CN113146724A

CN113146724A - Cutting die supply system and high-speed intelligent cutting machining center using same

Info

Publication number: CN113146724A
Application number: CN202110567905.7A
Authority: CN
Inventors: 王卸斌; 童俊翔; 童惠忠; 王文寅; 童孝忠
Original assignee: Quzhou Taiwei Machinery Industry Co ltd
Current assignee: Quzhou Taiwei Machinery Industry Co ltd
Priority date: 2021-05-24
Filing date: 2021-05-24
Publication date: 2021-07-23
Also published as: WO2022247236A1; EP4201616A1

Abstract

The invention relates to a cutting die supply system, which comprises a cutting die plate storage rack arranged in a frame and a driving device thereof, wherein the cutting die plates are stacked in the storage rack layer by layer up and down, guide posts are respectively arranged at four corners of the frame, guide sleeves in sliding fit with the guide posts are arranged on the storage rack, and the driving device drives the storage rack to move up and down along the guide posts. The driving device comprises synchronous belts arranged on the left side and the right side of the frame, a knife rest fixing plate is respectively arranged on each synchronous belt, one end of each knife rest fixing plate is fixed on the synchronous belt, the other end of each knife rest fixing plate is fixed on the storage rack on the side, and the two synchronous belts simultaneously drive the storage rack to move up and down through the respective knife rest fixing plates. The invention also discloses a high-speed intelligent cutting machining center using the system. The synchronous belt structure is adopted, so that the driving structure is simplified, the equipment volume is effectively reduced, the position repeatability of the up-and-down operation of the cutting die plate storage rack is improved, and the equipment stability is good.

Description

Cutting die supply system and high-speed intelligent cutting machining center using same

Technical Field

The invention belongs to the technical field of automatic cutting machine equipment, and particularly relates to a cutting die supply system and a high-speed intelligent cutting machining center using the same.

Background

The general fixed mounting of cutting die of current cutting machine is on deciding the aircraft nose, when the cutting die of different models need to be changed, all need change through the manual work at every turn, and not only working strength is big, still need debug position, angle after changing the cutting die at every turn moreover, extravagant too much time, and production efficiency is low, and the product quality can not obtain control. Although some cutting machines adopt the technology of automatically replacing cutting dies, the cutting machines are complex in structure, large in size, large in occupied area, high in failure rate and poor in operation stability.

Disclosure of Invention

The invention aims to solve the technical problem of providing a cutting die supply system and a high-speed intelligent cutting machining center using the same, and the cutting die supply system is simple in structure, small in size and good in stability.

The invention is realized in this way, provide a cutting die supply system, including the frame and cutting die plate storage rack and its drive unit set up in frame, there are the cutting die plate that passes in and out the exit department of the storage rack in front and back both sides of the frame separately, a plurality of cutting die plates are stacked up and down in the storage rack hierarchically, set up the guide pillar separately in four corners of the frame, set up the guide bush cooperating with guide pillar sliding on the storage rack, the drive unit drives the storage rack to move up and down along the guide pillar; drive arrangement is including the motor gear box that is provided with dual output shaft, driving pulley, the driven shaft, driven bearing, driven pulley and hold-in range, the motor gear box sets up the top at the frame, two driving pulley set up respectively at the both ends of output shaft, two driven bearings are fixed in the frame lower part and are located the below of storage rack, the driven shaft is worn to establish in two driven bearings, driven pulley sets up the both ends at the driven shaft, driving pulley passes through the hold-in range and drives driven pulley and rotate, set up the hold-in range respectively in the left and right sides of frame, set up the knife rest fixed plate respectively on every hold-in range, knife rest fixed plate one end is fixed on the hold-in range, its other end is fixed on the storage rack of this side.

Furthermore, a plurality of slideways for placing the knife templates are respectively arranged on the left side and the right side of the storage rack from top to bottom, a knife template locking device for positioning the knife templates in the slideways is arranged on the right side of the storage rack, the knife template locking device comprises a locking cylinder, a locking operating rod, locking bearings, a driving rod, a locking rod rotating shaft and a rotating shaft fixing rod, the locking cylinder is fixed on the upper portion of the storage rack, the locking operating rod is fixedly connected with an output shaft of the locking cylinder, the locking operating rod is arranged on the two locking bearings in a penetrating manner, the two locking bearings are fixed on the storage rack and respectively positioned at two ends of the locking operating rod, the locking operating rod slides up and down along the locking bearings under the driving of the locking cylinder, the rotating shaft fixing rod is fixed on the side of the storage rack, a plurality of avoiding holes corresponding to the placing positions of the knife templates on each layer are arranged on the rotating shaft fixing rod, the driving rod, the locking rod and the rotating shaft are respectively arranged at the side of the placing positions of the knife templates on each layer in a set, set up waist shape hole, pivot hole and arc portion on the locking lever respectively, the locking lever pivot is passed the pivot hole of pivot dead lever and locking lever and is dodged the hole with locking lever swing joint in the locking lever, actuating lever one end is fixed on the locking lever, and its other end is pegged graft in the waist shape hole of locking lever movably, and the arc portion joint of locking lever is in setting up the spacing draw-in groove at the template of knife side, and the locking action bars slides from top to bottom and drives the locking lever through the actuating lever and rotate around the locking lever pivot.

Further, rollers are arranged on the side wall of each slide way.

Furthermore, a contact block is arranged on the locking operating rod, and an upper travel switch and a lower travel switch which are matched with the contact block are respectively arranged on the frame.

Furthermore, a knife rest supporting column is arranged at the bottom of the storage rack, and a knife rest limiting column is arranged at the top of the frame.

Further, a stop switch is provided on the frame to be triggered by the storage rack.

The present invention has been achieved in this way, and provides a high-speed intelligent cutting machining center using the cutting die supply system described above.

Compared with the prior art, the cutting die supply system and the high-speed intelligent cutting machining center using the same are characterized in that the cutting die supply system comprises a cutting die storage rack arranged in a frame and a driving device of the cutting die storage rack, the cutting die plates are stacked in the storage rack layer by layer up and down, guide columns are respectively arranged at four corners of the frame, guide sleeves in sliding fit with the guide columns are arranged on the storage rack, and the driving device drives the storage rack to move up and down along the guide columns. The driving device comprises synchronous belts arranged on the left side and the right side of the frame, a knife rest fixing plate is respectively arranged on each synchronous belt, one end of each knife rest fixing plate is fixed on the synchronous belt, the other end of each knife rest fixing plate is fixed on the storage rack on the side, and the two synchronous belts simultaneously drive the storage rack to move up and down through the respective knife rest fixing plates. By adopting the synchronous belt structure, the driving structure is simplified, the volume of the equipment is effectively reduced, the position repeatability of the up-and-down operation of the cutting die plate storage rack is improved, and the stability of the equipment is good. On the other hand, the tool changing template is convenient to automatically change, the changing time is shortened, the working efficiency is improved, the positioning is accurate, and the cutting precision of the high-speed intelligent cutting machining center is improved.

Drawings

FIG. 1 is a front view of a preferred embodiment of a die feed system of the present invention;

FIG. 2 is a perspective view of FIG. 1;

FIG. 3 is a perspective view of FIG. 2 from another angle;

FIG. 4 is an enlarged view of the portion M in FIG. 2;

FIG. 5 is a perspective view of the die plate of FIG. 2;

fig. 6 is a perspective view of the locking lever of fig. 2.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1 to 4, a preferred embodiment of a cutting die feeding system of the present invention includes a frame 1, a cutting die plate storage rack 2 disposed in the frame 1, and a driving device 3 thereof.

The front and rear side surfaces of the frame 1 are respectively provided with an entrance/exit portion 4 for the die plate a to enter/exit the storage rack 2. The portion of cominging in and going out 4 of one side is used for deciding machining center equipment with high-speed intelligence and is connected, decides machining center equipment for high-speed intelligence and provides required cutting die board A. The other access portion 4 is used for replacing and sequentially arranging the die plates a in the frame 1. A plurality of blade form panels a are stacked in layers above and below in the storage rack 2. Guide posts 5 are respectively arranged at four corners of the frame 1. The storage rack 2 is provided with a guide sleeve 6 which is in sliding fit with the guide post 5. The driving device 3 drives the storage rack 2 to move up and down along the guide post 5.

The drive device 3 includes a motor gear box 31 provided with dual output shafts, a driving pulley 32, a driven shaft 33, a driven bearing 34, a driven pulley 35, and a timing belt 36. The motor gear box 31 is arranged at the top of the frame 1, the two driving belt wheels 32 are respectively arranged at two ends of the output shaft, the two driven bearings 34 are fixed at the lower part of the frame 1 and positioned below the storage rack 2, the driven shaft 33 is arranged in the two driven bearings 34 in a penetrating way, and the driven belt wheels 35 are arranged at two ends of the driven shaft 33. The driving pulley 32 rotates the driven pulley 35 via a timing belt 36. The timing belts 36 are provided on the left and right sides of the frame 1. A tool holder fixing plate 37 is provided for each timing belt 36. One end of the tool rest fixing plate 37 is fixed to the timing belt 36, and the other end thereof is fixed to the storage rack 2 on the side. The two synchronous belts 36 respectively drive the storage rack 2 to move up and down along the guide post 5 through the knife rest fixing plate 37 on the synchronous belts. The synchronous belt technology is used, so that the structure of the driving device 3 is simplified, the position repeatability of the storage rack 2 in up-and-down operation is improved, and the operation stability is improved.

The left side and the right side of the storage rack 2 are respectively provided with a plurality of slideways 7 for placing the knife templates A from top to bottom, and the right side of the storage rack 2 is provided with a knife template locking device 8 for positioning the knife templates A in the slideways 7.

The die plate locking device 8 comprises a locking cylinder 81, a locking operating rod 82, a locking bearing 83, a driving rod 84, a locking rod 85, a locking rod rotating shaft 86 and a rotating shaft fixing rod 87. The lock cylinder 81, the lock bearing 83 and the rotation shaft fixing rod 87 are fixed to the storage rack 2, respectively.

The lock cylinder 81 is fixed to the upper portion of the storage rack 2, and the lock operation lever 82 is fixedly connected to an output shaft of the lock cylinder 81. The locking operation rod 82 is disposed through two locking bearings 83, the two locking bearings 83 are fixed on the storage rack 2 and located at two ends of the locking operation rod 82, and the locking operation rod 82 slides up and down along the locking bearings 83 under the driving of the locking cylinder 81. The rotating shaft fixing rod 87 is fixed on the side surface of the storage rack 2, and a plurality of avoiding holes 871 corresponding to the placing positions of the cutting templates A on each layer are arranged on the rotating shaft fixing rod 87.

The driving lever 84, the locking lever 85 and the locking lever rotating shaft 86 are respectively provided in a set at the side of the placement position of each layer of blade form a. As shown in fig. 6, a waist-shaped hole 851, a rotation shaft hole 852, and an arc portion 853 are provided on the lock lever 85, respectively, and the waist-shaped hole 851 and the arc portion 853 are located on both sides of the rotation shaft hole 852, respectively. The locking lever rotating shaft 86 passes through the rotating shaft fixing rod 87 and the rotating shaft hole 852 of the locking lever 85 to movably connect the locking lever 85 in the locking lever avoiding hole 871, and the locking lever 85 rotates around the locking lever rotating shaft 86. One end of the driving rod 84 is fixed on the locking rod 85, and the other end thereof is movably inserted into the kidney-shaped hole 851 of the locking rod 85. The arc-shaped portion 853 of the lock lever 85 is clamped in the limiting clamping groove B provided at the side edge of the knife template a, as shown in fig. 5.

The locking operating rod 82 slides up and down and drives the locking rod 85 to rotate around the locking rod rotating shaft 86 through the driving rod 84, so that the arc-shaped portion 853 of the locking rod 85 is clamped into the limiting clamping groove B of the knife template A to lock the knife template A, or the arc-shaped portion 853 of the locking rod 85 is released from the limiting clamping groove B of the knife template A to unlock the knife template A.

The contact block 88 is arranged on the locking operation rod 82, the upper travel switch 10 and the lower travel switch 11 which are matched with the contact block 88 are respectively arranged on the frame 1, and when the contact block 88 moves up and down along with the locking operation rod 82, the upper travel switch 10 and the lower travel switch 11 are respectively triggered to limit the upper position and the lower position of the movement of the locking operation rod 82, so that the operation safety of the knife template locking device 8 is improved.

The locking cylinder 81 is used as power, so that the response time of the cutting die plate locking device 8 is shortened, and the working efficiency of the cutting die supply system is improved.

Rollers 9 are provided on the side walls of each of the runners 7. The roller 9 is positioned above the cutting die plate A and close to the access part 4 at the rear side surface of the frame 1, and plays a role in limiting and guiding the cutting die plate A in the process of storing or guiding the cutting die plate A out of the storage rack 2. And a tool rest supporting column 12 is arranged at the bottom of the storage rack 2, and the tool rest supporting column 12 is fixed on the frame 1. And a tool rest limiting column 13 is arranged at the top of the frame 1. In this embodiment, four knife rest support columns 12 are respectively arranged at four corners of the bottom of the storage rack 2, and four knife rest limit columns 13 are respectively arranged at four corners of the top of the frame 1, so as to improve the safety and stability of the storage rack 2.

A stop switch 14 triggered by the storage rack 2 is arranged on the frame 1, and the stop switch 14 limits the descending position of the storage rack 2, so that the safety and the stability of the movement of the storage rack 2 are improved.

The present invention has been achieved in this way, and provides a high-speed intelligent cutting machining center using the cutting die supply system described above. The cutting die supply system automatically provides a cutting die plate A required for cutting for the high-speed intelligent cutting machining center.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims

1. A cutting die supply system is characterized by comprising a frame, a cutting die plate storage rack arranged in the frame and a driving device thereof, wherein the front side surface and the rear side surface of the frame are respectively provided with an in-out part for the cutting die plates to enter and exit the storage rack, a plurality of cutting die plates are stacked in the storage rack up and down in layers, guide pillars are respectively arranged at the four corners of the frame, guide sleeves in sliding fit with the guide pillars are arranged on the storage rack, and the driving device drives the storage rack to move up and down along the guide pillars; drive arrangement is including the motor gear box that is provided with dual output shaft, driving pulley, the driven shaft, driven bearing, driven pulley and hold-in range, the motor gear box sets up the top at the frame, two driving pulley set up respectively at the both ends of output shaft, two driven bearings are fixed in the frame lower part and are located the below of storage rack, the driven shaft is worn to establish in two driven bearings, driven pulley sets up the both ends at the driven shaft, driving pulley passes through the hold-in range and drives driven pulley and rotate, set up the hold-in range respectively in the left and right sides of frame, set up the knife rest fixed plate respectively on every hold-in range, knife rest fixed plate one end is fixed on the hold-in range, its other end is fixed on the storage rack of this side.

2. The cutting die supply system according to claim 1, wherein a plurality of slideways for placing the cutting die plates are respectively provided up and down on the left and right sides of the storage rack, a cutting die plate locking device for positioning the cutting die plates in the slideways is provided on the right side of the storage rack, the cutting die plate locking device comprises a locking cylinder, a locking operating rod, locking bearings, a driving rod, a locking rod rotating shaft and a rotating shaft fixing rod, the locking cylinder is fixed on the upper portion of the storage rack, the locking operating rod is fixedly connected with an output shaft of the locking cylinder, the locking operating rod is arranged on the two locking bearings in a penetrating manner, the two locking bearings are fixed on the storage rack and are respectively positioned at two ends of the locking operating rod, the locking operating rod slides up and down along the locking bearings under the driving of the locking cylinder, the rotating shaft fixing rod is fixed on the side surface of the storage rack, a plurality of avoiding holes corresponding to the placing positions of the cutting die plates on each layer are provided on the rotating shaft fixing rod, the actuating lever, locking lever and locking lever pivot set up the lateral part of placing the position at every layer of cutting die board respectively with the suit, set up waist shape hole on the locking lever respectively, pivot hole and arc portion, the pivot hole that the locking lever pivot passed pivot dead lever and locking lever is connected the locking lever swing joint in the locking lever dodges the hole, actuating lever one end is fixed on the locking lever, its other end is pegged graft in the waist shape hole of locking lever movably, the arc portion joint of locking lever is in the spacing draw-in groove of setting at the cutting die board side, the locking action bars slides from top to bottom and drives the locking lever through the actuating lever and rotate around the locking lever pivot.

3. The die feed system of claim 2 wherein rollers are provided on the side walls of each of said runners.

4. The die feed system according to claim 2, wherein a contact block is provided on the lock lever, and an upper stroke switch and a lower stroke switch which are engaged with the contact block are provided on the frame, respectively.

5. The die feed system of claim 1, wherein a tool holder support post is provided at the bottom of the storage rack and a tool holder retention post is provided at the top of the frame.

6. The die feed system of claim 1 wherein a stop switch is provided on the frame that is triggered by the storage rack.

7. A high-speed intelligent cutting machining center, characterized in that the cutting die supply system according to any one of claims 1 to 5 is used in the high-speed intelligent cutting machining center.