The present invention relates generally to a conductive component structure of electrical wire connection device, and more particularly to a conductive component having a restriction body and an aid unit or an elastic unit for guiding the conductive wire and enhancing the securing effect of the restriction body for the conductive wire.
A conventional terminal device or switch wire connection device has an insulation case (generally made of plastic material), a metal component (or so-called electrical conductive component) and a leaf spring conductor (or so-called metal leaf spring). The metal component and the leaf spring conductor are enclosed in the insulation case to press and electrically connect with or release a conductive wire plugged in the terminal device. For example, EP 2325947 A1 discloses a typical example.
Multiple conventional electrical connection terminals can be latched with a grounding rail (or conductive rail) in a row to set up a common grounding device of an electrical apparatus or mechanical equipment for conducting out the residual voltage or static of the machine. For example, US 2013/0143433 A1 “connection terminal”, US 2014/0127932 A1 “electrical connection terminal”, and U.S. Pat. No. 5,362,259 “ground conductor terminal” disclose typical examples.
Such electrical connection terminal or switch wire connection device generally includes an insulation case having a wire plug-in hole for the conductive wire to plug into the interior of the case. The case defines a chamber in which a conductive support (or conductive component) and a metal leaf spring are mounted. The metal leaf spring and the conductive component serve to press the conductive wire plugged into the case and contact or electrically connect with the conductive wire. Unless an operator uses a tool to extend into the case and push/press the metal leaf spring, the conductive wire cannot be released from the electrical connection or contact with the metal leaf spring and the conductive component.
The assembling structure of the conventional electrical connection terminal or switch wire connection device has some shortcomings in structure and operation application. For example, in practical wire layout operation, after a conductive wire is plugged into the case to connect with the conductive component, an operator will bend the conductive wire outside the case to perform wire trimming operation in accordance with the site space condition or wire layout path. The wire trimming operation is performed because when the metal leaf spring presses the conductive wire, a leverage effect is often produced to cause the rear end of the conductive wire to warp up (or leave the conductive component). As a result, the contact area between the conductive wire and the conductive support (or conductive component) is reduced to increase the impedance and raise the temperature of the conductive support. In case the temperature of the conductive support exceeds the heat tolerance of the plastic insulation case, the case will be damaged to affect the security.
In order to improve the shortcomings of insufficient pressing force and electro-conductive insecurity or efficiency, a conventional electrical connection terminal has been disclosed, which additionally includes a leaf spring arranged behind the metal leaf spring to help in pressing the conductive wire. For example, EP 3226351 A1 and EP 3226352 A1 disclose typical examples.
However, as well known by those who are skilled in this field, such electrical connection terminal is simply applicable to specific conductive wire or relatively small-diameter conductive wire to provide sufficient pressing force. When such conventional electrical connection terminal or switch wire connection device is connected with a large-diameter conductive wire, it often takes place that the pressing force applied by the metal leaf spring and the conductive component to the conductive wire is insufficient, the conductive wire can be hardly securely pressed, the rear end of the conductive wire is warped up and the conductive wire is apt to rotate, deflect or swing due to incautious touch of an operator to lead to poor contact and insecurity. This is not what we expect.
Another conventional electrical connection terminal has been disclosed, which includes a leaf spring and a steel leaf spring overlapped with the leaf spring to increase the pressing force for the conductive wire.
To speak representatively, the above reveals some shortcomings existing in the conventional wire connection terminal or switch wire connection device in structure assembly design and application. In case the structure assembly of the conductive component and the metal leaf spring or leaf spring conductor is redesigned to be different from the conventional wire connection terminal, the use form of the wire connection terminal can be changed to practically widen the application range thereof.
It is found that the structural form of an optimal conductive component must overcome or improve the aforesaid shortcomings of the conventional wire connection terminal and include several design considerations as follows:
It is therefore a primary object of the present invention to provide a conductive component structure of electrical wire connection device is more securely assembled with the conductive wire to enhance the electro-conduction performance. The conductive component includes a main body in the form of a plate body, a restriction body connected on the main body and an aid unit (or elastic unit) assembled with the restriction body. The restriction body has a base section, a first arm and a second arm connected with the base section and free sections connected with the first and second arms. The aid unit (or elastic unit) provides greater elastic holding action force for the restriction body. When the conductive wire is plugged into the case into contact with the conductive component, the rear end of the conductive wire is at least securely pressed between the first and second arms of the restriction body. The conductive component improves the shortcomings of the conventional structure that the conductive wire is apt to deflect or swing due to external force to lead to unstable contact and insecurity and affect the electro-conduction efficiency.
In the above conductive component structure of electrical wire connection device, the first arm and/or the second arm are bent from the base section to obliquely extend toward each other or in the same direction to define a mouth section. In addition, a bent section is formed between the first arm and the free section thereof and/or the second arm and the free section thereof to form an opening. Also, the free section of the first arm and/or the free section of the second arm are bent to extend toward outer side of the restriction body (or away from each other), whereby the restriction body can be elastically expanded to hold different diameters of conductive wires.
In the above conductive component structure of electrical wire connection device, the aid unit is a U-shaped structure having a base, a first waist section and a second waist section connected with the base and finger sections connected with the first waist section and/or the second waist section, whereby the aid unit can provide an elastic (holding) effect. The finger sections contact (or latch with) the bent section of the first arm or the bent section of the second arm of the restriction body to enhance the pressing action force applied by the first and second arms of the restriction body to the conductive wire. The finger sections also serve to control the expansion range of the first and second arms in response to the plug-in of the conductive wire so as to prevent the restriction body from permanently deforming.
The present invention can be best understood through the following description and accompanying drawings, wherein:
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Basically, the case 90 defines a chamber 91, in which the main body 10, the restriction body 20, the aid unit 40 and the metal leaf spring 30 of the conductive component are mounted. The case 90 has a wire plug-in hole 92 in communication with the chamber 91. The conductive wire 80 can be plugged through the wire plug-in hole 92 into the chamber 91 of the case 90 and the conductive component to electrically connect therewith.
The upper section, lower section, outer side and inner side mentioned hereinafter are recited with the direction of the drawings as the reference direction.
As shown in the drawings, the main body 10 is selectively made of an electro-conductive material (such as copper, brass or the like material) in the form of a plate body. The main body 10 has a first section 11 in parallel to the Z-direction reference axis and a second section 12 (perpendicularly) connected with the first section 11. The second section 12 is assembled and located in a locating slot 90a of the case 90. One end of the first section 11 is formed with a raised ridge section 13 as a load section for helping in pressing the conductive wire 80. The locating slot 90a of the case 90 is formed in a direction or a position along the X-direction reference axis.
In a preferred embodiment, the restriction body 20 is integrally formed (or assembled) on the main body 10. The restriction body 20 is selectively made of an electro-conductive (metal) material and disposed on the first section 11 of the main body 10. The restriction body 20 has a base section 25 connected with the main body 10 (or the first section 11), a first arm 21 and a second arm 22 connected with the base section 25 and free sections 23, 24 connected with the first and second arms 21, 22, which together provide elastic effect for the restriction body 20.
To speak more specifically, the first and second arms 21, 22 are respectively bent from the base section 25 to gradually obliquely extend toward each other along the X-direction reference axis (or in a direction normal to the plug-in direction of the conductive wire 80). The first and second arms 21, 22 define a mouth section 26 with a triangular configuration. A bent section 27, 28 is formed between each of the first and second arms 21, 22 and the free sections 23, 24, whereby the free section 23 of the first arm 21 and the free section 24 of the second arm 22 are bent to extend away from each other so as to define an opening 29, whereby the restriction body 20 can be elastically expanded to hold different diameters of conductive wires 80. As shown in the drawings, the opening 29 is open to the upper side (or along the X-direction reference axis).
In this embodiment, the metal leaf spring 30 is a substantially V-shaped structure including a first section 31, a second section 32 and a bow section 33 connected between the first and second sections 31, 32. The first section 31 has a head end 34 secured in a locating hole 14 of the case 90 or the main body 10. The bow section 33 is assembled on a stake 93 of the case 90 or the chamber 91, whereby the tail end 35 of the second section 32 can be elastically biased to press the conductive wire 80. As shown in the drawings, the locating hole 14 is disposed on the second section 12 of the main body.
The drawings also show the structures of the restriction body 20 and the aid unit 40 assembled with each other. The aid unit 40 is a U-shaped structure having an (arched) base 45, a first waist section 41 and a second waist section 42 connected with the base 45 and finger sections 43, 44 connected with the first and second waist sections 41, 42, which together define a space 46 with an opening 49, whereby the aid unit 40 can provide an elastic (holding) effect.
To speak more specifically, the first and second waist sections 41, 42 are respectively bent from two ends of the base 45 to extend along the X-direction reference axis (or in a direction normal to the plug-in direction of the conductive wire 80). The first and second waist sections 41, 42 are further bent toward each other along the Y-direction reference axis to form the finger sections 43, 44. The base 45 of the aid unit 40 is assembled on a locating section 94 of the case 90 (or the chamber 91) in the form of a plate-like structure). The finger sections 43, 44 contact or latch with the bent section 27 of the first arm and the bent section 28 of the second arm of the restriction body 20 to increase the elastic pressing action force applied by the first and second arms 21, 22 of the restriction body to the conductive wire 80. The finger sections 43, 44 also serve to control the expansion range of the first and second arms 21, 22 in response to the plug-in of the conductive wire 80 so as to prevent the restriction body 20 from permanently deforming.
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It should be noted that when a relatively large-diameter conductive wire is plugged into the conductive component and/or the wire trimming operation is performed, the rear end 81 of the conductive wire may be warped up. At this time, the rear end 81 of the conductive wire will be pressed/restricted or detained in the mouth section 26 by the first and second arms 21, 22 (and the aid unit 40) to keep in contact with the conductive component. This obviously improves the shortcoming of the conventional electrical connection terminal that the rear end of the conductive wire is apt to warp up and leave the conductive component so that the contact area between the conductive wire and the conductive component is reduced and the impedance is increased to raise the temperature of the conductive component.
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As shown in the drawings, the first and second arms 21, 22 of the restriction body are respectively bent from the base section 25 to gradually obliquely extend toward each other along the Z-direction reference axis (or in the plug-in direction of the conductive wire 80). The first and second arms 21, 22 define the mouth section 26.
A bent section 27, 28 is formed between each of the first and second arms 21, 22 and the free sections 23, 24, whereby the free section 23 of the first arm 21 and the free section 24 of the second arm 22 are bent to extend away from each other so as to define an opening 29 along the Z-direction reference axis (or in the plug-in direction of the conductive wire 80).
In this embodiment, the elastic unit 50 serves to help in increasing the elastic holding/securing action force applied by the restriction body 20 to the conductive wire 80. The elastic unit 50 is selectively made of an electro-conductive material identical to the restriction body 20 or a material with rigidity (or elastic action force) greater than that of the restriction body 20, such as steel material or the like material.
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As shown in the drawings, the first and second arms 51, 52 of the elastic unit are respectively bent from two ends of the base 55 to gradually obliquely extend toward each other along the Z-direction reference axis (or in the plug-in direction of the conductive wire 80). The first and second arms 51, 52 define a mouth section 56 with a triangular configuration. A bent section 57, 58 is formed between each of the first and second arms 51, 52 and the free sections 53, 54 of the elastic unit, whereby the free section 53 of the first arm 51 and the free section 54 of the second arm 52 of the elastic unit are bent to extend away from each other so as to define an opening 59 along the Z-direction reference axis (or in the plug-in direction of the conductive wire 80). Accordingly, the elastic unit encloses or overlaps a part of the restriction body 20 or the entire restriction body 20.
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As shown in the drawings, the restriction body 20 is formed with insertion sections 27a, 28a, with which the finger sections 43, 44 of the aid unit 40 are inserted. In a preferred embodiment, the insertion sections 27a, 28a are groove or dent structures positioned on the bent sections 27, 28 and/or the first and second arms 21, 22 and the free sections 23, 24 of the restriction body 20.
It should be noted that the inner sides of the first and second arms 21, 22 are formed with raised structures corresponding to the insertion sections 27a, 28a. Therefore, as shown in
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As shown in the drawings, at least the first arm 21 (and/or the second arm 22) of the restriction body 20 is integrally connected with the first section 11 of the main body along the Z-direction reference axis (or in the plug-in direction of the conductive wire 80). In addition, the first arm 21 (and/or the second arm 22) of the restriction body 20 is bent along the Y-direction reference axis to form a base section 25 connected with the first and second arms 21, 22 to together define the mouth section 26 with the opening 29. A bent section 28 is formed between the second arm 22 (and/or the first arm 21) and the free section 24 (and/or the free section 23). The free section 24 of the second arm 22 (and/or the free section 23 of the first arm 21) is bent to extend toward the outer side of the restriction body 20, whereby the opening 29 is open along the Z-direction reference axis (or in the plug-in direction of the conductive wire 80).
In this embodiment, the elastic unit 50 assembled with the restriction body 20 is similar to or identical to the restriction body 20. At least the first arm 51 (and/or the second arm 52) of the elastic unit 50 extends along the Z-direction reference axis (or in the plug-in direction of the conductive wire 80). In addition, the first arm 21 (and/or the second arm 22) of the elastic unit 50 is bent along the Y-direction reference axis to form a base section 55 connected with the first and second arms 51, 52 to together define the mouth section 56 with the opening 59.
As shown in the drawings, a bent section 58 is formed between the second arm 52 (and/or the first arm 51) and the free section 54 (and/or the free section 53). The free section 54 of the second arm 52 (and/or the free section 53 of the first arm 51) is bent to extend toward the outer side of the elastic unit 50, whereby the opening 59 is open along the Z-direction reference axis (or in the plug-in direction of the conductive wire 80). Accordingly, the elastic unit 50 encloses or overlaps a part of the restriction body 20 or the entire restriction body 20 as shown in
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In this embodiment, the metal leaf spring 30 is an α-shaped structure including a first section 31, a second section 32 and a bow section 33 connected between the first and second sections 31, 32. The first section 31 has a head end 34. The second section 32 is formed with a window 39 and a tail end 35 close to or adjacent to the second section 32. The head end 34 can be pressed and connected on the main body 10 (or the first section 11). The first section 31 and the bow section 33 provide elastic effect, whereby the main body 10 (or the first section 11) can block the window 39.
When an operator presses the metal leaf spring 30, the window 39 is unblocked, permitting the conductive wire 80 to enter the main body 10 through the window 39 to be securely held by the restriction body 20 assembled with the elastic unit 50. After the external pressing force applied to the metal leaf spring 30 disappears, the second section 32 and/or the window 39 is restored to securely press/restrict the conductive wire 80 together with the first section 11 of the main body (and/or the ridge section 13) as shown in
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In this embodiment, the main body 10 (or the first section 11) is bent along the X-direction reference axis to form a connection section 17. The connection section 17 is assembled and connected with the restriction body 20 (the first arm 21 and/or the second arm 22) by means of adhesion, riveting, welding, locking, etc. The restriction body 20 is assembled with the elastic unit 50 and cooperates with the window 39 of the α-shaped metal leaf spring 30 and the first section 11 of the main body (and/or the ridge section 13 of the first section 11) to together securely hold the conductive wire 80.
It should be noted that the V-shaped metal leaf spring or α-shaped metal leaf spring 30 can be alternatively assembled with and applied to the restriction body 20, the aid unit 40 or elastic unit 50 of the conductive component in accordance with practical requirement.
To speak representatively, in comparison with the conventional wire connection terminal, the conductive component structure of electrical wire connection device of the present invention has the following advantages:
In conclusion, the conductive component structure of electrical wire connection device of the present invention is different from the conventional wire connection terminal in space form and is advantageous over the conventional wire connection terminal. The conductive component structure of electrical wire connection device of the present invention is effective, greatly advanced and inventive.
The above embodiments are only used to illustrate the present invention, not intended to limit the scope thereof. Many modifications of the above embodiments can be made without departing from the spirit of the present invention.
Number | Date | Country | Kind |
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107109102 | Mar 2018 | TW | national |