JPH01260744A - Colour cathode-ray tube adjusting device - Google Patents

Abstract

PURPOSE:To safely adjust an image of a colour cathode-ray tube while watching the image by transferring rotation from a rotation drive unit to a pair of magnetic rings through an expandable, bend-free and eccentric-free rotation transfer joint and rotation divisional transfer mechanism. CONSTITUTION:A rotation divisional transfer mechanism 21 is adjusted its location adequately to be hooked with a pair of magnetic rings 1a and 1b attached to a neck portion of a colour cathode-ray tube. By a press mechanism 12, the rotation divisional transfer mechanism 21 is forced toward the pair of magnetic rings 1a and 1b. While watching an image under the state, a rotation drive unit 31 is operated so as to transfer rotation to an input shaft 24 of the rotation divisional transfer mechanism 21 through a rotation transfer joint 41. This causes that the pair of magnetic rings 1a and 1b are equally rotated in opposite directions so as to adjust an image of the colour cathode-ray tube or compensate a bow shaped-image thereof. Accordingly, an image of a large colour cathode-ray tube is safely and easily adjusted while watching the image.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a color cathode ray tube adjustment device for adjusting an image on a color cathode ray tube.

(Prior Art) When a straight line is displayed on the screen of a color cathode ray tube, it may appear arched.

To correct this, for example, attach two ring-shaped four-pole correction magnets, that is, magnetic field rings, to the neck of a color cathode ray tube, and connect these two magnetic field rings to each other around the neck axis. It is preferable to apply an appropriate magnetic field inside the color cathode ray tube by rotating the same amount in the opposite direction. Note that a technology that is far from this is described in, for example, Japanese Patent Laid-Open No. 56-93251.

Conventionally, when performing the above-mentioned image adjustment, in many cases, the adjuster extended his hand to the neck portion and rotated the magnetic field ring with his finger while looking at the screen.

(Problem to be Solved by the Invention) However, in this conventional method, the location of the magnetic field ring is close to high voltage and high current components such as 25 to 30 KV, 5 A' to IOA, so there is always a risk of electric shock. There was danger. Not only that, but if the color cathode ray tube is large, it is impossible to rotate it while looking at the screen.

The present invention aims to solve these problems, and it is possible to safely adjust the image by rotating the magnetic field ring, and also to easily adjust the image while viewing the screen even on a large color cathode ray tube. The purpose of this invention is to provide a color cathode ray tube adjustment device that can be used.

[Structure of the invention]

(Means for Solving the Problems) The color cathode ray tube adjustment device of the present invention has a pair of picture tubes each rotatably attached to the neck of a color cathode ray tube.
A rotation split transmission mechanism that transmits the rotation of one input shaft to both magnetic field rings as equal rotation in opposite directions to the adjustment magnetic field ring and whose position is variable is removably engaged with the adjustment magnetic field ring. The rotational drive source and the input shaft of the rotational split transmission mechanism are connected by a telescopic and bendable or eccentric rotational transmission joint, and the rotational splitting transmission mechanism is directed toward the magnetic field ring by a pressing mechanism. It is something that energizes.

(Function) In the color cathode ray tube adjusting device of the present invention, first, the position of the rotary divided transmission mechanism is adjusted appropriately, and this rotary divided transmission mechanism is connected to a pair of magnetic field rings attached to the neck of the color cathode ray tube. Match. Then, the rotation division transmission mechanism is urged toward the magnetic field ring by the pressing mechanism. In this state, while looking at the screen, drive the rotational drive source and transmit rotation from this rotational drive source to the input shaft of the rotational split transmission mechanism via the rotational transmission joint. The magnetic field rings are rotated by equal amounts in opposite directions to adjust the image of the color cathode ray tube, that is, to correct the arcuate display. At this time, the error in the relative positional relationship between the rotational drive source and the rotational division transmission mechanism is
It is absorbed by a rotation transmission joint that is telescopic and bendable or eccentric.

(Embodiment) Hereinafter, one embodiment of the color cathode ray tube adjusting device of the present invention will be described based on the drawings.

First, the conditions that this type of color cathode ray tube adjusting device must satisfy will be explained.

A two-ply magnetic field ring 1a as shown in FIG.

1b is attached to the neck portion (not shown) of the cathode ray tube, and it is necessary to similarly attach a deflection cork 2 for applying an alternating magnetic field to the cathode ray tube and an image quality adjuster (not shown) to this neck portion. There is only a gap with a width of about 10 #11 between the deflection yoke 2 and the image quality adjuster, but the magnetic field rings Ia and lb need to be installed in that gap, so they are usually installed as shown in the figure. The deflection yoke 2 is attached as an accessory to the deflection yoke 2.

In addition to the bow-shaped display correction that is the object of the present invention, there are various corrections and adjustments for adjusting the image of a cathode ray tube. In order to work particularly on the deflection yoke 2 and the image quality adjuster, various devices are attached to the neck of the cathode ray tube.

Therefore, even if the bow-shaped display is corrected by the device,
The installation space for this device is limited. In addition, when using a magnetic material such as iron in the device, the magnetic material should be placed 300 to 50 mm away from the neck of the cathode ray tube so as not to interfere with the magnetic field.
It is necessary to keep a distance of 0a or more. In other words, the adjustment position for the magnetic field rings 1a and 1b is such that at least the part installed near the magnetic field rings 1a and lb is compact, and if a motor is used, the motor can be connected to the neck of the cathode ray tube. It must be possible to install it at a sufficient distance from the

Next, an embodiment of the present invention is shown in FIGS. 1 and 2.

A pair of identical magnetic field rings 1a and lb have teeth formed on their outer peripheral surfaces to form a gear-like shape, and are rotatable independently.

In FIG. 1, 11 is a base plate, and the position of this base plate 11 is adjustable.

A pressing mechanism 12 is provided on this base plate 11. In this suppression mechanism 12, a shaft 14 is slidably supported by a support 13 fixed to the pace plate 11, and a main body 16 of a cylinder 15 is fixed to the base plate 11. A rod 11 that can move forward and backward is fixedly connected to the shaft 14.

A thin box body 22, which constitutes the outer shell of the rotation split transmission mechanism 21, is fixed to the tip of the shaft 14.

Next, the internal structure of the rotation split transmission mechanism 21 provided within the box body 22 will be explained with reference to FIG.

Bearing portion 23 formed in the box body 22 (shown in FIG. 1)
A bevel gear 2 is attached to the tip of the input shaft 24 which is rotatably supported by the input shaft 24.
5 is fixed. A bevel gear 26 is meshed with this bevel gear 25, and a thick gear 26 is engaged with this bevel gear 26.
7 are provided integrally and coaxially. Further, the thick gear 21 is meshed with a first drive gear 28a, which is thinner than the thick gear 27, and an idle gear 29. Furthermore, this idle gear 29 has a second drive gear 28t.
l are engaged. And each of the drive gears 28a
, 28b are adapted to be removably engaged with each of the magnetic field rings 1a, lb.

In addition, in FIG. 1, 31 is a motor as a rotational drive source.
The rotary shaft 32 of this motor 31 is equipped with a heavy vehicle 11i33.
is fixed. The support body 3 of the motor 31 is
An output shaft 36 is rotatably supported by a bearing portion 35 formed at 4, and a bevel gear 37 fixed to one end of the output shaft 36 is meshed with the bevel gear 33.

The output shaft 36 is connected to the input shaft 24 of the rotation split transmission mechanism 21 via a rotation transmission joint 41. Next, this rotation transmission joint 41 will be explained.

The output shaft 36 is connected to the first connecting rod 42 via a universal joint 43 so as to be bendable and rotationally transmittable.

For example, the universal joint 43 connects the first connecting rod 4 to a connecting body 44 fixed to the right end of the output shaft 36 in the figure.
A connecting body 45 fixed to the left end of 2 in the figure is pivoted. Further, the first connecting rod 42 is connected to the second connecting rod 46 via an expansion joint 47 so as to be movable forward and backward, bendable, and rotationally transmittable. This expansion joint 47
For example, a pin 49 provided at the left end of the second connecting rod 46 in the figure is slidably and rotatably engaged with a groove 48 formed at the right end of the first connecting rod 42 in the figure. This is what happens. Further, the second connecting rod 46 is connected to the input shaft 24 via a universal joint 50 so as to be bendable and rotationally transmittable. This universal joint part 50 also
A pair of connecting bodies 50 similar to the universal joint 43 described above.
It consists of 51 items.

Next, the operation of the above adjustment device will be explained.

By holding and moving the base plate 11 or the box body 22 by hand, for example, to adjust the position, each drive gear 28a, 28b inside the box body 22 is meshed with each of the stacked magnetic field rings 1a, 1b, respectively. Then, by operating the cylinder 15, the rod 17 is connected to the shaft 14.
A force is applied to the box body 22 through the drive gear 28a.

28b is pressed against the magnetic field rings 1a and 1b with a constant force.

Note that this pressing force of about 1 to 2 cloths is sufficient.

In this state, the user, while looking at the CRT screen,
The motor 31 is driven to correct the bow-shaped display. At this time, the rotational force of the motor 31 is transmitted to the output shaft 36 via the heavy shafts 133. The signal is transmitted to the input shaft 24. In this rotation split transmission mechanism 21, for example, as shown by the arrows in FIG. The rotation is directly transmitted to the first drive gear 28a, and the rotation is transmitted via the idle gear 29 to the second drive gear 28b.

Therefore, these driving gears 28a and 28b rotate in opposite directions at the same circumferential speed. As a result, the magnetic field rings Ia and 1b with which the drive gears 28a and 28b are meshed rotate by equal amounts in opposite directions.

Incidentally, there is an error of about 1 to 3 degrees in the attachment position of the magnetic field rings Ia and 1b to the neck portion of the cathode ray tube. In addition, there are errors in the shape of the cathode ray tube itself. therefore,
In order to mesh the drive gears 28a, 28b with the magnetic field rings la, lb having such positional errors, these teeth 1128a are adjusted as described above.

Box body 2 incorporating rotational division transmission mechanism 21 including 28b
2 must be moved to match the positions of the magnetic field rings 1a and 1b, but as a result, the distance and relative angle between the box 22 and the motor 31 will change for each cathode ray tube. The magnitude of this change is due to the distance 1 to 3j111
The angle is about 1 to 2 degrees. However, according to the above configuration, since the motor 31 and the rotation split transmission mechanism 21 are connected by the rotation transmission joint 41 which is expandable and bendable, this joint 41, more specifically, the expansion joint part 47 The above-mentioned position error is absorbed by the flexible joint portion 43.degree. 50, and the rotation of the motor 31 is smoothly transmitted no matter where the box body 22 is located.

In addition, as mentioned above, the rotation transmission joint 4 is extendable and bendable.
1, it becomes possible to separate the motor 31, which necessarily uses a magnetic material, by a sufficient distance from the cathode ray tube without increasing the size of the entire adjustment device. and,
The rotation division transmission mechanism 21, which can be made thin, can be installed even in the narrow space 111w1 between the deflection yoke 2 and the image quality adjuster, and it is this rotation division transmission mechanism 21 that must be installed near the magnetic field rings la and lb. It does not interfere with the installation of other adjustment devices. In addition, bevel gear 25.26
The reason why the rotation is bent at right angles is to pull out the joint 41 in the radial direction of the magnetic field rings 1a, lb so as not to interfere with other adjusting devices.

Then, if the above adjustment device is used, the magnetic field ring Ia,
These magnetic field rings 1a without directly touching 1b.
, 1b can be rotated, there is no risk of electric shock, and image adjustment can be performed safely.

Also, since you can work at a location away from the magnetic field ring 1,
It is now possible to easily adjust the size of a large-sized power rabra-kun tube, which cannot be adjusted while looking at the screen using the conventional method of turning the magnetic field rings 1a and 1b by hand.

In the above embodiment, the rotational drive source is the motor 31, but the rotational drive source may be a handle or the like that is manually rotated directly by the adjuster.

In addition to a bendable joint, an eccentric joint may be used as the rotation transmission joint.

〔Effect of the invention〕

According to the present invention, since the rotation is transmitted from the rotation drive source to the pair of magnetic field rings via the telescopic, bendable or eccentric rotation transmission joint and the rotation division transmission mechanism, high voltage,
There is no risk of touching high-current parts with your hands, so you can safely adjust images, and even with large color cathode ray tubes, you can adjust while viewing the image. In addition, since only the rotation split transmission mechanism needs to be installed near the magnetic field ring, it does not interfere with the installation of other adjustment devices. By connecting them together, the rotating drive source can be sufficiently separated from the magnetic field ring without increasing the size of the entire device, and it is also possible to deal with positional errors of the magnetic field ring and the like.

[Brief explanation of the drawing]

FIG. 1 is a front view showing an embodiment of the color cathode ray tube adjusting device of the present invention, FIG. 2 is a perspective view showing the internal structure of the rotation division transmission mechanism, and FIG. 3 is a front view showing an embodiment of the color cathode ray tube adjusting device of the present invention. FIG. 3 is a perspective view showing the relationship between a magnetic field ring and a deflection yoke for explanation. 1a, lb...Magnetic field ring, 12...Press mechanism, 21
...Rotation division transmission mechanism, 24..Input shaft, 31..Motor as a rotation drive source, 41..Rotation transmission joint. lct,.

Claims (1)

[Claims] (1) A pair of image adjustment magnetic field rings each rotatably attached to the neck of a color cathode ray tube are removably engaged with each other, and the rotation of one input shaft is applied to both of the magnetic field rings in opposite directions. A rotary split transmission mechanism that transmits an equal amount of rotation and whose position is variable; a rotary drive source; and a telescoping and bendable transmission mechanism that connects the rotary drive source and the input shaft of the rotary split transmission mechanism. A color cathode ray tube adjusting device comprising: an eccentric rotation transmission joint; and a pressing mechanism that biases the rotation division transmission mechanism toward the magnetic field ring.