JPH01232707A - Integrally-formed inductance line - Google Patents

Abstract

PURPOSE:To make it possible to reduce the manhours in mounting operation by a method wherein, an inductance line, loops and the like are formed with a sheet of material, a low-end trimmer, to be used to finely adjust inductance, and a high-end trimmer with which capacitance is finely adjustable, are provided. CONSTITUTION:In an integrally-formed inductance line 13, a bending work is conducted on a metal plate having conductivity, loops 1, 4 and 6, and inductance lines 2, 3, 5 and 7 are connected by a connecting part 14. The leg 16 to be connected to a capacitor C1 is formed independently, the leg 17 on the side of an earth and the earth of the line 2 are used common. The U-shaped part located between legs 17 and 18, which are the legs to be inserted into a printed substrate, are used as the inductance for tuning, and in order to finely adjust the irregularity of the turning frequency of a variable capacitance diode D1, the small capacitance varies by changing the high-end trimmer 8 to be used for fine adjustment in the direction E. A low-end trimmer 9 for fine adjustment is tuned in the direction F. The inductance lines 3, 5 and 7, and the loops 4 and 6 can be adjusted in the same manner as above-mentioned.

Description

Detailed Description of the Invention (Field of Application in Industry) The present invention applies not only to the structure of inductance lines and loops used in electronic tuning tuners used in televisions (TVs) and video tape recorders (VTRs), etc. This article relates to the structure of inductances that can be used in other high-frequency devices.

(Prior art) A tuner section used in TVs, VTRs, etc. consists of a V HF channel section and a U HF channel section.
Generally, the inductance in the VHF frequency band is an air-core coil, and since the frequency in the UHF frequency band is higher than that in the V I-IF band, it is formed by a distributed constant circuit.

FIG. 5 shows the circuit configuration of the UHF block of the electronic tuner, and FIG. 6 shows the mounting state of the conventional inductance line and loop.

In Figures 5 and 6, 1, 4.6 are loops, 2,
3, 5.7 is a U-shaped inductance line, 8 is a high-end trimmer for fine adjustment that is mainly adjusted in the Takagi UHF band, 9 is a low-end trimmer for fine adjustment that is mainly adjusted in the low frequency UHF 4r; 10 is a printed circuit board, l
l is the insertion hole, ll is the chip component, A is the input block, B
is a crotch-order block, C is an interstage secondary block, and D is a local oscillation block.

Next, the function and structure of the conventional example shown in FIG. 6 will be explained in comparison with the circuit configuration shown in FIG. 5. In FIGS. 5 and 6, loop 1 of input block A is connected to capacitor 05, and the current flowing through loop 1 electrically couples it to the next stage tuning circuit (described later). and,
A variable tuning circuit constituted by an inductance line 2, a variable capacitance diode D□, and a capacitor C2 is used to tune to the U)-IF channel to be selected by changing the reverse bias voltage of the variable capacitance diode. in this case.

Due to variations in the components used, such as capacitor C2, variable capacitance diode D1゜inductance line 2, etc.
As a fine adjustment function, a high-end trimmer 8 for fine adjustment and a low-end trimmer 9 for fine adjustment are integrated with the inductance line 2 (FIG. 6).

High-end trimmer 8 for fine adjustment and low-end trimmer 9 for fine adjustment
The tuning point can be finely adjusted by varying them in the directions indicated by arrows E and F in FIG. 6, respectively. Similarly, a similar tuning circuit is required in the interstage-next block B, so the inductance line 3. A variable capacitance diode D constitutes a capacitor C1. Similarly, in the crotch secondary block C, a tuning circuit is configured by an inductance line 5, a variable capacitance diode D, and a capacitor C4. In the interstage secondary block C, the coupling loop 4 is set parallel to the inductance line 5 in order to supply the high frequency signal to the next stage mixer and attenuate the image frequency. In order to generate local oscillation corresponding to the local frequency, it is composed of an inductance line 7, a variable capacitance diode D4, a capacitor 05, etc., and a loop 6 for picking up this local oscillation frequency is set in parallel. When configuring the UHF circuit as described above, four inductance lines and three loops are configured substantially in parallel.

(Problems to be Solved by the Invention) However, in the above conventional mounting shown in FIG. In addition, there are five common grounding points for the inductance line and loop (points indicated by the symbol G in Figure 5), and since each is a single item, insertion holes must be made by drilling or punching on the printed circuit board. This poses a problem in that high-density chip mounting is hindered when chip components are mounted on the underside of a board, which requires many holes.

The present invention solves these conventional problems,
The purpose of this invention is to provide an integrated inductance line that can significantly reduce manufacturing and installation man-hours.

(Means for Solving the Problems) In order to achieve the above object, the present invention comprises an inductance line used in a high frequency circuit, a loop for picking up signals, etc. from a single conductive plate-like material, Connect each adjacent space to create an integrated structure, and
The integrated inductance line is equipped with a low-end trimmer for fine adjustment that can slightly vary the inductance and a high-end trimmer mechanism for fine adjustment that can slightly vary the capacitance.

(Function) Therefore, according to the present invention, by integrating the inductance of an electronic tuner, several types of inductance lines and pickup loops can be manufactured from one type of material by one press process, and also a printed circuit board. Because they are connected in the implementation, the work can be done all at once, making it possible to significantly reduce the number of man-hours. In addition, the ground land can be reduced, and since it is equipped with a low-end trimmer for fine adjustment and a high-end trimmer for fine adjustment, it has the effect of being able to provide the same performance as conventional products despite having an integrated configuration.

(Example) Fig. 1 shows a case where an integrated inductance line according to an embodiment of the present invention is mounted, and Fig. 2 shows a state of the integrated inductance line of the present invention before cutting. . Further, FIG. 3 shows a part of the negative inductance line developed, and FIG. 4 shows that the developed inductance line in FIG. 3 has been subjected to a bending process. In FIGS. 1 to 4, 1, 4.6 are loops, 2, 3, 5.
7 is an inductance line, 8 is a high-end trimmer for fine adjustment, 9 is a low-end trimmer for fine adjustment, IO is a printed circuit board, 13 is an integrated inductance line, 14 is a connection part,
15 is the insertion hole, 16 to 22 are the legs of the integrated inductance line, 23 is the chassis, 24 is the partition plate, 25° 26
．． 27, 28, and 29 are bending shapes of the low-end trimmer for fine adjustment, 30 is an inductance portion, A is an input block, B is an interstage-order block, C is an interstage secondary block, and D is a local oscillation block.

Next, the function and structure of the above embodiment will be explained. Second
The integrated inductance line 13 shown in the figure is manufactured by performing a development 1 bending process by pressing a metal plate with high conductivity such as a copper plate or a brass plate. And loops 1, 4.6 and inductance lines 2, 3, 5.
7 are connected by a connecting portion 14, and each loop and inductance line has an integrated structure with an approximately U-shape as a whole. This integrated inductance line 13 is connected to the printed circuit board I as shown in FIG.
Insert the foot 1 of the integrated inductance line into the insertion hole 15 of O.
6 to 22 are inserted, fixed, and soldered to the patterns on the printed circuit board 10, thereby connecting the respective inductance lines and loops to the patterns on the printed circuit board. In this case, in order to facilitate cutting just before or after insertion of the integrated inductance line 13, it is preferable that the connecting parts 14 are all connected in substantially the same shape on the upper side.

Loop 1 in Fig. 2 has a shape made by bending a metal plate of a certain width into a U-shape, and the leg 16 of the integrated inductance line connected to capacitor C0 shown in Fig. 5 is formed independently, while the ground Leg 1 of side integrated inductance line
7 is common to the ground of line 2, so it is possible to design it as a common ground leg. In order to prevent the connecting portion 1 from deforming until it is inserted into the printed circuit board 10,
It is connected by 4. In addition, the U-shape between the legs 17 and 18 of the integrated inductance line, which is the leg inserted into the printed circuit board 10, is configured as a tuning inductance,
Variable capacitance diode drawer shown in Figure 5, capacitor C8
In order to finely adjust the variation in the tuning frequency due to product variation in the inductance line 2, a high-end fine adjustment trimmer 8 is set in a structure parallel to the partition plate 24 of the chassis z3, and is variable in the direction of the arrow E in FIG. The structure is such that the minute capacitance changes due to the In addition, since it is constructed in an integrated structure with the low-end trimmer 9 for fine adjustment, it is unfolded as shown in FIG. is adjusted in the direction of arrow F using the base 29 of the trimmer and the tip 25 of the trimmer portion as fulcrums. Inductance line 2
If it is moved close to the inductance portion 30, the equivalent inductance decreases, and conversely, if it is moved away from the inductance portion 30, the equivalent inductance increases. In this case, the trimmer tip 25 of the low-end trimmer 9 for fine adjustment is connected to the ground of the printed circuit board 10, and serves as a fulcrum during adjustment and to widen the variable range. Similarly, the inductance lines 3, 5, 7 and the loops 4, 6 have similar structures, and are integrated at a connecting portion 14.

By using an integrated inductance line in this way, the ground point (symbol G in Fig. 5) shown in the circuit configuration of Fig. 5 can be configured at only one location, that is, the leg 17 of the integrated inductance line. becomes.

(Effects of the Invention) As is clear from the above embodiments, the present invention provides an integrated inductance line of an electronic tuner etc.
Several types of inductance lines and pickup loops can be manufactured from different materials in one press process. Furthermore, since they are connected when mounting on a printed circuit board, the work can be done all at once, significantly reducing the number of man-hours. Furthermore, the integrated structure makes it possible to significantly reduce the number of ground legs from the inductance line and pickup loop, reducing the need for drilling holes on the printed circuit board and securing space. In addition, the developed shape shown in Fig. 3,
With the bent shape shown in FIG. 4, a high-end trimmer for fine adjustment and a low-end trimmer for fine adjustment can be constructed, so that the same performance as the conventional one can be ensured.

[Brief explanation of the drawing]

Fig. 1 is a perspective view of the uniform inductance line of the present invention mounted, Fig. 2 is a perspective view showing the connected state of the uniform inductance line of one embodiment of the present invention before cutting, and Fig. 3 is the uniform inductance line of the present invention. Figure 4 is a partially developed view of the line, Figure 4 is a perspective view after the bending process shown in Figure 3, Figure 5 is a circuit configuration diagram of the UHF block of the electronic tuner, Figure 6 is the mounting state of the conventional inductance line and loop. FIG. 1.4.6...Loop, 2,3,5.7...Inductance line, 8...High-end trimmer for fine adjustment, 9...Low-end trimmer for fine adjustment, 10...Printed circuit board, 11. ...Insertion hole, 12...Chip component, 13...Integrated inductance line, 14...
Connecting portion, 15...Insertion hole, 16-22...Legs of integrated inductance line, 23...Chassis. 24... Partition plate, 25-29... Bending shape of low-end trimmer for fine adjustment (25... Tip of trimmer part, 29
...root part), 30...inductance part, A.
・Input block, B ・Interstage-next block, C・
... Interstage secondary block, D... Local oscillation block. Patent applicant: Matsushita Electric Industrial Co., Ltd. Takumiin 14...
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Claims (2)

[Claims] (1) Inductance lines used in high-frequency circuits or loops for signal pickup are constructed from conductive plate-shaped materials, and adjacent lines are connected to create an integrated structure of multiple inductance lines and loops. An integrated inductance line characterized by: (2) The integrated inductance line is provided with a fine inductance variable mechanism and a fine capacitance variable mechanism in order to set a resonance frequency between the capacitor and the integrated inductance line. Integrated inductance line.