CN210254609U - A quick multistation tin sticky device for skeleton PIN needle - Google Patents

Abstract

The utility model discloses a quick multistation tin sticky device for skeleton PIN needle, the on-line screen storage device comprises a base, the rigid coupling has the tin stove on the base, the top of tin stove is equipped with the bearing chamber of built-in high temperature tin water. The tin dipping device also comprises a tin cup and a tin dipping cross rod which are matched for use. The tin cup is positioned in the bearing cavity, and one side of the tin cup is provided with a first lifting assembly for driving the tin cup to move up and down. The tin dipping cross rod is positioned above the tin cup, and one side of the tin dipping cross rod is provided with a second lifting assembly used for driving the tin dipping cross rod to move up and down. The upper end of tin cup is provided with a plurality of tin grooves of getting that are used for loading high temperature tin water side by side, be equipped with a plurality of fixed chucks that are used for centre gripping skeleton PIN needle on the tin dipping horizontal pole. The utility model discloses a multistation tin sticky device has improved the tin sticky efficiency of skeleton PIN needle, has guaranteed the tin sticky quality, has avoided the potential safety hazard that the workman was scalded moreover.

Description

A quick multistation tin sticky device for skeleton PIN needle

Technical Field

The utility model relates to a tin sticky processing field especially relates to a quick multistation tin sticky device for skeleton PIN needle.

Background

Skeleton PIN needle need carry out the tin sticky operation to the PIN needle when production, and the tin sticky to the PIN needle at present generally adopts artifical mode, and artifical handheld skeleton PIN needle promptly to carry out the tin sticky in placing the tip of PIN needle in the tin stove. However, in the mode, tin dipping can be performed on only one skeleton PIN needle every time, time consumption is long when tin dipping is performed on a large scale, the tin dipping size is greatly influenced by human factors, and the tin dipping quality of a finished product is difficult to guarantee. In addition, because the tin furnace temperature is higher, the artificial tin dipping also has the potential safety hazard of being scalded.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects, the utility model aims to provide a quick multistation tin sticky device for skeleton PIN needle has improved the tin sticky efficiency of skeleton PIN needle, has guaranteed the tin sticky quality, has realized the automatic tin sticky of skeleton PIN needle through mechanical cooperation moreover, has avoided the potential safety hazard that the workman was scalded.

In order to achieve the above purpose, the utility model discloses a technical scheme is: the utility model provides a quick multistation tin sticky device for skeleton PIN needle, includes the base, the rigid coupling has the tin stove on the base, the top of tin stove is equipped with the bearing cavity of built-in high temperature tin water. The tin dipping device also comprises a tin cup and a tin dipping cross rod which are matched for use. The tin cup is positioned in the bearing cavity, and one side of the tin cup is provided with a first lifting assembly for driving the tin cup to move up and down. The tin dipping cross rod is positioned above the tin cup, and one side of the tin dipping cross rod is provided with a second lifting assembly used for driving the tin dipping cross rod to move up and down. The upper end of tin cup is provided with a plurality of tin grooves of getting that are used for loading high temperature tin water side by side, be equipped with a plurality of fixed chucks that are used for centre gripping skeleton PIN needle on the tin dipping horizontal pole.

When the tin dipping cross rod moves upwards, the tin cup moves downwards, the tin bath is taken to be immersed into high-temperature tin water in the bearing cavity, and at the moment, the framework PIN needle to be subjected to tin dipping is clamped on the fixed chuck; driving the tin dipping cross rod to move downwards, driving the tin cup to move upwards at the same time, loading high-temperature tin water into the tin taking tank and driving the tin taking tank to move upwards, and driving the framework PIN needle to move towards the tin taking tank by the fixed chuck until the end part of the framework PIN needle is immersed into the tin taking tank for tin dipping; after the tin dipping is finished, the tin dipping cross rod is driven to move upwards, the tin cup moves downwards, and at the moment, the skeleton PIN needle on the tin dipping cross rod can be taken out.

Furthermore, a slot is formed between every two adjacent tin taking grooves, and the fixed chucks correspond to the slots one to one. When the framework PIN needle is clamped on the fixed chuck through the one-to-one corresponding open slot and the fixed chuck, the PIN needle of the framework PIN needle can be placed in the tin taking groove, and the plastic column of the framework PIN needle can be positioned in the open slot; the plastic column is prevented from being scalded in the tin pick-up process by the arrangement of the groove.

Further, the first lifting assembly comprises a cylinder fixing seat fixedly connected to the base, a vertically-arranged lifting cylinder is arranged on the cylinder fixing seat, and a first linkage portion fixedly connected with the tin cup is arranged on a push rod of the lifting cylinder. The first linkage part comprises a connecting rod horizontally arranged, one end of the connecting rod is fixedly connected with the tin cup, and the other end of the connecting rod is fixedly connected with a lifting plate connected with the lifting cylinder. The lifting movement of the first linkage part is realized through the lifting cylinder, and then the lifting movement of the tin cup is realized.

Further, the cylinder fixing seat comprises a cylinder transverse plate for fixing the lifting cylinder, and one end of the cylinder transverse plate is provided with a cylinder vertical plate which forms an L-shaped structure with the cylinder transverse plate; the lifting plate is provided with a sliding block which is in sliding connection with the cylinder vertical plate. The moving direction of the lifting plate driven by the lifting cylinder is limited by the sliding connection of the lifting plate and the vertical plate of the cylinder.

Further, be equipped with on the cylinder riser with the slide rail that the slider matches, one side of slide rail is equipped with the limit stop who is used for restricting lifter plate moving range. The moving range of the lifting plate is limited by the limit stop.

Further, the second lifting assembly comprises a motor base fixedly connected to the base, a screw motor is arranged on the motor base, and a second linkage part connected with the tin-stained cross rod is sleeved on a screw of the screw motor. The lifting motion of the second linkage part is realized through the screw motor, and then the lifting motion of the tin-stained cross rod is realized.

Furthermore, one end of the tin wetting cross rod is also provided with a fine adjustment motor for driving the tin wetting cross rod to rotate. Can drive the tin sticky cross bar trace through fine setting motor and rotate, guarantee to move the in-process down, skeleton PIN needle on the tin sticky cross bar can enter into perpendicularly and get in the tin bath.

The beneficial effects of the utility model reside in that: the up-and-down movement of the tin cup is realized through the first lifting assembly, so that the tin bath is taken to load high-temperature tin water in the bearing cavity; the framework PIN needle is clamped by the fixed chuck, the vertical movement of the tin-dipping cross rod is realized by the second lifting assembly, and the framework PIN needle is immersed into the tin taking groove for tin dipping; the tin pick-up grooves and the fixed chucks are arranged to realize multi-station tin pick-up operation, so that the tin pick-up efficiency of the skeleton PIN needle is improved; the mechanical tin dipping operation is realized by matching the tin taking groove with the tin dipping cross rod, the consistency of the tin dipping size is ensured, and the tin dipping quality is further ensured; simultaneously, the tin cup is driven to move along with the tin dipping cross rod through the first lifting assembly and the second lifting assembly, workers are prevented from directly contacting the tin furnace, and the potential safety hazard that the workers are scalded during operation is avoided.

Drawings

Fig. 1 is a schematic perspective view of a skeleton PIN according to an embodiment of the present invention;

fig. 2 is a schematic perspective view of an embodiment of the present invention;

fig. 3 is a schematic perspective view of a first lifting assembly according to an embodiment of the present invention;

fig. 4 is a schematic perspective view of a second lifting assembly according to an embodiment of the present invention.

Detailed Description

The following detailed description of the preferred embodiments of the present invention will be provided in conjunction with the accompanying drawings, so as to enable those skilled in the art to more easily understand the advantages and features of the present invention, and thereby define the scope of the invention more clearly and clearly.

Examples

Referring to the attached drawing 1, the skeleton PIN in the prior art comprises a skeleton 1, wherein a plastic column 11 is arranged on the skeleton 1, and PIN PINs 12 are symmetrically arranged on two sides of the plastic column 11.

Referring to the attached drawing 2, the utility model discloses a quick multistation tin sticky device for skeleton PIN needle, including base 2, the rigid coupling has tin stove 3 on the base 2, the top of tin stove 3 is equipped with the bearing chamber 31 of built-in high temperature tin water. The tin dipping device also comprises a tin cup 4 and a tin dipping cross rod 5 which are matched for use. The tin cup 4 is positioned in the bearing cavity 31, and a first lifting assembly 6 for driving the tin cup to move up and down is arranged on one side of the tin cup. The tin dipping cross rod 5 is positioned above the tin cup 4, and one side of the tin dipping cross rod is provided with a second lifting component 7 for driving the tin dipping cross rod to move up and down. The upper end of the tin cup 4 is provided with a plurality of tin taking grooves 41 used for loading high-temperature tin water side by side, and the tin dipping cross rod 5 is provided with a plurality of fixed chucks 51 used for clamping the skeleton PIN needle.

A slot 42 is formed between each two adjacent tin taking grooves 41, and the fixed chucks 51 are located right above the slot 42 and correspond to the slots 42 one by one. When tin is stained, the plastic column 11 of the framework PIN needle is arranged in the open groove 42, and the PIN needles 12 of the framework PIN needle are respectively arranged in the two adjacent tin taking grooves 41.

When the tin dipping cross rod 5 moves upwards, the tin cup 4 moves downwards, the tin taking tank 41 is immersed into the high-temperature tin water in the bearing cavity 31, and at the moment, the skeleton PIN needle to be subjected to tin dipping is clamped on the fixed chuck 51; the tin dipping cross rod 5 is driven to move downwards, the tin cup 4 is driven to move upwards at the same time, the tin taking tank 41 is loaded with high-temperature tin water and driven to move upwards, the fixed chuck 51 drives the framework PIN needle to move towards the tin taking tank 41 until the end part of the framework PIN needle is immersed into the tin taking tank 41 for tin dipping; after the tin dipping is finished, the tin dipping cross rod 5 is driven to move upwards, the tin cup 4 moves downwards, and the skeleton PIN needle on the tin dipping cross rod 5 can be taken out at the moment.

Referring to fig. 3, the first lifting assembly 6 includes a cylinder fixing seat 61 fixedly connected to the base 2, a vertically disposed lifting cylinder 62 is disposed on the cylinder fixing seat 61, and a first linkage portion fixedly connected to the tin cup 4 is disposed on a push rod of the lifting cylinder 62. The first linkage part comprises a connecting rod 63 which is horizontally arranged, one end of the connecting rod 63 is fixedly connected with the tin cup 4, and the other end of the connecting rod 63 is fixedly connected with a lifting plate 64 connected with the lifting cylinder 62.

The cylinder fixing seat 61 comprises a cylinder transverse plate 611 for fixing the lifting cylinder 62, and one end of the cylinder transverse plate 611 is provided with a cylinder vertical plate 612 which forms an L-shaped structure with the cylinder transverse plate 611; the lifting plate 64 is provided with a sliding block which is in sliding connection with the cylinder vertical plate 612. A slide rail matched with the slide block is arranged on the cylinder vertical plate 612, and a limit stop 613 used for limiting the moving range of the lifting plate 64 is arranged on one side of the slide rail. The lifting cylinder 62 is driven, the lifting plate 64 moves, the sliding block moves along the sliding rail, the connecting rod 63 moves along with the sliding block, and then the tin cup 4 is driven to move, so that the lifting motion of the tin cup 4 is realized.

Referring to fig. 4, the second lifting assembly 7 includes a motor base 71 fixedly connected to the base 2, the motor base 71 is provided with a lead screw motor 72, and a lead screw of the lead screw motor 72 is sleeved with a second linkage portion connected to the tin-dipped cross rod 5. The second linkage part comprises a pair of connecting plates 73 sleeved at two ends of the tin pick-up cross rod 5, a linkage plate 74 connected with the lead screw motor 72 is arranged between the connecting plates 73, and a threaded through hole matched with a lead screw of the lead screw motor 72 is formed in the linkage plate 74.

The motor base 71 is further provided with guide holes positioned at two sides of the screw rod motor 72, a movable limiting guide pillar 75 is arranged in the guide holes, one end of the limiting guide pillar 75 is fixedly connected with the linkage plate 74, and the other end of the limiting guide pillar passes through the guide holes. And starting the screw rod motor 72, rotating the screw rod and driving the linkage plate 74 to move, and driving the connecting plate 73 to move along with the screw rod and driving the tin-dipped cross rod 5 to move, thereby realizing the lifting motion of the fixed chuck 51.

One end of the tin-dipping cross rod 5 is also provided with a fine adjustment motor 8 for driving the tin-dipping cross rod to rotate, and the fine adjustment motor 8 is fixedly connected to the connecting plate 73. Can drive the tin sticky horizontal pole trace through trimmer motor 8 and rotate, guarantee to move the in-process down, the tin bath 41 can be got to the frame PIN needle alignment on the tin sticky horizontal pole 5.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, so as not to limit the protection scope of the present invention, and all equivalent changes or modifications made according to the spirit of the present invention should be covered in the protection scope of the present invention.

Claims (7)

1. A rapid multi-station tin dipping device for a skeleton PIN comprises a base (2), wherein a tin furnace (3) is fixedly connected to the base (2), and the top of the tin furnace (3) is provided with a bearing cavity (31) internally provided with high-temperature tin water; the method is characterized in that: the tin dipping device also comprises a tin cup (4) and a tin dipping cross rod (5) which are matched for use; the tin cup (4) is positioned in the bearing cavity (31), and one side of the tin cup is provided with a first lifting assembly (6) for driving the tin cup to move up and down; the tin dipping cross rod (5) is positioned above the tin cup (4), and one side of the tin dipping cross rod is provided with a second lifting assembly (7) for driving the tin dipping cross rod to move up and down; the tin cup is characterized in that a plurality of tin taking grooves (41) used for loading high-temperature tin water are arranged at the upper end of the tin cup (4) side by side, and a plurality of fixed chucks (51) used for clamping the skeleton PIN needle are arranged on the tin dipping cross rod (5).

2. The wicking apparatus of claim 1, wherein: and a slot (42) is formed between every two adjacent tin taking grooves (41), and the fixed chucks (51) correspond to the slots (42) one by one.

3. The wicking apparatus of claim 1, wherein: the first lifting assembly (6) comprises a cylinder fixing seat (61) fixedly connected to the base (2), a lifting cylinder (62) vertically placed is arranged on the cylinder fixing seat (61), and a first linkage part fixedly connected with the tin cup (4) is arranged on a push rod of the lifting cylinder (62); the first linkage part comprises a connecting rod (63) which is horizontally arranged, one end of the connecting rod (63) is fixedly connected with the tin cup (4), and the other end of the connecting rod is fixedly connected with a lifting plate (64) connected with the lifting cylinder (62).

4. The wicking apparatus of claim 3, wherein: the cylinder fixing seat (61) comprises a cylinder transverse plate (611) used for fixing the lifting cylinder (62), and one end of the cylinder transverse plate (611) is provided with a cylinder vertical plate (612) which forms an L-shaped structure with the cylinder transverse plate; and the lifting plate (64) is provided with a sliding block which is in sliding connection with the cylinder vertical plate (612).

5. The wicking apparatus of claim 4, wherein: the cylinder vertical plate (612) is provided with a sliding rail matched with the sliding block, and one side of the sliding rail is provided with a limit stop (613) used for limiting the moving range of the lifting plate (64).

6. The wicking apparatus of any of claims 1-5, wherein: the second lifting assembly (7) comprises a motor base (71) fixedly connected to the base (2), a screw motor (72) is arranged on the motor base (71), and a second linkage part connected with the tin-stained cross rod (5) is sleeved on a screw of the screw motor (72).

7. The wicking apparatus of claim 1, wherein: one end of the tin-dipping cross rod (5) is also provided with a fine adjustment motor (8) for driving the tin-dipping cross rod to rotate.

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