JP2686523B2 - Hydrogen fuel gauge - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a hydrogen fuel gauge provided in a hydrogen storage tank, and in particular, can measure the hydrogen remaining quantity accurately at low cost. It relates to a hydrogen fuel gauge.

(Prior Art) Conventionally, there has been known a method of storing hydrogen by storing a hydrogen storage alloy in a hydrogen storage tank and causing the hydrogen storage alloy to store hydrogen. In this case, rare earth LaNi ₅ or the like is used as the hydrogen storage alloy.

In addition, in order to measure the remaining amount of hydrogen in the hydrogen storage tank, various methods for measuring the remaining amount of hydrogen are used.

Such a method for measuring the remaining amount of hydrogen is as follows: (1) For example, the temperature T of the hydrogen storage alloy and the pressure P (hydrogen equilibrium pressure) in the hydrogen storage tank are detected by a temperature and pressure sensor, and Van't shown in FIG. A method of obtaining the remaining amount of hydrogen from the Hoff diagram and the PCT curve shown in FIG. 4 has been considered.

Here, FIG. 3 shows the relationship between lnP and 1 / T when the hydrogen composition H / M in the hydrogen storage alloy is constant, and FIG. 4 shows lnP at each temperature T ₁ , T ₂ . And the relationship between H / M.

Specifically, a three-dimensional map of the temperature T, the pressure P, and the hydrogen composition H / M is created in advance from FIGS. 3 and 4, and based on the detected temperature and the detected pressure, the hydrogen is calculated based on the three-dimensional map. I'm looking for the remaining amount.

Since this method for measuring the remaining amount of hydrogen is generally performed by a microcomputer, the installation cost of the remaining hydrogen meter becomes high.

(2) In addition, in the PCT curve shown in Fig. 4, the plateau region (the region where pressure is flat and generally used as fuel) is inclined by making the composition of the alloy into a multi-element system. A method of obtaining the remaining amount of hydrogen by changing the pressure to a primary value and measuring this pressure is considered.

However, in this measurement method, the hydrogen pressure shifts, so that the measurement accuracy is very poor except in a place where the temperature is stable, and the temperature is forcibly raised and lowered at the time of hydrogen release and occlusion, so that measurement becomes impossible at all. .

(3) Furthermore, a method is also considered in which a mass flowmeter is provided between the hydrogen supply system and the consumption system and the hydrogen storage tank to measure the amount of transferred hydrogen, and the amount of hydrogen stored in the alloy is subtracted from the maximum amount of hydrogen storage. .

However, mass flow meters are very expensive (about 800,000 yen or more), and have a problem that they lack simplicity.

(Problems to be Solved by the Invention) In order to measure the remaining amount of hydrogen in the hydrogen storage tank as described above, various methods for measuring the remaining amount of hydrogen have been considered.

However, (1) temperature T, pressure P and hydrogen composition
In the method of creating a three-dimensional H / M map and obtaining the remaining hydrogen amount from the detected temperature and detected pressure based on the three-dimensional map, there is a problem in that the installation cost is high because a microcomputer or the like is used. is there. (2) Alternatively, in the method of obtaining the remaining hydrogen amount by inclining the plateau region of the PCT curve, there is a problem that the measurement accuracy is very poor except in the place where the temperature is stable. (3) Further, the method of measuring the moving hydrogen flow rate by providing a mass flow meter and subtracting from the maximum hydrogen storage amount of the alloy has a problem that the installation cost becomes high.

The present invention has been made in view of such a point, and an object of the present invention is to provide an inexpensive hydrogen remaining amount meter that can accurately measure the remaining amount of hydrogen.

[Configuration of the invention]

(Means for Solving the Problems) The present invention provides a storage box made of a hydrogen gas permeable material in a hydrogen storage tank, and stores a hydrogen storage alloy that causes a volume change by the hydrogen storage amount in the storage box, A thin tube whose upper end is opened is provided outside the storage box, and a detection liquid that moves according to the volume change of the hydrogen storage alloy is filled in the thin tube, and a magnetic float is provided on the upper surface of the detection liquid in the thin tube. And a magnetic ring that moves with the magnetic float and displays the hydrogen remaining amount outside the thin tube.

(Operation) Depending on the amount of hydrogen remaining in the hydrogen storage tank, the volume of the hydrogen storage alloy in the storage box changes, and the detection liquid in the capillaries moves according to the volume change of this hydrogen storage alloy. The remaining amount of hydrogen can be displayed by detecting the movement of the liquid by the magnetic ring via the magnetic float.

(Example) Hereinafter, an example of the present invention is described with reference to drawings.

1 and 2 are views showing an embodiment of a hydrogen fuel gauge according to the present invention. FIG. 1 is a sectional side view of the hydrogen fuel gauge, and FIG. 2 is a diagram showing characteristics of the hydrogen storage alloy. FIG.

In FIG. 1, a hydrogen storage alloy is stored in the hydrogen storage tank 31.
32 are stored. As the hydrogen storage alloy 32, for example, rare earth-based LaNi ₅ , LaNi _4,7 Al _0,3 or the like is used a particulate alloy that causes a volume change depending on the hydrogen storage amount, and the particle size of the hydrogen storage alloy 32 is adjusted in advance. ing.

 Next, the configuration of the hydrogen fuel gauge 10 will be described.

A mounting seat 33 is provided at the upper opening of the hydrogen storage tank 31. The mounting seat 33 has a cylindrical sintered metal filter
The holding body 11 having 14 is placed and fixed by a set screw 25. The space between the mounting seat 33 and the holder 11 is sealed by the O-ring 15.

The sintered metal filter 14 extends into the hydrogen storage tank 31, and the hydrogen storage alloy 13 is housed inside. The hydrogen storage alloy 13 housed in the sintered metal filter 14 has the same composition as the hydrogen storage alloy 32 stored in the hydrogen storage tank 31, but is pulverized by repeating storage and release of hydrogen. Compression molded alloys are used to prevent this.

The sintered metal filter 14 is made of bronze with good heat conductivity and allows hydrogen gas to permeate, but the alloy pulverized from the hydrogen storage tank 31 side is made of a sintered metal filter.
14 is not to enter. Further, the shape of the sintered metal filter 14 is a cylindrical shape elongated in the vertical direction, and for example, the ratio of the diameter to the length is 1/5.

A cylindrical space 11a is formed in the holding body 11, and this space 11a communicates with the inside of the sintered metal filter 14 attached below. The diameter in the space 11a is larger than the diameter in the sintered metal filter 14, and the sintered metal filter 14
A step portion 14a connected to the holding body 11 is formed at the upper end of the. Further, in this space 11a, an internal magnet that comes into contact with the upper surface of the hydrogen storage alloy 13 housed in the sintered metal filter 14 is provided.
17 are provided. The internal magnet 17 has a space 11a corresponding to the volume change of the hydrogen storage alloy 13 accompanying the change of the hydrogen storage amount.
It is possible to move up and down inside. Also, the space 11a
A disc spring 16 that presses the internal magnet 17 toward the upper surface of the hydrogen storage alloy 13 is interposed between the upper surface of the internal magnet 17 and the internal magnet 17. Further, the internal magnet 17 is formed with a plurality of through holes 17a that penetrate the internal magnet 17 in the vertical direction. This through hole 1
7a is formed at a position corresponding to the stepped portion 14a of the sintered metal filter 14, and therefore, the space 11 in which the disc spring 16 is provided 11
The hydrogen gas in a can be communicated with the hydrogen storage tank 31 through the through hole 17a and the step portion 14a.

Further, at the top of the holding body 11, the diaphragm chamber 27
A display body 27 in which a and a liquid chamber 27b are formed is provided. Of these, the diaphragm chamber 27a is located below and the liquid chamber 27b is located above and communicates with each other. The cross-sectional area of the liquid chamber 27b is the diaphragm chamber 2
It is much smaller than the cross section of 7a. Also,
The liquid chamber 27b is arranged vertically and has an open top.

A diaphragm 19 is arranged in the diaphragm chamber 27a, and an external magnet 18 is attached to the lower surface of the diaphragm 19. The outer magnet 18 is arranged at a position facing the inner magnet 17 across the upper wall of the holder 11, and is movable with the inner magnet 17 always at a predetermined distance by the repulsive force of magnetism. . Therefore, as the inner magnet 17 moves in the vertical direction, the outer magnet 18 also moves, which causes the diaphragm 19 to move in the vertical direction.

Further, a nonvolatile liquid (detection liquid) 20 is stored above the diaphragm 19, and this nonvolatile liquid 20 reaches from the diaphragm chamber 27a to the liquid chamber 27b. Also the liquid chamber 27b
On top of the non-volatile liquid 20 inside, float magnetic float 35
Is arranged. Further, a magnetic ring 36 that moves together with the magnetic float 35 by magnetic force is slidably attached to the outside of the liquid chamber 27b. The display body 27 is entirely covered with a cover body 28, and the cover body 28 is filled with an inert gas, for example, an argon gas. The inert gas prevents corrosion due to a chemical reaction between the nonvolatile liquid 20 and air.

The cover 28 is made of a metal material with a glass window,
A hydrogen remaining amount display portion 29 is drawn on the glass window of the cover body 28. The magnetic ring 3 attached to the outside of the liquid chamber 27b
Reference numeral 6 indicates a predetermined position of the hydrogen remaining amount display portion 29.

Next, the operation of the present embodiment having such a configuration will be described.

First, FIG. 2 shows a hydrogen storage alloy 13, 32, for example, LaNi _4,7 Al
The characteristics of _{0 and 3} will be described.

FIG. 2 shows the hydrogen storage amount (hydrogen composition) on the horizontal axis and the volume change rate on the vertical axis, and the number of hydrogen storage and release N = 5,10,1
5 shows a volume change rate corresponding to 5.

This volume change rate is detected as the amount of movement in the -axis direction (opening direction), and is calculated ignoring the change in the side wall direction.

As shown in FIG. 2, the volume change rate of the hydrogen storage alloy, that is, the amount of movement in the opening direction changes linearly in accordance with the change in the hydrogen storage amount. Therefore, the amount of hydrogen occlusion can be measured by detecting the volume change rate of the hydrogen occlusion alloy.

In the hydrogen fuel gauge 10 of FIG.
Since it is gas permeable, the sintered metal filter 14
The hydrogen storage alloy 13 therein and the hydrogen storage alloy 32 in the hydrogen storage tank 31 have the same hydrogen storage amount. In this case, when the hydrogen storage amount of the hydrogen storage alloy 32 in the hydrogen storage tank 31 increases, the hydrogen storage amount of the hydrogen storage alloy 13 in the sintered metal filter 14 also increases accordingly and the volume increases linearly. . In this way, the hydrogen storage alloy 13 in the sintered metal filter 14 is
When the volume of the internal magnet 1 in the space 11a of the holder 11 increases,
7 is pushed up by hydrogen storage alloy 13.

On the other hand, the hydrogen storage alloy stored in the hydrogen storage tank 31.
When hydrogen is released from 32 and consumed, the volume of the hydrogen storage alloy 13 in the sintered metal filter 14 decreases, and the internal magnet 17 is pressed by the disc spring 16 and moves downward.

When the inner magnet 17 moves up and down in the space 11a in this manner, the outer magnet 18 also moves at a predetermined interval from the inner magnet 17 due to the repulsive force due to the magnetism, and thus the diaphragm.
19 moves up and down.

A through hole 17a is formed in the internal magnet 17, and the disc spring 16
Hydrogen gas pressure and hydrogen storage tank 3 in the space 11a provided with
Since the hydrogen gas pressure in 1 is equal, the internal magnet 17
The up and down movement of the is not affected by the hydrogen gas pressure.

Next, as the diaphragm 19 moves in the vertical direction, the non-volatile liquid 20 contained in the diaphragm chamber 27a and the liquid chamber 27b moves in the vertical direction. In this case, the magnetic float 35 is disposed on the upper surface of the non-volatile liquid 20, and the liquid chamber 27b
A magnetic ring 36 that moves together with the magnetic float 35 to display the predetermined position of the hydrogen remaining amount display unit 29 is attached to the outside of the, so that the remaining amount of hydrogen can be accurately measured by this magnetic ring 36. .

As described above, according to this embodiment, since the magnetic ring 36 that moves with the magnetic float 35 by magnetic force to display the hydrogen remaining amount display portion 29 is attached to the outside of the liquid chamber 27b, the hydrogen remaining amount can be clearly displayed to the outside. can do.

〔The invention's effect〕

As described above, according to the present invention, the volume of the hydrogen storage alloy changes according to the residual hydrogen in the hydrogen storage tank, and when the detection liquid in the narrow tube moves according to the volume change of the hydrogen storage alloy, Since the ring moves together with the magnetic float on the upper surface of the detection liquid by magnetic force to display the remaining hydrogen amount, the remaining hydrogen amount can be clearly displayed on the outside.

[Brief description of the drawings]

FIG. 1 is a side sectional view showing an embodiment of a hydrogen fuel gauge according to the present invention, FIG. 2 is a view showing characteristics of a hydrogen storage alloy, FIG. 3 is a Van't Hoff diagram of the hydrogen storage alloy, FIG. FIG. 4 is a diagram showing a PCT curve of the hydrogen storage alloy. 10 ... Hydrogen fuel gauge, 11 ... Holder, 11a ... Space, 13 ...
… Hydrogen storage alloy, 14 …… Sintered metal filter, 17 …… Internal magnet, 18 …… External magnet, 19 …… Diaphragm, 20 …… Nonvolatile liquid, 27 …… Display body, 27a …… Diaphragm chamber, 2
7b ... Liquid chamber, 35 ... Magnetic float, 36 ... Magnetic ring.

Claims (1)

(57) [Claims] 1. A storage box made of a hydrogen gas permeable material is provided in a hydrogen storage tank, and a hydrogen storage alloy that causes a volume change depending on the amount of stored hydrogen is stored in the storage box. An open thin tube is provided vertically, and the thin tube is filled with a detection liquid that moves according to a change in volume of the hydrogen storage alloy, and a magnetic float is arranged on the upper surface of the detection liquid in the thin tube. A hydrogen fuel gauge, characterized in that a magnetic ring that moves with the magnetic float to display the hydrogen remaining amount is provided outside the.