RU133625U1 - CLOCK INDICATING TIME ANIMATING SANDWATCH - Google Patents

Abstract

1. A clock comprising a clock mechanism, a time setting element and time indicating means, characterized in that the time indicating means is configured to indicate time by animated images of moving sand in the hourglass in the form of hourglass animation means coupled to the time setting element of the clock by an hourglass animation means drive hours. 2. Clocks according to claim 1, characterized in that the hourglass animation means is made in the form of a figured cut-out in the dial in the form of an hourglass, containing a jumper connected to the upper part and the lower part, and located below the animation mechanism of sand movement in the hourglass with the possibility of animating flow movements sand from the top to the bottom of the hourglass. 3. The watch according to claim 1, characterized in that the hourglass animation means is configured to animate the automatic hourglass flipping at the end of the cycle of their operation at the time of complete flow of sand from the upper part to the lower part of the hourglass. A watch according to claim 1, characterized in that the hourglass animation means is adapted to animate the movement of sand in the hourglass in the form of an animation of the movements of sand flowing from the upper part to the lower part of the animated hourglass. Clocks according to claim 1, characterized in that the hourglass animation means is configured to animate the movement of sand in the hourglass in the form of an animation of the movements of sand flowing from the upper part to the lower part of the animated hourglass by means of movable curtains or movable frames. Clock according to claim 1, characterized in that the hourglass animation means is made

Description

Technical field

The utility model relates to the field of watch technology, to wrist watches and desktop mechanical watches, and can be used in the manufacture of original watches with time displays with animated images of moving sand in an hourglass (hourglass animation) on the dial.

State of the art

The date of the first hourglass is not known for certain. According to the surviving data, it can be assumed that the hourglass principle was known in Asia much earlier than the beginning of our reckoning. Mention of a bottle type, in all likelihood an hourglass, has existed since Archimedes. Antique Rome had no mention of an hourglass. The Romans knew how to make glass, but there was a lot of pollution in their glass and it was opaque [1].

Western European countries began to deal with hourglass only at the end of the Middle Ages. One of the oldest references to such a watch is a message from 1339, discovered in Paris, containing instructions on the preparation of fine sand from sifted powder of black marble, boiled in wine and dried in the sun.

Despite the fact that the hourglass appeared in Europe late, it quickly spread. This was facilitated by their simplicity, reliability, low price and, not least, the ability to measure time with their help at any moment of the day or night.

The disadvantage that prevented the widespread use of this watch was the relatively short time interval that could be measured without turning the watch over.

Usually the hourglass was calculated to work for half an hour or an hour. Hourglass, designed for continuous measurement of time for 3 hours, was less common, and only in very rare cases built a huge hourglass, designed for 12 hours.

Did not give a decisive improvement and the combination of several hourglasses into one. For example, a set of four hourglasses in a single case was arranged so that the contents of the first flask spilled out in a quarter of an hour, the second in half an hour, etc.

The production of transparent glass hourglass flasks was made possible thanks to the creation of the production technology of transparent glass and its formation into hollow spherical flasks. After narrowing the neck at the junction of both flasks, after filling with sand, a small horizontal metal diaphragm with a hole was usually inserted, regulating the amount and speed of pouring grains of sand. The junction was tied with a dense thread and fixed with resin. The accuracy of the hourglass depended on the manufacturing technology of the sand itself. The flasks were filled with annealed fine-grained sand, sifted repeatedly through thin sieves and thoroughly dried. The sand thus treated had a reddish color; light whitish sands came from fried thinly ground egg shells; grayish sand was made from zinc and lead dust.

The accuracy of the hourglass also depended on the shape of the flasks, on the smoothness of their inner walls, on the uniformity of the passage of sand through the regulating diaphragm in the neck, but above all, on the uniform granularity and flowability of this sand.

In this regard, the best results were obtained from flasks filled with lead sand, the granularity of which was more uniform. Lead sand was also distinguished by the fact that with long use it is less than other types of sand, violating the smoothness of the inner walls of the glass bulb.

Like a fire watch, an hourglass never reached the precision of a sundial. In addition, with prolonged use of such a watch, their accuracy changed, since the grains of sand gradually crushed into thinner ones, and the hole in the middle of the diaphragm gradually wore off and increased, so that the speed of sand passing through them became greater.

To compete with mechanical watches and when measuring long time intervals or even with continuous measurement of time, in the XVII and XVIII century. mainly in Nuremberg and Augsburg began to produce hourglasses with four flask systems in one case.

Some manufacturers in the first half of the 17th century. used ingenious devices to turn the hourglass.

The mathematician De la Hire made an hourglass to measure second intervals, while the astronomer Tycho Brahe tried to replace sand with mercury.

Automatic tipping of the hourglass was a problem that attracted the attention of many mathematicians and physicists.

Stefan Farfler from Altdorf used a spring mechanism for his hourglass, which he built in the second half of the 17th century.

Another solution to this problem, taking into account the change in the position of the center of gravity when pouring sand, is shown in Lani's drawing in the book “Inventionenuove”, published in 1670. French Grollier de Servier from Lyon, the author of many other remarkable instruments, who lived about 100 years later, created hourglass automatic tipping device.

Many peculiar solutions of this kind appeared in Germany.

The desire to find new, more advanced types of watches that can compete with mechanical watches is described in the literature on the theory and practical manufacture of chronometric devices.

Along with the already mentioned books by Archangel Maria Radi and Schott's famous work “Technicacuriosa”, a similar book was written by Italian Domenico Martinelli, which he called “Horologielementari”. In this book, he describes not only water and fire watches, but also pneumatic watches, driven by a small fur - element.

Despite the fact that the mechanisms for automatic tipping of the hourglass did not give the expected result, still the hourglass, due to its shape and ease of operation, retained a certain value until recently, for example, they used telephone exchanges to record the time of short telephone calls in the courtrooms meetings, and for some needs in the household, for example, when controlling time in photography, when conducting physiotherapeutic procedures for taking baths or sunbathing, and also as a suv sirs.

The ships used a four-hour hourglass (one shift) and 30 seconds to determine the speed of the ship by the lag.

In the operating system of the Microsoft Windows family of computer programs, the animated hourglass symbol used by the mouse pointer is used on the computer screen to indicate system busyness.

The hourglass is structurally the simplest device for indicating time intervals, consisting of two vessels connected by a narrow neck, one of which is partially filled with annealed, sifted through a fine sieve and carefully dried fine-grained sand, which is poured into a lower vessel [2].

The disadvantage of an hourglass is a short time interval from a few seconds to several hours, which can be measured by an hourglass.

Watches that became widespread in Europe were usually designed to work for half an hour or an hour. There were hours working for 3 hours, very rarely - 12 hours. To increase the measurement interval, hourglass sets were compiled in one case (case).

With prolonged use, the accuracy of the hourglass usually deteriorates due to sand damage to the inner surface of the flask, an increase in the diameter of the hole in the diaphragm between the flasks and crushing of the sand grains into smaller ones.

The accuracy of the hourglass depends on the quality of the sand, its uniform granularity and flowability, and on the shape of the flasks, on the smoothness of their inner walls.

The development of glass production allowed the production of flasks with smooth inner walls, this made it possible to sand flow evenly from the upper to the lower.

The preparation of sand for watches was considered in ancient times a matter requiring special skill. It was made from fired fine-grained sand or from fried frayed egg shells, or from zinc and lead dust.

In Paris, a 1339-year-old description of an hourglass with black marble powder was discovered, which indicated that the best sand is obtained from marble sawdust if boiled nine times with wine, removing foam each time, and then dried in the sun [3] .

The hourglass never achieved the accuracy of a sundial, as the grains of sand were gradually crushed into thinner ones, and the hole in the middle of the glass flasks was gradually rubbed and enlarged.

The hourglass was of great importance on the ships: in cloudy weather, when it was impossible to determine the time from the heavenly bodies covered with clouds, then it was recognized by the hourglass. On Russian courts they were called "flasks." Every half hour, when the “flask” was turned over, it was struck by a bell. From here, in fact, came the expression - "beat the bottle." Youngs measured out half-hour periods of time and beat the bell.

Previously, people wore an hourglass even on their feet, fastening them to their feet below the knee.

For hundreds of years, the hourglass has repeatedly tried to improve. So, the astronomer Tycho Brahe replaced sand with mercury. Stefan Farfler and Grollier de Servier made spring mechanisms for turning the clock. But all these innovations have not taken root, and the simplest hourglass is used to this day.

A known dial with a decorative design, containing a metal plate, a film polymer carrier of a decorative image and an adhesive layer of a hydrophobic material connecting the polymer carrier with a metal plate, the decorative image includes a dot pattern on the front surface of the polymer carrier, characterized in that the film polymer carrier is equipped with a microrelief reflective decorative layer forming a rainbow hologram, and a shading mask, partially covering the front surface of the polymeric carrier. In this case, the shading mask is made opaque or translucent, at least part of the pattern is applied on top of the shading mask, the polymer carrier is made of a transparent dacron film, and the microrelief reflective decorative layer forming a rainbow hologram is a prismatic holographic grating on the back surface of the dacron film applied to it has a reflective coating, and the dial is equipped with a transparent protective layer covering the front surface of the polymer carrier, and applied shading mask and figure [4], which are placed on the front surface.

Decorative clocks with a horizontal dial are known, containing a base and a clockwork with a minute exit and an arrow, which contain a figure-shaped part mounted vertically on the base behind the dial, the part is equipped with a movable element made in the form of a hand of a figure with a cane, the end of the cane connected to end of arrow. In this case, the movable element in the form of a hand with a cane contains a hinge at the location of the hand and a flexible connection at the junction of the end of the cane with the end of the arrow [5].

A device for indicating the time, in particular with the help of moving figures, made in the form of a decorative clock containing a clock mechanism installed in the base, is connected to a program unit. The outputs of the block are connected through control elements to parts made in the form of face elements. Details are located in parallel planes and can change the relative position during the day, which creates a visual image of age-related changes in the face [6].

A developed display mechanism for a watch device is known, which allows to display or not the current time, designed to control the movements of the display device of a watch device, for example, for at least one indication relative to the time or operation of the watch. The display mechanism according to the invention comprises a cam with a periphery of a predetermined shape and driven from the main wheel, a lever designed to be rotatably mounted relative to an element of the watch mechanism between the stop position associated with the display position of the display organ and the standby position associated with the alternative position display body. The lever has a tip designed to interact with the periphery of the said cam to determine said stop position, while the lever also has a comb designed to engage with the gear driving the display member. The mechanism comprises a movable control having at least one standby position and one display position, both of which are stable. The control is designed to alternate from one position to another in response to the corresponding sequential actions of the user and counteracting the action of elastic means acting on said lever to position it in said stop position, the cam being mounted with the possibility of constant drive irrespective of the position of said movable body control and the said lever, which together with the remaining features provides a technical result, ayuschiysya that utility model enables the replacement of one embodiment stable display mechanism on the other [7].

In mechanical watches, animation is historically represented by jacquemars (animated moving figures of people, for example, a man beating a bell), animated animals (for example, a screaming rooster, a cuckoo) and so on. landscape animation (for example, the sun moving across the sky, flowing water, moving leaves on trees).

Animation (from the Latin "anima" - soul) is a technology that allows using the inanimate motionless objects to create the illusion of movement [8].

Animation in a mechanical watch was initially closely connected with the repeater function - moving, figures in the watch enlivened the process of repetition of time.

The jacquemars were still present at the early tower clocks, later - in all kinds of interior clocks, and with the advent and development of pocket and then wristwatches, the jacquemars also decorated them.

Religious subjects, as well as a variety of frivolous scenes, became very popular motifs for animated watches of the Middle Ages.

There are no methods and devices for animating the moving sand of an hourglass (hourglass animation) on the dials of watches, timers, chronographs and stop watches, in the scope of the search.

Known by authors Butte Matias (FR), BarbaziniEnrico (FR), Nava Michel (FR) and DALTON PROPERTIES Incu. (BZ) an indication mechanism that can be installed on a basic clockwork with manual winding, with automatic winding, with a quartz or automatic quartz winding with the ability to recreate a given pattern of moving figures over a selected period of time. The mechanism incorporates a certain set of gears that are in gear engagement with each other or groups of gears and are driven by a moving element connected to the base clock mechanism. Moreover, on top of each of the gears there is a plate or disk bearing numbers, figures or signs and rotating in the corresponding hole in the dial of this watch product [9].

The watch mechanism created by Simonyan Sasnik (LB) is known, equipped with slow animation, which seeks to bring a sense of serenity and calm to the user, even when he sets the time, and to give the watch its original look, which contains the case and the working gear supported by this case, periodically driven in rotation by a drive element, and an animation part designed to be visible and adapted for animation by an oscillatory movement, allowing the simulation of a pendulum movement. The mechanism also contains an animated gear supported by the housing meshed with the movable part of the working gear and kinematically connected to the animation part [10].

This mechanism, animating the artificially created slow movement of the pendulum on the dial, which is not functional for the clockwork, can be attributed to permanent animation devices. A characteristic feature of this mechanism is that the animated gear, the control element and the animation part are located in such a way that the periodic movement is a sinusoidal oscillatory type, while the flexible element is placed between the moving part and the said part in such a way as to smooth the movement of the animation part.

There are no methods and devices for visualizing time intervals in a mechanical watch by indicating time with animated images of moving sand of an hourglass (hourglass indication) on the dials of watches, timers, chronographs and stop watches, in the scope of the search performed.

The closest in technical essence and the achieved technical result (prototype) is a time indication device containing front and rear disk-shaped indicator surfaces located on a common axis, each of which has optical characteristics varying in a circular direction, while the rear surface is opaque and the front surface at least partially made transparent, and at least one of the surfaces is mounted with the possibility of continuous rotation in round a common axis, wherein the front display surface is completely transparent, the color tone of each of the test surface is changed in the circumferential direction of saturated to unsaturated to form a visually distinguishable color tone transition boundary situated radially relative to the axis of rotation of said surfaces. In this case, the time indication device is made in the form of an electronic device containing a display and a microprocessor, while the front and rear indicator surfaces located on the common axis are made in the form of images of the indicated surfaces formed by the microprocessor on the display, at least one of which is provided virtual continuous rotation around a common axis [11].

The technical disadvantages of this device are the inability to accurately display the time, as well as the lack of additional decorative and entertaining functional capabilities of a mechanical clock in the form of an animated hourglass

Task and technical result

The objective and technical result of the utility model is to provide the ability to display time on the clock face through animated images of sand movement in the hourglass (hourglass animation) in the form of animated looped sand flows from the upper part to the lower part of the hourglass, and the additional movement of the hourglass flip in the end of each animated hourglass cycle.

Utility Model Essence

The author of the utility model proposes a new, previously unknown method and device for displaying time intervals with animated images of moving sand in an hourglass (hourglass display) on the dial of mechanical time indication devices with clock mechanisms or mechanical watches.

The salient features of the utility model are:

- the availability and means of accurate indication of time by an hourglass animation on a watch dial in the form of animated images of moving sand of an hourglass (time indication by an hourglass animation), which can be made as a cutout in a dial in the form of an hourglass with an animated image tool moving below it sand in the hourglass (hourglass animation means) coupled to the drive of the hourglass animation means with the hourglass animation means, which in turn ryazheno of timing element with a clockwork, conjugated with the hour, minute and second sleeve axis or normal clockwork.

A distinctive feature of the method for creating animated images of moving sand in an hourglass (hourglass display) on a mechanical watch’s dial is the availability of hourglass animation means and the hourglass animation means coupled with the clock mechanism.

The term "hourglass" in the framework of this application refers to stylized images of ordinary hourglasses in the form located vertically to each other and touching the tops of two flasks, triangles, trapezoid, etc., on which the flow of "sand" in the upper part is animated in contrasting colors to the bottom with a corresponding change in its levels in the upper and lower parts.

Distinctive features of watches with animated images on the hourglass dial with a constant change in the contrasting levels of sand in the upper and lower parts of the hourglass flasks (hourglass displays) corresponding to the flow of certain time intervals, as well as the presence of a mechanical drive for hourglass animation and hourglass animation.

The goal and the required technical result are achieved in that in a watch comprising a clock mechanism, a time setting element and a time indication means, characterized in that the time indication means is made in the form of an hourglass animation with animation of sand movement in an hourglass paired with a time setting element driven hourglass animation means.

At the same time, the watch is configured to implement the above method of indicating time or time periods in time or time indication devices.

In this case, the hourglass animation tool is executed:

- in the form of a figured cut-out in the dial in the form of an hourglass, containing a jumper connected to the upper part and the lower part c and located below the mechanism for animating the movement of sand in the hourglass with the possibility of animating the movements of the flow of sand from the upper part to the lower part of the hourglass;

- with the ability to animate an automatic hourglass flip at the end of its cycle of operation at the moment the sand completely flows from the upper part to the lower part of the hourglass;

- with the ability to animate the movement of sand in the hourglass in the form of an animation of the movements of the flow of sand from the top to the bottom of the animated hourglass;

- with the ability to animate the movement of sand in the hourglass in the form of an animation of the movements of the flow of sand from the upper part to the lower part of the animated hourglass, by means of movable curtains or movable frames;

- with the ability to animate the movement of sand in the hourglass in the form of an animation of the movements of sand flowing from the upper part to the lower part of the hourglass by means of movable curtains or movable frames with the possibility of indicating the upper movable curtain or background frame of the upper part of the hourglass, and the lower curtain or level indicator frame sand in the lower hourglass;

- with the possibility of animating the movement of sand in the hourglass in the form of animation of the movements of sand flowing from the upper part to the lower part of the hourglass by means of movable curtains or movable frames with the possibility of indicating the level of sand in the upper part of the hourglass with the background of the upper part of the hourglass and indicating the level of sand in the lower parts of the hourglass with the lower movable curtain or the frame of the lower part of the hourglass;

- with the possibility of animating the movement of sand in the hourglass in the form of animation of the movements of sand flowing from the upper part to the lower part of the hourglass by means of movable curtains or movable frames with the possibility of indicating the level of sand in the upper part of the hourglass with color, texture of the material or the contrast of a stationary background at the top hourglass identical to the color, texture of the material or contrast of the movable curtains or frames of leaked sand and another color, texture of the material or the contrast of movable curtains or frames flowing sand identical background color leaked sand bottom of the hourglass;

- with the possibility of animating the movement of sand in the hourglass in the form of animation of the movements of the flow of sand from the upper part to the lower part of the hourglass by means of movable curtains or movable frames;

- with the possibility of cyclic indication of hours, minutes or seconds;

- with the possibility of non-cyclical indication of hours, minutes or seconds, for example, when indicating time periods in alarms, stopwatch, timers or chronographs;

In addition, an hourglass animation tool:

- made in the form of at least two hourglasses;

- made in the form of a hole in the dial in the form of an hourglass and a mechanism for animating the movement of sand in the hourglass located under the dial;

- equipped with a scale indicating the time on the dial, relative to the animated sand level in the hourglass;

- equipped with movable and fixed elements with the ability to animate their sand level in the upper and lower parts of the hourglass.

In addition, in the hourglass animation means, the sand level in the upper and lower parts of the hourglass is formed by moving and stationary elements with the possibility of color or contrast animation of the flowing sand against a background that differs in color, texture or contrast.

The drive of the hourglass animation means is performed in the form of a mechanism for converting the rotational movement of the time-setting element of the clock mechanism into the movement of the elements of the hourglass indication means, for example, in the form of a reciprocating mechanism, a cam mechanism or a mechanism with a snail and a lever.

Brief Description of the Drawings

The essence of the utility model is illustrated by drawings.

In the preferred embodiments shown in the drawings, a clock with a minute and hour axis and a sleeve and a time indication with an hourglass animation comprises: case 1, dial 2, crown 3, hour hand 4, minute hand 5, cutout on dial 6, sand 7 hours, hourglass frame 8, hourglass axis 9, sprocket lock 10, background simulating the upper level of sand 11, background simulating the absence of sand 12, the upper movable curtain of lack of sand 13, the lower movable curtain of sand level 14, the guide rail hand 15, the axis of the drive wheel 16, the drive wheel 17, the upper curtain 18 wheel, the lower curtain wheel 19, the upper curtain 20 snail, the lower curtain snail 21, the upper curtain lever 22, the lower curtain lever 23, the upper curtain lever 24 spring, the lever spring the lower curtain 25, the finger lever of the upper curtain 26, the finger lever of the lower curtain 27, the lever lever of the upper curtain 28, the lever lever of the lower curtain 29, the pin of the upper curtain 30, the pin of the lower curtain 31, the lever of the lower curtain and turn 32, the wheel of the frame axis 33, sprocket wheel 34, sprocket 35, lever tooth 36, tooth spring 37, will limit flax pin 38.

Figure 1 shows the structural-functional diagram of the device, which shows the conjugated clockwork, a timing element, an hourglass indicator means and an hourglass indicator means.

Figure 2 shows the appearance of a watch with an hourglass in the upper part of the dial, which shows: case 1, dial 2, crown 3, hour hand 4, minute hand 5, cutout on dial 6, hourglass image 7.

Figure 3 shows the appearance of a watch with a visual display of an hourglass in the central part of the dial, which shows: case 1, dial 2, crown 3, hour hand 4, minute hand 5, cutout on dial 6, hourglass image 7.

Figure 4 shows the appearance of a table clock with a visual display of an hourglass in the upper part of the dial, which shows: case 1, dial 2, crown 3, hour hand 4, minute hand 5, cutout on dial 6, hourglass image 7 .

Figure 5 shows the appearance of a watch with a visual display of an hourglass in the upper part of the dial with the display of minutes using an hourglass, which shows: case 1, dial 2, crown 3, hour hand 4, minute hand 5, cutout dial 6, hourglass image 7, hourglass scale 39.

Figure 6 shows the appearance of a watch with a visual display of an hourglass in the upper and lower parts of the dial, displaying the minutes and seconds using an hourglass, which shows: case 1, dial 2, crown 3, hour hand 4, minute hand 5, the cutout on the dial 6, the image of the hourglass 7, scale 39

7 shows the appearance of a watch with a visual display of an hourglass in the upper and lower parts of the dial, displaying the hours and minutes using an hourglass, which shows: case 1, dial 2, crown 3, hour hand 4, minute arrow 5, cutout on dial 6, hourglass image 7, scale 39.

On Fig shows the appearance of a watch with a visual display of an hourglass in the upper part of the dial, performing the function of a timer for 30 minutes, with a start button, which shows: case 1, dial 2, crown 3, hour hand 4, minute hand 5, the cutout on the dial 6, the image of the hourglass 7, button 40.

Figure 9 shows a part of the dial in the design with a rotary frame, which shows: case 1, dial 2, hour hand 4, minute hand 5, hourglass image 7, hourglass frame 8, frame axis 9.

Figure 10 shows a variant of the curtain control mechanism, which shows: an image of an hourglass 7, a background simulating a top level of sand 11, a background simulating a lack of sand 12, an upper movable curtain of lack of sand 13, a lower movable curtain of sand level 14, a guide curtain 15.

Figure 11 shows an embodiment of a curtain control mechanism with drive parts, which shows: an image of an hourglass 7, a background simulating a top level of sand 11, a background simulating a lack of sand 12, an upper movable curtain of lack of sand 13, a lower movable curtain of sand level 14 , guide curtain 15, drive wheel axis 16, drive wheel 17, upper curtain wheel 18, lower curtain wheel 19, snail of the upper curtain 20, snail of the lower curtain 21, lever of the upper curtain 22, lever of the lower curtain 23, spring of the upper lever Torks 24, the spring arm lower shutter 25, the upper shutter lever finger 26, the finger 27, the lower shutter lever, fork lever 28, the upper shutter, a lower shutter fork lever 29, the pin 30, the upper shutter, a lower shutter pin 31.

On Fig shows the visual sequence of images on the dial without rotating the frame.

On Fig shows the visual sequence of images on the dial with the rotation of the frame.

On Fig shows the sequence of movements of the curtain.

On Fig shows an embodiment of the rotation mechanism of the frame of the animated hourglass, which contains: hourglass frame 8, hourglass axis 9, sprocket lock 10, snail of the lower curtain 21, lever of the lower curtain and rotation 32, wheel of the frame axis 33, wheel sprockets 34, sprocket 35, lever tooth 36, tooth spring 37, restriction pin 38.

On Fig-18 shows the phases of the movement of the rotation mechanism of the hourglass frame 8.

On Fig-21 shows options for the execution of the appearance of the animated hourglass.

Implementation and industrial implementation of utility model

Practically any quartz or mechanical clock mechanism with the possibility of displaying time indication axes, for example, any commercially available basic clock mechanism with hour and minute or with hour, minute and second axes or bushes, can be used as a clock mechanism in the implementation of the patented utility model.

According to a utility model, a conventional clockwork mechanism is complemented by a time-setting element, which is an additional mechanism or clockwork parts that are used to set the time / cycle period of an animated hourglass by engaging the second, minute or hour axes or bushes of a standard, base clockwork.

To obtain cycles that do not coincide with the time periods established by the standard mechanism (in the standard clock mechanism, the usual turn-around period of the hands is 12 hours, 1 hour, 60 seconds), additional kinematic elements, wheel pairs coupled to the clock mechanism, which transform standard cycles, can be used turn arrows in the necessary technical cycles.

So, for example, if you want to get a functioning hourglass for an animated hourglass with a period of 30 minutes, it is possible to use the rotation period of the minute axis (1 hour = 60 minutes), and by installing additional wheels, for example, put a wheel with 60 teeth on the minute axis and install a wheel with 30 teeth with it, then the axis of the wheel with 30 teeth will make one revolution in a cycle of 30 minutes, as required by the conditions of this example.

Similarly, other animated hourglass cycles may be provided.

Also, as a time-setting element, additional devices can be used - a timer, a chronograph, which can be triggered on demand by using the appropriate on / off means.

The drive of the hourglass animation means is structurally a mechanism that converts the rotational movement of the time-setting element into the movement of the elements of the hourglass display means.

The hourglass animation means is a time indicator made in the form of a hole in the form of an hourglass on the dial, under which there are movable curtains and a background beneath them, showing the movement of the pouring and sprinkled sand of the animated hourglass.

The hourglass animation tool can be supplemented with a rotary element simulating the rotation of the animated hourglass 180 degrees after each cycle of operation.

Visually, the display (time indication) of the animated hourglass is displayed by making a hole in the dial repeating the selected hourglass shape consisting of the upper and lower parts in the form of stylized “flasks”.

Under the dial is a mechanism for animating the movement of sand in the hourglass.

The animation mechanism for the movement of sand in the hourglass can be performed in various versions with rotation of the bulb-frame and without rotation of the bulb-frame.

On Fig and Fig shows a visual movement in dynamics in the hole on the dial.

The mechanism of the patented device (Fig. 10) contains an image of an hourglass 7, an asterisk lock 10, a background simulating a top level of sand 11, a background simulating a lack of sand 12, an upper movable curtain of lack of sand 13, a lower movable curtain of sand level 14, a guide curtain 15.

The background simulating the upper level of sand 11 and the background simulating the absence of sand 12 remain stationary. The upper movable curtain of the absence of sand 13 and the lower movable curtain of the sand level 14 move during the working cycle towards each other.

The cycle of this movement is shown in FIG.

The curtains 13 and 14 are located in the guides 15, which allow the curtains to make only translational movements. The upper curtain 13 has a background color of 12, and the curtain 14 has a background color of 11. The upper curtain 13 can be made with the lower flat part simulating the upper sand plane. The lower curtain 14 can be made triangular in shape simulating the lower level of sand in the flask.

Figure 11 shows a design variant of the device with a drive from the axis 16.

When the axis 16 rotates, the wheel 17 mounted on the axis 16 rotates. With the wheel 17, the wheel 18 engages, and with it the wheel 19.

The number of teeth of the wheel 18 and 19 is equal. Wheels 18 and 19 rotate at the same speed and in the opposite direction to each other.

Two snails 20 and 21 are planted on the axis of the wheels 18 and 19, the profiles of which constantly touch the fingers 26 and 27, which are on the levers 22 and 23.

The levers 22 and 23 are spring-loaded with springs 24 and 25. The levers 22 and 23 have forks 28 and 29 at their ends, in the grooves of which cover pins 30 and 31 located on the blinds 13 and 14.

The curtains 13 and 14 are located in the guides 15, which allow the curtains to make only translational movements.

When the wheels 17 rotate, the wheels 18 and 19 make multidirectional rotations at the same speed. The snails 20 and 21 located on them raise the levers 22 and 23, and they slide the shutters 13 and 14 towards each other, moving the pins 30 and 31 with the grooves in the forks 28 and 29. The shutters move to the extreme opposite positions. When the fingers 26 and 27 break away from the tops of the snails 20 and 21, the levers 22 and 23 fall into the lower position of the snail profile, and with it the shutters 13 and 14, move in the opposite direction relative to each other. And the cycle begins anew. The cycle time can be selected by any one, for example, 5, 10, 30, 60 minutes.

When executed with a rotary frame 8 (Fig.10-18), simulating the flip of the hourglass flasks at the end of the hourglass cycle, one of the levers can be replaced by a lever 32, which additionally has a tooth 36, spring 37, restrictive pin 38. And also there is an asterisk 35, fixing its latch 10, and a wheel 34 mounted on the axis of the asterisk, and a wheel 33 working with it, on the axis of which there is an axis 9 and frame 8.

When turning the cochlea 21, the lever 32 is lifted. When the finger breaks off the cochlea 21, the tooth 36 rotates the sprocket 35 by one tooth, and with it the wheel 34, wheel 33, and with it the frame 8 by 180 degrees.

The number of teeth of the sprocket 35, the gear ratio between the wheels 34 and 33 is selected so that when the sprocket rotates by one tooth, the frame 8, mounted on the axis 9 of the wheel 33, is rotated 180 degrees, for example.

The sprocket has 6 teeth, a wheel of 34-60 teeth, and a wheel of 33-20 teeth. Turning one tooth, the sprocket rotates the wheel 36, 360/6 = 60 degrees. Since the gear ratio between wheels 34 and 33 is 60/20 = 3, the angle of rotation of the frame is 60 × 3 = 180.

Thus, the causal relationship of the essential features of the utility model and the technical result is shown and the required technical result is achieved, namely, the possibility of creating an animated movement and mechanically displaying the visual movement of sand in the hourglass (indication of the hourglass) as an animated looping overflow sand from the upper part to the lower part of the hourglass, and the additional movement of the flip of the frame depicting the flask esochnyh hours per cycle

As options for the execution of individual elements of the case, parts, assemblies claimed as a useful model of the device and watch, various known, traditional for watch production technologies, materials and structural solutions commonly used in watch technology can be used [12].

Thus, given the novelty of the set of essential features, the technical solution of the problem, the inventive step and the significance of all the general and particular features of the utility model, proven in the section "prior art" and "the essence of the utility model", proven in the section "Implementation and industrial implementation of the utility model ", The technical feasibility and industrial applicability of the utility model, the confident solution of the inventive tasks and the confident achievement of the required technical result and in the implementation and use of the utility model, in our opinion, the claimed group of inventions satisfies all the eligibility requirements for the utility model m.

The analysis also shows that all the general and particular features of the utility model are essential, since each of them is necessary, and all together they are not only sufficient to achieve the goal of the utility model, but also allow you to implement the utility model in an industrial way.

INFORMATION SOURCES

1.http: //n-t.ru/ri/mh/ch134.htm

2.Http: //ru.wikipedia.org/wiki/%CF%Е5%F1%ЕЕ%F7%ED%FB%Е5_%F7%Е0%F1%FB

3.http: //class-fizika.narod.ru/tshpesok.htm

4. RU 29591 G04B 19/06, G04B 47/04 Publ. 05/20/2003

5. RU 2072739 G04B 25/06 Publ. 01/27/1997

6. RU 2082215 G04B 25/06 Publ. 06/20/1997

7. RU 2470338 G04B 19/02 Publ. 12/20/2012

8.http: //dic.academic.ru/dic.nsf/enc_colier/3304/ANIMATION

9. RU 2356078 G04B 45/00, G04B 47/04, G04B 19/10, publ. 05/20/2009 PCT application EP 2004/009691 2004083 PCT publication WO 2006/024311 20060309

10. RU 2342689 G04B 45/02 publ. 12/27/2008, conventional priority: 08/29/2003 EP 03405624.2

11. RU 115520 G04B 19/00, Publ. 04/27/2012 (prototype)

12. Pipunyrov V.N. “HISTORY OF HOURS FROM ANCIENT TIMES TO THE PRESENT DAY”, 1982, Nauka Publishing House, Moscow .; Chaykin K.Yu. “HOURS IN RUSSIA. Masters and Guardians ”, 2012,“ Lubavitch ”St. Petersburg; Kharitonchuk A.P. “Watch repair reference book”, 1977, Light Industry Publishing House, Moscow .; Belyakov I.S. Clockworks 1957, Mashgiz Publishing House; Romanov A.D. Designing time devices. M., 1975; Tarasov S.V. Technology of watch production, M., 1963; Popova V.D., Goldberg N.B. Device and assembly technology of watches. M., 1989

Claims (18)

1. A clock comprising a clock mechanism, a time setting element and time indicating means, characterized in that the time indicating means is configured to indicate time by animated images of moving sand in the hourglass in the form of hourglass animation means coupled to the time setting element of the clock by an hourglass animation means drive hours. 2. The watch according to claim 1, characterized in that the hourglass animation means is made in the form of a figured cut-out in the dial in the form of an hourglass, containing a jumper connected to the upper part and the lower part, and an animation mechanism located below the sand movement in the hourglass with the possibility of animation movements of sand overflowing from the top to the bottom of the hourglass. 3. The watch according to claim 1, characterized in that the hourglass animation means is configured to animate the automatic hourglass flipping at the end of its cycle of operation at the moment the sand completely flows from the upper part to the lower part of the hourglass. 4. The watch according to claim 1, characterized in that the hourglass animation means is configured to animate the movement of sand in the hourglass in the form of an animation of the movements of sand flowing from the upper part to the lower part of the animated hourglass. 5. The watch according to claim 1, characterized in that the hourglass animation means is configured to animate the movement of sand in the hourglass in the form of an animation of the movements of sand flowing from the upper part to the lower part of the animated hourglass by means of movable curtains or movable frames. 6. The watch according to claim 1, characterized in that the hourglass animation means is configured to animate the movement of sand in the hourglass in the form of an animation of the movements of sand flowing from the upper part to the lower part of the hourglass by means of movable curtains or movable frames with the possibility of indicating the upper movable a curtain or background frame for the top of the hourglass, and a lower curtain or frame for indicating the level of sand at the bottom of the hourglass. 7. The watch according to claim 1, characterized in that the hourglass animation means is configured to animate the movement of sand in the hourglass in the form of an animation of the movements of sand flowing from the upper part to the lower part of the hourglass by means of movable curtains or movable frames with the possibility of indicating the level of sand in the upper part of the hourglass with the background of the upper part of the hourglass and indication of the level of sand in the lower part of the hourglass with the lower movable curtain or the frame of the lower part of the hourglass. 8. The watch according to claim 1, characterized in that the hourglass animation means is configured to animate the movement of sand in the hourglass in the form of an animation of the movements of sand flowing from the upper part to the lower part of the hourglass by means of movable curtains or movable frames with the possibility of indicating the level of sand in the upper part of the hourglass, the color, texture of the material or the contrast of the stationary background in the upper part of the hourglass is identical to the color, texture of the material or the contrast of the moving curtains or frames of leaked sand, etc. gim color, material or texture contrast movable shutters or frames flowing sand identical background color leaked sand bottom of the hourglass. 9. The watch according to claim 1, characterized in that the hourglass animation means is made in the form of a hole in the dial in the form of an hourglass and a mechanism for animating sand movement in the hourglass located under the dial. 10. The watch according to claim 1, characterized in that the hourglass animation means is configured to animate the movement of sand in the hourglass in the form of an animation of the movements of sand flowing from the upper part to the lower part of the hourglass by means of movable curtains or movable frames. 11. The watch according to claim 1, characterized in that the hourglass animation means is configured to cyclically display hours, minutes or seconds. 12. The watch according to claim 1, characterized in that the hourglass animation means is capable of non-cyclic indication of the periods of hours, minutes or seconds, for example, when indicating time periods in alarms, stopwatch, timers or chronographs. 13. The watch according to claim 1, characterized in that the hourglass animation means is made in the form of at least two hourglasses. 14. The watch according to claim 1, characterized in that the hourglass animation means is provided with a scale indicating the time on the dial relative to the animated sand level in the hourglass. 15. The watch according to claim 1, characterized in that the hourglass animation means is equipped with movable and fixed elements with the possibility of animating the sand level in the upper and lower parts of the hourglass. 16. The watch according to claim 1, characterized in that in the hourglass animation means the sand level in the upper and lower parts of the hourglass is formed by means of movable and fixed elements with the possibility of color or contrast animation of the flowing sand on a material different in color, texture or contrast background. 17. The watch according to claim 1, characterized in that the drive of the hourglass animation means is made in the form of a mechanism for converting the rotational movement of the time setting element of the clock mechanism to the movement of the elements of the hourglass indication means. 18. Watch according to claim 17, characterized in that the hourglass animation means drive is made in the form of a reciprocating mechanism, a cam mechanism or a mechanism with a snail and a lever.

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