CN118763453A - Connector structure for electronic equipment - Google Patents

Abstract

The present invention belongs to the technical field of connectors, and in particular discloses a connector structure for electronic equipment, including a first connector and a second connector, the first connector and the second connector are arranged opposite to each other, a plug is arranged on the inner side of the second connector, a wire is arranged at the center of the outer side of the first connector, a plug shell is arranged on the inner side of the first connector and is sleeved on the outer side of the plug, bumps are arranged on both sides of the plug, sleeves are arranged on both sides of the plug shell, two sleeves correspond to two bumps one by one, and the sleeves are sleeved on the surface of the bumps, and rotating rods are inserted on both sides of the first connector. The present invention realizes the detachable connection effect of the first connector and the second connector under the limitation of the connecting component, and at this time, the first connector and the second connector are quickly separated by directly pulling, which speeds up the disassembly and installation effect of the first connector and the second connector.

Description

Connector structure for electronic equipment

Technical Field

The invention belongs to the technical field of connectors, and in particular relates to a connector structure for electronic equipment.

Background Art

When a computer needs to transmit signals, a high-speed transmission signal connector is required. However, existing computer high-speed transmission signal connectors still have some problems when used.

When an existing computer high-speed transmission signal connector is connected to a host, screws are usually used to connect the connector to the computer host, which is very troublesome when connecting and removing the connector.

Summary of the invention

In view of the above problems, the present invention provides a connector structure for electronic equipment to solve the problems raised in the above background technology.

To achieve the above object, the present invention provides the following technical solutions:

A connector structure for an electronic device comprises a first connector and a second connector, wherein the first connector is arranged opposite to the second connector, a plug is arranged on the inner side of the second connector, a wire is arranged at the center of the outer side surface of the first connector, a plug shell is arranged on the inner side of the first connector and is sleeved on the outer side of the plug, protrusions are arranged on both sides of the plug, sleeve frames are arranged on both sides of the sleeve shell, the two sleeve frames correspond to the two protrusions one by one, and the sleeve frames are sleeved on the surfaces of the protrusions correspondingly, rotating rods are inserted on both sides of the first connector, the inner end of the rotating rod is correspondingly inserted into the inner side of the circular groove of the second connector through the protrusion, the outer end of the rotating rod is connected to a circular plate, the inner end of the rotating rod is provided with a connecting component, and the connecting component is correspondingly snapped into the inside of the circular groove.

Furthermore, a through groove corresponding to the inner end of the rotating rod is provided at the center of the protrusion, and side grooves are provided on both sides of the through groove. Two opposite side blocks are fixed to the inner end of the rotating rod, and the two side blocks correspond to the two side grooves one by one. When the rotating rod is inserted into the inner side of the through groove, the rotating rod moves inside the side groove using the side blocks. The diameter of the circular groove is larger than the diameter of the through groove, and the center line of the circular groove coincides with the center line of the through groove.

Furthermore, the connecting component includes two opposite side plates, both of which are located inside the inner end of the rotating rod, and a limiting rod penetrating the two side plates is arranged inside the inner end of the rotating rod, a spring is sleeved on the surface of the limiting rod, and both ends of the spring are respectively connected to the inner side surfaces of the two side plates, a first convex plate is fixed to the inner end of the side plate, and a second convex plate is fixed to the outer end of the side plate, the first convex plate corresponds to and passes through the center of the side block, and the second convex plate passes through the rotating rod, and the outer side surface of the first convex plate is provided with an inclined surface, and the inclined surface of the first convex plate corresponds to the side groove.

Furthermore, the outer end of the second convex plate is provided with a chamfer, and the inner end of the side groove is provided with an arc surface, and the chamfer of the second convex plate corresponds to the arc surface of the side groove.

Furthermore, a sticking plate is provided at the center of the rotating rod. When the sleeve frame is sleeved on the surface of the protrusion, the inner side surface of the sticking plate fits with the inner side surface of the protrusion. Arc grooves are provided at the top and bottom of the sticking plate. An arc plate is fixed inside the arc groove. A slider is slidably sleeved on the surface of the arc plate. An insertion rod is fixed at the inner end of the slider. The inner end of the insertion rod extends out of the inner side of the arc groove. Plug holes are provided at the top and bottom of the inner side surface of the protrusion, and the plug rod is correspondingly inserted into the plug holes.

Furthermore, the overall shape of the arc plate is set to be an arc-shaped long strip structure. When the rotating rod rotates, the rotating rod drives the arc plate to rotate synchronously by using the contact plate.

Furthermore, a pressure rod is inserted into the slider, and the outer end of the pressure rod extends out of the slider. A spring sheet is fixed on the slider, and the outer end of the pressure rod is correspondingly connected to the center of the spring sheet. The elastic force of the spring sheet makes the inner end of the pressure rod fit with the outer convex surface of the arc plate, and grooves are provided on both sides of the outer convex surface of the arc plate.

Furthermore, two opposite arcuate bars are arranged inside the arcuate groove, the inner end of the arcuate bar is connected to the insertion rod, and the outer end of the arcuate bar is connected to the inner wall of the arcuate groove, and the elastic force of the two arcuate bars makes the insertion rod be located at the center of the arcuate groove.

Technical effects and advantages of the present invention:

1. The present invention realizes a detachable connection effect between the first connector and the second connector under the limitation of the connecting component. At this time, the first connector and the second connector are quickly separated by directly pulling, which speeds up the disassembly and installation of the first connector and the second connector.

2. The present invention uses the elastic force of the spring sheet to insert the inner end of the pressure rod into the groove, and uses the elastic force of the spring sheet to limit the rotation rod. At this time, the inner end of the rotation rod uses the second convex plate to limit the connecting component to avoid the first connector and the second connector being separated due to a simple collision.

3. The present invention improves the connection stability between the first connector and the second connector by cooperating with the second convex plate and the circular plate, avoiding the first connector and the second connector from being separated due to simple dragging, thereby preventing the plug from falling out of the plug housing.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of the connection between a first connector and a second connector according to an embodiment of the present invention;

FIG2 is an overall schematic diagram of a second connector according to an embodiment of the present invention;

FIG3 is an overall schematic diagram of a first connector according to an embodiment of the present invention;

FIG4 is an enlarged structural view of section A in FIG2 according to an embodiment of the present invention;

5 is a schematic diagram of a rotating rod according to an embodiment of the present invention plugged into a second connector through a first connector;

FIG6 is an enlarged view of the structure of section B in FIG5 according to an embodiment of the present invention;

FIG7 is an enlarged view of the structure of section C in FIG3 according to an embodiment of the present invention;

FIG8 is a schematic diagram of a rotating rod portion inside a sleeve frame according to an embodiment of the present invention;

FIG9 is an enlarged view of the structure of section D in FIG8 according to an embodiment of the present invention;

In the figure: 1, first connector; 2, second connector; 3, plug; 4, plug shell; 5, protrusion; 6, sleeve frame; 7, rotating rod; 8, circular groove; 9, circular plate; 10, through groove; 11, side groove; 12, side block; 13, side plate; 14, limiting rod; 15, spring; 16, first protrusion plate; 17, second protrusion plate; 18, arc surface; 19, sticking plate; 20, arc plate; 21, slider; 22, plug rod; 23, socket; 24, pressure rod; 25, spring piece; 26, groove; 27, arc strip.

DETAILED DESCRIPTION

In order to make the purpose, technical solution and advantages of the embodiments of the present invention more clear, the technical solution of the present invention will be clearly and completely described below in conjunction with the embodiments.

The present invention provides a connector structure for electronic equipment, as shown in Figures 1 to 6, a connector structure for electronic equipment, including a first connector 1 and a second connector 2, the first connector 1 and the second connector 2 are arranged opposite to each other, a plug 3 is arranged on the inner side of the second connector 2, a wire is arranged at the center of the outer side of the first connector 1, a plug-in shell 4 is arranged on the inner side of the first connector 1 and is sleeved on the outer side of the plug 3, protrusions 5 are arranged on both sides of the plug 3, sleeve frames 6 are arranged on both sides of the plug-in shell 4, the two sleeve frames 6 correspond to the two protrusions 5 one by one, and the sleeve frames 6 are correspondingly sleeved on the surface of the protrusions 5, rotating rods 7 are inserted on both sides of the first connector 1, the inner end of the rotating rod 7 is correspondingly inserted into the inner side of the circular groove 8 of the second connector 2 through the protrusion 5, the outer end of the rotating rod 7 is connected to a circular plate 9, the inner end of the rotating rod 7 is provided with a connecting component, and the connecting component is correspondingly buckled in the circular groove 8. The first connector 1 uses the plug 3 to correspond to the plug-in shell 4 of the second connector 2 until the plug-in shell 4 is correspondingly sleeved on the surface of the plug 3. At this time, the two sleeve frames 6 are respectively sleeved on the surfaces of the two protrusions 5. At this time, the rotating rod 7 is pushed to move, and the connecting component at the inner end of the rotating rod 7 is correspondingly clamped in the circular groove 8 of the second connector 2 through the protrusion 5. The connecting component is used to improve the connection stability between the first connector 1 and the second connector 2, avoid separation of the first connector 1 and the second connector 2 due to simple dragging, and prevent the plug 3 from falling out of the plug-in shell 4.

In Figures 2 to 7, a through groove 10 corresponding to the inner end of the rotating rod 7 is provided at the center of the protrusion 5, and side grooves 11 are provided on both sides of the through groove 10. Two opposite side blocks 12 are fixed to the inner end of the rotating rod 7. The two side blocks 12 correspond to the two side grooves 11 one by one. When the rotating rod 7 is inserted into the inner side of the through groove 10, the rotating rod 7 moves inside the side groove 11 using the side blocks 12. The diameter of the circular groove 8 is larger than the diameter of the through groove 10, and the center line of the circular groove 8 coincides with the center line of the through groove 10. When the rotating rod 7 is pushed to move, the inner end of the rotating rod 7 gradually approaches the protrusion 5 until the side block 12 at the inner end of the rotating rod 7 enters the side groove 11. When the inner end of the rotating rod 7 moves inside the through groove 10, the rotating rod 7 drives the side block 12 to move synchronously inside the side groove 11 until the side block 12 at the inner end of the rotating rod 7 completely enters the circular groove 8 of the second connecting head 2. At this time, the rotating rod 7 is rotated, and the connecting part at the inner end of the rotating rod 7 rotates inside the circular groove 8. At this time, the connecting part at the inner end of the rotating rod 7 is correspondingly clamped in the circular groove 8.

In Figures 2 to 7, the connecting component includes two opposite side plates 13, both of which are located inside the inner end of the rotating rod 7, and a limiting rod 14 that penetrates the two side plates 13 is arranged inside the inner end of the rotating rod 7, and a spring 15 is sleeved on the surface of the limiting rod 14, and both ends of the spring 15 are respectively connected to the inner side surfaces of the two side plates 13, a first convex plate 16 is fixed to the inner end of the side plate 13, and a second convex plate 17 is fixed to the outer end of the side plate 13, the first convex plate 16 corresponds to and penetrates the center of the side block 12, and the second convex plate 17 penetrates the rotating rod 7, and the outer side surface of the first convex plate 16 is provided with an inclined surface, and the inclined surface of the first convex plate 16 corresponds to the side groove 11. When the side block 12 at the inner end of the rotating rod 7 enters the side groove 11, the inclined surface of the first convex plate 16 slides on the inner side edge of the side groove 11. Due to the squeezing of the first convex plate 16 by the inner side edge of the side groove 11, the first convex plate 16 gradually enters the rotating rod 7. At this time, the two first convex plates 16 approach each other, and the moving first convex plate 16 drives the side plate 13 to slide on the surface of the limiting rod 14. The two side plates 13 approaching each other cooperate to squeeze the spring 15 on the surface of the limiting rod 14. The elastic force of the spring 15 makes the outer side surface of the first convex plate 16 fit with the inner wall of the side groove 11 until the first convex plate 16 enters completely. After reaching the circular groove 8, the elastic force of the spring 15 pushes the two side plates 13 away from each other, and the moving side plate 13 drives the outer side surface of the second convex plate 17 to contact the inner wall of the side groove 11 until the second convex plate 17 enters the circular groove 8. At this time, the rotating rod 7 is rotated, and the rotating rod 7 drives the first convex plate 16 and the second convex plate 17 to rotate synchronously. At this time, the second convex plate 17 cooperates with the outer edge of the side groove 11 to clamp the rotating rod 7, and the circular plate 9 at the outer end of the rotating rod 7 is attached to the outer side surface of the first connecting head 1. Through the cooperation of the second convex plate 17 and the circular plate 9, the connection stability between the first connecting head 1 and the second connecting head 2 is further improved.

The outer end of the second convex plate 17 is provided with a chamfer, and the inner end of the side groove 11 is provided with an arc surface 18, and the chamfer of the second convex plate 17 corresponds to the arc surface 18 of the side groove 11. The rotating rod 7 is rotated so that the chamfered portion of the second convex plate 17 corresponds to the arc surface 18 of the side groove 11, and the rotating rod 7 is pulled, and the rotating rod 7 drives the second convex plate 17 to approach the side groove 11 until the chamfer of the second convex plate 17 fits on the surface of the arc surface 18. The rotating rod 7 continues to move, and the pressure of the arc surface 18 on the second convex plate 17 causes the second convex plate 17 to gradually enter the inside of the rotating rod 7, and under the elastic force of the spring 15, the outer side surface of the second convex plate 17 fits on the inner wall of the side groove 11. Continue to pull the rotating rod 7, the rotating rod 7 drives the first protruding plate 16 to contact the arc surface 18, and the arc surface 18 cooperates to squeeze the first protruding plate 16 until the first protruding plate 16 completely enters the inside of the side block 12. At this time, the connecting component can be easily pulled out from the inside of the second connecting head 2 through the rotating rod 7 to ensure the detachable connection effect of the first connecting head 1 and the second connecting head 2. At this time, the first connecting head 1 and the second connecting head 2 are quickly separated by direct pulling, which speeds up the disassembly and installation effect of the first connecting head 1 and the second connecting head 2.

In Fig. 8 and Fig. 9, a plate 19 is provided at the center of the rotating rod 7. When the sleeve frame 6 is sleeved on the surface of the protrusion 5, the inner side of the plate 19 is in contact with the inner side of the protrusion 5. The top and bottom of the plate 19 are provided with arc grooves. An arc plate 20 is fixed inside the arc groove. A slider 21 is slidably sleeved on the surface of the arc plate 20. An insertion rod 22 is fixed on the inner end of the slider 21. The inner end of the insertion rod 22 extends out of the inner part of the arc groove. A plug hole 23 is provided on the top and bottom of the inner side of the protrusion 5, and the plug rod 22 is correspondingly inserted into the plug hole 23. The overall shape of the arc plate 20 is set to an arc-shaped long strip structure. When the rotating rod 7 rotates, the rotating rod 7 drives the arc plate 20 to rotate synchronously by using the plate 19. When the connecting part at the inner end of the rotating rod 7 moves inside the through groove 10, the rotating rod 7 drives the sticking plate 19 to gradually approach the protrusion 5 until the insertion rod 22 on the inner side of the slider 21 is gradually inserted into the insertion hole 23 on the inner side of the protrusion 5. At this time, the connecting part at the inner end of the rotating rod 7 is inside the circular groove 8. The rotating rod 7 is rotated, and the rotating rod 7 drives the arc plate 20 to rotate by using the sticking plate 19. Since the protrusion 5 limits the insertion rod 22 by using the insertion hole 23, the rotating arc plate 20 slides at the center of the slider 21.

In Fig. 8 and Fig. 9, a pressure rod 24 is inserted into the slider 21, and the outer end of the pressure rod 24 extends out of the slider 21. A spring sheet 25 is fixed to the slider 21, and the outer end of the pressure rod 24 is correspondingly connected to the center of the spring sheet 25. The elastic force of the spring sheet 25 makes the inner end of the pressure rod 24 fit with the outer convex surface of the arc plate 20. Both sides of the outer convex surface of the arc plate 20 are provided with grooves 26. Two opposite arc strips 27 are provided inside the arc groove. The inner end of the arc strip 27 is connected to the insertion rod 22, and the outer end of the arc strip 27 is connected to the inner wall of the arc groove. The elastic force of the two arc strips 27 makes the insertion rod 22 be located at the center of the arc groove. When the arc plate 20 slides at the center of the slider 21, the outer convex surface of the arc plate 20 slides on the inner end surface of the pressure rod 24 until the inner end of the pressure rod 24 corresponds to the groove 26 of the arc plate 20. The elastic force of the spring sheet 25 makes the inner end of the pressure rod 24 inserted into the groove 26, and the elastic force of the spring sheet 25 is used to limit the rotating rod 7. At this time, the inner end of the rotating rod 7 uses the second convex plate 17 to limit the connecting part, so as to avoid the first connector 1 and the second connector 2 being separated due to a simple collision.

When the rotating rod 7 rotates in the opposite direction, since the opening of the groove 26 is chamfered, the rotating rod 7 uses the plate 19 to drive the arc plate 20 to rotate in the opposite direction. At this time, the groove 26 of the arc plate 20 gradually separates from the inner end of the pressure rod 24. The groove 26 uses the chamfer to make the outer end of the pressure rod 24 squeeze the spring sheet 25 until the inner end of the pressure rod 24 moves out of the groove 26. The elastic force of the spring sheet 25 makes the inner end of the pressure rod 24 always fit the outer convex surface of the arc plate 20. When the rotating rod 7 drives the plate 19 to rotate, the rotating plate 19 cooperates with the plug rod 22 to squeeze and pull the arc strip 27 inside the arc groove. Through the two arc strips 27, the plug rod 22 is conveniently placed at the center of the arc groove, so that the inner end of the rotating rod 7 in the process of plugging the through groove 10, the inner end of the plug rod 22 located at the center of the arc groove always corresponds to the plug hole 23 of the protrusion 5, ensuring the corresponding effect of the plug rod 22 and the plug hole 23.

Working principle of the present invention:

As shown in Figures 1 to 9, the first connector 1 uses the plug 3 to correspond to the plug housing 4 of the second connector 2 until the plug housing 4 is correspondingly sleeved on the surface of the plug 3, and at this time, the two sleeve frames 6 are respectively sleeved on the surfaces of the two protrusions 5. At this time, the rotating rod 7 is pushed to move, and the inner end of the rotating rod 7 gradually approaches the protrusion 5 until the side block 12 at the inner end of the rotating rod 7 enters the inside of the side groove 11. When the inner end of the rotating rod 7 moves inside the through groove 10, the rotating rod 7 drives the side block 12 to move synchronously inside the side groove 11 until the side block 12 at the inner end of the rotating rod 7 completely enters the inside of the circular groove 8 of the second connector 2.

When the side block 12 at the inner end of the rotating rod 7 enters the side groove 11, the inclined surface of the first convex plate 16 slides on the inner side of the side groove 11. Due to the squeezing of the first convex plate 16 by the inner side of the side groove 11, the first convex plate 16 gradually enters the rotating rod 7. At this time, the two first convex plates 16 approach each other, and the moving first convex plate 16 drives the side plate 13 to slide on the surface of the limiting rod 14. The two side plates 13 approaching each other cooperate to squeeze the spring 15 on the surface of the limiting rod 14. The elastic force of the spring 15 makes the outer side surface of the first convex plate 16 fit with the inner wall of the side groove 11 until the first convex plate 16 enters completely. After reaching the circular groove 8, the elastic force of the spring 15 pushes the two side plates 13 away from each other, and the moving side plate 13 drives the outer side surface of the second convex plate 17 to contact the inner wall of the side groove 11 until the second convex plate 17 enters the circular groove 8. At this time, the rotating rod 7 is rotated, and the rotating rod 7 drives the first convex plate 16 and the second convex plate 17 to rotate synchronously. At this time, the second convex plate 17 cooperates with the outer edge of the side groove 11 to clamp the rotating rod 7, and the circular plate 9 at the outer end of the rotating rod 7 is attached to the outer side surface of the first connecting head 1. Through the cooperation of the second convex plate 17 and the circular plate 9, the connection stability between the first connecting head 1 and the second connecting head 2 is further improved.

The rotating rod 7 is rotated so that the chamfered portion of the second convex plate 17 corresponds to the arc surface 18 of the side groove 11. The rotating rod 7 is pulled, and the rotating rod 7 drives the second convex plate 17 to approach the side groove 11 until the chamfer of the second convex plate 17 fits against the surface of the arc surface 18. The rotating rod 7 continues to move, and the pressure of the arc surface 18 on the second convex plate 17 causes the second convex plate 17 to gradually enter the interior of the rotating rod 7, under the elastic force of the spring 15, until the outer side surface of the second convex plate 17 fits against the inner wall of the side groove 11. Continue to pull the rotating rod 7, the rotating rod 7 drives the first protruding plate 16 to contact the arc surface 18, and the arc surface 18 cooperates to squeeze the first protruding plate 16 until the first protruding plate 16 completely enters the inside of the side block 12. At this time, the connecting component can be easily pulled out from the inside of the second connecting head 2 through the rotating rod 7 to ensure the detachable connection effect of the first connecting head 1 and the second connecting head 2. At this time, the first connecting head 1 and the second connecting head 2 are quickly separated by direct pulling, which speeds up the disassembly and installation effect of the first connecting head 1 and the second connecting head 2.

When the connecting part at the inner end of the rotating rod 7 moves inside the through groove 10, the rotating rod 7 drives the sticking plate 19 to gradually approach the protrusion 5 until the insertion rod 22 on the inner side of the slider 21 is gradually inserted into the insertion hole 23 on the inner side of the protrusion 5. At this time, the connecting part at the inner end of the rotating rod 7 is inside the circular groove 8. The rotating rod 7 is rotated, and the rotating rod 7 drives the arc plate 20 to rotate by using the sticking plate 19. Since the protrusion 5 limits the insertion rod 22 by using the insertion hole 23, the rotating arc plate 20 slides at the center of the slider 21. When the arc plate 20 slides at the center of the slider 21, the outer convex surface of the arc plate 20 slides on the inner end surface of the pressure rod 24 until the inner end of the pressure rod 24 corresponds to the groove 26 of the arc plate 20. The elastic force of the spring sheet 25 makes the inner end of the pressure rod 24 inserted into the groove 26, and the elastic force of the spring sheet 25 is used to limit the rotating rod 7. At this time, the inner end of the rotating rod 7 uses the second convex plate 17 to limit the connecting part, so as to avoid the first connector 1 and the second connector 2 being separated due to a simple collision.

When the rotating rod 7 rotates in the opposite direction, since the opening of the groove 26 is chamfered, the rotating rod 7 uses the plate 19 to drive the arc plate 20 to rotate in the opposite direction. At this time, the groove 26 of the arc plate 20 gradually separates from the inner end of the pressure rod 24. The groove 26 uses the chamfer to make the outer end of the pressure rod 24 squeeze the spring sheet 25 until the inner end of the pressure rod 24 moves out of the groove 26. The elastic force of the spring sheet 25 makes the inner end of the pressure rod 24 always fit the outer convex surface of the arc plate 20. When the rotating rod 7 drives the plate 19 to rotate, the rotating plate 19 cooperates with the plug rod 22 to squeeze and pull the arc strip 27 inside the arc groove. Through the two arc strips 27, it is convenient to make the plug rod 22 at the center of the arc groove, so that the inner end of the rotating rod 7 in the process of plugging the through groove 10, the inner end of the plug rod 22 at the center of the arc groove always corresponds to the plug hole 23 of the protrusion 5, ensuring the corresponding effect of the plug rod 22 and the plug hole 23.

The above embodiments are only used to illustrate the technical solutions of the present invention, rather than to limit the same.

Claims (8)

1. A connector structure for an electronic device, comprising a first connector (1) and a second connector (2), characterized in that: the first connector (1) and the second connector (2) are arranged opposite to each other, a plug (3) is arranged on the inner side of the second connector (2), a wire is arranged at the center of the outer side of the first connector (1), a plug shell (4) is arranged on the inner side of the first connector (1) and is sleeved on the outer side of the plug (3), protrusions (5) are arranged on both sides of the plug (3), sleeve frames (6) are arranged on both sides of the sleeve frames (4), the two sleeve frames (6) correspond to the two protrusions (5) one by one, and the sleeve frames (6) are sleeved on the surfaces of the protrusions (5), rotating rods (7) are inserted on both sides of the first connector (1), the inner side end of the rotating rod (7) is correspondingly inserted into the inner side of a circular groove (8) of the second connector (2) through the protrusion (5), the outer side end of the rotating rod (7) is connected to a circular plate (9), the inner side end of the rotating rod (7) is provided with a connecting component, and the connecting component is correspondingly buckled in the inner side of the circular groove (8). 2. The connector structure for electronic equipment according to claim 1 is characterized in that: a through groove (10) corresponding to the inner end of the rotating rod (7) is provided at the center of the protrusion (5), and side grooves (11) are provided on both sides of the through groove (10); two opposite side blocks (12) are fixed to the inner end of the rotating rod (7), and the two side blocks (12) correspond to the two side grooves (11) one by one; when the rotating rod (7) is inserted into the inner side of the through groove (10), the rotating rod (7) moves inside the side groove (11) by means of the side blocks (12); the diameter of the circular groove (8) is larger than the diameter of the through groove (10), and the center line of the circular groove (8) coincides with the center line of the through groove (10). 3. The connector structure for electronic equipment according to claim 2, characterized in that: the connecting component comprises two opposite side plates (13), the two side plates (13) are both located inside the inner end of the rotating rod (7), a limiting rod (14) penetrating the two side plates (13) is arranged inside the inner end of the rotating rod (7), a spring (15) is sleeved on the surface of the limiting rod (14), and two ends of the spring (15) are respectively connected to the inner side surfaces of the two side plates (13), a first convex plate (16) is fixed to the inner end of the side plate (13), and a second convex plate (17) is fixed to the outer end of the side plate (13), the first convex plate (16) corresponds to penetrating the center of the side block (12), and the second convex plate (17) penetrates the rotating rod (7), and the outer side surface of the first convex plate (16) is provided with an inclined surface, and the inclined surface of the first convex plate (16) corresponds to the side groove (11). 4. The connector structure for electronic equipment according to claim 3, characterized in that: the outer end of the second protruding plate (17) is provided with a chamfer, and the inner end of the side groove (11) is provided with an arc surface (18), and the chamfer of the second protruding plate (17) corresponds to the arc surface (18) of the side groove (11). 5. The connector structure for electronic equipment according to claim 1 is characterized in that: a pasting plate (19) is provided at the center of the rotating rod (7), and when the sleeve frame (6) is sleeved on the surface of the protrusion (5), the inner side surface of the pasting plate (19) fits with the inner side surface of the protrusion (5), and the top and bottom of the pasting plate (19) are provided with arc grooves, and an arc plate (20) is fixed inside the arc groove, and a slider (21) is slidably sleeved on the surface of the arc plate (20), and an insertion rod (22) is fixed to the inner end of the slider (21), and the inner end of the insertion rod (22) extends out of the inner side of the arc groove, and the top and bottom of the inner side surface of the protrusion (5) are provided with insertion holes (23), and the insertion rod (22) is correspondingly inserted into the inside of the insertion hole (23). 6. The connector structure for electronic equipment according to claim 5, characterized in that the overall shape of the arc plate (20) is set to be an arc-shaped long strip structure, and when the rotating rod (7) rotates, the rotating rod (7) uses the sticking plate (19) to drive the arc plate (20) to rotate synchronously. 7. The connector structure for electronic equipment according to claim 5 is characterized in that: a pressure rod (24) is inserted into the slider (21), the outer end of the pressure rod (24) extends out of the slider (21), a spring sheet (25) is fixed to the slider (21), and the outer end of the pressure rod (24) is correspondingly connected to the center of the spring sheet (25), the elastic force of the spring sheet (25) makes the inner end of the pressure rod (24) fit with the outer convex surface of the arc plate (20), and grooves (26) are provided on both sides of the outer convex surface of the arc plate (20). 8. The connector structure for electronic equipment according to claim 5 is characterized in that: two opposite arc strips (27) are arranged inside the arc groove, the inner end of the arc strip (27) is connected to the insertion rod (22), and the outer end of the arc strip (27) is connected to the inner wall of the arc groove, and the elastic force of the two arc strips (27) makes the insertion rod (22) be located at the center of the arc groove.