JP2845437B2 - Evaluation method of variable capacitor - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for evaluating a variable capacitor, and more particularly to a method for evaluating a variable capacitor which determines a variable coefficient curve and defines the curve within a reference value. . [Problems to be Solved by Conventional Techniques and Inventions] A variable capacitor changes the capacitance by increasing or decreasing the facing area of a stator and a rotor according to the rotation angle of a shaft. The capacitance value when the opposing area of the stator and the rotor is overlapped so as to maximize is called the maximum capacity (Cmax), and the shaft is reversed so that the opposing area of the stator and the rotor is minimized. The capacitance value in the closed state is called the minimum capacitance (Cmin). If the rotation angle when this axis is rotated to the maximum is 180 °, and this rotation position is 100%, and the rotation angle in the middle is a rotation index (RI), the variable capacitance of the variable capacitor ( Cv) is as shown in FIG. Note that the minimum rotation index (RI) is not always 0 as shown in FIG. Here, if the capacitance change curve of a standard variable capacitor curve (A) shown in FIG. 4, for example, the reference value of the capacitance when rotating finger degree (RI) of Q ₁ represents a Cv _1. if,
When measuring capacitance of a variable capacitor, capacity when rotating finger degree (RI) of Q ₁ is if Cv _2, so that there ΔC error of only capacitance than the reference value. In this way, the capacitance of an appropriate number of variable capacitors is measured, and the error Δ
C is shown in FIG. 5, and the capacitance error of each variable capacitor is various, and many of them are outside the upper and lower limits of the predetermined standard. Conventionally, as shown in FIG. 6, in order to adjust a portion outside the allowable error range and to keep it within a predetermined capacitance standard, each of the variable capacitors is manually assembled after assembly. Need to be adjusted. This adjustment is performed by, for example, bending the rotor plate with a pin set or the like at a rotating finger position indicating a capacitance value outside the range of the allowable error and changing the gap between the rotor plate and the stator plate so that the capacitance error ΔC falls within the standard. Therefore, a large amount of time has been spent for bending and adjusting each part of the roller plate. However, as shown in Fig. 6, the tendency of the capacitance error is not constant due to the rotation index (RI) because of manual operation. At the time of mounting, as described later, the characteristics of the variable capacitors do not theoretically coincide with each other, which sometimes lacks the correlation with the device, causing scale deviation and tracking error. Therefore, when the variable capacitor is mounted on a device such as a radio, there arises a technical problem to be solved in order to evaluate and select a variable capacitor that does not cause a scale shift or a tracking error. The purpose is to solve this problem. Means for Solving the Problems The present invention has been proposed to achieve the above object, and receives a predetermined maximum reception frequency with the minimum rotation index of an assembled variable capacitor, and The trimmer unit and the antenna coil unit are adjusted so as to receive a predetermined minimum reception frequency at the maximum rotation index, and the capacitance of the variable capacitor is measured and converted into a variable coefficient expressed as a percentage of the maximum variable capacitance. Then, it is determined whether or not the variable coefficient is within a preset reference value of the variable coefficient, and when the variable capacitor is incorporated in a device, whether the variable capacitor is suitable or unsuitable as a variable capacitor capable of eliminating scale deviation and tracking error is determined. An object of the present invention is to provide a method for evaluating a variable capacitor, which is capable of being sorted. According to the present invention, the capacitance error of the variable capacitor is not
Evaluation is performed using the variable coefficient (KA). Variable coefficient (KA)
Is a value in which the maximum variable capacitance (Cvmax) of the variable capacitor is set to 100 and the variable capacitance (Cv) in the middle is expressed as a percentage, and each variable capacitor has a unique characteristic. Therefore, if the capacity of the variable capacitor is measured and converted to a variable coefficient (KA), a variable coefficient curve from the maximum reception frequency (fmax) to the minimum reception frequency (fmin) of the variable capacitor can be obtained. . Therefore, by standardizing the permissible range for the reference value of the predetermined variable coefficient (KA), it is possible to determine whether or not a scale deviation or tracking error will occur when each variable capacitor is incorporated in a device such as a radio. It can be sorted properly. That is, after setting the variable capacitor to receive a predetermined maximum reception frequency (fmax) and a minimum reception frequency (fmin) according to the broadcast reception band, the variable coefficient (KA) of the variable capacitor is set.
Is within the allowable range for the reference value of the predetermined variable coefficient (KA), even if the capacitance value of the variable capacitor deviates from the reference value, an appropriate variable capacitor that does not cause the scale deviation or tracking error. It can be evaluated as. An embodiment of the present invention will be described below with reference to the accompanying drawings. Incidentally, for convenience of explanation, a configuration belonging to the related art will be described at the same time. Also, as long as the objects and effects of the present invention match, the present invention naturally extends to other types without being limited to the following embodiment. 1 to 3, metal pillars (2), (2), (2) and (2) are fitted into the four corners of the resin substrate (1) from the bottom surface, and the metal pillars (2), (2) and (2) are inserted. ) (2) and auxiliary support (3)
(3) (3) (3) a plurality of stator plates (4) (4) ...
To be supported. The stator plates (4) (4) are formed so as to be laminated with a plurality of rotor plates (6) (6) ... fitted on the rotor shaft (5) via a film. Further, a resin pressing plate (7) is covered from above, and the metal columns (2), (2), (2), and (2) are made to protrude from the upper surface of the resin pressing plate (7). 8) (8) (8)
After inserting the ends of the nuts, the nuts (9), (9), (9) and (9) are tightened. The terminal plate (10) is connected to the ANT side, the terminal plate (11) is connected to the OSC side, and the terminal plates (12) (1
Reference numerals 3) denote earth terminals, respectively, which are connected to the rotor shaft (5) and the trimmer shaft (8a) of the trimmer section (8). When the variable capacitor is incorporated in a device such as a radio, a predetermined maximum reception frequency (fma) is set at a minimum rotation index (RI) of the variable capacitor according to a broadcast reception band.
x), the trimmer shaft (8a) is rotated to adjust the capacitance value of the trimmer section (8), and a predetermined minimum reception is performed at the maximum rotation index (RI) of the variable capacitor. The inductance of the antenna coil unit (not shown) is adjusted so that the frequency (fmin) can be received. Thus, the maximum receiving frequency (fma
x) and the minimum reception frequency (fmin) are respectively set to predetermined values. As will be described later, the variable capacitance (Cv) is measured at the rotation index (RI) in the middle of the variable capacitor, and the percentage with respect to the maximum variable capacitance (Cvmax) is obtained. The variable coefficient (KA) is calculated. Then, a variable coefficient (KA) is calculated for each rotation index (RI) to obtain a variable coefficient curve, and it is determined whether the variable coefficient is within a preset reference value of the variable coefficient. The variable capacitor according to the present embodiment measures a variable capacitance, converts the capacitance into a variable coefficient (KA), and defines the variable coefficient within a reference value of a predetermined variable coefficient (KA). The evaluation is performed using the variable coefficient (KA) regardless of the error alone. Accordingly, the variable capacitor conforms to the variable coefficient curve shown in FIG. 7, and the error of the variable coefficient falls within the employment range with respect to the reference value as shown in FIG. In addition, in the same variable capacitor that has not been adjusted, the graphs of the variable capacitance error and the variable coefficient error are compared, and as shown in FIGS. Is 1/3 to 1/5. Thus, the variable capacitor requires no or very little adjustment. Then, as shown in the curve (B) shown in FIG. 4, even if the curve deviates from the standard capacitance change curve (A), if the variable coefficient (KA) is the same, it becomes electrically equivalent. The variable capacitor conforms to the variable coefficient curve shown in FIG. Further, the variable coefficient (KA) will be described in detail. First, there is the following relational expression between the reception frequency and the tuning capacitance of the variable capacitor. Therefore, the ratio between the maximum reception frequency and the minimum reception frequency is expressed by the following equation. The maximum tuning capacity (Ccmax) is represented by Ccmax = Cvmax + Ccmin (2) Cvmax: maximum variable capacity. Therefore, the following equation is established from the equations (1) and (2). The above-described variable coefficient (KA) is represented by the following equation. From Equations (3) and (4), the variable coefficient at an arbitrary reception frequency fv is represented by the following equation. That is, the maximum reception frequency (fmax) and the minimum reception frequency (fm)
in) is determined, the variable coefficient (KA) is obtained regardless of capacitance values such as the maximum tuning capacity (Ccmax) and the minimum tuning capacity (Ccmin). From the above, with a variable capacitor in which the variable coefficient (KA) is defined within an allowable range with respect to the reference value, an accurate frequency can always be obtained for the rotation index (RI).
As described above, when the variable capacitor is incorporated into a device such as a radio, the trimmer section (8) and the antenna coil section are adjusted (or hardly adjusted) to obtain a predetermined maximum reception frequency (fmax). After the minimum receiving frequency (fmin) can be received, if the variable coefficient (KA) is a plurality of variable capacitors with the same value, the same frequency can always be obtained for the rotating finger (RI). Electrically equivalent,
Therefore, there is no scale difference between the plurality of variable capacitors. Although the above description has been made on the OSC side, the same applies to the tracking error on the ANT side. Further, it is not necessary to perform manual adjustment after assembling the variable capacitor, and it is possible to prevent poor quality, to eliminate time spent for adjustment, and to contribute to labor saving. (Effects of the Invention) The present invention, as described in detail in the above embodiment, adjusts the trimmer section and the antenna coil section so that the maximum reception frequency and the minimum reception frequency of each variable capacitor become predetermined values, respectively. The capacity of the variable capacitor is measured and converted into a variable coefficient expressed as a percentage of the maximum variable capacity, and it is determined whether the variable coefficient is within a preset reference value of the variable coefficient. The variable coefficient is obtained regardless of the variable capacitance value if the maximum reception frequency and the minimum reception frequency are determined. Even if the variable capacitance of the variable capacitor is not suitable for the reference value, the variable coefficient of the variable capacitor is If the variable coefficient is within the preset reference value of the variable coefficient, the tuning frequencies match. For this reason, even in the case where it is conventionally determined that the variable capacitor is inappropriate, the variable capacitor can be given an appropriate evaluation as being capable of eliminating scale deviation and tracking error. Therefore, it is not necessary to adjust the capacity after assembling, which conventionally requires a lot of manpower and time, so that it is possible to reduce the number of steps and man-hours, thereby contributing to cost reduction and so on.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows an embodiment of the present invention. 1 is a front view of the variable capacitor, FIG. 2 is a side view of the variable capacitor, FIG. 3 is a plan view of the variable capacitor, FIG. 4 is a graph showing a change in the variable capacitance, and FIG. FIG. 6 is a graph showing the relationship with the error (ΔC), FIG. 6 is a graph showing the case where the capacitance error (ΔC) falls within the standard, FIG. 7 is a graph of the variable coefficient curve, and FIG.
The figure is a graph showing the relationship between the rotation index (RI) and the variable coefficient error. Description of symbols (1) resin substrate (2) metal support (4) stator plate (5) rotor shaft (6) rotor plate (7) resin pressing plate (8) ) Trimmer Cmax Maximum capacity, Cmin Minimum capacity Cv Variable capacity, RI Rotational index KA Variable coefficient

Claims (1)

(57) [Claims] The trimmer unit and the antenna coil unit are adjusted so as to receive a predetermined maximum reception frequency at the minimum rotation index of the assembled variable capacitor and to receive a predetermined minimum reception frequency at the maximum rotation index. At the same time, the capacity of the variable capacitor is measured and converted into a variable coefficient expressed as a percentage of the maximum variable capacity, and it is determined whether the variable coefficient is within a reference value of a preset variable coefficient, and the variable An evaluation method for a variable capacitor, characterized in that when the capacitor is incorporated in a device, it is possible to select a suitable or unsuitable variable capacitor capable of eliminating scale deviation and tracking error.