CN111408953A - Material handle clearing device and engine cylinder block production line - Google Patents

Abstract

The invention discloses a 201911254096.3 divisional application, belonging to the field of automobile accessory manufacturing, and discloses a material handle clearing device and an engine cylinder block production line, wherein the engine cylinder block production line comprises: the cylinder sleeve carrying device comprises a clamping mechanical arm used for moving the cylinder sleeve to a material conveying vehicle and the material conveying vehicle used for conveying the cylinder sleeve to the die-casting device; the die-casting device comprises a die-casting machine for die-casting the cylinder body by matching with the cylinder sleeve and a transferring mechanical arm for transferring the cylinder body to the chain conveying line; the chain conveying line is used for conveying the cylinder body to the material removing handle device; the material removing handle device is butted with the output end of the chain conveying line and is used for removing the material handle on the cylinder body; the pressure reducing strip removing device comprises a first pressing mechanism used for pressing the cylinder body on the chain conveying line and a knocking mechanical arm used for knocking out the pressure reducing strip on the cylinder body; through the high automation that realizes the production line, reduce staff's working strength, improve production efficiency, reduce enterprise's cultivation personnel's cost.

Description

Material handle clearing device and engine cylinder block production line

The application is a divisional application of patent application with the patent application number of '201911254096.3', the application date of 12 months and 10 days in 2019 and the name of 'an engine cylinder block production line'.

Technical Field

The invention relates to the field of automobile accessory manufacturing, in particular to a material handle clearing device and an engine cylinder body production line.

Background

With the improvement of living standard, automobiles become common transportation means in people's life and trip. The cylinder body is an important part of an automobile, and the manufacturing of the engine cylinder body of the automobile needs a plurality of processes of conveying a cylinder sleeve, casting the cylinder body, removing a water gap and the like. At present, a cylinder body production line of a cylinder body does not realize high automation, and procedures such as conveying a cylinder sleeve and removing a water gap of the cylinder body often need manual operation equipment, so that the work intensity of an operator is high, and the cost of operating technical personnel for training a professional is high for an enterprise; it is therefore necessary to achieve a high degree of automation of the production line.

It is seen that improvements and enhancements to the prior art are needed.

Disclosure of Invention

In view of the defects of the prior art, the invention aims to provide an engine cylinder block production line, which aims to realize high automation of the cylinder block production line, improve the production efficiency and reduce the working strength and talent culture cost.

In order to achieve the purpose, the invention adopts the following technical scheme:

an engine block production line comprising: the cylinder sleeve carrying device comprises a clamping mechanical arm used for carrying the cylinder sleeve to a material conveying vehicle and the material conveying vehicle used for conveying the cylinder sleeve to the die-casting device; the die-casting device comprises a die-casting machine and a transfer mechanical arm, wherein the die-casting machine is used for being matched with the cylinder sleeve to perform die-casting on the cylinder body, and the transfer mechanical arm is used for transferring the cylinder body to the chain conveying line; the chain conveying line comprises two conveying chains which are arranged in parallel, and the chain conveying line is used for conveying the cylinder body to the material removing handle device; the material handle removing device is butted with the output end of the chain conveying line and is used for removing the material handle on the cylinder body; the pressure reducing strip removing device comprises a first pressing mechanism arranged above the chain conveying line close to one side of the material removing handle device and a knocking mechanical arm arranged on one side of the first pressing mechanism; the first pressing mechanism is used for pressing the cylinder body on the chain conveying line, and the knocking mechanical arm is used for knocking out a pressure reducing strip on the cylinder body.

The production line of the engine cylinder block further comprises a deburring device, wherein the deburring device comprises a second pressing mechanism for pressing the cylinder block and a knocking mechanism for knocking out burrs at the bottom of the cylinder block; the second pressing mechanism is arranged above the input end of the chain conveying line, and the knocking-out mechanism is arranged between the two conveying chains.

In the engine cylinder production line, a lifting mechanism corresponding to the first pressing mechanism and the second pressing mechanism up and down is arranged between the two conveying chains; the lifting mechanism comprises a supporting block, a limiting strip, a support, a first lifting cylinder and a second lifting cylinder; the first lifting cylinder is vertically arranged between the two conveying chains, and the output end of the first lifting cylinder is connected with the supporting block; the support mounting is between two conveying chains, second lifting cylinder sets up in the below of support, its output pass the support with spacing connection, spacing and the parallel top that just sets up at the supporting block of conveying chain.

The production line of the engine cylinder body is characterized in that the two sides of the supporting block are respectively provided with a limiting mechanism, each limiting mechanism comprises a limiting cylinder, a limiting plate and a guide seat, the fixed end of each limiting cylinder is connected with the chain conveying line, and the output end of each limiting cylinder is connected with the limiting plate and faces the supporting block; the guide seats are arranged on two sides of the supporting block and provided with openings matched with the limiting plates, and the limiting plates penetrate through the guide seats.

The production line of the engine cylinder body is characterized in that a plurality of guide strips parallel to the conveying chains are arranged between the two conveying chains along the conveying direction of the conveying chains, and one side of the output end of each guide strip is provided with a vertically arranged stop rod; the lower end of the blocking rod is connected with a telescopic cylinder, and the upper end of the blocking rod is provided with a probe used for detecting the motion state of the cylinder body.

The production line of the engine cylinder body further comprises a material handle transferring device arranged above the material handle removing device, wherein the material handle transferring device comprises a beam frame, an X-axis moving mechanism, a Y-axis moving mechanism and a Z-axis moving mechanism which are vertically arranged, and a material handle gripper connected with the Z-axis moving mechanism; the X-axis movement mechanism is arranged on the beam frame; the Y-axis movement mechanism is movably connected to the X-axis movement mechanism, and the Z-axis movement mechanism is movably connected to the Y-axis movement mechanism; the Z-axis motion mechanism can drive the material handle gripper to move up and down.

The engine cylinder body production line further comprises a waste material vehicle and a conveying guide rail; the waste material vehicle is movably connected to the conveying guide rail, and the waste material vehicle is arranged on one side of the knock-out mechanical arm and is located below the material handle conveying device.

The engine cylinder body production line is characterized in that the material handle removing device comprises a first rack, a sliding seat arranged on the first rack, a feeding mechanism used for driving the sliding seat to move back and forth relative to the first rack, a cylinder body conveying mechanism arranged on the upper end surface of the sliding seat, a material handle bearing frame arranged on the rear side of the sliding seat, a third pressing mechanism used for clamping a cylinder body, a cutting mechanism used for removing a material handle and a material handle guiding mechanism arranged on the lower side of the material handle bearing frame; the cylinder body conveying mechanism is butted with the chain conveying line; the material handle guiding mechanism comprises a transmission rod which is rotatably arranged at the bottom of the material handle bearing frame, two or more than two guiding rods which are arranged on the transmission rod at equal intervals along the length direction of the transmission rod, and a guiding driving mechanism, wherein the guiding driving mechanism is used for driving the transmission rod to rotate so that the guiding rods extend out of the material handle bearing frame.

The pressure reducing strip removing device comprises an engine cylinder body production line, a pressure reducing strip removing device and a pressure reducing strip conveying device, wherein the pressure reducing strip removing device further comprises an auxiliary pressing mechanism, and the auxiliary pressing mechanism comprises an auxiliary pressing cylinder, an auxiliary pressing plate, an upper baffle and a stepping motor; the auxiliary pressing cylinder is vertically arranged on one side of the chain conveying line, the output end of the auxiliary pressing cylinder is connected with the auxiliary pressing plate through a connecting plate, and a spring pressing column is arranged between the connecting plate and the auxiliary pressing plate; one side of the auxiliary pressure plate is connected with a supporting plate, the stepping motor is vertically arranged on the supporting plate, and the output end of the stepping motor is connected with the upper baffle.

The production line of the engine cylinder block is characterized in that the cylinder sleeve carrying device further comprises a second rack; the clamping mechanical arm is arranged at the top of the second rack, and a replacing frame for replacing the hand grips of the clamping mechanical arm is arranged on one side of the second rack.

Has the advantages that:

the invention provides an engine cylinder body production line, which is characterized in that compared with the prior art, a cylinder sleeve carrying device, a die-casting device, a chain conveying line, a material handle removing device and a pressure reducing strip removing device are arranged; after an operator pushes the material cage with the cylinder sleeve to a cylinder sleeve conveying device, the processes of clamping the cylinder sleeve, conveying the cylinder sleeve, die-casting the cylinder body, transferring the cylinder body, removing a pressure reducing strip, removing a material handle and the like are automatically completed in sequence; the whole production line is highly automated, manual control operation of operators is not needed, the working strength of the operators is greatly reduced, the production efficiency is improved, and the cost of enterprise culture professional technicians is further reduced.

Drawings

Fig. 1 is a schematic structural diagram of an engine block production line according to the present invention.

Fig. 2 is a schematic structural diagram of the chain conveying line of the invention.

Fig. 3 is an enlarged schematic view of a portion a in fig. 2.

Fig. 4 is an enlarged schematic view of a portion B in fig. 2.

Fig. 5 is an enlarged schematic view of a portion C in fig. 2.

Fig. 6 is a schematic structural diagram of the lifting mechanism according to the present invention.

Fig. 7 is a schematic view of a first structure of the material removing handle device.

Fig. 8 is a second structural schematic diagram of the material removing handle device of the present invention.

Fig. 9 is an enlarged schematic view of a portion D in fig. 8.

Fig. 10 is a schematic structural view of the material handle transfer device according to the present invention.

Fig. 11 is a schematic front view of an engine block to which the present invention is applied.

Fig. 12 is a schematic top view of an engine block to which the present invention is applied.

Description of the main element symbols: 100-cylinder sleeve conveying device, 110-clamping mechanical arm, 120-material conveying vehicle, 130-second machine frame, 140-replacing frame, 150-cylinder sleeve frame, 160-material conveying guide rail, 200-die casting device, 210-die casting machine and 220-transferring mechanical arm;

300-a chain conveying line, 310-a conveying chain, 320-a lifting mechanism, 321-a supporting block, 322-a limiting strip, 323-a support, 324-a first lifting cylinder, 325-a second lifting cylinder, 330-a limiting mechanism, 331-a limiting cylinder, 332-a limiting plate, 333-a guide seat, 340-a guide strip, 350-a blocking rod, 351-a telescopic cylinder, 352-a probe, 360-a speed reducing motor and 370-a protective baffle plate;

400-material handle removing device, 410-first frame, 420-sliding base, 430-feeding mechanism, 440-cylinder body conveying mechanism, 450-material handle bearing frame, 460-third pressing mechanism, 470-cutting mechanism, 471-hydraulic cylinder, 472-pressing hand, 473-trimming die, 480-material handle guiding mechanism, 481-transmission rod, 482-guiding rod and 490-guiding driving mechanism;

500-decompression strip removing device, 510-first pressing mechanism, 511-first pressing cylinder, 512-first pressing block, 513-supporting bracket, 520-knockout mechanical arm, 530-auxiliary pressing mechanism, 531-auxiliary pressing cylinder, 532-auxiliary pressing plate, 533-upper baffle, 534-stepping motor, 535-connecting plate, 536-spring pressing column and 537-supporting plate;

600-a deburring device, 610-a second pressing mechanism, 611-a second pressing cylinder, 612-a second pressing block, 620-a knockout mechanism, 621-a hammer and 622-a knockout cylinder;

700-material handle transfer device, 710-beam frame, 720-X axis movement mechanism, 721-X axis slide rail, 722-limit switch, 730-Y axis movement mechanism, 740-Z axis movement mechanism, 750-material handle gripper, 800-waste vehicle, 810-conveying guide rail, 900-engine cylinder body, 910-pressure reducing bar and 920-material handle.

Detailed Description

The invention provides an engine cylinder block production line, which is further described in detail below by referring to the attached drawings and embodiments in order to make the purpose, technical scheme and effect of the invention clearer and clearer. It should be understood that the specific embodiments described herein are merely illustrative of the invention and do not limit the scope of the invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; may be mechanically connected, may be electrically connected or may be in communication with each other; either directly or indirectly through intervening media, either internally or in any other suitable relationship. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Referring to fig. 1-2, 4, and 11-12, the present invention provides an engine block production line, comprising: the cylinder sleeve carrying device 100 comprises a clamping mechanical arm 110 used for carrying cylinder sleeves to a material conveying vehicle 120 and the material conveying vehicle 120 used for conveying cylinder sleeves to the die-casting device 200, and a material conveying guide rail 160 used for moving the material conveying vehicle 120 is arranged between the die-casting device 200 and the cylinder sleeve carrying device 100; the die-casting device 200 comprises a die-casting machine 210 for die-casting out a cylinder body by matching with a cylinder sleeve and a transfer mechanical arm 220 for transferring the cylinder body to the chain conveying line 300; the chain conveying line 300 comprises two conveying chains 310 arranged in parallel, the chain conveying line 300 is used for conveying the cylinders to the material removing handle device 400, and the two conveying chains 310 are driven by a speed reducing motor 360; the material handle removing device 400 is butted with the output end of the chain conveying line 300 and is used for removing the material handle 920 on the cylinder body; and a de-bar-pressing device 500, which comprises a first pressing mechanism 510 arranged above the chain conveying line 300 close to one side of the de-bar-handle device 400 and a knock-out mechanical arm 520 arranged at one side of the first pressing mechanism 510; the first pressing mechanism 510 is used for pressing a cylinder on the chain conveying line 300, and the knocking-out mechanical arm 520 is used for knocking out the pressure reducing strip 910 on the cylinder.

Industrial cameras are mounted on the clamping mechanical arm 110, the transferring mechanical arm 220 and the knockout mechanical arm 520, and the industrial cameras can be 2D cameras or 3D cameras, so that functions of online image recognition, object detection and diagnosis are realized. For example: the clamping mechanical arm 110 captures the same cylinder sleeve as the target object through image recognition, and the knocking mechanical arm 520 detects burrs and pressure reducing strips 910 on the diagnosis cylinder body through image recognition and performs accurate knocking.

The material conveying vehicle 120 is provided with a carrier for placing the cylinder sleeves, and in the embodiment, 4 cylinder sleeves are used as a group for transportation, and the transportation is divided into two specifications, namely a large cylinder sleeve and a small cylinder sleeve; according to the actual specification, a technician can set a plurality of carriers in a group with multiple specifications.

Referring to fig. 1 and 11-12, in practical application, an operator needs to push a material cage with cylinder liners to a cylinder liner handling device 100, a clamping mechanical arm 110 clamps the cylinder liners out of the material cage and places the cylinder liners on a material conveying cart 120, and when the material conveying cart 120 detects that a group of cylinder liners are filled, the cylinder liners are conveyed to a die casting device 200; the cylinder body is die-cast and formed by the die-casting machine 210, and after being cooled, the cylinder body is transferred to the chain conveying line 300 by the transfer mechanical arm 220; the cylinder body is conveyed along the chain conveying line 300, passes through the pressure reducing strip removing device 500, and the pressure reducing strips 910 and burrs on the cylinder body are knocked out through the knocking-out mechanical arm 520; and finally, conveying the cylinder body to a material handle removing device 400, and removing the material handle 920 of the cylinder body to finish the production of the cylinder body. The whole working process and the production line are highly automated, manual control operation of operators is not needed, the working intensity of the operators is greatly reduced, the production efficiency is improved, and the cost of enterprise culture professional technicians is further reduced.

Referring to fig. 2-4, in some embodiments, the deburring device 600 further includes a second pressing mechanism 610 for pressing the cylinder and a knock-out mechanism 620 for knocking out the burr at the bottom of the cylinder; the second pressing mechanism 610 is disposed above the input end of the chain conveying line 300, and the knock-out mechanism 620 is disposed between the two conveying chains 310.

In actual production, due to the structural reasons of the models of part of the cylinder bodies, burrs exist at the bottom of the die-cast cylinder body, and normal transmission of the die-cast cylinder body on the chain conveying line 300 is influenced; therefore, through the arrangement, the burrs at the bottom of the cylinder body are removed in advance through the deburring device 600, and the normal transmission of the cylinder body on the chain conveying line 300 is guaranteed.

Referring to fig. 2-6 and 11, in some embodiments, a lifting mechanism 320 is disposed between the two conveyor chains 310, and corresponds to the first pressing mechanism 510 and the second pressing mechanism 610 up and down; the lifting mechanism 320 comprises a supporting block 321, a limiting strip 322, a bracket 323, a first lifting cylinder 324 and a second lifting cylinder 325; the first lifting cylinder 324 is vertically arranged between the two conveying chains 310, and the output end of the first lifting cylinder is connected with the supporting block 321; the bracket 323 is arranged between the two conveying chains 310, the second lifting cylinder 325 is arranged below the bracket 323, and the output end of the second lifting cylinder passes through the bracket 323 and is connected with the limiting strip 322; the limiting bar 322 is parallel to the conveying chain 310 and is disposed above the supporting block 321.

Referring to fig. 6 and 11, the position-limiting bar 322 is engaged with the arc-shaped groove at the bottom of the engine block 900 to limit the position of the engine block, and the supporting blocks 321 are used to support the edge portions at two sides of the arc-shaped groove.

With the above arrangement, when the engine block 900 moves to the lifting mechanism 320, the engine block 900 is lifted off the chain conveyor line 300, and the first pressing mechanism 510 or the second pressing mechanism 610 is matched to clamp the engine block 900 up and down. Meanwhile, the pressing mode does not influence the normal conveying of other engine cylinder blocks 900 on the chain conveying line 300, the operation of deburring or de-pressing strips is not required to be stopped, and the production efficiency is improved.

Referring to fig. 5 and 12, in the present embodiment, specifically, the first pressing mechanism 510 includes a support bracket 513, a first pressing cylinder 511 and a first pressing block 512; the support bracket 513 is arranged at one side of the chain conveying line 300, the first pressing cylinder 511 is arranged on the support bracket 513, and the output end of the first pressing cylinder is arranged downwards and connected with the first pressing block 512; the first pressing block 512 corresponds to the lifting mechanism 320 up and down. When the engine block 900 moves below the first pressing mechanism 510, the engine block 900 is pressed, and then the knock-out mechanical arm 520 knocks out burrs on the block and removes the pressure reduction strip 910.

Referring to fig. 3 to 4, in this embodiment, specifically, the second pressing mechanism 610 includes a second pressing cylinder 611 and a second pressing block 612, the second pressing cylinder 611 is disposed between the two conveying chains 310, and an output end of the second pressing cylinder 611 faces upward and is connected to the second pressing block 612, and the second pressing block 612 is configured in an elongated shape and is disposed parallel to the conveying chains 310. The knockout mechanism 620 comprises a knockout cylinder 622 vertically arranged between the two conveying chains 310, and the output end of the knockout cylinder 622 is connected with a hammer 621.

Referring to fig. 6, further, in some embodiments, the supporting block 321 is provided with a limiting mechanism 330 on both sides, the limiting mechanism 330 includes a limiting cylinder 331, a limiting plate 332 and a guiding seat 333, a fixed end of the limiting cylinder 331 is connected to the chain conveying line 300, and an output end of the limiting cylinder is connected to the limiting plate 332 and faces the supporting block 321; the guide holder 333 is mounted on two sides of the support block 321 and has an opening matching with the limit plate 332, and the limit plate 332 is inserted on the guide holder 333. Through the arrangement, after the bearing block 321 is lifted, the limiting plate 332 extends out of the bottom of the bearing block 321, so that the bearing block 321 is supported and limited, and the bearing capacity of the bearing block 321 is improved.

Referring to fig. 2 and 4-5, in some embodiments, a plurality of guide bars 340 parallel to the conveying chains 310 are disposed between the two conveying chains 310 along the conveying direction, and a blocking rod 350 disposed vertically is mounted on one side of an output end of each guide bar 340; the lower end of the blocking rod 350 is connected with a telescopic cylinder 351, and the upper end of the blocking rod 350 is provided with a probe 352 for detecting the motion state of the cylinder body. The guide strips 340 are matched with an arc-shaped groove structure at the bottom of the engine cylinder body 900 to play a role in guiding, so that the engine cylinder body 900 is prevented from deviating; and the blocking rod 350 is used to separate the engine blocks 900, maintain a distance between the engine blocks 900 and prevent the following engine block 900 from affecting the preceding engine block 900; the motion state of the engine block 900 is discriminated by the probe 352 and the distance between the engine blocks 900 is determined.

Preferably, a protective baffle 370 is disposed at one side of the chain conveyor line 300 to prevent the removed waste material from splashing out.

Referring to fig. 1, 10-12, in some embodiments, the present invention further includes a material handle transfer device 700 disposed above the material handle removing device 400, where the material handle transfer device 700 includes a beam frame 710, an X-axis motion 720, a Y-axis motion 730, a Z-axis motion 740 disposed perpendicular to each other, and a material handle gripper 750 connected to the Z-axis motion 740; the X-axis movement mechanism 720 is arranged on the beam frame 710; the Y-axis movement mechanism 730 is movably connected to the X-axis movement mechanism 720, and the Z-axis movement mechanism 740 is movably connected to the Y-axis movement mechanism 730; the Z-axis motion mechanism 740 may drive the material handle gripper 750 to move up and down. Through the above arrangement, the material handle transferring device 700 is a three-axis type gripper, which is convenient for adjusting the position of the gripper and transferring the material handle 920.

Preferably, the X-axis moving mechanism 720 includes an X-axis sliding rail 721, and two ends of the X-axis sliding rail 721 are provided with limit switches 722 to prevent the Y-axis moving mechanism 730 from coming off the X-axis sliding rail 721.

Preferably, the device also comprises a waste car 800 and a conveying guide rail 810; the scrap cart 800 is movably connected to a conveying rail 810 to facilitate the removal of the scrap; the waste car 800 is disposed on the knock-out robot 520 side and below the stem transfer device 700. Through the arrangement, the material handle transfer device 700 is convenient to transfer the material handle 920 to the waste car 800; meanwhile, after the knock-out robot knocks out the depression bar 910, the knocked-down depression bar 910 can be conveniently sent to the waste car 800, so that the centralized treatment of waste materials is realized, and the production efficiency is improved.

Referring to fig. 1, 7-12, in some embodiments, the material handle removing device 400 includes a first frame 410, a sliding base 420 disposed on the first frame 410, a feeding mechanism 430 for driving the sliding base 420 to move back and forth relative to the first frame 410, a cylinder transportation mechanism 440 disposed on an upper end surface of the sliding base 420, a material handle receiving frame 450 disposed on a rear side of the sliding base 420, a third pressing mechanism 460 for clamping the cylinder, a cutting mechanism 470 for removing the material handle 920, and a material handle guiding mechanism 480 disposed on a lower side of the material handle receiving frame 450; the cylinder body conveying mechanism 440 is in butt joint with the chain conveying line 300; the feed stalk guide mechanism 480 includes a transmission rod 481 rotatably disposed at the bottom of the feed stalk receiving rack 450, two or more guide rods 482 equidistantly disposed on the transmission rod 481 along the length direction of the transmission rod 481, and a guide driving mechanism 490 for driving the transmission rod 481 to rotate so that the guide rods 482 protrude out of the feed stalk receiving rack 450.

Specifically, the third pressing mechanism 460 is driven by an air cylinder, and the cutting mechanism 470 is driven by a hydraulic cylinder 471. The cutting mechanism 470 includes a hydraulic cylinder 471, a pressing hand 472, and a trimming die 473, the trimming die 473 is vertically disposed on the end of the material handle receiving frame 450 near the slide carriage 420, the hydraulic cylinder 471 is disposed above the trimming die 473, and the output end thereof is connected with the pressing hand 472 downward.

Through the arrangement, the cylinder is conveyed to the cylinder conveying mechanism 440 of the material removing handle device 400 by the chain conveying line 300, and after the cylinder is detected to be in place, the sliding seat 420 moves to the position below the cutting mechanism 470 and the third pressing mechanism 460; the third pressing mechanism 460 presses the engine cylinder body 900, the hydraulic cylinder 471 drives the pressing hand 472 to press down towards the material handle 920 of the engine cylinder body 900, the joint of the engine cylinder body 900 and the material handle 920 is abutted against the trimming die 473, and the material handle 920 is cut off. When the material handle 920 falls, the guide rod 482 keeps a state of extending the material handle receiving frame 450, and the material handle 920 is inclined after falling, at this time, the guide rod 482 is slowly retracted to place the material handle 920 flat, so that the material handle transfer device 700 can transfer the material handle 920.

Referring to fig. 5, 11-12, further, in the present embodiment, the pressure reducing strip removing device 500 further includes an auxiliary pressing mechanism 530, and the auxiliary pressing mechanism 530 includes an auxiliary pressing cylinder 531, an auxiliary pressing plate 532, an upper baffle 533 and a stepping motor 534; the auxiliary pressing cylinder 531 is vertically arranged at one side of the chain conveying line 300, the output end of the auxiliary pressing cylinder is connected with the auxiliary pressing plate 532 through a connecting plate 535, and a spring pressing column 536 is arranged between the connecting plate 535 and the auxiliary pressing plate 532; one side of the auxiliary pressure plate 532 is connected with a supporting plate 537, the stepping motor 534 is vertically installed on the supporting plate 537, and the output end thereof is connected with an upper baffle 533. Through the arrangement, the auxiliary pressing plate 532 ascends to press the extending part of the pressure reducing strip 910, the stepping motor 534 controls the upper baffle 533 to rotate above the auxiliary pressing plate 532, so that the vibration of the pressure reducing strip 910 in the knockout process is reduced, and the knockout precision is improved; meanwhile, the auxiliary pressing plate 532 and the upper baffle 533 clamp the extending part of the pressure reducing strip 910, so that the pressure reducing strip 910 is prevented from directly falling off and touching the equipment after being removed.

Preferably, the cylinder sleeve handling device 100 further includes a second frame 130; the gripping robot 110 is mounted on the top of the second frame 130, and a replacing frame 140 for replacing the gripper of the gripping robot 110 is provided at one side of the second frame 130. In practical application, generally, each layer of cylinder sleeve in the material cage is separated by leatheroid or each cylinder barrel is separated by cross-shaped separation paper, so that the gripper of the clamping mechanical arm 110 needs to be replaced to clamp the leatheroid or the cross-shaped separation paper, and the gripper used for clamping the leatheroid or the cross-shaped separation paper is placed on the replacement frame 140 through the replacement frame 140, so that the clamping mechanical arm 110 can be conveniently replaced according to conditions.

Preferably, a cylinder sleeve frame 150 for placing a cylinder sleeve is further arranged on one side of the second frame 130; through the arrangement, when the material conveying vehicle 120 transports the cylinder sleeve, the clamping mechanical arm 110 still can keep the working state, the cylinder sleeve is taken out of the material cage and placed on the cylinder sleeve frame 150, and after the material conveying vehicle 120 returns, the cylinder sleeve is transferred to the material conveying vehicle 120 from the cylinder sleeve frame 150, so that the production efficiency is improved.

In summary, in the embodiment, the engine block production line of the present invention includes the following work flows: clamping a cylinder sleeve, removing a paper sheet, removing cross paper, transporting the cylinder sleeve, die-casting a cylinder body, transferring the cylinder body, pre-removing burrs, conveying the cylinder body, removing a pressure reducing strip 910, cutting off a material handle 920, transferring the pressure reducing strip 910, carrying waste materials and the like; the whole production line is highly automated, manual control operation of operators is not needed, the working strength of the operators is greatly reduced, the production efficiency is improved, and the cost of enterprise culture professional technicians is further reduced.

It should be understood that equivalents and modifications of the technical solution and inventive concept thereof may occur to those skilled in the art, and all such modifications and alterations should fall within the protective scope of the present invention.

Claims (6)

1. The material handle clearing device is characterized by comprising a material handle removing device and a material handle transferring device arranged above the material handle removing device; the material handle removing device comprises a first machine frame, a sliding seat arranged on the first machine frame, a feeding mechanism used for driving the sliding seat to move back and forth relative to the first machine frame, a cylinder body conveying mechanism arranged on the upper end surface of the sliding seat, a material handle bearing frame arranged on the rear side of the sliding seat, a third pressing mechanism used for clamping a cylinder body, a cutting mechanism used for removing a material handle and a material handle guiding mechanism arranged on the lower side of the material handle bearing frame; the material handle guiding mechanism comprises a transmission rod which is rotatably arranged at the bottom of the material handle bearing frame, two or more than two guiding rods which are arranged on the transmission rod at equal intervals along the length direction of the transmission rod, and a guiding driving mechanism, wherein the guiding driving mechanism is used for driving the transmission rod to rotate so that the guiding rods extend out of the material handle bearing frame; the material handle transferring device is used for transferring the material handle removed by the material handle removing device.

2. The material handle removing device as claimed in claim 1, wherein the material handle transferring device comprises a beam frame, an X-axis motion mechanism, a Y-axis motion mechanism and a Z-axis motion mechanism which are arranged vertically, and a material handle gripper connected with the Z-axis motion mechanism; the X-axis movement mechanism is arranged on the beam frame; the Y-axis movement mechanism is movably connected to the X-axis movement mechanism, and the Z-axis movement mechanism is movably connected to the Y-axis movement mechanism; the Z-axis motion mechanism can drive the material handle gripper to move up and down.

3. The charge handle clearing device according to claim 2, wherein the X-axis movement mechanism comprises an X-axis slide rail, and limit switches are arranged at two ends of the X-axis slide rail.

4. The apparatus according to claim 1, wherein the cutting mechanism comprises a hydraulic cylinder, a pressing hand and a trimming die, the trimming die is vertically arranged at one end of the material handle bearing frame close to the sliding seat, the hydraulic cylinder is arranged above the trimming die, and the output end of the hydraulic cylinder is downward and is connected with the pressing hand.

5. The charge shank removing device according to claim 1, further comprising a waste car and a transport rail, the waste car being movably connected to the transport rail, the waste car being located below the charge shank transfer device.

6. An engine block production line using the tang removing device of any one of claims 1 to 5, further comprising:

the cylinder sleeve carrying device comprises a clamping mechanical arm used for carrying the cylinder sleeve to a material conveying vehicle and the material conveying vehicle used for conveying the cylinder sleeve to the die-casting device;

the die-casting device comprises a die-casting machine and a transfer mechanical arm, wherein the die-casting machine is used for being matched with the cylinder sleeve to perform die-casting on the cylinder body, and the transfer mechanical arm is used for transferring the cylinder body to the chain conveying line;

the chain conveying line is used for conveying the cylinder body to the material handle removing device of the material handle removing device;

the pressure reducing strip removing device comprises a first pressing mechanism and a knocking mechanical arm, wherein the first pressing mechanism is arranged above the chain conveying line close to one side of the material removing handle device, and the knocking mechanical arm is arranged on one side of the first pressing mechanism;

the first pressing mechanism is used for pressing a cylinder body on the chain conveying line, and the knocking mechanical arm is used for knocking out a pressure reducing strip on the cylinder body; the cylinder body conveying mechanism of the material removing handle device can be in butt joint with the output end of the chain conveying line.

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