SU734799A1 - Globe - Google Patents

Description

one

The invention relates to educational devices, namely the globe .;

The globe is known, which contains the globe body with images of the surface of the Earth and geographic coordinates, placed movably relative to the base, moving inner and outer - deposited on its surface. rings with boxes covering the globe and dividing its surface into equal parts

However, the design of this globe does not allow the determination of geomagnetic time relative to local time.

The aim of the invention is to expand the functionality by determining the geomagnetic time relative to local time.

The goal is achieved by the fact that the globe has a semiring element with scales of heights and distances, located in a plane perpendicular to the plane of the movable rings, and fixed on the inner ring at diametrically opposite points, while the movable rings are placed on the base with the possibility of moving one-sidedly other, and the scale is inside. The outer and outer rings are respectively azimuthal and temporal.

Fig 1 shows a globe, a general view; in fig. 2 - an example of the calculation of the local geomagnetic noon. The globe contains body 1, performed

W in the form of a hollow sphere, geographic pole 2 (north or south), magnetic pole 3 (north or south), movable inner ring 4 with an azimuth scale, movable outer

15 a ring 5 with a time scale, a semi-ring element 6 with a scale of heights and rasters rigidly fixed on the inner ring 4 at diametrically opposite points and encompassing the globe body 1, the base of the globe, which is a cross 7, the bracket 8 supporting cola 9 , geographic grid of coordinates 10, geomagnetic grid of coordinates 11, at a rate of 12, FIG. 2 shows the position of the Sun 13 on the globe, geographical point A, relative to which geomagnetic time is calculated (negative correction) 14, geographical point B, relative to which geomagnetic time is calculated (positive correction) 15, earth equator 16-17, geomagnetic equator 18- 19, solar declination 13–2О, paralelle of the Sun 21–22, angle of time correction relative to geomagnetic midday to get geomagnetic time at point A 3 13–23, angle of positive time correction relative to geomagnetic time Most of the time to get geomagnetic time at point B, 26-25-23. The body of one globe is placed in the cross. fault 7, having a notch in the upper part equal to the radius of curvature of the globe body, and providing it with free rotational motion in any direction relative to its center. For better gliding and scratching, the neckline of the cross 7 is glued over with a soft cloth, and due to its own weight, the globe retains a predetermined position that does not require any additional fixation. The cross 7 can be1 a configuration, for example, a flat cylinder, square, with the specified above the notch, the depth of which would minimally capture the body area of the globe, at the same time ensuring its stable position. The height of the bracket 8, the thickness of the supporting ring 9, as well as the thickness of the movable rings 4 and 5 are chosen so that the upper edges of the rings 4 and 5 coincide with the line of the large circle on the body 1 of the globe, i.e. divides it into two equal parts. Rings 4 and 5 are located on the surface of the supporting ring 9 of the globe enclosing the body 1 and have a gap between them providing rotation around the body | Globe Usa 1 and relative to each other from O to ZbOCH Cross 7, bracket 8 and stand 12 are rigidly interconnected, but if necessary, arm 7, bracket 8 can be the middle part to put on the stem of the stage 12, which provides a circular rotation with the globe body mounted on the crosspiece 7 around its axis. T1-ring element 6 is fixed on the movable inner ring 4 so that its plane passes through the readings 0 ° and 180 ° of ring 4 and is strictly perpendicular to it. The functioning of the globe is as follows. To determine the geomagnetic time, it is necessary to know the position of the Sun 13 relative to the earth's surface, which is determined by its declination 13–20 on a given date and local solar time. Geomagnetic time is determined by a correction representing the angle between the arc of the large circle 3 15-26 (3.-14-24) passing through the magnetic pole 3 and the position of the sun 13 above the earth's surface. This correction is added or subtracted from the geomagnetic midday. At the specified date, the declination of the Sun 13-2O ... is determined from the Sun's declination table. The globe body 1 is set so that the north geographical pole 2 is at the zenith relative to the plane of the azimuth scale of the ring 4. Opposite to the meridian of the point for which geomagnetic time is determined the scale of the ring 5 sets the value of the local solar in temen. Moving the azimuth scale of the ring 4, it is set to zero against the division of 12 o'clock of the time scale of the ring 5, which corresponds to the midday value of the solar meridian. In accordance with the value of the Sun declination of point A on the heights scale of semi-ring element 6, mark the position of the Sun 13f on the globe without shifting the heights of element 6, rotate the globe body 1 until the magnetic pole 3 coincides with a division of 90 of the ring height scale of the semi-ring element 6 so that the Sun 13 and the magnetic pole 3 are on the same geomagnetic meridian under the HEIGHT scale of the semi-ring element 6. Crossing the azimuth scale of the ring 4 with a small height of the semi-ring element 6 to the geomagnetic point meridian for Time is determined, against the zero azimuth scale of the ring 4 is removed from the time scale of the ring 5, the value of geomagnetic time. At the same time, the geomagnetic head allows to determine the azimuths and the distance -i; not from a given point to any point.

the earth’s surface as well as geomagnetic coordinates.

Claims (1)

1. US Patent No. 2958959, cl. 35-46, 1960. / //