DE114075C - - Google Patents

Description

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IMPERIAL

PATENT OFFICE.

The purpose of the invention is to manufacture a calendar watch that can be easily changed from on a clockwork and on any ordinary clockwork, including pocket watches, without particular difficulties and without inhibiting the movement of the clock mechanism, attach let.

For this purpose the calendar mechanism receives its movement by means of a switch lever which the pointer mechanism of the driving clockwork works for hours, so that here an extreme little effort is required. This happens evenly every day, so that the clock mechanism continues to work without any disturbance.

The fluctuations in the number of days in the different months (28 to 31 days), as well as the irregularities arising from leap years regulate the peculiarly designed Double wheel, from which, however, no day, date or month slices directly to be moved; the said double wheel acts as a regulator for the various Irregularities of the year by turning the lever for the actual calendar movement in such a way that the calendar always has the correct day of the week, date and time Month indicates. The whole calendar consists of the following three working together Share:

ι. the calendar hands,

2. the switch lever,

3. the double wheel for setting the calendar according to the different months and Years lengths.

Fig. Ι shows a calendar work in view;

Fig. 2 is the notch ring with its toothed wheel;

3 is the star wheel with its non-circular disk which revolves once in four years;

Fig. 4 illustrates the displacement of the date wheel by the pawl spring.

Fig. 5 is the dial;

Fig. 6 is the month disk;

Fig. 7 is the day disk.

The calendar movement consists of three star wheels, the three-toothed star wheel 32, the fourteen-tooth star wheel 38 and the twelve-tooth star wheel 46. The middle one Star wheel 32 is used to hold the pointer 34 of the date disc (or the date disc itself), the star wheel 38 for recording the days of the week, and the star wheel 46 for recording of the months, which are indicated by means of hands or discs. All of these star wheels are rotatable about their axes with their spindles 47, 39 and are locked by locking springs 33,41,48 held in the usual way from tooth to tooth in their position.

The monthly switching is effected by a contact piece 44 rotatable about pin 42; a pin 45 attached to the star wheel 32 rotates the pin 45 which is switched off from the star wheel 46 Position held by means of a spring

Contact piece always on the first of each month on his nose 43 so much that that Wheel 46 advances one tooth, and then starts running again.

Furthermore, the date star wheel 32 is fixedly connected to a gear 36, which is in a the spindle 24 engages rotatable gear 35. With the latter is a twenty-four toothed one The wheel is firmly connected, the two pins 22, 23 separated by 180 ° from each other wearing. These pins transmit the movement from the calendar hand train to the star wheel 20 respectively on the double wheel.

A changeover lever 31, 27 can be rotated on a spindle 16 and is actuated by means of a spring 17 get in its location. It consists of a longer arm 27 and a second arm 31, on which a hook-like pawl 15 and one of the latter opposite against the star wheel 38 directional pawl are attached. The long arm 27 is used to transmit the movement from a clock by means of its hand mechanism. With every oscillation The lever 27, 31 moves the pawl of the arm 31, which is directed against the star wheel 38 the same thing by a tooth. This will make the pointer or disk that is on the Star wheel 38 respectively. mounted on its spindle 39, rotated one day of the week further, while attached to the end of the arm 31 and, as it were, its extension forming spring 30, the star wheel 32 by a BEZW. at two, three, or even four Teeth, and therefore also the date disc (or the date hand), around one, two, three or is switched forward by four days in the manner specified below.

The double wheel consists of a star wheel 20 with a non-circular disk i attached to it (FIG. 3) and of the notch rings 3 (FIG. 2) combined with a toothed wheel 19 to form one piece. All named parts of the double wheel rotate around the spindle 2. The star wheel 20, which is pushed onto the spindle 2 with its hollow hub, has forty-eight teeth. It periodically receives a substance from the two above-mentioned pins 22, 23, which are located on the small transmission wheel of the spindle 24, in such a way that, when the date star wheel 32 makes a full turn, the star wheel 20 through one of the two Pins 22, 23 is rotated around a tooth, that is, around one forty-eighth of its circumference. Since the star wheel 20 is pushed one tooth further every month, a complete revolution of the same takes 4 years.

On the hub of this star wheel 20 there is, loosely attached, a gear wheel ig provided with one hundred and forty-four teeth, which is firmly connected to a notch ring 3. Gear 19 meshes with a small transmission gear seated on the spindle 24, which has twenty-four teeth, and is rotated by the same so that when the date star wheel 32 is rotated by one tooth (i.e. by one and thirty-first of its circumference), i.e. by one day, moves further, the gear 19 advances only by the three hundred and seventy-twoth part of its circumference. Therefore, if the date wheel has made .32 a full rotation, then the saddle ring its circumference revolves around _^31/372, ie the twelfth part. The gear 19 together with the notch ring 3 therefore takes one year to complete a full revolution.

On the circumference of the notch ring 3, notches or incisions 8, 7, 6, 5 and an average 4 are made in order to take into account the different number of days in the different months. For this purpose the date wheel 32 is set in such a way that it cooperates with the switching lever 31 and with the notch rings 3 in the following manner. As often as a month with only thirty days (e.g. on April 30th) nears its end, the relevant notch section (here 5) comes to stand in front of the pawl 15 of the switching lever, and this switching lever, which is operated by a spring 17 is pressed against the circumference of the notch ring 3, loses the support and falls into the opening 5. As a result, the lever 3 1 gains a larger deflection, and if it. is then moved by the clock on the next day, the weekday wheel 38 is merely moved by one tooth respectively. but shifted by a day of the week, the date wheel 32 by two teeth (that is, from Dreifsigsten direct to the first), and the notch ring 3 also by _^2/37 ° of its circumference. At the same time, the month wheel 46 is pushed one tooth further by a pin 45 fastened under the date star wheel 32 by means of the month trigger 44 (and in this example set to the month of May). In this case, therefore, the notch ring ^{3 has} to be 3 Y ₃₇₂ ? 4 · h · advanced by the twelfth part of its circumference.

This is repeated for all months that have thirty days. For those months those who have thirty-one days do not need to be regulated by the Schartenring.

In the month of February in the normal year, the pawl 15 of the switching lever 31 falls on average 4 to the disk 1. Its deflection is therefore correspondingly larger than in the previous cases, and the next day the date wheel 32 is advanced by four teeth, i.e. from Twenty-eighth on the first. The saddle ring 3 is also shifted by _^4/372 part of its circumference. The notch ring 3 is also in this case

advanced by ³¹ J ₃₇₂ part of its size.

4 illustrates the various switching positions of the lever 3 1.

In order to control the resulting by the twenty-nine days in February in a leap year irregularity, is located in the notch ring 3 a on the hub of the star wheel firmly plugged-20 non-round disc 1, which is designed so, that _^3/4 further protrude its circumference from the notch ring 3 as the remaining ^: / ₄ , with which it almost touches the notch ring, but just allows it to turn freely. This disk rotates with the star wheel 20, with which it is connected to one piece, as already mentioned above, once in four years around its common axis.

To compensate for the influence of the leap year, a pin or a pin is also in the cutout 4. a screw 9 rotatable and held in place by a spring 11 switching piece 10 is attached. In the position shown in FIG. 1, a nose 12 attached to this contact piece 10 is influenced by the spring Ίΐ in such a way that the contact piece 10 leans against the notch ring at 13. But as soon as the coulter ring 3 and the non-circular disc 1 are placed next to one another in such a way that the raised quarter 14 of the non-circular disc 1 comes to rest under the nose 12, the nose 12 is pushed outwards, the piece 10 rotates a little at 9 and the opening 4 narrows somewhat. This narrowing is calculated in such a way that the pawl 15 of the switching lever 31 does not enter the ring 3 here until February 29th instead of the 28th. can. At the same time, the out-of-round disk 1, which is in the position just discussed every fourth year, with its protruding part 14 prevents the usual collapse of the pawl 15, so that in the leap year the date star wheel 3 2 only changes by three teeth (three days) and the gathered ring around _^3/372 advances its circumference.

A pointer can also be attached to the hollow spindle of the disk 1, which shows the Dial points to 366 in the leap year and to 365 in the three remaining years. With this Hands can be adjusted if there is no leap year in the four years, such as Am the years 1900 or 2100. You need in such years to set the pointer to 365 only before the month of February.

Claims (1)

Patent address: Calendar clockwork, characterized by a double wheel that turns once every four years (20, 1), whose non-circular disc (1) is around the three hundred and seventy-second within one day Part of its circumference moving notch rings (3) and one in the February notch (4) around a pin (9) rotatable insert (10) held in position by a spring (11) every four years in this way adjusted so that the latch (15) does not enter the notch (4) until February 29th instead of February 28th can come up. 1 sheet of drawings.