JP2009037924A - Electric connector and backlight device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric connector capable of maintaining a stable connection state with a terminal of a fluorescent tube. <P>SOLUTION: A first contact 15 of the electric connector has a pair of elastic piece parts 30 in order to pinch an outer lead 13 of a terminal part 7a of a cold-cathode tube 7. Accompanying the displacement of a cover housing as an operation member, first pressurizing parts 77 pressurize respective elastic piece parts 30 at the outer lead 13 [Fig.28 (b)]. Next, second pressurizing parts 78 pressurize the respective elastic piece parts 30 at the outer lead 13 [Fig.28 (c)]. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an electrical connector and a backlight device attached to a fluorescent tube for a backlight of a liquid crystal display device.

As a backlight device for a liquid crystal display device, for example, a long cold cathode fluorescent lamp (CCFL) is used. The cold cathode tube has an elongated shaft-like electrode terminal (outer lead) protruding from an end portion thereof.
In patent document 1, the core wire of the power supply line connected to the inverter circuit is connected to the outer lead by soldering. However, the soldering work requires many man-hours and takes time to manufacture.
JP 2004-227007 A

Therefore, it is conceivable to connect the elastic piece of the contact of the electrical connector to the outer lead by elastic contact. However, if the elastic piece is pressed for a long time with the elastic piece pressed against the outer lead, the elastic piece may sag and the connection with the outer lead may become unstable.
In particular, when heat generated by a fluorescent tube such as a cold cathode tube is transmitted to a resin member such as a housing via an outer lead, the pressing force of the elastic piece portion on the outer lead may be weakened.

  Accordingly, an object of the present invention is to provide an electrical connector and a backlight device that can maintain a stable connection state with the terminals of a fluorescent tube.

  In order to achieve the above object, the present invention comprises an insulating housing, a contact held by the housing, and an operating member for operating the contact, and the contact is provided at the end of the fluorescent tube. The terminal includes a pair of elastic pieces that can be inserted between each other along a mounting direction corresponding to the radial direction of the terminal and can sandwich the inserted terminal. There is provided an electrical connector including a plurality of pairs of pressing parts for pressing an elastic piece part to a terminal. In the present invention, it is possible to increase the pressure applied to the terminal by the pair of elastic pieces, and it is possible to achieve a reliable connection between the contact and the terminal. As the operating member is operated, pressurization by a plurality of pairs of pressurization units may be achieved at the same time, or may be achieved by shifting the time for each pair.

In addition, the plurality of pairs of pressure parts may include at least a pair of metal parts (claim 2). In this case, there are the following advantages. That is, even when receiving heat from the fluorescent tube that generates heat, the metal portion as the pressurizing portion does not sag due to thermal deterioration (plastic deformation) or the like. Therefore, a sufficient contact pressure can be maintained between the contact and the terminal over a long period of time.
Moreover, the protrusion which contacts the other may be formed in any one of the part of the elastic piece part pressed by the said metal part, and the said metal part (Claim 3). In this case, since the area of the contact region between the metal part as the pressurizing part and the corresponding elastic piece part that becomes a metal contact can be reduced, heat is transferred from the fluorescent tube to the housing through the contact by heat conduction. Can be suppressed. As a result, thermal deterioration of the housing can be prevented.

  The operating member is supported by the housing so as to be displaceable in first and second positions, and the operating member is moved in pairs from the first position to the second position. In some cases, the pressure is increased with increasing pressure for each pair (claim 4). In this case, since the force for operating the operating member may be increased stepwise, the operating member can be operated smoothly.

Further, when the operation member is displaced to the first position, the terminal may be inserted between the pair of elastic pieces with no insertion force along the attachment direction (claim 5). In this case, the terminal can be easily inserted between the pair of elastic pieces without imposing a burden on the terminal of the fluorescent tube.
When the housing includes a base housing, the operation member includes a cover housing that covers at least a part of the housing, and the plurality of pairs of pressurizing portions are provided on a rib formed on the cover housing. (Claim 6). In this case, a single member can perform a plurality of functions, and the structure can be simplified.

  Further, when the pair of elastic pieces are viewed along the holding direction in which the pair of elastic pieces hold the terminal, the direction in which the elastic piece extends is parallel to the direction in which the terminal extends. There is a case (Claim 7). In this case, when viewed from the clamping direction, the extending direction of the elastic piece is orthogonal to the fluorescent tube mounting direction. Therefore, the electrical connector can be reduced in size with respect to the mounting direction.

The fluorescent tube may include a cold cathode tube, and the terminal may include an outer lead exposed from an end of the cold cathode tube. The fluorescent tube may include an external electrode fluorescent tube, and the terminal may include an electrode layer coated on a peripheral surface of an end portion of the external electrode fluorescent tube.
In addition, a backlight device characterized in that it includes the electrical connector described above in which a plurality are mounted side by side on a support plate and a fluorescent tube supported by each electrical connector is preferable. ).

Preferred embodiments of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is a schematic cross-sectional view showing a schematic configuration for a liquid crystal display device including an electrical connector according to an embodiment of the present invention. With reference to FIG. 1, the liquid crystal display device 1 is used as a monitor of a television or a personal computer, for example.
The liquid crystal display device 1 includes a housing 2, a liquid crystal display panel 4 held by the housing 2 so as to cover the opening 3 of the front surface 2 a of the housing 2, and a direct back that irradiates the liquid crystal display panel 4 with light. And a light device 5.

  The backlight device 5 is disposed behind the cold cathode tubes 7 as a plurality of cold cathode tubes 7 as a plurality of fluorescent tubes facing in parallel with the diffusion plate 6 provided along the back surface of the liquid crystal display panel 4. A support plate 8 as a first support plate made of a metal plate provided with a reflection surface 8a for reflecting the light of the cathode tube 6 and an inverter circuit board as a second support plate for driving the cold cathode tube 7 9 and a plurality of electrical connectors 10 for connecting the corresponding cold cathode tubes 7 to the inverter circuit board 9.

The support plate 8 and the inverter circuit board 9 are arranged in parallel with the diffusion plate 6. The number of cold cathode tubes 7 is, for example, two per inch of the liquid crystal display panel 4. Therefore, in the backlight device 5 of the large-sized liquid crystal display device 1, a large number of cold cathode tubes 7 are arranged.
Referring to FIG. 1 and FIG. 2 which is a perspective view of the main part of the backlight device 5, each electrical connector 10 includes a first electrical connector 11 and a second electrical connector 12 which are detachably connected to each other. ing. The first electrical connectors 11 of the plurality of electrical connectors 10 are collectively supported by the support plate 8 in a side-by-side arrangement. A corresponding end portion of the cold cathode tube 7 is attached to and electrically connected to each first electrical connector 11. On the other hand, the second electrical connectors 12 of the plurality of electrical connectors 10 are collectively attached to the inverter circuit board 9 in a state of being lined up side by side. That is, each electrical connector 10 functions as a board-to-board connector for connecting the corresponding cold cathode tube 7 to the inverter circuit board 9 (see FIG. 3).

Referring to FIG. 4 which is an exploded perspective view of the main part of the backlight device 5, the cold cathode tube 7 is a straight tube extending in the longitudinal direction, and the end portion 7a of the cold cathode tube 7 projects in the axial length direction X1. An outer lead 13 is provided as a shaft-shaped terminal. In the drawing, only one end 7a is shown, but the outer lead 13 is also provided for the other end 7a.
The outer lead 13 of the cold cathode tube 7 is attached to the first electrical connector 11 along an attaching direction Y1 corresponding to the radial direction of the outer lead 13.

  Referring to FIG. 4 and FIG. 5 which is an exploded cross-sectional view of the main part of the backlight device 5, the first electrical connector 11 is supported by an insulating first housing 14 and the first housing 14. And a first contact 15. The second electrical connector 12 includes an insulating second housing 16 attached to the surface 9 a of the inverter circuit board 9 and a pair of second contacts 17 held by the first housing 16. Yes.

The first housing 14 includes a synthetic resin base housing 18 attached to the support plate 8, and a synthetic resin cover housing 19 that functions as an operation member for operating the first contact 15. ing.
Referring to FIGS. 5, 6, and 7, the base housing 18 includes a main body 20 disposed on the surface 8 a of the support plate 8, and protrudes downward from the main body 20 in the drawing to support holes in the support plate 8. 21 is provided with a cylindrical first insertion convex portion 22 inserted through 21, and a removal prevention shaft 24 that protrudes downward from the main body 20 in the drawing and is inserted into a removal prevention hole 23 of the support plate 8. Yes.

  Referring to FIG. 5, the first insertion convex portion 22 is formed with a first insertion concave portion 25 that opens in the insertion direction of the first insertion convex portion 22. Further, the main body 20 of the base housing 18 is formed with a contact accommodating portion 26 that opens upward in FIG. The contact accommodating portion 26 communicates with a first insertion recess 25 formed in the first insertion protrusion 22. The upper part of the contact housing recess 26 is covered with the cover housing 19.

The first contact 15 is a connector connection for connecting a fluorescent tube terminal connection contact 27 for connecting the outer lead 13 of the cold cathode tube 7 and a second contact 17 of the second electrical connector 12. The contact 28 is formed integrally with a single sheet metal.
The fluorescent tube connecting contact 27 is accommodated and held in the contact accommodating portion 26 of the main body 20 of the base housing 18.

Specifically, referring to FIG. 8 and FIGS. 9A and 9B, the fluorescent tube connecting contact 27 includes a groove-shaped fixing portion 29 fitted to the inner wall of the contact accommodating portion 26. And a pair of opposing elastic piece portions 30 extending from the fixing portion 29.
The fixing portion 29 includes a pair of flanges 29a and a web 29b that connects the pair of flanges 29a. The pair of elastic pieces 30 are extended from the pair of flanges 29 a of the fixed portion 29.

As shown in FIGS. 10 and 11, the outer lead 13 of the cold cathode tube 7 inserted between the pair of elastic pieces 30 is sandwiched between the pair of elastic pieces 30 to connect the outer lead 13 and the fluorescent tube. An electrical connection with the contact 27 is achieved.
Each elastic piece part 30 of the contact 27 for connecting the fluorescent tube has a first piece part 32 and a second piece part 33 which are connected to each other via a folded part 31. Each first piece 32 is extended from the corresponding flange 29a of the fixed portion 29, and the second piece 33 is connected to the inner side of the extended first piece 32 via the folded portion 31. It is folded back.

Each first piece 32 has a first inclined portion 34 inclined so as to expand outward from the corresponding flange 29a, and a second inclined portion that connects between the first inclined portion 34 and the folded portion 31. Part 35. The inclination of the second inclined portion 35 is made gentler than the inclination of the first inclined portion 34. For this reason, each 1st piece part 32 has comprised the mountain shape which protrudes outward.
Each second piece 33 has a mountain shape protruding inward, and a contact portion 36 for contacting the outer lead 13 is formed at the top of the mountain shape. The pair of elastic pieces 30 sandwich the outer lead 13 in the clamping direction Z1 by the contact portion 36.

  In a state where the pair of elastic pieces 30 are not pressed by a pressure unit (described later) of the cover housing 19 as an operation member (unconstrained state), as shown in FIG. The interval W1 between the contact portions 30 of the second piece 30 is larger than the diameter D1 of the outer lead 13. The outer lead 13 is inserted between the pair of elastic pieces 30 with no insertion force.

  As shown in FIG. 12, when the contact 27 for connecting the fluorescent tube of the first contact 15 is viewed along the clamping direction Z1, the axial length direction X1 in which the outer lead 13 of the cold cathode tube 7 extends and each elasticity The extending direction K1 (corresponding to the longitudinal direction) of the piece 30 is parallel to each other. Thereby, the contact 27 can be reduced in size with respect to the mounting direction Y1, and as a result, the first electrical connector 11 can be reduced in size with respect to the mounting direction Y1.

  Referring to FIGS. 8 and 9A and 9B, connector connecting contact 28 includes first and second fixing pieces 37 and 38 facing each other, and the first and second fixings. It has the connection part 39 which connects the edge part of the piece parts 37 and 38 mutually. The first fixed piece portion 37 extends from the web 29b of the fixed portion 29 of the contact 27 for connecting the fluorescent tube so as to be flush with the web 29b. The first fixed piece portion 37, the second fixed piece portion 38, and the connecting portion 39 are connected to each other to form a groove shape, and are fitted and fixed to the inner wall surface of the first insertion recess 25.

  Referring to FIGS. 5 and 6 again, the second housing 16 of the second electrical connector 12 has a bottom wall 40 attached to the surface 9a facing the surface 9a of the inverter circuit board 9, and a bottom thereof. A second insertion convex portion 41 having a prismatic shape that can be fitted into the first insertion concave portion 25 of the first electrical connector 11 and a peripheral edge of the bottom wall 40 rising from the central portion of the wall 40 and the first And a peripheral wall 42 surrounding the periphery of the two insertion convex portions 41.

Further, an annular second insertion recess 43 into which the first insertion projection 22 of the first electrical connector 11 can be fitted is defined between the second insertion projection 41 and the peripheral wall 42. The second insertion convex portion 41 of the second electrical connector 12 forms a pair of contact holding grooves 44 that open in opposite directions.
Each second contact 17 includes a fixed piece 45 held in a corresponding contact holding groove 44, a cantilevered elastic piece 46 extended from one end of the fixed piece 45 via a folded portion, And a lead 47 extending orthogonally from the other end of the fixed piece 45.

The other end of the fixed piece 45 protrudes below the second housing 16, and the lead 47 is connected to the conductive portion of the surface 9 a of the inverter circuit board 9 by soldering. The elastic piece portion 46 of each second contact 17 includes a mountain-shaped portion 48, and the top of the mountain-shaped portion 48 protrudes from the corresponding contact holding groove 44 to constitute a contact portion 49.
On the inverter circuit board 9, the periphery of the second insertion convex portion 41 holding the second contact 17 is surrounded by the peripheral wall 42, so that the so-called creepage distance can be increased.

  When the first insertion convex portion 22 of the first electrical connector 11 is fitted into the second insertion concave portion 43 of the second electrical connector 12, the first insertion concave portion 25 of the first electrical connector 11. Is fitted to the second insertion convex portion 41 of the second electrical connector 12. Accordingly, the contact portion 49 of each second contact 17 is elastically in contact with the first and second fixing piece portions 37 and 38 of the contact 28 for connecting the first contact 15. It has become.

  With reference to FIG. 13 and FIG. 14, the outer peripheral surface 22a of the 1st insertion convex part 22 inserted in the support hole 21 of the support plate 8 has a pair of curved surface part 50 which opposes, and two surfaces between each other. It has a pair of opposing flat parts 51 which form a width. Each curved surface part 50 consists of a part of cylindrical surface, for example. The support hole 21 of the support plate 8 has the same shape as the cross-sectional shape of the first insertion convex portion 22. That is, the inner peripheral surface of the support hole 21 has a pair of curved surface portions 21 a that match the pair of curved surface portions 50 and a pair of flat portions 21 b that match the pair of flat portions 51.

By arranging the pair of flat portions 51 of the first insertion convex portion 22 and the pair of flat portions 21b of the support hole 21 along each other, each first relative to the support plate 8 with respect to the circumferential direction of the first insertion convex portion 22 is arranged. The amount of displacement of the electrical connector 11 (corresponding to the angle error with respect to the axial direction X1 of the cold cathode tube 7) can be reduced. As a result, each first electrical connector 11 can be attached with high positional accuracy.

Further, the removal prevention shaft 24 inserted through the removal prevention hole 23 of the support plate 8 has, for example, a round cross section. The removal prevention shaft 24 is provided with a pair of locking members 52 that are opposed to each other in the radial direction of the removal prevention shaft 24. Each locking member 52 is provided with a cantilevered elastic arm 53 extending in the axial direction of the removal preventing shaft 24, and protrudes radially outward of the removal preventing shaft 24 provided at the tip of the elastic arm 53. And a locking portion 54.

As shown in FIG. 15, the locking portion 54 of each locking member 52 is engaged with the back surface 8 b of the support plate 8 in a state where the removal preventing shaft 24 is inserted into the removal preventing hole 23. The removal prevention shaft 24 is prevented from coming off, and as a result, the first housing 14 of the first electrical connector 11 is fixed to the support plate 8.
7 and 16, the main body 20 of the base housing 18 of the first housing 14 has, for example, a U-shaped groove 55 inserted when the end portion 7a of the cold cathode tube 7 is attached. Is formed. A receiving portion 56 for receiving the end portion 7a of the inserted cold cathode tube 7 is provided at the bottom of the groove 55 (see FIG. 6).

  With reference to FIGS. 7, 16, 17, and 18, the cover housing 19 of the first housing 14 has a top wall 57, a pair of side walls 58, and a rear wall 59. Referring to FIGS. 7, 16, and 18, a slit 60 extending in the front-rear direction is formed in the front half portion of the ceiling wall 57, and the end portion 7 a of the cold cathode tube 7 is attached through the slit 60. It has become.

  Referring to FIGS. 7, 16, and 17, a pressed portion 61 made of an inclined cam surface is provided on the upper surface of the rear half of the ceiling wall 57 so that the height decreases toward the rear. It has been. The top surface of the ceiling wall 57 has a flat portion 83 that is orthogonal to the mounting direction Y1. Thus, since the flat part is ensured on the upper surface of the ceiling wall 57 of the cover housing 19, it is suitable for the case where the upper surface of the ceiling wall 57 is sucked and transported. As a result, it is suitable for automatic assembly by a robot.

Referring to FIG. 18, on the top wall 57, a retaining engagement portion 62 composed of a pair of tongue pieces disposed on both sides of the slit 60 is extended downward.
The pair of retaining engagement portions 62 are opposed to the receiving portion 56, and the cover housing 19 as an operation member is moved from the state shown in FIGS. 20 (b) and 22 (a) to FIGS. By operating to the state of (b), as shown in FIG. 21 (c), the end portion 7a of the cold cathode tube 7 (end portion of the cold cathode tube 7) is engaged, and as a result, the cold cathode tube 7 is cooled. The cathode tube 7 is prevented from being pulled out in the direction Y2 opposite to the mounting direction Y1. That is, a holding space for the end portion 7 a of the cold cathode tube 7 is defined between the receiving portion 56 and the retaining engagement portion 62.

Referring to FIG. 19, a pair of side surfaces 63 (only one side surface 63 is shown in FIG. 19) of the base housing 18 of the first housing 14, the first protrusions projecting sideways. The part 64, the 2nd convex part 65, and the 3rd convex part 66 are formed.
A third convex portion 66 is arranged between the first convex portion 64 and the second convex portion 65 in the front-rear direction of the base housing 18. The tops of the first convex portion 64, the second convex portion 65, and the third convex portion 66 are all formed on a flat surface. Further, the protruding amount of the third convex portion 66 from the side surface 63 is set smaller than each of the protruding amount of the first convex portion 64 and the protruding amount of the second convex portion 65. On the lower surface of the third convex portion 66, a lock portion 79 that engages with a locking projection 72 described later of the cover housing 19 is formed.

At least a part of the front surface of the first convex portion 64 forms a first inclined cam surface 67 whose height decreases toward the front. In addition, at least a part of the rear surface of the first convex portion 65 forms a second inclined cam surface 68 whose height decreases toward the front.
On the other hand, on the inner side surfaces 58a of the pair of side walls 58 of the cover housing 19 (only one inner side surface 58a is shown in FIG. 19), the first rib 69, the second rib 70, and the third The rib 71 and the locking projection 72 are formed to protrude.

The first rib 69 has, for example, a triangular shape. The top of the first rib 69 has a flat surface and makes surface contact with the top of the third convex portion 66 of the base housing 18. At least a part of the rear surface of the first rib 69 is formed on a first inclined cam surface 73 whose height decreases toward the front.
The 2nd rib 70 has comprised the protrusion which inclined diagonally so that height might become low as it goes ahead. At least a part of the rear surface of the second rib 70 is formed on a second inclined cam surface 74 whose height decreases toward the front.

  The first inclined cam surface 73 of the cover housing 19 and the first inclined cam surface 67 of the base housing 18 are engaged, and the second inclined cam surface 74 of the cover housing 19 is connected to the base housing 18. By engaging the second inclined cam surface 68, the cover housing 19 moves with respect to the base housing 18 along a crossing direction M1 that intersects the mounting direction Y1 of the cold cathode tube 7. , Will be guided. In the present embodiment, the crossing direction M1 crosses obliquely with respect to the mounting direction Y1.

The first inclined cam surface 73 and the first inclined cam surface 67 that are engaged with each other constitute a first cam mechanism 75. The second inclined cam surface 74 and the second inclined cam surface 68 that are engaged with each other constitute a second cam mechanism 76.
By the action of the first and second cam mechanisms 75 and 76, the cover housing 19 as the operation member is moved to the first position (see FIGS. 21A and 21B) along the intersecting direction M1. And a second position (see FIG. 21C) are supported by the base housing 18 so as to be displaceable.

  Referring to FIGS. 19 and 25, the third rib 71 of each side wall 58 of the cover housing 19 has a first pressing element as a pressing element for pressing the corresponding elastic piece 30 of the first contact 15. The pressure member 77 and the second pressure member 78 are provided. As shown in FIG. 25, the first pressure portions 77 of the pair of third ribs 71 face each other, and the second pressure portions 78 of the pair of third ribs 71 face each other. .

  The first pressure member 77 is formed on a flat surface parallel to the axial length direction X1 of the outer lead 13. The second pressure member 78 is formed on an inclined surface that is inclined with respect to the axial length direction X <b> 1 of the outer lead 13. Each of the second pressure parts 78 is arranged so that the distance between the pair of second pressure parts 78 becomes narrower toward the front of the cover housing 19 (corresponding to the moving direction of the cover housing 19 when the cover housing 19 is closed). The pressurizing part 78 is inclined.

Each third rib 71 is provided with an inclined guide surface 79 adjacent to the front end of the first pressure member 77. Each inclined guide surface 79 is inclined so that the distance between the pair of inclined guide surfaces 79 increases toward the front of the cover housing 19.
When the cover housing 19 as the operation member is displaced to the second position as shown in FIG. 21 (c), the locking projections 72 of the side walls 58 of the cover housing 19 are as shown in FIG. It engages with the lock portion 80 on the lower surface of the 18th third convex portion 66. As a result, the cover housing 19 is releasably locked in the second position (position shown in FIG. 20C).

  As shown in FIG. 26, the pair of side walls 58 of the cover housing 19 are extended from the pair of side edges of the top wall 57, and are supported by the top wall 57 in a cantilevered manner. A corresponding locking projection 72 is provided at the lower end of the inner side surface 58 a of each side wall 58. The side walls 58 are relatively thick, and the side walls 58 are relatively thin. As a result, the pair of side walls 58 can apply an elastic clamping force for clamping the base housing 18 between them.

As shown in FIG. 27, the locking projection 72 has first and second inclined surfaces 81 and 82 that are inclined in opposite directions. The first inclined surface 81 serves as a guide when the cover housing 19 is attached to the base housing 18. The second inclined surface 82 functions as an engaging portion that engages with the lock portion 80 at the lower end of the third convex portion 60 of the base housing 18.
Next, with reference to FIG. 20, FIG. 21, and FIG. 28, the operation of attaching the cold cathode tube 7 to the electrical connector 11 will be described.

As shown in FIGS. 20A and 21A, the outer lead 13 of the cold-cathode tube 7 is attached along the mounting direction Y1 in a state where the cover housing 19 as the operation member is disposed at the first position. Install.
When the cover housing 19 is in the first position, the first pressing portion 77 and the second pressing portion 78 are still elastic pieces of the first contact 15 as shown in FIG. It is not in contact with the portion 30. For this reason, the interval W <b> 1 between the contact portions 36 of the pair of elastic pieces 30 is larger than the diameter D <b> 1 of the outer lead 13 between the contact portions 36.

Therefore, as shown in FIGS. 10, 20B and 21B, the outer lead 13 is inserted between the contact portions 36 along the mounting direction Y1 with no insertion force (ZIF). can do. No excessive force is applied to the outer lead 13.
Next, the inclined pressed portion 61 of the top wall 57 of the cover housing 19 is pressed to the lower second electrical connector 12 side. At this time, as shown in FIGS. 23 and 24, a common cover 84 that collectively covers the cover housings 19 of the plurality of first electrical connectors 11 attached to the support plate 8 can be used. A screw 111 as an attachment member inserted into a screw insertion hole 110 of a ceiling wall 85 (to be described later) of the cover 84 is screwed into, for example, a screw hole 112 formed in the support plate 8, and the cover 84 is fixed to the support plate 8. It has become so.

The cover 84 functions to prevent light leakage from the plurality of first electrical connectors 11. That is, it functions as a light shielding cover. Also, it functions as a drive member for collectively driving the cover housing 19 as an operation member of the plurality of first electrical connectors 11.
That is, the cover 84 can be collectively attached to the plurality of first electrical connectors 11 along a direction parallel to the attachment direction Y1 of the cold cathode tube 7. The cover 84 includes a flat top wall 85 that is orthogonal to the mounting direction Y <b> 1, a front wall 86, a pair of side walls 87, and a pressing plate 88 that connects the lower edges of the pair of side walls 87. The pressing plate 88 has a pressing portion 88 a made of an inclined cam surface that can be engaged with the inclined cam surface as the pressed portion 61. The pressed portion 61 and the pressing portion 88a constitute a third cam mechanism 89 including a pair of inclined cam surfaces inclined in opposite directions. The third cam mechanism 89 converts a force pushing the cover 84 in a direction parallel to the mounting direction Y1 into a force pushing the cover 84 obliquely forward. This direction may be a direction along the cross direction M1 or a direction crossing the cross direction M1. A direction on the same side as the intersecting direction M1 may be used.

When the cover 84 is attached to the plurality of first electrical connectors 11, the pressed portion 61 of the top wall 57 of each cover housing 19 of the plurality of electrical connectors 11 is pressed in a direction parallel to the attachment direction Y1. Each cover housing 19 can be displaced from the first position to the second position along the intersecting direction M1.
Specifically, when the cover housing 19 is pushed in a direction parallel to the mounting direction Y1, the functions of the first and second cam mechanisms 75 and 76 (see FIG. 19) are used, and FIGS. As shown in (c), the cover housing 19 is displaced to the second position along an intersecting direction M1 that obliquely intersects the axial length direction X1 of the outer lead 13.

When the cover housing 19 is displaced from the first position to the second position, from the state shown in FIG. 28 (a), the inclined guide surface 79 of each third rib 71 corresponds to the corresponding elastic piece 30. The state shown in FIG. 28B is obtained after a state of contacting the first inclined portion 34 (not shown).
In the state shown in FIG. 28 (b), each of the first pressurizing portions 77 presses the second inclined portion 35 of the corresponding elastic piece portion, so that the pressed second inclined portion 35 is outer. The lead 13 is parallel to the axial length direction X1. As a result, each contact portion 36 is pressed against the outer lead 13, and the outer lead 13 is sandwiched between the pair of contact portions 36.

Next, as the cover housing 19 reaches the second position, as shown in FIG. 28 (c), each second pressurizing portion 78 has the first inclined portion 34 of the corresponding elastic piece portion 30. Pressed. As a result, the pressure applied to the outer lead 13 by each contact portion 36 is strengthened, and reliable contact between the first contact 15 and the outer lead 13 is achieved.
According to the present embodiment described above, the following effects are obtained. That is, the cover housing 19 as an operation member for operating the first contact 15 of the first electrical connector 11 is attached to the cold cathode tube 7 in the mounting direction Y1 as shown in FIGS. Can be displaced in the intersecting direction M1 that intersects the first and second electrical connectors 11 in a direction parallel to the mounting direction Y1.

In particular, since the intersecting direction M1 is a direction that obliquely intersects the mounting direction Y1, both the direction parallel to the mounting direction Y1 and the direction orthogonal to the mounting direction Y1 are as follows: The electrical connector 11 can be reduced in size.
Specifically, when the cover housing 19 as the operation member is pushed in a direction parallel to the mounting direction Y1 of the cold cathode tube 7, the first is for displacing the cover housing 19 along the intersecting direction M1. Since the second cam mechanisms 75 and 76 are provided, there are the following advantages.

  That is, the direction in which the cover housing 19 is pushed when operating the first contact 15 is parallel to the mounting direction Y1 of the cold cathode tube 7. Therefore, in order to insert the outer lead 13 of the cold cathode tube 7 into the first electrical connector 11 between the pair of elastic pieces 30 and to sandwich the inserted outer lead 13 between the pair of elastic pieces 30. The operation of operating the cover housing 19 can be performed from the same direction (one direction). Therefore, for example, it is suitable for automating the work for securing the electrical connection by attaching the outer lead 13 of the cold cathode tube 7 to the first electrical connector 11 of the backlight device 5 of the liquid crystal display device 1.

  Further, when the cover housing 19 as the operation member is displaced to the first position shown in FIG. 20A, the outer lead 13 of the cold cathode tube 7 is interposed between the pair of elastic pieces 30 as shown in FIG. Can be inserted with no insertion force along the mounting direction Y1. Therefore, the outer lead 13 can be easily inserted between the pair of elastic pieces 30 without imposing a burden on the outer lead 13.

  Further, as the cover housing 19 as the operation member is displaced from the first position shown in FIG. 20B to the second position shown in FIG. 20C, FIGS. As shown in FIG. 3, between the pair of elastic pieces 30 of the pressurized first contact 15 pressurized by the first and second pressure portions 77 and 78 of the cover housing 19, Since the outer lead 13 is clamped, a reliable connection between the outer lead 13 and the first contact 15 can be achieved.

  When each elastic piece 30 of the first contact 15 is pressed against the outer lead 13, as shown in FIGS. 28 (b) and (c), a pair of first pressing portions 77 and a pair of first Since the pressure is applied by a plurality of pairs of pressurizing portions 77 and 78, which are two pressurizing portions 78, a more reliable connection between the outer lead 13 and the first contact 15 can be achieved. Further, even when used for a long time, the pressure does not weaken, and a high contact pressure can be maintained between the outer lead 13 and the first contact 15 for a long time.

  Further, when operating the cover housing 19 as the operation member, a plurality of pairs of pressurizations such that the pair of second pressurization units 78 pressurizes after the pressurization of the pair of first pressurization units 77. The parts 77 and 78 increase the pressure stepwise for each pair. Therefore, the force for operating the cover housing 19 as the operating member only needs to be increased stepwise, so that the cover housing 19 can be operated smoothly.

Further, since the operating member for operating the first contact 15 is configured as the cover housing 19 that covers at least a part of the base housing 18, a single member can perform a plurality of functions, and the structure Can be simplified.
Further, since the operating member for operating the first contact 15 is configured as the cover housing 19 that covers at least a part of the base housing 18, a single member can perform a plurality of functions, and the structure Can be simplified.

  Further, in the state where the cover housing 19 is displaced to the second position shown in FIG. 20 (c), the retaining engagement portion 62 of the cover housing 19 is engaged with the end portion 7 a (end portion of the tube) of the cold cathode tube 7. Therefore, it is possible to reliably prevent the cold cathode tube 7 from coming off in the direction opposite to the mounting direction Y1. In particular, the operation of the cover housing 19 for pressurizing the pair of elastic pieces 30 of the first contact 15 to the outer lead 13 can be achieved to prevent the end portion 7a of the cold cathode tube 7 from coming off. Is good.

  Further, as shown in FIG. 18, the base housing 18 of the first electrical connector 11 is opposed to the retaining engagement portion 62 and receives the end portion 7a (end portion of the tube) of the cold cathode tube 7. When the cover housing 19 is displaced to the second position, as shown in FIG. 21C, the receiving portion 56 of the base housing 18 and the retaining engagement portion 62 of the cover housing 19 are provided. The end 7a of the cold cathode tube 7 can be sandwiched between and securely held.

  Further, when the fluorescent tube connecting contact 27 of the first contact 15 is viewed along the clamping direction Z1 shown in FIG. 10, as shown in FIG. The extending direction K1 (corresponding to the longitudinal direction) of the elastic piece 30 is parallel to each other. Since the axial length direction X1 is orthogonal to the mounting direction Y1 of the cold cathode tube 7, the contact 27 can be reduced in size with respect to the mounting direction Y1, and as a result, the first electrical connector 11 is connected to the mounting direction. The size can be reduced with respect to Y1.

Further, as shown in FIG. 3, a plurality of first electrical connectors 11 mounted side by side on the support plate 8 and a plurality of second electrical connectors 12 provided side by side on the inverter circuit board 9 provide a cold cathode tube. 7 and the inverter circuit board 9 can be easily and reliably connected using a so-called board-to-board connector type.
In particular, the support plate 8 is constituted by a metal plate on which a reflection surface 8a for reflecting the light of the cold cathode tube 7 is formed. Since the member that performs the reflection function, which is an essential configuration, is also used as the support plate 8, the structure can be simplified as compared with the case where a support plate is separately provided. However, a dedicated support plate may be provided separately from the member performing the reflection function.

  Further, as shown in FIG. 23, when the common cover 84 is attached to the plurality of first electrical connectors 11 mounted side by side on the support plate 8, the operation members of the plurality of first electrical connectors 11 are used. The cover housing 19 can be displaced to the second position (see FIG. 20C) to connect the plurality of first contacts 15 to the corresponding outer leads 13 (see FIG. 28C).

  Further, as shown in FIG. 24B, the pressing portion 88a of the common cover 84 and the pressed portion 61 of the cover housing 19 are inclined in opposite directions with respect to the direction parallel to the mounting direction Y1 and are engaged with each other. Since a pair of sloped cam surfaces that can be combined is included, the force applied from the cover 84 to the cover housing 19 as the operation member can be satisfactorily converted into the force in the cross direction M1 that is the moving direction of the cover housing 19. it can.

  Therefore, even when the direction in which the cover housing 19 as the operation member is displaced (corresponding to the crossing direction M1) is not parallel to the mounting direction Y1 of the cold cathode tube 7, the outer leads 13 of the cold cathode tube 7 are connected to the respective first leads. The operation of inserting between the pair of elastic pieces 30 of the first contact 15 of the first electrical connector 11 and the operation of collectively attaching the cover 84 as a driving member to the plurality of first electrical connectors 11 are parallel to each other. It becomes possible to carry out from the same direction.

  In addition, since the driving member for driving the cover housing 19 as the operation member is also used by the light shielding cover 84 which is an essential configuration, the structure can be simplified. In addition, since the work of attaching the light shielding cover 84, which is an essential configuration, can be performed simultaneously with the work of holding the outer lead 13 of the cold cathode tube 7 by the pair of elastic pieces 30, the assembly process can be simplified. it can.

Next, another embodiment of the present invention will be described with reference to FIGS. Referring to FIG. 29, the present embodiment is mainly different from the embodiment of FIG. 25 in that the second pressurizing unit is configured by a part of the metal member.
Specifically, referring to FIG. 30, a pressurizing portion forming member 91 formed of a metal member, for example, a sheet metal, is fitted and fixed to the recess 90 formed in each third rib 71A. The pressurizing part forming member 91 includes a main part 92 that extends along the bottom of the concave part 90, a first side wall 93 that rises orthogonally from one end of the main part 92 and that corresponds to the corresponding inner wall of the concave part 90, and the other end of the main part 92. A second side wall 94 extending vertically from the corresponding inner wall of the recess 90, a third side wall 95 as a second pressurizing portion provided in parallel with the second side wall 94, and a second side wall 94 and a connecting portion 96 that connects the opposing end portions of the third side wall 95.

A groove shape is formed by the second side wall 94, the connecting portion 96, and the third side wall 95, and the third side wall 95 as the second pressurizing portion extends along a part of the top portion of the third rib 71A. ing.
On the other hand, as shown in FIG. 31 (a), the first inclined portion 34 of the second piece 33 of each elastic piece 30 of the first contact 15A has a protrusion 97 made of a rib protruding outward. Is formed. The protrusion 97 extends longitudinally along the direction in which the first inclined portion 34 extends.

According to the present embodiment, similarly to the embodiment of FIG. 28, the pair of first pressurizing portions 77 and the third side walls 95 as the pair of second pressurizing portions, that is, a plurality of pairs. Since the pressure is applied by the pressure members 77 and 95, a more reliable connection between the outer lead 13 and the first contact 15A can be achieved.
In addition, since the third side wall 95 as the second pressurizing part is constituted by a part of the metal member, the second side can be used for a long time in an environment where heat transfer from the cold cathode tube 7 is received. The third side wall 95 as the pressurizing portion does not sag due to thermal deterioration (plastic deformation) or the like. As a result, a sufficient contact pressure can be maintained between the first contact 15A and the outer lead 13 over a long period of time.

  Further, as shown in FIG. 31A, a protrusion 97 is provided on the first inclined portion 34 of each elastic piece 30 of the first contact 15A, and the cover housing 19 is displaced to the second position. Then, as shown in FIG. 31 (b), the protrusion 97 is pressed by the third side wall 95 as the second pressing portion. Thus, both the protrusion 97 of the first contact 15A and the third side wall 95 of the pressurizing portion forming member 91 made of a metal member are in metal contact, but both are in contact with the protrusion 97, and the contact area thereof. Is narrowed. That is, the heat transfer area by heat conduction is narrowed.

Therefore, heat conduction from the cold cathode tube 7 to the cover housing 19 can be suppressed. Deterioration of the cover housing 19 can be prevented.
32 and 33 show still another embodiment of the present invention. Referring to FIGS. 32 and 33, the present embodiment is mainly different from the embodiments of FIGS. 4 to 6 in the following. 4 to 6, the second housing 16 of the second electrical connector 12 has a peripheral wall 42, whereas in the present embodiment, the second electrical connector 12A is provided. It is in the point which abolished the surrounding wall.

  In the embodiment shown in FIGS. 4 to 6, the first contact 15 of the first electrical connector 11 is provided with the first and second fixing pieces 37 and 38, and the second electrical connector 12 The pair of elastic pieces 46 that can contact the first and second fixed pieces 37 and 38 are provided on the two contacts 17. In contrast, in the present embodiment, as shown in FIG. 33, a pair of elastic pieces 98 is provided on the first contact 15B of the first electrical connector 11A, and the pair of elastic contacts 98 is provided on the second contact 17A. A pair of fixed piece portions 99 that can contact the elastic piece portions 98 are provided.

A corresponding elastic piece 98 is extended from the lower end of each of the first fixed piece 37 and the second fixed piece 38 of the first contact 15B. Each elastic piece 98 has a mountain-shaped portion 100 protruding inward, and a contact portion 101 is formed on the top of the mountain-shaped portion 100.
On the other hand, the second electrical connector 12A has a second insertion convex portion 41A, and a pair of contact holding grooves 44A that open in opposite directions are formed in the second insertion convex portion 41A. . The pair of fixed piece portions 99 are held in the corresponding contact holding grooves 44A.

A pair of side walls 102 are connected to the lower portion of the insertion convex portion 41A of the second electrical connector 12A. The pair of side walls 102 are disposed to face each other in a direction orthogonal to the direction in which the pair of contact holding grooves 44A face each other.
According to the present embodiment, since the second housing 16A of the second electrical connector 12A has eliminated the peripheral wall, the structure can be simplified. Further, the area occupied by the second electrical connector 12A on the inverter circuit board 9 can be reduced.

The present invention is not limited to the above-described embodiments. For example, an external electrode fluorescent tube 103 (EEFL) as shown in FIG. 34 is used as the fluorescent tube in place of the cold cathode tube 7 described above. It may be. The external electrode fluorescent tube 103 includes an electrode layer 104 as a terminal covered on the peripheral surface of the end portion 103 a of the external electrode fluorescent tube 103.
Further, the operation member may not be used as the cover housing 19.

In the embodiment of FIG. 31, the protrusion 97 is provided on each elastic piece 30 of the first contact 15A. However, instead of or in addition to this, as shown in FIG. The protrusion 105 may be provided on the third side wall 95A serving as the second pressurizing portion of the pressurizing portion forming member 91A.
In each of the above embodiments, a circuit board may be used as the support plate. Further, the first pressurizing unit 77 and the second pressurizing unit 78 may be pressurized simultaneously with the operation of the operation member such as the cover housing 19.

  In addition, various modifications can be made within the scope of the claims of the present invention.

1 is a schematic cross-sectional view showing a schematic configuration of a liquid crystal display device to which a backlight device including an electrical connector according to an embodiment of the present invention is applied. It is a disassembled perspective view of the principal part of a backlight apparatus. It is a schematic exploded view of a backlight device. It is a disassembled perspective view of the principal part of a backlight apparatus. It is a disassembled sectional view of the principal part of a backlight apparatus. It is sectional drawing of the principal part of a backlight apparatus. It is a disassembled perspective view of a 1st electrical connector and a support plate. It is a perspective view of the 1st contact of the 1st electric connector. (A) is a side view of the first contact, and (b) is a rear view of the first contact. It is a disassembled perspective view of a cold cathode tube and a 1st contact. It is a top view of a cold cathode tube and a 1st contact. It is a side view of the principal part of a cold cathode tube and a 1st contact. It is a disassembled perspective view of a 1st electrical connector and a support plate. It is a bottom view of the first electrical connector and the support plate. It is a front view of the 1st electric connector attached to the support plate and the support plate. It is a top view of the 1st electric connector. It is a side view of the 1st electric connector. It is a front view of the 1st electric connector. It is a partially broken disassembled side view of a 1st electric connector. (A), (b) and (c) are the schematic side views which show sequentially the process of attaching a cold cathode tube to the 1st electrical connector. (A), (b) and (c) are the schematic front views which show sequentially the process of attaching a cold cathode tube to the 1st electrical connector. (A) And (b) is a schematic plan view which shows the process of attaching a cold cathode tube to a 1st electrical connector in order. (A) And (b) is a schematic perspective view which shows sequentially the process of attaching a common cover to the some 1st electrical connector attached to the support plate. (A) And (b) is a partially broken schematic side view which shows sequentially the process of attaching a common cover to the some 1st electric connector attached to the support plate. It is a schematic plan view of the 3rd rib which has a cold cathode tube, a 1st contact, and the 1st and 2nd pressurization part. FIG. 6 is a cross-sectional view of a major view of the first housing of the first electrical connector including a locking structure for locking the cover housing in a second position in a closed state. It is sectional drawing of the latching protrusion for the lock structure of FIG. (A), (b) and (c) show the operation in which the first and second pressurizing portions of the third rib pressurize the pair of elastic pieces of the first contact to the outer leads of the cold cathode tubes. FIG. 3 is a schematic plan view of a main part of the first electrical connector. It is a bottom view of the principal part of the 1st electric connector of another embodiment of the present invention, and shows the change form of the 2nd pressurizing part. FIG. 30 is a schematic exploded perspective view of a pressing portion forming member and a third rib for forming the second pressing portion of FIG. 29. (A) is a perspective view of the 1st contact used for embodiment of FIG. 29, (b) is an expanded cross section of the contact part of the 1st contact and the 3rd side wall as a 2nd pressurizing part. FIG. It is a disassembled perspective view of the principal part of the backlight apparatus of another embodiment of this invention. It is sectional drawing of the principal part of the backlight apparatus of FIG. It is a schematic perspective view of the external electrode fluorescent tube as a modification of the fluorescent tube. It is a general | schematic disassembled perspective view of the pressurization part formation member and 3rd rib of another embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Liquid crystal display device 4 Liquid crystal display panel 5 Backlight apparatus 7 Cold cathode tube (fluorescent tube)
7a End 8 Support plate (first support plate)
8a Reflecting surface 8b Back surface 9 Inverter circuit board (circuit board, second support plate)
DESCRIPTION OF SYMBOLS 10 Electrical connector 11, 11A 1st electrical connector 12, 12A 2nd electrical connector 13 Outer lead (terminal)
14 1st housing 15, 15A, 15B 1st contact 16, 16A 2nd housing 17, 17A 2nd contact 18 Base housing 19 Cover housing (operation member)
DESCRIPTION OF SYMBOLS 20 Main body 21 Support hole 21a Curved surface part 21b Flat part 22 1st insertion convex part 23 Pull-out prevention hole 24 Pull-out prevention shaft 30 Elastic piece part 31 Folding part 32 First piece part 33 Second piece part 34 First inclined part 35 Second inclined part 36 Contact part 50 Curved part 51 Flat part 52 Locking member 55 Groove 56 Receiving part 61 Pressed part 62 Detachment engaging part 71 Third rib 72 Locking protrusion 73 First 1 inclined cam surface 74 2nd inclined cam surface 75 1st cam mechanism 76 2nd cam mechanism 77 1st pressurizing part 78 2nd pressurizing part 80 Lock part 84 Cover 88 Pressing plate 88a Press Part 89 Third cam mechanism 91, 91A Pressurizing part forming member 95A Third side wall (second pressurizing part)
97 Protrusions 103 External electrode fluorescent tube 104 Electrode layer 105 Protrusions D1 Diameter K1 The direction in which the elastic piece extends when viewed along the clamping direction M1 Crossing direction W1 Spacing X1 Axis length direction (terminal extending direction)
Y1 mounting direction Y2 direction opposite to the mounting direction Z1 clamping direction

Claims (10)

An insulating housing;
Contacts held by this housing;
An operation member for operating the contact,
The contact has a pair of elastic pieces that can insert the terminal at the end of the fluorescent tube between each other along the mounting direction corresponding to the radial direction of the terminal, and can sandwich the inserted terminal. Including
The electrical connector according to claim 1, wherein the operation member includes a plurality of pairs of pressurizing portions for pressurizing the pair of elastic pieces to the terminals.   2. The electrical connector according to claim 1, wherein the plurality of pairs of pressurizing portions include at least a pair of metal portions.   3. The electrical connector according to claim 2, wherein a protrusion contacting the other is formed on one of the elastic piece portion pressed by the metal portion and the metal portion. In any one of Claims 1 thru | or 3,
The operation member is supported by the housing so as to be displaceable in the first and second positions,
As the operating member is displaced from the first position to the second position, the plurality of pairs of pressurizing units pressurize with increasing applied pressure for each pair. .   5. The electrical connector according to claim 4, wherein when the operation member is displaced to the first position, the terminal can be inserted between the pair of elastic pieces with no insertion force along the attachment direction. . The housing according to any one of claims 1 to 5, wherein the housing includes a base housing, and the operation member includes a cover housing that covers at least a part of the housing.
The electrical connector, wherein the plurality of pairs of pressurizing portions are provided on a rib formed on the cover housing.   The direction in which the elastic piece portion extends in any one of claims 1 to 6 when the pair of elastic piece portions is viewed along a holding direction in which the pair of elastic piece portions hold the terminal. An electrical connector characterized by being parallel to a direction in which the wire extends.   8. The electrical connector according to claim 1, wherein the fluorescent tube includes a cold cathode tube, and the terminal includes an outer lead exposed from an end portion of the cold cathode tube.   The electric tube according to any one of claims 1 to 7, wherein the fluorescent tube includes an external electrode fluorescent tube, and the terminal includes an electrode layer coated on a peripheral surface of an end portion of the external electrode fluorescent tube. connector.   A backlight device comprising: the electrical connector according to claim 1, wherein a plurality of the electrical connectors are mounted side by side on a support plate; and a fluorescent tube supported by each electrical connector.

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