WIRE CONNECTION TERMINAL STRUCTURE

Abstract

A wire connection terminal structure includes a case main body. Wire plug-in ports are connected with an electro-conductive module. Arcuate slide guide slots are disposed on the electro-conductive module. Rotary buttons are pivotally disposed in the case main body. Each rotary button has a movable section. A pin is disposed on the movable section. The pin is extended into the slide guide slot. At least one abutment leaf spring is pivotally disposed between the rotary button and the electro-conductive module. When a conductive wire passes through the wire plug-in port into the lateral side of the electro-conductive module, the rotary button can be driven to make the movable section gradually displace from a section of the abutment leaf spring near the pivotally rotational center to an outer lateral side. The abutment leaf spring is pushed to engage with the conductive wire.

Claims

1. A wire connection terminal structure comprising: a case main body, a recessed section and a wire plug-in port being disposed on a surface of the case main body; an electro-conductive module connected with the wire plug-in port, at least one slide guide slot being disposed on the electro-conductive module; at least one rotary button, the rotary button being pivotally disposed in the recessed section of the case main body via a first shaft rod, the rotary button having a shift section exposed to outer side of the case main body and a movable section extending toward the electro-conductive module, a pin being disposed on the movable section, the pin being extended into the slide guide slot and freely movably guided by the slide guide slot; and at least one abutment leaf spring pivotally disposed between the rotary button and the electro-conductive module, the abutment leaf spring being drivable by the rotary button to pivotally rotate.

2. The wire connection terminal structure as claimed in claim 1, wherein the slide guide slot is a hollow slide guide slot with an arcuate closed configuration.

3. The wire connection terminal structure as claimed in claim 1, wherein the abutment leaf spring is pivotally disposed in the case main body by means of a second shaft rod, which serves as a pivotally rotational center of the abutment leaf spring, during the process that the rotary button drives the abutment leaf spring, the movable section of the rotary button is gradually displaced from a section of the abutment leaf spring near the pivotally rotational center to an outer lateral side, whereby an arm of operation force applied by the rotary button to the abutment leaf spring to drive the same is gradually increased.

4. The wire connection terminal structure as claimed in claim 2, wherein the abutment leaf spring is pivotally disposed in the case main body by means of a second shaft rod, which serves as a pivotally rotational center of the abutment leaf spring, during the process that the rotary button drives the abutment leaf spring, the movable section of the rotary button is gradually displaced from a section of the abutment leaf spring near the pivotally rotational center to an outer lateral side, whereby an arm of operation force applied by the rotary button to the abutment leaf spring to drive the same is gradually increased.

5. The wire connection terminal structure as claimed in claim 3, wherein a middle section of the abutment leaf spring is formed with an arcuate bending section, an inner side of the bending section being pivotally fitted on the second shaft rod, whereby the abutment leaf spring is pivotally rotatably assembled on the second shaft rod, two ends of the bending section being respectively formed with a drive section in contact with the movable section and an engagement section proximal to the electro-conductive module.

6. The wire connection terminal structure as claimed in claim 4, wherein a middle section of the abutment leaf spring is formed with an arcuate bending section, an inner side of the bending section being pivotally fitted on the second shaft rod, whereby the abutment leaf spring is pivotally rotatably assembled on the second shaft rod, two ends of the bending section being respectively formed with a drive section in contact with the movable section and an engagement section proximal to the electro-conductive module.

7. The wire connection terminal structure as claimed in claim 5, wherein the abutment leaf spring is a set of abutment leaf springs composed of multiple overlapped abutment leaf springs with identical bending configuration, at least an outer end section of the engagement section being formed with a forked structure.

8. The wire connection terminal structure as claimed in claim 6, wherein the abutment leaf spring is a set of abutment leaf springs composed of multiple overlapped abutment leaf springs with identical bending configuration, at least an outer end section of the engagement section being formed with a forked structure.

9. The wire connection terminal structure as claimed in claim 1, wherein the electro-conductive module is composed of an electro-conductive plate and a lateral support disposed on a lateral side of the electro-conductive plate, the lateral support having a lateral socket connected with the wire plug-in port, parallel support sections being disposed on two sides of the lateral socket, the slide guide slots being respectively symmetrically formed on the support sections.

10. The wire connection terminal structure as claimed in claim 6, wherein the electro-conductive module is composed of an electro-conductive plate and a lateral support disposed on a lateral side of the electro-conductive plate, the lateral support having a lateral socket connected with the wire plug-in port, parallel support sections being disposed on two sides of the lateral socket, the slide guide slots being respectively symmetrically formed on the support sections.

11. The wire connection terminal structure as claimed in claim 9, wherein a perforation is formed on each support section of the lateral support, a shaft rod socket being disposed in the recessed section of the case main body, the first shaft rod being sequentially passed through the perforations of the support sections and the rotary button and then inserted into the shaft rod socket, whereby the electro-conductive module, the rotary button and the abutment leaf spring can be assembled in the case main body.

12. The wire connection terminal structure as claimed in claim 10, wherein a perforation is formed on each support section of the lateral support, a shaft rod socket being disposed in the recessed section of the case main body, the first shaft rod being sequentially passed through the perforations of the support sections and the rotary button and then inserted into the shaft rod socket, whereby the electro-conductive module, the rotary button and the abutment leaf spring can be assembled in the case main body.

13. The wire connection terminal structure as claimed in claim 9, wherein the electro-conductive plate and the lateral support of the electro-conductive module are an integrally formed structure body.

14. The wire connection terminal structure as claimed in claim 10, wherein the electro-conductive plate and the lateral support of the electro-conductive module are an integrally formed structure body.

15. The wire connection terminal structure as claimed in claim 9, wherein an opening is formed on the lateral support in communication with the lateral socket, a lateral side of the electro-conductive plate being fitted in the opening, whereby the lateral support is connected with the electro-conductive plate.

16. The wire connection terminal structure as claimed in claim 10, wherein an opening is formed on the lateral support in communication with the lateral socket, a lateral side of the electro-conductive plate being fitted in the opening, whereby the lateral support is connected with the electro-conductive plate.

17. The wire connection terminal structure as claimed in claim 1, wherein the rotary button has a shift section exposed to outer side of the case main body, an insertion socket being formed on the shift section for a tool to insert therein, a holding channel being formed on the movable section for holding the pin.

18. The wire connection terminal structure as claimed in claim 6, wherein the rotary button has a shift section exposed to outer side of the case main body, an insertion socket being formed on the shift section for a tool to insert therein, a holding channel being formed on the movable section for holding the pin.

19. The wire connection terminal structure as claimed in claim 17, wherein a support rod and an insertion sink are disposed in the recessed section, an elastic member being pivotally fitted on the support rod for elastically abutting against the rotary button to make the shift section protrude out of the case main body, a hook section being disposed on the shift section, the hook section being receivable in the recessed section with the shift section and engaged in the insertion sink.

20. The wire connection terminal structure as claimed in claim 18, wherein a support rod and an insertion sink are disposed in the recessed section, an elastic member being pivotally fitted on the support rod for elastically abutting against the rotary button to make the shift section protrude out of the case main body, a hook section being disposed on the shift section, the hook section being receivable in the recessed section with the shift section and engaged in the insertion sink.

21. The wire connection terminal structure as claimed in claim 1, wherein two sets of symmetrical recessed sections and wire plug-in ports are disposed on the surface of the case main body, the electro-conductive module being connected and disposed between the two wire plug-in ports, lateral sockets being respectively disposed on two lateral sides of the electro-conductive module and connected with the wire plug-in ports for receiving conductive wires plugged from outer side through the wire plug-in ports into the recessed sections, two rotary buttons being respectively symmetrically disposed in the two recessed sections, two abutment leaf springs being respectively symmetrically pivotally disposed between the rotary buttons and the electro-conductive module, the abutment leaf springs being drivable by the rotary buttons on the same side to pivotally rotate so as to press the conductive wires against the electro-conductive module, whereby the two conductive wires can be electrically connected with each other via the electro-conductive module.

22. The wire connection terminal structure as claimed in claim 2, wherein two sets of symmetrical recessed sections and wire plug-in ports are disposed on the surface of the case main body, the electro-conductive module being connected and disposed between the two wire plug-in ports, lateral sockets being respectively disposed on two lateral sides of the electro-conductive module and connected with the wire plug-in ports for receiving conductive wires plugged from outer side through the wire plug-in ports into the recessed sections, two rotary buttons being respectively symmetrically disposed in the two recessed sections, two abutment leaf springs being respectively symmetrically pivotally disposed between the rotary buttons and the electro-conductive module, the abutment leaf springs being drivable by the rotary buttons on the same side to pivotally rotate so as to press the conductive wires against the electro-conductive module, whereby the two conductive wires can be electrically connected with each other via the electro-conductive module.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0010] FIG. 1 is a perspective exploded view of a first embodiment of the present invention;

[0011] FIG. 2 is a perspective partially assembled view of the first embodiment of the present invention;

[0012] FIG. 3 is a sectional assembled view of the first embodiment of the present invention;

[0013] FIG. 4 is a sectional assembled view of the first embodiment of the present invention according to FIG. 3, showing that the conductive wire is plugged into the case main body and the rotary button is not yet rotated to drive the abutment leaf spring to engage with the conductive wire;

[0014] FIG. 5 is a sectional assembled view of the first embodiment of the present invention according to FIG. 3, showing that the rotary button is rotated to drive the abutment leaf spring to engage with the conductive wire;

[0015] FIG. 6 is a perspective exploded view of a second embodiment of the present invention; and

[0016] FIG. 7 is a perspective partially assembled view of the second embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0017] Please refer to FIGS. 1 to 3. According to a first embodiment, the wire connection terminal structure of the present invention includes a case main body 1, an electro-conductive module 2, a rotary button 3 and an abutment leaf spring 4. The case main body 1 is composed of two half case bodies 1a, 1b opposite to each other. A receiving section 111 and at least one recessed section 15 are formed in the case main body 1. The receiving section 111 has at least one wire plug-in port 11 open to outer side. In the recessed section 15 are disposed a first shaft rod 12, a second shaft rod 13, a support rod 14 and an insertion sink 151.

[0018] In practice, two wire plug-in ports 11 can be respectively disposed on two lateral sides of the receiving section 111 as necessary. In addition, two recessed sections 15 are disposed on a surface of the case main body 1 corresponding to each other. Two symmetrical first shaft rods 12, two symmetrical second shaft rods 13, two symmetrical support rods 14 and two symmetrical insertion sinks 151 are respectively disposed in the two recessed sections 15.

[0019] The electro-conductive module 2 is disposed in the receiving section 111. In a preferred embodiment, the electro-conductive module 2 is composed of an electro-conductive plate 21 and at least one lateral support 22 assembled on a lateral side of the electro-conductive plate 21. The lateral support 22 has a lateral socket 221 connected with the wire plug-in port 11. At least one (or two parallel) support sections 223 are disposed on two sides of the lateral socket 221. Two (symmetrical) slide guide slots 225 are (respectively) formed on the support sections 223. The slide guide slots 225 can have the form of a closed structure (or a partially open structure). In addition, a receiving space 224 is defined in the lateral support 22 in communication with the lateral socket 221.

[0020] In practice, the electro-conductive plate 21 and the lateral support 22 of the electro-conductive module 2 can be an integrally formed structure body. Alternatively, an opening 222 can be formed on the lateral support 22 in communication with the lateral socket 221. The lateral side of the electro-conductive plate 21 is fitted in the opening 222, whereby two lateral sides of the electro-conductive plate 21 can be extended into the lateral sockets 221 of the two lateral supports 22 and assembled therewith in accordance with the requirements of different structural designs or manufacturing cost.

[0021] The rotary button 3 has a shaft hole 31. The first shaft rod 12 in the recessed section 15 can be pivotally fitted in the shaft hole 31, whereby the rotary button 3 is pivotally rotatably assembled with the first shaft rod 12. The rotary button 3 further has a shift section 32 exposed to outer side of the case main body 1 and a movable section 33 extending to one side of the electro-conductive module 2. An outward protruding hook section 321 and an inward recessed insertion socket 322 are disposed on the shift section 32. A holding channel 331 is formed on the movable section 33 for holding a pin 34. The pin 34 can extend into the slide guide slots 225 on the same side to be freely movably guided within the slide guide slots 225. In addition, an elastic member 141 is disposed on the support rod 14 for elastically abutting against the rotary button 3 to make the shift section 32 protrude out of the case main body 1.

[0022] In practice, two rotary buttons 3 are respectively disposed in the two recessed sections 15 of the case main body 1. The two rotary buttons 3 are symmetrically disposed in the recessed sections 15.

[0023] The abutment leaf spring 4 (or a set of abutment leaf springs) is disposed in the receiving space 224 of the lateral supports 22. A middle section of each abutment leaf spring 4 is formed with an arcuate bending section 41. A drive section 42 proximal to the rotary button 3 and an engagement section 43 proximal to the electro-conductive module 2 are respectively formed at two ends of the bending section 41. When assembled, an inner side of the bending section 41 is pivotally fitted on the second shaft rod 13, whereby the second shaft rod 13 serves as a pivotally rotational shaft of the abutment leaf spring 4.

[0024] In practice, the abutment leaf spring 4 can be a set of abutment leaf springs composed of multiple overlapped abutment leaf springs with identical bending configuration. In addition, at least an outer end section of the engagement section 43 is formed with a forked structure.

[0025] Please refer to FIGS. 4 and 5. In use of the wire connection terminal structure of the present invention, two conductive wires A are plugged from the outer side through the wire plug-in ports 11 into the lateral sockets 221 of the electro-conductive module 2. At this time, the shift section 32 of the rotary button 3 keeps protruding out of the case main body 1 and the movable section 33 (the pin 34) is in contact with a portion of the drive section 42 near the bending section 41 (as shown in FIG. 4).

[0026] Then, an operator can use a tool (such as a screwdriver) and extend the tool into the insertion socket 322 of the shift section 32 to drive and rotate the rotary button 3 (or directly drive and rotate the rotary button 3). Accordingly, the movable section 33 is gradually moved in a direction away from the bending section 41 (toward an outer end section of the drive section 42) to push the drive section 42 and pivotally rotate the abutment leaf spring 4. At the same time, the outer end section of the engagement section 43 at the other end is engaged with a surface of the conductive wire A (in a direction the same as the direction in which the conductive wire A is extended into the lateral socket 221 as shown in FIG. 5). Accordingly, the conductive wires A can tightly attach to the electro-conductive plate 21 of the electro-conductive module 2 (and electrically connect with each other via the electro-conductive plate 21 of the electro-conductive module 2). Also, the hook section 321 of the shift section 32 is engaged into the insertion sink 151 of the recessed section 15 and located therein. In the above structure, the slide guide slot 225 for guiding the pin 34 is formed on the metal-made lateral support 22 (the support section 223).

[0027] Therefore, the slide guide slot 225 has better structural strength and is able to more precisely and securely guide the pin 34. Moreover, the structure arrangement in the internal space of the case main body is simplified. Furthermore, during the process that the rotary button 3 drives the abutment leaf spring 4 to engage with the conductive wire A, the position where the movable section 33 abuts against the drive section 42 is gradually changed from a position near the bending section 41 to a position near the outer end section of the drive section 42 (away from the bending section 41). Therefore, the arm of the operation force applied by the movable section 33 of the rotary button 3 to the drive section 42 is gradually increased. Accordingly, the moving direction of the rotary button 3 or the movable section 33 is reverse to the moving direction of the set of the abutment leaf springs 4 or the drive section 42 and the engagement section 43. Therefore, the operation force required for driving the abutment leaf spring 4 to pivotally rotate is gradually reduced. As a result, the operation can be performed with less strength and the rotary button 3 can be more smoothly moved.

[0028] In practice, during the process that the rotary button 3 drives the abutment leaf spring 4 to engage with the conductive wire A, the drive section 42 is also pivotally rotated with the second shaft rod 13 serving as the rotational center. Therefore, the drive section 42 can be properly designed with such a configuration that after the outer end section of the engagement section 43 is engaged with the surface of the conductive wire A, the outer end section of the drive section 42 is also engaged with the surface of the conductive wire A in cooperation with the elastic deformation of the abutment leaf spring 4 itself. In this case, the drive section 42 and the engagement section 43 can respectively engage with different portions of the surface of the conductive wire A to achieve a multi-engagement system. Accordingly, a better engagement effect for the conductive wire A can be achieved.

[0029] Please now refer to FIGS. 6 and 7. According to a second embodiment, the wire connection terminal structure of the present invention includes a case main body 10, an electro-conductive module 20 and a rotary button 3 and an abutment leaf spring 4 (not shown) identical to the rotary button 3 and the abutment leaf spring 4 of the first embodiment. The case main body 10 is composed of two half case bodies 10a, 10b opposite to each other. A receiving section 111, a recessed section 15 and a wire plug-in port 11 are formed in the case main body 1 as the first embodiment. A second shaft rod 13, a support rod 14 and an insertion sink 151 are disposed in the recessed section 15. The second embodiment is different from the first embodiment in that a shaft rod socket 1021 is further disposed in the recessed section 15 for a first shaft rod 102 to insert therein.

[0030] The electro-conductive module 20 is disposed in the receiving section 111 of the case main body 10. The electro-conductive module 20 is composed of an electro-conductive plate 21 identical to the electro-conductive plate 21 of the first embodiment and at least one lateral support 202 assembled on a lateral side of the electro-conductive plate 21. The lateral support 202 has a lateral socket 221 connected with the wire plug-in port 11. At least one (or two parallel) support sections 2023 are disposed on two sides of the lateral socket 221. Two (symmetrical) slide guide slots 2025 are (respectively) formed on the support sections 2023. In addition, a perforation 2026 is formed on each support section 2023 for the first shaft rod 102 to pivotally fit therein. The slide guide slots 2025 can have the form of a closed structure (or a partially open structure). In addition, a receiving space 224 is defined in the lateral support 202 in communication with the lateral socket 221.

[0031] When assembled, the rotary button 3 and the abutment leaf spring 4 are assembled on the electro-conductive module 20 in the same positions and by the same way as the first embodiment. Then, the first shaft rod 102 is sequentially passed through the perforations 2026 of the support sections 2023 and the shaft hole 31 of the rotary button 3 and then inserted into the shaft rod socket 1021 in the recessed section 15. Accordingly, the electro-conductive module 20, the rotary button 3 and the abutment leaf spring 4 can be assembled in the case main body 10 (by the same way as the first embodiment) with the shift section 32 of the rotary button 3 exposed to the outer side of the recessed section 15. The second embodiment provides another assembling structure in another form. The first shaft rod 102 is inserted and assembled in the shaft rod socket 1021 and passed through the perforations 2026 of the support sections 2023 to help the lateral support 202 (the support sections 2023) in forming a securer assembling structure. As a whole, the operation manner of the second embodiment and the effect achieved by the second embodiment are both the same as the first embodiment and thus will not be redundantly described hereinafter.

[0032] In conclusion, the wire connection terminal structure of the present invention can truly achieve the effects that the operation is performed with less strength, the structural strength is enhanced and the guide system is more precise and securer. The wire connection terminal structure of the present invention is novel, advanced and inventive.

[0033] 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.