CN113385613B - Steel fiber pressure-feeding type production equipment based on wave method principle - Google Patents

Abstract

The invention relates to steel fiber production equipment, in particular to steel fiber pressure-feeding type production equipment based on a wave method principle. In particular to steel fiber pressure-feeding type production equipment based on a wave method principle, which is free from manual cutting, improves efficiency and ensures processing quality. A steel fiber pressure-feeding type production device based on a wave method principle comprises: the base, base top one side is equipped with the mount pad, and the mount pad top is equipped with servo motor, is equipped with 2 first sector gears on servo motor's the output shaft. The basic functions of the device are realized by arranging the upper clamping plate and the lower clamping plate and pressing the steel fibers by a wave method.

Description

Steel fiber pressure-feeding type production equipment based on wave method principle

Technical Field

The invention relates to steel fiber production equipment, in particular to steel fiber pressure-feeding type production equipment based on a wave method principle.

Background

The steel fiber is short fiber of steel, cut off steel wire, pressed into hooks at two ends according to a specified pattern, has certain strength, is mainly used for manufacturing steel fiber concrete, is applied to the fields of tunnels, industrial floors and the like, and can be selected from various special-shaped steel fibers for increasing interface bonding of the fiber and mortar or concrete.

At present, a cutter and a punch are generally used for steel fiber processing means, a rotary cutter is generally used for cutting extruded steel fibers, the cutting efficiency of a human hand is too low, the cutting efficiency of a machine is obviously improved, but the processing cost is increased, so that the design of steel fiber pressure-feeding type production equipment based on the principle of a wave method is required, the efficiency is improved, and the processing quality is ensured.

Disclosure of Invention

In order to overcome the defects that the direct cutting efficiency of hands is too low and the cutting efficiency of a machine is obviously improved but the processing cost is increased in the prior art, the invention provides steel fiber feeding and pressing type production equipment based on the principle of a wave method, which is free from cutting by hands, improves the efficiency and ensures the processing quality.

The technical scheme of the invention is as follows: a steel fiber pressure-feeding type production device based on a wave method principle comprises:

the device comprises a base, wherein an installation seat is arranged on one side of the top of the base, a servo motor is arranged on the top of the installation seat, and 2 first sector gears are arranged on an output shaft of the servo motor;

the first racks are arranged on the top of the base in a sliding mode, and are respectively meshed with the first sector gears on the same side in an intermittent mode;

the first return springs are connected between the bottoms of the first racks and the top of the base;

the upper clamping plate is connected between the tops of the first racks, and contact blocks are symmetrically arranged at the upper part of the upper clamping plate;

the support frame is arranged at the top of the base, and 2 jacking blocks are slidably arranged at the top of the support frame;

the second reset springs are connected between the inner side of the jacking block and the top of the support frame;

the lower clamping plate is arranged at the top of the support frame in a sliding manner, and a plurality of third reset springs are connected between the bottom of the lower clamping plate and the top of the support frame;

the feeding placing mechanism is arranged at the top of the base and can be used for conveying steel fibers, and the feeding placing mechanism is positioned at one side of the servo motor;

the steel sheet slitter is arranged at the top of the base and can slit steel fibers, and the steel sheet slitter is positioned at the other side of the servo motor;

the shredding mechanism is arranged at the top of the base and can shred the steel fibers.

As a preferable technical scheme of the invention, when the contact block is matched with the jacking block, the lower clamping plate is driven to be contacted with the upper clamping plate to extrude the steel fibers into a waveform.

As a preferred technical scheme of the invention, the feeding and placing mechanism comprises:

the top of the base is provided with 2 mounting frames;

the upper clamping wheels are rotatably arranged between the mounting frames;

the lower clamping wheel is rotatably arranged between the mounting frames.

As a preferable technical scheme of the invention, the steel sheet slitter comprises:

the bearing seat is arranged on one side of the top of the base, and the high-speed motor is arranged on the top of the bearing seat;

the strip cutting tool is rotatably arranged at the top of the base, and a first gear set is connected between the strip cutting tool and an output shaft of the high-speed motor.

As a preferred technical scheme of the invention, the shredding mechanism comprises:

the support bracket is arranged at the top of the base, and 2 second racks are arranged on one side of the support bracket in a sliding manner;

a fourth reset spring is connected between the bottom of the second rack and the support bracket;

the output shaft of the high-speed motor and one side of the top of the base are connected with second sector gears, and the second sector gears are intermittently meshed with second racks on the same side;

the top of the second rack is connected with a shredding cutter;

and a second gear set is connected between the rotating shaft of the second sector gear at one side and the slitting cutter.

As a preferable technical scheme of the invention, the invention also comprises a raw material placing mechanism, wherein the raw material placing mechanism comprises:

the mounting support is arranged on one side of the top of the base, and a placing support column is rotatably arranged between the tops of the mounting supports;

and the detachable mounting plate is arranged on one side of the support column in a threaded manner.

As a preferable technical scheme of the invention, the invention also comprises a raw material feeding mechanism, wherein the raw material feeding mechanism comprises:

the upper feeding wheel is rotatably arranged at the upper part of the bearing bracket, and a first belt pulley is connected between the two sides of the upper feeding wheel and the output shaft of the servo motor;

a lower feeding wheel is rotatably arranged at the top of the base;

the inner side of the upper part of the bearing bracket is rotatably provided with 2 rotating rods, and the third gear set is connected between the rotating rods and the upper feeding wheel;

and the second belt pulleys are connected between the rotating rod and the lower feeding wheel.

As a preferred technical scheme of the invention, the invention also comprises a screening mechanism, wherein the screening mechanism comprises:

the driving lever is arranged on the output shaft of the high-speed motor and the rotating shaft of the second sector gear at one side;

the top of the base is provided with 2 supporting guide frames;

the upper parts of the supporting guide frames are provided with the contact rods in a sliding manner, and the contact rods are matched with the deflector rods;

a limiting spring is connected between the contact rod and the inner wall of the supporting guide frame;

the waste material collecting frame is connected between the inner sides of the contact rods, and a plurality of detachable nuts are connected between the two sides of the waste material collecting frame and the contact rods;

the filter screen is placed to filter screen, waste material collection frame inner wall slidingtype.

As a preferable technical scheme of the invention, the invention also comprises a material stirring mechanism, wherein the material stirring mechanism comprises:

the top of the base is provided with 2 mounting guide frames;

the transmission gears are rotatably arranged on the outer sides of the upper parts of the installation guide frames;

the guide plates are arranged between the tops of the installation guide frames in a sliding manner, and the bottoms of the guide plates are provided with poking sheets;

the guide plate is provided with a first rack and a second rack;

and the middle part of the contact rod is provided with a third rack, and the third rack and the fourth rack are matched with the same-side transmission gear.

The beneficial effects are that: the basic functions of the device are realized by arranging an upper clamping plate and a lower clamping plate and pressing steel fibers by a wave method; the steel fibers are placed by arranging the feeding placement mechanism, the raw material placement mechanism and the raw material feeding mechanism, and then the steel fibers are driven to automatically convey and feed to the right, so that the steel fibers are not required to be pushed by hands, and safety accidents are prevented; the steel sheet slitter and the shredding mechanism are arranged, so that the pressed steel fibers are firstly slitted and then shredded, and the steel sheet slitter is automatically processed and produced, thereby being convenient and quick; through setting up screening mechanism and stirring mechanism, stir the steel fiber that the cutting was accomplished, realize the filtration to the steel wire in the manufacturing process, improve the manufacturing quality of steel fiber.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic view of a partial perspective structure of the present invention.

Fig. 3 is a schematic perspective view of the feeding placement mechanism of the present invention.

Fig. 4 is a schematic perspective view of a steel sheet slitter and a slitter according to the present invention.

Fig. 5 is a schematic perspective view of the raw material placement mechanism and the raw material feeding mechanism of the present invention.

Fig. 6 is a schematic perspective view of a screening mechanism and a kick-out mechanism according to the present invention.

Fig. 7 is an exploded view of a partial perspective structure of the present invention.

Fig. 8 is an exploded view of a portion of the shredder mechanism of the present invention.

FIG. 9 is an exploded view of the stock placement mechanism of the present invention.

Wherein: 1-base, 2-mount, 3-servo motor, 4-first sector gear, 5-first rack, 6-first reset spring, 7-upper clamp plate, 8-support frame, 9-contact block, 10-jacking block, 11-second reset spring, 12-lower clamp plate, 13-third reset spring, 14-feeding placement mechanism, 141-mount, 142-lower clamp wheel, 143-upper clamp wheel, 15-steel sheet slitting mechanism, 151-bearing seat, 152-high speed motor, 153-first gear set, 154-slitting cutter, 16-slitting mechanism, 161-support bracket, 162-second sector gear, 163-second rack, 164-fourth reset spring, 165-slitting cutter, 166-second gear set, 17-raw material placing mechanism, 171-mounting bracket, 172-placing pillar, 173-detachable mounting plate, 18-raw material feeding mechanism, 181-bearing bracket, 182-first belt pulley, 183-upper feed wheel, 184-third gear set, 185-second belt pulley, 186-lower feed wheel, 19-screening mechanism, 191-supporting guide, 192-deflector rod, 193-contact rod, 194-limit spring, 195-detachable nut, 196-filter screen, 197-waste material collecting frame, 20-deflector mechanism, 201-mounting guide, 202-third rack, 203-transmission gear, 204-fourth rack, 205-guide plate, 206-deflector plate.

Detailed Description

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

Example 1

The steel fiber pressure-feeding type production equipment based on the wave method principle comprises a base 1, an installation seat 2, a servo motor 3, a first sector gear 4, a first rack 5, a first return spring 6, an upper clamping plate 7, a support frame 8, a contact block 9, a jacking block 10, a second return spring 11, a lower clamping plate 12, a third return spring 13, a feeding placement mechanism 14, a steel sheet slitter mechanism 15 and a shredding mechanism 16, wherein the installation seat 2 is arranged on the front side of the top of the base 1, the servo motor 3 is arranged on the top of the installation seat 2, 2 first sector gears 4 are arranged on the output shaft of the servo motor 3 in a front-back symmetrical manner, 2 first racks 5 are arranged on the top of the base 1 in a sliding manner, the first racks 5 are symmetrically arranged in a front-back manner, the first racks 5 are respectively meshed with the first sector gears 4 on the same side intermittently, a first reset spring 6 is connected between the bottom of the first rack 5 and the top of the base 1, an upper clamping plate 7 is connected between the tops of the first racks 5, contact blocks 9 are symmetrically arranged at the upper part of the upper clamping plate 7, a supporting frame 8 is arranged at the top of the base 1, 2 jacking blocks 10 are slidably arranged at the top of the supporting frame 8, the jacking blocks 10 are symmetrically arranged front and back, 2 second reset springs 11 are connected between the inner sides of the jacking blocks 10 and the top of the supporting frame 8, a lower clamping plate 12 is slidably arranged at the top of the supporting frame 8, 3 third reset springs 13 are connected between the bottom of the lower clamping plate 12 and the top of the supporting frame 8, a feeding placing mechanism 14 capable of conveying steel fibers is arranged at the top of the base 1, the feeding placing mechanism 14 is positioned at the left side of the servo motor 3, a steel sheet slitting mechanism 15 capable of slitting the steel fibers is arranged at the top of the base 1, the slitting mechanism 15 is positioned at the right side of the servo motor 3, the top of the base 1 is provided with a shredding mechanism 16 which can shred the steel fibers.

When the contact block 9 is matched with the jacking block 10, the lower clamping plate 12 is driven to be contacted and matched with the upper clamping plate 7 to extrude the steel fibers into a wave shape.

Starting the servo motor 3, the staff can put one end of the steel fiber into the feeding placing mechanism 14, then the steel fiber is conveyed between the lower clamping plate 12 and the upper clamping plate 7, the output shaft of the servo motor 3 rotates to drive the first sector gear 4 to rotate, when the first sector gear 4 rotates to be in contact with the first rack 5, the first rack 5 moves downwards to drive the upper clamping plate 7 to move downwards, the first return spring 6 is compressed, the upper clamping plate 7 moves downwards to drive the contact block 9 to be matched with the jacking block 10, the jacking block 10 moves inwards to drive the lower clamping plate 12 to move upwards, the second return spring 11 is compressed, the third return spring 13 is stretched, so that the lower clamping plate 12 and the upper clamping plate 7 move relatively to squeeze the steel fiber into waveforms, after the extrusion is finished, the first sector gear 4 rotates to be out of contact with the first rack 5, the first return spring 6, the second return spring 11 and the third return spring 13 reset to drive the rear parts of the lower clamping plate 12 to reversely operate to reset, the lower clamping plate 12 moves back to the steel sheet to the right, the extruded steel fiber can be conveyed to be in contact with the cutting mechanism 15 and the cutting mechanism 16 to cut the steel fiber, and the servo motor 3 can stop the operation of the steel fiber is finished, and the cutting operation of the steel fiber is finished.

Example 2

On the basis of embodiment 1, as shown in fig. 3, 4 and 8, the feeding and placing mechanism 14 comprises a mounting frame 141, a lower clamping wheel 142 and an upper clamping wheel 143, wherein 2 mounting frames 141 are arranged at the top of the base 1, the mounting frames 141 are symmetrically arranged front and back, the upper clamping wheels 143 are rotatably arranged between the upper parts of the mounting frames 141, and the lower clamping wheels 142 are rotatably arranged between the lower parts of the mounting frames 141.

The steel sheet slitter 15 includes a bearing seat 151, a high-speed motor 152, a first gear set 153 and a slitter 154, wherein the bearing seat 151 is disposed on the right front side of the top of the base 1, the high-speed motor 152 is disposed on the top of the bearing seat 151, the slitter 154 is rotatably disposed on the top of the base 1, and the first gear set 153 is connected between the front of the slitter 154 and the output shaft of the high-speed motor 152.

The shredder mechanism 16 includes a support bracket 161, a second sector gear 162, a second rack 163, a fourth return spring 164, a shredder 165 and a second gear set 166, the top of the base 1 is provided with the support bracket 161, the left side of the support bracket 161 is slidably provided with 2 second racks 163, the second racks 163 are symmetrically arranged in front and back, the fourth return spring 164 is connected between the bottom of the second racks 163 and the support bracket 161, the output shaft of the high-speed motor 152 and the rear side of the top of the base 1 are both connected with the second sector gear 162, the second sector gear 162 is symmetrically arranged in front and back, the second sector gear 162 is intermittently meshed with the second racks 163 on the same side, the top of the second racks 163 is connected with the shredder 165, and the second gear set 166 is connected between the rotating shaft of the second sector gear 162 on the back side and the rear of the shredder 154.

The staff can draw out the steel fiber between lower clamp wheel 142 and upper clamp wheel 143, again with steel fiber transfer between lower plate 12 and upper plate 7, start servo motor 3, servo motor 3's output shaft rotates and drives lower plate 12 and upper plate 7 to extrude the design to steel fiber, the steel fiber that the design was accomplished continues to move to the right and contact with slitting cutter 154, start high-speed motor 152, high-speed motor 152's output shaft rotates and drives slitting cutter 154 through first gear train 153 and rotates and cut the strip to the steel fiber that moves, the steel fiber after the slitting continues to move right, high-speed motor 152's output shaft rotates and drives the contact of front side second sector gear 162 and second rack 163, simultaneously slitting cutter 154 rotates and drives rear side second sector gear 162 and second rack 163 through second gear train 166, second rack 163 moves down and drives the slitting cutter 165 to cut the steel fiber, fourth reset spring 164 is compressed, when second sector gear 162 does not contact with second rack 163, fourth reset spring 164 stretches and drives second rack 163 and cutter 165 and moves upward, the reciprocating operation of the slitting operation of the steel fiber that cuts the high-speed is accomplished, thus cut and finished.

Example 3

On the basis of embodiment 2, as shown in fig. 5 and 9, the device further comprises a raw material placing mechanism 17, wherein the raw material placing mechanism 17 comprises a mounting bracket 171, a placing support 172 and a detachable mounting disc 173, the mounting bracket 171 is arranged on the left side of the top of the base 1, the placing support 172 is rotatably arranged between the tops of the mounting brackets 171, and the detachable mounting disc 173 is arranged on the front side of the placing support 172 in a threaded manner.

The staff can rotate the detachable mounting plate 173 and break away from and place the pillar 172, place the coiled steel fiber on placing the pillar 172, after placing, rotate the detachable mounting plate 173 and reset, so can pull out the one end of steel fiber through between lower pinch roller 142 and upper pinch roller 143, cooperation production.

The feeding device is characterized by further comprising a raw material feeding mechanism 18, wherein the raw material feeding mechanism 18 comprises a bearing bracket 181, a first belt pulley 182, an upper feeding wheel 183, a third gear set 184, a second belt pulley 185 and a lower feeding wheel 186, the top of the base 1 is provided with the bearing bracket 181, the upper portion of the bearing bracket 181 is rotatably provided with the upper feeding wheel 183, the front side and the rear side of the upper feeding wheel 183 are respectively connected with the output shaft of the servo motor 3 through the first belt pulley 182, the top of the base 1 is rotatably provided with the lower feeding wheel 186, the lower feeding wheel 186 is positioned below the left side of the upper feeding wheel 183, the inner side of the upper portion of the bearing bracket 181 is rotatably provided with 2 rotating rods, the third gear set 184 is connected between each rotating rod and the upper feeding wheel 183, and the second belt pulley 185 is connected between each rotating rod and the lower feeding wheel 186.

The staff can pull out one end of the steel fiber and bypass the bottom of the lower feeding wheel 186 and the top of the upper feeding wheel 183, then the steel fiber is transmitted between the lower clamping plate 12 and the upper clamping plate 7 through the space between the lower clamping wheel 142 and the upper clamping wheel 143, the output shaft of the servo motor 3 rotates to drive the upper feeding wheel 183 to rotate through the first belt pulley 182, the upper feeding wheel 183 rotates to drive the second belt pulley 185 to rotate through the third gear set 184, the second belt pulley 185 rotates to drive the lower feeding wheel 186 to rotate, and therefore the lower feeding wheel 186 and the upper feeding wheel 183 rotate to drive the steel fiber to be transmitted and fed.

Example 4

On the basis of embodiment 3, as shown in fig. 6, screening mechanism 19 is further included, screening mechanism 19 is including supporting guide 191, driving lever 192, contact lever 193, limit spring 194, detachable nut 195, filter screen 196 and waste material collection frame 197, all be equipped with driving lever 192 on the axis of rotation of the output shaft of high-speed motor 152 and rear side second sector gear 162, base 1 top is equipped with 2 supporting guide 191, supporting guide 191 is the fore-and-aft symmetry setting, supporting guide 191 upper portion all is equipped with contact lever 193 in the slidingtype, contact lever 193 cooperates with driving lever 192, be connected with limit spring 194 between contact lever 193 and the supporting guide 191 inner wall, be connected with waste material collection frame 197 between the contact lever 193 inboard, be connected with a plurality of detachable nuts 195 between waste material collection frame 197 front and back both sides and contact lever 193, filter screen 196 has been placed to waste material collection frame 197 inner wall slidingtype.

When the steel fibers after shredding are moved rightwards and automatically fall onto a filter screen 196 in a waste material collecting frame 197, an output shaft of a high-speed motor 152 rotates to drive a deflector rod 192 to rotate and intermittently contact a contact rod 193, when the deflector rod 192 contacts with the contact rod 193 and drives the deflector rod to be extruded, the contact rod 193 moves rightwards to drive the waste material collecting frame 197 and parts above to move rightwards, a limiting spring 194 deforms, when the deflector rod 192 does not contact with the contact rod 193, the limiting spring 194 resets to drive the waste material collecting frame 197 to move leftwards, so that the waste material collecting frame 197 moves leftwards and rightwards to shake the steel fibers in the steel fibers, the steel fibers in the steel fibers can be filtered in the manufacturing process, a certain number of steel fibers are piled on the filter screen 196, equipment operation is stopped, the filter screen 196 is pushed to move upwards to separate from the waste material collecting frame 197, the steel fibers on the filter screen 196 are collected, and the steel fibers in the waste material collecting frame 197 are recovered.

Still including the stirring mechanism 20, stirring mechanism 20 is including installation guide 201, third rack 202, drive gear 203, fourth rack 204, deflector 205 and plectrum 206, base 1 top is equipped with 2 installation guide 201, installation guide 201 is the front and back symmetry setting, the equal rotation in the outside of installation guide 201 upper portion is equipped with drive gear 203, sliding type is equipped with deflector 205 between the installation guide 201 top, deflector 205 bottom is equipped with plectrum 206, both sides all are equipped with fourth rack 204 around the deflector 205, contact lever 193 middle part right side all is equipped with third rack 202, third rack 202 and fourth rack 204 all cooperate with homonymy drive gear 203.

The contact rod 193 moves left and right to drive the transmission gear 203 to rotate in a forward and reverse reciprocating manner through the third rack 202, the transmission gear 203 rotates to drive the guide plate 205 and the shifting plate 206 to move left and right in a reciprocating manner through the fourth rack 204, and the shifting plate 206 moves left and right to shift steel fibers piled on the filter screen 196 to match with filtration.

The foregoing has shown and described the basic principles, principal features and advantages of the invention; it will be understood by those skilled in the art that the present invention is not limited to the foregoing embodiments, which have been described in the foregoing embodiments and description merely illustrates the principles of the invention, and that various changes and modifications may be effected therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents.

Claims (6)

1. A steel fiber pressure-feeding type production device based on a wave method principle is characterized by comprising the following components:

the device comprises a base (1), wherein an installation seat (2) is arranged on one side of the top of the base (1), a servo motor (3) is arranged on the top of the installation seat (2), and 2 first sector gears (4) are arranged on an output shaft of the servo motor (3);

the first racks (5), 2 first racks (5) are arranged on the top of the base (1) in a sliding manner, and the first racks (5) are respectively meshed with the first sector gears (4) on the same side intermittently;

the first return springs (6) are connected between the bottoms of the first racks (5) and the top of the base (1);

an upper clamping plate (7), wherein the upper clamping plate (7) is connected between the tops of the first racks (5), and contact blocks (9) are symmetrically arranged at the upper part of the upper clamping plate (7);

the support frame (8) is arranged at the top of the base (1), and 2 jacking blocks (10) are arranged at the top of the support frame (8) in a sliding manner;

the second return springs (11) are connected between the inner side of the jacking block (10) and the top of the supporting frame (8);

the lower clamping plate (12) is arranged at the top of the support frame (8) in a sliding manner, and a plurality of third return springs (13) are connected between the bottom of the lower clamping plate (12) and the top of the support frame (8);

the feeding placing mechanism (14), the feeding placing mechanism (14) capable of conveying the steel fibers is arranged at the top of the base (1), and the feeding placing mechanism (14) is positioned at one side of the servo motor (3);

the steel sheet slitter mechanism (15) is arranged at the top of the base (1), the steel sheet slitter mechanism (15) can slit steel fibers, and the steel sheet slitter mechanism (15) is positioned at the other side of the servo motor (3);

the top of the base (1) is provided with a shredding mechanism (16) which can shred the steel fibers;

the steel sheet slitter constructs (15) including:

the high-speed motor comprises a bearing seat (151), wherein one side of the top of the base (1) is provided with the bearing seat (151), and the top of the bearing seat (151) is provided with a high-speed motor (152);

the strip cutting tool (154), the strip cutting tool (154) is rotatably arranged at the top of the base (1), and a first gear set (153) is connected between the strip cutting tool (154) and the output shaft of the high-speed motor (152);

the shredding mechanism (16) comprises:

the support bracket (161) is arranged at the top of the base (1), the support bracket (161) is provided with 2 second racks (163) on one side of the support bracket (161) in a sliding manner;

a fourth return spring (164), wherein the fourth return spring (164) is connected between the bottom of the second rack (163) and the support bracket (161);

the output shaft of the high-speed motor (152) and one side of the top of the base (1) are connected with the second sector gear (162), and the second sector gear (162) is intermittently meshed with a second rack (163) on the same side;

the top of the second rack (163) is connected with a shredding cutter (165);

a second gear set (166), wherein the second gear set (166) is connected between the rotating shaft of the second sector gear (162) on one side and the slitting cutter (154);

still including screening mechanism (19), screening mechanism (19) are including:

the deflector rod (192) is arranged on the output shaft of the high-speed motor (152) and the rotating shaft of the second sector gear (162) at one side;

the support guide frames (191), 2 support guide frames (191) are arranged at the top of the base (1);

the upper parts of the supporting guide frames (191) are respectively provided with a contact rod (193) in a sliding manner, and the contact rods (193) are matched with the deflector rods (192);

a limit spring (194), wherein the limit spring (194) is connected between the contact rod (193) and the inner wall of the supporting guide frame (191);

a waste material collecting frame (197), wherein a waste material collecting frame (197) is connected between the inner sides of the contact rods (193), and a plurality of detachable nuts (195) are connected between the two sides of the waste material collecting frame (197) and the contact rods (193);

the filter screen (196), the filter screen (196) has been placed to waste material collection frame (197) inner wall slidingtype.

2. A steel fiber feeding and pressing type production device based on the principle of a wave method as claimed in claim 1, wherein: when the contact block (9) is matched with the jacking block (10), the lower clamping plate (12) can be driven to be contacted and matched with the upper clamping plate (7) to extrude the steel fibers into a waveform.

3. A steel fibre feed press based on the principle of wave form method according to claim 2, characterized in that the feed placement mechanism (14) comprises:

the mounting frames (141), the top of the base (1) is provided with 2 mounting frames (141);

the upper clamping wheels (143), and upper clamping wheels (143) are rotatably arranged between the mounting frames (141);

the lower clamping wheels (142) are rotatably arranged between the mounting frames (141), and the lower clamping wheels (142) are rotatably arranged between the mounting frames.

4. A steel fiber feeding and pressing type production device based on the principle of wave method according to claim 3, characterized by further comprising a raw material placing mechanism (17), wherein the raw material placing mechanism (17) comprises:

the mounting bracket (171) is arranged on one side of the top of the base (1), and a placing strut (172) is rotatably arranged between the tops of the mounting brackets (171);

and a detachable mounting plate (173), wherein the detachable mounting plate (173) is arranged on one side of the placing pillar (172) in a threaded manner.

5. A steel fiber feeding and pressing type production device based on the principle of wave method according to claim 4, further comprising a raw material feeding mechanism (18), wherein the raw material feeding mechanism (18) comprises:

the device comprises a bearing support (181), wherein the top of a base (1) is provided with the bearing support (181), the upper part of the bearing support (181) is rotatably provided with an upper feeding wheel (183), and a first belt pulley (182) is connected between the two sides of the upper feeding wheel (183) and an output shaft of a servo motor (3);

a lower feeding wheel (186), wherein the lower feeding wheel (186) is rotatably arranged at the top of the base (1);

the inner side of the upper part of the bearing bracket (181) is rotationally provided with 2 rotating rods, and the third gear set (184) is connected between the rotating rods and the upper feeding wheel (183);

and a second belt pulley (185), and a second belt pulley (185) is connected between the rotating rod and the lower feeding wheel (186).

6. The steel fiber feeding and pressing type production equipment based on the principle of a wave method according to claim 5, further comprising a stirring mechanism (20), wherein the stirring mechanism (20) comprises:

the mounting guide frames (201), 2 mounting guide frames (201) are arranged at the top of the base (1);

the transmission gears (203) are rotatably arranged on the outer sides of the upper parts of the installation guide frames (201);

the guide plates (205) are arranged between the tops of the installation guide frames (201) in a sliding mode, the guide plates (205) are arranged at the bottoms of the guide plates (205) in a sliding mode, and the poking plate (206) is arranged at the bottoms of the guide plates;

the fourth racks (204) are arranged on two sides of the guide plate (205);

and the middle part of the contact rod (193) is provided with a third rack (202), and the third rack (202) and a fourth rack (204) are matched with the same-side transmission gear (203).

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