CN114769446A - Punch forming equipment and process for corrosion-resistant stainless steel seamless steel pipe fitting - Google Patents

Abstract

The invention discloses punch forming equipment for a corrosion-resistant stainless steel seamless steel pipe fitting, which comprises a base, a feeding assembly, a material conveying assembly and a punching assembly, wherein the feeding assembly, the material conveying assembly and the punching assembly are arranged in the base, a cavity is arranged in the base, a material receiving groove for receiving a steel pipe section, an operation groove for clamping the steel pipe section and a material discharging groove for discharging the steel pipe section are sequentially and fixedly connected in the cavity from left to right, a material collecting cavity is formed in the right side of the material discharging groove, a stop door is hinged to the right side of the material collecting cavity, and the material conveying assembly is arranged in the base. According to the automatic feeding device, the feeding assembly can be used for automatically feeding the section bar, the material conveying assembly can be used for automatically conveying the steel pipe section bar, the automation degree of the automatic feeding device is improved, the labor force is greatly saved, the punching assembly can be used for simultaneously punching two ends of the steel pipe section bar, the machining efficiency of the automatic feeding device is greatly improved, and the machining process is saved.

Description

Punch forming equipment and process for corrosion-resistant stainless steel seamless steel pipe fitting

Technical Field

The invention relates to the field of stamping equipment, in particular to stamping forming equipment and a stamping forming process for a corrosion-resistant stainless steel seamless steel pipe fitting.

Background

The steel pipe is a steel material with a hollow section, the length of the steel pipe is far greater than the diameter or the circumference, the steel pipe is an indispensable material in the current building industry, the steel pipe is not only used for conveying fluid and powdery solid, exchanging heat energy and manufacturing mechanical parts and containers, but also is an economic steel material and can be used for manufacturing building structure net racks, pillars, mechanical supports and the like.

When the corrosion-resistant stainless steel seamless steel pipe fitting is punched in the prior art, the feeding and discharging are usually carried out manually, and most of the feeding and discharging can only be carried out on one end of the steel pipe fitting at one time, so that the process is complicated, the machining efficiency is low, and the production efficiency is seriously restricted.

Therefore, it is necessary to provide a press forming apparatus for stainless seamless steel pipes with corrosion resistance to solve the above problems.

Disclosure of Invention

The invention aims to provide stamping forming equipment and a stamping forming process for corrosion-resistant stainless steel seamless steel pipes, which can automatically feed and set a section bar through a feeding assembly, can automatically transfer and set a steel pipe section bar through a material transfer assembly, improve the automation degree of a device, greatly save labor force, and simultaneously stamp two ends of the steel pipe section bar through a stamping assembly, thereby greatly improving the processing efficiency of the device and saving processing procedures.

In order to achieve the above purpose, the invention provides the following technical scheme: the punch forming equipment for the corrosion-resistant stainless steel seamless steel pipe comprises a base, a feeding assembly, a material conveying assembly and a punching assembly, wherein the feeding assembly, the material conveying assembly and the punching assembly are arranged in the base;

the material conveying assembly is arranged inside the base, and the material receiving groove, the operation groove and the material discharging groove are matched with the material conveying assembly;

the feeding assembly comprises a feeding cylinder, and the output end of the feeding cylinder is matched with the material receiving groove;

the top of the base is fixedly connected with a protective shell, the stamping assembly is arranged inside the protective shell and comprises a clamping plate, and the clamping plate is matched with the operation groove;

the stamping assembly further comprises a stamping die, and the clamping plate and the operation groove are matched with the stamping die.

As a preferable scheme of the invention, the feeding cylinder is fixed inside the protective shell, a plurality of feeding roller sets are arranged inside the feeding cylinder, each feeding roller set comprises four feeding concave columns which are distributed annularly, two ends of each feeding concave column are fixedly connected with conical teeth, the sides of the conical teeth are rotatably connected with fixed blocks which are fixedly connected with the feeding cylinder, the conical teeth at two ends of the four feeding concave columns are connected end to end, every two adjacent conical teeth are meshed and connected, a servo motor is installed at the input end of one feeding concave column, and a plurality of groups of feeding roller sets are connected through a first transmission belt.

As a preferable scheme of the invention, an electric cutter is arranged at an outlet of the feeding cylinder, an electric push rod is fixedly mounted on the inner top wall of the protective shell, and the top of the electric cutter is fixedly connected with the output end of the electric push rod.

As a preferable scheme of the invention, the material conveying assembly comprises two groups of material conveying mechanisms, each material conveying mechanism comprises a first cam and a second cam, the left side and the right side in the base are rotatably connected with two rotating shafts which are arranged in parallel, a second transmission belt is connected between the two rotating shafts, a material conveying motor is mounted at the input end of one of the rotating shafts, the end part of one of the rotating shafts is fixedly connected with the first cam, the end part of the other rotating shaft is fixedly connected with the second cam, a connecting plate is connected between the end parts of the first cam and the second cam, and the first cam and the second cam are both rotatably connected with the connecting plate.

As a preferable scheme of the invention, two groups of material conveying mechanisms are symmetrically distributed at the front end and the rear end of the rotating shaft, Y-shaped fork rods are fixedly connected to both ends of the inner side of the connecting plate, and the distance between the Y-shaped fork rods at both ends of the inner side of the connecting plate is equal to the distance between the material receiving groove and the operation groove and the distance between the operation groove and the material discharging groove.

As a preferable scheme of the invention, a fixed hydraulic cylinder is installed at the top of the protective shell, an output end of the fixed hydraulic cylinder extends into the protective shell, an output end of the fixed hydraulic cylinder is fixedly connected with a lifting plate, a slide rod is connected between the lifting plate and the clamping plate, the slide rod is fixed at the top of the clamping plate and penetrates through the lifting plate, an anti-falling block is fixedly connected at the top of the slide rod, and a spring is arranged outside the slide rod.

As a preferable scheme of the invention, a first hinged rod is hinged to the top of the clamping plate, a second hinged rod is hinged to the top of the first hinged rod, a connecting rod is hinged to the joint of the first hinged rod and the second hinged rod, a sleeve rod is rotatably connected to the outer side of the connecting rod, a pull rod is fixedly connected to the edge side of the sleeve rod, an inserting rod is fixedly connected to the end part of the pull rod, and an inserting groove matched with the inserting rod is formed in the stamping die.

According to a preferable scheme of the invention, the number of the stamping dies is two, the two stamping dies are symmetrically distributed on the front side and the rear side of the base, the front side and the rear side of the base are both fixedly connected with a fixed plate, an elastic part is fixedly connected between the fixed plate and the stamping dies, the top of the base is provided with a sliding groove, and the bottom of the stamping dies is fixedly connected with a fixed sliding block matched with the sliding groove.

The machining process of the punch forming equipment for the corrosion-resistant stainless steel seamless steel pipe fitting comprises the punch forming equipment for the corrosion-resistant stainless steel seamless steel pipe fitting, and comprises the following specific steps of:

s1: inputting the steel pipe section into the device through a feeding assembly;

s2: cutting off the steel pipe section by an electric cutter;

s3: conveying the cut steel pipe section to an operation groove through a material conveying assembly;

s4: performing punch forming on the steel pipe profile through a punching assembly;

s5: and conveying the product subjected to punch forming into a material collecting cavity through the material conveying assembly.

In the technical scheme, the invention has the following technical effects and advantages:

1. the corrosion-resistant stainless steel seamless steel pipe profile is placed inside the feeding cylinder, then the servo motor is started, the feeding concave columns below the feeding roller sets are driven to synchronously rotate through the first transmission belt, the feeding roller sets are coaxially arranged, each feeding concave column is matched with the profile, each feeding concave column is in contact with the profile, automatic feeding setting can be conducted on the profile, the feeding concave columns rotate simultaneously, the steel pipe profile can be protected, abrasion and resistance are reduced, the electric cutter can automatically cut off the steel pipe profile, automatic feeding setting can be conducted on the device conveniently, and machining efficiency is improved;

2. the material conveying motor is started to drive the first cam and the second cam to synchronously rotate clockwise and further drive the connecting plate to rotate, the end parts of the first cam and the second cam are connected with the connecting plate, so that the connecting plate can be kept balanced while the connecting plate is driven to rotate, the transmission of the steel pipe section is convenient to support, the side turning phenomenon of the steel pipe section is prevented, the left Y-shaped fork moves between the material receiving groove and the operating groove, the right Y-shaped fork rod moves between the operating groove and the material discharging groove, the left Y-shaped fork rod rotates clockwise, the steel pipe section in the material receiving groove is supported and then rotates to the position above the operating groove, the steel pipe section is placed in the operating groove, the right Y-shaped fork rod rotates clockwise, the steel pipe section in the operating groove is supported and then rotates to the position above the material discharging groove, and the steel pipe section is placed in the material discharging groove, thereby completing the automatic material conveying arrangement of the steel pipe section, improving the automation degree of the device and greatly saving labor force;

3. through starting fixed pneumatic cylinder, fixed pneumatic cylinder passes through the lifter plate and drives splint decline, wherein splint cooperate with the operation groove, can extrude fixedly to the steel pipe section bar of operation inslot portion, under the effect of spring, promote splint and carry out the centre gripping to steel pipe section bar more closely, prevent at the punching press in-process, steel pipe section bar takes place to shift, the lifter plate drives first hinge bar and second hinge bar and rotates, thereby promote the inboard activity of connecting rod and loop bar, the loop bar passes through the pull rod and drives the inserted bar to inside the activity, because the inserted bar extends to in the slot of stamping die, and then can drive stamping die and move to the inboard, because stamping die's quantity is provided with two, can carry out punching press simultaneously to the both ends of steel pipe section bar, the machining efficiency of device is greatly improved, and processing procedures are saved.

Drawings

In order to more clearly illustrate the embodiments of the present application or technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to the drawings.

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

FIG. 2 is a schematic view of an overall second perspective structure of the present invention;

FIG. 3 is a schematic view of the internal structure of the present invention;

FIG. 4 is a schematic diagram of the internal structure of the base of the present invention;

FIG. 5 is a cross-sectional view of the base of the present invention;

FIG. 6 is a perspective view of the material transfer assembly of the present invention;

FIG. 7 is a schematic view of the connection structure of the punch assembly and the protective shell according to the present invention;

FIG. 8 is a schematic view of the punch assembly of the present invention in an expanded configuration;

FIG. 9 is a schematic view of a punch assembly of the present invention in a retracted configuration;

FIG. 10 is an enlarged view of the structure at A in FIG. 9 according to the present invention;

FIG. 11 is a schematic cross-sectional view of the feeder of the present invention;

FIG. 12 is a schematic view of the connection structure of the feeding female pillar and the first driving belt of the present invention.

Description of the reference numerals:

1. a base; 2. a feeding cylinder; 3. a material conveying motor; 4. fixing a hydraulic cylinder; 5. a stamping die;

101. a material receiving groove; 102. an operation slot; 103. a discharge chute; 104. a material collection chamber; 105. a door; 106. a protective shell; 107. a chute;

201. a servo motor; 202. feeding a concave column; 203. conical teeth; 204. a fixed block; 205. a first drive belt; 206. an electric push rod; 207. an electric cutter;

301. a rotating shaft; 302. a first cam; 303. a second cam; 304. a second belt; 305. a connecting plate; 306. a Y-shaped yoke;

401. a lifting plate; 402. a slide rod; 403. a splint; 404. a first hinge lever; 405. a second hinge lever; 406. a connecting rod;

501. inserting slots; 502. a rod is inserted; 503. a pull rod; 504. a loop bar; 505. a fixing plate; 506. an elastic member.

Detailed Description

In order to make the technical solutions of the present invention better understood, those skilled in the art will now describe the present invention in further detail with reference to the accompanying drawings.

The invention provides stamping forming equipment for corrosion-resistant stainless steel seamless steel pipe fittings shown in figures 1-12, which comprises a base 1, a feeding assembly, a material conveying assembly and a stamping assembly, wherein the feeding assembly, the material conveying assembly and the stamping assembly are arranged in the base 1, a cavity is arranged in the base 1, a material receiving groove 101 for receiving steel pipe profiles, an operation groove 102 for clamping the steel pipe profiles and a material discharging groove 103 for discharging the steel pipe profiles are fixedly connected in the cavity from left to right in sequence, a material collecting cavity 104 is formed in the right side of the material discharging groove 103, and a blocking door 105 is hinged to the right side of the material collecting cavity 104;

the material conveying assembly is arranged inside the base 1, and the material receiving groove 101, the operation groove 102 and the material discharging groove 103 are matched with the material conveying assembly;

the feeding component comprises a feeding cylinder 2, and the output end of the feeding cylinder 2 is matched with the receiving groove 101;

the top of the base 1 is fixedly connected with a protective shell 106, the stamping assembly is arranged inside the protective shell 106 and comprises a clamping plate 403, and the clamping plate 403 is matched with the operation groove 102;

the punching assembly further includes a punching die 5, and the clamp plate 403 and the operation slot 102 are fitted to the punching die 5.

Specifically, inside the user passes through the feeding subassembly with the steel pipe section bar and inputs the device, then the steel pipe section bar drops naturally under the effect of gravity on connecing silo 101, then the user carries the steel pipe section bar that will cut off to operation groove 102 through passing the material subassembly on, carries out stamping forming to the steel pipe section bar through the punching press subassembly, then carries the product after the stamping forming to gather materials the chamber 104 in through passing the material subassembly to the completion is to the stamping forming of steel pipe section bar.

In the structure, the feeding cylinder 2 is fixed inside the protective shell 106, a plurality of feeding roller sets are arranged inside the feeding cylinder 2, each feeding roller set comprises four feeding concave columns 202 which are distributed annularly, two ends of each feeding concave column 202 are fixedly connected with conical teeth 203, the side edges of the conical teeth 203 are rotatably connected with fixing blocks 204 which are fixedly connected with the feeding cylinder 2, the conical teeth 203 at two ends of the four feeding concave columns 202 are connected end to end, and every two adjacent conical teeth 203 are meshed and connected, the input end of one feeding concave column 202 is provided with a servo motor 201, a plurality of groups of feeding roller sets are connected through a first transmission belt 205, a plurality of feeding concave columns 202 are all arranged in a concave manner, four feeding concave columns 202 in each group of feeding roller sets form a ring shape, and each feeding concave column 202 is contacted with the section bar, and a plurality of groups of feeding roller groups are coaxially arranged.

Specifically, the user is when carrying out the feeding to steel pipe section bar, can place inside feeding section of thick bamboo 2 through corrosion-resistant stainless steel seamless steel pipe section bar, then start servo motor 201, servo motor 201 drives the feeding spill post 202 of the below in one of them feeding roller set and rotates, feeding spill post 202 passes through the awl tooth 203 at both ends, the feeding spill post 202 that drives its both sides rotates, and then the feeding spill post 202 that drives the top rotates, thereby can promote inside steel pipe section bar, make it enter into protecting crust 106 inside, wherein, feeding spill post 202 that servo motor 201 drove drives the synchronous rotation of feeding spill post 202 of below in the multiunit feeding roller set through first drive belt 205, and then can carry out the automatic feed setting to the section bar.

As shown in fig. 3 and fig. 11, an electric cutter 207 is disposed at the outlet of the feeding cylinder 2, an electric push rod 206 is fixedly mounted on the inner top wall of the protective shell 106, the top of the electric cutter 207 is fixedly connected with the output end of the electric push rod 206, and the output end of the electric cutter 207 is located at the rear side of the material receiving slot 101 and does not contact with the material receiving slot 101.

Specifically, inside steel pipe section bar moved to stretch out and enter into behind feed cylinder 2 and connect silo 101, after the extension reached required length, closed servo motor 201, the user can be through starting electric putter 206, and electric putter 206 drives electric cutter 207 and moves down, starts electric cutter 207 simultaneously to cut steel pipe section bar, the steel pipe section bar after the cutting drops naturally and connects silo 101 inside.

In the further optimization in the above-mentioned embodiment, it includes that the material subassembly passes two sets of material mechanisms to pass, it includes first cam 302 and second cam 303 to pass the material mechanism, the inside left and right sides of base 1 rotates and is connected with two parallel arrangement's axis of rotation 301, be connected with second drive belt 304 between two axis of rotation 301, it installs and passes material motor 3 to pass the input of one of them axis of rotation 301, one of them axis of rotation 301 tip and first cam 302 fixed connection, the tip and the second cam 303 fixed connection of another axis of rotation 301, be connected with connecting plate 305 between the tip of first cam 302 and second cam 303, and first cam 302 and second cam 303 all rotate with connecting plate 305 and be connected.

Concretely, the user can be through starting to pass material motor 3, it drives axis of rotation 301 rotation to pass material motor 3, under the effect of second drive belt 304, two axis of rotation 301 synchronous rotations, and then drive first cam 302 and the synchronous clockwise rotation of second cam 303, and further drive connecting plate 305 and rotate, because the tip of first cam 302 and second cam 303 all is connected with connecting plate 305, consequently when driving connecting plate 305 pivoted, can make connecting plate 305 keep balanced, be convenient for hold the transmission of steel pipe section, prevent that steel pipe section from taking place the phenomenon of turning on one's side.

In the structure, the two groups of material conveying mechanisms are symmetrically distributed at the front end and the rear end of the rotating shaft 301, the two ends of the inner side of the connecting plate 305 are fixedly connected with the Y-shaped fork levers 306, the distance between the Y-shaped fork levers 306 at the two ends of the inner side of the connecting plate 305 is equal to the distance between the material receiving groove 101 and the operation groove 102 and the distance between the operation groove 102 and the material discharging groove 103, the Y-shaped fork levers 306 at the front side and the rear side are located on the front sides of the operation groove 102, the material discharging groove 103 and the material collecting cavity 104, and the rear Y-shaped fork levers 306 are located on the rear sides of the operation groove 102, the material discharging groove 103 and the material collecting cavity 104, so that the Y-shaped fork levers 306 do not generate movement interference with the operation groove 102, the material discharging groove 103 and the material collecting cavity 104.

Specifically, in connecting plate 305 pivoted, drive Y type fork 306 activity, left Y type fork is connecing the silo 101 and is moving between the operation groove 102, the Y type fork 306 on right side moves between operation groove 102 and blown down tank 103, left Y type fork 306 clockwise rotates, will connect the steel pipe section bar in the silo 101 to hold up the back, rotate to operation groove 102 top, and then place the steel pipe section bar inside operation groove 102, the Y type fork 306 clockwise on right side rotates, hold up the back with the steel pipe section bar in the operation groove 102, rotate to blown down tank 103 top, and place the steel pipe section bar inside blown down tank 103, blown down tank 103 slope sets up, it slides naturally to the chamber of gathering materials 104 of avris to drive the steel pipe section bar inside, and collect the product.

As a further optimization of the invention, a fixed hydraulic cylinder 4 is mounted on the top of the protective shell 106, the output end of the fixed hydraulic cylinder 4 extends into the protective shell 106, the output end of the fixed hydraulic cylinder 4 is fixedly connected with a lifting plate 401, a slide rod 402 is connected between the lifting plate 401 and a clamping plate 403, the slide rod 402 is fixed on the top of the clamping plate 403 and penetrates through the lifting plate 401, an anti-drop block is fixedly connected on the top of the slide rod 402, and a spring is arranged on the outer side of the slide rod 402.

Specifically, after the steel pipe section enters the operation groove 102, the user can start the fixed hydraulic cylinder 4, the fixed hydraulic cylinder 4 pushes the lifting plate 401 to descend, the lifting plate 401 drives the clamp plate 403 to descend, wherein the clamp plate 403 is matched with the operation groove 102, the steel pipe section inside the operation groove 102 can be extruded and fixed, the steel pipe section is prevented from being displaced in the stamping process, after the clamp plate 403 is contacted with the steel pipe section, the fixed hydraulic cylinder 4 continues to push the lifting plate 401 to descend, so that the sliding rod 402 at the top of the clamp plate 403 slides on the lifting plate 401, under the action of the spring, the clamp plate 403 is pushed to clamp the steel pipe section more closely, the anti-disengaging block can limit the distance between the clamp plate 403 and the lifting plate 401, the clamp plate 403 is prevented from disengaging, and further the first hinge rod 404 and the second hinge rod 405 are enabled to always keep a certain included angle.

In the structure, the top of the clamping plate 403 is hinged with a first hinge rod 404, the top of the first hinge rod 404 is hinged with a second hinge rod 405, the joint of the first hinge rod 404 and the second hinge rod 405 is hinged with a connecting rod 406, the outer side of the connecting rod 406 is rotatably connected with a loop rod 504, the side of the loop rod 504 is fixedly connected with a pull rod 503, the end part of the pull rod 503 is fixedly connected with an inserted link 502, and the inside of the stamping die 5 is provided with a slot 501 matched with the inserted link 502.

Specifically, when the litter 402 is slided on the lifter plate 401, because the distance between splint 403 and the lifter plate 401 reduces, and then drive first articulated rod 404 and second articulated rod 405 and rotate, thereby promote the inboard activity of connecting rod 406 between first articulated rod 404 and the second articulated rod 405, and then drive loop bar 504 to the inside activity, loop bar 504 drives inserted bar 502 through pull rod 503 and is moving to the inside activity, because inserted bar 502 extends to in the slot 501 of stamping die 5, and then can drive stamping die 5 and move to the inboard, and then carry out the punching press to inside steel tubular product.

In the structure, stamping die 5's quantity is provided with two, two stamping die 5 symmetric distribution are both sides around base 1, the equal fixedly connected with fixed plate 505 in both sides around base 1, fixed plate 505 and stamping die 5 between the fixed connection elastic component 506, spout 107 has been seted up at the top of base 1, stamping die 5's bottom fixedly connected with and spout 107 matched with fixed slider, wherein inserted bar 502 runs through stamping die 5 and extends to inside the base 1, inside base 1 be provided with inserted bar 502 matched with slide rail, make the bottom of inserted bar 502 be in stamping die 5's inside all the time, not only can carry on spacingly to stamping die 5, and can make inserted bar 502, pull rod 503 and loop bar 504 remain stable.

Specifically, because stamping die 5's quantity is provided with two, can carry out the punching press simultaneously to the both ends of steel pipe section bar simultaneously, improved the machining efficiency of device greatly, wherein the fixed slider of stamping die 5 bottom slides in spout 107 is inside, can carry on spacingly to stamping die 5, elastic component 506 can stimulate stamping die 5 and reset, after stamping die 5 resets, keep away from operation groove 102, the next operation of the biography material subassembly of being convenient for, and do not produce with passing the material subassembly and interfere.

The machining process of the punch forming equipment for the corrosion-resistant stainless steel seamless steel pipe fitting comprises the steps of:

s1: inputting the steel pipe section into the device through a feeding assembly;

s2: cutting the steel pipe section by an electric cutter 207;

s3: conveying the cut steel pipe section to the operation groove 102 through the material conveying assembly;

s4: the steel pipe section is subjected to punch forming through the punching assembly;

s5: the punched and formed product is conveyed into the aggregate cavity 104 through the material conveying assembly.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims (9)

1. The utility model provides a stamping forming equipment of corrosion-resistant stainless steel seamless steel pipe fitting, includes base (1), sets up in the inside feeding subassembly of base (1), passes material subassembly and punching press subassembly, its characterized in that: a cavity is formed in the base (1), a material receiving groove (101) for receiving a steel pipe profile, an operation groove (102) for clamping the steel pipe profile and a material discharging groove (103) for discharging the steel pipe profile are sequentially and fixedly connected in the cavity from left to right, a material collecting cavity (104) is formed in the right side of the material discharging groove (103), and a stop door (105) is hinged to the right side of the material collecting cavity (104);

the material conveying assembly is arranged inside the base (1), and a material receiving groove (101), an operation groove (102) and a material discharging groove (103) are matched with the material conveying assembly;

the feeding assembly comprises a feeding cylinder (2), and the output end of the feeding cylinder (2) is matched with the receiving groove (101);

a protective shell (106) is fixedly connected to the top of the base (1), the stamping assembly is arranged inside the protective shell (106), the stamping assembly comprises a clamping plate (403), and the clamping plate (403) is matched with the operating groove (102);

the stamping assembly further comprises a stamping die (5), and the clamping plate (403) and the operation groove (102) are matched with the stamping die (5).

2. The punch forming equipment for the corrosion-resistant stainless steel seamless steel pipe fitting according to claim 1, characterized in that: the inside at protecting crust (106) is fixed in feeding section of thick bamboo (2), the inside of feeding section of thick bamboo (2) is provided with a plurality of feeding roller sets, each the feeding roller set all includes feeding concave post (202) that four rings shape distributes, each the equal fixedly connected with awl tooth (203) in both ends of feeding concave post (202), the avris of awl tooth (203) all rotates be connected with feeding section of thick bamboo (2) fixed block (204), four awl tooth (203) end to end at feeding concave post (202) both ends, and every two adjacent awl tooth (203) meshing connection, servo motor (201) are installed to the input of one of them feeding concave post (202), the multiunit connect through first drive belt (205) between the feeding roller set.

3. The press forming equipment for the corrosion-resistant stainless steel seamless steel pipe fitting according to claim 2, wherein: an electric cutter (207) is arranged at an outlet of the feeding barrel (2), an electric push rod (206) is fixedly mounted on the inner top wall of the protective shell (106), and the top of the electric cutter (207) is fixedly connected with the output end of the electric push rod (206).

4. The press forming equipment for the corrosion-resistant stainless steel seamless steel pipe fitting according to claim 1, wherein: pass the material subassembly and include two sets of material mechanisms of passing, it includes first cam (302) and second cam (303) to pass the material mechanism, the inside left and right sides of base (1) is rotated and is connected with two parallel arrangement's axis of rotation (301), two be connected with second drive belt (304) between axis of rotation (301), one of them the input of axis of rotation (301) is installed and is passed material motor (3), one of them axis of rotation (301) tip and first cam (302) fixed connection, another the tip and second cam (303) fixed connection of axis of rotation (301) are connected with connecting plate (305) between the tip of first cam (302) and second cam (303), and first cam (302) and second cam (303) all rotate with connecting plate (305) and are connected.

5. The press forming equipment for the corrosion-resistant stainless steel seamless steel pipe fitting according to claim 4, wherein: the two groups of material conveying mechanisms are symmetrically distributed at the front end and the rear end of the rotating shaft (301), Y-shaped fork rods (306) are fixedly connected to the two ends of the inner side of the connecting plate (305), and the distance between the Y-shaped fork rods (306) at the two ends of the inner side of the connecting plate (305) is equal to the distance between the material receiving groove (101) and the operating groove (102) and the distance between the operating groove (102) and the material discharging groove (103).

6. The press forming equipment for the corrosion-resistant stainless steel seamless steel pipe fitting according to claim 1, wherein: fixed pneumatic cylinder (4) are installed at the top of protecting crust (106), the output of fixed pneumatic cylinder (4) extends to inside protecting crust (106), and the output fixedly connected with lifter plate (401) of fixed pneumatic cylinder (4), be connected with litter (402) between lifter plate (401) and splint (403), litter (402) are fixed at the top of splint (403) and are run through lifter plate (401), the top fixedly connected with anticreep piece of litter (402).

7. The punch forming equipment for the corrosion-resistant stainless steel seamless steel pipe fitting according to claim 6, wherein the punch forming equipment comprises: the top of splint (403) articulates there is first articulated rod (404), the top of first articulated rod (404) articulates there is second articulated rod (405), the junction of first articulated rod (404) and second articulated rod (405) articulates there is connecting rod (406), the outside of connecting rod (406) is rotated and is connected with loop bar (504), avris fixedly connected with pull rod (503) of loop bar (504), the tip fixedly connected with inserted bar (502) of pull rod (503), the inside of stamping die (5) is provided with slot (501) with inserted bar (502) matched with.

8. The press forming equipment for the corrosion-resistant stainless steel seamless steel pipe fitting according to claim 1, wherein: the quantity of stamping die (5) is provided with two, two stamping die (5) symmetric distribution is both sides around base (1), the equal fixedly connected with fixed plate (505) in both sides around base (1), fixed connection elastic component (506) between fixed plate (505) and stamping die (5), spout (107) have been seted up at the top of base (1), the bottom fixedly connected with and spout (107) matched with solid fixed sliding block of stamping die (5).

9. A processing technology of punch forming equipment for corrosion-resistant stainless steel seamless steel pipes comprises the punch forming equipment for corrosion-resistant stainless steel seamless steel pipes according to any one of claims 1 to 8, and is characterized in that: the method comprises the following specific steps:

s1: inputting the steel pipe section into the device through a feeding assembly;

s2: cutting the steel pipe section by an electric cutter (207);

s3: conveying the cut steel pipe section to an operation groove (102) through a material conveying assembly;

s4: performing punch forming on the steel pipe profile through a punching assembly;

s5: conveying the punched and formed product into a material collecting cavity (104) through a material conveying assembly.

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