KR20020005814A - Device for frequency tuning in dielectric resonator oscillator - Google Patents

Abstract

PURPOSE: A frequency adjusting device of a DRO(Dielectric Resonator Oscillator) is provided to maintain constantly the gap of a DR by manually pressing a second section formed over a cavity to bend the second section toward the cavity so as to easily and simply adjust preset oscillating frequency, thereby preventing the change of the oscillating frequency due to external impulse. CONSTITUTION: A first section(160) is formed by forming a spherical recess(150) on a top cover(140) of a cavity(130) for inserting a DR(120) positioned on a substrate. A second section(170) is formed by forming a spherical recess(170) inside the spherical recess(150). The second section(170) is bent toward inside the cavity(130) so as to be separated with a constant gap between the DR(120).

Description

DIALO's frequency regulator {DEVICE FOR FREQUENCY TUNING IN DIELECTRIC RESONATOR OSCILLATOR}

The invention adjusts the frequency of the DRO to easily and easily tune the oscillator frequency of the dialect (DELECTRIC RESONATOR OSCILLATOR) (hereinafter referred to as "DRO") used for the adjustment of the oscillation frequency in the LNB. In particular, the apparatus relates to a DR positioned on a substrate and an upper surface of the upper cover portion of the cavity installed around the DR. The spherical groove is concave in a predetermined shape to form a first cross section, and the spherical bent back into the rectangular spherical groove. The groove is recessed in a predetermined shape to form a second cross section, and the second cross section is bent into the cavity by the spherical bending groove so that the groove is installed at a predetermined interval apart from the DR. By a simple operation of pressing the second end face formed by the hand, the distance between the second end face and the DR is kept constant at all times. The present invention relates to a DRO frequency adjusting device that allows easy and easy forwarding.

In general, the DRO used in the LNB is composed of a DR installed inside the cavity and an oscillation frequency adjustment screw installed above the cavity, and the bottom of the adjustment screw and the top of the DR are maintained at a constant interval by the operation of turning the adjustment screw. The oscillation frequency is adjusted.

In the conventional DRO configuration related to such a technique, as shown in FIG. 1, the DR 20 mounted above the substrate 10 is provided inside the cavity 30, and above the cavity 30. The frequency adjustment screw 40 is provided on the vertical line coaxial with the DR 20, and is configured to be adjustable to be spaced apart from the DR 20 by a predetermined interval t.

Accordingly, in order to adjust the distance between the DR 20 installed inside the cavity 30 and the frequency adjusting screw 40 positioned above the cavity 30, the frequency adjusting screw 40 is turned by a driver or the like. After adjusting the oscillation frequency, the frequency adjusting screw 40 is bonded to complete the frequency adjusting operation.

However, it is difficult to adjust the frequency due to the change in the spacing of the screw thread formed in the cavity 30 and the frequency adjustment screw 40 is fastened to the upper side of the cavity 30, the frequency adjustment screw 40 There was a lot of problems, such as the change in the amount of the bond applied for the fixing of the) is extremely generated, as well as the oscillation frequency is difficult to adjust due to the flow of the frequency adjusting screw 40 due to external impact, etc. will be.

The present invention has been made to improve the above-mentioned conventional problems, the object of which is that the second cross-section by a simple operation by pressing the second cross-section formed on the upper side of the cavity when adjusting the oscillator frequency of the DRO It is bent into the cavity to maintain the DR interval at all times, and accordingly, it is easy and easy to adjust the preset oscillation frequency, and changes in oscillation frequency characteristics are caused by external impacts. It is to provide a DRO frequency adjuster that can be prevented.

1 is a cross-sectional structural view of the installation state of the DRO for adjusting the conventional oscillation frequency.

2 is a schematic perspective view of a DRO for the adjustment of the oscillation frequency according to the present invention.

3 is a partially cutaway configuration diagram of an upper cover part installed at an upper side of the DRO cavity of the present invention to adjust a frequency;

Figure 4 is a cross-sectional structure of the use state of the upper cover portion is installed in the upper side of the DRO cavity of the present invention to adjust the frequency.

Explanation of symbols on the main parts of the drawings

110 ... substrate 120 ... DR

130 ... cavity 140 ... cover

150 ... Spherical groove 160 ... First cross section

170 ... Spherical bent groove 180 ... Second section

As a technical means for achieving the above object, the present invention, the spherical grooves are formed in a predetermined shape on the upper cover portion of the DR positioned on the substrate and the cavity circumferentially mounted to the DR, the first cross section is formed, The second bent groove is formed in the rectangular spherical groove again to form a second cross section, and the second cross section is bent into the cavity by the spherical bent groove to be spaced apart from the DR by a predetermined distance. By providing a DRO frequency adjustment device characterized in that.

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

2 is a schematic perspective view of a DRO for adjusting the oscillation frequency according to the present invention, and FIG. 3 is a partially cut-away configuration diagram of an upper cover part installed at an upper side of the DRO cavity of the present invention to adjust a frequency, and the upper side of the substrate 110. The mounted DR 120 is installed inside the cavity 130.

In addition, the spherical groove 150 is formed in a predetermined shape on the DR 120 positioned on the substrate 110 and the upper cover part 140 of the cavity 130 in which the DR is installed. ) Is formed, and the second bent groove 170 is again recessed into a predetermined shape into the spherical groove 150, which is the first end surface 160, and a second end surface 180 is formed, and the spherical bending groove 170 is formed. As a result, the second end face 180 is bent into the cavity 130 to be spaced apart from the DR 120 by a predetermined interval (t).

Referring to the operation and effect of the present invention made of such a configuration as follows.

2 to 4, in the state where the DR 120 mounted above the substrate 110 is installed inside the cavity 130, the DR 120 positioned on the substrate 110 is disposed. When the oscillation frequency adjustment operation is performed, the spherical groove 150 is formed in a predetermined shape on the upper cover portion 140 of the cavity 130 in which the DR is installed, thereby forming the first end surface 160.

Subsequently, the first end face 160 formed in the quadrangular shape by the spherical groove 150 has a rectangular second end face 180 having the rectangular bent groove 170 in the predetermined shape. It can be formed, and by a simple operation of pressing the second end surface 180 by hand, the second end surface is bent into the cavity 130 while the spherical bending groove 170 is bent.

At this time, the spherical bent groove 170 forming the second end surface 180 is formed deeper than the depth of the spherical groove 150 forming the first end surface 160, the second end surface 180 by hand. When pressed, the first end face 160 is maintained as it is, so that only the second end face 180 can be bent into the cavity.

In addition, the second end surface 180 is positioned on the vertical line coaxial with the DR 120 installed inside the cavity 130 so that the DR 120 and the second end surface (when bending the second end surface 180). 180 may be maintained at a constant interval at all times, wherein a cutout groove 190 is formed at one side of the first end surface 160 and the second end surface 180 to form the first end surface or the second end surface. When spreading in the shape, by inserting the driver and the like in the notch groove 190 and lifted from the inside so that each cross section can be unfolded in its original shape.

Accordingly, when the oscillation frequency is adjusted through the DR 120, the second end surface 180 is closed by the simple operation of pressing the second end surface 180 formed on the upper side of the cavity 130 by the hand 130. Be easily bent inward to maintain a constant distance between the DR 120 and the second end surface 180 at all times.

According to the frequency adjustment apparatus of the DRO according to the present invention as described above, the second end surface is bent into the cavity by a simple operation of pressing the second end surface formed on the upper side of the cavity when the oscillator frequency of the DRO is adjusted by hand. The DR interval can be kept constant at all times, and accordingly, the adjustment of the preset oscillation frequency can be easily and easily performed, and the excellent effect of preventing the change of oscillation frequency characteristics caused by external impacts. There is.

Claims (3)

In the frequency adjusting structure of the DRO in which the DR 120 mounted above the substrate 110 is provided inside the cavity 130, A first end surface 160 having a spherical groove 150 formed in a predetermined shape on the DR 120 positioned on the substrate 110 and the upper cover part 140 of the cavity 130 in which the DR is installed. )and, A second end face 180 formed by recessing the spherical bent groove 170 in a predetermined shape again into the spherical groove 150 that is the first end surface 160; The second cross section 180 is bent into the cavity 130 by the bending of the spherical bending recess 170 to be installed spaced apart from the DR 120 by a predetermined interval (t) of the DRO, characterized in that Frequency regulator. The method of claim 1, wherein the spherical bent groove 170 forming the second end surface 180 is formed deeper than the depth of the spherical groove 150 forming the first end surface (160). Frequency regulator. The frequency adjusting device of the DRO according to claim 1, wherein cutout grooves (190) are formed at one side of the first end surface (160) and the second end surface (180), respectively.