KR20050068403A - Refrigerants heating structure of display set with ultraviolet rays heating - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a refrigerant heating structure of an imaging device, and more particularly, to reduce a heat run time of a CRT assembly that significantly affects the screen focus of an imaging device such as a CRT projection TV. Refrigerant heating structure of an image device to be heated by using a separate ultraviolet heating device, the refrigerant heating structure of the image device according to the present invention, the image display device and the image emitted from the image display device constant magnification A projection lens device for magnifying and projecting the light source, a coupler for mechanically coupling the image display device and the projection lens device, and the coupler / projection lens device / image display device are injected into a combined internal space to act as heat radiation. In a video device composed of a refrigerant,

In order to shorten the preheating section of the production line for manufacturing the imaging device, after placing the ultraviolet heating device on the projection lens device, by applying power to the ultraviolet heating device, ultraviolet light is generated to cool the refrigerant inside the coupler It characterized in that to heat the.

Description

Refrigerants Heating Structure of Display set with ultraviolet rays heating

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a refrigerant heating structure of an imaging device, and more particularly, to reduce a heat run time of a CRT assembly that significantly affects the screen focus of an imaging device such as a CRT projection TV. It relates to a refrigerant heating structure of the imaging device to be heated using a separate ultraviolet heating device.

In general, commercialization of televisions equipped with CRTs larger than 36 inches is virtually impossible, so projection TVs using a method of projecting a general television screen onto a screen using a mirror and an optical lens have been developed and used.

Such a projection TV can be divided into a CRT projection TV, an LCD projection TV, and a DLP projection TV according to a driving element, and all of the structures are similar.

1 is a schematic diagram showing the structure of a projection TV to which the CRT assembly according to the prior art is applied.

As shown in the figure, the structure of the CRT projection TV which is most commonly used is a transmission screen by enlarging an image emitted from three R, G, and B monochrome CRTs 10 at a constant magnification through the projection lens 20. Formed at 40, it is configured to show a large screen image.

Figure 2 is a perspective view showing a CRT assembly according to the prior art, Figure 3 is a schematic cross-sectional view showing the internal structure of the CRT assembly according to the prior art.

As shown in the drawing, in the conventional CRT assembly, the projection lens device 20 and the CRT 10 are connected by the coupler 30, and the projection lens device 20 / coupler 30 / image display device 10 ) Has a configuration in which a highly transparent refrigerant (50) is injected into the inner space where the) is combined.

At this time, the coolant 50 is inserted between the projection lens device 20 and the image display device 10 as described above to minimize the reflected light generated between the image display device 10 and the projection lens device 20. The heat dissipation from the image display device 10 can be performed.

Such a method is called an optical coupling method and is used as a scanning method of a projection TV.

As described above, the coolant 50 minimizes the reflected light generated between the image display apparatus 10 and the projection lens apparatus 20, and simultaneously serves as heat dissipation from the image display apparatus 10. In order to stabilize the lens system such as the C lens 60, the heat transfer role for reaching the proper temperature is also performed.

Such a heat transfer process is referred to as a heat run of the CRT assembly.

The prior art as described above is a CRT heat run module consisting of a minimum circuit (high voltage / low voltage power supply) for the heat run of the CRT assembly when the set assembly of the CRT projection TV, and made a heat run, and then the projection of the projection TV Assemble with other parts, adjust / inspect and ship.

However, the heat run of the prior art as described above allows the refrigerant to be heated by heat generated entirely from the CRT, that is, the electron beam emitted from the ELECTRON GUN hits the fluorescent film PHOSPHOR. Since the refrigerant is heated to an appropriate temperature and the screen focus is stabilized, it takes a long time to heat up the lens system.

As such, as the heat run time is delayed, the preheating section and the working process in the production line are lengthened, which leads to a reduction in the productivity and thus a great economic loss, so that the heat run time can be shortened as much as possible. The CRT assembly structure of the CRT projection TV is urgently required.

The present invention has been proposed to solve the above problems, and an object of the present invention is to allow the refrigerant in the coupler of the CRT assembly to be directly heated by using a separate ultraviolet heater, thereby reducing the heat run time. It is to provide a heating structure.

In addition, it is possible to shorten the preheating period in the projection TV production line to provide a refrigerant heating structure of the imaging device that can be reduced according to the production equipment, production line, work process and work time accordingly.

Refrigerant heating structure of the imaging apparatus according to the present invention for achieving the above object, an image display device, a projection lens device for magnifying and projecting the image emitted from the image display device at a constant magnification, and the image display device and In the imaging device comprising a coupler for mechanically coupling the projection lens device, and a refrigerant that is injected into the interior space where the coupler / projection lens device / image display device is combined to act as a heat radiation,

In order to shorten the preheating section of the production line for manufacturing the imaging device, after placing the ultraviolet heating device on the projection lens device, by applying power to the ultraviolet heating device, ultraviolet light is generated to cool the refrigerant inside the coupler It characterized in that to heat the.

Here, the ultraviolet heating device is characterized in that the cap is formed to cover the projection lens device.

Here, the image display device is characterized in that the cathode ray tube (CRT).

Here, the ultraviolet heater is characterized in that it is controlled by a temperature sensor so that no more heating after the temperature of the refrigerant reaches the set temperature.

Here, the ultraviolet heater is characterized in that after the refrigerant is heated, separated from the image device.

In this case, the UV heating apparatus is manufactured in a single type so as to be independently installed on each of R, G, and B video devices.

Here, the ultraviolet heater is characterized in that the R, G, B integral type to be installed on each of the R, G, B image equipment.

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

4 is an exploded perspective view of a refrigerant heating structure of an imaging apparatus using ultraviolet heating according to an embodiment of the present invention. As shown in the figure, a CRT assembly structure according to an embodiment of the present invention may include: A projection lens device 120 for projecting the image emitted from the CRT 110 at a predetermined magnification, a coupler 130 for mechanically coupling the CRT 110 and the projection lens device 120; The coupler 130, the projection lens device 120, and the CRT 110 are injected into the combined internal space and constitute a refrigerant (see FIG. 3) that acts as a heat radiating agent.

In this case, the coolant not only minimizes the reflected light generated between the CRT 110 and the projection lens device 120, but also dissipates heat generated from the image display device 110 and at the same time the C lens (FIG. 3). In order to stabilize the lens system, the electrothermal role is simultaneously performed to bring the lens system to an appropriate temperature. The heat transfer process here is called a heat run of the CRT assembly.

The present invention is to position the ultraviolet heating device 170 above the projection lens device 120, for the purpose of shortening the preheating section of the production line for manufacturing an imaging device having the above configuration, the ultraviolet heating device ( As power is applied to the 170, ultraviolet rays are generated to heat the refrigerant inside the coupler 130.

The ultraviolet heating device 170 serving as described above is preferably manufactured in a cap shape so as to cover the projection lens device 120.

Here, the ultraviolet light used in the present invention will be briefly described.

Ultraviolet rays are invisible light that appears outside the short wavelength of visible light when the spectrum of sunlight is photographed. It is used as a generic term for a wide range of electromagnetic waves with wavelengths ranging from about 397 to 10 nm.

Ultra-short wavelength ultraviolet light is rarely distinguished from X-rays. Since ultraviolet rays have a strong chemical effect, infrared rays may also be called chemical rays in response to heat rays.

Also, depending on the wavelength, near ultraviolet rays (wavelength of 290 nm or more), ultraviolet rays in the crystal range (290 to 190 nm that pass through the crystal), Schumann rays (190 to 120 nm), Lyman rays (120 to 60 nm), and millicon lines ( 60 nm or less) or ultraviolet rays having a wavelength of 190 nm or less are also referred to as far-ultraviolet rays.

The ultraviolet heater 170 is controlled by a temperature sensor so that the refrigerant is no longer heated after the temperature of the refrigerant reaches the set temperature, and separated from the image device after the refrigerant is heated.

5 is a graph showing a comparison between the heat run arrival time in the prior art and the present invention. As shown in the figure, the time to reach the appropriate temperature required by the refrigerant is compared with that of the present invention. It can be seen that the application of ultraviolet heaters is much faster.

As described above, the present invention is applied to a preheating section of a production line for manufacturing an imaging apparatus such as a CRT projection TV, thereby shortening the heat run time, thereby shortening the preheating section of the production line.

In this case, in the application of the present invention to the preheating section, as shown in Figure 4 to produce a single type to be installed independently of each of the R, G, B each image device, or integrally as shown in Figure 6 Can be manufactured and installed at the same time to increase the work efficiency.

According to the present invention, in the CRT projection TV, the refrigerant in the coupler of the CRT assembly is directly heated by using a separate ultraviolet heater, thereby shortening the heat run time and thus having the following effects.

First, the present invention can shorten the preheating section in the projection TV production line has the effect of reducing the production equipment accordingly.

Second, according to the present invention, it is possible to reduce the production equipment in the projection TV production line, thereby reducing the length of the production line, that is, reducing the work process and working time.

1 is a schematic diagram showing the structure of a projection TV to which the CRT assembly according to the prior art is applied.

Figure 2 is a perspective view of a CRT assembly according to the prior art.

Figure 3 is a schematic cross-sectional view showing the internal structure of the CRT assembly according to the prior art.

4 is an exploded perspective view of a refrigerant heating structure of an imaging apparatus using ultraviolet heating according to an embodiment of the present invention.

5 is a graph showing a comparison of heat run arrival times in the prior art and the present invention.

* Description of the symbols for the main parts of the drawings *

110: CRT 120: projection lens unit

130: coupler 170: UV heater

Claims (7)

An image display apparatus, a projection lens apparatus for enlarging and projecting an image emitted by the image display apparatus at a constant magnification, a coupler mechanically coupling the image display apparatus and a projection lens apparatus, and the coupler / projection lens apparatus / In the video device is composed of a refrigerant that is injected into the interior space of the image display device is a heat dissipation, In order to shorten the preheating section of the production line for manufacturing the imaging device, after placing the ultraviolet heating device on the projection lens device, by applying power to the ultraviolet heating device, ultraviolet light is generated to cool the refrigerant inside the coupler Refrigerant heating structure of an imaging apparatus using ultraviolet heating, characterized in that to heat the. The method of claim 1, The ultraviolet heating device is a refrigerant heating structure of the imaging device, characterized in that the cap is formed to cover the projection lens device. The method of claim 1, And the image display device is a cathode ray tube (CRT). The method of claim 1, The ultraviolet heating device is a refrigerant heating structure of a video device, characterized in that controlled by a temperature sensor so that no more heating after the temperature of the refrigerant reaches the set temperature. The method of claim 1, The ultraviolet heater is a refrigerant heating structure of the imaging device, characterized in that after the heating the refrigerant, is separated from the imaging device. The method of claim 1, The ultraviolet heating device is made of a single type, the refrigerant heating structure of the imaging device, characterized in that to be independently installed one by one in each of the R, G, B video equipment. The method of claim 1, The ultraviolet heating device is a refrigerant heating structure of the imaging device, characterized in that the R, G, B integral type to be installed at the same time each of the R, G, B image equipment.