The present invention relates to a wire-to-board connector.
As a technique of this type, Patent Literature 1 discloses a connector including a socket connector 100 shown in
The socket connector 100 includes a housing 102 and a plurality of socket contacts (not shown) which are engaged with the housing 102. Lead wires extending substantially forward are respectively attached to the socket contacts.
The base connector 101 is fixed to a printed circuit board by solder joining. The base connector 101 includes a housing 103 and a plurality of contacts 104 which are held by the housing 103. The housing 103 has a recess 105 which is opened in a direction away from the printed circuit board. The socket connector 100 is inserted into and removed from the recess 105 of the base connector 101 along an inserting/removing direction which is orthogonal to the printed circuit board.
A pair of lock pieces 106 is formed so as to protrude from an end face of the housing 102 of the socket connector 100. A pair of mating grooves 107 is formed in the housing 103 of the base connector 101. In the state where the socket connector 100 and the base connector 101 are coupled together, the pair of lock pieces 106 of the housing 102 of the socket connector 100 are respectively mated with the pair of mating grooves 107. The pair of lock pieces 106 and the pair of mating grooves 107 constitute a lock mechanism for maintaining the state in which the socket connector 100 is engaged with base connector 101.
[Patent Literature 1] Japanese Patent No. 4020907
However, in the structure disclosed in Patent Literature 1 described above, there is a possibility that the socket connector 100 is disengaged from the base connector 101 when the lead wires are raised in the direction away from the printed circuit board. Meanwhile, there is a potential need for removing the socket connector 100 from the base connector 101 depending on the situation.
It is an object of the present invention to provide a connector capable of maintaining a mated state even when a wire is raised in a direction away from a board and capable of intentionally releasing the mated state.
According to a first aspect of the present invention, there is provided a wire-to-board connector including: a plug connector including a plug contact to which a wire is attached, and a plug housing that holds the plug contact; and a receptacle connector that is mounted on a connector mounting surface of a board and includes a receptacle contact corresponding to the plug contact, and a receptacle housing that holds the receptacle contact, the plug connector being mated with the receptacle connector to thereby allow the plug contact to contact the receptacle contact. In a mated state in which the plug connector is mated with the receptacle connector, a vicinity portion of the wire, the vicinity portion being located in the vicinity of the plug connector, extends along the connector mounting surface of the board. A mating direction in which the plug connector is mated with the receptacle connector is a direction approaching the connector mounting surface of the board. The plug housing includes a plug side surface as a side surface of the plug housing. The receptacle connector includes a side surface opposing portion that is opposed to the plug side surface in the mated state. The plug side surface is provided with a claw portion projecting toward the side surface opposing portion. The claw portion includes a plug lock surface that faces in a direction away from the connector mounting surface of the board and extends in a wire direction specified as a longitudinal direction of the vicinity portion in the mated state. The side surface opposing portion of the receptacle connector includes a receptacle lock surface that faces in a direction approaching the connector mounting surface of the board and is opposed to the plug lock surface in the mated state. The plug lock surface includes a lock maintaining surface disposed on a side in a connector wire direction in which the wire is viewed from the plug connector in the wire direction, and an unlocking surface disposed on a side in a wire connector direction which is opposite to the connector wire direction. In a cross-section orthogonal to the wire direction, assuming that an angle formed between the lock maintaining surface and a reference plane that is a portion of the plug side surface located on a side farther from the connector mounting surface of the board than the claw portion is a lock maintaining angle θ1 and an angle formed between the reference plane and the unlocking surface is an unlocking angle θ2, the lock maintaining angle θ1 is smaller than the unlocking angle θ2.
Preferably, the unlocking angle θ2 is greater than 90 degrees.
Preferably, the lock maintaining angle θ1 is equal to or smaller than 90 degrees.
Preferably, the unlocking surface is inclined so as to approach the plug side surface in the wire connector direction.
Preferably, the unlocking surface is connected to an edge of the lock maintaining surface on a side far from the plug side surface.
Preferably, at an end in the wire connector direction of the claw portion, an inclined surface that is inclined so as to approach the plug side surface in the wire connector direction is formed, and the inclined surface is connected to the unlocking surface.
Preferably, the side surface opposing portion includes a lock piece supporting portion and a lock piece that is supported by the lock piece supporting portion; the lock piece is formed in a cantilever shape including a lock piece held portion that is held by the lock piece supporting portion, and a lock piece opposing portion that is opposed to the plug side surface; the lock piece opposing portion is elastically displaceable in a direction away from the plug side surface; and the receptacle lock surface is formed in the lock piece opposing portion.
Preferably, the side surface opposing portion includes a displacement regulating portion that is disposed on a side opposite to the connector mounting surface of the board with the lock piece opposing portion interposed therebetween, thereby regulating the lock piece opposing portion from being elastically displaced in a direction away from the connector mounting surface of the board.
Preferably, the lock piece held portion and the lock piece opposing portion are formed so as to extend in the wire direction.
Preferably, an end in the wire connector direction of the lock piece held portion is coupled with an end in the wire connector direction of the lock piece opposing portion.
Preferably, the plug housing is provided with a releasing projection that allows the plug connector to be inclined in such a manner that the wire approaches the connector mounting surface of the board.
Preferably, the releasing projection is formed so as to protrude in the wire connector direction from an end in the wire connector direction of the plug housing.
According to a second aspect of the present invention, there is provided a wire-to-board connector including: a plug connector including a plug contact to which a wire is attached, and a plug housing that holds the plug contact; and a receptacle connector that is mounted on a connector mounting surface of a board and includes a receptacle contact corresponding to the plug contact, and a receptacle housing that holds the receptacle contact, the plug connector being mated with the receptacle connector to thereby allow the plug contact to contact the receptacle contact. In a mated state in which the plug connector is mated with the receptacle connector, a vicinity portion of the wire, the vicinity portion being located in the vicinity of the plug connector, extends along the connector mounting surface of the board. A mating direction in which the plug connector is mated with the receptacle connector is a direction approaching the connector mounting surface of the board. The plug housing includes a plug side surface as a side surface of the plug housing. The receptacle connector includes a side surface opposing portion that is opposed to the plug side surface in the mated state. The plug side surface is provided with a claw portion projecting toward the side surface opposing portion. The claw portion includes a plug lock surface that faces in a direction away from the connector mounting surface of the board and extends in a wire direction specified as a longitudinal direction of the vicinity portion in the mated state. The side surface opposing portion of the receptacle connector includes a receptacle lock surface that faces in a direction approaching the connector mounting surface of the board and is opposed to the plug lock surface in the mated state. The plug lock surface includes a lock maintaining surface disposed on a side in a connector wire direction in which the wire is viewed from the plug connector in the wire direction, and an unlocking surface disposed on a side in a wire connector direction which is opposite to the connector wire direction. The unlocking surface is formed to be curved so as to approach the connector mounting surface of the board in a direction away from the plug side surface.
According to the second aspect of the present invention, there is provided a wire-to-board connector including: a plug connector including a plug contact to which a wire is attached, and a plug housing that holds the plug contact; and a receptacle connector that is mounted on a connector mounting surface of a board and includes a receptacle contact corresponding to the plug contact, and a receptacle housing that holds the receptacle contact, the plug connector being mated with the receptacle connector to thereby allow the plug contact to contact the receptacle contact. In a mated state in which the plug connector is mated with the receptacle connector, a vicinity portion of the wire, the vicinity portion being located in the vicinity of the plug connector, extends along the connector mounting surface of the board. A mating direction in which the plug connector is mated with the receptacle connector is a direction approaching the connector mounting surface of the board. The plug housing includes a plug side surface as a side surface of the plug housing. The receptacle connector includes a side surface opposing portion that is opposed to the plug side surface in the mated state. The plug side surface is provided with a claw portion projecting toward the side surface opposing portion. The claw portion includes a plug lock surface that faces in a direction away from the connector mounting surface of the board and extends in a wire direction specified as a longitudinal direction of the vicinity portion in the mated state. The side surface opposing portion of the receptacle connector includes a receptacle lock surface that faces in a direction approaching the connector mounting surface of the board and is opposed to the plug lock surface in the mated state. The plug lock surface includes a lock maintaining surface disposed on a side in a connector wire direction in which the wire is viewed from the plug connector in the wire direction, and an unlocking surface disposed on a side in a wire connector direction which is opposite to the connector wire direction. In a cross-section orthogonal to the wire direction, assuming that an angle formed between the lock maintaining surface and a reference plane that is a portion of the plug side surface located on a side farther from the connector mounting surface of the board than the claw portion is a lock maintaining angle θ1 and an angle formed between the reference plane and the unlocking surface is an unlocking angle θ2, the lock maintaining angle θ1 is smaller than the unlocking angle θ2. The side surface opposing portion includes a lock piece supporting portion and a lock piece that is supported by the lock piece supporting portion. The lock piece is formed in a cantilever shape including a lock piece held portion that is held by the lock piece supporting portion, and a lock piece opposing portion that is opposed to the plug side surface. The lock piece opposing portion is elastically displaceable in a direction away from the plug side surface. The plug side surface of the plug housing is provided with an overhanging portion projecting toward the lock piece of the side surface opposing portion, and the overhanging portion is in contact with an elastically displaceable portion of the lock piece opposing portion in the mated state.
When the wire is raised in the direction away from the connector mounting surface of the board and the plug connector is inclined, the lock maintaining surface contacts the receptacle lock surface in advance of the unlocking surface. On the other hand, when the plug connector is intentionally inclined in such a manner that the wire approaches the connector mounting surface of the board, the unlocking surface contacts the receptacle lock surface in advance of the lock maintaining surface. Thus, according to the structure described above, when the wire is raised in the direction away from the connector mounting surface of the board, the mated state is easily maintained without releasing the opposed relationship between the plug lock surface and the receptacle lock surface, and when the plug connector is intentionally inclined in such a manner that the wire approaches the connector mounting surface of the board, the opposed relationship between the plug lock surface and the receptacle lock surface is released and thus the mated state is easily released. Consequently, a wire-to-board connector capable of maintaining the mated state even when the wire is raised in the direction away from the connector mounting surface of the board and capable of intentionally releasing the mated state is achieved.
(Wire-to-Board Connector 1)
A first embodiment of the present invention will be described below with reference to
As shown in
The receptacle connector 3 includes a plurality of receptacle contacts 7, a receptacle housing 8 which holds the plurality of receptacle contacts 7, and a pair of assistant fittings 9 (lock pieces). The receptacle contacts 7 respectively correspond to the plug contacts 4. The receptacle connector 3 is mounted on a connector mounting surface 10a of a circuit board 10 (board).
As shown in
The terms “wire direction”, “connector height direction”, and “connector width direction” are now defined. The term “wire direction” refers to a direction specified as a longitudinal direction of a vicinity portion 6a, which is a portion in the vicinity of the plug connector 2 of the wire 6, in a mated state in which the plug connector 2 is mated with the receptacle connector 3 as shown in
In the following description, each component of the wire-to-board connector 1 will be described by using the terms “wire direction”, “connector height direction”, and “connector width direction”, which are defined in the mated state in which the plug connector 2 is mated with the receptacle connector 3.
As shown in
The plurality of wires 6 are arranged side by side in the connector width direction. Similarly, the plurality of receptacle contacts 7 are arranged side by side in the connector width direction.
(Receptacle Connector 3)
Next, the receptacle connector 3 will be described in detail with reference to
As shown in
As shown in
The board opposing portion 15 is a flat plate parallel to the connector mounting surface 10a of the circuit board 10, and is formed in a rectangular shape elongated in the connector width direction.
The receptacle contact holding portion 16 is a portion that is connected to an end in the wire connector direction of the board opposing portion 15, protrudes in the board separating direction, and extends in an elongated shape in the connector width direction. The receptacle contact holding portion 16 has a plurality of receptacle contact mounting holes 18 formed therein. Each receptacle contact mounting hole 18 is a hole for attaching each receptacle contact 7 to the receptacle housing 8. The plurality of receptacle contact mounting holes 18 are formed at a predetermined interval along the connector width direction. The plurality of receptacle contact mounting holes 18 are formed between both ends 19 in the connector width direction of the receptacle contact holding portion 16. Each receptacle contact mounting hole 18 is formed so as to penetrate the receptacle contact holding portion 16 in the wire direction. That is, each receptacle contact mounting hole 18 is formed so as to be opened in the wire connector direction and the connector wire direction. The both ends 19 are walls orthogonal to the wire direction.
The pair of side portions 17 are respectively connected to the both ends in the connector width direction of the board opposing portion 15 and the receptacle contact holding portion 16, and are formed so as to protrude in the connector wire direction. The pair of side portions 17 is formed to be elongated along the wire direction. The pair of side portions 17 is formed in a symmetrical shape with respect to the center in the connector width direction of the wire-to-board connector 1. Accordingly, only one of the pair will be described, and the description of the other one of the pair will be omitted.
As shown in
The positioning groove side partition wall portion 20 is a wall that is connected to an end in the connector width anti-center direction at the corresponding end 19 of the receptacle contact holding portion 16, and extends in the connector wire direction. The positioning groove side partition wall portion 20 is orthogonal to the connector width direction.
The positioning groove front partition wall portion 21 is a wall that is connected to an end in the connector wire direction of the positioning groove side partition wall portion 20, and extends in the connector width center direction. The positioning groove front partition wall portion 21 is orthogonal to the wire direction.
The end 19 of the receptacle contact holding portion 16, and the positioning groove side partition wall portion 20 and the positioning groove front partition wall portion 21 of the side portion 17 constitute a positioning groove 41. The end 19 of the receptacle contact holding portion 16 defines a space in the wire connector direction of the positioning groove 41. The positioning groove side partition wall portion 20 defines a space in the connector width anti-center direction of the positioning groove 41. The positioning groove front partition wall portion 21 defines a space in the connector wire direction of the positioning groove 41.
The press-fit groove side partition wall portion 22 is a wall that is connected to an end in the connector width anti-center direction of the positioning groove front partition wall portion 21, and extends in the connector wire direction. The press-fit groove side partition wall portion 22 is orthogonal to the connector width direction.
The press-fit groove front partition wall portion 23 is a wall that is connected to an end in the connector wire direction of the press-fit groove side partition wall portion 22, and extends in the connector width center direction. The press-fit groove front partition wall portion 23 is orthogonal to the wire direction.
The press-fit groove inner partition wall portion 24 is a wall that is connected to an end in the connector width center direction of the press-fit groove front partition wall portion 23, and extends in the wire connector direction. The press-fit groove inner partition wall portion 24 is orthogonal to the connector width direction.
The press-fit groove side partition wall portion 22 and the press-fit groove inner partition wall portion 24 constitute a press-fit groove 26. The press-fit groove side partition wall portion 22 defines a space in the connector width anti-center direction of the press-fit groove 26. The press-fit groove inner partition wall portion 24 defines a space in the connector width center direction of the press-fit groove 26. The press-fit groove front partition wall portion 23 defines a space in the connector wire direction of the press-fit groove 26. The press-fit groove 26 is opened in the board separating direction. The press-fit groove 26 is formed to be elongated along the wire direction.
An end 24a in the wire connector direction of the press-fit groove inner partition wall portion 24 is opposed to the positioning groove front partition wall portion 21. A gap “g” is formed between the end 24a of the press-fit groove inner partition wall portion 24 and the positioning groove front partition wall portion 21.
The displacement regulating portion 25 is connected to an end in the connector wire direction of the press-fit groove inner partition wall portion 24, and is formed so as to protrude in the connector width center direction. As shown in
The pair of assistant fittings 9 is formed in a symmetrical shape with respect to the center in the connector width direction of the wire-to-board connector 1. Accordingly, only one of the pair will be described, and the description of the other one of the pair will be omitted.
As shown in
The lock piece held portion 30 is a portion held by the receptacle housing 8. The lock piece held portion 30 is formed so as to extend in the wire direction. The lock piece held portion 30 is orthogonal to the connector width direction. The lock piece held portion 30 includes a press-fitted portion 30a and a soldered leg portion 33. The press-fitted portion 30a is formed in a rod shape protruding in the board approaching direction. The soldered leg portion 33 is a portion that is soldered to the connector mounting surface 10a of the circuit board 10.
The lock piece opposing portion 31 is formed so as to extend in the wire direction. The lock piece opposing portion 31 is orthogonal to the connector width direction. The lock piece opposing portion 31 includes an opposing portion body 34 and a regulated projection 35.
The opposing portion body 34 is formed to be elongated in the wire direction. The opposing portion body 34 is orthogonal to the connector width direction. The opposing portion body 34 has a lock hole 36 which is formed in a substantially rectangular shape when viewed along the connector width anti-center direction. The lock hole 36 is formed to be elongated in the wire direction. Since the lock hole 36 is formed, a lock beam 37 which defines a space in the board separating direction of the lock hole 36 is formed on a side in the board separating direction of the lock hole 36. The lock beam 37 includes a receptacle lock surface 38, a plug opposing surface 39, and an assembly guide surface 40. The receptacle lock surface 38 is a surface that faces in the direction approaching the connector mounting surface 10a of the circuit board 10. The receptacle lock surface 38 is a flat surface that faces in the board approaching direction. The receptacle lock surface 38 is orthogonal to the connector height direction. The receptacle lock surface 38 is formed to be elongated in the wire direction. The plug opposing surface 39 is a flat surface that is connected to an edge in the connector width center direction of the receptacle lock surface 38 and faces in the connector width center direction. The plug opposing surface 39 is orthogonal to the connector width direction. The assembly guide surface 40 is a flat surface that is connected to an edge in the board separating direction of the plug opposing surface 39 and is inclined in the connector width center direction toward the board approaching direction.
The regulated projection 35 is a portion that is connected to a side in the board approaching direction of an end in the connector wire direction of the opposing portion body 34 and is formed so as to protrude in the connector wire direction. The regulated projection 35 includes a regulated surface 35a that faces in the board separating direction. The regulated surface 35a is orthogonal to the connector height direction.
The lock piece coupling portion 32 is a portion that couples an end in the wire connector direction of the lock piece held portion 30 with an end in the wire connector direction of the lock piece opposing portion 31. The lock piece coupling portion 32 is connected to an end in the wire connector direction of the lock piece held portion 30, and is formed so as to extend in the connector width center direction. The lock piece coupling portion 32 is orthogonal to the wire direction. An end in the connector width center direction of the lock piece coupling portion 32 is connected to an end in the wire connector direction of the lock piece opposing portion 31.
The assistant fitting 9 includes the lock piece held portion 30, the lock piece opposing portion 31, and the lock piece coupling portion 32, thereby forming a U-shape when viewed along the board approaching direction.
(Assembly of the Receptacle Connector 3)
Next, a method for assembling the receptacle connector 3 will be described in detail.
First, as shown in
Next, as shown in
Then, the lock piece held portion 30 of each assistant fitting 9 is inserted into the press-fit groove 26 of the corresponding side portion 17 of the receptacle housing 8. At this time, the press-fitted portion 30a (also see
The regulated projection 35 of the lock piece opposing portion 31 of each assistant fitting 9 passes over the inclined guide surface 27 of the displacement regulating portion 25 of the corresponding side portion 17 of the receptacle housing 8 in the connector width center direction, while the opposing portion body 34 of the lock piece opposing portion 31 is elastically displaced in the connector width center direction. Then, the regulated projection 35 slides on the erect guide surface 28 of the displacement regulating portion 25 in the board approaching direction.
When each assistant fitting 9 is further pushed in the board approaching direction, the regulated projection 35 eventually passes over the displacement regulating portion 25 in the board approaching direction, and is displaced in the connector width anti-center direction as shown in
In the state shown in
As shown in
In this embodiment, “a side surface opposing portion R” corresponds to each side portion 17 and each assistance fitting 9 of the receptacle housing 8 as shown in
(Plug Connector 2)
Next, the plug connector 2 will be described in detail with reference to
The plug connector 2 shown in
The plug housing 5 includes a plug housing body 50, a releasing projection 51, a pair of positioning projections 52, and a pair of claw portions 53.
The plug housing body 50 is a flat body with a small thickness in the connector height direction. The plug housing body 50 has a rectangular shape when viewed along the board approaching direction, and is formed to be elongated in the connector width direction. The plug housing body 50 has a plurality of plug contact mounting holes 54 formed therein. The plurality of plug contact mounting holes 54 are formed at a predetermined interval along the connector width direction. Each plug contact mounting hole 54 is formed so as to penetrate the plug housing body 50 in the wire direction. That is, each plug contact mounting hole 54 is formed so as to be opened in the wire connector direction and the connector wire direction.
The plug housing body 50 includes a pair of plug side surfaces 50a serving as a pair of side surfaces of the plug housing body 50. Each of the pair of plug side surfaces 50a is a flat surface substantially parallel to both of the wire direction and the connector height direction. That is, each plug side surface 50a is substantially orthogonal to the connector width direction. In this embodiment, the pair of plug side surfaces 50a is parallel to both of the wire direction and the connector height direction. The pair of plug side surfaces 50a is orthogonal to the connector width direction.
As shown in
The pair of positioning projections 52 is formed in a symmetrical shape with respect to the center in the connector width direction of the wire-to-board connector 1. Accordingly, only one of the pair will be described, and the description of the other one of the pair will be omitted. The positioning projection 52 is connected to an end in the connector width direction of the end in the wire connector direction of the plug housing body 50, and is formed so as to protrude in the connector width anti-center direction.
The pair of claw portions 53 is formed in a symmetrical shape with respect to the center in the connector width direction of the wire-to-board connector 1. Accordingly, only one of the pair will be described, and the description of the other one of the pair will be omitted. The claw portion 53 is connected to a side in the connector wire direction of the plug side surface 50a, and is formed so as to protrude in the connector width anti-center direction from the plug side surface 50a. The claw portion 53 is formed to be elongated in the wire direction. As shown in
The plug lock surface 60 is a surface that faces in a direction away from the connector mounting surface 10a of the circuit board 10 and is elongated in the wire direction. The plug lock surface 60 includes a lock maintaining surface 65 that is disposed on the side in the connector wire direction, and an unlocking surface 66 that is disposed on the side in the wire connector direction. The lock maintaining surface 65 is a flat surface that is connected to the plug side surface 50a and is substantially orthogonal to the connector height direction. The unlocking surface 66 is a flat surface that is connected to the plug side surface 50a, is inclined in the connector width center direction toward the board separating direction, and is inclined in the connector width center direction toward the wire connector direction. The lock maintaining surface 65 and the unlocking surface 66 are connected to each other. The lock maintaining surface 65 and the unlocking surface 66 are adjacent to each other in the wire direction. The lock maintaining surface 65 is disposed on the side in the connector wire direction when viewed from the unlocking surface 66. That is, the unlocking surface 66 is disposed on the side in the wire connector direction when viewed from the lock maintaining surface 65. The unlocking surface 66 is connected to an edge 65a on a side far from the plug side surface 50a of the lock maintaining surface 65. In other words, the unlocking surface 66 is connected to the edge 65a on a side in the connector width anti-center direction of the lock maintaining surface 65.
The mating guide surface 61 is a flat surface that faces in the direction approaching the connector mounting surface 10a of the circuit board 10 and is elongated in the wire direction. The mating guide surface 61 is inclined in the connector width center direction toward the board approaching direction.
The side standing surface 62 is a flat surface that faces in the connector width anti-center direction and is elongated in the wire direction. The side standing surface 62 is orthogonal to the connector width direction. The side standing surface 62 is connected to the plug lock surface 60 and the mating guide surface 61. The side standing surface 62 is formed between the plug lock surface 60 and the mating guide surface 61.
The end standing surface 63 is a flat surface that is connected to the plug side surface 50a and faces in the connector wire direction. The end standing surface 63 is orthogonal to the wire direction. The end standing surface 63 is connected to each of the plug lock surface 60, the mating guide surface 61, and the side standing surface 62.
The end inclined surface 64 is a flat surface that is connected to the plug side surface 50a and faces in the wire connector direction and the connector width anti-center direction. The end inclined surface 64 is inclined in the connector width center direction toward the wire connector direction. The end inclined surface 64 is connected each of the unlocking surface 66 of the plug lock surface 60, the mating guide surface 61, and the side standing surface 62.
The plug side surface 50a has a reference plane Q as indicated by an alternate long and two short dashes line in
In the cross-section X shown in
As shown in
(Assembly of the Plug Connector 2)
Next, a method for assembling the plug connector 2 will be described. To assemble the plug connector 2, each plug contact 4 is attached to an end of the corresponding wire 6 as shown in
(Method for Mating the Wire-to-Board Connector 1)
Next, a method for mating the wire-to-board connector 1 will be described. To mate the plug connector 2 with the receptacle connector 3, the receptacle connector 3 is preliminarily mounted on the connector mounting surface 10a of the circuit board 10 as shown in
Next, as shown in
(1) The pair of positioning projections 52 of the plug housing 5 shown in
(2) As shown in
(3) As shown in
Specifically, in the mated state shown in
(Method for Disengaging the Wire-to-Board Connector 1)
On the other hand, as shown in
In sum, the preferred embodiment of the present invention described above has the following features.
(1) The wire-to-board connector 1 includes the plug connector 2 and the receptacle connector 3. The plug connector 2 includes the plug contacts 4 to which the wires 6 are respectively attached, and the plug housing 5 that holds the plug contacts 4. The receptacle connector 3 includes the receptacle contacts 7 respectively corresponding to the plug contacts 4, and the receptacle housing 8 that holds the receptacle contacts 7. The receptacle connector 3 is mounted on the connector mounting surface 10a of the circuit board 10 (board). The plug connector 2 is mated with the receptacle connector 3, thereby allowing the plug contacts 4 to respectively contact the receptacle contacts 7. In the mated state in which the plug connector 2 is mated with the receptacle connector 3, the vicinity portion 6a which is a portion located in the vicinity of the plug connector 2 of each wire 6 extends along the connector mounting surface 10a of the circuit board 10. The mating direction P in which the plug connector 2 is mated with the receptacle connector 3 is a direction approaching the connector mounting surface 10a of the circuit board 10. The plug housing 5 includes the plug side surfaces 50a serving as side surfaces of the plug housing 5. The receptacle connector 3 includes the side surface opposing portion R that is opposed to the corresponding plug side surface 50a in the mated state. Each plug side surface 50a is provided with the claw portion 53 that protrudes toward the side surface opposing portion R. The claw portion 53 includes the plug lock surface 60 that faces in the direction away from the connector mounting surface 10a of the circuit board 10 and extends in the wire direction which is specified as the longitudinal direction of the vicinity portion 6a in the mated state. The assistant fitting 9 in the side surface opposing portion R of the receptacle connector 3 includes the receptacle lock surface 38 that faces in the direction approaching the connector mounting surface 10a of the circuit board 10 and is opposed to the plug lock surface 60 in the mated state. The plug lock surface 60 includes the lock maintaining surface 65 that is disposed on a side in the connector wire direction which is the direction in which each wire 6 is viewed from the plug connector 2 in the wire direction, and the unlocking surface 66 that is disposed on a side in the wire connector direction which is a direction opposite to the connector wire direction. In a cross-section orthogonal to the wire direction, assuming that the angle formed between the lock maintaining surface 65 and the reference plane Q, which is a portion of the plug side surface 50a that is located on a side farther from the connector mounting surface 10a of the circuit board 10 than the claw portion 53, is the lock maintaining angle θ1 and the angle formed between the reference plane Q and the unlocking surface 66 is the unlocking angle θ2, the lock maintaining angle θ1 is smaller than the unlocking angle θ2.
Specifically, when the wires 6 are raised in the direction away from the connector mounting surface 10a of the circuit board 10 and the plug connector 2 is inclined, the lock maintaining surface 65 contacts the receptacle lock surface 38 in advance of the unlocking surface 66. On the other hand, when the plug connector 2 is intentionally inclined so that the wires 6 approach the connector mounting surface 10a of the circuit board 10, the unlocking surface 66 contacts the receptacle lock surface 38 in advance of the lock maintaining surface 65. Thus, according to the structure described above, when the wires 6 are raised in the direction away from the connector mounting surface 10a of the circuit board 10, the mated state is easily maintained without releasing the opposed relationship between the plug lock surface 60 and the receptacle lock surface 38, and when the plug connector 2 is intentionally inclined so that the wires 6 approach the connector mounting surface 10a of the circuit board 10, the opposed relationship between the plug lock surface 60 and the receptacle lock surface 38 is released, thereby facilitating the release of the mated state. Consequently, the wire-to-board connector 1 capable of maintaining the mated state even when the wires 6 are raised in the direction away from the connector mounting surface 10a of the circuit board 10 and capable of intentionally releasing the mated state is achieved.
The receptacle lock surface 38 is formed in the assistant fitting 9 of the side surface opposed portion R in this embodiment, but instead may be formed in the side portion 17 of the side surface opposed portion R. In a modified example shown in
(2) The unlocking angle θ2 is greater than 90 degrees. According to the structure described above, when the plug connector 2 is intentionally inclined so that the wires 6 approach the connector mounting surface 10a of the circuit board 10, the opposed relationship between the plug lock surface 60 and the receptacle lock surface 38 is released more easily.
(3) The lock maintaining angle θ1 is equal to or smaller than 90 degrees. According to the structure described above, when the wires 6 are raised in the direction away from the connector mounting surface 10a of the circuit board 10, the opposed relationship between the plug lock surface 60 and the receptacle lock surface 38 is less likely to be released.
(4) The unlocking surface 66 is inclined so as to approach the plug side surface 50a in the wire connector direction. According to the structure described above, when the plug connector is intentionally inclined so that the wires approach the connector mounting surface of the board, the opposed relationship between the plug lock surface and the receptacle lock surface can be released more smoothly.
(5) The unlocking surface 66 is connected to the edge 65a of the lock maintaining surface 65 on a side far from the plug side surface 50a. According to the structure described above, when the plug connector 2 is intentionally inclined so that the wires 6 approach the connector mounting surface 10a of the circuit board 10 and the opposed relationship between the plug lock surface 60 and the receptacle lock surface 38 is released, the receptacle lock surface 38 is prevented from being caught on the boundary between the unlocking surface 66 and the lock maintaining surface 65.
(6) The end inclined surface 64 (inclined surface) that is inclined so as to approach the plug side surface 50a in the wire connector direction is formed at an end in the wire connector direction of the claw portion 53. The end inclined surface 64 is connected to the unlocking surface 66. According to the structure described above, when the plug connector 2 is intentionally inclined so that the wires 6 approach the connector mounting surface 10a of the circuit board 10, the opposed relationship between the plug lock surface 60 and the receptacle lock surface 38 can be released more smoothly.
(7) The side surface opposing portion R includes the side portion 17 (lock piece supporting portion) and the assistant fitting 9 (lock piece) which is supported by the side portion 17. The assistant fitting 9 is formed in a cantilever shape including the lock piece held portion 30 which is held by the side portion 17, and the lock piece opposing portion 31 which is opposed to the plug side surface 50a. The lock piece opposing portion 31 is elastically displaceable in the direction away from the plug side surface 50a. The receptacle lock surface 38 is formed in the lock piece opposing portion 31. According to the structure described above, when the plug connector 2 is intentionally inclined so that the wires 6 approach the connector mounting surface 10a of the circuit board 10, the receptacle lock surface 38 is pushed out by the unlocking surface 66 in the direction away from the plug side surface 50a, so that the opposed relationship between the plug lock surface 60 and the receptacle lock surface 38 can be released more smoothly.
(8) The side portion 17 of the side surface opposing portion R includes the displacement regulating portion 25 that is disposed on the side opposite to the connector mounting surface 10a of the circuit board 10 with the regulated projection 35 of the lock piece opposing portion 31 interposed therebetween, thereby regulating the lock piece opposing portion 31 from being elastically displaced in the direction away from the connector mounting surface 10a of the circuit board 10. According to the structure described above, when the plug connector 2 is intentionally inclined so that the wires 6 approach the connector mounting surface 10a of the circuit board 10, the receptacle lock surface 38 is rapidly pushed out by the unlocking surface 66 in the direction away from the plug side surface 50a.
In this embodiment, the displacement regulating portion 25 is formed at the side portion 17 of the side surface opposing portion R, but instead may be formed at, for example, the lock piece held portion 30 of the assistant fitting 9 of the side surface opposing portion R.
(9) The lock piece held portion 30 and the lock piece opposing portion 31 are formed so as to extend in the wire direction. The above-mentioned structure contributes to a reduction in the height of the wire-to-board connector 1.
(10) An end in the wire connector direction of the lock piece held portion 30 and an end in the wire connector direction of the lock piece opposing portion 31 are coupled together.
(11) The plug housing 5 is provided with the releasing projection 51 that allows the plug connector 2 to be inclined so that the wires 6 approach the connector mounting surface 10a of the circuit board 10.
(12) The releasing projection 51 is formed so as to protrude in the wire connector direction from an end in the wire connector direction of the plug housing 5.
The preferred embodiment of the present invention described above can be modified in the following manner, for example.
In the embodiment described above, the unlocking surface 66 of the plug lock surface 60 is formed as a flat surface, but instead may be formed as a curved surface that is curved so as to approach the connector mounting surface 10a of the circuit board 10 in a direction away from the plug side surface 50a as shown in
Upon assembly of the receptacle connector 3, the assistant fittings 9 are positioned relative to the respective side portions 17, and the assistant fittings 9 are pushed in the board approaching direction. However, instead, the assistant fittings 9 may be pushed in the board separating direction. That is, upon attachment of the assistant fittings 9 to the respective side portions 17, the attachment direction is not limited to the board approaching direction.
A second embodiment of the present invention will be described below with reference to
As shown in
To avoid such a problem, in the first embodiment described above, a gap “i” is left between the plug side surface 50a of the plug housing body 50 of the plug housing 5 of the plug connector 2 and the lock piece opposing portion 31 of the assistant fitting 9 of the receptacle connector 3 in the mated state of the wire-to-board connector 1.
However, due to the presence of the gap “i”, the movement of the plug housing 5 of the plug connector 2 in the connector width direction is allowed within the receptacle connector 3 in the mated state of the wire-to-board connector 1 shown in
As shown in
Specifically, as shown in
Since each overhanging portion 80 is formed at a location as far as possible from the corresponding positioning projection 52 as shown in
Next, a third embodiment of the present invention will be described with reference to
As shown in
In this structure, as shown in
This application is based upon and claims the benefit of priority from Japanese patent application No. 2012-072085, filed on Mar. 27, 2012, and Japanese patent application No. 2012-247408, filed on Nov. 9, 2012, the disclosure of which is incorporated herein in its entirety by reference.
Number | Date | Country | Kind |
---|---|---|---|
2012-072085 | Mar 2012 | JP | national |
2012-247408 | Nov 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2013/000707 | 2/8/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2013/145527 | 10/3/2013 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
7329158 | Roberts et al. | Feb 2008 | B1 |
9039429 | Shimoji | May 2015 | B2 |
20060094305 | Masaki et al. | May 2006 | A1 |
20080305668 | Wu | Dec 2008 | A1 |
20140302694 | Qiao | Oct 2014 | A1 |
Number | Date | Country |
---|---|---|
2006-128032 | May 2006 | JP |
2006-128034 | May 2006 | JP |
4020907 | Oct 2007 | JP |
Entry |
---|
International Search Report dated Apr. 2, 2013 from corresponding International Patent Application No. PCT/JP2013/000707; 1 pg. |
Number | Date | Country | |
---|---|---|---|
20150155658 A1 | Jun 2015 | US |