KR830000254Y1 - Dual Beam Pin Terminal - Google Patents

Abstract

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Description

Dual Beam Pin Terminal

1 is a front view of two of the terminals of the present invention attached to the primary and secondary support strips.

2 is a side view of one of the inventive terminals after removal from the support strip.

3, 4 and 5 are perspective views of other embodiments of the subject innovation.

6 is an exploded perspective view of a connector of the present invention having a plurality of terminals in FIGS. 1 and 2.

The present invention relates to a pin terminal, in particular a microcircuit connector with a preloaded double beam, and more particularly to a connector having a plurality of such terminals which engages a long double beam electrical terminal and a pin contact.

Beam contacts are widely used in many applications, including circuit board edge connectors and pin connectors. Many applications in the application of edge connectors include techniques to preload the beam to reduce circuit board insertion force. For example, US Pat. No. 3,464,054 describes a connector block having contact members pre-tensioned to the wall to reduce the force required to insert an insulating substrate into a long channel. In another example, US Pat. No. 3,671,917 describes a connector housing in which the flange of each terminal is held away from each other by a lip portion to preload the terminals to accommodate a male pin contact.

The use of a double beam at one end of the terminal is described in US Pat. No. 3,665,375. Such terminals as shown in FIGS. 1 and 2 are used for edge connectors.

Recently, the size of the fin area in microcircuit applications has been increased. This has been the cause of the reduction in insertion force in pin connector technology. One convention is to use an integrally formed long plastic protrusion in the sidewall of the connector housing that preloads the double beam terminals by unfolding the beams apart from each other when the terminal is inserted into the housing cavity. The main disadvantage of this approach, however, is that the beam is easily damaged by the plastic protrusion upon insertion into the housing cavity.

Also, the method cannot use non-standard pins. Thus, poor contact is sometimes obtained when the terminal cannot be biased or accommodate misaligned pins because the terminal is fixed by the plastic protrusion.

The long electrical terminals of the present invention have one contact at one end and one of the contacts is a set of double beams separated from each other to accommodate the pin contacts. Each beam has laterally opposed and spaced tabs extending from its side toward its opposite beam. The tab is arranged symmetrically such that one of each of the two nonclinical tabs holds the beams in a preloaded position in contact with one of the opposing nonclinical tabs. In this way a low insertion force connection between the beam and the male pin contact can be achieved.

The connector of the present invention incorporates a plurality of terminals described above, and has a terminal housing having a plurality of parallel cavities for holding the terminals. The long terminal used in this connector has an insulation displacement contact at the opposite end of the double beam contact. The insulation displacement contact of each terminal protrudes from each terminal cavity for electrical connection with the insulation wire. The insulation displacement contact block is coupled to the terminal housing at the end of the housing through which the insulation displacement contact protrudes. The contact block has parallel slots extending laterally across the mating surface adapted to hold the insulated wire for connection with the protruding contact. A stress relief cover is installed on the insulation displacement contact block and mounted on the terminal housing to complete the fully assembled connector.

One end of the terminal housing is provided with a hole for accommodating the pins extending from the pin area every day. Each hole has an inlet portion in one of the inner cavities to preposition the pin for connection with a double beam of terminals.

The advantages of these connectors and terminals are numerous. Although the insulating displacement end of the terminal is fixed to the wire supported on the insulating displacement contact block, the double beam end of the terminal is free in the housing cavity. Thus, compensation for misaligned or misaligned pins in the pin area is automatically performed. Such an arrangement reduces the likelihood of damage to the plated contact surface of the beam that is sometimes caused by such knitted pins.

In addition, since each terminal has its own preload characteristics, no cooperation between the terminal and the housing projection or other housing parts is required. Thus, damage caused by inserting the non-terminal into the cavity with the plastic protrusion is prevented. Furthermore, since the pins do not have plastic protrusions that rub against them, fouling of the pin surface is prevented. Thus, a more reliable contact is achieved than in the case of applications requiring repeated insertion and insertion.

Finally, a more reliable manufacturing state is achieved because only the terminal tolerances have to be adjusted, rather than the terminal and housing tolerances. As a result, the spacing between beams and the equivalent preload force are close to the desired values. Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

One embodiment of the dual non-terminal of the present invention is shown in FIGS. 1 and 2. In FIG. 1 two of the terminals 10 are shown attached to primary and secondary carrier strips 12 and 14. The secondary support strip 14 is used to maintain the rigidity during the manufacturing and plating steps to prevent the terminal from deviating out of the axial direction. 2 shows one of the terminals after being separated from the support strips. The terminals are separated by blanking at tangents 16 and 18 (FIG. 1).

The terminal is long and has a double beam contact 20 of one end and a contact 28 of the other end. In the present invention, the contact 28 is an IDC contact for use in a connector. The contacts are separated by a neck 25 which allows the double beam end to bend relative to the fixed IDC end of the terminal 10 when used in the connector of the present invention. The double contact is formed by two opposing spring arms (or beams) 22 that are spaced apart to receive a malepin contact. A laterally opposed tab 24 extends symmetrically from the edge of each beam 22, one of two non-clinical tabs abuts one of the opposite non-clinical tabs. As a result, the two beams 22 are spring loaded towards each other to provide unloaded contacts for low insertion force to engage the pin contacts, as held by the tabs. For proper connection, the tab must develop a beam smaller than the width of the pin contact to be inserted.

The terminals are stamped from a flat metal plate of copper-nickel alloy, phosphor-bronze, or other suitable electrophoretic material and formed into a final form by die, followed by nickel and / or gold (or other desired plating). Metal). The terminal is preferably attached to the primary and support strips throughout the entire forming and plating step.

The preload of the beam 22 is achieved during manufacture. The beam extends from the segment 26 of the terminal 10. After engraving and all the elements of the terminal 10, including the shaped segment 26, the beam 22 and the tab 24, remain flat on the same plane. The tab 24 is then bent 90 ° inward and the beam 22 is bent 5 ° -15 ° inward toward the segment 26 along the dotted line 27.

Segment 26 is then shaped into a " U " shape whereby the tabs 24 of each beam become contacts and the beams 22 are elastically deformed or preloaded.

As an example, the contact 28 of the terminal 10 may be a second double beam contact, a crimp contact or a wire wrap tail, as shown in FIGS. 3, 4 and 5. One may be used, of course, other useful contacts are also allowed. However, for use in the connector of the present invention, a large dielectric displacement contact (IDC) has a branch 30 designed to penetrate the insulator to make electrical contact with the insulated wire. The branch 30 extends from the second U-shaped segment 32 of the terminal. The segment 32 is formed into a U shape at the same time that the segment 26 is formed. A fixing detent 34 protrudes from the segment 32 to fix the terminal in the connector housing cavity. It can be seen in FIG. 1 that the centerline of the IDC contact 28 is slightly biased from the centerline of the double beam contact 20. This form provides an advantage associated with the use of the terminal 10 in the connector of the present invention.

The connector of the present invention is shown in FIG. Connector 40 is shown in exploded perspective view and has multiple terminals 10 of the present invention. The main components of the connector are the terminal housing 50, the insulation displacement contact block 70 (formed with two halves 74) and the stress relief cover 90.

The terminal 10 is supported in the terminal cavity 52 of the terminal housing 50. The housing 50 has two rows of holes 54 which provide passages for coupling the terminals 10 embedded in each cavity 52 and the male pin contacts (not shown). The hole 54 has a slanted inlet 55 that provides easy entry and exit of the daily pin contact. The terminal 10 is inserted into the locking end 56 of the housing 50. As mentioned, the centerline of the IDC contact 28 is slightly biased from the centerline of the double beam contact on the terminal plane of FIG. This form provides the knitted edge 33 of the segment 32 that the housing brick outlet 53 abuts. Thus, although the double beamed end of the terminal can be inserted into the cavity 52 without obstruction of the protrusion 53, the knitted edge 33 contacts the protrusion 53 and thereby inhibits the terminal from further moving forward. Intracavity terminals are more firmly secured by an integral fixation pawl 34 extending outwardly from segment 32 to provide interfitting in the cavity by frictional contact with the walls of the cavity.

The locking end 56 of the terminal housing 50 has an extension 58 in which the projections 60 and 62 are integrally formed and the notch 64 is also formed. The locking projection 60 holds the connector assembly coupled in cooperation with the corresponding locking hole 92 of the stress relief cover 90. The protrusion 62 (which cooperates with the notch 94 of the stress relief shroud 90 allows the connector to be assembled in one direction only for proper electrical polarity. It cooperates with the protrusion 72 shown on the half 74.

The IDC blow 70 is formed of two identical block halves 74. These half halves are coupled to each other in a hermaphrodite manner by the projections 78 and the cavities 80. Insulating wire 100 is inserted in block half 74 and wire slot 82 before joining those halves together. The wire slot extends laterally on the inner face 84 of both halves 74 and continues over the contact face 86 of both halves. The portions of each wire slot 82 extending over the contact surface 86 are longitudinally provided to provide a space for receiving the branch 30 of the terminal 10 upon engagement of the terminal housing 50 and the IDC block 70. It intersects with the IDC accommodation slot 88 arranged. Coupling of the connector parts includes cutting the insulation on wire 100 by branch 30. After cutting of the insulation, a physical contact between the metal branch 30 and the metal wire for electrical connection is formed.

In FIG. 6, it can be seen that the lateral position of the terminal 10 in the cavity of the upper row is 180 ° upside down from that of the terminal of the lower row. This is a good way to surround the terminals for the following two reasons.

First, it is possible to use the hermaphrodite block half 74, which requires only one mold to make both halves, and second, the housing rather than having to be in the inner wall separating the rows of cavities. Both projections 53 can be located on the outer wall of 50. The latter consideration is important when the spacing between pin centers is small, for example 0.125 inches.

Wire 100 extends from cable 120. The stress relief cover 90 is used to provide a cable-housing fixation for removing wire stress formed by the tension on the cable 120. The cover 90 is installed on the IDC block 70 and fixed to the terminal housing 50 by the described means after the IDC block is combined with the terminal housing. Cable tie 122 (preferably made of nylon) is used to tie the cover 90 to the cable. The cover 90 is integrally formed with a tab 96 extending over a portion of the cable periphery. A tie 122 is disposed on the tab 96 and tightened around the cable.

The double beam terminal of the present invention and a connector for moving one example of the terminal can be used for countless microcircuit applications. The terminal includes any one of crimp contacts, pintails, wire tap tails, and the like. It can be used where pin contacts are used to achieve electrical connections such as circuit boards and pin connectors. The connector is useful for various applications including IDC contacts, and one example of the application is a telephone signal system.

Claims (1)

A beam 22 arranged in a pair of longitudinal axes with one contact 20, 28 at each end, one of which contacts having tabs 24 laterally opposed to keep the beam apart and retained Long electrical terminal composed of.