CONCENTRATION DETECTION DEVICE AND THE DETECTION METHOD

Abstract

The present invention provides a concentration detection device, which is used to detect the concentration of liquid fuel within a container. The device comprises: a float, which is floating on the surface of liquid fuel, wherein the upper portion of the float has a figure of a first reference circle, and the float is just formed as a figure of a first intersection circle on the surface of liquid fuel; an image capture device with an imaging plane, wherein the imaging plane is configured upon the float; a sunshade, wherein the sunshade is configured between the imaging plane and the float, and the sunshade is configured with a hole, so the figures of the first reference circle and the first intersection circle could be respectively projected onto the imaging plane through the hole to form a second reference circle and a second intersection circle; a calculation device, which could calculate the concentration of the liquid fuel according to the first and second reference circles and the first and second intersection circles.

Description

BRIEF DESCRIPTION OF DRAWINGS

The foregoing aspects, as well as many of the attendant advantages and features of this invention will become more apparent by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:

FIG. 1A is a side view of a preferred embodiment for a concentration detection device according to the present invention;

FIG. 1B is a perspective view of the concentration detection device in FIG. 1A;

FIGS. 2A and 2B are the concentration detection method of liquid fuel for liquid fuel cell according to the present invention, and

FIG. 3 is an image captured on the imaging plane (140) in FIG. 1B.

Claims

1. A concentration detection method of liquid fuel for liquid fuel cell, comprising the steps of: (a) providing a float with radius R, wherein the upper portion of the float has a figure of a first reference circle, and the radius of the first reference circle is r, and the angle formed by one point on the first reference circle, the center of mass for the float, and the center of circle for the first reference circle is α1,(b) making the float floating on the surface of the liquid fuel, and making the first reference circle sustaining upon the surface of the liquid fuel, in which the float is just formed as a figure of a first intersection circle on the surface of the liquid fuel;(c) providing an imaging plane, in which the imaging plane is configured above the float in step (a);(d) providing a sunshade, in which the sunshade is configured between the imaging plane and the float, and the sunshade is configured with a hole, and the vertical distance between the hole and the imaging plane is f, so the figures of the first reference circle and the first intersection circle could be respectively projected onto the imaging plane through the hole to form a second reference circle and a second intersection circle, in which each coordinate variable for the point coordinate (u, v) on the second reference circle and the point coordinate (x, y) on the second intersection circle could be satisfied with the following equations: u=(S·cos θ·cos φ−R·cos α1·sin θ·cos φ+R·sin α1·cos(β+φ))·(−f)/(−S·sin θ−R·cos α1·cos θ+R·cos α1·F);v=(S·cos θ·sin φ−R·cos α1·sin θ·sin φ+R·sin α1·sin(β+φ))·(−f)/(−S·sin θ−R·cos α1·cos θ+R·cos α1·F);x=(S·cos θ·cos φ−R·cos α·sin θ·cos φ+·sin α·cos(β+φ))·(−f)/(−S·sin θ−R·cos α·cos θ+R·cos α−F);y=(S·cos θ·sin φ−R·cos α·sin θ·sin φ+R·sin α·sin(β+φ))·(−f)/(−S·sin θ−R·cos α·cos θ+R·cos α−F);

2. The concentration detection method of liquid fuel according to claim 1, wherein, in step (e), the calculation device could calculate the S value based on a function S=r·(a/b), wherein a is the distance between the geometrical center G of the second reference circle and the origin 0 of the imaging plane, and b is the distance between one point on the second reference circle in the line GO direction and the geometrical center G.

3. The concentration detection method of liquid fuel according to claim 2, wherein, in step (e), the calculation device could calculate the F value based on a function F=f·(c1/c2), wherein c2 is the distance between one point on the second reference circle in the direction vertical to line GO passing the origin O and the geometrical center G; and, c1 is calculated by the function c1=√(r2−S2).

4. The concentration detection method of liquid fuel according to claim 1, wherein the β value in step (f) is between 0 and 2π.

5. The concentration detection method of liquid fuel according to claim 1, wherein the α value in step (f) is not less than α1.

6. A concentration detection device, which is used to detect the concentration of liquid fuel within a container, the concentration detection device comprises: a float, which is floating on the surface of liquid fuel, wherein the upper portion of the float has a figure of a first reference circle, and the float is just formed as a figure of a first intersection circle on the surface of liquid fuel;an image capture device with an imaging plane, wherein the imaging plane is configured upon the float;a sunshade, which is configured between the imaging plane and the float, in which the sunshade is configured with a hole, so the figures of the first reference circle and the first intersection circle could be respectively projected onto the imaging plane through the hole to form a second reference circle and a second intersection circle;a calculation device, which could calculate the concentration of the liquid fuel according to the first and second reference circles and the first and second intersection circles.

7. The concentration detection device according to claim 6, wherein the float is a ball.

8. The concentration detection device according to claim 6, wherein the image capture device is a CCD sensing device.

9. The concentration detection device according to claim 6, wherein the image capture device is a CMOS sensing device.

10. The concentration detection device according to claim 6, further comprises at least one light emitting device, which are configured on the inner wall of the container, below the sunshade, and above the surface of the liquid fuel.

11. The concentration detection device according to claim 6, wherein the container is a fuel supply tank for supplying the fuel required by a liquid fuel cell.

12. The concentration detection device according to claim 6, wherein the liquid fuel is a methanol aqueous solution.

13. The concentration detection device according to claim 10, wherein the light emitting device is a light emitting diode.

14. The concentration detection device according to claim 11, wherein the liquid fuel cell is a direct methanol fuel cell.

15. The concentration detection device according to claim 6, wherein the calculation device could calculate the vertical distance between the hole and the surface of the liquid fuel based on the data of the first and second reference circles, and the first and second intersection circles to obtain the level of the liquid fuel within the container.