KR102041548B1 - Waveguide feeding alignment device and method - Google Patents

Abstract

Disclosed are a waveguide feeding alignment apparatus and method. A formation unit 10 which forms a feeding structure 12 on the Teflon substrate 11 on which one side surface of the square plate protrudes in a square shape; And placing the Teflon substrate 11 having one side surface of the square plate protruding in a square shape on the alignment unit 20, and contacting the protruding edge of the alignment unit 20 to the cut edge of the Teflon substrate 11. And an alignment portion 20 for aligning the waveguide 21 with the square feeding 13 of the substrate 11. Therefore, the protruding edge of the alignment unit 20 contacts the cut edge of the Teflon substrate 11 so that the waveguide 21 can be aligned with the square feeding 13 of the Teflon substrate 11, and the square feeding 13 One side of the wave guide 21 is aligned to one surface of the antenna loss is reduced, the position of one surface of the square feeding 13 is calculated, and one surface of the wave guide 21 is one surface of the square feeding 13 After alignment to the waveguide 21 is fixed to the Teflon substrate 11, the antenna loss can be reduced.

Description

Waveguide Feeding Alignment Device and Method {WAVEGUIDE FEEDING ALIGNMENT DEVICE AND METHOD}

The present invention relates to a waveguide feeding alignment device and method, and more particularly to a waveguide feeding alignment device and method for aligning the waveguide 21 to the square feeding (13).

The waveguide feeding alignment device aligns the waveguide 21 and the square feeding 13. The antenna loss increases as the waveguide 21 and the square feeding 13 are aligned left or right. To reduce antenna loss, the waveguide 21 and the square feeding 13 must be correctly aligned. The conventional waveguide feeding alignment device aligns the waveguide 21 and the square feeding 13, but there is a problem that the reliability of the product is lowered because the antenna loss is different for each antenna component because the two components are not properly aligned.

Registration Number: 10-1693843, Chip-to-Chip Interface Using Microstrip Circuits and Dielectric Waveguides Registration Number: 10-1375938, Chip-to-Chip Interface Using Low-Power, High-Speed Multi-Channel Dielectric Waveguide

SUMMARY OF THE INVENTION An object of the present invention for solving the above problems is to provide a waveguide feeding alignment device and method for correctly aligning the waveguide 21 in the square feeding (13).

The present invention for achieving the above object, Forming portion 10 for forming a feeding structure 12 on the Teflon substrate 11, one side surface of the rectangular plate protruding in a square shape; And placing the Teflon substrate 11 having one side surface of the square plate protruding in a square shape on the alignment unit 20, and contacting the protruding edge of the alignment unit 20 to the cut edge of the Teflon substrate 11. And an alignment portion 20 for aligning the waveguide 21 with the square feeding 13 of the substrate 11.

In addition, the Teflon substrate 11 has a feeding structure 12 placed in the center, and a thin film arranged parallel to the feeding structure 12 is formed, and the feeding structure 12 protrudes a predetermined length from the thin film and has a square feeding end. It is formed of 13, and protects the feeding structure 12 and the thin film and has a bottle shape.

In addition, the alignment unit 20 aligns one surface of the wave guide 21 on one surface of the rectangular feeding 13.

In addition, the alignment unit 20 includes a camera 21 for photographing the square feeding 13; And a fixing part 22 for calculating the position of one surface of the square feeding 13, aligning one surface of the wave guide 21 to one surface of the square feeding 13, and then fixing the wave guide 21 to the Teflon substrate 11. ).

In addition, the step of forming a feeding structure 12 on the Teflon substrate 11, one side of the rectangular plate protruding in a square shape; And placing the Teflon substrate 11 having one side surface of the square plate protruding in a square shape on the alignment unit 20, and contacting the protruding edge of the alignment unit 20 to the cut edge of the Teflon substrate 11. Aligning the waveguide 21 with the square feeding 13 of the substrate 11.

In addition, the Teflon substrate 11 has a feeding structure 12 placed in the center, and a thin film arranged parallel to the feeding structure 12 is formed, and the feeding structure 12 protrudes a predetermined length from the thin film and has a square feeding end. It is formed of 13, and protects the feeding structure 12 and the thin film and has a bottle shape.

In addition, the step of aligning includes aligning one surface of the wave guide 21 on one surface of the rectangular feeding 13.

In addition, the step of aligning is a step in which the camera 21 photographs the square feeding 13; Calculating the position of one surface of the rectangular feeding 13; And aligning one surface of the wave guide 21 to one surface of the square feeding 13 and then fixing the wave guide 21 to the Teflon substrate 11.

In the case of using the waveguide feeding alignment device and method according to the present invention as described above, the projected edge of the alignment portion 20 is in contact with the cut edge of the Teflon substrate 11, the square feeding 13 of the Teflon substrate 11 ), The waveguide 21 can be aligned.

In addition, one surface of the wave guide 21 is aligned with one surface of the square feeding 13, so that antenna loss is reduced.

In addition, the position of one surface of the square feeding 13 is calculated, and one surface of the wave guide 21 is aligned with one surface of the square feeding 13, and then the waveguide 21 is fixed to the Teflon substrate 11 to reduce antenna loss. Can be small.

1 is an exemplary view showing a waveguide 21 feeding structure 12 of a millimeter waveband system.
2 is an exemplary view showing a Teflon substrate 11.
3 shows an example of a misalignment.
4 is a block diagram showing the configuration of the waveguide feeding alignment device.
5 is an exemplary view showing a Teflon substrate 11.
6 is an exemplary view in which one surface of the wave guide 21 is aligned with one surface of the rectangular feeding 13.
7 is a block diagram showing another embodiment of the waveguide feeding alignment device.
8 is an operation flowchart of a waveguide feeding alignment method.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

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

The waveguide feeding alignment device aligns the waveguide 21 with the feeding structure 12. The waveguide feeding alignment device aligns the waveguide 21 with the square feeding 13 of the feeding structure 12 formed on the Teflon substrate 11.

The waveguide feeding alignment device fixes the waveguide 21 to the Teflon substrate 11 by aligning one surface of the waveguide 21 on one surface of the square feeding 13.

1 is an exemplary view showing a waveguide 21 feeding structure 12 of a millimeter waveband system.

A feeding structure 12 is formed on the Teflon substrate 11, and the waveguide 21 is aligned with the feeding structure 12.

2 is an exemplary view showing a Teflon substrate 11.

The Teflon substrate 11 has a bottle shape.

The feeding structure 12 is formed on the Teflon substrate 11.

The feeding structure 12 is placed in the center, and a thin film arranged parallel to the feeding structure 12 is formed, and the feeding structure 12 protrudes from the thin film at a predetermined length and is formed with a square feeding 13 at an end thereof. The structure 12 and the thin film are protected and have a bottle shape.

3 shows an example of a misalignment.

FIG. 3A shows that the feeding structure 12 is misaligned to the right of the waveguide 21 and FIG. 3B shows that the feeding structure 12 is misaligned to the left of the waveguide 21.

4 is a block diagram showing the configuration of the waveguide feeding alignment device.

The forming unit 10 forms a feeding structure 12 on the Teflon substrate 11 on which one side surface of the square plate protrudes in a square shape. The forming unit 10 forms the antenna feeding structure 12 on the Teflon substrate 11. The antenna feeding structure 12 has a thin film arranged in both sides parallel to the feeding structure 12 placed in the center, the feeding structure 12 is formed by protruding a predetermined length from the thin film and the end of the square feeding 13 The Teflon substrate 11 protects the feeding structure 12 and the thin film and has a bottle shape.

The alignment unit 20 is a teflon substrate 11 on which one side of the square plate protrudes in a square shape on the alignment unit 20 and the protruding edge of the alignment unit 20 at the cut edge of the Teflon substrate 11. Contact and align the waveguide 21 with the square feeding 13 of the Teflon substrate 11.

The alignment unit 20 aligns one surface of the wave guide 21 to one surface of the square feeding 13.

The alignment unit 20 aligns the square bottom surface of the wave guide 21 with the square bottom surface of the square feeding 13.

The alignment unit 20 minimizes antenna loss by aligning one surface of the square feeding 13 and one surface of the wave guide 21.

5 is an exemplary view showing a Teflon substrate 11.

The Teflon substrate 11 has a feeding structure 12 placed in the center thereof, and a thin film arranged parallel to the feeding structure 12 is formed, and the feeding structure 12 protrudes a predetermined length from the thin film and ends at a square feeding 13. And protects the feeding structure 12 and the thin film and has a bottle shape.

6 is an exemplary view in which one surface of the wave guide 21 is aligned with one surface of the rectangular feeding 13.

One surface of the wave guide 21 is aligned with one surface of the square feeding 13.

The square bottom surface of the wave guide 21 is aligned with the square bottom surface of the square feeding 13.

7 is a block diagram showing another embodiment of the waveguide feeding alignment device.

The alignment unit 20 includes a camera 21 for photographing the square feeding 13; And a fixing part 22 for calculating the position of one surface of the square feeding 13, aligning one surface of the wave guide 21 to one surface of the square feeding 13, and then fixing the wave guide 21 to the Teflon substrate 11. ).

The camera 21 photographs the square feeding 13.

The fixing unit 22 calculates the position of one surface of the square feeding 13, aligns one surface of the wave guide 21 with one surface of the square feeding 13, and then fixes the wave guide 21 to the Teflon substrate 11. Let's do it.

The fixing unit 22 calculates the position of the square bottom surface of the square feeding 13, aligns the square bottom surface of the wave guide 21 with the square bottom surface of the square feeding 13, and then moves the wave guide 21 to Teflon. It is fixed to the board | substrate 11.

8 is an operation flowchart of a waveguide feeding alignment method.

The waveguide feeding alignment method will be described.

The waveguide feeding alignment device includes a program memory for storing a program, a data memory for storing data, and a processor for executing the program.

Referring to the data stored in the program memory, the program memory may include forming a feeding structure 12 on the Teflon substrate 11 on which one side surface of the square plate protrudes in a square shape (S81); And placing the Teflon substrate 11 having one side surface of the square plate protruding in a square shape on the alignment unit 20, and contacting the protruding edge of the alignment unit 20 to the cut edge of the Teflon substrate 11. Aligning the waveguide 21 with the square feeding 13 of the substrate 11 (S82).

The waveguide feeding alignment device executes a program stored in a program memory by a processor.

The procedures performed by the waveguide feeding alignment device will be described in chronological order.

The waveguide feeding alignment device forms a feeding structure 12 on the Teflon substrate 11 on which one side of the square plate protrudes in a square shape. The waveguide feeding alignment device forms an antenna feeding structure 12 on the Teflon substrate 11. The antenna feeding structure 12 is placed in the center, and a thin film arranged parallel to the feeding structure 12 is formed, and the feeding structure 12 is formed by protruding a predetermined length from the thin film and having a square feeding 13 at an end thereof. The feeding structure 12 and the thin film are protected and have a bottle shape.

The waveguide feeding alignment device puts the Teflon substrate 11 on which one side of the square plate protrudes in a square shape and contacts the protruding edges to the uneven edges of the Teflon substrate 11, and the square feeding of the Teflon substrate 11. The waveguide 21 is aligned with (13).

The waveguide feeding alignment device aligns one surface of the waveguide 21 to one surface of the square feeding 13.

The waveguide feeding alignment device aligns the square bottom surface of the wave guide 21 with the square bottom surface of the square feeding 13.

The waveguide feeding alignment device minimizes antenna loss by aligning one surface of the square feeding 13 and one surface of the waveguide 21.

The camera 21 photographs the square feeding 13.

The waveguide feeding alignment device calculates the position of one surface of the square feeding 13, aligns one surface of the wave guide 21 to one surface of the square feeding 13, and then fixes the waveguide 21 to the Teflon substrate 11. Let's do it.

The waveguide feeding alignment device calculates the position of the square bottom surface of the square feeding 13, aligns the square bottom surface of the wave guide 21 with the square bottom surface of the square feeding 13, and then moves the waveguide 21 to Teflon. It is fixed to the board | substrate 11.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

10: forming portion 11: teflon substrate
12: feeding structure 13: square feeding
20: alignment section 21: wave guide

Claims (8)

A formation unit 10 which forms a feeding structure 12 on the Teflon substrate 11 on which one side surface of the square plate protrudes in a square shape;
Place the Teflon substrate 11 protruding in a square shape on one side of the square plate on the alignment unit 20 and contacting the protruding edges of the alignment unit 20 to the uneven corners of the Teflon substrate 11. And an alignment unit 20 for aligning the waveguide 21 with the square feeding 13 of the teflon substrate 11,
The alignment unit 20 includes a camera 21 for photographing the square feeding 13; And
The position of one surface of the square feeding 13 is calculated, one surface of the wave guide 21 is aligned with one surface of the square feeding 13, and the wave guide 21 is fixed to the Teflon substrate 11. Waveguide feeding alignment device comprising a fixed portion (22). The method of claim 1,
The Teflon substrate 11 has the feeding structure 12 placed in the center thereof, and a thin film arranged parallel to the feeding structure 12 is formed. Waveguide feeding alignment device is formed of a square feeding (13), and protects the feeding structure (12) and the thin film and has a bottle shape. The method of claim 1,
The alignment unit 20 is a wave guide feeding alignment device for aligning one surface of the wave guide 21 on one surface of the rectangular feeding (13). delete Forming a feeding structure 12 on the Teflon substrate 11 on which one side of the square plate protrudes in a square shape; And
Place the Teflon substrate 11 protruding in a square shape on one side of the square plate on the alignment unit 20 and contacting the protruding edges of the alignment unit 20 to the uneven corners of the Teflon substrate 11. And aligning the waveguide 21 with the square feeding 13 of the teflon substrate 11,
The aligning may include a step in which the camera 21 photographs the square feeding 13;
Calculating the position of one surface of the rectangular feeding (13); And
And aligning one surface of the wave guide (21) with one surface of the square feeding (13) and then fixing the wave guide (21) to the Teflon substrate (11). The method of claim 5,
The Teflon substrate 11 has the feeding structure 12 placed in the center thereof, and a thin film arranged parallel to the feeding structure 12 is formed. Wave guide feeding alignment method formed of the square feeding (13), and protects the feeding structure (12) and the thin film and has a bottle shape. The method of claim 5,
The aligning step includes aligning one surface of the wave guide (21) on one surface of the rectangular feeding (13). delete

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