CN210815027U

CN210815027U - Raw materials screening all-in-one of nanometer silver colloid

Info

Publication number: CN210815027U
Application number: CN201921221753.XU
Authority: CN
Inventors: 裴忠勇; 王晶
Original assignee: Huangshan Yongrui Bio Tech Co ltd
Current assignee: Huangshan Yongrui Bio Tech Co ltd
Priority date: 2019-07-30
Filing date: 2019-07-30
Publication date: 2020-06-23
Anticipated expiration: 2029-07-30

Abstract

The utility model provides a raw materials screening all-in-one of nanometer silver colloid, including upper landing plate, lower landing plate and support cylinder, the both ends symmetry of upper landing plate upper surface is equipped with former storage bucket device, two the bottom of former storage bucket device is equipped with unable adjustment base, two one side of unable adjustment base is equipped with the booster pump respectively, two the booster pump is respectively through pipe and two the lateral wall bottom of former storage bucket device is connected, four apex angle departments of upper landing plate upper surface are equipped with electric hydraulic pump one by one, the one end of lower landing plate upper surface is equipped with intelligent control ware, intelligent control ware's rear end is equipped with screening plant, screening plant keeps away from intelligent control ware's one end is equipped with the collecting tank, just the bottom of lower landing plate is equipped with from driving wheel and telescopic support leg one by one. The utility model discloses it is convenient to remove to have accurate screening, stirring and operating temperature adjustable control's advantage, make the nanometer silver colloid quality of producing improve to some extent.

Description

Raw materials screening all-in-one of nanometer silver colloid

Technical Field

The utility model relates to a technical field of nanometer silver production facility, concretely relates to raw materials screening all-in-one of nanometer silver colloid.

Background

Nano Silver (Nano Silver) is a metallic Silver simple substance with a Nano-scale particle size. The particle size of the nano silver is mostly about 25 nanometers, and the nano silver has strong inhibiting and killing effects on dozens of pathogenic microorganisms such as escherichia coli, gonococcus, chlamydia trachomatis and the like, and can not generate drug resistance. The cotton socks made of the nano silver and the combed cotton fiber have good antibacterial and deodorant effects.

The nano silver colloid is colloidal solution containing nano silver particles, the particle size of silver in the colloid is about 10nm, most of the silver particles are less than 10nm, and the nano silver particles with the size of 10nm can rapidly and directly kill bacteria by a unique antibacterial mechanism. The product is bright yellow and has good stability. The concentration is 100-1000ppm, and the product can be diluted for use.

The existing mode for producing the nano silver colloid is various, and comprises a mode of producing the nano silver by taking a silver nitrate solution as a raw material and a tannic acid solution as a reducing agent and a protective agent through reaction. Most of the equipment for preparing the nano-silver by the method has the defects of complex structure and inconvenient movement, and the nano-silver is not uniformly screened during preparation, so that the quality of the finished nano-silver colloid is not high, the silver nitrate solution and the tannic acid solution need to be mixed and stirred at a certain temperature to react, and the quality of the finished nano-silver colloid can be influenced due to the non-uniform stirring.

Therefore, it is necessary to develop a nano silver colloid production apparatus which integrates precise screening, uniform stirring and adjustable and controllable production conditions, so that the quality of the nano silver colloid is improved.

SUMMERY OF THE UTILITY MODEL

The utility model mainly provides a raw material screening all-in-one machine for nano silver colloid for solve the technical problem who proposes in the above-mentioned background art.

The utility model provides a technical scheme that above-mentioned technical problem adopted does:

a raw material screening all-in-one machine for nano silver colloid comprises an upper platform plate, a lower platform plate and four supporting columns, wherein the number of the supporting columns is four, the supporting columns are fixed at four top corners of the bottom of the upper platform plate and four top corners of the upper surface of the lower platform plate one by one, the interiors of the supporting columns are of cavity structures, and telescopic supporting legs are sleeved on a shell, penetrating through the lower platform plate, of the bottoms of the supporting columns; raw material barrel devices are symmetrically arranged at two ends of the upper surface of the upper platform plate, fixed bases are arranged at the bottoms of the two raw material barrel devices, booster pumps are respectively arranged on one sides of the two fixed bases, the two booster pumps are respectively connected with the bottoms of the side walls of the two raw material barrel devices through guide pipes, electric hydraulic pumps are arranged at four top corners of the upper surface of the upper platform plate one by one, and the electric hydraulic pumps penetrate through a shell of the upper platform plate and are correspondingly connected with the tops of the supporting columns one by one; the one end of lower landing slab upper surface is equipped with intelligent control ware, intelligent control ware's rear end is equipped with screening plant, screening plant keeps away from intelligent control ware's one end is equipped with the liquid collecting tank, the top of liquid collecting tank is run through and is equipped with level detection sensor, just the bottom of lower landing slab is equipped with from the driving wheel one by one.

Further, two raw material barrel device's casing is including outer inoxidizing coating and interior anti-corrosion coating, two raw material barrel device's top all is equipped with agitator motor, two agitator motor's output runs through in proper order outer inoxidizing coating and interior anti-corrosion coating extend to two raw material barrel device's internal connection has the puddler, two the symmetry is equipped with stirring vane one by one on the puddler.

Further, two one side of agitator motor all is equipped with infrared level sensor, two infrared level sensor's bottom is run through respectively outer inoxidizing coating extends to be connected with glass lens on the inner wall on interior anti-rotten layer, and two agitator motor keeps away from one side of infrared level sensor all is equipped with the feeding check valve, two the feeding check valve runs through respectively outer inoxidizing coating and interior anti-rotten layer extend to the internal connection of former storage bucket device has a filtration piece.

Further, the top symmetry of screening plant is equipped with the flow switch subassembly, the inside of screening plant is equipped with the mixing reaction bucket, one side of mixing reaction bucket is equipped with constant temperature equipment, constant temperature equipment's lower extreme is equipped with the screening filter, the lower extreme of screening filter is equipped with the delivery pump, just the delivery pump with the collection liquid case is connected.

Further, the mixed reaction bucket is kept away from one side of constant temperature equipment is equipped with the bracket component, bracket component from the top down is separated and is equipped with first driving motor and second driving motor, the bottom of bracket component is equipped with spring shock attenuation fixing base, just first driving motor and second driving motor's output runs through respectively the lateral wall of mixed reaction bucket extends to the internal connection of mixed reaction bucket has first stirring body and second stirring body.

Further, two the inside of flow switch subassembly is equipped with flow measurement module, and two the one end of flow switch subassembly is passed through the pipe and is connected, two the flow switch subassembly is kept away from two the one end of booster pump is equipped with the current-limiting check valve, two the current-limiting check valve passes through the pipe and runs through in proper order screening plant's top casing with the top casing of mixing the reaction bucket extends to mix the inside of reaction bucket.

Furthermore, the thermostatic device penetrates through the side wall of the mixing reaction barrel and extends to the inside of the mixing reaction barrel, a heat conduction pipe set is connected with the inside of the mixing reaction barrel, a temperature sensing module is arranged at one end, close to the thermostatic device, of the heat conduction pipe set, and the heat conduction pipe set is located in an interval of the first stirring body and the second stirring body.

Furthermore, a sedimentation isolation chamber is arranged at the bottom of the mixing reaction barrel, a filter membrane is arranged at the upper end of the sedimentation isolation chamber, and a discharge hole is formed in one side, close to the screening filter, of the mixing reaction barrel.

Further, the screening filter with the discharge gate is connected, the inside of screening filter is kept away from the one end of discharge gate is equipped with ejection of compact check valve, ejection of compact check valve with the delivery pump is connected, just the inside of screening filter is equipped with primary screening filter membrane, fine screening filter membrane and hyperfine filter membrane one by one.

Further, be equipped with the access door of running from opposite directions on screening plant's the lateral wall, four apex angles departments in screening plant's bottom are equipped with spring shock attenuation callus on the sole one by one, and are a plurality of the bottom of spring shock attenuation callus on the sole pass through the bolt with the upper surface of lower landing slab is connected.

Compared with the prior art, the beneficial effects of the utility model are that:

one of them, through upper mounting plate, lower landing plate and a plurality of support cylinder constitution stable equipment support, can carry out convenient removal from the driving wheel through a plurality of bottoms, the while during operation utilizes a plurality of electronic hydraulic pumps to make the telescopic support leg of a plurality of support cylinder bottoms and ground form the support, and a plurality of overhead follow driving wheels make equipment more firm.

Secondly, deposit raw materials silver nitrate solution and tannic acid solution respectively through two former feed cylinder devices, can stir when depositing, keep the activity of solution, avoid the material to deposit too much, and utilize intelligent control ware to make two kinds of solutions carry through two booster pumps, then utilize two flow switch subassemblies to carry out accurate proportional control after, get into the mixing reaction bucket in the screening plant, reuse two stirring bodies carry out even stirring cooperation constant temperature equipment and carry out temperature control, later utilize the screening filter to progressively sieve, thereby produce high-quality nanometer silver colloid, then collect the collecting tank with finished product nanometer silver colloid in, whole process is intelligent degree when making nanometer silver colloid production higher, control degree to production conditions is comparatively accurate, better improvement the quality of nanometer silver colloid.

The present invention will be explained in detail with reference to the drawings and specific embodiments.

Drawings

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

FIG. 2 is a schematic structural view of the raw material barrel device of the present invention;

FIG. 3 is a schematic structural view of the sieving device of the present invention;

fig. 4 is an enlarged view of a region a in fig. 3.

Reference numerals: 1. an upper deck plate; 11. a raw material barrel device; 11a, a fixed base; 11b, a stirring motor; 11b-1, a stirring rod; 11b-2, stirring blades; 11c, an infrared liquid level sensor; 11c-1, a glass lens; 11d, a feeding one-way valve; 11d-1, a filter element; 111. an outer protective layer; 112. an inner corrosion-resistant layer; 12. a booster pump; 13. an electrically-driven hydraulic pump; 2. a lower deck plate; 21. an intelligent controller; 22. a screening device; 22a, a flow switch assembly; 22a-1 and a flow-limiting one-way valve; 22a-2 and a flow metering module; 221. opening the access door in half; 222. a spring shock-absorbing foot pad; 223. mixing the reaction barrel; 223a, a filter membrane; 223b, a settling isolation chamber; 223c, a discharge hole; 224. a thermostatic device; 224a, a heat conduction pipe set; 224b, a temperature sensing module; 225. a bracket assembly; 225a, a first driving motor; 225b, a second driving motor; 225c, a first stirring body; 225d, a second stirring body; 225e, a spring shock absorption fixing seat; 226. screening the filter; 226a, primary screening the filter membrane; 226b, fine screening the filter membrane; 226c, hyperfine filtration membrane; 226d, discharge check valve; 227. a delivery pump; 23. a liquid collection tank; 23a, a liquid level detection sensor; 24. a driven wheel; 3. a support column; 31. a telescopic supporting leg.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully with reference to the accompanying drawings, in which several embodiments of the present invention are shown, but the present invention can be implemented in different forms, and is not limited to the embodiments described in the text, but rather, these embodiments are provided to make the disclosure of the present invention more thorough and comprehensive.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may be present, and when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present, as the terms "vertical", "horizontal", "left", "right" and the like are used herein for descriptive purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, and the use of the term knowledge in the specification of the present invention is for the purpose of describing particular embodiments and is not intended to limit the present invention, and the term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Please refer to fig. 1-4, which illustrates a raw material screening integrated machine for nano silver colloid, comprising an upper platform plate 1, a lower platform plate 2 and four supporting columns 3, wherein the number of the supporting columns 3 is four, the supporting columns 3 are fixed at four top corners of the bottom of the upper platform plate 1 and four top corners of the upper surface of the lower platform plate 2 one by one, the supporting columns 3 are of a cavity structure, and telescopic supporting legs 31 are sleeved on a shell of the supporting columns 3, the bottom of which penetrates through the lower platform plate 2; raw material barrel devices 11 are symmetrically arranged at two ends of the upper surface of the upper platform plate 1, fixed bases 11a are arranged at the bottoms of the two raw material barrel devices 11, booster pumps 12 are respectively arranged at one sides of the two fixed bases 11a, the two booster pumps 12 are respectively connected with the bottoms of the side walls of the two raw material barrel devices 11 through guide pipes, electric hydraulic pumps 13 are arranged at four top corners of the upper surface of the upper platform plate 1 one by one, and the electric hydraulic pumps 13 penetrate through a shell of the upper platform plate 1 and are correspondingly connected with the tops of the support columns 3 one by one; the one end of lower landing slab 2 upper surface is equipped with intelligent control ware 21, the rear end of intelligent control ware 21 is equipped with screening plant 22, screening plant 22 keeps away from the one end of intelligent control ware 21 is equipped with header tank 23, the top of header tank 23 is run through and is equipped with level detection sensor 23a, just the bottom of lower landing slab 2 is equipped with from driving wheel 24 one by one.

Please refer to fig. 2 again, the shells of the two raw material barrel devices 11 include an outer protective layer 111 and an inner corrosion-resistant layer 112, the top of each of the two raw material barrel devices 11 is provided with a stirring motor 11b, the output ends of the two stirring motors 11b sequentially penetrate through the outer protective layer 111 and the inner corrosion-resistant layer 112 and extend to the inside of each of the two raw material barrel devices 11 to be connected with stirring rods 11b-1, and the two stirring rods 11b-1 are respectively and symmetrically provided with stirring blades 11 b-2. In the embodiment, the storage conditions of the silver nitrate solution and the tannic acid solution are effectively guaranteed through the outer protective layer 111 and the inner anti-corrosion layer 112 of the two raw material barrel devices 11, and the stirring rod 11b-1 and the stirring blade 11b-2 are driven by the stirring motor 11b to stir the silver nitrate solution and the tannic acid solution, so that the silver nitrate solution and the tannic acid solution can keep high activity.

Referring to fig. 2 again, an infrared liquid level sensor 11c is disposed on each of two stirring motors 11b, bottoms of the two infrared liquid level sensors 11c respectively penetrate through the outer protective layer 111 and extend to an inner wall of the inner corrosion-resistant layer 112 to be connected with a glass lens 11c-1, a feeding one-way valve 11d is disposed on each of two sides of the two stirring motors 11b far away from the infrared liquid level sensor 11c, and the two feeding one-way valves 11d respectively penetrate through the outer protective layer 111 and the inner corrosion-resistant layer 112 and extend to the interior of the raw material barrel device 11 to be connected with a filter element 11 d-1. In this embodiment, the infrared liquid level sensor 11c measures the liquid level of the solution in the raw material barrel device 11 through the glass lens 11c-1, so as to know the dosage of the internal solution in real time, and the feeding check valve 11d is used in cooperation with the filtering member 11d-1, so that the raw material solution can be prevented from overflowing or flowing back when entering the raw material barrel device 11, and impurities in the raw material solution can be filtered.

Please refer to fig. 3 again, the top of the sieving device 22 is symmetrically provided with flow switch assemblies 22a, the inside of the sieving device 22 is provided with a mixing reaction barrel 223, one side of the mixing reaction barrel 223 is provided with a thermostatic device 224, the lower end of the thermostatic device 224 is provided with a sieving filter 226, the lower end of the sieving filter 226 is provided with a delivery pump 227, and the delivery pump 227 is connected with the liquid collecting tank 23; a bracket assembly 225 is arranged on one side of the mixing reaction barrel 223 far away from the thermostatic device 224, a first driving motor 225a and a second driving motor 225b are separately arranged on the bracket assembly 225 from top to bottom, a spring shock absorption fixing seat 225e is arranged at the bottom of the bracket assembly 225, and output ends of the first driving motor 225a and the second driving motor 225b respectively penetrate through the side wall of the mixing reaction barrel 223 to extend to the inside of the mixing reaction barrel 223 and are connected with a first stirring body 225c and a second stirring body 225 d; a flow metering module 22a-2 is arranged inside the two flow switch assemblies 22a, one end of each of the two flow switch assemblies 22a is connected with the two booster pumps 12 through a conduit, one end of each of the two flow switch assemblies 22a, which is far away from the two booster pumps 12, is provided with a flow limiting one-way valve 22a-1, and the two flow limiting one-way valves 22a-1 sequentially penetrate through the top shell of the screening device 22 and the top shell of the mixing reaction barrel 223 through conduits and extend into the mixing reaction barrel 223; the thermostatic device 224 extends through the side wall of the mixing reaction barrel 223 to the inside of the mixing reaction barrel 223, a heat conduction pipe set 224a is connected, a temperature sensing module 224b is arranged at one end of the heat conduction pipe set 224a close to the thermostatic device 224, and the heat conduction pipe set 224a is positioned in the interval between the first stirring body 225c and the second stirring body 225 d; the bottom of the mixing reaction barrel 223 is provided with a settling isolation chamber 223b, the upper end of the settling isolation chamber 223b is provided with a filter membrane 223a, and one side of the mixing reaction barrel 223 close to the sieving filter 226 is provided with a discharge hole 223 c. In this embodiment, the silver nitrate solution and the tannic acid solution are precisely metered by the flow metering modules 22a-2 in the two flow switch assemblies 22a, the mixture enters a mixing reaction barrel 223 after being opened by two flow-limiting one-way valves 22a-1 according to a specific proportion, then the heat is conducted through the heat conduction pipe set 224a on the thermostatic device 224, and the temperature sensing module 224b is matched for precise temperature control, so that the proper working temperature in the mixing reaction barrel 223 is maintained, and under the agitation of the first agitating body 225c and the second agitating body 225d in the mixing reaction tub 223 by the first driving motor 225a and the second driving motor 225b, the solution is fully and evenly stirred, so that the reaction effect of the solution is improved, meanwhile, the sedimentation isolation chamber 223b at the bottom of the mixing reaction barrel 223 can sieve out other impurities through the filter membrane 223a, the mixed solution is fed from the outlet 223c into the sieving filter 226 for sieving after the reaction is completed.

Please refer to fig. 4 again, the sieving filter 226 is connected to the discharging port 223c, a discharging check valve 226d is disposed at an end of the sieving filter 226 away from the discharging port 223c, the discharging check valve 226d is connected to the conveying pump 227, and a primary sieving filter membrane 226a, a fine sieving filter membrane 226b and a hyperfine filter membrane 226c are disposed inside the sieving filter 226 one by one. In this embodiment, the reacted solution is gradually screened by the primary screening filter 226a, the fine screening filter 226b and the hyperfine filter 226c, and then is delivered to the external header tank 23 by the delivery pump 227 through the opening of the discharge check valve 226d, thereby forming the nano silver colloid.

Please refer to fig. 1 and 3 again, a side wall of the sieving device 22 is provided with a split access door 221, four top corners of the bottom of the sieving device 22 are provided with spring shock-absorbing foot pads 222 one by one, and the bottoms of the spring shock-absorbing foot pads 222 are connected with the upper surface of the lower platform plate 2 through bolts. In this embodiment, the maintenance and repair of the equipment are facilitated by the split access door 221 on the side wall of the screening device 22, and the good shock absorption is performed for the screening device 22 by using the plurality of spring shock absorption foot pads 222, so that the working operation of the equipment is protected.

The utility model discloses a concrete operation as follows:

firstly, after silver nitrate solution and tannic acid solution are respectively injected into two raw material barrel devices 11, an intelligent controller 21 controls a stirring motor 11b on the two raw material barrel devices 11 to drive a stirring rod 11b-1 and a stirring blade 11b-2 to stir the silver nitrate solution and the tannic acid solution, then two booster pumps 12 are controlled to pump and convey the silver nitrate solution and the tannic acid solution to two flow switch assemblies 22a, the silver nitrate solution and the tannic acid solution are accurately metered by utilizing flow metering modules 22a-2 in the two flow switch assemblies 22a, the silver nitrate solution and the tannic acid solution are opened by two flow limiting one-way valves 22a-1 according to a specific proportion and then enter a mixing reaction barrel 223, then heating is carried out by a heat conducting pipe group 224a on a constant temperature device 224, and the temperature sensing module 224b is matched for accurate temperature control, so that proper working temperature in the mixing reaction barrel 223 is maintained, meanwhile, the first driving motor 225a and the second driving motor 225b on the bracket assembly 225 are controlled to drive the first stirring body 225c and the second stirring body 225d to fully and uniformly stir the silver nitrate solution and the tannic acid solution, so as to accelerate the solution mixing and reaction, and the settling compartment 223b at the bottom of the mixing reaction barrel 223 screens out other impurities through the filtering membrane 223a, and the mixed solution enters the sieving filter 226 from the discharge port 223c after the reaction is completed for sieving, the reacted solution is gradually screened by the primary screening filter 226a, the fine screening filter 226b and the hyperfine filter 226c in the screening filter 226, through the opening of the discharge check valve 226d, the liquid is delivered to the external header tank 23 by the delivery pump 227, the dosage of the nano silver colloid in the liquid collecting tank 23 is known in real time through the liquid level detection sensor 23a at the top of the liquid collecting tank 23.

The above description of the present invention is made in conjunction with the accompanying drawings, and it is obvious that the present invention is not limited by the above embodiments, and the method and the technical solution of the present invention are not substantially improved or directly applied to other occasions without improvement, and are all within the protection scope of the present invention.

Claims

1. The raw material screening all-in-one machine for the nano silver colloid comprises an upper platform plate (1), a lower platform plate (2) and supporting cylinders (3), and is characterized in that the number of the supporting cylinders (3) is four, the supporting cylinders (3) are fixed at four top corners of the bottom of the upper platform plate (1) and four top corners of the upper surface of the lower platform plate (2) one by one, the supporting cylinders (3) are of a cavity structure, and a shell sleeve, which penetrates through the lower platform plate (2), at the bottoms of the supporting cylinders (3) is provided with telescopic supporting legs (31);

raw material barrel devices (11) are symmetrically arranged at two ends of the upper surface of the upper platform plate (1), fixing bases (11a) are arranged at the bottoms of the two raw material barrel devices (11), booster pumps (12) are respectively arranged on one sides of the two fixing bases (11a), the two booster pumps (12) are respectively connected with the bottoms of the side walls of the two raw material barrel devices (11) through guide pipes, electric hydraulic pumps (13) are arranged at four top corners of the upper surface of the upper platform plate (1) one by one, and the electric hydraulic pumps (13) penetrate through a shell of the upper platform plate (1) and are correspondingly connected with the tops of the supporting columns (3) one by one;

the one end of lower landing slab (2) upper surface is equipped with intelligent control ware (21), the rear end of intelligent control ware (21) is equipped with screening plant (22), screening plant (22) are kept away from the one end of intelligent control ware (21) is equipped with header tank (23), the top of header tank (23) is run through and is equipped with level detection sensor (23a), just the bottom of lower landing slab (2) is equipped with from driving wheel (24) one by one.

2. The raw material screening all-in-one machine for nano-silver colloid as claimed in claim 1, wherein the shells of the two raw material barrel devices (11) comprise an outer protective layer (111) and an inner corrosion-resistant layer (112), stirring motors (11b) are arranged at the tops of the two raw material barrel devices (11), the output ends of the two stirring motors (11b) sequentially penetrate through the outer protective layer (111) and the inner corrosion-resistant layer (112) and extend to the insides of the two raw material barrel devices (11) to be connected with stirring rods (11b-1), and stirring blades (11b-2) are symmetrically arranged on the two stirring rods (11b-1) one by one.

3. The raw material screening all-in-one machine for nano-silver colloid according to claim 2, wherein an infrared liquid level sensor (11c) is arranged on one side of each of the two stirring motors (11b), the bottoms of the two infrared liquid level sensors (11c) respectively penetrate through the outer protective layer (111) and extend to the inner wall of the inner corrosion-resistant layer (112) to be connected with a glass lens (11c-1), a feeding one-way valve (11d) is arranged on one side, away from the infrared liquid level sensor (11c), of each of the two stirring motors (11b), and the two feeding one-way valves (11d) respectively penetrate through the outer protective layer (111) and the inner corrosion-resistant layer (112) and extend to the inner part of the raw material barrel device (11) to be connected with a filter element (11 d-1).

4. The raw material screening all-in-one machine for nano-silver colloid of claim 1, wherein flow switch assemblies (22a) are symmetrically arranged at the top of the screening device (22), a mixing reaction barrel (223) is arranged inside the screening device (22), a thermostatic device (224) is arranged on one side of the mixing reaction barrel (223), a screening filter (226) is arranged at the lower end of the thermostatic device (224), a conveying pump (227) is arranged at the lower end of the screening filter (226), and the conveying pump (227) is connected with the liquid collecting tank (23).

5. The raw material screening all-in-one machine for nano-silver colloid according to claim 4, wherein a bracket assembly (225) is arranged on one side of the mixing reaction barrel (223) far away from the thermostatic device (224), a first driving motor (225a) and a second driving motor (225b) are separately arranged on the bracket assembly (225) from top to bottom, a spring shock absorption fixing seat (225e) is arranged at the bottom of the bracket assembly (225), and output ends of the first driving motor (225a) and the second driving motor (225b) respectively penetrate through the side wall of the mixing reaction barrel (223) and extend to the inner part of the mixing reaction barrel (223) to be connected with a first stirring body (225c) and a second stirring body (225 d).

6. The integrated nano-silver colloid raw material screening machine according to claim 5, wherein the thermostatic device (224) extends through the side wall of the mixing reaction barrel (223) to the inside of the mixing reaction barrel (223) and is connected with a heat conduction pipe set (224a), one end of the heat conduction pipe set (224a) close to the thermostatic device (224) is provided with a temperature sensing module (224b), and the heat conduction pipe set (224a) is positioned in a spacing interval between the first stirring body (225c) and the second stirring body (225 d).

7. The raw material screening all-in-one machine for nano silver colloid as claimed in claim 4, wherein a flow metering module (22a-2) is arranged inside two flow switch assemblies (22a), one end of each of the two flow switch assemblies (22a) is connected with the two booster pumps (12) through a conduit, one end of each of the two flow switch assemblies (22a), which is far away from the two booster pumps (12), is provided with a flow limiting one-way valve (22a-1), and the two flow limiting one-way valves (22a-1) sequentially penetrate through a top shell of the screening device (22) and a top shell of the mixing reaction barrel (223) through conduits and extend to the inside of the mixing reaction barrel (223).

8. The integrated nano-silver colloid raw material screening machine according to claim 4, wherein a settling isolation chamber (223b) is arranged at the bottom of the mixing reaction barrel (223), a filter membrane (223a) is arranged at the upper end of the settling isolation chamber (223b), and a discharge hole (223c) is arranged at one side of the mixing reaction barrel (223) close to the screening filter (226).

9. The raw material screening all-in-one machine for nano-silver colloid according to claim 8, wherein the screening filter (226) is connected with the discharge port (223c), one end of the inside of the screening filter (226) far away from the discharge port (223c) is provided with a discharge one-way valve (226d), the discharge one-way valve (226d) is connected with the delivery pump (227), and the inside of the screening filter (226) is provided with a primary screening filter membrane (226a), a fine screening filter membrane (226b) and a hyperfine filter membrane (226c) one by one.

10. The raw material screening all-in-one machine for nano-silver colloid of claim 4, wherein a split access door (221) is arranged on the side wall of the screening device (22), spring shock absorption foot pads (222) are arranged at four top corners of the bottom of the screening device (22) one by one, and the bottoms of the spring shock absorption foot pads (222) are connected with the upper surface of the lower platform plate (2) through bolts.