JP2601889B2 - Alkali metal thermoelectric converter - Google Patents

Description

Description: BACKGROUND OF THE INVENTION The present invention relates to an alkali metal thermoelectric converter, and more particularly to the above device used as a power supply system for space equipment.

[Conventional technology]

Alkali Metal Thermo El Converter
As shown in FIG. 2, the principle of ectric convertor (hereinafter referred to as AMTEC) is that an alkali metal (for example, Na) (for example, Na) heated to 600 to 1000 ° C. on the high-temperature heating side has a vapor pressure of 0.03 to 0.03. 2.6atm), β ″ -alumina solid electrolyte (has an action of selectively permeating alkali metal ions)
Through the inside, electrons are neutralized by obtaining electrons on the electrode (+) surface and evaporated (β ″ -alumina solid electrolyte is sufficiently thin, and thus the electrode is at a high temperature, and the neutralized alkali metal is removed by this electrode. Heated to evaporate), 100-500 ° C (vapor pressure 10 ^-9 -10 ^-2 at
Liquefies on the cold side of m).

When the external circuit is open, electric charges accumulate on the electrode (+) surface due to the difference in Na vapor pressure between the β ″ -alumina solid electrolyte, and a release voltage is generated in a direction to stop the flow of Na ⁺ ions. When the circuit is closed, the Na ⁺ ion becomes the electrode (+)
Electrons are obtained on the surface and neutralized, pass through a porous electrode, evaporate in a vacuum (vacuum is drawn for quick evaporation of neutralized Na), and liquefy on the low-temperature condensing surface .

[Problems to be solved by the invention]

The conventional AMTEC method described above has the following problems.

(1) Since the high-temperature side Na finally moves to the low-temperature side,
Na disappears on the high temperature side, and power generation stops.

Conventionally, as a countermeasure for this, FIG. 3 (A) (overall view)
(B) As shown in the (plan view), continuous power generation is enabled by a method of refluxing Na on the low temperature side to the high temperature side using a pump, but not only the system and structure are complicated, Since it has a drive unit (only in the case of a mechanical pump, there is no problem in the case of an electromagnetic pump), there is a problem in reliability.

(2) Since the entire system is not a closed system, there are the following problems on the heating side and the cooling side.

On the cooling side, a vacuum system is required, and the system becomes complicated.

Since Na is active on the heating side, a cover gas system such as argon gas is required, and a trap for removing mist generated from high-temperature Na is also required.

(3) According to the above (1) and (2), there are various problems in making the thermoelectric exchange section a closed cycle of a completely closed system due to the sealing property with the outside and the system configuration.

Therefore, an object of the present invention is to propose an AMTEC device that performs a continuous power generation by alternately repeating an open cycle, instead of a closed cycle, but a closed cycle.

[Means for solving the problem]

The object of the present invention is to provide a rotary cylinder at the outer central portion of a completely closed cylindrical container formed by a metal cylinder having a bottom at the upper end and a lower end and a central portion made of an insulating material at the central portion. Is installed so that the cylindrical container can be vertically exchanged by rotation, and a β ″ -alumina solid electrolyte is installed as a partition in the central cylindrical portion of the cylindrical container to partition the inside of the cylindrical container into two upper and lower chambers. An alkali metal is vacuum-sealed in the cylindrical container, metal wicks are arranged on both sides of the inner wall surface of the cylindrical container except for the central cylindrical portion and the wall surface of the β ″ -alumina solid electrolyte, and inner wall surfaces of the upper and lower chambers are provided. This is achieved by an alkali metal thermoelectric converter characterized in that the above metal wick and the metal wick on the β ″ -alumina solid electrolyte wall are connected by a metal bridge wick.

[Operation] In the apparatus of the present invention, one end of the cylindrical container is set as the heating side, and the other end is set as the cooling side, and the liquid alkali metal vacuum-sealed inside the container is heated and evaporated.

At this time, the liquid alkali metal is sucked upward by the capillary action of the metal wick (a wool-like metal having a capillary force) provided on the inner wall of the container or the wall of the β ″ -alumina solid electrolyte.

Since the above-mentioned heating side heats the metal wick portion that has sucked up the liquid alkali metal, it acts as a so-called heat pipe and performs extremely effective heating.

This alkali metal vapor, according to the principle of AMTEC,
It permeates the β ″ -alumina solid electrolyte provided as a partition at the center of the container, reaches the cooling side, is cooled and condensed, and accumulates here.

In this way, when the liquid alkali metal on the heating side moves to the cooling side, the rotating rod is rotated and the container is turned upside down.

And the part that was the heating side until now is the cooling side,
The portion that was on the cooling side acts as the heating side, and power can be continuously generated without moving the liquid alkali metal.

〔Example〕

FIG. 1 is an explanatory view showing one embodiment of the apparatus of the present invention.

In FIG. 1, a β ″ -alumina solid electrolyte 1 is installed as a partition in a central cylindrical portion in a cylindrical container 2 by a support 14. The partition has a shape of an alkali metal 6 as shown in FIG.
It is desirable to increase the contact area between the solid electrolyte 1 and the β ″ -alumina solid electrolyte 1.

In the cylindrical container 2, the center tube 3 is made of an insulating material such as ceramics, and both end tubes 4, 5 are made of a metal such as stainless steel or Inconel.

An alkali metal (here, N
a) 6 is vacuum sealed.

A metal wick (also serving as an electrode) 7 is disposed on both surfaces of the β ″ -alumina solid electrolyte 1, and metal wicks 8 are also provided on the inner surfaces of the metal end tubes 4 and 5 of the cylindrical container 2. Is arranged.

The metal wick 7 and the metal wick 8 are partially formed of a metal bridge wick (a liquid alkali metal, for example,
Na is passed freely).

In the figure, the upper part of the cylindrical container 2 is the heating side 10 and the lower part is the cooling side 11, and the load 12 is connected to the high-temperature (heating) side 10 and the low-temperature (cooling) side 11 made of metal end tubes 4,5. It is connected.

A rotating rod 13 is mounted near the center of the cylindrical container 2 and is rotated so that the cylindrical container 2 can be turned upside down.

In the example shown in FIG. 1, a cylindrical vessel with a flange, which is relatively inexpensively available, is used as the β ″ -alumina solid electrolyte 1. Therefore, the structure is not vertically symmetrical, but the electrodes are functionally arranged on both sides. Is vertically symmetrical with respect to the β ″ -alumina solid electrolyte 1 on which the metal wick 7 is disposed, and the same function as before the inversion can be exerted even when it is inverted upside down.

In the apparatus of the present invention having such a configuration, the liquid alumina metal 6 is sucked upward by the capillary action of the metal wicks 7, 8. When the heating side 10 is heated in this state,
The heating side 10 has the function of a so-called heat pipe, so that the liquid alkali metal 6
Can be heated.

The heated liquid alkali metal 6 evaporates, and the above-described AM
According to the principle of TEC, it passes through β ″ -alumina solid electrolyte 1,
It reaches the cooling side 11, condenses, and accumulates on the cooling side 11 surface.

At this time, the circuit in FIG. 1 is an alkali metal (heating side) 6 → a metal wick (heating side) 8 → both-end cylinder (heating side)
4 → load 12 → both end tubes (cooling side) 5 → metal wick (cooling side) 8 → bridge wick (cooling side) 9 → metal wick (cooling side) 7 and electrons flow in this direction, and the current flows in the opposite direction. Flowing in the direction, the cooling side becomes the positive electrode, and the heating side becomes the negative electrode.

In this way, when the liquid alkali metal 6 on the heating side 10 is depleted, the voltage and current of power generation decrease.

This is electrically detected, the rotating rod 13 is rotated, the cylindrical container 2 is rotated, and the cylindrical container 2 is turned upside down.

Then, the part which existed in the lower part and acted as the cooling side 11 and stored the liquid alkali metal moved to the upper part, acted as the heating side, and the part which existed in the upper part and acted as the heating side 10 became the lower part. To act as a cooling side.

That is, the heating side 11 heats and evaporates the liquid alkali metal 6 stored here and sucked upward by the action of the capillary of the metal wick 7, the bridge wick 9, and the metal wick 8, and evaporates the β ″ -alumina solid electrolyte. 1 and move to the cooling side 10. The alkali metal vapor is cooled on this cooling side 10, condenses and accumulates on the surface of the cooling side 10.

As a result, the same circuit as described above is formed in an upside down manner, and power generation is continuously performed only by switching the polarity of the load.

The above operation can be intermittently repeated to continuously generate power.

In this example, the liquid alkali metal (Na) 6 on the heating side is used.
Is electrically detected, but other detection means such as a liquid level meter may be used.

〔The invention's effect〕

According to the device of the present invention described in detail above, the following effects can be obtained.

(1) Since it is a sealed container, no extra system is required, and the purity of the active liquid alkali metal sealed inside is effectively maintained.

(2) Since there is no drive unit for moving the liquid alkali metal, the reliability is high.

(3) Since the configuration is simple, the cost of the apparatus is low, and the number of failures of the apparatus is extremely small.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing an embodiment of the apparatus of the present invention, and FIG.
FIG. 3 is a diagram showing the principle of AMTEC, and FIG. 3 is a diagram showing an example of a conventional apparatus. FIG. 3 (A) is an overall view, and FIG. 3 (B) is a plan view.

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Katsuhiko Hamada 1-1-1, Wadazakicho, Hyogo-ku, Kobe City, Hyogo Prefecture Inside the Mitsubishi Heavy Industries, Ltd.Kobe Shipyard (72) Inventor Naoaki Ikeda, Hyogo-ku, Kobe City, Hyogo Prefecture 1-1 1-1 Tazakicho Mitsubishi Heavy Industries, Ltd., Kobe Shipyard

Claims (1)

(57) [Claims] 1. A metal cylinder having a bottom at an upper end and a lower end,
A rotating rod is installed at the center of the outside of a completely closed cylindrical container having a central portion formed of a central tube made of an insulating material, and the cylindrical container is rotatable up and down by rotation. A β ″ -alumina solid electrolyte is installed in a central cylindrical portion of the inside as a partition for dividing the inside of the cylindrical container into upper and lower two chambers, and an alkali metal is vacuum-sealed in the cylindrical container to remove the central cylindrical portion. The metal wicks are disposed on both sides of the inner wall of the container and the β ″ -alumina solid electrolyte, and the metal wick on the inner wall of the container in both upper and lower chambers and the metal wick on the wall of the β ″ -alumina solid electrolyte are made of metal. An alkali metal thermoelectric converter connected by a bridge wick.