JP2595469Y2 - Microgravity test equipment equipped with a cooling furnace - Google Patents

Description

[Detailed description of the invention]

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a zero gravity test apparatus, and more particularly, to a microgravity test apparatus having a furnace capable of rapidly cooling a high-temperature sample.

[0002]

2. Description of the Related Art In the fields of biotechnology, metal, electronics, fine ceramics and the like, experiments in a zero gravity state are desired. As means for obtaining such a state close to complete weightlessness (hereinafter referred to as a microgravity state), a method using space, a method using ballistic flight of an airplane or the like, a method using a falling tower, and the like are currently known. In particular, the drop-type microgravity test device is less affected by disturbances such as weather and driving techniques than in space or ballistic flight. It has the characteristic that can be.

FIG. 2 shows an example of a falling-type microgravity experimental device currently under development. This experimental device
A capsule comprising a thruster module 1, a payload module 2, and a bus module 3 is provided, and the capsule is dropped in a vertical pit provided with a total length of 700 m or more provided underground so that a microgravity state is realized in the capsule. Has become. The thruster module 1 includes an upward gas jet nozzle (not shown), and accelerates the capsule downward to reach a microgravity state in a short time. Further, by compensating the resistance due to the air by the precise control of the gas jet, a more complete weightless state can be realized in the capsule. An experimental device is built in the payload module 2 so that various experiments can be performed in a microgravity state. The bus module 3 contains various devices for supporting the experiment, such as a power supply and a data transmission device.

[0004] The above-mentioned drop type microgravity experimental apparatus is used to
0 ^-3 G (micro G) can be realized in the payload module for more than 10 seconds.

[0005]

In an experiment to develop a new material under such microgravity, it is necessary to move the sample from the heating furnace to the cooler in a short time while holding the sample under microgravity. . In this case, in the microgravity experiment, since the entire experiment time is short (for example, 10 seconds or less), it is necessary to move the sample from the heating furnace to the cooling furnace in a very short time (for example, within 1 second). However, in a conventional experimental apparatus equipped with an electric furnace, the temperature of the end of the electric furnace was lower than that of the central part, and the heating furnace had to be considerably long in order to heat the sample uniformly. In particular, when the end of the heating furnace is opened so that the sample can be easily removed from the heating furnace, the cooling of the end is remarkable, and the total length of the heating furnace needs to be further increased.
For this reason, it took a relatively long time to move the sample from the heating furnace to the cooler, which significantly restricted the entire experiment.

[0006] The present invention has been made to solve such a problem, and while holding a sample under microgravity,
Provides a microgravity experimental device equipped with an additional furnace with a cooler that can move a sample from a heating furnace to a cooler in a short time and maintain a microgravity state from the molten state until the test piece solidifies The purpose is to do.

[0007]

According to the present invention, there is provided a microgravity test apparatus for performing an experiment in a microgravity state close to zero gravity, which has an inner capsule (10) inside and has a zero gravity.
An outer capsule (11) held in a near microgravity state ;
One end (12a) is fixed to the outer capsule and the other end (12a).
b) is located in the inner capsule and the other end of the sample (5)
An axially extending support rod (1
2), a heating furnace (14) fixed in the inner capsule and surrounding the other end of the support rod, and a cooler (1) fixed in the inner capsule adjacent to the heating furnace in the axial direction.
6), wherein the heating furnace and the cooler are arranged in the axial direction.
Each having an opening therethrough, wherein the openings are axially
Linearly aligned and said inner capsule (10)
It is possible to move inside the outer capsule (11) in the axial direction.
As a result, the outer capsule (11) is brought into a microgravity state.
Move the inner capsule (10) in the axial direction while holding
The heated sample (5) in microgravity
A microgravity experimental apparatus provided with a cooler-added heating furnace, wherein the apparatus is moved from a heating furnace to a cooler while holding the furnace .

[0008]

According to the structure of the present invention, the sample (5) is fixed to the other end (12b) of the support rod (12) and heated by the heating furnace (14) in a microgravity state close to zero gravity. . Since this heating furnace includes a plurality of heat pipes extending in the axial direction, the internal temperature can be made uniform to the end, and the total length of the heating furnace can be shortened as compared with the related art.

During cooling, the outer capsule (11) is
While maintaining the state of small gravity, the inner capsule (10) is
By moving in the linear direction, the heated sample (5)
While maintaining microgravity, the same inner capsule (1
0) A heating furnace (14) and a cooler (16) fixed in
Moves in the axial direction, the heating furnace moves out of the position of the sample, and the cooler surrounds the sample. This operation is simply outside
While the capsule (11) is kept in the microgravity state and the inner capsule (10) is moved only by a small distance in the axial direction, the process is completed.
The sample can be moved from the heating furnace to the cooler in a short time.

The above operation is extremely simple because the heating furnace and the cooler each have openings penetrating in the axial direction, and the openings are axially aligned with each other.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a partial configuration diagram showing a payload module of the microgravity experimental device according to the present invention. In this figure, the payload module of the microgravity experimental device includes an outer capsule 11 containing an inner capsule 10 and a support rod 12 extending in the axial direction. Support rod 12
Has one end 12a fixed in the outer capsule 11 and the other end 12b positioned in the inner capsule 10, and the sample 5 is attached to the other end 12b. The payload module of the microgravity experiment apparatus further includes a heating furnace 14 fixed inside the inner capsule 10 and surrounding the other end 12b of the support rod 12, and an inner side of the inner capsule 10 adjacent to the heating furnace 14 in the axial direction. And a cooler 16 fixed to the cooling device.

The outer capsule 11 is a hermetically sealed container constituting the main body of the payload module, and the above-mentioned thruster module 1 and bus module 3 can be attached to each other vertically. The inner capsule 10 is also a closed container, and the space between the inner capsule 10 and the outer capsule 11 is kept in a vacuum. Further, the inside of the inner capsule 10 is kept in a state suitable for an experiment, for example, a vacuum, a reducing atmosphere, or an oxidizing atmosphere.

Further, the inner capsule 10 can be freely moved in the axial direction by well-known means, for example, the rail 24 and the linear guide 26, and can be moved in the axial direction by a driving device (not shown).

Although one end 12a of the support rod 12 is fixed to the upper end of the outer capsule 11 in the illustrated example, it may be fixed to the lower end. Further, the number of the support rods 12 is not limited to one, and a plurality of support rods 12 may be arranged at intervals. The support rod 12 penetrates a part of the inner capsule 10, and this penetrating portion is hermetically sealed by well-known means (not shown), for example, an O-ring. The attachment of the sample 5 to the other end 12b of the support rod 12 is performed by an arbitrary method, for example, a pin, a screw, a fitting, welding, or the like. The sample 5 may be directly attached to the support rod 12, or may be housed in a suitable container, for example, a heat-resistant container made of ceramic, and this container may be attached to the support rod 12.

The heating furnace 14 and the cooler 16 have openings 14a, 16a penetrating in the axial direction.
16a are axially aligned with each other. Heating furnace 1
4 is fixed to the inner surface of the inner capsule 10. Thus, the sample 5 can be moved from the heating furnace 14 to the cooler 16 in a short time only by moving the inner capsule 10 by a small distance in the axial direction.

The heating furnace 14 surrounds the other end 12b of the support rod 12 and has a plurality of heat pipes 18 extending in the axial direction.
A heater 20 for heating the heat pipe 18 and a heat insulating material 22 for preventing heat radiation of the sample 5 and the heater 20 are provided. The heat pipe 18 is provided closely around the sample 5 so that the sample 5 can be uniformly heated.
The heat pipe 18 may be made of an appropriate medium in accordance with the heating temperature of the heating furnace 14. Particularly, in a high-temperature furnace in which metal is melted, a pipe and a wick are formed of tantalum using liquid sodium as a medium. Things are good. In such a heat pipe, heating at 1000 ° C. or higher, preferably about 1250 ° C., can be performed. The heat pipe has the property of maintaining a substantially constant temperature over the entire length, and therefore, the end of the heating furnace 14 can be maintained at substantially the same temperature as the central portion.

The heater 20 is preferably an electric resistor or a coil for induction heating, but is not limited to this. Further, the heater 20 may be shorter than the heat pipe 18 due to the uniform temperature characteristics of the heat pipe.

The cooler 16 has a hollow cylindrical shape and contains a liquid having a low boiling point, for example, water. With this configuration, the cooler 16 is kept at a low temperature by evaporating the liquid inside,
The sample can be cooled effectively. Furthermore, the cooler 1
6 is provided with a cooling gas line (not shown) for flowing a cooling gas through its opening 16a so as to increase the cooling rate. In particular, when the sample 5 is small, the cooler 16 may be a solid metal cylindrical shape, for example, a pipe made of pure copper.

According to the configuration of the present invention, the sample 5 is connected to the other end 1 of the support rod 12 in a microgravity state close to zero gravity.
2b and heated by the heating furnace 14. The heating furnace 14 includes a plurality of heat pipes 18 extending in the axial direction.
Because the temperature inside is uniform to the end,
The total length of the heating furnace is shorter than before. For example, a conventional heating furnace requires about 3 to heat a 50 mm long test piece.
According to the present invention, the total length of the furnace can be reduced to less than half, while an electric furnace of 00 mm is required.

In use, a test piece made of aluminum or an alloy of aluminum-copper or the like is dropped to the vicinity of a melting temperature by using a drop tower in a state where the temperature is raised to around a melting temperature. Outside
After the capsule 11 reaches the microgravity state, the molten state is maintained for 1 to 2 seconds, and then the inner capsule 10 is moved to the outer capsule 1.
1. Rapid cooling by moving in the axial direction of 1 . That is, at the time of cooling, the outer capsule 11 is kept in a microgravity state,
By moving the inner mosquitoes capsule 10 in the axial direction, heating
With the sample 5 kept in the microgravity state,
Heating furnace 14 and cooler 16 fixed in inner capsule 10
Move in the axial direction, the heating furnace moves out of the sample position,
A cooler will surround the sample. This operation is simply
Since the inner capsule 10 is moved only a short distance in the axial direction while the outer capsule 11 is kept in the microgravity state , the sample is transferred from the heating furnace to the cooler for a short time while the sample is kept under the microgravity. That is, it can be moved within one second. Next, while maintaining the microgravity state, the specimen is cooled for about 7 seconds to solidify the test piece.

The above operation is extremely simple because the heating furnace and the cooler each have openings penetrating in the axial direction, and the openings are axially aligned with each other.

[0022]

According to the present invention described above, therefore, the sample can be moved from the heating furnace to the cooler in a short time while the sample is held under microgravity, and from the molten state to the solidification of the test piece. In addition, it is possible to provide a microgravity experiment apparatus provided with a cooler-added heating furnace capable of maintaining a microgravity state.

[Brief description of the drawings]

FIG. 1 is a partial configuration diagram illustrating a microgravity experimental device according to the present invention.

FIG. 2 is an overall configuration diagram of a microgravity experiment apparatus.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Thruster module 2 Payload module 3 Bus module 5 Sample 10 Inner capsule 11 Outer capsule (stand) 12 Support rod 14 Heating furnace 16 Cooler 18 Heat pipe 20 Heater 22 Insulation material 24 Rail 26 Linear guide

Continuation of the front page (56) References JP-A-59-35773 (JP, A) JP-A-4-350492 (JP, A) JP-A-4-335990 (JP, A) JP-A-54-102208 (JP, A) JP-A-61-287226 (JP, A) JP-A-53-59937 (JP, A) JP-A-1-220436 (JP, A) JP-A-51-107535 (JP, A) 51-107536 (JP, A) Fully open 57-138967 (JP, U) Fully open 1984-59,052 (JP, U) Fully open, 57-77897 (JP, U) Fully open, 6-8199 (JP, U.S.) U) (58) Fields investigated (Int. Cl. ⁶ , DB name) B64G 1/66 B64G 7/00 F27B 17/02 F27B 14/04

Claims (1)

(57) [Scope of request for utility model registration] 1. A microgravity experimental apparatus for experimental in close microgravity weightlessness, has an inner capsule (10) on the inside, microgravity near-zero gravity
An outer capsule (11) held in a force state; one end (12a) fixed to the outer capsule (12a);
b) is located in the inner capsule and the other end of the sample (5)
An axially extending support rod (1
2), a heating furnace (14) fixed in the inner capsule and surrounding the other end of the support rod, and a cooler (16) fixed in the inner capsule adjacent to the heating furnace in the axial direction. And the heating furnace and the
The coolers each have an opening therethrough in the axial direction,
The openings are axially aligned with one another and
The capsule (10) is axially inside the outer capsule (11).
The outer capsule (11) is kept in a microgravity state by being movable.
While moving the inner capsule (10) in the axial direction
This keeps the heated sample (5) in a microgravity state.
A microgravity experiment apparatus provided with a cooler-added heat furnace, wherein the microgravity experiment apparatus is moved from a heating furnace to a cooler while being held.