CN117001019A - Hardware lathe machining system and production process - Google Patents

Abstract

The application relates to the technical field of machining devices, and particularly discloses a hardware lathe machining system which comprises a lathe body, a lathe cover, a glass cover and a chip removing mechanism, wherein the lathe cover is arranged at the upper end of the lathe body, the glass cover is arranged at the upper end of the lathe cover, the glass cover covers the lathe cover, the chip removing mechanism comprises a swinging assembly, a driving assembly, hanging lugs, a mounting plate body and high-pressure nozzles, the swinging assembly is fixedly connected with the lathe cover, the driving assembly is arranged at one side of the lathe body, the driving assembly and the swinging assembly are mutually matched, the two hanging lugs are respectively fixedly connected with the mounting plate body and are respectively positioned at the upper end of a half day of installation, the two hanging lugs are respectively arranged at the output end of the swinging assembly, and each high-pressure nozzle is respectively fixedly connected with the mounting plate and respectively penetrates through the mounting plate. The setting of above structure can need not the manual work and cleans the sweeps, cleans efficiently, reduces the manual work simultaneously and cleans the potential safety hazard of sweeps, protects operating personnel's personal safety.

Description

Hardware lathe machining system and production process

Technical Field

The application relates to the technical field of processing devices, in particular to a hardware lathe processing system and a production process.

Background

At present, a lathe is one of important workpiece processing devices, and mainly uses a turning tool to carry out turning processing on a rotating workpiece, and a drill bit, a reamer and a tap tool can be used for processing the workpiece on the lathe, so that the processing efficiency of the workpiece can be improved, but workpiece scraps can splash everywhere in the processing process, so that the workpiece scraps are difficult to recover, and operators are easy to be accidentally injured.

In the prior art, through increasing the insulating glass door on the lathe body of lathe, can carry out the check to the sweeps that splashes in the operation process for the sweeps fall into the inside of lathe, can be convenient for retrieve the sweeps, can not accidentally injure operating personnel simultaneously.

But in the prior art, when carrying out the isolation processing to the work piece, the sweeps can splash to on slip table and the blade disc of lathe, lead to when the clearance lathe, need the manual sweeps clearance of manual with the brush, lead to the clearance process slow to there is the potential safety hazard in the clearance process.

Disclosure of Invention

The application aims to provide a hardware lathe machining system and a production process, and aims to solve the technical problems that in the prior art, when a workpiece is isolated, scraps can splash on a sliding table and a cutter head of a lathe, when the lathe is cleaned, the scraps need to be manually cleaned by a hairbrush, the cleaning process is slow, and potential safety hazards exist in the cleaning process.

In order to achieve the above purpose, the hardware lathe processing system comprises a lathe body, a lathe cover, a glass cover and a chip removing mechanism, wherein the lathe cover is arranged at the upper end of the lathe body, the glass cover is arranged at the upper end of the lathe cover, the glass cover is covered with the lathe cover, the chip removing mechanism comprises a swinging component, a driving component, a plurality of hanging lugs, a mounting plate body and high-pressure nozzles, the swinging component is fixedly connected with the lathe cover and is positioned in the lathe cover, the driving component is arranged at one side of the lathe body, the driving component is mutually matched with the swinging component, the number of the hanging lugs is two, the two hanging lugs are respectively fixedly connected with the mounting plate body and are respectively positioned at the upper end of the mounting plate body for half a day, the two hanging lugs are respectively arranged at the output end of the swinging component, the number of the high-pressure nozzles is multiple, and each high-pressure nozzle is respectively fixedly connected with the mounting plate and respectively penetrates through the mounting plate.

The swinging assembly comprises a support plate, a shaft rod, a rotating disc, a guide rod, a driving fluted disc, a reciprocating toothed disc and sliding lugs, wherein the support plate is fixedly connected with the bed cover and is positioned in the bed cover, the shaft rod is rotatably connected with the support plate and penetrates through the support plate, the rotating disc is fixedly connected with the support plate and is sleeved on the outer surface wall of the shaft rod, the guide rod is rotatably connected with the rotating disc and is positioned on one side of the rotating disc, the driving fluted disc is rotatably connected with the support plate and is positioned on one side of the support plate, one end of the driving fluted disc is mutually matched with the guide rod, the number of the sliding lugs is two, the two sliding lugs are respectively fixedly connected with the support plate and are respectively positioned on one side of the support plate, the reciprocating toothed disc is slidably connected with the two sliding lugs and are respectively positioned in the two sliding lugs, the reciprocating toothed disc is meshed with the driving toothed disc, and the two hanging lugs are respectively arranged at two ends of the reciprocating lugs.

The driving fluted disc comprises a disc shaft, a sector tooth and a hollow handle, wherein the disc shaft is rotationally connected with the support plate, the disc shaft penetrates through the support plate, the sector tooth is fixedly connected with the disc shaft and is positioned on the outer surface wall of the disc shaft, the sector tooth is meshed with the reciprocating toothed bar, the hollow handle is fixedly connected with the disc shaft and is positioned on the outer surface wall of the disc shaft, and the guide rod is embedded in the hollow handle.

The driving assembly comprises a motor frame, a driving motor and an inclined plate, wherein the motor frame is fixedly connected with the lathe body and is positioned on one side of the lathe body, two ends of the inclined plate are respectively fixedly connected with the motor frame and the lathe body and are positioned between the motor frame and the lathe body, the driving motor is arranged at the upper end of the motor frame, and the output end of the driving motor penetrates through the lathe body and is fixedly connected with the shaft rod.

The hardware lathe machining system further comprises an electromagnetic valve, a flow dividing assembly and an external pump pipe, wherein the electromagnetic valve is fixedly connected with the bed cover and embedded in the bed cover, the external pump pipe is communicated with the electromagnetic valve and located outside the bed cover, one end of the flow dividing assembly is communicated with the high-pressure nozzles, and the other end of the flow dividing assembly is communicated with the electromagnetic valve and located inside the bed cover.

The shunt assembly comprises a shunt tube body and a universal tube, wherein the shunt tube body is communicated with the high-pressure nozzles, and two ends of the universal tube are respectively communicated with the shunt tube body and the electromagnetic valve and are positioned in the bed cover.

The application also provides a production process of the hardware lathe processing system, which is applied to the hardware lathe processing system and comprises the following steps:

clamping the material rod on the lathe body and performing tool setting;

after the tool setting operation is finished, sliding the glass cover to cover and seal the bed cover;

starting a preset program of the lathe body to process the material rod;

after the processing of the material rod is finished, the driving assembly drives the swinging assembly to swing so as to drive the mounting plate body and the high-pressure nozzle to swing reciprocally, high-pressure gas is introduced into the high-pressure nozzle, and the high-pressure gas sprayed by the high-pressure nozzle blows and washes scraps in the lathe body;

blowing scraps into the scrap box for collection;

thereby completing the cleaning of scraps in the lathe body.

According to the hardware lathe processing system and the production process, the glass cover is supported by the bed cover, meanwhile, the lathe body is covered by the bed cover, the lathe cover is covered by the glass cover, high-pressure gas is introduced into the high-pressure nozzle, the high-pressure nozzle is supported by the mounting plate body, the mounting plate body is connected with the swinging assembly through the hanging lugs, and the driving assembly drives the swinging assembly to swing reciprocally, so that the high-pressure nozzle carries out reciprocating jetting back and forth to carry out high-pressure jetting on the scraps on the lathe body.

Drawings

In order to more clearly illustrate the embodiments of the application or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural view of a first embodiment of the present application.

Fig. 2 is a top view of a first embodiment of the present application.

Fig. 3 is a partial structural schematic diagram of a first embodiment of the present application.

Fig. 4 is a partial structural sectional view of a second embodiment of the present application.

Fig. 5 is a side view of a third embodiment of the present application.

Fig. 6 is a partial structural sectional view of a third embodiment of the present application.

Fig. 7 is a process step flow diagram of a production process of a hardware lathe machining system of the present application.

101-lathe body, 102-bed cover, 103-glass cover, 104-support plate, 105-shaft rod, 106-turntable, 107-guide rod, 108-reel shaft, 109-sector gear, 110-hollow handle, 111-reciprocating toothed bar, 112-sliding support lug, 113-motor frame, 114-driving motor, 115-sloping plate, 116-hanging lug, 117-mounting plate body, 118-high-pressure nozzle, 201-electromagnetic valve, 202-external pump pipe, 203-shunt pipe body, 204-universal pipe, 301-scrap box, 302-universal wheel, 303-side plate, 304-magnetic block, 305-placing cylinder, 306-telescopic rod and 307-holding rod.

Detailed Description

The first embodiment of the application is as follows:

referring to fig. 1 to 3, fig. 1 is a schematic structural diagram of a first embodiment of the present application, fig. 2 is a top view of the first embodiment of the present application, and fig. 3 is a schematic partial structural diagram of the first embodiment of the present application.

The application provides a hardware lathe machining system, which comprises: including lathe body 101, bed cover 102, glass cover 103 and clear bits mechanism, clear bits mechanism includes swing subassembly, drive assembly, hangers 116, mounting panel body 117 and high-pressure nozzle 118, swing subassembly includes extension board 104, axostylus axostyle 105, carousel 106, guide bar 107, initiative fluted disc, reciprocal toothed bar 111 and slip journal stirrup 112, initiative fluted disc includes dish axle 108, sector 109 and cavity handle 110, drive assembly includes motor frame 113, driving motor 114 and swash plate 115.

For this embodiment, the lathe body 101 supports the lathe cover 102, while the lathe cover 102 covers the lathe body 101, the glass cover 103 covers the lathe cover 102, and the driving motor 114 drives the turntable 106 to rotate and then drives the driving fluted disc to reciprocate, so that the mounting plate 117 and the high-pressure nozzle 118 reciprocate, thereby achieving the purpose of reciprocating injection of the lathe body 101.

The lathe is characterized in that the lathe cover 102 is arranged at the upper end of the lathe body 101, the glass cover 103 is arranged at the upper end of the lathe cover 102, the glass cover 103 covers the lathe cover 102, the swinging component is fixedly connected with the lathe cover 102 and is positioned in the lathe cover 102, the driving component is arranged at one side of the lathe body 101, the driving component is mutually matched with the swinging component, the number of the hanging lugs 116 is two, the hanging lugs 116 are respectively fixedly connected with the mounting plate body 117 and are respectively positioned at the upper end of the mounting half day, the two hanging lugs 116 are respectively arranged at the output end of the swinging component, the number of the high-pressure nozzles 118 is multiple, each high-pressure nozzle 118 is respectively fixedly connected with the mounting plate and respectively penetrates through the mounting plate, the lathe cover 102 supports the glass cover 103, the lathe cover 102 is covered with the lathe body 101, the two hanging lugs 116 are respectively connected with the mounting plate body in a reciprocating mode, the high-pressure nozzles are driven by the high-pressure jetting component, and the high-pressure jetting component is driven by the reciprocating component to reciprocate.

Secondly, the support plate 104 with bed cover 102 fixed connection, and be located bed cover 102's inside, axostylus axostyle 105 with support plate 104 rotates to be connected, and runs through support plate 104, carousel 106 with support plate 104 fixed connection, and the cover is located the outer wall of axostylus axostyle 105, guide bar 107 with carousel 106 rotates to be connected, and is located one side of carousel 106, initiative fluted disc with support plate 104 rotates to be connected, and is located one side of support plate 104, and the one end of initiative fluted disc with guide bar 107 is mutually adapted, the quantity of slip lug 112 is two, two slip lug 112 respectively with support plate 104 fixed connection, and be located respectively one side of support plate 104, reciprocal fluted disc 111 with two slip lug 112 sliding connection, and be located two slip lug 112's inside, just reciprocal fluted disc 111 with initiative meshing, two initiative fluted disc 116 set up respectively in support plate 111 reciprocal fluted disc 111 the guide lug 105 is rotated and is carried out reciprocal fluted disc 111 and is carried out reciprocal fluted disc 107 and is carried out reciprocal fluted disc assembly and is carried out reciprocal fluted disc 107 and is carried out reciprocal carrier wave motion, and carries out reciprocal fluted disc assembly carries out reciprocal carrier wave guide disc 107 and is rotated and carries out reciprocal carrier wave assembly and carries out reciprocal carrier wave-absorbing disc 107 and carries out reciprocal carrier assembly.

Meanwhile, the disc shaft 108 is rotatably connected with the support plate 104, the disc shaft 108 penetrates through the support plate 104, the sector gear 109 is fixedly connected with the disc shaft 108 and located on the outer surface wall of the disc shaft 108, the sector gear 109 is meshed with the reciprocating gear rod 111, the hollow handle 110 is fixedly connected with the disc shaft 108 and located on the outer surface wall of the disc shaft 108, the guide rod 107 is embedded in the hollow handle 110, the disc shaft 108 supports the sector gear 109 and the hollow handle 110, meanwhile, the sector gear 109 is meshed with the reciprocating gear rod 111 to drive the reciprocating gear rod 111 to reciprocate, the hollow handle 110 is matched with the guide rod 107, and the sector gear 109 is driven to swing by the hollow handle 110.

In addition, the motor frame 113 with lathe body 101 fixed connection, and be located one side of lathe body 101, the both ends of swash plate 115 respectively with motor frame 113 with lathe body 101 fixed connection, and be located between motor frame 113 and the lathe body 101, driving motor 114 set up in the upper end of motor frame 113, just driving motor 114's output run through lathe body 101 and with axostylus axostyle 105 fixed connection, motor frame 113 is right driving motor 114 supports, driving motor 114 drives axostylus axostyle 105 rotates, simultaneously by swash plate 115 supports motor frame 113 improves the support intensity of motor frame 113.

When the hardware lathe processing system of the embodiment is used, the lathe cover 102 supports the glass cover 103, meanwhile, the lathe cover 102 covers the lathe body 101, the glass cover 103 covers the lathe cover 102, high-pressure gas is introduced into the high-pressure nozzle 118, the high-pressure nozzle 118 is supported by the mounting plate body 117, the mounting plate body 117 is connected with the swinging assembly through the hanging lugs 116, the driving assembly drives the swinging assembly to reciprocate, so that the high-pressure nozzle 118 performs reciprocating injection, the waste chips on the lathe body 101 are simultaneously supported by the supporting plate 104, the shaft rod 105 and the turntable 106 are driven by the driving assembly to rotate, the turntable 106 and the guide rod 107 are further driven to rotate, the driving fluted disc 107 is driven to swing back and forth, the sliding lugs 112 support and limit the reciprocating toothed rod 111, when the driving fluted disc 111 is in driving motion, the driving motor is driven by the driving motor, the reciprocating fluted disc 111 drives the hollow fluted disc 109 to reciprocate, the hollow toothed disc 109 is driven by the driving motor, the hollow toothed disc 109 is driven by the hollow toothed disc 109, the hollow toothed disc 109 is driven by the driving motor 113, the hollow toothed disc 109 is simultaneously, the hollow toothed disc 109 is driven by the hollow toothed disc 109 to reciprocate, and the hollow toothed disc 109 is driven by the hollow toothed disc 109, the supporting strength of the motor frame 113 is improved.

The second embodiment of the application is as follows:

on the basis of the first embodiment, please refer to fig. 4, wherein fig. 4 is a partial structural cross-sectional view of a second embodiment of the present application.

The application provides a hardware lathe machining system, which comprises: also included are solenoid valve 201, shunt assembly, external pump tube 202, shunt tube body 203, and universal tube 204.

For the present embodiment, the electromagnetic valve 201 controls the opening and closing of the air pressure, and the external pump pipe 202 communicates the electromagnetic valve 201 with the output end of the air compressor, so as to supply high-pressure air to the high-pressure nozzle 118 and blow the processing scraps in the lathe body 101.

The electromagnetic valve 201 is fixedly connected with the bed cover 102 and is embedded in the bed cover 102, the external pump pipe 202 is communicated with the electromagnetic valve 201 and is located outside the bed cover 102, one end of the flow dividing assembly is communicated with the high-pressure nozzles 118, the other end of the flow dividing assembly is communicated with the electromagnetic valve 201 and is located inside the bed cover 102, the electromagnetic valve 201 is connected with the external pump pipe 202 and the flow dividing assembly, the external pump pipe 202 is connected with the output end of the air compressor, high-pressure gas is provided for the flow dividing assembly through the external pump pipe 202, and the electromagnetic valve 201 can control the on and off of the high-pressure gas so as to achieve the purpose of intelligent control.

Secondly, the shunt tube body 203 is communicated with a plurality of high pressure nozzles 118, two ends of the universal tube 204 are respectively communicated with the shunt tube body 203 and the electromagnetic valve 201, and are located inside the bed cover 102, the shunt tube body 203 is connected with the corresponding high pressure nozzles 118, and provides high pressure gas for each high pressure nozzle 118, the shunt tube body 203 is communicated with the electromagnetic valve 201 through the universal tube 204, and the universal tube 204 can facilitate the shunt tube body 203 to follow the mounting plate body 117 to perform reciprocating swing operation.

When the hardware lathe machining system of the embodiment is used, the electromagnetic valve 201 is connected with the external pump pipe 202 and the shunt assembly, the external pump pipe 202 is connected with the output end of the air compressor, high-pressure gas is supplied to the shunt assembly through the external pump pipe 202, the electromagnetic valve 201 can control the opening and closing of the high-pressure gas to achieve the purpose of intelligent control, the shunt pipe body 203 is communicated with the electromagnetic valve 201 through the universal pipe 204, and the shunt pipe body 203 can conveniently follow the mounting plate body 117 to perform reciprocating swing operation.

The third embodiment of the application is as follows:

on the basis of the second embodiment, please refer to fig. 5 and 6, wherein fig. 5 is a side view of the third embodiment of the present application, and fig. 6 is a partial structural cross-sectional view of the third embodiment of the present application.

The application provides a hardware lathe machining system, which comprises: further comprises a scrap box 301, a universal wheel 302, a side plate 303, a magnetic block 304, a placing barrel 305, a telescopic rod 306 and a holding rod 307.

For this embodiment, the scraps generated during processing are collected by the scrap box 301, and meanwhile, the scrap box 301 is supported by the universal wheels 302, and is magnetically attracted to the lathe body 101 by the magnetic blocks 304, so that the scraps are placed on the ground due to the movement of the scrap box 301.

The number of the universal wheels 302 is a plurality of, the universal wheels 302 are respectively and fixedly connected with the scrap box 301 and are respectively positioned at the lower end of the scrap box 301, the number of the side plates 303 is two, the two side plates 303 are respectively and fixedly connected with the scrap box 301 and are respectively positioned at the two sides of the scrap box 301, the number of the magnetic blocks 304 is two, each magnetic block 304 is respectively and fixedly connected with the corresponding side plate 303 and is respectively embedded at one side of the corresponding side plate 303, the scrap box 301 is arranged at the lower end of the lathe body 101, the scrap box 301 is used for collecting and loading the scraps blown off from the upper end of the lathe body 101, meanwhile, the universal wheels 302 can also drive the scrap box 301 to move, the magnetic blocks 304 are respectively supported by the side plates 303, and when the magnetic blocks 304 are contacted with the lathe body 101, the magnetic blocks are respectively fixed to the lathe body 101, and the scraps are prevented from falling into the lathe body 301, and the scraps are prevented from being sucked and being difficult to be absorbed into the ground.

Secondly, the number of placing barrels 305 is two, two placing barrels 305 respectively with sweeps case 301 fixed connection, and be located respectively one side of sweeps case 301, the number of telescopic link 306 is two, every telescopic link 306 respectively with corresponding placing barrels 305 fixed connection, and be located respectively corresponding placing barrels 305's inside, grip 307 and two telescopic link 306 fixed connection, and be located two telescopic link 306's one end, sweeps case 301 is to two placing barrels 305 supports fixedly, simultaneously telescopic link 306 is placed in corresponding placing barrels 305's inside, grip 307 is connected two telescopic link 306, when removing sweeps case 301, upwards pull grip 307 passes through telescopic link 306 extends, and through grip 307 pulling or pushing sweeps case 301 moves, can be more laborsaving in the process of clearance bits.

When the hardware lathe processing system of the embodiment is used, the scrap box 301 is used for accommodating the scraps blown off from the upper end of the lathe body 101, meanwhile, the universal wheels 302 are used for supporting the universal wheels 302, the universal wheels 302 can also drive the scrap box 301 to move, the side plates 303 are used for supporting the magnetic blocks 304, meanwhile, when the magnetic blocks 304 are contacted with the lathe body 101, the magnetic blocks 304 are used for magnetically attracting and fixing the lathe body 101, the purpose that the scrap box 301 moves in the accommodating process can be achieved, the scraps fall into the ground and are difficult to clean is achieved, the scrap box 301 supports and fixes two accommodating cylinders 305, meanwhile, the telescopic rods 306 are arranged in the corresponding accommodating cylinders 305, the holding rods 307 are connected with the two telescopic rods 306, when the scrap box 301 is moved, the holding rods 307 are lifted upwards to extend through the telescopic rods 306, and the scrap box 307 is pulled or pushed to move, and therefore the scrap box 301 can be cleaned more easily.

Referring to fig. 7, the application further provides a production process of the hardware lathe processing system, which is applied to the hardware lathe processing system, and comprises the following steps:

s1: clamping the material rod on the lathe body 101 and performing tool setting;

s2: after the tool setting operation is finished, sliding the glass cover 103 to cover and seal the bed cover 102;

s3: starting a preset program of the lathe body 101 to process a material rod;

s4: after the processing of the material rod is completed, the driving assembly drives the swinging assembly to swing so as to drive the mounting plate body 117 and the high-pressure nozzle 118 to swing reciprocally, high-pressure gas is introduced into the high-pressure nozzle 118, and the high-pressure gas sprayed by the high-pressure nozzle 118 blows and washes scraps in the lathe body 101;

s5: blowing scraps into the scrap box 301 for collection;

s6: thereby completing the cleaning of the scraps inside the lathe body 101.

Through the production process, the blowing mode can be preset, the opening and closing of the driving motor 114 and the electromagnetic valve 201 can be controlled, a preset system is carried out according to production requirements, the blowing can be carried out once after each workpiece is processed, the blowing can be carried out once after ten workpieces are processed, or the blowing can be carried out by manual control, so that the corresponding blowing can be carried out according to the processing requirements, meanwhile, the blowing can be carried out in the processing process, and the temperature of the workpieces can be reduced through high-pressure gas.

The above disclosure is only a preferred embodiment of the present application, and it should be understood that the scope of the application is not limited thereto, and those skilled in the art will appreciate that all or part of the procedures described above can be performed according to the equivalent changes of the claims, and still fall within the scope of the present application.

Claims (7)

1. The hardware lathe processing system comprises a lathe body, a lathe cover and a glass cover, wherein the lathe cover is arranged at the upper end of the lathe body, the glass cover is arranged at the upper end of the lathe cover, and the glass cover covers the lathe cover,

the device also comprises a scrap removing mechanism;

the chip removing mechanism comprises a swinging assembly, a driving assembly, two hanging lugs, a mounting plate body and high-pressure nozzles, wherein the swinging assembly is fixedly connected with the bed cover and is positioned in the bed cover, the driving assembly is arranged on one side of the lathe body, the driving assembly is mutually matched with the swinging assembly, the two hanging lugs are respectively fixedly connected with the mounting plate body and are respectively positioned at the upper end of the mounting half day, the two hanging lugs are respectively arranged at the output end of the swinging assembly, the number of the high-pressure nozzles is multiple, and each high-pressure nozzle is respectively fixedly connected with the mounting plate and respectively penetrates through the mounting plate.

2. A hardware lathe work system according to claim 1, wherein,

the swing assembly comprises a support plate, a shaft rod, a rotating disc, a guide rod, a driving fluted disc, a reciprocating fluted disc and a sliding support lug, wherein the support plate is fixedly connected with the bed cover and is positioned in the bed cover, the shaft rod is rotationally connected with the support plate and penetrates through the support plate, the rotating disc is fixedly connected with the support plate and is sleeved on the outer surface wall of the shaft rod, the guide rod is rotationally connected with the rotating disc and is positioned on one side of the rotating disc, the driving fluted disc is rotationally connected with the support plate and is positioned on one side of the support plate, one end of the driving fluted disc is mutually matched with the guide rod, the number of the sliding support lugs is two, two sliding support lugs are respectively fixedly connected with the support plate and are respectively positioned on one side of the support plate, the reciprocating fluted disc is slidingly connected with the two sliding support lugs and are positioned in the two sliding support lugs, the reciprocating fluted disc is meshed with the driving fluted disc, and the two hanging lugs are respectively arranged at two ends of the reciprocating fluted disc.

3. A hardware lathe work system according to claim 2, wherein,

the driving fluted disc comprises a disc shaft, a sector tooth and a hollow handle, wherein the disc shaft is rotationally connected with the support plate, the disc shaft penetrates through the support plate, the sector tooth is fixedly connected with the disc shaft and is positioned on the outer surface wall of the disc shaft, the sector tooth is meshed with the reciprocating toothed bar, the hollow handle is fixedly connected with the disc shaft and is positioned on the outer surface wall of the disc shaft, and the guide rod is embedded in the hollow handle.

4. A hardware lathe system as defined in claim 3, wherein,

the driving assembly comprises a motor frame, a driving motor and an inclined plate, wherein the motor frame is fixedly connected with the lathe body and is positioned on one side of the lathe body, two ends of the inclined plate are respectively fixedly connected with the motor frame and the lathe body and are positioned between the motor frame and the lathe body, the driving motor is arranged at the upper end of the motor frame, and the output end of the driving motor penetrates through the lathe body and is fixedly connected with the shaft rod.

5. A hardware lathe system as defined in claim 4, wherein,

the hardware lathe processing system further comprises an electromagnetic valve, a flow dividing assembly and an external pump pipe, wherein the electromagnetic valve is fixedly connected with the bed cover and embedded in the bed cover, the external pump pipe is communicated with the electromagnetic valve and located outside the bed cover, one end of the flow dividing assembly is communicated with the high-pressure nozzles, and the other end of the flow dividing assembly is communicated with the electromagnetic valve and located inside the bed cover.

6. A hardware lathe work system according to claim 5, wherein,

the shunt assembly comprises a shunt tube body and a universal tube, wherein the shunt tube body is communicated with the high-pressure nozzles, and two ends of the universal tube are respectively communicated with the shunt tube body and the electromagnetic valve and are positioned in the bed cover.

7. A process for producing a hardware lathe machining system, which is applied to the hardware lathe machining system as claimed in claim 6, and is characterized by comprising the following steps:

clamping the material rod on the lathe body and performing tool setting;

after the tool setting operation is finished, sliding the glass cover to cover and seal the bed cover;

starting a preset program of the lathe body to process the material rod;

after the processing of the material rod is finished, the driving assembly drives the swinging assembly to swing so as to drive the mounting plate body and the high-pressure nozzle to swing reciprocally, high-pressure gas is introduced into the high-pressure nozzle, and the high-pressure gas sprayed by the high-pressure nozzle blows and washes scraps in the lathe body;

blowing scraps into the scrap box for collection;

thereby completing the cleaning of scraps in the lathe body.