JP5615118B2 - Board to board connector - Google Patents

Description

  The present invention relates to a board-to-board connector.

  As this type of technology, Patent Document 1 discloses a three-piece connector 102 for electrically connecting one substrate 100 and the other substrate 101 as shown in FIGS. 18 and 19 of the present application. The three-piece connector 102 includes three connectors: a connector 103 mounted on one substrate 100, a connector 104 mounted on the other substrate 101, and a connector 103 and a connection connector 105 connected to the connector 104. ing. As shown in FIG. 19 of the present application, the connection connector 105 includes a housing 106 and a housing 107, and a plurality of contacts 108 held by the housing 106 and the housing 107. That is, the housing 106 and the housing 107 are connected through a plurality of contacts 108. A gap 109 is formed between the housing 106 and the housing 107.

  As shown in FIG. 19 of the present application, the plurality of contacts 108 includes a contact portion 108 a that contacts the contact 103 a of the connector 103 and a contact portion 108 b that contacts the contact 104 a of the connector 104. The contact portion 108a and the contact portion 108b are located in the vicinity of the one end portion 108c and the other end portion 108d, respectively. The one end portion 108c and the other end portion 108d are bent upward with respect to the contact portion 108a and the contact portion 108b and are held by the wall portion 106a and the dust-proof wall 107a.

  With the above configuration, even when the connector 103 and the connector 104 connected to the connection connector 105 are misaligned, if the housing 106 and the housing 107 are swung, the misalignment can be absorbed. Yes.

JP 2008-71698 A

  By the way, inferring from the configuration in which the one end portion 108c and the other end portion 108d are bent upward with respect to the contact portion 108a and the contact portion 108b, the contact 108 in FIG. It is reasonable to think that the contact portion 108a and the contact portion 108b are parallel to the one substrate 100 and the other substrate 101 in a state where the connecting connector 105 is attached to the connector 103 and the connector 104. is there. If this is the case, in FIG. 18 of the present application, the three-piece connector 102 cannot absorb the positional deviation between the connector 103 and the connector 104 in the direction indicated by “X” in the drawing. This is because the plate width is effective to the cube of the deformation of the contact 108 in the direction indicated by “X” in the drawing.

  An object of the present invention is to provide a board-to-board connector that is more flexible in view of the above-mentioned problems inherent in Patent Document 1.

According to an aspect of the present invention, a board-to-board connector includes a plurality of first contacts and a first housing that holds the plurality of first contacts, and is mounted on the first board. A second connector part mounted on a second substrate, and a plurality of the first connector parts, the second connector part having a portion, a plurality of second contacts, and a second housing holding the plurality of second contacts. A third connector portion having a plurality of third contacts for connecting the first contacts and the plurality of second contacts of the second connector portion, respectively, and a third housing for holding the plurality of third contacts; . The board-to-board connector absorbs a positional shift between the first connector part and the second connector part in a first direction as a direction in which the first connector part and the second connector part are arranged. Absorbs misalignment between the first connector portion and the second connector portion in a second direction as a direction in which the first misalignment absorbing means and the plurality of third contacts of the third connector portion are arranged. And a second misalignment absorbing means. The first connector portion functions as one of the first misalignment absorbing means or the second misalignment absorbing means, and the third connector portion is the first misalignment absorbing means or the second misalignment absorbing means. It functions as the other side.

Preferably, the first connector portion functions as the first misalignment absorbing means,
The third connector portion functions as the second misalignment absorbing means.

  Preferably, the third housing of the third connector portion includes a first connector portion side housing disposed on the first connector portion side, and a second connector portion side housing disposed on the second connector portion side. Have. Each third contact of the third connector part includes a third contact first fixing part fixed to the first connector part side housing and a third contact second fixing part fixed to the second connector part side housing. And a third contact connecting portion that connects the third contact first fixing portion and the third contact second fixing portion. The third contact connecting portion of each third contact of the third connector portion is plate-shaped. The plate thickness direction of the third contact connecting portion of each third contact of the third connector portion is substantially parallel to the second direction.

  Preferably, the third housing of the third connector portion includes a limiting mechanism that limits a relative displacement of the first connector portion side housing and the second connector portion side housing in the second direction within a predetermined range. I have.

  Preferably, each first contact of the first connector portion includes a first contact first fixing portion fixed to the first substrate and a first contact connection connected to each third contact of the third connector portion. And a first contact bellows portion interposed between the first contact first fixing portion and the first contact connection portion and folded in a bellows shape in the first direction.

  Preferably, the first housing of the first connector portion includes a first housing fixing portion fixed to the first substrate, and a first housing relatively displaceable in the first direction with respect to the first housing fixing portion. And a housing displacement portion. Each first contact of the first connector portion has a first contact second fixing portion fixed to the first housing displacement portion. The first contact second fixing portion is disposed between the first contact connecting portion and the first contact bellows portion.

  Preferably, the first housing of the first connector portion is formed with a bellows portion accommodating chamber for accommodating the first contact bellows portion of each first contact of the first connector portion.

  Preferably, the bellows portion accommodating chamber is formed in the first housing displacement portion of the first housing of the first connector portion.

  Preferably, the first connector portion further includes an auxiliary metal fitting for fixing the first housing fixing portion of the first housing of the first connector portion to the first substrate. The auxiliary metal fitting has a displacement restricting portion that prevents the first housing displacement portion of the first housing of the first connector portion from being displaced in a direction away from the first substrate.

  Preferably, the first housing of the first connector portion is formed with a first housing partition wall that separates the first contact bellows portions of the first contacts of the first connector portion.

  Preferably, each first housing partition wall portion is formed such that the first contact bellows portion of each first contact of the first connector portion is not exposed to the outside from the first housing of the first connector portion. .

  Preferably, a rigid connection that prohibits relative displacement between the first contacts of the first connector portion and the third contacts of the third connector portion is employed.

  Preferably, when connecting the first contacts of the first connector portion and the third contacts of the third connector portion, the third contacts of the third connector portion are connected to the first connector portion. A positioning mechanism for positioning with respect to each first contact is further provided.

  Preferably, a first substrate mounting surface as a surface of the first connector portion that contacts the first substrate, and a second substrate mounting as a surface of the second connector portion that contacts the second substrate. The surface exists in substantially the same plane in a state where the first connector portion and the second connector portion are connected by the third connector portion.

  According to the present invention, it is possible to simultaneously absorb the positional deviation in the first direction and the positional deviation in the second direction between the first connector part and the second connector part. A working board-to-board connector is realized.

FIG. 1 is a perspective view of a board-to-board connector before connection. (First embodiment) FIG. 2 is a perspective view of the base connector portion. (First embodiment) FIG. 3 is a partially enlarged view of FIG. (First embodiment) FIG. 4 is a perspective view of the base housing of the base connector portion. (First embodiment) FIG. 5A is a perspective view of the hold-down of the base connector portion, and FIG. 5B is a perspective view of the hold-down of the base connector portion viewed from another angle. (First embodiment) FIG. 6 is a partially cutaway perspective view of FIG. 3 and omits the foremost base contact. (First embodiment) FIG. 7 is a perspective view of the base contact. (First embodiment) 8 is a partially cutaway perspective view of FIG. (First embodiment) 9 is a cross-sectional view taken along line IX-IX in FIG. (First embodiment) FIG. 10 is a perspective view of the connecting connector portion as viewed from the front side. (First embodiment) FIG. 11 is a perspective view of the connecting connector portion viewed from the back side. (First embodiment) FIG. 12 is a partially enlarged view of FIG. 11, and some connecting contacts are omitted. (First embodiment) FIG. 13 is a perspective view of the connecting contact. (First embodiment) 14A is a view similar to FIG. 9 and shows a state before the bellows portion is deformed, and FIG. 14B is a view similar to FIG. 9 and after the bellows portion is deformed. Indicates the state. (First embodiment) FIG. 15A is a bottom view of the connection connector portion and shows a state before the connection contact is deformed, and FIG. 15B is a bottom view of the connection connector portion after the connection contact is deformed. Indicates the state. (First embodiment) FIG. 16 is a plan view of the connecting connector portion. (Second Embodiment) FIG. 17 is a perspective view of the base contact. (Third embodiment) FIG. 18 is a diagram corresponding to FIG. FIG. 19 is a diagram corresponding to FIG.

(First embodiment)
Hereinafter, the first embodiment of the present invention will be described with reference to FIGS.

  As shown in FIG. 1, for example, a plurality of backlight substrates 1 are arranged without overlapping each other in a housing of a liquid crystal display. The plurality of backlight substrates 1 are arranged so that the element mounting surface 2 (connector mounting surface) which is the surface on the display front side of each backlight substrate 1 is substantially in the same plane. A number of light emitting elements 3 are attached to the element mounting surface 2 of each backlight substrate 1. The board-to-board connector 4 of this embodiment is used to electrically connect the adjacent backlight boards 1 to each other.

  Here, for convenience of explanation, one of the two backlight substrates 1 shown in FIG. 1 is denoted by “A” and referred to as a backlight substrate 1A (first substrate). Similarly, the element mounting surface 2 of the backlight substrate 1A is referred to as an element mounting surface 2A. The other of the two backlight substrates 1 shown in FIG. 1 is denoted by “B” and is referred to as a backlight substrate 1B (second substrate). Similarly, the element mounting surface 2 of the backlight substrate 1B is referred to as an element mounting surface 2B.

  As shown in FIG. 1, the board-to-board connector 4 includes a base connector portion 5A (first connector portion), a base connector portion 5B (second connector portion), and a connecting connector portion 6 (third connector portion). Are provided as the main components. The base connector portion 5A is mounted on the element mounting surface 2A of the backlight substrate 1A. The base connector portion 5B is mounted on the element mounting surface 2B of the backlight substrate 1B. The connecting connector portion 6 is used to connect the base connector portion 5A and the base connector portion 5B to each other. FIG. 1 shows a state immediately before the base connector portion 5A and the base connector portion 5B are connected using the connecting connector portion 6.

  In the present embodiment, the base connector portion 5A and the base connector portion 5B are completely the same. That is, the description of the configuration and operation of the base connector portion 5A can be applied to the base connector portion 5B as it is. Therefore, in order to avoid redundant description, the configuration and operation of the base connector portion 5A will be mainly described below, and the base connector portion 5B will be described only when necessary.

  As shown in FIGS. 1 and 2, the base connector portion 5 </ b> A mainly includes a plurality of base contacts 7 (first contacts) and a base housing 8 (first housing) that holds the plurality of base contacts 7. I have. Similarly, the connection connector portion 6 includes a plurality of connection contacts 9 (third contacts) and a connection housing 10 (third housing) that holds the plurality of connection contacts 9 as main components.

  Here, for convenience of explanation, in FIG. 1, “connector parallel direction (first direction)”, “substrate orthogonal direction”, and “contact parallel direction (second direction)” are defined. The “connector parallel direction” is a direction in which the adjacent base connector portion 5A and the base connector portion 5B are arranged. Of the “connector parallel directions”, the direction facing the adjacent base connector portion 5B when viewed from the base connector portion 5A is referred to as the “connector facing direction”, and the direction facing the opposite side of the adjacent base connector portion 5B is defined as “connector opposite direction”. It is called “direction”. The “substrate orthogonal direction” is a direction orthogonal to the element mounting surface 2A of the backlight substrate 1A. Of the “substrate orthogonal directions”, the direction away from the element mounting surface 2A of the backlight substrate 1A is referred to as “substrate separation direction”, and the direction approaching the element mounting surface 2A of the backlight substrate 1A is referred to as “substrate proximity direction”. The “contact parallel direction” is a direction in which the connection contacts 9 of the connection connector portion 6 are arranged. In other words, the “contact parallel direction” is a direction in which the base contacts 7 of the base connector portion 5A are arranged. Of the “contact parallel direction”, a direction approaching the center of the base connector portion 5A is referred to as a “center proximity direction”, and a direction away from the center of the base connector portion 5A is referred to as a “center separation direction”. Each direction defined above is applied as it is to the individual components shown in FIG.

  As shown in FIG. 1, the board-to-board connector 4 includes a connector parallel direction displacement absorbing mechanism P (first position deviation absorbing means) and a contact parallel direction position absorbing mechanism Q (second position deviation absorbing means). Is further provided. The connector parallel direction misalignment absorbing mechanism P is a mechanism that absorbs misalignment between the base connector portion 5A and the base connector portion 5B in the connector parallel direction. In the present embodiment, the base connector portion 5A functions as a connector parallel direction misalignment absorbing mechanism P. On the other hand, the contact misalignment absorbing mechanism Q in the contact parallel direction is a mechanism that absorbs misalignment between the base connector portion 5A and the base connector portion 5B in the contact parallel direction. In the present embodiment, the connecting connector portion 6 functions as a contact parallel direction misalignment absorbing mechanism Q.

(Base connector part 5A)
Next, the configuration of the base connector portion 5A will be described with reference to FIGS.

(Base connector part 5A: Overview)
As shown in FIG. 2, the base connector portion 5 </ b> A includes a plurality of base contacts 7, a base housing 8 that holds the plurality of base contacts 7, and a pair of hold-downs 11 (auxiliary metal fittings).

(Base connector part 5A: Base housing 8)
As shown in FIGS. 3 and 4, the base housing 8 has a housing fixing portion 12 (first housing fixing portion) and a housing displacement portion 13 (first housing displacement portion). The housing fixing portion 12 is fixed to the element mounting surface 2A (see FIG. 1) of the backlight substrate 1A. The housing displacement portion 13 can be displaced relative to the housing fixing portion 12 in the connector parallel direction. Specifically, the housing displacement portion 13 can be relatively displaced with respect to the housing fixing portion 12 only in the connector parallel direction.

(Base connector part 5A: Hold down 11)
As shown in FIG. 4, a hold-down mounting groove 14 is formed at the end of the housing fixing portion 12 in the center separation direction. As shown in FIGS. 5A and 5B, the hold-down 11 includes a pressed-in part 11a, a soldering part 11b, and a retaining part 11c (displacement restricting part). The holddown 11 is integrally formed by sheet metal bending. The press-fit portion 11 a is a portion that is press-fit into the hold-down mounting groove 14 (see FIG. 4) of the housing fixing portion 12. The soldering portion 11b is a portion to be soldered to a land (not shown) formed on the element mounting surface 2A (see FIG. 1) of the backlight substrate 1A. The soldering portion 11b extends in a direction orthogonal to the press-fit portion 11a. The retaining portion 11c displaces the housing displacement portion 13 in the direction away from the backlight substrate 1A while allowing the housing displacement portion 13 to be displaced relative to the housing fixing portion 12 in the connector parallel direction. Reference numeral 13 denotes a part for preventing the housing fixing part 12 from coming off in the board separation direction. The retaining portion 11c extends in a direction orthogonal to the press-fit portion 11a. The soldering part 11b and the retaining part 11c extend in opposite directions with respect to the press-fit part 11a.

  5A or the like is attached to the housing fixing portion 12 of the base housing 8 shown in FIG. 4, and the soldering portion 11b of the holddown 11 shown in FIG. By soldering to the element mounting surface 2A of the substrate 1A, the housing fixing portion 12 of the base housing 8 of the base connector portion 5A is fixed to the element mounting surface 2A of the backlight substrate 1A. That is, the hold-down 11 has a function of fixing the housing fixing portion 12 of the base housing 8 of the base connector portion 5A to the backlight substrate 1A.

(Base connector part 5A: Base housing 8)
As shown in FIGS. 3, 4, and 6, the housing fixing portion 12 of the base housing 8 is formed in a box shape having a substantially U-shaped cross section that opens in the board separation direction. The housing displacement portion 13 of the base housing 8 is accommodated in the housing fixing portion 12.

(Base connector part 5A: Base housing 8: Housing fixing part 12)
The housing fixing part 12 of the base housing 8 includes a bottom wall part 12a, a first long side wall part 12b, a second long side wall part 12c, and a short side wall part 12d shown in FIG.

  The bottom wall portion 12a shown in FIG. 6 is a portion that is parallel to the backlight substrate 1A (see FIG. 1) and faces the backlight substrate 1A.

  The first long side wall portion 12b and the second long side wall portion 12c shown in FIGS. 4 and 6 are formed at positions sandwiching the housing displacement portion 13 in the connector parallel direction. The first long side wall portion 12 b is located on the side opposite to the connector as viewed from the housing displacement portion 13. The second long side wall portion 12 c is located on the connector facing direction side when viewed from the housing displacement portion 13.

  As shown in FIG. 4, the pair of short side wall portions 12 d is formed at a position sandwiching the housing displacement portion 13 in the contact parallel direction. As shown in FIG. 4, the above-described hold-down mounting groove 14 is formed in the short side wall portion 12 d of the housing fixing portion 12 of the base housing 8.

  As shown in FIG. 6, a plurality of fixed side contact slits 12h are formed in the first long side wall portion 12b at a predetermined pitch in the contact parallel direction. The fixed-side contact slit 12h includes a first contact press-fitting groove 12e, a first contact insertion groove 12f, and a second contact insertion groove 12g. The first contact press-fitting groove 12e is formed so as to penetrate the first long side wall portion 12b in the direction orthogonal to the substrate. The base contact 7 is fixed to the first long side wall portion 12b by being partially press-fitted into the first contact press-fitting groove 12e. The first contact insertion groove 12f is a groove formed in a portion of the first long side wall 12b on the side opposite to the connector, and opens in the direction opposite to the connector. The second contact insertion groove 12g is a groove formed in a portion on the substrate separation direction side of the first long side wall portion 12b and opens in the substrate separation direction. Part of the base contact 7 is inserted into the first contact insertion groove 12f and the second contact insertion groove 12g.

(Base connector portion 5A: Base housing 8: Housing displacement portion 13)
As shown in FIGS. 4 and 6, the housing displacement portion 13 of the base housing 8 is formed in a substantially rectangular parallelepiped shape. The housing displacement portion 13 is formed with a connecting groove 15, a displacement portion side contact slit 16 and a positioning hole 17.

  The connection groove 15 is a groove into which a part of the connection housing 10 (see FIG. 1) of the connection connector portion 6 is inserted. The connecting groove 15 is formed in a portion of the housing displacement portion 13 on the connector facing direction side. The connecting groove 15 extends along the contact parallel direction.

  As shown in FIG. 6, the displacement portion side contact slit 16 is partitioned into a first contact accommodating chamber 16a, a second contact accommodating chamber 16b (bellows portion accommodating chamber), and a second contact press-fitting groove 16c. .

  The first contact storage chamber 16 a is a space for storing a part of the base contact 7. The first contact accommodating chamber 16 a is formed in a portion of the housing displacement portion 13 of the base housing 8 on the connector facing direction side. The first contact storage chamber 16a is open in the substrate separation direction. The first contact accommodating chamber 16a is connected to the connecting groove 15 as shown in a sectional view shown in FIG. The first contact accommodating chamber 16a and the connecting groove 15 are formed so as to partially overlap each other. The first contact accommodating chamber 16a and the connecting groove 15 are formed so as to partially intersect. The first contact accommodating chamber 16a and the connecting groove 15 share a partial space.

  The second contact storage chamber 16 b is a space for storing a part of the base contact 7. The second contact housing chamber 16 b is formed in a portion of the housing displacement portion 13 of the base housing 8 on the side opposite to the connector. The second contact storage chamber 16b opens in the substrate separation direction.

  The second contact press-fit groove 16c is formed between the first contact accommodation chamber 16a and the second contact accommodation chamber 16b in the connector parallel direction. That is, the second contact press-fit groove 16c is formed on the opposite side of the first contact press-fit groove 12e of the first long side wall 12b of the housing fixing portion 12 of the base housing 8 and the second contact accommodating chamber 16b. Yes. The second contact press-fitting groove 16c is formed so as to penetrate the housing displacement portion 13 of the base housing 8 in the direction orthogonal to the substrate. A part of the base contact 7 is fixed to the housing displacement portion 13 by being press-fitted into the second contact press-fitting groove 16 c.

  As shown in FIG. 4, the positioning hole 17 is formed in the end portion 13 a of the housing displacement portion 13 in the center separation direction. The positioning hole 17 is formed to open in the substrate separation direction. A chamfer 17 a is formed at the opening edge of the positioning hole 17.

(Base connector part 5A: Base contact 7)
As shown in FIG. 7, the base contact 7 includes a connecting connector gripping portion 7a (first contact connecting portion), an elastic support portion 7b, a housing displacement portion fixed portion 7c (first contact second fixing portion), and a bellows portion 7d. (First contact bellows part), housing fixing part fixed part 7e, and backlight substrate fixed part 7f (first contact first fixing part) are provided as main components. The base contact 7 is integrally formed by punching a sheet metal in this embodiment. The connecting connector gripping portion 7a, the elastic support portion 7b, the housing displacement portion fixed portion 7c, the bellows portion 7d, the housing fixing portion fixed portion 7e, and the backlight substrate fixed portion 7f are connected in series along the connector parallel direction. ing.

  The connection connector gripping portion 7 a is connected to the connection contact 9 of the connection connector portion 6. The connection connector gripping portion 7a is formed in a substantially U shape that opens in the board separation direction. A pair of opposing claw portions 7g are formed at the end of the connecting connector gripping portion 7a on the board separation direction side.

  The elastic support part 7b is a part that makes the housing displacement part fixed part 7c elastically support the connection connector gripping part 7a. The elastic support portion 7b is formed in a substantially U shape.

  The housing displacement portion fixed portion 7 c is fixed to the housing displacement portion 13 of the base housing 8. The housing displacement portion fixed portion 7c is formed to extend in the board proximity direction. The housing displacement portion fixed portion 7c is disposed between the connecting connector gripping portion 7a and the bellows portion 7d.

  The bellows portion 7d is interposed between the backlight substrate fixed portion 7f and the connecting connector gripping portion 7a, and is formed to be folded in a bellows shape in the connector parallel direction.

  The housing fixing part fixed part 7 e is fixed to the housing fixing part 12 of the base housing 8. The housing fixing part fixed part 7e is formed to extend in the board proximity direction.

  The backlight substrate fixed portion 7f is fixed to the element mounting surface 2A (see FIG. 1) of the backlight substrate 1A. The backlight substrate fixed portion 7f is soldered to the element mounting surface 2A of the backlight substrate 1A.

  Further, the elastic support portion 7b, the housing displacement portion fixed portion 7c, and the bellows portion 7d are connected by a first arm portion 7h extending in the connector parallel direction. The bellows part 7d and the housing fixing part fixed part 7e are connected by a second arm part 7i extending in the connector parallel direction. The housing fixing portion fixing portion 7e and the backlight substrate fixing portion 7f are connected by a third arm portion 7j extending in the direction orthogonal to the substrate.

  The base contact 7 in FIG. 7 is attached to the base housing 8 in FIG. 6 as shown in FIGS.

  That is, the connecting connector gripping portion 7a and the elastic support portion 7b of the base contact 7 of FIG. 7 are placed in the board proximity direction in the first contact accommodating chamber 16a of the displacement portion side contact slit 16 of the housing displacement portion 13 of the base housing 8 of FIG. Is inserted into and accommodated. At this time, the pair of claws 7g of the connection connector gripping portion 7a of the base contact 7 in FIG. 7 sandwiches the connection groove 15 of the housing displacement portion 13 of the base housing 8 in FIG. 6 in the connector parallel direction.

  Similarly, the housing displacement portion fixed portion 7c of FIG. 7 is press-fitted into the second contact press-fitting groove 16c of the displacement portion side contact slit 16 of FIG.

  The bellows portion 7d of FIG. 7 is inserted and accommodated in the second contact accommodating chamber 16b of the displacement portion side contact slit 16 of FIG.

  7 is pressed into the first contact press-fitting groove 12e of the housing fixing portion 12 of the base housing 8 in FIG.

  As a result, as shown in FIGS. 8 and 9, the bellows portion 7 d of each base contact 7 is separated by the partition wall portion 13 b of the housing displacement portion 13 of the base housing 8. In the present embodiment, the partition wall portion 13b is formed so that the bellows portion 7d is not exposed to the outside from the base housing 8, as shown in FIGS. In other words, the housing displacement portion 13 of the base housing 8 is formed sufficiently thick in the direction orthogonal to the substrate so that the bellows portion 7d is not exposed in the substrate separation direction from the housing displacement portion 13 of the base housing 8 no matter how the bellows portion 7d is deformed. Has been. That is, the partition wall portion 13b of the housing displacement portion 13 of the base housing 8 is formed sufficiently high in the direction perpendicular to the substrate.

  As shown in FIG. 9, the substrate mounting surface 50 as the surface of the base connector portion 5A that contacts the element mounting surface 2A (see FIG. 1) of the backlight substrate 1A is the hold-down 11 of the base connector portion 5A. This corresponds to the lower surface of the soldering portion 11b and the lower surface of the backlight substrate fixed portion 7f of the base contact 7 of the base connector portion 5A. In this embodiment, the board mounting surface 50 of the base connector portion 5A and the board mounting surface 50 of the base connector portion 5B are in a state where the base connector portion 5A and the base connector portion 5B are connected by the connecting connector portion 6. It is adjusted to exist in substantially the same plane.

(Connecting connector part 6)
Next, the structure of the connection connector part 6 is demonstrated, referring FIGS. 10-13.

(Connecting connector part 6: Overview)
As shown in FIGS. 10 and 11, the connection connector portion 6 includes a plurality of connection contacts 9 and a connection housing 10 that holds the plurality of connection contacts 9.

(Connecting connector part 6: Connecting housing 10)
As shown in FIGS. 10 and 11, the connection housing 10 includes a top plate 19 and a peripheral wall portion 20. The top plate 19 is parallel to the element mounting surface 2A (see FIG. 1) of the backlight substrate 1A. The peripheral wall portion 20 is formed so as to slightly protrude from the peripheral edge of the top plate 19 in the substrate proximity direction. The connection housing 10 is divided in the connector parallel direction so as to correspond to the gap between the base connector portion 5A and the base connector portion 5B as shown in FIG. That is, the connection housing 10 is constituted by a first connection housing part 10A (first connector part side housing) and a second connection housing part 10B (second connector part side housing) which are adjacent in the connector parallel direction.

(Connecting connector part 6: Connecting housing 10: First connecting housing part 10A)
As shown in FIG. 1, the first connecting housing portion 10A is a portion disposed on the base connector portion 5A side. As shown in FIG. 10, a notch 22 is formed at each of the end portions 21 in the contact parallel direction of the first connecting housing portion 10A, and opens toward the center connecting direction and the second connecting housing portion 10B. As shown in FIGS. 11 and 12, the first connecting housing portion rear surface 23 as the surface of the first connecting housing portion 10A on the backlight substrate 1A (see FIG. 1) side has a pair of positioning protrusions 24 and a contact portion. A support beam 25, a plurality of connecting portion deformation prohibiting grooves 26, and a connecting portion deformation allowing groove 27 are formed. The contact portion support beam 25, the plurality of connecting portion deformation prohibiting grooves 26, and the connecting portion deformation allowing groove 27 are formed in this order toward the connector facing direction.

  As shown in FIG. 11, each positioning protrusion 24 is formed in the vicinity of the end 21 of the first connecting housing portion 10A. Each positioning protrusion 24 is formed to protrude in the substrate proximity direction. A chamfer 24 a is formed at the tip of each positioning protrusion 24.

  As shown in FIG. 12, the contact portion support beam 25 is formed to extend in the contact parallel direction. The contact portion support beam 25 is formed with a plurality of slits 25a into which a part of the connection contact 9 is inserted.

  Each connecting portion deformation prohibiting groove 26 is formed to extend in the connector parallel direction. Each connecting portion deformation prohibiting groove 26 is formed continuously with each slit 25 a of the contact portion supporting beam 25. In other words, each slit 25 a of the contact portion support beam 25 is connected to the connecting portion deformation prohibiting groove 26. Each connecting portion deformation prohibiting groove 26 is formed so as to accommodate a part of each connecting contact 9 with almost no gap. A part of each connection contact 9 accommodated in each connection portion deformation prohibiting groove 26 is accommodated with almost no gap, so that bending deformation in the contact parallel direction is prohibited in each connection portion deformation prohibition groove 26. . In addition, a pair of press-fitting holes 26a shown in FIG.

  The connecting portion deformation allowance groove 27 is formed continuously with the plurality of connecting portion deformation prohibiting grooves 26. In other words, the plurality of connecting portion deformation prohibiting grooves 26 are connected to the connecting portion deformation allowing grooves 27. The connecting portion deformation allowing groove 27 is formed so as to accommodate a part of each connecting contact 9. A part of each connection contact 9 accommodated in the connection portion deformation allowance groove 27 is allowed to bend and deform in the contact parallel direction in the connection portion deformation allowance groove 27.

(Connecting connector part 6: Connecting housing 10: Second connecting housing part 10B)
As shown in FIG. 1, the second connecting housing portion 10B is a portion disposed on the base connector portion 5B side. As shown in FIG. 10, each of the end portions 28 in the contact parallel direction of the second connecting housing portion 10B is formed with a protruding portion 29 protruding toward the first connecting housing portion 10A. The protrusions 29 of the second connection housing part 10B are in a relationship of being accommodated in the notches 22 of the first connection housing part 10A. Each notch 22 of the first connection housing portion 10A and each protrusion 29 of the second connection housing portion 10B face each other in the contact parallel direction. The pair of protrusions 29 of the second connection housing portion 10B sandwich the top plate 19 of the first connection housing portion 10A in the contact parallel direction. Accordingly, the relative displacement in the contact parallel direction between the first connecting housing portion 10A and the second connecting housing portion 10B is limited within a predetermined range. That is, the connection housing 10 of the connection connector portion 6 includes a limiting mechanism R that limits the relative displacement of the first connection housing portion 10A and the second connection housing portion 10B in the contact parallel direction within a predetermined range. In the present embodiment, the limiting mechanism R is realized by the notches 22 of the first connecting housing portion 10A and the protrusions 29 of the second connecting housing portion 10B.

  Except for the above-described configuration, the second connecting housing portion 10B is configured symmetrically with the first connecting housing portion 10A. That is, the first connecting housing portion 10A and the second connecting housing portion 10B are line symmetric in the connector parallel direction. Therefore, in the configuration of the second connection housing part 10B, the description of the parts common to the first connection housing part 10A is omitted. Refer to FIG. 1 and FIGS. 10 to 12 if necessary.

(Connecting connector part 6: connecting contact 9)
As shown in FIG. 13, each connection contact 9 of the connection connector portion 6 is for connecting each base contact 7 of the base connector portion 5A and each base contact 7 of the base connector portion 5B. Each connection contact 9 of the connection connector portion 6 includes a first fixing portion 30A (third contact first fixing portion), a second fixing portion 30B (third contact second fixing portion), and a connecting portion 31 (third contact connecting portion). ), A first connection portion 32A, and a second connection portion 32B. Each connection contact 9 of the connection connector portion 6 is integrally formed. Specifically, the first fixing portion 30A, the second fixing portion 30B, and the connecting portion 31 are formed by sheet metal punching, and the first connecting portion 32A and the second connecting portion 32B are formed by sheet metal bending.

  The first fixing portion 30 </ b> A is fixed to the first connection housing portion 10 </ b> A of the connection housing 10 of the connection connector portion 6. The first fixing portion 30 </ b> A includes a pair of press-fit portions 33 and a connecting portion 34 that connects the pair of press-fit portions 33. The connecting portion 34 extends in the connector parallel direction. The pair of press-fit portions 33 are connected to the connecting portion 34 and are formed so as to protrude from the connecting portion 34 in the board separating direction.

  The second fixing portion 30 </ b> B is fixed to the second connection housing portion 10 </ b> B of the connection housing 10 of the connection connector portion 6. Similarly to the first fixing portion 30A, the second fixing portion 30B includes a pair of press-fit portions 33 and a connecting portion 34 that connects the pair of press-fit portions 33. The connecting portion 34 extends in the connector parallel direction. The pair of press-fit portions 33 are connected to the connecting portion 34 and are formed so as to protrude from the connecting portion 34 in the board separating direction.

  The connecting part 31 connects the first fixing part 30A and the second fixing part 30B. The connecting portion 31 extends in the connector parallel direction. The connecting portion 34 of the first fixing portion 30A, the connecting portion 31, and the connecting portion 34 of the second fixing portion 30B are formed in a straight line. As described above, the connecting portion 31 has a plate shape. The plate thickness direction T of the connecting portion 31 is substantially parallel to the contact parallel direction.

  The first connection portion 32A is a portion where the base connector portion 5A shown in FIG. 8 is connected to the connection connector gripping portion 7a of the base contact 7. As shown in FIG. 13, the first connecting portion 32A is connected to the connecting portion 34 of the first fixing portion 30A and is formed to protrude from the connecting portion 34 in the substrate proximity direction. A part of the first connecting portion 32A can be inserted into the slit 25a of the contact portion supporting beam 25 of the first connecting housing portion 10A shown in FIG.

  The second connecting portion 32B is a portion where the base connector portion 5B is connected to the connecting connector gripping portion 7a of the base contact 7 (see also FIG. 8). As shown in FIG. 13, the second connecting portion 32B is connected to the connecting portion 34 of the second fixing portion 30B and is formed to protrude from the connecting portion 34 in the substrate proximity direction. A part of the second connecting portion 32B can be inserted into the slit 25a of the contact portion supporting beam 25 of the second connecting housing portion 10B shown in FIG.

  13 is attached to the first connection housing part 10A and the second connection housing part 10B of the connection housing 10 shown in FIGS. 10 and 11, as shown in FIG.

  That is, each press-fit portion 33 of the first fixed portion 30A of the connection contact 9 shown in FIG. 13 is press-fitted into the press-fit hole 26a of the first connection housing portion 10A of FIG. Similarly, each press-fit portion 33 of the second fixed portion 30B of the connection contact 9 shown in FIG. 13 is press-fitted into the press-fit hole 26a of the second connection housing portion 10B of FIG.

  At the same time, each connecting portion 34 of the connecting contact 9 shown in FIG. 13 is connected to the connecting portion deformation prohibiting groove 26 of the first connecting housing portion 10A and the connecting portion deformation prohibiting groove 26 of the second connecting housing portion 10B shown in FIG. Each is inserted. Further, a part of the first connecting portion 32A of the connecting contact 9 shown in FIG. 13 is inserted into the slit 25a of the contact portion supporting beam 25 of the first connecting housing portion 10A shown in FIG. Similarly, a part of the second connection portion 32B of the connection contact 9 shown in FIG. 13 is inserted into the slit 25a of the contact portion support beam 25 of the second connection housing portion 10B shown in FIG.

  As a result, the first fixing portion 30A of the connection contact 9 shown in FIG. 13 is fixed to the first connection housing portion 10A shown in FIG. The connecting portion 34 of the first fixing portion 30A of the connecting contact 9 shown in FIG. 13 is accommodated in the connecting portion deformation prohibiting groove 26 of the first connecting housing portion 10A shown in FIG. Deformation is prohibited.

  Similarly, the second fixing portion 30B of the connection contact 9 shown in FIG. 13 is fixed to the second connection housing portion 10B shown in FIG. The connecting portion 34 of the second fixed portion 30B of the connecting contact 9 shown in FIG. 13 is accommodated in the connecting portion deformation prohibiting groove 26 of the second connecting housing portion 10B shown in FIG. Deformation is prohibited.

  On the other hand, the connecting portion 31 of the connecting contact 9 shown in FIG. 13 is inserted into the connecting portion deformation allowable groove 27 of the first connecting housing portion 10A and the connecting portion deformation allowable groove 27 of the second connecting housing portion 10B shown in FIG. Be contained. Since the connecting portion deformation allowing groove 27 is formed to extend in the contact parallel direction, the connecting portion 31 of the connecting contact 9 is allowed to bend and deform in the contact parallel direction.

(Attaching method of board-to-board connector 4)
Next, a method for attaching the board-to-board connector 4 will be described with reference to FIG.

  First, as shown in FIG. 1, the base connector portion 5A is attached to the backlight substrate 1A. Specifically, the backlight substrate fixed portion 7f of the base contact 7 shown in FIG. 3 is soldered to the land on the element mounting surface 2A (see FIG. 1) of the backlight substrate 1A. Similarly, the soldering part 11b of the hold down 11 shown in FIG. 3 is soldered to the land on the element mounting surface 2A (see FIG. 1) of the backlight substrate 1A.

  Similarly, as shown in FIG. 1, the base connector portion 5B is attached to the backlight substrate 1B.

  Next, the base connector portion 5A and the base connector portion 5B are connected by the connecting connector portion 6. Specifically, the chamfer 24a of each positioning protrusion 24 of the first connecting housing portion 10A of the connecting housing 10 of the connecting connector portion 6 shown in FIG. 11 is replaced with the housing displacement portion 13 of the base housing 8 of the base connector portion 5A shown in FIG. Each of the positioning holes 17 is brought into contact with the chamfer 17a. Similarly, the chamfer 24a of each positioning protrusion 24 of the second connecting housing portion 10B of the connecting housing 10 of the connecting connector portion 6 shown in FIG. 11 is replaced with each positioning hole of the housing displacement portion 13 of the base housing 8 of the base connector portion 5B. 17 are brought into contact with the chamfers 17a (see also FIG. 3).

  In this state, the connecting connector portion 6 is strongly pushed in the board proximity direction. Then, due to the interaction between the chamfer 24a of each positioning projection 24 and the chamfer 17a of each positioning hole 17, each positioning projection 24 and each positioning hole 17 try to line up on the same axis.

(Operation of connector misalignment absorbing mechanism P in the parallel direction of the connector)
At this time, it is assumed that there is a displacement in the connector parallel direction between the base connector portion 5A and the base connector portion 5B before the connection of the base connector portion 5A and the base connector portion 5B by the connecting connector portion 6. .

  On the other hand, as shown in FIG. 9, the housing displacement portion 13 of the base housing 8 of the base connector portion 5A (or the base connector portion 5B, the same shall apply hereinafter) is relatively displaced with respect to the housing fixing portion 12 in the connector parallel direction. It is configured to be possible. Therefore, the base connector portion 5A can absorb the positional shift in the connector parallel direction by the relative displacement of the housing displacement portion 13 of the base housing 8 of the base connector portion 5A with respect to the housing fixing portion 12. Therefore, even if there is a positional shift in the connector parallel direction, the positioning projections 24 and the chamfers 24a of the positioning projections 24 and the chamfers 17a of the positioning holes 17 interact with each other. The positioning holes 17 can be aligned on the same axis. Then, the contact support beam 25 of the first connection housing part 10A of the connection housing 10 of the connection connector part 6 shown in FIG. 12 is connected to the connection groove 15 of the housing displacement part 13 of the base housing 8 of the base connector part 5A shown in FIG. Will be inserted without problems. As a result, the first connection portions 32A of the connection contacts 9 of the connection connector portion 6 shown in FIG. 12 are connected to the connection connector gripping portions 7a of the base contacts 7 of the base connector portion 5A shown in FIG. The The connection form between the first connection portion 32A of each connection contact 9 of the connection connector portion 6 shown in FIG. 12 and the connection connector gripping portion 7a of each base contact 7 of the base connector portion 5A shown in FIG. A so-called rigid connection that prohibits relative displacement between the one connecting portion 32A and the connecting connector gripping portion 7a is employed.

  In this embodiment, the connector parallel direction displacement absorbing mechanism P is realized by including at least a connecting connector gripping portion 7a of the base contact 7, a bellows portion 7d, and a backlight substrate fixed portion 7f, as shown in FIG. Has been.

  In this embodiment, when connecting each base contact 7 of the base connector portion 5A and each connection contact 9 of the connection connector portion 6, each connection contact 9 of the connection connector portion 6 is connected to the base connector portion 5A. The positioning mechanism for positioning with respect to each base contact 7 includes the positioning protrusions 24 of the first connecting housing portion 10A of the connecting housing 10 of the connecting connector portion 6 shown in FIG. 11 and the base connector portion 5A shown in FIG. And at least a positioning hole 17 of the housing displacement portion 13 of the base housing 8.

  FIGS. 14A and 14B show how the connector parallel direction displacement absorbing mechanism P absorbs the position shift in the connector parallel direction between the base connector portion 5A and the base connector portion 5B. 14B, from the state of FIG. 14A, the housing displacement portion 13 of the base housing 8 is displaced relative to the housing fixing portion 12 in the direction opposite to the connector, and the bellows portion 7d is in the connector parallel direction. In FIG.

  By the way, suppose that after the connection of the base connector part 5A and the base connector part 5B by the connection connector part 6, a position shift in the connector parallel direction newly occurs between the base connector part 5A and the base connector part 5B. The main cause of this occurrence is the backlight substrate 1A and the backlight due to the heat generated by the light emitting elements 3 mounted on the element mounting surface 2A of the backlight substrate 1A and the element mounting surface 2B of the backlight substrate 1B shown in FIG. For example, the substrate 1B itself thermally expands in the connector parallel direction. On the other hand, in this embodiment, even if thermal expansion or thermal contraction occurs in the connector parallel direction of the backlight substrate 1A or the backlight substrate 1B itself, the base connector portion 5A has the above-described connector parallel direction displacement absorbing mechanism P. Therefore, the board-to-board connector 4 is not damaged.

(Operation of contact misalignment absorbing mechanism Q in the contact parallel direction)
Similarly, it is assumed that there is a displacement in the contact parallel direction between the base connector portion 5A and the base connector portion 5B before the connection of the base connector portion 5A and the base connector portion 5B by the connecting connector portion 6. .

  On the other hand, as shown in FIG. 12, the first connection housing part 10 </ b> A and the second connection housing part 10 </ b> B of the connection housing 10 of the connection connector part 6 are accompanied by bending deformation of the connection part 31 of each connection contact 9. It is configured to be capable of relative displacement in the contact parallel direction. Therefore, the connecting connector portion 6 can absorb the displacement in the contact parallel direction by the relative displacement of the first connecting housing portion 10A of the connecting housing 10 of the connecting connector portion 6 with respect to the second connecting housing portion 10B. . Therefore, even if there is a positional deviation in the contact parallel direction, the positioning projections 24 and the positioning chamfers 24a and chamfers 17a of the positioning holes 17 interact with each other. The positioning holes 17 can be aligned on the same axis. Then, the contact support beam 25 of the first connection housing part 10A of the connection housing 10 of the connection connector part 6 shown in FIG. 12 is connected to the connection groove 15 of the housing displacement part 13 of the base housing 8 of the base connector part 5A shown in FIG. Will be inserted without problems. As a result, the first connection portions 32A of the connection contacts 9 of the connection connector portion 6 shown in FIG. 12 are connected to the connection connector gripping portions 7a of the base contacts 7 of the base connector portion 5A shown in FIG. The

  In the present embodiment, the contact parallel direction misalignment absorbing mechanism Q includes, as shown in FIG. 13, a first connection portion 32A, a connection portion 31, and a second connection portion 32B of the connection contact 9 of the connection connector portion 6. It is realized with at least.

  FIGS. 15A and 15B show how the contact parallel direction misalignment absorbing mechanism Q absorbs the position shift in the contact parallel direction between the base connector portion 5A and the base connector portion 5B. 15B, from the state of FIG. 15A, the first connecting housing portion 10A of the connecting connector portion 6 is relatively displaced in the contact parallel direction with respect to the second connecting housing portion 10B, and the connecting portion 31 is also provided. Shows a state of bending and deforming in the contact parallel direction.

  By the way, suppose that after the connection of the base connector part 5A and the base connector part 5B by the connection connector part 6, a position shift in the contact parallel direction newly occurs between the base connector part 5A and the base connector part 5B. The main cause of this occurrence is the backlight substrate 1A and the backlight due to the heat generated by the light emitting elements 3 mounted on the element mounting surface 2A of the backlight substrate 1A and the element mounting surface 2B of the backlight substrate 1B shown in FIG. For example, the substrate 1B itself thermally expands in the contact parallel direction. On the other hand, in this embodiment, even if thermal expansion or thermal contraction occurs in the contact parallel direction of the backlight substrate 1A or the backlight substrate 1B itself, the connecting connector portion 6 is in the contact parallel direction misalignment absorbing mechanism Q described above. Therefore, the board-to-board connector 4 is not damaged.

  The first preferred embodiment of the present invention has been described above. In short, the first embodiment has the following features.

  The board-to-board connector 4 includes a base connector portion 5A (first connector portion), a base connector portion 5B (second connector portion), and a connecting connector portion 6 (third connector portion). The base connector portion 5A includes a plurality of base contacts 7 (first contacts) and a base housing 8 (first housing) that holds the plurality of base contacts 7, and is attached to the backlight substrate 1A (first substrate). Installed. The base connector portion 5B includes a plurality of base contacts 7 (second contacts) and a base housing 8 (second housing) that holds the plurality of base contacts 7 (second contacts). It is mounted on the second substrate). The connection connector portion 6 includes a plurality of connection contacts 9 (third contacts) for connecting the plurality of base contacts 7 of the base connector portion 5A and the plurality of base contacts 7 of the base connector portion 5B, and a plurality of connection contacts 9. A connection housing 10 (third housing). The board-to-board connector 4 further includes a connector parallel direction positional deviation absorbing mechanism P (first positional deviation absorbing means) and a contact parallel direction positional deviation absorbing mechanism Q (second positional deviation absorbing means). The connector parallel direction misalignment absorbing mechanism P is a position misalignment between the base connector portion 5A and the base connector portion 5B in the connector parallel direction (first direction) as a direction in which the base connector portion 5A and the base connector portion 5B are arranged. Absorbs. The contact parallel direction misalignment absorbing mechanism Q is a position between the base connector portion 5A and the base connector portion 5B in the contact parallel direction (second direction) as a direction in which the plurality of connection contacts 9 of the connection connector portion 6 are arranged. Absorb the deviation. According to the above configuration, it is possible to simultaneously absorb the position shift in the connector parallel direction and the position shift in the contact parallel direction between the base connector portion 5A and the base connector portion 5B. The board connector 4 is realized.

  In the first embodiment, the base connector portion 5A functions as the connector parallel direction misalignment absorbing mechanism P, and the connecting connector portion 6 functions as the contact parallel direction misalignment absorbing mechanism Q. In short, the role as the connector parallel direction misalignment absorbing mechanism P and the contact parallel direction misalignment absorbing mechanism Q is shared by the base connector portion 5A and the connecting connector portion 6. According to the above configuration, only the base connector portion 5A or the connecting connector portion 6 can be used without sharing the roles as the connector parallel direction displacement absorbing mechanism P and the contact parallel direction position absorbing mechanism Q. In comparison, a simple structure is realized.

  In the first embodiment, the base connector portion 5A functions as the connector parallel direction misalignment absorbing mechanism P, and the connecting connector portion 6 functions as the contact parallel direction misalignment absorbing mechanism Q. Instead, the base connector portion 5A may function as the contact parallel direction misalignment absorbing mechanism Q, and the connecting connector portion 6 may function as the connector parallel direction misalignment absorbing mechanism P.

  The connection housing 10 of the connection connector portion 6 includes a first connection housing portion 10A (first connector portion side housing) disposed on the base connector portion 5A side and a second connection housing disposed on the base connector portion 5B side. And a portion 10B (second connector portion side housing). Each connection contact 9 of the connection connector portion 6 has a first fixing portion 30A (third contact first fixing portion) fixed to the first connection housing portion 10A and a second fixing fixed to the second connection housing portion 10B. 30B (third contact second fixing portion) and a connecting portion 31 (third contact connecting portion) for connecting the first fixing portion 30A and the second fixing portion 30B. The connecting portion 31 of each connecting contact 9 of the connecting connector portion 6 has a plate shape. The plate thickness direction T of the connecting portion 31 of each connecting contact 9 of the connecting connector portion 6 is substantially parallel to the contact parallel direction. According to the above configuration, the first connection housing portion 10A and the second connection housing portion 10B of the connection housing 10 of the connection connector portion 6 can be smoothly relatively displaced in the contact parallel direction, so that the connection connector portion 6 is in contact parallel. The directional displacement absorbing mechanism Q functions without any problem.

  The connection housing 10 of the connection connector portion 6 includes a limiting mechanism R that limits the relative displacement of the first connection housing portion 10A and the second connection housing portion 10B in the contact parallel direction within a predetermined range. According to the above structure, it can prevent that each connection contact 9 of the connection connector part 6 deform | transforms excessively.

  Each base contact 7 of the base connector portion 5A is connected to a backlight substrate fixed portion 7f (first contact first fixing portion) fixed to the backlight substrate 1A and each connection contact 9 of the connection connector portion 6. Connected connector gripping portion 7a (first contact connecting portion), a bellows portion interposed between the backlight substrate fixed portion 7f and the connecting connector gripping portion 7a, and formed by being folded in a bellows shape in the connector parallel direction. 7d (first contact bellows portion). According to the above configuration, the connecting connector gripping portion 7a is displaceable within a range in which the connecting connector gripping portion 7a can be relatively displaced with respect to the backlight substrate fixed portion 7f of each base contact 7 of the base connector portion 5A. A large range can be secured. Therefore, according to the above configuration, a large displacement in the connector parallel direction between the base connector portion 5A and the base connector portion 5B can be absorbed, so that the base connector portion 5A can absorb the displacement in the connector parallel direction. Functions as P without problems.

  In addition, when the bellows part 7d is interposed between the connection connector gripping part 7a and the backlight substrate fixed part 7f as described above, simply considering the connection connector gripping part 7a as the bellows part 7d is deformed. It can be said that the posture is easy to change. When the posture of the connection connector gripping portion 7a is changed, the connection between the connection connector gripping portion 7a and the connection contact 9 of the connection connector portion 6 becomes unstable. On the other hand, the base housing 8 of the base connector portion 5A can be relatively displaced in the connector parallel direction with respect to the housing fixing portion 12 (first housing fixing portion) fixed to the backlight substrate 1A and the housing fixing portion 12. Housing displacement portion 13 (first housing displacement portion). Each base contact 7 of the base connector portion 5A has a housing displacement portion fixed portion 7c (first contact second fixing portion) fixed to the housing displacement portion 13. The housing displacement portion fixed portion 7c is disposed between the connecting connector gripping portion 7a and the bellows portion 7d. According to the above configuration, the posture of the connecting connector gripping portion 7a does not change depending on the deformation of the bellows portion 7d. Therefore, according to the above structure, the stable connection between the connection connector holding part 7a and the connection contact 9 is implement | achieved.

  Further, the base housing 8 of the base connector portion 5A is formed with a second contact housing chamber 16b (a bellows portion housing chamber) that houses the bellows portion 7d of each base contact 7 of the base connector portion 5A. According to the above structure, the deformation | transformation to the direction which the bellows part 7d does not intend can be suppressed.

  As shown in FIG. 9, the second contact housing chamber 16b is formed in the housing displacement portion 13 of the base housing 8 of the base connector portion 5A. As described above, since the second contact accommodating chamber 16b is formed not in the housing fixing portion 12 of the base housing 8 of the base connector portion 5A but in the housing displacement portion 13, first, the housing displacement portion fixed portion 7c is the base. The housing displacement portion 13 of the housing 8 is positioned substantially at the center in the connector parallel direction. Since the housing displacement portion fixed portion 7c is positioned at the approximate center of the housing displacement portion 13 of the base housing 8 in the connector parallel direction, the housing displacement portion 13 of the base housing 8 is more smoothly connected in the connector parallel direction within the housing fixing portion 12. To be able to slide into. Second, the entire base housing 8 can be made compact in the connector parallel direction. That is, even if the second contact accommodating chamber 16b is formed in the housing fixing portion 12 of the base housing 8 of the base connector portion 5A, if the housing displacement portion 13 of the base housing 8 is appropriately fleshed out, the housing displacement will be The part fixed portion 7 c is located at the approximate center in the connector parallel direction of the housing displacement portion 13 of the base housing 8. However, this fleshing hinders the compactness of the entire base housing 8 in the connector parallel direction. In view of such circumstances, when the second contact accommodating chamber 16b is formed in the housing displacement portion 13 of the base housing 8 of the base connector portion 5A, it can be said that the entire base housing 8 can be made compact in the connector parallel direction. it can.

  However, as one variation, it is recognized that the second contact accommodating chamber 16b is formed in the housing fixing portion 12 of the base housing 8 of the base connector portion 5A.

  The base connector portion 5A further includes a hold down 11 (auxiliary metal fitting) for fixing the housing fixing portion 12 of the base housing 8 of the base connector portion 5A to the backlight substrate 1A. The hold-down 11 has a retaining portion 11c (displacement restricting portion) that prevents the housing displacement portion 13 of the base housing 8 of the base connector portion 5A from being displaced in a direction away from the backlight substrate 1A. According to the above configuration, a dedicated retaining part is not necessary, which contributes to a reduction in the number of parts.

  Further, the base housing 8 of the base connector portion 5A is formed with a partition wall portion 13b (first housing partition wall portion) that separates the bellows portions 7d of the base contacts 7 of the base connector portion 5A. According to the above configuration, an unintended short circuit between the bellows portions 7d of the base contacts 7 of the base connector portion 5A can be prevented. In addition, the partition wall portion 13b inhibits deformation of the base contact portion 5A of each base contact 7 in the contact parallel direction of the bellows portion 7d, but the connecting connector portion 6 functions as a contact parallel direction displacement absorbing mechanism Q. Therefore, it is no longer necessary to deform the bellows portion 7d of each base contact 7 of the base connector portion 5A in the contact parallel direction. Therefore, the inhibition of the deformation does not become a problem.

  Each partition wall 13b is formed so that the bellows portion 7d of each base contact 7 of the base connector portion 5A is not exposed to the outside from the base housing 8 of the base connector portion 5A. According to the above configuration, an unintended short circuit between the bellows portions 7d of the base contacts 7 of the base connector portion 5A can be more reliably prevented.

  Further, as a connection form between each base contact 7 of the base connector portion 5A and each connection contact 9 of the connection connector portion 6, rigid connection that prohibits relative displacement between them is adopted. According to the above configuration, even if the backlight substrate 1A and the backlight substrate 1B are displaced relatively repeatedly, the contacts of the base contacts 7 and the connecting contacts 9 are always in the same position without being rubbed. Contact stability between the contact 7 and each connecting contact 9 can be maintained for a long period of time.

  Further, when connecting each base contact 7 of the base connector part 5A and each connection contact 9 of the connection connector part 6, each connection contact 9 of the connection connector part 6 is connected to each base contact 7 of the base connector part 5A. In addition, a positioning mechanism (positioning protrusion 24 and positioning hole 17) for positioning is further provided. According to the above configuration, each connection contact 9 can be smoothly connected to each base contact 7.

  Further, a substrate mounting surface 50 (first substrate mounting surface) as a surface of the base connector portion 5A that contacts the backlight substrate 1A, and a substrate as a surface of the base connector portion 5B that contacts the backlight substrate 1B. The mounting surface 50 (second substrate mounting surface) exists in substantially the same plane when the base connector portion 5A and the base connector portion 5B are connected by the connecting connector portion 6. According to the above configuration, the connection between the two substrates (backlight substrate 1A and backlight substrate 1B) arranged so that the element mounting surface 2A and the element mounting surface 2B (connector mounting surface) are substantially in the same plane. The board-to-board connector 4 described above can be used.

  The first embodiment described above can be modified as follows, for example.

  If the range of displacement in two directions can be realized by the cooperation of the base connector portion 5A and the connecting connector portion 6, the base connector portion 5B does not necessarily have to include the bellows portion 7d and the housing displacement portion 13. Absent.

  Although the connector mounting board is described as the backlight board, it can be applied to any board where a board-to-board connector is used, and it is more effective if it is a board on which heat-generating components such as LEDs are mounted. Can demonstrate.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIG. Here, the present embodiment will be described with a focus on differences from the first embodiment, and overlapping descriptions will be omitted as appropriate. In addition, in principle, the same reference numerals are assigned to components corresponding to the respective components of the first embodiment.

  In the present embodiment, a first projecting portion 40 projecting in the connector facing direction is formed at one end portion 21 of the first connecting housing portion 10A of the connecting housing 10 of the connecting connector portion 6, and the other end portion 21. The first concave portion 41 is formed in the direction opposite to the connector. Similarly, a second recess 42 is formed in one end portion 28 of the second connection housing portion 10B of the connection housing 10 of the connection connector portion 6 so as to be recessed in the direction opposite to the connector. A second projecting portion 43 projecting in the connector facing direction is formed. And the 1st protrusion part 40 of 10 A of 1st connection housing parts is accommodated in the 2nd recessed part 42 of 10 B of 2nd connection housing parts. The second protrusion 43 of the second connection housing part 10B is accommodated in the first recess 41 of the first connection housing part 10A. In the present embodiment, the limiting mechanism R that limits the relative displacement in the contact parallel direction of the first connecting housing portion 10A and the second connecting housing portion 10B within a predetermined range includes the first protrusion 40, the first recess 41, This is realized by the second recess 42 and the second protrusion 43. It should be noted that by adopting the above-described configuration, the first connection housing portion 10A and the second connection housing portion 10B can be formed using the same mold. This contributes to a reduction in manufacturing cost.

  Since it is sufficient that the movement in both directions in the contact parallel direction can be restricted in this way, it may be uneven at one place.

(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIG. Here, the present embodiment will be described with a focus on differences from the first embodiment, and overlapping descriptions will be omitted as appropriate. In addition, in principle, the same reference numerals are assigned to components corresponding to the respective components of the first embodiment.

  In the first embodiment, the base contact 7 is formed by punching a sheet metal. However, instead of this, as shown in FIG. 17, the base contact 7 may be formed by sheet metal bending.

1A Backlight board (first board)
1B Backlight board (second board)
2A element mounting surface (connector mounting surface)
2B element mounting surface (connector mounting surface)
4 Board-to-board connector 5A Base connector part (first connector part)
5B Base connector part (second connector part)
6 Connecting connector part (third connector part)
7 Base contact (first contact, second contact)
7a Connecting connector gripping part (first contact connecting part)
7c Housing displacement part fixed part (first contact second fixing part)
7d bellows (first contact bellows)
7f Backlight substrate fixing part (first contact first fixing part)
8 Base housing (first housing, second housing)
9 Connection contact (3rd contact)
10 Connection housing (third housing)
10A first connecting housing part (first connector part side housing)
10B Second connecting housing part (second connector part side housing)
11 Hold down (auxiliary bracket)
11c Retaining part (displacement restricting part)
12 Housing fixing part (first housing fixing part)
13 Housing displacement part (first housing displacement part)
13b Partition (first housing partition)
16b 2nd contact accommodation room (accordion part accommodation room)
17 Positioning hole (part of positioning mechanism)
24 Positioning protrusion (part of positioning mechanism)
30A first fixing part (third contact first fixing part)
30B second fixing part (third contact second fixing part)
31 connecting part (third contact connecting part)
50 Substrate mounting surface (first substrate mounting surface, second substrate mounting surface)
P connector parallel direction displacement absorption mechanism (first displacement absorption means)
Q Contact misalignment absorbing mechanism (second misalignment absorbing means)
T thickness direction
R restriction mechanism

Claims (14)

A first connector portion having a plurality of first contacts and a first housing for holding the plurality of first contacts, and mounted on a first substrate;
A second connector portion mounted on the second substrate, and having a plurality of second contacts and a second housing holding the plurality of second contacts;
A plurality of third contacts for connecting the plurality of first contacts of the first connector portion and the plurality of second contacts of the second connector portion, respectively, and a third housing for holding the plurality of third contacts And a third connector part having
With
First misalignment absorbing means for absorbing misalignment between the first connector portion and the second connector portion in a first direction as a direction in which the first connector portion and the second connector portion are arranged;
Second misalignment absorbing means for absorbing misalignment between the first connector portion and the second connector portion in the second direction as the direction in which the plurality of third contacts of the third connector portion are arranged; ,
In addition example Bei a,
The first connector portion functions as one of the first misalignment absorbing means or the second misalignment absorbing means;
The third connector portion functions as the other of the first misalignment absorbing means or the second misalignment absorbing means;
Board to board connector. The board-to-board connector according to claim 1 ,
The first connector portion functions as the first misalignment absorbing means;
The third connector portion functions as the second misalignment absorbing means;
Board to board connector. The board-to-board connector according to claim 2 ,
The third housing of the third connector portion includes a first connector portion side housing disposed on the first connector portion side and a second connector portion side housing disposed on the second connector portion side. And
Each third contact of the third connector part includes a third contact first fixing part fixed to the first connector part side housing and a third contact second fixing part fixed to the second connector part side housing. And a third contact connecting part for connecting the third contact first fixing part and the third contact second fixing part,
The third contact connecting portion of each third contact of the third connector portion is plate-shaped,
The thickness direction of the third contact connecting portion of each third contact of the third connector portion is substantially parallel to the second direction.
Board to board connector. The board-to-board connector according to claim 3 ,
The third housing of the third connector part includes a limiting mechanism that limits relative displacement of the first connector part side housing and the second connector part side housing in the second direction within a predetermined range. ,
Board to board connector. A board-to-board connector according to any one of claims 2 to 4 ,
Each first contact of the first connector portion includes a first contact first fixing portion fixed to the first substrate, a first contact connection portion connected to each third contact of the third connector portion, A first contact bellows portion interposed between the first contact first fixing portion and the first contact connection portion and formed in a bellows shape in the first direction;
Board to board connector. The board-to-board connector according to claim 5 ,
The first housing of the first connector portion includes a first housing fixing portion fixed to the first substrate, and a first housing displacement portion that can be relatively displaced in the first direction with respect to the first housing fixing portion. And having
Each first contact of the first connector portion has a first contact second fixing portion fixed to the first housing displacement portion,
The first contact second fixing portion is disposed between the first contact connection portion and the first contact bellows portion,
Board to board connector. The board-to-board connector according to claim 6 ,
In the first housing of the first connector portion, a bellows portion accommodating chamber for accommodating the first contact bellows portion of each first contact of the first connector portion is formed.
Board to board connector. The board-to-board connector according to claim 7 ,
The bellows portion accommodating chamber is formed in the first housing displacement portion of the first housing of the first connector portion.
Board to board connector. A board-to-board connector according to any one of claims 6 to 8 ,
The first connector portion further includes an auxiliary metal fitting for fixing the first housing fixing portion of the first housing of the first connector portion to the first substrate,
The auxiliary metal fitting has a displacement restricting portion that prevents the first housing displacement portion of the first housing of the first connector portion from being displaced in a direction away from the first substrate.
Board to board connector. A board-to-board connector according to any one of claims 5 to 9 ,
In the first housing of the first connector portion, a first housing partition wall is formed that separates the first contact bellows portions of the first contacts of the first connector portion.
Board to board connector. The board-to-board connector according to claim 10 ,
Each first housing partition wall is formed such that the first contact bellows of each first contact of the first connector portion is not exposed to the outside from the first housing of the first connector portion.
Board to board connector. A board-to-board connector according to any one of claims 1 to 11 ,
Rigid connection prohibiting relative displacement between each first contact of the first connector part and each third contact of the third connector part is employed,
Board to board connector. A board-to-board connector according to any one of claims 1 to 12 ,
When connecting each first contact of the first connector portion and each third contact of the third connector portion,
A positioning mechanism for positioning each third contact of the third connector portion with respect to each first contact of the first connector portion;
Board to board connector. A board-to-board connector according to any one of claims 1 to 13 ,
A first substrate mounting surface as a surface of the first connector portion that contacts the first substrate, and a second substrate mounting surface as a surface of the second connector portion that contacts the second substrate. ,
In the state where the first connector part and the second connector part are connected by the third connector part, they exist in substantially the same plane.
Board to board connector.

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