CN111729582A - Intelligent material mixing and distributing and quality detecting device for architectural coatings - Google Patents

Abstract

The invention discloses an intelligent material mixing, distributing and quality detecting device for building coating, which belongs to the technical field of building coating and comprises a mixing bin, a control device, a supporting frame and a material conveying pipe, wherein a film forming material bin, a pigment filling bin, a solvent bin and an auxiliary agent bin are respectively fixed above the right side of the supporting frame, the mixing pipe is respectively communicated with the film forming material bin, the pigment filling bin, the solvent bin and the auxiliary agent bin, the mixing bin is communicated with the material conveying pipe, a detecting device is arranged above the mixing bin, a discharging port is arranged below the mixing bin, the control device is respectively electrically connected with the material conveying pipe, the mixing bin, the film forming material bin, the pigment filling bin, the solvent bin, the auxiliary agent bin and the detecting device, firstly, the device can improve the generation efficiency by adopting intelligent adjustment and reduce the manpower loss, thereby reducing the product cost, secondly, and secondly, the device adopts reverse stirring inside and outside, and greatly improves the stirring, thereby saving the time cost of production.

Description

Intelligent material mixing and distributing and quality detecting device for architectural coatings

Technical Field

The invention belongs to the technical field of building coatings, and particularly relates to an intelligent material mixing, distributing and quality detecting device for building coatings.

Background

The coating is applied to the surface of an object, and the coating is a material which can be well adhered to a base material and form a complete and tough protective film, and is called building coating. Coatings are the same concept as paints. The paint is a well-established name of people, and is always utilized in the building industry after being introduced into China. The effect of the coating can be summarized in three aspects: protection, decoration and special functions. General composition of the coating: comprises film forming matter, pigment and filler, solvent and auxiliary agent.

Present simple agitator of architectural coating stirs and mixes, remaining detection and last unloading all adopt manual operation, very big consume the manpower, work efficiency does not have the machine operation height yet, lead to the indirect improvement of cost of architectural coating, consequently need a mechanical device that can intelligent management and control, can detect and independently adjust material loading, quality effectively, carry out concentrated mechanical operation, can reduce the time cost like this, the manpower cost, the qualification rate of improvement coating that again can be very big.

Disclosure of Invention

Aiming at the technical problems, the invention provides an intelligent material mixing, distributing and quality detecting device for building coatings.

An intelligent material mixing, distributing and quality detecting device for building coatings comprises a material mixing bin, a control device, a support frame and a material conveying pipe, wherein a film forming material bin, a color filling material bin, a solvent bin and an auxiliary agent bin are respectively fixed above the right side of the support frame, the material conveying pipe is respectively communicated with the film forming material bin, the color filling material bin, the solvent bin and the auxiliary agent bin, a first feeding hole is formed above the film forming material bin, a staggered sieving plate is obliquely arranged in the middle of the film forming material bin, the material mixing bin is communicated with the material conveying pipe, a detecting device is arranged above the material mixing bin and comprises a sampler and an electron microscope, a reverse material mixing barrel is arranged in the middle of the material mixing bin, grid plates are uniformly arranged on the inner wall of the reverse material mixing barrel, a circle of toothed rails is arranged on the outer wall of the reverse material mixing barrel, gears are rotatably connected to the outer sides, the control device is respectively and electrically connected with the material conveying pipe, the mixing bin, the film forming material bin, the pigment and filler bin, the solvent bin, the auxiliary agent bin and the detection device.

The staggered screening plate consists of an upper screening plate and a lower screening plate, a connecting rod is arranged at the left end of the upper screening plate and the left end of the lower screening plate, the middle of the connecting rod is movably connected with the film forming material bin, the upper end and the lower end of the connecting rod are respectively movably connected with the upper screening plate and the lower screening plate, a cam is arranged at the left end of the connecting rod, a motor I is movably connected to the rear side of the cam, and a feeding port II is arranged on the right side below the staggered screening plate.

The bottom of the film forming material bin and the bottom of the pigment and filler bin are provided with weighing devices, the right side of each weighing device is provided with a material pushing device, and materials are quantified through the weighing devices and then pushed into the conveying pipe through the material pushing devices.

The bottom of the solvent bin and the bottom of the auxiliary agent bin are both provided with a pump, the outlet of the pump is both provided with a flow velocity detector, the pump is communicated with a conveying pipe through a pipeline, the blanking speed is adjusted through the pump, and the liquid material is quantified through the flow velocity detector.

The inside screw feeder that is equipped with of conveying pipeline, screw feeder right side upper end is equipped with motor two, and motor two provides power for screw feeder, and the conveying pipeline lower surface is stainless steel material, and the upper surface is transparent resin material, carries the material through screw feeder, watches the unloading condition through transparent resin material's conveying pipeline upper surface.

The blending bunker includes agitator, motor three, and the agitator is located the inside of blending bunker, and the one end of agitator is passed through motor three and is rotated the connection, agitator and reverse blending bucket antiport, can be more effectual mix the stirring to the material.

The sampler is from stretching into the blending bunker and taking a sample, and inside the sample back shrink detection device, carry out micro analysis to the composition through electron microscope, take out the coating sample through the sampler, collect data by electron microscope again.

The control device comprises a transformer, a memory, a display, a CPU, an image processor and a controller, wherein the transformer is electrically connected with an external power supply, and provides electric energy for each electric appliance, the controller is respectively electrically connected with the first motor, the second motor, the third motor, the fourth motor and the pump, the image processor is electrically connected with the electron microscope, the CPU is respectively electrically connected with the memory, the display, the image processor, the weighing device, the flow velocity detector and the material pushing device, the controller controls the motors to rotate, the CPU analyzes the data, the CPU feeds back data through the image processor, the CPU makes intelligent adjustment, the controller is a commercial product, a first motor, a second motor, a third motor and a fourth motor all adopt 42 two-phase stepping motors, the memories adopt eRAM type memories, the CPU adopts Kurui i7 type memories, the image processor is of the Intel pentium 4670 type, and the controller is of the CAN bus 42 type.

Compared with the prior art, the invention has the beneficial effects that:

the invention adopts intelligent control to quantify materials, then carries out final sampling and data acquisition through the quality detection device, and carries out feedback on the acquired data, and the acquired data is adjusted by the CPU.

Drawings

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

FIG. 2 is a block diagram of a film forming material cartridge according to the present invention;

FIG. 3 is a block diagram of a solvent silo according to the invention;

FIG. 4 is a view showing a structure of a feed delivery pipe of the present invention;

FIG. 5 is a block diagram of the control apparatus of the present invention;

fig. 6 is a structural view of the transformer of the present invention.

Wherein, 1-mixing bin, 2-control device, 3-support frame, 4-conveying pipe, 5-feed opening, 31-film forming material bin, 32-pigment filling bin, 33-solvent bin, 34-auxiliary agent bin, 11-detection device, 311-feed opening I, 312-staggered sieving plate, 313-upper sieving plate, 314-lower sieving plate, 315-connecting rod, 316-cam, 317-motor I, 318-feed opening II, 321-weighing device, 322-material pushing device, 35-pump machine, 36-flow rate detector, 41-spiral feeder, 42-motor II, 12-stirrer, 13-motor III, 14-grid plate, 15-reverse mixing barrel, 151-rack, 152-gear, 153-motor four, 111-sampler, 112-electron microscope, 21-transformer, 22-memory, 23-display, 24-CPU, 25-image processor, 26-controller.

Detailed Description

For the convenience of understanding the embodiments of the present invention, the following further explanation is made with reference to fig. 1 to 6, and the embodiments do not limit the embodiments of the present invention.

As shown in figure 1, an intelligent mixing, distributing and quality detecting device for architectural coatings comprises a mixing bin 1, a control device 2, a support frame 3 and a material conveying pipe 4, wherein a film forming material bin 31, a pigment and filler bin 32, a solvent bin 33 and an auxiliary agent bin 34 are respectively fixed above the right side of the support frame 3, the mixing pipe is respectively communicated with the film forming material bin 31, the pigment and filler bin 32, the solvent bin 33 and the auxiliary agent bin 34, the mixing bin 1 is communicated with the material conveying pipe 4, a detecting device 11 is arranged above the mixing bin 1, a feed opening 5 is arranged below the mixing bin 1, the control device 2 is respectively electrically connected with the material conveying pipe 4, the mixing bin 1, the film forming material bin 31, the pigment and filler bin 32, the solvent bin 33, the auxiliary agent bin 34 and a detecting device 11, the detecting device 11 comprises a sampler 111 and an electronic microscope 112, the sampler 111 is extended into the mixing bin 1 for sampling, the sampling is retracted into the detecting, carry out microcosmic analysis through electron microscope 112 to the composition, take out the coating sample through sampler 111, collect data by electron microscope 112 again, blending bunker 1 includes agitator 12, motor three 13, agitator 12 is located the inside of blending bunker 1, three 13 rotations of motor are passed through to the one end of agitator 12 and are connected, the middle part of blending bunker 1 is equipped with reverse blending bunker 15, reverse blending bunker 15's inner wall evenly is equipped with grid tray 14, reverse blending bunker 15's outer wall is equipped with round rack 151, rack 151's outside is rotated and is connected with gear 152, gear 152 one end is rotated and is connected with motor four 153, agitator 12 and reverse blending bunker 15 reverse rotation, can more effectually mix the stirring to the material.

As shown in fig. 2, a first feeding hole 311 is arranged above the film forming material bin 31, a staggered screening plate 312 is obliquely arranged in the middle of the film forming material bin 31, the staggered screening plate 312 is composed of an upper screening plate 313 and a lower screening plate 314, a connecting rod 315 is arranged at the left end of the upper screening plate 313 and the left end of the lower screening plate 314, the middle of the connecting rod 315 is movably connected with the film forming material bin 31, the upper end and the lower end of the connecting rod 315 are respectively movably connected with the lower screening plate 314 of the upper screening plate 313, a cam 316 is arranged at the left end of the connecting rod 315, a first motor 317 is movably connected to the rear side of the cam 316, a second feeding hole 318 is arranged on the right side below the staggered screening plate 312, when the film forming materials are required to be subjected to particle screening, the film forming materials are added from the.

As shown in FIG. 2, weighing devices 321 are disposed at the bottoms of the film forming material bin 31 and the pigment and filler bin 32, a material pushing device 322 is disposed at the right side of the weighing devices 321, and the materials are quantified by the weighing devices 321 and then pushed into the material conveying pipe 4 by the material pushing device 322.

As shown in fig. 3, the bottoms of the solvent bin 33 and the auxiliary agent bin 34 are both provided with a pump 35, the outlets of the pump 35 are both provided with a flow rate detector 36, the pump 35 is communicated with the feed delivery pipe 4 through a pipeline, the feeding speed is adjusted through the pump 35, and the liquid material is quantified through the flow rate detector 36.

As shown in fig. 4, a screw feeder 41 is arranged inside the feed delivery pipe 4, a second motor 42 is arranged at the upper end of the right side of the screw feeder 41, the second motor 42 provides power for the screw feeder 41, the lower surface of the feed delivery pipe 4 is made of stainless steel, the upper surface of the feed delivery pipe is made of transparent resin material, the feed delivery pipe 41 is used for conveying the material, and the feeding condition is observed through the upper surface of the feed delivery pipe 4 made of the transparent resin material.

As shown in fig. 5, the control device 2 includes a transformer 21, a memory 22, a display 23, a CPU24, an image processor 25, and a controller 26, as shown in fig. 6, the transformer 21 is electrically connected to an external power source and provides power for each electrical appliance, the controller 26 is electrically connected to a motor 317, a motor 42, a motor 13, a motor 153, and a pump 35, respectively, the image processor 25 is electrically connected to the electron microscope 112, the CPU24 is electrically connected to the memory 22, the display 23, the image processor 25, the weighing device 321, the flow rate detector 36, and the material pushing device 322, respectively, the controller 26 controls the rotation of each motor, the CPU24 analyzes the data, the CPU24 makes intelligent adjustment by feeding back the data through the image processor 25, the controller 26 is a commercially available product, and the motor 317, the motor 42, the motor 13, and the motor 153 are 42 two-phase stepping motors, the memory 22 is an eRAM type memory, the CPU24 is a core i7 type memory, the image processor 25 is an Intel Pentium 4670 type memory, and the controller 26 is a CAN bus 42 type driver.

The working method of the embodiment comprises the following steps:

s1: after the device is started, when solid materials are added, the materials needing to be screened are added from the first feeding hole 311, the materials needing not to be screened are added from the second feeding hole 318, the solid materials are quantified through the weighing device 321, data are transmitted to the CPU24, the blanking speed of the solvent or the auxiliary agent is adjusted through the pump force of the pump 35, the data are collected through the flow velocity detector 36, and then the data are transmitted to the CPU 24;

s2: after being quantified, various materials enter a material conveying pipe 4, are spirally pushed to a mixing bin 1, a third motor 13 rotates to drive a stirrer 12 to rotate to stir the materials, and a fourth motor 153 drives a reverse mixing barrel 15 to reversely stir the materials;

s3, after the stirring and mixing are finished, the third motor 13 and the fourth motor 153 stop rotating, the sampler 111 samples, the electron microscope 112 collects data, the image processor 25 analyzes the data and transmits the data to the CPU24, and the CPU24 performs unified adjustment until the sampler 111 asks for a qualified sample.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some of the technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions.

Claims (8)

1. An intelligent material mixing, distributing and quality detecting device for architectural coatings is characterized by comprising a mixing bin (1), a control device (2), a support frame (3) and a material conveying pipe (4), wherein a film forming material bin (31), a pigment and filler bin (32), a solvent bin (33) and an auxiliary agent bin (34) are respectively fixed above the right side of the support frame (3), the material conveying pipe (4) is respectively communicated with the film forming material bin (31), the pigment and filler bin (32), the solvent bin (33) and the auxiliary agent bin (34), a feeding port I (311) is arranged above the film forming material bin (31), a staggered sieving plate (312) is obliquely arranged in the middle of the film forming material bin (31), the mixing bin (1) is communicated with the material conveying pipe (4), a detecting device (11) is arranged above the mixing bin (1), the detecting device (11) comprises a 111) and an electronic microscope sampler (112), and a reverse mixing barrel (15) is arranged in the middle of the mixing bin, the inner wall of reverse compounding bucket (15) evenly is equipped with grid tray (14), the outer wall of reverse compounding bucket (15) is equipped with round rack (151), the outside of rack (151) is rotated and is connected with gear (152), gear (152) one end is rotated and is connected with motor four (153), the below of blending bunker (1) is equipped with feed opening (5), controlling means (2) respectively with conveying pipeline (4), blending bunker (1), film forming material storehouse (31), face filler storehouse (32), solvent storehouse (33), auxiliary agent storehouse (34), and detection device (11) electric connection.

2. The intelligent material mixing, distributing and quality detecting device for the architectural coatings according to claim 1, characterized in that the staggered screening plate (312) consists of an upper screening plate (313) and a lower screening plate (314), a connecting rod (315) is arranged at the left end of the upper screening plate (313) and the left end of the lower screening plate (314), the middle part of the connecting rod (315) is movably connected with the film forming material bin (31), the upper end and the lower end of the connecting rod (315) are respectively movably connected with the upper screening plate (313) and the lower screening plate (314), a cam (316) is arranged at the left end of the connecting rod (315), a first motor (317) is movably connected at the rear side of the cam (316), and a second feed inlet (318) is arranged at the right side below the staggered screening plate (312).

3. The intelligent mixing, distributing and quality detecting device for architectural coatings as claimed in claim 2, wherein the bottom of the film forming material bin (31) and the pigment and filler bin (32) is provided with a weighing device (321), and the right side of the weighing device (321) is provided with a material pushing device (322).

4. The intelligent mixing, distributing and quality detecting device for architectural coatings according to claim 1, characterized in that the bottoms of the solvent bin (33) and the auxiliary agent bin (34) are respectively provided with a pump (35), the outlets of the pumps (35) are respectively provided with a flow velocity detector (36), and the pumps (35) are communicated with the material conveying pipe (4) through pipelines.

5. The intelligent mixing, distributing and quality detecting device for architectural coatings as claimed in claim 1, wherein a screw feeder (41) is arranged inside the feed delivery pipe (4), a second motor (42) is arranged at the upper end of the right side of the screw feeder (41), the second motor (42) provides power for the screw feeder (41), the lower surface of the feed delivery pipe (4) is made of stainless steel, and the upper surface is made of transparent resin.

6. The intelligent mixing, distributing and quality detecting device for the architectural coatings as claimed in claim 1, wherein the mixing bin (1) comprises a stirrer (12) and a motor III (13), the stirrer (12) is located inside the mixing bin (1), and one end of the stirrer (12) is rotatably connected through the motor III (13).

7. The intelligent mixing, dividing and quality detecting device for building coating as claimed in claim 1, wherein the sampler (111) is extended into the mixing bin (1) for sampling, and then retracted into the detecting device (11) for micro-analysis of the components by the electron microscope (112).

8. The intelligent material mixing, distributing and quality detecting device for the architectural coatings as claimed in any one of claims 1 to 7, wherein the control device (2) comprises a transformer (21), a memory (22), a display (23), a CPU (24), an image processor (25) and a controller (26), the transformer (21) is electrically connected with an external power supply and provides power for each electrical appliance, the controller (26) is electrically connected with the first motor (317), the second motor (42), the third motor (13), the fourth motor (153) and the pump (35), the image processor (25) is electrically connected with the electron microscope (112), and the CPU (24) is electrically connected with the memory (22), the display (23), the image processor (25), the weighing device (321), the flow rate detector (36) and the material pushing device (322).

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