DE102014001039A1 - spaceplane - Google Patents

Abstract

The hemispherical space glider has a two-part construction. The upper part consists of a glass dome. The lower part consists of the extended outer dome and the inner lower dome. Essentially, in the glass dome is a glass bulb, which moves in a circle, even in the lowered state. In the glass bulb move with, the seat, the fittings, the electric motor and the piston pump. The glass bulb is surrounded with a glass container, a vacuum container and hot air ducts. Around the hot air ducts, an accumulator is attached, on the outside of the interior lights are installed. The outdoor spotlights are located above the glass dome floor on the glass dome. Beneath the glass dome floor are the compressors and the space between the extended outer dome and the inner lower dome. Under the accumulators are the nozzles. At the extended outer dome is congruent with the extent of the compressors, the solar system. Operated the space glider with hot air, which is generated by the compressors and emitted with the nozzles centered and generate high pressure in the center of the inner lower dome. The hot air tubes fill the glass dome with hot air, which is further heated by the accumulator. This creates enormous high pressure, which raises the space glider in the air. The space glider is steered with the nozzles. To get in and out of the glass bulb is lowered by air pressure and lifted by creating a suction high. There are hot air balloons known that are of limited use and pollute the environment by burning fossil fuels. Roads become redundant. The environment is spared. The airspace offers multilayered gliding space.

Description

The invention relates to a hemispherical space slider according to the preamble of the claim.

It is known a hot air balloon.

The hot air balloon does not have a stable shell. It is operated with polluting heating material. He is slow and difficult to steer. In strong winds it is driven off. He can not ascend in stronger winds. His range is low. It can only be operated in daylight. Its operation is dangerous, as it can only be operated with an open flame. Destination flight is only possible in favorable weather.

The object of the invention is to ascend the space glider with hot air and targeted by ejecting hot air without bringing fossil fuel into the sliding phase.

To solve the problem, a space slider according to the invention, which has the features: The glass dome space ( 1 ) is hot air through the hot air ducts ( 5 ) and the hot air tubes ( 17 ). The air is supplied by the compressors ( 21 ) and from the accumulator ( 9 ) heated higher.

The compressors ( 21 ) are inclusive of the intake systems ( 18 ) around the same distance on the inside of the extended outer dome ( 26 ) adjusted. They reach from the glass cupola floor ( 13 ) to the foot ( 25 ) of the space glider. The heated air from the compressors ( 21 ) by means of the nozzles ( 24 ) Centered so that the hottest air centrally under the inner lower dome ( 19 ) bundles. As the hot air expands, pressure is created on the inner lower dome ( 19 ). The space slider is pushed up. The hotter the air, the higher the pressure. The faster the space glider rises. The accumulator ( 9 ) is on the glass dome floor ( 13 ) around the hot air channels ( 5 ) assembled. He draws the electricity from the solar system ( 22 ) attached to the extended outer dome ( 26 ), congruent with the size of the compressors ( 21 ), mounted around the space slider and over the arcuate pantograph bracket ( 23 ). The pantograph bracket ( 23 ) has strong current-reducing devices. To remove current from the power line, the arcuate pantograph bracket ( 23 ) lowered. The electricity is supplied via the power line ( 16 ) the accumulator ( 9 ) and stored. On board the space glider is an electricity meter. The arcuate pantograph bracket ( 23 ) is on the two sliding shoes ( 15 ) attached. With the sliding shoes ( 15 ), the pantograph bracket ( 23 ) over the slide rail ( 16 ) are moved around the space slider. The slide rail ( 16 ) covers the power line ( 16 ), Under the compressors ( 21 ) are the nozzles ( 24 ), which are inside and outside the extended outer dome ( 26 ) movable. To drive the nozzles ( 24 ) turned outwards. There are always 2 nozzles ( 24 ) side by side, switched in pairs. The remaining nozzles ( 24 ) serve the steering.

The glass bulb ( 6 ) can be rotated during the sliding phase. At the same time both nozzles ( 24 ) switched to drive against the direction of travel. The seat, the fittings ( 10 ), the door ( 8th ), the electric motor and the piston pump ( 3 ) are with the glass bulb ( 6 ) firmly and turn with. By the piston pump ( 3 ) leads an intake pipe ( 2 ). With the intake pipe ( 2 ) Fresh air is sucked in for the pilot. The consumed warm air rises in the glass bulb ( 6 ) and is through the intake pipe ( 2 ) blown off. The glass bulb ( 6 ) is from a glass container ( 7 ), which surrounds the glass bulb ( 6 ) encloses airtight.

To get off the glass flask ( 6 ) lowered down. The valves in the glass container ( 7 ) will be opened. The vacuum in the glass container ( 7 ) sucks in air and the glass bulb ( 6 ) descends to a rack with access down. If there is no parking space, the space glider can be blocked by hot air in the glass dome ( 1 ) are kept stationary in the air. By means of an elevator system, which in the glass bulb ( 6 ), the glass bulb bottom ( 29 ) for getting in and out, loading and unloading further lowered. The elevator system is connected to the electric motor ( 3 ) operated.

When the air from the glass container ( 7 ) from the piston pump ( 3 ) is suctioned, creates a suction, the glass bulb ( 6 ) sucks upwards.

The glass container ( 7 ) is from a vacuum container ( 4 ) enclosed. This prevents the air in the glass bulb ( 6 ) gets hot.

The lights for the interior ( 11 ) of the glass dome ( 1 ) and the external radiators ( 12 ) are supplied with power from the accumulator ( 9 ) provided. The interior lights ( 11 ) are around the accumulator ( 9 ) appropriate. The outdoor spotlights ( 12 ) are between the exhaust air systems ( 14 ). The space glider glides at night and fog with the outdoor floodlights ( 12 ).

To avoid that the hot air in the glass dome ( 1 ), the cooler air in the glass dome ( 1 ) through the exhaust air systems ( 14 ) drained. The exhaust air is still very warm. It is supplied by the intake systems ( 18 ) of the compressors ( 21 sucked). The exhaust air systems ( 14 ) are located above the intake systems ( 18 ). The space ( 20 ) below the glass dome floor ( 13 ) is through the inner lower dome ( 19 ) and the compressors ( 21 ) limited. It is used to transport liquid and solid materials. The access is therefore variable.

The nozzles ( 24 ) must be placed inside when landing. As a result, the landing can be slowed down.

To maintain equilibrium, the air in the glass dome ( 1 ) be hotter than those under the inner lower dome ( 19 ).

The stand area ( 27 ) is electromagnetic and is used to salvage the same size space glider.

The space glider is represented graphically symetrical, therefore, the names apply on the one hand for the other side.

On the large button-transporting space gliders following the power lines, the smaller space gliders can be moved by means of the arc-shaped current collector ( 23 ) dock. As a result, they save electricity as they glide in the lee.

The production of the space glider is considerably cheaper than the known vehicles.

The cost of road maintenance is eliminated because there is only air traffic. Also, the skin charge does not have to be paid. The environment is spared. Fuel is no longer needed. Oil supplies are spared.

The airspace is used in many layers.

The space gliders are using the vacuum glider Alpha DE 4316247 transported to the exploration of the planets and their moons. The vacuum glider is manufactured by the German Aerospace Center (DLR).

LIST OF REFERENCE NUMBERS

1

Glass dome and glass dome room

2

intake

3

Electric motor, piston pump

4

vacuum vessel

5

Hot air ducts

6

flask

7

glass container

8th

door

9

accumulator

10

Seat and fittings

11

interior lights

12

outdoor spotlight

13

Glass dome floor

14

exhaust systems

15

skids

16

power line

17

Hot air pipes

18

intake systems

19

Inner lower dome

20

three-dimensionality

21

compressors

22

solar system

23

Bow shaped pantograph strap

24

jet

25

foot

26

extended outer dome

27

footprint

28

Glass flask, hatched

29

Glass bulb bottom, hatched

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 4316247 [0021]

Claims (31)

The space glider is characterized in that it consists of a hemispherical glass dome ( 1 ), an intake pipe ( 2 ), an electric motor and piston pump ( 3 ), a vacuum container ( 4 ), Hot air channels ( 5 ), an accumulator ( 9 ), a seat and fittings ( 10 ), a glass bulb bottom ( 29 ), an elevator system in the glass bulb ( 6 ), Interior lights ( 11 ), Outdoor spotlights ( 12 ), a glass cupola floor ( 13 ), a power line ( 16 ), a slide rail ( 16 ), from 2 sliding shoes ( 15 ), Exhaust air systems ( 14 ), Hot air tubes ( 17 ), Intake systems ( 18 ), an inner lower dome ( 19 ), Space for liquid and solid substances ( 20 ), Kompreßoren ( 21 ), Solar system ( 22 ), a pantograph bracket ( 23 ), Nozzles ( 24 ), Foot ( 25 ), an elongated outer dome ( 26 ) and a stand ( 27 ) consists. Apparatus according to claim 1, characterized in that the glass dome ( 1 ) a glass dome space ( 1 ), which passes through the glass cupola floor ( 13 ) is hermetically sealed. Apparatus according to claim 1, characterized in that in the glass dome space ( 1 ) of the glass bulb ( 6 ) is centrally positioned. Apparatus according to claim 1, characterized in that on the ceiling of the glass bulb ( 6 ) the electric motor and the piston pump ( 3 ) are adjusted. Apparatus according to claim 1, characterized in that the intake pipe ( 2 ) between the electric motor and piston pump ( 3 ) is adjusted. Device according to claim 1, characterized in that the seat ( 10 ), centrally in the glass bulb ( 6 ) on the glass dome floor ( 13 ) is circularly movable, is attached. Device according to claim 1, characterized in that the fittings ( 10 ) around the glass bulb ( 6 ) are adjusted in range of the pilot. Apparatus according to claim 1, characterized in that the elevator system for the glass piston bottom ( 29 ) in the glass flask ( 6 ) is adjusted. Apparatus according to claim 1, characterized in that the glass bulb ( 6 ) from a glass container ( 7 ) is enclosed. Apparatus according to claim 1, characterized in that the vacuum container ( 4 ) encloses the glass container. Apparatus according to claim 1, characterized in that the hot air ducts ( 5 ) above the hot air tubes ( 17 ) around the vacuum container ( 4 ) are arranged. Apparatus according to claim 1, characterized in that the accumulators ( 9 ) around the hot air ducts ( 5 ) on the glass dome floor ( 13 ) are attached. Device according to claim 1, characterized in that the interior lights ( 11 ) on the outside of the accumulators ( 9 ) are attached. Device according to claim 1, characterized in that the external radiators ( 12 ) between the exhaust air systems ( 14 ) are arranged. Apparatus according to claim 1, characterized in that the exhaust air systems ( 14 ) on the glass dome floor ( 13 ) and the glass dome ( 1 ) are mounted. Apparatus according to claim 1, characterized in that the glass dome bottom ( 13 ) completes the upper half of the half space shuttle. Apparatus according to claim 1, characterized in that the power line ( 16 ) around the glass dome floor ( 13 ). Apparatus according to claim 1, characterized in that the slide rail ( 16 ) the power line ( 16 ) covers Device according to claim 1, characterized in that the two sliding shoes ( 15 ) opposite one another on the slide rail ( 16 ) are mounted. Apparatus according to claim 1, characterized in that the arcuate pantograph bracket ( 23 ) on the two sliding shoes ( 15 ) is attached. Apparatus according to claim 1, characterized in that the hot air tubes ( 17 ) in the center of the inner lower dome ( 19 ) and under the hot air ducts ( 5 ) are mounted. Apparatus according to claim 1, characterized in that the intake systems ( 18 ) below the glass dome floor ( 13 ) and below the exhaust air systems ( 14 ) on the extended outer dome ( 26 ) are mounted. Apparatus according to claim 1, characterized in that the compressors ( 21 ) within the extended outer dome ( 26 ) and below the intake systems ( 18 ) to the foot ( 25 ) are mounted. Device according to claim 1, characterized in that the spatiality ( 20 ), around the space glider, bounded by the glass cupola floor ( 13 ), the inner lower dome ( 19 ) and the compressors ( 21 ) is arranged. Device according to claim 1, characterized in that the foot ( 25 ) is the lowest annular part of the space slider. Device according to claim 1, characterized in that the nozzles ( 24 ) below the compressors ( 21 ) are mounted. Apparatus according to claim 1, characterized in that the solar system ( 22 ) on the extended outer dome ( 26 ), around the space glider, bounded by the intake systems ( 18 ) and nozzles ( 24 ), is mounted. Apparatus according to claim 1, characterized in that the footprint ( 27 ) is electromagnetic. Device according to claim 1, characterized in that the inner lower dome ( 19 ) is the lower half of the hemispherical space glider. Device according to claim 1, characterized in that the glass dome ( 1 ) with the extended outer dome ( 26 ) form a hemisphere. Apparatus according to claim 1, characterized in that the glass bulb ( 6 ) is circularly movable, even in the lowered state.

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