BACKGROUND OF THE INVENTION
It is desired that an electrical female terminal be provided with structural arrangements or features including; overstress protection using support members which prevent undesired deformation of the electrical female terminal; a shape having an orientation or polarity of the electrical female terminal as defined by a main body; a wire fastening feature using a wire fastening portion of the electrical female terminal for securing a wire; a locking feature using a tang member to fasten and assure the electrical female terminal is locked within a housing; a spring feature using a two-bodied spring which efficiently and resiliently connects the electrical female terminal with a male pin or male terminal, or further “blade-like” object; and a guiding feature using a guide member to direct and “self-correct” the male pin or male terminal, or further “blade-like” object into the electrical female terminal. Additionally, the electrical female terminal of the present invention can accommodate and can receive a TPA device within a space above the wire fastening portion thereof and located behind the main body.
Further, the two-bodied spring of the present invention is “two-bodied” wherein the application or orientation uses a lower spring member and an upper spring member. Preferably, the lower spring member and upper spring member operate in unison or together and in total, to provide a spring force applied to or acting upon to the male pin or male terminal, or further “blade-like” object, when one of such aforementioned objects is being inserted into the female electrical terminal. The lower spring member extends further along a lengthwise direction of the pin and further downward and towards a floor of the main body, than the upper spring member.
The upper spring member and lower spring members are integrally structured with each other and connected by curved side members and folded one above the other. The lower spring member is below the upper spring member, and the upper spring member is above the lower spring member, respectively. The relationship between the unflexed orientation of the upper and the lower spring member is provided wherein they may or may not contact. When the lower and upper spring members are in contact in an unflexed state, the initial applied spring force will be evident as that of both the upper and lower spring members, applying their respective spring forces in unison or together and in total against the male pin or male terminal, or further “blade-like” object. In contrast, when the lower and upper spring members do not contact in an unflexed orientation, the initial applicable spring force against the male pin or male terminal, or further “blade-like” object will be evident solely as that of the lower spring member spring force, that is until the lower spring member makes contacts with the upper spring member, whereby the upper spring member will apply a spring force against the lower spring and in unison or together and in total against the male pin or male terminal, or further “blade-like” object. Additionally, in one instance of the present invention, as the spring travels upward, the lower spring member may flex and contact the tang member, the tang member may additionally provide a resistance against the upward movement of the lower spring member, thereby applying a resilient force against its upward travel, and consequently the tang member increases the total spring force of the spring. The above described orientations of the spring are provided to efficiently and resiliently connect and secure the electrical female terminal with the male pin or male terminal, or further “blade-like” object, as necessary and or in operation.
It is further also desired that the shape of the electrical female terminal of the present invention has an orientation or polarity that is maintained and ensured, and is provided in order to mate the electrical female terminal with a corresponding connector assembly, one which has an opening with a similar orientation or similar polarity to that of the electrical female terminal, respectively, for proper fitting and mating therewith.
SUMMARY OF THE INVENTION
This invention provides the electrical female terminal for mating with a male pin or male terminal or further “blade-like” object as well as mating and locking with a connector assembly. The electrical female terminal generally includes a main body, a two-bodied spring, and a wire fastening portion.
The main body of the electrical female terminal has a shape or form that is substantially box-shaped, whereby a portion of the main body is formed into a box like orientation. The main body generally includes an upper and a lower main body, a tang member and the two-bodied spring. The tang member includes a lever member which locks the electrical female terminal within the connector assembly. The lever member has a protruding member which meets another protruding member, extending from the main body, when the lever member is flexed. Both protruding members act as an overstress protection for the lever member; i.e., to prevent or protect the lever member from becoming deformed when the electrical female terminal is being mated with the connector assembly. Another protruding member extends from the lever member to protect the two-bodied spring from becoming overstressed. The main body is also comprised of a support member at both front and back ends thereof, which prevent overstress and deformation of the electrical female terminal.
The two-bodied spring is substantially located within a passageway PW of the main body, and includes two members, which act or operate to create a spring force which can be applied to a male pin or male terminal, or further “blade-like” object, when one of such aforementioned objects is being inserted into the female electrical terminal.
The electrical female terminal of this invention also has an orientation or polarity which is maintained and ensured for proper fitment into a corresponding connector assembly. The connector assembly has an opening with a similar orientation or similar polarity which is also maintained for proper fitting with the electrical female terminal.
Additionally, a front portion of the wire fastening portion has a neck member which transitions to the main body of the electrical female terminal, with a space thereof for accommodating a TPA device.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1A is a front top perspective view of the electrical female terminal of this invention; and FIG. 1B is a back top perspective view of the electrical female terminal of this invention.
FIG. 2A is right side elevational view of the electrical female terminal of this invention; and FIG. 2B is a left side elevational view of the electrical female terminal of this invention; FIG. 2C shows a terminal position assurance (TPA) device positioned in a space of the electrical female terminal; and FIG. 2D is a cross-sectional view taken along the line along line 2D-2D in FIG. 8B illustrating surface area of the electrical female terminal to interfere with a terminal position assurance (TPA) device.
FIG. 3A is a top elevational view of the electrical female terminal of this invention; and FIG. 3B is a bottom elevational view of the electrical female terminal of this invention.
FIG. 4 is a partial side elevational view of the electrical female terminal of this invention showing protruding members respectively extending from a lever member and from the main body and the support member of the upper guide member.
FIG. 5A illustrates an opening of the front end portion of the electrical female terminal and a guide member for guiding a male terminal pin or male terminal upon entry therethrough and into a passageway, while FIG. 5B is a cross-sectional view taken along line 5B-5B in FIG. 5A which illustrates the opening of the front end portion and a guide member, as well as the lower spring member having an apex on a curved portion thereof.
FIG. 6A is a cross-sectional view taken along line 6A-6A in FIG. 1B, while FIG. 6B is a schematic illustration of the guide member located near the opening of the front end portion of the electrical female terminal.
FIG. 7 shows the two-bodied spring and further shows a top retainer member mounted onto the spring.
FIG. 8A shows, in part, a side of the electrical female terminal having a window for at least partially accommodating a curved side member of the two-bodied spring; and FIG. 8B illustrates, in part, another side of the electrical female terminal showing various elements of the electrical female terminal of this invention, including support members located at front and back end portions of the main body.
FIG. 9 shows a conventional electrical wire or cable for interaction with the electrical female terminal of this invention, the conventional electrical wire or cable having a wire insulation portion and a wire core portion at a front portion thereof.
FIG. 10A shows a front elevational view of the electrical female terminal of this invention at pre-lock position within the connector assembly; and FIG. 10B shows a front elevational view of the electrical female terminal of this invention fully rested and at a full-lock position within the corresponding connector assembly, FIGS. 10A and 10B further showing the polarities or orientations of the electrical female terminal of this invention and the corresponding connector assembly for effective fitting therewith.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1A shows a front top perspective view of the electrical female terminal, generally referred to as reference number 1. The electrical female terminal 1 is integrally formed as a continuous piece, being folded, creased, or curved, to form a single construct, and one which includes a main body 5, a two-bodied spring 130, and a wire fastening portion 3. The main body 5 further includes a tang member 15. The wire fastening portion 3 may be of a foldable crimp or clamping type as shown here, but may further be of an insulation displacement contact (IDC) type, or other similarly formed wire fastening means being integrally formed and preferably extending substantially with or in the lengthwise direction of the electrical female terminal 1, and more specifically extending from a rear portion of the main body 5 of the electrical female terminal 1 which is able to interact with an wire insulation portion 120 and or wire core portion 110 of the electrical wire or cable 100 to securely connect the electrical wire or cable 100 to the electrical female terminal 1. Further, an additional or sole wire fastening of the electrical wire or cable 100 to the electrical female terminal 1 may be accomplished by including means of creating a secure and or an electrically conductive fastening by including but not limited to, for example, welding, brazing, soldering and or other similar means.
Illustrated in more detail, in a back top perspective view of the electrical female terminal 1 in FIG. 1B, are the tang member 15 and the two-bodied spring 130. It is preferable that the main body 5 has a shape or form that is substantially box-shaped in the lengthwise direction, and similarly, in a direction opposite the lengthwise direction of the electrical female terminal 1, whereby a substantial portion of the main body 5 is formed into a box like orientation or construct, although the shape or form thereof is not restricted thereto (See, FIGS. 1A, 1B, 5A).
As illustrated in FIGS. 2A and 2B, the wire fastening portion 3 transitions to and is integrally formed with and to the main body 5 by a neck member 52 (see also, FIGS. 3A, 3B).
As illustrated in FIG. 2A, the tang member 15 includes a lever member 25, the lever member 25 having an unattached end portion 28 and an attached end portion 30. As further seen in FIGS. 2A and 2B, the lever member 25, is shown here in a normal, relaxed state. The lever member 25 is resiliently biased to the normal relaxed state whereby, it is not being influenced by outside contact, and whereby the point of subsequent flex of lever member 25 may occur at the attached end portion 30 when the unattached end portion 28 is moved. The unattached end portion 28 of the lever member 25 preferably has, in a cross-section along a width thereof, a substantially U-shaped form, or the like, although the form thereof is not restricted thereto (see, FIGS. 1B, 5B). The attached end portion 30 of the lever member 25 preferably has, a substantially L-shaped form or the like, although the form thereof is not restricted thereto (see, FIG. 1B, 5A, 5B).
Further, the lever member 25 has a protruding member 35, which meets another protruding member 37 that extends from the main body 5 (see, FIGS. 1B, 2B, 5 and 8A). Both protruding members 35, 37 act as an overstress protection for the lever member 25. That is, the protruding members 35, 37 impinge against each other, when the lever member 25 is in a flexed state. This form thereby prevents or protects the lever member 25 from becoming deformed when the female terminal 1 contacts or mates with a connector assembly 90 or the like (see also, FIGS. 10A and 10B). As such, the lever member 25 is operative to substantially move between a flexed state and a normal, relaxed state whereby it may return to the normal, relaxed state without being substantially deformed, or be inoperable, and still able to secure the female electrical terminal 1 with a connector housing 90, as discussed later (FIGS. 10A, 10B). As seen at the side elevational view of FIG. 2B, the protruding members 35, 37 are preferably substantially rectangular, round, trapezoid, or the like (see also, FIGS. 4, 8A), although the shape or form thereof is not restricted thereto.
In operation, when the electrical female terminal 1 enters the connector assembly 90, the unattached end portion 28 of the lever member 25 is freely pushed downward and moves from the normal relaxed state, to a flexed state (that is, the protruding member 35 approaches the another protruding member 37) (see, FIG. 10A). Upon full insertion of the electrical female terminal 1 into the connector assembly 90, the unattached end portion 28 of the lever member 25 freely moves upward, with a return to a normal, relaxed state of the lever member 25 (that is, the protruding member 35 moves away from the another protruding member 37 and when the lever member 25 is resiliently biased back to its normal, relaxed state) (see, FIGS. 2A, 10B). Further, the unattached end portion 28 is preferably thereby impinged onto a member (not shown) inside the connector assembly 90, locking and securing therein the electrical female terminal 1. Such a structural arrangement, which has the unattached end portion 28 of the lever member 25 impinged inside the connector assembly 90, acts as a locking and securing feature of the electrical female terminal 1 with the connector assembly 90 (see, FIG. 10B). The lever member 25 and the unattached end portion 28 may be further freely movable in an upward direction away from the normal, relaxed state, and flex away from a floor 122 of main body 5, and as will be discussed later, if the lever member 25 is flexed upward this may result in a resistance in a direction back to the normal relaxed state of the lever member 25. If the two-bodied spring 130 pushes or contacts the lever member 25 to the aforementioned flexed state, the lever member 25 can act upon the two-bodied spring 130 and add to the spring force of the two-bodied spring 130. This, notably, when the two-bodied spring 130 is flexed upward and away from the floor 122 and makes contact the lever member 25 and more specifically as the two-bodied spring 130 interacts with a male pin or male terminal, or further “blade-like” object.
As seen in FIG. 1A, a protruding member 36 also extends from a side of the lever member 25. Protruding member 36 is located substantially above, and further may engage with, a lower spring member 133, and even further provide overstress protection for the lower spring member 133, and generally the two-bodied spring 130, as will be discussed in more detail later (see, e.g., FIGS. 1A, 2A, 5, 6A and 8A). The protruding member 36 moves freely and unobstructed within the movement of the lever member 25, when the lever member 25 moves in a downward travel from its normal, relaxed state, into a flexed state toward the two-bodied spring 130 and a floor 122 of the main body 5. Protruding member 36 is preferably substantially rectangular, round, trapezoid, or the like (see, FIG. 6A), although the shape or form thereof is not restricted thereto. Additionally, and with respect to the side of the lever member 25 from which protruding member 35 extends, protruding member 36 extends on an opposite side thereof of lever member 25, as well as on a different portion and having a different orientation with respect to the side of the lever member 25 from which the protruding member 35 extends, more specifically, the protruding member 36 is closer to the attached end portion 30 and the protruding member 35 is closer to the unattached end portion 28 when comparing their location along the lever member 25 (see, FIGS. 4, 6A, and 8A). The protruding member 36 and the protruding member 35 are positioned along the lever member 25 wherein they are neither mirror images, nor directly opposed, and further thus do not have portions thereof, respectively, which are mirror images or directly opposed, therefore no portions thereof of protruding member 36 and protruding member 35 overlap along the lengthwise direction of the electrical female terminal 1 (see, FIGS. 2A, 2B).
As also seen in FIGS. 1A and 1B, 2A and 2B, the wire fastening portion 3 of the electrical female terminal 1 has a space or transition area 50 above the neck member 52. The space or transition area 50 is located at a front portion 51 of the wire fastening portion 3, and behind the main body 5. When the electrical female terminal 1 is fully inserted into the connector assembly 90, a space or transition area 50 is thereby available for accommodating therein a terminal position assurance (TPA) device 300 (see, FIG. 2C) for assuring that the electrical female terminal 1 remains locked, secured, and correctly positioned within the connector assembly 90. Further, when the terminal position assurance (TPA) device 300 is located substantially behind the main body 5, it may additionally prevent the electrical female terminal 1 from being removable, ejected, slidably removable or slidably ejected from the connector assembly 90, in use and in operation (see, e.g., FIG. 2C).
FIG. 2D is a cross-sectional view illustrating a surface area located on a rear portion of the lower spring member 133, of the electrical female terminal 1. Specifically, the surface area on a rear portion of the lower spring member 133 of the main body 5, may engage with the terminal position assurance (TPA) device 300. In operation, the rear portion of the lower spring member 133, provides an added interface area or interference surface for the electrical female terminal 1 for it to interact with, and or contact, and thereby interfere with the TPA device 300 when the TPA device 300 is inserted thereinto the space or transition area 50, further assuring that the electrical female terminal 1 remains locked, secured, and correctly positioned within the connector assembly 90 and preventing the electrical female terminal 1 from being removable, ejected, slidably removable or slidably ejected from the connector assembly 90, in use and in operation (see, e.g., FIG. 2C).
Illustrated in FIGS. 3A and 3B is the top and bottom elevational views, respectively, of the electrical female terminal 1, illustrating the main body 5 and wire fastening portion 3 which are integrally connected and formed together, substantially, in a lengthwise direction of the electrical female terminal 1.
Also illustrated in each of FIGS. 4A and 4B, is the front portion 51 of the wire fastening portion 3. The front portion 51 of the wire fastening portion 3 includes the space or transition area 50 which is above the neck member 52 as previously discussed. More specifically, the neck member 52 has a narrowly tapered shape, narrowly tapering along the lengthwise direction of the electrical female terminal 1 from the wire fastening portion 3 toward, and meeting narrowly at, the main body 5. Also, the narrowly tapered shape of the neck member 52 of the front portion 51 prevents the wire core portion 110 of the electrical wire or cable 100 from being seated or mounted, in its entirety, onto and into the neck member 52. Preferably, the narrowly tapered form of the neck member 52 of the wire fastening portion 3 allows only a front portion of the wire core portion 110 of the electrical wire or cable 100 to protrude into the neck member 52. That is, the narrowly tapered form of the neck member 52 further prevents the wire core portion 110 from entering substantially into the space or transition area 50. The transition area 50, as described earlier, becomes available for accommodating therein the TPA device 300 (see FIG. 2C) for assuring that the electrical female terminal 1 remains locked, secured, and correctly positioned when inserted within the connector assembly 90. Thus, wherein only a front portion of the wire core portion 110 enters or protrudes into the space or transition area 50, the wire core portion 110 will not interfere with or inhibit accommodating therein, of the TPA device 300.
Illustrated in FIG. 4 is the tang member 15 and the attached end 30 and unattached end portion 28 of the lever member 25 thereof. As previously discussed with respect to FIGS. 2A and 2B, FIG. 4 further illustrates the protruding member 35 of the unattached end portion 28 of the lever member 25, which is capable of impinging against another protruding member 37 that extends from the main body 5 (more particularly, extending from a lower portion 250 of the main body 5) in preventing the lever member 25 from being deformed when the lever member 25 is flexed. The just-described structural arrangement protects the lever member 25 from being overstressed (and thereby prevented from being deformed, over-flexed or inoperable to lock the terminal with connector assembly 90) when the lever member 25 is pushed downward toward the lower portion 250 of the main body 5 and two-bodied spring 130, upon the electrical female terminal 1 entering or slidably entering into the connector assembly 90.
As further illustrated in FIG. 4, the attached end portion 30 of the lever member 25 is attached to an upper portion 200a of main body 5 (see also, FIG. 8B). Also shown in FIG. 4 is an aperture 113 passing through a side member 121 of the main body 5 for accommodating therein, for support, a support member 115 of an upper guide member 105, as more fully discussed below (see, e.g., FIGS. 5A, 5B).
The front opening 125 of the main body 5 is shown in FIG. 5A. The front opening 125 is defined by the front end portion 200, having a floor 122, a side member 103, a side member 121, and the upper guide member 105. As mentioned above, side member 121 includes the aperture 113, passing through the side member 121, and for accommodating the support member 115 of the upper guide member 105. FIG. 5B is a cross-sectional view taken along line 5B-5B in FIG. 5A. As illustrated in FIGS. 5A and 5B, the aperture 113 substantially accommodates therein the support member 115. The support member 115 integrally extends from the upper guide member 105 and in a direction perpendicular to the lengthwise direction of the electrical female terminal 1. The support member 115 ensures that the upper guide member 105 remains properly oriented, and stably supported by and within the main body 5 an front opening 125. The support member 115 also prevents the deformation of the front opening 125 and stable orientation of the front end portion 200, floor 122, side member 103, side member 121, with respect to the upper guide member 105, further to ensure the shape, polarity or orientation, of the main body 5 is not disrupted by the insertion of the male pin or male terminal, or further “blade-like” object (not shown). Also shown in FIG. 5B is a substantially hump-like member 120 extending upward from the floor 122, which is further discussed in more detail below.
Further displayed in FIGS. 5A and 5B is a passageway PW which extends through the lengthwise direction of the electrical female terminal 1 and main body 5 and is defined by the front opening 125, the front end portion 200 (which defines the front opening 125 as described previously), and the space surrounded by the inner surfaces of a lower portion 250 of the main body 5. The passageway PW therefore is able to accommodate therein the male pin or male terminal, or further “blade-like” object.
The relationship between the substantially hump-like member 120 and the two-bodied spring 130 is illustrated in FIG. 6A, which is a cross-sectional view taken along line 6A-6A in FIG. 1B. Further illustrated in FIG. 6A, is the upper guide member 105 of the front end portion 200 of the main body 5. The upper guide member 105 is comprised of a first substantially level portion 105a, a substantially inclined portion 105b, and a second substantially level portion 105c. The aforementioned portions of the upper guide member 105 comprise and act as a guiding feature, to direct, orient and or “self-correct” the male pin or male terminal, or further “blade-like” object into the front opening 125 and passageway PW of the electrical female terminal 1. More specifically, the lower surface of the upper guide member 105 extends substantially along and defines the upper portion of the passageway PW, from the front opening 125 of the main body 5, toward the two-bodied spring 130 of the electrical female terminal 1, in the respective lengthwise direction of the electrical female terminal 1 (see FIGS. 5A, 5B, 6A). From the front opening 125, the first substantially level portion 105a extends and defines the upper surface of the front opening 125 and front portion of passageway PW, the second substantially inclined portion 105b further defines the passageway PW, and similarly, the third substantially level portion 105c defines the passageway PW, respectively, as illustrated in FIGS. 6A and 6B. More specifically, the upper guide member 105 directs, orients and or “self-corrects” a male pin or male terminal, or further “blade-like” object (not shown) in a lengthwise direction through the passageway PW, by guiding the male pin or male terminal, or further “blade-like” object at the front opening 125 from the front end portion 200 of the main body 5, further guiding the object towards the two-bodied spring 130, and\or further guiding the object towards the substantially hump-like member 120 extending from the floor 122 and the respective lower spring member 133, and toward\into a space 160. The male pin or male terminal, or further “blade-like” object (not shown) here described, is inserted by entering or slidably entering into the electrical female terminal 1 into the passageway PW. As the male pin or male terminal, or further “blade-like” object (not shown) is further inserted into the passageway PW in a lengthwise direction, it is secured or impinged and fastened between the two-bodied spring 130 and the substantially hump-like member 120 and into the space 160, and further acted upon by the spring force of the two-bodied spring 130. As the male pin or male terminal, or further “blade-like” object (not shown) continues entering or slidably entering further into the passageway PW, it may lose contact with the upper guide member 105, as the male pin or male terminal, or further “blade-like” object becomes oriented in a substantially level or perpendicular orientation to\with the topmost surface of the substantially hump-like member 120. More specifically, the male pin or male terminal, or further “blade-like” object (not shown) may lose contact with the first substantially level portion 105a, a second substantially inclined portion 105b respectively (and depending on the size of the male pin or male terminal or further “blade-like” object, it may lose contact with the third substantially level portion 105c) as the male pin or male terminal, or further “blade-like” object becomes oriented in a substantially level or perpendicular orientation to\with the topmost surface of the substantially hump-like member 120. Further, if the male pin or male terminal, or further “blade-like” object (not shown) is inserted in an angled orientation with respect to the lengthwise direction of the pin, it is preferable that an end or tip of such object will not enter into the distance or the space formed between the third substantially level portion 105c and the two-bodied spring 130. Additionally, the male pin or male terminal, or further “blade-like” object (not shown) may be further oriented during its initial insertion into the electrical female terminal 1, wherein the end or tip of the male pin or male terminal, or further “blade-like” object may contact or may not contact the lower surface of the upper guide member 105 when within the passageway PW.
The two-bodied spring 130, as shown in FIG. 6A, has an upper spring member 131 and the lower spring member 133. The two-bodied spring 130 extends substantially from a back end portion 210 of the main body 5 towards the front end portion 200 of the main body 5 and in a lengthwise direction along electrical female terminal 1. As in FIG. 6A, the lower spring member 133 extends longer and or further in the lengthwise direction than the upper spring member 131, and reaches further towards the front end portion 200 of the main body 5 and above the substantially hump-like member 120, as well.
As illustrated in FIG. 6A, the upper spring member 131 extends partially along and above the lower spring member 133. As further seen in FIG. 6A, the upper spring member 131 may contact the lower spring member 133 at a point located on the lower spring member 133 thereof which is substantially toward the front end portion 200 of the main body, and more specifically at a point located before the portion of lower spring member 133 above the substantial hump-like member 120. Further, an inclined portion of the upper spring member 131 extends and is substantially inclined and toward the floor 122 of the main body 5. In an unflexed position, this substantially inclined portion of the upper spring member 131 does not substantially contact the lower spring member 133 except for, preferably in full or in part, at a single point, and less preferably the substantially inclined portion of the upper spring member 131 may not contact the lower spring member 133 at all. Further, in a flexed position the upper spring member 131 can be in contact with, and be slidably contacted with, in full or in part, against a similarly flexed lower spring member 133 while providing a spring force, therewith, the spring force of the lower spring member 133, resulting in the a combined spring force of both the lower and upper spring members respectively and thereby provided by the two-bodied spring 130 in its entirety (as shown in FIGS. 6A, 8B).
As further evidence of the relationship mentioned above, when the lower spring member 133 and upper spring members 131 are in contact in an unflexed state, the initial spring force will be evident as that of both the upper and lower spring members 131, 133 by both applying their respective spring forces in unison or together, and or in total, and acting upon the male pin or male terminal, or further “blade-like” object (not shown) inserted into the electrical female terminal 1. In contrast, when the upper and lower spring members 131, 133 do not contact in their respective unflexed states, the initial applied spring force will be evident solely as that of the lower spring member 133 spring force, as it flexes, until the lower spring member 133 makes initial contact or contacts with the upper spring member 131, whereby the upper spring member 131 will apply a spring force against the lower spring member 133 and in unison or together and or in total against the male pin or male terminal, or further “blade-like” object.
As further seen in FIG. 6A, a portion of the lower spring member 133, while in a normally relaxed and unflexed state, is substantially inclined downward toward the floor 122 of the main body 5, and into the lower portion 250 of the main body 5 and into the passageway PW. A portion of the lower spring member 133, within the passageway PW, is movable substantially unobstructed in an upward direction away from the floor 122. Another portion of the lower spring member 133 is obstructed by, and except for, a concurrent movement upward with and against the upper spring member 131, as the result of the lower spring member 133 contacting the upper spring member 131. More specifically, when the male pin or male terminal (not shown) is inserted into the passageway PW, the two-bodied spring 130 will move from its normal, relaxed state and into a flexed state, and the substantially unobstructed portion of the lower spring member 133 may additionally substantially exit the passageway PW. Thus, the two-bodied spring 130 asserts its spring force against and or acting upon the male pin or male terminal or further “blade-like” object, in the direction of a return to its normal, unflexed state. The two-bodied spring 130, at the substantially unobstructed portion of lower spring member 133, will move further upward, away from the floor 122, and towards the lever member 25. Thus, the two-bodied spring 130 may continue to be movable substantially unobstructed until its travel is limited by the lower spring member 133, as the two-bodied spring 130 contacts the protruding member 36 of the lever member 25. Additionally, the lever member 25 may be static or immobile or prevented from moving in the direction away from the floor 122 (e.g. by potential contact with the connector assembly 90), whereby the protruding member 36 provides an overstress protection for the lower spring member 133, and thus the two-bodied spring 130. In operation, and or when the electrical female terminal 1 resides in the connector assembly 90, the lever member 25 is preferably in a normal, unflexed state wherein the lower spring member 133 commences to interact with the male pin or male terminal (not shown), thereby providing for the greatest distance of substantially unobstructed travel of the two-bodied spring 130 in an upward direction, away from the floor 122, to accommodate fully the size of the male pin or male terminal (not shown) and prevent the two-bodied spring 130 from contact with the lever member 25. In the situation where the lever member 25 is further movable away from the floor 122, and not static or not immobile or prevented from moving in the direction away from the floor 122 (e.g. contact with the connector assembly 90), the lever member 25 is further movable upward and away from its normal, unflexed state. Thus if the two-bodied spring 130 contacts the lever member 25 when it is in the aforementioned position, the resulting contact of the end portion 135 of lower spring member 133 with a portion of the protruding member 36 or lever member 25 results in the resilient force of the lever member 25, as it flexes away from its normal, relaxed state and away from the floor 122, to be applied and added in addition to the spring force of the two-bodied spring 130. Specifically, the lever member 25 thereby adds onto the spring force of the lower spring member 133 as it makes contact with the lever member 25, in full or in part, and thus generally the two-bodied spring 130. More specifically, in the aforementioned situation, the resilient force applied by the lever member 25, in the direction of return to its normal, relaxed state, is in a direction opposite the movement of the end portion 135 of lower spring member 133 when making contact with the lever member 25 and or protruding member 36, and thereby, increases the spring force of the two-bodied spring 130 in a downward direction towards the floor 122, or the male pin or male terminal or further “blade-like” object under the two-bodied spring 130, and even more specifically directed to an apex A of the two-bodied spring 130, as will be discussed below.
As further illustrated in FIG. 6A, an end portion 135 of the lower spring member 133 includes a substantially curved portion 137 that curves to an apex A, and is directed downward toward the substantially hump-like member 120 (see FIG. 5B). The male pin or male terminal (not shown) upon entering through the front opening 125 and into passageway PW, will become secured or impinged between the substantially curved portion 137 and the substantially hump-like member 120 and within the space 160. The space 160 accommodating the male pin or male terminal (not shown) is defined by the distance between the substantially curved portion 137, and the topmost surface of the hump-like member 120 substantially parallel to the floor 122 of the lower portion 250 of the main body 5. The space 160 becomes enlarged or expansive wherein the two-bodied spring 130 moves in an upward direction, away from the floor 122, while further interacting with the male pin or male terminal (not shown). As the two-bodied spring 130 moves in an upward direction, away from the floor 122, and this increases the distance between the substantially curved portion 137, and the topmost surface of the hump-like member 120, and thus increases the space 160. The substantially curved portion 137, at its apex A, provides preferably for a single point of contact between the two-body spring 130 and an inserted male pin or male terminal (not shown), within space 160. The apex A of the substantially curved portion 137, allows for the spring force of the two-bodied spring 130 to be located, directed, and substantially fixated at a point above, central, and centered over the substantially hump-like member 120, and onto and act upon a respective male pin or male terminal as it is inserted or resides in space 160.
As also shown in FIG. 6A and located above the upper spring member 131 is a top retainer member 140. The ends of the top retainer member 140 are substantially connected to the main body 5 at two points, (one end connected to the side member 121 of the main body 5 and one at the upper main body 210a at the back end portion 210) (see, FIGS. 6A, 8A and 8B). Top retainer member 140 has a portion substantially U-shaped, as the bottom part 142 thereof, which contacts and abuts, in part, the upper spring member 131 (also see, FIGS. 8A, 8B). As seen in FIG. 6A, the top retainer member 140 provides a substantially rigid and resilient surface abutting the upper spring member 131 and ensures the folded construction of the two-bodied spring 130 is maintained and contact between the upper spring member 131 and lower spring member 133 is maintained. As in FIGS. 7, 8A, the top retainer member 140 prevents and maintains the upper spring member 131 from being unfurled, unfolded, substantially separated, or deformed from a level, and preferably substantially parallel orientation with the lower spring member 133 above the lower portion 250 of the main body 5. The upper spring member 131 and lower spring member 133 may be oriented whereby they contact in full or in part. Additionally, the top retainer member 140 maintains the folded construction of the two-bodied spring 130 by preventing the upper spring member 131 and lower spring member 133 from being unfurled, unfolded, substantially separated, or deformed as the two-bodied spring 130 is in a normal, unflexed state, or is in a flexed state wherein spring force is exerted against a male pin or male terminal (not shown).
As illustrated in the schematic diagram in FIG. 6B, the front end tip 150, of the end portion 135 of the lower spring member 133, is to be in line or above the lower surface 155 of the second level portion 105c of the upper guide member 105. This orientation ensures the male pin or male terminal (not shown) passing through the front opening 125 is effectively guided by the upper guide member 105 and the end portion 135 of the lower spring member 133, along the substantially curved portion 137, and passes through a space 160 between the curved portion 137 of the lower spring 133 and the substantially hump-like member 120 (see also, FIG. 6A). Additionally, the front end tip 150 of the end portion 135 of the lower spring member 133 is to be in line or above the lower surface 155 of the second level portion 105c of the upper guide member 105 so as to prevent the lower spring member 133 from being impinged or oriented whereby unfavorably the male pin or male terminal passes between the lower surface 155 of the second level portion 105c and the end portion 135 of the lower spring member 133, and or into the gap or space created there between the aforementioned portions when the male pin or male terminal is inserted in an angled orientation with respect to a lengthwise direction of the electrical female terminal 1.
As illustrated in FIG. 7, the upper spring member 131 and the lower spring member 133 of the two-bodied spring 130 are integrally structured with each other and connected by curved side members 170, 133a, and folded one above the other, with the upper spring member 131 being above the lower spring member 133 respectively. Under the top retainer member 140, the two-bodied spring 130 is preferably substantially parallel in a lengthwise direction of electrical female terminal 1 to the floor 122 (also see, FIG. 6A). The upper spring member 131 and lower spring member 133 may also be oriented whereby they contact in full or in part along the lengthwise direction of the electrical female terminal 1 to the floor 122. As further shown in FIG. 7, the upper and lower spring members 131, 133 are integrally connected by the curved side member 170 of the two-body spring member 130 (also see FIG. 8A). The curved side member 170 is accommodated, at least in part, within a window or opening 180 of the main body 5. Also illustrated in FIG. 7 is the curved side portion 133a of the main body 5, which integrally connects the lower spring member 133 to the lower portion 250 of the main body 5 (also see, FIG. 8B). The curved side member 170 and curved side portion 133a may further influence and allow the resultant spring force of the two-bodied spring 130 to be further dependent or optimized upon the aspects of thickness, length, or radius of curvature etc. of the curved side member 170 and or curved side portion 133a, both respectively.
As previously mentioned, a portion of the lower spring member 133 is movable unobstructed in an upward direction, away from the floor 122, until a portion of the lower spring member 133 contacts protruding member 36 of the lever member 25. Preferably, the two-bodied spring 130 will be initially flexed in the upward direction and away from the floor 122, by a male pin or male terminal (not shown), and initially and preferably occurring when the lever member 25 is in a normal unflexed orientation to allow the lower spring member 133 the greatest distance of travel between the floor 122 and the protruding member 36. The lower spring member 133 has the end portion 135 which is a portion of the lower spring member 133 projected upward or inclined towards the upper main body 200a and lever member 25. The upward movement away from the floor 122 of the lower spring member 133 and end portion 135, will ultimately lead to, and result with the end portion 135 thereof reaching substantially near or touch/contact the protruding member 36 of lever member 25, and thereby limit the upward travel of the two-bodied spring 130 where the lever member 25 is static or immobile or prevented from moving in the direction away from the floor 122. In the previous instance, a resulting contact of the end portion 135 of lower spring member 133 with a portion of the protruding member 36, will prevent the end portion 135, and consequently, the lower spring member 133 and upper spring member 131 from being further moveable, overstressed or substantially deformed upward when the female terminal 1 is mating with a male pin or male terminal (not shown). Thus, this prevents the overstress or substantial deformation of the two-body spring 130 and the two-body spring 130 may return to an unflexed state if or when a male pin or male terminal is further then removed from the electrical female terminal 1. Further, and as previously mentioned, in the situation wherein the lever member 25 is further movable away from the floor 122, and not static or not immobile, and is instead mobile, and unimpeded, the lever member 25 is further movable upward and away from the floor 122, and or concurrently with the two-bodied spring 130. It is then further possible, where the resulting contact of the end portion 135 of lower spring member 133 with a portion of the protruding member 36, results in a resilient force applied to the lower spring member 133 by the lever member 25. The resilient force applied by the lever member 25 against the end portion 135 of lower spring member 133 therefore adds onto the spring force of the two-bodied spring 130.
Illustrated in FIG. 8B are both the front and the back end portions 200, 210 of the main body 5, having a first support member 215 and a second support member 220, respectively. More particularly, an upper portion 200a at a front end portion 200 of the main body 5 includes the first support member 215, while the upper portion 210a at the back end portion 210 of the main body 5 includes the second support member 220. A gap 230 may separate the first support member 215 from a lower portion 250 of the main body 5. A gap 240 may separate the second support member 220 from the lower portion 250 of the main body 5. When the electrical female terminal 1 enters the connector assembly 90, the first support member 215 and the second support member 220 are resiliently pushed downward toward, and may substantially contact, the lower portion 250 of the main body 5 through the gaps 230, 240, respectively, which may eliminate the gaps 230, 240. On the other hand, the gaps 230, 240 may not exist before the electrical female terminal 1 enters the connector assembly 90, wherein the first support member 215 and second support member 220 are fully contacting the lower portion 250 of the main body 5. With the above-described structural arrangements, the first and second support members 215, 220 provide structural resilience and rigidity to the main body 5, providing a support for the upper portions 200a, 210a of the main body by providing an available interface surface thereof facing the lower portion 250 of the main body 5. Therein, the first and second support members 215, 220 prevent the electrical female terminal 1 of this invention from being overstressed or deformed and as well as when being fitted into the connector assembly 90 and in use (see FIGS. 10A, 10B).
FIG. 9 illustrates an exemplary electrical wire or cable 100 having the wire core portion 110 and the wire insulation portion 120, which are accommodated onto the electrical female terminal 1 of this invention. The priority or order of accommodation of the wire insulation portion 120 and the wire core portion 110 of electrical wire or cable 100 with the electrical female terminal 1 is not limited. thereto one embodiment of the wire fastening portion 3. The wire fastening portion 3 shown in this invention is one such embodiment of a wire fastening portion 3, but the current invention is not limited to this embodiment. However, as previously mentioned, the wire fastening portion 3 may be of a foldable crimp or clamping type as shown, but further may be an insulation displacement contact (IDC) type, or other similarly formed wire fastening means being integrally formed with a rear portion and preferably extending substantially with or in the lengthwise direction of the electrical female terminal 1, more specifically extending from the rear portion of the main body 3 of the electrical female terminal 1, and preferably able to interact with the wire insulation portion 120 and wire core portion 110 of the electrical wire or cable 100 to securely connect the electrical wire or cable 100 to the electrical female terminal 1. Further, as mentioned, the fastening of the electrical wire or cable 100 to the electrical female terminal 1 may include means of creating a secure and electrically conductive wire fastening including but not limited to welding, brazing, soldering and or other similar means. This invention is further not limited to the steps of insertion of the electrical wire or cable 100, wherein, the wire insulation portion 120 can be inserted first and the wire core portion 110 can be inserted second, and vice versa, and both may occur simultaneously depending on the structure and features of the wire fastening portion 3.
After or once the electrical wire or cable 100, having the wire insulation portion 120 and the wire core portion 110 thereof, is securely attached or inserted onto the electrical female terminal 1 by wire fastening means of the wire fastening portion 3 to the electrical female terminal 1, the electrical female terminal 1 is then in condition to be inserted into the connector assembly 90 or the like, as illustrated in FIGS. 10A and 10B.
Illustrated in FIG. 10A is the electrical female terminal 1, in a pre-lock position, while being inserted into the connector assembly 90 or the like, the electrical female terminal 1 being shown in a front elevational view. As shown in FIG. 10A, the electrical female terminal is inserted into the corresponding connector assembly 90, the lever member 25 is consequently positively pushed downward by contact with the connector assembly 90 or by a user or device, to allow the electrical female terminal 1 to move further into, and be further inserted into the connector assembly 90. As discussed earlier, and seen in FIG. 10A, during insertion of the electrical female terminal 1 into the connector assembly 90, the protruding members 35, 37 (see, e.g., FIGS. 2B, 5 and 8A) and the first and second support members 215, 220 (see, e.g., FIG. 8B) prevent or protect at least the lever member 25, the main body 5, and the electrical female terminal 1 from becoming substantially overstressed or deformed, and further, to retain the proper orientation or polarity of the electrical female terminal 1, as further described later.
FIG. 10B shows the fully inserted electrical female terminal 1 into the connector assembly 90. As shown in FIG. 10B, the lever member 25 retracts upward to a normal, relaxed state and is further preferably locked or secured at the unattached end portion 28 by a member (not shown) inside the connector assembly 90. After or at this time, as discussed earlier (see, e.g., FIG. 2C), the TPA device 300 is then able to be accommodated within the space 50 located above the neck member 52 and behind the main body 5, thereby assuring that the electrical female terminal 1 remains locked, secured, and correctly positioned within the connector assembly 90.
Further as in FIGS. 10A and 10B, the upper portions 200a, 210a and the lower portion 250 of the main body 5 are in such polarity or orientation, so as to assure correct orientation of the electrical female terminal 1 for accurate insertion and fitting of the present electrical female terminal 1 of this invention inside an upper portion 90a and a lower portion 90b of the connector assembly 90, respectively.
Also shown in FIGS. 10A and 10B are the upper portion 90a and the lower portion 90b of the connector assembly 90 or the like. The orientation or polarity of the electrical female terminal 1 of this invention is such that when the electrical female terminal 1 of this invention is oriented, inserted, and fitted with the connector assembly 90, the upper portion 200a at the front end portion 200 and the upper portion 210a at the back end portion 210 (see, FIG. 8B) of the main body 5 are respectively accommodated by the upper portion 90a of the connector assembly 90, while the lower portion 250 (see, FIG. 8B) of the main body 5 is respectively accommodated by the lower portion 90b of the connector assembly 90. The structural orientation or polarity shown in FIGS. 10A and 10B of the electrical female terminal 1 of this invention are such that the upper portions 200a, 210a of the main body 5 will reside or fit within the narrower upper portion 90a. Further here the upper portion 200a and upper portion 210a are offset to one side in comparison to the lower portion 250 of the main body 5. The lower portion 250 is wider than the upper portions 200a, 210a and resides within the wider lower portion 90b of the connector assembly 90. However, such structural orientations or polarities of the electrical female terminal 1 of this invention, when inserted or fitted into the connector assembly 90 are not limited thereto. That is, when the electrical female terminal 1 of this invention is oriented, inserted, and fitted with connector assembly 90, it may have the upper portions 200a, 210a of the main body 5 and the upper portion 90a of the connector assembly 90 being wider in comparison to the lower portion 250 of the main body 5 and the lower portion 90b of the connector assembly 90 (not shown). And similarly, the upper portions 200a, 210a may be centered (not shown) or offset (FIGS. 10A, 10B), compared to the lower portion 250 of the main body 5 while the electrical female terminal 1 is mating with the connector assembly 90 (not shown). The polarity or orientation of the electrical female terminal 1 and connector assembly 90 will be substantially similar to allow a substantial fitment thereby together.
Although the foregoing description is directed to the preferred embodiments of the invention, it is noted that other variations and modifications will be apparent to those skilled in the art, and may be made without departing from the spirit or scope of the invention. Moreover, features described in connection with one embodiment of the invention may be used in conjunction with other embodiments, even if not explicitly stated above.