阅读说明：本技术 连接器保护罩 (Connector protective cover ) 是由 曾崇铭 于 2020-09-10 设计创作，主要内容包括：本发明的连接器保护罩包含：内壳体,该内壳体为中空且外表面上形成有控制导槽,该控制导槽包含有相互连通的第一导槽、第二导槽及第三导槽,其中该第二导槽朝纵向方向延伸；耦接螺母,该耦接螺母为中空并套设在该内壳体外,该耦接螺母用于和一物体耦接；以及锁定环,该锁定环为中空并套设在该内壳体外,该锁定环的内表面上形成有插脚,该插脚能够在该控制导槽中移动,其中当该插脚位于该第二导槽中时,拉动该锁定环能够远离该耦接螺母,当该插脚位于该第一导槽或该第三导槽中时,转动该锁定环能够带动该耦接螺母转动。(The connector protection cover of the present invention comprises: the inner shell is hollow, a control guide groove is formed in the outer surface of the inner shell, the control guide groove comprises a first guide groove, a second guide groove and a third guide groove which are communicated with each other, and the second guide groove extends towards the longitudinal direction; the coupling nut is hollow and sleeved outside the inner shell body, and is used for coupling with an object; and the locking ring is hollow and sleeved outside the inner shell, the inner surface of the locking ring is provided with a pin, the pin can move in the control guide groove, when the pin is positioned in the second guide groove, the locking ring can be pulled to be away from the coupling nut, and when the pin is positioned in the first guide groove or the third guide groove, the locking ring can be rotated to drive the coupling nut to rotate.)

1. A connector boot, comprising:

the inner shell is hollow, a control guide groove is formed in the outer surface of the inner shell, the control guide groove comprises a first guide groove, a second guide groove and a third guide groove which are communicated with each other, and the second guide groove extends towards the longitudinal direction;

the coupling nut is hollow and sleeved outside the inner shell body, and is used for coupling with an object; and

the locking ring is hollow and sleeved outside the inner shell, pins are formed on the inner surface of the locking ring and can move in the control guide groove, when the pins are located in the second guide groove, the locking ring can be pulled to be away from the coupling nut, and when the pins are located in the first guide groove or the third guide groove, the locking ring can be rotated to drive the coupling nut to rotate.

2. The connector boot of claim 1, wherein the locking ring defines an opening, a cantilever arm is disposed within the opening, the cantilever arm extends in the longitudinal direction, and the pin is disposed on the cantilever arm.

3. The connector boot of claim 1, wherein two tabs extend from a rear end of the coupling nut, and wherein a protrusion is formed on an inner surface of the locking ring, the protrusion being disposed between the two tabs.

4. The connector boot of claim 1, wherein a tab is formed in the second channel, and wherein movement of the lock ring to move the pin over the tab causes a change in resistance to movement of the lock ring.

5. The connector boot of claim 1, wherein a first offset is formed at a junction of the first guide groove and the second guide groove for preventing the pin from moving from the second guide groove to the first guide groove.

6. A connection boot, comprising:

the inner shell is hollow, a control guide groove is formed in the outer surface of the inner shell, and the control guide groove extends towards the longitudinal direction;

the coupling nut is hollow and sleeved outside the inner shell, the front end of the coupling nut is used for being coupled with an object, a protruding piece extends out of the rear end of the coupling nut, a guide groove is formed in the protruding piece and comprises a first guide groove and a second guide groove, the second guide groove is communicated with the first guide groove, and the extending direction of the second guide groove and the longitudinal direction form a preset angle; and

the locking ring is hollow and sleeved outside the inner shell, a first pin and a second pin are formed on the inner surface of the locking ring, the first pin can move in the control guide groove, the second pin can move in the guide groove, and when the second pin is located in the second guide groove, the locking ring can be moved to drive the coupling nut to rotate.

7. The connector boot of claim 6, wherein a direction of extension of the first guide groove is parallel to the longitudinal direction.

8. The connector boot of claim 6, wherein the locking ring defines an opening, a cantilever arm is disposed within the opening, the cantilever arm extends in the longitudinal direction, and the first pin is disposed on the cantilever arm.

9. The connector boot as claimed in claim 6, wherein a convex portion is formed on an outer surface of the inner housing, and a concave portion is formed on the convex portion.

10. The connector boot of claim 6, wherein the control channel has a tab formed therein that causes a change in resistance to movement of the locking ring when the locking ring is moved to cause the first prong to pass the tab.

Technical Field

The invention relates to the technical field of protective covers, in particular to a protective cover for an optical fiber connector.

Background

In recent years, the amount of optical fiber used in the field of communications has become very large, and data, voice, and other communications networks increasingly use optical fiber to transmit information. Optical fibers are typically configured as glass fibers for carrying light. A single fiber can carry a large amount of data simultaneously.

In constructing a fiber optic network, each fiber is typically connected to source equipment and destination equipment. In addition, along the fiber path between the source and destination, various connections or couplings may be made on the fiber to adjust the fiber length. Each connection or coupling requires a connector and adapter to align the optical fibers so that light can be transmitted without interruption.

Referring to fig. 1, U.S. patent No. 9,755,382 discloses a connector system for optical fiber and electrical conductor connector modules, which is characterized in that after the coupling nut 18 is rotated to the closed position, the locking ring 26 can be used as a safety device to prevent unlocking. The locking method is to lock the coupling nut 18 clockwise and then push the locking ring 26 forward against the coupling nut 18 to prevent the coupling nut 18 from rotating. To unlock, the lock ring 26 is pulled back and the coupling nut 18 is unscrewed counterclockwise. However, if the user forgets to push up on the locking ring 26 after locking the coupling nut 18, there is no assurance that the coupling nut 18 remains in the closed position.

The disadvantage of the above connector design is that it cannot be installed side by side because the coupling nut is held by hand and space next to the coupling nut must be allowed to allow hand rotation of the coupling nut, resulting in a connector that cannot be installed with too high a density and must be installed over a wider distance.

Disclosure of Invention

Accordingly, the present invention is directed to a connector protection cover that allows a user to perform connecting, locking and unlocking operations with only one hand.

A connector boot, comprising:

the inner shell is hollow, a control guide groove is formed in the outer surface of the inner shell, the control guide groove comprises a first guide groove, a second guide groove and a third guide groove which are communicated with each other, and the second guide groove extends towards the longitudinal direction;

the coupling nut is hollow and sleeved outside the inner shell body, and is used for coupling with an object; and

the locking ring is hollow and sleeved outside the inner shell, pins are formed on the inner surface of the locking ring and can move in the control guide grooves, when the pins are located in the second guide grooves, the locking ring can be pulled to be away from the coupling nut, and when the pins are located in the first guide grooves or the third guide grooves, the locking ring can be rotated to drive the coupling nut to rotate.

In one embodiment, the locking ring has an opening, a cantilever is disposed in the opening, the cantilever extends in the longitudinal direction, and the pin is disposed on the cantilever.

In one embodiment, two tabs extend from the rear end of the coupling nut, and a protrusion is formed on the inner surface of the locking ring and disposed between the two tabs.

In one embodiment, the second guide slot has a protrusion formed therein, and when the lock ring is moved to cause the pins to pass over the protrusion, the resistance to movement of the lock ring is changed.

In one embodiment, a first offset is formed at the junction of the first guide slot and the second guide slot, and the offset can prevent the pin from moving from the second guide slot to the first guide slot.

A connector boot, comprising:

the inner shell is hollow, a control guide groove is formed in the outer surface of the inner shell, and the control guide groove extends towards the longitudinal direction;

the coupling nut is hollow and sleeved outside the inner shell, the front end of the coupling nut is used for being coupled with an object, a protruding piece extends out of the rear end of the coupling nut, a guide groove is formed in the protruding piece and comprises a first guide groove and a second guide groove, the second guide groove is communicated with the first guide groove, and the extending direction of the second guide groove and the longitudinal direction form a preset angle; and

the locking ring is hollow and sleeved outside the inner shell, a first pin and a second pin are formed on the inner surface of the locking ring, the first pin can move in the control guide groove, the second pin can move in the guide groove, and when the second pin is located in the second guide groove, the locking ring can be moved to drive the coupling nut to rotate.

In one embodiment, the extending direction of the first guide groove is parallel to the longitudinal direction.

In one embodiment, the locking ring has an opening, a cantilever is disposed in the opening, the cantilever extends in the longitudinal direction, and the first pin is disposed on the cantilever.

In one embodiment, a convex part is formed on the outer surface of the inner shell, and a concave part is formed on the convex part.

In one embodiment, the control guide slot has a protrusion formed therein, and when the locking ring is moved to allow the first prong to pass over the protrusion, the resistance to movement of the locking ring is changed.

After adopting this technical scheme, compare with prior art, this technical scheme has following beneficial effect: by adopting the connector protection cover, a user can control the coupling nut to rotate only by rotating or moving the locking ring without directly rotating the coupling nut. This eliminates the need for a space adjacent to the coupling nut to allow a user to hold the coupling nut, thereby increasing the density of the connector.

Drawings

FIG. 1 is a schematic diagram of a conventional connector system;

fig. 2 is an exploded view of a first embodiment of the connector boot of the present invention;

fig. 3a and 3b are perspective views of the inner housing of the first embodiment of the connector boot of the present invention from different perspectives;

fig. 4a to 4c are perspective views of the coupling nut of the first embodiment of the connector boot of the present invention from different perspectives;

fig. 5a and 5b are perspective views of the locking ring of the first embodiment of the connector boot of the present invention from different perspectives;

fig. 6a is a perspective view of a first embodiment of a connector boot of the present invention;

fig. 6b is another perspective view of the first embodiment of the connector boot of the present invention;

FIG. 7 is a perspective view of a prior art flange;

FIG. 8 is a schematic view of a first embodiment of the connector boot of the present invention in connection with a conventional flange;

fig. 9 is an exploded view of a second embodiment of the connector boot of the present invention;

fig. 10a and 10b are perspective views of the inner housing of the second embodiment of the connector boot of the present invention from different perspectives;

fig. 11a to 11c are perspective views of a coupling nut of a second embodiment of a connector boot of the present invention from different perspectives;

fig. 12a and 12b are perspective views of a locking ring of a second embodiment of a connector boot of the present invention from different perspectives;

fig. 13a is a perspective view of a second embodiment of a connector boot of the present invention;

fig. 13b is another perspective view of the second embodiment of the connector boot of the present invention;

fig. 14 is a schematic view of a second embodiment of the connector boot of the present invention in connection with a conventional flange.

18-a coupling nut; 26-a locking ring; 100-cable joints; 200-an inner housing; 210-a ring groove; 220-a convex part; 222-a recess; 230-a control channel; 231-a first guide groove; 232-a second guide slot; 233-a third guide groove; 241-first offset; 242-bumps; 243-second offset; 300-a coupling nut; 310-a tab; 320-a receiving groove; 322-retaining wall; 324-a notch; 400-a locking ring; 410-pins; 420-a bump; 430-opening; 440-a cantilever; 511-longitudinal direction; 590-flange; 591-ring; 592-opening holes; 593-a tab; 594-a bump; 600-cable joint; 700-an inner housing; 710-ring groove; 720-a convex part; 722-a recess; 730-control channel guide; 732-bumps; 800-a coupling nut; 810-tab; 820-a holding groove; 822-retaining wall; 824-gap; 830-a guide groove; 831-first guide slot; 832-a second guide groove; 900-a locking ring; 910-a first pin; 920-a second pin; 930-opening the hole; 940-cantilever.

Detailed Description

Referring to fig. 2, the first embodiment of the connector protection cover of the present invention includes a cable connector 100, an inner housing 200, a coupling nut 300 and a locking ring 400. The cable connector 100, the inner housing 200, the coupling nut 300 and the locking ring 400 can be integrally formed by plastic molding.

The cable connector 100 may be made of a flexible material and provide strain relief to a cable (not shown) using materials and connection techniques known in the art. The cable connector 100 is a hollow structure with a length direction parallel to the longitudinal direction 511. The front end of the cable connector 100 has a hexagonal nut-like shape and can be coupled to the inner housing 200.

Referring to fig. 3a and 3b, the inner housing 200 is hollow and cylindrical, and the length direction thereof is parallel to the longitudinal direction 511. A recessed ring groove 210 is formed at a front end of an outer surface of the inner housing 200 to receive a sealing ring (not shown). An annular protrusion 220 is formed on the outer surface of the inner housing 200, behind the ring groove 210. The protrusion 220 is formed with two symmetrically disposed recesses 222, and the front end of each recess 222 is formed with an opening. Two symmetrically arranged control guide grooves 230 are further formed on the outer surface of the inner housing 200, each control guide groove 230 includes a first guide groove 231, a second guide groove 232 and a third guide groove 233, and the guide grooves 231, 232 and 233 form a closed triangle. The second guide groove 232 extends in the longitudinal direction 511, and a projection 242 is formed on the bottom at the center thereof. A first offset 241 is formed at the connection position of the first guide groove 231 and the second guide groove 232, and the first offset 241 is higher than the bottom surface of the second guide groove 231. A second offset 243 is formed at the connection between the third guide groove 233 and the first guide groove 231, and the offset 243 is higher than the bottom surface of the first guide groove 231.

Referring to fig. 4a, 4b and 4c, the coupling nut 300 is hollow and cylindrical and can be sleeved outside the inner housing 200. At the rear end of the coupling nut 300, a plurality of lugs 310 having an arcuate shape in cross section are protruded. Two symmetrically disposed receiving grooves 320 are formed on the inner surface of the front end of the coupling nut 300, a retaining wall 322 is formed at the front end of each receiving groove 320, and a notch 324 is formed at the left side of the retaining wall 322.

Referring to fig. 5a and 5b, the locking ring 400 is hollow and cylindrical, and can be sleeved outside the inner housing 200 and cover the arcuate tab 310 at the rear end of the coupling nut 300. The locking ring 400 has two symmetrically disposed square protrusions 420 formed on an inner surface thereof near the front end, and a length direction of each protrusion 420 is parallel to the longitudinal direction 511. The locking ring 400 also has two symmetrically disposed prongs 410 formed on the inner surface thereof. In another embodiment, the lock ring 400 has two symmetrically disposed openings 430, each opening 430 has a cantilever 440 extending in the longitudinal direction 511, the root of each cantilever 440 is connected to the sidewall of the lock ring 400, and each pin 410 is fixed to the front section of the cantilever 440.

Referring to fig. 6a and 6b, according to the first embodiment of the connector protection cover of the present invention, the rear end of the inner housing 200 is inserted into the front end of the cable connector 100, and the coupling nut 300 is sleeved outside the front end of the inner housing 200. The locking ring 400 is fitted over the middle end of the inner housing 200 and covers the arcuate tabs 310 at the rear end of the coupling nut 300. The two square protrusions 420 on the inner surface of the locking ring 400 are respectively disposed between the adjacent two arcuate tabs 310 of the coupling nut 300, and the two pins 410 on the inner surface of the locking ring 400 are respectively disposed in the two control guide grooves 230 of the inner housing 200. The connector to be protected is disposed in the inner housing 200 (not shown).

Fig. 7 is a perspective view of a conventional flange (flange)590 for locking to a device to enable a connector disposed on the device to mate with an external connector. The flange 590 is a square structure, and a bolt hole is formed in each of four corners of the flange, so that the flange 590 can be locked on the device. The flange 590 defines a circular opening 592 at a center thereof, the opening 592 is surrounded by a protruding ring 591. Two symmetrically arranged lugs 593 extend from the ring 591, and a projection 594 is arranged on the outer surface of each lug 593.

Referring to fig. 8, the first embodiment of the connector protection cover of the present invention can be coupled to the flange 590 shown in fig. 7, so that the connector inside the connector protection cover can be mated with the connector behind the flange 590 (not shown). To accomplish the coupling, the inner housing 200 of the connector protection cover is inserted into the ring 591 of the flange 590, so that the tabs 593 of the flange 590 are respectively inserted into the recesses 222 on the protrusions 220 of the inner housing 200, and the inner housing 200 is restricted from rotating. After the coupling nut 300 is rotated, the protrusions 594 of the flange 590 are respectively snapped into the receiving grooves 320 from the notches 324 at the left side of the retaining wall 322 of the coupling nut 300, and the coupling nut 300 is coupled to the flange 590, so that the connector protective cover is locked on the flange 590. To unlock the connector boot from the flange 590, the coupling nut 300 is rotated in the opposite direction such that the protrusions 594 of the flange 590 are respectively moved out of the receiving grooves 320 from the notches 324. In other embodiments, the coupling nut 300 is not limited to be coupled to the flange 590, and may be designed to be coupled to other objects.

Referring to fig. 3a again, according to the first embodiment of the connector protection cover of the present invention, the two pins 410 on the inner surface of the locking ring 400 can slide in the two control guide slots 230 of the inner housing 200 in the direction indicated by the arrow, i.e. clockwise direction, respectively. Specifically, the pins 410 can slide from the first guide slot 231 to the second guide slot 232 and the third guide slot 233 in sequence, and then return to the first guide slot 231. The pin 410 cannot slide back to the origin in the counterclockwise direction in the control guide groove 230 due to the limitation of the first and second offsets 241 and 243.

When the pins 410 are in the first guide slots 231, rotating the locking ring 400 clockwise allows the pins 410 to slide over the first offset 241 to the second guide slots 232, and the locking ring 400 approaches the flange 590. When the prongs 410 are positioned in the second guide slots 232, pulling back on the locking ring 400 causes the prongs 410 to pass over the tabs 242 and approach the third guide slots 233 as the second guide slots 232 extend in the longitudinal direction 511, as the locking ring 400 moves progressively away from the flange 590. As the prongs 410 pass over the bumps 242, the user experiences a significant change in resistance, thus providing tactile feedback to the user. When the pin 410 is located in the third guide groove 233, rotating the locking ring 400 counterclockwise allows the pin 410 to slide back into the first guide groove 231 over the second offset 243. It is noted that the locking ring 400 cannot rotate the inner housing 200 during the rotation.

According to the first embodiment of the connector boot of the present invention, since the two square protrusions 420 on the inner surface of the locking ring 400 are respectively sandwiched by the two adjacent arcuate tabs 310 of the coupling nut 300, the rotation of the locking ring 400 can thus simultaneously rotate the coupling nut 300. Additionally, the pull-back locking ring 400 does not pull the coupling nut 300. When the pin 410 slides from the first guide slot 231 to the second guide slot 232, the coupling nut 300 is rotated clockwise and locked. To unlock the coupling nut 300, the locking ring 400 is pulled backward, and then the locking ring 400 is rotated backward so that the pins 410 slide from the second guide grooves 232 to the third guide grooves 233.

According to the first embodiment of the connector boot of the present invention, the user can rotate the locking ring 400 to control the rotation of the coupling nut 300 without directly rotating the coupling nut 300. This eliminates the need for a space beside the coupling nut 300 for a user to hold, thereby increasing the density of the connector.

Referring to fig. 9, the second embodiment of the connector protection cover of the present invention includes a cable connector 600, an inner housing 700, a coupling nut 800 and a locking ring 900. The cable connector 600, the inner housing 700, the coupling nut 800 and the locking ring 900 can be integrally formed by plastic injection molding.

The cable connector 600 may be made of a flexible material and provide strain relief to a cable (not shown) using materials and connection techniques known in the art. The cable connector 600 is a hollow structure with a length direction parallel to the longitudinal direction 511. The front end of the cable connector 600 has a hexagonal nut-like shape and can be coupled to the inner housing 700.

Referring to fig. 10a and 10b, the inner housing 700 is hollow and cylindrical, and the length direction thereof is parallel to the longitudinal direction 511. A recessed ring groove 710 is formed at the front end of the outer surface of the inner housing 700 for receiving a sealing ring (not shown). An annular protrusion 720 is formed on the outer surface of the inner housing 700 behind the ring groove 710. The protrusion 720 is formed with two symmetrically disposed recesses 722, and an opening is formed at the front end of each recess 722. Two symmetrically disposed control guide grooves 730 are further formed on the outer surface of the inner housing 700, the control guide grooves 730 extend in the longitudinal direction 511, and a projection 732 is formed on the bottom at the center thereof.

Referring to fig. 11a, 11b and 11c, the coupling nut 800 is hollow and cylindrical and can be sleeved outside the inner housing 700. Two symmetrically disposed receiving grooves 820 are formed on the inner surface of the front end of the coupling nut 800, a transverse retaining wall 822 is formed at the front end of each receiving groove 820, and a notch 824 is formed at the left side of the retaining wall 822. Two symmetrically arranged protruding pieces 810 extend from the rear end of the coupling nut 800, and a guide groove 830 is formed on each protruding piece 810. The two guiding grooves 830 are symmetrically disposed and each includes a first guiding groove 831 and a second guiding groove 832. The first guide 831 extends from the rear end of the tab 810 in the longitudinal direction 511. The second guide slot 832 is communicated with the first guide slot 831 and extends from the front end of the first guide slot 831 to the front end of the coupling nut 800, and the extending direction of the second guide slot 832 forms a preset angle with the longitudinal direction 511.

Referring to fig. 12a and 12b, the locking ring 900 is hollow and cylindrical, and can be sleeved outside the inner housing 700 and cover the protruding piece 810 at the rear end of the coupling nut 800. The inner surface of the locking ring 900 near the front end is formed with two symmetrically arranged second prongs 920. The locking ring 900 also has two symmetrically disposed first prongs 910 formed on an inner surface thereof. In another embodiment, the lock ring 900 has two symmetrically disposed openings 930, each opening 930 has a cantilever 940 extending toward the longitudinal direction 511, a root of each cantilever 940 is connected to a sidewall of the lock ring 900, and each first pin 910 is disposed at a front section of the cantilever 940.

Referring to fig. 13a and 13b, according to the second embodiment of the connector protection cover of the present invention, the rear end of the inner housing 700 is inserted into the front end of the cable connector 600, and the coupling nut 800 is sleeved outside the front end of the inner housing 700. The locking ring 900 is disposed over the middle section of the inner housing 700 and covers the tabs 810 at the rear end of the coupling nut 800. The two first pins 910 on the inner surface of the locking ring 900 are respectively located in the two control guide slots 730 of the inner housing 700, and the two second pins 920 on the inner surface of the locking ring 900 are respectively located in the two guide slots 830 of the coupling nut 800. A connector to be protected is disposed in the inner housing 700 (not shown).

Referring to fig. 14, a second embodiment of the connector protection cover of the present invention can be coupled to the flange 590 shown in fig. 7, so that the connector inside the connector protection cover can be mated with the connector behind the flange 590 (not shown). To couple, the inner housing 700 of the connector protection cover is inserted into the ring 591 of the flange 590, so that the two tabs 593 of the flange 590 are respectively inserted into the recesses 722 on the protrusions 720 of the inner housing 700, and the inner housing 700 is restricted from rotating. The coupling nut 800 is then rotated to allow the protrusions 594 of the flange 590 to be respectively inserted into the receiving grooves 820 from the notches 824 at the left side of the retaining wall 822 of the coupling nut 800, and the coupling nut 800 is coupled to the flange 590, so that the connector protective cover is locked on the flange 590. If the connector boot is to be unlocked from the flange 590, the coupling nut 800 is rotated in the opposite direction to allow the protrusions 594 of the flange 590 to move out of the receiving grooves 820 from the notches 824, respectively. In other embodiments, the coupling nut 800 is not limited to be coupled to the flange 590, and may be designed to be coupled to other objects.

Referring to fig. 10a, in the second embodiment of the connector protection cover according to the present invention, the two first pins 910 on the inner surface of the locking ring 900 can slide back and forth in the two control guide slots 730 of the inner housing 700, respectively. As the first prong 910 passes over the projection 732, the user experiences a significant change in resistance, thus providing tactile feedback to the user.

According to the second embodiment of the connector protection cover of the present invention, the two second pins 920 on the inner surface of the locking ring 900 are respectively located in the two guide grooves 830 of the coupling nut 800. When the second pins 920 are located in the first guide slots 831, the coupling nut 800 is not moved by pushing the locking ring 900 forward because the first guide slots 831 are disposed parallel to the longitudinal direction 511; when the second pins 920 are located in the second guide grooves 832, the forward pushing of the locking ring 900 causes the coupling nut 800 to rotate clockwise to lock. Similarly, pulling back on the locking ring 900 causes the coupling nut 800 to rotate counterclockwise and unlock when the second prongs 920 are in the second guide slots 832.

According to the second embodiment of the connector boot of the present invention, the user can move the locking ring 900 back and forth to control the rotation of the coupling nut 800 without directly rotating the coupling nut 800. This eliminates the need for a space around the coupling nut 800 to be grasped by the user, thereby increasing the density of the connector.

While the invention has been described with reference to the foregoing embodiments, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Therefore, the protection scope of the present invention should be determined by the appended claims.