JP2009245951A - Backlight lighting unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the size and thickness of a backlight lighting system for a liquid crystal display, and to enhance safety and reliability in assembling it. <P>SOLUTION: A frame arranged on the back side of a liquid crystal unit 2 has an opening having almost the same size as the liquid crystal unit 2 on the face plate, is formed in a thin box-like shape, and is structured to extend a light transmitting type light diffusion plate in the opening. An inverter printed circuit board 14 provided with an inverter circuit 16 and a cold-cathode tube 22 are directly or indirectly integrally connected with the frame through a holder to unify the frame, the inverter circuit 16, and the cold-cathode tube 22. A lead wire of an electrode of the cold-cathode tube 22 is connected to a high-voltage output terminal of the inverter circuit 16. A connector 20 to be connected to outside wiring is fixed to the inverter printed circuit board 14 or the frame, power is supplied to the inverter circuit 16 through the connector 20, and high voltage is supplied to the electrode of the cold-cathode tube 22 from the inverter circuit 16. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a backlight illumination unit used in a liquid crystal display device such as a personal computer, a car navigation system, and a television.

In recent years, backlit liquid crystal display devices have been widely used in liquid crystal display electronic devices such as personal computers, televisions, and car navigation systems. A fluorescent tube such as a cold cathode tube is used as a light source of the backlight. As shown in FIG. 15, this type of liquid crystal display device includes a liquid crystal unit (2), a lamp unit (6) having a cold cathode tube (4), a liquid crystal control unit (8), an inverter unit ( 10) and a connector (12). These devices are electrically connected as shown in the figure via a cord, and are assembled to a personal computer or a car navigation system. Power is supplied to the inverter unit (10) through the connector (12), and power and control signals are input to the liquid crystal control unit (8) through the connector (12). In recent years, products in which a liquid crystal unit and a liquid crystal control unit are integrated have been developed.

When trying to reduce the size and thickness of the liquid crystal display device, it is extremely inconvenient if the lamp unit and the inverter unit are configured separately from each other, which is not suitable for downsizing the liquid crystal display device. In addition, if the lamp unit and the inverter unit are configured separately, the high voltage supply wire connecting the inverter unit and the lamp unit may become long, which may hinder safety. is there. In addition, when the high-voltage electric wire becomes long, current leaks due to stray capacitance between the ground and the voltage drops until the voltage reaches the lamp portion. In this case, there is a problem that it is necessary to readjust the circuit of the inverter unit. The present invention aims to solve the above problems.

In order to achieve the above object, the present invention is provided on the back side of the liquid crystal unit which is formed in a thin box shape having an opening on the surface plate, and a light transmission type light diffusion plate is stretched on the opening. A frame disposed; a cold cathode tube built in the frame; and an inverter printed circuit board provided with an inverter circuit, the inverter printed circuit board being fixed to a lower surface of a bottom plate of the frame, the frame, the cold cathode The tube and the inverter printed circuit board are integrally combined to be unified, a notch is formed in the frame, and the lead wire of the cold cathode tube electrode is connected to the high voltage output terminal of the inverter circuit through the notch. A connector for connecting to external wiring on the inverter printed circuit board, and supplying power to the inverter circuit through the connector; from the inverter circuit The electrode of Kihiya cathode tube is obtained so as to supply a high voltage.
Further, the present invention provides the liquid crystal wherein the surface plate has an opening having a size substantially the same as that of the liquid crystal unit and is formed in a thin box shape, and a light transmission type light diffusion plate is stretched in the opening. A frame disposed on the back side of the unit, a cold cathode tube built in the frame, and an inverter printed circuit board provided with an inverter circuit and a dimming circuit, and the inverter printed circuit board is disposed on a lower surface of the bottom plate of the frame The frame, the cold cathode tube and the inverter printed circuit board are integrally coupled and unified, a notch is formed in the frame, and the lead wire of the electrode of the cold cathode tube is passed through the notch. Lead to the through hole of the inverter printed circuit board, connect to the high voltage output terminal of the inverter circuit, and fix the connector for connecting to the external wiring on the inverter printed circuit board, It supplies power to the inverter circuit through the connector, provides power and dimming signal to the dimmer circuit, is obtained so as to supply a high voltage to the electrodes of the cold cathode tube from the inverter circuit.

In the present invention, the cold cathode fluorescent lamp and the inverter printed circuit board are integrated as described above, and both are unitized, so that the entire backlight illumination device can be reduced in size and thickness, and the high-voltage line is not required to be routed. Safety and operational reliability can be improved. Further, the lead wire of the cold cathode tube and the inverter board can be connected in the shortest distance through the through hole of the inverter printed board, and the backlight illumination unit can be configured compactly. Further, by connecting the external wiring to the connector, it is possible to supply power to the inverter circuit and supply power to the light control circuit and light control signal at the same time, so that there is an effect that the wiring work becomes easy.

It is an AA line sectional view showing an embodiment of the present invention. It is explanatory front view which shows embodiment of this invention. It is explanatory front view which shows embodiment of this invention. It is a BB sectional view. It is a planar front view which shows other embodiment of this invention. It is CC sectional view taken on the line. It is DD sectional view taken on the line. It is explanatory drawing of a lamp holding | maintenance mechanism. It is sectional drawing which shows the connection mechanism of a cold cathode tube and a printed circuit board. It is an explanatory front view showing other embodiments of the present invention. It is an explanatory front view showing other embodiments of the present invention. It is an explanatory front view showing other embodiments of the present invention. It is the EE sectional view. It is an explanatory front view showing other embodiments of the present invention. It is explanatory drawing of a prior art.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. In FIG. 2, reference numeral (14) denotes a printed board made of glass epoxy resin or the like, and a high voltage generating circuit including a ceramic piezoelectric transformer and a winding transformer, that is, an inverter circuit (16), and a light control circuit (16) connected thereto. 18) is formed by printed wiring technology. A connector (20) is fixed to the side of the printed circuit board (14), and two terminals for inputting power to the input side of the connector (20) and one terminal for inputting a dimming signal are provided. Is provided. The inverter circuit (16) and the dimming circuit (18) are connected to the connector (20), and power is input from the outside through the connector (20).

The light control circuit (18) is configured to receive a power supply and a light control signal through the connector (20). (22) is a cold cathode fluorescent lamp (CCFL) which is bent in a U-shape and is lit at a high voltage, and both ends thereof are fixed to the printed circuit board (14) by holding metal fittings (24). The lead wire (26) of one electrode of the cold cathode tube (22) is fixed to the high voltage output terminal (28) of the inverter circuit (16) by soldering at the shortest distance, and the other of the cold cathode tube (22) is fixed. The electrode lead wire (26) is connected to the ground potential terminal (30) of the printed circuit board (14) by soldering. This eliminates the need for a high-voltage line between the lead wire (26) of the cold cathode tube (22) and the inverter circuit (16).

The other output terminal (32) of the inverter circuit (16) is connected to the ground potential. The printed circuit board (14) and the cold cathode tube (22) constitute a backlight illumination unit. In the embodiment of the present invention, the following configuration is added to the above configuration. Reference numeral (34) denotes a frame, which is formed in a thin box shape having an opening (34d) of almost the same size as the liquid crystal unit (2) on the surface plate (34c) and having a structure in which the side is opened. ing. A light transmissive light diffusing plate (44) is stretched at the opening of the frame (34) so as to form a light uniform irradiation surface for uniformly irradiating light. The frame (34) is disposed on the back side of the liquid crystal unit (2) and is fixed thereto. Therefore, the frame (34) has an attachment portion (not shown) for fixing the frame (34) to the liquid crystal unit (2) and an attachment portion for fixing the frame (34) to the body of the liquid crystal display electronic device. (Not shown) is provided. As shown in FIG. 4, the cold cathode tube (22) is accommodated in the U-shaped part of the frame (34).

A light-reflective light-reflecting diffuser plate (36) having a large number of minute pyramid-shaped convex portions is fixedly arranged on the back surface of the frame (34), that is, the bottom plate (34e) of the frame (34). The rear open portion of the frame (34) is shielded by the diffusion plate (36). A transparent acrylic plate (38) is disposed at the open center of the bottom plate (34e) of the frame (34), and the three-direction edges of the acrylic plate (38) are U-shaped portions of the frame (34). It is supported by. The acrylic plate (38) guides the light of the cold cathode tube (22) in the horizontal direction from the end surface side, and forms a uniform white light irradiation surface on the front side of the acrylic plate (38). A mirror surface (34a) for reflecting light toward the end face of the acrylic plate (38) is formed on the inner surface of the U-shaped portion of the frame (34).

A transparent light diffusion plate (40) and a light guide plate (42) are laminated and adhered to each other at the front side opening (34d) of the frame (34), thereby forming a uniform white light irradiation surface. The light irradiation surface (44) shields the opening (34d) on the front side of the frame (34). Only one side of each of the light diffusion plate (40) and the light guide plate (42) constituting the light irradiation surface (44) is fixed to one side of the U-shaped portion of the frame (34). Escape the contraction phenomenon. The one side (34b) of the frame (34) is notched at the top, and the notch end surface is in contact with one side of the printed circuit board (14). In this state, the one side (34b) is screwed (46). Is fixed to one side of the printed circuit board (14). The periphery of the acrylic plate (38) is supported in a rectangular holding space surrounded by the end face of the printed circuit board (14) and the frame (34).

In the above configuration, the cold cathode tube (22), the printed circuit board (14), the frame (34), the light reflection diffusion plate (36), the light diffusion plate (40), the light guide plate (42), and the acrylic plate (38) The backlight device is integrally joined to form a thin plate unit as a whole. The backlight illumination unit is disposed so as to overlap the back surface of the liquid crystal unit and irradiates the liquid crystal plate. In the above embodiment, the cold cathode tube (22) is directly fixed to the printed circuit board (14) by the lamp holder (24). However, the cold cathode tube (22) may be fixed to the frame (34). Further, as shown in FIGS. 5 to 9, a lamp holding plate (50) is provided separately from the frame (34), and the lamp holding plate (50) is fitted into the lamp holding plate (50). The cold cathode fluorescent lamp (22) may be held via the lamp, and the lamp holding plate (50) may be fixed to the printed circuit board (14) with screws (54).

In FIG. 6, the cold cathode tube (22) is loosely placed in the U-shaped portion of the frame (34) together with the lamp holding plate (50), and the frame (34) includes an inverter circuit (16) and a dimming circuit ( 18) is fixed to the printed circuit board (14) formed with screws (54). This embodiment is the same as the first embodiment except for the configuration of holding the cold cathode tube (22) by the lamp holding plate (50). Both ends of the cold cathode tube (22) are arranged on a printed circuit board (14) as shown in FIG. 7, and the lead wire (56) of the electrode at one end of the cold cathode tube (22) is shown in FIG. As described above, the high voltage output terminal (58) of the inverter circuit of the printed circuit board (14) is connected by soldering via the metal fitting (59), and the lead wire of the other electrode is soldered to the ground of the printed circuit board (14). Connected by attaching. The lead wire (56) may be soldered directly to the high voltage output terminal (58) of the printed circuit board (14) without using the metal fitting (58). The lamp holder (52) is made of an elastic body, presses the cold cathode tube (22) against the elasticity of the holder (52) from the upper gap, and inserts the cold cathode tube into the holding recess (52a). It is comprised so that it can mount | wear.

Next, another embodiment of the present invention will be described with reference to FIG. (60), (62), and (64) are straight tube type cold cathode fluorescent lamps, each of which is formed with an inverter circuit (16) and a light control circuit (18) via a holding metal fitting (66). The other end of each printed circuit board (14) is fixed to a support plate (68) made of a glass epoxy resin plate or the like via a holding metal fitting (70). The lead wires (78) of the electrodes of the cold cathode tubes (60) (62) (64) are soldered to the high voltage output terminals (72) (74) (76) of the inverter circuit (16). It is glued.

The output terminal (80), which forms a pair with the high voltage output terminals (72), (74), (76) of the inverter circuit (16), is grounded to the printed circuit board (14). A line (82) made of a conductor is formed on the support plate (68), and lead wires (each of the other end electrodes of the cold cathode tubes (60) (62) (64)) are formed on the line (82). 84) are connected by soldering. The line (82) is connected to the connector (86) fixed to the support plate (68), the connector (88) fixed to the printed circuit board (14), and the connector (86) (88). The printed circuit board (14) is grounded through the voltage cord (90).

In the above configuration, input power is supplied to the inverter circuit (16) through the connector (20) fixed to the printed circuit board (14), and the input power is supplied to the dimming circuit (18) through the connector (20). And the lighting and brightness of the cold cathode fluorescent lamps (60), (62) and (64) are controlled by the inverter circuit (16). As shown in FIG. 13, the surface plate (102a) has an opening (102b) of almost the same size as the liquid crystal unit (2) and is formed in a thin box shape, and light is transmitted to the opening (102b). A transmissive light diffusing plate (114) is stretched, and a frame (102) is provided on the back side of the liquid crystal unit (2). A printed circuit board shown in FIG. 10 is provided on the frame (102). (14), support plate (68), cold cathode fluorescent lamps (60), (62) and (64), and the frame (102), printed circuit board (14), cold cathode fluorescent lamps (60), (62) and (64). A unit may be configured with.

FIG. 11 shows a printed circuit board in which an inverter circuit (16) and a dimming circuit (18) are formed on both ends of a plurality of U-shaped cold cathode tubes (92) and (94) via holding metal fittings (96). 14) shows a fixed embodiment. The high voltage output terminals (98) and (100) of the inverter circuit (16) are connected to lead wires of electrodes at one end of the cold cathode tubes (92) and (94) by soldering. The voltage output terminal and the pair of output terminals (80) are connected to the ground potential. The lead wire of the electrode at the other end of the cold cathode tubes (92) (94) is connected to the ground potential of the printed circuit board (16) by soldering. Power is input to the inverter circuit (16) through the connector (20), and power and a dimming signal are input to the dimming circuit (18) through the connector (20). In this embodiment as well, as shown above, as shown in FIG. 13, the surface plate (102a) has an opening (102b) of almost the same size as the liquid crystal unit (2) and is in a thin box shape. A frame (102) disposed on the back side of the liquid crystal unit (2), in which a light transmission type light diffusion plate (114) is stretched and formed in the opening (102b), is provided. 102), a printed board (14) and cold cathode tubes (92) and (94) shown in FIG. 11 may be built in, and the frame, the printed board, and the cold cathode tube may constitute a unit.

Next, another embodiment of the present invention will be described with reference to FIGS. (102) is a frame made of metal, plastic or the like in which an opening (102b) is formed in the surface plate (102a), and is configured in a thin box shape. The frame (102) has a mounting portion (108) for fastening a screw (106) to the body (104) of a liquid crystal display electronic device such as a television, and a stud for fastening a screw (112) to the liquid crystal unit (2). A mounting portion (110) is provided. A light guide plate (112) and a light transmission type light diffusion plate (114) are attached to the opening (102b) of the frame (102). The opening (102b) constitutes a light irradiation surface, and the light irradiation surface is set to be approximately the same size as the liquid crystal unit (2). A light reflection type light diffusion surface is formed on the upper surface (102d) of the bottom plate (102c) of the frame (102), that is, the bottom surface of the frame (102), and the light reflection plate having a triangular cross section is formed on the bottom surface. (116) is fixed. Reference numeral (118) denotes a cold cathode tube, which is fixed to the bottom surface of the frame (102) via a holder base (120) and a holding metal fitting (122). An inverter printed circuit board (14) is fixed to the bottom surface of the frame (102) by screws (124) adjacent to the electrodes of the cold cathode tube (118).

The lead wire (126) of one electrode of the cold cathode tube (118) (118) is fixed to the high voltage output terminal of the inverter printed circuit board (14) by soldering, and the cold cathode tube (118) (118) The lead wire (128) of the other electrode is connected to the ground potential terminal of the inverter printed circuit board (14) by soldering. A connector (130) is fixed to the frame (102), and the connector (130) is connected to the connector (20) of the inverter printed circuit board (14). In the above-described configuration, the frame (102), the cold cathode tube (118), and the inverter printed circuit board (14) are integrally coupled to form a thin box unit as a whole, and the unit includes the liquid crystal unit (2 ) And is attached to the back surface of the liquid crystal unit (2) to irradiate the liquid crystal plate. In the above embodiment, the inverter printed circuit board (14) is disposed inside the frame (102) so as to be cut off from the outside. However, as shown in FIG. 14, the bottom outer wall surface of the frame (102), that is, the frame A notch in which lead wires (126) and (128) of a cold cathode tube (118) fixed to the lower surface (102e) of (102) are formed in the bottom plate (102a) of the frame (102). The lead wire may be led to the through hole of the printed circuit board (14) through the part (132) and soldered to the printed circuit board (14).

2 Liquid Crystal Unit 4 Cold Cathode Tube 6 Lamp Unit 8 Liquid Crystal Control Unit 10 Inverter 12 Connector 14 Inverter Printed Circuit Board 16 Inverter Circuit 18 Dimming Circuit 20 Connector 22 Cold Cathode Tube 24 Holding Bracket 26 Lead Wire 28 Terminal 30 Terminal 32 Terminal 34 Frame 34a Mirror surface 36 Light reflection diffusion plate 38 Acrylic plate 40 Light diffusion plate 42 Light guide plate 44 Light irradiation surface 46 Screw 50 Lamp holding plate 52 Lamp holder 54 Screw 56 Lead wire 58 Terminal 60 Cold cathode tube 62 Cold cathode tube 64 Cold cathode tube 66 Holding bracket 68 Support plate 70 Holding bracket 72 Terminal 74 Terminal 76 Terminal 78 Lead wire 80 Terminal 82 Line 84 Lead wire 86 Connector 88 Connector 90 Cord 92 Cold cathode tube 94 Cold cathode tube 96 Holding bracket 98 Terminal 100 Terminal 102 Frame 104 Body 106 Screw 108 mounting 110 mounting portion 112 guiding unit 114 the light diffusing portion 116 the light reflection plate 118 CCFL 120 holder base 122 supporting bracket 124 inverter 126 lead 128 lead 130 connector 132 notch

Claims (2)

A frame disposed on the back side of the liquid crystal unit, which is formed in a thin box shape having an opening on the surface plate, and a light transmission type light diffusion plate is stretched in the opening, and built in the frame A cold cathode fluorescent lamp and an inverter printed circuit board provided with an inverter circuit, the inverter printed circuit board being fixed to a lower surface of the bottom plate of the frame, and the frame, the cold cathode fluorescent lamp and the inverter printed circuit board are integrally formed. Combine and unify, drill a notch in the frame, connect the lead wire of the cold cathode tube electrode to the high voltage output terminal of the inverter circuit through the notch, and connect external wiring to the inverter printed circuit board A connector for connecting to the inverter circuit, supplying power to the inverter circuit through the connector, and supplying high voltage to the electrodes of the cold cathode tube from the inverter circuit Backlight illumination unit, characterized in that the so that. Arranged on the back side of the liquid crystal unit, which is formed in a thin box shape having an opening of the same size as the liquid crystal unit on the surface plate, and a light transmission type light diffusion plate is stretched in the opening. A frame, a cold cathode tube built in the frame, and an inverter printed circuit board provided with an inverter circuit and a dimming circuit, and fixing the inverter printed circuit board to a lower surface of a bottom plate of the frame, The cold cathode tube and the inverter printed circuit board are integrally coupled and unified, a notch is formed in the frame, and the lead wire of the cold cathode tube electrode is passed through the notch through the inverter printed circuit board. Lead to the hall, connect to the high voltage output terminal of the inverter circuit, and fix a connector for connecting to the external wiring on the inverter printed circuit board. A power source and a dimming signal are supplied to the dimming circuit, and a high voltage is supplied from the inverter circuit to the electrodes of the cold cathode tube. Light lighting unit.

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