CN112677018A

CN112677018A - Precision mold polishing equipment

Info

Publication number: CN112677018A
Application number: CN202011525016.6A
Authority: CN
Inventors: 李紫怡
Original assignee: Individual
Current assignee: Guangzheng Intelligent Manufacturing Technology Jiangsu Co ltd
Priority date: 2020-12-22
Filing date: 2020-12-22
Publication date: 2021-04-20
Anticipated expiration: 2040-12-22
Also published as: CN112677018B

Abstract

The invention discloses precision mold polishing equipment which comprises a transverse moving device, a translation device, a rotating device and an elastic polishing device, wherein the transverse moving device, the translation device, the rotating device and the elastic polishing device are arranged on a rack, a mold to be polished is placed on a working platform, a mechanical group in the transverse moving device and the translation device operates to move the elastic polishing device to the mold to be polished, the mechanical group in the rotating device operates to drive the elastic polishing device to rotate to be vertical to the mold, a mechanical group in the elastic polishing device operates to drive a polishing grinding head to rotate in a telling mode so as to polish and polish the precision mold to be polished, and when a special-shaped cavity is met in a polishing process, a first spring and a second spring in the elastic polishing device are compressed transversely and longitudinally to ensure the polishing force of the.

Description

Precision mold polishing equipment

Technical Field

The invention relates to the field of polishing, in particular to precision die polishing equipment.

Background

In many production fields, the machining and polishing of the mold is the first element of efficient and high-quality production, while the existing polishing technology is time-consuming and labor-consuming, increases the cost, and easily damages the mold during polishing, and in order to solve such a problem, application No. CN201711350240.4 discloses a polishing device, but the device cannot automatically polish the mold, and the mold is easily damaged without a polishing protection device.

Disclosure of Invention

The invention provides precision die polishing equipment aiming at the technical problems, which comprises a transverse moving device, a translation device, a rotating device and an elastic polishing device.

The transverse moving device comprises a protection plate. The translation device comprises a sliding block, a fixed plate, a rack and a driven nut seat. The rotating device comprises a driven sliding block, a connecting plate, a nut seat fixing block and a lower side left driven shaft. The elastic polishing device comprises a connecting shaft.

Guard plate fixed mounting on PMKD, the slider have two respectively with the upper and lower both sides of guard plate form sliding fit, fixed plate fixed mounting on the slider, rack fixed mounting at the middle part of fixed plate, rack and last driven straight-teeth gear form gear engagement, driven slider and fixed plate form sliding fit, the connecting plate carry out fixed connection with driven slider, nut seat fixed block fixed mounting on the connecting plate, nut seat fixed block carry out fixed connection with driven nut seat, the left driven shaft of downside rotate and install in the right side below shaft hole of connecting plate, the one end of connecting axle rotate and install then the other end then carry out fixed connection with the left driven shaft of downside in the downside left side shaft hole of connecting plate.

The sideslip device still include work platform, PMKD, motor fixed plate, motor, worm, turbine driven shaft, turbine, lower driven spur gear, middle driven shaft, middle driven spur gear, middle driven helical gear, go up driven shaft, go up driven helical gear and last driven spur gear, PMKD fixed mounting on work platform, motor fixed plate fixed mounting on the guard plate, motor fixed mounting on the motor fixed plate, the worm rotate and install on the guard plate, worm and motor fixed connection, the turbine driven shaft rotate and install in the middle shaft hole of guard plate, the turbine rotate and install on the turbine driven shaft, turbine and worm form gear engagement, lower driven spur gear rotate and install on the turbine driven shaft and be located the left side of turbine, middle driven shaft rotate and install in the upside shaft hole of guard plate, the middle driven straight gear rotate and install on middle driven shaft, middle driven straight gear and driven straight gear form gear engagement down, middle driven helical gear rotate and install the right side that lies in middle driven straight gear on middle driven shaft, last driven shaft rotate and install in the upside shaft hole of guard plate, last driven helical gear rotate and install on last driven shaft, last driven straight gear rotate and install the top that lies in last driven helical gear on last driven shaft.

The translation device further comprises a lead screw and a servo motor, two ends of the lead screw are rotatably installed in shaft holes in the upper side and the lower side of the fixing plate, the servo motor is fixedly installed on the lower side of the fixing plate and fixedly connected with the lead screw, and the driven nut seat is rotatably installed on the lead screw.

The rotating device also comprises a stepping motor fixing plate, a stepping motor, a driving bevel gear, a left belt pulley driven shaft, a left driven bevel gear, a left belt pulley, a right belt pulley driven shaft, a right belt pulley, a belt, a lower driven bevel gear and a lower side left driven bevel gear, wherein the stepping motor fixing plate is fixedly arranged on a connecting plate, the stepping motor is fixedly arranged on the stepping motor fixing plate, the driving bevel gear is rotatably arranged on the stepping motor, the left belt pulley driven shaft is rotatably arranged in a left shaft hole of the connecting plate, the left driven bevel gear is rotatably arranged on the left belt pulley driven shaft, the left driven bevel gear is meshed with the driving bevel gear, the left belt pulley is rotatably arranged on the left belt pulley driven shaft and is positioned below the left driven bevel gear, the right belt pulley driven shaft is rotatably arranged in a right shaft hole of the connecting, the right belt pulley is rotatably arranged on a right belt pulley driven shaft, the lower driven helical gear is rotatably arranged on the right belt pulley driven shaft and is positioned below the right belt pulley, the lower left driven helical gear is rotatably arranged on the lower left driven shaft, and the lower left driven helical gear and the lower driven helical gear form gear engagement.

The elastic polishing device also comprises a first spring fixing plate, a first spring shaft, a first spring, a first elastic connecting plate, a second spring fixing plate, a second spring shaft, a second spring, a second elastic connecting plate, a connecting fixing plate, a side fixing plate, a fixing top plate, a high-speed motor fixing plate, a high-speed motor, a right driving helical gear, a high-speed driven shaft, a lower driven helical gear and a polishing grinding head connecting rod, wherein the first spring fixing plate is fixedly arranged on the connecting shaft, the first spring shaft is rotatably arranged on the first spring fixing plate, the first spring rotatably penetrates through the first spring shaft, one end of the first spring is fixedly connected with the first spring fixing plate on the right side, the first elastic connecting plate is rotatably arranged on the first spring shaft, and the first elastic connecting plate is fixedly connected with the left side of the first spring, the second spring fixing plate is fixedly arranged on the first elastic connecting plate, the second spring shaft is rotatably arranged on the second spring fixing plate, the second spring rotates to penetrate through the second spring shaft, one end of the second spring is fixedly connected with the upper side of the second spring fixing plate, the second elastic connecting plate is rotatably arranged on the second spring shaft, one end of the second elastic connecting plate is fixedly connected with the lower side of the second spring, the second elastic connecting plate and the second spring form spring fit, the connecting fixing plate is fixedly arranged on the lower surface of the second elastic connecting plate, the side fixing plate is fixedly arranged on the lower surface of the connecting fixing plate, the fixing top plate is fixedly connected with the side fixing plate, the high-speed motor fixing plate is fixedly arranged on the connecting fixing plate, and the high-speed motor is fixedly arranged on the high-speed motor fixing plate, the polishing grinding head comprises a right side driving helical gear, a high-speed driven shaft, a connecting fixing plate, a lower side driven helical gear, a polishing grinding head connecting rod and a polishing grinding head, wherein the right side driving helical gear is rotatably installed on the high-speed motor, the high-speed driven shaft is rotatably installed on the connecting fixing plate, the lower side driven helical gear is rotatably installed on the high-speed driven shaft, the lower side driven helical gear and the right side driving helical gear form gear engagement.

Furthermore, the upper driven helical gear and the middle driven helical gear form gear engagement.

Furthermore, the belt is in belt transmission fit with the right belt pulley and the left belt pulley.

Furthermore, the first elastic connecting plate and the first spring form spring fit.

Compared with the prior art, the invention has the beneficial effects that: (1) the invention can adapt to various precision molds, automatically polish the molds and save the cost. (2) The invention can axially rotate the polishing grinding head, has a great polishing angle and can improve the efficiency. (3) The invention can be provided with an elastic protection device, and can protect the die during polishing to prevent the die from being damaged.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

FIG. 2 is a schematic view of a traversing apparatus according to the present invention.

FIG. 3 is a schematic view of an internal assembly of the traverse device of the present invention.

FIG. 4 is a schematic view of the internal structure of the translation device according to the present invention.

Fig. 5 is a schematic view of the internal assembly of the rotating device of the present invention.

FIG. 6 is a schematic view of the internal assembly structure of the elastic polishing device of the present invention.

FIG. 7 is a schematic structural diagram of the elastic polishing apparatus of the present invention.

Reference numerals: 1-a traversing device; 2-a translation device; 3-a rotating device; 4-a resilient polishing means; 101-a working platform; 102-a fixed baseplate; 103-protective plate; 104-motor fixing plate; 105-an electric machine; 106-worm; 107-turbine driven shaft; 108-a turbine; 109-lower driven spur gear; 110-intermediate driven shaft; 111-intermediate driven spur gear; 112-intermediate driven bevel gear; 113-upper driven shaft; 114-an upper driven bevel gear; 115-upper driven spur gear; 201-a slide block; 202-a fixed plate; 203-a rack; 204-a lead screw; 205-a servo motor; 206-follower nut seat; 301-follower slider; 302-connecting plate; 303-nut seat fixing block; 304-a stepper motor fixing plate; 305-a stepper motor; 306-driving bevel gear; 307-left pulley driven shaft; 308-left driven bevel gear; 309-left belt pulley; 310-right pulley driven shaft; 311-right belt pulley; 312-a belt; 313-lower driven bevel gear; 314-lower left driven shaft; 315-lower left driven bevel gear; 401-a connecting shaft; 402-a first spring retainer plate; 403-a first spring shaft; 404-a first spring; 405-a first resilient connecting plate; 406-a second spring retainer plate; 407-a second spring shaft; 408-a second spring; 409-a second elastic connecting plate; 410-connecting the fixing plate; 411-side fixing plate; 412-fixed top plate; 413-high speed motor fixing plate; 414-high speed motor; 415-right drive bevel gear; 416-a high speed driven shaft; 417-lower driven bevel gear; 418-polishing grinding head connecting rod.

Detailed Description

The present invention will be further described with reference to specific examples, which are illustrative of the invention and are not to be construed as limiting the invention.

A precision mold polishing apparatus shown in fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7 includes a traverse device 1, a translation device 2, a rotation device 3, and a resilient polishing device 4. The traverse device 1 includes a shielding plate 103. The translation device 2 comprises a sliding block 201, a fixed plate 202, a rack 203 and a driven nut seat 206. The rotating device 3 comprises a driven slide block 301, a connecting plate 302, a nut seat fixing block 303 and a lower left driven shaft 314. The elastic polishing apparatus 4 includes a connection shaft 401.

Protection plate 103 fixed mounting is on PMKD 102, slider 201 has two to form sliding fit with the upper and lower both sides of protection plate 103 respectively, fixed plate 202 fixed mounting is on slider 201, rack 203 fixed mounting is at the middle part of fixed plate 202, rack 203 forms gear engagement with last driven spur gear 115, driven slider 301 forms sliding fit with fixed plate 202, connecting plate 302 carries out fixed connection with driven slider 301, nut seat fixed block 303 fixed mounting is on connecting plate 302, nut seat fixed block 303 carries out fixed connection with driven nut seat 206, downside left driven shaft 314 rotates and installs in the right side below shaft hole of connecting plate 302, the one end rotation of connecting axle 401 is installed in the downside left side shaft hole of connecting plate 302 then the other end then carries out fixed connection with downside left driven shaft 314.

The traverse device 1 further comprises a working platform 101, a fixed base plate 102, a motor fixing plate 104, a motor 105, a worm 106, a turbine driven shaft 107, a turbine 108, a lower driven spur gear 109, an intermediate driven shaft 110, an intermediate driven spur gear 111, an intermediate driven helical gear 112, an upper driven shaft 113, an upper driven helical gear 114 and an upper driven spur gear 115, wherein the fixed base plate 102 is fixedly arranged on the working platform 101, the motor fixing plate 104 is fixedly arranged on the protection plate 103, the motor 105 is fixedly arranged on the motor fixing plate 104, the worm 106 is rotatably arranged on the protection plate 103 and takes the motor 105 as a power source, when the motor 105 rotates, the worm 106 is driven to rotate, the worm 106 is fixedly connected with the motor 105, the turbine driven shaft 107 is rotatably arranged in an intermediate shaft hole of the protection plate 103, the turbine 108 is rotatably arranged on the turbine driven shaft 107, the turbine 108 and the worm 106 form gear meshing, the lower driven spur, when the worm 106 rotates, the worm gear 108 and a lower driven spur gear 109 synchronously connected with the worm gear are driven to rotate synchronously, an intermediate driven shaft 110 is rotatably arranged in an upper shaft hole of the protection plate 103, an intermediate driven spur gear 111 is rotatably installed on the intermediate driven shaft 110, the intermediate driven spur gear 111 forms a gear engagement with the lower driven spur gear 109, an intermediate driven helical gear 112 is rotatably installed on the intermediate driven shaft 110 on the right side of the intermediate driven spur gear 111, when the lower driven spur gear 109 rotates, the middle driven spur gear 111 and the middle driven bevel gear 112 synchronously connected with the middle driven spur gear are driven to synchronously rotate, the upper driven shaft 113 is rotatably installed in the upper shaft hole of the protection plate 103, an upper driven bevel gear 114 is rotatably mounted on the upper driven shaft 113, an upper driven spur gear 115 is rotatably mounted on the upper driven shaft 113 above the upper driven bevel gear 114, when the middle driven bevel gear 112 rotates, the upper driven bevel gear 114 and an upper driven spur gear 115 synchronously connected with the upper driven bevel gear are driven to synchronously drive.

The translation device 2 further comprises a screw 204 and a servo motor 205, the upper driven spur gear drives the rack 203 to move when the upper driven spur gear 115 rotates, two ends of the screw 204 are rotatably installed in shaft holes at the upper side and the lower side of the fixing plate 202, the servo motor 205 is fixedly installed at the lower side of the fixing plate 202, the servo motor 205 is fixedly connected with the screw 204, the driven nut seat 206 is rotatably installed on the screw 204, the servo motor 205 is a power source, and the screw 204 is driven to rotate to drive the driven nut seat 206 to move when the servo motor 205 rotates.

The rotating device 3 further comprises a stepping motor fixing plate 304, a stepping motor 305, a driving bevel gear 306, a left pulley driven shaft 307, a left driven bevel gear 308, a left pulley 309, a right pulley driven shaft 310, a right pulley 311, a belt 312, a lower driven bevel gear 313 and a lower left driven bevel gear 315, wherein the stepping motor fixing plate 304 is fixedly arranged on the connecting plate 302, the stepping motor 305 is fixedly arranged on the stepping motor fixing plate 304, the driving bevel gear 306 is rotatably arranged on the stepping motor 305, the stepping motor 305 is a power source, the driving bevel gear 306 is driven to rotate when the stepping motor 305 rotates, the left pulley driven shaft 307 is rotatably arranged in a left shaft hole of the connecting plate 302, the left driven bevel gear 308 is rotatably arranged on the left pulley driven shaft 307, the left driven bevel gear 308 is in gear engagement with the driving bevel gear 306, the left pulley 309 is rotatably arranged on the left pulley driven shaft 307, when the driving bevel gear 306 rotates, the left driven bevel gear 308 and the left belt pulley 309 synchronously connected with the driving bevel gear are driven to rotate, the right belt pulley driven shaft 310 is rotatably installed in a right shaft hole of the connecting plate 302, the right belt pulley 311 is rotatably installed on the right belt pulley driven shaft 310, the lower driven bevel gear 313 is rotatably installed on the right belt pulley driven shaft 310 and is positioned below the right belt pulley 311, when the left belt pulley 309 rotates, the right belt pulley 311 and the lower driven bevel gear 313 synchronously connected with the left belt pulley 311 are driven to rotate through a belt 312, the lower left driven bevel gear 315 is rotatably installed on the lower left driven shaft 314, the lower left driven bevel gear 315 and the lower driven bevel gear 313 form gear engagement, and when the lower driven bevel gear 313 rotates, the lower left driven.

The elastic polishing device 4 further comprises a first spring fixing plate 402, a first spring shaft 403, a first spring 404, a first elastic connecting plate 405, a second spring fixing plate 406, a second spring shaft 407, a second spring 408, a second elastic connecting plate 409, a connecting fixing plate 410, a side fixing plate 411, a fixing top plate 412, a high-speed motor fixing plate 413, a high-speed motor 414, a right driving helical gear 415, a high-speed driven shaft 416, a lower driven helical gear 417 and a polishing grinding head connecting rod 418, wherein the first spring fixing plate 402 is fixedly arranged on the connecting shaft 401, the first spring shaft 403 is rotatably arranged on the first spring fixing plate 402, the first spring 404 is rotatably penetrated through the first spring shaft, one end of the first spring 404 is fixedly connected with the first spring fixing plate 402 on the right side, the first elastic connecting plate 405 is rotatably arranged on the first spring shaft 403, the first elastic connecting plate 405 is fixedly connected with the left side of the first spring 404, a second spring fixing plate 406 is fixedly installed on the first spring fixing plate 405, a second spring shaft 407 is rotatably installed on the second spring fixing plate 406, a second spring 408 is rotatably inserted through the second spring shaft 407, one end of the second spring 408 is fixedly connected with the upper side of the second spring fixing plate 406, a second spring connecting plate 409 is rotatably installed on the second spring shaft 407, one end of the second spring connecting plate 409 is fixedly connected with the lower side of the second spring 408, the second spring connecting plate 409 forms a spring fit with the second spring 408, a connecting fixing plate 410 is fixedly installed on the lower surface of the second spring connecting plate 409, a side fixing plate 411 is fixedly installed on the lower surface of the connecting fixing plate 410, a fixing top plate 412 is fixedly connected with the side fixing plate 411, a high-speed motor fixing plate 413 is fixedly installed on the connecting fixing plate 410, and a high-speed motor 414 is fixedly installed on the high-speed motor fixing plate, the high-speed motor 414 is a power source, when the high-speed motor 414 rotates, the right driving helical gear 415 is rotatably installed on the high-speed motor 414, the high-speed driven shaft 416 is rotatably installed on the connecting fixing plate 410, the lower driven helical gear 417 is rotatably installed on the high-speed driven shaft 416, the lower driven helical gear 417 and the right driving helical gear 415 form gear engagement, the polishing grinding head connecting rod 418 is fixedly installed at the upper end of the high-speed driven shaft 416, and when the right driving helical gear 415 rotates, the lower driven helical gear 417 and the polishing grinding head connecting rod 418 synchronously connected with the lower driven helical gear 417.

The upper driven helical gear 114 forms a gear mesh with the intermediate driven helical gear 112. Belt 312 is in belt driving engagement with right pulley 311 and left pulley 309. The first resilient connecting plate 405 forms a spring fit with the first spring 404.

Claims

1. The utility model provides a precision mold polishing equipment, includes sideslip device (1), translation device (2), rotary device (3) and elasticity burnishing device (4), its characterized in that:

the transverse moving device (1) comprises a protection plate (103);

the translation device (2) comprises a sliding block (201), a fixed plate (202), a rack (203) and a driven nut seat (206);

the rotating device (3) comprises a driven sliding block (301), a connecting plate (302), a nut seat fixing block (303) and a lower left driven shaft (314);

the elastic polishing device (4) comprises a connecting shaft (401);

protection plate (103) fixed mounting on PMKD (102), slider (201) have two respectively and form sliding fit with the upper and lower both sides of protection plate (103), fixed plate (202) fixed mounting on slider (201), rack (203) fixed mounting at the middle part of fixed plate (202), rack (203) and last driven spur gear (115) form gear engagement, driven slider 301 and fixed plate (202) form sliding fit, connecting plate (302) and driven slider (301) carry out fixed connection, nut seat fixed block (303) fixed mounting on connecting plate (302), nut seat fixed block (303) and driven nut seat (206) carry out fixed connection, downside left driven shaft (314) rotate and install in the right side below shaft hole of connecting plate (302), the one end of connecting shaft (401) rotate and install then another in the left side shaft hole of connecting plate (302) another The end is fixedly connected with a lower left driven shaft (314).

2. A precision mold polishing apparatus as set forth in claim 1, wherein: the transverse moving device (1) further comprises a working platform 101, a fixed base plate (102), a motor fixing plate (104), a motor (105), a worm (106), a turbine driven shaft (107), a turbine (108), a lower driven spur gear (109), an intermediate driven shaft (110), an intermediate driven spur gear (111), an intermediate driven helical gear (112), an upper driven shaft (113), an upper driven helical gear (114) and an upper driven spur gear (115), wherein the fixed base plate (102) is fixedly arranged on the working platform (101), the motor fixing plate (104) is fixedly arranged on a protection plate (103), the motor (105) is fixedly arranged on the motor fixing plate (104), the worm (106) is rotatably arranged on the protection plate (103), the worm (106) is fixedly connected with the motor (105), the turbine driven shaft (107) is rotatably arranged in an intermediate shaft hole of the protection plate (103), turbine (108) rotate and install on turbine driven shaft (107), turbine (108) and worm (106) form gear engagement, lower driven spur gear (109) rotate and install the left side that lies in turbine (108) on turbine driven shaft (107), middle driven shaft (110) rotate and install in the upside shaft hole of guard plate (103), middle driven spur gear (111) rotate and install on middle driven shaft (110), middle driven spur gear (111) and lower driven spur gear (109) form gear engagement, middle driven helical gear (112) rotate and install the right side that lies in middle driven spur gear (111) on middle driven shaft (110), last driven shaft (113) rotate and install in the upside shaft hole of guard plate (103), last driven helical gear (114) rotate and install on last driven shaft (113), the upper driven spur gear (115) is rotatably arranged on the upper driven shaft (113) and is positioned above the upper driven bevel gear (114).

3. A precision mold polishing apparatus as set forth in claim 1, wherein: the translation device (2) further comprises a lead screw (204) and a servo motor (205), two ends of the lead screw (204) are rotatably installed in shaft holes at the upper side and the lower side of the fixing plate (202), the servo motor (205) is fixedly installed at the lower side of the fixing plate (202), the servo motor (205) is fixedly connected with the lead screw (204), and the driven nut seat (206) is rotatably installed on the lead screw (204).

4. A precision mold polishing apparatus as set forth in claim 1, wherein: the rotating device (3) further comprises a stepping motor fixing plate (304), a stepping motor (305), a driving bevel gear (306), a left belt pulley driven shaft (307), a left driven bevel gear (308), a left belt pulley (309), a right belt pulley driven shaft (310), a right belt pulley (311), a belt (312), a lower driven bevel gear (313) and a lower side left driven bevel gear (315), wherein the stepping motor fixing plate (304) is fixedly arranged on the connecting plate (302), the stepping motor (305) is fixedly arranged on the stepping motor fixing plate (304), the driving bevel gear (306) is rotatably arranged on the stepping motor (305), the left belt pulley driven shaft (307) is rotatably arranged in a left shaft hole of the connecting plate (302), the left driven bevel gear (308) is rotatably arranged on the left belt pulley driven shaft (307), and the left driven bevel gear (308) is in gear engagement with the driving bevel gear (306), left belt pulley (309) rotate and install the below that is located left driven helical gear (308) on left belt pulley driven shaft (307), right belt pulley driven shaft (310) rotate and install in the right side shaft hole of connecting plate (302), right belt pulley (311) rotate and install on right belt pulley driven shaft (310), lower driven helical gear (313) rotate and install the below that is located right belt pulley (311) on right belt pulley driven shaft (310), downside left driven helical gear (315) rotate and install on downside left driven shaft (314), downside left driven helical gear (315) and lower driven helical gear (313) form gear engagement.

5. A precision mold polishing apparatus as set forth in claim 1, wherein: the elastic polishing device (4) further comprises a first spring fixing plate (402), a first spring shaft (403), a first spring (404), a first elastic connecting plate (405), a second spring fixing plate (406), a second spring shaft (407), a second spring (408), a second elastic connecting plate (409), a connecting fixing plate (410), a side fixing plate (411), a fixing top plate (412), a high-speed motor fixing plate (413), a high-speed motor (414), a right-side driving helical gear (415), a high-speed driven shaft (416), a lower-side driven helical gear (417) and a polishing grinding head connecting rod (418), wherein the first spring fixing plate (402) is fixedly installed on the connecting shaft (401), the first spring shaft (403) is rotatably installed on the first spring fixing plate (402), the first spring (404) is rotatably penetrated through the first spring shaft (403), and one end of the first spring (404) is fixedly connected with the first spring fixing plate (402) on the right side The first elastic connecting plate (405) is rotatably installed on a first spring shaft (403), the first elastic connecting plate (405) is fixedly connected with the left side of a first spring (404), the second spring fixing plate (406) is fixedly installed on the first elastic connecting plate (405), the second spring shaft (407) is rotatably installed on the second spring fixing plate (406), the second spring (408) is rotatably arranged on the second spring shaft (407), one end of the second spring (408) is fixedly connected with the upper side of the second spring fixing plate (406), the second elastic connecting plate (409) is rotatably installed on the second spring shaft (407), one end of the second elastic connecting plate (409) is fixedly connected with the lower side of the second spring (408), and the second elastic connecting plate (409) and the second spring (408) form a spring fit, the connecting fixing plate (410) is fixedly arranged on the lower surface of the second elastic connecting plate (409), the side fixing plate (411) is fixedly arranged on the lower surface of the connecting fixing plate (410), the fixed top plate (412) is fixedly connected with the side fixed plate (411), the high-speed motor fixed plate (413) is fixedly arranged on the connecting fixed plate (410), the high-speed motor (414) is fixedly arranged on the high-speed motor fixing plate (413), the right driving bevel gear (415) is rotationally arranged on a high-speed motor (414), the high-speed driven shaft (416) is rotatably arranged on the connecting fixing plate (410), the lower driven bevel gear (417) is rotatably arranged on a high-speed driven shaft (416), the lower driven bevel gear (417) and the right driving bevel gear (415) form gear engagement, and the polishing grinding head connecting rod (418) is fixedly arranged at the upper end of the high-speed driven shaft (416).

6. A precision mold polishing apparatus as set forth in claim 1, wherein: the upper driven bevel gear (114) and the middle driven bevel gear (112) form gear engagement.

7. A precision mold polishing apparatus as set forth in claim 1, wherein: the belt (312) is in belt transmission fit with the right belt pulley (311) and the left belt pulley (309).

8. A precision mold polishing apparatus as set forth in claim 1, wherein: the first elastic connecting plate (405) and the first spring (44) form spring fit.