CN113182015A

CN113182015A - Glass material pre treatment equipment

Info

Publication number: CN113182015A
Application number: CN202110562736.8A
Authority: CN
Inventors: 董青文
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-05-24
Filing date: 2021-05-24
Publication date: 2021-07-30

Abstract

The invention relates to the field of glass manufacturing, in particular to glass material pretreatment equipment, wherein in the process of glass manufacturing, pretreatment is an important process and determines the quality of finished products, the automation degree of the traditional equipment is too low, and automatic batching cannot be completed according to requirements.

Description

Glass material pre treatment equipment

Technical Field

The invention relates to the field of glass manufacturing, in particular to glass material pretreatment equipment.

Background

In the process of glass manufacturing, pretreatment is a very important process, the quality of finished products is determined, the automation degree of traditional equipment is too low, automatic batching can not be completed according to requirements, and the equipment solves the problems.

Disclosure of Invention

The invention aims to provide glass material pretreatment equipment which can automatically finish glass material pretreatment.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a glass material pre treatment facility, includes abrasive brick assembly, crocus assembly, deferent assembly and batching assembly, the abrasive brick assembly is connected with the crocus assembly, and the crocus assembly is connected with the deferent assembly, and the deferent assembly is connected with the batching assembly.

As a further optimization of the technical scheme, the grinding block assembly comprises a feeding hopper, a grinding block chamber support, a double-end motor shaft I, a double-end motor shaft II, a double-end motor support, a grinding block roller, a block outlet, a partition plate I and a gear support, wherein the feeding hopper is connected with the grinding block chamber, the grinding block chamber is connected with the grinding block chamber support, the double-end motor is connected with the double-end motor shaft I and the double-end motor shaft II, the double-end motor shaft I is rotatably connected with the grinding block chamber, the double-end motor is connected with the double-end motor support, the double-end motor shaft I is rotatably connected with the grinding block roller, the double-end motor shaft I is rotatably connected with the partition plate I, the partition plate I is connected with the grinding block chamber, the block outlet is located below the grinding block chamber, and the double-end motor support is connected with the gear support.

As a further optimization of the technical scheme, the grinding combination body comprises a bevel gear shaft bracket, a double-end motor shaft II bracket, a bevel gear I, a bevel gear II, a bevel gear shaft II, a disc, a shifting shaft, a connecting rod, a swinging gear shaft, a rack, a grinding tool bracket, a grinding tool, a support lug, a screw rod, a partition plate II and a connecting bracket, wherein the double-end motor bracket is connected with the bevel gear shaft bracket, the bevel gear shaft bracket is connected with the double-end motor shaft II bracket, the double-end motor shaft II is rotationally connected with the double-end motor shaft II bracket, the double-end motor shaft II is connected with the bevel gear I, the bevel gear I is meshed with the bevel gear II, the bevel gear II is connected with the bevel gear shaft bracket, the bevel gear II is rotationally connected with the disc, the disc is connected with the shifting shaft, the shifting shaft is rotationally connected with the connecting rod, and the connecting rod is hinged with the swinging gear, rock the gear and rock the gear shaft and be connected, rock the gear shaft and rotate with gear bracket and be connected, rock the gear and be connected with two rack toothing, two racks are connected with two grinding apparatus supports respectively, two grinding apparatus supports respectively with two grinding apparatus sliding connection, two grinding apparatus supports, two grinding apparatus are connected with eight journal stirrup respectively, the journal stirrup that the grinding apparatus support is connected passes through screw rod threaded connection with the journal stirrup that the grinding apparatus is connected, division board II is connected with abrasive brick room support, two grinding apparatus supports all with abrasive brick room support sliding connection, abrasive brick room support is connected with linking bridge.

As a further optimization of the technical scheme, the iron removing assembly comprises two belt wheels I, two belts I, two shafts of the belt wheels I, a separating plate, an iron collecting chamber and magnetic fan blades, a double-head motor shaft II is connected with the belt wheels I, the two belt wheels I are connected through the belts I, one belt wheel I is connected with the shaft of the belt wheel I, the shaft of the belt wheel I is connected with the separating plate, the separating plate is connected with the iron collecting chamber, the shaft of the belt wheel I is connected with the magnetic fan blades, and the separating plate and the iron collecting chamber are respectively connected with connecting supports on two sides.

As a further optimization of the technical scheme, the batching assembly comprises a batching chamber, a batching motor, a gear I, a gear II shaft, a belt wheel II, a belt II, a ball groove sleeve, a friction wheel, a threaded rod, an adjusting plate, an adjusting ball, a friction disc, a discharging fan blade shaft, a discharging fan blade and a partition plate III, wherein the partition plate is connected with the batching chamber, the batching motor is connected with the gear I, the gear I is meshed with the gear II, the gear II is connected with the gear II shaft, the gear II shaft is rotatably connected with the batching chamber, the belt wheel II is connected with an adjacent belt wheel II through the belt II, the gear II shaft is connected with the belt wheel II, the ball groove sleeve and the friction wheel are both in sliding connection with the gear II shaft, the threaded rod is rotatably connected with the batching chamber, the threaded rod is in threaded connection with the adjusting plate, the adjusting plate is connected with the adjusting ball, and the adjusting ball is in sliding connection with the ball groove sleeve, the friction wheel is in friction connection with the friction disc, the friction disc is connected with the discharging fan blade shaft, the discharging fan blade shaft is connected with the discharging fan blades, and the partition plate III is connected with the batching chamber.

As a further optimization of the technical scheme, three discharging fan blade shafts are arranged, the discharging fan blade shafts on two sides are respectively and rotatably connected with two sides of the batching chamber, and the middle discharging fan blade shaft is rotatably connected with two partition plates III.

The glass material pretreatment equipment has the beneficial effects that: put into corresponding hopper respectively with raw and other materials, open the abrasive brick assembly, the abrasive brick assembly is smashed the raw materials and is blocked, the grinding of being convenient for, the crocus assembly can be ground the fragment into powder, the grinding apparatus is convenient for change, the ferromagnetic metal separation in the material that the de-ironing assembly can be smashed has guaranteed that finished product glass's colour does not receive the influence, the batching assembly can be according to the demand of finished product glass ratio, according to the volume of the ejection of compact at every turn of volume ratio adjustment, adapt to various glass's manufacturing.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

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

fig. 2 is a schematic view of the structure of the abrasive block assembly 1 according to the invention;

FIG. 3 is a first sectional view of the structure of the grinding block assembly 1 of the present invention;

FIG. 4 is a structural sectional view II of the grinding block assembly 1 of the present invention;

FIG. 5 is a first schematic diagram of the milling assembly 2 of the present invention;

FIG. 6 is a second schematic diagram of the milling assembly 2 of the present invention;

FIG. 7 is an enlarged schematic view of the structure of the milling assembly 2 of the present invention;

FIG. 8 is a third schematic diagram of the milling assembly 2 of the present invention;

figure 9 is a fourth schematic diagram of the milling assembly 2 of the present invention;

figure 10 is a schematic view of the construction of the iron-removing assembly 3 according to the invention;

figure 11 is a structural cross-sectional view of the iron-removing assembly 3 of the present invention;

FIG. 12 is a first schematic view of the dispensing assembly 4 of the present invention;

FIG. 13 is a second schematic structural view of the dispensing assembly 4 of the present invention;

FIG. 14 is a schematic view of the third embodiment of the dispensing assembly 4 of the present invention;

FIG. 15 is a fourth schematic structural view of the dispensing assembly 4 of the present invention;

FIG. 16 is a schematic view of the dispensing assembly 4 of the present invention;

fig. 17 shows a sixth embodiment of the dosing assembly 4 according to the invention.

In the figure: a grinding block assembly 1; feeding into a hopper 1-1; a grinding block chamber 1-2; 1-3 of a grinding block chamber bracket; 1-4 of a double-head motor; 1-5 parts of a double-end motor shaft; a double-end motor shaft II 1-6; 1-7 of a double-head motor bracket; 1-8 parts of grinding block roller; 1-9 of block outlet; 1-10 parts of a partition plate I; 1-11 parts of a gear bracket; a milling assembly 2; bevel gear shaft supports 2-1; a double-end motor shaft II bracket 2-2; bevel gears I2-3; bevel gears II 2-4; 2-5 of a bevel gear II shaft; 2-6 of a disc; 2-7 of a shifting shaft; 2-8 of a connecting rod; shaking the gears 2-9; shaking the gear shaft 2-10; 2-11 of racks; 2-12 parts of a grinding tool bracket; 2-13 parts of a grinding tool; 2-14 of a support lug; 2-15 parts of screw; partition plates II 2-16; connecting brackets 2-17; a deferrization assembly 3; a belt wheel I3-1; 3-2 parts of a belt; 3-3 of a shaft I with a wheel; 3-4 of a separation plate; an iron collection chamber 3-5 and a magnetic fan blade 3-6; a dosing assembly 4; a batching room 4-1; 4-2 of a batching motor; 4-3 parts of a gear I; 4-4 of a gear; 4-5 of a gear II shaft; belt wheels II 4-6; 4-7 of a belt II; 4-8 parts of a ball groove sleeve; 4-9 parts of friction wheel; 4-10 parts of threaded rod; adjusting plates 4-11; 4-12 of an adjusting ball; 4-13 of friction disc; 4-14 parts of discharging fan blade shaft; 4-15 parts of discharge fan blades; partition plates III to 16.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the present embodiment will be described with reference to fig. 1 to 17, and a glass material pretreatment apparatus includes an abrasive block assembly 1, a grinding powder assembly 2, a deferrization assembly 3, and a dosing assembly 4, wherein the abrasive block assembly 1 is connected to the grinding powder assembly 2, the grinding powder assembly 2 is connected to the deferrization assembly 3, and the deferrization assembly 3 is connected to the dosing assembly 4.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-17, and the embodiment further describes the first embodiment, wherein the grinding block assembly 1 comprises a feeding hopper 1-1, a grinding block chamber 1-2, a grinding block chamber support 1-3, a double-end motor 1-4, a double-end motor shaft I1-5, a double-end motor shaft II 1-6, a double-end motor support 1-7, a grinding block roller 1-8, a block outlet 1-9, a partition plate I1-10 and a gear support 1-11, the feeding hopper 1-1 is connected with the grinding block chamber 1-2, the grinding block chamber 1-2 is connected with the grinding block chamber support 1-3, the double-end motor 1-4 is connected with the double-end motor shaft I1-5 and the double-end motor shaft II 1-6, the double-end motor shaft I1-5 is rotatably connected with the grinding block chamber 1-2, the double-head motor 1-4 is connected with a double-head motor support 1-7, the double-head motor support 1-7 is connected with a grinding block chamber support 1-3, a double-head motor shaft I1-5 is rotationally connected with a grinding block roller 1-8, a double-head motor shaft I1-5 is rotationally connected with a partition plate I1-10, the partition plate I1-10 is connected with a grinding block chamber 1-2, a block outlet 1-9 is positioned below the grinding block chamber 1-2, the double-head motor support 1-7 is connected with a gear support 1-11, raw materials are respectively put into corresponding hoppers, and a grinding block assembly breaks the raw materials into blocks to facilitate grinding.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1-17, and the embodiment further describes the first embodiment, the milling assembly 2 includes a bevel gear shaft bracket 2-1, a double-head motor shaft ii bracket 2-2, a bevel gear i 2-3, a bevel gear ii 2-4, a bevel gear ii shaft 2-5, a disk 2-6, a dial shaft 2-7, a connecting rod 2-8, a rocking gear 2-9, a rocking gear shaft 2-10, a rack 2-11, a grinding tool bracket 2-12, a grinding tool 2-13, a support lug 2-14, a screw 2-15, a partition plate ii 2-16 and a connecting bracket 2-17, the double-head motor bracket 1-7 is connected with the bevel gear shaft bracket 2-1, the bevel gear shaft bracket 2-1 is connected with the double-head motor shaft ii bracket 2-2, the double-end motor shaft II 1-6 is rotationally connected with the double-end motor shaft II support 2-2, the double-end motor shaft II 1-6 is connected with the bevel gear I2-3, the bevel gear I2-3 is meshed with the bevel gear II 2-4, the bevel gear II 2-4 is connected with the bevel gear II shaft 2-5, the bevel gear II shaft 2-5 is rotationally connected with the bevel gear shaft support 2-1, the bevel gear II shaft 2-5 is connected with the disc 2-6, the disc 2-6 is connected with the dial shaft 2-7, the dial shaft 2-7 is rotationally connected with the connecting rod 2-8, the connecting rod 2-8 is hinged with the shaking gear 2-9, the shaking gear 2-9 is connected with the shaking gear shaft 2-10, and the shaking gear shaft 2-10 is rotationally connected with the gear support 1-11, the shaking gear 2-9 is meshed with two racks 2-11, the two racks 2-11 are respectively connected with two grinding tool supports 2-12, the two grinding tool supports 2-12 are respectively connected with two grinding tools 2-13 in a sliding manner, the two grinding tool supports 2-12 and the two grinding tools 2-13 are respectively connected with eight support lugs 2-14, the support lug 2-14 connected with the grinding tool support 2-12 is connected with the support lug 2-14 connected with the grinding tool 2-13 through a screw 2-15 in a threaded manner, the partition plates II 2-16 are connected with grinding block chamber supports 1-3, the two grinding tool supports 2-12 are both connected with the grinding block chamber supports 1-3 in a sliding manner, the grinding block chamber supports 1-3 are connected with connecting supports 2-17, and a grinding assembly can grind the fragments into powder, the grinding tool is convenient to replace.

The fourth concrete implementation mode:

referring to FIGS. 1-17, the embodiment will be described in detail, wherein the de-ironing assembly 3 comprises two pulleys I3-1, two belts I3-2, two shafts 3-3, a separating plate 3-4, an iron collecting chamber 3-5 and a magnetic fan blade 3-6, a double-headed motor shaft II 1-6 is connected to the two pulleys I3-1, the two pulleys I3-1 are connected via the belt I3-2, one pulley I3-1 is connected to the shaft 3-3, the shaft 3-3 is connected to the separating plate 3-4, the separating plate 3-4 is connected to the iron collecting chamber 3-5, the shaft 3-3 is connected to the magnetic fan blade 3-6, and the separating plate 3-4, The iron collecting chambers 3-5 are respectively connected with the connecting supports 2-17 at the two sides, and the iron removing assembly can separate ferromagnetic metal in the crushed material, so that the color of the finished glass is not affected.

The fifth concrete implementation mode:

the embodiment is described below by combining with figures 1-17, and the embodiment further describes the first embodiment, the batching assembly 4 comprises a batching chamber 4-1, a batching motor 4-2, a gear I4-3, a gear II 4-4, a gear II shaft 4-5, a belt wheel II 4-6, a belt II 4-7, a ball groove sleeve 4-8, a friction wheel 4-9, a threaded rod 4-10, an adjusting plate 4-11, an adjusting ball 4-12, a friction disc 4-13, a discharging fan blade shaft 4-14, a discharging fan blade 4-15 and a partition plate III 4-16, a separation plate 3-4 is connected with the batching chamber 4-1, a batching motor 4-2 is connected with the batching chamber 4-1, and a batching motor 4-2 is connected with the gear I4-3, the gear I4-3 is meshed with the gear II 4-4, the gear II 4-4 is connected with a gear II shaft 4-5, the gear II shaft 4-5 is rotationally connected with the batching chamber 4-1, the belt wheel II 4-6 is connected with an adjacent belt wheel II 4-6 through a belt II 4-7, the gear II shaft 4-5 is connected with the belt wheel II 4-6, the ball groove sleeve 4-8 and the friction wheel 4-9 are both connected with the gear II shaft 4-5 in a sliding way, the threaded rod 4-10 is rotationally connected with the batching chamber 4-1, the threaded rod 4-10 is in threaded connection with the adjusting plate 4-11, the adjusting plate 4-11 is connected with the adjusting ball 4-12, the adjusting ball 4-12 is in sliding connection with the ball groove sleeve 4-8, the friction wheel 4-9 is in frictional connection with the friction disc 4-13, the friction disk 4-13 is connected with the discharging fan blade shaft 4-14, the discharging fan blade shaft 4-14 is connected with the discharging fan blade 4-15, the partition plate III 4-16 is connected with the batching chamber 4-1, and the batching assembly can adjust the volume of each discharging according to the volume ratio and the requirement of the proportioning of the finished glass, thereby being suitable for the manufacture of various glasses.

The sixth specific implementation mode:

the following describes the present embodiment with reference to fig. 1 to 17, and the present embodiment further describes the first embodiment, there are three discharging fan blade shafts 4 to 14, the two discharging fan blade shafts 4 to 14 on two sides are respectively rotatably connected with two sides of the batching chamber 4-1, and the middle discharging fan blade shaft 4 to 14 is rotatably connected with two partition plates iii 4 to 16.

The invention relates to a glass material pretreatment device, which has the working principle that: materials are respectively added into a grinding block chamber 1-2 through different feeding hoppers 1-1, a partition plate I1-10 is arranged in the grinding block chamber 1-2 to prevent the materials from mixing, a double-head motor 1-4 is started, the double-head motor 1-4 drives a double-head motor shaft I1-5 to rotate, the double-head motor shaft I1-5 drives a grinding block roller 1-8 to rotate, the grinding block roller 1-8 drives the materials to mutually collide and grind between the grinding block roller 1-8 and the grinding block chamber 1-2, the materials are processed into the materials which can fall on the inclined surface of a material block grinding tool 2-13 through a block outlet 1-9, the partition plate II 2-16 can prevent the materials from mixing, the double-head motor 1-4 drives a double-head motor shaft II 1-6 to rotate, the double-head motor shaft II 1-6 drives a bevel gear I2-3 to rotate, the bevel gear I2-3 drives the bevel gear II 2-4 to rotate, the bevel gear II 2-4 drives the bevel gear II shaft 2-5 to rotate, the bevel gear II shaft 2-5 drives the disc 2-6 to rotate, the disc 2-6 drives the dial shaft 2-7 to rotate, the dial shaft 2-7 drives the rocking gear 2-9 to reciprocate in the gear bracket 1-11 through the connecting rod 2-8 and rotate positively and negatively, the rocking gear 2-9 respectively drives the two racks 2-11 to move oppositely along the connecting bracket 2-17, the two racks 2-11 respectively drive the two grinding tools 2-13 to move oppositely, materials falling on the grinding tools 2-13 are ground into powder under the action of the dislocation friction of the two grinding tools 2-13 and fall on the separating plate 3-4, and each material contains ferromagnetic metal elements, ferromagnetic metal elements can affect the quality of glass forming, a double-head motor shaft II 1-6 drives a belt wheel I3-1 to rotate, two belt wheels I3-1 drive a belt wheel I shaft 3-3 to rotate through a belt I3-2, the belt wheel I shaft 3-3 drives a magnetic fan blade 3-6 to rotate, materials without ferromagnetic metal fall into a corresponding batching chamber 4-1 through the radian of a separating plate 3-4, materials containing ferromagnetic metal move to the inclined surface of an upper separating plate 3-4 under the action of the attraction of the magnetic fan blade 3-6, the magnetic force of the magnetic fan blade 3-6 is reduced far away at the moment, the ferromagnetic metal falls into an iron collecting chamber 3-5 to be collected, the screened materials are separated by a separating plate III 4-16 and cannot be mixed, a batching motor 4-2 is started, the batching motor 4-2 drives a gear I4-3 to rotate, the gear I4-3 drives the gear II 4-4 to rotate, the gear II 4-4 drives the gear II shaft 4-5 to rotate, the gear II shaft 4-5 drives the friction wheel 4-9 to rotate, the friction wheel 4-9 drives the friction disc 4-13 to rotate, the friction disc 4-13 drives the discharging fan blade shaft 4-14 to rotate, the discharging fan blade shaft 4-14 drives the discharging fan blade 4-15 to rotate, the discharging fan blade 4-15 discharges materials in the batching chamber 4-1, the volume of the materials discharged by each rotation of the discharging fan blade 4-15 is consistent, the volume of the total amount of discharged materials can be adjusted by adjusting the rotating speed of the discharging fan blade 4-15, three discharging fan blade shafts 4-14 are arranged, the discharging fan blade shafts 4-14 on two sides are respectively connected with the two sides of the batching chamber 4-1 in a rotating manner, the middle discharging fan blade shaft 4-14 is connected with two partition plates III-16 in a rotating manner, the belt wheel II 4-6 is connected with the adjacent belt wheel II 4-6 through a belt II 4-7, the gear II shaft 4-5 is connected with the belt wheel II 4-6, the adjacent gear II shaft 4-5 is driven to rotate at a constant speed through the belt wheel II 4-6 and the belt II 4-7, when the discharge volume of the corresponding material needs to be adjusted, the threaded rod 4-10 is rotated, the threaded rod 4-10 drives the adjusting plate 4-11 to move up and down, the adjusting plate 4-11 drives the adjusting ball 4-12 to move up and down, the adjusting ball 4-12 drives the friction wheel 4-9 to slide on the gear II shaft 4-5 through the ball groove sleeve 4-8, the rotating speed of the friction disc 4-13 is adjusted by switching the contact position of the friction wheel 4-9 and the friction disc 4-13, and then the discharge volume of each material is adjusted, and finishing the material proportioning.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a glass material pre treatment facility, includes abrasive brick assembly (1), crocus assembly (2), deferent assembly (3) and batching assembly (4), its characterized in that: the grinding block assembly (1) is connected with the grinding powder assembly (2), the grinding powder assembly (2) is connected with the iron removing assembly (3), and the iron removing assembly (3) is connected with the ingredient assembly (4).

2. A glass material pretreatment apparatus according to claim 1, characterized in that: the grinding block assembly (1) comprises a feeding hopper (1-1), a grinding block chamber (1-2), a grinding block chamber support (1-3), a double-end motor (1-4), a double-end motor shaft I (1-5), a double-end motor shaft II (1-6), a double-end motor support (1-7), a grinding block roller (1-8), a block outlet (1-9), a partition plate I (1-10) and a gear support (1-11), wherein the feeding hopper (1-1) is connected with the grinding block chamber (1-2), the grinding block chamber (1-2) is connected with the grinding block chamber support (1-3), the double-end motor (1-4) is connected with the double-end motor shaft I (1-5) and the double-end motor shaft II (1-6), the double-end motor shaft I (1-5) is rotatably connected with the grinding block chamber (1-2), the double-head motor (1-4) is connected with a double-head motor support (1-7), the double-head motor support (1-7) is connected with a grinding block chamber support (1-3), a double-head motor shaft I (1-5) is rotationally connected with a grinding block roller (1-8), the double-head motor shaft I (1-5) is rotationally connected with a partition plate I (1-10), the partition plate I (1-10) is connected with a grinding block chamber (1-2), a block outlet (1-9) is located below the grinding block chamber (1-2), and the double-head motor support (1-7) is connected with a gear support (1-11).

3. A glass material pretreatment apparatus according to claim 1, characterized in that: the milling assembly (2) comprises a bevel gear shaft support (2-1), a double-end motor shaft II support (2-2), a bevel gear I (2-3), a bevel gear II (2-4), a bevel gear II shaft (2-5), a disc (2-6), a shifting shaft (2-7), a connecting rod (2-8), a rocking gear (2-9), a rocking gear shaft (2-10), a rack (2-11), a grinding tool support (2-12), a grinding tool (2-13), a support lug (2-14), a screw (2-15), a partition plate II (2-16) and a connecting support (2-17), wherein the double-end motor support (1-7) is connected with the bevel gear shaft support (2-1), the bevel gear shaft support (2-1) is connected with the double-end motor shaft II support (2-2), the double-end motor shaft II (1-6) is rotationally connected with the double-end motor shaft II support (2-2), the double-end motor shaft II (1-6) is connected with the bevel gear I (2-3), the bevel gear I (2-3) is meshed with the bevel gear II (2-4), the bevel gear II (2-4) is connected with the bevel gear II shaft (2-5), the bevel gear II shaft (2-5) is rotationally connected with the bevel gear shaft support (2-1), the bevel gear II shaft (2-5) is connected with the disc (2-6), the disc (2-6) is connected with the shifting shaft (2-7), the shifting shaft (2-7) is rotationally connected with the connecting rod (2-8), the connecting rod (2-8) is hinged with the shaking gear (2-9), the shaking gear (2-9) is connected with the shaking gear shaft (2-10), the rocking gear shaft (2-10) is rotatably connected with the gear support (1-11), the rocking gear (2-9) is meshed with two racks (2-11), the two racks (2-11) are respectively connected with two grinding tool supports (2-12), the two grinding tool supports (2-12) are respectively connected with two grinding tools (2-13) in a sliding manner, the two grinding tool supports (2-12) and the two grinding tools (2-13) are respectively connected with eight support lugs (2-14), the support lugs (2-14) connected with the grinding tool supports (2-12) are connected with the support lugs (2-14) connected with the grinding tools (2-13) through screw rods (2-15) in a threaded manner, the partition plates II (2-16) are connected with the grinding block chamber support (1-3), the two grinding tool supports (2-12) are both connected with the grinding block chamber support (1-3) in a sliding manner, the grinding block chamber bracket (1-3) is connected with the connecting bracket (2-17).

4. A glass material pretreatment apparatus according to claim 1, characterized in that: the iron removing assembly (3) comprises belt wheels I (3-1), a belt I (3-2), a belt wheel I shaft (3-3), separating plates (3-4), an iron collecting chamber (3-5) and magnetic fan blades (3-6), a double-end motor shaft II (1-6) is connected with the belt wheels I (3-1), two belt wheels I (3-1) are arranged, the two belt wheels I (3-1) are connected through the belt I (3-2), one belt wheel I (3-1) is connected with the belt wheel I shaft (3-3), the belt wheel I shaft (3-3) is connected with the separating plates (3-4), the separating plates (3-4) are connected with the iron collecting chamber (3-5), the belt wheel I shaft (3-3) is connected with the magnetic fan blades (3-6), the separating plate (3-4) and the iron collecting chamber (3-5) are respectively connected with the connecting brackets (2-17) at the two sides.

5. A glass material pretreatment apparatus according to claim 1, characterized in that: the batching assembly (4) comprises a batching chamber (4-1), a batching motor (4-2), a gear I (4-3), a gear II (4-4), a gear II shaft (4-5), a belt wheel II (4-6), a belt II (4-7), a ball groove sleeve (4-8), a friction wheel (4-9), a threaded rod (4-10), an adjusting plate (4-11), an adjusting ball (4-12), a friction disc (4-13), a discharging fan blade shaft (4-14), a discharging fan blade (4-15) and a partition plate III (4-16), wherein a separating plate (3-4) is connected with the batching chamber (4-1), the batching motor (4-2) is connected with the batching chamber (4-1), and the batching motor (4-2) is connected with the gear I (4-3), the gear I (4-3) is meshed with the gear II (4-4), the gear II (4-4) is connected with the gear II shaft (4-5), the gear II shaft (4-5) is rotationally connected with the batching chamber (4-1), the belt wheel II (4-6) is connected with the adjacent belt wheel II (4-6) through a belt II (4-7), the gear II shaft (4-5) is connected with the belt wheel II (4-6), the ball groove sleeve (4-8) and the friction wheel (4-9) are both in sliding connection with the gear II shaft (4-5), the threaded rod (4-10) is rotationally connected with the batching chamber (4-1), the threaded rod (4-10) is in threaded connection with the adjusting plate (4-11), the adjusting plate (4-11) is connected with the adjusting ball (4-12), the adjusting balls (4-12) are connected with the ball groove sleeves (4-8) in a sliding mode, the friction wheels (4-9) are connected with the friction discs (4-13) in a friction mode, the friction discs (4-13) are connected with the discharging fan blade shafts (4-14), the discharging fan blade shafts (4-14) are connected with the discharging fan blades (4-15), and the partition plates (4-16) are connected with the batching chamber (4-1).

6. A glass material pretreatment apparatus according to claim 5, characterized in that: three discharging fan blade shafts (4-14) are arranged, the discharging fan blade shafts (4-14) on two sides are respectively and rotatably connected with two sides of the batching chamber (4-1), and the discharging fan blade shaft (4-14) in the middle is rotatably connected with two partition plates (4-16).