KR20190050175A - Waveguide feeding alignment device and method - Google Patents

Abstract

Disclosed are a waveguide feeding arrangement device and a method thereof. The present invention includes: a forming part forming a feeding structure (12) on a Teflon substrate (11) having one side protruding in a square shape; and an align part (20) placing the Teflon substrate (11) having one side protruding in a square shape on the align part (20) and making contact between a grooved corner of the Teflon substrate (11) and a protruding corner of the align part (20), and aligning a waveguide (21) in a square feeding (13) of the Teflon substrate (11). Therefore, the contact between the grooved corner of the Teflon substrate (11) and the protruding corner of the align part (20) enables the waveguide (21) to be aligned in the square feeding (13) of the Teflon substrate (11), one side of the waveguide (21) is aligned on one side of the square feeding (13) to reduce an antenna loss, and the position of one side of the square feeding (13) is calculated, one side of the waveguide (21) is aligned on one side of the square feeding (13), and then, the waveguide (21) is fixed to the Teflon substrate (11) to reduce antenna loss.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a waveguide feeding device,

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

The waveguide feeding alignment device aligns the waveguide 21 and the square feed 13. As the waveguide 21 and the square feed 13 are biased to the left or to the right, the antenna loss increases. The waveguide (21) and the square feed (13) must be properly aligned to reduce antenna loss. The conventional waveguide feeding aligner aligns the waveguide 21 and the square feed 13 but fails to properly align the two parts, so that the antenna loss is different for each antenna part, and the reliability of the product is lowered.

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

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problems described above and to provide a waveguide feeding aligning apparatus and method for properly aligning a waveguide (21) on a square feeding (13).

According to an aspect of the present invention, there is provided a plasma display panel comprising: a forming part (10) for forming a feeding structure (12) on a Teflon substrate (11) having one side of a rectangular plate projecting in a square shape; And a Teflon substrate 11 having a rectangular shape protruding from one side of a rectangular plate are placed on the alignment part 20 and the projected edges of the alignment part 20 are brought into contact with the corners of the Teflon substrate 11, And an alignment portion 20 for aligning the waveguide 21 to the square feed 13 of the substrate 11. [

The Teflon substrate 11 is formed such that the feeding structure 12 is centered and the thin film arranged parallel to the feeding structure 12 is formed and the feeding structure 12 is protruded by a predetermined length from the thin film, (13), which protects the feeding structure (12) and the membrane and has a bottle shape.

In addition, the alignment portion 20 aligns one surface of the waveguide 21 on one surface of the square feed 13.

In addition, the alignment portion 20 includes a camera 21 for photographing the square feeding 13; And a fixing unit 22 for fixing the waveguide 21 to the Teflon substrate 11 after one surface of the waveguide 21 is aligned on one surface of the square feed 13, ).

Forming a feeding structure (12) on a Teflon substrate (11) having one side of a rectangular plate projecting in a square shape; And a Teflon substrate 11 having a rectangular shape protruding from one side of a rectangular plate are placed on the alignment part 20 and the projected edges of the alignment part 20 are brought into contact with the corners of the Teflon substrate 11, And aligning the waveguide (21) to the square feed (13) of the substrate (11).

The Teflon substrate 11 is formed such that the feeding structure 12 is centered and the thin film arranged parallel to the feeding structure 12 is formed and the feeding structure 12 is protruded by a predetermined length from the thin film, (13), which protects the feeding structure (12) and the membrane and has a bottle shape.

In addition, aligning includes aligning one side of the waveguide 21 on one side of the square feed 13.

In addition, the step of aligning includes the steps of the camera 21 photographing the square feed 13; Calculating a one-sided position of the square feed 13; And fixing the waveguide 21 to the Teflon substrate 11 after aligning one side of the waveguide 21 on one side of the square feed 13.

When the apparatus and method for aligning the wave guide according to the present invention as described above are used, the protruding edges of the aligning portion 20 are brought into contact with the corners of the Teflon substrate 11 to form the square feeding 13 of the Teflon substrate 11 The waveguide 21 can be aligned.

Also, one side of the waveguide 21 is aligned on one side of the square feed 13, which reduces the antenna loss.

The waveguide 21 is fixed on the Teflon substrate 11 to align the surface of the square waveguide 13 with one side of the square waveguide 13, Can be reduced.

Figure 1 is an exemplary view showing the waveguide 21 feeding structure 12 of a millimeter waveband system.
2 is an exemplary view showing a Teflon substrate 11. As shown in Fig.
Fig. 3 is a diagram showing an example of a misalignment.
4 is a block diagram showing a configuration of a waveguide feeding alignment apparatus.
5 is an illustration showing an example of a Teflon substrate 11. [
6 is an exemplary view in which one side of the wave guide 21 is aligned on one side of the square feed 13.
7 is a block diagram illustrating another embodiment of a waveguide feeding alignment device.
8 is a flow chart of the operation of the 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 to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

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

The waveguide feeding alignment device aligns the waveguide (21) to the feeding structure (12). The waveguide feeding alignment device aligns the waveguide 21 to the square feed 13 of the feeding structure 12 formed on the Teflon substrate 11. The waveguide feeding alignment device,

The waveguide feeding aligning device aligns one surface of the waveguide 21 on one surface of the square feed 13 to fix the waveguide 21 to the Teflon substrate 11.

Figure 1 is an exemplary view showing the 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. As shown in Fig.

The Teflon substrate 11 has a bottle shape.

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

The feeding structure 12 is centered and a thin film arranged parallel to the feeding structure 12 is formed and the feeding structure 12 is protruded by a certain length from the thin film and the end is formed into a square feed 13, Protects the structure (12) and the film and has a bottle shape.

Fig. 3 is a diagram showing an example of a misalignment.

3a, the feeding structure 12 misaligns to the right of the waveguide 21, and Fig. 3b the feeding structure 12 misaligns to the left of the waveguide 21.

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

The forming portion 10 forms a feeding structure 12 on a Teflon substrate 11 having one side of a rectangular plate projecting in a square shape. The forming portion 10 forms the antenna feeding structure 12 on the Teflon substrate 11. The antenna feeding structure 12 is formed with a thin film arranged on both sides in parallel with the feeding structure 12 placed at the center and the feeding structure 12 is protruded by a predetermined length from the thin film and the tip is formed into a square feed 13 , The Teflon substrate 11 protects the feeding structure 12 and the thin film and has a bottle shape.

The alignment portion 20 is formed by placing a Teflon substrate 11 having a rectangular shape protruding from one side of a rectangular plate on the alignment portion 20 and aligning the projected edges of the alignment portion 20 with the corners of the Teflon substrate 11 And the waveguide 21 is aligned with the square feed 13 of the Teflon substrate 11. [

The alignment portion 20 aligns one surface of the waveguide 21 on one side of the square feed 13.

The alignment portion 20 aligns the rectangular lower end face of the wave guide 21 on the rectangular lower end face of the square feed 13.

The alignment portion 20 aligns one side of the square feed 13 with one side of the waveguide 21 to minimize antenna loss.

5 is an illustration showing an example of a Teflon substrate 11. [

The Teflon substrate 11 is formed such that the feeding structure 12 is centered and a thin film arranged parallel to the feeding structure 12 is formed and the feeding structure 12 is protruded by a predetermined length from the thin film, And protects the feeding structure 12 and the thin film and has a bottle shape.

6 is an exemplary view in which one side of the wave guide 21 is aligned on one side of the square feed 13.

One surface of the wave guide 21 is aligned on one surface of the square feed 13.

The rectangular lower end face of the wave guide 21 is aligned on the rectangular lower end face of the square feed 13.

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

The alignment portion 20 includes a camera 21 for photographing the square feeding 13; And a fixing unit 22 for fixing the waveguide 21 to the Teflon substrate 11 after one surface of the waveguide 21 is aligned on one surface of the square feed 13, ).

The camera 21 photographs the square feed 13.

The fixing section 22 calculates the position of the one surface of the square feed 13 and aligns one surface of the wave guide 21 on one surface of the square feed 13 and then fixes the wave guide 21 to the Teflon substrate 11 .

The fixing section 22 calculates the position of the rectangular lower end surface of the rectangular feed 13 and aligns the rectangular lower end surface of the wave guide 21 to the rectangular lower end surface of the rectangular feed 13, And fixed to the substrate 11.

8 is a flow chart of the operation of the waveguide feeding alignment method.

The wave guide feeding method will be described below.

The waveguide feeding alignment apparatus 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 includes a step S81 of forming the feeding structure 12 on the Teflon substrate 11 having one side of the rectangular plate protruding in a square shape; And a Teflon substrate 11 having a rectangular shape protruding from one side of a rectangular plate are placed on the alignment part 20 and the projected edges of the alignment part 20 are brought into contact with the corners of the Teflon substrate 11, And aligning the waveguide 21 to the square feed 13 of the substrate 11 (S82).

The waveguide feeding alignment apparatus executes the program stored in the program memory by the processor, and the operation will be described as follows.

The procedures performed in the waveguide feeding arrangements are described in time series.

The waveguide feeding alignment apparatus forms a feeding structure 12 on a Teflon substrate 11 having a rectangular shape with one side of a rectangular plate projecting in a rectangular shape. The waveguide feeding alignment device forms the antenna feeding structure 12 on the Teflon substrate 11. The antenna feeding structure 12 is centered and a thin film is arranged parallel to the feeding structure 12. The feeding structure 12 is protruded by a predetermined length from the thin film and is formed into a square feed 13, It protects the feeding structure 12 and the film and has a bottle shape.

In the waveguide feeding aligning apparatus, a Teflon substrate 11 having a rectangular shape protruding from one side of a rectangular plate is placed, a protruding edge is contacted with a corrugated edge of the Teflon substrate 11, The waveguide 21 is aligned with the waveguide 13.

The waveguide feeding alignment device aligns one side of the waveguide (21) on one side of the square feed (13).

The waveguide feeding alignment device aligns the rectangular bottom surface of the waveguide 21 on the square bottom surface of the square feed 13.

The waveguide feeding alignment device aligns one side of the square feed 13 with one side of the waveguide 21 to minimize antenna loss.

The camera 21 photographs the square feed 13.

The waveguide feeding alignment apparatus calculates the position of one surface of the square feed 13 and aligns one surface of the waveguide 21 on one surface of the square feed 13 and then fixes the waveguide 21 to the Teflon substrate 11 .

The waveguide feeding alignment apparatus calculates the position of the rectangular lower end surface of the rectangular feed 13 and aligns the rectangular lower end surface of the wave guide 21 to the rectangular lower end surface of the rectangular feed 13, And fixed to the substrate 11.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the present invention as defined by the following claims It can be understood that

10: forming part 11: Teflon substrate
12: Feeding structure 13: Square feeding
20: Alliance 21: Waveguide

Claims (8)

(10) for forming a feeding structure (12) on a Teflon substrate (11) having one side of a rectangular plate projecting in a square shape;
A Teflon substrate 11 having a rectangular shape protruding from one side of the rectangular plate is placed on the alignment portion 20 and the projecting edge of the alignment portion 20 is brought into contact with the corners of the Teflon substrate 11 And an alignment portion (20) for aligning the waveguide (21) on the square feed (13) of the Teflon substrate (11). The method according to claim 1,
The Teflon substrate 11 is formed such that the feeding structure 12 is centered and a thin film arranged parallel to the feeding structure 12 is formed and the feeding structure 12 is protruded by a predetermined length from the thin film, A feeding device according to any one of the preceding claims, wherein the feeding device (12) is formed of a square feed (13) and has a bottle shape to protect the feeding structure (12) and the thin film. The method according to claim 1,
Wherein the alignment portion (20) aligns one surface of the wave guide (21) on one side of the square feeding (13). The method according to claim 1,
The alignment portion 20 includes a camera 21 for photographing the square feeding 13;
The position of one side of the rectangular feed 13 is calculated and the one side of the waveguide 21 is aligned with one side of the rectangular feed 13 and then the waveguide 21 is fixed to the Teflon substrate 11 And a fixing portion (22). Forming a feeding structure (12) on a Teflon substrate (11) having one side of a rectangular plate projecting in a square shape; And
A Teflon substrate 11 having a rectangular shape protruding from one side of the rectangular plate is placed on the alignment portion 20 and the projecting edge of the alignment portion 20 is brought into contact with the corners of the Teflon substrate 11 And aligning the waveguide (21) to the square feed (13) of the Teflon substrate (11). 6. The method of claim 5,
The Teflon substrate 11 is formed such that the feeding structure 12 is centered and a thin film arranged parallel to the feeding structure 12 is formed and the feeding structure 12 is protruded by a predetermined length from the thin film, Wherein the feeder structure (12) is formed of the square feed (13) and has a bottle shape to protect the feed structure (12) and the thin film. 6. The method of claim 5,
Wherein aligning comprises aligning one side of the waveguide (21) on one side of the square feed (13). 6. The method of claim 5,
Wherein the aligning comprises: photographing the square feed (13) by a camera (21);
Calculating a one-sided position of the square feed (13); And
And aligning one side of the waveguide (21) on one side of the square feed (13) and then fixing the waveguide (21) to the Teflon substrate (11).

Images