ENERGY FROM THE SUNOur period of hi

ENERGY FROM THE SUN

Our period of history is sometimes called the atomic age, but scientists and engineers continue to investigate other new sources of energy. During the past few years, there has been much interest in the possibility of converting the energy of the sun into useful power.

Radiation, the fuel for solar energy, is the radiation which, the sun transmits to the earth through some 92 500 000 miles of virtually empty space.

The distribution of radiation intensity throughout the solar spectrum tells us that the sun’s surface temperature is about 10 000° F. The temperature of the sun’s interior is estimated to be 30000000° F.

Solar energy is measured in terms of the heat produced when the radiation falling on a surface is completely absorbed! The rate at which solar energy reaches the earth’s atmosphere is known as the solar constant.

The radiant energy which reaches the outer fringes of our atmosphere is materially reduced by scattering and absorption before it reaches the earth’s surface. On a clear day, at sea level, the direct radiation may range from 250 to 320 BtU/ft2hr. The 30 to 40 per cent which is scattered by dust and absorbed by air molecules, water vapor, etc., is not entirely lost, because about half of it reaches the earth as diffused radiation. The total usable solar energy is the sum of these two components. A concentrating collector, such as a solar furnace, can use only the direct radiation which travels in straight lines and can be focused. A flat plate collector can use both the direct and the diffused radiation. The total amount of radiation which reaches a collector on the earth’s surface depends upon the number of hours of sunshine per day, and the thickness and nature of the atmospheric path through which the sun’s rays must travel.

Most of the inhabited areas of the world receive plenty of solar energy to meet all of man’s requirements. The problem which the engineer must solve is how to use this abundant supply of free income energy at a total cost which is within our ability to day.

We expect the solar station to look very different to the usual power plant — no smoky chimneys, no giant dams.

The unit will consist of an enormous circle with trees around it to cut down the amount of dust.

In the center there will be a 130 foot tower with the high pressure boiler installed at the top of it. Around the tower 23 concentric circular railway tracks are being built. Along them trains, automatically following the movement of the sun, will pull 12, 93 large mirrors mounted on special cars. The mirrors will always be directed towards the sun by means of automatic relays thus reflecting the beams on the flat surface of the boiler.

Other automatic devices, synchronized with the train will adjust the angle of the boiler so that all these beams reflected from the mirrors fall on it perpendicular.

The sun’s rays will heat the water in the boiler from which steam at a pressure of 30-35 atmospheres will be piped off to the 1,200 kw steam turbine the same way as ordinary boilers operating with ordinary fuel.

The station will be able to operate only when the sun shines. The sun’s rays, falling upon photo-electric cells, the whole apparatus will automatically go into operation.

The power from the station will be used for operating irrigation pumps, on the local farms, and the waste steam from the turbines can be used for providing ice. Hot water from the station stored in underground reservoirs will serve the purpose of heating hot-houses and private homes.

ENERGY FROM THE SUN

Our period of history is sometimes called the atomic age, but scientists and engineers continue to investigate other new sources of energy. During the past few years, there has been much interest in the possibility of converting the energy of the sun into useful power.

Radiation, the fuel for solar energy, is the radiation which, the sun transmits to the earth through some 92 500 000 miles of virtually empty space.

The distribution of radiation intensity throughout the solar spectrum tells us that the sun’s surface temperature is about 10 000° F. The temperature of the sun’s interior is estimated to be 30000000° F.

Solar energy is measured in terms of the heat produced when the radiation falling on a surface is completely absorbed! The rate at which solar energy reaches the earth’s atmosphere is known as the solar constant.

The radiant energy which reaches the outer fringes of our atmosphere is materially reduced by scattering and absorption before it reaches the earth’s surface. On a clear day, at sea level, the direct radiation may range from 250 to 320 BtU/ft2hr. The 30 to 40 per cent which is scattered by dust and absorbed by air molecules, water vapor, etc., is not entirely lost, because about half of it reaches the earth as diffused radiation. The total usable solar energy is the sum of these two components. A concentrating collector, such as a solar furnace, can use only the direct radiation which travels in straight lines and can be focused. A flat plate collector can use both the direct and the diffused radiation. The total amount of radiation which reaches a collector on the earth’s surface depends upon the number of hours of sunshine per day, and the thickness and nature of the atmospheric path through which the sun’s rays must travel.

Most of the inhabited areas of the world receive plenty of solar energy to meet all of man’s requirements. The problem which the engineer must solve is how to use this abundant supply of free income energy at a total cost which is within our ability to day.

We expect the solar station to look very different to the usual power plant — no smoky chimneys, no giant dams.

The unit will consist of an enormous circle with trees around it to cut down the amount of dust.

In the center there will be a 130 foot tower with the high pressure boiler installed at the top of it. Around the tower 23 concentric circular railway tracks are being built. Along them trains, automatically following the movement of the sun, will pull 12, 93 large mirrors mounted on special cars. The mirrors will always be directed towards the sun by means of automatic relays thus reflecting the beams on the flat surface of the boiler.

Other automatic devices, synchronized with the train will adjust the angle of the boiler so that all these beams reflected from the mirrors fall on it perpendicular.

The sun’s rays will heat the water in the boiler from which steam at a pressure of 30-35 atmospheres will be piped off to the 1,200 kw steam turbine the same way as ordinary boilers operating with ordinary fuel.

The station will be able to operate only when the sun shines. The sun’s rays, falling upon photo-electric cells, the whole apparatus will automatically go into operation.

The power from the station will be used for operating irrigation pumps, on the local farms, and the waste steam from the turbines can be used for providing ice. Hot water from the station stored in underground reservoirs will serve the purpose of heating hot-houses and private homes.

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ENERGY FROM THE SUNOur period of history is sometimes called the atomic age, but scientists and engineers continue to investigate other new sources of energy. During the past few years, there has been much interest in the possibility of converting the energy of the sun into useful power.Radiation, the fuel for solar energy, is the radiation which, the sun transmits to the earth through some 92 500 000 miles of virtually empty space.The distribution of radiation intensity throughout the solar spectrum tells us that the sun’s surface temperature is about 10 000° F. The temperature of the sun’s interior is estimated to be 30000000° F.Solar energy is measured in terms of the heat produced when the radiation falling on a surface is completely absorbed! The rate at which solar energy reaches the earth’s atmosphere is known as the solar constant.The radiant energy which reaches the outer fringes of our atmosphere is materially reduced by scattering and absorption before it reaches the earth’s surface. On a clear day, at sea level, the direct radiation may range from 250 to 320 BtU/ft2hr. The 30 to 40 per cent which is scattered by dust and absorbed by air molecules, water vapor, etc., is not entirely lost, because about half of it reaches the earth as diffused radiation. The total usable solar energy is the sum of these two components. A concentrating collector, such as a solar furnace, can use only the direct radiation which travels in straight lines and can be focused. A flat plate collector can use both the direct and the diffused radiation. The total amount of radiation which reaches a collector on the earth’s surface depends upon the number of hours of sunshine per day, and the thickness and nature of the atmospheric path through which the sun’s rays must travel.Most of the inhabited areas of the world receive plenty of solar energy to meet all of man’s requirements. The problem which the engineer must solve is how to use this abundant supply of free income energy at a total cost which is within our ability to day.We expect the solar station to look very different to the usual power plant — no smoky chimneys, no giant dams.The unit will consist of an enormous circle with trees around it to cut down the amount of dust.In the center there will be a 130 foot tower with the high pressure boiler installed at the top of it. Around the tower 23 concentric circular railway tracks are being built. Along them trains, automatically following the movement of the sun, will pull 12, 93 large mirrors mounted on special cars. The mirrors will always be directed towards the sun by means of automatic relays thus reflecting the beams on the flat surface of the boiler.Other automatic devices, synchronized with the train will adjust the angle of the boiler so that all these beams reflected from the mirrors fall on it perpendicular.The sun’s rays will heat the water in the boiler from which steam at a pressure of 30-35 atmospheres will be piped off to the 1,200 kw steam turbine the same way as ordinary boilers operating with ordinary fuel.The station will be able to operate only when the sun shines. The sun’s rays, falling upon photo-electric cells, the whole apparatus will automatically go into operation.The power from the station will be used for operating irrigation pumps, on the local farms, and the waste steam from the turbines can be used for providing ice. Hot water from the station stored in underground reservoirs will serve the purpose of heating hot-houses and private homes.

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Энергия солнца

нашего периода истории иногда называют атомным веком, но ученые и инженеры продолжают исследовать другие новые источники энергии. В течение последних нескольких лет наблюдается большой интерес к возможности преобразования энергии солнца в полезную энергию.

Излучение, топливо для солнечной энергии, является излучение , которое, солнце передает на Землю через некоторые 92 500 000 миль практически пустого пространства.

Распределение интенсивности излучения во всем спектре Солнца говорит нам , что температура поверхности Солнца составляет около 10 000 ° F. Температура недр Солнца оценивается в 30000000 ° F.

измеряется солнечной энергии с точки зрения тепла , производимого , когда излучение падения на поверхности полностью поглощается! Скорость , с которой солнечная энергия достигает атмосферы Земли известна как солнечной постоянной.

Лучистая энергия , которая достигает внешних полос нашей атмосферы существенно уменьшается за счет рассеяния и поглощения , прежде чем он достигнет поверхности Земли. В ясный день, на уровне моря, прямое излучение может находиться в диапазоне от 250 до 320 BTU / ft2hr. От 30 до 40 процентов , которое рассеивается пылью и поглощается молекулами воздуха, водяного пара и т.д., не полностью теряется, так как около половины его достигает земли как рассеянное излучение. Общая полезная солнечная энергия является суммой этих двух компонентов. Обогатительной коллектор, например солнечной печи, можно использовать только прямое излучение , которое перемещается по прямой линии и может быть сфокусирован. Пластинчатый коллектор может использовать как прямой , так и рассеянным излучением. Общее количество излучения , которое достигает коллектора на поверхности Земли зависит от количества солнечных часов в день, а также от толщины и характера атмосферного пути , через которые солнечные лучи должны путешествовать.

Большинство населенных пунктов мира получают большое количество солнечной энергии , чтобы удовлетворить все потребности человека. Проблема , которую необходимо решить инженер, как использовать этот избытке свободной энергии доходов на общую сумму , которая находится в пределах нашей способности день.

Мы ожидаем , что солнечная станция не выглядеть очень отличается от обычной электростанции - нет дымные трубы, ни гигантских плотин.

Устройство будет состоять из огромного круга с деревьями вокруг него , чтобы сократить количество пыли.

В центре будет 130 футов башня с котлом высокого давления , установленного в верхней части этого. Вокруг башни 23 концентрических круговых железнодорожных путей строятся. Вдоль них поезда, автоматически следуя за движением солнца, будет тянуть 12, 93 больших зеркал , установленных на специальных автомобилях. Зеркала всегда будут направлены к Солнцу с помощью автоматических реле , таким образом , отражающие лучи на плоской поверхности котла.

Другие автоматические устройства, синхронизированные с поездом будет регулировать угол наклона котла таким образом , чтобы все эти лучи , отраженные от зеркала падают на нее перпендикулярно.

Солнечные лучи будут нагревать воду в котле , из которого пар при давлении 30-35 атмосфер будет поступать от до 1200 кВт паровой турбины так же, как обычные котлы работающие с обычным топливом.

Станция будет иметь возможность работать лишь тогда , когда светит солнце. Солнечные лучи, падающие на фотоэлементов, весь аппарат автоматически перейдет в эксплуатацию.

Мощность от станции будет использоваться для работы ирригационных насосов, на местных фермах, а отработанный пар из турбины могут быть использованы для обеспечения льда. Горячая вода от станции , хранящегося в подземных резервуарах будет служить цели отопления тепличные и частные дома.

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