CN221069915U - A reposition of redundant personnel transfer chain for double-screw bolt is beaten mark - Google Patents

Abstract

The utility model discloses a diversion conveyor line for stud marking, which comprises a first conveyor belt, wherein a feeding machine is arranged on one side of the first conveyor belt, two second conveyor belts parallel to the first conveyor belt are arranged at the rear end of the first conveyor belt, a push-pull mechanism is arranged at the rear end of the first conveyor belt, a plurality of conveyor slides are arranged on the side surface of the second conveyor belt, a blocking mechanism for blocking and stopping studs and a pushing mechanism for pushing the studs to the conveyor slides are arranged at the joint of each conveyor slide and the second conveyor belt, and an automatic marking machine is arranged at the rear end of each conveyor slide; according to the scheme, through the cooperation of the feeding machine, the first conveying belt, the two second conveying belts and the plurality of conveying slideways, the studs are respectively conveyed to the plurality of automatic marking machines to be marked simultaneously, so that marking efficiency of the studs is increased exponentially, and the studs are prevented from being blocked on a conveying line due to the fact that the conveying line is single in structure and the marking speed of the automatic marking machines is low.

Description

A reposition of redundant personnel transfer chain for double-screw bolt is beaten mark

Technical Field

The utility model relates to the technical field, in particular to a split-flow conveying line for stud marking.

Background

The stud is also called a stud bolt, is cylindrical, has a section of thread at two ends and is not provided with a head, one end of the stud bolt is screwed into a part with an internal threaded hole, the other end of the stud bolt penetrates through the part with the through hole, and then a nut is screwed, so that the two parts can be fastened and connected into a whole through the stud bolt; in the production and processing process of the stud, the stud needs to be marked so as to be convenient for identifying parameters such as the size of the stud.

At present, a stud is conveyed to a conveying line through a feeding machine, and then conveyed to an automatic marking machine through a conveying line for marking one by one, but due to the fact that the conveying line is single in structure, single-line conveying can only be achieved, and when the automatic marking machine is used for marking the stud one by one, a certain pause time is needed, the conveying speed of the conveying line on the stud is extremely higher than the marking speed of the automatic marking machine on the stud, and therefore marking efficiency of the stud is low.

Disclosure of utility model

Aiming at the defects in the prior art, the utility model provides a diversion conveying line for stud marking, which solves the problem of low stud marking efficiency caused by single conveying line structure.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

The utility model provides a reposition of redundant personnel transfer chain for stud marking, it includes first conveyer belt, one side of first conveyer belt is provided with the material loading machine that is used for transporting the stud to first conveyer belt, the rear end of first conveyer belt is provided with two second conveyer belts rather than parallel, and the rear end of first conveyer belt is provided with the push-pull mechanism that shunts the stud on the first conveyer belt to two second conveyer belts in turn, the side of second conveyer belt is provided with a plurality of transport slide, and the department of handing-over of every transport slide and second conveyer belt all is provided with the stop mechanism that is used for stopping the stud and is used for pushing away the stud to the pushing mechanism of transport slide, the rear end of a plurality of transport slide all is provided with automatic marking machine.

Further, the two sides of the rear end of the first conveying belt are respectively and smoothly connected with one sides of the front ends of the two second conveying belts through horizontal plates, a first baffle is arranged at the rear end of the first conveying belt, the push-pull mechanism comprises a first telescopic cylinder with a horizontal telescopic direction and vertical to the conveying direction of the first conveying belt, a push-pull plate is arranged at the telescopic end of the first telescopic cylinder, and the telescopic part of the first telescopic cylinder is located above the stud on the first conveying belt.

Further, a pressure sensor is arranged on the first baffle, and the pressure sensor and the first telescopic cylinder are electrically connected with the controller.

Further, the blocking mechanism comprises a second telescopic cylinder with a telescopic direction vertically downward, a second baffle is arranged at the telescopic end of the second telescopic cylinder, and the second baffle is located above the second conveying belt.

Further, the pushing mechanism comprises a third telescopic cylinder with a horizontal telescopic direction and vertical to the conveying direction of the second conveying belt, a pushing plate is arranged at the telescopic end of the third telescopic cylinder, and the pushing plate and the front end of the conveying slideway are respectively located on two sides of the second conveying belt.

Further, be provided with laser sensor on the push pedal, laser sensor, flexible jar of second and flexible jar of third all are connected with the controller electricity, and are connected through the response counter electricity between laser sensor and the controller.

Further, limit baffles are arranged on two sides of the first conveying belt and the second conveying belt.

The beneficial effects of the utility model are as follows:

1. According to the scheme, through the cooperation of the feeding machine, the first conveying belt, the two second conveying belts and the plurality of conveying slideways, the studs are respectively conveyed to the plurality of automatic marking machines to be marked simultaneously, so that marking efficiency of the studs is increased exponentially, and the studs are prevented from being blocked on a conveying line due to the fact that the conveying line is single in structure and the marking speed of the automatic marking machines is low.

2. When the stud is driven by the first conveying belt to contact the first baffle, the pressure sensor sends a signal, the controller drives the first telescopic cylinder to perform one-time extension or contraction action, when the first telescopic cylinder performs extension action, the front end of the push-pull plate can push the stud and enable the stud to roll onto the second conveying belt, and when the first telescopic cylinder performs contraction action, the rear end of the push-pull plate can pull the stud and enable the stud to roll onto the other second conveying belt, so that the stud on the first conveying belt is alternately shunted onto the two second conveying belts, and a certain distance exists between two adjacent studs on the second conveying belt.

3. When the laser sensor senses that the stud passes through the second conveyor belt, the laser sensor sends a signal, the controller drives the second telescopic cylinder to extend, the second baffle descends and blocks the stud, the pushing plate pushes the stud to roll into the conveying slideway through the extension of the third telescopic cylinder, and finally the automatic marking machine is used for automatically marking the stud.

4. The laser sensor is electrically connected with the induction counter, so that the laser sensor can trigger signals for a plurality of times, and after the signals reach the count times of the induction counter, the controller drives the second telescopic cylinder and the third telescopic cylinder to act, and the stud is pushed into the conveying slideway; and each time the laser sensor triggers a signal, the stud passes through, so that the stud can be shunted into each conveying slideway from the front end to the rear end on the second conveying belt, and the studs can be marked simultaneously by a plurality of automatic marking machines.

Drawings

Fig. 1 is a top view of a shunt conveying line for stud marking according to the scheme.

Fig. 2 is a top view of the stud of fig. 1 in transit.

Fig. 3 is a side view of the blocking mechanism.

The automatic marking machine comprises a first conveying belt, a feeding machine, a second conveying belt, a conveying slideway, a 5 automatic marking machine, a 6 horizontal plate, a 7 first baffle, a 8 first telescopic cylinder, a 9 push-pull plate, a 10 second telescopic cylinder, a 11 second baffle, a 12 third telescopic cylinder, a 13 push-pull plate, a 14 limit baffle, a 15 stud and a 10 second telescopic cylinder.

Detailed Description

The following description of the embodiments of the present utility model is provided to facilitate understanding of the present utility model by those skilled in the art, but it should be understood that the present utility model is not limited to the scope of the embodiments, and all the utility models which make use of the inventive concept are protected by the spirit and scope of the present utility model as defined and defined in the appended claims to those skilled in the art.

Example 1

As shown in fig. 1 to 3, the diversion conveyor line for stud marking in this scheme includes a first conveyor belt 1, one side of the first conveyor belt 1 is provided with a feeder 2 for conveying studs 15 to the first conveyor belt 1 in a line, two second conveyor belts 3 parallel to the first conveyor belt 1 are arranged on two sides of the rear end of the first conveyor belt 1, two sides of the rear end of the first conveyor belt 1 are respectively and smoothly connected with one sides of the front ends of the two second conveyor belts 3 through horizontal plates 6, the rear end of the first conveyor belt 1 is provided with a push-pull mechanism for alternately diverting studs 15 on the first conveyor belt 1 to the two second conveyor belts 3, two conveyor slides 4 are arranged on the side surfaces of the second conveyor belt 3, a blocking mechanism for blocking the studs 15 and a pushing mechanism for pushing the studs 15 to the conveyor slides 4 are arranged at the joint of each conveyor slide 4, automatic marking machines 5 are arranged on the rear ends of the four conveyor slides 4, and limit baffles 14 are arranged on the two sides of the first conveyor belt 1 and the second conveyor belt 3.

According to the scheme, through the cooperation of the feeding machine 2, the first conveying belt 1, the two second conveying belts 3 and the four conveying slide ways 4, the studs 15 are respectively conveyed to the four automatic marking machines 5 for simultaneous marking, so that marking efficiency of the studs 15 is increased exponentially, and the studs 15 are prevented from being blocked on a conveying line due to the fact that the conveying line is single in structure and the automatic marking machines 5 are slow in marking speed.

Example 2

The embodiment provides a specific scheme of a push-pull mechanism on the basis of embodiment 1, wherein the push-pull mechanism comprises a first telescopic cylinder 8 with a horizontal telescopic direction and vertical to the conveying direction of a first conveying belt 1, a push-pull plate 9 is arranged at the telescopic end of the first telescopic cylinder 8, and a telescopic part of the first telescopic cylinder 8 is positioned above a stud 15 on the first conveying belt 1, so that the telescopic part of the first telescopic cylinder 8 can prevent the stud 15 from moving.

The rear end of the first conveyer belt 1 is provided with a first baffle 7, a pressure sensor is arranged on the first baffle 7, and the pressure sensor and a first telescopic cylinder 8 are electrically connected with a controller.

The technical scheme is that the studs 15 on the first conveying belt 1 can be alternately split onto the two second conveying belts 3 through the push-pull mechanism, specifically, when the studs 15 are driven by the first conveying belt 1 to contact the first baffle 7, the pressure sensor sends out signals, the controller drives the first telescopic cylinder 8 to perform one-time extending or contracting action, when the first telescopic cylinder 8 performs the extending action, the front end of the push-pull plate 9 can push the studs 15 and enable the studs 15 to roll onto the second conveying belts 3, and when the first telescopic cylinder 8 performs the contracting action, the rear end of the push-pull plate 9 can pull the studs 15 and enable the studs 15 to roll onto the other second conveying belt 3, so that the studs 15 are alternately split, and a certain distance exists between two adjacent studs 15 on the second conveying belt 3.

Example 3

The embodiment provides a specific scheme of a blocking mechanism and a pushing mechanism on the basis of embodiment 1, wherein the blocking mechanism comprises a second telescopic cylinder 10 with a telescopic direction vertically downward, a telescopic end of the second telescopic cylinder 10 is provided with a second baffle plate 11, the second baffle plate 11 is located above the second conveying belt 3, the second baffle plate 11 is flush with one side of a front port of the conveying slideway 4, and the side is located at a rear end of the second conveying belt 3.

The pushing mechanism comprises a third telescopic cylinder 12 with a horizontal telescopic direction and a vertical telescopic direction to the conveying direction of the second conveying belt 3, a pushing plate 13 is arranged at the telescopic end of the third telescopic cylinder 12, and the pushing plate 13 and the front end of the conveying slideway 4 are respectively positioned at two sides of the second conveying belt 3; the pushing plate 13 is provided with a laser sensor, the second telescopic cylinder 10 and the third telescopic cylinder 12 are electrically connected with a controller, and the laser sensor is electrically connected with the controller through an induction counter.

The working principles of the blocking mechanism and the pushing mechanism are specifically described below:

When the laser sensor senses that the stud 15 passes through the second conveyor belt 3, the laser sensor sends a signal, the controller drives the second telescopic cylinder 10 to extend, so that the second baffle 11 descends and blocks the stud 15, then the pushing plate 13 pushes the stud 15 to roll into the conveying slideway 4 through the extension of the third telescopic cylinder 12, and finally the automatic marking machine 5 automatically marks the stud 15; the laser sensor is electrically connected with the induction counter, so that the laser sensor can trigger signals for a plurality of times and can trigger the blocking mechanism and the pushing mechanism to act after the count times of the induction counter are reached, namely, the laser sensor at the front end triggers signals for two times, and then drives the second telescopic cylinder 10 and the third telescopic cylinder 12 to act through the controller, and pushes the stud 15 into the conveying slideway 4; and each time the laser sensor triggers a signal represents that one stud 15 passes through, the stud 15 can be equally divided into two conveying slide ways 4 on the second conveying belt 3, so that the studs 15 can be marked simultaneously by four automatic marking machines 5.

Claims (7)

1. The utility model provides a reposition of redundant personnel transfer chain for double-screw bolt is beaten mark, its characterized in that, including first conveyer belt, one side of first conveyer belt is provided with the material loading machine that is used for transporting the double-screw bolt to first conveyer belt, the rear end of first conveyer belt is provided with two second conveyer belts rather than parallel, and the rear end of first conveyer belt is provided with the push-pull mechanism that shunts the double-screw bolt on the first conveyer belt to two second conveyer belts in turn, the side of second conveyer belt is provided with a plurality of transport slide, and the junction of every transport slide and second conveyer belt all is provided with the barrier mechanism that is used for stopping the double-screw bolt and the pushing mechanism that is used for pushing the double-screw bolt to transport slide, a plurality of the rear end of transport slide all is provided with automatic marking machine.

2. The shunt conveying line for stud marking according to claim 1, wherein two sides of the rear end of the first conveying belt are respectively and smoothly connected with one sides of the front ends of the two second conveying belts through horizontal plates, the rear end of the first conveying belt is provided with a first baffle, the push-pull mechanism comprises a first telescopic cylinder with a horizontal telescopic direction and a vertical telescopic direction, the telescopic end of the first telescopic cylinder is provided with a push-pull plate, and the telescopic part of the first telescopic cylinder is positioned above the stud on the first conveying belt.

3. The shunt conveying line for stud marking according to claim 2, wherein a pressure sensor is arranged on the first baffle plate, and the pressure sensor and the first telescopic cylinder are electrically connected with a controller.

4. The split conveying line for stud marking according to claim 1, wherein the blocking mechanism comprises a second telescopic cylinder with a telescopic direction vertically downward, a telescopic end of the second telescopic cylinder is provided with a second baffle, and the second baffle is located above the second conveying belt.

5. The split conveying line for stud marking according to claim 4, wherein the pushing mechanism comprises a third telescopic cylinder with a horizontal telescopic direction and a vertical telescopic direction with respect to the conveying direction of the second conveying belt, a pushing plate is arranged at a telescopic end of the third telescopic cylinder, and the pushing plate and the front end of the conveying slideway are respectively located at two sides of the second conveying belt.

6. The shunt conveying line for stud marking according to claim 5, wherein a laser sensor is arranged on the pushing plate, the laser sensor, the second telescopic cylinder and the third telescopic cylinder are all electrically connected with the controller, and the laser sensor is electrically connected with the controller through an induction counter.

7. The split conveyor line for stud marking according to claim 1, wherein both sides of the first conveyor belt and the second conveyor belt are provided with limit stops.