This Paris Convention Patent Application claims benefit under 35 U.S.C. § 119 and claims priority to Japanese Patent Application No. JP 2017-154393, filed on Aug. 9, 2017, titled “ELECTRICAL CONNECTOR FOR CIRCUIT BOARDS AND METHOD OF MANUFACTURE THEREOF”, the content of which is incorporated herein in its entirety by reference for all purposes.
The present disclosure relates to an electrical connector for circuit boards connected to a counterpart connector component while being mounted to a circuit board, as well as to a method of manufacture thereof.
In this type of connector, its housing, in which terminals are secured in place, is rigidly mounted to a circuit board, and a counterpart connector component, such as a counterpart connector, a counterpart board, or the like, is inserted into a receiving portion formed in said housing. The connecting portions of the terminals, which are formed at one end of said terminals, are solder-connected to corresponding circuitry on the circuit board, and contact portions, which are formed at the other end, are placed in contact with a counterpart connector component under contact pressure. The terminals are often molded integrally with the housing via unitary co-molding in order to simplify the manufacture of the connector and increase the holding power of the housing.
In Patent Document 1, the terminals are secured in place by unitary co-molding with the housing. In this Patent Document 1, the housing is formed such that it is divided into two sections: a stationary housing (pedestal) and a movable housing (terminal box portion). The stationary housing secures one end of the terminals in place and is mounted to a circuit board, and the movable housing, which is positioned above and spaced apart from the stationary housing, has the other end of the terminals secured in place.
In the connector of Patent Document 1, the terminals are not supported in any way in the region between the stationary and movable housings, and the portions of said terminals located in this region are resilient portions capable or resilient flexural deformation when acted upon by an external force. In this connector of Patent Document 1, in order to ensure mating with the receiving portion and contact with the above-mentioned contact portions even if the counterpart connector component is offset from the normal position with respect to the contact portions of the terminals disposed in the movable housing, the offset is absorbed by resilient flexural deformation of the resilient portions of the above-mentioned terminals.
[Patent Document 1] Japanese Patent No. 3976454
There is a need to provide an electrical connector for circuit boards that makes it possible to readily obtain different connectors of different heights and that is fully capable of withstanding external forces, as well as a method of manufacture thereof.
Since in Patent Document 1 the stationary and movable housings are formed so as to be spaced apart in the direction of connection to the counterpart connector component (in a vertical direction perpendicular to the surface of the circuit board), in addition to the advantage of being able to absorb the above-mentioned offset, there is another advantage in that different connectors with different connector height dimensions in the above-mentioned direction of connection can be obtained by simply changing the length settings of the resilient portions of the terminals.
However, in the case of ordinary connectors, which do not require absorbing the above-mentioned offset, an attempt to obtain different connectors of different height by dividing the housing in two and spacing the halves apart, as described in Patent Document 1, results in a considerable reduction in holding power between the terminals and inability to withstand exposure to external forces.
In view of these circumstances, it is an object of the present disclosure to provide an electrical connector for circuit boards that makes it possible to readily obtain different connectors of different heights and that is fully capable of withstanding external forces, as well as a method of manufacture thereof.
According to the present disclosure, the above-described problem is solved by the following electrical connector for circuit boards according to a first example implementation and a method of manufacture of an electrical connector for circuit boards according to a second example implementation.
The electrical connector for circuit boards according to the first example implementation involves terminals having formed therein connecting portions configured to be connected to a circuit board at one end in the longitudinal direction of said terminals and contact portions configured to be placed in contact with a counterpart connector component at the other end, and a housing holding a plurality of said terminals in place in array form, with said housing having disposed therein the contact portions of the above-mentioned terminals.
Such an electrical connector for circuit boards according to the first example implementation is characterized in that the housing is formed such that it is divided into a receiving-side housing, which accommodates the contact portions of the above-mentioned terminals and receives a counterpart connector component such that said counterpart connector component is placed in contact with the above-mentioned contact portions, and a board-side housing, which holds the above-mentioned terminals in place in sections more proximal to the connecting portions than to the above-mentioned contact portions and which is mounted to a circuit board, and in that the receiving-side housing and the board-side housing are molded as a single unit.
Since of the two housings that have been formed in a divided manner, i.e., the receiving-side housing and the board-side housing, it is the receiving-side housing that accommodates the contact portions of the above-mentioned terminals, its structure is more complicated and requires a higher level of dimensional accuracy. On the other hand, since merely securing a portion of the receptacle terminals is sufficient, the board-side housing has a simple structure and does not require a high level of dimensional accuracy. In the first example implementation, when the height dimension settings of the entire housing are changed, this is achieved by changing the height of the above-mentioned board-side housing. For this reason, the height dimension of the connector becomes readily modifiable. In addition, in the first example implementation, when the connector is manufactured, the contact portions of the terminals are placed in the receiving-side housing, whereupon the board-side housing, in which the terminals are secured in place at locations more proximal to the connecting portions than to said contact portions, is molded as a single unit with the above-mentioned receiving-side housing. Therefore, an electrical connector for circuit boards is obtained in which the holding power between the terminals and the housing is increased.
The method of manufacture of an electrical connector for circuit boards according to the second example implementation is a method of manufacture of an electrical connector for circuit boards wherein the connector includes terminals having formed therein connecting portions configured to be connected to a circuit board at one end in the longitudinal direction of said terminals and contact portions configured to be placed in contact with a counterpart connector component at the other end, and a housing holding a plurality of said terminals in place in array form, with said housing having disposed therein the contact portions of the above-mentioned terminals.
Such a method of manufacture according to the second example implementation is characterized by the fact that after molding the receiving-side housing, which receives the counterpart connector component, while the contact portions of the terminals are accommodated in said receiving-side housing, the board-side housing, which holds the above-mentioned terminals in place in sections more proximal to the connecting portions than to the above-mentioned contact portions and which is mounted to a circuit board, is formed via integral molding with the above-mentioned terminals and the above-mentioned receiving-side housing, such that the above-mentioned receiving-side housing and the above-mentioned board-side housing form an integrated housing.
In the second example implementation, in the same manner as in the previously discussed first example implementation, varying the height of the board-side housing, which is structurally simpler and does not require a high level of dimensional accuracy, allows for the height dimension of the connector to be easily modified. In addition, integrating the above-mentioned receiving-side housing and the above-mentioned board-side housing into a single unit makes it possible to increase the holding power between the terminals and the housing.
In the second example implementation, after placing the contact portions of the above-mentioned terminals in the above-mentioned receiving-side housing, the protruding sections of the terminals protruding from said receiving-side housing may be bent at arbitrary locations in the direction of protrusion, thereby forming connecting portions configured to be connected to a circuit board and, moreover, the above-mentioned board-side housing, whose height dimension corresponds to the length of the above-mentioned protruding sections between the locations of protrusion from the receiving-side housing to the locations of the bend, may be formed via integral molding of the protruding sections of the above-mentioned terminals and the above-mentioned receiving-side housing.
In accordance with such a second example implementation, if the above-mentioned protruding sections of the terminals are bent at heightwise locations corresponding to the height dimension of the board-side housing, terminals provided in many types of connectors of different heights can be made from a single type of stock material and increases in manufacturing costs can be minimized accordingly.
In addition, in the second example implementation, when molding the above-mentioned receiving-side housing, said receiving-side housing is molded integrally with anchor fittings configured for mounting to a circuit board. After the integral molding, anchoring portions configured for connecting to the circuit board are formed by bending the protruding sections of the above-mentioned anchor fittings protruding from the above-mentioned receiving-side housing at arbitrary locations in the direction of protrusion. Moreover, the above-mentioned board-side housing, whose height dimension corresponds to the length of the above-mentioned protruding sections between the locations of protrusion from the receiving-side housing to the locations of the bend, may be formed via integral molding of the protruding sections of the above-mentioned anchor fittings and the above-mentioned receiving-side housing.
In accordance with such a second example implementation, if the above-mentioned protruding sections of the terminals are bent at heightwise locations corresponding to the height dimension of the board-side housing, anchor fittings provided in many types of connectors of different heights can be made from a single type of stock material and increases in manufacturing costs can be minimized accordingly.
In the present disclosure, as described above, the housing, which has the terminals secured in place therein, is divided into the receiving-side housing, which is structurally complex and requires a high level of dimensional accuracy in order to accommodate the contact portions of the terminals, and the board-side housing, which is structurally simple and does not require a high level of dimensional accuracy because it simply needs to have the terminals secured in place therein, and the two housings are then integrally molded. For this reason, it is sufficient to change dimensions only in the structurally simple board-side housing when making design modifications. Accordingly, other types of connectors of various height dimensions and configurations can be readily obtained at low cost. Moreover, since both housings are mutually integrated into a single unit via integral molding, it is possible to not only reinforce the housings themselves, but also strengthen the holding force between terminals.
As indicated below, example implementations of the present disclosure will be described with reference to the accompanying drawings.
In the example implementation described herein, a connector assembly is formed by a plug connector 1 serving as an electrical connector for circuit boards disposed on the mounting face of a connector assembly circuit board (not shown) and a receptacle connector 2 serving as an electrical connector for circuit boards disposed on the mounting face of another circuit board (not shown). The two connectors are inserted and extracted such that the two mounting faces of the first and second circuit boards are arranged in a mutually parallel orientation and the direction perpendicular to the said mounting faces (vertical direction) is the direction of connector insertion and extraction. Specifically, as can be seen in
The plug connector 1 has a plug housing 10, which extends such that a direction parallel to the mounting face of the circuit board is its longitudinal direction; plug signal terminals 40 and plug power supply terminals 50 (referred to as the “plug terminals 40, 50” below for brevity when there is no need to distinguish the two), which are arranged and held in place in the plug housing 10 such that said longitudinal direction is the terminal array direction; and retaining fittings 60, abutment fittings 70, and anchor fittings 80, which are held in place in the plug housing 10 on the outside of the terminal array range in the direction of the terminal array. In addition, the plug housing 10 includes stationary housings 20 mounted to the circuit board by means of the plug terminals 40, 50; and a movable housing 30 formed as a member that is separate from said stationary housings 20 and is movable relative to said stationary housings 20.
In this example implementation, the plug connector 1 is made to be symmetrical in the connector width direction, i.e., in a direction parallel to the surface of the circuit board, which is also a transverse direction perpendicular to the above-mentioned longitudinal direction. The stationary housings 20, which are made of an electrically insulating material, are formed in the shape of plates extending in the above-mentioned longitudinal direction as members separate from said movable housing 30 in locations spaced apart from said movable housing 30 on both sides of the lower half of the movable housing 30 in the width direction of the connector, with their major faces disposed at right angles to the connector width direction. The respective stationary housings 20 on both sides of the movable housing 30 are also formed as separate members.
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Although the stay portion 32 extends downwardly from the bottom wall 31C of the mating portion 31, in which the receiving portion 33 is formed, to the vicinity of the surface of the circuit board, it is not secured to said circuit board, such that the entire movable housing 30 is movable in the width direction, length direction, and vertical direction of the connector when acted upon by external forces.
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The signal-type connecting portions 41 extend outwardly in the connector width direction so as to be located on the upper face of the circuit board. In addition, the plug signal terminals 40 have stationary-side retained portions 44 that are bent in the sections adjacent to said signal-type connecting portions 41 and extend upwardly. Said stationary-side retained portions 44 are embedded in the stationary housings 20 and held in place as a result of being molded integrally with said stationary housings 20. In other words, the stationary housings 20 have formed therein stationary-side retaining portions for the stationary-side retained portions 44. The above-mentioned signal-type connecting portions 41 are located below the bottom faces of the stationary housings 20 and extend outwardly in the connector width direction along said bottom faces.
On the other hand, the inverted U-shaped insertion portions 42, which are located higher than the stationary-side retained portions 44, extend in an inverted U-shaped configuration along the inner lateral faces, upper faces, and outer lateral faces of the side walls 31A of the movable housing 30 and maintain surface contact with said inner lateral faces, upper faces, and outer lateral faces. As can be seen in
In addition, the upper end curved portions 42C that couple the upper ends of the signal-type inner contact portions 42A and signal-type outer contact portions 42B are curved convexly upward, and their upper faces and, in particular, the inside upper faces located on the inside in the connector width direction of said upper end curved portions 42C form surfaces at substantially the same level as the upper faces of the above-mentioned side walls 31A, thereby forming guiding lead-in surfaces for the receptacle connector 2.
Since in the present example implementation the inverted U-shaped insertion portions 42 extend along the inner lateral faces, upper faces, and outer lateral faces of the side walls 31A in surface contact with said inner lateral faces, upper faces, and outer lateral faces, when the connectors are in a mated state, the signal-type inner contact portions 42A and signal-type outer contact portions 42B can be sufficiently resistant to contact pressure during contact with the receptacle signal terminals 120 of the receptacle connector 2.
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The horizontal resilient portion 43A, which is capable of resilient displacement in the vertical direction, resiliently flexes in response to vertical movement of the movable housing 30. Accordingly, when the movable housing 30 is mated with the receptacle connector 2 in the receiving portion 33 and the movable housing 30 is positioned with an offset relative to the stationary housings 20, for example, relative to the normal position in the vertical direction, the above-mentioned offset is absorbed by the resilient displacement of the above-mentioned horizontal resilient portions 43A in the vertical direction, resulting in so-called floating. In addition, since in the present example implementation the horizontal resilient portions 43A are at the same level as the upper ends of the stationary housings 20 in the vertical direction and do not protrude upwardly above the stationary housings 20, the risk of a finger or another external object touching said horizontal resilient portions 43A can be made extremely low.
While in the present example implementation the horizontal resilient portions 43A are designed to extend parallel to the mounting face of the circuit board, they do not necessarily have to be parallel to said mounting face and may extend at an angle with respect to said mounting face. In other words, it is sufficient for the horizontal resilient portions 43A to extend such that some element thereof is parallel to the mounting face of the circuit board. In addition, while in the present example implementation the horizontal resilient portions 43A are designed to be parallel to the mounting face throughout their entire length, as an alternative, for example, a longitudinally intermediate portion of the horizontal resilient portions may be bent such that only part thereof in said longitudinal direction is made parallel to the mounting face while other parts may be inclined with respect to the mounting face. In addition, while in the present example implementation the horizontal resilient portions 43A are at the same level as the upper ends of the stationary housings 20, as an alternative, they may be provided, for example, in locations that are somewhat lower than the upper ends of the stationary housings 20, i.e., in locations proximal to the upper ends (top portion locations).
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In the present example implementation, the horizontal resilient portions 43A of the plug signal terminals 40 extend from the stationary-side retained portions 44 (at the level of the upper ends of the stationary housings 20) inwardly in the connector width direction parallel to the surface of the circuit board. In other words, the horizontal resilient portions 43A are positioned separately from the movable housing 30 in the connector width direction. Accordingly, the horizontal resilient portions 43A undergo considerable resilient flexure in response to the vertical movement of the movable housing 30. As a result, the amount of offset that can be absorbed in the vertical direction increases.
In addition, while the curved resilient portions 43B are more proximal to the movable housing 30 in the connector width direction than the horizontal resilient portions 43A, the amount of resilient flexure of said curved resilient portions 43B in directions parallel to the surface of the circuit board (in the connector width direction and in the terminal array direction) is determined by the dimensions of said curved resilient portions 43B in the vertical direction and does not vary depending on position in the connector width direction. Therefore, the amount of offset that can be absorbed by the curved resilient portions 43B in directions parallel to the surface of the circuit board is ensured without being affected by the position of the curved resilient portions 43B.
In addition, since in the present example implementation the curved resilient portions 43B are located below the inverted U-shaped insertion portions 42, the flexible arm length (dimensions in the vertical direction) of the curved resilient portions can be configured to be longer, and, therefore, the amount of resilient deformation of the curved resilient portions 43B in directions parallel to the surface of the circuit board can be increased.
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Between power supply-type connecting portions 51 and inverted U-shaped insertion portions 52, the plug power supply terminals 50 have power supply-type resilient portions 53 that couple the two. Said power supply-type resilient portions 53, in other words, the horizontal resilient portions 53A and curved resilient portions 53B, are divided into multiple (four in the present disclosure) narrow resilient portions 54 with the help of slits formed in multiple locations in the terminal array direction. The arrangement pitch dimensions of the multiple narrow resilient portions 54 are all the same and smaller than the arrangement pitch dimensions of the multiple plug signal terminals 40. In addition, the arrangement pitch dimensions of the multiple narrow resilient portions 54 are smaller than the arrangement pitch dimensions of the hereinafter-described receptacle power supply terminals 130 provided in the receptacle connector 2. The portions that are divided in the plug power supply terminals 50 are the power supply-type resilient portions 53, in other words, in the plug power supply terminals 50 parts other than the narrow resilient portions 54 of the power supply-type resilient portions 53 are continuous in the terminal array direction and constitute a single member.
Although in the present example implementation all the arrangement pitch dimensions of the multiple narrow resilient portions 54 are designed to be the same, as an alternative, the arrangement pitch dimensions may be different for some or all of the multiple narrow resilient portions 54. In addition, although in the present example implementation adjacent narrow resilient portions 54 are designed to be spaced apart from each other throughout their entire extent in the longitudinal direction, as an alternative, they may be partly interconnected in said longitudinal direction.
In the present example implementation, the spacing of the pairs of multiple narrow resilient portions 54 in the power supply-type resilient portions 53 is narrower than the gaps between the pairs of signal-type resilient portions 43 in the multiple plug signal terminals, and it is therefore possible to correspondingly increase the number of the narrow resilient portions 54 or make the cross-sectional area of each narrow resilient portion 54 larger. As a result, the cross-sectional area of the power supply-type resilient portions 53, in other words, the total cross-sectional area of the multiple narrow resilient portions 54, is increased, thus making it possible to pass a larger current that is proportional to the amount of the increase. Moreover, as a result of reducing the arrangement pitch dimensions of the narrow resilient portions 54, the width of each narrow resilient portion 54 can also be reduced and a resilience equal to or greater than that of the signal-type resilient portions 43 can be ensured in the power supply-type resilient portions 53.
Further, since in the present example implementation the inverted U-shaped insertion portions 52 are not divided in the terminal array direction and the power supply-type inner contact portions 52A and power supply-type outer contact portions 52B of the inverted U-shaped insertion portions 52 have a single surface of contact extending in a continuous manner in the terminal array direction, a larger current can be passed by increasing the number of the narrow resilient portions 54 or by expanding the cross-sectional area of each narrow resilient portion 54 regardless of the arrangement pitch dimensions of the plug signal terminals 40. In addition, the number of the hereinafter-described receptacle power supply terminals 130, which serve as counterpart terminals, can be selected regardless of the number of the narrow resilient portions 54 and, furthermore, high resilience can be ensured regardless of the number of the receptacle power supply terminals 130.
In addition, since the plug power supply terminals 50 are of substantially equal width throughout their entire length, even though the width dimensions (dimensions in the terminal array direction) of the plug power supply terminals 50 are not locally increased, their width dimensions can be generally kept to a minimum and their width can be efficiently used and, furthermore, the resilience of the power supply-type resilient portions 53 can be ensured.
Furthermore, since the plug power supply terminals 50 are of the same configuration as the above-mentioned signal terminals when viewed in the terminal array direction, the same fittings can be used to bend the plug signal terminals 40 and the plug power supply terminals 50 when the plug connector 1 is manufactured. In addition, since the plug power supply terminals 50 are arranged at the same level as the above-mentioned signal terminals when viewed in the terminal array direction, the signal-type resilient portions 43 and power supply-type resilient portions 53 are in the same plane when viewed in the direction of the terminal array and, as a result, in the entire plug connector 1, the resilient flexural deformation used for floating in the plug signal terminals 40 and the plug power supply terminals 50 can be more easily generated.
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The retaining portions 62 have a pair of resilient clamping pieces 62A resiliently displaceable in the connector width direction, which extend upward and have their major faces opposed in said connector width direction. As can be seen in
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Due to the fact that in the present example implementation the abutment surfaces 72A of the abutment portions 72 of the abutment fittings 70 are positioned so as to be exposed on the bottom face of the movable housing 30, it is not the movable housing 30 but the abutment surfaces 72A of the abutment fittings 70 that abut the circuit board when the receptacle connector 2 is pushed into the movable housing 30 with a substantial force. Therefore, the movable housing 30 itself never abuts the circuit board and, as a result, damage to said movable housing 30 is prevented. In addition, since in the present example implementation the abutment surface 72A of the above-mentioned abutment portions 72 is a major face (rolled surface) of the sheet metal member, when the movable housing 30 moves in a direction parallel to the circuit board and absorbs offset in the same direction, the abutment portions 72 can be smoothly placed in sliding contact with the surface of the circuit board.
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Along with coupling the two stationary housings 20, the thus configured anchor fittings 80 anchor these stationary housings 20 to said circuit board as a result of being solder-connected to the circuit board by the anchoring portions 83.
The steps involved in the manufacture of the plug connector 1 will be described next with reference to
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Next, once the plug terminal blanks P1, P2 and reinforcing fitting blank P3 are positioned in the mold, a molten electrically insulating material (plastic, etc.) is injected into and solidified in the mold, thereby molding the stationary housings 20 and the movable housing 30. As a result, as can be seen in
Next, plug terminals 40, 50 are formed by removing the carriers from each of the plug terminal blanks P1, P2. In addition, retaining fittings 60, abutment fittings 70, and anchor fittings 80 are formed by removing the carrier and the coupling section P3A from the reinforcing fitting blank P3. As shown with dashed lines in
In addition, since in the present example implementation the two lateral overhang portions 73 of the abutment fittings 70 are located below the coupling portion 82 of the anchor fitting 80, even if the movable housing 30 is moved in a direction parallel to the circuit board, said two lateral overhang portions 73 never abut the coupling portion 82 and, therefore, damage to said lateral overhang portions 73 and coupling portion 82 can be reliably prevented.
In addition, in the present example implementation, the edge overhang portion 63 of the retaining fitting 60 is located at the same height as the coupling portion 82 of the anchor fitting 80. However, as can be seen in
In this manner, the removal of the carriers from the plug terminal blanks P1, P2 and the removal of the carrier and coupling section P3A from the reinforcing fitting blank P3 completes the fabrication of the plug connector 1.
In the present example implementation the retaining fittings 60, the abutment fittings 70, and anchor fittings 80 are simultaneously formed as a result of removing the above-mentioned coupling section P3A in a state in which a single metal reinforcing fitting blank P3 is held in place in the stationary housings 20 and in the movable housing 30, thereby ensuring excellent accuracy of relative positioning of the retaining fittings 60, abutment fittings 70, and anchor fittings 80. In addition, since the reinforcing fitting blank P3 is made of metal, the cut surfaces produced are smooth surfaces superior to those produced, for example, when cutting blanks made of a glass fiber-containing plastic, and there is almost no debris from cutting and any cutting debris is easy to handle. In addition, the cutting blade (not shown) does not get damaged and, furthermore, since the cut surfaces of the reinforcing fitting blank P3 are smooth, the dimensional accuracy of the movable-side reinforcing fittings and stationary-side reinforcing fittings is also excellent.
The configuration of the receptacle connector 2 will be described next. As can be seen in
The receptacle housing 90 is divided into a receiving-side housing 100, which holds the hereinafter-described inverted U-shaped receiving portions 121, 131 of the receptacle terminals 120, 130 and receives the plug connector 1, and a board-side housing 110, which holds receptacle terminals 120, 130 in place in locations more proximal to the hereinafter-described connecting portions 124, 134 than to the above-mentioned inverted U-shaped receiving portions 121, 131 and which is mounted to the above-mentioned other circuit board, with the receiving-side housing 100 and board-side housing 110 molded as a single piece.
The receiving-side housing 100 is made symmetrical in the connector width direction, which is a direction parallel to the surface of the other circuit board and which is a transverse direction perpendicular to the above-mentioned longitudinal direction. As can be seen in
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Since in the present example implementation the receptacle housing 90 is divided into a receiving-side housing 100 and a board-side housing 110, when the height dimension settings of the entire receptacle housing 90 are changed, this can be achieved by changing the height dimension of the above-mentioned board-side housing 110. For example, although in the present example implementation the height dimension of the board-side housing 110 is designed to be sufficient for said entire board-side housing 110 to be accommodated in the bottom recessed portion 103A of the receiving-side housing 100, if an increase in the height dimension of the receptacle housing 90 becomes desirable, this can be easily addressed without changing the receiving-side housing 100 by providing a board-side housing of a different type with a larger height dimension instead of the board-side housing 110 and molding it as a single piece with the receiving-side housing 100.
In addition, since of the two housings, i.e., the receiving-side housing 100 and the board-side housing 110, it is the receiving-side housing 100 that accommodates the contact portions of the receptacle terminals 120, 130, its structure is more complicated and requires a higher level of dimensional accuracy. On the other hand, since merely securing a portion of the receptacle terminals 120, 130 is sufficient, the board-side housing 110 has a simple structure and does not require a high level of dimensional accuracy. Therefore, replacing only the board-side housing 110 with another board-side housing having a different height dimension without changing the receiving-side housing 100, as discussed above, makes it possible to minimize increases in manufacturing costs.
The receptacle signal terminals 120 and receptacle power supply terminals 130 are fabricated with the same shape and are arranged at equal intervals to match the arrangement pitch dimensions of the plug signal terminals 40 in the terminal array direction. In the present example implementation, there are four receptacle signal terminals 120 and three receptacle power supply terminals 130.
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The inverted U-shaped receiving portions 121 have a base portion 121A, which extends in the connector width direction within the bottom groove portion 106C; a signal-type inner arm portion 121B, which extends downwardly from the inward end of said base portion 121A in the connector width direction through the inner groove portion 106B; and a signal-type outer arm portion 121C, which extends downwardly from the outboard end of said base portion 121A in the connector width direction through the outer groove portion 106A and is coupled to the above-mentioned transitional portion 122. The signal-type inner arm portion 121B and signal-type outer arm portion 121C are capable of resilient displacement in the respective through-thickness direction (connector width direction).
The signal-type inner arm portion 121B has a signal-type inner contact portion 121B-1 that is curved convexly outward in the connector width direction at a location proximal to its lower end. The signal-type outer arm portion 121C has a signal-type outer contact portion 121C-1 that is curved convexly inward in the connector width direction at a location proximal to its lower end (at substantially the same level in the vertical direction as the signal-type inner contact portion 121B-1). The signal-type inner contact portion 121B-1 and the signal-type outer contact portion 121C-1 both have curved apex portions that protrude from the inner groove portions 106B and the outer groove portions 106A and are located within the mating concave portion 105. As can be seen in
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Since, as discussed previously, the receptacle power supply terminals 130 are of the same shape as the receptacle signal terminals 120 and are denoted by like reference numerals obtained by adding “10” to the reference numerals of each component of the receptacle signal terminals 120, and thus their configuration is not further discussed herein. In such instances, it is presumed that the term “signal-type” in the designation of each component would be read as “power supply-type”.
In the present example implementation, the three receptacle power supply terminals 130 provided in the receptacle connector 2 are positioned such that they correspond to a single plug power supply terminal 50 of the plug connector 1 (see
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Next, the steps involved in the manufacture of the receptacle connector 2 will be described with reference to
Next, a receiving-side housing 100 is molded by injecting a molten electrically insulating material (plastic, etc.) into the mold and solidifying it therein. As a result, the reinforcing fitting blanks P4 are molded integrally with the receiving-side housing 100.
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Thus, in the present example implementation, as a result of providing long strip-like pieces P4A, P4B in the reinforcing fitting blanks P4, when the height dimension of the board-side housing 110 is modified in response to a change in the height dimension settings of the entire receptacle housing 90, the anchoring portions 143, 152 can be formed by bending the strip-like pieces P4A, P4B at locations (locations in the longitudinal direction of the strip-like pieces P4A, P4B) corresponding to the modified height dimension of the board-side housing 110. Consequently, in accordance with the present example implementation, the retained fittings 140 and anchor fittings 150 provided in many types of connectors of different heights can be made from a single type of stock material and increases in manufacturing costs can be minimized accordingly.
Next, the inverted U-shaped receiving portions 121, 131 of carrier-equipped receptacle terminal blanks P5 are received in the terminal holding portion 106 of the receiving-side housing 100 from the side of the bottom wall 103 of said receiving-side housing 100 (bottom side in
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Thus, in the present example implementation, as a result of providing long thin strips P5A in the receptacle terminal blanks P5, when the height dimension of the board-side housing 110 is modified in response to a change in the height dimension settings of the entire receptacle housing 90, the connecting portions 124, 134 can be formed by bending the thin strips P5A at locations (locations in the longitudinal direction of the thin strips P5A) corresponding to the modified height dimension of the board-side housing 110. Consequently, in accordance with the present example implementation, the receptacle terminals 120, 130 provided in many types of connectors of different heights can be made from a single type of stock material and increases in manufacturing costs can be minimized accordingly.
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The operation of mating the plug connector 1 and the receptacle connector 2 will be described next with reference to
First, the plug connector 1 and the receptacle connector 2 are respectively mounted to corresponding circuit boards (not shown). Specifically, in the plug connector 1, the connecting portions 41, 51 of the plug terminals 40, 50 are solder-connected to the corresponding circuitry of a circuit board, and the anchoring portions 83 of the anchor fittings 80 are solder-connected to the corresponding portions of this circuit board. In addition, in the receptacle connector 2, the connecting portions 124, 134 of the receptacle terminals 120, 130 are solder-connected to the corresponding circuitry of another circuit board, and the anchoring portions 143 of the retained fittings 140 and the anchoring portions 152 of the anchor fittings 150 are solder-connected to the corresponding portions of this other circuit board.
In this state, as can be seen in
In the process of connector mating, when the receptacle connector 2 is pushed into the movable housing 30 of the plug connector 1 from above, the movable housing 30 travels downwardly as a result of resilient displacement of the horizontal resilient portions 43A, 53A of the plug terminals 40, 50. Due to the fact that in the present example implementation the abutment portions 72 of the abutment fittings 70 are exposed on the bottom face of the movable housing 30, it is not the bottom face of the movable housing 30 but the abutment portions 72 of the above-mentioned abutment fittings 70 that abut the mounting face of the circuit board with the abutment surfaces 72A. As a result, the movable housing 30 never abuts the circuit board and damage to the movable housing 30 is prevented.
When the connectors are in a mated state, the inverted U-shaped insertion portions 42, 52 of the plug terminals 40, 50 enter the inverted U-shaped receiving portions 121, 131 of the receptacle terminals 120, 130 from below and are clamped by the contact portions 121B-1, 121C-1, 131B-1, 131C-1 of said inverted U-shaped receiving portions 121, 131 in the connector width direction. In such a clamped state, the receptacle signal terminals 120 have their signal-type contact portions 121B-1, 121C-1 brought into contact with the signal-type contact portions 42A, 42B of the plug signal terminals 40 under contact pressure and, in addition, receptacle power supply terminals 130 have their power supply-type contact portions 131B-1, 131C-1 brought into contact with the power supply-type contact portions 52A, 52B of the plug power supply terminals 50 under contact pressure (see
In addition, as can be seen in
In the present example implementation, the retaining fittings 60 and the retained fittings 140 are located outside of the terminal array range, with the pair of resilient clamping pieces 62A of the retaining fittings 60 clamping and holding the retained plate portions 142A of the retained fittings 140. Thus, the retaining fittings 60 and the retained fittings 140 are provided in the vicinity of the ends of the connectors 1, 2 in the terminal array direction. In other words, when viewed in the vertical direction, they are located sufficiently far from the vertical axes (axial lines extending in the vertical direction) passing through the mid-width locations of each respective connector 1, 2, as well as the horizontal axes (axial lines extending in the connector width direction) passing through the central locations in the terminal array direction of the connectors 1, 2. As a result, the connectors can withstand torque that may be inadvertently generated about the above-mentioned vertical axes and about the above-mentioned horizontal axes and can sufficiently maintain a state of contact between terminals.
The mating position of the receptacle connector 2 with respect to the plug connector 1 is not necessarily limited to the normal position in the terminal array direction, connector width direction, and vertical direction. Since the receptacle connector 2 is mounted to a circuit board and the view of the plug connector 1 is shielded by this circuit board, mating in a position offset from the above-mentioned normal position is likely to occur. In the present example implementation, the offset of the connectors 1, 2 is absorbed by the movement of the movable housing 30 in the direction of offset as a result of resilient displacement of the resilient portions 43, 53 of the plug terminals 40, 50. Specifically, offset in the vertical direction is primarily absorbed by the resilient displacement of the horizontal resilient portions 43A, 53A of the above-mentioned resilient portions 43, 53. In addition, offset in the terminal array direction and in the connector width direction is absorbed by the resilient displacement of the curved resilient portions 43B, 53B of the above-mentioned resilient portions 43, 53.
If the height dimension settings of the entire receptacle housing 90 in the receptacle connector according to the present example implementation are changed, the issue can be readily addressed by simply changing the height dimension of the board-side housing. An example implementation utilizing a board-side housing with a larger height dimension than that of the board-side housing 110 of the present example implementation will be described below with reference to
The receptacle connector 2′ according to this variation differs from the configuration of the previously described example implementation in that: the hereinafter-described board-side housing 110′ is formed to have a larger height dimension than the board-side housing 110 of the previously described example implementation; the retained arm portions of the receptacle terminals 120′, 130′ are formed to be longer than the retained arm portions 123, 133 of the receptacle terminals 120, 130 of the previously described example implementation; and each of the retained fittings 140′ and anchor fittings 150′ has an extension portion whose length corresponds to the height dimension of the board-side housing 110′. The discussion below will focus on differences from the configuration of the previously described example implementation.
The board-side housing 110′ used in the variation illustrated in
The board-side housing 110′ has two lateral walls 111′ that extend in the direction of the terminal array and end walls 112′ that extend in the connector width direction and couple the ends of the two lateral walls 111. The dimensions of said board-side housing 110′ in the vertical direction (height dimension) are set in accordance with the height dimension settings of the entire receptacle housing 90.
In the receptacle signal terminals 120′, the rectilinear sections extending in the vertical direction in the retained arm portions 123 of the receptacle terminals 120 used in the previously described example implementation illustrated in
The retained fittings 140′ are shaped so as to couple the anchoring portions 143 and mounting portions 141 of the retained fittings 140 in the previously described example implementation illustrated in
The reinforcing fitting blanks P4 and receptacle terminal blanks P5 used in the previously described example implementation can be utilized “as is” in the fabrication steps of the receptacle connector 2′ of this variation. In addition, the order of fabrication steps is also the same as the order of fabrication steps of the receptacle connector 2 in the previously described example implementation.
In the variation, the strip-like pieces P5A of the receptacle terminal blanks P5 (see
In addition, in the variation, the strip-like pieces P4A of the reinforcing fitting blanks P4 (see
1 Plug connector
2 Receptacle connector
10 Plug housing
20 Stationary housing
30 Movable housing
31 Mating portion
33 Receiving portion
40 Plug signal terminal
41 Signal-type connecting portion
42 Inverted U-shaped insertion portion (movable-side retained portion)
42A Signal-type inner contact portion
42B Signal-type outer contact portion
43 Signal-type resilient portion
43A Horizontal resilient portion
43B Curved resilient portion
44 Stationary-side retained portion
50 Plug power supply terminal
51 Power supply-type connecting portion
53 Power supply-type resilient portion
53A Horizontal resilient portion
53B Curved resilient portion
54 Narrow resilient portion
60 Retaining fitting
61 Mounting portion
62 Retaining portion
62A Resilient clamping piece
63 Edge overhang portion
70 Abutment fitting
72 Abutment portion
72A Abutment surface
73 Lateral overhang portion
80 Anchor fitting
82 Coupling portion (exposed portion)
90 Receptacle housing
100 Receiving-side housing
110 Board-side housing
120 Receptacle signal terminal
121B-1 Signal-type inner contact portion
121C-1 Signal-type outer contact portion
124 Signal-type connecting portion
130 Receptacle power supply terminal
131B Power supply-type contact portion
140 Retained fitting
142A Retained plate portion
150 Anchor fitting
Number | Date | Country | Kind |
---|---|---|---|
2017-154393 | Aug 2017 | JP | national |
Number | Name | Date | Kind |
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5224866 | Nakamura | Jul 1993 | A |
5545051 | Summers | Aug 1996 | A |
5700151 | Korsunsky | Dec 1997 | A |
6645005 | Wu | Nov 2003 | B2 |
6875027 | Ye | Apr 2005 | B2 |
6923659 | Zhang | Aug 2005 | B2 |
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7985099 | Wu | Jul 2011 | B2 |
8142203 | Chen | Mar 2012 | B2 |
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8277241 | Horchler | Oct 2012 | B2 |
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8414310 | Zhu | Apr 2013 | B2 |
8540534 | Sato | Sep 2013 | B2 |
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20100068900 | Wu | Mar 2010 | A1 |
Number | Date | Country |
---|---|---|
3976454 | Sep 2007 | JP |
Number | Date | Country | |
---|---|---|---|
20190052004 A1 | Feb 2019 | US |