JP5158429B2 - Variable delay device - Google Patents

Description

  The present invention relates to a variable delay device, and more particularly to improvement of a rotary variable delay device used in a microwave region.

  Conventionally, as a variable delay device used in the microwave region, as shown in FIG. 3, two transmission boards having a low dielectric constant in which a transmission line pattern is formed in the circumferential direction are in contact with each other. In some cases, the transmission line length is adjusted by overlapping and rotating one printed circuit board.

  In FIG. 3, the first printed circuit board 10 is formed in a circular shape, and is formed with projecting portions 11 and 12 serving as connector portions, and one end is positioned on the projecting portions 11 and 12, and the arc-shaped transmission is performed. Line patterns 13 and 14 are formed.

  The second printed circuit board 20 is also formed in a circular shape, and an earth pattern is formed on the entire surface on one side. On the other surface, when the surface is overlapped with the surface on which the transmission line patterns 13 and 14 of the first printed circuit board 10 are formed, the arc-shaped transmission is overlapped with the transmission line patterns 13 and 14. Line patterns 22 and 23 are formed. One end of these transmission line patterns 22 and 23 is opened, and the other end is connected by a connection pattern 24 so that the patterns 22 and 23 are continuous.

  The first printed circuit board 10 and the second printed circuit board 20 are overlapped so that the transmission line patterns 13, 14 and 22, 23 are opposed to each other as shown in FIG. By rotating clockwise or counterclockwise with respect to the first printed circuit board 10, the transmission line patterns 13 and 14 and the transmission line patterns 22 and 23 are electrically connected and the position of the connection pattern 24 is changed. The transmission line length between the protrusions 11 and 12 becomes longer or shorter, and a desired delay time can be set.

  Patent Document 1 describes a configuration example of a variable delay device as shown in FIG.

Japanese Utility Model Publication No. 2-103905

  By the way, in such a conventional variable delay device, the transmission line patterns 13 and 14 and the transmission line patterns 22 and 23 are stable when the first printed board 10 and the second printed board 20 are overlapped and integrated. In order to allow the second printed circuit board 20 to be rotated clockwise or counterclockwise with respect to the first printed circuit board 10, a plurality of spacers may be sandwiched. It was done.

  However, these spacers, the first printed circuit board 10 and the second printed circuit board 20 are overlapped so that the transmission line patterns 13 and 14 and the transmission line patterns 22 and 23 are electrically connected in a stable state. In order to integrate the second printed circuit board 20 so as to be rotated clockwise or counterclockwise with respect to the first printed circuit board 10, fine adjustment after assembly is necessary.

  The present invention solves such a problem, and an object thereof is to provide a variable delay device that does not require adjustment after assembly.

In order to achieve such a problem, the invention according to claim 1 of the present invention is:
A fixed printed circuit board having a circular main plane formed with an arc-shaped transmission line pattern and a rotating printed circuit board having a circular main plane formed with an arc-shaped transmission line pattern are in contact with each other. It is stacked and stored in the lower case,
The lower case has a bottom surface facing the rotating printed circuit board formed as a smooth flat surface, and the upper surface also stores a spacer provided with mounting holes in which springs are fitted at equal angular intervals along the circumferential direction. And
A variable delay characterized in that an upper case is overlapped and fastened to the lower case in a state in which a spring is fitted so as to press the two printed circuit boards superimposed on the mounting hole of the spacer. Device.

The invention according to claim 2 is the variable delay device according to claim 1,
The lower case is formed with a substantially circular storage portion for storing the two superimposed printed boards, and a part of the inner periphery of the storage portion constitutes a stopper for regulating the rotation range of the rotary printed board. Formed as a stepped large diameter part,
A protrusion is formed on a part of the circular main plane of the rotating printed circuit board so as to form a stopper that fits the stepped large diameter portion of the lower case and restricts the rotation range of the rotating printed circuit board. and said that you are.

  According to the present invention, by selecting a spring having a predetermined elastic force in advance, adjustment after assembly becomes unnecessary.

  Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 is an assembly explanatory view showing an embodiment of the present invention. The variable delay device according to the present invention includes a lower case 30, a fixed printed circuit board 40, a rotating printed circuit board 50, a spacer 60, a spring 70, an upper case 80, and a screw 90.

  The lower case 30 is obtained by cutting a metal block, and includes a storage portion 31 cut into a substantially circular shape to which a main plane 41 of the fixed printed circuit board 40 is fitted, and an input / output protruding side 42 of the fixed printed circuit board 40. , 43 are notched 32, 33 cut so as to communicate with the storage portion 31, the shaft hole 34 supporting the end of the rotating shaft 52 provided on the rotating printed circuit board 50, and fixing screws 91-94. Screw holes 35 to 38 to be screwed are provided. A part of the inner periphery of the storage portion 31 is formed as a stepped large-diameter portion 39 so as to constitute a stopper that regulates the rotation range of the rotary printed circuit board 50.

  The fixed printed circuit board 40 has a low dielectric constant like a fluororesin board, and has a circular main plane 41 formed so as to fit in the storage portion 31 of the lower case 30, and a radial direction from the main plane 41. The rectangular input / output protruding sides 42 and 43 are formed so as to protrude and to be orthogonal to each other.

  A ring-shaped ground pattern 44 is formed on the outer periphery of one surface of the main plane 41, and a part of the ground pattern 44 is formed so as to extend to the input / output projecting sides 42 and 43. The ground pattern 44 formed on the main plane 41 and the input / output projecting sides 42 and 43 is electrically connected via a ground pattern (not shown) formed on the entire other surface and a number of through holes (not shown). It is connected.

  Further, arc-shaped transmission line patterns 45 and 46 are formed on one surface of the main plane 41 so that one end thereof is positioned on the input / output protruding sides 42 and 43. The input / output projecting sides 42 and 43 are provided with connectors 47 and 48 for connecting cables (not shown). A shaft hole 49 that supports the end of the rotating shaft 51 provided in the rotating printed circuit board 50 is provided in the central portion of the main plane 41 so as to coincide with the shaft hole 34 of the lower case 30.

  The rotary printed circuit board 50 also has a low dielectric constant like a fluororesin substrate, and has a circular main plane 51 formed so as to be rotatably fitted in the storage portion 31 of the lower case 30, and the main plane 51. It is comprised with the rotating shaft 52 inserted and fixed to the center part.

  A ring-shaped ground pattern 53 is formed on the outer surface of the main plane 51 facing the fixed printed circuit board 40 so as to overlap the ring-shaped ground pattern 44 of the fixed printed circuit board 40.

  In addition, arc-shaped transmission line patterns 54 and 55 are formed on the surface of the main plane 51 facing the fixed printed circuit board 40 so as to overlap the arc-shaped transmission line patterns 45 and 46 of the fixed printed circuit board 40. . One end of these transmission line patterns 54 and 55 is opened, and the other end is connected by a connection pattern 56 so that the patterns 54 and 55 are continuous.

  A protruding portion 57 is formed on a part of the main plane 51 so as to form a stopper that fits into the stepped large diameter portion 39 of the lower case 30 and restricts the rotation range of the rotary printed circuit board 50. .

  An entire ground pattern is formed on the other surface of the main plane 51, and this ground pattern and the ring-shaped ground pattern 53 on one surface are electrically connected through a number of through holes (not shown).

  The spacer 60 is also obtained by cutting a metal block into a circular shape so as to fit in the storage portion 31 of the lower case 30. The bottom surface of the spacer 60 facing the rotating printed circuit board 50 is formed as a smooth flat surface so that the rotating printed circuit board 50 can smoothly rotate, and the upper surface has equal angular intervals along the circumferential direction (60 degrees in this embodiment). ), Mounting holes 61 to 66 into which the coil springs 71 to 76 are fitted are provided. A shaft hole 67 is provided in the central portion of the spacer 60 so that the operation end of the rotating shaft 51 provided in the rotating printed board 50 is inserted therethrough.

  The spring 70 accommodates the fixed printed circuit board 40, the rotary printed circuit board 50, the spacer 60, and the spring 70 in the lower case 30, and the upper case 80 is fixed to the lower case 30 with the screws 90, so The fixed printed circuit board 40 and the rotary printed circuit board 50 which are stored in the storage unit 31 of the lower case 30 so that the patterns 44 and 53 and the arcuate transmission line patterns 45, 46, 54 and 55 are in contact with each other are rotated The substrate 50 is pressed in a semi-fixed state in which the substrate 50 can rotate. In this embodiment, an example in which coil springs 71 to 76 are used as the spring 70 is shown.

  The upper case 80 is also obtained by cutting a metal block. The upper case 80 is fixed to the lower case 30 in which the fixed printed circuit board 40, the rotary printed circuit board 50, the spacer 60, and the spring 70 are accommodated with screws 90. Screw holes 81 to 84 for fixing the upper case 80 to the lower case 30 with screws 90 are provided at the four corners of the upper case 80, and an operation end of the rotary shaft 51 provided on the rotary printed circuit board 50 is provided at the central portion. A shaft hole 85 to be inserted so that the portion penetrates is provided. A mounting hole in which the other ends of the coil springs 71 to 76 are fitted and a notch (for example, 86) in which the connectors 47 and 48 provided on the fixed printed board 40 are fitted are formed on the surface facing the spacer 60. ing.

  The screws 90 are used to superimpose the upper case 80 on the lower case 30 in which the fixed printed circuit board 40, the rotary printed circuit board 50, the spacer 60, and the spring 70 are housed, and are screwed. The screws 91 to 94 are respectively screwed into the screw holes 81 to 84 to be fastened and fixed.

  According to such a configuration, the upper case 80 is superimposed on the lower case 30 in which the fixed printed board 40, the rotary printed board 50, the spacer 60, and the coil springs 71 to 76 are accommodated, and the screws 91 to 94 are set in advance. The elastic force of the coil springs 71 to 76 can be selected in advance according to the material and mechanical dimensions of the coil springs 71 to 76 so that a desired pressing force can be obtained when fastened with torque. Adjustment can be made unnecessary.

  FIG. 2 is a configuration explanatory view of a stopper that restricts the rotation range of the rotary printed circuit board 50 incorporated in the variable delay device configured as shown in FIG. 1 to a predetermined angle range, and is seen through with the upper case removed. Indicates the state.

  In FIG. 2, the large-diameter portion 39 of the storage portion 31 of the lower case 30 is formed in an angle range of 100 degrees with respect to the center so as to restrict the rotation angle range of the rotary printed circuit board 50 to 100 degrees. The large-diameter portion 39 is fitted with a protruding portion 57 formed on a part of the main plane 51 of the rotary printed circuit board 50, and the solid line indicates a state in which the rotary printed circuit board 50 is fully rotated counterclockwise. A broken line indicates a state in which the rotary printed board 50 is fully rotated in the clockwise direction.

  When attention is paid to the transmission line lengths of the transmission line patterns 45, 46 and 54 to 56 formed between the connectors 47 and 48, the state where the transmission line patterns 45, 46 and 54 to 56 are completely turned in the counterclockwise direction indicated by the solid line becomes the shortest and the counterclockwise direction indicated by the broken line is indicated. The state where the rotation is completed is the longest, and a desired delay time corresponding to the transmission line length can be set between the shortest and longest.

  In the above embodiment, the example in which the lower case 40, the spacer 70, and the upper case 90 are manufactured by cutting a metal block has been described. However, the present invention is not limited to this, and the lower case 40, the spacer 70, and the upper case 90 can be molded by casting or the like. .

  Moreover, although the example which uses the six coil springs 71-76 as the spring 70 was demonstrated in the said Example, it is not restricted to this, For example, a leaf | plate spring may be sufficient.

  As described above, according to the present invention, a variable delay device that does not require adjustment after assembly can be realized, and is suitable as a variable delay device in the microwave region.

It is assembly explanatory drawing which shows one Example of this invention. FIG. 2 is a configuration explanatory diagram of a stopper that regulates a rotation range of the rotary printed board 50 of FIG. 1 within a predetermined angle range. It is structure explanatory drawing which shows an example of the conventional variable delay apparatus.

Explanation of symbols

30 Lower case 31 Storage part 39 Large diameter part 40 Fixed printed circuit board 50 Rotating printed circuit board 51 Main plane 57 Projection part 60 Spacer 70 Spring 71-76 Coil spring 80 Upper case 90 Screw

Claims (2)

A fixed printed circuit board having a circular main plane formed with an arc-shaped transmission line pattern and a rotating printed circuit board having a circular main plane formed with an arc-shaped transmission line pattern are in contact with each other. It is stacked and stored in the lower case,
The lower case has a bottom surface facing the rotating printed circuit board formed as a smooth flat surface, and the upper surface also stores a spacer provided with mounting holes in which springs are fitted at equal angular intervals along the circumferential direction. And
A variable delay characterized in that an upper case is overlapped and fastened to the lower case in a state in which a spring is fitted so as to press the two printed circuit boards superimposed on the mounting hole of the spacer. apparatus. The lower case is formed with a substantially circular storage portion for storing the two superimposed printed boards, and a part of the inner periphery of the storage portion constitutes a stopper for regulating the rotation range of the rotary printed board. Formed as a stepped large diameter part,
A protrusion is formed on a part of the circular main plane of the rotating printed circuit board so as to form a stopper that fits the stepped large diameter portion of the lower case and restricts the rotation range of the rotating printed circuit board. the variable delay device according to claim 1, characterized in that there.