CN111890439A

CN111890439A - Numerical control machine tool for shaping and cutting epoxy resin glass fiber plate

Info

Publication number: CN111890439A
Application number: CN202010787418.7A
Authority: CN
Inventors: 鲍宪丽; 廉静
Original assignee: Guangzhou Lixin Intelligent Technology Co ltd
Current assignee: Guangzhou Lixin Intelligent Technology Co ltd
Priority date: 2020-08-07
Filing date: 2020-08-07
Publication date: 2020-11-06

Abstract

The invention relates to a numerical control machine tool for shaping, cutting and processing an epoxy resin glass fiber plate, which comprises a workbench, a transmission device and a collection device, the workbench is placed on the ground, the transmission devices are arranged on the front side and the rear side of the workbench, the collecting devices are arranged on the left side and the right side of the workbench, the workbench comprises a square block, a rectangular long plate, a circular plate, a rotating shaft, a poking long rod, a first motor, a rotating frame, a rectangular plate and a fixing frame, the collecting device comprises a telescopic support rod, a square long plate, an isolating block, rectangular teeth, a tooth claw, a ratchet wheel and a fourth motor, the invention provides a numerical control machine tool for shaping, cutting and processing an epoxy resin glass fiber plate, through the matching of the workbench, the transmission device and the collecting device, the cutting machine can realize cutting after transportation, and can cut a plurality of glass fiber boards simultaneously, improve glass fiber board cutting machine's work efficiency greatly.

Description

Numerical control machine tool for shaping and cutting epoxy resin glass fiber plate

Technical Field

The invention relates to the field of glass fiber board processing, in particular to a numerical control machine tool for shaping and cutting an epoxy resin glass fiber board.

Background

The glass fiber board is also called glass fiber composite board, is synthesized by glass fiber material and high heat resistance composite material, and does not contain asbestos component harmful to human body. Has high mechanical performance, dielectric performance, heat resistance, moisture resistance and good processability. The plastic mold is used for plastic molds, injection molds, machine manufacturing, forming machines, drilling machines, injection molding machines, motors and the like. Injection molding typically requires a high temperature material and a low temperature mold. In the same machine condition, a heat insulation method must be adopted. The injection temperature is kept low while the temperature of the injection molding machine cannot be too high. This requirement is met by installing an insulating panel between the injection mold and the injection molding machine. The production period is shortened, the productivity is improved, the energy consumption is reduced, the quality of finished products is improved, the continuous production process ensures the stable quality of the products, the machines are prevented from being overheated, no electric appliance fails, and a hydraulic system has no oil leakage. The glass fiber board is generally used for soft package base layers, and is coated with cloth art, leather and the like to make attractive wall surfaces and ceiling decorations. The application is very wide. Has the characteristics of sound absorption, sound insulation, heat insulation, environmental protection, flame retardance and the like.

In the process of cutting the glass fiber board, due to the limitation of the glass fiber board structure, the following problems exist in the actual operation process:

(1) traditional glass fiber board cuts machinery is carrying out the in-process that cuts to glass fiber board, does not transport the cutting, and can not cut to a plurality of glass fiber boards simultaneously, greatly reduced the work efficiency who cuts.

(2) When traditional glass fiber board cutting machine is cutting the glass fiber board, because the structure restriction of glass fiber board makes machinery can not be quick, convenient fixes the glass fiber board, leads to reducing the efficiency of cutting machine at the during operation.

Disclosure of Invention

In order to make up the defects of the prior art, the invention provides a numerical control machine tool for shaping and cutting an epoxy resin glass fiber plate.

The technical scheme adopted by the invention to solve the technical problem is as follows: the utility model provides an epoxy glass fiber board design cuts processing and uses digit control machine tool, includes workstation, transmission and collection device, the workstation is placed subaerial, and both sides are provided with transmission around the workstation, and the workstation left and right sides is provided with collection device, wherein:

the workbench comprises a square block, a rectangular long plate, a circular plate, a rotating shaft, a poking long rod, a first motor, a rotating frame, a rectangular plate and a fixing frame, wherein the square block is placed on the ground, the rectangular long plate is fixedly arranged at the upper end of the square block, four first arc grooves are uniformly formed in the upper end of the rectangular long plate, the circular plate is arranged in the first arc groove, the rotating shaft is fixedly arranged on the lower end face of the circular plate and penetrates through the rectangular long plate, the poking long rod is uniformly arranged at the lower end of the rotating shaft along the circumferential direction, a second arc groove is formed in the middle of the rectangular long plate, the first motor is fixedly arranged at the lower end of the middle of the rectangular long plate through a motor base, the rotating frame is arranged on an output shaft at the upper end of the first; the rectangular long plate is fixed through the square block, the round plate is limited through the rectangular long plate, the rotating shaft is fixed through the round plate, the stirring long rod is fixed through the rotating shaft, the first motor is fixed through the rectangular long plate, the rectangular plate is fixed through the rectangular long plate, and when the first motor is started, the first motor drives the rotating frame to move, so that the glass fiber plate is cut;

the transmission device comprises a rectangular long block, a fixed block, a second motor and a first rotating roller, the glass fiber plate glass fiber; the rectangular long block is fixed through the rectangular long plate, the fixed block is fixed through the rectangular long block, the motor II is fixed through the fixed block, the motor III is fixed simultaneously, the rotating roller I is positioned between the rear end of the rectangular long plate and the fixed block, the rotating roller II is positioned between the front end of the rectangular long plate and the fixed block, the electric push rod I is fixed through the fixed block, the electric push rod II is fixed, when the motor II moves, the motor II drives the rotating roller I to move forwards, when the motor III moves, the motor III drives the rotating roller II to move forwards, when the wave fiber plate moves to the position of the electric push rod I, the electric push rod I pushes the glass fiber plate to move the glass fiber plate to the circular plate, and when the glass fiber plate moves to the position of the electric push rod II, the electric push rod II pushes the glass fiber plate, moving the glass fiber sheet onto the circular plate;

as a preferred technical scheme of the invention, the collecting device comprises a telescopic support rod, a square long plate, an isolation block, rectangular teeth, tooth claws, a ratchet wheel and a fourth motor, wherein the telescopic support rod is symmetrically arranged on the left side and the right side of the workbench, the square long plate is fixedly installed at the tail end of the upper side of the telescopic support rod, the isolation block is uniformly and fixedly installed on the upper end surface of the square long plate relative to the position of the glass fiber plate, the rectangular teeth are uniformly arranged on the inner side of the upper end of the telescopic support rod, the rectangular teeth are connected with the tooth claws in a sliding fit manner, the tooth claws are fixedly installed on the ratchet wheel, and the fourth motor is fixedly installed on the; the square long plate is fixed through the telescopic support rod, the rectangular teeth are limited through the telescopic support rod, the isolation block is fixed through the square long plate, the fourth motor is fixed through the square block, the ratchet wheel is fixed through the fourth motor, the tooth claw is fixed through the ratchet wheel, when the cut glass fiber plate moves onto the square long plate, the ratchet wheel drives the tooth claw, the tooth claw drives the rectangular teeth, meanwhile, the rectangular teeth drive the telescopic support rod to move downwards, so that the height of the square long plate is consistent with that of the rectangular long plate, and the cut glass fiber plate is stacked;

according to a preferred technical scheme, the rotating frame comprises a cylindrical shaft, a poking rod, a circular block, a circular ring block, a support rod, a circular arc cutter holder and a circular arc cutter blade, wherein the cylindrical shaft is mounted on an output shaft at the upper end of a first motor through a coupler, the circular ring block is fixedly mounted at the upper end of the cylindrical shaft, the poking rod is uniformly arranged at the lower end of the cylindrical shaft along the circumferential direction, the poking rod and the fluctuation long rod are staggered, the circular ring block is sleeved outside the circular block, a rectangular groove is formed in the inner part of the circular ring block along the circumferential direction, the support rod is fixedly mounted in the rectangular groove, the other end of the support rod is uniformly and fixedly mounted on the circular block, the circular arc cutter holder which is staggered with the poking rod is uniformly and fixedly; when an angle is cut, a poking rod at the lower end of the cylindrical shaft and the arc tool apron are staggered to simultaneously move a poking long rod, a fluctuation long rod drives a rotating shaft to simultaneously drive a circular block to move, and thus, the glass fiber board is subjected to angle changing cutting;

according to a preferred technical scheme, the fixing frame comprises a square plate, a third electric push rod, a connecting rod and a bidirectional electric push rod, the square plate is fixedly installed on the upper side of the rectangular plate, the third electric push rod is uniformly and fixedly installed on the lower end face of the square plate, the connecting rods are symmetrically and fixedly installed on the front inner side and the rear inner side of the square plate, and the bidirectional electric push rod is fixedly installed at the tail end of the lower side of the connecting rod; the square plate is fixed through the rectangular long plate, the third electric push rod piece is fixed through the square plate, the connecting rod moves simultaneously, the bidirectional electric push rod is fixed through the connecting rod, when the glass fiber plate is placed on the circular block to be cut, the third electric push rod moves downwards, so that the glass fiber plate to be cut is fixed, and after the cutting is finished, the bidirectional electric push rods symmetrically and fixedly installed on the front inner side and the rear inner side of the square plate push the cut glass fiber plate to move left and right to enable the cut glass fiber plate to move to the square long plate;

according to a preferable technical scheme, a large arc groove is formed in the middle of the rectangular long plate, and the diameter of the large arc groove is larger than that of a circle cut by the arc blade; when the arc-shaped blade cuts, the arc-shaped blade can extend into the large arc groove, so that the glass fiber plate is completely cut;

as a preferred technical scheme of the invention, the tail ends of two sides of the bidirectional electric push rod are fixedly provided with rubber blocks; through the rubber block that sets up, when making two-way electric putter promote the glass fiber board that the cutting is good, be unlikely to make and dial fiber board surface wear.

Compared with the prior art, the invention has the following advantages:

1. according to the numerical control machine tool for shaping, cutting and processing the epoxy resin glass fiber board, the cutting machine can cut after transportation through the cooperation of the workbench, the transmission device and the collecting device, and can simultaneously cut a plurality of glass fiber boards, so that the working efficiency of the glass fiber board cutting machine is greatly improved.

2. According to the invention, through the arranged workbench and the arranged rotating frame, when the first motor is started, the first motor drives the cylindrical shaft, the cylindrical shaft drives the circular ring block, the circular arc blade holder drives the circular arc blade to move, so that the fiber shifting plate is cut, when a corner is cut, the shifting rod at the lower end of the cylindrical shaft and the circular arc blade holder are staggered, the shifting rod simultaneously drives the shifting long rod to move, and the fluctuating long rod drives the rotating shaft to simultaneously drive the circular block to move, so that the corner-changing cutting is carried out on the glass fiber plate.

3. According to the invention, through the arranged collecting device, the telescopic support rod is used for fixing the square long plate, the square long plate is used for fixing the isolation block, meanwhile, the square block is used for fixing the fourth motor, the ratchet wheel is fixed through the fourth motor, and the tooth claw is fixed through the ratchet wheel.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic structural view of the front view of the present invention;

FIG. 3 is a schematic top view of the present invention;

FIG. 4 is a schematic structural diagram of the present invention viewed from the right;

FIG. 5 is a cross-sectional view taken along line A-A of FIG. 2 in accordance with the present invention;

FIG. 6 is a cross-sectional view taken along line B-B of FIG. 4 in accordance with the present invention;

fig. 7 is a schematic view of the inclined blade of the present invention after cutting is complete.

Detailed Description

In order to make the technical means, the creation features, the achievement purposes and the effects of the invention easy to understand, the invention is further explained with reference to fig. 1 to 7.

The utility model provides an epoxy glass fiber board design cuts processing and uses digit control machine tool, includes workstation 1, transmission 2 and collection device 3, workstation 1 is placed subaerial, and both sides are provided with transmission 2 around the workstation 1, and the 1 left and right sides of workstation is provided with collection device 3, wherein:

the workbench 1 comprises a square block 11, a rectangular long plate 12, a circular plate 13, a rotating shaft 14, a poking long rod 15, a first motor 16, a rotating frame 17, a rectangular plate 18 and a fixing frame 19, wherein the square block 11 is placed on the ground, the rectangular long plate 12 is fixedly installed at the upper end of the square block 11, a large arc groove is formed in the middle of the rectangular long plate 12, and the diameter of the large arc groove is larger than that of a circle cut by an arc blade 177; the diameter of the large arc groove is larger than that of the arc blade 177, so that the arc blade 177 can extend into the large arc groove when the arc blade cuts, and the glass fiber plate is cut comprehensively; four first arc grooves are uniformly formed in the upper end of the rectangular long plate 12, a circular plate 13 is arranged in each first arc groove, a rotating shaft 14 is fixedly mounted on the lower end face of each circular plate 13, the rotating shaft 14 penetrates through the rectangular long plate 12, long toggle rods 15 are uniformly arranged at the lower end of the rotating shaft 14 along the circumferential direction, a second circular groove is formed in the middle of the rectangular long plate 12, a first motor 16 is fixedly mounted at the lower end of the middle of the rectangular long plate 12 through a motor base, a rotating frame 17 is mounted at the upper end output shaft of the first motor 16 through a coupler, rectangular plates 18 are symmetrically and fixedly mounted on the left side and the right side of the upper end of the rectangular long plate;

the rectangular long plate 12 is fixed through the square block 11, the round plate 13 is limited through the rectangular long plate 12, the rotating shaft 14 is fixed through the round plate 13, the toggle long rod 15 is fixed through the rotating shaft 14, the first motor 16 is fixed through the rectangular long plate 12, the rectangular plate 18 is fixed through the rectangular long plate 12, and when the first motor 16 is started, the first motor 16 drives the rotating frame 17 to move, so that the glass fiber plate is cut;

the rotating frame 17 comprises a cylindrical shaft 171, a poke rod 172, a circular block 173, a circular ring block 174, a support rod 175, a circular arc tool apron 176 and a circular arc blade 177, the cylindrical shaft 171 is mounted on an output shaft at the upper end of the first motor 16 through a coupler, the circular ring block 174 is fixedly mounted at the upper end of the cylindrical shaft 171, the poke rod 172 is uniformly arranged at the lower end of the cylindrical shaft 171 along the circumferential direction, the poke rod 172 and the long fluctuating rod are staggered, the circular ring block 174 is sleeved outside the circular block 173, a rectangular groove is formed in the circular ring block 174 along the circumferential direction, the support rod 175 is fixedly mounted in the rectangular groove, the other end of the support rod 175 is uniformly and fixedly mounted on the circular block 173, the circular arc tool apron 176 staggered with the poke rod 172 is uniformly and fixedly mounted at the lower end of the circular arc tool;

the first motor 16 is fixed through the rectangular long plate 12, the first motor 16 is used for fixing the cylindrical shaft 171, the circular ring block 174 is fixed through the cylindrical shaft 171, the support rod 175 is fixed through the circular ring block 174, the circular arc tool apron 176 is fixed through the circular ring block 174, the circular arc blade 177 is fixed through the circular arc tool apron 176, when the first motor 16 is started, the first motor 16 drives the cylindrical shaft 171, the cylindrical shaft 171 drives the circular ring block 174, the circular ring block 174 drives the circular arc tool apron 176, the circular arc tool apron 176 drives the circular arc blade 177 to move, so that the fiber shifting plate is cut, when one corner is cut, the shifting rod 172, which is staggered between the lower end of the cylindrical shaft 171 and the circular arc tool apron 176, simultaneously shifts the long rod 15, the fluctuating long rod drives the rotating shaft 14 and simultaneously drives the circular block 173 to move, so that the glass fiber plate is subjected to corner changing cutting;

the fixed frame 19 comprises a square plate 191, a third electric push rod 192, a connecting rod 193 and a bidirectional electric push rod 194, the square plate 191 is fixedly installed on the upper side of the rectangular plate 18, the third electric push rod 192 is uniformly and fixedly installed on the lower end face of the square plate 191, and rubber blocks are fixedly installed at the tail ends of two sides of the bidirectional electric push rod 194; through the arranged rubber block, when the bidirectional electric push rod 194 pushes the cut glass fiber plate, the surface of the fiber pulling plate is not abraded; the front inner side and the rear inner side of the square plate 191 are symmetrically and fixedly provided with connecting rods 193, and the tail ends of the lower sides of the connecting rods 193 are fixedly provided with bidirectional electric push rods 194;

fix the square plate 191 through rectangular long plate 12, fix No. three electric putter 192 pieces through square plate 191, move connecting rod 193 simultaneously, fix two-way electric putter 194 through connecting rod 193, when the glass fiber board is placed and is cut on circular block 173, No. three electric putter 192 downward displacement, thereby fix the glass fiber board that will cut, after the cutting is accomplished, the two-way electric putter 194 of inboard symmetry fixed mounting around the square plate 191 promotes the glass fiber board that cuts and controls the displacement and make the glass fiber board that cuts move to square long plate 32 on.

The transmission device 2 comprises a rectangular long block 21, a fixed block 22, a second motor 23, a first rotating roller 24, a third motor 25, a second rotating roller 26, a first electric push rod 27 and a second electric push rod 28, the rectangular long block 12 is symmetrically and fixedly provided with the rectangular long block 21 at the front side and the rear side, the fixed block 22 is fixedly provided at the front outer side and the rear outer side of the rectangular long block 21, the second motor 23 is fixedly provided at the rear end of the left side of the front fixed block 22 through a motor base, the first rotating roller 24 is provided at the front end output shaft of the second motor 23 through a coupler, the third motor 25 is fixedly provided at the front end of the left side of the rear fixed block 22 through a motor base, the second rotating roller 26 is provided at the rear end of the third motor 25 through a coupler, the first electric push rods 27 are uniformly arranged at the upper end of the inner side of the front glass rectangular plate 18 relative to the position of the fiber plate, the, the first electric push rod 27 and the second electric push rod 28 are respectively positioned in the middle of the rotating frame 17;

the rectangular long block 21 is fixed through the rectangular long plate 12, the fixed block 22 is fixed through the rectangular long block 21, the second motor 23 is fixed through the fixed block 22, the third motor 25 is fixed at the same time, the first rotating roller 24 is positioned between the rear end of the rectangular long plate 12 and the fixed block 22, the second rotating roller 26 is positioned between the front end of the rectangular long plate 12 and the fixed block 22, the first electric push rod 27 is fixed through the fixed block 22, and the second electric push rod 28 is fixed, when the second motor 23 moves, the second motor 23 drives the first rotating roller 24 to move forwards, when the third motor 25 moves, the third motor 25 drives the second rotating roller 26 to move forwards, when the fiber board moves to the position of the first electric push rod 27, the first electric push rod 27 pushes the fiber board to move the fiber board to the circular plate 13, and when the fiber board moves to the position of the second electric push rod 28, the second electric push rod 28 pushes the glass fiber plate, so that the glass fiber plate also moves to the circular plate 13.

The collecting device 3 comprises a telescopic support rod 31, a square long plate 32, an isolation block 33, rectangular teeth 34, tooth claws 35, a ratchet wheel 36 and a fourth motor 37, wherein the telescopic support rods 31 are symmetrically arranged on the left side and the right side of the workbench 1, the square long plate 32 is fixedly installed at the tail end of the upper side of the telescopic support rod 31, the isolation block 33 is uniformly and fixedly installed on the upper end surface of the square long plate 32 relative to the position of a glass fiber plate, the rectangular teeth 34 are uniformly arranged on the inner side of the upper end of the telescopic support rod 31, the rectangular teeth 34 are connected with the tooth claws 35 in a sliding fit mode, the tooth claws 35 are fixedly installed on the ratchet wheel 36, and the fourth motor 37 is fixedly installed on;

the rectangular long plate 32 is fixed through the telescopic support rod 31, the rectangular teeth 34 are limited through the telescopic support rod 31, the isolation block 33 is fixed through the rectangular long plate 32, the fourth motor 37 is fixed through the rectangular block 11, the ratchet 36 is fixed through the fourth motor 37, the pawl 35 is fixed through the ratchet 36, when the cut glass fiber plate moves to the rectangular long plate 32, the ratchet 36 drives the pawl 35, the pawl 35 drives the rectangular teeth 34, meanwhile, the rectangular teeth 34 drives the telescopic support rod 31 to move downwards, the height of the rectangular long plate 32 is consistent with that of the rectangular long plate 12, and therefore the cut glass fiber plate is stacked.

When the glass fiber plate cutting machine works, firstly, a square glass fiber plate is placed on a first rotating roller 24 and a second rotating roller 26, a second motor 23 and a third motor 25 are started to transport the glass fiber plate, when the glass fiber plate moves to a first electric push rod 27 position, a first electric push rod 27 pushes the glass fiber plate to enable the glass fiber plate to move to a circular plate 13, meanwhile, when the glass fiber plate moves to a second electric push rod 28 position, a second electric push rod 28 pushes the glass fiber plate to enable the glass fiber plate to move to the circular plate 13, at the moment, a third electric push rod 192 moves downwards to fix the glass fiber plate to be cut, after the fixation is finished, a first motor 16 is started, a first motor 16 drives a cylindrical shaft 171, a circular ring block 174 drives a circular arc blade 177 to move to cut the fiber shifting plate, when one corner is cut, a shifting rod 172 which is staggered with the lower end of the cylindrical shaft 171 and a circular arc cutter seat 176 simultaneously shifts a long rod 15, the long fluctuating rod drives the rotating shaft 14 to simultaneously drive the circular block 173 to move, so that the glass fiber plate is subjected to corner changing cutting, after the cutting is completed, the two-way electric push rod 194 mounted on the square plate 191 pushes the cut glass fiber plate to move left and right to enable the cut glass fiber plate to move to the square long plate 32, the fourth motor 37 is started, the fourth motor 37 drives the ratchet wheel 36, the ratchet wheel 36 drives the tooth claw 35, the tooth claw 35 drives the rectangular teeth 34 to move downwards, meanwhile, the telescopic support rod 31 is driven to move downwards, the height of the square long plate 32 is consistent with the height of the rectangular long plate 12, and therefore the cut glass fiber plate is stacked.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are given by way of illustration of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides an epoxy glass fiber board design cuts processing and uses digit control machine tool, includes workstation (1), transmission (2) and collection device (3), its characterized in that: workstation (1) is placed subaerial, and both sides are provided with transmission (2) around workstation (1), and workstation (1) left and right sides is provided with collection device (3), wherein:

the workbench (1) comprises a square block (11), a rectangular long plate (12), a circular plate (13), a rotating shaft (14), a poking long rod (15), a first motor (16), a rotating frame (17), a rectangular plate (18) and a fixing frame (19), wherein the square block (11) is placed on the ground, the rectangular long plate (12) is fixedly installed at the upper end of the square block (11), four first arc grooves are uniformly formed in the upper end of the rectangular long plate (12), the circular plate (13) is arranged in the first arc groove, the rotating shaft (14) is fixedly installed on the lower end face of the circular plate (13), the rotating shaft (14) penetrates through the rectangular long plate (12), the poking long rod (15) is uniformly arranged at the lower end of the rotating shaft (14) along the circumferential direction, a second circular groove is formed in the middle of the rectangular long plate (12), the first motor (16) is fixedly installed at the, an output shaft at the upper end of the first motor (16) is provided with a rotating frame (17) through a coupler, the left side and the right side of the upper end of the rectangular long plate (12) are symmetrically and fixedly provided with rectangular plates (18), and the upper side of each rectangular plate (18) is provided with a fixed frame (19);

the transmission device (2) comprises a rectangular long block (21), a fixing block (22), a second motor (23), a first rotating roller (24), a third motor (25), a second rotating roller (26), a first electric push rod (27) and a second electric push rod (28), the rectangular long block (21) is symmetrically and fixedly installed on the front side and the rear side of the rectangular long plate (12), the fixing block (22) is fixedly installed on the front outer side and the rear outer side of the rectangular long block (21), the second motor (23) is fixedly installed at the rear end of the left side of the front side fixing block (22) through a motor base, the first rotating roller (24) is installed at the front end output shaft of the second motor (23) through a coupler, the third motor (25) is fixedly installed at the front end of the left side of the rear side fixing block (22) through a motor base, the second rotating roller (26) is installed at the rear end output shaft of the third motor (25) through a coupler, the first electric push rod (27) is uniformly, the upper end of the inner side of the rear side rectangular plate (18) is evenly provided with a second electric push rod (28) relative to the position of the glass fiber plate, and the first electric push rod (27) and the second electric push rod (28) are respectively positioned in the middle of the rotating frame (17).

2. The numerical control machine tool for sizing and cutting of the epoxy resin glass fiber plate as claimed in claim 1, is characterized in that: the collecting device (3) comprises a telescopic support rod (31), a square long plate (32), an isolation block (33), rectangular teeth (34), tooth claws (35), a ratchet wheel (36) and a fourth motor (37), wherein the telescopic support rod (31) is symmetrically arranged on the left side and the right side of the workbench (1), the square long plate (32) is fixedly mounted at the tail end of the upper side of the telescopic support rod (31), the isolation block (33) is uniformly and fixedly mounted on the upper end face of the square long plate (32) relative to the position of a glass fiber plate, the rectangular teeth (34) are uniformly arranged on the inner side of the upper end of the telescopic support rod (31), the rectangular teeth (34) are connected with the tooth claws (35) in a sliding fit mode, the tooth claws (35) are fixedly mounted on the ratchet wheel (36), and the inner side of the ratchet wheel (36).

3. The numerical control machine tool for sizing and cutting of the epoxy resin glass fiber plate as claimed in claim 1, is characterized in that: the rotating frame (17) comprises a cylindrical shaft (171), a poking rod (172), a circular block (173), a circular ring block (174), a supporting rod (175), a circular arc cutter holder (176) and a circular arc blade (177), an output shaft at the upper end of a first motor (16) is provided with the cylindrical shaft (171) through a coupling, the upper end of the cylindrical shaft (171) is fixedly provided with the circular ring block (174), the lower end of the cylindrical shaft (171) is uniformly provided with the poking rod (172) along the circumferential direction, the poking rod (172) and the fluctuation long rod are staggered, the circular ring block (174) is sleeved outside the circular block (173), a rectangular groove is formed in the circular ring block (174) along the circumferential direction, the supporting rod (175) is fixedly arranged in the rectangular groove, the other end of the supporting rod (175) is uniformly and fixedly arranged on the circular block (173), the lower end of the circular ring block (174) is uniformly and fixedly arranged on the gap of the, the lower end of the arc cutter holder (176) is provided with an arc blade (177).

4. The numerical control machine tool for sizing and cutting of the epoxy resin glass fiber plate as claimed in claim 1, is characterized in that: the fixing frame (19) comprises a square plate (191), a third electric push rod (192), a connecting rod (193) and a bidirectional electric push rod (194), the square plate (191) is fixedly mounted on the upper side of the rectangular plate (18), the third electric push rod (192) is uniformly and fixedly mounted on the lower end face of the square plate (191), the connecting rod (193) is symmetrically and fixedly mounted on the front inner side and the rear inner side of the square plate (191), and the bidirectional electric push rod (194) is fixedly mounted at the tail end of the lower side of the connecting rod (193).

5. The numerical control machine tool for sizing and cutting of the epoxy resin glass fiber plate as claimed in claim 1, is characterized in that: the middle part of the rectangular long plate (12) is provided with a large arc groove, and the diameter of the large arc groove is larger than that of the circular arc blade (177) for cutting a circle.

6. The numerical control machine tool for sizing and cutting of the epoxy resin glass fiber plate as claimed in claim 4, is characterized in that: and rubber blocks are fixedly arranged at the tail ends of the two sides of the bidirectional electric push rod (194).