KR20000038575A - Apparatus for measuring curvature radius of lens - Google Patents

Abstract

PURPOSE: An apparatus for measuring a curvature radius of a lens is provided to relatively facilitate the measurement of a curvature radius with respect to the plural lenses by providing a probe minutely moving upwards and downwards. CONSTITUTION: A body(10) is formed in a disc shape. A supports(15) is mounted to support the body(10) from below the body(10). A magnet scale(20) having a head part(24) and a scale part(22) is mounted on the center of the upper side of the body(10). A probe(30) is connected with the scale part(22) of the magnet scale(20) to minutely move upwards and downwards. The lower portion of the probe(30) is located in the center of a lens to measure a curvature radius and the upper portion of the probe(30) is connected to the head part(24).

Description

Curvature radius measuring instrument

The present invention relates to a curvature radius measuring device of the lens, in particular, because the distance between the meter connected to the magnifier and the support in the triangular position in the horizontal position, the radius of curvature of the lens that can easily measure the curvature of the lens by the trigonometry It relates to a measuring instrument.

In general, the measuring equipment is equipped with a sensor suitable for each measurement, the sensor displays the measurement amount in analog or digital to provide information about the measurement to the user.

Among the measurement equipment, a number of equipments for measuring curvature of optical elements such as lenses have been developed, and the principle of such measurement equipment is mostly measured according to the optical principle using the optical function of the lens.

On the other hand, the curvature of the lens determines the distance to the imaging point of the lens, the focal length, and the like, and is a radius display of the concave or convex degree of the lens. Most of the equipment for measuring the curvature of the lens is based on the optical properties of the lens. That is, the curvature of the lens is determined as follows when the distance between the lens and the object and the distance between the lens and the imaging point are known.

Here, r is the radius of curvature of the lens, a is the distance between the lens and the object, b is the distance between the lens and the imaging point.

As described above, the curvature of the lens was measured based on the optical properties of the lens.

However, when measuring the curvature of a plurality of lenses, it is cumbersome to measure all the basic values of the optical properties of the lens, and if you want to know the difference in curvature between the plurality of lenses as described above It is very difficult and inconvenient to measure the individual curvature of.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a curvature radius measurer for a lens that can easily measure the curvature of a lens and, in particular, can easily determine a difference in curvature between a plurality of lenses.

In order to achieve the above object, the present invention provides a device for measuring the curvature of a spherical body, a support body, each of which is standing upright at an equilateral triangular position at a lower portion of the body, and is installed at an upper center of the body. It is achieved by providing a curvature radius measuring device for a lens consisting of a magnification scale consisting of a portion and a scale portion, and a meter portion that is addressed to the scale portion of the magnesscale and is installed through the center of the support and moved up and down.

1 is an exploded perspective view of a measuring device according to an embodiment of the present invention;

2 is a side cross-sectional view of FIG.

3 is an explanatory diagram schematically illustrating the principle of the measuring device of the present invention;

Figure 4 is a state of use of the measuring device according to the present invention.

<Explanation of symbols for main parts of drawing>

10: body 15: support

20: magnesite 22: scale portion

24: head portion 30: meter reading

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The present invention, as shown in Figure 1, the body 10 of the disk-shaped body, the support 15 and each standing upright in the equilateral triangular position at the bottom of the body 10, and in the upper center of the body 10 It is installed to the magnet scale 20 composed of the head portion 24 and the scale portion 22, and the scale portion 22 of the magnesia scale 20 is penetrated at the center position of the support 15, the upper and lower It consists of the metering unit 30 is fine.

The body 10 is formed of a disk-shaped surface plate.

The support 15 is installed in the equilateral triangle position from the lower side of the body, respectively.

In the center of the triangular position of the support 15, that is, the central position of the support 15, a through hole is formed in the body 10, and a metering portion 30 penetrates the through hole.

The lower end of the meter 30 is a curvature measuring unit is located in the center of the lens, the upper end is connected to the head portion 24 of the magnet scale (20).

Thus, when the meter reading unit 30 is moved up and down while measuring the curvature of the lens, the head portion 24 is interlocked according to the position of the microscopic movement.

The magnet scale 20 is a general position measuring instrument using a magnet.

It is composed of a magnetic lattice and a magnetic head, and measures the position according to the amount of movement of the magnetic head to move the pitch of the magnetic lattice. The head part 24 is provided with a magnetic head, and the scale part 22 ) Is provided with a magnetic lattice.

Thus, as shown in FIG. 2, when the metering unit 30 slides up and down, the head unit 24 is interlocked, and when the head unit 24 is interlocked, the magnetic head is a magnetic lattice of the scale unit 22. While moving the position corresponding to the movement amount is displayed.

In the display of the movement amount for the vertical movement of the meter reading part 30, when the pitch of the scale part 22, which is the magnetic lattice, is divided, the resolution is improved and the resolution is 1 to 10 μm by interpolation.

In addition, the scale part 22 is standing up on the center of the body (10).

Next, with reference to the contents shown in Figures 3 and 4 will be described the operation of the present invention made as described above.

First, the measuring device of the present invention is located on a horizontal surface of the body 10 and a horizontal position.

Thus, the meter reading part 30 is brought into contact with the floor, and the reset switch (not shown) of the magnet scale 20 is set while the meter reading part 30 is in contact with the floor, and the numerical value displayed on the head part 24 is determined. Adjust zero.

In the state where the meter reading part 30 is placed on the bottom surface and the value is zero, the lens to be measured is placed on the bottom surface in a horizontal position with the body.

When one surface of the lens is placed on the floor, the surface having the curvature of the lens faces upward, and at this time, the measuring device is positioned at the top of the lens.

When the meter is positioned on the top of the lens, the supports are placed in the triangular position x on the upper surface of the lens, respectively.

As described above, in the state in which the support 15 is positioned on the upper surface of the lens, the meter 30 is moved to the upper end of the lens.

When the meter unit 30 is microscopically positioned at the center position m of the lens, the head unit 24 of the magnet scale 20 is in a state in which the meter unit 30 is placed on the bottom surface when the lens is a convex lens. Since it is finely moved upward, it is placed on the upper side while reading the scale portion 22 of the magnet scale 20.

Thus, the head portion 24 measures the curvature of the lens.

Curvature measurement of such a lens is as follows.

As shown in FIG. 4, if the distance between the support 15 and the metering unit 30 is A, the head 24 of the magnesia scale 20 is moved up and down along the curvature of the lens at the initial bottom position. The distance corresponds to d.

From this,

According to the above equation, the curvature of the lens is as follows.

Therefore, since the numerical value read by the magnesia scale 20 is d, and the distance A between the metering part 30 and the support stand 15 is known, the curvature of a lens can be calculated | required easily.

In addition, when one wants to measure the relative curvature between the lens and the lens, one of the lenses is first positioned below the support 15, and then the head portion 24 of the magnet scale 20 is zeroed.

Thus, by placing another lens at the lens position and sliding the meter unit 30 upward of the lens, it is possible to easily measure the relative curvature of the other lens relative to the lens.

When the curvature of the lens is measured in this way, when the head portion 24 of the magnesia scale 20 reads the scale portion 22 and has a positive value, the curvature has a positive value and it can be seen that it is a convex lens. When the read value has a negative value, the curvature has a negative value and it can be seen that it is a concave lens.

As described above, in the present invention, the meter portion 30 which is finely conveyed up and down is connected to the head portion 24 of the magnesia scale 20 to measure the curvature of the lens from the position of the meter portion 30, Since the curvature of the lens is measured using the magnet scale 20, it is easy to measure the relative curvature between the lenses.

The curvature radius measuring device of the present invention is a mechanism for measuring the curvature of a lens using a magnetic scale, a magnetic measuring device from a simple principle by a trigonometry, while the curvature of the lens can be easily measured, and the relative curvature measurement of a plurality of lenses is easier. There is a losing effect.

Claims (1)

In the apparatus for measuring the curvature of a sphere, Body 10; Supports 15 which are respectively installed standing in the equilateral triangular position at the bottom of the body (10); A magnet scale 20 installed at an upper center of the body 10 and configured of a head part 24 and a scale part 22; And Curvature radius measuring device of the lens, characterized in that made up of the metering portion 30 which is addressed to the scale portion 22 of the magnet scale 20 and penetrated and installed at the center position of the support 15.