RU95865U1 - SUNNY CALENDAR CLOCK (OPTIONS) - Google Patents

Abstract

 1. A solar calendar-clock containing a gnomon, the upper part of which is a sight, and a screen on which a calendar date scale is applied, characterized in that it contains a housing, in the upper part of which a recess is made in the form of a part of a spherical ring in which the gnomon is placed, consisting of a rod with a sight mounted on it in the form of a ball, and the rod is oriented parallel to the axis of rotation of the Earth, and the sight is located in the center of the ring, part of the surface of the ring is a screen on which a grid is made, made in spherical coordinates similar to the geographical coordinates of the Earth, and additionally containing a time scale of the day, and the screen is bounded above by a horizontal plane passing through the center of the sight and two planes parallel to the plane of the celestial equator and at least 23º apart from it , the diameter of the ball of the sight is at least 0.017 of the distance from the sight to the screen, and the center of the sun’s shadow on the screen is an indicator of the date and time of day. ! 2. A solar calendar-clock, containing a screen on which a calendar of dates is applied, characterized in that a translucent screen with a coordinate grid deposited on its outer surface, made in spherical coordinates similar to the geographic coordinates of the Earth, is mounted on a rack with a base, and additionally containing the time scale of the day, and the screen is made in the form of part of a spherical surface, which is part of a thin-walled ring, bounded above by a horizontal plane passing through the center with of spherical surface, the axis to

Description

The proposed utility models relate to technical physics, in particular to instruments for determining the time from the sun, and can be used to determine the calendar date and time of day in the light period.

Known equatorial sundials [RF patent No. 2316035, IPC (2006.01) G04B 49/02, publ. November 25, 2005], containing the gnomon of summer time and the gnomon of winter time, coaxially and rigidly connected with each other and with a circle of hour angles, which is made of a transparent material with a matte surface and has a uniform scale and a displacement diagram of the reference point of local time relative to the center or edge of the shadow , which is made in the form of a graph of the equation of time plotted on the image of shadows cast by the gnomon of summer and winter time, while the plane of the circle of hour angles is set parallel to the plane of the celestial equator Of the earth. The upper end of the summer gnomon is connected by a clamp to a clamp fixed to a pole, the circle of hour angles is fixed by an edge to the base, which is attached to the column below the clamp of the summer gnomon. To determine the time in the spring and autumn equinox, a visor is fixed along the lower edge of the scale, onto which the shadow from the gnomon of winter time falls, and the dial is made in different colors.

The disadvantage of this device is the inability to determine the calendar day.

The known solar calendar [RF patent No. 2127894, IPC6 G04B 49/02, publ. 03/20/1999], selected as a prototype, consisting of two vertical rods installed next to each other on the received line, one of which acts as a gnomon, and the other as a screen, the dial of which shows calendar dates - days, months, seasons, half a year true sunny noon time. The dial of the screen is a nomogram made according to daily marks throughout the year according to the shadow of the upper part of the gnomon and consisting of three main parts - a central longitudinal line with marks of true sunny noon, a grid formed of calendar (horizontal) and minute (additional longitudinal) lines, and an 8-shaped curve of the equation of time with marks of true time at half-day average time or average time at half-day true time, with calendar dates, digital The data of the nomogram, as well as the scale of the declination of the sun, are shown along the lateral edge of the dial.

This solar calendar does not allow you to determine the time of day. With it, you can determine the date only at astronomical noon.

The task of utility models is to simultaneously determine the calendar date and time of day throughout the daylight hours.

The problem is solved due to the fact that the solar calendar-watch, as in the prototype, contains a gnomon, the upper part of which is a sight, and a screen on which the scale of calendar dates is given.

According to a utility model, a recess is made in the upper part of the housing in the form of a part of a spherical ring in which a gnomon is placed, consisting of a rod on which the sight is fixed in the form of a ball. The axis of the rod and ring are oriented parallel to the axis of rotation of the Earth, and the sight is located in the center of the ring. Part of the surface of the recess is a screen on which a coordinate grid is applied, made in spherical coordinates similar to the geographical coordinates of the Earth and additionally containing a time scale of the day. The screen is bounded above by a horizontal plane passing through the center of the sight, and two planes parallel to the plane of the ring and the celestial equator, and separated from the equator by at least 23 degrees. round trip. The diameter of the ball of the sight is at least 0.017 distance from the sight to the screen. The pointer to the date and time of day is the center of the sun’s shadow on the screen.

In the second embodiment of the utility model, the problem is solved due to the fact that the solar calendar-clock, as in the prototype, contains a screen on which the calendar of calendar dates is shown.

In contrast to the prototype, a translucent screen is fixed on a rack with a base, with a coordinate grid deposited on its outer surface made in spherical coordinates similar to the geographic coordinates of the Earth and additionally containing a time scale of the day. The screen is made in the form of a part of a spherical surface, which is a part of a thin-walled ring bounded from above by a horizontal plane passing through the center of the spherical surface. The axis of the ring is coaxial with the axis of rotation of the Earth. The width of the ring is selected taking into account the inclination of the earth's axis to the plane of the ecliptic and is at least 23 degrees on both sides of the equator of the ring. A transparent spherical lens is mounted on a stand and is located in the center of the screen, the diameter of which is from 0.95 to 1.05 of the focal length of the spherical lens. The indicator of the date and time of day is a spot of sunlight focused by a spherical lens on the screen.

In the third embodiment of the utility model, the task is solved in that the solar calendar-watch, as in the prototype, contains a screen on which the scale of calendar dates is given.

According to this embodiment of the utility model, a transparent spherical lens is mounted on a stand with a base, on the surface of which there is a translucent screen with a coordinate grid deposited on it, made in spherical coordinates similar to the geographical coordinates of the Earth and additionally containing a time scale of the day. The screen is made in the form of a part of a ring bounded above by a horizontal plane passing through the center of the lens. The axis of the ring is coaxial with the axis of rotation of the Earth. The width of the ring is selected based on the inclination of the earth's axis to the plane of the ecliptic and is at least 23 degrees on both sides of the equator of the ring. On the base of the pillar, on the side facing the Sun, a slit shutter is installed from vertical strips of opaque material radially located relative to the lens at a distance of at least one diameter of the spherical lens from its center. The width of the gaps of the slit curtain is selected from the condition of visibility of the light lines on the screen. The date and time indicator is the center of the intersection of light lines on the screen.

Due to the use of the proposed screen shape with a coordinate grid in spherical coordinates similar to the geographic coordinates of the Earth, the proposed options for useful models allow us to determine not only the calendar date, but also the time of day.

Figure 1 presents a sketch of the first embodiment of a utility model with a gnomon for the latitude of Tomsk and Moscow (57 ° N). The grid is not shown.

Figure 2 shows a sketch of the first embodiment of a utility model with a gnomon for the latitude of Tomsk and Moscow (57 ° N) without a hull. The grid is not shown.

Figure 3 shows the overall scan of the spherical coordinate grid of the screen for all variants of the solar calendar-clock with explanations for constructing a specific coordinate grid for a given latitude.

Figure 4 presents two images of the second variant of the solar calendar-clock with a spherical lens and a translucent screen for the latitude of Tomsk and Moscow (57 ° N).

Figure 5 presents a sketch of an example implementation of the solar second variant of the calendar-clock for the equatorial region of the Earth.

Figure 6 presents a sketch of an example implementation of the second variant of the solar calendar-clock for the poles of the Earth.

Figure 7 presents a sketch of the third variant of the solar calendar-clock for the latitude of Tomsk and Moscow (57 ° N).

The solar calendar-clock according to the first embodiment (Figs. 1, 2) contains a housing, in the upper part of which a recess is made in the form of a part of a spherical ring in which a gnomon is placed, consisting of a rod 1 on which the sight 2 is fixed in the form of a ball. The axis of the rod and ring coincide and are oriented parallel to the axis of rotation of the Earth. Sight 2 is located in the center of the ring (recess). Part of the spherical surface of the recess (ring) is a screen 3, on which the coordinate grid is applied. The screen 3 is bounded above by a horizontal plane passing through the center of the sight 2, and two planes parallel to the plane of the ring and the celestial equator, and at least 23 degrees from the equator. round trip. The coordinate grid (figure 3) is made in spherical coordinates, similar to the geographic coordinates of the Earth. The diameter of the ball of the sight 2 is at least 0.017 of the distance from the sight 2 to the screen 3. The calendar-hour indicator is the center of the sun shadow of the sight 2 on the screen 3.

The coordinate grid (figure 3) consists of a time scale of the day and a calendar date scale. The scales are perpendicular to each other and form a spherical coordinate system similar to the Earth's geographical coordinate system.

The time scale of the day is applied to the coordinate grid by lines formed by the intersection of the planes passing through the axis of the gnomon (screen ring) with screen 3 (meridians of the coordinate grid), and the full circle is divided into 24 equivalent segments corresponding to the hours of the day (a series of pointers and numbers under the coordinate grid in figure 3). When you install the inventive utility model in the southern hemisphere, the hour scale is mirrored. The scan shows the time scale of the day, which when applied to screen 3 shows astronomical time. The time scale is linked to the administrative time of the given area, for example, when the pointer of the solar calendar-hours is located in the direction of geographical north (astronomical noon) or using other known methods of establishing the correspondence of the Sun's azimuth to the given area with the administrative time.

The calendar days scale is plotted on the screen by 3 lines (arcs) parallel to the equator of screen 3 (parallel to the coordinate grid). The line of the equinox dates (March 21 and September 20) coincides with the equator of screen 3. The date lines of the winter (December 17-23) and summer (June 17-23) solstices limit the coordinate grid from above and below and coincide with the lines of the tropics in the Earth system coordinates (the boundary coordinates of the latitudes of the coordinate grid are equal in absolute value to the angle of inclination of the earth's axis to the ecliptic plane). Parallels corresponding, for example, to either the 20th day of the corresponding months, or specific dates, depending on the resolution of the grid, can also be plotted on the grid. On the sides, the grid is limited by lines formed by the intersection of the screen 3 with a horizontal plane drawn through its center. Examples of such lines are shown in Fig.6 for models installed at equator A, latitude of Tomsk and Moscow (57 ° N) B and in the region of the Arctic Circle C.

The solar calendar-clock according to the second embodiment (Fig. 4) consists of a stand 4, on which, with the help of the holder 5, a translucent screen 3 is mounted, for example, either from a cloudy plastic or from a cloudy glass, with a coordinate grid deposited on its outer surface. The screen 3 is made in the form of a part of a spherical surface, which is part of a thin-walled ring, bounded above by a horizontal plane passing through the center of the spherical surface. The axis of the ring is inclined to the horizontal by the latitude value of a particular area and is coaxial with the axis of rotation of the Earth. The width of the ring is chosen taking into account the inclination of the earth's axis to the plane of the ecliptic and is at least 23 degrees on both sides of the equator of the ring. A transparent spherical lens 6, for example, of either transparent plastic or glass, is mounted on a stand 4 and is located in the center of the screen 3. The diameter of the screen is in the range from 0.95 to 1.05 of the focal length of the lens 6. The indicator is a spot of sunlight focused with the lens 6 on the screen 3. To prevent (reduce) the destructive effect on the screen 3 of condensed solar radiation from the spherical lens 6 in the pointer, absorbing opacity can be installed on the side of the surface of the lens 6 facing the Sun nye curtains. For example, on the surface facing the Sun, the surface of the spherical lens 6 can be applied with opaque paint spots that act as curtains.

For the equatorial (Fig. 5) region of the Earth, the solar calendar-clock according to the second embodiment differs in the fastening of the spherical lens 6 and the screen 3 to the rack 4. In this case, there are two racks 4 on the base, between which the lens 6 and the screen 3 are mounted on an annular holder 5.

For the polar (Fig.6) region of the Earth, the solar calendar-clock according to the second embodiment is distinguished by the fastening of the screen 3 to the rack 4 with two holders 5 from the bottom.

The solar calendar-clock according to the third embodiment (Fig. 7) consists of a stand with a base 4 on which a transparent spherical lens 6 is mounted, for example, either of transparent plastic or glass. On the surface of the lens 6 is a translucent screen 3, for example, applied by coloring with a translucent paint, with a coordinate grid deposited on it. The screen 3 is made in the form of a part of the ring, bounded above by a horizontal plane passing through the center of the lens 6. The axis of the ring is inclined to the horizontal by the latitude value of a particular area and is aligned with the axis of rotation of the Earth. The width of the ring is selected taking into account the inclination of the earth's axis to the plane of the ecliptic and is at least 23 degrees on both sides of the equator of the ring. The pointer is the center of intersection of the light lines on the screen 3, which are formed by sunlight passing through the slit shutter 7 and refracted by a spherical lens 6. The slit shutter 7 is made of vertical, radially relative to the lens 6 strips of opaque material at a distance equal to at least at least one lens diameter 6 from its center on the side facing the Sun. The width of the gaps of the slit curtain is selected from the condition of satisfactory visibility of the light lines on the screen 3.

The installation of the claimed utility models in any particular place on the Earth should meet the following requirements:

1. The axis of the screen should be oriented coaxially with the axis of rotation of the Earth (for example, in the northern hemisphere, point to the North Star), and, therefore, should be directed north in the northern hemisphere of the Earth, and south in the southern hemisphere of the Earth. Thus, the axis of the screen with its projection onto the horizontal plane makes an angle corresponding to the geographical latitude of the area on which the utility model is installed.

2. The compass orientation of utility models is acceptable, taking into account the magnetic declination of a given area.

3. Utility models should be installed horizontally to increase the accuracy of measurements, for this it is possible to use a horizontal sensor.

4. To count the administrative time, bind the time scale of the day.

After installing any of the variants of the described models in the presence of direct sunlight on the screen, observe and record the position of the pointer.

The time of day is determined by the time scale of the day. The calendar day is determined on a calendar of calendar dates. The accuracy of determination of both parameters depends on the division price of the corresponding scales, which is interconnected with the absolute size of the screen. It should be noted that the calendar date scale is non-linear (sinusoidal), and therefore the accuracy of determination is greatly reduced during the winter and summer solstices, and is maximum at the equinox.

To determine the administrative time using the claimed utility models in each specific place on the Earth, the time scale of the day is linked to the administrative time by taking into account the shift of the astronomical time to the administrative time.

It should be noted that in the claimed utility models, the pointer to the coordinate sphere is always in the presence of direct sunlight, unlike some other models of solar calendars and sundials.

Claims (3)

1. A solar calendar-clock containing a gnomon, the upper part of which is a sight, and a screen on which a calendar date scale is applied, characterized in that it contains a housing, in the upper part of which a recess is made in the form of a part of a spherical ring in which the gnomon is placed, consisting of a rod with a sight mounted on it in the form of a ball, and the rod is oriented parallel to the axis of rotation of the Earth, and the sight is located in the center of the ring, part of the surface of the ring is a screen on which a grid is made, made in spherical coordinates similar to the geographical coordinates of the Earth, and additionally containing a time scale of the day, and the screen is bounded above by a horizontal plane passing through the center of the sight, and two planes parallel to the plane of the celestial equator and at least 23º apart from it , the diameter of the ball of the sight is at least 0.017 of the distance from the sight to the screen, and the center of the sun’s shadow on the screen is an indication of the date and time of day. 2. A solar calendar-clock, containing a screen on which a calendar of dates is applied, characterized in that a translucent screen with a coordinate grid deposited on its outer surface, made in spherical coordinates similar to the geographic coordinates of the Earth, is mounted on a rack with a base, and additionally containing the time scale of the day, and the screen is made in the form of part of a spherical surface, which is part of a thin-walled ring, bounded above by a horizontal plane passing through the center with of the surface of the ring, while the axis of the ring is coaxial with the axis of rotation of the Earth, and the width of the ring is selected based on the inclination of the Earth's axis to the ecliptic plane and is at least 23º on both sides of the equator of the ring, a transparent spherical lens is mounted on a stand and is located in the center of the screen the diameter of which is from 0.95 to 1.05 of the focal length of a spherical lens, and the indicator of the date and time of day is a spot of sunlight focused by a spherical lens on the screen. 3. A solar watch calendar containing a screen on which a calendar date scale is applied, characterized in that a transparent spherical lens is mounted on a rack with a base, on the surface of which there is a translucent screen with a coordinate grid deposited on it, made in spherical coordinates similar to geographical coordinates of the Earth, and additionally containing a time scale of the day, and the screen is made in the form of a part of the ring, bounded above by a horizontal plane passing through the center of the lens, and the axis of the ring with of the sleep axis of the Earth’s rotation, the width of the ring is selected based on the inclination of the Earth’s axis to the ecliptic plane and is at least 23º in both directions from the equator of the ring, in addition, on the base of the rack, a slit curtain is installed on the side facing the Sun from vertical with respect to the lens of strips of opaque material at a distance of at least one diameter of the spherical lens from its center, the gap width of the slit curtain selected from the condition of visibility of light lines on the screen, and the date indicator Yemeni is the intersection of the center lines of light on the screen.