CN210817721U - Quick milling system for miniature cross groove of connector - Google Patents

Abstract

The utility model relates to a machine-building technical field discloses a miniature cross recess of connector mills system fast. Comprises a guide type vibration disc for feeding and a milling device. The milling device comprises a positioning groove, a first radial push rod, a clamp assembly, a transverse cutting saw blade, a longitudinal cutting saw blade and a second radial push rod; the first radial push rod pushes the connector in the positioning groove to the clamp assembly. The clamp assembly can move to a first preset position; the transverse cutting saw blade can move to a first preset position along the second V-shaped guide rail so as to transversely cut the connecting head; the clamp assembly can move to a second preset position along the first V-shaped guide rail, and a longitudinal cutting saw blade is arranged at the second preset position to longitudinally cut the connector. The clamp assembly can move to a third preset position along the first V-shaped guide rail, and a second radial push rod is arranged at the third preset position so as to push the connector out of the clamp assembly. The utility model discloses can realize accurate milling to machining efficiency is high.

Description

Quick milling system for miniature cross groove of connector

Technical Field

The utility model relates to a machine-building technical field, specificly a miniature cross recess of connector mills system fast.

Background

The pressure-tight water meter glass display cover assembly is mainly used for fluid metering and monitoring of large-scale industrial equipment and civil equipment. Because these pipelines and instrument equipment all lay in the underground, and the distance is very far away from local-style dwelling houses or urban gathering areas, the data that the measurement was obtained all transmits through data line and central control integrated data center, and the timeliness and the stability of the information that transmits depend on this transmission signal route signal flow quality that obtains. If the signal flow is stable and continuous, the data acquired by the terminal is comprehensive and objective, otherwise, the data is not continuous and the gear is broken.

Three signal flow transmission ports are arranged on the water meter glass display cover component, and signal flow output from a screw inner hole fixed at the end of the meter is transmitted to the central control integrated data center through a data line by a connector inserted into the screw inner hole. In the signal transmission link, a connector for transferring a signal from the inside of glass to the outside of the glass is very critical, and the signal transmission link needs to have good conductivity and corrosion resistance, be properly matched with an inner hole of a screw and be tightly sealed with a data line end, and causes problems in signal transmission when any characteristic is not satisfied. In order to meet the requirements, an oval plug port with a cross groove and a step surface is specially designed to be matched with signal switching of an inner hole of a screw. Thus requiring cross slots to be milled into the connector.

In the prior art, when a cross groove is machined on a part, firstly, a groove in the first direction of the cross groove is milled on the part, then, a rotary table drives the part to rotate together for 90 degrees, and then, a groove in the second direction of the cross groove is milled. According to researches, the machining method is poor in stability, and the rotation angle of a part can deviate under the influence of the accuracy of the device and the machining fault. If the rotation angle of the part has errors, the milling position is not accurate, and the whole part becomes defective or is directly scrapped. And along with the increase of the service life of the processing device, the error of the rotating angle is increased continuously, the processing efficiency and the yield are influenced, and especially for the milling of some small parts, the requirement on the processing precision is higher. For milling of small parts in large production batches, it is also necessary to consider improving the machining efficiency. Research shows that the automatic feeding can greatly improve the processing efficiency, and the mechanical arm clamping is generally adopted in the prior art, so that the method can actually improve the efficiency compared with the traditional manual workpiece clamping method, but the method occupies a larger space and has a lower processing speed. Therefore, it is necessary to develop a milling system that can achieve precise milling and has high machining efficiency.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defect among the prior art, the utility model provides a miniature cross recess of connector mills system fast can realize quick material loading and mill to the accuracy of milling is high.

The utility model provides a connector micro cross groove rapid milling system, which comprises a guide type vibration disc for feeding and a milling device;

the milling device comprises a base, a specific guide rail, a positioning groove, a first radial push rod, a clamp assembly, a transverse cutting saw blade, a first V-shaped guide rail and a second V-shaped guide rail which are vertically arranged on the base, a longitudinal cutting saw blade and a second radial push rod;

the guide type vibration disc is connected with the specific guide rail, and the output end of the specific guide rail is provided with a positioning groove, so that a connector can be conveyed into the positioning groove from the guide type vibration disc along the specific guide rail to realize feeding; the first radial push rod is arranged on one side of the positioning groove so as to push the connector in the positioning groove into the clamp assembly;

the clamp assembly is arranged on the first V-shaped guide rail through a mounting plate, so that the clamp assembly can move up and down along the first V-shaped guide rail through the mounting plate; the clamp assembly can move on the mounting plate, so that the clamp assembly can move to a first preset position along the direction perpendicular to the length direction of the first V-shaped guide rail;

the second V-shaped guide rail is arranged on one side of the first V-shaped guide rail, the transverse cutting saw blade is arranged on the second V-shaped guide rail, and the transverse cutting saw blade can transversely move to the first preset position along the second V-shaped guide rail so as to transversely cut a connector in the clamp assembly which moves to the first preset position;

the clamp assembly can move to a second preset position along the length direction of the first V-shaped guide rail, and the second preset position is provided with the longitudinal cutting saw blade so as to longitudinally cut the connector after transverse cutting;

the fixture assembly can move to a third preset position along the length direction of the first V-shaped guide rail, and the third preset position is provided with the second radial push rod so as to push out the longitudinally cut connector from the fixture assembly.

Preferably, the pushing direction of the first radial push rod is not parallel to the conveying direction of the specific guide rail.

Preferably, the first preset position is provided with a positioning bolt to position the clamp assembly moving to the first preset position.

Preferably, an infrared probe is arranged in the clamp assembly, so that the fact that the connecting head enters the clamp can be sensed, and signals are transmitted to the PLC control system.

Preferably, the guide type vibration plate comprises a body, a first guide chute, a second guide chute and a third guide chute; the first material guide grooves are arranged around the outer edge of the body in a surrounding manner so as to arrange the piled connectors into a row; the second material guide groove is arranged around the outer edge of the first material guide groove in a certain inclination angle, so that the heads of the connectors can be orderly arranged outwards; one end of the third guide chute is connected with the second guide chute, and the other end of the third guide chute is connected with the milling device, so that the connector is conveyed into the milling device.

Further preferably, the inclination angle of the second material guide chute is 5-15 °.

Further preferably, the interface between the second material guiding groove and the first material guiding groove can only pass through one connector at a time.

The utility model discloses the miniature cross recess of connector mills the system fast and adopts the miniwatt, and directional removal after the low noise vibration dish vibrates the connector makes it move forward along specific track through multi-angle, the guide of multistage journey, can realize automatic quick material loading. The utility model discloses a locate the anchor clamps subassembly on first V-arrangement guide rail, make the anchor clamps subassembly can slide on first V-arrangement guide rail to the realization is to the quick aversion of connector, thereby improves the efficiency of milling. The utility model discloses a position department is equipped with positioning bolt at first predetermineeing, when anchor clamps subassembly removes to first predetermined position department, positioning bolt can fix a position the anchor clamps subassembly, makes anchor clamps subassembly stop on positioning bolt to it is accurate to make the connector location in the anchor clamps subassembly, improves the accuracy nature of milling.

In order to make the aforementioned and other objects, features and advantages of the present invention comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a front view of an embodiment of the present invention (to show the clamp assembly, the positioning slot is shown shifted to the right with respect to a particular rail position as driven by a motor);

fig. 2 is a side view in an embodiment of the invention;

fig. 3 is a left side view in an embodiment of the invention;

fig. 4 is a partial enlarged view of an embodiment of the present invention;

FIG. 5 is a schematic view of the product after the milling process is completed in the embodiment of the present invention;

reference numerals of the above figures: 1-a guide type vibration plate, 2-a base, 3-a specific guide rail, 4-a positioning groove, 5-a first radial push rod, 6-a clamp assembly, 7-a transverse cutting saw blade, 8-a first V-shaped guide rail, 9-a second V-shaped guide rail, 10-a longitudinal cutting saw blade, 11-a second radial push rod, 12-a body, 13-a first guide chute, 14-a second guide chute, 15-a third guide chute and 16-a positioning bolt.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the utility model provides a micro cross groove rapid milling system for a connector, which comprises a guide type vibration disc 1 for feeding and a milling device;

the milling device comprises a base 2, a specific guide rail 3, a positioning groove 4, a first radial push rod 5, a clamp assembly 6, a transverse cutting saw blade 7, a first V-shaped guide rail 8 and a second V-shaped guide rail 9 which are vertically arranged on the base 2, a longitudinal cutting saw blade 10 and a second radial push rod 11;

the guide type vibration disk 1 is connected with the specific guide rail 3, and the output end of the specific guide rail 3 is provided with a positioning groove 4, so that a connector can be conveyed from the guide type vibration disk 1 to the positioning groove 4 along the specific guide rail 3 to realize feeding; one side of the positioning groove 4 is provided with the first radial push rod 5 so as to push the connector in the positioning groove 4 into the clamp assembly 6;

the clamp assembly 6 is arranged on the first V-shaped guide rail 8 through a mounting plate, so that the clamp assembly 6 can move up and down along the first V-shaped guide rail 8 through the mounting plate; the clamp assembly 6 can move on the mounting plate, so that the clamp assembly 6 can move to a first preset position along the direction perpendicular to the length direction of the first V-shaped guide rail 8;

the second V-shaped guide rail 9 is arranged on one side of the first V-shaped guide rail 8, the transverse cutting saw blade 7 is arranged on the second V-shaped guide rail 9, and the transverse cutting saw blade 7 can transversely move to the first preset position along the second V-shaped guide rail 9 so as to transversely cut a connector in the clamp assembly 6 which moves to the first preset position;

the clamp assembly 6 can move to a second preset position along the length direction of the first V-shaped guide rail 8, and the second preset position is provided with the longitudinal cutting saw blade 10 so as to longitudinally cut the connector after transverse cutting;

the clamp assembly 6 can move to a third preset position along the length direction of the first V-shaped guide rail 8, and the third preset position is provided with the second radial push rod 11 so as to push out the longitudinally cut connector from the clamp assembly 6.

Adopt miniwatt in this embodiment, the directional removal after the guide formula vibration dish 1 of low noise vibrates the connector, through multi-angle, the guide of multistage journey, makes the connector move along specific track forward to carry the connector to milling device.

The conveying direction of the guide type vibration plate 1 in this embodiment is substantially clockwise.

The guided vibration disk 1 includes a body 12, a first material guide chute 13, a second material guide chute 14, and a third material guide chute 15. The first material guiding chutes 13 are arranged around the outer edge of the main body 12, and when the main body 12 vibrates, the connecting heads stacked on the main body 12 can be arranged in rows along the first material guiding chutes 13.

The second material guiding chute 14 is arranged around the outer edge of the first material guiding chute 13 at a certain inclination angle. The inclination angle of the second guide chute 14 may be set to 5-15 deg.. The inclination angle of the second material guide chute 14 is set to 10 ° in this embodiment. The weight of the head part of the connecting head is greater than that of the tail part of the connecting head, and the connecting head can follow the second material guide groove 14 inclined downwards by 10 degrees in the vibration process

The second material guide chutes 14 are formed to be arranged head-outward. The interface between the second material guiding groove 14 and the first material guiding groove 13 can only pass through one connector at a time, so that the connectors can be orderly arranged on the second material guiding groove 14.

One end of the third material guiding groove 15 is connected with the second material guiding groove 14, and the connectors in the second material guiding groove 14 can be conveyed to the third material guiding groove 15 and are closely arranged on the third material guiding groove 15. The other end of the third material guide groove 15 is connected with the specific guide rail 3, and the connector can be conveyed to the specific guide rail 3 from the third material guide groove 15, so that the guide type vibration disc 1 can automatically and quickly supply materials to the milling device, and the processing efficiency is further improved.

The output end of the specific guide rail 3 is provided with a positioning groove 4, so that the connectors can sequentially enter the positioning groove 4. The left side of the positioning groove 4 is provided with a clamp assembly 6, and the right side of the positioning groove is provided with a first radial push rod 5. The connector in the positioning slot 4 can be pushed into the clamp assembly 6 by means of a first radial push rod 5.

In this embodiment, the first radial push rod 5 is disposed in the elongated groove to limit the movement of the first radial push rod 5, thereby providing the pushing accuracy. And the elongated groove can play a good role in protecting the first radial push rod 5. The positioning groove 4 is at least partially arranged at the end part of the elongated groove, so that the first radial push rod 5 in the elongated groove can accurately enter the positioning groove 4. The two ends of the positioning groove 4 are provided with openings so that the first radial push rod 5 can enter the positioning groove 4 from one end to push out the connector from the other end. One end of the first radial push rod 5 is connected with the first driving cylinder, so that the first radial push rod 5 can be driven by the first driving cylinder to do telescopic motion in the long groove. The other end of the first radial push rod 5 can penetrate into the positioning groove 4 under the driving of the first driving air cylinder so as to push the connector in the positioning groove 4 into the clamp assembly 6. After the pushing is completed, the first radial push rod 5 can be driven by the first driving cylinder to reset to wait for pushing the material at the next time.

The direction of movement of the first radial push rod 5 is perpendicular to the transport direction of the particular guide rail 3. The locating slot 4 is arranged on the right side of the clamp assembly 6 in the embodiment, so that the first radial push rod 5 can push the connector in the locating slot 4 to the left side into the clamp assembly 6 from the tail part of the connector. Be equipped with infrared probe in the anchor clamps subassembly 6, infrared probe can perceive during the connector has got into anchor clamps to with signal transmission to PLC control system, make anchor clamps subassembly 6 press from both sides the connector tightly.

The clamp assembly 6 is mounted on the first V-shaped rail 8 by means of a mounting plate. The mounting panel bottom is equipped with the slider with 8 sliding fit of first V-arrangement guide rails to the mounting panel can slide on 8 first V-arrangement guide rails, makes anchor clamps subassembly 6 can slide on 8 first V-arrangement guide rails under the drive of mounting panel, with the realization to the quick aversion of connector, thereby improves the efficiency of milling. The transport direction of the first V-shaped rail 8 is longitudinal, so that the gripper assembly 6 can be moved up and down along the first V-shaped rail 8 by means of the mounting plate.

In this embodiment the clamp assembly 6 is slidably connected to the mounting plate. Therefore, the clamp assembly 6 can move left and right on the mounting plate under the driving of the driving device, so that the clamp assembly 6 can move along the length direction vertical to the first V-shaped guide rail 8. In another alternative embodiment, the drive means is provided on the mounting plate and the clamp assembly 6 is connected to the drive means such that the clamp assembly 6 is provided on the mounting plate by the drive means. The driving device can drive the clamp assembly 6 to move left and right, so that the clamp assembly 6 can move along the direction vertical to the length direction of the first V-shaped guide rail 8.

In this embodiment, the second V-shaped guide rail 9 is disposed on the left side of the first V-shaped guide rail 8, and the clamp assembly 6 can be driven by the driving device to move to the first preset position from the left side. The first predetermined position is provided with a positioning bolt 16. When the clamp assembly 6 moves to the first preset position, the positioning bolt 16 can position the clamp assembly 6, so that the clamp assembly 6 stops on the positioning bolt 16, the connector in the clamp assembly 6 is positioned accurately, and the milling accuracy is improved.

The second V-shaped guide rail 9 is provided with a transverse cutting saw blade 7, and the transportation direction of the second V-shaped guide rail 9 is the horizontal direction. The transverse cutting blade 7 can be moved laterally on the second V-shaped rail 9 to a first preset position to close the clamp assembly 6 resting on the set bolt 16 to transversely slot the coupling head in the clamp assembly 6.

The clamp assembly 6 can move up and down along the first V-shaped guide rail 8 through the mounting plate, so that the clamp assembly 6 can drive the connector after transverse cutting to move downwards to a second preset position along the first V-shaped guide rail 8. The second predetermined position is provided with a longitudinal cutting blade 10, so that the longitudinal cutting blade 10 can longitudinally cut the connecting head, thereby milling the cross slot of the connecting head.

The clamp assembly 6 can move up and down along the first V-shaped guide rail 8 through the mounting plate, so that the clamp assembly 6 can drive the connector which finishes milling the cross groove to continuously move downwards to a third preset position along the first V-shaped guide rail 8. A second radial push rod 11 is arranged at a third preset position. In this embodiment, one end of the second radial push rod 11 is connected to an output shaft of the second driving cylinder, so that the second radial push rod can be driven by the second driving cylinder to perform telescopic motion. After the clamp assembly 6 drives the connector which finishes the milling of the cross slot to continuously move downwards to the third preset position, the second radial push rod 11 can push out the connector in the clamp assembly 6 under the driving of the second driving cylinder, and therefore the unloading process is finished.

The working principle of the embodiment is as follows: put into on guide vibration dish 1 with the connector of treating the grooving, guide vibration dish 1 arranges the connector of piling up, makes its head outwards, and the orderly arrangement then carries to constant head tank 4 through specific track.

After the connector is conveyed to the positioning groove 4, the first radial push rod 5 is driven by the first driving cylinder to push the connector to the clamp assembly 6.

After the connector enters the clamp assembly 6, the infrared probe in the clamp assembly 6 can sense that the connector enters the clamp, and transmits a signal to the PLC control system, so that the clamp assembly 6 clamps the connector tightly.

After the clamp assembly 6 clamps the connector, the clamp assembly 6 moves to the first preset position to the left side under the driving of the driving device, and stops at the positioning bolt 16.

After the clamp assembly 6 stops on the positioning bolt 16, the PLC control system is triggered to send out an instruction, so that the transverse cutting saw blade 7 moves to a first preset position on the second V-shaped guide rail 9 along the horizontal direction, and therefore transverse grooving is conducted on the connector in the clamp assembly 6.

After the transverse grooving of the connector in the clamp assembly 6 is finished, the PLC control system is triggered to send out an instruction, so that the clamp assembly 6 moves downwards to a second preset position along the first V-shaped guide rail 8.

After the clamp assembly 6 is moved to the second predetermined position, the longitudinal cutting blade 10 begins to longitudinally slot the connector in the clamp assembly 6.

And after the longitudinal grooving is finished, the cross groove milling is finished. At the moment, the PLC control system is triggered to send an instruction, the clamp assembly 6 continues to move downwards to a third preset position, the PLC control system sends an instruction, the clamp assembly 6 loosens the connector, and the second radial push rod 11 is driven by the second driving air cylinder to push out the connector which finishes the cross milling from the clamp assembly 6, so that the unloading process is finished.

The utility model discloses the principle and the implementation mode of the utility model are explained by applying the concrete embodiment, and the explanation of the above embodiment is only used for helping to understand the technical scheme and the core idea of the utility model; meanwhile, for the general technical personnel in the field, according to the idea of the present invention, there are changes in the specific implementation and application scope, to sum up, the content of the present specification should not be understood as the limitation of the present invention.

Claims (7)

1. A micro cross groove rapid milling system for a connector is characterized by comprising a guide type vibration disc for feeding and a milling device;

the milling device comprises a base, a specific guide rail, a positioning groove, a first radial push rod, a clamp assembly, a transverse cutting saw blade, a first V-shaped guide rail and a second V-shaped guide rail which are vertically arranged on the base, a longitudinal cutting saw blade and a second radial push rod;

the guide type vibration disc is connected with the specific guide rail, and the output end of the specific guide rail is provided with a positioning groove, so that a connector can be conveyed into the positioning groove from the guide type vibration disc along the specific guide rail to realize feeding; the first radial push rod is arranged on one side of the positioning groove so as to push the connector in the positioning groove into the clamp assembly;

the clamp assembly is arranged on the first V-shaped guide rail through a mounting plate, so that the clamp assembly can move up and down along the first V-shaped guide rail through the mounting plate; the clamp assembly can move on the mounting plate, so that the clamp assembly can move to a first preset position along the direction perpendicular to the length direction of the first V-shaped guide rail;

the second V-shaped guide rail is arranged on one side of the first V-shaped guide rail, the transverse cutting saw blade is arranged on the second V-shaped guide rail, and the transverse cutting saw blade can transversely move to the first preset position along the second V-shaped guide rail so as to transversely cut a connector in the clamp assembly which moves to the first preset position;

the clamp assembly can move to a second preset position along the length direction of the first V-shaped guide rail, and the second preset position is provided with the longitudinal cutting saw blade so as to longitudinally cut the connector after transverse cutting;

the fixture assembly can move to a third preset position along the length direction of the first V-shaped guide rail, and the third preset position is provided with the second radial push rod so as to push out the longitudinally cut connector from the fixture assembly.

2. The rapid milling system for the micro cross slot of the connector according to claim 1, wherein the pushing direction of the first radial push rod is not parallel to the conveying direction of the specific guide rail.

3. The system for rapidly milling the micro cross slot of the connecting head according to claim 1, wherein the first predetermined position is provided with a positioning bolt for positioning the clamp assembly moving toward the first predetermined position.

4. The system for rapidly milling the micro cross groove of the connecting head according to claim 1, wherein an infrared probe is arranged in the clamp assembly, so that the fact that the connecting head enters the clamp can be sensed, and signals are transmitted to a PLC control system.

5. The connector micro cross slot rapid milling system according to claim 1, wherein the guided vibration disk comprises a body, a first guide chute, a second guide chute and a third guide chute; the first material guide grooves are arranged around the outer edge of the body in a surrounding manner so as to arrange the piled connectors into a row; the second material guide groove is arranged around the outer edge of the first material guide groove in a certain inclination angle, so that the heads of the connectors can be orderly arranged outwards; one end of the third guide chute is connected with the second guide chute, and the other end of the third guide chute is connected with the milling device, so that the connector is conveyed into the milling device.

6. The rapid milling system for the miniature cross groove of the connector as claimed in claim 5, wherein the inclination angle of the second material guiding groove is 5-15 °.

7. The rapid milling system for the miniature cross grooves of the connectors as claimed in claim 5, wherein the interface between the second material guiding groove and the first material guiding groove can pass through only one connector at a time.

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