The description of a new device which is an improved version of the classic torsion balance is given. The device, which is the so-called “torsind”, seemed to be very sensitive to solar/lunar eclipses, and a Venus transit. It even responded to a solar eclipse when installed underground. The results of the most well-documented cases are described.
Nowadays scientific researchers often use devices in which the sensor is a mass freely suspended by a quartz, metal or synthetic fiber filament, or attached to a solid rod [
Starting in January, 2010, a new device “torsind” has been used at the Main Astronomical Observatory of the Ukrainian Academy of Science. It is used for monitoring of astronomical phenomena: solar and lunar eclipses, planetary transits and conjunctions. Torsind is a specific type of torsion balance that uses a very light metal disc instead of the linear beam of a classical unit, suspended from a monofilament made from natural silk, instead of quartz or a rigid suspension.
Our long-term studies have shown that such a device clearly responds to many astronomical phenomena [
The mobile part of the torsion balances used in our experiments consists of a very light 120 mm diameter aluminum disk and a very thin suspension fiber (a specially treated natural silk thread about 20 μm in diameter). The design of such a balance makes it insensitive to variations in gravitational potential and ensures that it is unaffected by gravitational (tidal) influences from any direction. In addition, the symmetrical shape of the disc rules out the possibility of any affect on the disk due to air convection inside the housing. Such a convection is considered to be the main interference source in the classical torsion balance. The disk is marked with a dark dot referred hereafter as the “pointer”. The total weight of this suspended part is »100 mg or less.
The housing of the torsind is made from a quartz cylinder (
influences inner parts of the walls and bottom of the cylinder are completely surrounded by a reliably grounded aluminum foil. The edges of this quartz-glass housing are sealed from the inside with a silicon joint sealant material. The upper end of the silk suspension thread is attached by adhesive to the center of the upper glass plate. The sealing of the housings prevents interference due to air currents or humidity variations, and improves thermal stabilization.
A webcam connected to a computer was mounted above the upper face of the cylinder. The image from the camera was processed by custom-made software that determines the position of a marker and calculates its polar coordinates relative to the vertical axis of symmetry of the cylinder. One measurement was taken each minute. The reading error does not exceed 0.3˚.
The device used was fully automated one and did not require the presence of an observer. Since mid-2008 the torsind has been sited in an isolated, shaded room with tightly closed doors and windows, the entrance being disbarred to outsiders. Our observations were performed in very favorable conditions:
• absence of any mechanisms within 50 m, such as motors and generators or moving objects;
• absence of electrical and wireless devices (except for one computer);
• no mechanical vibrations;
• complete silence and absence of strong light and heat radiation.
• closed room, no visitors.
1) The main feature of the device is the use of a silk thread because it has no reverse torque when twisted. The experiment was conducted as follows. A specially made adjuster allowed the suspension point of the thread to rotate around its vertical axis for any given angle or full rotations. The operator manually rotated the hang point of the thread for a certain number of degrees and registered how many degrees the disk will rotate in the opposite direction. Several twists were performed in both directions: both clockwise (plus) and counter-clockwise (minus).
It was noticed that the response was at least an order of magnitude weaker than the initial angle of twist (angle of roll-up). The experimental results are shown in the
This relationship was only true when the twisting rate was high (about 100 degrees per second). If the twist rate is small and does not exceed 1 degree per second then the reaction is zero. In other words reverse torque does not build in the thread.
This is well illustrated by actual observations. There are dozens of cases where the disk of the torsind slowly made several revolutions around its axis following which the marker of the device again pointed to the same azimuth, as before the start of rotation. This feature of the torsind is illustrated in
The observations made on 15.01.2012 are plotted in
This surprising property of a silk thread is due to its specific molecular structure. The basis of a thread is fibroin protein molecules, substances even stronger than Kevlar. Repetitive amino acid sequences of this protein form antiparallel pleated β-layers which are connected to
each other by hydrogen bonds. These bonds are not very strong and allow for moderate mechanical offsetting of the layers. This explains the fact that under slow (necessarily slow!) rotation the layers can slide relative to each other. Moreover, it does not reduce the mechanical strength of the thread.
2) The torsind is not sensitive to changes in gravitational potential by definition. If it were not so, then the torsind should have been able to register a tidal wave from the Moon with a period of 12 hours. This phenomenon was not observed, however.
3) The torsind is not sensitive to changes of microload on a thread due to the daily change in the Sun’s height above and below the horizon. This property was shown as follows.
A special experiment was conducted to ensure that the daily variations in the solar gravity force (the difference “noon minus midnight”) do not affect the reading. For this purpose, an additional micro weight (448 μg) was repeatedly loaded and unloaded on the thread within two weeks. Statistical analysis of the resulting data (938 individual measurements) showed that this microloading has no effect on readings. The results of this experiment are shown in
4) The effect of temperature variations on the readings was also investigated. A temperature sensor was installed inside the housing. Long-term measurements showed that the readings and the temperature inside the torsind were unrelated. Neither drastic temperature fluctuation (
5) The dependence of the torsind readings on humidity
has not been investigated. Firstly, the torsind housing was tightly sealed. Secondly, the torsind does not respond to changes in barometric pressure. This fact is reflected in
6) Significant variations of the external electric field did not have an observable effect on the torsind readings. The growth of the electric field during a thunderstorm storm on 10.08.2011 and a close (50 meters) lightning discharge at 11 h 36 m UT did not affect the torsind readings.
7) Prolonged studies have shown that the following factors cannot be the cause of the significant pointer rotation and therefore should be excluded from further consideration:
• convective air flow inside the torsind housing;
• changes in outdoor weather parameters (temperature, humidity, barometer);
• tidal effects of the Moon and Sun;
• change in the degree of excitation of the ionosphere over the place of observation (see
• Coriolis acceleration;
• floor vibration;
• local mobile phone interference;
• a grounded aluminum screen excluded interference from static electricity and reduced magnetic pickups.
8) Currently, torsind metrology is impossible because of the lack of metrological standards. Moreover, we do not know what force acts on the disk of the device. However, we can calculate a torque value by observing angular acceleration of the disk. There are many such cases. One of the minimum acceleration values was calculated using observations on 01.15.2012 (device WEB_1) during a time interval of 07 h 16 m to 08 h 27 m UT. These data are presented in
The average value of the acceleration Aang equals:
The torque T was calculated using a known radial distribution of mass in the torsind disk:
This value T can serve as a reliable indicator of the torsind sensitivity. The actual sensitivity may be even higher.
Silk monofilament as has been shown in paragraph 1 has no elastic properties. It cannot accumulate and save the reverse torque. Therefore the twisted torsind thread does not return a disc to its original position. Thus the torsind can not directly measure strength or magnitude of the applied torque. Therefore, the above-described device cannot be called as “a balance”. It is like a weather vane, which indicates direction of the wind only, but does not measure its speed.
The torsind determines a direction and angular velocity of the rotation only. Therefore, our instrument should be properly referred to as a “torsion indicator” or TORSIND.
Observations for the behavior of a torsind pointer during solar/lunar eclipses, and other astronomical phenomena have led to unexpected results [3-6]. The most interesting and well-documented cases are below.
Several years ago the author found that the superlight torsion balances are constantly registering a periodic signal of unknown nature. Devices of different designs and different types of detectors were sensitive to this periodic background signal. The signal waveform can
vary greatly, but the period of the signal remained exactly 24 hours. Conventionally, this signal is called background daily variation (BDV). Subsequently the BDV was taken into account when analyzing the observations.
Four panels in the
Amplitude of the BDV does not exceed 30 - 35 angle degrees. Usually it is lesser (see BDV in
To account for the influence of BDV we began our observations 3 days prior to this astronomical event and ended 2 days after its completion [
The observations were performed in the same way [
From this we may conclude that the increased torsind reactions during the solar/lunar eclipses were caused by these phenomena.
The last transit of Venus occurred June 5-6, 2012. We were observing this phenomenon during 5, 6 and 7 of June using the two torsinds—WEB_2 and WEB_3. Observation conditions remained the same.
The first contact occurs at 22 h 09 m UT and the last one—at 04 h 49 m UT the next day.
It is obvious that almost all of the time, while the Venus was crossing the sun’s disk; the responses of both torsinds were nearly constant, except for small fluctuations. It was only 5 h 50 m after the first contact when both devices began to increase their readings at the same time. Despite the fact that the reactions of the devices were somewhat different, the most important result remains that both units have shown a reaction to this phenomenon.
It has been above shown that torsind, despite its simplic-
ity, has a very high sensitivity to an unexplored kind of energy, most likely associated with the Sun. The unknown energy transfers a torque; and that disk rotation is an obvious response to this phenomenon. The disk of torsind turns in one direction or another due to being affected by this energy. In many cases torsind can “feel” phenomena occurring in faraway parts of the globe very well. Furthermore, it responds to such phenomena even when installed underground [
The use of such devices in astronomy opens a new chapter in that science, because it gives the opportunity to study many known phenomena from a completely unknown aspect, thus deepening our understanding of the cosmos from a completely new cognitive point of view.
We do not still know what force causes the rotation of a torsind disk. But this fact should not stop us. Quite the contrary, it is possible that the force is one of the manifestations of super-weak fields. Thus the use of this device will give us the opportunity to answer the question of how this force acts and how torque is transmitted.
I express my gratitude to all my colleagues with whom I planned this work, prepared experiments, and discussed the results of my observations: Thomas Goodey (UK), Dimitrie Olenici (Romania), Antonio Iovane (Italy), Daniel Vorobiov (Ukraine), Lavrenty Shikhobalov (Russia) Alan Stout (USA), Jean-Bernard Deloly (France), John Francis (UK).