JP5334753B2 - Shield connector - Google Patents

Description

  The present invention relates to a shielded connector in which a connector housing is covered with a shield shell, and more particularly to a shielded connector for high-speed transmission relay applied to communication, in which the shield shell between the connectors is reliably electrically connected. The present invention relates to a connector that can be contacted to prevent electrification and ensure noise resistance.

<Conventional connector>
As a high-speed transmission relay connector, a so-called shield connector is known in which terminals are covered with a dielectric and the outer periphery thereof is covered with a conductive shield shell. Conventional shield shells are generally formed in a bowl shape by appropriately punching and bending a single metal plate. (See Patent Document 1)

JP 2006-286223 A

FIG. 9 is a perspective view of a connector that matches the shield connector for high-speed transmission relay described in Patent Document 1. In FIG. 9, reference numeral 100 denotes a conventional shield connector, and the shield connector 100 includes a connector housing 110 and a shield shell 120 that covers the connector housing 110. The connector housing 110 has a space 110H formed therein, and a connector metal terminal is accommodated in the space 110H. A wire harness is connected to the connector metal terminal, and the rear of the connector housing 110 (the opposite side of the mating connector 200). ) To the outside. By inserting the tip of the connector housing 210 of the mating connector 200 into the space 110H, the terminals are connected to each other.
The shield shell 120 is formed along the outer shape of the connector housing 110 by punching and bending a single metal plate.
The shield shell 120 is formed by punching a metal plate into a U-shape (120K) so that the shield shell 220 of the counterpart shield connector 200 housed inside can be brought into contact, and bending the punched three sides inward. 120-shaped contact spring piece 120S is formed.
Also in the connector housing 110, an opening is formed in the vicinity of the contact spring piece 120S of the connector housing 110 so that the contact at the tip of the contact spring piece 120S can come into contact with the shield shell 220 of the counterpart shield connector 200.

<Mating connector>
The mating shield connector 200 fitted to the shield connector 100 for high-speed transmission relay includes a connector housing 210 and a shield shell 220 that covers the connector housing 210.
The connector housing 210 accommodates a connector metal terminal, and a wire harness is connected to the metal terminal, and is taken out from the rear of the connector housing 210 (opposite side of the shield connector 100). The tip of the connector 200 (on the shield connector 100 side) has a shape that can be inserted into the internal space 110H of the connector housing 110.
The side surface portion 220S of the shield shell 220 comes into contact with the contact spring piece 120S of the shield shell 120 through an opening (not visible in the figure) formed in the opposite portion of the connector housing 110 when fitted.

<Problems of conventional connectors>
FIG. 10 is a perspective view showing the high-speed transmission relay connector 300 in a state where the shield connector 100 and the counterpart shield connector 200 shown in FIG. 9 are fitted. At this time, in the high-speed transmission relay connector 300, the contact spring piece 120S of the shield shell 120 of the shield connector 100 is connected to the side surface of the shield shell 220 of the counterpart shield connector 200 through the opening of the connector housing 110 (not shown). It is in contact with the part 220S.
However, if a large vibration is applied to the high-speed transmission relay connector 300, the contact spring piece 120S forms a cantilevered contact spring piece obtained by punching and bending a single metal plate. As a result of displacement, contact at the tip of the contact spring piece is released, creating a gap, and noise characteristics may be deteriorated.

<Reason why noise characteristics deteriorate when large vibrations are applied>
FIGS. 11A and 11B are diagrams for explaining the reason why the noise characteristics deteriorate when a large vibration is applied. FIG. 11A shows a normal state without vibration, and FIG.
In FIG. 11A, the contact spring piece 120S of the shield shell 120 is formed by forming a notch 120K in a U-shape from the metal plate of the shield shell 120 and bending the notch inward from the shield shell 120. Therefore, it has a spring property due to the elasticity of the metal material, and the contact S20 at the tip thereof is in contact with the shield shell side surface 220S, and the contact S20 remains in contact with the shield shell side surface 220S in a slight vibration.
However, when a large vibration P is applied to the shield shell 120, as shown in FIG. 11B, the end S10 of the contact spring piece 120S of the shield shell 120 is greatly swung to the outside with t10, and therefore the contact S20 at the opposite end. Will remain away from the shield shell side face 220S. If the contact spring piece 120S remains away from the shield shell 220, the charged charge generated inside the high-speed transmission relay connector 300 cannot be removed from the shield shell 120 to the ground via the contact spring piece 120S. Electric charges increase inside the high-speed transmission relay connector 300, and this moves inside, resulting in noise and deterioration in noise characteristics.

  Therefore, the present invention has been made to solve these problems, and even if a large vibration is applied to the shield shell, the gap between the shield shell can be prevented by preventing the contact from separating from the side surface of the shield shell. Therefore, an object of the present invention is to provide a shield connector in which noise characteristics are not deteriorated.

The first invention related to this shield connector is a shield connector comprising a connector housing and a metal plate shield shell covering the connector housing, and the shield shell is punched into three U-shaped sides. Further, a cantilevered contact spring piece formed by bending the three punched sides inward is formed, and the contact of the cantilevered contact spring piece of the shield shell is formed on the connector housing from the front side to the back side of the connector housing. In the shielded connector having a through-opening that can pass therethrough, the front end of the connector housing in the mating direction extends outward from the front end in the mating direction so as to be free of the cantilevered contact spring piece. A stopper portion extending in parallel with the connector housing surface on one side of the cantilevered contact spring at a predetermined distance beyond the end side. Made the contact spring piece stopper is erected, the movement of the free end of the lateral cantilevered contact spring piece between the stopper portion and the connector housing is characterized in that it is constrained.
The second invention is characterized in that, in the first invention, the contact spring piece stoppers are erected on both the left and right sides with respect to the fitting direction of the connector housing.
Further, the third invention is characterized in that the predetermined distance is equal to or less than a distance immediately before the contact of the contact spring piece is separated from the shield shell of the mating connector due to the movement of the free end of the cantilevered contact spring piece. It is said.
The fourth invention relates to a shield connector for high-speed transmission relay, and is characterized in that the shield connector of any of the first to third inventions is used as a shield connector for high-speed transmission relay.

  According to the first aspect of the present invention, the cantilevered contact spring piece is parallel to the connector housing surface at a predetermined distance extending from the front end portion in the fitting direction to the outside vertically and exceeding the free end side of the cantilevered contact spring piece. Since the contact spring piece stopper formed with a stopper portion extending in the direction of the connector housing is erected on the front end in the fitting direction, the free end of the cantilevered contact spring piece is moved between the connector housing and the stopper portion. Be bound. Therefore, even if a large vibration is applied to the shield shell, the contact point of the cantilevered contact spring piece does not move away from the side surface of the shield shell, so that the inner and outer shield shells are always in contact with each other and the noise characteristics are not deteriorated. .

  According to the second invention, the contact spring piece stoppers are erected on both the left and right sides with respect to the mating direction of the connector housing, so that the inner and outer shield shells are in contact with each other at two locations. The certainty without deterioration is further increased.

  According to the third invention, the predetermined distance may be equal to or less than the distance until the contact of the contact spring piece is separated from the shield shell of the mating connector due to the movement of the free end of the cantilevered contact spring piece. This increases the degree of freedom of design.

  According to the fourth aspect of the invention, since the shield connector that does not deteriorate the noise characteristics is used as the shield connector for high-speed transmission relay, reliable relay for high-speed transmission is guaranteed.

FIG. 1 is a perspective view of a communication shield connector of the present invention as seen from the shield connector side. FIG. 2 is a perspective view seen from the counterpart shield connector side. FIG. 3 is a perspective view of the shield connector before mating and the counterpart shield connector. FIG. 4 is a side view of the communication shield connector shown in FIG. FIG. 5 is an AA arrow view of the communication shield connector of FIG. 6 is a perspective view seen from the side of the communication shield connector of FIG. FIG. 7 is an enlarged view in a square indicated by a dotted line of the communication shield connector of FIG. 8A and 8B are diagrams for explaining the operation of the contact spring piece of the shield connector for high-speed transmission relay. FIG. 8A shows a normal state and FIG. 8B shows a vibration state. FIG. 9 is a perspective view of a connector similar to the shield connector for high-speed transmission relay described in Patent Document 1. FIG. 10 is a perspective view showing the high-speed transmission relay connector in a state where the shield connector shown in FIG. 9 and the counterpart shield connector are fitted. 11A and 11B are diagrams for explaining the problem of the shield connector for high-speed transmission relay described in Patent Document 1. FIG. 11A shows a normal state and FIG. 11B shows a vibration state.

  Hereinafter, a shield connector according to the present invention that can prevent a gap generated in a shield shell by preventing the contact from separating from the side surface of the shield shell even when a large vibration is applied to the shield shell will be described with reference to the drawings.

<Shield connector for communication according to the present invention>
1 to 3 are perspective views of the shield connector for communication in a state where the shield connector and the counterpart shield connector according to the present invention are fitted, FIG. 1 is a perspective view seen from the shield connector side, and FIG. 2 is the counterpart shield connector. FIG. 3 is a perspective view of the shield connector before mating with the communication shield connector and the counterpart shield connector (a), and the contact spring piece stopper 11L is removed from the connector housing 11 of FIG. It is a fragmentary perspective view (b) of the shield connector drawn.
1 to 3, reference numeral 30 denotes a shield connector according to the present invention. The shield connector 30 includes a shield connector 10 and a mating connector 20 that fits the shield connector 10. Hereinafter, the shield connector 10 and the counterpart connector 20 will be described.

<Configuration of shield connector 10>
The shield connector 10 includes a connector housing 11 and a shield shell 12 that covers the connector housing 11. Hereinafter, the connector housing 11 and the shield shell 12 will be described.

<< Configuration of Connector Housing 11 >>
The connector housing 11 has a space 11H (FIG. 3) formed therein. A connector metal terminal is accommodated in the space 11H, and a wire harness is connected to the connector metal terminal. 20 on the opposite side). By connecting the tip of the mating connector 20 (FIG. 3) into the space 11H, the terminals are connected to each other.
The connector housing 11 has an opening formed in the vicinity of the contact spring piece 12S of the connector housing 11 so that the contact spring piece 12S (FIG. 3) of the shield shell 12 can contact the shield shell 22 of the counterpart shield connector 20. Yes.
A contact spring piece stopper 11L, which will be described later, is provided in the movable range of the contact spring piece 12S according to the present invention.

<< Configuration of Shield Shell 12 >>
The shield shell 12 has the same configuration as that of the conventional shield shell 120 (FIG. 9), and is formed along the outer shape of the connector housing 11 by punching and bending a single metal plate. In FIG. 3B, the shield shell 12 punches a metal plate into a U-shape (12K) (however, one side reaches the end of the shield shell 12 and the other side leaves the connecting portion S1). When one side that is not punched is bent as a bent portion, the three sides are bent inward to form a contact spring piece 12S, and the contact S2 at the tip of the contact spring piece 12S is attached to the side surface portion 22S of the shield shell 22 of the mating connector 20 I try to contact them. That is, the lower notch 12K1 of the contact spring piece 12S extends to the connecting portion S1, and the connecting portion S1 is connected to the tip of the lower side end portion 12U of the shield shell 12, so that the shield shell lower side end portion 12U is formed. It forms a cantilever support, the connecting portion S1 becomes a free end of the cantilever support, and the contact spring piece 12S is further supported by the cantilever from the connecting portion S1 which is a free end. Therefore, the contact spring piece 12S has a function as a contact spring due to the elasticity of the metal plate material itself.
The contact spring piece 12S contributes to contact with the side surface portion 22S of the shield shell 22 of the mating shield connector 20 through the above-described opening of the connector housing 11 during fitting.

<Configuration of counterpart shield connector 20>
The mating shield connector 20 (FIG. 3) includes a connector housing 21 and a shield shell 22 that covers the connector housing 21. The connector housing 21 accommodates a connector metal terminal therein, and a wire harness is connected to the metal terminal and is taken out from the rear of the connector housing 210 (opposite side of the shield connector 10). The tip of the connector housing 21 (on the shield connector 10 side) has a shape that can be inserted into the internal space 110H of the connector housing 11. When the counterpart shield connector 20 is engaged with the shield connector 10, the side surface portion 22S of the shield shell 22 contacts the contact spring piece 12S of the shield shell 12 through the opening formed in the connector housing 11, and the counterpart shield connector. The charged charge on the 20 side is discharged to the outside of the shield shell 12 via the contact spring piece 12S.

<Contact spring piece stopper 11L according to the present invention>
4-6 is a figure explaining the structure of the stopper 11L for contact spring pieces concerning this invention, FIG. 4 is a side view of the shield connector shown in FIG. 1, FIG. 5 is the AA arrow line view of FIG. 6 is a perspective view seen from the side of FIG. 4 to 6, reference numeral 30 denotes a shield connector, which includes a shield connector 10 and a mating connector 20. The shield connector 10 includes a connector housing 11 and a shield shell 12. The shield shell 12 includes a contact spring piece 12S. Is formed.
The connector housing 11 is formed with a contact spring piece stopper 11L according to the present invention. The contact spring piece stopper 11L is erected in a lateral direction (a direction perpendicular to the connector fitting direction) from the connector housing 11 and is formed in a key-like member when viewed in a cross section. In other words, when the connector housing 11 is included, the U-shaped member is seen in a cross section.
That is, the contact spring piece stopper 11L extends outward from the front end portion in the fitting direction of the connector housing 11 in a right angle direction and contacts at a predetermined distance beyond the free end side which is the connecting portion S1 of the contact spring piece 12S. A stopper portion L1 (FIG. 8) facing the spring piece 12S is formed in parallel with the connector housing surface. Therefore, the movement of the connecting portion (free end) S1 of the cantilevered contact spring piece 12S is restrained between the connector housing 11 and the stopper portion L1.
The contact spring piece stoppers 11 </ b> L are formed on both side surfaces of the connector housing 11.

<Function of contact spring piece stopper 11L>
FIG. 7 is an enlarged view in the square indicated by the dotted line in FIG. 6, FIG. 8 is a diagram for explaining the function of the contact spring piece stopper 11L in FIG. 7, and (a) is normal when the contact spring piece is not subjected to vibration. , (B) is during vibration.
<< When (a) is normal >>
In FIG. 8A, the contact S2 at the tip of the contact spring piece 12S of the shield shell 12 contacts the shield shell 22, and the contact S2 is separated from the shield shell 22 by the elastic force of the contact spring piece 12S in a slight vibration. It is always in contact with the shield shell side surface 22S.
<< When vibration (b) >>
However, when a large vibration P is applied to the shield shell 12, as shown in FIG. 8B, the contact spring piece 12S of the shield shell 12 tends to vibrate outwardly, so that the free end S1 also faces outward. The free end S1 abuts against the key portion L1 of the contact spring piece stopper 11L and is prevented from further swinging, and the contact S2 at the tip on the opposite side does not leave the shield shell 22.

<Effect of the present invention>
As described above, according to the present invention, the contact S2 of the contact spring piece 12S is not separated from the shield shell 22 by the contact spring piece stopper 11L, so the inside of the high-speed transmission relay connector 30 (FIGS. 1 and 2). Since the charged charge generated in the circuit is always removed from the shield shell 12 to the ground via the contact spring piece 12S, the charge does not accumulate in the high-speed transmission relay connector 30, and the charge may move inside. It cannot happen and the noise characteristics will not deteriorate.

DESCRIPTION OF SYMBOLS 10 Shield connector 11 Connector housing 11H Connector housing internal space 11L Contact spring piece stopper 12 Shield shell 12K U-shaped punching part 12K1 Lower notch 12S Contact spring piece 12U Shield shell lower end 20 Counterpart shield connector 21 Connector housing 22 Shield shell 22S shield shell side face 30 high speed transmission relay shield connector S1 coupling part (contact spring piece free end) fitted
S2 Contact point of contact spring piece

Claims (4)

A shield connector comprising a connector housing and a metal plate shield shell covering the connector housing, wherein the shield shell is punched into three U-shaped sides and the three punched sides are bent inward. The connector housing is formed with a through-opening through which the contact of the shield-like contact spring piece of the shield shell can pass from the front side to the back side of the connector housing. For shielded connectors,
The front end of the connector housing in the mating direction extends vertically outward from the front end of the mating direction and extends in a predetermined distance from the free end of the cantilevered contact spring piece. A contact spring piece stopper formed with a stopper portion extending parallel to the connector housing surface on the contact spring piece side is erected,
A shield connector characterized in that movement of a free end of the cantilevered contact spring piece is restricted between the connector housing and the stopper portion.   The shield connector according to claim 1, wherein the contact spring piece stopper is erected on both the left and right sides with respect to the fitting direction of the connector housing.   2. The shield according to claim 1, wherein the predetermined distance is equal to or less than a distance immediately before the contact of the contact spring piece is separated from the shield shell of the counterpart connector due to the movement of the free end of the cantilevered contact spring piece. connector.   A shield connector for high-speed transmission relay, wherein the shield connector according to any one of claims 1 to 3 is used as a shield connector for high-speed transmission relay.

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