JPS6387715A - Flyback transformer - Google Patents

Abstract

PURPOSE:To improve insulating properties and reduce the size of a flyback transformer by a method wherein an insulation cylinder is integrally inserted into the center of a high voltage film capacitor and a protective resistor and the joint between the protective resistor and the high voltage line are provided inside the insulation cylinder and the insulation cylinder is fixed to the fixing parts provided in the case of the flyback transformer. CONSTITUTION:A low voltage coil, a high voltage coil 3, a high voltage capacitor 7 connected to the output part of the high voltage coil 3 and a protective resistor 18 connected to the high voltage capacitor 7 in series are housed in a case 12. At that time, an insulation cylinder 17 protruding along the direction of drawing out lead wires is provided at the center of the high voltage capacitor 7 and the protective resistor 18 and the high voltage line connected to the protective resistor 18 are provided and housed in the insulation cylinder 17. After the insulation cylinder 17 is fixed to the fixing parts 12a and 12b provided inside the case 12 so as to make the high voltage capacitor 17 and the protective resistor 18 keep predetermined positions inside the case 12, the inside of the case 12 is filled with insulating material by injection and solidly insulated. With this constitution, the insulating properties can be improved and the size can be reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application] The present invention relates to a flyback transformer with a built-in high-voltage capacitor used in television receivers and the like, and particularly to a high-voltage capacitor and a high-voltage capacitor.

This invention relates to a flyback transformer that can improve the insulation of a protective resistor.

[Conventional technology]

Flyback transformers for television receivers etc. are 20~
It generates a high voltage of 30KV and supplies DC high voltage to the anode of the cathode ray tube. Recently, screen curvature (voltage changes due to changes in high-voltage load current due to bright and dark areas of the screen),
The screen appears to be distorted due to the change in screen size. ) For the purpose of improvement, a high voltage capacitor is installed in parallel with the cathode ray tube to increase the capacitance of the cathode ray tube.

Since the high-voltage capacitor receives the cathode ray tube's anode voltage, it is built into the case of the flyback transformer, and the capacitor is miniaturized by being insulated by casting the flyback transformer's insulating material.

FIG. 9 is a circuit diagram showing the connection state of the flyback transformer and the cathode ray tube high voltage capacitor. -1 is a flyback transformer, which consists of a low voltage coil 2, a high voltage coil 3, a diode 4, etc. 5 is a cathode ray tube and is connected to an output section 6 of a flyback transformer.

A cathode ray tube has a capacitance of 100C to 2000PF. 7 is a high voltage capacitor for the purpose of increasing the capacitance of the cathode ray tube, and is connected to the output section 6 of the flyback transformer. 18 is a protective resistor for the high-voltage capacitor 7, which limits the discharge current of the high-voltage capacitor 7 connected in parallel to prevent destruction of the high-voltage capacitor 7 when sudden discharge occurs due to internal discharge of a cathode ray tube, etc. It is something to do.

FIG. 10 is a sectional view showing a conventional example of a flyback transformer incorporating a high-voltage capacitor. The same parts as in Fig. 9 are given the same numbers.

The high voltage capacitor 7 has a high voltage side lead 8 and a low voltage side lead wire 9.
is connected to the output terminal 6 and the low voltage side terminal 10 of the flyback transformer, and is inserted into the case 12 at the same time as the high voltage wire 11 connected to the protective resistor 18 connected to the output terminal 6. It is built into flyback transformer 1 and is integrally insulated.

#11 Related flyback transformers of this type include, for example, the one described in Japanese Utility Model Publication No. 58-21554.

[Problem that the invention seeks to solve]

By the way, since the high-voltage capacitor 7 is connected in a suspended manner by the high-voltage side lead 8 and the low-voltage side lead 9, there is a risk that the lead wires 8 and 9 may deform and come into contact with the inner surface of the case 12, causing dielectric breakdown. Ta.

Further, the connection between the protective resistor 18 and the high voltage line 11 was also suspended, and there was a risk of contact with the inner surface of the case 12 and dielectric breakdown.

In order to prevent this, it is necessary to increase the size of the case 12 and to increase the storage space for the high voltage capacitor 7 and the protective resistor 18. As a result, the flyback transformer 1 becomes larger in size, and the amount of insulator 13 increases, making it expensive.

Furthermore, as the amount of the insulator 13 increases, stress due to thermal expansion, contraction, etc. around the high voltage capacitor 7 and the protective resistor 18 increases, and stress is applied to the high voltage capacitor 7 and the protective resistor 18, causing shellac, etc., and the insulation deteriorates. There is a high risk of destruction.

An object of the present invention is to solve these conventional problems and provide a flyback transformer that prevents high-voltage capacitors and protective resistors from coming into contact with the inner surface of the case or the high-voltage coil without increasing the size. .

[Means for solving problems]

In the present invention, by integrally providing a fixing tube (insulating tube) for fixing the high-voltage capacitor to the case, the distance from the case is kept constant, and by arranging a protective resistor in this fixing tube, it can be fixed to the case. This is to achieve the above objective.

[Effect]

That is, by fitting the fixing insulating cylinder provided at the center of the high voltage capacitor into the capacitor holding groove provided in the case, the distance between the high voltage capacitor and the case is kept constant;
By arranging the protective resistor within this fixed insulating cylinder, it is isolated from the case, which solves the conventional problems.

〔Example〕

An embodiment of the present invention will be described below with reference to FIGS. 1 to 8.

FIG. 2 is generally used as a high voltage capacitor. FIG. 2 is an explanatory diagram of a film capacitor using a film as a dielectric. 14 is a polyester film, and several sheets are stacked on top of each other. Aluminum 15 is vapor-deposited on some of the films 14 to serve as electrodes.

FIG. 3 is an explanatory diagram showing a state in which the high-voltage capacitor 7 of FIG. 2 is extended in the length direction.

As shown in FIG. 3, aluminum 15 is continuously deposited on the film 14' so that the relatively upper layer film 14' and the relatively lower layer film 14' partially overlap. Therefore, capacitors C1 to C7 as shown in the lower part of the figure are formed. 8.9 is the lead wire of the high-voltage capacitor 7, but this is made of a mild steel wire with a diameter of about 0.6 mm (#), and since it is difficult to connect to the evaporated part of aluminum 15, aluminum foil 16 is attached to both ends. are inserted and connected by welding to the aluminum foil 16. The withstand voltage of capacitor 7 is C1~c
It has a withstand voltage of 7 in series. The capacitance of the capacitor 7 is determined by the values of C4 to C7, and is set to several hundred PF to several thousand PF in accordance with the capacity of the cathode ray tube 5.

FIG. 4 is a perspective view showing the manufacturing process of a general high voltage capacitor. In general, the capacitor in Figure 3 is replaced with the capacitor in Figure 4 (
After winding it into a cylindrical shape as shown in (a) and forming it flat as shown in Figure 4 (b), it is immersed in an insulator to impregnate the gap between the films and harden it. Yes, it is a high voltage capacitor. A high voltage side lead wire 8 and a low voltage side lead wire 9 are attached to the capacitor 7 as shown in the figure.

FIG. 5 is a perspective view showing a high voltage capacitor used in the present invention. The high voltage capacitor shown in FIG.
A plastic insulating cylinder 17 is inserted into the center of Figure (A). The insulating tube 17 has a substantially cylindrical shape and is inserted so as to protrude from the capacitor 7 so that both ends thereof are combined with the case 12. The insulating cylinder 17 has a high pressure side 17a and a low pressure side 17.
There is b. When the insulator is impregnated and cured in this state, the capacitor 7 and the insulating cylinder 17 become one body. When impregnating an insulator with this method, the insulator is dipped into the insulator.
It is best to put a plug (not shown) made of silicone rubber or the like on the inside of 7 to prevent insulating material from adhering to the inside, and then remove the plug later.

The inner diameter of the insulating cylinder 17 is equal to the outer diameter of the protective resistor 18.

The diameter is slightly larger than the outer diameter of high pressure a11.
“Ru.

The high voltage capacitor 7 has an electrode on the side in contact with the insulating cylinder 17 on the high voltage side, to which a high voltage side lead wire 8 is connected, and an outer peripheral side on the low voltage side, to which a low voltage side lead wire 9 is connected. The outer diameter of the low voltage side 17b of the insulating cylinder 17 (the direction in which the low voltage side lead 9 comes out) is:
It is designed to fit into the inner diameter of the high voltage line drawing tube of the case 12. High voltage side 17a of insulating tube 17 (high voltage side lead wire 8
A slit 17o is provided in the direction in which the slit 17c comes out, and the tip of the slit 17c is elongated, and the locking portion 17
d is a provision. - FIG. 6 is a sectional view showing a state in which the protective resistor 18 and the high voltage line 11 are incorporated into the capacitor 7 of FIG. 5.

A protective resistor 18 is inserted inside the high voltage side 17a side of the insulating cylinder 17, and the lead of the protective resistor 18 and the high voltage side lead wire 8 are connected through the slit 170. - the other lead of the blade protection resistor 1 is connected to the high voltage line 11; That is, high voltage line 1
1 is inserted into the low-pressure side 17b of the insulating cylinder 17. The value of the protective resistor 18 is several kiloohms to several tens of kiloohms, the current flowing through it is several hundred microamperes/bare, and the potential difference that occurs between the two ends of the protective resistor is several volts per day. It is small and has almost the same potential as the several tens of kilovolts of the high-voltage capacitor 7, so there is no problem because there is no potential difference during normal use. Insulating cylinder 17
The thickness of the tube should be made to withstand approximately 30 kilovolts in case the cathode ray tube 5 discharges and becomes ground potential, but since voltage is not always applied, there is no need to make it particularly thick. .

FIGS. 1A and 1B are cross-sectional views showing one embodiment of the present invention. Here, FIG. 1(a) shows a state in which the high voltage capacitor 7 and the protective resistor 18 of FIGS. 5 and 6 are incorporated into a flyback transformer, and FIG. 1(b) shows another embodiment of the present invention. Example A state in which the high voltage capacitor 7 and protective resistor 18 of FIG. 8 are incorporated into a flyback transformer is shown.

The case 12 has a locking part 12 for fixing the insulating cylinder 17.
a and 12b are provided, and are fixed by locking the high voltage side 17a and the low voltage side 17b of the high voltage capacitor 7, respectively.

In this way, the insulating tube 17 and case 12 of the high voltage capacitor 7
If the protective resistor 18 is fixed inside the insulating tube 17, the vertical position of the high voltage capacitor 7 and the protective resistor will be fixed.

Fifth. In FIG. 6, the high voltage side lead wire 8 and the low voltage side lead wire 9 are pulled out from opposite sides, but
Figure i shows another embodiment in which both are pulled out in the same direction.

In this case, when wiring the low voltage side lead 9 to the flyback transformer, it can be placed close to the bin terminal side of the flyback transformer, which has the advantage of improving work efficiency.

FIG. 8 shows another embodiment in which two high voltage side lead wires are drawn out. In this case, one wire is connected to the protective resistor 18, and the other wire is connected to the protective resistor 18.
If the book is connected to the high voltage electrode 6, work efficiency can be improved. 1st
Figure (b) shows how it is assembled into a flyback transformer.

〔Effect of the invention〕

As described above, in the present invention, an insulating tube is inserted into the center of a film high-voltage capacitor to integrate it, a protective resistor and a connection part between the protective resistor and the high-voltage line are arranged inside the insulating tube, and the insulating tube is fried. By fixing the high voltage capacitor and protective resistor in the flyback transformer case by fixing them to the locking parts provided on the back transformer case, there is a risk that the high voltage capacitor body and protective resistor will come into contact with the high voltage coil or the inner surface of the case. The insulation properties are significantly improved. Therefore, the flyback transformer can also be made smaller, which also makes it possible to reduce costs.

[Brief explanation of the drawing]

Figures 1 (A) and (B) are cross-sectional views showing one embodiment of the present invention, Figures 2 and 3 are explanatory diagrams for explaining a film capacitor, and Figure 4 is a general high-voltage capacitor. FIG. 5 is a perspective view showing the high-voltage capacitor used in the present invention, FIG. 6 is a cross-sectional view showing the connection between the high-voltage capacitor and protective resistor used in the present invention, and FIG. FIG. 8 is a sectional view showing another structural example of the high voltage capacitor used in the present invention. 1...Flyback transformer 7...High voltage capacitor 12...Case 17...Insulating tube 17a of high voltage capacitor...High voltage side insulating tube 17b...Low voltage side insulating tube 17c...High voltage side insulation Slits 12a and 12b of the cylinder...Locking part 18 of the case...Protective resistance. 11D (a) Beak 1 (b) 2nd mouth 31 yen] Figure 4 Figure 5 Figure 6 Figure 6 70 Chapter 80 Chapter 10 10th procedure amendment (method) % formula % Display of case Showa 1961 Inter-Patent No. 251144 Title of the invention Record of flyback transformer correction and bookkeeper Name of patent applicant (5101 Hitachi Co., Ltd.)
Written by Osamu Toshiro Hitoi Beak Address: 5-1 Marunouchi-chome, Chiyoda-ku, Tokyo
No. L Hitachi, Ltd. Telephone unit φa! 212-1
111 (Representative of France) Figure 9 is a circuit diagram of a high voltage generation section including a conventional flyback transformer, and Figure 10 is a cross-sectional view of the flyback transformer shown at 5 on the left in Figure 9. ” is corrected. that's all

Claims (2)

[Claims] 1. The case houses a low-voltage coil, a high-voltage coil, a high-voltage capacitor connected to the output part of the high-voltage coil, and a protective resistor (a resistor for limiting the discharge current of the high-voltage capacitor) connected in series to the high-voltage capacitor. In this case, an insulating tube is provided in the center of the high-voltage capacitor that protrudes in the lead wire drawing direction, and the protective resistor and the high-voltage wire connected to the protective resistor are arranged and housed inside the insulating tube,
After the insulating cylinder is locked to a locking part provided inside the case so that the high voltage capacitor and the protective resistor are kept in a predetermined position inside the case, the inside of the case is integrally cast with an insulating material. A flyback transformer characterized by insulation. 2. In the flyback transformer according to claim 1, the high-voltage capacitor is formed by stacking several films, some of the films are provided with electrodes made of aluminum vapor deposition and aluminum foil, and are wound into a cylindrical shape. A flyback transformer characterized in that the above-mentioned insulating cylinder is subjected to insulation treatment.