CN220094000U - Programming-free milling, grinding, drilling, tapping and boring integrated machine - Google Patents

Abstract

The programming-free milling, grinding, drilling, tapping and boring all-in-one machine comprises a base, wherein a first upright post and a second upright post are respectively arranged on one side of the base, an X-direction screw rod transmission mechanism is arranged on the base, a Y-direction screw rod transmission mechanism is arranged on the X-direction screw rod transmission mechanism, and a workbench is arranged on the Y-direction screw rod transmission mechanism; a main shaft mechanism is arranged at the front side of the first upright post, and a tool magazine is arranged at one side of the main shaft mechanism; the front side of the second upright post is provided with a grinding head mechanism. The whole structural design of the utility model realizes that a workpiece can be milled, tapped, bored, chamfered and the like in a plurality of different processing procedures by changing different types of cutters on one device, and the workpiece can be milled and ground by the grinding head mechanism, so that the workpiece processed by the utility model not only avoids deformation, but also has the advantages of high processing precision, high yield and high production efficiency, in addition, the labor intensity of workers is reduced, and the labor cost of enterprises is reduced.

Description

Programming-free milling, grinding, drilling, tapping and boring integrated machine

Technical Field

The utility model relates to the field of machine tools, in particular to a programming-free milling, grinding, drilling, tapping and boring integrated machine.

Background

At present, the function of a numerical control machine tool for cutting metal on the market is single because of unreasonable structural design, vertical drilling cannot be realized generally, and one machine tool can only independently perform drilling, tapping, boring or milling, when the numerical control machine tool needs to perform multiple machining procedures such as drilling, tapping, boring, chamfering, milling and the like on a workpiece, the workpiece needs to be processed step by step among multiple machine tools with different functions to finish a series of procedures. In addition, the workpiece is required to be manually transferred during loading and unloading between two machine tools with different functions, so that the workpiece has the problems of low working efficiency, high labor intensity of workers and high labor cost of enterprises, the workpiece is easy to deform in the transferring process, and the deformed workpiece has large error with the previous correction, so that the workpiece has the defects of poor machining precision and low yield.

Disclosure of Invention

The utility model aims to solve the technical problems of providing a programming-free milling, grinding, drilling, tapping and boring all-in-one machine, the whole structural design of the machine can realize a plurality of different machining procedures such as milling, tapping, boring, chamfering and the like on a workpiece by replacing different types of cutters on one machine, and milling and grinding the workpiece by a grinding head mechanism, the machined workpiece has the advantages of high machining precision, high yield and high production efficiency, the labor intensity of workers and the labor cost of enterprises are reduced, and the problems that the workpiece is easy to deform, the machining precision of the workpiece is poor, the correction error before and after the workpiece deformation is large and the yield of the workpiece is low due to the fact that a human hand is required to be subjected to clamping for a plurality of times when a plurality of machine tools with different functions are used for drilling, tapping, boring, chamfering, milling, grinding and the like on the workpiece are effectively solved. The utility model is realized by the following technical scheme:

the programming-free milling, grinding, drilling and boring integrated machine comprises a base, wherein a first upright post and a second upright post are respectively arranged on one side of the base, the second upright post is positioned on one side of the first upright post, an X-direction screw rod transmission mechanism is arranged on the base, a Y-direction screw rod transmission mechanism is arranged on the X-direction screw rod transmission mechanism in a sliding manner, and a workbench is arranged on the Y-direction screw rod transmission mechanism; a first Z-direction screw rod transmission mechanism is arranged on one side of the first upright column facing the base, a main shaft mechanism is arranged on one side of the first Z-direction screw rod transmission mechanism, a tool magazine is arranged on one side of the main shaft mechanism, and tools with different specifications or different types for milling holes, tapping, boring, chamfering and the like on a workpiece are placed in the tool magazine; a second Z-direction screw rod transmission mechanism is arranged on one side of the second upright post, which faces the base, and a grinding head mechanism is arranged on one side of the second Z-direction screw rod transmission mechanism.

When the technical scheme is adopted, the Y-direction screw rod transmission mechanism can move in the X direction through the X-direction screw rod transmission mechanism, and the workbench can move in the Y direction through the Y-direction screw rod transmission mechanism, so that the workbench can move left and right and can move back and forth under the common drive of the X-direction screw rod transmission mechanism and the Y-direction screw rod transmission mechanism, and a workpiece placed on the workbench can be accurately positioned under the spindle mechanism or the grinding head mechanism for machining after moving left and right and moving back and forth along with the workbench, and the purposes of automatic positioning, accurate positioning and accurate machining are achieved. The main shaft mechanism can perform lifting movement through the first Z-direction screw rod transmission mechanism, and the grinding head mechanism can also perform lifting movement through the second Z-direction screw rod transmission mechanism, so that the grinding head mechanism is suitable for processing workpieces with different specifications, and the purpose of strong universality is achieved. Because various tools with different specifications or different types for milling holes, tapping, boring, chamfering and the like are arranged in the tool magazine, the tool magazine can rotate under the drive of a driving motor connected with the tool magazine, so that the tool suitable for machining can rotate to one side of the spindle mechanism, the specific structure and the working principle of the tool magazine are already common knowledge, and the specific structure and the working principle of the tool magazine are not explained in detail; meanwhile, the working principle of tool changing of the spindle from the tool magazine is common knowledge, and is not explained in detail here. After the spindle mechanism is used for replacing different types of cutters from the cutter magazine according to the production requirement, the spindle mechanism can respectively perform machining such as hole milling, tapping, boring, chamfering and the like on a workpiece placed on a workpiece table when being driven by the first Z-direction screw rod transmission mechanism to move downwards; similarly, when the grinding head mechanism moves downwards under the drive of the second Z-direction screw rod transmission mechanism, the workpiece can be milled, so that a plurality of different processing procedures can be completed on the workpiece on one machine tool, and the problems that the workpiece is easy to deform and the processing precision and the yield of the workpiece are influenced due to the fact that the workpiece is required to be transferred and clamped in a plurality of machine tools with different functions are avoided.

Preferably, the workbench is one of a strong magnetic fixed sucker, a permanent magnetic sucker and the like, for example, the workbench can adopt a hydraulic electric permanent magnetic sucker with the model of PMC-600, but the workbench is not limited by the model.

Preferably, the spindle mechanism comprises a first mounting frame sliding on the front side of the first Z-direction screw rod transmission mechanism, a first balance cylinder is arranged on the first mounting frame, a spindle box is arranged on the front side of the first mounting frame, a spindle vertically penetrates through the spindle box, a rotating motor is arranged on the spindle box, and a cutter selected from a cutter magazine is arranged at the lower end of the spindle.

After the technical scheme is adopted, the first balance cylinder can play a role in balancing the operation of the main shaft so as to improve the machining precision of the main shaft; when the spindle is driven by the rotating motor to rotate, the cutters can be driven to synchronously rotate, and when different types of cutters rotate, the workpiece placed on the workpiece table can be subjected to machining such as hole milling, tapping, boring, chamfering and the like.

Preferably, the grinding head mechanism comprises a second mounting frame, a second balance cylinder is arranged on the second mounting frame, two belt wheels are arranged on one side of the second mounting frame and distributed up and down, the two belt wheels are connected with a grinding belt, a first motor is arranged on one side of the grinding belt, and the belt wheel on one side of the first motor is connected with a first belt wheel mechanism.

After the technical scheme is adopted, the second balance cylinder can play a parallel role in running of the two abrasive belt wheels so as to improve the milling and grinding precision of the abrasive belt wheels; when the first motor rotates, one of the belt pulleys connected with the first motor can be driven to synchronously rotate through the first belt pulley mechanism, and when one of the belt pulleys rotates, the other belt pulley can be driven to synchronously rotate through the abrasive belt, namely, when the two belt pulleys synchronously rotate, the abrasive belt can be driven to rotate, and when the abrasive belt rotates, the workpiece which is transferred to the lower side of the workbench along with the workbench or the workpiece which is transferred to the side of the workbench can be milled.

Preferably, the X-direction screw transmission mechanism comprises an X-direction ball screw, X-direction guide rails are respectively arranged on two sides of the X-direction ball screw, one end of the X-direction ball screw is connected with a second motor, and a first nut supporting seat is arranged on the connection of the X-direction ball screw and the Y-direction screw transmission mechanism.

After the technical scheme is adopted, when the second motor rotates forward and backward, the X-direction ball screw can be driven to synchronously rotate forward and backward, and the X-direction ball screw which rotates forward and backward can drive the first nut supporting seat to move left and right, so that the Y-direction screw transmission mechanism can move left and right along with the movement of the first nut supporting seat.

Preferably, the Y-direction screw transmission mechanism comprises a Y-direction ball screw, Y-direction guide rails are respectively arranged on two sides of the Y-direction ball screw, one end of the Y-direction ball screw is connected with a third motor, and a second nut supporting seat is arranged on the connection between the Y-direction ball screw and the workbench.

After the technical scheme is adopted, when the third motor rotates forward and backward, the Y-direction ball screw can be driven to synchronously rotate forward and backward, the Y-direction ball screw which rotates forward and backward can drive the second nut supporting seat to move forward and backward, and when the second nut supporting seat moves forward and backward, the workbench can be driven to synchronously move forward and backward.

Preferably, the first Z-direction screw rod transmission mechanism comprises a first Z-direction ball screw rod, the two sides of the first Z-direction ball screw rod are respectively provided with a first Z-direction guide rail, one end of the first Z-direction ball screw rod is connected with a fourth motor, and a third nut supporting seat is arranged on the first Z-direction ball screw rod penetrating through the center of the first Z-direction ball screw rod.

After the technical scheme is adopted, when the fourth motor rotates forward and backward, the first Z-direction ball screw can be driven to synchronously rotate forward and backward, the first Z-direction ball screw which rotates forward and backward can drive the third nut supporting seat to move up and down, and because the third nut supporting seat is fixedly assembled with the first mounting frame of the spindle mechanism, the spindle mechanism can move up and down along with the lifting of the third nut supporting seat, so that the spindle mechanism can flexibly process a workpiece, and the processing precision of the spindle mechanism is high.

Preferably, the second Z-direction screw rod transmission mechanism comprises a second Z-direction ball screw rod, two sides of the second Z-direction ball screw rod are respectively provided with a second Z-direction guide rail, one end of the second Z-direction ball screw rod is connected with a fifth motor, and a fourth nut supporting seat is arranged on the center of the second Z-direction ball screw rod in a penetrating way.

After adopting foretell technical scheme, can drive the synchronous forward and backward rotation of second Z to ball screw when fifth motor forward and backward rotates, forward and backward pivoted second Z to ball screw can drive fourth nut supporting seat and go up and down to remove, because fourth nut supporting seat is the second mounting bracket fixed assembly with grinding head mechanism, makes grinding head mechanism can carry out the reciprocating along with the lift of fourth nut supporting seat to make grinding head mechanism realize can carrying out nimble processing to the work piece, with guarantee its machining precision height.

Preferably, the first pulley mechanism and the second pulley mechanism each comprise two pulleys to which a belt is connected.

Preferably, the device is respectively in signal connection with the X-direction screw rod transmission mechanism, the Y-direction screw rod transmission mechanism, the first Z-direction screw rod transmission mechanism, the second Z-direction screw rod transmission mechanism, the main shaft mechanism, the grinding head mechanism and other mechanisms, a touch panel is arranged in the touch panel, a CNC (computer numerical control) system is arranged in the touch panel, an operator can input parameters for controlling the operation of each mechanism or each component to the CNC system through the touch panel, such as the type of a tool to be replaced for main shaft machining, the depth data of working procedures such as drilling, tapping, boring, chamfering and the like of a workpiece, and the like, so that the device can realize automatic operation. The CNC numerical control system is applied to enable the running of the equipment to be free of programming, the dependence on programmers can be reduced, the programming training of operators can be reduced, and the operation of the equipment is simpler and more convenient.

Compared with the prior art, the utility model has the beneficial effects that: 1. the structure of the X-direction screw rod transmission mechanism, the Y-direction screw rod transmission mechanism, the first Z-direction screw rod transmission mechanism, the second Z-direction screw rod transmission mechanism, the main shaft mechanism and the grinding head mechanism is respectively designed, and the structures of the X-direction screw rod transmission mechanism, the Y-direction screw rod transmission mechanism, the first Z-direction screw rod transmission mechanism, the second Z-direction screw rod transmission mechanism, the main shaft mechanism and the grinding head mechanism are matched with the components such as a base, a workbench and the like for use, the integral structural design realizes that a workpiece can be subjected to a plurality of different processing procedures such as hole milling, tooth milling, boring and chamfering by replacing different types of cutters on one device, and the workpiece can be subjected to milling and grinding by the grinding head mechanism, so that the problem that the traditional machine tool structure cannot be used for carrying out a plurality of different processing procedures such as hole milling, tooth milling, boring, chamfering and milling and grinding on the workpiece is required to take part in a plurality of feeding and blanking times among a plurality of different devices, the workpiece is easy to deform and error is large compared with the previous calibration, and the workpiece has poor precision is avoided; the workpiece processed by the method not only avoids deformation, but also has the advantages of high processing precision, high yield and high production efficiency, and in addition, the labor intensity of workers and the labor cost of enterprises are reduced.

2. When the workbench is matched with the X-direction screw rod transmission mechanism, the Y-direction screw rod transmission mechanism, the first Z-direction screw rod transmission mechanism, the second Z-direction screw rod transmission mechanism, the main shaft mechanism and the grinding head mechanism for use, a workpiece can move left and right and can move back and forth along with the workbench under the common driving of the X-direction screw rod transmission mechanism and the Y-direction screw rod transmission mechanism, and the main shaft mechanism can move up and down under the driving of the first Z-direction screw rod transmission mechanism, so that the workpiece can be machined on five surfaces to the greatest extent, the trouble of secondarily clamping the workpiece among a plurality of machine tools with different functions is reduced, the time waste for secondarily clamping the workpiece is avoided, the machining efficiency of the workpiece is improved, and the workpiece deformation caused by secondarily clamping the workpiece can be avoided, so that the machining precision of the workpiece is affected.

Drawings

For ease of illustration, the utility model is described in detail by the following preferred embodiments and the accompanying drawings.

Fig. 1 is a perspective view of a programming-free milling, grinding, drilling, tapping and boring integrated machine.

Fig. 2 is a perspective view of the programming-free milling, grinding, drilling, tapping and boring integrated machine without a mounting base, an X-direction screw rod transmission mechanism, a Y-direction screw rod transmission mechanism, a workbench, a main shaft mechanism and a grinding head mechanism.

Description of the embodiments

In order that the utility model may be readily understood, a more complete description of the utility model will be rendered by reference to the appended drawings. The drawings illustrate preferred embodiments of the utility model. This utility model may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

In this embodiment, referring to fig. 1 to 2, the programming-free milling, grinding, drilling, tapping and boring integrated machine of the present utility model includes a base 1, wherein a first upright 21 and a second upright 22 are respectively disposed on one side of the base 1, the second upright 22 is disposed on one side of the first upright 21, an X-direction screw transmission mechanism 3 is disposed on the base 1, a Y-direction screw transmission mechanism 4 is slidingly disposed on the X-direction screw transmission mechanism 3, and a workbench 5 is disposed on the Y-direction screw transmission mechanism 4; a first Z-direction screw rod transmission mechanism 61 is arranged on one side of the first upright post 21 facing the base 1, a main shaft mechanism 7 is arranged on one side of the first Z-direction screw rod transmission mechanism 61, and a tool magazine 8 is arranged on one side of the main shaft mechanism 7; a second Z-direction screw transmission mechanism 62 is arranged on the side of the second upright 22 facing the base 1, and a grinding head mechanism 9 is arranged on the side of the second Z-direction screw transmission mechanism 62.

In one embodiment, the spindle mechanism 7 includes a first mounting frame 71 sliding on the front side of the first Z-direction screw transmission mechanism 61, a first balance cylinder 72 is provided on the first mounting frame 71, a spindle box 73 is provided on the front side of the first mounting frame 71, a spindle 74 is provided vertically penetrating the spindle box 73, a rotating motor 75 is provided on the spindle box 73, and a cutter 76 is mounted on the lower end of the spindle 74.

In one embodiment, the grinding head mechanism 9 includes a second mounting frame 91, a second balance cylinder 92 is disposed on the second mounting frame 91, two belt wheels 93 are disposed on one side of the second mounting frame 91, the two belt wheels 93 are distributed up and down, the two belt wheels 93 are connected with an abrasive belt 94, a first motor 95 is disposed on one side of the abrasive belt 94, and the belt wheel 93 on one side of the first motor 95 is connected with the first motor 95.

In one embodiment, a second pulley mechanism is coupled to the spindle 74 and the rotary motor 75.

In one embodiment, the X-direction screw transmission mechanism 3 includes an X-direction ball screw 31, two sides of the X-direction ball screw 31 are respectively provided with an X-direction guide rail 32, one end of the X-direction ball screw 31 is connected with a second motor 33, and a first nut support seat is installed in connection with the X-direction ball screw 31 and the Y-direction screw transmission mechanism 4.

In one embodiment, the Y-direction screw transmission mechanism 4 includes a Y-direction ball screw 41, two sides of the Y-direction ball screw 41 are respectively provided with a Y-direction guide rail 42, one end of the Y-direction ball screw 41 is connected with a third motor 43, and a second nut supporting seat is installed in connection between the Y-direction ball screw 41 and the workbench 5.

In one embodiment, the first Z-direction screw transmission mechanism 61 includes a first Z-direction ball screw 611, two sides of the first Z-direction ball screw 611 are respectively provided with a first Z-direction guide rail 612, one end of the first Z-direction ball screw 611 is connected with a fourth motor 613, and the first Z-direction ball screw 611 is provided with a third nut supporting seat penetrating through the center thereof.

In one embodiment, the second Z-direction screw transmission mechanism 62 includes a second Z-direction ball screw 621, two sides of the second Z-direction ball screw 621 are respectively provided with a second Z-direction guide rail 622, one end of the second Z-direction ball screw 621 is connected with a fifth motor 623, and a fourth nut supporting seat is provided through the center of the second Z-direction ball screw 621.

In one embodiment, the operation flow of the programming-free milling, grinding, drilling, tapping and boring integrated machine is as follows: the workpiece to be processed is firstly placed on the workbench 5, and when the second motor 33 in the X-direction screw rod transmission mechanism 3 rotates forwards and backwards, the Y-direction screw rod transmission mechanism 4 can be driven to move left and right through the X-direction ball screw rod 31. When the third motor 43 in the Y-direction screw rod transmission mechanism 4 rotates forwards and backwards, the workbench 5 can be driven to move forwards and backwards through the Y-direction ball screw 41, so that the workbench 5 can accurately position a workpiece below the spindle mechanism 7 after left-right movement and front-back movement under the common drive of the X-direction screw rod transmission mechanism 3 and the Y-direction screw rod transmission mechanism 4; when the fourth motor 613 in the first Z-direction screw rod transmission mechanism 61 rotates forwards and backwards, the first Z-direction ball screw rod 611 can drive the main shaft mechanism 7 to move upwards and downwards, when the main shaft 74 in the main shaft mechanism 7 descends to the surface of a workpiece under the drive of the fourth motor 613, the main shaft 74 can drive various different types of cutters 76 arranged at the lower end of the main shaft 74 to synchronously rotate under the drive of the rotating motor 75, and the various different types of cutters 76 can respectively mill holes, tap, bore holes, chamfer angles and the like on the workpiece placed on the workbench 5 when rotating; because the main shaft mechanism 7 is used together with the X-direction screw rod transmission mechanism 3 and the Y-direction screw rod transmission mechanism 4, the workpiece can move along with the movement of the workbench 5, so that the main shaft 74 can respectively mill holes, tap teeth, bore holes, chamfer angles and the like on the top surface and four side surfaces (five surfaces in total) of the workpiece; when the main shaft 74 finishes the processing of milling holes, tapping, boring, chamfering and the like on the workpiece, the workpiece can be accurately transferred to one side or right below the grinding head mechanism 9 along with the workbench 5 under the common drive of the X-direction screw rod transmission mechanism 3 and the Y-direction screw rod transmission mechanism 4, so that the grinding head mechanism 9 can mill the side surface and the top surface of the workpiece, and after the workpiece finishes milling, the workpiece can move forwards along with the workbench 5 under the drive of the Y-direction screw rod transmission mechanism 4, and the workbench 5 after the forward movement can facilitate the blanking of the workpiece; the whole structural design of the workpiece milling machine can realize a plurality of different machining procedures such as milling holes, tapping, boring, chamfering and the like on the workpiece by replacing different types of cutters 76 on one piece of equipment, and the workpiece machined by adopting the workpiece milling machine can be milled and ground through the grinding head mechanism 9, so that the workpiece machined by adopting the workpiece milling machine has the advantages of high machining precision, high yield and high production efficiency, and in addition, the labor intensity of workers and the labor cost of enterprises are reduced, so that the workpiece milling machine effectively solves the problems that when a machine tool of the traditional structure is used for drilling, tapping, boring, chamfering, milling and the like on the workpiece, a human hand is needed to participate in feeding and discharging among a plurality of machine tools with different functions, and the workpiece is required to be subjected to clamping for a plurality of times, so that the workpiece is easy to deform, the machining precision of the workpiece is poor, the correction error before and after the workpiece deformation is large, and the yield of the workpiece is low.

The above embodiment is only an example of the present utility model and is not intended to limit the scope of the present utility model, and all technical solutions identical or equivalent to those described in the claims should be included in the scope of the present utility model.

Claims (8)

1. Exempt from to programme milling, bore and attack boring all-in-one, its characterized in that: the device comprises a base, wherein a first upright post and a second upright post are respectively arranged on one side of the base, the second upright post is positioned on one side of the first upright post, an X-direction screw rod transmission mechanism is arranged on the base, a Y-direction screw rod transmission mechanism is arranged on the X-direction screw rod transmission mechanism in a sliding manner, and a workbench is arranged on the Y-direction screw rod transmission mechanism; a first Z-direction screw rod transmission mechanism is arranged on one side of the first upright column facing the base, a main shaft mechanism is arranged on one side of the first Z-direction screw rod transmission mechanism, and a tool magazine is arranged on one side of the main shaft mechanism; a second Z-direction screw rod transmission mechanism is arranged on one side of the second upright post, which faces the base, and a grinding head mechanism is arranged on one side of the second Z-direction screw rod transmission mechanism.

2. The programming-free milling, grinding, drilling, tapping and boring integrated machine according to claim 1, wherein: the spindle mechanism comprises a first mounting frame sliding on the front side of the first Z-direction screw rod transmission mechanism, a first balance cylinder is arranged on the first mounting frame, a spindle box is arranged on the front side of the first mounting frame, a spindle is arranged vertically penetrating through the spindle box, a rotating motor is arranged on the spindle box, and a cutter is arranged at the lower end of the spindle.

3. The programming-free milling, grinding, drilling, tapping and boring integrated machine according to claim 1, wherein: the grinding head mechanism comprises a second mounting frame, a second balance cylinder is arranged on the second mounting frame, two abrasive belt wheels are arranged on one side of the second mounting frame and distributed up and down, the two abrasive belt wheels are connected with abrasive belts, a first motor is arranged on one side of each abrasive belt, and the abrasive belt wheel on one side of the first motor is connected with a first belt wheel mechanism.

4. The programming-free milling, grinding, drilling, tapping and boring integrated machine according to claim 2, wherein: the main shaft and the rotating motor are connected with a second leather wheel mechanism.

5. The programming-free milling, grinding, drilling, tapping and boring integrated machine according to claim 1, wherein: the X-direction screw rod transmission mechanism comprises an X-direction ball screw rod, X-direction guide rails are respectively arranged on two sides of the X-direction ball screw rod, and one end of the X-direction ball screw rod is connected with a second motor.

6. The programming-free milling, grinding, drilling, tapping and boring integrated machine according to claim 1, wherein: the Y-direction screw rod transmission mechanism comprises a Y-direction ball screw rod, two sides of the Y-direction ball screw rod are respectively provided with a Y-direction guide rail, and one end of the Y-direction ball screw rod is connected with a third motor.

7. The programming-free milling, grinding, drilling, tapping and boring integrated machine according to claim 1, wherein: the first Z-direction screw rod transmission mechanism comprises a first Z-direction ball screw rod, first Z-direction guide rails are respectively arranged on two sides of the first Z-direction ball screw rod, and one end of the first Z-direction ball screw rod is connected with a fourth motor.

8. The programming-free milling, grinding, drilling, tapping and boring integrated machine according to claim 1, wherein: the second Z-direction screw rod transmission mechanism comprises a second Z-direction ball screw rod, two sides of the second Z-direction ball screw rod are respectively provided with a second Z-direction guide rail, and one end of the second Z-direction ball screw rod is connected with a fifth motor.