CN216419170U - Processing ultralow VOC's energy-conserving speed governing dispenser of antibiotic interior wall coating - Google Patents

Abstract

The utility model discloses an antibacterial inner wall coating energy-saving speed-regulating dispersion machine for processing ultralow VOC, which comprises a cylinder body, a first dispersion mechanism and a second dispersion mechanism, wherein the two side walls of the cylinder body are respectively and fixedly connected with the first dispersion mechanism and the second dispersion mechanism, one end of the first dispersion mechanism and one end of the second dispersion mechanism both penetrate through the outer wall of the cylinder body and extend to the inside, the first dispersion mechanism comprises a material guide pipe, the antibacterial inner wall coating energy-saving speed-regulating dispersion machine for processing ultralow VOC relates to the technical field of coating processing, inner wall coating mountain flour can enter the first dispersion mechanism and the second dispersion mechanism through a material feeding hopper, the mountain flour can uniformly flow out through a material outlet under the driving of an auger blade, the flow velocity of the mountain flour can be controlled according to the rotation speed of the auger blade, the purpose of controlling the speed of the mountain flour is achieved, and the material outlets of the first dispersion mechanism and the second dispersion mechanism are all in an inclined shape, and are close to each other so that the initial mixing can be accomplished as the stone dust flows out.

Description

Processing ultralow VOC's energy-conserving speed governing dispenser of antibiotic interior wall coating

Technical Field

The utility model relates to a coating processing technology field specifically is an energy-conserving speed governing dispenser of processing ultralow VOC's antibiotic interior wall coating.

Background

The traditional name of the coating in China is paint. The coating is a continuous film which is coated on the surface of an object to be protected or decorated and can form firm adhesion with the object to be coated, and is a viscous liquid which is prepared by taking resin, oil or emulsion as a main material, adding or not adding pigments and fillers, adding corresponding auxiliaries and using an organic solvent or water.

However, one of the dispersion modes used in the production of the interior wall coating at present is manual dispersion, which consumes time and labor, causes limited yield of the interior wall coating and cannot meet the increasing market demand, and manual stirring causes raw materials to be not fully mixed and product quality to be uneven.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides a processing ultra-low VOC's energy-conserving speed governing dispenser of antibiotic interior wall coating has solved interior wall coating raw materials manual dispersion inefficiency, and the raw materials mixes the inequality and leads to product quality not good and dispenser stirring time long, can't satisfy the problem of interior wall coating production demand.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: an energy-saving speed-regulating dispersion machine for processing antibacterial inner wall coating with ultra-low VOC comprises a cylinder body, a first dispersion mechanism and a second dispersion mechanism, wherein two side walls of the cylinder body are respectively and fixedly connected with the first dispersion mechanism and the second dispersion mechanism, one ends of the first dispersion mechanism and the second dispersion mechanism penetrate through the outer wall of the cylinder body and extend to the inside, the first dispersion mechanism comprises a material guide pipe, an air channel is formed in the outer wall of the material guide pipe, a driving shaft is rotatably connected to the inside of the material guide pipe, auger blades are fixedly arranged on the outer wall of the driving shaft, one end of the driving shaft penetrates through the inner wall of the material guide pipe and is fixedly connected with a servo motor, two side walls of the material guide pipe are respectively and fixedly connected with an exhaust fan, the exhaust fans are communicated with the inside of the air channel through pipelines, one end of the material guide pipe is provided with a plurality of discharge ports and a plurality of air outlets, and the air outlets are distributed around the discharge ports in an annular array mode, and a material distributing baffle is fixedly arranged inside the discharge hole.

Furthermore, the first dispersion mechanism and the second dispersion mechanism are two components with the same structure, the cross section of the material distribution baffle plate in the X-axis direction is in a cross shape, and the air outlet is communicated with the inside of the air duct.

Furthermore, the first dispersion mechanism and the second dispersion mechanism form a fixed connection structure with the side wall of the cylinder body through the fixing frame.

Further, the top fixedly connected with motor of barrel, the drive end of motor runs through the outer wall of barrel and extends to inside, and fixedly connected with agitator.

Further, the top fixedly connected with first storage tank and second storage tank of barrel, first storage tank and second storage tank symmetric distribution are in the both sides of motor, and the feeding hopper has all been seted up at the top.

Further, the bottom fixedly connected with base of barrel, and the bottom of barrel openly has seted up the bin outlet, the bottom of first storage tank, second storage tank is equallyd divide and is linked together through the inside of conveying pipeline and first dispersion mechanism, second dispersion mechanism respectively.

Advantageous effects

The utility model provides an energy-conserving speed governing dispenser of antibiotic interior wall coating of processing ultra-low VOC.

Compared with the prior art, the method has the following beneficial effects:

1. the energy-saving speed-regulating dispersion machine for processing the antibacterial inner wall coating with ultra-low VOC comprises a cylinder body, a first dispersion mechanism and a second dispersion mechanism, wherein the two side walls of the cylinder body are fixedly connected with the first dispersion mechanism and the second dispersion mechanism respectively, one ends of the first dispersion mechanism and the second dispersion mechanism penetrate through the outer wall of the cylinder body and extend to the inside, when the device is used, inner wall coating stone powder can enter the first dispersion mechanism and the second dispersion mechanism through a feeding hopper, the stone powder can uniformly flow out through a discharge hole under the driving of an auger blade, the flow speed of the stone powder can be controlled according to the rotating speed of the auger blade, the purpose of controlling the speed of the stone powder is achieved, the discharge holes of the first dispersion mechanism and the second dispersion mechanism are inclined and close to each other, and therefore, preliminary mixing can be completed when the stone powder flows out.

2. This processing ultralow VOC's antibiotic interior wall coating energy-saving speed governing dispenser, first dispersion mechanism all are provided with the air outlet with second dispersion mechanism, when the mountain flour passes through the discharge gate and flows, highly-compressed air passes through the air outlet blowout, consequently can blow off the mountain flour that flows to make multiple mountain flour raw materials intensive mixing, the mountain flour through preliminary mixing is favorable to the further mixed dispersion work of follow-up raw materials, has shortened the production time of product, has improved work efficiency.

Drawings

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

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

fig. 3 is a schematic structural view of a first dispersing mechanism of the present invention;

fig. 4 is a schematic view of the bottom structure of the first dispersing mechanism of the present invention.

In the figure: 1. a barrel; 2. a first dispersion mechanism; 201. a material guide pipe; 202. an air duct; 203. a drive shaft; 204. a screw blade; 205. a servo motor; 206. an exhaust fan; 207. a discharge port; 208. a material distributing baffle plate; 209. an air outlet; 3. a second dispersion mechanism; 4. a fixed mount; 5. an electric motor; 6. a first material storage tank; 7. a second material storage tank; 8. a feeding hopper; 9. a base; 10. a discharge outlet; 11. a stirrer; 12. A delivery pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-2, the present invention provides a technical solution: an energy-saving speed-regulating disperser for processing antibacterial interior wall coating with ultra-low VOC comprises a cylinder body 1, a first dispersing mechanism 2 and a second dispersing mechanism 3, wherein two side walls of the cylinder body 1 are fixedly connected with the first dispersing mechanism 2 and the second dispersing mechanism 3 respectively, one ends of the first dispersing mechanism 2 and one end of the second dispersing mechanism 3 both penetrate through the outer wall of the cylinder body 1 and extend to the inside, the first dispersing mechanism 2 and the second dispersing mechanism 3 are two components with completely same structures, the cross-sectional shape of a material distribution baffle plate 208 in the X-axis direction is cross-shaped, an air outlet 209 is communicated with the inside of an air duct 202, the first dispersing mechanism 2 and the second dispersing mechanism 3 both form a fixed connection structure with the side wall of the cylinder body 1 through a fixing frame 4, the top of the cylinder body 1 is fixedly connected with a motor 5, the driving end of the motor 5 penetrates through the outer wall of the cylinder body 1 and extends to the inside, and is fixedly connected with a stirrer 11, the top fixedly connected with first storage tank 6 and the second storage tank 7 of barrel 1, first storage tank 6 and 7 symmetric distribution of second storage tank are in the both sides of motor 5, and the feeding hopper 8 has all been seted up at the top, the bottom fixedly connected with base 9 of barrel 1, and the bottom of barrel 1 has openly seted up bin outlet 10, the bottom of first storage tank 6, second storage tank 7 is equallyd divide and is linked together through conveying pipeline 12 and first dispersion mechanism 2, the inside of second dispersion mechanism 3 respectively.

Referring to fig. 3-4, the first dispersing mechanism 2 includes a material guiding pipe 201, an air duct 202 is formed in an outer wall of the material guiding pipe 201, a driving shaft 203 is rotatably connected inside the material guiding pipe 201, an auger blade 204 is fixedly disposed on an outer wall of the driving shaft 203, one end of the driving shaft 203 penetrates through an inner wall of the material guiding pipe 201 and is fixedly connected with a servo motor 205, exhaust fans 206 are fixedly connected to two side walls of the material guiding pipe 201, the exhaust fans 206 are communicated with the inside of the air duct 202 through pipelines, a material outlet 207 and a plurality of air outlets 209 are formed in one end of the material guiding pipe 201, the air outlets 209 are distributed around the material outlet 207 in an annular array manner, and a material separating baffle 208 is fixedly disposed inside the material outlet 207.

When in use, firstly, stone dust raw materials are put into the first storage tank 6 and the second storage tank 7 through the feeding hopper 8, different stone dust respectively enters the first dispersion mechanism 2 and the second dispersion mechanism 3 through the feeding pipe 12 under the action of gravity, the servo motor 205 drives the driving shaft 203 to rotate, thereby driving the auger blade 204 to push the stone dust to flow out of the material guiding pipe 201 through the material outlet 207, at the moment, the exhaust fan 206 sucks external air into the air guiding duct 202 and blows out the air through the plurality of air outlets 209, the stone dust is blown away under the action of wind power, the bottoms of the first dispersion mechanism 2 and the second dispersion mechanism 3 are both inclined and close to each other, therefore, the blown stone dust can be fully mixed together, when the mixed and floated stone dust falls on the bottom of the barrel body 1 under the action of gravity, the motor 5 drives the stirrer 11 to stir and mix the primarily mixed stone dust again, so that various raw materials can be fully dispersed, and the device can set up a plurality of different storage tanks and dispersion mechanism according to the required raw materials kind of interior wall coating production, satisfies the purpose that multiple raw materials dispersed mixture.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides an energy-conserving speed governing dispenser of antibiotic interior wall coating of processing ultralow VOC, includes barrel (1), first dispersion mechanism (2) and second dispersion mechanism (3), the both sides wall difference fixedly connected with first dispersion mechanism (2) and second dispersion mechanism (3) of barrel (1), the outer wall that barrel (1) was all run through and extend to inside, its characterized in that with the one end of second dispersion mechanism (3) in first dispersion mechanism (2): the first dispersion mechanism (2) comprises a material guide pipe (201), an air channel (202) is arranged in the outer wall of the material guide pipe (201), a driving shaft (203) is rotatably connected inside the material guide pipe (201), a packing auger blade (204) is fixedly arranged on the outer wall of the driving shaft (203), one end of the driving shaft (203) penetrates through the inner wall of the material guiding pipe (201) and is fixedly connected with a servo motor (205), two side walls of the material guide pipe (201) are fixedly connected with exhaust fans (206), the exhaust fan (206) is communicated with the inside of the air duct (202) through a pipeline, one end of the material guide pipe (201) is provided with a material outlet (207) and a plurality of air outlets (209), the air outlets (209) are distributed around the discharge hole (207) in an annular array manner, and a material distributing baffle plate (208) is fixedly arranged in the discharge hole (207).

2. The energy-saving speed-regulating dispersion machine for processing the antibacterial inner wall coating with ultra-low VOC according to claim 1, characterized in that: the first dispersion mechanism (2) and the second dispersion mechanism (3) are two components with the same structure, the cross section of the material distribution baffle (208) in the X-axis direction is in a cross shape, and the air outlet (209) is communicated with the inside of the air duct (202).

3. The energy-saving speed-regulating dispersion machine for processing the antibacterial inner wall coating with ultra-low VOC according to claim 1, characterized in that: the first dispersion mechanism (2) and the second dispersion mechanism (3) form a fixed connection structure with the side wall of the cylinder body (1) through the fixing frame (4).

4. The energy-saving speed-regulating dispersion machine for processing the antibacterial inner wall coating with ultra-low VOC according to claim 1, characterized in that: the top fixedly connected with motor (5) of barrel (1), the drive end of motor (5) runs through the outer wall of barrel (1) and extends to inside, and fixedly connected with agitator (11).

5. The energy-saving speed-regulating dispersion machine for processing the antibacterial inner wall coating with ultra-low VOC according to claim 4, characterized in that: the top fixedly connected with first storage tank (6) and second storage tank (7) of barrel (1), first storage tank (6) and second storage tank (7) symmetric distribution are in the both sides of motor (5), and feeding hopper (8) have all been seted up at the top.

6. The energy-saving speed-regulating dispersion machine for processing the antibacterial inner wall coating with ultra-low VOC according to claim 5, characterized in that: the bottom fixedly connected with base (9) of barrel (1), and the bottom of barrel (1) openly has seted up bin outlet (10), the bottom of first storage tank (6), second storage tank (7) is equallyd divide and is linked together through the inside of conveying pipeline (12) with first dispersion mechanism (2), second dispersion mechanism (3) respectively.

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