KR100349900B1 - Flat laser cathode ray tube - Google Patents

Abstract

PURPOSE: A flat laser cathode ray tube is provided to reduce the size and the weight of the cathode ray tube by using a flat electron gun block having a plurality of electron guns. CONSTITUTION: A laser screen includes a semiconductor layer(29) for oscillating a laser beam. A reflective mirror(28) is installed at one side of the semiconductor layer(29). A semipermeable mirror(30) is installed at the other side of the semiconductor layer(29). A heat removal support member(32) is adhered to the semipermeable mirror(30) by using an adhesive layer(31). A flat multi-electron beam generator is installed at a back side of the laser screen. The flat multi-electron beam generator includes a cathode(22). The cathode(22) is formed by stacking a plurality of metal tips(24) on a back glass substrate(21). An insulating layer(23) is inserted between the metal tips(24). A gate electrode(25) having a through-hole(25a) is installed at a front face of the metal tip(24). A spacer(26) is formed between the back side of the laser screen and the flat multi-electron beam generator. A predetermined space(27) is formed to preserve the electron beam energy.

Description

Planar Laser Cathode Ray Tube

The present invention relates to a flat laser cathode ray tube (Flat Laser CRT), and more particularly to a laser cathode ray tube having a plurality of planar electron beam generators.

When the laser is generated by exciting the semiconductor portion located inside the optical cavity with the electron beam, it is possible to display image information through scanning of the electron beam. Since the generated laser is emitted in the same direction as the electron beam, the scanning of the output light can be controlled by scanning the electron beam. By projecting the scanning of this output light onto an external screen, a desired image can be obtained.

A conventional projection laser CRT is shown in FIG.

Referring to FIG. 1, a laser CRT includes an electron gun 1 for generating an electron beam, a deflection device 5 for deflecting the generated electron beam, a laser screen 10 that is excited by an accelerated electron beam, and outputs a laser. do.

The laser screen 10 is also disclosed in US Pat. No. 5,339,003 and US Pat. No. 5,313,483.

Referring to FIG. A, which is a partially enlarged view, the laser screen 10 includes a semiconductor layer 13 composed of a single-crystal wafer, and mirrors are provided on both sides of the semiconductor layer. (11) and (12) are located opposite each other. The mirror 11 here is a reflecting mirror and the mirror 12 is a partially transparent mirror.

On the other hand, a transparent heat removing support member 15 is attached to the outside of the semi-permeable mirror by a cement layer 26.

In the operation of the conventional laser CRT configured as described above, the electron beam emitted from the electron gun 1 is accelerated by the accelerator and deflected by the deflection coil 5.

Finally, the electron beam reaches and hits the laser screen 10, which then passes through the reflection mirror 11 to excite the semiconductor layer 13 to oscillate the laser. The oscillated laser resonates between the reflecting mirror 11 and the translucent mirror 12 and is eventually emitted through the translucent mirror 12, the adhesive layer 14 and the transparent heat removal support member 15. At this time, the heat released from the semiconductor 13 is cooled by the heat removal support member 15. Project the emitted laser onto the screen to get the desired screen. In this case, in order to make a color screen, three tubes are manufactured and projected onto one screen by using laser semiconductor materials having wavelengths corresponding to R, G, and B, respectively.

By the way, the laser CRT as described above has a structure using a conventional electron gun 1 and a deflector 5, which has a large volume and weight, and thus acts as a basic problem in thinning and reducing the laser CRT currently required.

An object of the present invention is to provide a laser CRT that can reduce the size and weight by using a planar electron gun block having a plurality of electron guns instead of a single electron gun structure to solve the above problems.

The planar laser cathode ray tube of the present invention for achieving the above object,

A laser screen comprising a semiconductor layer excited by an external stimulus to oscillate a laser, a reflection mirror and a semi-transmissive mirror respectively positioned on both sides of the semiconductor layer, and a heat removal support member attached to the outside of the semi-transmissive mirror; And

And a planar multiple electron beam generating device positioned at the rear of the reflecting mirror to emit a plurality of electrons simultaneously to excite the laser oscillation of the laser screen.

In addition, the planar multi-electron beam generator may be provided in various forms. As an embodiment of the present invention, the multi-electron beam generator includes:

Back glass substrate;

A cathode in which metal tips are arranged in a predetermined pattern with an insulating layer interposed therebetween on the rear substrate; And

And a stripe-shaped gate electrode formed with a through hole formed at a front opposing portion of the metal tip.

Furthermore, the planar multiple electron beam generator,

Back glass substrate;

A line cathode disposed on the back glass substrate in a straight line to generate electrons;

A rear horizontal electrode disposed on a bottom surface of the line cathode and spaced apart from each other at a predetermined interval perpendicular to the line cathode; And

In order to deflect electrons emitted from the line cathode, a horizontal deflection electrode may be installed in parallel to both sides of the line cathode.

In another embodiment of the present invention, the electron beam generator,

Back glass substrate;

An arcuate cathode repeatedly disposed in the shape of an arch projecting on the back glass substrate to generate electrons;

A rear horizontal electrode installed below the arch of the arcuate cathode and spaced apart from each other by a predetermined interval perpendicular to the arch; And

And a horizontal deflection electrode disposed parallel to both sides of the arcuate cathode in order to deflect electrons emitted from the arcuate cathode.

Next, the present invention will be described in detail with reference to the accompanying drawings.

2 shows an embodiment of a planar laser cathode ray tube according to the invention.

Referring to the drawings, a laser screen is installed on the front surface of the laser cathode ray tube of the present invention. As described above, the laser screen includes a semiconductor layer 29 which is self-excited by an external stimulus to oscillate a laser. One side of the semiconductor layer 29 is provided with a reflecting mirror 28, and the other side is semi-transmissive. The mirror 30 is located. On the other hand, a heat removal support member 32 for removing heat generated when the laser is finally oscillated is attached to the front surface of the semi-transparent mirror 30 by the adhesive layer 31.

On the other hand, the back of the laser screen is coupled to a planar multiple electron beam generator for emitting electrons for excitation of the semiconductor layer 29. This planar multi-electron beam generator includes a cathode 22 having a plurality of metal tips 24 formed on the rear glass substrate 21.

An insulating layer 23, which is an insulating material, is interposed between the metal tips 24, and a gate electrode 25 having a through hole 25a is formed on the front surface of the metal tip 24 in a stripe shape.

The multiple electron beam generator having the above structure is installed on the rear surface of the laser screen by spaced intervals by the spacer 26 and the space 27 may be in a vacuum state in order to efficiently conserve energy of the electron beam.

Looking at the operation of the planar laser cathode ray tube according to the present invention. First, when a high voltage is applied to the metal tip 24 on the cathode 22, electrons are emitted, which are controlled by the gate electrode 25. Electrons generated from the metal tip 24 pass through the reflective mirror 28 to reach the semiconductor layer 29. The semiconductor layer 29 is then excited by electrons to oscillate the laser, the oscillated laser resonating between the reflective mirror 28 and the semi-transmissive mirror 30 and eventually the semi-transmissive mirror 12, the adhesive layer 14 and the transmissive It is discharged through the heat removal support member (15). The desired screen is obtained by projecting the emitted laser onto the screen.

If desired, the electron beam generator preferably includes electron beam control means (not shown) for accelerating and connecting electrons emitted from the metal tip 24.

Another preferred embodiment of the invention is shown in FIGS. 3 and 4, which is another example of the planar multiple electron beam generator.

Referring to FIG. 3, the electron beam generator is provided with a line cathode 51 having a straight line of a cathode for emitting electrons on the rear substrate 50. A rear horizontal electrode 52 is provided on the bottom surface of the line cathode 51, and is spaced apart from each other by a predetermined interval in the vertical direction to the line cathode 51.

On the other hand, horizontal deflection electrodes 53 are arranged in parallel on both sides of the line cathode 51.

In the electron beam generator as described above, the electrons generated in the line cathode 51 are controlled by the rear horizontal electrode 52 on the rear side, and the electrons once controlled and emitted to the front are again returned to the horizontal deflection electrode 53. Deflected by

The electron beam generator shown in FIG. 4 also has a structure similar to that of FIG. However, the cathode is installed in the semicircular arcuate 61 above the rear substrate 60, and the rear horizontal electrode 62 is located below the arch in the vertical direction. In addition, as described above, the horizontal deflection electrode 63 is disposed side by side on both sides of the arcuate cathode 61 to deflect the emitted electrons.

The basic operation of the electron beam generator shown in FIG. 4 is similar to that of FIG. The electrons once generated from the arcuate cathode 61 are controlled by the back horizontal electrode 62 and are deflected by the horizontal deflection electrode 63.

As described above, the planar laser cathode ray tube according to the present invention composed of an electron beam generator that emits a large number of electrons and a laser screen excited by the electrons and oscillates a laser can be made thin by improving the structure of a conventional bulb type cathode ray and a planar shape. There is an advantage that enables the production of simple products.

Although the present invention has been described in terms of limited drawings and embodiments, it will be understood that various modifications may be made as appropriate as long as it falls within the scope of the invention.

1 is a schematic cross-sectional view showing a conventional laser cathode ray tube.

2 is a cross-sectional view showing a planar laser cathode ray tube according to the present invention.

3 is a perspective view showing an embodiment of a multiple electron beam generator according to the present invention.

4 is a perspective view showing another embodiment of a multiple electron beam generator according to the present invention.

* Explanation of symbols for main parts of the drawings

1. Electron gun 5. Deflection coil

10.Laser screen 11,28.Reflective mirror

Semi-Transparent Mirrors 13,29. Semiconductor layer

Adhesive Layer 15,32. Heat removal support member

21. Back glass substrate 22. Cathode

23. Insulation layer 24. Metal tip

25.gate electrode 25a.through hole

Spacer 27. Vacuum layer

50.60.Rear substrate 52.Line cathode

Rear horizontal electrode 53,63 Horizontal deflection electrode

Arch type cathode

Claims (5)

A laser screen comprising a semiconductor layer excited by an external stimulus to oscillate a laser, a reflection mirror and a semi-transmissive mirror respectively positioned on both sides of the semiconductor layer, and a heat removal support member attached to the outside of the semi-transmissive mirror; And And a planar multiple electron beam generator positioned on the rear surface of the reflecting mirror to excite the laser oscillation of the laser screen and emitting a plurality of electrons at the same time. The method of claim 1, The planar multiple electron beam generator, Back glass substrate; A cathode in which metal tips are arranged in a predetermined pattern with an insulating layer interposed therebetween on the rear substrate; And Planar laser cathode ray tube, characterized in that it comprises a stripe-shaped gate electrode formed with a through hole formed in the front opposing portion of the metal tip. The method of claim 2, The planar multi-electron beam generating apparatus further comprises an electron beam control means for accelerating and focusing electrons emitted from the metal tip. The method of claim 1, The planar multiple electron beam generator, Back glass substrate; A line cathode disposed on the back glass substrate in a straight line to generate electrons; A rear horizontal electrode disposed on a bottom surface of the line cathode and spaced apart from each other at a predetermined interval perpendicular to the line cathode; And And a horizontal deflection electrode disposed parallel to both sides of the line cathode to deflect electrons emitted from the line cathode. The method of claim 1, The planar multiple electron beam generator, Back glass substrate; An arcuate cathode repeatedly disposed in the shape of an arch projecting on the back glass substrate to generate electrons; A rear horizontal electrode installed below the arch of the arcuate cathode and spaced apart from each other by a predetermined interval perpendicular to the arch; And And a horizontal deflection electrode disposed parallel to both sides of the arcuate cathode in order to deflect electrons emitted from the arcuate cathode.