LT6583B - Device for tracking of moon traction force direction - Google Patents

Abstract

Invention relates to portable household appliances for astrophysics, gravimetry and chronology, and is intended to continuously track the direction of the Moon's traction force and its variation at a certain point in the Earth's surface.Device consists housing (1) with the marked longitudinal axis (2), engine (3), cylinder (4) with index attached on it (5). Housing (1) is covered with dial-plate (6) with two scales on it: moon traction intensity scale (7), painted with different color intensity, and graded planar scale of Moon traction force direction - azimuth scale (8). On the housing there are engine (3) control - start switch (9) and compass (10), with its scale‘s north - south (0°/360° - 180°) direction coaxed with housing‘s longitudinal axis (2).

Description

The invention relates to portable household astrophysics, gravimetry and chronology devices and is intended to continuously follow the direction of the lunar gravitational force and its change at a certain point on the Earth's surface.

All bodies on the Earth's surface are affected by the attraction of the Earth and other celestial bodies, of which the Moon has a significant influence. The effect of lunar traction on large water bodies is known, but the effect of its traction on buildings, transport and other technical means and all living nature has been little studied, therefore it is important to record and evaluate the regularities of lunar traction intensity and direction change.

Humans, like all living nature, experience changes in well-being due to the lunar attraction, but there are no comparable indicators to evaluate their interaction that can be related to those changes in well-being. Traditionally, the Moon's impact on wildlife and human well-being has been assessed as "favorable and" unfavorable "visible phases (youth, full moon, full moon, delay) related to the Moon's reflected sunlight and unclear as to the Moon's direction of gravity and its effect on body gravity. t. y. the force of gravity acting on the material.

When measuring the force of gravity of a body with a dynamometer, this force varies depending on the position of the Moon in relation to the Earth and the body. When the Moon is at its zenith above the body, the force pulling it in the direction of the Earth's center decreases because the direction of the Moon's gravitational pull is opposite to the direction of the Earth's gravitational pull. Then when the Moon is diametrically on the other side of the Earth's sphere, then the force of attraction of the aforementioned body increases as the directions of the Moon and Earth's gravitational forces coincide.

Preliminary study of the impact of gravity change on the environment is known (V. Kazanavičiūtė, K. Kazanavičius // Works of Young Scientists. ISSN 1648-8776. 2009, no.3 (24), pp. 170-173). The study found that the relative change in body weight per kilogram of body weight measured with a spring dynamometer ranged from 0.6 to 1.05 g / kg. It has also been found that due to the rotation of the Earth and the movement of the Moon above the Earth, the relative change in the force of gravity of one kilogram of body mass changes over the course of the lunar diurnal cycle. The disadvantage of the stationary device used for the study is that it cannot be adapted for individual use, nor can it determine the time of the lunar diurnal cycle and the direction of the lunar attraction.

As used herein, the term the lunar diurnal cycle refers to the time (24 or 52 min) during which the Moon once "flies" across the celestial vault of the globe due to the Earth's rotation around its axis. The "lunar diurnal cycle" is different from the "lunar lunar cycle", during which the Moon orbits the Earth and lasts 27 days 7 or 43.1 minutes.

Various electronic timers are known (http://www.casio.com) according to the Gregorian, lunar, luno-solar, Muslim, Chinese, Hebrew and other calendars. Clocks adapted for them show seconds, minutes, hours, days, weeks, months, years, phases of the moon, floods, biological cycles, leap years, holidays, temperature, wind direction, acting as a compass, barometer or altimeter, and so on. No devices indicating the intensity and direction of the lunar traction were found.

The known "Sea Moon Tide Clock" (US5086417; G04B19 / 26), which has a rotating dial rotating about a central axis with a scale and lunar phase displays, a rotating motor which rotates the pointer of the device about an axis at one revolution in 12 hours and 25 minutes . The device has tidal imaging devices. The design and operation of this apparatus include lunar and wave clocks, and this makes it possible to determine the time and magnitude of tides at sea. The disadvantage of this device is that its pointer about an axis rotates twice during the lunar diurnal cycle, the device does not show the intensity and direction of the lunar traction force, and the complex design of the device.

The closest known technical solution is the US patent for the lunar zenith timer and its device (US6452871; G04B47 / 00). It is a fish feed dosing device that dispenses feed when the Moon is above the feeding point at the highest point of the celestial vault, i. zenith. The patent justification provides evidence that animals (deer, fish) have higher activity and better nutrition during the Moon's zenith and when the Moon is on the exact opposite side of the globe, i. i.e., when the Earth is rotated 180 degrees. (The Corpus Christi Caller Times, C3 page, Thursday, April. 30, 1992). The fish feed dosing device is controlled by the "Moon's zenith timer", which records the zenith time when the Moon is at the highest point in the sky. The time of the lunar zenith is similar to noon, when the sun in the sky vault is at its highest. The time of the lunar zenith varies at different points on the Earth's surface. The lunar zenith cannot always be observed directly due to clouds and so on. In order to capture the moment of the lunar zenith time, it traditionally uses the solar time, which needs to be converted to lunar time. The timer described in the present invention signals the feed dispenser when the Moon is at its zenith and later after half the lunar diurnal cycle. The electronic timer signal is generated every half of the lunar diurnal cycle by an oscillator and its oscillation calculators. The timer starts at the time of the Moon's zenith, so each output signal occurs at the moment of the zenith and / or after half the lunar diurnal cycle. The disadvantages of the present invention are as follows: the timer is tuned to only two signals per day, it does not show the change of the lunar traction force and its direction. The construction of the timer is complicated and it is not suitable for household use.

Like the Earth as a whole, individual objects on its surface are also affected by the attraction of the Moon, Sun, and other cosmic bodies in a changing direction and intensity of force.

An important form of lunar exposure is the change in gravitational force at different lunar positions in relation to the body, such as man.

The object of the invention is to provide a portable household device for continuously monitoring the change of the direction of the lunar gravitational force at a certain point on the Earth's surface during the day. The patented device will also have to display the intensity of the lunar gravitational pull on the bodies at the observation site, ie the change in object gravity expressed by a colored marker on a circular scale with a sliding lunar direction indication or a coefficient of change in gravity direction , South) or the corresponding index. The total vector of the gravitational forces of the Earth and the Moon depends on the location of the object on the surface of the globe, the direction of the Moon towards that object, and the distance to it.

The patented Lunar Traction Direction Tracker consists of a housing with a timing mechanism consisting of a motor, a roller, a dial with an Lunar Traction Intensity and Azimuth Scale, an arrow, an adjustment-start switch, a protective cover and a compass on the outer surface.

The motor of the patented device is either mechanical, electric or electromechanical.

The color of the lunar traction intensity scale of the patented device is of unequal intensity and it is symmetrically covered with a decreasing color brightness coating in the direction of 360 ° (0 °) - 180 °.

The directions of movement of the roller and the arrow of the patented device coincide with

In the direction of movement of the moon, and the rotation speed of the roller and arrow is one revolution in 24 hours and 52 minutes.

The azimuthal scale of the patented device is 0 ° / 360 ° graduated in short increments every 5 ° and longer increments every 15 °.

The protective cover of the patented device is transparent and openable.

The patented device may have sensors for transmitting either an electrical or an audible or other signal or command.

The patented device has a pointer to start position control - start switch.

The dial and compass of the patented device are attached to the housing so that the north-south directions of the dial azimuth scale (0 ° / 360 ° - 180 °) and the compass scale coincide with its longitudinal axis marked on the housing.

The azimuth scale of the patented device is marked either on the visible surface of the dial together with the lunar gravity intensity scale or on the visible plane of the housing.

The essence and novelty of the patented device is that it continuously follows and shows the direction and intensity of the lunar gravitational force for bodies measured with this device at a point (spot) on the Earth's surface. The direction and intensity of the lunar gravitational force on bodies depends on their position on the Earth's surface. The arrow on the azimuthal scale of the dial of the device indicates the angle of the direction of the lunar gravitational force to the meridian, and on the color scale the corresponding increase or decrease of the gravitational force.

The invention is illustrated by drawings.

FIG. 1 shows a top view of a lunar traction direction tracking device with a housing 1 with a longitudinal axis 2 marked thereon, a motor 3 with a shaft 4 on which an arrow 5 is mounted. The housing 1 is covered concentrically to the shaft 4 by a dial 6 with two scales. : lunar gravity intensity scale 7, which is of different color intensities, and a plane-graduated plane lunar gravity direction or azimuth scale 8. The dial is mounted so that the north-south (07360 ° to 180 °) direction of its azimuth scale coincides with the marked on its longitudinal axis 2 and directed towards the left side of the housing 1. On the left side of the housing 1 there is a control-start switch 9 of the motor 3. On the housing there is a compass 10 which is mounted so that the north-south (07360 ° -180 °) direction of its scale coincides with its longitudinal axis 2 marked on the housing and points at the housing. in the direction of the left.

FIG. Figure 2 shows the construction of a lunar traction direction tracking device. The device consists of a housing 1 with a motor 3 which rotates a roller 4. The housing 1 is covered by a dial 6, an arrow 5 mounted on the roller 4. The housing 1 has a protective cover 11 which protects the dial 6 and an arrow 5. The motor 3 has a control start switch 9. A compass 10 is built into or attached to the housing 1.

The lunar traction direction tracking device works as follows:

the motor 3 is adjusted so that the roller 4 and the arrow 5 rotate clockwise at one revolution in 24 hours and 52 minutes, that is, during the period of the lunar diurnal cycle.

In different places, the Moon reaches its zenith at different times. At the moment of the lunar zenith, the device is regulated and activated at the point where the intensity of the lunar traction force and its direction will be monitored. The device is oriented according to the compass in a northerly direction (07360 °) and with the adjusting-start switch 9 directs the spike of the arrow 5 in the direction of the Moon azimuth and at the same time starts the motor 3. On the dial 6 there is a direction or azimuth scale 8. Point 5 of the arrow indicates on the scale 8 the direction of the lunar gravitational pull and the position of the moon (azimuth) with respect to the observation point. At the same time, the spike of the arrow 5 on the scale 7 indicates the intensity (relative magnitude) of the lunar gravitational force for the bodies at the observation site. The light part of the lunar gravity scale 7 shows the intensity of the decrease in body gravity due to the lunar gravitational "lifting" force, and the dark part shows the intensity of the increase in body gravity due to the lunar gravitational "pressure" force. The device continuously shows the direction and intensity of the lunar gravitational force, which changes over the years due to the distance from the Earth to the change of the Moon as it orbits the Earth in an elliptical orbit.

Examples of the use of a lunar traction direction tracking device:

example

Launch-adjustment of the lunar traction direction tracking device according to the astronomical data of the lunar visibility.

Required for start-up: Moon traction direction tracking device, clock, astronomical Moon visibility data in relation to the observation location - Moon azimuth direction in degrees at the time of device start-adjustment.

With the control-start switch 9, the arrow 5 is rotated in the azimuth direction indicated by the lunar calendar in the astronomical lunar calendar and at the selected time and the engine is started 3. The activated device is placed in its permanent position and oriented north (07360 °) according to compass 10. At any time, the position of the lunar force on the azimuth scale 8 and the lunar force intensity (relative magnitude) on the color lunar intensity scale 7 can be determined from the position of the arrow 5 on the azimuth scale 8. The light part of the scale shows the intensity of the dark part is the intensity of the increase in the gravity of the body due to the gravitational "pressure" force of the Moon. The maximum decrease in body gravity is at the moment of the Moon's zenith, and the maximum increase is when the Moon is nadyre t.y. on the other side of the globe. When the device is moved, it is re-oriented in a north-south direction, and there is no need to change the direction of the arrow 5.

example

Determination of the direction of the lunar traction device by direct observation of the Moon.

The measurement requires a lunar traction direction device, a horizontal plane and a 10-15 cm long rod with a 4-hole hole in the roller. The setting is best done when the Moon is full.

The lunar traction direction tracking device is placed on a horizontal plane so that the longitudinal axis 2 marked on its body 1 coincides with the arrow of the compass 10 pointing North (07360 °). The protective cover 11 is removable and a 10-15 cm long rod is placed on the end of the roller 4 above the arrow 5. With the control start switch 9, the arrow 5 is turned so that the shadow cast by the rod passes through the middle of the cut-out at the blunt end of the arrow 5. At the same time, the motor 3 is started. The rod is removed and the protective cover 11 is covered.

When switched on, the switched-on device is placed in its permanent position and oriented according to the compass 10 in the North (07360 °) direction. At any time, the direction of the lunar force on the azimuth scale 8 and the direction (relative magnitude) of the lunar force on the color lunar force scale 7 can be determined from the position of the arrow 5 on the azimuth scale 8. The maximum decrease in body gravity is at the lunar zenith, and the maximum increase is when the Moon is nadyre t. i.e., on the other side of the globe. When the device is moved, it is reoriented in a north-south direction, and there is no need to change the direction of the arrow.

Checking the accuracy of the lunar traction direction tracking device.

Possible errors in the setting-start torque of the device and changes in the speed of the motor shaft can lead to discrepancies in the actual lunar azimuth direction displayed by the device. This requires periodic adjustment of the device. It is recommended that the adjustment be performed monthly in one of the methods described in Examples 1 and 2.

The patented household, portable compact device makes it possible to individually associate various changes with the direction of the lunar gravity and its intensity. The device can also be used to monitor the effects of the Moon on human well-being, animal behavior, plant vegetation, natural phenomena and / or prediction.

Claims (10)

Definition of the invention 1. A lunar traction direction tracking device comprising a housing with a timing mechanism, characterized in that the timing mechanism comprises a motor, a roller, a dial on the outer surface of which there is a lunar traction intensity and azimuthal scale, an indicator, a control release switch, a protective the cover and the housing have a compass. 2. A device according to claim 1, characterized in that its motor is either mechanical, electric or electromechanical. 3. Device according to claims 1 and 2, characterized in that the color of the lunar gravity intensity scale is of unequal intensity and is coated with a symmetrically decreasing color brightness coating in the direction of 360 ° (0 °) to 180 °. 4. The device according to claims 1 to 3, characterized in that the directions of movement of the roller and the arrow coincide with the direction of movement of the Moon, and the rotation speed of the roller and the arrow is one revolution in 24 hours and 52 minutes. 5. Device according to claims 1-4, characterized in that the azimuthal scale of the device is graduated in 360 ° short increments every 5 ° and longer every 15 °. 6. Device according to claims 1-5, characterized in that the protective cover is transparent and openable. 7. Device according to claims 1-6, characterized in that the device may have sensors for transmitting either an electrical or an audible or other signal or command. 8. Device according to claims 1-7, characterized in that the device has a pointer reset switch. 9. Device according to claims 1-8, characterized in that the dial and the compass are attached to the housing so that the north-south directions of the device azimuth scale (07360 ° 180 °) and the compass scale coincide with its longitudinal axis marked on the housing. 10. Device according to claims 1-9, characterized in that the azimuth scale is marked either on the visible surface of the dial together with the lunar attraction intensity scale or on the visible plane of the housing.