CN113067197A - Pin of light emission component adds electric frock - Google Patents

Abstract

The application discloses a pin power-up tool of a light emitting assembly, which comprises a tool plug, a power-up tool and a power-up module, wherein the tool plug is used for inserting the pin of the light emitting assembly into the power-up tool; the tool plug comprises a plurality of jacks, the arrangement mode of the jacks corresponds to the arrangement mode of the pins of the light emitting assembly, and the pins of the light emitting assembly are inserted into the tool plug; the jack comprises a hole with a larger hole diameter and a hole with a smaller hole diameter, the hole with the larger hole diameter is used for guiding the pin of the light emitting component to be inserted into the jack, and the hole with the smaller hole diameter is used for clamping the pin of the light emitting component. In this application, the jack includes the great hole in a aperture and the less hole in an aperture, has increased and has been used for the male jack size of pin, and the jack of frock plug is aimed at to the pin of the light emission subassembly of being convenient for, has improved the difficult problem of pin plug of light emission subassembly.

Description

Pin of light emission component adds electric frock

Technical Field

The application relates to the technical field of optical fiber communication, in particular to a pin power-on tool of a light emitting assembly.

Background

In the optical communication industry, a light emitting module is used as one of core parts of an optical module, and a test procedure and a coupling procedure of the light emitting module need to power up a power-up tool.

The current power-up mode generally adopts a pin power-up mode. The pin power-on mode is to insert the pin of the light emitting component into a tool plug of the test tool and utilize the pin of the light emitting component to power on. Because the pin of the light emitting component is very thin, and the aperture size of the jack of the tool plug is very small, the pin of the light emitting component is difficult to be completely aligned with the jack of the tool plug, so that the pin of the light emitting component is difficult to plug and pull.

Disclosure of Invention

The application provides a pin of optical transmission subassembly adds electric frock, and the jack of frock plug is aimed at entirely to optical transmission subassembly's pin, makes things convenient for optical transmission subassembly's pin plug.

The utility model provides a pin of light emission subassembly adds electric frock, includes the frock plug, wherein:

the tool plug is used for inserting the pin of the light emitting component into the power-on tool;

the tool plug comprises a plurality of jacks, the arrangement mode of the jacks corresponds to the arrangement mode of the pins of the light emitting assembly, and the pins of the light emitting assembly are inserted into the tool plug;

the jack comprises a hole with a larger hole diameter and a hole with a smaller hole diameter, the hole with the larger hole diameter is used for guiding the pin of the light emitting component to be inserted into the jack, and the hole with the smaller hole diameter is used for clamping the pin of the light emitting component.

The application provides a pin of light emission subassembly adds electric frock, including the frock plug, the frock plug is used for the pin of light emission subassembly to insert and adds electric frock. The tool plug comprises a plurality of jacks, the arrangement mode of the jacks corresponds to the arrangement mode of the pins of the light emission assembly, and the pins of the light emission assembly are inserted into the tool plug. Due to the small size of the jack, the pins are difficult to align completely, and plugging and unplugging are difficult. To solve this problem, the socket includes a hole with a larger diameter for guiding the pin of the light emitting module to be inserted into the socket and a hole with a smaller diameter for holding the pin of the light emitting module. In this application, the jack includes the great hole in a aperture and the less hole in an aperture, has increased and has been used for the male jack size of pin, and the jack of frock plug is aimed at to the pin of the light emission subassembly of being convenient for, has improved the difficult problem of pin plug of light emission subassembly.

Drawings

In order to more clearly explain the technical solution of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious to those skilled in the art that other drawings can be obtained according to the drawings without any creative effort.

Fig. 1 is a schematic structural diagram of a pin powering-up tool of an optical transmission assembly provided in an embodiment of the present application;

fig. 2 is an exploded schematic view of a pin power-on tool of an optical transmission assembly according to an embodiment of the present disclosure;

fig. 3 is a schematic structural diagram of a tool plug provided in an embodiment of the present application;

fig. 4 is a cross-sectional view of a tooling plug provided in an embodiment of the present application;

fig. 5 is a schematic structural diagram of a light emitting assembly provided in an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Fig. 1 is a schematic structural diagram of a pin power-up tool of an optical transmission assembly provided in the present application, and fig. 2 is a schematic exploded structural diagram of the pin power-up tool of the optical transmission assembly provided in the present application. As shown in fig. 1 and 2, the power-on tool provided by the present application includes a tool plug 100, a light emitting assembly 200, and a limit plate 300.

The tool plug 100 is fixed to the machining tool through the limiting plate 300. Specifically, the limiting plate 300 is fixed on the electrician, the limiting plate 300 includes a bottom plate 301 and a side plate 302, and the side plate 302 is fixed on one side of the bottom plate 301. The bottom plate 301 and the side plate 302 of the stopper plate 300 fix the tool plug 100 to the machining equipment.

The light emitting assembly 200 is inserted into the tool plug 100. Specifically, the light emitting assembly 200 is provided with a plurality of pins 201, and the plurality of pins 201 are used for being inserted into the tool plug 100. The tool plug 100 is provided with a plurality of jacks 104.

The arrangement of the plurality of sockets 104 corresponds to the arrangement of the pins 201 of the light emitting assembly 200. Specifically, when the pins 201 are located in the same row of the light emitting assembly 200, the sockets 104 are located in the same row of the tooling plug 100, the number of the pins 201 is equal to the number of the sockets 104, and the positions of the pins 201 correspond to the positions of the sockets 104. When the pins 201 are located in multiple rows of the light emitting assembly 200, the plurality of sockets 104 of the tool plug 100 are located in multiple rows of the tool plug 100, the number of the pins 201 in the same row of the light emitting assembly 200 is the same as the number of the sockets 104 in the same row of the tool plug 100, and the positions of the pins 201 correspond to the positions of the sockets 104. For example, 9 pins 201 are located in two rows of the light emitting assembly 200, the number of pins 201 located in the first row of the light emitting assembly 200 is 5, the number of pins 201 located in the second row of the light emitting assembly 200 is 4, and a vacancy exists between the middle two pins 201 in the four pins 201 located in the second row of the light emitting assembly 200, then, among the 9 jacks 104 of the tooling plug 100, the number of jacks 104 located in the first row of the tooling plug 100 is 5, the number of jacks 104 located in the second row of the tooling plug 100 is 4, and a vacancy exists between the middle two jacks 104 in the four jacks 104 in the second row.

Fig. 3 is a schematic structural diagram of a plug assembly according to an embodiment of the present disclosure. As shown in fig. 3, the tooling plug 100 includes a fixing plate 101 and two protrusions 102, the two protrusions 102 are respectively located at one end of the fixing plate 101, the two protrusions 102 and the fixing plate 101 are integrally formed, a side surface of one protrusion 102 of the tooling plug 100 includes a plurality of insertion surfaces 103, and each insertion surface 103 is provided with a plurality of insertion holes 104.

The receptacle 104 is a flared hole. Specifically, the insertion hole 104 includes a hole with a larger diameter for guiding the pin 201 of the light emitting module 200 to be inserted into the insertion hole 104 and a hole with a smaller diameter for holding the pin 201 of the light emitting module 200 in the insertion hole 104. The larger-diameter holes are used for guiding the pins 201 of the light emitting component 200 to be inserted into the jacks 104, so that the size of the jacks 104 for inserting the pins 201 is increased, and the pins 201 of the light emitting component 200 are aligned to be inserted into the jacks 104.

A step-shaped transition surface is arranged between the hole with the larger aperture and the hole with the smaller aperture, and the step-shaped transition surface is used for guiding the pin 201 of the light emitting component 200 to slide from the hole with the larger aperture to the hole with the smaller aperture. Specifically, when the pins 201 of the light emitting assembly 200 are straight, the stepped transition surface may also guide the pins 201 to slide from a larger hole to a smaller hole.

There may also be a smooth transition between the larger and smaller apertures for guiding the pins 201 of the light emitting assembly 200 to slide from the larger aperture to the smaller aperture. Specifically, the shape of the receptacle 104 is flared when there is a smooth transition between the larger and smaller apertures. When the pin 201 of the light emitting assembly 200 is not straightened, the smooth transition surface can facilitate the pin 201 to smoothly slide from the hole with the larger aperture to the hole with the smaller aperture, so that the contact between the transition surface and the pin 201 is reduced, and the pin 201 is prevented from being folded.

The generatrix of the receptacle 104 makes an angle of 30 with the central axis of the receptacle. Specifically, when the included angle between the generatrix of the jack 104 and the central axis of the jack 104 is 0 ° to 30 °, the hole with a larger aperture in the jack 104 is smaller. At this time, the pins 201 of the light emitting module 200 are inserted into the insertion holes 104, the view is obstructed, and the pins 201 of the light emitting module 200 are not easily aligned with the insertion holes 104, which easily causes the pins 201 of the light emitting module 200 to be folded. When the included angle between the generatrix of the insertion hole 104 and the central axis of the insertion hole exceeds 60 °, and the depth of the insertion hole 104 is not changed, the hole with a larger diameter in the insertion hole 104 is larger, and the pins 201 of the light emitting module 200 are easily aligned with the insertion hole 104, but the pins 201 of the light emitting module 200 are easily folded when inserted into the insertion hole 104. Therefore, when the included angle between the generatrix of the jack 104 and the central axis of the jack is 30 ° to 60 °, the hole with larger aperture in the jack 104 is moderate, and the pins 201 of the light emitting assembly 200 are relatively easy to be aligned with the jack 104 completely. As the included angle between the generatrix of the jack 104 and the central axis of the jack 104 gradually increases, and the hole with larger bore diameter in the jack 104 gradually increases, the pins 201 of the light emitting assembly 200 are more easily aligned with the jack 104, but the pins 201 of the light emitting assembly 200 are easily crushed when being inserted into the jack 104. Therefore, when the included angle between the generatrix of the jack 104 and the central axis of the jack 104 is 30 °, the size of the jack 104 is moderate, and the pins 201 of the light emitting module 200 are easily inserted into the jack 104 in a full alignment manner, so that the pins 201 of the light emitting module 200 are not easily folded.

The distance between the center points of two adjacent insertion holes 104 is equal to the sum of the hole radii of the two adjacent insertion holes 104 with larger hole diameters. Specifically, when the distance between the center points of two adjacent insertion holes 104 is equal to the sum of the radii of the holes with larger diameters in the two adjacent insertion holes 104, the radius of the hole with larger diameter in the insertion hole 104 reaches the maximum without affecting the adjacent insertion holes 104. The radius of the hole with the larger diameter in the insertion hole 104 reaches the maximum, and the tolerance before the pins 201 of the light emitting assembly 200 are inserted is increased, so that mutual noninterference among the pins 201 is ensured, and the short circuit of the pins 201 is prevented.

The depth of the receptacles 104 is increased to maximize the radius of the larger bore of two adjacent receptacles 104. Specifically, when the included angle between the generatrix of the plug hole 104 and the central axis of the plug hole 104 is fixed, and under other conditions, the distance between the center points of two adjacent plug holes 104 is fixed, and the distance between the center points of two adjacent plug holes 104 may be greater than or equal to the sum of the radii of the holes with larger diameters in the two adjacent plug holes 104. When the distance between the center points of two adjacent insertion holes 104 is equal to the sum of the radii of the holes with larger diameters in two adjacent insertion holes 104, the radius of the hole with larger diameter in two adjacent insertion holes 104 reaches the maximum, that is, two adjacent insertion holes 104 are tangent. In order not to change the included angle between the generatrix of the insertion hole 104 and the central axis of the insertion hole 104, the radius of the hole with larger diameter in two adjacent insertion holes 104 can be maximized as much as possible by increasing the depth of the insertion holes 104.

Two adjacent jacks 104 are divided into two cases, in each case, with different explanations.

In the first case: when no vacant space exists among the plurality of jacks 104 of the tool plug 100, any one jack 104 and jack 104A close to both sides of the jack 104A are two adjacent jacks 104.

In the second case: when empty spaces B exist among the plurality of insertion holes 104 of the tool plug 100, the adjacent two insertion holes 104 do not include two insertion holes 104 on both sides of the empty spaces, but include only any two insertion holes 104 on one side of the empty spaces B.

For example, when the jacks 104 of the tooling plug 100 are divided into two rows, the number of the jacks 104 in the first row is 5, the number of the jacks 104 in the second row is 4, there is no empty space between five jacks 104 in the first row, there is an empty space between two jacks 104 on the left side and two jacks 104 on the right side in the second row, and the empty space is the same as the position of the middle jack 104 in the first row. Any two adjacent jacks 104 in the first row are both two adjacent jacks 104, and any two adjacent jacks 104 in the second row include only the left two jacks 104 or the right two jacks 104.

The side of the boss 102 where the insertion surface 103 is located also includes a mesa 105. Specifically, the insertion surface 103 is perpendicular to the mesa 105, the mesa 105 is provided with a plurality of guide grooves 106, the plurality of guide grooves 106 correspond to the plurality of insertion holes 104, the guide grooves 106 are provided at the edge of the hole with a larger hole diameter in the flared hole, and the guide grooves 106 are used for inserting the plurality of pins 201 of the light emitting assembly 200 into the insertion holes 104 from a plurality of directions.

The insertion hole 104 provided on the insertion surface 103 corresponds to the guide groove 106 provided on the table surface 105. Specifically, when the insertion holes 104 are located in a row of the tool plug 100, one insertion surface 103 is provided on which the insertion holes 104 are located, and one land 105 is provided on which the guide grooves 106 are located. When the insertion holes 104 are located in multiple rows of the tool plug 100, there are multiple insertion surfaces 103 on which the insertion holes 104 are arranged, multiple table surfaces 105 on which the guide grooves 106 are arranged, the multiple table surfaces 105 are stepped, and the side surface of the upper table surface 105 is the insertion surface 103 corresponding to the lower table surface 105. For example, when the insertion holes 104 are located in two rows of the tool plug 100, there are 2 insertion surfaces 103 on which the insertion holes 104 are provided, and 2 lands 105 on which the guide grooves 106 are provided, the two lands 105 are stepped, and the side surface of the second step land 105 is the insertion surface 103 corresponding to the first step land 105. The stepped mesa 105 prevents interference between the upper and lower rows of pins 201 as much as possible, reducing error accumulation.

The guide groove 106 is used for inserting the plurality of pins 201 of the light emitting module 200 into the receptacle 104 from a plurality of directions. Specifically, the guide groove 106 is connected to a hole having a larger diameter in the bell-mouth, and the plurality of pins 201 of the light emitting module 200 are inserted into the hole having a larger diameter in the bell-mouth along the guide groove 106, and further inserted into the hole having a smaller diameter in the bell-mouth. After the guide groove 106 is added, the pins 201 can be inserted obliquely, so that the pins 201 can be led into the power-on holes along the guide groove 106 more quickly.

The guide groove 106 is a semicircular guide groove, which is convenient for reducing the friction between the pin 201 of the light emitting assembly 200 and the guide groove 106, and further reducing the buckling of the pin 201 of the light emitting assembly 200.

Fig. 4 is a cross-sectional view of a tool plug according to an embodiment of the present application. As shown in fig. 3 and 4, the tooling plug 100 provided in the embodiment of the present application further includes a bent conductive tube 107.

The bent conductive tube 107 is disposed in the tool plug 100, and the pin 201 of the light emitting assembly 200 is connected to the bent conductive tube 107. Specifically, the conductive pipe provided with a bend at the middle position of the pipe is a bent conductive pipe 107. One end of the bent conductive tube 107 traverses one convex body 102 without the insertion surface 103 and the table surface 105; the other end of the bent conductive tube 107 traverses a convex body 102 provided with an insertion surface 103 and a table surface 105 and is connected with an insertion jack 104; the angle between the bent conductive tube 107 between the two convex bodies 102 and the horizontal plane is 20-30 deg. The bending degree of the bent conductive pipe 107 is 120-140 degrees.

The conductive tube has a diameter larger than that of the pin 201 for insertion of the pin 201. When the conductive tube is a straight tube, the pin 201 is inserted into the conductive tube, and the pin 201 cannot be in complete contact with the conductive tube, even under an extreme condition, the pin 201 cannot be in contact with the conductive tube, so that the problem of abnormal power-up cannot be solved well. When the conductive tube is the bent conductive tube 107, the pin 201 is inserted into the bent conductive tube 107, and the pin 201 can be in complete contact with the bent conductive tube 107, so that the problem of abnormal power-on can be well solved. When the conductive tube is the bent conductive tube 107, the bent conductive tube 107 is convenient to contact with the pin 201 of the light emitting assembly 200, and the contact area between the bent conductive tube 107 and the pin 201 of the light emitting assembly 200 is increased.

Fig. 5 is a schematic structural diagram of the light emitting assembly provided in the present application, and as shown in fig. 5, in the embodiment of the present application, the light emitting assembly 200 includes a plurality of pins 201, and the plurality of pins 201 are used for connecting the light emitting assembly 200 and the tool plug 100. According to circumstances, the plurality of pins 201 of the light emitting module 200 may be arranged in one row or in a plurality of rows.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. The utility model provides a pin of light emission subassembly adds electric frock which characterized in that, includes the frock plug, wherein:

the tool plug is used for inserting the pin of the light emitting component into the power-on tool;

the tool plug comprises a plurality of jacks, the arrangement mode of the jacks corresponds to the arrangement mode of pins of the light emitting assembly, and the pins of the light emitting assembly are inserted into the tool plug;

the jack comprises a hole with a larger hole diameter and a hole with a smaller hole diameter, the hole with the larger hole diameter is used for guiding the pin of the light emitting component to be inserted into the jack, and the hole with the smaller hole diameter is used for clamping the pin of the light emitting component.

2. The power-up tool of claim 1, wherein the tool plug further comprises a guide slot, wherein:

the guide groove is arranged at the edge of the hole with the larger aperture and is used for inserting the pins of the light emitting component into the insertion holes from multiple directions.

3. The power-up tool of claim 1, wherein a smooth transition surface is formed between the larger-diameter hole and the smaller-diameter hole, and the transition surface is used for guiding the pin of the light emitting module to slide from the larger-diameter hole to the smaller-diameter hole.

4. An energized tool according to claim 1 wherein a stepped transition surface is provided between said larger bore hole and said smaller bore hole.

5. The power-up tool of claim 1, wherein an included angle between a generatrix of the receptacle and a central axis of the receptacle is 30 °.

6. The power-on tool of claim 5, wherein the distance between the center points of two adjacent insertion holes is equal to the sum of the hole radii of the two adjacent insertion holes with the larger hole radius.

7. The power-up tool of claim 2, wherein the guide groove is a semicircular guide groove.

8. The power-on tool of claim 7, wherein the tool plug further comprises a bent conductive tube, wherein:

the bent conductive tube is arranged in the tool plug and is used for connecting a pin of the light emitting assembly with the bent conductive tube;

the included angle between the bent conductive tube and the horizontal plane is 20-30 degrees.

9. The power-on tool according to claim 2, wherein the tool plug comprises an insertion surface provided with the insertion hole and a table surface provided with the guide groove, and the insertion surface is perpendicularly connected with the table surface.

10. The power-on tool according to claim 9, wherein when the plurality of table tops are provided, the plurality of table tops are stepped, and the side surface of the table top at the upper stage is an insertion surface corresponding to the table top at the lower stage.

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