DE98899C - - Google Patents

Description

L.

IMPERIAL

PATENT OFFICE

GREAT

Instruments.

HRBEK & WEJROSTEK in PRAGUE. Perpetual calendar.

Patented in the German Empire on November 14, 1897.

The subject of the present invention is a perpetual calendar, characterized essentially by the fact that a clockworks one after the expiry of 24 hours. Disk about ¹ J ₇ rotates its circumference forward and this pulse is automatically and time according to further transmitted to three with each other are in engagement with discs, the first of which (28 theilige) days of the week, the second (3 i.theilige) the daily data of a month and the third (i2theilige) disc shows the months. Mechanisms are also provided for the correct setting of the discs for the months with 30, 28 and 29 days.

The result (date) of the automatic movement then appears every day of the day, the date and. of the month within the cutouts of the front panel of a Housing in which said device is enclosed (see Fig. 8 of the drawing; Tuesday November 30th).

The invention is illustrated in the accompanying drawings, namely shows

Fig. Ι a view with the front panel removed of the housing,

Fig. 2 shows a section according to χ - χ from Fig. 1 (arrow direction I).

Fig. 3 is a section according to χ - χ from Fig. 1 (arrow direction II).

Fig. 4 shows the position of the calendar on February 28 for an ordinary year,

Fig. 5 shows a device, which the date disc according to the leap years (February with 29 days),

FIG. 6 shows a section along yy from FIG. 5.

7 shows a detail.

The disk A, which is rotated further by a spring mechanism U every time exactly after the expiry of 24 hours, consists of five disks of the same size a Ci ₁ a ₂ a _s a _i (Figs. 1 and 2), which are firmly connected to each other and two through each seven equidistant from

, // "St.

a ^vlI ₂ etc,

standing pins a \ a W ₁ a VU ₁ a \ a ⁿ ₂ a ' ^u _? a ^l \ a \
which latter _{are offset from one another by V 28 of} the circumference between "two disks, so that, viewed as a whole, a pin wheel with 28 pins appears Two days, three for a month with 29 days, and finally four pens at the same time for a month with 28 days.

To the axis of the disc A is another slice A (Fig. 2) pushed determine which (etc Sunday Monday) with at equal distances from one another registered days marks is provided, and the spring work naturgemä'fs at each start-up to ¹ J ₇ continues to rotate its circumference in order to make the next day mark visible within the cutout in the front plate.

In order to allow a further rotation of the disk A only after the respective expiry of 24 hours, a disk A _{2 is} inserted into the spring mechanism U , which has a recess A _s on its circumference, one side of which (in this case the right one) as a result of the The spring tension of the spring mechanism presses against the arm Z of a lever Z ₂ mounted at Z ₁ . If now, after 24 hours have elapsed from the clockwork, lever Z ₂ in the direction of the arrow I (Fig. 1)

was lifted, the rod Z has the disk A ₂ respectively. the spring mechanism released. The gears RR ₁ R ₂ -R _{3 are} rotated and the disc A continues to rotate (by Y _{7 of} its circumference). ₂ has made one complete revolution, the disc A, it is returned to the in Figure ι. Subscribed normal position, the arm Z of the raised periphery of the disc A ₂ into the recess A ₃ (either by own weight of the lever Z ₂ or by Spring action), whereby the spring mechanism appears arrested, only to be put into action again after 24 hours have elapsed.

The pin wheel A is in engagement with a 31-toothed gear wheel B , which is keyed on an axis b rotatably mounted in the frame. This wheel B is connected to three bars O ₁ b ₂ b _s by means of four guide pins c in such a way that they must join in the rotation of wheel B , but can be moved independently of wheel B in its diametrical direction. The magnitude of this longitudinal motion by the pins c limited, to which the lugs b 'b' of the bolt during the displacement to create. In order to c in Nuthen 'of the pins c linearly guided and equidistant b from each remote bolt _x b ₂ b ₃ to fix in their limit positions, a leaf spring is disposed d to the wheel B, can engage their bent ends in corresponding lateral recesses of the bars. the latter are at one of their ends, with teeth b \ b \ b \ provided, which is a division offset of the gear against each other (Fig. 7), while .Rollen T ₁ r ₂ r ₃ (Fig. 3 and 6) are pushed onto pins loose, which are screwed at the other ends of the bars. the bars b ₁ b ₂ b ₃ are provided with respective hubs e, which have on their inside a nose e ^1, the purpose of which will be explained in the course of the description. supervisors Erdem is the top (from the wheel B farthest from) latch _b% with an easily rotatable , on a bolt deferred role f equipped.

An arm g is attached to the circumference of the gear B , and a short pin h (FIGS. 1, 3 and 4) is screwed into the hub of the wheel B, the function of which will be explained later. The gear B is in any position by resilient pawls d 'd "become fixed (Fig. 1 and 2). With the front panel P, a projecting through the hub. E the bolt and from the axis b of the wheel B interspersed sleeve k (Fig 2 and 3) firmly connected.This sleeve is equipped on the outer circumference with a longitudinal rib k ^l , against which the lugs e 'of the bolt b _l b ₂ b _s abutt, whereby when the wheel B rotates the previously depressed bolt is lifted up again Similar to the day disk on the axis of the pin wheel A , a date disk B ' (Figs. 2 and 3) described with numbers 1 to 31 is wedged on the axis b at its end protruding from the front plate P gear B corresponding respectively Bethätigung a new (the next succeeding) point within said cutout appears visible. It must, therefore, as easily understood, the gear B and with it the disc -B 'on the last day of a month at dreifsigtägigen z white teeth or turn two digits further to set a correct date (the first of the next month). Likewise, the gear B and the disk B ' on the last day of a 28 respectively. 29 day month at four resp. Have to move forward three teeth moving digits in order to set "March 1st" both in the common and in the leap year after the last day of February.

A third wheel C is described on the circumference with the name of the month and sits firmly on an axle rotatably mounted in the frame, on which a wheel C equipped with five identically shaped teeth / I ₁ I ₂ I ₃ Z _{4 is fixed.} The teeth H ₂ 1 ₃ I ₁ lie in the plane of the wheel C, the tooth I _1, however, also has two narrow metal strips L connected to one another and exactly overlapping the tooth shape provided in the plane of the wheel C. The distance of the segment from the basic tooth (Bike C) resp. the distance between two segments forming the tooth I ₁ is dimensioned in such a way that each of them can come into engagement with one of the rollers r _x r ₂ r ₃ arranged on the bars b ₁ b ₂ b _3.

The back of the wheel C, in one arm of which a pin m is inserted, is connected to a gear C ₁ provided with 12 pins η on the side facing away from the wheel C.

Below the wheel C on an axis -D (Fig. 1, 3 and 4) an angle lever 0 is pushed loosely, the vertical leg of which is connected to a lever ρ fixed on the same axis D by a spiral spring q , while the other leg is connected to the pins h screwed into the hub of the gear B can come into contact. The vertical leg of the lever o and the lever ρ serve to fix the wheel C ₁ , which is moved from the wheel C in the following way.

When the latter rotates, the pin h of the wheel B lifts the horizontal leg of the angle lever 0, which results in the pins η being released by the vertical leg of the angle lever 0. The arm g can now move the wheel C ₁ further by striking one of the pins η , but

only by one tooth, since the pin h has released the horizontal leg of the lever ο, and its vertical leg has returned to its original position as a result of the spring action q. In addition, the lever j? into the teeth of the wheel C ₁ .

The device for setting the mechanisms to leap years consists essentially of a sleeve v, which is equipped _{with a thumb washer V 1} at one end and a four-pronged wheel v ₂ at the other end, which is loosely pushed onto a bolt E. The thumb disk has three higher and one lower notches, on which the pawl-like end S _{1 of} a lever s rotatable about bolt F rests constantly, which is caused by the excess weight of the second, longer lever arm equipped with an arcuate sliding surface S _{2 at its end.} The rotation of the sleeve ν takes place through the pin m of the wheel C, which _{engages in the toothed wheel v 2} , in such a way that with each new year the sleeve is moved by the length of the circumference of a thumb of the thumb disk V ₁ and in the case of a leap year the pawl-like end S _{1 of} the lever s rests on the deepest detent of the thumb disk, the sliding surface S _{2 of} the lever s thus assumes its lowest position.

The following is the mode of operation of the perpetual calendar, based on the position described in Fig. 1, which corresponds to "Tuesday, November 30th" will.

Before it should only be mentioned that the teeth I ₁ and Z ₂ Z ₃ Z ₄ Z of the wheel C. the months with 28, 29 resp. 30 days correspond to February, April, June, September and November, and indeed the wheel C adjusts itself in each of these months in such a way that with the intermittent movement of the wheel B (after every 24 hours) the rollers T ₁ r ₂ r ₃ the bolt b _x b ₂ b _a pass the teeth ZZ _x Z ₂ Z ₃ Z _4.

Consider the position shown in Fig. 1 position; so that the when occurring by initiation of the disc A ₂ on November 30, 12 at night rotation of the disk A pin a \ is clear, with the numeral 30 engages corresponding tooth of the wheel B and moves it forward by one tooth. But since November is a month with 30 days, when the arm g hits one of the pins η of the wheel C _1, the wheel C is set on the last day of October in such a way that the role T _{1 of} the first bolt b _x passes the tooth Z when the wheel B rotates in the month of November, which would result in a displacement of the first bolt b ₁ . This, however, the tooth was b \ the bolt b in a position brought in which it with the stylus a 'can engage ₂ of the disc A, and thus rotates the wheel B as a result of this successive engagement of pin a' ₂ with the tooth b \ and pin α \ with tooth 31 of wheel B two teeth further, which is necessary for the correct setting of the date disc B ¹ (skipping the 31st day) from the last of the month of November to the 1st of December.

During this rotation of the wheel B , the wheel C has moved further as a result of the pins g hitting a pin η , namely in such a way that the position of the tooth Z is occupied by a tooth gap, i.e. the latches b _Y b ₂ b ₃ without diametrical to be moved, take part in the rotation of wheel B and the latter is actuated 31 times by pin wheel A corresponding to the month of December.

From the position shown in FIG. 1, the bolt b _t , which was moved in November, has returned to its original position in that when the wheel B is rotated, the nose e ' sticks against the longitudinal rib k' of the sleeve k , which is the case with a further rotation of the Wheel B resulted in a diametrical displacement of the bolt b _l (Fig. 5).

In order to correspond to the sequence of two months with 31 days, a longer tooth gap is provided between the teeth 11 ₁ and I ₃ I ₁₁ so that the bars b ₁ b ₂ b ₃ cannot be moved here. The calendar is set automatically by specifying the days in December and January from 1 to 31. If the calendar is started on the last January of each year, the disk C rotates in the manner described above, and the tooth Z ₁ comes to such a position that the rollers T ₁ T ₂ T _{3 of} the bolt b ₁ b ₂ b _s must pass the metal strips of tooth Z ₁ (Fig. 4). Let us now first consider the function of the mechanisms in the month of February of a common year. February has 28 days. Accordingly, on the last of this month, when turning disk A, disc B must be rotated four teeth further in order to have the 1st follow in the date hand after the 28th.

This happens . simply by the fact that when the wheel B rotates in the month of February of a common year, all the rollers T ₁ T ₂ r ₃ move the bars b _x b ₂ b _s when the tooth Z _{1 is passed} . Since the teeth b ' ₁ b' ₂ b ' _s , as already mentioned, are offset from one another by one division of the wheel B _{, the pins a' 4} a \ a ' ₂ and a \ act one after the other with the teeth b \ b ' ₂ b \ and the tooth 31 of the wheel B together, so that this continues to rotate four times shortly after each other. In the ordinary year after February 28, the i. March can be seen.

The situation is different in February of a leap year in. which month only two bars b _i b. _{2 must be maintained} in their shifted position caused by striking the rollers T ₁ r ₂ against the tooth Z _1. On the last of February of a leap year, the date hand has to move from 28 to 29 and from this day to March 1st. In order to achieve this, the device (sleeve ν and lever s) explained in more detail earlier is provided.

Namely, the roller m always moves the sleeve forward after a full turn of the wheel C corresponding to the expiry of a year by striking one of the prongs of the toothed wheel V ₂ , so that the pawl-like end S _{1 of} the lever s every common year on one of the three higher detents in the leap year but rests on the deepest detent, which, as mentioned earlier, due to the deepest position of the lever end provided with the arcuate sliding surface s. _2,.

When passing the tooth Z ₁ , as usual, the latches b ₁ b ₂ b ₃ are shifted at the same time. But now the one on the bolt hits Z? ₃ attached Rolley, which otherwise moves under the sliding surface (Fig. 5, dotted), with a further rotation of the wheel B onto the sliding surface S ₂ , slides on this and thereby pushes the bolt b _{s back} into its original position (Fig . 5 and 6). So this way, the possibility is created, that is on 28 February due to the pushed-back tooth b _'a Wheel B continues to rotate around a tooth and adjusting the 29I on the date hand, after 24 hours, similar to before, b teeth' ₂ b ' ₁ and the tooth 31 each with a pin of the disc A are brought into three successive engagements in order to turn the wheel B by three teeth on February 29th (12 o'clock at night) and the calendar on March 1st skips etc.

Claims (1)

Patent claim: Perpetual calendar, in which the setting of the month, day and date of the associated disc wheels CAB (from which the latter two receive an impulse from a clockwork after 24 hours each) is thus correctly carried out, a) that in a 30 day month one (bJ of three bars connected to the wheel B b _Y b ₂ b ₃ diametrically to the latter by striking its roller r _x on one of the five teeth corresponding to the months with less than 31 days / Z ₁ Z ₂ Z ₃ Z _{4 of} the disk C touches, whereby the tooth b \ of the bolt Z ^ _{1 is brought} into such a position that both it and the tooth 31 of the wheel B of one of the 28 each by the division of the wheel B pins spaced from one another and arranged in four separate steps of the day disc A. are actuated on the last of the 30-day month for the purpose of turning the 31-tooth date wheel two teeth further; b) that in a 28-day month all three bars move ^ ₁ Zp ₂ b ₃ and by successive engagement of the pins of the disc A in the teeth b ' _g b' ₂ b \ and the tooth 31 of the wheel B the latter on Last of the 28 day month at four ^ Keep turning teeth; c) that in the month of February of a leap year the pawl-like end S _{1 of} the lever s falls into the larger thumb of a four-thumb disk V _1, which is rotated one thumb further by the month wheel C after each revolution of the same, and the lever end, which is provided with an arcuate sliding surface S ₂ , assumes its lowest position , for the purpose of the simultaneous with the latches Z ^ ₁ b. ₂ bolt b _a or respectively advanced in the month of February to return the tooth b ' ₃ to its original position and thereby enable the date disc B to be set to the 29th respectively. at the end of this day to allow wheel B to continue turning three teeth; ■ d) that in a 31-day month the functions of the mechanisms described under a), b) and c) do not occur, but that the wheel B rotates regularly by one tooth for the whole month after every 24 hours. For this purpose 2 sheets of drawings.