JP2008243538A - Connector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a connector capable of easily connecting printed-circuit boards mutually arranged in parallel and capable of connecting excellently even the printed-circuit boards shifted from a prescribed position relation. <P>SOLUTION: The connector 10 is constituted of a pair of sockets 11 mounted on two printed-circuit boards P1, P2 and a connecting member 12 to be connected to each socket 11. A first and a second board contacts 16 are installed on the sockets 11 and the connecting members 12 are composed of a pair of holders 17 to be connected to the socket 11 and a plurality of a first and a second connecting contacts 18, 19 to be held between these holders 17. Each holder 17 is joined to the socket 11 in thickness direction of the printed-circuit boards P1, P2. The first and second connecting contacts 18, 19 are covered by a cover 13 fixed to the both holders 17. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a connector for detachably connecting printed circuit boards arranged in parallel to each other.

Conventionally, as this type of connector, there is a connector having a structure as shown in FIG. The connector 80 includes a socket 81 mounted on one of the printed boards P1, P2 that are electrically connected, and a header 82 mounted on the other. Inside the connection recess 83 of the socket 81, a plurality of contacts 84a and 84b connected to the circuit on the printed circuit board P1 are provided. The header 82 includes an insertion portion 85 that is inserted into and coupled to the connection recess 83 of the socket 81, and the insertion portion 85 is provided with a plurality of contacts 86 a and 86 b that contact the contacts 84 a and 84 b of the socket 81. ing. Then, when the insertion portion 85 of the header 82 is inserted into the connection recess 83 of the socket 81, the contacts 84a and 84b of the socket 81 and the contacts 86a and 86b of the header 82 are electrically connected to each other, and both printed circuit boards P1 and P2 are connected to each other. Electrical connection is made via a connector 80.
Japanese Patent Laid-Open No. 2000-100501

  However, in the connector 80 described in the above publication, when trying to connect the socket 81 and the header 82 mounted on the printed circuit boards P1 and P2, respectively, the connection work is made closer to the printed circuit boards P1 and P2. It is necessary to carry out while moving. Accordingly, since the connector 80 cannot be mounted alone after the positional relationship between the two printed circuit boards P1 and P2 is fixed, the connection workability of the connector 80 is poor.

  Further, when the printed boards P1 and P2 connected by the connector 80 are fixed, the printed boards P1 and P2 may deviate from a predetermined positional relationship. In this case, since the positional relationship between the socket 81 and the header 82 is restricted by the insertion portion 85 and the contacts 86a and 86b, an excessive force is applied to the socket 81 and the header 82. As a result, the insertion portion 85 is deviated from the normal positional relationship with respect to the socket 81, the contact state between the contacts 84a, 84b, 86a, 86b is deteriorated, and further, the printed board of each contact 84a, 84b, 86a, 86b. The contact state with respect to P1 and P2 may deteriorate.

  The present invention has been made paying attention to such problems existing in the prior art. The purpose is to provide a connector that can easily connect printed circuit boards that are arranged in parallel to each other, and that can connect well even printed circuit boards that deviate from a predetermined positional relationship. It is to provide.

  In order to achieve the above object, the present invention is a connector for electrically connecting two printed circuit boards arranged in parallel to each other, and is mounted on each printed circuit board and mounted on each printed circuit board. A pair of sockets each provided with a plurality of board contacts disposed along the surface; and a connection member that electrically connects the sockets to each other, and the connection member is connected to each socket with the printed circuit board. A pair of holders that can be coupled to each other in the thickness direction, and a plurality of connection contacts disposed between the holders, and when the holders are coupled to the sockets, the substrate contacts of the sockets are connected to each other. Each holder is integrally formed with a first engagement portion, and each socket has a front. It said first engagement portion in the thickness direction of the printed circuit board is characterized in that it is formed integrally with the second engagement portion engaging.

  According to this configuration, the printed circuit boards are connected to each other by connecting the holders of the connection members to the sockets on the two printed circuit boards arranged in parallel with each other in the thickness direction of the printed circuit boards. Connected through. For this reason, since it is not necessary to move a printed circuit board in order to couple | bond a connection member to each socket, mounting | wearing of the connector with respect to both printed circuit boards becomes easy. Further, the first engaging portion of each holder is engaged with the second engaging portion of the socket, and each holder is firmly coupled to the socket. Therefore, even if the positional relationship between the two printed circuit boards deviates from the predetermined positional relationship, each holder and the socket are not easily deviated from the normal positional relationship, and the contact state between the substrate contact and the connection contact is not easily deteriorated.

In the present invention, each of the connection contacts has a bent portion or a bent portion that allows a change in the positional relationship between both ends thereof.
According to this configuration, in a state where the connection member is mounted on both printed circuit boards whose positions in the thickness direction are shifted from each other, a change in the positional relationship between both ends of each connection contact is allowed by the bent portion or the curved portion. Is done. For this reason, it is prevented that an excessive force is applied to each holder from each connection contact in an elastically deformed state. Therefore, even if the positional relationship between the two printed circuit boards deviates from the predetermined positional relationship, the positional relationship between each holder and the socket is normally maintained, and the contact state between each substrate contact and the connection contact is favorably maintained. .

  In addition, the present invention includes a cover made of an insulating material that covers the connection contact in a state of being fixed to the both holders or both sockets, and the cover includes a space between the two holders in the thickness direction of the two printed circuit boards. A misalignment allowing portion that allows misalignment is provided.

  According to this configuration, when the cover is attached to the connector attached to both printed circuit boards whose positions in the thickness direction are shifted from each other, the cover fixed to at least one of both the holders and both the sockets The positional deviation tolerance portion allows the positional deviation of both holders in the thickness direction. As a result, an excessive force is prevented from being applied from the cover to the holder coupled to the socket. Therefore, the cover is easily attached to the connector connected to both printed circuit boards that are displaced in the thickness direction, and the deviation from the normal positional relationship between the holder and the socket due to the attachment of the cover is prevented. The In addition, the attached cover protects the first connection contact and the second connection contact from contact with a person, adhesion of dust, and the like, and improves insulation.

Further, the present invention is characterized in that the positional deviation allowing portion allows positional deviation between the two holders in the approaching and separating directions of the sockets.
According to this configuration, when the cover is attached to the connector attached to both printed circuit boards in a state where the positions of the sockets in the approaching and separating directions are shifted from each other, the cover fixed to both the holders or both the sockets The positional deviation tolerance portion allows the positional relationship between the holders to be displaced in the same direction. As a result, an excessive force is prevented from being applied from the cover to the holder coupled to the socket. Accordingly, the cover is easily attached to the connector connected to both printed circuit boards that are displaced in the same direction, and the deviation from the normal positional relationship between the holder and the socket due to the attachment of the cover is prevented. .

Further, the present invention is characterized in that the positional deviation allowing portion allows positional deviation between the holders in a direction orthogonal to the approaching and separating directions in the same plane.
According to this configuration, when the cover is mounted on the connector mounted on both printed circuit boards in a state where the positions in the orthogonal direction with respect to the approach and separation directions of the two sockets are shifted from each other, the socket is fixed to both the holders or both the sockets. The positional deviation tolerance portion of the cover in the state allows deviation of the positional relationship between the two holders in the same direction. As a result, an excessive force is prevented from being applied from the cover to the holder coupled to the socket. Accordingly, the cover is easily attached to the connector connected to both printed circuit boards that are displaced in the same direction, and the deviation from the normal positional relationship between the holder and the socket due to the attachment of the cover is prevented. .

  Further, according to the present invention, the cover includes a first component fixed to one of the sockets and a second component fixed to the other of the sockets. It is an elastic deformation part integrally formed between the first component and the second component so as to connect the first component and the second component.

According to this configuration, an increase in the number of parts is prevented, and further, an increase in the number of assembly steps is prevented.
Further, according to the present invention, the cover includes a first member fixed to one of the sockets and a second member fixed to the other of the sockets. A pair of first connection pieces integrally formed with each other, a pair of second connection pieces integrally formed with the second member, and a first connection piece integrally formed with each second connection piece. It is comprised by the holding part which connects a 1st member and a 2nd member so that relative displacement is possible, and the clearance gap which accept | permits those positional offsets was formed between the 1st connection piece and the holding part, It is characterized by the above-mentioned.

  According to the present invention, printed circuit boards arranged in parallel to each other can be easily connected to each other, and even printed circuit boards that deviate from a predetermined positional relationship can be connected well.

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

  As shown in FIG. 1, the connector 10 of this embodiment electrically connects a pair of sockets 11 mounted on two printed circuit boards P1 and P2 arranged in parallel to each other and the sockets 11 to each other. The connecting member 12 and a cover 13 that covers both the sockets 11 and the connecting member 12 are configured.

  As shown in FIGS. 2 and 3, both the sockets 11 have the same configuration, and include a housing 14 integrally formed of an insulating material. The housing 14 includes a plurality of first members integrally formed of a conductive material. The first substrate contact 15 and the second substrate contact 16 are mounted in a state of being disposed along the surfaces of the printed circuit boards P1 and P2. The housing 14 is disposed on the printed circuit boards P1 and P2. In this state, the first substrate contacts 15 and the second substrate contacts 16 are electrically connected to a plurality of connection terminals (not shown) on the printed circuit boards P1 and P1, respectively. Connected. In this embodiment, the first substrate contact 15 and the second substrate contact 16 are substrate contacts.

  As shown in FIG. 6, the connection member 12 is integrally formed of an insulating material and is detachably attached to each socket 11, and is integrally formed of a conductive material and between the holders 17. A plurality of first connection contacts 18 and second connection contacts 19 are held. In the coupled state of the holder 17 to the socket 11, each first connection contact 18 is connected to each first substrate contact 15 of the socket 11, and each second connection contact 19 is connected to each second connection socket 19. Connected to the substrate contact 16. The first and second connection contacts 18 and 19 can be elastically deformed so as to allow a positional shift between the holders 17. In this embodiment, the first connection contact 18 and the second connection contact 19 are connection contacts.

As shown in FIG. 7, the cover 13 is integrally formed in a box shape whose lower side is opened by a transparent or translucent synthetic resin insulating material.
Next, the socket 11, the connection member 12, and the cover 13 will be described in detail.

  As shown in FIG. 3, the housing 14 of the socket 11 is formed with a groove-shaped female-side connection portion 20 for coupling the holder 17. A plurality of holding grooves 21 are formed on one inner surface of both wall portions of the female side connection portion 20, and the first substrate contact 15 is held in each holding groove 21. A plurality of holding grooves 22 are formed on the other inner surface of the both wall portions, and the second substrate contact 16 is held in each holding groove 22. That is, the first substrate contact 15 and the second substrate contact 16 are disposed so as to face each other. Further, a locking convex portion 23 for fixing the cover 13 is integrally formed on the outer surface of the wall portion where the holding groove 22 is formed. The locking convex portion 23 has an inclined surface 23a that faces obliquely upward. Further, on the lower surface of the housing 14 are integrally formed a plurality of positioning convex portions 24 that engage with positioning holes formed on the printed circuit boards P1 and P2 and position the socket 11 by the engagement.

  Each first substrate contact 15 has a held portion 15a held in the holding groove 21 of the socket 11, and from the upper end of the held portion 15a, a contact portion 15b disposed in the female side connecting portion 20 is provided. Is extended downward, and from the lower end of the held portion 15a, a terminal portion 15c abutting on the printed circuit board P1 (or P2) is extended to the outside of the socket 11. Each of the second substrate contacts 16 has the same configuration as the first substrate contact 15 and includes a held portion 16a, a contact portion 16b, and a terminal portion 16c corresponding to the held portion 15a, the contact portion 15b, and the terminal portion 15c. Have.

  As shown in FIG. 4, the holder 17 of the connection member 12 is formed with a ridge-like male side connection portion 30 to be inserted into the female side connection portion 20 of the socket 11, and a plurality of the wall surfaces are provided on one of the wall surfaces. The holding groove 31 is formed. Each holding groove 31 communicates with a slit-like holding recess 32 formed on the upper side of the holder 17 via a holding hole 33. The holding groove 31, the holding recess 32 and the holding hole 33 hold the end of the first connection contact 18. A plurality of holding grooves 34 are formed on the other of the wall surfaces of the male-side connecting portion 30 of the holder 17. Each holding groove 34 communicates with a holding groove 35 formed on the upper side of the holder 17 through a holding hole 36. The end of the second connection contact 19 is held by the holding groove 34, the holding groove 35 and the holding hole 36.

  Further, as shown in FIG. 6, convex engagement portions 37 for fixing the cover 13 are integrally formed on both end surfaces of the holder 17. Each convex engagement portion 37 has a slope that faces obliquely upward. The cover 13 is fixed on both holders 17 via the respective convex engaging portions 37 of both holders 17. Details of the cover 13 will be described later.

  Further, as shown in FIGS. 4 and 6, a locking piece 38 as a second engaging portion for fixing the holder 17 to the socket 11 is integrally formed on the outside of each holder 17. The locking piece 38 includes a deformable portion 38a protruding from the outer surface of the holder 17, a plate-like movable piece 38b supported by the deformable portion 38a, a pressing portion 38c formed on the outer side of the upper end of the movable piece 38b, and the movable piece 38b. It has the latching convex part 38d formed in the lower end inner side.

  As shown in FIG. 6, the first connection contact 18 includes a linear connection portion 18 a for connecting both the printed circuit boards P <b> 1 and P <b> 2, bent from both ends and extended upward, A bent portion 18b that is bent again and extends in parallel with the connecting portion 18a is extended. From the end portion of the bent portion 18b, an L-shaped held portion 18c that includes a portion extending in parallel with the connecting portion 18a and a portion extending downward from the end portion is extended, and the lower end thereof is connected to the contact portion 18d. It has become. As shown in FIG. 4, the held portion 18 c of the first connection contact 18 is held in the holding hole 33 of the holder 17, and the contact portion 18 d is arranged in the holding groove 31.

  Further, as shown in FIG. 6, each second connection contact 19 has the same configuration as that of the first connection contact 18, and a communication portion corresponding to the communication portion 18a, the bent portion 18b, the held portion 18c, and the contact portion 18d. 19a, a bent portion 19b, a held portion 19c, and a contact portion 19d. However, the bent portion 19b and the contact portion 19d of the second connection contact 19 are formed larger than the bent portion 18b and the contact portion 18d of the first connection contact 18. As shown in FIG. 4, the held portion 19c of the second connection contact 19 is held in the holding hole 36 of the holder 17, the contact portion 19d is in the holding groove 34, and the end portion of the bent portion 19b. Are respectively disposed in the holding grooves 35. That is, the first connection contact 18 and the second connection contact 19 are arranged so as to intersect the extending direction of the male side connection portion 30 of the holder 17 and to face each other in a direction parallel to the printed circuit board P1 (or P2). Has been.

  As shown in FIG. 7, the cover 13 includes a first component 13 a fixed to one of the sockets 11 and a second component 13 b fixed to the other of the sockets 11. Each side wall of the first and second component parts 13a, 13b is formed with a rectangular engagement opening 40 as a first engagement part with which the convex engagement part 37 of each holder 17 engages. Yes. Each engagement opening 40 is formed to engage with the convex engagement portion 37 when the cover 13 is put on both the holders 17 in the thickness direction with respect to the printed circuit boards P1 and P2.

  In addition, a pair of elastically deforming portions 41 as a misalignment allowing portion are integrally formed between the side walls of the first and second constituent portions 13a and 13b so as to connect the first and second constituent portions 13a and 13b. Has been. The elastic deformation portion 41 is formed so as to meander up and down, and can be elastically deformed so as to allow a positional deviation between the first and second constituent portions 13a and 13b.

  In addition, a vertical wall 43 is integrally formed at the inner center of the cover 13 so as to connect the two elastically deformable portions 41, and at the lower part of the vertical wall 43, between the first connection contacts 18 and each of the first connection contacts 18. A plurality of interposition portions 44 respectively disposed between the second connection contacts 19 are formed in a comb-like shape as a whole. Further, an “H” -shaped gap 45 is formed at the center of the top plate portion of the cover 13.

Further, on both sides of the cover 13, notches 42 in which the locking pieces 38 of the holder 17 are disposed are formed.
Next, the operation of this embodiment configured as described above will be described.

  In order to electrically connect the two printed circuit boards P <b> 1 and P <b> 2 arranged in parallel to each other by the connector 10, first, the connection member 12 is fitted inside the cover 13. That is, the convex engagement portions 37 of the respective holders 17 are engaged with the respective engagement openings 40 of the cover 13, and the connection member 12 is assembled inside the cover 13 by this engagement as shown in FIG. 8. As a result, both holders 17 of the connection member 12 are held in a predetermined positional relationship.

  Next, as shown by an arrow in FIG. 8, when the connecting member 12 mounted on the cover 13 is put on the socket 11 on both printed circuit boards P1 and P2, the male side connection of each holder 17 of the connecting member 12 is performed. The part 30 is inserted in the Z direction (that is, the thickness direction of the printed circuit boards P1 and P2) with respect to the female side connection part 20 of the socket 11. At this time, the locking convex portion 38d of the locking piece 38 of each holder 17 abuts on the inclined surface 23a of the locking convex portion 23 of the socket 11, and as shown by a two-dot chain line in FIG. As a result, the movable piece 38b tilts around the deformable portion 38a. Then, after the locking projection 38d gets over the locking projection 23, it engages with the locking projection 23 by its own elasticity. As a result, each holder 17 is fixed to the socket 11, and the connection member 12 is coupled to both the sockets 11 together with the cover 13.

  In this coupled state, as shown in FIGS. 2 and 5, the contact portions 18 d of the first connection contacts 18 of the holder 17 are in contact with the contact portions 15 b of the first substrate contacts 15 of the socket 11, respectively. At the same time, the contact portions 19d of the second connection contacts 19 are in contact with the contact portions 16b of the second substrate contacts 16, respectively. As a result, both printed circuit boards P1 and P2 are connected by the connector 10. Therefore, the connector 10 can be independently connected between the printed boards P1 and P2 whose positional relationship is fixed in advance. In this state, since the connection member 12 and the sockets 11 are covered by the cover 13, an operator carelessly cares about each of the first and second connection contacts 18 and 19 and the first and second substrate contacts 15 and 16. It will not be touched or the surrounding dust will adhere. Further, in the mounted state of the cover 13, as shown in FIG. 9, each interposition part 44 formed on the vertical wall 43 is between the adjacent first connection contacts 18 and between the second connection contacts 19. It will be in an intervening state.

  By the way, when the connecting member 12 is attached to both the sockets 11 together with the cover 13, the positional relationship between the two printed circuit boards P1 and P2 is in the X direction shown in FIG. , The sockets 11 may be closer than the predetermined positional relationship in the approaching and separating directions). That is, both printed circuit boards P1 and P2 may be displaced in the X1 and X2 directions in FIG. In such a case, if the holders 17 of the connection member 12 are to be mounted in the sockets 11, the bent portions 18b and 19b of the first and second connection contacts 18 and 19 are obtained as shown in FIG. As the degree of bending increases, the connecting portions 18a and 19a curve upward, and the distance between the holders 17 decreases. For this reason, each holder 17 is mounted on the socket 11 without any unreasonable force without receiving unnecessary force from the first and second connection contacts 18 and 19. Further, at this time, as shown in FIG. 10, the elastic deformation portion 41 is bent at each bending portion, and both side portions thereof are close to each other, so that a reduction in the interval between the two holders 17 coupled to the cover 13 is allowed. The Note that the both side portions of the elastic deformation portion 41 can be approached by the presence of the “H” -shaped gap 45. As a result, an excessive force is prevented from being applied from the cover 13 to the holder 17 coupled to each socket 11.

  Further, when the connecting member 12 is attached to both the sockets 11 together with the cover 13, the positional relationship between the two printed circuit boards P1 and P2 may be separated from the predetermined positional relationship in the X direction shown in FIG. That is, both printed circuit boards P1 and P2 may be displaced in the -X1 and -X2 directions in FIG. In such a case, if the holders 17 of the connection member 12 are to be attached to both sockets 11, the bending of the first and second connection contacts 18, 19 of the connection member 12 as shown in FIG. The degree of bending of the portions 18b and 19b becomes weak, and the distance between the holders 17 increases. For this reason, each holder 17 is mounted on the socket 11 without any unreasonable force without receiving unnecessary force from the first and second connection contacts 18 and 19. Further, at this time, as shown in FIG. 11, the elastic deformation portion 41 extends in each bending portion and both side portions thereof are separated from each other, and an increase in the distance between the holders 17 coupled to the cover 13 is allowed. . Note that the two side portions of the elastic deformation portion 41 can be separated by the presence of the gap 45. As a result, an excessive force is prevented from being applied from the cover 13 to the holder 17 coupled to each socket 11.

  In addition, when the connection member 12 is attached to both the sockets 11, the positional relationship between the two printed circuit boards P1 and P2 is in the Y direction shown in FIG. There is a case that the predetermined positional relationship is deviated in the direction orthogonal to the approaching and separating directions. That is, both printed circuit boards P1 and P2 may be displaced in the Y1 and Y2 directions in FIG. In such a case, the adjacent first and second connection contacts 18 and 19 may be in contact with each other. However, contact between the first and second connection contacts 18 and 19 is prevented by the interposition portions 44 interposed between the adjacent first and second connection contacts 18 and 19, respectively. Further, at this time, as shown in FIG. 13, the elastic deformation portion 41 of the cover 13 is elastically deformed, and a positional deviation between the two holders 17 coupled to the cover 13 is allowed. In addition, the position shift of the both side parts of the elastic deformation part 41 becomes possible by the presence of the gap 45. As a result, an excessive force is prevented from being applied from the cover 13 to the holder 17 coupled to each socket 11.

  Further, when the connection member 12 is mounted in both the sockets 11, the positional relationship between the two printed circuit boards P1 and P2 is a predetermined position in the Z direction shown in FIG. 1 (that is, the thickness direction of the two printed circuit boards P1 and P2). May deviate from the relationship. That is, both printed circuit boards P1 and P2 may be displaced in the Z1 and Z2 directions in FIG. In such a case, if each holder 17 is to be mounted in the socket 11, the first and second connection contacts 18 and 19 are elastically deformed, and the positional relationship between the holders 17 is shifted in the Z direction. At this time, as shown in FIG. 14, the elastic deformation portion 41 of the cover 13 is elastically deformed, and a positional deviation between the two holders 17 coupled to the cover 13 is allowed. In addition, the position shift of the both side parts of the elastic deformation part 41 becomes possible by the presence of the gap 45. As a result, an excessive force is prevented from being applied from the cover 13 to the holder 17 coupled to each socket 11.

  In order to remove the connection member 12 from both the sockets 11, the pressing portions 38 c of the locking pieces 38 of the respective holders 17 are pressed to tilt the movable piece 38 b, and the locking convex portions 38 d from the locking convex portions 23 of the socket 11. Remove. In this state, the connection member 12 is pulled together with the cover 13 above both printed circuit boards P1 and P2. Then, the connection member 12 is removed from both sockets 11 while being coupled to the cover 13.

Therefore, this embodiment detailed above has each effect described below.
(1) Since the holders 17 of the connection member 12 can be mounted in the thickness direction of the printed boards P1 and P2 with respect to the sockets 11 mounted on the two printed boards P1 and P2, It is possible to eliminate the need to move the printed circuit boards P1 and P2. Therefore, the connector 10 can be easily attached to both the printed boards P1 and P2.

  Further, the locking piece 38 formed integrally with each holder 17 is engaged with the locking projection 23 formed integrally with the socket 11 in the thickness direction of the printed circuit boards P 1 and P 2, and the holder 17 is attached to the socket 11. It was made to make it couple | bond firmly with respect. Therefore, when the connection member 12 is attached to the sockets 11 of the two printed circuit boards P1 and P2 fixed in a state of being deviated from the predetermined positional relationship, the first and second connection contacts 18 and 19 that are elastically deformed are used. The force applied to the holder 17 can prevent the holder 17 and the socket 11 from deviating from a normal positional relationship. Thereby, the contact state between the first and second substrate contacts 15 and 16 and the first and second connection contacts 18 and 19 can be maintained satisfactorily.

  (2) The first and second connection contacts 18 and 19 are formed with bent portions 18b and 19b for allowing relative displacement between the held portions 18c and 19c. Therefore, when the connector 10 is mounted on the printed circuit boards P1 and P2 that are fixed in a state of being deviated from the predetermined positional relationship, the positional relationship between the holders 17 changes without difficulty due to the elastic deformation of the bent portions 18b and 19b. Accordingly, it is possible to prevent an excessive force from being applied to both the holder 17 and the socket 11, and to maintain the positional relationship between the holder 17 and the socket 11 normally, and to each of the first and second substrate contacts 15, 16 and the first and first. The contact state with the two connection contacts 18, 19 can be maintained well.

  (3) Due to the elastic deformation of the elastic deformation portion 41 formed on the cover 13, displacement between the holders 17 in the Z direction is allowed, and an excessive force is applied from the cover 13 to the holder 17 coupled to the socket 11. Is prevented. Accordingly, the cover 13 can be easily attached to the connector 10 connected to both printed circuit boards P1 and P2 that are displaced in the thickness direction, and between the holders 17 and the sockets 11 due to the attachment of the cover 13. A positional shift can be prevented.

  (4) Due to the elastic deformation of the elastic deformation portion 41 formed on the cover 13, the positional deviation between the two holders 17 in the X direction is allowed, and an excessive force is applied from the cover 13 to the holder 17 coupled to the socket 11. Is prevented. Accordingly, the cover 13 can be easily attached to the connector 10 connected to both printed circuit boards P1 and P2 that are displaced in the approaching and separating directions of the sockets 11, and the holders 17 and sockets that are provided by the attachment of the cover 13 11 can be prevented from deviating from the positional relationship with.

  (5) Due to the elastic deformation of the elastic deformation portion 41 formed in the cover 13, the positional relationship between the holders 17 in the Y direction is allowed to be shifted, and an excessive force is applied to the holder 17 coupled to the socket 11 from the cover 13. It is prevented from joining. Accordingly, the cover 13 can be easily attached to the connector 10 connected to both printed circuit boards P1 and P2 that are displaced in the direction orthogonal to the approaching and separating directions of the sockets 11, and each holder obtained by attaching the cover 13 Deviation from the positional relationship between 17 and the socket 11 can be prevented.

  (6) Since the elastic deformation portion 41 that allows the positional relationship between the printed circuit boards P1 and P2 to be displaced is formed integrally with the cover 13, the number of parts is not increased and the number of assembly steps is not increased. Can do.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS. Only the cover 50 which is the difference between this embodiment and the first embodiment will be described.

  As shown in FIGS. 15 and 16, the cover 50 of this embodiment is configured by combining a first member 51 and a second member 52 that are integrally formed of a transparent or translucent synthetic resin insulating material. Yes.

  The first member 51 is formed with an engaging opening 40 and a notch 42 similar to the cover 13 of the first embodiment, and a pair of first members extending in the X direction in FIG. The connecting piece 53 is integrally formed. A lower engagement recess 53 a is formed below the first connection piece 53, and an upper engagement recess 53 b is formed above the first connection piece 53. Further, a notch 53 c extending in the X direction is formed at the center in the width direction of the first connecting piece 53.

  The second member 52 is formed with an engaging opening 40 and a notch 42 similar to the cover 13, and a pair of second connecting pieces 54 extending in the X direction in FIG. It is integrally formed. A vertical wall 43 having an interposition part 44 is formed between both the second connection pieces 54. Further, holding portions 57 for integrally connecting the first member 51 and the second member 52 so as to be relatively displaceable by holding the first connecting piece 53 are integrally formed on the outer surfaces of both the second connecting pieces 54. Yes. The holding portion 57 has a pair of hook-like lower engagement portions 55 that engage with the lower engagement recess portion 53a of the first connecting piece 53 and a pair of hook-like upper engagement portions that engage with the upper engagement recess portion 53b. Part 56. As shown in FIGS. 16 and 17, the first member 51 and the second member 52 are configured such that the lower engagement portion 55 is engaged with the lower engagement recess 53 a of the first connection piece 53 and the upper side When the upper engagement portion 56 is engaged with the engagement recess 53b, the engagement recess 53b is connected so as to be relatively displaceable in the X direction. In this connected state, the space between the lower engaging portion 55 and the upper engaging portion 56 is larger than the total width of the lower engaging recessed portion 53a, the upper engaging recessed portion 53b, and the notched portion 53c of the first connecting piece 53. Widely formed. Each first connecting piece 53 is assembled between the lower engaging portion 55 and the upper engaging portion 56 by being elastically deformed so that the cutout portion 53c is reduced. The first connecting piece 53, the second connecting piece 54, and the holding portion 57 constitute a misalignment allowing portion.

  Now, the connecting member 12 is also incorporated in the cover 50 of this embodiment in the same manner as the cover 13 of the first embodiment. The cover 50 is attached to both sockets 11 together with the connecting member 12.

  When the connecting member 12 is attached to the sockets 11 together with the cover 50, the positional relationship between the printed boards P1 and P2 may be closer than the predetermined positional relationship in the X direction shown in FIG. That is, both printed circuit boards P1 and P2 may be displaced from each other in the X1 and X2 directions in FIG. In this case, when each holder 17 is inserted into the socket 11, as shown in FIG. 18, the first member 51 and the second member 52 of the cover 50 are accompanied by relative displacement between the first connecting piece 53 and the holding portion 57. While approaching each other, the distance between the holders 17 decreases. As a result, even if both printed circuit boards P1 and P2 are closer than the predetermined positional relationship, an excessive force is prevented from being applied from the cover 13 to the holder 17 coupled to each socket 11.

  Further, when the connecting member 12 is attached to both the sockets 11 together with the cover 50, the positional relationship between the two printed circuit boards P1 and P2 may be separated from the predetermined positional relationship in the X direction shown in FIG. That is, both printed circuit boards P1 and P2 may be displaced in the -X1 and -X2 directions in FIG. In this case, when each holder 17 is inserted into the socket 11, the first member 51 and the second member 52 of the cover 50 are accompanied by relative displacement between the first connecting piece 53 and the holding portion 57, as shown in FIG. 19. However, they are separated from each other, and the distance between the holders 17 increases. As a result, even if the two printed circuit boards P1 and P2 are separated from each other in a predetermined positional relationship, an excessive force is prevented from being applied from the cover 13 to the holder 17 coupled to each socket 11.

  Further, when the connecting member 12 is attached to both the sockets 11 together with the cover 50, the positional relationship between the two printed circuit boards P1 and P2 may deviate from the predetermined positional relationship in the Y direction shown in FIG. In other words, both printed circuit boards P1 and P2 may be displaced in the Y1 and Y2 directions in FIG. In this case, when each holder 17 is to be inserted into the socket 11, as shown in FIG. 20, both the first connecting pieces 53 and the second connecting pieces 54 are elastically deformed, and a positional deviation between the holders 17 is allowed. The As a result, even if both printed circuit boards P1 and P2 are displaced from the predetermined positional relationship in the Y direction, it is possible to prevent an excessive force from being applied from the cover 13 to the holder 17 coupled to each socket 11.

  Further, when the connecting member 12 is attached to both the sockets 11 together with the cover 50, the positional relationship between the two printed circuit boards P1 and P2 may deviate from a predetermined positional relationship in the Z direction shown in FIG. That is, both printed circuit boards P1 and P2 may be displaced in the Z1 and Z2 directions in FIG. In this case, when trying to insert each holder 17 into the socket 11, as shown in FIG. 21, the relative displacement between the first connecting pieces 53 of the first member 51 and the holding portion 57 of the second member 52 is between them. It is allowed by the gap, and a positional deviation between both holders 17 is allowed. As a result, even if both printed circuit boards P1 and P2 deviate from a predetermined positional relationship in the Z direction, it is possible to prevent an excessive force from being applied from the cover 13 to the holder 17 coupled to each socket 11.

Therefore, this embodiment described in detail above has the effects described in (1) to (5) of the first embodiment.
(Other embodiments)
In addition, this embodiment can also be changed and embodied as follows.

  -In 1st or 2nd embodiment, the convex engagement part replaced with the convex engagement part 37 of the holder 17 is integrally formed in the socket 11, and the engagement opening 40 of the cover 13 is engaged with the convex engagement part. The cover 13 is fixed to both sockets 11 by combining them.

-The elastic deformation part 41 of 1st Embodiment is made into the shape bent in zigzag shape.
The present invention is applied to the connector 10 constituted by the socket 11 provided with only the substrate contact corresponding to the first substrate contact 15 and the connection member 12 provided only with the connection contact corresponding to the first connection contact 18. Make it concrete.

The perspective view which shows the connector of 1st Embodiment. The longitudinal cross-sectional view which shows a connector. The longitudinal cross-sectional view which shows a socket. The longitudinal cross-sectional view which shows a holder. The longitudinal cross-sectional view which shows the connection part of a connector. The disassembled perspective view which shows a connection member. The partially broken perspective view which shows a cover. The schematic diagram which shows the mounting state of the connection member to both sockets. The partial longitudinal cross-sectional view of the cover which shows an interposition part. The side view which shows the connector of a mounting state. The side view which shows the connector of a mounting state. (A), (b) is a longitudinal cross-sectional view which shows the connector of a mounting state. The top view which shows a connector. The side view which shows the connector of a mounting state. The disassembled perspective view which shows the cover of the connector of 2nd Embodiment. The perspective view which shows the cover of a connector. (A) is a partially broken side view showing the connecting portion of the connector, (b) is a cross-sectional view taken along line aa in (a). The side view which shows the connector of a mounting state. The side view which shows the connector of a mounting state. The top view which shows a connector. The side view which shows the connector of a mounting state. The longitudinal cross-sectional view which shows the conventional connector.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Connector, 11 ... Socket, 12 ... Connection member, 13 ... Cover, 13a ... 1st structure part, 13b ... 2nd structure part, 15 ... 1st board contact as a board contact, 16 ... 2nd board contact similarly DESCRIPTION OF SYMBOLS 17 ... Holder, 18 ... 1st connection contact as a connection contact, 19 ... Similarly 2nd connection contact, 18b, 19b ... Bending part, 38 ... Locking piece as 2nd engagement part, 40 ... 1st engagement part , An opening for engagement as 41, an elastic deformation portion as an allowance portion for misalignment, 45 ... a gap, 50 ... a cover, 51 ... a first member constituting the cover, 52 ... a second member, 53 ... a misalignment allowance portion. 1st connection piece which comprises, 54 ... Similarly 2nd connection piece, 57 ... Similarly holding | maintenance part, P1, P2 ... Printed circuit board.

Claims (7)

A connector for electrically connecting two printed circuit boards arranged in parallel to each other,
A pair of sockets each mounted on each printed circuit board and provided with a plurality of substrate contacts disposed along the surface of each printed circuit board, and a connection member for electrically connecting the sockets. Prepared,
The connection member comprises a pair of holders that can be coupled to the sockets in the thickness direction of the printed circuit board, and a plurality of connection contacts disposed between the holders.
In the coupled state of the holder to each socket, the connection between the substrate contacts of each socket by a connection contact,
Each holder is integrally formed with a first engaging portion, and each socket is integrally formed with a second engaging portion that engages with the first engaging portion in the thickness direction of the printed circuit board. A connector characterized by that.   2. The connector according to claim 1, wherein each of the connection contacts has a bent portion or a curved portion that allows a change in a positional relationship between both end portions thereof. With a cover made of an insulating material covering the connection contact in a state fixed to both the holders or both sockets,
The connector according to claim 1, wherein the cover is provided with a displacement allowance portion that allows a displacement between the holders in the thickness direction of the printed boards.   The connector according to claim 3, wherein the misalignment allowing portion allows misalignment between the holders in the approaching and separating directions of the sockets.   5. The connector according to claim 4, wherein the displacement allowance portion allows a displacement between the holders in a direction orthogonal to the approaching and separating directions. The cover has a first component fixed to one of the sockets and a second component fixed to the other of the sockets,
The said position shift | offset | difference permission part is an elastic deformation part integrally formed between both so that the said 1st structure part and a 2nd structure part may be connected, The any one of Claims 3-5 characterized by the above-mentioned. The connector according to one item. The cover includes a first member fixed to one of the sockets and a second member fixed to the other of the sockets.
The misalignment allowing portion is integrally formed with a pair of first connection pieces integrally formed with the first member, a pair of second connection pieces integrally formed with the second member, and each second connection piece. Each holding a first connecting piece to hold the first member and the second member so that they can be displaced relative to each other, and the positional displacement between the first connecting piece and the holding part is allowed. The connector according to claim 3, wherein a gap is formed.

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