CN205346488U - Automatic wire winding device - Google Patents

Abstract

The utility model relates to a technical field of wire winding structure discloses automatic wire winding device for optical fiber cable between winding light transceiver module subassembly and the connector, including winding arrangement and helical pitch structure, the winding arrangement has by power components drive rotation and supplies the fixed carousel of placing of light transceiver module subassembly, is equipped with the wire winding structure that is used for twining optical fiber cable on the carousel, the helical pitch structure has the helical pitch groove strip of arranging outside the carousel and being used for placing the connector, and the tip of helical pitch groove strip has the opening, and the opening of helical pitch groove strip is arranged towards the carousel. During optical fiber cable between needs winding light transceiver module subassembly and connector, will be bare that the transceiver module subassembly is fixed to be placed in the carousel, and place the connector in the strip of helical pitch groove, and rotate through power components drive turntable, optical fiber cable is twined the outside in the wire winding structure, and the connector also along helical pitch groove strip, removes towards the carousel to realize optical fiber cable's automatic winding, the staff's that significantly reduces work load improves work efficiency.

Description

Automatic coiling device

Technical field

This utility model relates to the technical field of Winder, particularly relates to automatic coiling device.

Background technology

Optical device is divided into active device and passive device, and optical active component is to need can converting the electrical signal to optical signal or converting optical signals into the opto-electronic device of the signal of telecommunication of external energy driving work in optical communication system, is the heart of optical transmission system；Optical passive component is the opto-electronic device not needing external energy driving work.

In prior art, optical device includes optical transceiver module assembly and adapter, wherein, is connected by optical fiber cable between optical transceiver module assembly and adapter.The particular advantages that optical fiber cable has becomes outstanding delay medium, determines the length of winding optical fiber optical cable according to the difference of time delay.

Winding currently for optical fiber cable is generally adopted manual winding, considerably increases the workload of staff, not only increases cost, and it is substantially reduced winding efficiency.

Utility model content

The purpose of this utility model is in that to provide automatic coiling device, it is intended to solves the optical fiber cable in optical device of the prior art and adopts false twist, has that cost is high and inefficient problem.

This utility model is achieved in that automatic coiling device, for being wound around the optical fiber cable between optical transceiver module assembly and adapter, including winding arrangement and helical pitch structure；Described winding arrangement has by dynamical element driving rotation and the rotating disk for optical transceiver module assembly fixed placement, and described rotating disk is provided with the winding structure for winding optical fiber cable；Described helical pitch structure has and is arranged in outside described rotating disk and for placing the helical pitch groove bar of adapter, and the end of described helical pitch groove bar has opening, and the opening of described helical pitch groove bar is arranged towards described rotating disk.

Further, described winding structure includes multiple column being arranged on described rotating disk, and multiple described columns are arranged in around shape.

Further, being provided with upper end open and the groove for fixed placement optical transceiver module assembly in described rotating disk, described groove is positioned at the outside of described winding structure.

Further, described winding arrangement includes connecting axle, and described connection axle is fixedly connected on the lower end of described rotating disk, and described dynamical element is motor, and described motor is positioned at the lower section of described rotating disk, and the rotating shaft of described motor be connected between axle and connected by shaft coupling.

Further, described winding arrangement includes the first installing rack being positioned at below described rotating disk, has through hole in the upper end of described first installing rack, and described motor is placed in described first installing rack, and the through hole of rotating shaft described first installing rack of traverse of described motor.

Further, described winding arrangement includes the second installing rack being located on described first installing rack, has installing hole in the upper end of described second installing rack, is provided with bearing in described installation card, and described connection axle is plugged in described bearing.

Further, described helical pitch structure includes support and two helical pitch sticks arranged on the bracket, and two helical pitch stick intervals in opposite directions are arranged, and extend layout towards described rotating disk, and described helical pitch groove bar is formed between two described helical pitch sticks.

Further, described support is provided with surface plate, and two described helical pitch sticks are arranged on described surface plate.

Further, described helical pitch groove bar is vertical bar shape towards one end of described rotating disk.

Further, described automatic coiling device includes base plate, described winding arrangement and helical pitch structure and is arranged on described base plate.

Compared with prior art, the automatic coiling device that this utility model provides, when needing to be wound around the optical fiber cable between optical transceiver module assembly and adapter, by optical transceiver module assembly fixed placement in rotating disk, adapter is placed in helical pitch groove bar, rotating disk is driven to rotate by dynamical element, optical fiber cable is wrapped in the outside of winding structure, adapter is also along helical pitch groove bar, move towards rotating disk, thus realizing the automatic winding of optical fiber cable, greatly reducing the workload of staff, improving work efficiency.

Accompanying drawing explanation

Fig. 1 is the schematic perspective view of the automatic coiling device that this utility model embodiment provides；

Fig. 2 is the A place enlarged diagram in Fig. 1；

Fig. 3 is the B place enlarged diagram in Fig. 1；

Fig. 4 is the exploded perspective schematic diagram of the winding arrangement that this utility model embodiment provides；

Fig. 5 is the schematic perspective view of the optical device that this utility model embodiment provides.

Detailed description of the invention

In order to make the purpose of this utility model, technical scheme and advantage clearly understand, below in conjunction with drawings and Examples, this utility model is further elaborated.Should be appreciated that specific embodiment described herein is only in order to explain this utility model, be not used to limit this utility model.

Below in conjunction with specific embodiment, realization of the present utility model is described in detail.

Shown in 5, for the preferred embodiment that this utility model provides.

The automatic coiling device that the present embodiment provides is for being wound around the optical fiber cable 112 in optical device, namely it is wound around the optical fiber cable 112 between optical transceiver module assembly 109 and adapter 111, such as BOSA optical device, certainly, it can also apply to the winding of the optical fiber cable 112 in other optical devices, is not limited to the utilization in the present embodiment.

Automatic coiling device includes winding arrangement and helical pitch structure, wherein, winding arrangement has the rotating disk 106 being driven rotation by dynamical element, optical transceiver module assembly 109 is placed in rotating disk 106, and after optical transceiver module assembly 109 is placed in rotating disk 106, optical transceiver module assembly 109 is fixed relative to rotating disk 106, rotates along with the rotation of rotating disk 106；Rotating disk 106 is provided with multiple column 107, and multiple columns 107 are arranged in around shape；Helical pitch structure is arranged in the outside of rotating disk 106, and it has helical pitch groove bar 100, and the end of this helical pitch groove bar 100 forms opening, and helical pitch groove bar 100 is arranged in the outside of rotating disk 106, and the opening of helical pitch groove bar 100 is arranged towards rotating disk 106.

So, when needs are wound optical fiber cable 112, optical transceiver module assembly 109 fixed placement is in rotating disk 106, adapter 111 is placed in helical pitch groove bar 100, optical fiber cable 112 is placed in the outside of multiple column 107, so, dynamical element drives rotating disk 106 to rotate, along with rotating disk 106 rotates, multiple columns 107 also rotate, optical fiber cable 112 is then wrapped in the outside of multiple column 107, and adapter 111 is then along helical pitch groove bar 100, move towards rotating disk 106, after reaching coiling length, stop winding optical fiber cable 112, artificial taking-up optical transceiver module assembly 109 and adapter 111, spiral silica gel tube is installed.

The automatic coiling device of above-mentioned offer, rotated by rotating disk 106 and the setting of helical pitch groove bar 100, it is possible to be automatically obtained the winding of optical fiber cable 112, relative to false twist's optical fiber cable 112 of the prior art, greatly reduce the workload of staff, be greatly improved work efficiency.

In the present embodiment, rotating disk 106 is provided with four columns 107, and certainly, it can also be three columns 107, and the optical fiber cable 112 after winding forms the outside at multiple columns 107.

Or; as other embodiments; cylindrical piece can also be set on rotating disk 106; utilize cylindrical piece winding optical fiber cable 112; or other blocks etc.; as long as rotating disk 106 rotates, it is possible to the winding structure being wound around by optical fiber cable 112, all in protection domain of the present utility model, is not limited to the multiple columns 107 in the present embodiment.

In order to realize being relatively fixed between optical transceiver module assembly 109 and rotating disk 106, rotating disk 106 is provided with the groove 110 of upper end open, optical transceiver module assembly 109 is then embedded in groove 110, and the optical transceiver module assembly 109 after embedding is lower than the upper surface of rotating disk 106, so, avoiding in the process of winding optical fiber cable 112, optical transceiver module assembly 109 forms the impacts such as interference.

Specifically, groove 110 is arranged in the outside of the ring of encirclement that multiple column 107 is formed, and so, also allows for the optical fiber cable 112 after being wound around and is arranged in the outside of multiple column 107.

Certainly, the formation of above-mentioned groove 110, it is possible to arrange according to the shape of optical transceiver module assembly 109, be not limited to the shape in the present embodiment.Certainly, so that optical transceiver module assembly 109 is fixed in rotating disk 106, it would however also be possible to employ optical transceiver module assembly 109 is attached fixing by screw etc..

In the present embodiment, winding arrangement includes connecting axle 113, and this connection axle 113 is fixedly connected on the lower end of rotating disk 106；Dynamical element is motor 108, and motor 108 is arranged in the lower section of rotating disk 106, and the rotating shaft 116 of motor 108 be connected between axle 113 and connected by shaft coupling 105, so, the rotating shaft 116 of motor 108 rotates, by the linkage of shaft coupling 105, drive connection axle 113 to rotate, and then drive rotating disk 106 to rotate.

Certainly, as other embodiments, it is also possible to be placed in, either directly through the rotating shaft 116 of motor 108, the lower end being connected to rotating disk 106, and then directly drive rotating disk 106 to rotate, concrete setting is determined by being actually needed.It addition, as required, motor 108 can be polytype motor 108.

In the present embodiment, winding arrangement includes the first installing rack 102, this the first installing rack 102 is positioned at the lower section of rotating disk 106, motor 108 is arranged in the first installing rack 102, and first installing rack 102 upper end there is through hole 1023, the rotating shaft 116 of motor 108 then directly through this through hole 1023, extends to the top of the first installing rack 102, and is connected with shaft coupling 105.

Specifically, first installing rack 102 includes two first side plates 1022 and the first top boards 1021, two the first side plates 1022 are formed in the both sides of motor 108, first top board 1021 is positioned at the top of motor 108, and it being connected to the upper end of two the first side plates 1022, above-mentioned through hole 1023 is formed in the first top board 1021.

Certainly, the structure of the first installing rack 102 arranges and in a variety of forms, can not only limit concrete structure in the present embodiment.

In the present embodiment, winding arrangement includes the second installing rack 103, this second installing rack 103 is placed in the top of the first installing rack 102, and the upper end of this second installing rack 103 is provided with installing hole 1033, this installing hole 1033 is provided with bearing 114, above-mentioned rotating shaft 116 is plugged in bearing 114, coordinates with bearing 114, and is connected with shaft coupling 105.So so that motor 108 can drive rotating disk 106 to rotate more smoothly, it is to avoid occur rotating the phenomenon of vibration.

Specifically, the second installing rack 103 includes two second side plates 1032 and the second top boards 1031, and two the second side plates 1032 are formed on the first top board 1021, and shaft coupling 105 is placed between two the second side plates 1032；Second top board 1031 is positioned at the lower section of rotating disk 106, and is connected to the upper end of two the second side plates 1032, and above-mentioned installing hole 1033 is formed in the second top board 1031.

Certainly, the structure of the second installing rack 103 arranges and in a variety of forms, can not only limit concrete structure in the present embodiment.

In the present embodiment, helical pitch structure includes support 117 and two helical pitch sticks 105, and two helical pitch sticks 105 are placed on support 117, two helical pitch stick 105 intervals in opposite directions are arranged, and extend layout towards rotating disk 106, so, above-mentioned helical pitch groove bar 100 is then defined between two helical pitch sticks 105.

Specifically, so that adapter 111 is mobile more steady in helical pitch groove bar 100, support 117 is provided with surface plate 104, and two above-mentioned helical pitch sticks 105 are then placed on surface plate 104, forms the helical pitch groove bar 100 that bottom is smooth.Or, as other embodiments, this helical pitch groove bar 100 can also be formed in surface plate 104.

It addition, for the movement of better guiding fiber cable 112, helical pitch groove bar 100 is vertical bar shape towards one end of rotating disk 106, and size is slightly larger than the width of optical fiber cable 112, so, it is to avoid optical fiber cable 112, in the process of movement, excessive vibration occurs.

Moving and laying for the ease of automatic coiling device, in the present embodiment, automatic coiling device includes base plate, above-mentioned winding arrangement and helical pitch structure and is then separately fixed on base plate.

The foregoing is only preferred embodiment of the present utility model, not in order to limit this utility model, all any amendment, equivalent replacement and improvement etc. made within spirit of the present utility model and principle, should be included within protection domain of the present utility model.

Claims (10)

1. automatic coiling device, it is characterised in that for being wound around the optical fiber cable between optical transceiver module assembly and adapter, including winding arrangement and helical pitch structure；Described winding arrangement has by dynamical element driving rotation and the rotating disk for optical transceiver module assembly fixed placement, and described rotating disk is provided with the winding structure for winding optical fiber cable；Described helical pitch structure has and is arranged in outside described rotating disk and for placing the helical pitch groove bar of adapter, and the end of described helical pitch groove bar has opening, and the opening of described helical pitch groove bar is arranged towards described rotating disk.

2. automatic coiling device as claimed in claim 1, it is characterised in that described winding structure includes multiple column being arranged on described rotating disk, and multiple described columns are arranged in around shape.

3. automatic coiling device as claimed in claim 1, it is characterised in that being provided with upper end open and the groove for fixed placement optical transceiver module assembly in described rotating disk, described groove is positioned at the outside of described winding structure.

4. the automatic coiling device as described in any one of claims 1 to 3, it is characterized in that, described winding arrangement includes connecting axle, described connection axle is fixedly connected on the lower end of described rotating disk, described dynamical element is motor, described motor is positioned at the lower section of described rotating disk, and the rotating shaft of described motor be connected between axle and connected by shaft coupling.

5. automatic coiling device as claimed in claim 4, it is characterized in that, described winding arrangement includes the first installing rack being positioned at below described rotating disk, the upper end of described first installing rack has through hole, described motor is placed in described first installing rack, and the through hole of rotating shaft described first installing rack of traverse of described motor.

6. automatic coiling device as claimed in claim 5, it is characterized in that, described winding arrangement includes the second installing rack being located on described first installing rack, has installing hole in the upper end of described second installing rack, described installation in card is provided with bearing, and described connection axle is plugged in described bearing.

7. the automatic coiling device as described in any one of claims 1 to 3, it is characterized in that, described helical pitch structure includes support and two helical pitch sticks arranged on the bracket, two helical pitch stick intervals in opposite directions are arranged, and extending layout towards described rotating disk, described helical pitch groove bar is formed between two described helical pitch sticks.

8. automatic coiling device as claimed in claim 7, it is characterised in that described support is provided with surface plate, and two described helical pitch sticks are arranged on described surface plate.

9. automatic coiling device as claimed in claim 7, it is characterised in that described helical pitch groove bar is vertical bar shape towards one end of described rotating disk.

10. the automatic coiling device as described in any one of claims 1 to 3, it is characterised in that described automatic coiling device includes base plate, described winding arrangement and helical pitch structure and is arranged on described base plate.