CN216780440U - End face groove milling equipment - Google Patents

Abstract

The utility model discloses end face groove milling equipment which comprises an equipment frame, an equipment protective cover, a material pressing mechanism, a positioning mechanism, a transverse moving mechanism, a longitudinal moving mechanism, two vertical moving mechanisms and a cutting mechanism, wherein the equipment protective cover is arranged on the equipment frame, the material pressing mechanism, the positioning mechanism, the transverse moving mechanism, the longitudinal moving mechanism, the two vertical moving mechanisms and the cutting mechanism are all positioned in the equipment protective cover, the material pressing mechanism and the transverse moving mechanism are both arranged on the equipment frame, the material pressing mechanism is positioned in front of the transverse moving mechanism, a positioning bottom supporting plate is fixedly arranged on the left side of the bottom surface of the transverse moving mechanism close to the front, and a positioning mechanism is fixedly arranged on the top surface of the positioning bottom supporting plate. The milling device has the advantages of reasonable structural design, convenience in use and simplicity in operation, and can be used for milling two end surface grooves of a workpiece to be processed simultaneously, so that the processing efficiency is improved, and the processing cost is reduced.

Description

End face groove milling equipment

Technical Field

The utility model relates to machining equipment, in particular to end face groove milling equipment.

Background

The end face slot milling is generally carried out by an end face slot milling machine, but the end face slot milling machine in the prior art has a complex structure and is inconvenient to operate, so the production efficiency is low, and the processing cost is relatively high.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide end face groove milling equipment to solve the problems in the prior art.

In order to achieve the purpose, the utility model provides the following technical scheme:

an end face groove milling device comprises a device frame, a device protective cover, a material pressing mechanism, a positioning mechanism, a transverse moving mechanism, a longitudinal moving mechanism, two vertical moving mechanisms and a cutting mechanism, wherein the device protective cover is arranged on the device frame, the material pressing mechanism, the positioning mechanism, the transverse moving mechanism, the longitudinal moving mechanism, the two vertical moving mechanisms and the cutting mechanism are all arranged in the device protective cover, the material pressing mechanism and the transverse moving mechanism are both arranged on the device frame, the material pressing mechanism is arranged in front of the transverse moving mechanism, a positioning bottom supporting plate is fixedly arranged on the left side of the bottom surface of the transverse moving mechanism close to the front, the positioning mechanism is fixedly arranged on the top surface of the positioning bottom supporting plate, the positioning mechanism is arranged on the left side of the transverse moving mechanism, the two longitudinal moving mechanisms are arranged on the transverse moving mechanism, the two longitudinal moving mechanisms are symmetrically distributed on the left and the right, and the vertical moving mechanisms are arranged on the longitudinal moving mechanisms, the cutting mechanisms are arranged on the vertical moving mechanism, and the two cutting mechanisms are distributed one above the other.

The end face groove milling equipment comprises a lower pressing flat plate, the lower pressing flat plate is fixed on an equipment support, supporting rods are fixedly installed on the left side and the right side of the top surface of the lower pressing flat plate respectively, the top ends of the four supporting rods are fixedly connected through an upper air cylinder flat plate, a pressing plate is arranged between the upper air cylinder flat plate and the lower pressing flat plate, a through hole I is formed in the middle of the top surface of the upper air cylinder flat plate, an air cylinder is fixedly installed in the middle of the top surface of the upper air cylinder flat plate, the movable end of the air cylinder penetrates through the through hole I to be fixedly connected with the top surface of the pressing plate, two through holes II which are distributed in bilateral symmetry are formed in the top surface of the upper air cylinder flat plate, a sliding sleeve is installed in each through hole II, a guide rod is arranged in each sliding sleeve and can slide up and down along each sliding sleeve, the top end of each guide rod is located above the upper air cylinder flat plate, the bottom end of each guide rod is fixedly connected with the top surface of the corresponding pressing flat plate, blocking strips are installed on the left side and the right side of the top surface of the lower pressing flat plate respectively, and the blocking strips are located on the inner sides of the supporting rods.

The end face groove milling equipment comprises a positioning support platform, wherein the positioning support platform is fixed on a positioning bottom supporting plate, two longitudinal guide rails I which are bilaterally and symmetrically distributed are fixedly arranged on the top surface of the positioning support platform, a longitudinal slide block I is arranged on each longitudinal guide rail I in a matching way and can move back and forth along the corresponding longitudinal guide rail I, the top surfaces of the two longitudinal slide blocks I are fixedly connected through a push plate casting, a push plate is fixedly arranged in front of the push plate casting, an axle seat is fixedly arranged on the top surface of the positioning support platform and is positioned at the rear part of the middle of the two longitudinal guide rails I and behind the push plate casting, a through hole III is formed in front of the axle seat, a fine adjustment hand wheel is arranged in a bearing in the through hole III, the front side and the rear side of the fine adjustment hand wheel are both positioned outside the axle seat, a threaded through hole is formed in the middle part of the front side of the fine adjustment hand wheel, a positioning screw rod is arranged in the threaded through hole, and the plane is positioned on the top part of the positioning screw rod, positioning screw and screw thread through-hole screw-thread fit, the scale is installed to the positioning screw top surface, installs on the positioning screw and prevents changeing the piece, prevents changeing the piece and is located between axle bed and the push pedal foundry goods, prevents between changeing the piece and the push pedal foundry goods opposite side through two longitudinal connecting rod fixed connection, two longitudinal connecting rod bilateral symmetry distribute.

As above an end face milling flutes equipment, lateral shifting mechanism include the lateral guideway of two longitudinal symmetry distributions, the lateral guideway is fixed on equipment support, the cooperation is equipped with four horizontal sliders on the lateral guideway, horizontal slider can move about along the lateral guideway that corresponds, through big carriage fixed connection between the eight horizontal slider top surfaces, be close to rear department and offer through-hole IV through big carriage top surface middle part, through-hole IV top fixed mounting motor I, motor I's output passes through-hole IV, and be located big carriage below, motor I's output fixed mounting drive gear, drive gear is located between two lateral guideway, fixed mounting rack on the equipment support, the rack is located between two lateral guideway, and be located drive gear the place ahead, rack and drive gear meshing cooperation.

The end face groove milling equipment comprises two longitudinal moving mechanisms, wherein the two longitudinal moving mechanisms respectively comprise two longitudinal guide rails II which are bilaterally symmetrically distributed, the longitudinal guide rails II are fixed on a large slide carriage, two longitudinal slide blocks II are arranged on the longitudinal guide rails II in a matching way and can move back and forth along the corresponding longitudinal guide rails II, the top surfaces of the longitudinal slide blocks II are fixedly provided with connecting cushion blocks, the top surfaces of the four connecting cushion blocks are fixedly connected through a small slide carriage, two mounting vertical plates which are bilaterally symmetrically distributed are arranged at the rear part of the middle of the two longitudinal guide rails II, the back surfaces of the two mounting vertical plates are fixedly connected through a fixing plate, a through hole V is formed in the fixing plate, a motor II is fixedly arranged at the rear end of the through hole V, the output end of the motor II penetrates through the through hole V and is positioned in front of the fixing plate, a longitudinal screw rod is fixedly arranged at the output end of the motor II, two supporting seats I which are arranged in front and back are arranged on the longitudinal screw rod in a bearing way, the bottom surfaces of the supporting seats I are fixedly connected with the top surface of the large slide carriage, the longitudinal screw is provided with a thread seat I, the thread seat I is positioned between the two supporting seats I, the thread seat I is in thread fit with the longitudinal screw, and the top surface of the thread seat I is fixedly connected with the bottom surface of the small slide carriage.

The end face groove milling equipment comprises the upright post, the bottom surface of the upright post is fixed on the small slide carriage, two vertical guide rails which are symmetrically distributed front and back are fixedly arranged on the inner side of the upright post, two vertical slide blocks are matched and arranged on the vertical guide rails and can move up and down along the corresponding vertical guide rails, the inner sides of the four vertical guide rails are fixedly connected through a connecting plate, a motor mounting plate is fixedly arranged at the top end of the upright post, a through hole VI is formed in the motor mounting plate, a motor III is fixedly arranged at the top end of the through hole VI, the output end of the motor III passes through the through hole VI and is positioned below the motor mounting plate, a vertical screw rod is fixedly arranged at the output end of the motor III, two supporting seats II which are distributed up and down are arranged on the vertical screw rod through a bearing, the supporting seat II positioned above is fixedly connected with the upright post, the supporting seat II positioned below is fixedly connected with the small slide carriage, and a screw seat II is arranged on the vertical screw rod, screw thread seat II and vertical screw rod screw-thread fit, screw thread seat II and connecting plate fixed connection.

According to the end face groove milling equipment, the bottom surface of the equipment support is provided with the scrap collecting box.

According to the end face groove milling equipment, the left side and the right side of the equipment frame are respectively and fixedly provided with the limiting plates I, and the limiting cushion blocks I are fixedly arranged on the limiting plates I.

According to the end face groove milling equipment, the large slide carriage is fixedly provided with the two limiting plates II which are symmetrically distributed in the left-right direction, the limiting blocks are fixedly arranged in front of the fixing plates and correspond to the limiting plates II, and the front sides of the limiting blocks and the back sides of the limiting plates II are respectively fixedly provided with the limiting cushion blocks II.

According to the end face groove milling equipment, the limiting plate III is fixedly installed on the inner side of the lower sliding plate, the limiting cushion block III is fixedly installed on the inner sides of the top surface of the limiting plate III and the bottom surface of the motor installation plate, one limiting cushion block III is installed on the top surface of the limiting plate III, and two limiting cushion blocks III are installed on the bottom surface of the motor installation plate.

According to the end face groove milling equipment, the cutting mechanism comprises the mounting plate and the cutting motor, the cutting motor is mounted on the mounting plate, the mounting plate is mounted on the connecting plate, and the milling cutter is fixedly mounted at the output end of the cutting motor.

The utility model has the advantages that: the milling device has the advantages of reasonable structural design, convenience in use and simplicity in operation, and can simultaneously complete milling of two end surface grooves of a workpiece to be processed, so that the processing efficiency is improved, and the processing cost is reduced.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive labor.

FIG. 1 is a schematic structural view of the present invention; FIG. 2 is a schematic view of a perspective of the present invention with the equipment rack removed; FIG. 3 is a schematic view of another alternate view of the present invention with the equipment rack removed; FIG. 4 is a schematic view of the structure of the equipment rack; FIG. 5 is a schematic view of the structure of the equipment shelter from one perspective; FIG. 6 is a schematic view of another perspective of the equipment shelter; FIG. 7 is a schematic view of a connection structure of the equipment rack and the traverse mechanism; FIG. 8 is a schematic view of the structure of FIG. 7 with the large slide removed; FIG. 9 is a schematic view of the structure of a large slide; FIG. 10 is a schematic structural view of the swaging mechanism; FIG. 11 is a schematic structural view of the upper cylinder plate; FIG. 12 is a schematic view of the positioning mechanism; FIG. 13 is a top view of FIG. 12;

FIG. 14 is a schematic view of a fine adjustment hand wheel; FIG. 15 is a schematic view of the shaft seat; FIG. 16 is a schematic view of the connection of the large slide and the longitudinal moving mechanism with the small slide removed; FIG. 17 is a schematic view showing a coupling structure of a small slide and a vertical moving structure; FIG. 18 is a schematic view of the structure of FIG. 17 with the connecting plate removed; FIG. 19 is a schematic view showing a coupling structure of the small slide, the pillar and the motor mounting plate; fig. 20 is a schematic structural view of the cutting mechanism.

Reference numerals: 1. an equipment rack; 2. an equipment shield; 3. a material pressing mechanism; 301. pressing a lower flat plate; 302. a strut; 303. an upper cylinder plate; 304. pressing a plate; 305. a cylinder; 306. a sliding sleeve; 307. a guide bar; 308. blocking strips; 4. a positioning mechanism; 401. positioning the support table; 402. a longitudinal guide rail I; 403. a longitudinal slide block I; 404. a push plate casting; 405. pushing the plate; 406. a shaft seat; 407. finely adjusting a hand wheel; 408. a threaded through hole; 409. positioning a screw rod; 410. a scale; 411. a rotation prevention sheet; 412. a longitudinal connecting rod; 5. a lateral movement mechanism; 501. a transverse guide rail; 502. a transverse slide block; 503. a large slide carriage; 504. a motor I; 505. a drive gear; 506. a rack; 6. a longitudinal movement mechanism; 601. a longitudinal guide rail II; 602. a longitudinal slide block II; 603. connecting the cushion blocks; 604. a small slide carriage; 605. installing a vertical plate; 606. a fixing plate; 607. a motor II; 608. a longitudinal screw; 609. a support seat I; 610. a threaded seat I; 7. a vertical moving mechanism; 701. a column; 702. a vertical guide rail; 703. a vertical slide block; 704. a connecting plate; 705. a motor mounting plate; 706. a motor III; 707. a vertical screw; 708. a supporting seat II; 709. a screw base II; 8. a cutting mechanism; 801. mounting a plate; 802. cutting the motor; 803. milling cutters; 9. positioning a bottom supporting plate; 10. a scrap collecting box; 11. a limiting plate I; 12. a limiting cushion block I; 13. a limiting plate II; 14. a limiting block; 15. a limiting cushion block II; 16. a limiting plate III; 17. and limiting cushion blocks III.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1-20, an end face slot milling device comprises a device frame 1, a device shield 2, a material pressing mechanism 3, a positioning mechanism 4, a transverse moving mechanism 5, a longitudinal moving mechanism 6, two vertical moving mechanisms 7 and a cutting mechanism 8, wherein the device shield 2 is mounted on the device frame 1, the material pressing mechanism 3, the positioning mechanism 4, the transverse moving mechanism 5, the longitudinal moving mechanism 6, the two vertical moving mechanisms 7 and the cutting mechanism 8 are all located in the device shield 2, the material pressing mechanism 3 and the transverse moving mechanism 5 are both mounted on the device frame, the material pressing mechanism 3 is located in front of the transverse moving mechanism 5, a positioning bottom support plate 9 is fixedly mounted on the left side of the bottom surface of the transverse moving mechanism 5 near the front, the positioning mechanism 4 is fixedly mounted on the top surface of the positioning bottom support plate 9, the positioning mechanism 4 is located on the left side of the transverse moving mechanism 5, the two longitudinal moving mechanisms 6 are mounted on the transverse moving mechanism 5, the two longitudinal moving mechanisms 6 are distributed in bilateral symmetry, the vertical moving mechanism 7 is installed on the longitudinal moving mechanism 6, the cutting mechanism 8 is installed on the vertical moving mechanism 7, and the two cutting mechanisms 8 are distributed one above the other. When the utility model is used, firstly, a workpiece to be processed is placed on the material pressing mechanism 3, then the workpiece to be processed is put on the material pressing mechanism 3 by the positioning mechanism 4 for positioning, then the workpiece to be processed is pressed and fixed by the material pressing mechanism 3, then the two vertical moving mechanisms 7 are adjusted to enable the two vertical moving mechanisms 7 to be distributed one above the other, thereby enabling the two cutting mechanisms 8 to be distributed one above the other, then the longitudinal moving mechanism 6 drives the vertical moving mechanism 7 to move forward, the vertical moving mechanism 7 drives the cutting mechanism 8 to move forward, therefore, the two cutting mechanisms 8 are moved to proper positions, finally, the transverse moving mechanism drives the longitudinal moving mechanism 6 to move leftwards, the longitudinal moving mechanism 6 drives the two vertical moving mechanisms 7 to move leftwards, the vertical moving mechanism 7 drives the cutting mechanism 8 to move leftwards, and the cutting mechanism 8 cuts a workpiece to be machined to finish groove milling; the milling device has the advantages of reasonable structural design, convenience in use and simplicity in operation, and can simultaneously complete milling of two end surface grooves of a workpiece to be processed, so that the processing efficiency is improved, and the processing cost is reduced.

Specifically, the pressing mechanism 3 described in this embodiment includes a pressing lower plate 301, the pressing lower plate 301 is fixed on the apparatus support 1, the support rods 302 are respectively and fixedly installed on the left and right sides of the top surface of the pressing lower plate 301, the top ends of the four support rods 302 are fixedly connected through an upper cylinder plate 303, a pressing plate 304 is disposed between the upper cylinder plate 303 and the pressing lower plate 301, a through hole I is formed in the middle of the top surface of the upper cylinder plate 303, an air cylinder 305 is fixedly installed in the middle of the top surface of the upper cylinder plate 303, the movable end of the air cylinder 305 passes through the through hole I and is fixedly connected with the top surface of the pressing plate 304, two through holes II symmetrically distributed in the left and right direction are formed in the top surface of the upper cylinder plate 303, a sliding sleeve 306 is installed in the through hole II, a guide rod 307 is disposed in the sliding sleeve 306, the guide rod 307 can slide up and down along the sliding sleeve 306, the top end of the guide rod 307 is located above the upper cylinder plate 303, the bottom end of the guide rod 307 is fixedly connected with the top surface of the pressing plate 304, the left side and the right side of the top surface of the material pressing lower flat plate 301 are respectively provided with a barrier strip 308, and the barrier strips 308 are positioned at the inner side of the supporting rod 302. During the use, through the flexible clamp plate 304 that drives of control cylinder 305 down or up-shift correspondingly, clamp plate 304 is close to gradually or keeps away from and places the work piece of treating on pressing material lower plate 301 to can push down or loosen the work piece of treating processing, when clamp plate 304 down or up-shift, guide bar 307 slides from top to bottom along the sliding sleeve 306 that corresponds and leads to clamp plate 304, makes the removal of clamp plate 304 more stable.

Specifically, the positioning mechanism 4 described in this embodiment includes a positioning support platform 401, the positioning support platform 401 is fixed on the positioning bottom supporting plate 9, two longitudinal guide rails I402 which are bilaterally symmetrically distributed are fixedly installed on the top surface of the positioning support platform 401, a longitudinal slide block I403 is cooperatively installed on the longitudinal guide rail I402, the longitudinal slide block I403 can move back and forth along the corresponding longitudinal guide rail I402, the top surfaces of the two longitudinal slide blocks I403 are fixedly connected through a push plate casting 404, a push plate 405 is fixedly installed in front of the push plate casting 404, a shaft seat 406 is fixedly installed on the top surface of the positioning support platform 401, the shaft seat 406 is located behind the middle of the two longitudinal guide rails I402, the shaft seat 406 is located behind the push plate casting 404, a through hole III is formed in front of the shaft seat 406, a fine adjustment hand wheel 407 is installed in the through hole III, both front and rear sides of the fine adjustment hand wheel 407 are located outside the shaft seat 406, a threaded through hole 408 is formed in the middle of the front side of the fine adjustment hand wheel 407, a positioning screw rod 409 is arranged in the threaded through hole 408, the top position plane of the positioning screw 409, the positioning screw 409 is in threaded fit with the threaded through hole 408, the scale 410 is installed on the top surface of the positioning screw 409, the anti-rotation piece 411 is installed on the positioning screw 409, the anti-rotation piece 411 is located between the shaft seat 406 and the push plate casting 404, the anti-rotation piece 411 is fixedly connected with the opposite side of the push plate casting 404 through two longitudinal connecting rods 412, and the two longitudinal connecting rods 412 are distributed in bilateral symmetry. When the fine adjustment hand wheel 407 is used, the fine adjustment hand wheel 407 is rotated, because the positioning screw 409 is in threaded fit with the threaded through hole 408 on the fine adjustment hand wheel 407, and the positioning screw 409 cannot rotate under the limitation of the longitudinal connecting rod 412, the positioning screw 409 can only move forwards along the threaded through hole 408, the positioning screw 409 drives the rotation preventing piece 411 and the longitudinal connecting rod 412 to move forwards, the longitudinal connecting rod 412 pushes the push plate casting 404 and the push plate 405 thereon to move forwards, the push plate 405 pushes the workpiece to be processed to enable the workpiece to be processed to swing forwards, and when the push plate casting 404 and the push plate 405 thereon move forwards, the longitudinal slide block I403 moves forwards along the corresponding longitudinal guide rail I402 to guide the push plate casting 404.

Further, the transverse moving mechanism 5 described in this embodiment includes two transverse guide rails 501 symmetrically distributed in the front-back direction, the transverse guide rails 501 are fixed on the equipment support 1, four transverse sliders 502 are cooperatively arranged on the transverse guide rails 501, the transverse sliders 502 can move left and right along the corresponding transverse guide rails 501, the top surfaces of the eight transverse sliders 502 are fixedly connected through a large slide carriage 503, a through hole IV is formed in the middle of the top surface of the large slide carriage 503 near the rear, a motor I504 is fixedly installed at the top end of the through hole IV, the output end of the motor I504 passes through the through hole IV and is located below the large slide carriage 503, a drive gear 505 is fixedly installed at the output end of the motor I504, the drive gear 505 is located between the two transverse guide rails 501, a rack 506 is fixedly installed on the equipment support 1, the rack 506 is located between the two transverse guide rails 501 and is located in front of the drive gear 505, and the rack 506 is engaged with the drive gear 505. When the sliding device is used, the motor I504 is started, the motor I504 drives the driving gear 505 to rotate, the driving gear 505 is meshed and matched with the rack 506, the driving gear 505 moves left and right along the rack 506, the driving gear 505 drives the large sliding plate 503 to move left and right, and the transverse sliding block 502 moves left and right along the corresponding transverse guide rail 501 to guide the large sliding plate 503 while moving left and right.

Furthermore, in this embodiment, each of the two longitudinal moving mechanisms 6 includes two longitudinal guide rails II601 symmetrically distributed left and right, the longitudinal guide rails II601 are fixed on the large slide carriage 503, two longitudinal sliding blocks II602 are disposed on the longitudinal guide rails II601 in a matching manner, the longitudinal sliding blocks II602 can move back and forth along the corresponding longitudinal guide rails II601, the top surfaces of the longitudinal sliding blocks II602 are fixedly mounted with the connecting pads 603, the top surfaces of the four connecting pads 603 are fixedly connected through the small slide carriage 604, two mounting vertical plates 605 symmetrically distributed left and right are disposed behind the middle of the two longitudinal guide rails II601, the back surfaces of the two mounting vertical plates 605 are fixedly connected through the fixing plate 606, the fixing plate 606 is provided with a through hole V, the back end of the through hole V is fixedly mounted with the motor II607, the output end of the motor II607 passes through the through hole V and is located in front of the fixing plate 606, the output end of the motor II607 is fixedly mounted with a longitudinal screw 608, the longitudinal screw 608 is bearing-mounted with two supporting seats I609 distributed front and back, the bottom surfaces of the supporting seats I609 are fixedly connected with the top surface of the large slide carriage 603, the longitudinal screw 608 is provided with a threaded seat I610, the threaded seat I610 is positioned between the two supporting seats I609, the threaded seat I610 is in threaded fit with the longitudinal screw 608, and the top surface of the threaded seat I610 is fixedly connected with the bottom surface of the small slide carriage 604. When the small slide carriage is used, the motor II607 is started, the motor II607 drives the longitudinal screw rod 608 to rotate, the longitudinal screw rod 608 is in threaded fit with the threaded seat I610, and the threaded seat I610 cannot rotate under the limitation of the small slide carriage 604, so the threaded seat I610 can only move back and forth along the longitudinal screw rod 608, the threaded seat I610 drives the small slide carriage 604 to move back and forth, and the longitudinal slide block II602 moves back and forth along the corresponding longitudinal guide rail II601 to guide the small slide carriage 604 while the small slide carriage 604 moves back and forth.

Furthermore, the vertical moving mechanism 7 described in this embodiment includes an upright column 701, a bottom surface of the upright column 701 is fixed on a small slide carriage 604, two vertical guide rails 702 symmetrically distributed back and forth are fixedly installed inside the upright column 701, two vertical sliders 703 are cooperatively arranged on the vertical guide rails 702, the vertical sliders 703 can move up and down along the corresponding vertical guide rails 702, insides of the four vertical guide rails 702 are fixedly connected by a connecting plate 704, a motor mounting plate 705 is fixedly installed at a top end of the upright column 701, a through hole VI is formed in the motor mounting plate 705, a motor III706 is fixedly installed at a top end of the through hole VI, an output end of the motor III706 passes through the through hole VI and is located below the motor mounting plate 705, a vertical screw 707 is fixedly installed at an output end of the motor III706, two vertically distributed support bases II708 are installed on the vertical screw 707 in a bearing manner, the support base II708 located above is fixedly connected with the upright column 701, and the support base II708 located below is fixedly connected with the small slide carriage 604, and a thread seat II709 is arranged on the vertical screw 707, the thread seat II709 is in thread fit with the vertical screw 707, and the thread seat II709 is fixedly connected with the connecting plate 704. During the use, starter motor III706, motor III706 drives vertical screw 707 and rotates, because vertical screw 707 and screw thread seat II709 screw-thread fit, and screw thread seat II709 receives the restriction of connecting plate 704 can not rotate, consequently screw thread seat II709 can only reciprocate along vertical screw 707, vertical screw 707 drives connecting plate 704 and reciprocates, when connecting plate 704 reciprocates, vertical slider 703 reciprocates along corresponding vertical guide rail 702 and leads to connecting plate 704.

Further, the bottom surface of the equipment stand 1 according to the present embodiment is provided with a scrap collecting box 10. The waste scraps can be collected by arranging the waste scrap collecting box 10, and the waste scraps are prevented from being scattered randomly.

Furthermore, the left and right sides of the equipment rack 1 according to this embodiment are respectively and fixedly installed with a limiting plate I11, and a limiting pad I12 is fixedly installed on the limiting plate I11. By providing this structure, the lateral slider 502 can be prevented from being separated from the lateral guide 501 during the movement.

Furthermore, two limit plates II13 are fixedly mounted on the large slide carriage 503, the limit blocks II13 are symmetrically arranged on the left and right sides of the large slide carriage, the limit block 14 is fixedly mounted in front of the fixing plate 606, the limit block 14 corresponds to the limit plate II13, and the limit cushion blocks II15 are fixedly mounted in front of the limit block 14 and on the back of the limit plate II13 respectively. By the arrangement of the structure, the longitudinal sliding block II602 can be prevented from being separated from the longitudinal guide rail II601 in the moving process.

Furthermore, a limiting plate III16 is fixedly mounted on the inner side of the lower chute plate 604, a limiting cushion block III17 is fixedly mounted on the inner sides of the top surface of the limiting plate III16 and the bottom surface of the motor mounting plate 705, a limiting cushion block III17 is mounted on the top surface of the limiting plate III16, and two limiting cushion blocks III17 are mounted on the bottom surface of the motor mounting plate 705. By adopting the structure, the vertical sliding block 703 can be prevented from being separated from the vertical guide rail 702 in the moving process.

Furthermore, the cutting mechanism 8 according to the embodiment includes a mounting plate 801 and a cutting motor 802, the cutting motor 802 is mounted on the mounting plate 801, the mounting plate 801 is mounted on the connecting plate 704, and the output end of the cutting motor 802 is fixedly mounted with the milling cutter 803.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (8)

1. The end face groove milling equipment is characterized in that: comprises an equipment frame (1), an equipment protective cover (2), a material pressing mechanism (3), a positioning mechanism (4), a transverse moving mechanism (5), a longitudinal moving mechanism (6), two vertical moving mechanisms (7) and a cutting mechanism (8), wherein the equipment protective cover (2) is arranged on the equipment frame (1), the material pressing mechanism (3), the positioning mechanism (4), the transverse moving mechanism (5), the longitudinal moving mechanism (6), the two vertical moving mechanisms (7) and the cutting mechanism (8) are all positioned in the equipment protective cover (2), the material pressing mechanism (3) and the transverse moving mechanism (5) are all arranged on the equipment frame, the material pressing mechanism (3) is positioned in front of the transverse moving mechanism (5), a positioning bottom supporting plate (9) is fixedly arranged at the position close to the front part on the left side of the bottom surface of the transverse moving mechanism (5), and the positioning mechanism (4) is fixedly arranged on the top surface of the positioning bottom supporting plate (9), the positioning mechanism (4) is positioned on the left side of the transverse moving mechanism (5), the two longitudinal moving mechanisms (6) are installed on the transverse moving mechanism (5), the two longitudinal moving mechanisms (6) are distributed in a bilateral symmetry mode, the vertical moving mechanism (7) is installed on the longitudinal moving mechanism (6), the cutting mechanisms (8) are installed on the vertical moving mechanism (7), and the two cutting mechanisms (8) are distributed one above the other.

2. An end face milling flutes apparatus as claimed in claim 1 wherein: the pressing mechanism (3) comprises a pressing lower flat plate (301), the pressing lower flat plate (301) is fixed on the equipment frame (1), the left side and the right side of the top surface of the pressing lower flat plate (301) are respectively and fixedly provided with a support rod (302), the top ends of the four support rods (302) are fixedly connected through an upper air cylinder flat plate (303), a pressing plate (304) is arranged between the upper air cylinder flat plate (303) and the pressing lower flat plate (301), the middle part of the top surface of the upper air cylinder flat plate (303) is provided with a through hole I, the middle part of the top surface of the upper air cylinder flat plate (303) is fixedly provided with an air cylinder (305), the movable end of the air cylinder (305) passes through the through hole I and is fixedly connected with the top surface of the pressing plate (304), the top surface of the upper air cylinder flat plate (303) is provided with two through holes II which are distributed in bilateral symmetry, a sliding sleeve (306) is arranged in the through hole II, a guide rod (307) is arranged in the sliding sleeve (306), and the guide rod (307) can slide up and down along the sliding sleeve (306), the top end of the guide rod (307) is positioned above the upper cylinder flat plate (303), the bottom end of the guide rod (307) is fixedly connected with the top surface of the pressing plate (304), blocking strips (308) are respectively arranged on the left side and the right side of the top surface of the pressing lower flat plate (301), and the blocking strips (308) are positioned on the inner side of the supporting rod (302).

3. An end face slot milling apparatus as claimed in claim 1, wherein: the positioning mechanism (4) comprises a positioning support platform (401), the positioning support platform (401) is fixed on a positioning bottom supporting plate (9), two longitudinal guide rails I (402) which are bilaterally symmetrically distributed are fixedly installed on the top surface of the positioning support platform (401), a longitudinal sliding block I (403) is arranged on each longitudinal guide rail I (402) in a matching mode, each longitudinal sliding block I (403) can move back and forth along the corresponding longitudinal guide rail I (402), the top surfaces of the two longitudinal sliding blocks I (403) are fixedly connected through a push plate casting (404), a push plate (405) is fixedly installed on the front surface of each push plate casting (404), a shaft seat (406) is fixedly installed on the top surface of the positioning support platform (401), the shaft seat (406) is located behind the middle of the two longitudinal guide rails I (402), the shaft seat (406) is located behind the push plate casting (404), a through hole III is formed in the front surface of the shaft seat (406), and a fine-tuning hand wheel (407) is installed in the through hole III) through bearing, both sides all are located axle bed (406) outside around fine setting hand wheel (407), screw thread through-hole (408) are seted up at fine setting hand wheel (407) front side middle part, be equipped with positioning screw (409) in screw thread through-hole (408), positioning screw (409) top bit plane, positioning screw (409) and screw thread through-hole (408) screw-thread fit, scale (410) are installed to positioning screw (409) top surface, install on positioning screw (409) and prevent changeing piece (411), prevent changeing between piece (411) are located axle bed (406) and push pedal foundry goods (404), prevent changeing between piece (411) and the push pedal foundry goods (404) opposite side through two longitudinal connecting rod (412) fixed connection, two longitudinal connecting rod (412) bilateral symmetry distribute.

4. An end face slot milling apparatus as claimed in claim 1, wherein: the transverse moving mechanism (5) comprises two transverse guide rails (501) which are symmetrically distributed front and back, the transverse guide rails (501) are fixed on the equipment frame (1), four transverse sliding blocks (502) are arranged on the transverse guide rails (501) in a matched mode, the transverse sliding blocks (502) can move left and right along the corresponding transverse guide rails (501), the top surfaces of the eight transverse sliding blocks (502) are fixedly connected through a large sliding plate (503), a through hole IV is formed in the middle of the top surface of the large sliding plate (503) and close to the rear part, a motor I (504) is fixedly installed at the top end of the through hole IV, the output end of the motor I (504) penetrates through the through hole IV and is located below the large sliding plate (503), a driving gear (505) is fixedly installed at the output end of the motor I (504), the driving gear (505) is located between the two transverse guide rails (501), a rack (506) is fixedly installed on the equipment frame (1), and the rack (506) is located between the two transverse guide rails (501), and is positioned in front of the driving gear (505), and the rack (506) is meshed with the driving gear (505).

5. An end face milling flutes apparatus as claimed in claim 1 wherein: the two longitudinal moving mechanisms (6) respectively comprise two longitudinal guide rails II (601) which are bilaterally and symmetrically distributed, the longitudinal guide rails II (601) are fixed on a large slide carriage (503), two longitudinal sliding blocks II (602) are arranged on the longitudinal guide rails II (601) in a matching way, the longitudinal sliding blocks II (602) can move back and forth along the corresponding longitudinal guide rails II (601), the top surfaces of the longitudinal sliding blocks II (602) are fixedly provided with connecting cushion blocks (603), the top surfaces of the four connecting cushion blocks (603) are fixedly connected through a small slide carriage (604), two mounting vertical plates (605) which are bilaterally and symmetrically distributed are arranged at the rear part of the middle of the two longitudinal guide rails II (601), the back surfaces of the two mounting vertical plates (605) are fixedly connected through a fixing plate (606), a through hole V is formed in the fixing plate (606), a motor II (607) is fixedly arranged at the rear end of the through hole V, the output end of the motor II (607) passes through the through hole V and is positioned in front of the fixing plate (606), the output end of the motor II (607) is fixedly provided with a longitudinal screw rod (608), two supporting seats I (609) which are distributed front and back are arranged on the longitudinal screw rod (608) in a bearing mode, the bottom surface of each supporting seat I (609) is fixedly connected with the top surface of the large slide carriage (503), a threaded seat I (610) is arranged on the longitudinal screw rod (608), the threaded seat I (610) is located between the two supporting seats I (609), the threaded seat I (610) is in threaded fit with the longitudinal screw rod (608), and the top surface of the threaded seat I (610) is fixedly connected with the bottom surface of the small slide carriage (604).

6. An end face milling flutes apparatus as claimed in claim 1 wherein: the vertical moving mechanism (7) comprises a vertical column (701), the bottom surface of the vertical column (701) is fixed on a small slide carriage (604), two vertical guide rails (702) which are symmetrically distributed front and back are fixedly arranged on the inner side of the vertical column (701), two vertical sliding blocks (703) are arranged on the vertical guide rails (702) in a matching manner, the vertical sliding blocks (703) can move up and down along the corresponding vertical guide rails (702), the inner sides of the four vertical guide rails (702) are fixedly connected through a connecting plate (704), a motor mounting plate (705) is fixedly arranged at the top end of the vertical column (701), a through hole VI is formed in the motor mounting plate (705), a motor III (706) is fixedly arranged at the top end of the through hole VI, the output end of the motor III (706) passes through the through hole VI and is positioned below the motor mounting plate (705), a vertical screw rod (707) is fixedly arranged at the output end of the motor III (706), two supporting seats II (708) which are vertically distributed are arranged on the vertical screw rod (707) in a bearing manner, the supporting seat II (708) and the upright post (701) that are located the top are fixedly connected, the supporting seat II (708) and the small slide carriage (604) that are located the below are fixedly connected, a thread seat II (709) is arranged on the vertical screw rod (707), the thread seat II (709) is in thread fit with the vertical screw rod (707), and the thread seat II (709) is fixedly connected with the connecting plate (704).

7. An end face milling flutes apparatus as claimed in claim 1 wherein: the cutting mechanism (8) comprises a mounting plate (801) and a cutting motor (802), the cutting motor (802) is mounted on the mounting plate (801), the mounting plate (801) is mounted on a connecting plate (704), and a milling cutter (803) is fixedly mounted at the output end of the cutting motor (802).

8. An end face milling flutes apparatus as claimed in claim 1 wherein: the bottom surface of the equipment frame (1) is provided with a scrap collecting box (10).

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