CN218940293U - Single-station contact pin shearing mechanism - Google Patents

Abstract

The utility model discloses a single-station contact pin shearing mechanism, which belongs to the technical field of automation and comprises a table top, wherein a rubber core shearing mechanism, a terminal shearing mechanism and a material sucking mechanism are arranged on the table top, the rubber core shearing mechanism comprises a rubber core material belt and a rubber core material channel, the terminal shearing mechanism comprises a feeding terminal and a terminal material channel, one end of the rubber core material channel is provided with a cutter, the cutter is connected to a rubber core shearing cylinder, the terminal shearing mechanism comprises a lifting cylinder positioned at one side of the terminal material channel, the lifting cylinder is connected with a clamping block for clamping the feeding terminal, one side of the clamping block is provided with a terminal cutter and a terminal shearing cylinder connected with the terminal cutter, the terminal shearing mechanism further comprises a pushing cylinder and a pushing plate for realizing a displacement function, the pushing plate conveys the sheared terminal to a preassembling position and is assembled to a rubber core, the material sucking mechanism is arranged at one side of the preassembling position, the single-station shearing and contact pin is realized, the assembling period is effectively shortened, and the cost is reduced while the efficiency is improved.

Description

Single-station contact pin shearing mechanism

Technical Field

The utility model belongs to the technical field of automation, and particularly relates to a single-station contact pin shearing mechanism.

Background

Because current rubber core and terminal need be with both follow material area separation through the manual work, perhaps adopt semi-automatization equipment to cut rubber core and terminal respectively, the rethread is artifical to be inserted the needle, and whole assembly process cycle is long, inefficiency, and is with high costs. Therefore, it is necessary to relate to a single-position pin shearing mechanism.

Disclosure of Invention

Aiming at the problems, the utility model provides the single-station contact pin shearing mechanism, which realizes single-station shearing and contact pin, effectively shortens the assembly period, improves the efficiency and reduces the cost.

In order to solve the problems, the utility model adopts the following technical scheme.

The utility model provides a simplex position contact pin shearing mechanism, includes the mesa, be provided with on the mesa and glue core shearing mechanism, terminal shearing mechanism and inhale the material mechanism, glue core shearing mechanism includes gluey core material area and supplies gluey core material area to place and remove gluey core material way, terminal shearing mechanism includes feeding terminal and supplies feeding terminal to place and remove the terminal material way, glue core material way one end is provided with the cut-off knife, and this cut-off knife is connected to gluey core shearing cylinder, terminal shearing mechanism is including being located the lifting cylinder of terminal material way one side, and this lifting cylinder is connected with the clamp piece that plays the centre gripping effect to feeding terminal, and this clamp piece one side is provided with terminal cut-off knife and is connected in the terminal shearing cylinder of terminal cut-off knife, terminal shearing mechanism is still including realizing the propelling movement cylinder and the propelling movement board of displacement function, and this propelling movement board will cut the terminal to preassemble position and assemble to gluey core, inhale material mechanism setting in position one side.

Preferably, the rubber core shearing mechanism further comprises a feeding module which is inserted into the rubber core material belt and moves, a jacking module is arranged on one side of the feeding module, and the feeding module and the jacking module are both connected with corresponding cylinders.

Preferably, the cutter comprises a fixed cutter and a movable cutter which are arranged on two sides of the rubber core material channel, wherein the upper end of the movable cutter is connected with a movable cylinder, and the lower end of the rubber core material channel is provided with a top plate and a lifting cylinder connected with the top plate.

Preferably, a feeding gear for driving the feeding terminal to move is arranged at the lower end of the terminal material channel, a motor is arranged at one side of the terminal material channel, and the feeding gear is rotationally connected to an output shaft of the motor.

Preferably, a rocker structure is arranged between the lifting cylinder and the clamping block, namely, one end of the lifting cylinder is provided with a rocker, and the other end of the rocker is connected into the clamping block.

Preferably, the material sucking mechanism comprises a transversely arranged displacement cylinder, one end of the displacement cylinder is connected with a first displacement plate, a second displacement plate is connected to the first displacement plate through a sliding rail, a lifting cylinder is connected to the second displacement plate, and a material sucking piece is arranged on the end face of the second displacement plate.

Advantageous effects

Compared with the prior art, the utility model has the beneficial effects that:

according to the utility model, the rubber core material belt and the connecting terminal are respectively fed from the rubber core shearing mechanism and the terminal shearing mechanism at the same time, the connecting terminal is moved and inserted into the rubber core after being sheared, at the moment, the rubber core shearing mechanism shears the rubber core, and the assembled product is sucked away through the material sucking mechanism to carry out the next process, so that the single-station shearing and pin inserting are realized, the assembly period is effectively shortened, the efficiency is improved, and the cost is reduced.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a single-station pin shearing mechanism.

Fig. 2 is a schematic structural diagram of a rubber core shearing mechanism of a single-station pin shearing mechanism.

Fig. 3 is a schematic diagram of a terminal shearing mechanism of a single-station pin shearing mechanism.

Fig. 4 is a schematic diagram of a terminal shearing mechanism of a single-station pin shearing mechanism.

Fig. 5 is a schematic diagram of a material sucking mechanism of a single-station pin shearing mechanism.

The correspondence between the reference numerals and the component names in the drawings is as follows:

10. a rubber core shearing mechanism; 101. a rubber core shearing cylinder; 102. a feeding module; 103. a rubber core material belt; 104. a rubber core material channel; 105. a cutter; 105a, a fixed cutter; 105b, a movable cutter; 106. a top plate; 107. a lifting cylinder; 108. a material ejection module; 109. a movable cylinder;

20. a terminal shearing mechanism; 201. a terminal material channel; 202. a connecting terminal; 203. a feed gear; 204. a terminal shearing cylinder; 205. lifting a cylinder; 206. a terminal cutter; 207. a pushing cylinder; 208. a pushing plate;

30. a material sucking mechanism; 301. a displacement cylinder; 302. a first displacement plate; 303. a second displacement plate; 304. a material absorbing member; 305. lifting cylinder.

Detailed Description

The technical solutions of the present utility model will be clearly and completely described in connection with the embodiments, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1-5, which is a schematic structural diagram of a single-station pin cutting mechanism according to a preferred embodiment of the present utility model, the single-station pin cutting mechanism includes a table surface, on which a rubber core cutting mechanism 10, a terminal cutting mechanism 20 and a suction mechanism 30 are disposed, the rubber core cutting mechanism 10 includes a rubber core material tape 103 and a rubber core material channel 104 for placing and moving the rubber core material tape 103, the terminal cutting mechanism 20 includes a feeding terminal and a terminal material channel 201 for placing and moving the feeding terminal, one end of the rubber core material channel 104 is provided with a cutter 105, the cutter 105 is connected to the rubber core cutting cylinder 101, the terminal cutting mechanism 20 includes a lifting cylinder 205 located on one side of the terminal material channel 201, the lifting cylinder 205 is connected with a clamping block for clamping the feeding terminal, one side of the clamping block is provided with a terminal cutter 206 and a terminal cutting cylinder 204 connected to the terminal cutter 206, the terminal shearing mechanism 20 further comprises a pushing cylinder 207 and a pushing plate 208 for realizing a displacement function, the pushing plate 208 is used for conveying the sheared terminal to a preassembly position and assembling the sheared terminal to a rubber core, the suction mechanism 30 is arranged on one side of the preassembly position, the rubber core material belt 103 is moved from one end of the rubber core material belt 104 to one end with the cutter 105, the connecting terminal 202 is moved from one side of the terminal material belt 201 to one end with the terminal cutter 206, the lifting cylinder 205 drives the clamping block to clamp the connecting terminal 202, the terminal shearing cylinder 204 drives the terminal cutter 206 to shear the terminal from the material belt and move the sheared terminal to the lower end of the rubber core material belt 104 (namely the preassembly position) through the pushing cylinder 207 and the pushing plate 208, at the moment, the top plate is lifted to press the terminal into the rubber core, and then the rubber core is sheared from the rubber core through the fixed cutter 105a and the movable cutter 105b, the displacement of the suction mechanism 30 sucks the assembled rubber core and terminal and sends the rubber core and terminal to the next station.

In this embodiment, the rubber core shearing mechanism 10 further includes a feeding module 102 inserted into the rubber core material belt 103 and moving, a material ejection module 108 is disposed on one side of the feeding module 102, the feeding module 102 and the material ejection module 108 are both connected with corresponding cylinders, a hook is disposed at one end of the feeding module 102, the hook stretches into the rubber core material belt 103 and drives the material belt to move, and the material ejection module 108 descends and presses to the end face of the rubber core material belt 103 under the action of the corresponding cylinders, so that the material is not easy to separate.

In this embodiment, the cutter 105 includes a fixed cutter 105a and a movable cutter 105b disposed on two sides of the rubber core material channel 104, wherein the upper end of the movable cutter 105b is connected with a movable cylinder 109, the lower end of the rubber core material channel 104 is provided with a top plate and a lifting cylinder 107 connected with the top plate, the terminal is pressed into the rubber core from the lower end of the rubber core to form an assembly, the rubber core material belt 103 drives the movable cutter 105b through the fixed cutter 105a and the movable cylinder 109, and the two cut the assembled rubber core from the material belt.

In this embodiment, a feeding gear 203 for driving the feeding terminal to move is disposed at the lower end of the terminal material channel 201, a motor is disposed at one side of the terminal material channel 201, the feeding gear 203 is rotatably connected to an output shaft of the motor, the feeding gear 203 is clamped into a gap of the feeding terminal, and the output shaft drives the feeding gear 203 to rotate and pull the feeding terminal during operation of the motor.

In this embodiment, a rocker structure is provided between the lifting cylinder 205 and the material clamping block, that is, one end of the lifting cylinder 205 is provided with a rocker, the other end of the rocker is connected into the material clamping block, two cylinders are arranged inside the material clamping block to realize that the material clamping block moves up and down along the cylinders, a bump is rotationally arranged at the lower end of the rocker, and when the lifting cylinder 205 acts, the rocker moves relative to the bump and pushes the material clamping block away, so that the material clamping block is in an open state.

In this embodiment, the material sucking mechanism 30 includes a transversely disposed displacement cylinder 301, one end of the displacement cylinder 301 is connected to a first displacement plate 302, the first displacement plate 302 is connected to a second displacement plate 303 through a sliding rail, the second displacement plate 303 is connected to a lifting cylinder 305, a material sucking member 304 is disposed on an end surface of the second displacement plate 303, and positions of the first displacement plate 302 and the second displacement plate 303 are controlled by actions of the displacement cylinder 301 and the lifting cylinder 305, so that the material sucking member 304 disposed on the second displacement plate 303 can suck a glue core, and the material sucking member 304 adopts a vacuum sucking manner.

The foregoing is a further elaboration of the present utility model in connection with the detailed description, and it is not intended that the utility model be limited to the specific embodiments shown, but rather that a number of simple deductions or substitutions be made by one of ordinary skill in the art without departing from the spirit of the utility model, should be considered as falling within the scope of the utility model as defined in the appended claims.

Claims (6)

1. A single-station contact pin shearing mechanism,

the method is characterized in that:

including the mesa, be provided with on the mesa and glue core shearing mechanism (10), terminal shearing mechanism (20) and inhale material mechanism (30), glue core shearing mechanism (10) are including gluing core material area (103) and supplying glue core material area (103) to place and remove glue core material way (104), terminal shearing mechanism (20) are including pay-off terminal and supplying the terminal material way (201) that the pay-off terminal placed and removed, glue core material way (104) one end is provided with cut-off knife (105), and this cut-off knife (105) are connected to glue core shearing cylinder (101), terminal shearing mechanism (20) are including being located lifting cylinder (205) of terminal material way (201) one side, and this lifting cylinder (205) are connected with the clamp piece that plays the centre gripping effect to the pay-off terminal, and this clamp piece one side is provided with terminal cut-off knife (206) and is connected to terminal shearing cylinder (204) of terminal cut-off knife (206), terminal shearing mechanism (20) are still including realizing the push cylinder (207) and push plate (208) of displacement function, and this push plate (208) will cut off the terminal to the position and inhale the position and set up in glue core mechanism (30) one side.

2. The single-position pin shearing mechanism as recited in claim 1 wherein: the rubber core shearing mechanism (10) further comprises a feeding module (102) which is inserted into the rubber core material belt (103) and moves, a jacking module (108) is arranged on one side of the feeding module (102), and the feeding module (102) and the jacking module (108) are connected with corresponding air cylinders.

3. The single-position pin shearing mechanism as recited in claim 1 wherein: the cutting knife (105) comprises fixed cutting knives (105 a) and movable cutting knives (105 b) which are arranged on two sides of the rubber core material channel (104), wherein the upper end of the movable cutting knife (105 b) is connected with a movable air cylinder (109), and the lower end of the rubber core material channel (104) is provided with a top plate (106) and a lifting air cylinder (107) connected with the top plate (106).

4. The single-position pin shearing mechanism as recited in claim 1 wherein: the feeding device is characterized in that a feeding gear (203) for driving the feeding terminal to move is arranged at the lower end of the terminal material channel (201), a motor is arranged on one side of the terminal material channel (201), and the feeding gear (203) is rotatably connected to an output shaft of the motor.

5. The single-position pin shearing mechanism as recited in claim 1 wherein: the lifting cylinder (205) and the clamping block are of a rocker structure, namely one end of the lifting cylinder (205) is provided with a rocker, and the other end of the rocker is connected into the clamping block.

6. The single-position pin shearing mechanism as recited in claim 1 wherein: the material sucking mechanism (30) comprises a transversely arranged displacement cylinder (301), one end of the displacement cylinder (301) is connected to a first displacement plate (302), a second displacement plate (303) is connected to the first displacement plate (302) through a sliding rail, a lifting cylinder (305) is connected to the second displacement plate (303), and a material sucking piece (304) is arranged on the end face of the second displacement plate (303).

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