CN215881140U - Production line for removing slag burrs of blanking part - Google Patents

Abstract

The utility model discloses a production line for removing slag and burrs of a blanking piece, which comprises a safety channel, a cutting blanking frame and a deburring channel which are arranged in parallel at intervals, wherein the deburring channel is arranged along the length extending direction of the interval between the safety channel and the cutting blanking frame, a plurality of blanking station positions are arranged on the cutting blanking frame at intervals, a blanking cutter is respectively arranged on each blanking station position, a feeding machine, a feeding conveyor device, a sanding device, a discharging conveyor device and a movable material receiving frame are respectively arranged along the extending direction from the feeding end to the discharging end of the deburring channel, the feeding machine stretches across two sides above the feeding conveyor device, the discharging end of the feeding conveyor device and the feeding end of the discharging conveyor device respectively extend into the sanding device, and a detection assembly is arranged between the feeding end of the feeding conveyor device and the sanding device. The utility model can efficiently remove residual slag and burrs on the surface of the lower plate with high quality, has high deburring efficiency and simultaneously considers plates with different dimensions.

Description

Production line for removing slag burrs of blanking part

Technical Field

The utility model relates to the field of machining technologies, in particular to a production line for removing slag and burrs of a blanking piece.

Background

The existing blanking plate slag removing process is characterized in that plates with the size of 200mm multiplied by 400mm are subjected to slag removal by a roller mixer, other large plates are subjected to manual polishing and slag removal, the workload of slag and burr residues on the manual polishing plate surface is large, the operating environment is poor, the working efficiency is low, a movable cover plate is arranged at the top of a roller of the roller mixer to form an opening for placing the plates, and a movable discharge hole is formed in the bottom of the roller. When feeding, the bottom discharge port is closed, and the top feeding port is opened; in the rotating process of the roller stirrer, the plates are overturned through the friction action with the inner wall of the roller, so that mutual collision and sliding are generated between the plates, and the slag attached to the plate surface falls off. After the operation for a certain time, the bottom discharge hole of the drum mixer is opened, and the plate falls into the collecting frame due to the dead weight. However, the roller deslagging equipment has high operation noise, and the generated dust and slag cause environmental dust pollution, so that workers have high occupational disease risk; the sharp corner of the plate is easy to flatten by the roller deslagging mode, and a new burr point is formed. Due to the irregular stacking of the plates in the roller, the plates cannot be completely contacted and rubbed. For plates with a number of points of two or more, the plate-adhering slag cannot be removed significantly.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a production line for removing slag and burrs from a blanking part, the burr production line can efficiently remove residual slag and burrs on the surface of the blanking plate with high quality, and simultaneously takes account of plates with different dimensions. In order to achieve the above object, the present invention adopts the following technical effects:

according to one aspect of the utility model, a production line for removing slag and burrs from blanking pieces is provided, which comprises a safety channel, a cutting blanking frame and a deburring channel which are arranged in parallel at intervals, wherein the deburring channel is arranged along the length extending direction of the interval between the safety channel and the cutting blanking frame, a plurality of blanking station positions are arranged on the cutting blanking frame at intervals, a blanking cutter is respectively arranged on each blanking station position, a feeding machine, a feeding conveyor device, a sanding device, a discharging conveyor device and a movable material receiving frame are respectively arranged along the extending direction from the feeding end to the discharging end of the deburring channel, the feeding machine spans two sides above the feeding conveyor device, one end of the feeding machine is fixed on the inner side edge of the safety channel, the other end of the feeding machine spans the feeding conveyor device and extends to the upper side of the cutting blanking frame, the discharge end of the feeding conveyor device and the feeding end of the discharging conveyor device respectively extend into the sanding device, and a detection assembly is arranged between the feeding end of the feeding conveyor device and the sanding device and arranged above the feeding conveyor device.

Preferably, the detection assembly comprises an aluminum alloy frame, fixed cross beams, cylindrical sliding guide rails, sensor assemblies and a detection controller, the aluminum alloy frame is fixed on the peripheral side wall of the feeding conveyor device, the fixed cross beams are transversely arranged at two ends of the aluminum alloy frame in a spanning manner, the fixed cross beams span over the feeding conveyor device, two ends of the fixed cross beams are fixed on the aluminum alloy frame through connecting seats, two parallel cylindrical sliding guide rails are fixed between two sides of the feeding conveyor device along the conveying direction and at two ends of the aluminum alloy frame through the fixed cross beams, one or more than two sensor assemblies are transversely arranged at intervals on the diameters of the two parallel cylindrical sliding guide rails, and the sensor assemblies are electrically connected with the detection controller; the outer wall of the end parts of the two ends of the cylindrical sliding guide rail is respectively sleeved with a fixing ring, and the sensor assembly is sleeved on the outer wall of the cylindrical sliding guide rail through the fixing ring.

The proposal is further preferred, the sensor component comprises a fastening handle, an aluminum profile beam and photoelectric sensors, a plurality of aluminum profile beams are respectively arranged on a cylindrical sliding guide rail between two sides of the feeding conveyor device at horizontal intervals, two ends of the aluminum profile beams are sleeved on the outer wall of the cylindrical sliding guide rail at two sides of the aluminum alloy frame, the side wall of the aluminum profile beam is provided with a round hole in a penetrating way along the width direction, the round hole is sleeved with an oilless bushing, two ends of the aluminum profile beam are sleeved on the cylindrical sliding guide rail through the oilless bushing, the photoelectric sensors are arranged on the side wall of each aluminum profile beam in a sliding way, the photoelectric sensors arranged at the front and the back between the adjacent aluminum profile beams are on the same straight line, and the center threaded holes penetrating through the outer wall of the oilless bushing are arranged at the center of the section at one end or/and the center of the section at the two ends of the aluminum profile beam, the tightening handle is in threaded connection with the cross section of the end part of the aluminum profile beam through a central threaded hole.

According to the scheme, the connecting piece is arranged in the side wall of the aluminum profile beam in a sliding mode, the bolt penetrates through the shell of the photoelectric sensor, and the photoelectric sensor is connected with the connecting piece in the side wall of the aluminum profile beam in a threaded mode through the bolt.

The further preferred of above-mentioned scheme, the sand light device includes sand light casing, pan feeding mouth, discharge gate and sand light subassembly, the discharge end of feed conveyor device stretches into the edge of pan feeding mouth, discharge conveyor's pan feeding end stretches into the edge of discharge gate, the sand light subassembly is fixed in the sand light casing, the pan feeding end of sand light subassembly with the pan feeding end transition of feed conveyor device links up, the discharge end of sand light subassembly with the pan feeding end transition of feed conveyor device links up.

The proposal is further preferred, the sanding component comprises an upper driving roller, a lower driving roller, a first knocking conveying belt, a second knocking conveying belt, an upper sanding belt, a lower sanding belt, an upper abrasive belt and a lower abrasive belt, the lower driving roller is respectively fixed between a feed inlet and a horizontal discharge outlet of the sanding shell at horizontal intervals, the upper driving roller is symmetrically arranged above the lower driving roller, the first knocking conveying belt and the second knocking conveying belt are sequentially horizontally and transversely arranged below the lower driving roller close to one side of the feed inlet and along the direction of the discharge outlet, knocking hammers extending into gaps between the adjacent lower driving rollers are vertically arranged along the surfaces of the first knocking conveying belt and the second knocking conveying belt, the lower grinding belt is transversely and horizontally arranged in the gaps between the adjacent lower driving rollers close to one side of the discharge outlet, and the upper belt is transversely and horizontally arranged in the gaps between the adjacent upper driving rollers above the lower abrasive belt, the horizontal setting between the lower drive roll clearance between second striking conveyer belt and lower emery cloth area the clearance setting between the lower drive roll directly over lower emery cloth area go up the emery cloth area.

Above-mentioned scheme is further preferred, is provided with the dust catcher at the pan feeding end of burring passageway and the input that is located the feeding conveyer device, this dust catcher pass through the pipeline with sand light device's intercommunication.

In summary, the utility model adopts the above technical scheme, and the utility model has the following technical effects:

the plate deburring production line disclosed by the utility model can be used for removing residual slag and burrs on the surface of an unloading plate with high quality and high efficiency, plates with different dimensions and specifications are considered at the same time, the deburring production line is used for removing the slag and the burrs of the plate after thermal cutting, the grinding and transferring efficiency is improved, the plate deburring production line is compatible with plates with various specifications, the specification range of the processable plate is expanded, the transferring time can be saved by matching with the loading and unloading of a loading machine (mechanical arm), the surface is smooth and smooth, the grinding efficiency is high, the demands of grinding personnel of the unloading plate are reduced, the labor cost is saved, the safety and reliability of deburring are improved, the production efficiency is improved, and the working environment is improved.

Drawings

FIG. 1 is a schematic structural diagram of a slag burr removing production line for blanking pieces according to the utility model;

FIG. 2 is a schematic top view of a slag deburring production line for blanking members according to the present invention;

FIG. 3 is a schematic structural view of a detection assembly of the present invention;

FIG. 4 is a schematic structural view of the feed conveyor apparatus of the present invention;

FIG. 5 is a schematic structural view of a sensor assembly of the present invention;

FIG. 6 is a schematic front view of the sensor assembly of the present invention;

fig. 7 is a schematic structural view of a sanding device of the present invention;

FIG. 8 is a schematic view of the construction of the sanding assembly of the present invention;

FIG. 9 is a front elevation schematic view of a sanding assembly of the present invention;

in the drawing, the safety channel 1, the cutting and placing frame 2, the deburring channel 3, the discharging station 4, the discharging cutter 5, the feeding machine 10, the detection assembly 11, the feeding conveyor device 12, the sanding device 13, the discharging conveyor device 14, the movable receiving frame 15, the aluminum alloy frame 111, the fixed cross beam 112, the cylindrical sliding guide rail 113, the connecting seat 114, the fixing ring 115, the sensor assembly 116, the sanding shell 130, the feeding port 131, the discharging port 132, the sanding assembly 133, the fastening handle 1161, the aluminum profile cross beam 1162, the oil-free bush 1163, the photoelectric sensor 1164, the connecting piece 1165, the bolt 1166, the upper driving roller 1330, the lower driving roller 1331, the first knocking conveying belt 1332, the second knocking conveying belt 1332a, the upper abrasive belt 1334, the lower abrasive belt 1335, the upper abrasive belt 1336 and the lower abrasive belt 1337.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail below with reference to the accompanying drawings by way of examples of preferred embodiments. It should be noted, however, that the numerous details set forth in the description are merely for the purpose of providing the reader with a thorough understanding of one or more aspects of the present invention, which may be practiced without these specific details.

Referring to fig. 1 and 2, the production line for removing slag and burr of a blanking member according to the present invention comprises a safety channel 1, a cutting blanking frame 2 and a deburring channel 3 which are arranged in parallel at intervals, wherein the deburring channel 3 is arranged along the length extension direction of the interval between the safety channel 1 and the cutting blanking frame 2, a plurality of blanking station positions 4 are arranged on the cutting blanking frame 2 at intervals, a blanking cutter 5 is arranged on each blanking station position, a feeding machine 10, a feeding conveyor device 12, a sanding device 13, a discharging conveyor device 14 and a movable material receiving frame 15 are arranged along the extension direction from the feeding end to the discharging end of the deburring channel 3, the feeding machine 10 spans two sides above the feeding conveyor device 12, wherein one end of the feeding machine 10 is fixed on the inner side edge of the safety channel 1, and the other end of the feeding machine 10 spans the feeding conveyor device 12 and extends above the cutting blanking frame 2, the discharge end of the feeding conveyor device 12 and the feed end of the discharge conveyor device 14 respectively extend into the sanding device 13, a detection assembly 11 is arranged between the feed end of the feeding conveyor device 12 and the sanding device 13, and the detection assembly 11 is arranged above the feeding conveyor device 12; one or more blanking cutting machines 5 are placed at a blanking station 4, the cut plates are placed at a cutting and blanking frame 2, a feeding machine 10 can be a gantry type single-column type air suction crane or a magnetic lifting appliance, the feeding conveyor device 12 and the discharging conveyor device 14 are drum-type conveyors, the feeding conveyor device 12 and the discharging conveyor device 14 are driven by a driving motor to convey the plates, the plates cut by the blanking cutting machines 5 pass through the feeding conveyor device 12, a detection assembly 11 is used for detecting whether the plates pass through the feeding conveyor device 12 or not and judging whether the plates are sent into a sanding device 13 to be deburred and processed by slag, the plates are sent into a movable material collecting frame 15 through the discharging conveyor device 14 after being processed by the sanding device 13, a dust suction machine 8 is arranged at the feeding end of the deburring channel 3 and at the input end of the feeding conveyor device 12, the dust collector 8 is communicated with the sanding device 13 through a pipeline 9; when the sanding device 13 removes the slag burrs, the slag burrs are sucked by the dust collector 8 and sent into the dust collector 8 from the sanding device 13 along the pipeline 9.

In the present invention, as shown in fig. 1 and fig. 3, the detecting assembly 11 includes an aluminum alloy frame 111, a fixed beam 112, a cylindrical sliding guide 113, a sensor assembly 116 and a detecting controller, the aluminum alloy frame 111 is fixed on the peripheral side wall of the feeding conveyor device 12, the fixed beam 112 is arranged across two ends of the aluminum alloy frame 111, the fixed beam 112 spans above the feeding conveyor device 12, and two ends of the fixed beam are fixed on the aluminum alloy frame 111 through a connecting seat 114, two parallel cylindrical sliding guide 113 are fixed between two sides of the feeding conveyor device 12 in the conveying direction and at two ends of the aluminum alloy frame 111 through the fixed beam 112, one or more than two sensor assemblies 116 are arranged between the two parallel cylindrical sliding guide 113 at a transverse interval, and the sensor assemblies 116 are electrically connected to the detecting controller, the detection controller is also electrically connected with the driving motors of the feeding conveyor device 12 and the discharging conveyor device 14; fixing rings 115 are respectively sleeved on the outer walls of the end parts of the two ends of the cylindrical sliding guide rail 113, the two ends of the two parallel cylindrical sliding guide rails 113 are clamped on the outer side walls of the two ends of the fixed cross beam 112 through the fixing rings 115, after the two ends of the cylindrical sliding guide rail 113 respectively penetrate through the outer sides of the fixed cross beam 112, the end parts of the cylindrical sliding guide rails 113 are clamped on the outer side walls of the fixed cross beam 112 through the fixing rings 115, so that the two parallel cylindrical sliding guide rails 113 are arranged between the two parallel fixed cross beams 112 transversely arranged at the two ends of the aluminum alloy frame 111 in a straddling manner, and the cylindrical sliding guide rails 113 are prevented from sliding on the fixed cross beam 112; the feeding conveyor device 12 is composed of a slope feeding section 121, a right-angle turning section 122 and a horizontal straight line section 123, as shown in fig. 4, the slope feeding section 121 is connected to the outer edge of the cutting and discharging frame 2, the slope feeding section 121 is in transition connection with the horizontal straight line section 123 through the right-angle turning section 122, and the sensor assemblies 116 are sequentially arranged from the feeding end to the discharging end of the horizontal straight line section 123 at intervals; the detection controller is a PLC controller, the feeding conveyor device 12 and the discharging conveyor device 14 are roller conveyors, one or more plate fixed-length sensor assemblies 116 are placed on one side of a feeding end of a straight line section of the feeding conveyor device 12, a distance between the front sensor assembly and the rear sensor assembly 116 in the cylindrical sliding guide rail 113 is adjusted through sliding, signals of plates running between the front sensor assembly and the rear sensor assembly 116 are detected through the PLC controller, and the feeding conveyor device 12 stops running when the length of the plates is less than 300 mm.

In the utility model, as shown in fig. 3, 4, 5 and 6, the sensor assembly 116 includes a fastening handle 1161, aluminum profile beams 1162 and photoelectric sensors 1164, a plurality of aluminum profile beams 1162 are horizontally arranged on the cylindrical sliding guide rail 113 between two sides of the feeding conveyor device 12 at intervals, two ends of the aluminum profile beams 1162 are sleeved on the outer wall of the cylindrical sliding guide rail 113 at two sides of the aluminum alloy frame 111, a circular hole is formed in the side wall of the aluminum profile beam 1162 and penetrates along the width direction, an oilless bush 1163 is sleeved in the circular hole, two ends of the aluminum profile beam 1162 are sleeved on the cylindrical sliding guide rail 113 through the oilless bush 1163, the aluminum profile beams 2 can slide on the cylindrical sliding guide rail 113 through the oilless bush 1163 to adjust the interval distance between adjacent aluminum profile beams 1162, the plurality of photoelectric sensors 1164 are slidably arranged on the side wall of each aluminum profile beam 1162, and the photoelectric sensors 1164 arranged in front and back between the adjacent aluminum profile beams 1162 are on the same straight line, when the plate is conveyed in the horizontal straight line segment 123 of the feeding conveyor device 12, the photoelectric sensors 1164 (photoelectric detection switches) emit laser detection signals to gaps between rollers in the feeding conveyor device 12, when the plate passes through the feeding conveyor device 12, the photoelectric sensors 1164 above the position of the plate detect blocking reflection signals, the photoelectric sensors 1164 output high-level detection signals to the detection controller for judgment, the spacing distance between the front and back adjacent photoelectric sensors 1164 is close to the size of the plate (more than or equal to 300mm), when the size of the plate is smaller than the spacing distance between the front and back adjacent photoelectric sensors 1164, the plate can reach the rear photoelectric sensor 1164 after being completely detected by the front photoelectric sensor 1164, and when the size of the plate is larger than the spacing distance between the front and back photoelectric sensors 1164, when the plate passes through the space between the photoelectric sensors 1164 adjacent to the front and the rear, a high-level detection signal that the plate passes through can be continuously detected at the same time, the plate smaller than 300mm is removed, the horizontal straight line segment 123 of the feeding conveyor device 12 is stopped, and the sanding device 13 is not started to perform sanding and deburring treatment; a central threaded hole penetrating through the outer wall of the oilless bush 1163 is formed in the center of one end or/and two end sections of the aluminum profile beam 1162, the tightening handle 1161 is in threaded connection with the end section of the aluminum profile beam 1162 through the central threaded hole, the tightening handle 1161 is screwed to be in contact with the oilless bush 1163, the oilless bush 1163 can be tightly jacked, the cylindrical sliding guide rail 113 is clamped, the sensor assembly 116 is fixed at a certain position on the cylindrical sliding guide rail 113, plates at different positions on the feeding conveyor device 12 (roller conveyor) can be conveniently detected, a connecting piece 1165 is arranged in the side wall of the aluminum profile beam 1162 in a sliding mode, a bolt 1166 penetrates through the shell of the photoelectric sensor 1164, the photoelectric sensor 1164 is in threaded connection with the connecting piece 1165 in the side wall of the aluminum profile beam 1162 through the bolt 1166, and the position of the sliding connecting piece 1165 in the aluminum profile beam 1162, then, the photoelectric sensor 1164 is placed at the connecting piece 1165, and penetrates through the shell of the photoelectric sensor 1164 through the bolt 1166 and is connected with the connecting piece 1165, the photoelectric sensor 1164 can be quickly installed, when the bolt 1166 is loosened, the photoelectric sensor 1164 can slide along the aluminum profile cross beam 1162, so that the spacing distance between the left and right adjacent photoelectric sensors 1164 on the aluminum profile cross beam 1162 is guaranteed, adjustment and fixation are carried out, and plates at different positions on the feeding conveyor device 12 (detecting roller conveyors) are facilitated.

In the present invention, as shown in fig. 1, fig. 2, fig. 7, fig. 8 and fig. 9, the sanding device 13 includes a sanding housing 130, a feeding port 131, a discharging port 132 and a sanding component 133, a discharging end of the feeding conveyor device 12 (horizontal straight line segment 123) extends into an edge of the feeding port 131, a feeding end of the discharging conveyor device 14 extends into an edge of the discharging port 132, the sanding component 133 is fixed in the sanding housing 130, a feeding end of the sanding component 133 is in transitional engagement with a feeding end of the feeding conveyor device 12, and a discharging end of the sanding component 133 is in transitional engagement with a feeding end of the feeding conveyor device 12; the sanding assembly 133 comprises an upper driving roller 1330, a lower driving roller 1331, a first knocking conveying belt 1332, a second knocking conveying belt 1332a, an upper abrasive belt 1334, a lower abrasive belt 1335, an upper abrasive belt 1336 and a lower abrasive belt 1337, the lower driving roller 1331 is fixed between the feeding port 131 and the horizontal discharging port 132 of the sanding shell 130 at horizontal intervals, the upper driving roller 1330 is symmetrically arranged above the lower driving roller 1331, the lower driving roller 1331 and the upper driving roller 1330 are symmetrically arranged up and down, a knocking conveying belt 1333 extending into a gap between the adjacent lower driving rollers 1331 is vertically arranged below the lower driving roller 1331 close to one side of the feeding port 131 and along the direction of the discharging port 132 in sequence and horizontally and transversely arranged at the position below the first knocking conveying belt 1332 and the second knocking conveying belt 1332a, the first knocking conveying belt 1332 and the second knocking conveying belt 1332a are symmetrically arranged front and back, and hammers are vertically arranged along the surfaces of the first knocking conveying belt 1332 and the second knocking conveying belt 1332a, horizontally arranging the lower abrasive belt 1337 at a gap between the adjacent lower driving rollers 1331 near one side of the discharge opening 132, horizontally arranging the upper abrasive belt 1336 at a gap between the adjacent upper driving rollers 1330 above the lower abrasive belt 1337, horizontally arranging the lower abrasive belt 1335 at a gap between the lower driving rollers 1331 between the second striking conveyer belt 1332a and the lower abrasive belt 1337, and horizontally arranging the upper abrasive belt 1334 at a gap between the lower driving rollers 1331 directly above the lower abrasive belt 1335;

the upper abrasive cloth strip 1334 and the lower abrasive cloth strip 1335 are arranged in an up-and-down symmetrical manner; when a plate is fed into the lower driving roller 1331 from the discharge end of the feeding conveyor device 12 (the horizontal straight line segment 123), the plate is continuously conveyed forward during the rotation of the lower driving roller 1331, the plate passes through a space between the first knocking conveying belt 1332 and the second knocking conveying belt 1332a which rotate forward and backward at a high speed, under the guiding action of the upper driving roller 1330 and the lower driving roller 1331, the knocking hammers 1333 on the first knocking conveying belt 1332 and the second knocking conveying belt 1332a which rotate forward and backward continuously knock the surface of the plate, and continuously lift the first knocking conveying belt 1332 and the second knocking conveying belt 1332a to make the plate contact with the upper driving roller 1330, so as to remove the large hanging slag on the lower surface of the plate, the hanging slag falling off during the knocking of the plate in the sanding shell 130 is adsorbed by the dust collector 8 through the pipeline 9, and because the first knocking conveying belt 1332 and the second knocking conveying belt 1332a rotate forward and backward, knocking the lower surface of the plate by a knocking hammer 1333, so as to enable the directions of friction force and knocking force received on the plate to be mutually offset, the plate cannot slide relatively, after the knocking hammer 1333 is knocked, feeding the plate between two upper abrasive belt 1334 and lower abrasive belt 1335 which are arranged up and down and transversely, removing smaller slag-hanging particles on the lower surface of the plate between the upper abrasive belt 1334 and the lower abrasive belt 1335 because the upper abrasive belt 1334 and the lower abrasive belt 1335 rotate at the same direction and speed at high speed, so that the plate cannot slide relatively, and finally removing burrs on the edges and inner holes of the material belt of the plate between the upper abrasive belt 1336 and the lower abrasive belt 1337 which are arranged transversely by two groups respectively up and down, wherein the rotating directions of the upper abrasive belt 1336 and the lower abrasive belt 1337 are the same; two sets of hammers, the abrasive material area of knocking are rotatory by independent power control, and the emery cloth area station, strike hammer station and abrasive material area station can go up and down the use alone, and the emery cloth area station of exclusive use can realize sand light, descaling technology, and the burring processing can be realized to the abrasive material area station of exclusive use, reaches energy-conserving effect. Because the plate is thicker, heavier and need two-sided polishing, still adopt rubber roller to pinch on the feeding conveyor device 12 (cylinder conveyer) and send the plate, feeding conveyor device 12 adopts variable frequency speed governing, and grinding dust is handled through supporting industrial pulse dust collector 8 to grinder 13, realizes the environmental protection and produces.

With reference to fig. 1 to 9, the deburring process of the production line for removing slag and burrs from a blanking member according to the present invention is further described, first, a pre-cut plate is sent to a blanking station 4 installed on a cutting and blanking frame, blanking and cutting are performed according to the size requirement, and the distance between adjacent sensor assemblies 116 on the cylindrical sliding guide rail 113 is adjusted, so that the distance between the front and rear adjacent photoelectric sensors 1164 is close to the size after cutting; secondly, transferring the cut plates onto a feeding conveyor device 12 through a feeding machine 10, and enabling the cut plates to be conveyed on the feeding conveyor device 12 in parallel; when the cut plate is conveyed on the feeding conveyor device 12, the photoelectric sensors 1164 adjacent to each other in the front and back direction detect the plate, when the front end of the plate passes through the previous photoelectric sensor 1164, a first detection signal is obtained, and when the front end of the plate passes through the next photoelectric sensor 1164, a second detection signal is obtained; thirdly, judging the level between the first detection signal and the second detection signal, if the detection signals of the first detection signal and the second detection signal are high level, acquiring high level synchronous duration, if the synchronous duration is longer than the preset duration, starting the sanding device 13, feeding the cut plate into the sanding device 13 by the feeding conveyor device 12 for processing, stopping the feeding conveyor device 12 from running at the moment, and feeding the plate into the movable material receiving frame 15 by the discharging conveyor device 14 after the sanding device 13 finishes processing the plate; the process of sending the cut plate into the sanding device 13 for deburring is as follows: the cut plate is fed between an upper driving roller 1330 and a lower driving roller 1331, the plate is conveyed on a conveying assembly consisting of the rotating lower driving rollers 133, under the guiding action of the upper driving roller 1330 and the lower driving roller 1331, the plate passes through a first knocking conveying belt 1332 and a second knocking conveying belt 1332a which rotate forward and backward at high speed, the directions of friction force and knocking force received on the plate are mutually offset, and large slag on the lower surface of the plate is removed through knocking hammers 1333 on the first knocking conveying belt 1332 and the second knocking conveying belt 1332 a; removing small slag particles on the lower surface of the plate through an upper abrasive belt 1334 and a lower abrasive belt 1335 which are transversely arranged from top to bottom and rotate at a high speed, and finally removing burrs on edges and inner holes of the plate through one or two groups of upper abrasive belts 1336 and lower abrasive belts 1337 which are transversely arranged from top to bottom and rotate at a high speed, wherein the rotating directions of the first knocking conveyor belt 1332 and the second knocking conveyor belt 1332a are opposite, the rotating directions of the upper abrasive belt 1334 and the lower abrasive belt 1335 as well as the rotating directions of the upper abrasive belt 1336 and the lower abrasive belt 1337 are the same, removing slag and burrs on the thermally cut plate by using a deburring production line, compatible with plates with large and small specifications, and improving grinding and transferring efficiency, deburring slag on the surface of the plate through the steps, so that the surface of the plate is smooth and smooth, the grinding efficiency is high, and the dedusting and denoising effects are good; and finally, if the synchronous duration is less than the preset duration, stopping the operation of the sanding device 13, and sending out the cut plate through the feeding conveyor device 12, the lower transmission roller 1331 and the discharging conveyor device 14 to enter the next step of processing. Thereby performing slag deburring on the plate with the preset specification size.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that those skilled in the art can make various improvements and modifications without departing from the principle of the present invention, and these improvements and modifications should also be construed as the protection scope of the present invention.

Claims (7)

1. The utility model provides a blanking member removes slag burr production line which characterized in that: the deburring machine comprises safe channels (1), cutting discharging frames (2) and deburring channels (3) which are arranged in parallel at intervals, wherein the deburring channels (3) are arranged along the length extending direction at intervals between the safe channels (1) and the cutting discharging frames (2), a plurality of blanking station positions (4) are arranged on the cutting discharging frames (2) at intervals, a blanking cutter (5) is arranged on each blanking station position, a feeding machine (10), a feeding conveyor device (12), a sanding device (13), a discharging conveyor device (14) and a movable material receiving frame (15) are respectively arranged along the extending direction from the feeding end to the discharging end of each deburring channel (3), the feeding machine (10) stretches across two sides above the feeding conveyor device (12), wherein one end of the feeding machine (10) is fixed at the inner side edge of the safe channels (1), the other end of material loading machine (10) transversely strides across feeding conveyor device (12) and extends to the top of cutting blowing frame (2), the discharge end of feeding conveyor device (12) and the pan feeding end of ejection of compact conveyor device (14) stretch into in sanding device (13) respectively the pan feeding end of feeding conveyor device (12) with be provided with between sanding device (13) detection component (11), this detection component (11) set up in the top of feeding conveyor device (12).

2. The blanking member slag and burr removing production line according to claim 1, wherein: the detection assembly (11) comprises an aluminum alloy frame (111), fixed cross beams (112), cylindrical sliding guide rails (113), sensor assemblies (116) and a detection controller, the aluminum alloy frame (111) is fixed on the peripheral side walls of the feeding conveyor device (12), the fixed cross beams (112) are arranged at two ends of the aluminum alloy frame (111) in a cross mode, the fixed cross beams (112) span above the feeding conveyor device (12) and are fixed on the aluminum alloy frame (111) through connecting seats (114), two parallel cylindrical sliding guide rails (113) are fixed between two sides of the feeding conveyor device (12) in the conveying direction and are fixed at two ends of the aluminum alloy frame (111) through the fixed cross beams (112), one or more sensor assemblies (116) are arranged at intervals in the transverse direction of the diameters of the two parallel cylindrical sliding guide rails (113), the sensor assembly (116) is electrically connected with the detection controller; the outer wall of cylindrical sliding guide (113) both ends tip is overlapped respectively and is equipped with solid fixed ring (115), sensor subassembly (116) are established through solid fixed ring (115) cover on the outer wall of cylindrical sliding guide (113).

3. The blanking member slag and burr removing production line according to claim 2, wherein: the sensor component (116) comprises a fastening handle (1161), aluminum profile beams (1162) and photoelectric sensors (1164), wherein a plurality of aluminum profile beams (1162) are respectively arranged on cylindrical sliding guide rails (113) between two sides of the feeding conveyor device (12) at horizontal intervals, two ends of each aluminum profile beam (1162) are sleeved on outer walls of the cylindrical sliding guide rails (113) on two sides of the aluminum alloy frame (111), a round hole is formed in the side wall of each aluminum profile beam (1162) in a penetrating mode along the width direction, oil-free bushes (1163) are sleeved in the round hole, two ends of each aluminum profile beam (1162) are sleeved on the cylindrical sliding guide rails (113) through the oil-free bushes (1163), the photoelectric sensors (1164) are arranged on the side wall of each aluminum profile beam (1162) in a sliding mode, and the photoelectric sensors (1164) arranged between the adjacent aluminum profile beams (1162) in the front and back mode are arranged on the same straight line, the center of the section of one end or/and two ends of the aluminum profile beam (1162) is provided with a central threaded hole penetrating to the outer wall of the oilless bushing (1163), and the tightening handle (1161) is connected to the section of the end of the aluminum profile beam (1162) through the central threaded hole.

4. The blanking member slag and burr removing production line according to claim 3, wherein: slide in the lateral wall of aluminium alloy crossbeam (1162) and be provided with connecting piece (1165), it is provided with bolt (1166) to run through on the shell of photoelectric sensor (1164), photoelectric sensor (1164) carry out threaded connection through connecting piece (1165) in bolt (1166) and the aluminium alloy crossbeam (1162) lateral wall.

5. The blanking member slag and burr removing production line according to claim 1, wherein: sanding device (13) are including sand light casing (130), pan feeding mouth (131), discharge gate (132) and sand light subassembly (133), the discharge end of feeding conveyor device (12) stretches into the edge of pan feeding mouth (131), the pan feeding end of discharging conveyor device (14) stretches into the edge of discharge gate (132), sand light subassembly (133) are fixed in sand light casing (130), the pan feeding end of sand light subassembly (133) with the pan feeding end transition of feeding conveyor device (12) links up, the discharge end of sand light subassembly (133) with the pan feeding end transition of feeding conveyor device (12) links up.

6. A blanking member slag and burr removing production line according to claim 5, characterized in that: the sanding component (133) comprises an upper driving roller (1330), a lower driving roller (1331), a first knocking transmission belt (1332), a second knocking transmission belt (1332a), an upper abrasive belt (1334), a lower abrasive belt (1335), an upper abrasive belt (1336) and a lower abrasive belt (1337), wherein the lower driving rollers (1331) are respectively fixed between a feeding port (131) and a horizontal discharging port (132) of the sanding shell (130) at horizontal intervals, the upper driving roller (1330) is symmetrically arranged above the lower driving roller (1331), knocking hammers (1333) extending into gaps between adjacent lower driving rollers (1331) are vertically arranged on the surfaces of the first knocking transmission belt (1332) and the second knocking transmission belt (1332a) below the lower driving roller (1331) close to one side of the feeding port (131) and horizontally arranged along the direction of the discharging port (132) in sequence, the horizontal level in clearance sets up down between adjacent lower driving roller (1331) near discharge gate (132) one side abrasive belt (1337) down, the horizontal level in clearance sets up between adjacent upper driving roller (1330) of abrasive belt (1337) top down abrasive belt (1336) down, the horizontal level sets up between lower driving roller (1331) clearance between second strike conveyer belt (1332a) and lower abrasive belt (1337) lower abrasive belt (1335) lower abrasive belt (1334) clearance sets up between lower driving roller (1331) directly over lower abrasive belt (1335).

7. The blanking member slag and burr removing production line according to claim 1, wherein:

a dust collector (8) is arranged at the feeding end of the deburring channel (3) and at the input end of the feeding conveyor device (12), and the dust collector (8) is communicated with the sanding device (13) through a pipeline (9).

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