阅读说明：本技术 一种机械加工用具有防钝化结构的镗床 (Boring machine with passivation preventing structure for machining ) 是由 李颖琼 陈静 黄小蕊 于 2021-08-12 设计创作，主要内容包括：本发明涉及一种机械加工用具有防钝化结构的镗床,包括设备壳体和细加工机构,所述设备壳体的内部下壁从中间至前后两侧依次设置有第一多节液压缸和皮带输送机,且皮带输送机的上端连接有托板,所述托板的上端放置有槽板,所述设备壳体的内部上壁从中间至左右两侧依次设置有连接轴和夹持上料机构,且连接轴的下端设置有按压固定机构,所述连接轴的一侧安装有第一电机,本发明的有益效果是：该机械加工用具有防钝化结构的镗床,通过第三电机带动螺旋杆旋转把粗刀开槽时产生的金属屑排走,防止大量的金属屑堆积在粗刀处,影响粗刀处槽板的加工,同时也能够增加粗刀处槽板切割的阻力,使粗刀容易出现钝化,降低粗刀的使用寿命。(The invention relates to a boring machine with an anti-passivation structure for machining, which comprises an equipment shell and a fine machining mechanism, wherein a first multi-section hydraulic cylinder and a belt conveyor are sequentially arranged on the inner lower wall of the equipment shell from the middle to the front side and the rear side, a supporting plate is connected to the upper end of the belt conveyor, a groove plate is placed on the upper end of the supporting plate, a connecting shaft and a clamping feeding mechanism are sequentially arranged on the inner upper wall of the equipment shell from the middle to the left side and the right side, a pressing and fixing mechanism is arranged at the lower end of the connecting shaft, and a first motor is installed on one side of the connecting shaft, so that the boring machine has the beneficial effects that: this boring machine with prevent passivation structure for machining drives the hob rotation through the third motor and removes the metal fillings that produce when thick sword fluting, prevents that a large amount of metal fillings from piling up in thick sword department, influences the processing of thick sword department frid, also can increase the resistance of thick sword department frid cutting simultaneously, makes the passivation appear easily in thick sword, reduces the life of thick sword.)

1. The utility model provides a boring machine with prevent passivation structure for machining, includes equipment casing (1) and fine processing mechanism (15), its characterized in that: the device comprises an equipment shell (1), wherein a first multi-section hydraulic cylinder (2) and a belt conveyor (3) are sequentially arranged on the inner lower wall of the equipment shell (1) from the middle to the front and back sides, a supporting plate (4) is connected to the upper end of the belt conveyor (3), a groove plate (5) is placed on the upper end of the supporting plate (4), a connecting shaft (6) and a clamping feeding mechanism (7) are sequentially arranged on the inner upper wall of the equipment shell (1) from the middle to the left and right sides, a pressing and fixing mechanism (8) is arranged at the lower end of the connecting shaft (6), a first motor (9) is installed on one side of the connecting shaft (6), a gear (10) is connected to the upper end of the first motor (9), an adjusting rod (11) is arranged at the rear end of the gear (10), a second motor (12) is installed at the upper end of the adjusting rod (11), and a T-shaped connecting plate (13) is installed at the lower end of the adjusting rod (11), and the front end of T shape connecting plate (13) is provided with rough machining mechanism (14), fine machining mechanism (15) are located the rear end of T shape connecting plate (13), the upper end of equipment casing (1) has set gradually sixth motor (16) and bin (17) from a left side to the right side, and installs first water pump (18) in one side of bin (17), second water pump (19) are installed to the opposite side of bin (17), and the lower extreme of second water pump (19) is connected with transfer line (20).

2. The boring machine with the passivation preventing structure for machining according to claim 1, characterized in that: the clamping and feeding mechanism (7) comprises an electric sliding rail (701), a second multi-section hydraulic cylinder (702), a first spring (703), a guide rod (704) and a sucker clamp (705), the second multi-section hydraulic cylinder (702) is installed at the lower end of the electric sliding rail (701), the first spring (703) and the guide rod (704) are sequentially arranged at the lower end of the second multi-section hydraulic cylinder (702) from the middle to the left side and the right side, and the lower end of the first spring (703) is connected with the sucker clamp (705).

3. The boring machine with the passivation preventing structure for machining according to claim 2, characterized in that: the sucker clamp (705) forms an elastic structure with the second multi-section hydraulic cylinder (702) through the first spring (703), the sucker clamp (705) forms a sliding structure with the second multi-section hydraulic cylinder (702) through the guide rod (704), and the first spring (703) is fixedly connected with the sucker clamp (705).

4. The boring machine with the passivation preventing structure for machining according to claim 1, characterized in that: the pressing fixing mechanism (8) comprises a connecting rod (801), a pressing loop bar (802), a first bearing (803), a pressure sensor (804) and a second spring (805), the pressing loop bar (802) is connected to the outside of the connecting rod (801), the inside of the connecting rod (801) is connected with the pressure sensor (804) through the first bearing (803), and the lower end of the pressure sensor (804) is connected with the second spring (805).

5. The boring machine with the passivation preventing structure for machining according to claim 4, wherein: the pressing loop bar (802) and the connecting rod (801) form an elastic structure through the second spring (805), the second spring (805) and the pressure sensor (804) are fixedly connected, and the pressure sensor (804) and the connecting rod (801) form a rotating structure through the first bearing (803).

6. The boring machine with the passivation preventing structure for machining according to claim 1, characterized in that: the outer surface of the gear (10) is meshed with the front surface of the adjusting rod (11), the T-shaped connecting plate (13) forms a rotating structure with the adjusting rod (11) through the second motor (12), and the adjusting rod (11) is movably connected with the connecting shaft (6).

7. The boring machine with the passivation preventing structure for machining according to claim 1, characterized in that: rough machining mechanism (14) include first box (1401), third motor (1402), fourth motor (1403), first chain (1404), first rotation loop bar (1405), second bearing (1406), thick sword (1407) and hob (1408), and third motor (1402) are installed to the upper end of first box (1401), fourth motor (1403) are installed to the rear end of first box (1401), and the upper end of fourth motor (1403) is connected with first rotation loop bar (1405) through first chain (1404), the external connection of first rotation loop bar (1405) has second bearing (1406), and thick sword (1407) are installed to the lower extreme of first rotation loop bar (1405), the inside of first rotation loop bar (1405) is provided with hob (1408).

8. The boring machine with the passivation preventing structure for machining according to claim 7, wherein: the central axis of the first rotating loop bar (1405) coincides with the central axis of the screw rod (1408), and the first rotating loop bar (1405) is connected with the coarse knife (1407) in an embedded manner.

9. The boring machine with the passivation preventing structure for machining according to claim 1, characterized in that: thin processing agency (15) include second box (1501) including fifth motor (1502), second chain (1503), second rotation loop bar (1504), third bearing (1505), thin sword (1506) and spray pipe (1507), and the rear end of second box (1501) ann has fifth motor (1502), the upper end of fifth motor (1502) is connected with second rotation loop bar (1504) through second chain (1503), and the external connection of second rotation loop bar (1504) has third bearing (1505), the lower extreme of second rotation loop bar (1504) is connected with thin sword (1506), and the inside of second rotation loop bar (1504) is provided with spray pipe (1507).

10. The boring machine with the passivation preventing structure for machining according to claim 9, wherein: constitute welding integrated structure between spray pipe (1507) and transfer line (20), and the axis of spray pipe (1507) and the axis of second rotation loop bar (1504) coincide mutually to thin sword (1506) is symmetrical about the axis of second rotation loop bar (1504).

Technical Field

The invention relates to the technical field of machining, in particular to a boring machine with an anti-passivation structure for machining.

Background

The groove plate is a mechanical part commonly used in machining, and a boring machine is required to be used for grooving the surface of the metal plate in the machining process of the groove plate, so that the boring machine is mechanical equipment commonly used in machining.

The existing boring machine can generate a large amount of metal chips at the contact part of a cutter and a slot plate in the process of machining the slot plate, the metal chips are accumulated at the cutter to interfere the operation of the cutter, and meanwhile, the cutter is easily passivated when being machined in the metal chips for a long time.

Disclosure of Invention

The invention aims to provide a boring machine with an anti-passivation structure for machining, which aims to solve the problems that the existing boring machine in the background art can generate a large amount of metal chips at the contact part of a cutter and a slot plate in the process of machining the slot plate, the metal chips are accumulated at the cutter to interfere the operation of the cutter, and the cutter is easily passivated after being machined in the metal chips for a long time.

In order to achieve the purpose, the invention provides the following technical scheme: a boring machine with an anti-passivation structure for machining comprises an equipment shell and a fine machining mechanism, wherein a first multi-section hydraulic cylinder and a belt conveyor are sequentially arranged on the inner lower wall of the equipment shell from the middle to the front side and the rear side, a supporting plate is connected to the upper end of the belt conveyor, a groove plate is placed on the upper end of the supporting plate, a connecting shaft and a clamping feeding mechanism are sequentially arranged on the inner upper wall of the equipment shell from the middle to the left side and the right side, a pressing and fixing mechanism is arranged at the lower end of the connecting shaft, a first motor is installed on one side of the connecting shaft, a gear is connected to the upper end of the first motor, an adjusting rod is arranged at the rear end of the gear, a second motor is installed at the upper end of the adjusting rod, a T-shaped connecting plate is installed at the lower end of the adjusting rod, a rough machining mechanism is arranged at the front end of the T-shaped connecting plate, and the fine machining mechanism is located at the rear end of the T-shaped connecting plate, the upper end of the equipment shell is sequentially provided with a sixth motor and a storage box from left to right, a first water pump is installed on one side of the storage box, a second water pump is installed on the other side of the storage box, and the lower end of the second water pump is connected with a liquid conveying pipe.

Preferably, the clamping and feeding mechanism comprises an electric sliding rail, a second multi-section hydraulic cylinder, a first spring, a guide rod and a sucker clamp, the second multi-section hydraulic cylinder is installed at the lower end of the electric sliding rail, the first spring and the guide rod are sequentially arranged at the lower end of the second multi-section hydraulic cylinder from the middle to the left side and the right side, and the lower end of the first spring is connected with the sucker clamp.

Preferably, the sucker clamp forms an elastic structure with the second multi-section hydraulic cylinder through the first spring, the sucker clamp forms a sliding structure with the second multi-section hydraulic cylinder through the guide rod, and the first spring is fixedly connected with the sucker clamp.

Preferably, press fixed establishment and include the connecting rod, press loop bar, first bearing, pressure sensor and second spring, and the external connection of connecting rod presses the loop bar, the inside of connecting rod is connected with pressure sensor through first bearing, and pressure sensor's lower extreme is connected with the second spring.

Preferably, the pressing sleeve rod forms an elastic structure with the connecting rod through the second spring, the second spring is fixedly connected with the pressure sensor, and the pressure sensor forms a rotating structure with the connecting rod through the first bearing.

Preferably, the outer surface of the gear is meshed with the front surface of the adjusting rod, the T-shaped connecting plate forms a rotating structure with the adjusting rod through the second motor, and the adjusting rod is movably connected with the connecting shaft.

Preferably, rough machining mechanism includes first box, third motor, fourth motor, first chain, first rotation loop bar, second bearing, thick sword and hob, and the third motor is installed to the upper end of first box, the fourth motor is installed to the rear end of first box, and the upper end of fourth motor is connected with first rotation loop bar through first chain, the external connection of first rotation loop bar has the second bearing, and the thick sword is installed to the lower extreme of first rotation loop bar, the inside of first rotation loop bar is provided with the hob.

Preferably, the central axis of the first rotating sleeve rod coincides with the central axis of the screw rod, and the first rotating sleeve rod is connected with the thick cutter in an embedded mode.

Preferably, the fine processing mechanism includes that the second box includes fifth motor, second chain, second rotation loop bar, third bearing, fine sword and spray pipe, and the rear end of second box ann has the fifth motor, the upper end of fifth motor is connected with the second rotation loop bar through the second chain, and the second rotation loop bar's external connection has the third bearing, the second rotates the lower extreme of loop bar and is connected with fine sword, and the inside of second rotation loop bar is provided with the spray pipe.

Preferably, constitute welding integral structure between spray pipe and the transfer line, and the axis of spray pipe coincides mutually with the axis of second rotation loop bar to thin sword is symmetrical about the axis of second rotation loop bar.

Compared with the prior art, the invention has the following beneficial effects:

1. the groove plate clamping and feeding device comprises a first clamping and feeding mechanism, a second clamping and feeding mechanism, a guide rod, a first spring, a second multi-section hydraulic cylinder, a sucker clamp and a guide rod, wherein the first spring is arranged between the first clamping and feeding mechanism and the second multi-section hydraulic cylinder, the second spring is arranged between the first clamping and feeding mechanism and the second clamping and feeding mechanism, the first clamping and feeding mechanism is arranged on the first clamping and feeding mechanism, the second clamping and feeding mechanism is arranged on the second multi-section hydraulic cylinder, the first spring is arranged between the first clamping and feeding mechanism and the second clamping and feeding mechanism, the second clamping and feeding mechanism is arranged on the second multi-section hydraulic cylinder, and the second multi-section hydraulic cylinder is arranged on the guide rod.

2. The groove plate fixing device can lead the pressing sleeve rod to tightly press the groove plate to fix the groove plate by virtue of the elastic structure formed between the second spring and the connecting rod, thereby preventing the groove plate from moving when equipment performs groove machining on the groove plate, and causing the change of the position and the size of the equipment for machining the groove plate.

3. According to the invention, the groove is formed on the surface of the groove plate through the rough machining mechanism, and then the groove body on the surface of the groove plate is modified and machined through the fine machining mechanism, so that the groove plate is machined by the equipment in two parts, the abrasion of the fine cutter is reduced, and the passivation of the fine cutter in the equipment can be effectively placed.

4. According to the invention, the screw rod is driven to rotate by the third motor, so that metal chips generated during grooving of the rough cutter can be removed, a large amount of metal chips are prevented from being accumulated at the rough cutter to influence the processing of the groove plate at the rough cutter, the cutting resistance of the groove plate at the rough cutter can be increased, the rough cutter is easily passivated, and the service life of the rough cutter is shortened.

5. According to the invention, the cutting fluid is input from the infusion tube to the spray pipe through the second water pump and sprayed out, so that the cutting fluid can be directly contacted with the fine cutter to cool the fine cutter, the service life of the fine cutter is prolonged, meanwhile, the metal chips generated by cutting the fine cutter can be sprayed away by the strong pressure water flow generated by the spray pipe, and the interference of the metal chips is reduced, so that the fine cutter can finish the groove plate conveniently.

Drawings

FIG. 1 is a schematic structural diagram of a front cross section of a boring machine with an anti-passivation structure for machining according to the present invention;

FIG. 2 is a schematic structural diagram of a pressing and fixing mechanism of a boring machine with an anti-passivation structure for machining according to the present invention;

FIG. 3 is a schematic structural diagram of a rough machining mechanism of a boring machine with an anti-passivation structure for machining according to the invention;

FIG. 4 is an enlarged schematic structural view at A in FIG. 1 of a boring machine with an anti-passivation structure for machining according to the present invention;

FIG. 5 is an enlarged structural view of a groove plate of a boring machine with an anti-passivation structure for machining according to the present invention.

In the figure: 1. an equipment housing; 2. a first multi-section hydraulic cylinder; 3. a belt conveyor; 4. a support plate; 5. a groove plate; 6. a connecting shaft; 7. a clamping and feeding mechanism; 701. an electric slide rail; 702. a second multi-section hydraulic cylinder; 703. a first spring; 704. a guide bar; 705. a suction cup clamp; 8. a pressing and fixing mechanism; 801. a connecting rod; 802. pressing the loop bar; 803. a first bearing; 804. a pressure sensor; 805. a second spring; 9. a first motor; 10. a gear; 11. adjusting a rod; 12. a second motor; 13. a T-shaped connecting plate; 14. a rough machining mechanism; 1401. a first case; 1402. a third motor; 1403. a fourth motor; 1404. a first chain; 1405. a first rotating loop bar; 1406. a second bearing; 1407. coarse cutting; 1408. a screw rod; 15. a fine processing mechanism; 1501. a second case; 1502. a fifth motor; 1503. a second chain; 1504. a second rotating sleeve rod; 1505. a third bearing; 1506. fine cutting; 1507. a water spray pipe; 16. a sixth motor; 17. a storage tank; 18. a first water pump; 19. a second water pump; 20. an infusion tube.

Detailed Description

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 only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the referred devices or elements must have a specific orientation, be constructed in a specific orientation, and be operated, and thus are not to be construed as limiting the present invention, and furthermore, the terms "first", "second", "third", and the like are only used for descriptive purposes and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate, and those skilled in the art will understand the specific meaning of the above terms in the present invention in specific situations.

Referring to fig. 1-5, the present invention provides a technical solution: a boring machine with an anti-passivation structure for machining comprises an equipment shell 1 and a fine machining mechanism 15, wherein a first multi-section hydraulic cylinder 2 and a belt conveyor 3 are sequentially arranged on the inner lower wall of the equipment shell 1 from the middle to the front side and the rear side, a supporting plate 4 is connected to the upper end of the belt conveyor 3, a groove plate 5 is placed at the upper end of the supporting plate 4, a connecting shaft 6 and a clamping feeding mechanism 7 are sequentially arranged on the inner upper wall of the equipment shell 1 from the middle to the left side and the right side, a pressing and fixing mechanism 8 is arranged at the lower end of the connecting shaft 6, the clamping feeding mechanism 7 comprises an electric sliding rail 701, a second multi-section hydraulic cylinder 702, a first spring 703, a guide rod 704 and a sucker clamp 705, a second multi-section hydraulic cylinder 702 is installed at the lower end of the electric sliding rail 701, a first spring 703 and a guide rod 704 are sequentially arranged at the lower end of the second multi-section hydraulic cylinder 702 from the middle to the left side and the right side, and the lower end of the first spring 703 is connected with the sucker clamp 705, the sucker clamp 705 forms an elastic structure between the first spring 703 and the second multi-section hydraulic cylinder 702, the sucker clamp 705 forms a sliding structure between the guide rod 704 and the second multi-section hydraulic cylinder 702, the first spring 703 and the sucker clamp 705 are fixedly connected, the trough plate 5 is clamped and fed through the two clamping and feeding mechanisms 7, the sucker clamp 705 is uniformly stressed, the trough plate 5 is prevented from being laterally deviated to cause position errors of the trough plate 5, meanwhile, the sucker clamp 705 can be buffered through the guide rod 704, the first spring 703 and the second multi-section hydraulic cylinder 702 by virtue of the elastic telescopic structure formed between the guide rod 704 and the sucker clamp 705, and the sucker clamp 705 is convenient to clamp the trough plate 5.

The pressing and fixing mechanism 8 comprises a connecting rod 801, a pressing loop bar 802, a first bearing 803, a pressure sensor 804 and a second spring 805, the pressing loop bar 802 is connected to the outside of the connecting rod 801, the inside of the connecting rod 801 is connected with the pressure sensor 804 through the first bearing 803, the lower end of the pressure sensor 804 is connected with the second spring 805, the pressing loop bar 802 forms an elastic structure with the connecting rod 801 through the second spring 805, the second spring 805 is fixedly connected with the pressure sensor 804, the pressure sensor 804 forms a rotating structure with the connecting rod 801 through the first bearing 803, the pressing loop bar 802 can tightly press the groove plate 5 to fix the groove plate 5 through the elastic structure formed between the pressing loop bar 802 and the connecting rod 801, and therefore, the groove plate 5 is prevented from moving when equipment performs grooving and processing on the groove plate 5, the position and the size of the device for processing the groove plate 5 are changed, and meanwhile, the elastic force of the second spring 805 can be detected through the pressure sensor 804, so that the groove depth of the device can be accurately calculated.

A first motor 9 is installed at one side of the connecting shaft 6, a gear 10 is connected to the upper end of the first motor 9, the outer surface of the gear 10 is engaged with the front surface of the adjusting rod 11, a rotating structure is formed between the T-shaped connecting plate 13 and the adjusting rod 11 through a second motor 12, the adjusting rod 11 is movably connected with the connecting shaft 6, the adjusting rod 11 is arranged at the rear end of the gear 10, a second motor 12 is installed at the upper end of the adjusting rod 11, the T-shaped connecting plate 13 is installed at the lower end of the adjusting rod 11, a rough machining mechanism 14 is arranged at the front end of the T-shaped connecting plate 13, the rough machining mechanism 14 comprises a first box 1401, a third motor 1402, a fourth motor 1403, a first chain 1404, a first rotating sleeve 1405, a second bearing 1406, a rough cutter 1407 and a screw rod 1408, the third motor 1402 is installed at the upper end of the first box 1401, the fourth motor 1403 is installed at the rear end of the first box 1401, and the upper end of the fourth motor 1403 is connected with the first rotating sleeve bar 1405 through the first chain 1404, the outer portion of the first rotating sleeve bar 1405 is connected with the second bearing 1406, the rough knife 1407 is installed at the lower end of the first rotating sleeve bar 1405, the screw rod 1408 is arranged inside the first rotating sleeve bar 1405, the central axis of the first rotating sleeve bar 1405 coincides with the central axis of the screw rod 1408, the first rotating sleeve bar 1405 is connected with the rough knife 1407 in an embedded manner, the screw rod 1408 is driven to rotate through the third motor 1402, so that metal chips generated when the rough knife 1407 slots can be discharged, a large amount of metal chips are prevented from being accumulated at the rough knife 1407, the processing of the rough knife 1407 on the slot plate 5 is prevented from being influenced, meanwhile, the resistance of the rough knife 1407 on the slot plate 5 can be increased, the rough knife 1407 is easy to appear, and the service life of the rough knife 1407 is shortened.

The fine machining mechanism 15 is located at the rear end of the T-shaped connecting plate 13, the fine machining mechanism 15 comprises a second box 1501 including a fifth motor 1502, a second chain 1503, a second rotating sleeve 1504, a third bearing 1505, a fine knife 1506 and a spray pipe 1507, and the rear end of the second box 1501 is provided with a fifth motor 1502, the upper end of the fifth motor 1502 is connected with a second rotating loop bar 1504 through a second chain 1503, and a third bearing 1505 is connected to the outside of the second rotating sleeve rod 1504, a thin knife 1506 is connected to the lower end of the second rotating sleeve rod 1504, and the second rotating sleeve 1504 is internally provided with a water spray pipe 1507, the surface of the slot plate 5 is grooved by the rough machining mechanism 14, then, the groove body on the surface of the groove plate 5 is modified and processed through the fine processing mechanism 15, so that the equipment processes two parts of the groove plate 5, the abrasion of the fine cutter 1506 is reduced, and the passivation of the fine cutter 1506 in the equipment can be effectively placed.

Constitute welding integral structure between spray pipe 1507 and transfer line 20, and the axis of spray pipe 1507 coincides mutually with the axis of second rotation loop bar 1504, and thin sword 1506 is symmetrical about the axis of second rotation loop bar 1504, import the blowout of spray pipe 1507 department from transfer line 20 to cutting fluid through second water pump 19, can make the cutting fluid direct and thin sword 1506 contact to thin sword 1506 cooling, improve the life of thin sword 1506, the strong pressure rivers that the while spray pipe 1507 produced can spout the metal fillings that thin sword 1506 cutting produced, the interference of reduction metal fillings is convenient for thin sword 1506 to 5 finish machining of frid.

The upper end of the equipment shell 1 is sequentially provided with a sixth motor 16 and a storage box 17 from left to right, a first water pump 18 is installed on one side of the storage box 17, a second water pump 19 is installed on the other side of the storage box 17, and the lower end of the second water pump 19 is connected with a liquid conveying pipe 20.

In conclusion, when the boring machine with the passivation prevention structure for machining is used, the groove plate 5 is conveyed to a designated position through the belt conveyor 3, the electric slide rail 701 and the second multi-section hydraulic cylinder 702 drive the sucker clamp 705 to clamp the groove plate 5 on the supporting plate 4, the sucker clamp 705 is used for clamping the groove plate 5 through the guide rod 704 and the elastic telescopic structure formed between the first spring 703 and the second multi-section hydraulic cylinder 702, the supporting plate 4 is driven to ascend through the first multi-section hydraulic cylinder 2, the fourth motor 1403 is opened and drives the first rotating sleeve rod 1405 to rotate through the first chain 1404 so that the rough cutter 1407 machines the groove plate 5, the fifth motor 1502 is opened and drives the second rotating sleeve rod 1504 to rotate through the second chain 1503 so that the fine cutter 1506 machines the groove plate 5, the pressure sensor 804 can detect the distance of the contraction of the pressing sleeve rod 802 through the elastic structure formed between the second spring 805 and the connecting rod 801, therefore, the device can calculate the depth of the groove plate 5, meanwhile, the groove plate 5 can be pressed and fixed through the pressing sleeve rod 802, the groove plate 5 is prevented from moving, the connecting shaft 6 can be driven to rotate through the sixth motor 16, the device can perform arc-shaped groove forming, the device can open the third motor 1402 to drive the screw rod 1408 to rotate while performing groove forming, metal chips generated when the rough knife 1407 performs groove forming are discharged from the side surface of the first box 1401, a large amount of metal chips are prevented from being accumulated on the rough knife 1407 pair, the processing of the rough knife 1407 on the groove plate 5 is influenced, meanwhile, the second water pump 19 can work to convey cutting fluid in the storage box 17 to the water spray pipe 1507 through the liquid conveying pipe 20 to spray out the metal chips generated by cutting of the fine knife 1506, meanwhile, the strong pressure water flow generated by the water spray pipe 1507 can spray away the metal chips generated by cutting of the fine knife 1506, the T-shaped connecting plate 13 can be driven to rotate through the second motor 12, and the rough machining mechanism 14 and the fine machining mechanism 15 can be switched in position, the fine processing mechanism 15 of being convenient for is to the groove edge processing, opens first motor 9 simultaneously and drives regulation pole 11 through gear 10 and remove, adjusts rough machining mechanism 14 and fine processing mechanism 15's position, slots other positions to frid 5, can retrieve the cutting fluid after using through first water pump 18 and recycle, carries the completion processing on another band conveyer 3 to the frid 5 of accomplishing of processing through centre gripping feed mechanism 7 after the equipment processing is accomplished.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.