阅读说明：本技术 一种聚酯树脂纳米材料加工设备 (Polyester resin nano material processing equipment ) 是由 曹法秀 于 2021-07-22 设计创作，主要内容包括：本发明公开了一种聚酯树脂纳米材料加工设备,涉及高分子材料加工领域,针对现有的加工材料设备,不能充分研磨原料,影响聚酯树脂成型效果,对加工的聚酯树脂纳米材料所产生的废弃物不能净化处理等问题,现提出如下方案,包括支撑板和反应釜,所述支撑板的顶部焊接有超声分散箱,所述支撑板的底部焊接有搅拌箱。本发明设计巧妙,结构简单,添加的超声分散器使原料粉碎细化,添加的搅拌箱对原料搅拌,添加的反应釜、加热器对原料进行反应蒸发去水,添加的研磨盘、研磨网对生产好的聚酯树脂纳米材料研磨粉碎,添加的水箱、废气管在生产聚酯树脂纳米材料时所产生的废气进行净化处理,该装置方便使用,实用性强,便于推广。(The invention discloses polyester resin nano material processing equipment, relates to the field of high polymer material processing, and aims at solving the problems that raw materials cannot be fully ground, the forming effect of polyester resin cannot be influenced, waste generated by the processed polyester resin nano material cannot be purified and the like in the conventional processing material equipment. The device has the advantages of ingenious design and simple structure, the added ultrasonic disperser enables the raw materials to be crushed and refined, the added stirring box stirs the raw materials, the added reaction kettle and the added heater perform reaction evaporation on the raw materials to remove water, the added grinding disc and the added grinding net grind and crush the produced polyester resin nano materials, and the added water tank and the waste gas pipe perform purification treatment on waste gas produced during the production of the polyester resin nano materials.)

1. The utility model provides a polyester resin nano-material processing equipment, includes backup pad (1) and reation kettle (5), its characterized in that, the top welding of backup pad (1) has ultrasonic dispersion case (15), the bottom welding of backup pad (1) has agitator tank (10), there is double-shaft motor (17) top right side of backup pad (1) through bolt fixed mounting, the top left side welding of backup pad (1) has water tank (13), the inner circle welding of reation kettle (5) has heating pipe (7).

2. The polyester resin nano-material processing equipment as claimed in claim 1, wherein an ultrasonic dispersion tank cover (1501) is welded on the inner wall of the top of the ultrasonic dispersion tank (15), a second rotating shaft (14) is sleeved on the top of the ultrasonic dispersion tank (15), a plurality of groups of third stirring rods (1502) are arranged on the outer ring of one end, located in the ultrasonic dispersion tank (15), of the second rotating shaft (14), a plurality of ultrasonic dispersers (1504) are installed at one ends, located in the ultrasonic dispersion tank (15), of the second rotating shaft (14), a screen mesh (1503) is welded on the bottoms of the inner walls of two sides of the ultrasonic dispersion tank (15), and a feed hopper is sleeved on the left side of the top of the ultrasonic dispersion tank (15).

3. The polyester resin nano-material processing equipment as claimed in claim 2, wherein a third rotating shaft (16) is welded at the output end of each double-shaft motor (17), a first driving wheel is welded at one end, away from each other, of each third rotating shaft (16), a second driving wheel is welded at one end, located outside the ultrasonic dispersion box (15), of each second rotating shaft (14), the second driving wheels are in transmission connection with the first driving wheel at the top end of each third rotating shaft (16) through a first driving belt, and a through pipe penetrating through and extending into the stirring box (10) is welded at the bottom of each ultrasonic dispersion box (15).

4. The polyester resin nano-material processing equipment as claimed in claim 2, wherein a fourth rotating shaft (1002) penetrating through and extending out of the stirring tank (10) is rotatably connected to the inner wall of the left side of the stirring tank (10), a plurality of groups of second stirring rods (1001) are arranged on the outer ring of one end, located on the stirring tank (10), of the fourth rotating shaft (1002), a first bevel gear is welded on one end, located on the outer side of the stirring tank (10), of the fourth rotating shaft (1002), the double-shaft motor (17) is located on a third rotating shaft (16) welded at the bottom and penetrates through and extends to the bottom of the supporting plate (1), a second bevel gear is welded on the outer ring, located on the bottom of the supporting plate (1), of the third rotating shaft (16), and the first bevel gear is meshed with the second bevel gear.

5. The polyester resin nanomaterial processing apparatus according to claim 1, wherein a water feeding pipe is sleeved on the right side of the top of the water tank (13), a valve is sleeved on one end of the water feeding pipe located outside the water tank (13), a water pipe (11) penetrating and extending into the water tank (13) is sleeved on the top of the left side of the stirring tank (10), a flow regulating valve is sleeved on one side of the water pipe (11) located at the bottom of the support plate (1), and support columns (3) are welded on both sides of the bottom of the support plate (1).

6. The polyester resin nano-material processing equipment according to claim 1, wherein a reaction kettle cover (18) is welded on the inner wall of the top of the reaction kettle (5), the grinding net (6) is welded on the bottoms of the inner walls of the two sides of the reaction kettle (5), a first rotating shaft (2) is sleeved on the top of the reaction kettle (5), first stirring rods (19) are welded on the top and the bottom of one side of the first rotating shaft (2) in the reaction kettle (5), a plurality of groups of stirring rods (8) are welded on one side of the first stirring rods (19) close to each other, and the stirring rods (8) are V-shaped.

7. The polyester resin nanomaterial processing apparatus according to claim 1, wherein a waste gas pipe (12) is sleeved at the top of the left side of the reaction kettle (5), the waste gas pipe (12) penetrates and extends to the top of the support plate (1), one end of the waste gas pipe (12) located at the top of the support plate (1) extends into water in the water tank (13), the top of the reaction kettle (5) is sleeved with the connecting pipe (9), and an outer ring of one end of the connecting pipe (9) away from the reaction kettle (5) is sleeved with the bottom of the stirring tank (10).

8. The polyester resin nano-material processing equipment according to claims 2 and 6, wherein a third driving wheel is welded at one end of the first rotating shaft (2) positioned outside the reaction kettle (5), a first driving wheel welded at one end of the third rotating shaft (16) positioned at the bottom of the supporting plate (1) is in transmission connection with the third driving wheel through a second driving belt, a grinding disc (4) is welded at one end of the first rotating shaft (2) positioned inside the reaction kettle (5), and a discharge hopper is welded at the bottom of the reaction kettle (5).

9. The polyester resin nano-material processing device according to claim 1, which comprises the following steps,

s1, firstly, starting the double-shaft motor 17, feeding the raw material for making polyester resin into the ultrasonic dispersion box 15 through the feed hopper on the left side of the top of the ultrasonic dispersion box 15, at this time, the double-shaft motor 17 drives the third rotating shaft 16 welded with the output end thereof to rotate, because the ends of the third rotating shafts 16 far away from each other are all welded with the first transmission wheels, the end of the second rotating shaft 14 positioned outside the ultrasonic dispersion box 15 is welded with the second transmission wheels, the second transmission wheels are connected with the first transmission wheels on the top end of the third rotating shafts 16 through the first transmission belts, so the third rotating shafts 16 can drive the second rotating shafts 14 to rotate, the outer ring of the end of the second rotating shaft 14 positioned inside the ultrasonic dispersion box 15 is provided with a plurality of groups of stirring rods, one end of the second rotating shaft 14 positioned inside the ultrasonic dispersion box 15 is provided with a plurality of ultrasonic dispersers 1504, the raw material is subjected to ultrasonic dispersion through the ultrasonic disperser 1504, and then the raw material is fully stirred by the third stirring rods 1502, so that it is fully mixed.

S2, the mixed raw materials flow to the bottom of the ultrasonic dispersion box 15 through the screen 1503, a through pipe is welded at the bottom of the ultrasonic dispersion box 15, the raw materials flow into the stirring box 10 through the through pipe at the bottom of the ultrasonic dispersion box 15, the raw materials flow into the stirring box 10, a flow valve is sleeved at one side of the bottom of the support plate 1 of the water pipe 11, the size of water flow is controlled by adjusting the flow valve on the water pipe 11, the water flow is adjusted to a proper water quantity, the water flows into the stirring box 10 and is fully mixed and stirred with the raw materials in the stirring box 10, and organic aqueous solution is obtained after the raw materials and the water are fully mixed.

S3, organic water solution flows into a reaction kettle 5 through a connecting pipe 9, because a heating pipe 7 is welded on the inner ring of the reaction kettle 5, a first stirring rod 19 is welded on the top and the bottom of one side in the reaction kettle 5, a plurality of groups of stirring rods 8 are welded on one side of the first stirring rod 19 close to each other, the stirring rods 8 are V-shaped, full reaction is carried out under the action of the heating pipe 7 and the stirring of the stirring rods 8, waste gas generated in the reaction is conveyed into a water tank 13 through a waste gas pipe 12 for purification, the purified gas is discharged through the water tank 13, the organic water solution is evaporated by the heating pipe 7 to obtain solid polyester resin nanometer material, the polyester resin nanometer material flows onto a grinding net 6 and is continuously ground by a grinding disc 4 for crushing, and after being filtered and screened by the grinding net 6, the machine-made resin material is discharged out of the reaction kettle 5 through a discharging hopper at the bottom of the reaction kettle 5, for later packaging and storage.

Technical Field

The invention relates to the field of processing of high polymer materials, in particular to processing equipment for a polyester resin nano material.

Background

The polyester resin is an unsaturated polyester adhesive for short, the unsaturated polyester adhesive mainly comprises the unsaturated polyester resin, an initiator, an accelerant, a filler, a thixotropic agent and the like, has small viscosity, easy wetting, good manufacturability, large hardness of a cured adhesive layer, good transparency, high brightness, capability of being pressurized and quickly cured at room temperature, better heat resistance and excellent electrical property, and is mainly used for bonding glass fiber reinforced plastics, hard plastics, concrete, electric tank seals and the like.

The existing polyester resin nano processing material equipment can not fully grind the raw materials required by processing, the insufficient grinding can easily cause larger particles of the raw materials, the additive of the polyester resin can not be fully stirred, the forming effect of the polyester resin is influenced, and the waste generated by the processed polyester resin nano material can not be purified and treated, so that the environment is influenced.

Disclosure of Invention

Objects of the invention

In order to solve the technical problems in the background technology, the invention provides polyester resin nano material processing equipment, which is ingenious in design, simple in structure and capable of improving working efficiency, the added ultrasonic disperser and the screen can crush and refine raw materials, the added stirring box can add water and stir the refined raw materials, the added reaction kettle and the added heater can perform reaction evaporation and dehydration on the mixed polyester resin nano material, the added grinding disc and the added grinding net grind and crush the produced polyester resin nano material, so that the later-stage work of packaging, storage and the like is facilitated, and waste gas generated by the added water tank and the added waste gas pipe in the production of the polyester resin nano material is purified.

(II) technical scheme

The invention provides polyester resin nano material processing equipment which comprises a supporting plate and a reaction kettle, wherein an ultrasonic dispersion box is welded at the top of the supporting plate, a stirring box is welded at the bottom of the supporting plate, a double-shaft motor is fixedly installed on the right side of the top of the supporting plate through a bolt, a water tank is welded on the left side of the top of the supporting plate, and a heating pipe is welded on an inner ring of the reaction kettle.

Preferably, the top inner wall welding of supersound dispersion case has the supersound dispersion case lid, the second pivot has been cup jointed at the top of supersound dispersion case, the one end outer lane that the second pivot is located the supersound dispersion incasement is provided with multiunit third poking bar, a plurality of supersound deconcentrators are all installed to the one end that the second pivot is located the supersound dispersion incasement, the bottom welding of the both sides inner wall of supersound dispersion case has the screen cloth, the feeder hopper has been cup jointed on the top left side of supersound dispersion case.

Preferably, the output of double-shaft motor all welds there is the third pivot, first drive wheel has all been welded to the one end that the third pivot was kept away from each other, the one end welding that the second pivot is located the outer ultrasonic dispersion case has the second drive wheel, the second drive wheel is connected through the transmission of first drive belt with the first drive wheel on third pivot top, the bottom welding of ultrasonic dispersion case has the siphunculus that runs through and extend to in the agitator tank.

Preferably, the inner wall of the left side of the stirring box is rotatably connected with a fourth rotating shaft which runs through and extends to the outside of the stirring box, the outer ring of one end, located on the stirring box, of the fourth rotating shaft is provided with a plurality of groups of second stirring rods, the outer ring of one end, located on the stirring box, of the fourth rotating shaft is welded with a first bevel gear, the double-shaft motor is located at the bottom of a third rotating shaft welded with the bottom and runs through and extends to the bottom of the supporting plate, the outer ring, located at the bottom of the supporting plate, of the third rotating shaft is welded with a second bevel gear, and the first bevel gear is meshed with the second bevel gear.

Preferably, the filler pipe has been cup jointed on the top right side of water tank, the valve has been cup jointed to the one end that the filler pipe is located the water tank outside, the water pipe that runs through and extend to in the water tank has been cup jointed at the left side top of agitator tank, the flow control valve has been cup jointed to one side that the water pipe is located the backup pad bottom, the support column has all been welded to the bottom both sides of backup pad.

Preferably, the welding of reation kettle's top inner wall has the reation kettle lid, the welding of reation kettle's both sides inner wall bottom has the grinding net, first pivot has been cup jointed at reation kettle's top, first pivot is located in reation kettle and all welds first puddler in the top and the bottom of one side, the welding of one side that first puddler is close to each other has the multiunit puddler, the puddler is the V-arrangement.

Preferably, the waste gas pipe has been cup jointed at reation kettle's left side top, the waste gas pipe runs through and extends to the top of backup pad, the one end that the waste gas pipe is located the backup pad top stretches into in the water of water tank, reation kettle's top has been cup jointed the connecting pipe, and the outer lane of the one end of reation kettle was kept away from to the connecting pipe cup joints with the bottom of agitator tank.

Preferably, a third driving wheel is welded at one end, located outside the reaction kettle, of the first rotating shaft, a first driving wheel welded at one end, located at the bottom of the supporting plate, of the third rotating shaft is in transmission connection with the third driving wheel through a second driving belt, a grinding disc is welded at one end, located in the reaction kettle, of the first rotating shaft, and a discharge hopper is welded at the bottom of the reaction kettle.

Preferably, the main steps are,

s1, firstly, starting the double-shaft motor 17, feeding the raw material for making polyester resin into the ultrasonic dispersion box 15 through the feed hopper on the left side of the top of the ultrasonic dispersion box 15, at this time, the double-shaft motor 17 drives the third rotating shaft 16 welded with the output end thereof to rotate, because the ends of the third rotating shafts 16 far away from each other are all welded with the first transmission wheels, the end of the second rotating shaft 14 positioned outside the ultrasonic dispersion box 15 is welded with the second transmission wheels, the second transmission wheels are connected with the first transmission wheels on the top end of the third rotating shafts 16 through the first transmission belts, so the third rotating shafts 16 can drive the second rotating shafts 14 to rotate, the outer ring of the end of the second rotating shaft 14 positioned inside the ultrasonic dispersion box 15 is provided with a plurality of groups of stirring rods, one end of the second rotating shaft 14 positioned inside the ultrasonic dispersion box 15 is provided with a plurality of ultrasonic dispersers 1504, the raw material is subjected to ultrasonic dispersion through the ultrasonic disperser 1504, and then the raw material is fully stirred by the third stirring rods 1502, so that it is fully mixed.

S2, the mixed raw materials flow to the bottom of the ultrasonic dispersion box 15 through the screen 1503, a through pipe is welded at the bottom of the ultrasonic dispersion box 15, the raw materials flow into the stirring box 10 through the through pipe at the bottom of the ultrasonic dispersion box 15, the raw materials flow into the stirring box 10, a flow valve is sleeved at one side of the bottom of the support plate 1 of the water pipe 11, the size of water flow is controlled by adjusting the flow valve on the water pipe 11, the water flow is adjusted to a proper water quantity, the water flows into the stirring box 10 and is fully mixed and stirred with the raw materials in the stirring box 10, and organic aqueous solution is obtained after the raw materials and the water are fully mixed.

S3, organic water solution flows into a reaction kettle 5 through a connecting pipe 9, because a heating pipe 7 is welded on the inner ring of the reaction kettle 5, a first stirring rod 19 is welded on the top and the bottom of one side in the reaction kettle 5, a plurality of groups of stirring rods 8 are welded on one side of the first stirring rod 19 close to each other, the stirring rods 8 are V-shaped, full reaction is carried out under the action of the heating pipe 7 and the stirring of the stirring rods 8, waste gas generated in the reaction is conveyed into a water tank 13 through a waste gas pipe 12 for purification, the purified gas is discharged through the water tank 13, the organic water solution is evaporated by the heating pipe 7 to obtain solid polyester resin nanometer material, the polyester resin nanometer material flows onto a grinding net 6 and is continuously ground by a grinding disc 4 for crushing, and after being filtered and screened by the grinding net 6, the machine-made resin material is discharged out of the reaction kettle 5 through a discharging hopper at the bottom of the reaction kettle 5, for later packaging and storage.

Compared with the prior art, the technical scheme of the invention has the following beneficial technical effects:

1. through installing supersound dispersion case, poking bar, screen cloth, supersound deconcentrator, double-shaft motor, pivot, poking bar isotructure, through starting double-shaft motor, the double-shaft motor output rotates and drives the pivot and rotate, and the pivot drives poking bar and rotates, under the effect of supersound deconcentrator for the raw materials that get into supersound dispersion case pass through the supersound dispersion, and the raw materials after the dispersion is being stirred through poking bar and is mixed.

2. Through installation agitator tank, water pipe, poking bar, double-shaft motor, pivot isotructure, through starting double-shaft motor, the output of pivot motor rotates and drives the pivot and rotate, and the pivot drives poking bar and rotates, then the water tank passes through the water pipe and adds water stirring in to the agitator tank, at the agitator tank of poking bar, makes raw materials and water intensive mixing, obtains organic matter aqueous solution.

3. Through installing reation kettle, heating pipe, connecting pipe, stirring rod, puddler isotructure for organic matter aqueous solution passes through the connecting pipe and enters into reation kettle, and the organic matter aqueous solution that gets into among the reation kettle is under the effect of heating pipe, and through stirring rod and puddler to its stirring that does not stop, makes organic matter aqueous solution carry out abundant reaction, obtains the polyester resin nano-material.

4. By installing the reaction kettle, the waste gas pipe, the water tank and other structures, a large amount of harmful gas can be generated when the polyester resin nano material is prepared in the reaction kettle, at the moment, the harmful gas is discharged into the water tank through the waste gas pipe, and the harmful gas discharged into the water tank from the waste gas pipe is purified by using water in the water tank, so that the damage to the environment is reduced, and the purpose of protecting the environment is achieved.

5. Through installation double-shaft motor, the apparatus further comprises a rotating shaft, a stirring rod and the like, the double-shaft motor is started, the output end of the double-shaft motor is rotated to drive the rotating shaft to rotate, the rotating shaft is rotated to drive the stirring rod and the stirring rod to rotate, under the action of the heating pipe, organic matter aqueous solution is rapidly dried, polyester resin nano materials can be obtained after drying, the polyester resin nano materials are ground and crushed through a grinding disc and a grinding net, and the packaging and the storage in the future are facilitated.

To sum up, the device design benefit, moreover, the steam generator is simple in structure, and the work efficiency is improved, the supersound deconcentrator of interpolation, the screen cloth, can make the raw materials smash and refine, the agitator tank of interpolation, can add the water stirring to the raw materials after refining, the reation kettle of interpolation, the heating pipe can react the evaporation to dewater to the polyester resin nano-material after mixing, the abrasive disc of interpolation, the grinding net grinds the crushing to the polyester resin nano-material that has produced, make things convenient for going on of work such as packing and the storage in later stage, the water tank of interpolation, waste gas pipe produced waste gas carries out purification treatment when producing polyester resin nano-material, the device facilitates the use, therefore, the clothes generator is strong in practicability, and is convenient for popularization.

Drawings

Fig. 1 is a schematic front view of a processing apparatus for polyester resin nano-materials according to the present invention.

Fig. 2 is a schematic diagram of the internal structure of an ultrasonic dispersion tank of the processing equipment for polyester resin nano-materials provided by the invention.

Fig. 3 is a schematic view of a three-dimensional structure of a grinding net of a processing device for polyester resin nano-materials according to the present invention.

Fig. 4 is a schematic diagram of the internal structure of a stirring tank of the polyester resin nano-material processing equipment provided by the invention.

Fig. 5 is a schematic structural view of a heating pipe of the processing equipment for polyester resin nano-materials according to the present invention.

Reference numerals: 1. a support plate; 2. a first rotating shaft; 3. a support pillar; 4. a grinding disk; 5. a reaction kettle; 6. grinding the net; 7. heating a tube; 8. a stirring rod; 9. a connecting pipe; 10. a stirring box; 11. a water pipe; 12. an exhaust gas pipe; 13. a water tank; 14. a second rotating shaft; 15. an ultrasonic dispersion tank; 16. a third rotating shaft; 17. a double-shaft motor; 18. a reaction kettle cover; 19. a first stirring rod; 1001. a second stirring rod; 1002. a fourth rotating shaft; 1501. an ultrasonic dispersion tank cover; 1502. a third stirring rod; 1503. screening a screen; 1504. an ultrasonic disperser.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings in conjunction with the following detailed description. It should be understood that the description is intended to be exemplary only, and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

Embodiment one, as shown in fig. 1 to 5, the polyester resin nanomaterial processing apparatus provided by the present invention comprises a supporting plate 1 and a reaction vessel 5, wherein the supporting plate 1 plays a supporting role, an ultrasonic dispersion tank 15 is welded on the top of the supporting plate 1, the dispersion tank 15 can break and disperse raw materials, an agitation tank 10 is welded on the bottom of the supporting plate 1, the agitation tank 10 plays a stirring role, a double-shaft motor 17 is fixedly installed on the right side of the top of the supporting plate 1 through bolts, the double-shaft motor 17 provides rotation power, a water tank 13 is welded on the left side of the top of the supporting plate 1, a heating pipe 7 is welded on the inner ring of the reaction vessel 5, the heating pipe 7 plays a heating role, an ultrasonic dispersion tank cover 1501 is welded on the inner wall of the top of the ultrasonic dispersion tank 15, a second rotating shaft 14 is sleeved on the top of the ultrasonic dispersion tank 15, a plurality of third stirring rods 1502 are arranged on the outer ring of the second rotating shaft 14 in the ultrasonic dispersion tank 15, third stirring rod 1502 plays the stirring effect, and a plurality of supersound deconcentrators 1504 are all installed to the one end that second pivot 14 is located supersound dispersion case 15, and the bottom welding of the both sides inner wall of supersound dispersion case 15 has screen cloth 1503, and screen cloth 1503 plays the screening effect, and the feeder hopper has been cup jointed on the top left side of supersound dispersion case 15, and the feeder hopper makes things convenient for the feeding.

In the second embodiment, the output ends of the two-shaft motors 17 are welded with third rotating shafts 16, the ends of the third rotating shafts 16, which are far away from each other, are welded with first driving wheels, the end of the second rotating shaft 14, which is located outside the ultrasonic dispersion tank 15, is welded with second driving wheels, the second driving wheels are in transmission connection with the first driving wheels at the top ends of the third rotating shafts 16 through first driving belts, the bottom of the ultrasonic dispersion tank 15 is welded with through pipes which penetrate and extend into the stirring tank 10, the left inner wall of the stirring tank 10 is in transmission connection with a fourth rotating shaft 1002 which penetrates and extends out of the stirring tank 10, the outer ring of the end, which is located at the stirring tank 10, of the fourth rotating shaft 1002 is provided with a plurality of groups of second stirring rods 1001, the second stirring rods 1001 play a stirring role, the end, which is located at the outside the stirring tank 10, is welded with a first bevel gear, the third rotating shafts 16, which are located at the bottom of the two-shaft motors 17, penetrate and extend to the bottom of the supporting plate 1, the outer ring of the third rotating shaft 16 at the bottom of the supporting plate 1 is welded with a second bevel gear, and the first bevel gear is meshed with the second bevel gear.

Embodiment three, the filler pipe has been cup jointed on the top right side of water tank 13, the filler pipe is convenient to add water to water tank 13, the valve has been cup jointed to the one end that the filler pipe is located water tank 13 outer, the water pipe 11 that runs through and extend to in water tank 13 has been cup jointed at the left side top of agitator tank 10, the flow control valve has been cup jointed to one side that water pipe 11 is located backup pad 1 bottom, support column 3 has all been welded to backup pad 1's bottom both sides, reation kettle 5's top inner wall welding reation kettle cover 18, reation kettle 5 can be better messenger's raw materials react, reation kettle 5's both sides inner wall bottom welding has grinding net 6, reation kettle 5's top has been cup jointed first pivot 2, first stirring rod 19 has all been welded to top and the bottom that first pivot 2 is located reation kettle 5 one side, the welding of first stirring rod 19 one side that is close to each other has multiunit puddler 8, puddler 8 is the V-arrangement.

Embodiment four, exhaust gas pipe 12 has been cup jointed at reation kettle 5's left side top, exhaust gas pipe 12 runs through and extends to the top of backup pad 1, the one end that exhaust gas pipe 12 is located backup pad 1 top stretches into the water of water tank 13, reation kettle 5's top has been cup jointed connecting pipe 9, the outer lane of the one end that reation kettle 5 was kept away from to connecting pipe 9 cup joints with the bottom of agitator tank 10, the one end welding that first pivot 2 is located reation kettle 5 outside has the third drive wheel, the one end welded first drive wheel that third pivot 16 is located backup pad 1 bottom is connected through the second drive belt transmission with the third drive wheel, the one end welding that first pivot 2 is located reation kettle 5 has abrasive disc 4, abrasive disc 4 and grinding mesh 6 mutually support and can smash polyester resin nano-material, make things convenient for the packing and the storage in later stage, reation kettle 5's bottom welding has out the hopper, it makes things convenient for the polyester resin nano-material to get rid of from reation kettle 5 to go out the hopper.

In the invention, firstly, starting 17, carrying raw materials for manufacturing polyester resin into 15 through a feed hopper at the left side of the top of 15, wherein the 17 drives 16 welded with the output end of the 15 to rotate, because the ends, far away from 16, of the 16 are welded with first transmission wheels, the end, located outside the 15, of the 14 is welded with a second transmission wheel, the second transmission wheel is connected with the first transmission wheel at the top end of the 16 through a first transmission belt, the 16 rotates to drive the 14 to rotate, the outer ring of the end, located inside the 15, of the 14 is provided with a plurality of groups of stirring rods, the end, located inside the 15, of the 14 is provided with a plurality of 1504, the raw materials are subjected to ultrasonic dispersion through 1504, the raw materials are fully stirred to be fully mixed, the mixed raw materials flow to the bottom of 15 through 1503, and because the bottom of the 15 is provided with a discharge hopper, raw materials flow into the pipe 10 through the through pipe at the bottom 15, in the raw materials flow into the pipe 10, because the flow regulating valve is sleeved on one side of the bottom 1 of the pipe 11, the flow regulating valve on the pipe 11 is regulated to control the size of water and regulate the water to a proper amount, so that the water flows into the pipe 10, the water and the raw materials in the pipe 10 are fully mixed and stirred, the raw materials and the water are fully mixed to obtain an organic aqueous solution, the organic aqueous solution flows into the pipe 5 through the pipe 9, because the inner ring of the pipe 5 is welded with the pipe 7, the top and the bottom of one side in the pipe 5 are welded with the pipe 19, one side of the pipe 19 which is close to each other is welded with a plurality of groups 8, the pipe 8 is V-shaped, under the action of the pipe 7 and the stirring of the pipe 8, the full reaction is carried out, and the waste gas generated in the reaction is conveyed from the pipe 12 to the pipe 13 for purification, gas after the purification will be discharged through water tank 13, and organic aqueous solution will obtain solid polyester resin nano-material under 7 evaporation, and polyester resin nano-material will flow 6 this moment on, through 4 constantly grinds, carries out the breakage, and after the filtration screening through 6, the mechanism resin material passes through (5) the bottom go out the hopper discharge 5 outside to the packing and the storage in later stage.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such changes and modifications that fall within the scope and bounds of the appended claims, or equivalents of such scope and bounds.