DE29830C - Calendar clock - Google Patents

Description

IMPERIAL

PATENT OFFICE.

The present perpetual calendar automatically functions and maintains its movement from a clock. The mechanism of the calendar is such that its manufacturing cost are relatively low. The mechanism is set in motion to mark the day that To change the date, the month, regardless of whether it has 28, 29, 30 or 31 days, and the year, without ever requiring manual adjustment.

This calendar is shown on the accompanying drawing. Fig. 1 shows an outer one View, it being noted that the dial of the clock can also be omitted. Fig. 2 is a rear view of the calendar with the case removed, Fig. 3 is a plan view, FIG. 4 shows a side view and FIG. 5 shows a development of the five cylinders or rollers, which form the calendar.

The calendar movement gets its movement from the striking mechanism of the clock A, the counting wheel A ^{1 of} which is provided with an attachment A ² , which turns the vertical shaft α at every beat at noon and midnight by Y ₆ tour.

The spring housing M is intended for the pointer mechanism and the spring housing S for the striking mechanism. The latter, which transfers its movement to the calendar mechanism, has retained its ordinary diameter, so that nothing has changed in the arrangement and dimensions of the ordinary organs of movement of the clock.

But in order to get a little more power from this spring housing, the spring itself has a slightly larger width and thus the housing a larger height.

The rear wall ζ is cut out to allow the spring housing S to pass through, the rear shaft journal of which is mounted in a so-called false wall ^{ζ 1} , which is connected to the wall ζ by stud bolts ζ ² , FIGS. The counting wheel A 'is mounted in the wrong wall z ¹ and at noon and midnight acts with its attachment A ² on the pins of the pin wheel a ^{1 of} the vertical shaft a. The approach D of the incidence is extended so far that it engages in the notches of the counting wheel A ¹ .

Otherwise the striking mechanism has not received any changes.

The approach A ² now acts with each revolution of the counting wheel on one of the six pins of the pin wheel a ^{l of} the shaft a. The latter is stored above in an angle plate α ² and below in the plate a ^s , Fig. 3, which is located above the calendar mechanism. Above the plate a ³ , the shaft α carries a second pin wheel with three downwardly bent pins b, which act on the star b ^l , which is called the "day star" and which has seven teeth. Directly below this star, a ratchet wheel b ^{2 is} fastened on its shaft c , in which the pawl b ³ engages by means of the spring b ^5. Pawl b ³ rotates about b ^e in association with arm # ⁴ which forms a V with b ³ and is moved by pins b . It follows from this arrangement, that, since the movement α the shaft at noon and at midnight to '/ ₆ Tour rotates, the pins b every 24 hours only once on the star ^ ¹ act, whatever happens at midnight.

This movement, which takes place every noon and every midnight, is used only to move the other parts of the calendar, which are all loosely mounted on a central and vertical axis e , which is held by plate a ³ above and a plate e ¹ below. The latter may or may not be attached to the base plate e ^{11 of the calendar.}

At the very top of the axis e is the year wheel d, below it the month wheel f, then the data wheel g, the day wheel h and finally the drive wheel k.

As already mentioned, the star ί> ^] has seven teeth and sits on the shaft c, which is held at the top by the plate a ³ and at the bottom by the plate e ' . On this shaft c , the wheel c ^l with 52 teeth is arranged at a corresponding height, which is in engagement with a toothing which is attached to the lower side of the day wheel h and consists of 52 pins h ^l . The day wheel A is provided on its upper side with a second toothing consisting of 84 pins A ² , which transmits the movement to an intermediate shaft i , which is arranged opposite the shaft c . The shaft rotates in the two arms jj ^{1 of} the column χ of the housing. On it sits the gear / with 24 teeth, which engage in the pins A ^2; above it carries a sleeve with two pins m, diametrically opposite to, and approximately in the center a sleeve having six pins n, which likewise lead to ever, two diametrically opposite one another are provided, in an angular distance of approximately '/ ₈ of the circumference. The pins form η THEREFORE two divisions, each with three, which are separated by a distance of _^2/8 of the circumference of each other. They can change their location, raise or lower themselves by sliding their sleeve up or down on i. For this purpose, the sleeve, in which the pins η are inserted, is provided with a pin which protrudes through a slot in the shaft i and rests on the upper end of a rod n ^l , which goes into the hollow shaft i and is below is based on the end v ^{l of} a lever ν which can be rotated about v ^s and is provided with a counterweight » ² . This device allows the movement of the shaft i to be transmitted to the data wheel with the aid of the two pins m and the pins η, as will be described below.

The wheel g is provided on the lower side of its central wall, Fig. 5, representing the spokes with a ring of 31 pins g ¹ , 28 of which have the same height and 3, g ² g ^s g ⁱ , have a gradually increasing height. In the months with 31 days the two arms m act on all pins of the wheel g, in the months with 30 days the pin wheel η is raised so far that its pins come into engagement with the pin g ² , but not with g ³ and g ⁴ ", in the months with 29 days the plane of rotation of the pins η is so high that they come into engagement with the pins g ² and g ³ , and finally in the months with 28 days the pins η are so high that they come into engagement with the pins g 2 and g 3 they g with all three pins ² g ³ and ⁱ g come into engagement. it follows that if the pins η only with the longest pin g of ² come into engagement, it receives only a single blow and the wheel g by two divisions further is rotated, namely from 30 to 1; but if the two pins g ^ and g ^{3 come} into contact with the pins η , then each of the pins g ² and g ³ receives a blow and the wheel g is rotated by three divisions, namely from 2 9 to 1. When finally the three pins g ² g ³ g ⁱ are hit by the pins η, so the wheel g is moved four divisions, from 28 to 1.

The data wheel g now moves the month wheel / in the following way: The wheel g is provided on its upper side with two pins q and q ¹ of different heights and different distances from the center of the wheel g . The smaller pin q is farthest from the center point and comes into engagement with the six pins p of a pin wheel mounted on the shaft / ' with each rotation of g and rotates it one pin further. This shaft / ¹ is mounted in the arms / ^2/3, which are mounted on the intermediate shaft χ.

The shaft p 'is now also provided with a ratchet wheel 0 , in which the pawl o' engages; it is also provided with a toothed wheel r which meshes with the 72 pins f ^{l of} the month wheel /. The gröfsere pin q ^l of the data wheel g is the center of the next g and encountered in the rotation of one of the twelve pins g s a s on the vertical shaft ¹ fastened pin wheel. The shaft s * runs in the plates a ³ and e \ The movement which the pin q ¹ gives to the star s is transmitted to the star s by the gear wheel s ² and the 144 pins k ^{1 of} the wheel k .

The data wheel g is locked by the locking spring g ^x .

Month wheel divides f schliefslich its movement the Jahresrade d, doing so by means of the pin ^l d, which at a sufficient distance from the center of / during the rotation of the latter to the six pins of a pin wheel t engages. The wheel t sits on the shaft t \ which rotates in the arms uu ^ which are attached to * ·. This shaft is provided with a ratchet wheel t ² and a pawl t ³ , and furthermore with the gear wheel w of 36 teeth, which meshes with the 120 pins d ″ of the year wheel d .

It is only superfluous to describe the lower wheel k. This is provided with 144 pins k ¹ , which are in engagement with the gear i ^{2 of} the shaft s ^x. Every third pin k ¹ is of greater length than the others, for the reason to simultaneously form the ratchet wheel for the locking spring k ^s . On the circumference of its upper edge, the wheel k is provided with 20 elevations which, when the wheel k rotates, more or less lift the lower end of the lever ν and thereby place the plane of rotation of the pins η higher or lower.

If we take the point 1 as the starting point, which corresponds to the month of January, then the lead 2 corresponds to the month of February, which has 28 days. The following incision 3 gives the lever ν its position for March by being supported against projection 4 for the month of April. Furthermore, the incision 5 corresponds to the month of May and the projection 6 to June. The next long segment 7 is for July and August, which have 31 days, segment 8 for September, segment 9 for October, segment 10 for November.

■ This is followed by a longer incision 1 for December and January with 31 days each. So the last half of incision 1 begins that second year, which has a February with 28 days, like the previous year; accordingly the projection 2 'is of the same height as the projection 2 of the previous year. In the same way are then also Incisions 3 ', 5', 7 'and 9' and the projections 4 ', 6', 8 'and 10' are arranged.

The cuts 1 ", 3", 5 ", 7", 9 "and the projections 2", 4 ", 6", 8 "and 10" correspond to the third year, also with 365 days. The fourth year, which is a leap year, corresponds to the indentations i '", 3'", 5 '", 7'", 9 '"and the protrusions 2'", 4 '", 6'", 8 '"and 10 '", but the protrusion 2'" is slightly higher than the protrusions 2, 2 'and 2 ", which determine the incline of the lever υ for the month of February. These last three projections are themselves higher than the projections 4, 6, 8, 10, ₄ ', 6', 8 ', 10', 4 ", 6", 8 ", 10" and 4 '", 6'", 8 '", 10'", which correspond to the months with 30 days, i.e. April, June, September and November. All cuts correspond to the 31-day months, and the cuts i, 7, 1 ', 7', 1 ", 7" and i '", 7'" are twice as long as those for the 31-day months and intended for December, January, July and August, at which times it is not necessary to shift the plane of rotation of the pins η.

The movement of this calendar happens in the following way:

The continuous and regular movement of the clockwork is converted into an intermittent movement of the shaft c , which at the same moment causes the intended rotation of the day wheel h through the gear c ^1.

The transmission of the movement of the clockwork to the shaft c takes place, as already described above, by means of the shaft a in such a way that the counting wheel A ^{1 of} the clockwork A prepares the rotation of the shaft e at midday and only executes it at midnight. The rotation of the shaft c, which only happens every 24 hours, precisely at midnight, is transmitted to the day wheel h by the gear wheel c. The partial rotation of h is transmitted through the gearwheel /, the shaft i and the pinwheels m and η with two resp. six pins with the assistance of the disk k and the lever ν on the data wheel g. The pin wheel m engages in the toothing ^ ¹ of g and the pin wheel η rises for the months of 30 days and the first year, which is assumed to be 365 days, through the projections 4, 6, 8 and 10 of the disk k upwards , and for the following years by the protrusions 4 ', 6', 8 ', 10', 4 ", 6", 8 ", 10", 4 '", 6'", 8 '", 10'". The protrusions 2, 2 'and 2 "lift it a little more, for the months with 28 days for the first three years and the protrusion 2'" even higher for the month with 29 days of the fourth (leap) year. Each revolution of the data wheel G causes a partial rotation of month wheel f, with the aid of the parts qp r and y "is ^1, and according to the k by the projections and recesses of the disc caused movement changes a corresponding movement change of month wheel / with the aid of the ^_parts? N ^J and k \

Finally, the month wheel rotates the year wheel d by Y ₂₀ with every revolution by means of the parts d ¹ and d ".,

If the whole mechanism is enclosed in a housing made of wood, metal or other material, the various indications are visible in the cutouts B-C DE , as shown in FIG. With regard to the arrangement of the wheels df gh the mechanism can be modified so that e.g. B. the order of the information can be reversed, so the days at the top, then the dates, the months and at the bottom the years.

Claims (1)

Patent claim: A calendar clock, which is characterized by the combination of the following mechanisms: i. the five wheels dfg h and k, loosely arranged one above the other on the same vertical shaft e , of which the day wheel h is driven directly by the clockwork at midnight and which controls its movement by pin teeth and pin wheels Transmits data, month and year wheel and also to wheel k , which automatically indicates the 28, 29, 30 or 31 days of the various months; the wheel (the disk) k with the alternating indentations and elevations, Fig. 5, and the movable lever ν in connection with the pin n ¹ , the shaft i, the pin wheels η and m and the toothed wheel /, which parts cooperate in such a way that by raising and lowering the pin wheel n by means of ν and k the data wheel g is rotated two, three or four divisions (digits) further, if it is a matter of one month with 31 days to one skip those with 30, 29 or 28 days. 1 sheet of drawings.