QUICK CONNECT PLUG FOR CABLES

Abstract

A quick connect plug for cables includes a connecting portion configured to connect a cable and a plug pin configured to form a plug-in connection with a socket. The plug pin is fixedly provided with a plug-in unit. A portion of the plug-in unit protruding out of an external annular surface of the plug pin forms a locking head matched with a socket slot. A gap is provided between a portion of the plug-in unit near the locking head and the plug pin, so as to enable the locking head to move along an axis direction of the plug pin, and the gap can limit the maximum displacement of the locking head. By providing a plug-in unit and a gap between the portion of the plug-in unit near the locking head and the plug pin, the plug-in unit is enabled to move, thus having certain elasticity.

Description

TECHNICAL FIELD

The present invention relates to the technical field of cable connect, in particular to a quick connect plug for cables.

BACKGROUND

In the prior art, welding cables are fitted and connected to other welding cables or welding equipment through plug and socket. The inner wall of the insertion hole of the socket is provided with a guide slot along the axis direction of the insertion hole. The end of the guide slot is connected to a spiral slot. The spiral slot is arranged at the inner annular surface of the insertion hole, and the axis of the spiral slot coincides with the axis of the insertion hole. The front end of the plug is provided with a protruded locking head. During connection, the plug is inserted along the guide slot of the socket, and then the plug is rotated so as to make the locking head of the plug rotate along the spiral slot. The end face of the plug closely fit the end face of the socket after tightening. In this structure, as both, the plug and the socket are of integral steel structure, the operating distance between tightening and loosening is only 1-2.5 mm during use. During production and operation, the locking head of the plug easily gets loose from the slot due to factors such as handling, vibration, collision, expansion and contraction, and pulling of cables etc. The loosening of the locking head causes insufficient connection and unstable current on the contacting surface. When large current flows through, the plug and socket will heat up, and may burn the connector, thereby causing fire hazards.

SUMMARY

The objective of the present invention is to provide a quick connect plug for cables which can realize convenient and reliable plug-in connect.

In order to achieve the above-mentioned objective, the present invention adopts the following technical solution. A quick connect plug for cables includes a connecting portion configured to connect a cable and a plug pin configured to form a plug-in connection with a socket. The plug pin is fixedly provided with a plug-in unit. A portion of the plug-in unit protruding out of an external annular surface of the plug pin forms a locking head matched with the socket slot. A gap is provided between a portion of the plug-in unit near the locking head and the plug pin, so as to enable the locking head to move along an axis direction of the plug pin, and the gap can limit the maximum displacement of the locking head.

Compared with the prior art, the present invention has following technical effects. By providing a plug-in unit and providing a gap between the portion of the plug-in unit near the locking head and the plug pin, the plug-in unit is enabled to move, thus having certain elasticity. During assembly, due to the existence of elastic force, even though external force is applied on the plug, the plug-in unit will not be damaged, so the phenomenon where the locking head of the plug gets loose from the slot will not occur, thereby ensuring an extremely reliable connection between the welding cables or between the welding cable and welding equipment.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1a-1c are structural schematic diagrams of Embodiment 1 of the present invention;

FIGS. 2a and 2b are structural schematic diagrams of Embodiment 2 of the present invention;

FIG. 3a-3c are structural schematic diagrams of Embodiment 3 of the present invention;

FIGS. 4a-4e are structural schematic diagrams of Embodiment 4 of the present invention;

FIGS. 5a-5e are structural schematic diagrams of Embodiment 5 of the present invention;

FIG. 6 is a structural schematic diagram of Embodiment 6 of the present invention.

DETAILED DESCRIPTION OF EMBODIMENTS

The present invention will be described in detail with reference to FIGS. 1a-1c to FIG. 6, hereinafter.

With reference to FIGS. 1a-1c to FIG. 6, a quick connect plug for cables includes connecting portion 10 configured to connect the cable and plug pin 20 configured to form a plug-in connection with a socket. The plug pin 20 is fixedly provided with plug-in unit 21, and the portion of the plug-in unit 21 protruding out of the external annular surface of the plug pin 20 forms a locking head 211 which is matched with the socket slot. The plug-in unit 21 is fixedly connected to the plug pin 20. Gap 212 is provided between the portion of the plug-in unit 21 near the locking head 211 and the plug pin 20, so as to enable the locking head 211 to move along the axis direction of the plug pin 20. The gap 212 can limit the maximum displacement of the locking head 211. By providing the plug-in unit 21 and the gap 212 between the portion of the plug-in unit 21 near the locking head 211 and the plug pin 20, the plug-in unit 21 is enabled to move and has a certain elasticity. During assembly, due to the existence of elastic force, even though external force is applied on the plug, the plug-in unit 21 will not be damaged, so the phenomenon where the locking head 211 of the plug gets loose from the slot will not occur, thereby ensuring an extremely reliable connect between the welding cables or between the welding cable and welding equipment.

As a preferred embodiment of the present invention, one end of the plug-in unit 21 protruding out of the external annular surface of the plug pin 20 forms the locking head 211, and the other end of the plug-in unit 21 is fixedly connected to the plug pin 20. In this structure, there is only one locking head 211. Due to existence of the gap 212 at the side of the locking head 211, one locking head 211 is sufficient to ensure reliable connection between the plug and the socket. Alternatively, the following solution may also be used. Both ends of the plug-in unit 21 protrude out of the external annular surface of the plug pin 20 to form locking heads 211, and the two locking heads 211 are symmetrical with respect to the center of the plug pin 20. The middle portion of the plug-in unit 21 is fixedly connected to the plug pin 20. Here, two locking heads 211 are provided. Although the arrangement of two locking heads 211 is a bit more complex, the reliability increases. According to Embodiments 1, 2, 3, 4 and 5, one locking head 211 is used, and according to Embodiment 6, two locking heads 211 are used, the section view thereof is shown in FIG. 6. Since Embodiment 6 is similar to Embodiment 3 except for two locking heads 211 are used, merely one figure is provided herein and the details are not described. Embodiment 3 may be referred for the specific structure. Similarly, the structure of two locking heads 211 may be used in other embodiments.

Many structures may be used to form the gap 212 between the plug-in unit 21 and the plug pin 20, and multiple embodiments are described in detail in the present invention.

With reference to FIGS. 1 and 2, preferably, the plug pin 20 is provided with stepped hole 22. The stepped hole 22 includes a small hole section and a large hole section. The plug-in unit 21 is a straight rod. One end of the straight rod is inserted into the small hole section and they are in an interference fit. Alternatively, the straight rod and the small hole section are in a screw thread fit. Any matching mode is acceptable as long as one end of the straight rod and the small hole section can be fixedly connected to each other. The other end of the straight rod passes through the large hole section and extends out of the external annular surface of the plug pin 20 to form the locking head 211. Moreover, the diameter of the straight rod is less than the diameter of the large hole section. The axes of the small hole section and the large hole section are perpendicular to the axis of the plug pin 20. By providing the stepped hole 22 and configuring the plug-in unit 21 as a straight rod, the gap 212 is formed between the straight rod and the large hole section. In practical application, the gap 212 must exist at the side of the plug-in unit 21 away from the connecting piece 10, and the gap may be or may not be provided on the other side. Therefore, the small hole section and the large hole section may be concentrically arranged, or the side of the small hole section near the connecting portion 10 may be aligned with the side of the large hole section near the connecting portion 10. For the latter solution, actually, it can be understood as the large hole section and the small hole section being eccentrically arranged. When the small hole section and the large hole section are concentrically arranged, there is gap 212 surrounding the plug-in unit 21. When the side of the small hole section near the connecting portion 10 is aligned with the side of the large hole section near the connecting portion 10, and the side of the plug-in unit 21 away from the connecting piece 10 has the gap 212. Usage demands are satisfied in both scenarios.

The section profiles of the plug-in unit 21 and the stepped hole 22 may come in many shapes, for example, round, waist shape, square or elliptic. The section profile is round in Embodiment 1, and the section profile is waist-shaped in Embodiment 2. Certainly, other shapes are also acceptable, and they are not described in detail hereinafter.

With reference to FIG. 3, in Embodiment 3, the plug pin 20 is provided with through hole 23, and the plug-in unit 21 is a straight rod. The straight rod includes the large-diameter rod section and the small-diameter rod section. The large-diameter rod section is inserted into the through hole 23 and the large-diameter rod section and the through hole 23 are in an interference fit. Alternatively, the large-diameter rod section and the through hole 23 are in a screw thread fit. The small-diameter rod section passes through the through hole 23 and extends out of the external annular surface of the plug pin 20 to form locking head 211. Moreover, the diameter of the small-diameter rod section is less than the diameter of the through hole 23. The axis of the through hole 23 is perpendicular to the axis of the plug pin 20. The small-diameter rod section and the large-diameter rod section are concentrically arranged, or the side of the small-diameter rod section near the connecting portion 10 is aligned with the side of the large-diameter rod section near the connecting portion 10. The section profiles of the straight rod and the through hole 23 may be round, waist-shaped, square, or elliptic. This structure is similar to the previous structure, the difference is that the hole is the stepped hole 22 and the plug-in unit is a straight rod in the previous two embodiments. Here, the hole is through hole 23, and the plug-in unit 21 is a stepped rod.

With reference to FIGS. 4 and 5, the end face of the side of the plug pin 20 away from the connecting piece is provided with the recess 24. The plug-in unit 21 is plate-like and located in the recess 24. In addition, one end of the plug-in unit 21 extends out of the external annular surface of the plug pin 20 to form the locking head 211. The side of the plug-in unit 21 away from the connecting piece is provided with a pressing plate 25. The side of the plug-in unit 21 away from the locking head 211 fits the pressing plate 25 and is fixed on the plug pin 20 with a screw. Gap 211 is formed between the portion of the plug-in unit 21 near the locking head 211 and the pressing plate 25. The fixation of the plug-in unit 21 and the formation of gap 212 are achieved by providing the recess 24 and pressing plate 25. The plug-in unit 21 has a uniform thickness, and the side of the pressing plate 25 near the locking head 211 is wedge-shaped, or the plate thickness of the side of the pressing plate 25 near the locking head 211 is less than the plate thickness of the side of the pressing plate 25 away from the locking head 211 to form the gap 212. The pressing plate 25 has a uniform thickness, and the side of the plug-in unit 21 near the locking head 211 is wedge-shaped, or the plate thickness of the side of the plug-in unit 21 near the locking head 211 is less than the plate thickness of the side of the plug-in unit 21 away from the locking head 211 to form the gap 212.

As shown in FIG. 4 of Embodiment 4, the side of the pressing plate 25 near the locking head 211 is wedge-shaped. As shown in FIG. 5 of Embodiment 5, the plate thickness of the side of the pressing plate 25 near the locking head 211 is less than the plate thickness of the side of the pressing plate 25 away from the locking head 211. In these two embodiments, the thickness of the plug-in unit 21 is uniform. Certainly, the user may also select the pressing plate 25 with a uniform thickness, and the plug-in unit 21 with changing thickness to form the gap 212.

Claims

1. A quick connect plug for cables, comprising: a connecting portion configured to connect a cable and a plug pin configured to form a plug-in connection with a socket; whereinthe plug pin is fixedly provided with a plug-in unit;a portion of the plug-in unit protruding out of an external annular surface of the plug forms a locking head matched with a socket slot;a gap is provided between a portion of the plug-in unit near the locking head and the plug pin, so as to enable the locking head to move along an axis direction of the plug pin, and the gap can limit a maximum displacement of the locking head.

2. The quick connect plug for cables according to claim 1, wherein a first end of the plug-in unit protrudes out of the external annular surface of the plug pin to form the locking head, and a second end of the plug-in unit is fixedly connected to the plug pin.

3. The quick connect plug for cables according to claim 1, wherein both ends of the plug-in unit protrude out of the external annular surface of the plug pin—to form two locking heads, and the two locking heads are symmetrical with respect to a center of the plug pin; anda middle portion of the plug-in unit is fixedly connected to the plug pin.

4. The quick connect plug for cables according to claim 2, wherein the plug pin is provided with a stepped hole;the stepped hole comprises a small hole section and a large hole section;the plug-in unit is a straight rod;a first end of the straight rod is inserted into the small hole section to form an interference fit with the small hole section, or the straight rod and the small hole section are in a screw thread fit;a second end of the straight rod passes through the large hole section and extends out of the external annular surface of the plug pin to form the locking head; anda diameter of the straight rod is less than a diameter of the large hole section.

5. The quick connect plug for cables according to claim 4, wherein axes of the small hole section and the large hole section of the stepped hole are perpendicular to an axis of the plug pin;the small hole section and the large hole section are concentrically arranged; ora side of the small hole section near the connecting portion is aligned with a side of the large hole section near the connecting portion.

6. The quick connect plug for cables according to claim 4, wherein section profiles of the plug-in unit and the stepped hole are round, waist-shaped, square, or elliptic.

7. The quick connect plug for cables according to claim 2, wherein the plug pin is provided with a through hole, and the plug-in unit is a straight rod;the straight rod comprises a large-diameter rod section and a small-diameter rod section;the large-diameter rod section is inserted into the through hole to form an interference fit with the through hole; orthe large-diameter rod section and the through hole are in a screw thread fit;the small-diameter rod section passes through the through hole and extends out of the external annular surface of the plug pin to form the locking head; anda diameter of the small-diameter rod section is less than a diameter of the through hole.

8. The quick connect plug for cables according to claim 2, wherein an end face of a side of the plug pin away from the connecting piece is provided with a recess;the plug-in unit is plate-like and located in the recess;the first end of the plug-in unit extends out of the external annular surface of the plug pin to form the locking head;a side of the plug-in unit away from the connecting piece is provided with a pressing plate;a side of the plug-in unit away from the locking head fits the pressing plate and is fixed on the plug pin with a screw; anda gap is formed between the portion of the plug-in unit near the locking head—and the pressing plate.

9. The quick connect plug for cables according to claim 8, wherein the plug-in unit has a uniform thickness;a side of the pressing plate near the locking head is wedge-shaped; ora plate thickness of the side of the pressing plate near the locking head is less than a plate thickness of a side of the pressing plate away from the locking head to form the gap.

10. The quick connect plug for cables according to claim 8, wherein the pressing plate has a uniform thickness, and the side of the plug-in unit near the locking head is wedge-shaped; ora plate thickness of the side of the plug-in unit near the locking head is less than a plate thickness of the side of the plug-in unit away from the locking head to form the gap.

11. The quick connect plug for cables according to claim 5, wherein section profiles of the plug-in unit and the stepped hole are round, waist-shaped, square, or elliptic.