KR20000020701A - Lcd having lamp assembly - Google Patents

Abstract

PURPOSE: An LCD having lamp assembly is provided to simplify the structure of a lamp assembly and improve an assembly and a durability by grounding a ground electrode of a lamp to a chassis. CONSTITUTION: An AC voltage is supplied to a driving voltage providing terminal(H) through an inverter(18) having a pulse generating unit(10) and a transformer(12). A brightness switching signal(Bs) and a brightness adjusting signal(Bc) are supplied to a controller(16). The controller(16) supplies a control signal to the pulse generating unit(10). A ground terminal(C) of a lamp(14) is connected to a chassis(19) through a ground path(G). The pulse generating unit(10) generates a pulse to which an on-time of the pulse is adjusted and outputs the generated pulse to the transformer(12). The transformer(12) amplifies an input signal and supplies the amplified signal to the lamp(14). A driving voltage providing terminal(H) is connected to an inverter by one wire.

Description

Liquid Crystal Display With Lamp Assembly

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device having a lamp assembly, and more particularly, to a liquid crystal display device having a lamp assembly in which a grounding electrode of the lamp is grounded with a chassis to simplify the structure of the lamp assembly and improve assembly and durability. will be.

Recently, due to the development of computer related technologies, notebook computers are widely used, and liquid crystal display devices are configured for display of predetermined information in notebook computers. Since the liquid crystal display does not emit light by itself, many lamps are installed as light sources.

In general, a lamp configured in a liquid crystal display device is commonly used, such as a cold cathode ray tube emitting light by discharge, and a lamp using the discharge principle is generally applied with a stabilized alternating voltage of about 300 Vrms to 700 Vrms at both ends. In the place where a DC voltage such as a notebook computer is used for driving, an inverter for converting a DC into an AC and applying the same to a lamp is configured, and the lamp receives a driving voltage through the inverter.

In the inverter installed in the liquid crystal display, a current dimming method and a duty method are frequently used.

The current dimming method adjusts the brightness of the lamp by adjusting the amplitude of the voltage. The duty method adjusts the brightness of the lamp by adjusting the on-time of the pulse while keeping the amplitude of the voltage at a constant maximum.

The current dimming method regulates the current by the amplitude of the inverter output voltage, so the lower the amplitude of the voltage toward the lower current, and the higher the lower the current requires the higher voltage, so the lamp may be incompletely lit. The maximum luminance: minimum luminance ratio of 5: 1 is not possible.

However, the duty method adjusts the time for which the output is turned on in a state in which the amplitude of the output voltage is high, so that the lamp can be turned on even at a low current, so that a ratio of maximum luminance to minimum luminance of 5: 1 or more is possible.

Therefore, in recent years, since the brightness adjustment is required to be broadly adjusted according to the convenience of a user using a notebook computer using a liquid crystal display device, a duty type inverter is widely used in the liquid crystal display device.

The lamp driven by applying the voltage from the above-described inverter is installed as a lamp assembly when installed in the liquid crystal display. In general, the lamp assembly is installed in combination with the lamp reflector, the lamp reflector is installed on the lamp back cover or the mold frame itself. In addition, the inverter and the lamp are configured to supply power by connecting the corresponding terminals with wires.

The wires here are also difficult to install and create significant difficulties when designing lamp assemblies. Wires also affect durability.

The lamp is configured to receive a voltage through the inverter to the voltage applying electrode and the ground electrode for driving, and the wire connected to either of them must be connected between the reflector and the back cover of the lamp assembly or between the reflector and the mold frame in order to be connected to the inverter. It is designed to pass through the space formed between them, which acts as a limiting factor in determining the diameter of the lamp or designing for slimming the lamp assembly.

Therefore, the power supply method to the lamp through the inverter described above has a considerable problem in slimming the liquid crystal display and improving image quality.

An object of the present invention is to connect the inverter and the lamp with a single wire, and to change the grounding of the lamp to chassis ground through various paths to enable the slimming of the lamp assembly and the relative expansion of the diameter of the lamp.

Other objects of the present invention will become more apparent from the following detailed description and the accompanying drawings.

1 is a block diagram showing a preferred embodiment of a liquid crystal display device having a lamp assembly according to the present invention.

2 is an exemplary view of applying an embodiment to the lamp assembly of the back cover method

3 is an exemplary view of applying an embodiment to the lamp assembly of the metal lamp reflector method

A liquid crystal display device having a lamp assembly according to the present invention displays a predetermined image in a liquid crystal module using light of a lamp driven by a voltage applied from an inverter, and among the terminals formed for voltage application to the lamp, The chassis is grounded.

The ground terminal may be chassis grounded through a predetermined connecting member such as a conductive elastic clip, or the ground terminal may be connected to the chassis by being made of an elastic body, and the ground terminal is a printed circuit configured to drive the liquid crystal module. The ground terminal may be connected to a ground line of a substrate or a liquid crystal module, and the ground terminal may be grounded to a metallic lamp back cover or a lamp reflector.

In addition, the present invention is preferably applied when the inverter is a duty dimming method.

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

Preferably, the present invention is implemented in a duty type inverter for applying an alternating voltage to the lamp.

In the current dimming inverter, a feedback loop is provided in which current from the ground terminal is fed back to regulate the voltage output of the controller. Therefore, the ground terminal of the lamp and the inverter must be connected.

However, the duty type inverter does not need to form a separate feedback loop because the output of the voltage is directly controlled by the controller. Thus, there is no need to connect the ground terminal of the lamp and the inverter.

Embodiment according to the present invention has the configuration as shown in Figure 1 focusing on the above point.

That is, the AC voltage Vcc is applied to the driving voltage application terminal H of the lamp 14 via the waveform generator 10 and the transformer 12 constituting the inverter 18, and to the waveform generator 10. The controller 16 to which the brightness switching signal Bs and the brightness adjustment signal Bc are applied is configured to apply a control signal for brightness adjustment according to the input signal. In addition, the ground terminal C of the lamp 14 is connected to the chassis 19 used for main ground through the ground path G. That is, the lamp 14 is chassis grounded.

Accordingly, the waveform generator 10 generates a waveform in which the ON time of the pulse is controlled and outputs the waveform to the transformer 12 according to a control signal applied from the controller 16, and the transformer 12 amplifies the input signal and ramps the ramp. (14).

The driving voltage application terminal H constituted in the lamp 14 is connected to the inverter 18 by a single strand of wire. Since only one wire is connected between the inverter 18 and the lamp 14, the lamp 14 of the lamp assembly may be connected at the shortest distance from one end of the lamp assembly.

In addition, the ground path G between the lamp 14 and the chassis 19 may be formed in various ways.

First, the ground path G can be constructed by shorting a conductive elastic clip (not shown) to the ground terminal C of the lamp 14 and shorting the other end of the elastic clip to the chassis.

Alternatively, the ground line G may be configured by configuring the ground terminal C of the lamp 14 itself with a conductive elastic body (not shown) and shorting the elastic body with the chassis 19. At this time, the elastic body is preferably used in the form of a plate.

Further, the ground terminal C of the lamp 14 can be grounded with the chassis 19 by connecting to a ground line of a printed circuit board (not shown) or a liquid crystal module (not shown). In this case, the liquid crystal module and the printed circuit board are basically grounded with the chassis 19 for self grounding.

On the other hand, the path to ground to the chassis 19 can be set in various ways, some conductive components constituting the lamp assembly may be used.

The lamp assembly is composed of a back cover method or a lamp reflector method using metal.

In the case of the back cover method as shown in FIG. 2, the lamp assembly includes a non-conductive mold frame 20 such as plastic and a metallic lamp back cover 22 having conductivity, and a non-conductive lamp reflector 24 is formed therein. In the lamp reflector 24, the lamps 26 are spaced apart from each other. The light guide plate 28 is configured to reflect light upward while guiding the light in one direction in which the light of the lamp 26 is irradiated.

In the case of the back cover method, since the lamp back cover 22 is a metallic component, the contact 34 is positioned at a position close to the ground electrode 30 of the lamp 26 on the lamp back cover 22, and the ground electrode 30 and the contact 34 are connected to the ground line 32 to form a ground. At this time, the lamp back cover 22 is connected to the chassis 19 for the main ground.

On the other hand, in the case of the lamp cover method using a metal as shown in FIG. 3, the lamp assembly is formed on the upper portion of the non-conductive mold frame 40 such as plastic, the lamp reflector 42 is configured inside the one end, the lamp reflector 42 In the interior of the lamp 44 is spaced apart. The light guide plate 46 is configured to reflect light upward while guiding the light in one direction in which the light of the lamp 44 is irradiated.

Since the lamp reflector 42 is metallic, the lamp reflector 22 and the ground electrode 30 are connected to form a ground, and the lamp reflector 42 is also connected to the chassis for the main ground.

As described above, the lamp can be grounded through various paths. Accordingly, the lamp can be driven by connecting a single wire between the lamp and the inverter, and there is no unnecessary wire configuration inside the lamp assembly. Relative expansion of the lamp diameter is possible and the design of the lamp assembly is easy.

In addition, assembling and arranging complicated wires are unnecessary, thereby improving assembly and durability.

As described in detail above, the present invention has been described in detail with respect to preferred embodiments, but those skilled in the art to which the present invention pertains, various embodiments of the present invention without departing from the spirit and scope of the present invention It will be appreciated that the present invention may be modified or modified as described above.

Therefore, according to the present invention, it is possible to slim the lamp assembly and improve its structure, and the assembly and durability of the lamp assembly are improved.

Claims (11)

A liquid crystal display device having a lamp assembly for displaying a predetermined image in a liquid crystal module using light of a lamp driven by a voltage applied from an inverter, And a ground terminal of the terminals formed to apply voltage to the lamp, wherein the ground terminal is chassis grounded. The method of claim 1, And the ground terminal is chassis grounded through a predetermined connection member. The method of claim 2, And the connection member is a conductive elastic clip, the ground terminal is shorted to the elastic clip, and the elastic clip is connected to the chassis. The method of claim 1, And the ground terminal is connected to the chassis by being composed of an elastic body. The method of claim 1, And the ground terminal is connected to a ground line of a printed circuit board configured to drive the liquid crystal module. The method of claim 1, And the ground terminal is connected to a ground line of the liquid crystal module. The method of claim 1, And the ground terminal is grounded to a metallic lamp back cover. The method of claim 7, wherein And the lamp back cover is connected to the chassis to form a ground path. The method of claim 1, And the ground terminal is grounded to a metallic lamp reflector. The method of claim 9, And the lamp reflector is connected to the chassis to form a ground path. The method according to any one of claims 1 to 10, And the inverter is driven by a duty dimming method.