CN220636903U - Optical module assembling device - Google Patents

Abstract

The utility model discloses an optical module assembling device, which comprises a base; the first station and the second station are arranged on the base; the guide rail is arranged on the upper surface of the base; the first sliding groove and the second sliding groove are respectively arranged at the first station and the second station, one end of the first sliding groove and one end of the second sliding groove are communicated with the guide rail, and the first sliding groove, the second sliding groove and the guide rail are respectively used for accommodating the first workpiece, the second workpiece and the third workpiece to slide in; and when the third workpiece in the guide rail moves to the junction of the first chute and the second chute, the two limiting mechanisms are used for limiting respectively. In the utility model, the guide rail is arranged, the third workpiece slides on the guide rail, the limiting mechanism is used for limiting the third workpiece at the intersection of the guide rail and the first chute and the intersection of the guide rail and the second chute, and the first workpiece and the third workpiece and the second workpiece and the third workpiece are assembled at the intersection, so that the assembling efficiency is greatly improved compared with the prior art.

Description

Optical module assembling device

Technical Field

The present utility model relates to an optical module assembling device.

Background

The existing SFP optical module is divided into a single-fiber module and a double-fiber module, and is subdivided into a panel, a spring, a tongue piece, a pull ring and other structures according to parts. The current manual assembly sequence is to press the spring into the panel spring slot first, then snap the tongue into the tongue slot of the panel, and then load the tab into the panel. In the prior art, all materials are assembled manually by manpower, and the assembly efficiency is low.

Disclosure of Invention

The utility model aims to provide an optical module assembling device with higher assembling efficiency.

In order to solve the above problems, the present utility model provides an optical module assembling device, comprising:

a flat plate-shaped base;

the first station and the second station are arranged on the upper surface of the base and are adjacent to each other;

a guide rail of a groove-shaped structure arranged on the upper surface of the base;

the first sliding groove and the second sliding groove are respectively arranged at the first station and the second station, one end of the first sliding groove and one end of the second sliding groove are communicated with the guide rail, and the first sliding groove, the second sliding groove and the guide rail are respectively used for accommodating a first workpiece, a second workpiece and a third workpiece to slide in;

and when the third workpiece in the guide rail moves to the junction of the first chute and the second chute, the two limiting mechanisms are used for limiting respectively.

As a further improvement of the present utility model, the limiting mechanism includes:

an opening disposed on the base;

a stopper slidable in a vertical direction within the opening, which can partially protrude out of the opening during a sliding stroke of the stopper portion.

As a further improvement of the present utility model, the limiting mechanism includes:

the positioning column is fixed in the base;

the movable block is arranged in the base in a sliding way, a sliding groove is formed in the movable block, the positioning column is positioned in the sliding groove, and the limiting block is fixed on the movable block or is of an integrated structure with the movable block;

a spring positioned in the sliding groove, wherein the spring is compressed when the movable block moves downwards;

the rotating shaft is rotatably connected to the base, the rotating shaft comprises an extending section which partially extends into the base, the extending section is provided with a cam structure, and the profile surface of the cam structure is contacted with the contact surface of the movable block below the cam structure.

As a further improvement of the utility model, the bottom of the base is provided with a supporting block through a counter bore, and the positioning column is fixedly arranged on the supporting block.

As a further improvement of the utility model, a third station and a fourth station on the upper surface of the base are provided with a first mounting groove and a second mounting groove which are communicated, and the first mounting groove is longer than the second mounting groove.

The utility model has the beneficial effects that the guide rail is arranged, the third workpiece slides on the guide rail, the limiting mechanism is used for limiting the third workpiece at the intersection of the guide rail and the first chute and the intersection of the guide rail and the second chute, and the first workpiece, the third workpiece and the second workpiece are assembled at the intersection, so that compared with the prior art, the assembly efficiency is greatly improved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of a portion of the structure of FIG. 1;

fig. 3 is a partial enlarged view at a in fig. 2.

In the figure: 200-base; 202-a first station; 204-a second station; 206-a guide rail; 208-a first chute; 210-a second chute; 211-a first workpiece; 212-a second workpiece; 214-a third workpiece; 400-limiting mechanism; 404-limiting blocks; 406-positioning columns; 408-an active block; 410-a sliding groove; 412-a spring; 414-spindle; 416-support blocks; 600-third station; 800-a fourth station; 602-a first mounting groove; 802-second mounting slot.

Detailed Description

The technical scheme of the utility model is further described below by the specific embodiments with reference to the accompanying drawings.

As shown in fig. 1-3, the present utility model includes:

a flat plate-shaped base 200;

a first station 202 and a second station 204 which are arranged on the upper surface of the base 200 and are adjacent to each other;

a guide rail 206 having a groove-like structure provided on the upper surface of the base 200;

a first chute 208 and a second chute 210 respectively disposed at the first station 202 and the second station 204, one end of the first chute 208 and one end of the second chute 210 are communicated with the guide rail 206, and the first chute 208, the second chute 210 and the guide rail 206 are respectively used for accommodating a first workpiece 211, a second workpiece 212 and a third workpiece 214 to slide therein;

at least two limiting mechanisms 400 are respectively limited by the two limiting mechanisms 400 when the third workpiece 214 in the guide rail 206 moves to the junction with the first chute 208 and the second chute 210.

As a further improvement of the present utility model, the limiting mechanism 400 includes:

an opening provided on the base 200;

a stopper 404 slidable in the vertical direction within the opening, and capable of partially protruding out of the opening during a partial sliding stroke of the stopper 404.

As a further improvement of the present utility model, the limiting mechanism 400 includes:

a positioning post 406 secured within the base;

the movable block 408 is slidably arranged in the base, a sliding groove 410 is arranged in the movable block 408, the positioning column 406 is positioned in the sliding groove 410, and the limiting block 404 is fixed on the movable block 408 or is in an integral structure with the movable block 408;

a spring 412 located in the sliding groove 410, the movable block 408 compresses the spring 412 when moving downward;

a shaft 414 rotatably connected to the base, the shaft 414 comprising an extension part extending partially into the base, the extension part being provided with a cam structure, the profile surface of which is in contact with the contact surface of the movable block 408 below the cam structure.

As a further improvement of the utility model, the bottom of the base is provided with a supporting block 416 through a counter bore, and the positioning column 406 is fixedly installed on the supporting block 416.

As a further improvement of the present utility model, a third station 600 and a fourth station 800 on the upper surface of the base 200 are provided with a first mounting groove 602 and a second mounting groove 802 which are communicated, and the first mounting groove 602 is longer than the second mounting groove 802.

The specific principle of the utility model is as follows:

(1) The third workpiece 214 (panel) moves linearly along the guide rail 206 until sliding to the intersection of the guide rail 206 and the first chute 208, and is limited by the limiting mechanism 400 at the position, specifically, the movable block 408 ejects the limiting block 404 (the limiting block 404 and the movable block 408 are of an integral structure, or of course, can be provided as a combined installation structure) under the action of the spring 412, and the limiting block 404 is clamped at the bottom of the panel when ejected, so that the limiting of the panel, namely the third workpiece 214, is realized;

(2) After the intersection of the first chute 208 and the guide rail 206 is limited, the first workpiece 211 in the first chute 208, i.e. the spring workpiece slides along the first chute 208 until the spring workpiece is clamped into the spring slot of the panel, so as to complete the first-step installation;

(3) After the first step of installation is completed, the rotating handle arranged outside the base 200 through the rotating shaft 414 rotates to drive the rotating shaft 414 to rotate, the cam structure on the rotating shaft 414 rotates along with the rotating shaft, and the movable block 408 is pressed downwards, so that the upper surface of the limiting block 404 (or the movable block 408) is lower than the upper surface of the base 200, the panel can smoothly pass through the intersection, and continuously move along the guide rail 206 until sliding to the intersection of the guide rail 206 and the second chute 210, and at the intersection, another limiting mechanism 400 is arranged for limiting, the limiting mechanism 400 has the same structure, and the working principle is completely the same (after the panel passes through the limiting mechanism 400, the rotating handle is loosened, and under the action of the spring 412, the movable block 408 moves upwards, so that the limiting block 404 or the movable block 408 protrudes out of the upper surface of the base 200);

(4) After the intersection of the second chute 210 and the guide rail 206 is limited, the second workpiece 212 in the second chute 210, i.e. the clamping tongue slides along the second chute 210 until the clamping tongue is clamped into the clamping tongue groove of the panel, so as to complete the second-step installation;

(5) After the second step of installation is completed, the limiting block 404 or the movable block 408 is moved downward by rotating the handle, so that the panel can pass through the limiting mechanism 400;

(6) Continuing to slide the panel completely off of the rail 206;

(7) The tab is installed in the first mounting slot 602 of the third station 600 and slid into the second mounting slot 802 of the fourth station 800 to complete the tab assembly.

Compared with the prior art, the utility model greatly improves the assembly efficiency and effectively solves the problems encountered in the prior art.

The technical principle of the present utility model is described above in connection with the specific embodiments. The description is made for the purpose of illustrating the general principles of the utility model and should not be taken in any way as limiting the scope of the utility model. Other embodiments of the utility model will be apparent to those skilled in the art from consideration of this specification without undue burden.

Claims (5)

1. An optical module assembling apparatus, comprising:

a flat plate-shaped base (200);

the first station (202) and the second station (204) are arranged on the upper surface of the base (200) and are adjacent to each other;

a guide rail (206) having a groove-like structure and provided on the upper surface of the base (200);

a first chute (208) and a second chute (210) respectively arranged at the first station (202) and the second station (204), wherein one end of the first chute (208) and one end of the second chute (210) are communicated with the guide rail (206), and the first chute (208), the second chute (210) and the guide rail (206) are respectively used for accommodating a first workpiece (211), a second workpiece (212) and a third workpiece (214) to slide in;

at least two limiting mechanisms (400), wherein when the third workpiece (214) in the guide rail (206) moves to the junction of the first sliding groove (208) and the second sliding groove (210), the limiting mechanisms (400) respectively limit the position.

2. An optical module assembly device according to claim 1, wherein the limit mechanism (400) comprises:

an opening provided on the base (200);

a stopper (404) capable of sliding in the vertical direction within the opening, and capable of partially protruding out of the opening during a partial sliding stroke of the stopper (404).

3. An optical module assembly device according to claim 2, wherein the limit mechanism (400) comprises:

a positioning column (406) fixed in the base (200);

the movable block (408) is arranged in the base (200) in a sliding manner, a sliding groove (410) is formed in the movable block (408), the positioning column (406) is positioned in the sliding groove (410), and the limiting block (404) is fixed on the movable block (408) or is of an integral structure with the movable block (408);

a spring (412) located in the sliding groove (410), the movable block (408) compressing the spring (412) when moving downward;

a rotating shaft (414) connected to the base (200) is rotated, the rotating shaft (414) comprises an extending section which extends into the base (200), the extending section is provided with a cam structure, and the profile surface of the cam structure is contacted with the contact surface of the movable block (408) below the cam structure.

4. A light module assembly device according to claim 3, characterized in that the bottom of the base (200) is provided with a support block (416) through a counter bore, and the positioning column (406) is fixedly mounted on the support block (416).

5. The optical module assembling device according to claim 4, wherein a third station (600) and a fourth station (800) on the upper surface of the base (200) are provided with a first mounting groove (602) and a second mounting groove (802) which are communicated, and the first mounting groove (602) is longer than the second mounting groove (802).