JPH0642613B2 - Crystal oscillator manufacturing method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Outline] A method for manufacturing a crystal oscillator, comprising a coil using a magnetic material in an oscillation circuit including a crystal oscillator, and sealing the oscillation circuit in a metal container by resistance welding, The purpose is to manufacture a crystal oscillator with a proper frequency close to the nominal frequency by compensating for changes in the oscillation frequency after sealing by resistance welding, and is characterized by the degaussing process being provided after resistance welding. A method of manufacturing a crystal oscillator is configured.

[Industrial application field]

The present invention relates to a method of manufacturing a crystal oscillator, and in particular, includes a coil using a magnetic material in an oscillation circuit including a crystal resonator,
The present invention relates to a method for manufacturing a crystal oscillator in which the oscillation circuit is sealed in a metal container by resistance welding.

An oscillation circuit including a crystal oscillator may be configured as a voltage controlled oscillator or the like, for example. The voltage-controlled oscillator is an oscillator capable of controlling the oscillation frequency by changing the voltage applied to the input terminal.In such a voltage-controlled oscillator, the control width of the oscillation frequency, that is, the variation width of the obtained frequency is For the purpose of increasing the number, a coil using a magnetic material, for example, a chip inductance may be provided in the oscillation circuit.

On the other hand, the oscillation circuit is usually formed on a ceramic substrate or the like by being hybridized, for example, and the ceramic substrate is mounted on a metal base plate and sealed by resistance welding between the base plate and the metal cap. ,
Configured as one crystal oscillator. However, when the oscillation circuit is hermetically sealed by resistance welding in a metal container made of such a base plate and a cap, the magnetic field generated by the momentary large current flowing between the base plate and the cap causes the oscillation circuit to be present in the oscillation circuit. There is a phenomenon in which the magnetic material of the coil is magnetized and its magnetic permeability changes, and the oscillation frequency changes. Therefore, it is necessary to appropriately correct such a change in the oscillation frequency that occurs during resistance welding.

[Conventional technology]

FIG. 4 is a diagram of an oscillator circuit including a crystal oscillator, which shows a circuit configured as a voltage controlled oscillator. The voltage controlled oscillator circuit 20 includes a crystal oscillator 10 and a resistor R ₁
To R _8, capacitor C ₁ -C _3, are constituted from transistors T _1, T _2, etc., to increase the variation width of the oscillation frequency in as described above, the output unit for the input voltage V _c (OUTPUT) Purpose Then, a coil using a magnetic material, for example, a chip inductance 12 is provided.

FIG. 5 schematically shows a state in which the oscillation circuit 20 as shown in FIG. 4 is hermetically sealed in a metal container by resistance welding. The oscillator circuit 20 is hybridized and formed on a ceramic substrate (not shown).
It is sealed in a metal container (for example, an iron plate) 14 including 6 and a cap 18. These flanges are sandwiched by the welding jigs 22 and 23 from above and below and pressed, a large voltage is applied between them, and they are sealed by heat generated by the flow of current (resistance welding). Then, one crystal oscillator 30 enclosed in the metal container is manufactured.

However, as described above, during resistance welding, an electric field is momentarily generated at the contact portion between the base plate and the cap, and a magnetic field is also generated accordingly. Under the influence of this magnetic field, the magnetic material of the chip inductance 12 in the oscillation circuit is momentarily exposed to a large magnetic field and magnetized, and as a result, the magnetic susceptibility changes, the inductance value of the coil changes, and the oscillation frequency changes. Appears.

Therefore, conventionally, the frequency has been adjusted before the sealing by anticipating the change. That is, the frequency is set higher by a frequency corresponding to the frequency changed (decreased) by resistance welding so that a frequency close to the nominal frequency can be obtained after sealing by resistance welding.

[Problems to be Solved by the Invention] However, the chip inductance in resistance welding 1
The change in the oscillation frequency due to the magnetization of No. 2 has a considerable variation depending on the welding conditions and the like, so that a crystal oscillator having a large deviation from the nominal frequency was obtained.

Therefore, in the present invention, when a crystal oscillator is manufactured by sealing an oscillation circuit having a coil using a magnetic material as described above in a metal container by resistance welding, a change in oscillation frequency after sealing by resistance welding. The objective is to manufacture a crystal oscillator having an appropriate frequency close to the nominal frequency by correcting

[Means for solving problems]

In order to solve such problems, according to the present invention,
In a method of manufacturing a crystal oscillator, wherein a coil using a magnetic material is provided in an oscillation circuit including a crystal oscillator, and the oscillation circuit is sealed in a metal container by resistance welding, a demagnetization step is provided after sealing by resistance welding. A method for manufacturing a crystal oscillator is provided.

[Action]

According to the present invention, since the degaussing step is provided after sealing, the magnetic body of the coil is magnetized during the resistance welding which is the preceding step, and even if the oscillation frequency changes due to this effect, the coil is degaussed in the degaussing step. Since the magnetic substance of is demagnetized, it is restored to a frequency close to the original nominal frequency. Therefore, the frequency of the first oscillation circuit may be set to the nominal frequency.

〔Example〕

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

FIG. 1 shows a state in which a crystal oscillator is inserted into a degaussing coil. The crystal oscillator 30 is one in which the oscillation circuit 20 as shown in FIG. 4 is incorporated and the oscillation circuit 20 is hermetically sealed in the metal container 14 by resistance welding as shown in FIG. FIG. 2 shows changes in the oscillation frequency after forming the oscillation circuit, sealing by resistance welding, and demagnetizing. Further, FIG. 3 shows the magnetic field (H) when an AC voltage is applied to the degaussing coil in the degaussing process.
It is the figure which showed the hysteresis of the relationship between magnetization and magnetization (M).

The crystal unit 30 itself is manufactured by the same method as the conventional method described with reference to FIGS. 4 and 5. However, the setting of the first oscillation frequency of the crystal oscillation circuit (voltage controlled oscillation circuit) is set so as to exactly match the nominal frequency. That is, the oscillation frequency before sealing by resistance welding is set to, for example, 12 MHz, which is shown in FIG.

Next, the oscillation circuit 20 is sealed in the metal container 14 with a resistance welding machine as shown in FIG. At that time, the frequency decreased by Δ as shown in FIG. 2 for the reason described above. The amount of change is Δ / is 50 PPM (generally 50 to 100 PP
It was M).

The crystal oscillator 30 sealed by resistance welding is inserted into the cylindrical degaussing coil 40, and an alternating current for degaussing is applied to this coil. That is, the AC voltage applied to the degaussing coil 40 is gradually decreased so that the magnetic field (H) and the magnetization (M) decrease while drawing a hysteresis as shown in FIG.

In this degaussing process, by adding such a degaussing process to the magnetized coil, the oscillation frequency is gradually restored to a value very close to the original nominal frequency, as shown in FIG. That is, the magnetic material of the coil such as the chip inductance 12 (FIG. 4) magnetized during the resistance welding in the previous step is gradually demagnetized, and the inductance value of this coil gradually returns to the original value. Of. In this embodiment, the frequency difference from the frequency of -x / is 2PP.
It was a very small value of M.

〔The invention's effect〕

As described above, according to the present invention, the degaussing step is provided after the sealing by resistance welding to degauss the magnetized magnetic material of the coil so that the oscillation frequency returns to the original value. , A crystal oscillator having an oscillation frequency extremely close to the nominal frequency initially set can be obtained, and even when a large number of crystal oscillators of this type are manufactured, a crystal oscillator having a small variation with respect to the nominal frequency can be obtained. Moreover, since the inductance value of the coil is restored to the original value by demagnetization, a crystal oscillator in which the oscillation frequency changes little with time can be obtained.

[Brief description of drawings]

FIG. 1 shows an embodiment of the present invention, and is a perspective view showing a state in which a crystal oscillator is inserted into a degaussing coil. FIG. 2 shows an oscillation frequency after forming an oscillation circuit, after sealing by resistance welding, and after degaussing. 3 shows the change in the magnetic field, FIG. 3 shows the hysteresis of the relationship between the magnetic field (H) and the magnetization (M) when an AC voltage is applied to the degaussing coil, and FIG. 4 shows the oscillation including a crystal oscillator. Circuit diagram that configured the circuit as a voltage controlled oscillator,
FIG. 5 is a schematic view showing a state in which the oscillation circuit is hermetically sealed in a metal container by resistance welding. 10 ... Crystal oscillator 12 ... Coil using magnetic material (chip inductance) 14 ... Metal container 16 ... Base plate 18 ... Cap 20 ... Oscillation circuit (voltage controlled oscillation circuit) 22, 23 ... Resistance welding Jig 30 ... Crystal oscillator 40 ... Degaussing coil

Claims (2)

[Claims] 1. An oscillation circuit (2) including a crystal oscillator (10).
0) is provided with a coil (12) using a magnetic material, and the oscillation circuit is sealed by resistance welding (22, 23) in a metal container (14).
A method of manufacturing a crystal oscillator, comprising a step of demagnetizing after sealing by resistance welding. 2. The degaussing step is performed by sealing the crystal oscillator (3
0) is inserted into a cylindrical degaussing coil (40) and an alternating current for degaussing is applied to the coil to produce a crystal oscillator according to claim 1.