KR20150105992A - Female electrical terminal - Google Patents

Abstract

The present invention relates to a female electrical terminal having a contact section for receiving a contact pin (21) of a male electrical terminal. A spring module of the female electrical terminal is disposed in the contact section, and the contact pin (21) is fixed to the contact section. The spring module includes a first plate spring 131 for pressing the contact pin 21 toward the contact section and a second plate spring 132 for pressing the first plate spring 131 toward the contact pin 21 . The first leaf spring 131 preferably includes a first bend 131a in contact with the contact pin 21 at an intermediate portion thereof. The second leaf spring 132 preferably includes a first bend section 132a at its free end to be in contact with the first bend section 131a of the first leaf spring 131.

Description

FEMALE ELECTRICAL TERMINAL

The present invention relates to a female electrical terminal for an electrical connector.

An electrical connector is used for electrical connection between the two electronic devices. The electrical connector includes a male electrical connector and a female electrical connector that can be complementarily matched to each other. The male electrical terminal and the female electrical connector are fixed to their respective electrical connectors.

A typical electrical terminal is formed by bending a piece of metal blank in a predetermined shape. The female electrical terminal may comprise a contact section and an elastic element. The contact section is configured to receive the contact pin of the male electrical terminal. The elastic element fixes the contact pin of the male electrical terminal to the contact section inside the contact section. When these female electrical terminals and these male electrical terminals are matched with each other, the contact pin comes into close contact with the contact section from the elastic element perpendicularly to the insertion direction of the contact pin, under the contact force, And the contact section.

The metal blank for forming the female electrical terminal comprises a highly conductive metallic material, but such metal material does not have satisfactory stiffness. Focusing on the conductivity, the contact section and the elastic element may be made from a single piece of metal blank comprising a highly conductive metal material. However, this may lead to a weakening of the contact force provided by the resilient element, thus leading to an unintended separation between the female electrical terminal and the male electrical terminal.

Further, the contact section and the elastic element may be made from a single piece of metal blank comprising a highly rigid metal material. This, in turn, may improve the contact force of the elastic element, but it degrades the conductivity of the contact section and the elastic element, thus reducing the allowable current density.

That is, since the contact section and the elastic element are manufactured from a single piece of metal blank, the conductivity and stiffness are incompatible with each other.

In addition, the conventional female type electrical terminal includes an elastic element configured to apply a single contact force to the contact pin of the male type electrical terminal. Therefore, when the conventional female type electrical terminal is used under vibration, its contact structure between the contact pin and the elastic element may be weakened.

When the electric terminal is used in the engine compartment of an automobile, the vibration occurring in the automobile may weaken the contact between the resilient element of the female electrical terminal and the contact pin of the male electrical terminal. This may not make a stable connection between the two electronic devices and may cause connection failure.

The present invention relates to solving the above-mentioned problems. It is an object of the present invention to provide a female electrical terminal for applying a stronger contact force to a contact pin of a male electrical terminal and achieving a more stable connection.

To achieve these and other objects, in an exemplary embodiment, the present invention provides a female electrical terminal adapted to be connected to a male electrical terminal with a contact pin. The female electrical terminal

A contact section having an internal cavity adapted to receive a contact pin, and

And a spring module arranged in the inner cavity and fixing the contact pin to the contact section.

The spring module includes a first leaf spring for urging the contact pin toward the contact section and a second leaf spring for urging the first leaf spring toward the contact pin. The first leaf spring preferably includes a first bend which is in contact with the contact pin at an intermediate portion thereof. The second leaf spring preferably includes a first bent portion that is brought into contact with the first bent portion of the first leaf spring at its free end.

In an embodiment of the present invention, the spring module further comprises a frame adapted to fit in the inner cavity. The first leaf spring extends from one end of the frame, while the second leaf spring extends from the opposite end of the frame.

In an embodiment of the present invention, the first leaf spring further includes a second bend at its free end which is brought into contact with the opposite end of the frame.

In an embodiment of the present invention, the second leaf spring further comprises a second bent portion positioned between the first bent portion of the second leaf spring and the opposite end of the frame.

In an embodiment of the present invention, the first leaf spring has a wider width than that of the second leaf spring.

In an embodiment of the present invention, the contact section has a locking lip that engages one end of the frame.

In an embodiment of the present invention, the frame has a stop lug that engages the end of the contact section.

In an embodiment of the present invention, along a line perpendicular to the contact pin, the first bent portion of the first leaf spring is brought into contact with the contact pin, and the first bent portion of the second leaf spring is engaged with the first bent portion of the first leaf spring .

In an embodiment of the invention, the contact section comprises a contact strap extending from the end of the contact section opposite the spring module. The contact pin is interposed between the spring module and the contact strap.

In an embodiment of the present invention, the contact strap has at least one contact ridge protruding toward the spring module.

In an embodiment of the invention, the first leaf spring has at least one slit extending in the first bend in the longitudinal direction of the first leaf spring.

In an embodiment of the invention, the contact section comprises a copper alloy material, while the spring module comprises a copper alloy material or a stainless steel material having a higher stiffness than the copper alloy material of the contact section.

According to the female electric terminal of the present invention, the spring modules disposed in the contact section to apply a contact force to the contact pins of the male electrical terminal are provided individually from the contact section. The contact section is made from a highly conductive metal material, while the spring module is made from a highly rigid metal material. Thus, the female electrical terminal enhances the contact force of the spring module without any increase in the allowable current strength, and thus can provide a more stable electrical connection.

The spring module also includes two leaf springs arranged in a bilayer arrangement. These upper leaf springs apply a primary contact force to the contact pins of the male electrical terminals, while these lower leaf springs support the upper leaf spring and apply a secondary contact force to the upper leaf spring. Thus, the female type electric terminal stably fixes the contact pin of the male type electrical terminal to the contact section without causing connection failure caused by vibration.

Of course, other features, alternatives, and / or embodiments of the present invention may be combined with one another in various configurations to the extent that they are incompatible or not exclusive of the others.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be better understood upon reading the following detailed description, which, when taken in conjunction with the drawings and detailed description, is given by way of non-limiting example, which is used to complete the understanding of the invention and which, if appropriate, Will be better understood, and other features and advantages will become apparent.

1 is a perspective view showing a female type electrical terminal and a complementary male type electrical terminal according to an embodiment of the present invention.
Fig. 2 is a perspective view showing the female electrical terminal shown in Fig. 1 and the spring module separated from the contact section, which are turned upside down.
3 is a transverse cross-sectional perspective view showing the contact section of the female electrical terminal with the contact strap visible.
4 is an enlarged perspective view of the spring module shown in Fig.
Figure 5 is a view similar to Figure 4, where the first plate spring is shown in dashed lines.
6 is a longitudinal cross-sectional perspective view showing the front portion of the female electrical terminal.
Figure 7 is a longitudinal cross-sectional view corresponding to Figure 6, with the contact pin inserted in the contact section.
8 is a plan view of a fragment of a metal blank forming a contact section wire connection section of a female electrical terminal.
9 is a plan view of a fragment of another metal blank forming the spring module of the female electrical terminal.

In the drawings, it should be noted that the structural and / or functional elements common to the different embodiments may have the same reference numerals. Thus, unless otherwise stated, these elements have the same structural, dimensional, and material properties.

Further, a description of an embodiment of the female electrical terminal according to the present invention is made with reference to the accompanying drawings. As used herein, the directional term " forward "or" forward "refers to the direction in which the female electrical terminal faces the complementary male electrical terminal, and the directional term" back "or" backward " .

1, a female type electrical terminal 100 according to an embodiment of the present invention is matched to a complementary male type electrical terminal 20, thereby electrically connecting an electric wire coupled to the female type electrical terminal 100 and a male type electrical terminal 20 to other electrical wires.

The male electrical terminal 20 comprises a thin elongated contact pin 21 and a wire connecting section 22 extending opposite the contact pin 21. [ The contact pin 21 is inserted into the female type electrical terminal 100. An electrical wire is coupled to the wire connection section (22).

1 and 2, the female type electrical terminal 100 includes:

A contact section 110 configured to receive the contact pin 21 of the male electrical terminal 20,

A wire connection section 120 extending rearward from the contact section 110, and

And a spring module 130 disposed in the contact section 110 for resiliently fixing the contact pin 21 of the male electrical terminal 20 to the contact section 110.

The contact section 110 and the wire connection section 120 are formed by bending a piece of the metal blank 100a shown in Figure 8 while the spring module 130 is formed by bending a piece of the metal blank 100b shown in Figure 8, . ≪ / RTI >

The contact section 110 has a generally box or tubular shape with a rectangular cross section. The contact section 110 includes a bottom portion 111, a pair of side portions 112 extending vertically from the bottom portion 111 and a pair of side portions 112 extending from the side portion 112, And has an inner cavity 114 for receiving the contact pin 21 of the male electrical terminal 20 and has a rectangular cross section. Preferably, each upper portion 113 has a size that is one half of the bottom portion 111.

The upper portion 113 is opposed to each other to form the upper portion of the contact section 110. The front end of the contact section 110 is open for entry of the contact pin 21 of the male electric terminal 20. [

3, 6, and 7, the contact section 110 includes a contact strap 115 that extends rearward from the front end of the bottom portion 111. As shown in Fig. The contact strap 115 extends parallel to the bottom portion 111 and is opposed to the spring module 130. The contact strap 115 is connected to the bottom portion 111 by a joint 115a. The joint 115a includes a forwardly convex curved surface. The joint 115a of the contact strap 115 guides the insertion of the contact pin 21 of the male electric terminal 20. [

The contact strap 115 has a pair of support legs 115c extending from its free end toward the bottom portion 111, as shown in Figs. The support legs 115c abut against the inner surface of the bottom portion 111. The contact strap 115 contacts the contact pin 21 of the male electrical terminal 20 and thus allows the flow of current.

3, the contact strap 115 has four contact ridges 115b that project inwardly of the inner cavity 114 toward the spring module 130. As shown in Fig. The contact ridges 115b extend forward and rearward on the surface of the contact strap 115 contacting the contact pins 21 of the male electrical terminal 20. [

When the female type electrical terminal 100 and the male type electrical terminal 20 are matched with each other and the contact pin 21 contacts the contact strap 115, the surface of the contact strap 115 or the surface of the contact pin 21 is fixed Any foreign object may cause unstable contact. The contact strap 115 and the contact pin 21 contact each other via the contact ridge 115b and thus provide a stable electrical connection without the influence of the surface condition of the contact strap 115 or the contact pin 21. [

The contact section 110 has a pair of locking lips 116 extending downwardly from each upper portion 113. The locking lip 116 blocks a portion of the front end of the contact section 110 and prevents the spring module 130 inserted in the contact section 110 from separating from the contact section 110. The locking lip 116 may be bent inward after the spring module 130 is inserted into the inner cavity 114 of the contact section 110. [

The wire connection section 120 extends rearward from the contact section 110. The wire connection section 120 has a wire crimp barrel 121, an insulating crimp barrel 122 and a transition section 123.

The wire crimp barrel 121 is connected to the conductive wire core of the electric wire. The insulating crimp barrel 122 extends from the wire crimp barrel 121 and is connected to the insulating covering of the electrical wire. The wire crimp barrel 121 and the insulating crimp barrel 122 have two laterally projecting wing tabs. These wingtips may be folded or crimped to couple the insulating covering of the conductive wire core and electrical wire to the respective barrel.

Transition section 123 interconnects contact section 110 and wire crimp barrel 121. Advantageously, transition portion 123 progressively narrows backward, thus preventing spring module 130 in contact section 110 from moving backward.

The spring module 130 fits into the inner cavity 114 of the contact section 110 and is positioned against the contact strap 115. The spring module 130 is inserted into the inner cavity 114 from the front end of the contact section 110.

The contact pin 21 is interposed between the contact strap 115 and the spring module 130 when the contact pin 21 of the male electric terminal 20 is inserted into the contact section 110. [

The spring module 130 presses or deflects the contact pin 21 toward the inner surface of the contact section 110, i.e., toward the contact strap 115. The spring module 130 applies a normal contact force to the contact pin 21 perpendicularly to the contact strap 115 or the contact pin 21 so that the contact pin 21 contacts itself and the contact strap 115 .

4 to 7, the spring module 130 includes a first plate spring 131 and a second plate spring 132, which are juxtaposed on one another or arranged in a bilayer arrangement.

The first leaf spring 131 is directed toward the inner cavity 114. The first leaf spring 131 comes into surface contact with the contact pin 21 and presses the contact pin 21 toward the contact section 110 (toward the contact strap 115). The first leaf spring 131 applies a primary vertical contact force to the contact pin 21.

The second leaf spring 132 located outside the first leaf spring 131 supports the first leaf spring 131 and urges the first leaf spring 131 toward the contact pin 21. [ The second leaf spring 132 applies an additional or secondary vertical contact force to the contact pin 21 via the first leaf spring 131.

The spring module (130)

A frame 133, preferably a rectangular frame 33, which is fitted in the inner cavity 114 of the contact section 110,

A first leaf spring 131 extending from the front end (one end) 133a of the frame 133, and

And a second leaf spring 132 extending from the rear end (opposing end) 133b of the frame 133. As shown in Fig.

The first leaf spring 131 and the second leaf spring 132 extend from the longitudinal end of the frame 133 in the opposite direction. The first leaf spring 131 and the second leaf spring 132 take the form of a cantilever.

The frame 133 has a pair of side walls 133c standing upright from the front end 133a and the rear end 133b. Preferably, the opposing tip portion of the side wall 133c is curved inward of the spring module 130. [ The side wall 133c has a height corresponding to the vertical height of the cavity 114 of the contact section 110.

The frame 133 may contact the inner surface of the contact section 110 at the outer surface of the side wall 133c. The sidewall 133c of the frame 133 is upright from its bottom and thus permits fitting between the spring module 130 and the inner surface of the contact section 110. [

In particular, a pair of laterally projecting stop lugs 133d are formed at the front end of the side wall 133c. When the spring module 130 is fitted into the inner cavity 114 of the contact section 110, the stop lug 133d engages the front end of the side portion 112 of the contact section 110, ).

Preferably, the first leaf spring 131 has a wider width than that of the second leaf spring 132 and is configured to cover the second leaf spring 132.

The first leaf spring 131 has a first bent portion 131a and a second bent portion 131b. The first bent portion 131a extends rearward from the front end portion 133a of the frame 133. [ Particularly, the first bent portion 131a is located in the middle portion of the first leaf spring 131, that is, between the front end 133a of the frame 133 and the free end of the first leaf spring 131. Advantageously, the first bend 131a is convex toward the contact strap 115, and comes into contact with the contact pin 21 at about half its point.

The second bend section 131b extends from the first bend section 131a and is convex with respect to the contact strap 115, i.e., against the curvature of the first bend section 131a. And the end of the second bent portion 131b becomes the free end of the first leaf spring 131. [

Particularly, the first bent portion 131a is formed with a plurality of slits 131c extending forwardly and rearwardly, that is, in the longitudinal direction of the first leaf spring 131.

The first leaf spring 131 is brought into contact with the base end of the second leaf spring 132 or the rear end 133b of the frame 133, particularly at approximately half of the second bent portion 131b.

The second leaf spring 132 is located outside the first leaf spring 131. The second leaf spring 132 extends forward from the rear end 133b of the frame 133. [ The second leaf spring 132 has a first bent portion 132a and a second bent portion 132b.

The first bent portion 132a of the second leaf spring 132 is configured to be in contact with the first bent portion 131a of the first leaf spring 131 and forms the free end of the second leaf spring 132. [

The second bent portion 132b of the second leaf spring 132 is positioned between the first bent portion 132a and the rear end 133b of the frame 133. [

Preferably, the first bend portion 132a is convex toward the contact strap 115. Similarly, the second bend section 132b is convex, preferably against the contact strap 115, i.e. against the curvature of the first bend section 132a of the second leaf spring 132. [

The second leaf spring 132 does not come into contact with the first bent portion 131a of the first leaf spring 131 when no load acts on the first leaf spring 131 of the spring module 130 . When a load acts on the first leaf spring 131, the second leaf spring 132 is pressed against the surface of the first bent portion 131a of the first leaf spring 131 at approximately half of the first bent portion 132a Can be contacted.

When the contact pin 21 of the male electric terminal 20 is inserted between the spring module 130 and the contact strap 114 in a state where the spring module 130 is fitted in the inner cavity 114 of the contact section 110, The first leaf spring 131 and the second leaf spring 132 are resiliently flexed or elastically pressed away from the contact strap 115.

The first bent portion 131a of the first leaf spring 131 may be brought into contact with the contact pin 21 along a line substantially perpendicular to the contact pin 21. [ Similarly, the first bent portion 132a of the second leaf spring 132 may be in contact with the first bent portion 131a of the first leaf spring 131. [

That is, not only the contact point between the contact pin 21 and the first leaf spring 131 and the second leaf spring 132, the contact point between the contact pin 21 and the first leaf spring 131, The other contact point between the first leaf spring 131 and the second leaf spring 132 may be on a line substantially perpendicular to the contact pin 21 or may be located in intimate contact with the line.

By the above-described pressure or bending, the first leaf spring 131 preferably applies a normal contact force from the half of the first bent portion 131a toward the contact pin 21. The second leaf spring 132 preferably extends from the half of the first bent portion 132a to the first bent portion 131a of the first leaf spring 131 as well as to the additional vertical Apply contact force.

Moreover, since the contact point between the contact pin 21 and the first leaf spring 131 and the second leaf spring 132 lies on the line as described above, the vertical contact force and the additional vertical contact force are integrated on the line So that a strong contact force is applied to the contact pin 21.

The vertical contact force from each of the first leaf spring 131 and the second leaf spring 132 is applied to the contact pin 21 so that the contact force between the contact strap 115 and the first leaf spring 131 The contact pin 21 is firmly held and the contact pin 21 is stably brought into contact with the contact strap 115 and the spring module 130. [

8 shows a single fragment of a metal blank formed of a contact section 110 and a wire connection section 120 of a female electrical terminal 100. Fig. Figure 9 shows a single piece of another metal blank formed with the spring module 130.

8 and 9, the contact section 110 and the wire connecting section 120 are formed by bending the first metal blank 100a and the spring module 130 is formed by bending the second metal blank 100b, .

The first metal blank 100a and the second metal blank 100b may be formed by blanking. Also preferably, the first metal blank 100a is made from a high conductivity copper alloy material, and the second metal blank 100b is preferably made of a material having a higher hardness than that of the high-strength stainless steel or first metal blank 100a And is made from a copper alloy material having rigidity. Accordingly, the contact section 110 is fabricated from a highly conductive metal material, while the spring module 130 is fabricated from a highly rigid metal material.

Therefore, the female type electrical terminal 100 can improve the elasticity of the spring module 130 while preventing a decrease in allowable current intensity. In addition, the female type electrical terminal 100 and the male type electrical terminal 20 can be firmly connected to each other.

Obviously, the invention is presented by way of example only and is not limited to the embodiments described herein. The present invention also encompasses different modifications and alternatives that may be considered by one of ordinary skill in the art as part of the present invention, including all combinations of the different embodiments described hereinabove, taken alone or in combination.

Claims (14)

A female electric terminal (100) suitable for being connected to a male type electrical terminal (20) by a contact pin (21)
- a contact section (110) having an internal cavity (114) adapted to receive said contact pin (21), and -
- a spring module (130) arranged inside said inner cavity (114) and fixing said contact pin (21) to said contact section (110)
The spring module 130 includes a first plate spring 131 for pressing the contact pin 21 toward the contact section 110 and a second plate spring 131 for pressing the first plate spring 131 toward the contact pin 21 And a second plate spring (132)
The first leaf spring 131 preferably includes a first bent portion 131a at its middle portion to be in contact with the contact pin 21,
The second leaf spring 132 preferably has a female electrical terminal 100 including a first bent portion 132a which is brought into contact with the first bent portion 131a of the first leaf spring 131 at a free end thereof, . The female electrical terminal (100) of claim 1, wherein the spring module (130) further comprises a frame (133) configured to fit within the inner cavity (114). 3. The apparatus of claim 2, wherein the first leaf spring (131) extends from one end (133a) of the frame (133) and / or the second leaf spring (132) 133b). ≪ / RTI > The connector according to claim 3, wherein the first leaf spring (131) further comprises a female electric terminal (100) including a second bent portion (131b) at its free end to be brought into contact with an opposite end (133b) . 4. The apparatus according to claim 3 or 4, wherein the second leaf spring (132) is located between the first bend (132a) of the second leaf spring (132) and the opposite end (133a) of the frame (100) further comprising a second bent portion (132b). 6. The female electric terminal (100) according to any one of claims 3 to 5, wherein the contact section (110) has a locking lip (116) engaging one end (133a) of the frame (133). 7. A female electrical terminal (100) according to any one of claims 1 to 6, wherein the frame (133) has a stop lug (133d) engaging an end of the contact section (110). 8. The connector according to any one of claims 1 to 7, wherein a first bend (131a) of the first leaf spring (131) is formed along the line perpendicular to the contact pin (21) And the first bent portion 132a of the second leaf spring 132 comes into contact with the first bent portion 131a of the first leaf spring 131. [ 9. A spring module (130) according to any one of the preceding claims, wherein the contact section (110) comprises a contact strap (115) extending from an end of the contact section (110) Terminal (100). 10. The female electrical terminal (100) according to claim 9, wherein the contact pin (21) is interposed between the spring module (130) and the contact strap (115). 11. The female electrical terminal (100) of claim 9 or 10, wherein the contact strap (115) comprises at least one contact ridge (115b) projecting toward the spring module (130). 12. The apparatus according to any one of claims 1 to 11, wherein the first leaf spring (131) comprises at least one slit (131) extending from the first bend (131a) in the longitudinal direction of the first leaf spring 131c). ≪ / RTI > 13. The female electric terminal (100) according to any one of claims 1 to 12, wherein the first leaf spring (131) has a wider width than that of the second leaf spring (132). 14. A method according to any one of claims 1 to 13, wherein the contact section (110) comprises a copper alloy material and the spring module (130) has a higher stiffness than the copper alloy material of the contact section A female electrical terminal (100) comprising a copper alloy material or a stainless steel material.

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