CN107837941B - Colloid mill funnel mechanism with classifier - Google Patents

Abstract

The invention discloses a belt grading machine the colloid mill funnel mechanism of the device, comprises a funnel body, a classifier, a lapping pipeline and a classifying connecting pipe; the funnel body a discharge hole is arranged on the utility model, the lower end of the side wall of the funnel body is provided with a lapping inlet; the classifier comprises a classifier shell, a finished product discharge pipeline and a classifying mechanism, one end of the finished product discharge pipe is inserted from the bottom of the classifier shell and extends upwards; the two ends of the grading connecting pipe are respectively provided with a connecting pipe inflow port and a connecting pipe outflow port, the connecting pipe inflow port is communicated with a discharge port of the grinding mechanism, and the connecting pipe outflow port is arranged in the grader; one end of the lapping pipeline is connected with the lower end of the side wall of the classifier shell, and the other end of the lapping pipeline is connected to the lower end of the side wall of the funnel body; the grading mechanism is used for grading the materials to reach the standard the material is discharged from the finished product discharge pipeline, and the materials which do not reach the standard flow back to the funnel body from the grinding return pipeline.

Description

With classifier colloid mill funnel mechanism

Technical Field

The invention relates to the field of machinery, in particular to a colloid mill funnel mechanism with a classifier.

Background

The colloid mill is a common dispersing and grinding device in the industries of food, chemical industry, medicine, building materials and the like, and particularly a common colloid mill for building paint factories to grind materials.

The traditional colloid mill main body part comprises a shell, a stator, a rotor, an adjusting mechanism, a cooling mechanism, a motor and the like. The shell is provided with a hopper, and the bottom of the shell is provided with two channels, a discharge hole and a return hole. When the materials are ground, the materials are added into a colloid mill containing funnel, a discharging hole is closed, a motor is started, the materials start to be ground, the materials are pumped into the reflux containing funnel from a feed back hole while being ground, and enter the colloid mill again together with the materials which are not ground in the containing funnel for grinding, so that the materials are circularly ground for many times until the materials are ground to the required fineness, the discharging hole is opened, and the materials are discharged.

The material lacks the classifying function in the existing colloid mill funnel, can only be quantitatively ground once and once, and cannot be continuously produced. The materials with the fineness reaching the standard can be easily ground repeatedly and do idle work. And the materials which do not reach the standard are discharged to a finished product area due to grinding missing.

Disclosure of Invention

In order to overcome the defects and shortcomings of the prior art, the invention discloses a colloid mill funnel mechanism with a classifier, which comprises a funnel body, a classifier, a grinding return pipeline and a classifying connecting pipe; the hopper body is provided with a discharge hole, and the lower end of the side wall of the hopper body is provided with a lapping flow inlet; the classifier comprises a classifier shell, a finished product discharge pipeline and a classifying mechanism, wherein one end of the finished product discharge pipeline is inserted from the bottom of the classifier shell and extends upwards; the two ends of the grading connecting pipe are respectively provided with a connecting pipe inflow port and a connecting pipe outflow port, the connecting pipe inflow port is communicated with a discharge port of the grinding mechanism, and the connecting pipe outflow port is arranged in the grader; one end of the lapping pipeline is connected with the lower end of the side wall of the classifier shell, and the other end of the lapping pipeline is connected to the lower end of the side wall of the funnel body; and the classifying mechanism discharges classified materials reaching standards from the finished product discharge pipeline, and materials not reaching standards flow back to the funnel body from the lapping pipeline.

Further, the classifying mechanism comprises a speed regulating motor and a classifier rotating piece, and the classifier rotating piece is sleeved outside the finished product discharge pipeline; the upper end of the classifier rotating piece is connected with the speed regulating motor, and the speed regulating motor can drive the classifier rotating piece to rotate by taking the finished product discharge pipeline as an axis.

Further, the upper end of the finished product discharge pipeline is provided with a water leakage hole.

Further, the outer wall of the finished product discharge pipeline is provided with a classifier fixed ceramic bearing, and the lower end of the classifier rotating piece is clamped on the fixed ceramic bearing.

Further, the classifier rotating piece is in a conical cylinder shape, and the diameter of the classifier rotating piece is gradually reduced from top to bottom.

Further, the connecting pipe outflow port is located above the classifier rotary blade.

Further, a guide vane is arranged on the inner wall of the classifier shell.

Further, the guide vane is a spiral guide vane.

Further, a one-way valve is arranged in the lapping pipeline, and the flow direction of the one-way valve is set to flow from the classifier shell to the funnel body.

Further, a strong magnetic filter is arranged at the discharge hole of the funnel body.

According to the colloid mill funnel mechanism with the classifier, the classifier with the classifying function is used for classifying the ground materials, and the materials which do not reach the standard are sent back to the funnel body to be ground again. The classification range can be adjusted, and the classification size of the classifier can be adjusted according to the grinding of different material concentrations, so that the classification purpose is realized. The classifier has no screen design and does not need to be cleaned midway. The colloid mill can realize the purpose of continuous production.

For a better understanding and implementation, the present invention is described in detail below with reference to the drawings.

Drawings

Fig. 1 is a schematic diagram of the present invention.

Fig. 2 is an enlarged schematic view of the grinding mechanism of the present invention.

Detailed Description

Referring to fig. 1 and 2, an ultrafine colloid mill device of the present invention includes a base 10, a driving mechanism, a grinding mechanism and a colloid mill funnel with a classifier, which are disposed on the base 10, wherein the colloid mill funnel with the classifier includes a colloid mill funnel, a classifier, a classifying connection pipe 15 and a grinding return pipe 16. The colloid mill funnel is arranged above the grinding mechanism, the driving mechanism can transmit power to the grinding mechanism, and the classifier is respectively connected with the colloid mill funnel and the grinding mechanism. The discharge gate of colloid mill funnel with grinding mechanism's feed inlet links to each other, grinding mechanism's discharge gate with the one end of classifying connection pipe 15 links to each other, classifying connection pipe 15's the other end intercommunication to the classifier, return the both ends of grinding pipeline 16 to be connected to respectively colloid mill funnel with the classifier. The two ends of the classifying connecting pipe 15 are respectively provided with a connecting pipe inflow port and a connecting pipe outflow port 151, the connecting pipe inflow port is communicated with a discharge port of the grinding mechanism, and the connecting pipe outflow port 151 is arranged in the classifier.

The drive mechanism includes a drive motor 11, a pulley 12, a belt 13, and a drive shaft 14. The output shaft of the driving motor 11 is connected with the belt pulley 12 through a belt 13, and the belt pulley 12 is fixed on the driving shaft 14, so that the driving shaft 14 is driven to rotate through the belt pulley 12. The drive shaft 14 is inserted into the grinding mechanism from below the grinding mechanism.

The colloid mill funnel comprises a funnel body 21, a funnel rotating piece 22, a spiral guide piece 23, a water inlet 24, a V-shaped protective cover 25 and a strong magnetic filter 26. The lower extreme of funnel body 21 is provided with the discharge gate, V-arrangement protective cover 25 sets up the top surface of funnel body 21 guarantees the security of machine during operation guarantee staff. The spiral guide vane 23 is arranged on the inner wall of the funnel body 21, and the spiral guide vane 23 extends from the upper end of the inner wall of the funnel body 21 along a spiral shape to the discharge port of the funnel body 21. The water inlet 24 is arranged at the upper end of the side wall of the funnel body, the water inlet 24 and the spiral guide vane 23 are in the same direction, and the water inlet 24 is connected with a liquid interface which needs to be ground outside or directly connected with tap water. The funnel rotating piece 22 is disposed in the funnel body 21, and the funnel rotating piece 22 can rotate by being externally connected with a power source. The strong magnetic filter 26 is arranged on the outer wall of the lower end discharge hole of the funnel body 21, and when iron filings are mistaken, the iron filings are sucked by strong magnetism, so that the grinding disc is prevented from being damaged. In this embodiment, the funnel rotary piece 22 in the funnel body is a triangular rotary piece, and the width of the funnel rotary piece 22 gradually decreases from top to bottom. The rotation direction of the funnel rotation piece 22 is the same as the extending direction of the spiral guide piece 23, and a lapping flow inlet 27 for material backflow is arranged at the lower end of the side wall of the funnel body 21. The funnel rotating piece 22 is connected with a screw.

According to the colloid mill funnel mechanism with the classifier, the classifier with the classifying function is used for classifying the ground materials, and the materials which do not reach the standard are sent back to the funnel body to be ground. The colloid mill funnel utilizes the funnel rotary piece that can the rotation to accelerate the flow of material in the funnel, and the spiral water conservancy diversion piece can let the material keep certain track to slide simultaneously, makes the discharge gate be difficult for crowding. The colloid mill funnel utilizes the funnel rotary piece that can the rotation to drive the material and rotates at the vortex formula in the funnel, and spiral water conservancy diversion piece can let the material keep certain track to carry out the vortex formula slip simultaneously to produce a centrifugal force around, make in the material of water, solid, large granule, liquid etc. in the material mixture of the needs of adding the funnel: the larger-particle materials, the heavier materials and the solid materials can be preferentially transferred to the bottom of the funnel under the action of the rotating centrifugal force and the action of the spiral guide vane, so that the materials preferentially enter the millstone area for grinding, and the function of preferentially grinding after grading is achieved. The grinding efficiency and useful work required by the grinding area are directly improved. The idle work of repeated grinding of the ground materials is greatly reduced. When the floating objects or the foam are added into the funnel, the floating objects or the foam can be preferentially rolled into the bottom of the funnel under the action of vortex force, so that the fish which cannot be ground out and leak out of the net can be reduced.

The funnel rotating piece 22 is inserted from the outlet of the lower end of the funnel body 21 and protrudes upwards, the funnel rotating piece 22 is located on the central axis of the spiral guide piece 23, the lower end of the funnel rotating piece 22 is connected with the driving shaft 14, and the driving mechanism can drive the funnel rotating piece 22 to rotate on the central axis of the spiral guide piece 23. The funnel rotating piece 22 is connected with a screw, and a spiral pushing piece is arranged at the position of a funnel feeding hole around the lower surface of the screw. The spiral pushing piece is configured to have the following functions: when the ground material and water material enter the funnel (whether the material is floatable solid or coarser and denser level liquid or foam-generating liquid), the material can be accelerated to be screwed into the primary grinding device for grinding under the action of inertia and the action of the spiral guide vane 23 on the inner wall of the funnel under the action of the funnel rotating sheet 22, so that the situation that the material does not enter a grinding area timely and effectively after being put into the funnel can be avoided.

The grinding mechanism comprises a grinding shell, a plurality of static grinding discs and a plurality of movable grinding discs, grinding teeth are arranged on the outer surface of each movable grinding disc and the inner surface of each static grinding disc, each static grinding disc is arranged on the corresponding inner wall of the grinding shell, each movable grinding disc is arranged in the corresponding static grinding disc, a certain gap is reserved between each static grinding disc and each movable grinding disc, each movable grinding disc is connected with the corresponding driving mechanism, and the driving machine drives each movable grinding disc to rotate. The material flows from the gap between the stationary and moving discs and is ground. The driving shaft 14 passes through the movable millstone and is fixed relative to the movable millstones, so that the driving shaft 14 drives the movable millstone to rotate. The grinding mechanism is divided into a first grinding area, a second grinding area, a third grinding area, a fourth grinding area and a fifth grinding area which are arranged from top to bottom.

The first grinding zone comprises a first grinding zone housing 35, a first primary static grinding disc 31, a first primary movable grinding disc 32, a first secondary static grinding disc 33 and a first secondary movable grinding disc 34 which are arranged in the first grinding zone housing 35. The first primary static grinding disc 31 is arranged on the first secondary static grinding disc 33, and the first primary movable grinding disc 32 is arranged on the first secondary movable grinding disc 34. The first grinding area mainly plays a role in primary breaking and rough grinding on materials, and can primarily destroy and crush the materials.

The first-stage static grinding disc 31 is anti-sawtooth line straight grinding teeth, the grinding teeth number of each circle is not less than 60, the first-stage movable grinding disc 32 is positive sawtooth 25-degree left-hand helical teeth, diamonds are plated on the first-stage static grinding disc 31 and the first-stage movable grinding disc 32, the first-stage static grinding disc 31 is fixed on the first grinding zone shell 35, and the first-stage movable grinding disc 32 is arranged on a main shaft. The first primary static grinding disc 31 and the first primary movable grinding disc 32 have a distance of 10-20 wires, and are never contacted with each other.

The first secondary static grinding disc 33 is provided with square teeth, the number of teeth of each circle is not less than 60, the front angle of each square tooth is minus 10 degrees, the square teeth are provided with a plurality of cross flow grooves, and the cross flow grooves are arranged into square block diagonal stripe shapes. The staggered groove is inclined at 2 degrees to the right. The first secondary movable millstone 34 is a cylindrical milling cutter tooth, the number of teeth of each circle is not less than 60, the front angle of the cylindrical milling cutter tooth is minus 15 degrees, and the front angle of the cylindrical milling cutter tooth is a 25-degree left inclined spiral tooth. The first secondary stationary grinding disc 33 is fixed on the first grinding zone housing 35, and the first secondary movable grinding disc 34 is mounted on the first primary movable grinding disc 32. The distance between the first secondary static grinding disc 33 and the first secondary movable grinding disc 34 is 4-6 wires, and the first secondary static grinding disc and the first secondary movable grinding disc are never contacted with each other.

The first grinding area has the advantages of strong initial breaking force, large cutting amount and good rough grinding effect, and enables the ground materials to generate strong downward flowing force, when the grinding discs interact, the three-way knife edge is cut in a closed mode, a grabbing cutting principle is generated, the ground materials cannot slip in the cutting process, the materials are effectively ground through different tooth shapes and front and rear angles of the set grinding teeth, the ground materials are continuously baffled and rolled on the grinding teeth, the ground materials can be sheared at different angles, the shearing opportunities are not missed easily due to baffling and rolling in the shearing process, the grinding efficiency is improved, and the grinding efficiency is higher and more sufficient. The temperature generated in the grinding process can not exceed 50 degrees, and the grinding requirement of customers on special materials is met. The grinding disc has super-strong hardness and is not easy to wear.

The second grinding zone is a second ceramic bearing set 41, and the second ceramic bearing set 41 is also located in the first grinding zone housing 35. The driving shaft 14 passes through the second ceramic bearing group 41, the second ceramic bearing group 41 is formed by stacking two full-bead ceramic bearings up and down, wherein oil seals are arranged at two ends of the lower full-bead ceramic bearing, the lower ceramic bearing plays a role in stabilizing the position of the driving shaft 14, and meanwhile, the upper ceramic bearing can roll materials passing through bearing balls in the process of flowing materials from top to bottom. The bearing is full beads, and the material is a corrosion-resistant zirconia material. When the materials pass, the bearing beads rotate at a high speed and rub with each other. The ground material is effectively rolled and rubbed, the geometry of the material from the previous stage is changed, and the ground material is prepared for entering the grinding area of the next stage to be sheared more fully.

The third grinding zone comprises a third grinding zone shell 55, a third primary static grinding disc 51, a third primary movable grinding disc 52, a third secondary static grinding disc 53 and a third secondary movable grinding disc 54 which are arranged in the third grinding zone shell 55. The third-stage static grinding disc 51 is arranged on the third-stage second-stage static grinding disc 53, and the third-stage movable grinding disc 52 is arranged on the third-stage second-stage movable grinding disc 54. The third grinding area plays roles of fine grinding and fine grinding emulsification on materials. The third grinding section shell 55 and the cylindrical barrel 61 are fixedly connected together by the connecting locking nut 43.

The third-stage static grinding disc 51 is formed by processing sharp-angle reverse-surface-shaped teeth, the number of teeth of each circle is not less than 90, the width of each sharp-angle reverse-surface-shaped tooth groove is not more than 1.5mm, and the total height of each sharp-angle reverse-surface-shaped tooth groove is not more than 1.5mm. The front angle on the teeth is minus 10 degrees, the upper and lower sharp corner reverse surface shape teeth are arranged to be right inclined by 2 degrees, and form a sharp corner reverse surface groove, and a plurality of sharp corner reverse surface grooves are arranged to be right inclined strip shape of the lightning sign reverse surface shape. The total length of the shape of the right diagonal stripe of the reverse surface shape of the lightning mark is at least more than or equal to 30mm.

The third-stage movable millstone 52 is formed by processing sharp-angle reverse-surface-shaped teeth, the number of teeth of each circle is not less than 90, the width of each sharp-angle reverse-surface-shaped tooth groove is not more than 1.5mm, and the total height of each sharp-angle reverse-surface-shaped tooth groove is not more than 1.5mm. The front angle on the teeth is minus 10 degrees, the upper and lower sharp corner reverse surface shape teeth are arranged to be left inclined by 25 degrees, and form a sharp corner reverse surface groove, and a plurality of sharp corner reverse surface grooves are arranged to be left inclined strip shape of a lightning sign reverse surface shape. The total length of the shape of the right diagonal stripe of the reverse surface shape of the lightning mark is at least more than or equal to 30mm.

The third-stage static grinding disc 51 is mounted on the third grinding zone housing 55, and the third-stage movable grinding disc 52 is mounted on the main shaft. The third-stage movable grinding disc 52 and the third-stage static grinding disc 51 are not contacted with each other, and the distance between the two is 3-4 wires. The arrangement between the first-stage static grinding disc and the movable grinding disc of the third grinding area has a strong grabbing and cutting function, is not easy to slip, and continuously turns into a sharp-angle reverse side shape after grabbing and cutting, so that the ground material is continuously turned over, and the ground material is forced to be fully cut from different geometric angles. The number of cuts is greatly increased, up to millions of times per minute. When the ground material passes through the gap between the grinding discs, the ground material is subjected to the physical actions of strong shearing force, friction force, high-frequency vibration, high-speed vortex, high-speed impact and the like, and the fineness of the ground material can reach 4um level at most.

The lower ceramic bearings in the second ceramic bearing set 41 and the fourth ceramic bearing set 42 play a role in assembling and fixing the driving shaft 14, and the second grinding area and the fourth grinding area are formed by stacking two full-bead ceramic bearings up and down, wherein the lower ceramic bearings play a role in fixing, the two ends of the bearings are provided with oil seals, and the upper ceramic bearings play a role in rolling. And the second grinding area and the fourth grinding area are full-bead ceramic bearings.

The third-stage static grinding disc 51 and the third-stage movable grinding disc 52 do not rub each other when working, the temperature rise can be controlled within 10 ℃, and the heat generated by materials and the grinding discs and the heat released by the materials can permeate water or the ground liquid can quickly enter the next grinding area.

The second grinding disc of the third grinding area mainly plays a role of fine grinding and emulsification.

The third-stage static grinding disc 53 is made of saw teeth, the number of teeth in each circle is not less than 100, the width of each saw tooth groove is less than or equal to 1.5mm, and the total height of each zigzag tooth groove is less than or equal to 1.5mm. The front angle on the teeth is positive 10 degrees, the upper and lower saw teeth are arranged to incline to the right by 2 degrees, saw teeth staggered arrangement grooves are formed, and a plurality of saw grooves are staggered to form a right inclined strip shape. The total length of the staggered sawtooth bar shape is at least more than or equal to 30mm.

The third second-stage movable millstone 54 is made of saw teeth, the number of teeth in each circle is not less than 100, the width of each saw-shaped tooth groove is less than or equal to 1.5mm, and the total height of each saw-shaped tooth groove is less than or equal to 1.5mm. The front angle on the teeth is positive 10 degrees, the upper and lower saw teeth are arranged in staggered arrangement, and staggered grooves are formed, and the total length of the grooves is at least more than or equal to 30mm.

The third second-stage static grinding disc 53 is mounted on a third grinding zone housing 55, and the third second-stage movable grinding disc 54 is mounted on the main shaft. The third second-stage movable grinding disc 54 and the third second-stage static grinding disc 53 are not contacted with each other, and the distance between the two is 3-4 wires. The grinding of the third second-stage static grinding disc 53 and the third second-stage movable grinding disc 54 has a strong grabbing and cutting function, is not easy to slip, has continuous baffling after grabbing and cutting, continuously overturns the ground material, and forces the ground material to be fully cut from different geometric angles. The number of cuts is greatly increased, up to millions of times per minute. When the ground material passes through the gap between the grinding discs, the ground material is subjected to physical effects such as strong shearing force, friction force, high-frequency vibration, high-speed vortex, high-speed impact and the like, and has super-strong wall breaking and emulsification effects on the ground material (the main purpose), and meanwhile: the fineness of the ground materials can reach 3um level at most under the functions of dispersing, homogenizing, crushing, stirring, grinding and the like, and the temperature rise can be controlled within 15 ℃ during working.

The fourth grinding zone is a fourth ceramic bearing set 42, and the fourth ceramic bearing set 42 is also located in the first grinding zone housing 35. The driving shaft 14 passes through the fourth ceramic bearing group 42, the fourth ceramic bearing group 42 is formed by stacking two full-bead ceramic bearings up and down, wherein oil seals are arranged at two ends of the lower full-bead ceramic bearing, the lower ceramic bearing plays a role in stabilizing the position of the driving shaft 14, meanwhile, the upper ceramic bearing can roll materials passing through bearing balls in the process of flowing materials from top to bottom, and the oil seals are arranged at two ends of the lower ceramic bearing.

The fifth grinding zone is a sand grinder, and comprises a cylindrical barrel body 61, a rotary wheel 62, grinding beads 63, an upper filtering cover plate 64 and a lower filtering cover plate 65. The upper filtering cover plate 64 is arranged at the upper end of the cylindrical barrel body 61, the lower filtering cover plate 65 is arranged at the lower end of the cylindrical barrel body 61, and materials flow into the cylindrical barrel body 61 from the upper filtering cover plate 64 after being ground in the fourth grinding area. The driving shaft 14 passes through the lower filtering cover plate 65, the cylindrical barrel body 61 and the upper filtering cover plate 64 from bottom to top, the rotating wheel 62 is positioned in the cylindrical barrel body 61 and sleeved on the driving shaft 14, the rotating wheel 62 can rotate along with the rotation of the driving shaft 14, and the grinding beads 63 are arranged between the rotating wheel 62 and the cylindrical barrel body 61. The rotating wheel 62 can drive the grinding beads 63 to move when rotating, and collision friction between the grinding beads 63 can further generate a grinding effect on materials. The outer surface of the rotating wheel 62 is provided with grooves 621, and the movement of the grinding beads 63 can be further increased by the irregularities of the surface of the rotating wheel 62. The rotating wheel 62 is a zirconia ceramic rotating wheel 62. A central shaft-fixing ceramic bearing 44 is provided between the upper filter cover plate 64 and the fourth grinding zone. The cylindrical barrel 61, the rotating wheel 62, the upper filter cover plate 64 and the lower filter cover plate 65 are all made of zirconia ceramics, and the grinding beads 63 are made of zirconia. The material is ground in the fifth grinding area, so that the material with very high fineness is ground again from the fourth grinding area, the effect of ultra-micro melting is realized, and the fineness of the material can reach the level of 2um at most.

The grinding mechanism is connected with the classifier through a classifying connecting pipe 15 and a lapping pipeline 16. The lower part of the lower filter cover 65 of the fifth grinding zone is connected to the inflow port of the classifying connection pipe 15, and the connection pipe outflow port 151 of the classifying connection pipe 15 is connected to the classifier.

The classifier comprises a classifier shell 72, a finished product discharge pipeline 73 and a classifying mechanism, wherein the classifying mechanism discharges classified qualified materials from the finished product discharge pipeline 73, and unqualified materials flow back to the funnel body 21 from the lapping pipeline 16. The classifying mechanism comprises a speed regulating motor 71 and a classifier rotating sheet 74, an outflow opening of the classifying connecting pipe 15 is arranged in the classifier shell 72, and a spiral guide sheet is arranged on the inner wall of the classifier shell 72. The classifier housing 72 is funnel-shaped, one end of the finished product discharge pipe 73 is inserted from the bottom of the classifier housing 72 and extends upwards, a classifier fixed ceramic bearing 76 is arranged on the outer wall of the finished product discharge pipe 73, a classifier rotating piece 74 is sleeved outside the finished product discharge pipe 73, the lower end of the classifier rotating piece 74 is clamped on the classifier fixed ceramic bearing 76, the upper end of the classifier rotating piece 74 is connected with the speed regulating motor 71, and the speed regulating motor 71 can drive the classifier rotating piece 74 to rotate by taking the finished product discharge pipe 73 as an axis. The upper end of the product discharge pipe 73 is provided with a water leakage hole 731, and in this embodiment, the product discharge pipe 73 is provided with a water leakage hole 731 at a portion above the classifier fixed ceramic bearing 76. The connection pipe outflow port 151 of the classifying connection pipe 15 is located above the classifier rotation sheet 74. In this embodiment, the classifier rotation piece 74 has a conical cylindrical shape, and its diameter gradually decreases from top to bottom. The connection pipe outflow port 151 is located above the classifier rotation sheet 74.

One end of the lapping pipeline 16 is connected with the lower end of the side wall of the classifier housing 72, the other end of the lapping pipeline 16 is connected to the lower end of the side wall of the funnel body 21, a one-way valve 161 is arranged in the lapping pipeline 16, and the flow direction of the one-way valve 161 is set to flow from the classifier housing 72 to the funnel body 21. A purge outlet 45 is also provided below the grinding mechanism, the purge outlet 45 being connected to the classifying connection pipe 15, the purge outlet 45 being openable and closable.

The materials are poured into the colloid mill funnel, guided by the spiral guide vane 23, filtered by the strong magnetic filter 26, and then flow into the grinding mechanism from the bottom end of the colloid mill funnel, are ground from top to bottom by five grinding areas of the grinding mechanism, finally flow into the grading connecting pipe 15, flow into the grader by the grading connecting pipe 15, and the grader speed regulating motor 71 drives the grader rotating sheet 74 to rotate. Larger material particles are thrown out of the classifier rotating plate 74 due to centrifugal force, and then flow downwards from the inner wall of the classifier shell 72 to the lapping pipeline 16 preferentially according to the spiral guide plate, flow back to the funnel body 21 through the lapping pipeline 16 and are ground again; and the smaller materials meeting the requirements of thickness still remain in the classifier rotary plate 74 due to smaller centrifugal force, enter the finished product discharge pipeline 73 through the water leakage holes 731 on the finished product discharge pipeline 73 and flow downwards. The material can be ground up to a 1um level.

Compared with the prior art of common colloid mill, the ultra-micro colloid mill device has the following advantages:

(1) The power is lower, the yield of 2.2 kilowatts is higher, the refining effect is also good, the 220v electric low voltage and the low rotating speed grind the high fineness effect, the fineness is finer in the same national condition and is temporarily at the most advanced level. Low voltage, low rotational speed, low power machines can make the customer use range broader.

(2) The refining effect on tough plant fibers, oily, water-containing, wet fibers and the like is good, for example, 99% of soybeans pass through 100-500 meshes. The grinding machine of the soybean milk and bean curd without slag is smooth in taste and has no granular feel.

(3) The grinding machine can reach high fineness (only temporarily in China) at 4000 rpm and low rotation speed. The frequency converter and the cooling device are not needed to be configured generally, and the cost is saved for customers.

(4) The grinding machine has the advantages that the grinding disc never contacts, the knife edge is sharp, and the precision is high. The service life of the colloid mill is more than 10 times of that of a common colloid mill. The millstone can be used for more than 5 years if the millstone is fed according to the requirements except for manual damage during normal use.

(5) The grinding machine has the advantages that the grinding disc is independent and integral, the grinding disc is in the best precision professional configuration when leaving the factory, if the grinding disc is replaced from the integral to a manufacturer when needing to be replaced, a client is provided with a brand new machine, and the brand new refining effect is achieved. The customer is not required to calibrate the disc gap.

(6) The grinding machine has the advantages that the grinding disks do not rub each other, the grinding disks are subjected to special treatment of the German technology reinforced hardness, rust is avoided, the food grade is realized, the basic hardness is 53HRC, the surface hardness is 1200HV, and the abrasion is little and can be almost ignored.

(7) The temperature is controlled to be about 10 degrees higher (different from the material) when the external cooling is not needed. The physical and chemical properties of the ground material are not changed.

(8) Selecting materials for grinding discs: the medical surgical knife is processed by adopting food grade stainless steel imported in Japan and Germany technology, and reaches the grade above that of a medical imported surgical knife. The material is not rusted, food grade and medical grade. Meanwhile, the alloy has the advantages of high hardness, sharp knife edge, very wear resistance, moderate toughness and brittleness, high cost price, good safety, and long service life.

(9) The pass rate of the finished product obtained by one-time grinding is very high and can reach 99 percent.

(10) Structurally, the material is mainly sheared and has obvious effects of grinding, breaking wall, mixing, stirring, emulsifying, homogenizing, and mutually fusing and grinding. During grinding and shearing work: in principle of cutting (cutting is carried out when the material passes through two-way knife edges, the material is easy to slip when the material passes through the two-way knife edges), the grabbing and cutting principle (3-way knife edges are mutually extruded and cut), meanwhile, the material can be continuously turned over in a grinding area, and the turning over times are about hundred thousand times per minute, and the material is turned over and sheared. The number of shears was millions of times per minute. The material which is easy to slip when the tough plant fiber is sheared can be grasped and cut (3-direction knife edges are mutually extruded and cut).

(11) The thickness is uniform, the difference is not large, and the use is convenient for customers. The slurry yield is higher, the utilization rate of clients is also improved, the refining effect is better, and the client decomposing effect is also much better.

(12) The grinding machine structure is independently assembled and convenient to maintain. The internal structure of the machine has higher precision and long service life.

(13) The noise in the working process is small, and the creak generated by mutual friction of the grinding discs is avoided, so that the creak is difficult to enter the pointed sound of the ear.

(14) The machine is provided with a cleaning interface, and can be cleaned at one time under high pressure within half a minute.

The ultra-micro colloid mill has the advantages of low cost, long service life, low temperature, high fineness, low speed, low voltage, environmental protection and energy saving. The machine material is food-grade and has wide application range. Is an upgrade version of the common colloid mill, is a new product for replacing the future development of the common colloid mill, and is also a substitute of the common stone mill, the grinding wheel mill, the ball mill, the emulsion homogenizing machine, the three-roller machine and the stamping machine. Meanwhile, the wet grinding technology is a latest development technology and has wide development prospect. And can be used in large national major engineering. Can also help more needed companies, enterprises, individuals and all needed field industries to solve various corresponding difficult problems of grinding.

The present invention is not limited to the above-described embodiments, but, if various modifications or variations of the present invention are not departing from the spirit and scope of the present invention, the present invention is intended to include such modifications and variations as fall within the scope of the claims and the equivalents thereof.

Claims (1)

1. The utility model provides a take colloid mill funnel mechanism of classifier which characterized in that: comprises a funnel body, a classifier, a lapping pipeline and a classifying connecting pipe; the hopper body is provided with a discharge hole, a strong magnetic filter is arranged at the discharge hole of the hopper body, and a lapping inflow port is arranged at the lower end of the side wall of the hopper body; the classifier comprises a classifier shell, a finished product discharge pipeline and a classifying mechanism, wherein a spiral guide vane is arranged on the inner wall of the classifier shell, one end of the finished product discharge pipeline is inserted from the bottom of the classifier shell and extends upwards, a water leakage hole is formed in the upper end of the finished product discharge pipeline, and a classifier fixed ceramic bearing is arranged on the outer wall of the finished product discharge pipeline; the classifying mechanism comprises a speed regulating motor and a classifier rotating piece, wherein the classifier rotating piece is in a conical cylinder shape, and the diameter of the classifier rotating piece is gradually reduced from top to bottom; the classifier rotating piece is sleeved outside the finished product discharge pipeline; the lower end of the classifier rotating piece is clamped on the fixed ceramic bearing, the upper end of the classifier rotating piece is connected with the speed regulating motor, and the speed regulating motor can drive the classifier rotating piece to rotate by taking the finished product discharge pipeline as an axis; the two ends of the classifying connecting pipe are respectively provided with a connecting pipe inflow port and a connecting pipe outflow port, the connecting pipe inflow port is communicated with a discharge port of the grinding mechanism, and the connecting pipe outflow port is arranged in the classifier and is positioned above the classifier rotating piece; one end of the lapping pipeline is connected with the lower end of the side wall of the classifier shell, the other end of the lapping pipeline is connected to the lower end of the side wall of the funnel body, a one-way valve is arranged in the lapping pipeline, and the flow direction of the one-way valve is set to flow from the classifier shell to the funnel body; and the classifying mechanism discharges classified materials reaching standards from the finished product discharge pipeline, and materials not reaching standards flow back to the funnel body from the lapping pipeline.