JPS6144375A - Apparatus for locating magnetic field measuring apparatus - Google Patents

Abstract

PURPOSE:To fix the magnetic field measuring element attached to the leading end of a slidable arm body at the desired position in a magnetic field, by providing a slidable main shaft body to an X-axis while providing the slidable arm body to Y- and Z-axes. CONSTITUTION:A handle 14 for X-axis movement is rotated to move a main shaft body 11 in an X-axis direction and the position of a Hall element 8 is determined on the X-axis. Next, a handle 17 for Y-axis movement is rotated to move an arm body 12 in a Y-axis direction while a handle 23 for X-axis direction is rotated to move the arm body 12 on the Z-axis and the positions of the Hall element 8 are determined on Y- and Z-axes. By this method, the Hall element 8 can be easily located at the predetermined position in a space.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a magnetic field measuring element positioning device for fixing a VCI field measuring element at a predetermined position in a space within a magnetic field.

[Prior art]

FIG. 1 is a perspective view showing an example of a conventional magnetic field probe positioning device, in which a pair of I-axis scale slopes and a Y-axis scale plate J are fixed to a cylindrical object L. Grooves λa and Ja are formed at equal intervals on the X-axis scale plate 7 and the y-axis scale plate 7, respectively. Both ends of the I-axis fixing jig 5 and the Y-axis fixing jig 5 are fitted into the grooves Ja, ja, respectively. At the point where the X-axis fixing jig and the Y-axis fixing jig intersect at right angles, there is a space (a two-axis fixing jig that can move in two of the two axes of the set orthogonal coordinate system, χ and V). A tool 6 is provided. At the tip of this two-axis fixing jig 6, for example, a Hall element is attached as a magnetic field measuring element. This Hall element t is guided in the z-axis direction along the railte VC. It looks like this.

The conventional magnetic field measuring element positioning device is configured as described above, and when positioning the Hall element t in a predetermined space, first, the predetermined groove JaKx-axis fixing jig V is inserted into the X-axis scale plate 2.
The position of the Hall element on the X-axis is fixed by fitting both ends of the Hall element. Next.

Both ends of the y-axis fixing jig 5 are fitted into a predetermined groove J a K of the y-axis scale plate J, and the position of the Hall element t on the y-axis is fixed. Furthermore, the position on the two axes is determined by sliding the Hall element l attached to the two-axis fixing jig Al' (on the rail yVcG).

A predetermined position of the Hall element g in space is set.

When changing the position of the Hall element t, use the -X t y-axis fixing jigs N and j to χ and y-axis scale plates, respectively.

Remove from the grooves a, 7a of J and repeat the above operation.

Since the conventional magnetic field measuring probe positioning device is configured as described above, when positioning on the Hall elements t (') x and V es, the X and Y axis fixing jigs, ! 1
1.2a, had to be removed from Ja, 1 workability was poor, the positioning of the Hall element t could not be easily set, and 1 the shape and dimensions of the cylindrical object were matched! , 7-axis scale plate, J, x, y-axis fixing jig.

This method has drawbacks such as the need to prepare s and the like.

[Summary of the Invention] This invention was made with the aim of eliminating the above-mentioned drawbacks, and one unit is provided with nine vertical main shafts that can slide in the By providing a slidable arm body orthogonally to each other and attaching a magnetic field measuring probe to the tip of this arm body.

To provide a magnetic field measuring element positioning device that can easily fix a magnetic field measuring element at a predetermined position in space by moving a main shaft body and an arm body.

[Embodiments of the invention]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the magnetic field probe positioning device of the present invention will be described below with reference to the drawings. FIG. 2 is a front view showing an embodiment of the present invention, and FIG. 3 is a side body shown in FIG. There is.

An I-axis scale /j is attached to the front wall of the table 10 along the longitudinal direction of the table /Q. A handle/4' for moving the X-axis is provided on the side of the stand IO.

By operating this X-axis moving handle 4', the slide base/guide rail, which is a component of the main shaft body, moves in the X-axis direction. The position of the main shaft body /l is x@ pointed by the X-axis pointer /6
This can be determined from the value on the scale/J scale. A y-axis moving handle 17 is attached to the upper part of the main shaft body //. By operating this handle 17, the zfi rod/2 and the bearing block θ which constitute the arm body lλ
moves in the Y-axis direction. The position of this arm body can be known from the value on the scale of the y-axis scale indicated by the y-axis pointer 1. A two-axis moving handle 23 is attached to the arm i2. From operating this handlebar J, z! 111
The rod can move in two axes. At this time, the position of the two-axis rod lde is.

It can be known from the value of the scale set on the two-axis rod/9 itself pointed by the two-axis pointer, 2hiro. A Hall element t, which is a magnetic field measuring element, is attached and swung to the tip of the arm body 1 via a fixture. Note that λ6 is a two-axis fine adjustment handle.

In the magnetic field probe positioning device configured as described above, by turning the X-axis moving handle//, the main shaft body// is moved in the X-axis direction, and the position of the Hall element on the X-axis is determined. Then, by first turning the y-axis moving handle 17, the arm body/g is moved in the y-axis direction, and the position of the Hall element g on the y-axis can be determined. After that, by turning the two-axis movement handle λJ, the two-axis rod l of the arm body/λ? is moved in the Z411 direction, and the 2 of Hall element C is
The position on the axis is determined and z#! The Hall element t attached to the tip 9 of the h rod 19 is set at a predetermined position in the orthogonal coordinate system.

Furthermore, since this device stands upright on the floor, it can also be positioned inside a cylindrical object.

Furthermore, for each sliding part of the main shaft body// and the arm body/2, we do not use ordinary bearings, but instead use non-magnetic bushings and packing, and we also use non-magnetic materials for the gears. In addition, special consideration is given to welding and cutting of each component to prevent non-magnetic deterioration. The device itself also has the unique property of not being affected by magnetism.

In the above embodiment, the case where the magnetic field probe is set at a predetermined position in space has been explained, but of course, even if the space is a strong magnetic field or high frequency value field, the magnetic field probe of this device can be set at a predetermined position. Easy to set up.

Furthermore, it goes without saying that if wheels are provided on the stand 10, transportation of the entire apparatus will be made easier.

〔Effect of the invention〕

As explained above, according to the magnetic field probe positioning device of the present invention, the magnetic field probe can be easily set at a predetermined position in space, and the workability of the magnetic field probe positioning device is greatly improved. effective.

[Brief explanation of drawings]

FIG. 1 is a perspective view showing an example of a conventional magnetic field probe positioning device, FIG. 1 is a front view showing an embodiment of the present invention, and FIG. 3 is a side view of FIG. 1. S...Hall element (magnetic field measuring element), 10-ψ level. //-・Main shaft body, l・・arm body, 13・−slide base, /l・・guide rail 5 /de・−2-axis rod・・ko Qψ
・Bearing block. In addition, in each figure, the same reference numerals indicate the same or equivalent parts. -r,'ls

Claims (1)

[Claims] A base, a main shaft that is installed perpendicular to the base and can slide in the x-axis direction of the two axes of the orthogonal coordinate system set in space, and a main shaft that is perpendicular to the main shaft. It is provided in
A magnetic field probe positioning device, wherein the main shaft body and the arm body are made of a non-magnetic material.