of the same length, it has moved so far against the wheel R ₃ that on the 28th night at 12 o'clock the pin t _{a of} this wheel controls the rotation of the lever A ₁₁ and thereby the position of the Date from the 28th to the 1st effected. If, on the other hand, the star A is set in such a way that the lever A ₁₁ rests on the shorter of the 4 pins of this star, the pin t _{9 of} the wheel R ₃ causes the rotation of the lever A ₁₁ on the 29th at 12 o'clock and thus the position of the Date from 29th to 1st

f) advancement of the month.

The month roll R ₂ , Fig. 32, 38, 39, 40 and 41 is pushed loosely rotatably onto the shaft w _s on which, as mentioned under b) and c), the weekday roll R ₁ and the date roller W are attached. The monthly roll R _{2 is} held in its correct position by the spring F ₄ , FIGS. 32 and 33. Between the wheel R ₃ and the monthly roll R ₂ there is a lever A ₁₂ with a joint, FIGS. 32, 33) 34. 4 ° ^and d 41 This lever rests, as Fig. 41 shows, on a pin α of the month roll R ₂ when at the end of the month the date band B is wound onto the roll r, as indicated under d) and c), Fig 35, as the action of the mainspring of the barrel H ₂ is going on.

The lever A ₁₂ now lies so far from the wheel R _{3 is} removed, that during the rotation of this wheel R ₃ in the direction of the arrow 10 at the end of the month the longest pen t _1, of the same against the lever A ₁₂ can push (s. Fig. 41 ), so that the month roll is rotated in the direction of arrow 41 under the influence of the tension spring H _2. Then as the wheel R ₃ rotates on the last one month, at night, 12 hours, in the direction of arrow 10 (namely, this rotation occurs about '/ ₁₂ of the roller circumference, are on which the names of the months recorded), as will appear in a corresponding opening the name of the new month on the watch case. Fig. 41 shows the position of the lever A ₁₂ shortly before the sliding and in the dotted position after the sliding of the monthly roll.

If the wheel R ₃ now rotates in the direction of the arrow 6 (see FIG. 39) when the date is advanced, as indicated under c), the pin t _xl presses again against the lever A ₁₂ and guides it as a result of its joint, as Fig. 30 shows, under the pin α of the month roll R ₂ away. If this pin t _ly , as indicated in Fig. 40 by the dotted position, has fallen off the lever A ₁₂ , a spiral spring / ₅ brings this lever A ₁ "back into contact with a pin α of the month roll (see

Claims (4)

Fig. 41). The lever keeps this position until at the end of the month it rotates the month roll by 1 ^ 2 of its circumference again by means of the pin Z11. g) Advancement of the year. Above the date roller W there is also the year roller W1 mounted in the frame of the calendar mechanism, Figs. 32, 33, 34 and 35. One end of a band B1 is attached to this roller, on which the year numbers are written, while the other The end of this band is fastened to a roller rx. The drive TK of this roller, Fig. 35, is in engagement with a wheel R., t, which is attached to the spring shaft of the barrel JZ1, the spring of which always pulls the tape taut. A spring / 6, Fig. 33, prevents the mainspring in the spring house JJ2 from winding the band B2 onto the roll, and at the same time causes the correct year number to appear in an opening in the watch case. A star A1 is fastened to the annual roller W1, against whose prongs on the last December night at 12 o'clock when turning the monthly roller i? 2 a pin a5 attached to the same presses, Fig. 38, and turns the star A1 around a prong, whereby from the annual band B1 wound a little on the roller W1 and as a result a new year number is visible on the clock. From this it can be seen that, depending on the length of the annual band, the calendar can be set up for any number of years. To simplify the execution, the year can also be attached in another way. The annual band Bx, the roll r, and wheel R ^ remain away, and the annual roller W1 is placed so far forward that it is tangent to the plane of the date band. The star A1 is made 8 jagged and the annual roller 8 angular, and any number of paper strips lying on top of one another are glued around it the year numbers printed on these paper strips come to lie on the surfaces of the eight-edged year roller. The pen «5 in the month roll now turns the star A1 around a point every year, as indicated above, with the consecutive year numbers on the After eight years you rip down the upper strip of paper located on the annual roller W1 and then have yourself on it afterwards table paper strips again 8 consecutive years. It is easy to see that, depending on the number of paper strips lying on top of one another, the calendar can be set up for any number of years. h) Establishment because of the leap year. Above under c) it is indicated how the date in February is shifted from March 28th or 29th to March 1st. It is only necessary here to indicate in which way the asterisk A1, Figs. 38 and 42, is rotated so that the lever h%, can be placed one after the other on the pins of the correct length so that, for three consecutive years, on February 28th and in the fourth year on February 29th the date band runs back and the i. makes visible on the clock. The star A, Figs. 38 and 42, has two motions; it rotates around its axis once a year with the monthly roller R1. During this rotation, one of the pins in star A always hits a fixed pin 11% (see Fig. 42), whereby with each rotation of the star around the axis of the month roll, the star itself is rotated around a pin, so that always in February of the following year the lever A11 is printed against a different star A pin than in the previous year. Since now, as stated under e), three pins of the star A are of the same length and the fourth is shorter than the other three, the date band rewinds on the 28th at 12 o'clock at night in three consecutive years in the month of February ., d. H. in the leap year, this return occurs on the 29th at 12 noon, as stated above under e). From this it can be seen that with a sufficiently long annual band B1, or with a sufficient number of paper strips glued to the annual roller W1, the calendar can be made into one which functions correctly for 400 years without any readjustment. Patent Claims: 1. The entire arrangement of the clockwork described under I. from a) to g) and under i) with walking mechanism, striking mechanism and repeater, both in its execution for an ordinary watch (weight or tension spring clock), as well as in its connection with the described alarm clock and the KaleÄderwerk. 2. The entire arrangement of the alarm clock described under II. From a) to c), namely both in its execution for an ordinary watch, as well as in connection with the items under I. from a) to g) and under i) described new watch. 3. The arrangement of the device described under I h) for pushing the calendar for the new watch described under I. from a) to g) and under i). 4. The arrangement of the under III. described calendar work in its embodiment as a continuous calendar with leap year and year, as well as without Year specification and setup for the leap year, both in its connection with the clock described under I. from a) to g) and under i), as well as in its connection with an ordinary watch. In addition 5 sheets of drawings.