阅读说明：本技术 一种高精密型卧式数控车床 (High-precision horizontal numerically controlled lathe ) 是由 刘巧茹 于 2021-01-05 设计创作，主要内容包括：本申请公开了一种高精密型卧式数控车床,包括平板、支撑脚、配重块、立柱、左侧板、第一驱动电机、第一三爪卡盘、右侧板、气缸、第二三爪卡盘、背板、支撑板、连接板、主动辊、从动辊、输送带、横向壳体、第一导向槽、第一导向杆、竖向壳体、第二导向槽、第二导向杆、减速驱动机构、外壳、伺服电机、内板、第一转轴、蜗轮、蜗杆、短杆、第一圆锥齿轮、第二转轴、第二圆锥齿轮、第一圆柱齿轮、第二圆柱齿轮、第三转轴、刀具、第一螺母、第一螺杆、第二螺母、第二螺杆和第二驱动电机。本申请有益之处在于通过减速驱动机构进行驱动,从而有效的进行了降速作用,从而有效的降低了每次驱动后的横向、竖向的进给量,从而提高了进给的精度。(The application discloses horizontal numerical control lathe of high accuracy type, which comprises a flat plate, the supporting legs, the balancing weight, the stand, the left side board, a driving motor, first three-jaw chuck, the right side board, the cylinder, second three-jaw chuck, the backplate, the backup pad, the connecting plate, the drive roll, the driven voller, the conveyer belt, horizontal casing, first guide way, first guide bar, vertical casing, the second guide way, the second guide bar, speed reduction drive mechanism, the shell, servo motor, the inner panel, first pivot, the worm wheel, the worm, the quarter butt, first conical gear, the second pivot, second conical gear, first cylindrical gear, the second cylindrical gear, the third pivot, the cutter, first nut, first screw rod, the second nut, second screw rod and second driving motor. The application has the advantages that the speed reduction driving mechanism is used for driving, so that the speed reduction effect is effectively realized, the transverse and vertical feeding amount after driving at every time is effectively reduced, and the feeding precision is improved.)

1. The utility model provides a horizontal numerical control lathe of high accuracy type which characterized in that: the device comprises a flat plate (1), a left side plate (5) and a right side plate (8), wherein the bottom of the left side plate (5) is fixedly connected with two stand columns (4), the bottoms of the stand columns (4) are fixedly connected with the top of the left side of the flat plate (1), a through groove is formed between the two stand columns (4), the right side plate (8) is fixedly connected with the top of the right side of the flat plate (1), the top of the left side plate (5) is fixedly connected with a first driving motor (6), the output end of the first driving motor (6) is fixedly connected with a first three-jaw chuck (7), the top of the right side plate (8) is fixedly connected with an air cylinder (9), and the output shaft end of the air cylinder (9) is rotatably connected with a second three-jaw chuck;

the top of the flat plate (1) is provided with a belt conveyor, the belt conveyor penetrates through the through groove, one side of the belt conveyor is connected with the side edge of the flat plate (1) through a connecting plate (13), and the other side of the belt conveyor is connected with the top of the flat plate (1) through a supporting plate (12);

the back of the left side plate (5) and the back of the right side plate (8) are fixedly connected with a back plate (11), the back of the back plate (11) is fixedly connected with a transverse moving mechanism, the output end of the transverse moving mechanism is fixedly connected with a vertical moving mechanism, and the output end of the vertical moving mechanism is connected with a cutter (24);

the transverse moving mechanism and the vertical moving mechanism are both connected with a speed reduction driving mechanism (23).

2. The high-precision horizontal numerically controlled lathe according to claim 1, wherein: the bottom four corners department of dull and stereotyped (1) all fixedly connected with supporting legs (2), the bottom of dull and stereotyped (1) is fixedly connected with balancing weight (3) still, and the figure of balancing weight (3) is three.

3. The high-precision horizontal numerically controlled lathe according to claim 1, wherein: band conveyer includes drive roll (14), driven voller (15), conveyer belt (16) and second driving motor (29), around winding conveyer belt (16) between drive roll (14) and driven voller (15), the both ends of drive roll (14) are all rotated and are connected with connecting plate (13), the terminal of connecting plate (13) and the side fixed connection of dull and stereotyped (1), the figure of connecting plate (13) is two, one of them fixedly connected with second driving motor (29) on the face of connecting plate (13), and the output shaft one end of second driving motor (29) and the one end fixed connection of drive roll (14), the both ends of driven voller (15) are all rotated and are connected with backup pad (12), and the bottom of backup pad (12) and the top fixed connection of dull and stereotyped (1).

4. The high-precision horizontal numerically controlled lathe according to claim 1, wherein: the transverse moving mechanism comprises a transverse shell (17), a first screw rod (26) and a first nut (25), the transverse shell (17) is fixedly installed on the back face of the back plate (11), the inside of the transverse shell (17) is rotatably connected with the first screw rod (26), the face of the first screw rod (26) is connected with the first nut (25) in a threaded mode, the outer ring of the first nut (25) is fixedly connected with a first guide rod (19), the tail end of the first guide rod (19) is fixedly connected with the outer portion of the vertical shell (20), one end of the first screw rod (26) is fixedly connected with the output end of the speed reduction driving mechanism (23), and the first guide rod (19) is connected with a first guide groove (18) formed in the surface of the back plate (11) in a sliding mode.

5. The high-precision horizontal numerically controlled lathe according to claim 1, wherein: the vertical moving mechanism comprises a vertical shell (20), a second screw rod (28) and a second nut (27), the second screw rod (28) is rotatably installed inside the vertical shell (20), the surface of the second screw rod (28) is connected with the second nut (27) in a threaded manner, the second nut (27) is fixedly connected with a second guide rod (22), one side of the vertical shell (20) is provided with a second guide groove (21), the second guide rod (22) is in sliding connection with the second guide groove (21), the tail end of the second guide rod (22) is connected with a cutter (24), and one end of the second screw rod (28) is fixedly connected with the output end of the speed reduction driving mechanism (23).

6. The high-precision horizontal numerically controlled lathe according to claim 1, wherein: the speed reduction driving mechanism (23) comprises a shell (2301), a servo motor (2302), an inner plate (2303), a first rotating shaft (2304), a worm wheel (2305), a worm (2306), a short rod (2307), a first conical gear (2308), a second rotating shaft (2309), a second conical gear (2310), a first cylindrical gear (2311), a second cylindrical gear (2312) and a third rotating shaft (2313), wherein the inner plate (2303) is fixedly connected inside the shell (2301), the first rotating shaft (2304), the second rotating shaft (2309), the third rotating shaft (2313) and the worm (2306) are all rotatably connected inside the shell (2301), a short shaft is rotatably connected to the inner plate (2303), one end of the short shaft is fixedly connected with one end of the worm (2306), the tail end of the short shaft is fixedly sleeved with the first conical gear (2308), the second conical gear (2310) and the first conical gear (2311) are fixedly sleeved on the shaft surface of the second rotating shaft (2309), the first conical gear (2308) is in meshed connection with the second conical gear (2310), a second cylindrical gear (2312) is fixedly sleeved on the axial surface of the third rotating shaft (2313), the first cylindrical gear (2311) is in meshed connection with the second cylindrical gear (2312), the servo motor (2302) is fixedly installed on the outer wall of the shell (2301), the output shaft of the servo motor (2302) is fixedly connected with one end of the third rotating shaft (2313), a worm wheel (2305) is fixedly sleeved on the axial surface of the first rotating shaft (2304), and the worm wheel (2305) is in meshed connection with the worm (2306).

7. The high-precision horizontal numerically controlled lathe according to claim 1, wherein: the number of the right side plates (8) is two, and the two right side plates (8) are arranged in parallel.

8. The high-precision horizontal numerically controlled lathe according to claim 6, wherein: the diameter of the second conical gear (2310) is four to five times that of the first conical gear (2308).

9. The high-precision horizontal numerically controlled lathe according to claim 6, wherein: the diameter of the first cylindrical gear (2311) is five to six times that of the second cylindrical gear (2312).

10. The high-precision horizontal numerically controlled lathe according to claim 5, wherein: the second guide rod (22) is of an L-shaped structure, and a clamp is arranged at the tail end of the second guide rod (22).

Technical Field

The application relates to a numerical control lathe, in particular to a high-precision horizontal numerical control lathe.

Background

The numerically controlled lathe is one of the widely used numerically controlled machines at present. The cutting tool is mainly used for cutting processing of inner and outer cylindrical surfaces of shaft parts or disc parts, inner and outer conical surfaces with any taper angles, complex rotary inner and outer curved surfaces, cylinders, conical threads and the like; the method is used for machining the revolving body.

In the prior art, the numerical control lathe has high machining precision, a single three-jaw chuck is used for clamping the end part, and the machining stability is poor; meanwhile, the feeding amount of the cutter is large, and the cutter cannot be fed in a small distance, so that the operation and machining precision is poor. Therefore, a high-precision horizontal numerically controlled lathe is proposed to solve the above problems.

Disclosure of Invention

In order to solve the defects of the prior art, the application provides a high-precision horizontal numerically controlled lathe which comprises a flat plate, a left side plate and a right side plate, wherein the bottom of the left side plate is fixedly connected with two stand columns, the bottoms of the stand columns are fixedly connected with the top of the left side of the flat plate, a through groove is formed between the two stand columns, the right side plate is fixedly connected with the top of the right side of the flat plate, the top of the left side plate is fixedly connected with a first driving motor, the output end of the first driving motor is fixedly connected with a first three-jaw chuck, the top of the right side plate is fixedly connected with an air cylinder, and the output shaft end of the air cylinder is rotatably; the top of the flat plate is provided with a belt conveyor, the belt conveyor penetrates through the through groove, one side of the belt conveyor is connected with the side edge of the flat plate through a connecting plate, and the other side of the belt conveyor is connected with the top of the flat plate through a supporting plate; the back of the left side plate and the back of the right side plate are fixedly connected with a back plate, the back of the back plate is fixedly connected with a transverse moving mechanism, the output end of the transverse moving mechanism is fixedly connected with a vertical moving mechanism, and the output end of the vertical moving mechanism is connected with a cutter; and the transverse moving mechanism and the vertical moving mechanism are both connected with a speed reduction driving mechanism.

Further, all fixedly connected with supporting legs in dull and stereotyped bottom four corners department, still fixedly connected with balancing weight in dull and stereotyped bottom, and the figure of balancing weight is three.

Further, band conveyer includes drive roll, driven voller, conveyer belt and second driving motor, around twining the conveyer belt between drive roll and the driven voller, the both ends of drive roll all rotate and are connected with the connecting plate, the end and the dull and stereotyped side fixed connection of connecting plate, the figure of connecting plate is two, one of them fixedly connected with second driving motor on the face of connecting plate, and second driving motor's output shaft one end and the one end fixed connection of drive roll, the both ends of driven voller all rotate and are connected with the backup pad, and the bottom of backup pad and dull and stereotyped top fixed connection.

Further, the transverse moving mechanism comprises a transverse shell, a first screw and a first nut, the transverse shell is fixedly mounted on the back face of the back plate, the first screw is rotatably connected inside the transverse shell, the first nut is in threaded connection with the face of the first screw, a first guide rod is fixedly connected to the outer ring of the first nut, the tail end of the first guide rod is fixedly connected with the outside of the vertical shell, one end of the first screw is fixedly connected with the output end of the speed reduction driving mechanism, and the first guide rod is in sliding connection with a first guide groove formed in the surface of the back plate.

Further, the vertical moving mechanism comprises a vertical shell, a second screw and a second nut, the second screw is rotatably installed inside the vertical shell, the second nut is connected to the surface of the rod of the second screw in a threaded manner, a second guide rod is fixedly connected to the second nut, a second guide groove is formed in one side of the vertical shell, the second guide rod is connected with the second guide groove in a sliding manner, the tail end of the second guide rod is connected with the cutter, and one end of the second screw is fixedly connected with the output end of the speed reduction driving mechanism.

Furthermore, the speed reduction driving mechanism comprises a shell, a servo motor, an inner plate, a first rotating shaft, a worm wheel, a worm, a short rod, a first conical gear, a second rotating shaft, a second conical gear, a first cylindrical gear, a second cylindrical gear and a third rotating shaft, wherein the inner plate is fixedly connected inside the shell, the first rotating shaft, the second rotating shaft, the third rotating shaft and the worm are all rotatably connected inside the shell, the inner plate is rotatably connected with the short shaft, one end of the short shaft is fixedly connected with one end of the worm, the tail end of the short shaft is fixedly sleeved with the first conical gear, the shaft surface of the second rotating shaft is fixedly sleeved with the second conical gear and the first cylindrical gear, the first conical gear is in meshed connection with the second conical gear, the shaft surface of the third rotating shaft is fixedly sleeved with the second cylindrical gear, and the first cylindrical gear is in meshed connection with the second cylindrical gear, servo motor fixed mounting is on the outer wall of shell, servo motor's output shaft and the one end fixed connection of third pivot, the fixed worm wheel that has cup jointed on the axial plane of first pivot, the worm wheel is connected with the worm meshing.

Furthermore, the number of the right side plates is two, and the two right side plates are arranged in parallel.

Further, the second conical gear diameter is four to five times the first conical gear diameter.

Further, the diameter of the first cylindrical gear is five to six times of the diameter of the second cylindrical gear.

Further, the second guide rod is of an L-shaped structure, and a clamp is arranged at the tail end of the second guide rod.

The beneficial effect of this application is: the application provides a horizontal numerically controlled lathe of high accuracy type convenient to work piece carries out both ends centre gripping and improves processing stability.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive exercise.

FIG. 1 is a schematic overall structure diagram of an embodiment of the present application;

FIG. 2 is a schematic structural diagram of a reduction drive mechanism according to an embodiment of the present application;

FIG. 3 is a schematic view of the internal structure of a transverse housing according to an embodiment of the present application;

fig. 4 is a schematic structural diagram of the interior of the vertical housing according to an embodiment of the present application.

In the figure: 1. a flat plate, 2, a supporting leg, 3, a balancing weight, 4, a column, 5, a left side plate, 6, a first driving motor, 7, a first three-jaw chuck, 8, a right side plate, 9, a cylinder, 10, a second three-jaw chuck, 11, a back plate, 12, a supporting plate, 13, a connecting plate, 14, a driving roller, 15, a driven roller, 16, a conveyer belt, 17, a transverse housing, 18, a first guide groove, 19, a first guide rod, 20, a vertical housing, 21, a second guide groove, 22, a second guide rod, 23, a speed reduction driving mechanism, 2301, a housing, 2302, a servo motor, 2303, an inner plate, 2304, a first rotating shaft, 2305, a worm wheel, 2306, a worm, 2307, a short rod, a first conical gear, 2309, a second rotating shaft, 2310, a second conical gear, 2311, a first cylindrical gear, 2, a second cylindrical gear, 2313, a third rotating shaft, 24, a cutter, 25, a first nut, 26. a first screw rod 27, a second nut 28, a second screw rod 29 and a second driving motor.

Detailed Description

In order to make the technical solutions better understood by those skilled in the art, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only partial embodiments of the present application, but not all embodiments. 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 application.

It should be noted that the terms "first," "second," and the like in the description and claims of this application and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It should be understood that the data so used may be interchanged under appropriate circumstances such that embodiments of the application described herein may be used. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

In this application, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "middle", "vertical", "horizontal", "lateral", "longitudinal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings. These terms are used primarily to better describe the present application and its embodiments, and are not used to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation.

Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meaning of these terms in this application will be understood by those of ordinary skill in the art as appropriate.

Furthermore, the terms "mounted," "disposed," "provided," "connected," and "sleeved" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present application will be described in detail below with reference to the embodiments with reference to the attached drawings.

Referring to fig. 1-4, a high-precision horizontal numerically controlled lathe comprises a flat plate 1, a left side plate 5 and a right side plate 8, wherein the bottom of the left side plate 5 is fixedly connected with two upright posts 4, the bottoms of the upright posts 4 are fixedly connected with the top of the left side of the flat plate 1, a through groove is formed between the two upright posts 4, the right side plate 8 is fixedly connected with the top of the right side of the flat plate 1, the top of the left side plate 5 is fixedly connected with a first driving motor 6, the output end of the first driving motor 6 is fixedly connected with a first three-jaw chuck 7, the top of the right side plate 8 is fixedly connected with an air cylinder 9, and the output shaft end of the air cylinder 9 is rotatably connected with a second three-jaw;

a belt conveyor is arranged at the top of the flat plate 1 and penetrates through the through groove, one side of the belt conveyor is connected with the side edge of the flat plate 1 through a connecting plate 13, and the other side of the belt conveyor is connected with the top of the flat plate 1 through a supporting plate 12;

the back of the left side plate 5 and the back of the right side plate 8 are fixedly connected with a back plate 11, the back of the back plate 11 is fixedly connected with a transverse moving mechanism, the output end of the transverse moving mechanism is fixedly connected with a vertical moving mechanism, and the output end of the vertical moving mechanism is connected with a cutter 24;

the horizontal moving mechanism and the vertical moving mechanism are both connected with a speed reduction driving mechanism 23.

The four corners of the bottom of the flat plate 1 are fixedly connected with supporting legs 2, the bottom of the flat plate 1 is also fixedly connected with three balancing weights 3, and the number of the balancing weights 3 is three; the belt conveyor comprises a driving roller 14, a driven roller 15, a conveying belt 16 and a second driving motor 29, wherein the conveying belt 16 is wound between the driving roller 14 and the driven roller 15, two ends of the driving roller 14 are both rotatably connected with connecting plates 13, the tail ends of the connecting plates 13 are fixedly connected with the side edges of the flat plate 1, the number of the connecting plates 13 is two, one of the plates of the connecting plates 13 is fixedly connected with the second driving motor 29, one end of an output shaft of the second driving motor 29 is fixedly connected with one end of the driving roller 14, two ends of the driven roller 15 are both rotatably connected with supporting plates 12, and the bottom ends of the supporting plates 12 are fixedly connected with the top of the flat plate 1; the transverse moving mechanism comprises a transverse shell 17, a first screw rod 26 and a first nut 25, the transverse shell 17 is fixedly mounted on the back surface of the back plate 11, the first screw rod 26 is rotatably connected inside the transverse shell 17, the first nut 25 is in threaded connection with the surface of the first screw rod 26, a first guide rod 19 is fixedly connected to the outer ring of the first nut 25, the tail end of the first guide rod 19 is fixedly connected with the outside of the vertical shell 20, one end of the first screw rod 26 is fixedly connected with the output end of the speed reduction driving mechanism 23, and the first guide rod 19 is in sliding connection with a first guide groove 18 formed in the surface of the back plate 11; the vertical moving mechanism comprises a vertical shell 20, a second screw 28 and a second nut 27, the second screw 28 is rotatably mounted inside the vertical shell 20, the second nut 27 is connected to the surface of the second screw 28 through a thread, the second nut 27 is fixedly connected with a second guide rod 22, a second guide groove 21 is formed in one side of the vertical shell 20, the second guide rod 22 is connected with the second guide groove 21 in a sliding manner, the tail end of the second guide rod 22 is connected with a cutter 24, and one end of the second screw 28 is fixedly connected with the output end of the speed reduction driving mechanism 23; the speed reduction driving mechanism 23 comprises a housing 2301, a servo motor 2302, an inner plate 2303, a first rotating shaft 2304, a worm wheel 2305, a worm 2306, a short rod 2307, a first conical gear 2308, a second rotating shaft 2309, a second conical gear 2310, a first cylindrical gear 2311, a second cylindrical gear 2312 and a third rotating shaft 2313, the inner plate 2303 is fixedly connected inside the housing 2301, the first rotating shaft 2304, the second rotating shaft 2309, the third rotating shaft 2313 and the worm 2306 are all rotatably connected inside the housing 2301, the inner plate 2303 is rotatably connected with a short shaft, one end of the short shaft is fixedly connected with one end of the worm 2306, a first conical gear 2308 is fixedly sleeved at the tail end of the short shaft, a second conical gear 2310 and the first conical gear 2311 are fixedly sleeved on the shaft surface of the second rotating shaft 2319, the first conical gear 2308 and the second cylindrical gear 2310 are meshed, a second conical gear 2312 is fixedly sleeved on the shaft surface of the third rotating shaft 2313, the first cylindrical gear 2311 and the second cylindrical gear 2312 are in meshed connection, the servo motor 2302 is fixedly installed on the outer wall of the housing 2301, an output shaft of the servo motor 2302 is fixedly connected with one end of a third rotating shaft 2313, a worm wheel 2305 is fixedly sleeved on the shaft surface of the first rotating shaft 2304, and the worm wheel 2305 is in meshed connection with a worm 2306; the number of the right side plates 8 is two, and the two right side plates 8 are arranged in parallel; said second conical gear 2310 has a diameter four to five times the diameter of the first conical gear 2308; the diameter of the first cylindrical gear 2311 is five to six times that of the second cylindrical gear 2312; the second guide rod 22 is of an L-shaped structure, and a clamp is arranged at the tail end of the second guide rod 22.

When the clamping device is used, electrical elements appearing in the clamping device are externally connected with a power supply and a control switch when the clamping device is used, the first three-jaw chuck 7 and the second three-jaw chuck 10 are used for clamping two ends of a workpiece to finish clamping and mounting, the air cylinder 9 is connected with external driving equipment and used for driving to adjust the distance between the first three-jaw chuck 7 and the second three-jaw chuck 10, and the clamping device is suitable for workpieces with different lengths; after clamping and mounting, the first driving motor 6 drives the workpiece to rotate, so that the workpiece rotates at a high speed;

the servo motor 2302 drives the third rotation shaft 2313 to rotate, thereby rotating the second cylindrical gear 2312, the second cylindrical gear 2312 and the first cylindrical gear 2311 are used for transmission, so that speed reduction driving is realized, the reduction effect of the first layer is completed, so that the second rotating shaft 2309 and the second conical gear 2310 rotate together, and are transmitted through the second conical gear 2310 and the first conical gear 2308, thereby, the second layer is decelerated, so that the short bar 2307 and the worm 2306 rotate together, the worm 2306 and the worm wheel 2305 realize meshing transmission, realize the speed reduction of the third layer, realize the low-speed driving of the first rotating shaft 2304, and when the first screw 26 is driven, the first nut 25 is driven, the driving in the transverse direction is achieved by the guidance by the first guide bar 19 and the first guide groove 18, which, by means of a deceleration effect, thereby reducing the feed amount after each driving and improving the moving precision of the cutter 24 in the transverse direction;

the speed reduction driving mechanism 23 provides driving for the second screw 28, so that the second screw 28 is driven and guided by the second guide rod 22 and the second guide groove 21, vertical driving is realized, and through a speed reduction function, the feeding amount after each driving is reduced, and the vertical moving precision of the cutter 24 is improved;

the precision effect is improved, and the using effect is better.

The whole lathe is controlled by numerical control, and a numerical control device and equipment are externally connected.

The application has the advantages that:

the whole high-precision horizontal numerically controlled lathe is high in machining precision of workpieces, suitable for clamping of long workpieces and capable of clamping two ends of the workpieces, clamping of the workpieces is stable, the workpieces are prevented from shaking when turning of the workpieces is carried out, machining effect and machining precision of turning are affected, and the whole machining effect is good.

Meanwhile, when machining is carried out, the cutter 24 is driven through the transverse moving mechanism and the vertical moving mechanism, so that the cutter 24 can be driven transversely and longitudinally, and meanwhile, the transverse moving mechanism and the vertical moving mechanism are driven through the speed reduction driving mechanism 23, so that the speed reduction effect is effectively carried out, the transverse and vertical feeding amount after driving at every time is effectively reduced, the feeding precision is improved, the machining precision is improved, and the machining effect is better.

Whole have piece driven structure simultaneously, the piece that the turning produced can fall on band conveyer, carries out clastic drive through band conveyer, can make the piece leave from dull and stereotyped 1 top, through leading to the groove, flows from one side of band conveyer, realizes concentrating the discharge, is convenient for carry out clastic discharge, and the discharge effect is better, has improved holistic result of use.

It is well within the skill of those in the art to implement, without undue experimentation, the present application is not directed to software and process improvements, as they relate to circuits and electronic components and modules.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.