CN110125994B

CN110125994B - Automatic wheat-pulling pipe cutting machine

Info

Publication number: CN110125994B
Application number: CN201910491270.XA
Authority: CN
Inventors: 任小龙; 王涛
Original assignee: Changzhou Juhao Electric Co ltd
Current assignee: Changzhou Juhao Electric Co ltd
Priority date: 2019-06-06
Filing date: 2019-06-06
Publication date: 2023-12-12
Anticipated expiration: 2039-06-06
Also published as: CN110125994A

Abstract

The invention relates to an automatic wheat pulling pipe cutting machine which comprises a frame, wherein an automatic feeding mechanism and an automatic cutting mechanism are arranged on the frame, and the automatic cutting mechanism is positioned at the output end of the automatic feeding mechanism. The invention has the effect of improving the production efficiency of the maillard.

Description

Automatic wheat-pulling pipe cutting machine

Technical Field

The invention relates to the field of cutting machines, in particular to an automatic wheat pulling pipe cutting machine.

Background

The Maillard tube is also called a polyester heat shrinkage tube or a PET sleeve, and is mainly applied to temperature resistant insulation and mechanical protection of welding spots, joints, coils, transformers, motors, electric heating elements and the like.

The Maillard tube is a long tube with the length of more than two meters for storage, and then is divided into different lengths according to the requirements of customers. When the existing wheat pulling pipe is produced, the mode of manual feeding is adopted for feeding, the wheat pulling pipe is conveyed to the lower portion of the cutting machine, then a plurality of wheat pulling pipes are cut into required lengths through the cutting machine, however, the feeding mode is high in working intensity and low in efficiency.

Disclosure of Invention

The invention aims to provide an automatic wheat straw cutter which has the advantages of reducing the labor intensity of wheat straw production and improving the production efficiency of wheat straw.

The technical scheme adopted for solving the technical problems is as follows:

an automatic wheat pulling pipe cutting machine comprises a frame,

the automatic feeding mechanism and the automatic cutting mechanism are arranged on the frame, and the automatic cutting mechanism is located at the output end of the automatic feeding mechanism.

Further: the automatic feeding mechanism comprises a slideway, a first lead screw, a sliding block and a first driving motor, wherein the first lead screw is arranged in the slideway and is arranged along the length direction of the slideway, the first driving motor is fixed at one end of the slideway far away from the automatic cutting mechanism, a rotor of the first driving motor is fixedly connected with one end of the first lead screw coaxially, and the sliding block is arranged above the slideway in a sliding way and is in threaded connection with the first lead screw;

the upper part of the sliding block is vertically and fixedly connected with two side plates, the side plates are positioned at two ends of the sliding block, the side walls of the side plates are respectively and fixedly connected with first finger cylinders facing the automatic cutting mechanism, and a first clamping plate which is arranged up and down is fixedly connected between the two first finger cylinders.

Further: the automatic cutting mechanism comprises vertical plates oppositely arranged on the frame, mounting plates arranged between the vertical plates, a cutter holder for fixing the blades, a die holder arranged below the cutter holder, a lower die fixed on the die holder and a driving mechanism for driving the mounting plates to move;

the tool apron is positioned in the mounting plate, and the driving mechanism is fixed on the outer side wall of one of the vertical plates;

the lower die is located right below the tool apron, and the second clamping plate faces the lower die.

Further: the middle part fixedly connected with of mounting panel divides into the separate piece in two grooves with the mounting panel, all slides in every groove and is connected with the blade holder, two the orientation of the fixed blade of blade holder below is opposite, be equipped with the cam mechanism of two blade holders of drive work in turn in the mounting panel.

Further: the cam mechanism comprises a cam plate, an impact block and a cam follower, wherein the side wall of the mounting plate is provided with a through hole for the two ends of the cam plate to penetrate out, the cam plate is provided with two groups of adjusting grooves which are arranged in one-to-one correspondence with the tool holders, one group of adjusting grooves comprises two S-shaped grooves which are positioned at the same height, the other group of adjusting grooves comprises two inverted S-shaped grooves which are positioned at the same height, each tool holder is provided with a mounting hole which is arranged in one-to-one correspondence with the S-shaped groove and the inverted S-shaped groove, one end of the cam follower is fixed in the mounting hole, and the idler wheels at the other end of the cam follower are positioned in the S-shaped grooves and the inverted S-shaped grooves;

the impact blocks are respectively fixed on the opposite inner side walls of the support columns, and the impact blocks are matched with the through holes.

Further: the die holder is characterized in that two ends of the die holder are fixedly connected with second finger cylinders, second clamping plates which are arranged up and down are fixedly connected between the second finger cylinders, and two ends of the die holder are respectively fixedly connected with a first sliding table cylinder which drives the second finger cylinders to move.

Further: the second finger cylinder is fixedly connected with a supporting plate, the second sliding table cylinder is fixedly connected to the supporting plate, a pushing plate is fixedly connected to a piston rod of the second sliding table cylinder, and the pushing plate is located between two second clamping plates.

Further: the driving mechanism comprises a second driving motor and a second lead screw which is coaxially and fixedly connected with a rotor of the second driving motor, and the mounting plate is in threaded connection with the second lead screw.

Further: the input end of the automatic feeding mechanism is provided with a Mylar tube carding mechanism;

the wheat straw carding mechanism comprises a fixing plate and a guide plate, wherein the fixing plate is oppositely arranged on the frame, the guide plate is fixed between the two fixing plates, and a plurality of guide holes for the wheat straw to pass out are formed in the guide plate along the length direction of the guide plate.

Further: and a blanking channel is fixedly connected below the die holder.

The beneficial effects of the invention are as follows: the automatic feeding mechanism is adopted to conveniently convey the wheat straw to the automatic cutting mechanism for cutting, so that the labor force is reduced, and the feeding efficiency of the wheat straw is improved. Meanwhile, the blades in the automatic cutting mechanism can cut the wheat straw in the reciprocating movement process, so that the cutting efficiency of the wheat straw is improved.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic diagram of an automated loading mechanism embodying the present invention;

fig. 3 is a schematic view of a mechanism for embodying the automatic cutting mechanism and the cam mechanism in the present invention.

In the figure, 1, an automatic feeding mechanism; 11. a slideway; 13. a slide block; 14. a first driving motor; 15. a side plate; 16. a first finger cylinder; 17. a first clamping plate; 2. an automatic cutting mechanism; 21. a riser; 22. a connecting plate; 23. a mounting plate; 231. perforating; 24. a die holder; 25. a lower die; 26. a tool apron; 261. a mounting hole; 3. a driving mechanism; 31. a second driving motor; 32. a second lead screw; 4. a separation block; 5. a cam mechanism; 51. a cam plate; 511. an S-shaped groove; 512. an inverted S-shaped groove; 52. an impact block; 53. a cam follower; 6. a maillard carding mechanism; 61. a fixing plate; 62. a guide plate; 63. a guide hole; 7. a first slipway cylinder; 71. a second finger cylinder; 72. a second clamping plate; 8. a second slipway cylinder; 81. a push plate; 82. a support plate; 9. and a discharging channel.

Detailed Description

The invention will now be further described with reference to the accompanying drawings. These drawings are simplified schematic views illustrating the basic structure of the present invention by way of illustration only, and thus show only the constitution related to the present invention.

Referring to fig. 1, an automatic wheat straw cutter comprises a frame, wherein an automatic feeding mechanism 1, an automatic cutting mechanism 2 and a wheat straw carding mechanism 6 are arranged on the frame. A blanking channel 9 is fixedly connected to the frame, and the blanking channel 9 is positioned below the automatic cutting mechanism 2. The wheat straw carding mechanism 6 is positioned at the input end of the automatic feeding mechanism 1, and the automatic cutting mechanism 2 is positioned at the output end of the automatic feeding mechanism 1.

As shown in fig. 1, the mailer comb mechanism 6 includes two fixing plates 61 fixed to the frame and disposed opposite to each other, and a guide plate 62 vertically fixed between the two fixing plates 61. The guide plate 62 is provided with a plurality of guide holes 63 along the length direction thereof for the wheat straw to pass through. Because the maillard is very long, the afterbody is crossed together easily in the in-process of material loading, sets up guiding hole 63 and can comb the maillard for the maillard is difficult for crossing, the convenience material loading.

As shown in fig. 2, the automatic feeding mechanism 1 comprises a slideway 11 fixed on the machine base, a first screw rod arranged in the slideway 11, a sliding block 13 in threaded connection with the first screw rod, and a first driving motor 14 coaxially and fixedly connected with one end of the first screw rod. The first driving motor 14 is fixed at one end of the slideway 11 far away from the automatic cutting mechanism 2, and the sliding block 13 is glidingly arranged above the slideway 11. Two side plates 15 are vertically and fixedly connected above the sliding block 13, the side plates 15 are positioned at two ends of the sliding block 13, first finger cylinders 16 facing the automatic cutting mechanism 2 are fixedly connected to opposite side walls of the side plates 15 respectively, and a first clamping plate 17 arranged up and down is fixedly connected between the two first finger cylinders 16.

As shown in fig. 3, the automatic cutting mechanism 2 includes a riser 21, a mounting plate 23, a tool holder 26, a die holder 24 (see fig. 2), a lower die 25 (see fig. 2), and a driving mechanism 3 (see fig. 1). The risers 21 are oppositely arranged on the frame, the tool apron 26 is arranged in the mounting plate 23, the die holder 24 is arranged below the tool apron 26, the lower die 25 is fixed on the die holder 24 and is oppositely arranged with the blades on the tool apron 26, and the driving mechanism 3 is fixed on the outer side wall of one of the risers 21 and used for driving the mounting plate 23 to move.

As shown in fig. 3, the driving mechanism 3 includes a second driving motor 31 and a second screw rod 32 coaxially and fixedly connected with a rotor of the second driving motor 31, and the mounting plate 23 is in threaded connection with the second screw rod 32. The second driving motor 31 is started to enable the second screw rod 32 to rotate, and in the process of rotating the second screw rod 32, the mounting plate 23 in threaded connection with the second screw rod 32 is driven to move along the length direction of the second screw rod 32, so that the cutter holder 26 is driven to move, and the wheat straw is cut.

As shown in fig. 3, in order to further improve the cutting efficiency of the mailer, the mailer can be cut in the process of moving the mounting plate 23 back and forth, a separation block 4 for separating the mounting plate 23 into two grooves is fixedly connected in the middle of the mounting plate 23, each groove is slidably connected with a knife holder 26, the lower parts of the two knife holders 26 are fixedly connected with blades with opposite directions, and a cam mechanism 5 for driving the two knife holders 26 to work alternately is arranged in the mounting plate 23.

As shown in fig. 3, the cam mechanism 5 includes a cam plate 51, an impact block 52, and a cam follower 53. The side wall of the mounting plate 23 is provided with a through hole 231 for the two ends of the cam plate 51 to penetrate out, the cam plate 51 is provided with two groups of adjusting grooves, the adjusting grooves are arranged in one-to-one correspondence with the tool apron 26, one group of adjusting grooves comprises two S-shaped grooves 511 which are positioned at the same height, the other group of adjusting grooves comprises two inverted S-shaped grooves 512 which are positioned at the same height, each tool apron 26 is provided with a mounting hole 261 which is arranged in one-to-one correspondence with the S-shaped grooves 511 and the inverted S-shaped grooves 512, one end of the cam follower 53 is fixed in the mounting hole 261, and the roller at the other end is positioned in the S-shaped grooves 511 and the inverted S-shaped grooves 512 and slides in a rolling way along the S-shaped grooves 511. The impact blocks 52 are respectively fixed on opposite inner side walls of the support column, and the impact blocks 52 are matched with the through holes 231. When installed, the cam follower 53 of one of the tool holders 26 is located at the upper end of the inverted S-shaped slot 512, and the cam follower 53 of the other tool holder 26 is located at the lower end of the S-shaped slot 511. When the cutter is used, the second driving mechanism 3 drives the mounting plate 23 to move, the cutter blade positioned at the lower end of the S-shaped groove 511 cuts the wheat straw, when the end part of the cam plate 51 is impacted with the impact block 52, the impact block 52 pushes the cam plate 51 to move towards the driving mechanism 3, so that the cam follower 53 positioned at the lower end of the S-shaped groove 511 rolls to the upper end of the S-shaped groove 511, the cam follower 53 positioned at the upper end of the inverted S-shaped groove 512 rolls to the lower end of the inverted S-shaped groove 512, and cutter replacement is realized, so that the cutter blade positioned at the lower end of the inverted S-shaped groove 512 cuts the wheat straw. The two blades work alternately to cut the wheat straw back and forth, so that the working efficiency is improved.

As shown in fig. 3, two ends of the die holder 24 are fixedly connected with second finger cylinders 71, second clamping plates 72 which are arranged up and down are fixedly connected between the second finger cylinders 71, and two ends of the die holder 24 are respectively fixedly connected with a first sliding table cylinder 7 which drives the second finger cylinders 71 to move. The wheat straw is fixed by the second clamping plate 72, so that the cutter blade is convenient to cut, and then the second clamping plate 72 is moved to the upper part of the blanking channel 9 through the first sliding table cylinder 7, so that finished wheat straw is collected.

As shown in fig. 3, a supporting plate 82 is fixedly connected between the second finger cylinders 71, a second sliding table cylinder 8 is fixedly connected to the supporting plate 82, a pushing plate 81 is fixedly connected to a piston rod of the second sliding table cylinder 8, and the pushing plate 81 is located between the two second clamping plates 72. The push plate 81 pushes the finished wheat straw in the second clamping plate 72 to fall into the blanking channel 9, so that the finished wheat straw is more convenient to fall.

The specific implementation process comprises the following steps:

the plurality of the mailer pipes penetrate through the corresponding guide holes 63 and are fixed between the first clamping plates 17, the first driving motor 14 drives the first screw rod to rotate, so that the sliding block 13 is driven to move, the first clamping plates 17 penetrate out of the lower die 25 and continue to convey the mailer pipes to the second clamping plates 72 in the moving process of the sliding block 13, and the second clamping plates 72 fix the end parts of the mailer pipes. The second driving motor 31 drives the second screw rod 32 to rotate, so that the mounting plate 23 is driven to move, and the cam follower 53 positioned at the lower end of the S-shaped groove 511 drives the corresponding blade to cut the wheat straw.

When the end of the cam plate 51 collides with the striking block 52, the striking block 52 pushes the cam plate 51 to move toward the driving mechanism 3, so that the cam follower 53 at the lower end of the S-shaped groove 511 rolls to the upper end of the S-shaped groove 511, and the cam follower 53 at the upper end of the inverted S-shaped groove 512 rolls to the lower end of the inverted S-shaped groove 512, thereby realizing tool changing, and further enabling the blade at the lower end of the inverted S-shaped groove 512 to cut the wheat straw. The two blades work alternately to cut the wheat straw back and forth, so that the working efficiency is improved.

After cutting is finished, the first slipway cylinder 7 drives the second clamping plate 72 to move to the upper side of the blanking channel 9, the second slipway cylinder 8 drives the push plate 81 to move to the position between the second clamping plates 72, finished wheat straw between the second clamping plates 72 is pushed down into the blanking channel 9 to be collected, and the whole wheat straw cutting is high in automation degree and efficiency. With the above-described preferred embodiments according to the present invention as an illustration, the above-described descriptions can be used by persons skilled in the relevant art to make various changes and modifications without departing from the scope of the technical idea of the present invention. The technical scope of the present invention is not limited to the description, but must be determined according to the scope of claims.

Claims

1. The utility model provides a wheat draws tub automatic cutout machine, includes frame, its characterized in that:

an automatic feeding mechanism (1) and an automatic cutting mechanism (2) are arranged on the frame, and the automatic cutting mechanism (2) is positioned at the output end of the automatic feeding mechanism (1);

the automatic feeding mechanism (1) comprises a slide way (11), a first screw rod, a sliding block (13) and a first driving motor (14), wherein the first screw rod is arranged in the slide way (11) and is arranged along the length direction of the slide way (11), the first driving motor (14) is fixed at one end, far away from the automatic cutting mechanism (2), of the slide way (11), a rotor of the first driving motor (14) is fixedly connected with one end of the first screw rod coaxially, and the sliding block (13) is arranged above the slide way (11) in a sliding manner and is in threaded connection with the first screw rod;

two side plates (15) are vertically and fixedly connected above the sliding block (13), the side plates (15) are positioned at two ends of the sliding block (13), first finger air cylinders (16) facing the automatic cutting mechanism (2) are fixedly connected to the side walls of the side plates (15), and first clamping plates (17) arranged up and down are fixedly connected between the two first finger air cylinders (16);

the automatic cutting mechanism (2) comprises a vertical plate (21) which is oppositely arranged on the frame, a mounting plate (23) which is arranged between the vertical plates (21), a cutter holder (26) for fixing the blade, a die holder (24) which is arranged below the cutter holder (26), a lower die (25) which is fixed on the die holder (24) and a driving mechanism (3) which drives the mounting plate (23) to move;

the tool apron (26) is positioned in the mounting plate (23), and the driving mechanism (3) is fixed on the outer side wall of one of the vertical plates (21);

the lower die (25) is positioned right below the tool apron (26), and the second clamping plate (72) faces the lower die (25);

the middle part of the mounting plate (23) is fixedly connected with a separation block (4) for dividing the mounting plate (23) into two grooves, each groove is slidably connected with a cutter holder (26), the directions of blades fixed below the two cutter holders (26) are opposite, and a cam mechanism (5) for driving the two cutter holders (26) to work alternately is arranged in the mounting plate (23);

the cam mechanism (5) comprises a cam plate (51), an impact block (52) and a cam follower (53), a through hole (231) for enabling two ends of the cam plate (51) to penetrate out is formed in the side wall of the mounting plate (23), two groups of adjusting grooves which are arranged in a one-to-one correspondence mode with the tool rest (26) are formed in the cam plate (51), one group of adjusting grooves comprises two S-shaped grooves (511) which are arranged at the same height, the other group of adjusting grooves comprises two inverted S-shaped grooves (512) which are arranged at the same height, mounting holes (261) which are arranged in one-to-one correspondence with the S-shaped grooves (511) and the inverted S-shaped grooves (512) are formed in each tool rest (26), one end of the cam follower (53) is fixed in the mounting hole (261), and a roller at the other end of the cam follower (53) is located in the S-shaped grooves (511) and the inverted S-shaped grooves (512).

The impact blocks (52) are respectively fixed on the opposite inner side walls of the support column, and the impact blocks (52) are matched with the through holes (231).

2. The automatic wheat straw cutter according to claim 1, wherein:

the die holder is characterized in that second finger air cylinders (71) are fixedly connected to two ends of the die holder (24), second clamping plates (72) are fixedly connected between the second finger air cylinders (71), and first sliding table air cylinders (7) for driving the second finger air cylinders (71) to move are fixedly connected to two ends of the die holder (24) respectively.

3. The automatic wheat straw cutter according to claim 2, wherein:

fixedly connected with backup pad (82) between second finger cylinder (71), fixedly connected with second slip table cylinder (8) on backup pad (82), fixedly connected with push pedal (81) on the piston rod of second slip table cylinder (8), push pedal (81) are located between two second splint (72).

4. The automatic wheat straw cutter according to claim 1, wherein:

the driving mechanism (3) comprises a second driving motor (31) and a second lead screw (32) which is coaxially and fixedly connected with a rotor of the second driving motor (31), and the mounting plate (23) is in threaded connection with the second lead screw (32).

5. The automatic wheat straw cutter according to claim 1, wherein:

the input end of the automatic feeding mechanism (1) is provided with a Mylar pipe carding mechanism (6);

the wheat straw carding mechanism (6) comprises fixing plates (61) and guide plates (62), the fixing plates (61) are oppositely arranged on the frame, the guide plates (62) are fixed between the two fixing plates (61), and the guide plates (62) are provided with a plurality of guide holes (63) for the wheat straw to pass out along the length direction of the guide plates (62).

6. The automatic wheat straw cutter according to claim 1, wherein:

and a blanking channel (9) is fixedly connected below the die holder (24).