COULD THE MOON be an ANCIENT TEMPERATURE CONVERSION SYSTEM.
by Henryk Szubinski
First some facts.
When humans first landed on the Moon the measurement system of temperature and the conversion system were not clearly
indicated. Why?.
Probably because the human thermal regulation could also be CONVERTIVE to the environment by working out the
temperature differences and any pattern of details on the Moon with the details on Earth.
So the astronauts could have worked out the FUTURE and kept it an "illegal secret". That's why it's now UNACKNOWLEDGED.
Image of Apollo 11 astronauts on the Moon.
by Henryk Szubinski
First some facts.
When humans first landed on the Moon the measurement system of temperature and the conversion system were not clearly
indicated. Why?.
Probably because the human thermal regulation could also be CONVERTIVE to the environment by working out the
temperature differences and any pattern of details on the Moon with the details on Earth.
So the astronauts could have worked out the FUTURE and kept it an "illegal secret". That's why it's now UNACKNOWLEDGED.
Image of Apollo 11 astronauts on the Moon.
How to Convert and how to relate to the temperature and the Thermal CONVERTION as "NOT THERMAL REGULATION" which astronauts felt and were working on.
www.reddit.com/r/AskScienceDiscussion/comments/41nex9/what_is_the_maximum_temperature_that_a_space_suit/
date 2018
April 6
This will depend on what you mean by "withstand". Should the suit be completely unaffected after the temperature has returned to normal? Or, at the other extreme, do you require only that the human inside the suit be able to survive the high-temperature exposure?
Another important variable is the duration of exposure. In general, a shorter duration will allow for a higher temperature. Similarly, it would be important to know what mechanism(s) of heat transfer are envisioned by OP. Is the suit receiving heat only by radiation (e.g., by absorbing increasingly intense light and infrared radiation as the astronaut approaches the surface of a star)? Or is the astronaut swimming in the plasma of the star, or otherwise in contact with hot fluids or solids?
Spacesuits are generally used in space, where the extreme distances between particles make ambient "temperature" somewhat hand-wavy. If you go by the temperature of the suit itself, NASA's EMU suits are covered in Ortho-fabric, which in a blend on Kevlar, Nomex, and Gore-Tex, rated to up to about 150 degrees Celsius.
radiant barrier is a type of building product that reflects thermal radiation and reduces heat transfer. Since thermal energy is also transferred via conduction and convection, radiant barriers are often supplemented with thermal insulation products that retard heat transfer via conduction or convection.
from
the ASTRONAUTS SUIT as HAVING "RADIANT BARRIER".
Wikipedia
date 2018
April 6
Radiant barrier reflects heat radiation (radiant heat), preventing transfer from one side to another due to a reflective, low emittance surface. In building applications, this surface is typically a very thin, mirror-like aluminum foil. The foil may be coated for resistance to the elements or for abrasion resistance. The radiant barrier may be one or two sided. One sided radiant barrier may be attached to insulating materials, such as polyisocyanate, rigid foam, bubble insulation, or OSB. Additionally, reflective tape can be adhered to strips of radiant barrier to make it a contiguous vapor barrier, alternatively, radiant barrier can be perforated for vapor transmittance.
Textiles
Since the 1970s,[3] sheets of metalized polyester called space blankets have been commercially available as a means to prevent hypothermia and other cold weather injuries. Because of their durability and light weight, these blankets are popular for survival and first aid applications. Swarms of people can be seen draped in reflective metalized film after a marathon, especially where the temperatures are particularly cold, like during the annual ING New York City marathon which takes place in the fall.[5]
The moving particles of a warm soild material can increase the heat energy of the particles in a cooler solid material by transferring it directly from one particle to the next. Since particles are closer together, solids conduct heat better than liquids or gases. Conduction moves heat through a material.Nov 20, 2009
This is the role of all cooling systems. To accomplish this, there are three primary modes of heat transfer. ... Conduction - the transfer of heat through matter with no net displacement of the matter. Convection - the circulatory motion of a gas or liquid caused by the variation of its density and the action of gravity.
from
Wikipedia
date 2018
April 6
Heat transfer is a discipline of thermal engineering that concerns the generation, use, conversion, and exchange of thermal energy (heat) between physical systems. Heat transfer is classified into various mechanisms, such as thermal conduction, thermal convection, thermal radiation, and transfer of energy by phase changes. Engineers also consider the transfer of mass of differing chemical species, either cold or hot, to achieve heat transfer. While these mechanisms have distinct characteristics, they often occur simultaneously in the same system.
Heat conduction, also called diffusion, is the direct microscopic exchange of kinetic energy of particles through the boundary between two systems. When an object is at a different temperature from another body or its surroundings, heat flows so that the body and the surroundings reach the same temperature, at which point they are in thermal equilibrium. Such spontaneous heat transfer always occurs from a region of high temperature to another region of lower temperature, as described in the second law of thermodynamics.
Heat convection occurs when bulk flow of a fluid (gas or liquid) carries heat along with the flow of matter in the fluid. The flow of fluid may be forced by external processes, or sometimes (in gravitational fields) by buoyancy forces caused when thermal energy expands the fluid (for example in a fire plume), thus influencing its own transfer. The latter process is often called "natural convection". All convective processes also move heat partly by diffusion, as well. Another form of convection is forced convection. In this case the fluid is forced to flow by use of a pump, fan or other mechanical means.
Thermal radiation occurs through a vacuum or any transparent medium (solid or fluid). It is the transfer of energy by means of photons in electromagnetic waves governed by the same laws.[1]
Wikipedia
date 2018
April 6
Heat transfer is a discipline of thermal engineering that concerns the generation, use, conversion, and exchange of thermal energy (heat) between physical systems. Heat transfer is classified into various mechanisms, such as thermal conduction, thermal convection, thermal radiation, and transfer of energy by phase changes. Engineers also consider the transfer of mass of differing chemical species, either cold or hot, to achieve heat transfer. While these mechanisms have distinct characteristics, they often occur simultaneously in the same system.
Heat conduction, also called diffusion, is the direct microscopic exchange of kinetic energy of particles through the boundary between two systems. When an object is at a different temperature from another body or its surroundings, heat flows so that the body and the surroundings reach the same temperature, at which point they are in thermal equilibrium. Such spontaneous heat transfer always occurs from a region of high temperature to another region of lower temperature, as described in the second law of thermodynamics.
Heat convection occurs when bulk flow of a fluid (gas or liquid) carries heat along with the flow of matter in the fluid. The flow of fluid may be forced by external processes, or sometimes (in gravitational fields) by buoyancy forces caused when thermal energy expands the fluid (for example in a fire plume), thus influencing its own transfer. The latter process is often called "natural convection". All convective processes also move heat partly by diffusion, as well. Another form of convection is forced convection. In this case the fluid is forced to flow by use of a pump, fan or other mechanical means.
Thermal radiation occurs through a vacuum or any transparent medium (solid or fluid). It is the transfer of energy by means of photons in electromagnetic waves governed by the same laws.[1]
Conclusion:
high temperature
The average temperature on the Moon (at the equator and mid latitudes) varies from-298 degrees Fahrenheit (-183 degrees Celsius), at night, to 224 degrees Fahrenheit (106 degrees Celsius) during the day.
COULD the MOON TEMPERATURES made to be the TRANSLATION values from Farenheit to Celcius and
from Celcius to Farenheit?
Meaning, could the MOON BE SOME TYPE OF INTELLIGENT CONVERSION SPACE BODY?.
As related to the EARTH's temperatures
so that Moon Celcius high and low may be converted to EARTH*s high and low FARENHEIT and could the
Moon's Farenheit be equal to the low and high Celcius temperature.
Here are some calculations to start with and the fact that the temperature variables are shifting from
farenheit to Celcius.
The clue is to read the temperature in degrees as the Celcius temperature not the Farenheit temperature.
Any astronaut may experience the same temperature as any human on Earth that experiences more heat than another human.
The fact being that when you create a specific high temperature insulation, you are in fact making it divide the highest temperature
with the lowest so that ;
106/-183
=0,579
as singular
1/0,579
=1,72 as the multiple of 172% of any celcius temperature with any Farenheit temperature so that
106 x 1,72=183 Farenheit
and
-183x1,72
=314,76 Farenheit
as added to define the highest temperature
=183 + -314,76
=- 131,76 Farenheit
Lets try with the Celcius and the multiple 172%
as;
highest =106 x 1,72
=183,2
and lowest at:
-183 x 1,72
=-314,76
The comparisons with Farenheit and Celcius as;
Farenheit=183 and -131,76
Celcius=183 and -314,76
Lets add them up;
as Farenheit
-131,76+183=-51,24
as Celcius
183-314,76=131,76
We have the temperature subtractions so lets
subtract again:
the Farenheit with the Celcius as
=-51,24+131,76
=-80,52
So far ,these are only temperature values but they may be related to the whole solar system and the planets and moons as
the TEMPERATURE CONVERSION from the Farenheit to the Celcius.
Lets see the temperatures for the planets in the solar system.
PlanetMinimum surface temperature °F (°C)Maximum surface temperature (°F (°C)
Mercury- 275 °F (- 170°C)+ 840 °F (+ 449°C)
Venus+ 870 °F (+ 465°C)+ 870 °F (+ 465°C)
Earth- 129 °F (- 89°C)+ 136 °F (+ 58°C)
Moon- 280 °F (- 173°C)+ 260 °F (+ 127°C)
3 more rows
Jupiter778,369,000 km (483,500,000 miles)-130 °C (-202 °F)
Saturn1,427,034,000 km (888,750,000 miles)-130 °C (-202 °F)
Uranus2,870,658,186 km (1,783,744,300 miles)-200 °C (-328 °F)
Neptune4,496,976,000 km (2,797,770,000 miles)-200 °C (-328 °F)
Pluto ranges from -387 to -369 Fahrenheit(-233 to -223 Celsius)
high temperature
The average temperature on the Moon (at the equator and mid latitudes) varies from-298 degrees Fahrenheit (-183 degrees Celsius), at night, to 224 degrees Fahrenheit (106 degrees Celsius) during the day.
COULD the MOON TEMPERATURES made to be the TRANSLATION values from Farenheit to Celcius and
from Celcius to Farenheit?
Meaning, could the MOON BE SOME TYPE OF INTELLIGENT CONVERSION SPACE BODY?.
As related to the EARTH's temperatures
so that Moon Celcius high and low may be converted to EARTH*s high and low FARENHEIT and could the
Moon's Farenheit be equal to the low and high Celcius temperature.
Here are some calculations to start with and the fact that the temperature variables are shifting from
farenheit to Celcius.
The clue is to read the temperature in degrees as the Celcius temperature not the Farenheit temperature.
Any astronaut may experience the same temperature as any human on Earth that experiences more heat than another human.
The fact being that when you create a specific high temperature insulation, you are in fact making it divide the highest temperature
with the lowest so that ;
106/-183
=0,579
as singular
1/0,579
=1,72 as the multiple of 172% of any celcius temperature with any Farenheit temperature so that
106 x 1,72=183 Farenheit
and
-183x1,72
=314,76 Farenheit
as added to define the highest temperature
=183 + -314,76
=- 131,76 Farenheit
Lets try with the Celcius and the multiple 172%
as;
highest =106 x 1,72
=183,2
and lowest at:
-183 x 1,72
=-314,76
The comparisons with Farenheit and Celcius as;
Farenheit=183 and -131,76
Celcius=183 and -314,76
Lets add them up;
as Farenheit
-131,76+183=-51,24
as Celcius
183-314,76=131,76
We have the temperature subtractions so lets
subtract again:
the Farenheit with the Celcius as
=-51,24+131,76
=-80,52
So far ,these are only temperature values but they may be related to the whole solar system and the planets and moons as
the TEMPERATURE CONVERSION from the Farenheit to the Celcius.
Lets see the temperatures for the planets in the solar system.
PlanetMinimum surface temperature °F (°C)Maximum surface temperature (°F (°C)
Mercury- 275 °F (- 170°C)+ 840 °F (+ 449°C)
Venus+ 870 °F (+ 465°C)+ 870 °F (+ 465°C)
Earth- 129 °F (- 89°C)+ 136 °F (+ 58°C)
Moon- 280 °F (- 173°C)+ 260 °F (+ 127°C)
3 more rows
Jupiter778,369,000 km (483,500,000 miles)-130 °C (-202 °F)
Saturn1,427,034,000 km (888,750,000 miles)-130 °C (-202 °F)
Uranus2,870,658,186 km (1,783,744,300 miles)-200 °C (-328 °F)
Neptune4,496,976,000 km (2,797,770,000 miles)-200 °C (-328 °F)
Pluto ranges from -387 to -369 Fahrenheit(-233 to -223 Celsius)
www.thoughtco.com/convert-farenheit-to-celcius-609232
Temperature Conversion FormulaThe temperature conversion is easy to do:
- Take the °F temperature and subtract 32.
- Multiply this number by 5.
- Divide this number by 9 to obtain your answer in °C.
T(°C) = (T(°F) - 32) × 5/9
which is
T(°C) = (T(°F) - 32) / 1.8
We still don't know ,but I'm sure that there are ANCIENT CONVERTER SYSTEMS or STRUCTURES such as the
MONOLITHS from the movie
2001 SPACE ODYSSEY.
So there are some similarities to the 1.72 and the 1.8 by an error of about
0,08
This could then be the MONOLITH SYSTEM CONVERTER between the
1.8 and 0,08 as the INFINITY VIBRATION of the MONOLITH on the Moon
as it does have some STRANGE VIBRATION where the
1.8=infinite
and
0.08=eternal
there are more similarities related to the -80,52 and the 0.08 as;(from the previous equation);
We have the temperature subtractions so lets
subtract again:
the Farenheit with the Celcius as
=-51,24+131,76
=-80,52
So that -80.52/1000 =-0.08052
which would define the CONVERSION by reduction of 1000 times as the
ORIGIN of the FREQUENCY.
CONVERSION of the 0.08 Farenheit=-17.73 Celcius
CONVERSION of the -80.52 Farenheit =26.955 Celcius
This defines the BALANCED EARTH TEMPERATURE RANGE as
cold =-17.73 degrees
and
Warm =26.955 degrees.
So to have defined the 1.8
lets define the -32 as related to the above equation and the result of -26.955 degrees
as their difference
=about 5.045 degrees
which relates to the use of the 5 in the , 5/9 in the equation for the CONVERSION.
The formula to convert °F to °C is:
T(°C) = (T(°F) - 32) × 5/9
which is
T(°C) = (T(°F) - 32) / 1.8
see image below:
The first image from Apollo to the Earth and the only image that may CONVERT the HEAT VALUES from Celcius to Farenheit and probably the only fact that the
change from our human reference to heat as being either TRUE on EARTH or TRUE IN SPACE or as TRUE on the MOON.
So there are at least 3 CONVERSIONS happening at the same time and are related to the Planet Earth as seen from space, but the CONTINENTS are not clearly shown, meaning that we do not know which continent converts to the other as HEAT VALUES. But we do have the BLUE EARTH as the image that may DO THIS.
SO IT WOULD BE EASY TO DEFINE THIS IMAGE AS:
The formula to convert °F to °C is:
which is
T(°C) = (T(°F) - 32) / 1.8
with the TC on the left side of Earth and the TF -32 /1.8 on the right side of the Earth.
As well as :
TF -32 /1.8 as alternatively on the left side of the Earth and TC on the right side of
the Earth.
So for any ALIEN SIGNALS and INTERACTIONS of PEACE with them would mean the
use of the theory alternations, such as:
TC / TF =-32/1.8
TC /TF=17.777 as the ALIEN and HUMAN peaceful interaction
as the TCTF heat conversions of
"INTERPLANETARY SPACE TEMPERATURE "=IT
as
TCTFIT
or as TC/TF=IT
Having divided it once, as the result being 17.77, the division again
will define the IT = 17.777/2
=8.885
And again as
8.885/2=4.4425 as the temperature CONVERSION of any ALIEN
SIGNALS as their own alternator between PLANETS and Moons
as the temperature CONSTANT of the universe
=4.4425 IT
Where the IT=the Monolith as the access being
4 on the approach side and 0.4425 on the alternate
side.
So the MONOLITH appears to be the TEMPERATURE
CONSTANT of the frequency SIGNAL of 0.4425 degrees.
I continues along the approach that if i keep on working on some new angles, the result will be found.
So in relation to the
44 and 0.425
I continued to define the division of the length to Earth orbit and the length to the Moon as
Low Earth orbit (LEO): geocentric orbits with altitudes from 160 to 2,000 km (100–1,240 miles). Medium Earth orbit (MEO): geocentric orbits ranging in altitude from2,000 km (1,240 miles) to just below geosynchronous orbit at 35,786 kilometers(22,236 mi).
Earth and the Moon orbit about their barycentre (common center of mass), which lies about 4,600 km(2,900 mi) from Earth's center (about 34 of the radius of Earth). On average, the distance to the Moon isabout 385,000 km (239,000 mi) from Earth's center, which corresponds to about 60 Earth radii.
The division of Earth orbit length with Moon position length from Earth
as:ANALYTICAL search for CLUES.
385 000 / 2 000 km
=1925
or about 2000
which as HEAT TRACE would be the 0.02 in the 0.425
as 2000 / 100 000
=0.02
Even the 0.425
has the similarity with the 25 in the result from the previous equation of 1925.
So in relation to the
44 and 0.425
I continued to define the division of the length to Earth orbit and the length to the Moon as
Low Earth orbit (LEO): geocentric orbits with altitudes from 160 to 2,000 km (100–1,240 miles). Medium Earth orbit (MEO): geocentric orbits ranging in altitude from2,000 km (1,240 miles) to just below geosynchronous orbit at 35,786 kilometers(22,236 mi).
Earth and the Moon orbit about their barycentre (common center of mass), which lies about 4,600 km(2,900 mi) from Earth's center (about 34 of the radius of Earth). On average, the distance to the Moon isabout 385,000 km (239,000 mi) from Earth's center, which corresponds to about 60 Earth radii.
The division of Earth orbit length with Moon position length from Earth
as:ANALYTICAL search for CLUES.
385 000 / 2 000 km
=1925
or about 2000
which as HEAT TRACE would be the 0.02 in the 0.425
as 2000 / 100 000
=0.02
Even the 0.425
has the similarity with the 25 in the result from the previous equation of 1925.