KR100322647B1 - Deflection yoke device - Google Patents

Abstract

The deflection yoke device comprises a pair of horizontal deflection coils, a pair of manual deflection coils, a coil bobbin with defined through holes along its central axis, a pair of windings wound around the coil bobbin and connected in series with the horizontal deflection coils. A magnetic core inserted into the through hole of the coil bobbin for finely adjusting the amount of inductance deviation between the coil and the pair of compensating coils by the displacement in the through hole of the coil bobbin, a substrate for installing the coil bobbin, and And a protective cover for covering the coil bobbin and the pair of compensation coils. The protective cover includes an adjusting range adjusting member for adjusting an adjusting range capable of displacing the magnetic core in the through hole of the coil bobbin.

Description

Deflection yoke device

The present invention relates to a deflection yoke for a cathode ray tube (CRT), in particular to a coil bobbin wound with a compensation coil of one rice to compensate for misconvergence by varying the inductance of a horizontal deflection coil caused by displacement of the magnetic core. A configuration for adjusting the displacement range of the magnetic core inserted into the through hole.

In general, in CRT displays used in televisions and computers, an image is formed with fluorescence generated from the fluorescent surface of the CRT display generated by forming an electron beam emitted from an electron gun that strikes the fluorescent surface. Here, the deflection yoke device is used to scan the electron beam to the fluorescent surface in the vertical and horizontal directions.

Generally, the deflection yoke device is provided with a pair of horizontal deflection coils for scanning electron beams in the horizontal direction and a pair of vertical deflection coils for scanning electron beams in the vertical direction (height direction). The deflection coil and others are additionally provided with a pair of compensation coils for correcting the precise amount of inductance deviation between the pair of horizontal deflection coils having a sensitivity higher than that of the vertical deflection coil.

The deflection yoke device of the prior art will be described with reference to FIGS.

1 is a side view illustrating a prior art deflection yoke device in which a compensation coil is described in cross section.

Fig. 2 is a sectional front view of the coil bobbin of the deflection yoke device according to the line A-A shown in Fig. 1.

3 is a partial side view of the coil bobbin shown in the "C" direction of FIG.

4 is a perspective view of a protective cover of the prior art.

In the prior art, a saddle type deflection yoke device is used.

In Fig. 1, reference numeral 1 denotes a saddle-shaped separator that separates and holds a pair of horizontal deflection coils 3a, 3b from a pair of vertical deflection coils 2a, 2b. There are a pair of horizontal deflection coils 3a, 3b inside the upper and lower positions of the separator 1 and a pair of vertical deflection coils 2a, outside the front and rear positions of the separator 1 shown in the drawing. 2b) is installed. The separator 1 is made of non-conductive plastic, for example, to insulate the horizontal deflection coils 3a and 3b from the pair of vertical deflection coils 2a and 2b due to the potential difference of several kV in between.

On the outside of the pair of vertical deflection coils 2a and 2b each wound in the form of a saddle, an outer core 4 made of ferrite is provided to reduce the magnetoresistance, so that the pair of vertical and horizontal deflection coils 2a and 2b, The leakage of the magnetic flux from 3a and 3b) is suppressed.

Even when the deflection coil is produced according to the specification, it is difficult to produce the deflection coils 2a, 2b, 3a, and 3b without any change in impedance. Therefore, a slight impedance deviation different from the specification is inevitably generated. In particular, the pair of horizontal deflection coils 3a and 3b have high sensitivity. As a result, the small deviation of the impedance will worsen the picture of the CRT screen. Therefore, the deflection yoke device requires a compensation circuit to correct the deterioration of the deviation characteristic caused by the impedance deviation. Specifically, as shown in FIG. 1, the printed circuit board 5 together with the compensation circuit can be installed in the separator 1, and in addition, as long as the printed circuit board 5 is wound around it. A coil bobbin 8 with a pair of compensating coils 15 and 16 (only one is shown) and a magnetic core 9 of the coil bobbin 8 are provided. In addition, since a high voltage is supplied to the printed circuit board 5, a protective cover 6 made of plastic is supplied to cover the entire printed circuit board 5 and the compensation coils 15 and 16. The outline of the protective cover 6 is shown in FIG. 4.

Based on Fig. 2, reference numeral 8 designates a coil bobbin integrally formed using an insulator such as resin, and reference numeral 9 designates a magnetic core made of ferrite with threads formed on its outer surface. The magnetic core 9 may be supplied with a jig 120 such as a hexagonal wrench as shown in FIG. 23 to be moved in the direction B-B 'as shown by a double-headed arrow. Along the central axis of the through hole 7 of the coil bobbin 8 (in the direction B-B '), a plurality of ribs 10 are provided to protrude to the inner wall of the through hole 7. Since the plurality of ribs 10 are screwed together by feeding the magnetic core 9 in the B-B 'direction, the magnetic core 9 is forcibly fitted with the plurality of ribs 10.

Here, reference numerals 9a and 9b denote end faces of the magnetic core 9, and reference numerals 11 to 14 denote four flanges of the coil bobbin 8. Reference numeral 15 designates a compensation coil provided between the flanges 11 and 12 of the coil boy 8 and reference numeral 16 designates a compensation coil provided between the flanges 13 and 14. Reference numerals 17 and 18 indicate nails provided integrally to the coil bobbin 8 at their lower ends to impart elasticity. Thereby the coil bobbin 8 is fixed to the printed circuit board 5 as described below. Reference numerals 19 and 20 designate a love provided integrally to the coil bobbin 8, and reference numerals 21 and 22 designate the printed circuit board for the nails 17 and 18 to fix the coil bobbin 8 to the printed circuit board 5. Indicate the coupling hole provided in the fixed coupling. Reference numeral 27 designates a hexagonal hole passed through the magnetic core 9 so that when the magnetic core 9 moves in the B-B 'direction, the hexagonal jig 120 can engage with it. Reference numerals 23 and 24 denote both sides of the protective cover 6 so that the jig 120 can be inserted into the hexagonal hole 27 of the magnetic core 9 when adjusting the misconvergence of the deflection yoke as described below. Instruct the jig insertion hole provided in the

In addition, as shown in Figs. 3 and 4, the guide groove 32 having a U shape of the protective cover 6 placed by the pair of convex portions 25 and 26 is defined.

FIG. 5 is a side view of the compensation coil shown in the C direction of FIG. 2 with a portion of the protective cover cut away to show the coil bobbin. FIG.

In Fig. 5, reference numerals 28a and 28b indicate nails formed integrally with the protective cover 6 in order to have elastic force. The protective cover 6 generally has a plurality of nails 28a and 28b at a predetermined inch and is elastically supported by the printed circuit board 5.

After that, the operation of the compensation coils 15 and 16 will be clearly described with reference to FIGS. 6 to 13.

6 is a circuit diagram showing an electrical connection between a pair of compensation coils 15 and 16 and a pair of horizontal deflection coils 3a and 3b of the prior art.

FIG. 7 is a diagram schematically showing a misronvergence pattern displayed on a screen of a CRT of the prior art, in which:

The horizontal displacement value Xv of the electron beams of R (red) and B (blue) colors with respect to G (green) color is obtained by moving the magnetic core 9 in the coil bobbin 8 It is fixed to zero by adjusting the inductance.

8 (a) and 8 (b) are front cross-sectional views for explaining the adjustment of the compensation coils 15 and 16 of the prior art.

9 is a graph for explaining the relationship between the amount of inductance deviation between the compensation coils and the position of the magnetic core provided in the through hole of the coil bobbin in which the compensation coils are wound.

10 (a) to 10 (e) are diagrams schematically showing the positional relationship between the magnetic core and the compensation coils at points A, B, C, D and E shown in FIG.

1 (a) and 11 (b) are front sectional views for explaining the adjustment of the compensation coil in the prior art.

12 is a front sectional view showing a state in which the magnetic core slips from the coil bobbin in the prior art.

In Fig. 6, one end of the pair of horizontal deflection coils 3a, 3b is connected in parallel to the plus side, and the other end thereof is connected in series to the minus side via respective compensation coils 15 and 16.

As shown in Figs. 10 (a) to 10 (e), the inductances L15 and L16 of the compensation loils 15 and 16 are in the BB 'direction together with the jig 120 as with the hexagon wrench shown in Fig. 23. This is changed differently by rotatably moving the magnetic core 9 in the coil bobbin 8. The current flowing through the horizontal deflection coils 3a and 3b is thereby changed. Therefore, by moving the magnetic core 9, the intensity of the magnetic field induced from the horizontal deflection coils 3a and 3b can be adjusted. The strength of the magnetic field from the horizontal deflection coils 3a and 3b is controlled to minimize the displacement value Xv shown in Fig. 7, which is one of misconvergence.

FIG. 9 shows the relationship between the inductance deviation ΔL (Ll6-L15) between the inductance of the compensation coils 15 and 16 and the position of the magnetic core 9 along the BB 'direction, and the vertical axis shows the inductance deviation ΔL. Indicative, the horizontal axis represents the displacement amount of the center point 33 of the magnetic core 9 from the center point 500 of the coil bobbin 8 along the BB 'direction shown in FIG. 10 (a) to 10 (e) are shown corresponding to points A to E shown in FIG. Here, when the center point 33 of the magnetic core 9 coincides with the center point 500 of the coil bobbin 8, that is, when the displacement amount of the center point 33 of the magnetic core 9 is zero, the inductance displacement amount ΔL is zero. Note that it is not. This is because there is a slight inductance deviation between the compensation coils 15 and 16 due to production error.

In Fig. 9, the point D is the maximum point of the inductance deviation amount ΔL in the positive direction (referred to as + MAX), and the point B is the maximum point of the amount ΔL in the negative direction (referred to as-MAX).

The effective range of the inductance deviation ΔL is between + MAX and-MAX in the vertical direction of FIG. 9. Therefore, the effective adjustment range F1 of the magnetic core 9 is between the points B and D in the horizontal direction B-B '. In general, in adjusting the inductance of the compensation coils 15 and 16, the center point 33 of the magnetic core 9 is preferably present between the points B and D in the horizontal direction. In practice, the magnetic core 9 is inserted into the coil bobbin 8 and centered by an automatic machine. After that, fine position adjustment is performed manually.

11 (a) and 11 (b), the positions indicated by the dotted lines 32a and 32h indicate the positions of the center points 33 of the magnetic core 9 corresponding to the points B and D of FIG. The positions indicated by the dotted lines 32a and 32b are referred to as upper and lower adjustment boundaries, respectively.

As described above, in the method of adjusting the convergence by using the compensation coils 15 and 16, the magnetic core 9 is rotatably moved in the B-B 'direction little by little within the effective adjustment range F1. Therefore, the current flowing through the compensation coils 15 and 16 can be controlled by balancing the inductances L15 and L16 of the compensation coils 15 and 16.

In practice, the operator moves the magnetic core 9 so that the displacement value Xv becomes zero while watching the misconvergence state moved on the screen shown in FIG. Therefore, it is very difficult for the worker to pay attention to the magnetic core 9 while working.

As shown in Fig. 9, there are two points J1 and J2 in which the inductance deviation amount ΔL becomes J. Point J1 is within the effective adjustment range F1, while point J2 is outside the effective adjustment range F1. In addition, in the outer regions F2 and F3 from the points D and B, the direction in which the magnetic core 9 slides from the coil bobbin 8 coincides with the direction in which the inductance deviation ΔL decreases to zero.

In the deflection yoke adjustment process, the center point 33 of the magnetic core 9 located approximately at the center in the effective adjustment range F1; Fig. 11 (a) is a range as shown in Fig. 11 (b) generated due to the effective adjustment range F1, i.e., the special vibrations added thereto or the insertion error of the magnetic core 9 into the coil bobbin 8; Is located outside (F2 or F3).

In FIG. 9, if the center point 33 of the magnetic core 9 is located at the point M of the range F3, for example, before adjustment, the optimum point of the inductance deviation amount ΔL is the point J. The magnetic core 9 is moved in the direction of the point 12 close to the point M by the operator because the operator does not pay attention to the magnetic core 9 except for the pattern of the screen shown in FIG. Easy to be

However, at point J2, the bonding area between the rib 10 and the magnetic core 9 is very small. Therefore, the magnetic core 9 can be moved, inclined or slipped from the coil bobbin 8 in the worst case generated by vibrations or external forces added to it. Therefore, the center point 33 of the magnetic core 9 is within the effective adjustment range F1. Therefore, the ranges F2 and F3 are unacceptable adjustment ranges.

When the operator realizes that the magnetic core 9 is located in the unacceptable adjustment range F2 by the feeling of processing or observation of the adjustment jig, he rotates the magnetic core 9 in the opposite direction to make the effective adjustment range F1. This results in reduced working efficiency in the adjustment of the deflection yoke.

In addition, assuming that the optimum adjustment point of the inductance deviation amount ΔL is the point K of FIG. 9, the adjustment point K1 coinciding with the optimum point K is within the effective adjustment range F1, but is not acceptable. The point K2 corresponding to the point J2 at F3 coincides with the position at which the magnetic core 9 slides from the coil bobbin 8.

In this case, when the worker moves the magnetic core 5 in the direction of the point K2, the magnetic core 9 slides from the coil bobbin 8 before reaching the point K2. 12 shows a magnetic core 9 sliding from the coil bobbin 8.

In normal operation, when the operator adjusts the inductance deviation ΔL while paying attention to the pattern of the screen, he does not recognize that the center point 33 of the magnetic core 9 is outside the effective adjustment range F1. In this case, a problem arises in which the magnetic core 9 slips from the coil bobbin 8. This applies when the center point 33 of the magnetic gore 9 is in an unacceptable adjustment range F2.

13 is a cross-sectional view showing another compensation coil of the deflection yoke in the prior art.

As a compensation coil device for a deflection yoke device capable of preventing the magnetic core from slipping, a deflection yoke device is disclosed in Japanese Patent Laid-Open No. 2-114434 / 1990. In Fig. 13, reference numeral 101 denotes a cylindrical member having a female thread and a male thread, and reference numerals 102 and 103 denote a compensation coil wound around a pair of coil bobbins 104 and 105. The pair of coil bobbins 104 and 105 have female threads and are movably coupled to the male threads of the cylindrical member 101 in the horizontal direction. The cover case 107 is provided to cover the entire element including the compensating coils 102, 103.

When adjusting the inductance deviation ΔL, the compensation coils 102 and 103 are rotatably moved in the center of the cylindrical member 101 by rotating with the handle 108 provided integrally with the cylindrical member 101. In addition, the magnetic core 106 can likewise be rotatably moved along the horizontal direction.

The magnetic core 106 is prevented from sliding out of the cylindrical member 101 by the flanges 104a and 105a provided at the distal ends of the coil bobbins 104 and 105, and the coil bobbins 104 and 105 are covered by the cover case 107. Sliding from the cylindrical member 101 is prevented by the wall surface 107a provided at the distal end portion.

When assembling the compensation coil arrangement, the magnetic core 106 is engaged with the female thread of the cylindrical member 101, and then the coil bobbins 104 and 105 are engaged with the male thread of the cylindrical member 101 from its distal end. Since the compensating coil device has a structure as described above, at least one coil bobbin 104 when there is an insertion error of the magnetic core 106 or a defect such as a crack or chipping generated by itself. , 105 need to be removed from the cylindrical member 101 in order to replace the magnetic core 106, and as a result, the working efficiency in the adjustment process is deteriorated.

In addition, since the position adjustment of the magnetic core 106 is made by the coil bobbins 104 and 105, the length of the available magnetic core 106 is limited. Therefore, it is difficult to meet the required specifications of the various compensation coil devices, which hinders the general use of the coil bobbin as a basic element.

In addition, since the compensating coil device has many threads, the operation function of the assembly is deteriorated, its configuration is complicated, and the production cost is increased.

It is therefore a general object of the present invention to provide a deflection yoke device in which the above disadvantages are eliminated.

It is a particular object of the present invention to provide a deflection yoke device capable of effectively adjusting the position of the magnetic core, thereby forming the protective cover so that the protective cover has a function of adjusting the position of the magnetic core so that the magnetic core slides from the coil bobbin without a complicated structure. To reduce the production cost by easily replacing the magnetic core.

Another specific object of the present invention is to improve the working efficiency of magnetic core adjustment by matching the adjustment range of the magnetic core to the effective adjustable range of the magnetic core and matching the direction for changing the inductance deviation with the direction for adjusting the magnetic core. It is to provide a deflection yoke device.

Another more specific object of the present invention is a pair of horizontal deflection coils, a pair of vertical deflection coils, a coil bobbin having a defined through hole along its central axis, wound around the coil bobbin and connected in series with the horizontal deflection coil. A coil bobbin and a magnetic core inserted into the through hole of the coil bobbin to finely adjust the amount of inductance deviation between the pair of compensation coils and the pair of compensation coils by the displacement in the through hole of the coil bobbin. To provide a deflection yoke device having a substrate and a protective cover for covering the coil bobbin and a pair of compensation coils, the protective cover has an adjustment range capable of displacing the magnetic core in the through hole of the coil bobbin. It is to provide a deflection yoke device including an adjustment range adjustment means for adjustment.

Other objects and additional features of the present invention are apparent from the following detailed description.

1 is a side view showing a deflection yoke device of the prior art in which the compensation coil device is shown in cross section;

2 is a front sectional view of the coil bobbin of the compensating coil device according to the line A-A shown in FIG.

3 is a partial side view of the compensating coil device shown in the "C" direction of FIG.

4 is a perspective view of a protective cover of the prior art;

5 is a side view of the compensating coil arrangement seen in the C direction of FIG. 2 with a portion of the protective cover cut away to show the coil bobbin.

6 is a circuit diagram showing an electrical connection between a pair of compensation coils and a pair of horizontal deflection coils in the prior art.

7 is a schematic diagram showing a misconvergence pattern displayed on the screen of a CRT in the prior art.

8 (a) and 8 (b) are front cross-sectional views for explaining the adjustment of the compensation coil in the prior art.

9 is a graph for explaining the relationship between the amount of inductance deviation between compensation coils and the position of a magnetic core provided in a coil bobbin in which a pair of compensation coils are wound.

10 (a) to 10 (e) schematically show the positional relationship between the magnetic core and the compensation coils at points A, B, C, D, and E shown in FIG. 9, respectively.

11 (a) and 11 (b) are front cross-sectional views for explaining the adjustment of a compensation coil in the prior art.

12 is a front sectional view showing a state in which a magnetic core slips from a coil bobbin in the prior art;

Fig. 13 is a sectional view showing another compensating coil device of the deflection yoke device in the prior art.

Fig. 14A is a front sectional view showing the compensation coil device of the first embodiment of the deflection yoke device in the present invention.

Fig. 14B is a front sectional view showing the compensation coil device of the first embodiment of the deflection yoke device in the present invention.

FIG. 15 is a partial side view of the compensating coil device shown in the direction of arrow C of FIG. 14 (a). FIG.

FIG. 16 is a side view of the change compensation coil arrangement of the first embodiment shown in FIGS. 14A and 14B.

17 (a) and 17 (b) are front cross-sectional views showing a second embodiment of the compensation coil device for deflection yoke feast in the present invention.

18 is a side view of the compensation coil arrangement shown in the direction shown by arrow C of FIG. 17 (2).

FIG. 19 is a side view of the strain compensation coil device of the second embodiment shown in FIGS. 17A and 17B.

20 (a) and 20 (b) are front sectional views showing the compensation coil device of the third embodiment of the deflection yoke device of the present invention.

21 is a side view of the compensating coil device shown in the direction of arrow C of FIG. 20 (a);

Fig. 22 is a front sectional view of the compensating coil device of the fourth embodiment of the deflection yoke device of the present invention.

FIG. 23 is a perspective view of a protective cover of the compensation coil device shown in FIG. 22; FIG.

Fig. 24 is a partial perspective view showing a characteristic portion of the compensating coil device of the fourth embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

2a, 2b: vertical deflection coils 3a, 3b: horizontal deflection coils

4: outer core 5: printed circuit board

6: protective cover 7: through hole

8: coil bobbin 9: magnetic core

10: rib 13, 14: flange

17, 18: nail 23, 24: jig insertion hole

27: hexagonal hole 32: guide groove

33: center point 40, 41: adjustment rib

42, 43: adjustable sidewall

Hereinafter, the deflection yoke device of the first to fourth embodiments of the present invention will be described with reference to Figs.

[First Embodiment]

14 (a) and 14 (b) are front views showing the compensation coil device of the first embodiment of the deflection yoke device in the present invention,

Fig. 15 is a partial side cross-sectional view of the compensating coil device shown in the direction seen by arrow C of Figs. 14 (a) and 14 (b).

The deflection yoke device of the first embodiment of the present invention is shown in FIG. 1 except that a pair of adjusting ribs 40, 41 are provided inside the protective cover 6 adjacent to the outer end of the coil bobbin 8 as an adjusting range adjusting member. It has the same structure as the prior art blinded based on -6.

Therefore, since the configuration is the same as described above with reference to FIG. 1, a pair of horizontal deflection coils 3a and 3b, a pair of vertical deflection coils 2a and 2b, and a pair of horizontal and vertical deflection coils 3a The description of the separator 1, the external core 4, and the printed circuit board 5 for separating the 3b, 2a, and 2b will be omitted.

Here, the peripheral part and the protective cover 6 which are the characteristic part of this invention are demonstrated.

In Figs. 14A and 14B, like numerals denote like parts or corresponding parts described based on Figs. 2 and 11.

14 (a) and 14 (b) are cross-sectional views corresponding to FIGS. 8 (a) and 8 (b), and FIG. 15 corresponds to FIG.

In Figs. 14 (a), 14 (b) and 15, reference numeral 8 denotes a coil bobbin formed integrally by using an insulating material such as resin to wind the coil, and reference numeral 9 denotes a male thread formed on the outer circumferential surface thereof. It is made of magnetic core. A plurality of ribs 10 protrude from the inner wall of the through hole 7 along the central axis of the through hole 7 in the coil bobbin 8 (B-B 'direction). Since the plurality of ribs 10 advance the magnetic core 9 in the BB 'direction, the magnetic core 9 is moved in the BB' direction by the jig 120 such as the hexagonal wrench shown in FIG. It is provided in the through-hole of the bobbin 8, and is provided with the some rib 10. As shown in FIG.

Here, reference numerals 9a and 9b denote end faces of the magnetic core 9, and reference numerals 11 to 14 denote four flanges of the coil bobbin 8. Reference numeral 15 designates a compensation coil wound between the flanges 11 and 12 of the coil bobbin 8 and reference numeral 16 designates a compensation coil wound between the flanges 13 and 14. Reference numerals 17 and 18 indicate nails provided integrally to the coil bobbin 8 at the lower end in order to have elastic force. Thereby the coil bobbin 8 is fixed to the printed circuit board 5 as described below. Reference numerals 19 and 20 indicate ribs integrally provided in the coil bobbin 8, and reference numerals 21 and 22 indicate that the nails 17 and 18 are firmly coupled to fix the coil bobbin 8 to the printed circuit board 5. Coupling holes provided in the printed circuit board 5. Reference numeral 27 designates a hexagonal hole penetrating the magnetic core 9 for inserting the jig 120 having a hexagon when moving the magnetic core in the direction B-B '. Reference numerals 23 and 24 denote jig insertion provided on the side of the protective cover 6 for inserting the jig 120 into the hexagonal hole 27 of the magnetic core 9 when adjusting the misconvergence of the flat yoke as described below. Indicate the hole.

In addition, the guide groove 32 which has a U shape in the protection cover 6 is defined by forming a pair of convex parts 25 and 26 in FIG.

Here, the structural features of the present invention will be described.

The main feature of the present invention is that the adjustment range G1 in which the center point 33 of the magnetic core 9 can be moved in the coil bobbin 8 is adjusted. In particular, reference numerals 6a and 6b indicate the inner wall of the inclined portion of the protective cover 6, which is provided with adjusting ribs 40 and 41 (limiters) for limiting the movement of the magnetic core 9. Since the adjusting ribs 40 and 41 extend downward from the inner walls 6a and 6b of the protective cover 6 integrally formed by molding, the end portions of the adjusting ribs 40 and 41 are printed by the protective cover 6. When installed in the circuit board 5, they are respectively located adjacent to the opening of the through hole 7. The adjusting ribs 40, 41 restrict the movement of the magnetic core 9 by colliding with the magnetic core 9 when the magnetic core 9 emerges from the through hole 7. In practice, the magnetic core 9 impinges against each of the inner surfaces 40a, 41a of the regulating ribs 40, 41, thereby preventing slipping from the coil bobbin 8. Thus, the allowable displacement range G5 of the magnetic core 9, ie the movable adjustment range G5, is the spacing between the inner surfaces 40a. 41a of the adjustment ribs 40, 41.

As shown in FIG. 15, the distal end 40b of the regulating rib 40 is located within the range where the distal end 40b may collide with the distal end 9b of the magnetic core 9, but the hole is in the magnetic core 9. Does not collide with the circumscribed circle 27 'of the hexagonal hole 27, and the hole is provided at the center of the magnetic core 9. Therefore, it is possible to prevent the jig 120 from colliding with the adjusting rib 40 when adjusting the magnetic core 9. The relationship between the other regulating rib 41 of the magnetic core 9 and the other distal end 9a is the same as that described above although the description is omitted.

16 is a side view of the modified compensation coil device of the first embodiment. As shown in FIG. 16, the plurality of regulating ribs 40 ′, 40 may collide with the distal end 9a of the magnetic core 9, but the circumscribed circle 27 of the hexagonal hole 27 of the magnetic core 9. Only copper located within a range that cannot collide with ') can be supplied.

Next, the assembling and adjusting operation of the compensation coil of the first embodiment will be described.

First, after the body of the deflection yoke device is configured, the printed circuit board 5 provided with the coil bobbin 8 is installed in the deflection yoke. Compensation coils 15 and 16 are wound around the coil bobbin 8. In addition, the magnetic core 9 is screwed into the through-hole 7 of the coil bobbin 8 by a manual or automatic machine. In the steady state, the magnetic core 9 is approximately centered in the longitudinal direction to allow fine adjustment work.

Thereafter, the printed circuit board 5, the coil bobbin 8 and the compensation coils 15 and 16 are elastically bonded to the nails 28a and 28b by the printed circuit board 5 so as to have the printed circuit board (B) on the side thereof. It is covered with a protective cover 6 fixed to 5).

The jig 120 is then manually inserted into the hexagonal hole 27 from one end, for example, by the operator, from the end defined at the end 9b. The operator adjusts the position of the fraud core 9 by minutely rotating and displacing the magnetic core 9 with the jig 120.

In this embodiment, the adjustment ribs 40, 41 are provided integrally with the protective cover 6. Therefore, the magnetic core 9 can be prevented from sliding off the coil bobbin 8 by colliding with one of the adjusting ribs 40, 41. In particular, as shown in FIG. 14, when the center point 33 of the magnetic core 9 is disposed in the B direction to reach the lower adjustment boundary 32a, the left distal end surface 9a of the magnetic core 9 is Against the inner surface 41a of the adjusting rib 41. Therefore, the position of the center point 33 of the magnetic core 9 is limited at the point B shown in FIG. 9 so that the magnetic core 9 does not move in the sliding direction.

As shown in Fig. 14B, when the center point 33 of the magnetic core 9 reaches the upper adjustment boundary 32b by moving in the B 'direction, the right end surface 9b of the magnetic core 9 is reached. ) Impinges against the inner surface 40a of the adjusting rib 40. Therefore, the position of the center point 33 of the magnetic core 9 is limited at the point D shown in FIG. 9 so that the magnetic core 9 does not move in the sliding direction.

Since the deflection yoke of the first embodiment has a configuration as shown in Figs. 14 (a) and 14 (b), one of the distal end surfaces 9a and 9b of the magnetic core 9 is provided with the adjusting ribs 40 and 41. The amount of displacement of the magnetic core 9 within the adjustment range G1 can be limited by executing the collision with respect to one of the inner surfaces 40a and 41a of the magnet. Therefore, when adjusting the position of the magnetic core 9, the magnetic The core 9 is safely prevented from sliding out of the coil bobbin 8.

In addition, the inner surfaces 40a, 4la of the adjusting ribs 40, 41 for limiting the displacement of the magnetic core 9 are respectively located in correspondence with the + MAX point B and the -MAX point D shown in FIG. . Therefore, it should be noted that the magnetic core position adjustment range and the direction of change of the inductance deviation amount coincide with the adjustment direction of the magnetic core position. Thereby, the operator can recognize the correct adjustment direction of the magnetic core 9 without watching the displacement direction of the magnetic core 9 by only watching the display and rotating the magnetic core 9 minutely, so that the magnetic core adjustment Improve the efficiency of the work.

As described above, the inner surfaces 40a and 41a of the adjusting ribs 40 and 41 are respectively positioned corresponding to the + MAX point B and the -MAX point D shown in FIG. However, the positions of the inner surfaces 40a and 41a are not limited to the points B and D. The inner surfaces 40a and 41a may be located respectively corresponding to the points B ', D' 'or points B' 'and D' shown in FIG. 9, and the points B 'and D' 'are the compensation coils 15, 16) corresponds to the outer position away from the points F1a, F1b by the length Δ1 corresponding to the tolerance of the inductance deviation inherent in (16), and the points B '', D 'are the length Δ1 corresponding to the tolerance of the inductance deviation Corresponds to the inner position away from points F1a and F1b.

When the adjusting ribs 40 and 41 are respectively positioned corresponding to the points B 'and D' ', the adjusting range of the inductance deviation amount of the compensation coil device can be maximized in consideration of the inductance deviation of the horizontal deflection yoke. When the adjusting ribs 40 and 41 are positioned respectively at points B '' and D 'corresponding to points B' 'and D', the inductance even when there is a maximum deviation (tolerance) in the compensation coils 15 and 16 The direction of change of the amount of deviation may be fixed to coincide with the adjustment direction of the magnetic core position of the one-to-one correspondence. This position can further improve the efficiency of the magnetic core adjustment operation.

In addition, after the coil bobbin 8 has been assembled, the protection compared with that disclosed in Japanese Patent Laid-Open No. 2-114434 / 1990, when the magnetic core 9 is changed due to a magnetic core insertion error or a magnetic core self defect. By removing the cover 6, the magnetic core 9 can be replaced more quickly and easily.

Further, in the above embodiment, since the coil bobbin 8 does not adjust the position of the magnetic core 9 by itself, it is easier to replace the magnetic core 9 with a different length, which makes the coil bobbin (8) can be used in common.

Second Embodiment

In the deflection yoke device of the first embodiment, the adjusting ribs 40, 41 are formed integrally with the protective cover 6 as the adjusting range adjusting member. However, part of the protective cover 6 can be used as the adjustment range adjusting member.

17 (a) and 17 (b) are front sectional views showing the second embodiment of the compensation coil device of the deflection yoke device in the present invention.

FIG. 18 is a side view of the compensation coil device shown in the direction of arrow C of FIG.

FIG. 19 is a side view of the deformation deflection compensating coil device of the second embodiment, wherein like reference numerals designate like or corresponding parts described with reference to FIGS. 14A to 15, and descriptions are omitted for simplicity.

Here, the adjustment side wall 42, 43 as the adjustment range adjustment member is lowered such that the side wall of the protective cover 6 for covering the compensation coils 15, 16 faces both end faces of the coil bobbin 8 in parallel. To the protective cover 6 in a vertically extending manner. In the above configuration, the lower ends 42b, 43b of the adjustment side walls 42, 43 are formed to be located at the same positions as the adjustment ribs 40, 41 of the first embodiment shown in Fig. 14A. Therefore, the lower ends 42b and 43b can collide against the distal end of the magnetic core 9 without difficulty in inserting the jig 120.

In addition, the spacing between the inner surfaces of the adjusting side walls 42 and 43 is as large as the spacing between the inner surfaces 40a and 41a of the adjusting ribs 40 and 41 of the first embodiment shown in Fig. 14 (a). As a result, the movable adjustment range G5 is formed.

17 (a) and 17 (b), when the center point 33 of the magnetic core 9 reaches the lower adjustment boundary 32a by moving in the direction shown by the arrow B, the left side of the magnetic core 9 The end face 9a impinges against the inner face 42a of the adjusting side wall 42 (Fig. 17 (a)), therefore, the center point 33 is located at the point B shown in Fig. 9 and slides. Do not move in the direction.

When the center point 33 of the magnetic core 9 reaches the upper adjustment boundary 32b by moving in the direction shown by the arrow B ', the right end face 9b of the magnetic core 9 is provided with an adjustment sidewall ( It collides with the inner surface 43a of 43 (Fig. 17 (b)). Therefore, the center point 33 is located at the point D shown in FIG. 9 and does not move in the sliding direction.

That is, when the magnetic core 9 is moved in the direction of the double-headed arrow BB 'by screwing, the displacement amount of the magnetic core 9 is determined by the magnetic core with respect to one of the inner surfaces 422 and 43a of the adjusting side walls 42 and 43. It is restricted in the movable adjustment range G5 by colliding one of the distal end surfaces 9a and 9b of (9). Therefore, since the magnetic core 9 can be prevented from slipping from the coil retaining 8, the efficiency of the magnetic core adjusting operation is improved as in the first embodiment.

As shown in FIG. 18, the collision range 9b of the inner surface 43a of the adjusting side wall 43 with the magnetic core 9 is a circumscribed circle of the hexagonal hole 27 provided in the center of the magnetic core 9. It is provided outside of 27 '. This is applied at the opposite inner surface 42a of the adjusting side wall 42.

In addition, as long as the impact area 44 of the inner surfaces 42a, 43a of the adjustment side walls 42, 43 is outside the circumscribed circle 27 ′ of the hexagonal hole 27 of the magnetic core 9. 44 may be replaced with a collision area 44 'as shown in FIG. 19, and the impact area 44' is formed to collide with the side of the magnetic core 9.

Third Embodiment

20 (a) and 20 (b) are front sectional views showing the third embodiment of the compensating coil device for the deflection yoke of the present invention.

FIG. 21 is a side view of the compensating coil arrangement shown in the direction of arrow C of FIG. 20 (a), wherein like numerals indicate similar or corresponding parts described with reference to FIGS. 14 (a) to 15 for simplicity; Description is omitted.

Here, the positional adjustment of the magnetic core 9 is carried out with the horizontal wall of the protective cover 6 and not with the side wall.

In the third embodiment, instead of extending down the sidewall of the protective cover 6 to form the adjustable sidewalls 42, 43, the adjustment horizontals 46, 47 are at both ends of the coil bobbin 8. It is supplied as an adjustment range adjusting member by extending the wall to form the guide groove 32 for the jig 120 adjacent to the.

In this case, the distal inner surfaces 46a and 47a of the adjusting horizontal walls 46 and 47 are formed to collide with the distal ends of the magnetic core 9. The spacing between the distal inner surfaces 46a and 47a of the adjusting horizontal walls 46 and 47 is determined to be the same as between the inner surfaces 40a and 41a of the adjusting ribs 40 and 41 shown in Fig. 14 (a). Therefore, the movable adjustment range G5 of the magnetic core 9 is limited.

20 (a) and 20 (b), when the center war 33 of the magnetic core 9 reaches the lower adjustment boundary 32a by moving in the direction shown by the arrow B, the magnetic core 9 and The left end surface 9a impinges against the distal inner surface 46a of the adjusting horizontal wall 46 (Fig. 20 (a)). Therefore, the center point is located at the point B shown in FIG.

When the center point 33 of the magnetic core 9 reaches the upper adjustment boundary 32b by moving in the direction shown by arrow B ', the right end face 9b of the magnetic core 9 is adjusted horizontal wall 47. Impinge against the distal inner surface 47a (Fig. 20 (b)). Therefore, the center point 33 is located at the point D shown in FIG.

That is, when the magnetic core 9 is screwed and moved in the direction shown by the double-headed arrow B-B ', the displacement amount of the magnetic core 9 is changed among the distal inner surfaces 46a and 47a of the adjusting horizontal walls 46 and 47. It is limited in the movable adjustment range G5 by colliding one of the end faces 9a, 9b of the magnetic core 9 with respect to one. Therefore, since the magnetic core 9 can be prevented from slipping from the coil bobbin 8, the efficiency of the magnetic core adjusting operation increases as in the first and second embodiments.

As shown in FIG. 21, the impingement section 48 of the distal inner surface 47a of the adjustable horizontal wall 47 with the magnetic core 9 is a hexagonal hole 27 provided in the center of the magnetic core 9. Is provided at a position facing the outside of the circumferential surface 27 '. This applies to the opposite distal inner surface 46a of the regulating horizontal housing 46.

[Example 4]

22 is a front view of a compensating coil device of the deflection yoke device of the fourth embodiment in the present invention.

FIG. 23 is a perspective view of a protective cover of the compensation coil device illustrated in FIG. 22.

Fig. 24 is a partial perspective view showing a characteristic portion of the protective cover of the compensating coil device of the fourth embodiment of the present invention, wherein like numerals designate and describe similar or corresponding parts described with reference to Figs. 14 (a) to 15. Is omitted for simplicity. As shown in Fig. 22, the vertical wall is provided in the protective cover 6 so as to be parallel to both distal ends of the coil bobbin 8, each having a pair of protrusions 52, 53 protruding therein. A pair of adjustment tab sections 50, 51 are provided on the vertical wall such that the pair of protrusions 52, 53 face the end face of the magnetic core 9. The adjusting tab sections 50, 51 are formed integrally with the protective cover 6 by molding.

The spacing between the tip of the protrusion 52 and the tip of the protrusion 53 is configured to be slightly shorter than the longitudinal length B1 of the coil bobbin 8.

In addition, when the protective cover 6 is installed on the printed circuit board or detached from the printed circuit board, each of the protrusions 52, 53 can easily deform the adjusting tab sections 50, 51 to the outside. So that it has a pair of walls 52a, 53a tapered on both sides.

Thus, when the protective cover 6 is installed on the printed circuit board in the direction shown by arrow A2, the adjusting tab section 50 has a pair of protrusions 52, 53 inserted into the through hole 7 at its distal end. Elastically outward so that it can Therefore, the gap between the tips of the projections 52 and 53 is the movable adjustment range H5 for limiting the amount of displacement of the magnetic core 9.

In addition, jig insertion holes 23 and 24 are formed in the center of the adjustment tab sections 50 and 51 for inserting the jig 120 to position the magnetic core 9.

In the fourth embodiment, this means that the movable adjustment range H5 of the magnetic core 9 is the longitudinal length of the coil bobbin 8 when the center point 33 of the magnetic core 9 moves within the adjustable range H1. It is effective when it is shorter than (B1).

In addition, in the above embodiment, the adjusting tab sections 50, 51 prevent the displacement of the magnetic core 9 even when the excess force on the protrusions 52, 53 is given by the displacement of the magnetic core 9. It has a sufficiently large elastic strength.

The operation and effect of the above embodiment are the same as described above. Therefore, the description is omitted here.

As described in each compensation coil device of the deflection yoke device of the embodiment in the present invention, the protective cover has a positioning structure of the magnetic core, so that the magnetic core is prevented from sliding from the coil bobbin. In addition, the deflection yoke device of the present invention can easily change the magnetic core after the deflection yoke device is assembled and can be changed from the market requirements to various kinds required by changing the length of the magnetic core. Coil bobbins can be used in common.

In general, the dimensions and compensation circuitry of the deflection yoke device have been changed to meet the various types of content required from market requirements. That is, the dimensions of the printed circuit board having the compensation circuit and the protective cover for covering the printed circuit board have been inevitably changed depending on the required change. Therefore, there is an advantage of realizing common use of the coil bobbin even when the dimensions of the protective cover are changed.

In each embodiment of the deflection yoke device, an example of using a saddle-saddle type deflection yoke is described, but the present invention is, for example, a saddle toroidal type in which a deflection coil is wound around an outer core. toroidal type).

Briefly, according to the deflection yoke of the present invention, the excellent action and effect are as follows.

(1) By providing the adjustment range adjusting member in the protective cover, the position of the magnetic core can be adjusted without complicating the structure of the deflection yoke device and the sliding of the magnetic core from the coil bobbin can be prevented.

(2) By removing the protective cover from the deflection yoke device, the defective magnetic core can be easily replaced with another one.

(3) By varying the length of the magnetic core to be inserted into the coil bobbin, various kinds of contents required by the market need can be satisfied, so that the coil bobbin can be used in common and the production cost can be reduced.

(4) by providing the adjustment range adjusting member at a position where the magnetic core is limited in displacement to provide a positive maximum value and a negative maximum value of the amount of inductance deviation between the compensation coils, thereby improving the efficiency of the magnetic core adjustment operation. The amount of inductance deviation can be matched with the position of the magnetic core to satisfy the amount in the coil bobbin one-to-one relationship.

Claims (10)

A pair of horizontal deflection coils, a pair of vertical deflection coils, a coil bobbin having a defined through hole along its central axis, a pair of compensation coils wound around the coil bobbin and connected in series with the horizontal deflection coil, A magnetic core inserted into the through hole of the coil bobbin for finely adjusting the amount of inductance deviation between the pair of compensation coils by the displacement in the through hole of the bobbin, a substrate for installing the coil bobbin, and a coil bobbin; A deflection yoke device having a protective cover for covering a pair of compensation coils, And said protective cover is provided with adjusting range adjusting means for adjusting an adjusting range capable of displacing the magnetic core in the through hole of the coil bobbin. 2. The through-hole of the coil bobbin according to claim 1, wherein said adjustment range adjusting means includes a first position of the magnetic core in the through-hole of the coil bobbin whose inductance deviation amount is the maximum value and a inductance deviation amount of the coil core. And the second position of the magnetic core of the deflection yoke is configured to coincide with a boundary of an adjustment range capable of displacing the magnetic core within the through hole of the coil bobbin. 2. A deflection yoke device according to claim 1, wherein said adjusting range adjusting means has an adjusting rib extending downward from an inner upper surface of said protective cover, said adjusting rib being disposed so as to face each distal end of the magnetic core. The deflection yoke device according to claim 1, wherein said adjustment range adjusting means is constituted by a portion of the protective cover side wall, and the portions of the protective cover side wall are respectively disposed to face the distal ends of the magnetic core. The deflection according to claim 1, wherein said adjusting range adjusting means is constituted by a portion of a horizontal wall of a protective cover for guiding the adjusting jig of the magnetic core, the portion of which is provided so as to face the distal end of the magnetic core, respectively. Yoke device. The method according to claim 1, wherein the adjustment range adjusting means has a pair of adjustment tab sections each having a pair of protrusions arranged in parallel at predetermined intervals, the pair of adjustment tab sections being a pair of protrusions. A deflection yoke device disposed at the side of the protective cover such that the distal end faces one distal end of the coil bobbin. 3. A deflection yoke device according to claim 2, wherein said adjusting range adjusting means has an adjusting rib extending downward from an inner upper surface of said protective cover, said adjusting rib being disposed so as to face each distal end of the magnetic core. 3. A deflection yoke device according to claim 2, wherein said adjustment range adjusting means is constituted by a part of the side wall of the protective cover, and the part of the side wall of the protective cover is arranged so as to face the distal end of the magnetic core respectively. The deflection according to claim 2, wherein said adjusting range adjusting means is constituted by a portion of a horizontal wall of a protective cover for guiding the adjusting jig of the magnetic core, and the portion of the horizontal wall is provided so as to face the distal end of the magnetic core, respectively. Yoke device. 3. The apparatus according to claim 2, wherein the adjustment range adjusting means has a pair of adjustment tab sections each having a pair of protrusions arranged in parallel at predetermined intervals, the pair of adjustment tab sections being a pair of protrusions. A deflection yoke device disposed at the side wall of the protective cover such that the distal end faces one distal end of the coil bobbin.

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