RU172414U1 - VIDEO MODULE - Google Patents

Abstract

The utility model relates to electronic equipment, in particular to electronic means of displaying information. The video module contains a housing (1) in which a liquid crystal display (2), fiberglass plate (3), a printed circuit board (4), a power source (5) and a controller (6) are fixed. The glass plate (3) is glued to the screen (7) of the liquid crystal display (2) with its optical glue (11) on its front side. On the glass plate (3) from the side facing the liquid crystal display (2), a transparent resistive coating (8) is applied. On two opposite edges of the coating (8), contact pads (9) are made, to which contact wires (10) are attached to supply voltage from the power source (5). The video module is also equipped with a protective glass plate (12) fixed in the housing parallel to the glass plate (3) with a transparent resistive coating and with a gap relative to the latter. To reduce the heating time of the video module to operating temperature at negative ambient temperatures, the transparent resistive coating (8) is low-emission, with an emission coefficient less than 0.4. 1 s.p. f-ly, 2 ill.

Description

The utility model relates to electronic equipment, in particular to electronic means of displaying information.

A known liquid crystal display containing two transparent substrates (glass plates), interconnected with a small gap in which there is a liquid crystal material, while one of the substrates has a transparent resistive coating, to which contact wires are connected from two opposite edges to supply voltage [patent No. 7023519, USA, IPC G02F 1/1333, Internal heater embedded in an LCD cell / Kay Pul But et al., 2006].

In this display, a transparent resistive coating is used to heat the liquid crystal screen at negative ambient temperatures.

A disadvantage of the known liquid crystal display is that its transparent resistive coating is deposited on the inside of one of the substrates. Such a coating can be applied to the substrate only at the manufacturer. This complicates the design and increases the cost of the liquid crystal display, despite the fact that most displays are used at room temperature when heating the liquid crystal screen is not required.

A video module is also known, comprising a housing in which a liquid crystal display, a fiberglass plate, a printed circuit board, a power supply and a controller are fixed, while the fiberglass is glued to the liquid crystal display with an optical glue on its front side, and the glass plate is coated on the side facing the liquid crystal display. transparent resistive coating, on two opposite edges of which are made contact pads to which wires are connected to supply voltage , [Utility Model Patent No.145576, RF, IPC G02F 1/13, Liquid Crystal Display / Voitenkov A.S. et al., 2014] - prototype.

A disadvantage of the known video module is that the transparent resistive coating applied to the glass plate has a large emission coefficient, i.e. reflects only a small part of infrared (thermal) radiation. Therefore, part of the heat generated by the elements of the video module is radiated through this fiberglass plate into the environment. As a result, when the ambient temperature is negative, a considerable amount of time is required to bring the video module to the ready state after it is turned on. This reduces the operational properties of the video module.

The problem to which the invention is directed is to increase the operational properties of the video module by reducing its heating time to operating temperature at negative ambient temperatures.

To solve this problem, in a video module containing a housing in which a liquid crystal display, a fiberglass plate, a printed circuit board, a power source and a controller are fixed, the fiberglass is glued to the liquid crystal display with its optical side on the front side and the glass plate on the side facing the liquid crystal the display, a transparent resistive coating is applied, on two opposite edges of which are made contact pads to which wires are connected to bring the electric apryazheniya, according to the utility model, transparent resistive coating on the glass sheet holds low-emission, with an emission coefficient less than 0.4. In addition, the video module is additionally equipped with a protective glass plate fixed in the housing parallel to the glass plate with a transparent resistive coating and with a gap relative to the latter.

The video module can also be additionally equipped with a plate with low thermal conductivity, mounted in the housing between the liquid crystal display and the printed circuit board parallel to the plane of the liquid crystal display.

The technical result provided by the proposed utility model is to reflect infrared (thermal) radiation emitted by the elements of the video module, and, as a result of this, to reduce the heating time of the liquid crystal display to operating temperature.

The utility model is illustrated by drawings. In FIG. 1 shows the proposed video module, a longitudinal section; in FIG. 2 is a section AA in FIG. one.

The video module contains a housing 1 in which a liquid crystal display 2, a glass plate 3, a printed circuit board 4, a power supply 5 and a controller 6 are fixed. The glass plate 3 is fixed on the front side of the screen 7 of the liquid crystal display 2 parallel to its plane. A transparent resistive coating 8 is applied to the glass plate 3 from the side facing the liquid crystal display 2. Metal contact pads 9 are made on two opposite edges of the transparent resistive coating 8, to which wires 10 are connected to supply voltage from the power supply 5.

Transparent resistive coating 8 is made of low emission, with an emission coefficient less than 0.4. This coating can be performed, for example, in the form of a thin layer with a thickness of 200-450 nm indium tin oxide containing about 90% indium oxide In ₂ O ₃ and about 10% tin oxide SnO ₂ and an additive of silver Ag (less than 0.1 %), or in the form of a thin layer 200-450 nm thick containing 95-99% tin oxide SnO ₂ doped with fluorine (1-5%) and silver additive Ag (less than 0.1%).

To increase the resistance of the video module to shock and vibration, the fiberglass 3 on the side on which the transparent resistive coating 8 is applied is glued to

the screen 7 of the liquid crystal display 2 from its front side.

The video module is equipped with a protective glass plate 12, mounted in the housing parallel to the glass plate 3 and with a gap relative to the latter.

In addition, the video module is equipped with a plate 13 with low thermal conductivity, mounted in the housing between the liquid crystal display 2 and the printed circuit board 4 parallel to the plane of the liquid crystal display.

The video module works as follows.

After turning on the power, the power source 5, controller 6, the liquid crystal display 2 and other elements of the video module begin to heat up and emit infrared (thermal) radiation. Additional heating of the liquid crystal display provides a resistive coating 8 of the glass plate 3, to which electrical voltage from the power supply 5 is supplied through the metal pads 9 via wires 10. Due to the fact that this resistive coating is low-emission with an emission coefficient less than 0.4, most infrared radiation emitted by the elements of the video module and the resistive coating is reflected from this coating back inside the video module. Due to this, the liquid crystal display heats up faster after it is turned on at low ambient temperatures.

A plate 13 with low thermal conductivity prevents the outflow of heat from the liquid crystal display from its inner side. This further reduces the time it takes for the video module to be ready.

The protective glass plate 12 protects the glass plate 3 and the liquid crystal display 2 from external influences.

Claims (2)

1. A video module comprising a housing in which a liquid crystal display, a fiberglass plate, a printed circuit board, a power supply and a controller are fixed, the fiberglass using optical glue glued to the liquid crystal display on its front side, on the glass plate on the side facing the liquid crystal display, is applied a transparent resistive coating, on two opposite edges of which are made contact pads to which wires are connected for supplying electrical voltage, characterized in that the transparent resistive coating for low emissivity glass sheet formed with emission coefficient less than 0.4, and, in addition, the video module is further provided with a protective glass plate fixed in the housing parallel to the glass sheet with a transparent resistive coating and with clearance relative to the latter. 2. The video module according to claim 1, characterized in that it is further provided with a plate with low thermal conductivity, mounted in the housing between the liquid crystal display and the printed circuit board parallel to the plane of the liquid crystal display.

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