CN213408971U

CN213408971U - High-efficient fluid energy mill

Info

Publication number: CN213408971U
Application number: CN202021604593.XU
Authority: CN
Inventors: 薛志宏; 张志远
Original assignee: Intercos Technology Sip Co ltd
Current assignee: Intercos Technology Sip Co ltd
Priority date: 2020-08-05
Filing date: 2020-08-05
Publication date: 2021-06-11
Anticipated expiration: 2030-08-05

Abstract

The utility model discloses a high-efficient fluid energy mill, including fluid energy mill body, feeding mechanism and detection mechanism, one side of fluid energy mill body sets up feeding mechanism, the opposite side of fluid energy mill body is provided with detection mechanism, detection mechanism includes the detection cavity, and the entry and the second discharging pipe of detection cavity communicate, and the outer anchor ring of detection cavity is provided with online sampler, and detection cavity opens the entry that the passageway communicates to online sampler, and online sampler's export is connected with the laser detector, and the output of laser detector is provided with the image display part, and the export of detection cavity is direct external material output pipeline; the utility model discloses do not need the staff manual to lift up the material, empty into fluid energy mill body in, can automatic feeding, reduced working strength, reduced personnel's cost, can not have debris moreover and get into fluid energy mill, eliminated the potential safety hazard, improved production efficiency greatly.

Description

High-efficient fluid energy mill

Technical Field

The utility model relates to a comminuted technical field, concretely relates to high-efficient fluid energy mill.

Background

The jet mill is characterized in that compressed air is frozen, filtered and dried, then forms supersonic airflow through nozzles and injects the supersonic airflow into a milling chamber to fluidize materials, accelerated materials are converged at the intersection point of the airflow sprayed by a plurality of nozzles to generate violent collision, friction and shearing to achieve ultrafine milling of particles, however, the feeding of the traditional jet mill needs staff to manually lift the materials and pour the materials into the jet mill, the working intensity is high, the personnel cost is high, impurities are easy to enter the jet mill, the potential safety hazard is not small, the power consumption of the jet mill is high, and the production efficiency is greatly reduced. Meanwhile, the crushed materials of the existing jet mill need to be collected by the collecting device and then detected by the detecting device arranged at another position, detection and production are not performed simultaneously, once the detected products are unqualified, the materials need to be reworked again, and the production efficiency is low. In view of the above disadvantages, there is a need for a high efficiency jet mill.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a high-efficient fluid energy mill to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a high-efficient fluid energy mill, includes fluid energy mill body, feeding mechanism and detection mechanism, one side of fluid energy mill body sets up feeding mechanism, the opposite side of fluid energy mill body is provided with detection mechanism, detection mechanism is including detecting the cavity, and the entry and the second discharging pipe intercommunication of detecting the cavity are provided with online sampler to the outer anchor ring of detecting the cavity, and it has the entry that the route communicates to online sampler to detect the cavity, and online sampler's exit linkage has laser detector, and laser detector's output part is provided with the formation of image display part, detects the direct external material output pipeline in export of cavity.

Preferably, feeding mechanism is including carrying the agitator tank, carry the agitator tank to install at the top of support frame, the support frame is fixed on the bottom plate, carries the first motor of left side fixedly connected with of agitator tank, and the output shaft of first motor runs through to the inner chamber and the fixedly connected with bull stick of carrying the agitator tank, and the surface of bull stick is provided with the delivery disc.

Preferably, carry the right side fixedly connected with filter of agitator tank inner chamber, the right side fixedly connected with power pump at bottom plate top, the discharge gate intercommunication of power pump has first discharging pipe, and the surface of first discharging pipe is provided with the bleeder valve, and the top intercommunication of carrying the agitator tank has first inlet pipe, and the left end of first discharging pipe extends to the inner chamber of first inlet pipe.

Preferably, the feed inlet intercommunication of power pump has the second inlet pipe, and the right-hand member of second inlet pipe is provided with the filter mantle, and the right side of bottom plate is provided with the storage case, and the right-hand member of second inlet pipe runs through to the inner chamber of storage case, carries the through-hole of agitator tank's top seted up with the filter plate looks adaptation, and the through-hole with second inlet pipe looks adaptation is seted up at the top of storage case.

Preferably, the bottom fixedly connected with support of fluid energy mill body, the equal fixedly connected with sliding seat in both sides of fluid energy mill body inner wall, the logical groove with lug looks adaptation is seted up on the surface of sliding seat, swing joint has the bushing between two sliding seats, has seted up the through-hole on the bushing, the equal fixedly connected with lug in both sides of bushing, the bottom fixedly connected with elastic block of sliding seat inner chamber, the top of elastic block and the bottom swing joint of lug.

Preferably, the equal fixedly connected with spring post in both sides at sliding seat inner chamber top, the equal fixedly connected with clamp plate in bottom of two spring posts, the top of clamp plate and the top swing joint of lug, the inside of fluid energy mill body just is located the bushing and rotates under and be connected with the pivot.

Preferably, the fixed surface of pivot is connected with the cam, and the cam is provided with two, two cam surface's top all with the bottom swing joint of bushing, the inside of fluid energy mill body just is located the bushing directly over fixedly connected with fixed plate, has seted up the through-hole on the fixed plate, the top fixedly connected with second motor of fixed plate.

Preferably, the outside cover of second motor is equipped with the dust cover, and the one end fixedly connected with (mixing) shaft of second motor output shaft, the bottom of (mixing) shaft run through the top of fixed plate and extend to the bottom of fixed plate, and the fixed surface of (mixing) shaft is connected with stirring blade, the bottom fixedly connected with high-pressure air jet system of jet mill body inner chamber.

Preferably, the bottom of the jet mill body is communicated with a conveying stirring box, the top of the jet mill body is communicated with a second discharging pipe, and the surface of the second discharging pipe is fixedly connected with a discharging valve.

Preferably, the right side of the jet mill body is fixedly connected with a rotary motor, and the right end of the rotating shaft extends to the outside of the jet mill body and is fixedly connected with one end of an output shaft of the rotary motor.

Compared with the prior art, the utility model relates to a high-efficient fluid energy mill, through setting up storage case, support frame, transport agitator tank, first motor, bull stick, delivery disc, filter, power pump, first discharging pipe, bleeder valve, first inlet pipe and second inlet pipe, can not need staff's manual lifting up the material, empty into the fluid energy mill body, can automatic feeding, reduced working strength, reduced personnel's cost, and can not have debris to get into the fluid energy mill, eliminated the potential safety hazard, greatly improved production efficiency; the utility model can filter out the impurities in the raw material preliminarily by arranging the filter cover, thereby avoiding the impurities from entering the jet mill body; the utility model discloses the exit end at the second discharging pipe of fluid energy mill body is connected with the entry that detects the cavity, make the granule of fluid energy mill processing let in and detect the cavity, the partial granule in the detection cavity flows in the entry of on-line sampler, later the export through on-line sampler gets into laser detector, laser detector carries out short-term test to the granule product of sample, it directly presents in the formation of image display part to detect the structure, the workman is according to presenting image or the data that the display part shows, carry out the adjustment nature operation to fluid energy mill, it makes the granule directly get into detection mechanism, obtain the condition of the granule that fluid energy mill produced in real time, carry out the quick adjustment, ensure the high efficiency of fluid energy mill production.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description, do not constitute a limitation of the invention, in which:

FIG. 1 is a schematic structural view of a high-efficiency jet mill of the present invention;

fig. 2 is a schematic structural diagram of a point a in fig. 1.

In the drawings:

1. a gas pulverizer body; 2. a feeding mechanism; 3. a detection mechanism; 4. a material storage box; 5. a filter housing; 6. a support frame; 7. a conveying stirring box; 8. a first motor; 9. a rotating rod; 10. a delivery tray; 11. a filter plate; 12. a base plate; 13. a power pump; 14. a first discharge pipe; 15. a discharge valve; 16. a first feed tube; 17. a second feed tube; 18. a rotating shaft; 19. a support; 20. a rotary motor; 21. a second discharge pipe; 22. a discharge valve; 23. a sliding seat; 24. a bump; 25. a bushing; 26. an elastic block; 27. a spring post; 28. pressing a plate; 29. a cam; 30. a fixing plate; 31. a second motor; 32. a stirring shaft; 33. a stirring blade; 34. a high pressure air injection device; 35. a detection cavity; 36. an online sampler; 37. a laser detector; 38. an imaging display section; 39. an output pipeline; 40. a first connecting flange; 41. a second connecting flange; 42. and a third connecting flange.

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 and 2, the present invention provides a technical solution: the utility model provides a high-efficient fluid energy mill, includes fluid energy mill body 1, feeding mechanism 2 and detection mechanism 3, one side of fluid energy mill body 1 sets up feeding mechanism 2, the opposite side of fluid energy mill body 1 is provided with detection mechanism 3.

The feeding mechanism 2 in this embodiment includes a conveying stirring box 7, the conveying stirring box 7 is installed on the top of a support frame 6, the support frame 6 is fixed on a bottom plate 12, a first motor 8 is fixedly connected to the left side of the conveying stirring box 7, an output shaft of the first motor 8 penetrates through an inner cavity of the conveying stirring box 7 and is fixedly connected with a rotating rod 9, a conveying disc 10 is arranged on the surface of the rotating rod 9, a filter plate 11 is fixedly connected to the right side of the inner cavity of the conveying stirring box 7, a power pump 13 is fixedly connected to the right side of the top of the bottom plate 12, a discharge port of the power pump 13 is communicated with a first discharge pipe 14, a discharge valve 15 is arranged on the surface of the first discharge pipe 14, a first feeding pipe 16 is communicated with the top of the conveying stirring box 7, the left end of the first discharge pipe 14 extends to the inner cavity of the first feeding pipe 16, a feeding port of the power pump 13 is, the aperture size of the filter mantle 5 can be adjusted, impurities in raw material particles can be filtered preliminarily by arranging the filter mantle 5, the impurities are prevented from entering the jet mill body 3, the right side of the bottom plate 12 is provided with the storage box 4, the right end of the second feeding pipe 17 penetrates into the inner cavity of the storage box 4, the top of the conveying stirring box 7 is provided with a through hole matched with the filter plate 11, the top of the storage box 4 is provided with a through hole matched with the second feeding pipe 17, the filter plate 11, the power pump 13, the first discharging pipe 14, the discharging valve 15, the first feeding pipe 16 and the second feeding pipe 17 can be poured into the jet mill body 1 without manually lifting the materials by staff by arranging the storage box 4, the support frame 6, the conveying stirring box 7, the first motor 8, the rotating rod 9, the conveying disc 10, the filter plate 11, the power pump 13, the first discharging pipe 14, the discharging valve 15, the first, personnel cost is reduced, sundries cannot enter the jet mill, potential safety hazards are eliminated, and production efficiency is greatly improved.

In this embodiment, a support 19 is fixedly connected to the bottom of the jet mill body 1, sliding seats 23 are fixedly connected to both sides of the inner wall of the jet mill body 1, through grooves adapted to the protrusions 24 are formed on the surface of the sliding seats 23, a bushing 25 is movably connected between the two sliding seats 23, through holes are formed in the bushing 25, the protrusions 24 are fixedly connected to both sides of the bushing 25, an elastic block 26 is fixedly connected to the bottom of the inner cavity of the sliding seat 23, the top of the elastic block 26 is movably connected to the bottom of the protrusion 24, spring columns 27 are fixedly connected to both sides of the top of the inner cavity of the sliding seat 23, pressing plates 28 are fixedly connected to the bottom ends of the two spring columns 27, the top of the pressing plates 28 is movably connected to the top of the protrusion 24, a rotating shaft 18 is rotatably connected to the inside of the jet mill body 1 and under the bushing 25, and a cam 29 is fixedly connected, and cam 29 is provided with two, the top on two cam 29 surfaces all with the bottom swing joint of bushing 25, the inside of fluid energy mill body 1 just is located bushing 25 directly over fixedly connected with fixed plate 30, the through-hole has been seted up on the fixed plate 30, the top fixedly connected with second motor 31 of fixed plate 30, the outside cover of second motor 31 is equipped with the dust cover, the one end fixedly connected with (mixing) shaft 32 of second motor 31 output shaft, the bottom of (mixing) shaft 32 runs through the top of fixed plate 30 and extends to the bottom of fixed plate 30, the fixed surface of (mixing) shaft 32 is connected with stirring blade 33, the bottom fixedly connected with high-pressure jet system 34 of fluid energy mill body 1 inner chamber, high-pressure jet system 34 can form high-pressure draught, the last fixedly connected with grinding plate of fluid energy mill body 1 inner wall, the grinding plate can decorate the powder.

In this embodiment the bottom intercommunication of fluid energy mill body 1 has transport agitator tank 7, and the top intercommunication of fluid energy mill body 1 has second discharging pipe 21, and the fixed surface of second discharging pipe 21 is connected with ejection of compact valve 22, and the right side fixedly connected with rotary motor 20 of fluid energy mill body 1, the right-hand member of pivot 18 extend to the outside of fluid energy mill body 1 and the one end fixed connection of rotary motor 20 output shaft.

The detection mechanism 3 in this embodiment includes a detection cavity 35, an inlet of the detection cavity 35 is communicated with the second discharge pipe 21, an online sampler 36 is disposed on an outer circumferential surface of the detection cavity 35, the detection cavity 35 is opened with a passage communicated to the inlet of the online sampler 36, an outlet of the online sampler 36 is connected with a laser detector 37, an output portion of the laser detector 37 is provided with an imaging display portion 38, and an outlet of the detection cavity 35 is directly externally connected with a material output pipeline.

The outlet of the in-line sampler 36 in this embodiment is connected to the inlet of a laser detector 37 via a vertical outlet line 39, ensuring that the particles quickly enter the laser detector 37.

In this embodiment, the discharge port of the second discharge pipe 21 is provided with a first connecting flange 40, the two ends of the detection cavity 35 are respectively provided with a second connecting flange 41 and a third connecting flange 42, the first connecting flange 40 is tightly connected with the second connecting flange 41, the third connecting flange 42 is externally connected with an inlet flange of a material output pipeline, the interface of the flange structure is provided with a sealing ring to ensure the sealing performance of the whole structure, and the contact surfaces of the first connecting flange 40 and the second connecting flange 41 are provided with a sealing ring to ensure the sealing performance of the whole interface.

In this embodiment, the outlet end of the second tapping pipe 21 is connected to the detection chamber 35 via a first connecting flange 40 and a second connecting flange 41.

The utility model discloses during the use, power pump 13 is opened, the raw materials granule is taken out from storage case 4 through second inlet pipe 17, entering into the inner chamber of carrying agitator tank 7 through first inlet pipe 16, can adjust through bleeder valve 15, thereby control flow opens first motor 8, filter 11 filters the raw materials granule, recycle bull stick 9 and delivery disc 10 with raw materials granule primary processing and carry and smash in the fluid energy mill body 1, thereby reach the purpose of high-efficient feeding. After the raw material particles enter the jet mill, the high pressure jet device 34 and the rotary motor 20 are started, the rotary motor 20 drives the rotating shaft 18 to rotate, then the cam 29 is driven to rotate, then the bushing 25 is driven to move up and down, then the bump 24 is driven to move up and down, further the pressing plate 28 is driven to move up and down, simultaneously the spring column 27 is caused to move up and down, the second motor 31 is started, the second motor 31 drives the stirring shaft 32 to rotate, then the stirring blade 33 is driven to rotate, large raw material particles are stirred, the grinding plate is used for rubbing the raw material particles to modify the raw material particles, after being crushed, the valve 22 on the second discharging pipe 21 is opened, the outlet end of the second discharging pipe 21 of the jet mill body 1 is connected with the inlet of the detection cavity, so that the particles processed by the jet mill are led into the detection cavity 35, and part of the particles in the, then enters the laser detector 37 through the outlet of the online sampler 36, the laser detector 37 rapidly detects the sampled particle products, the detection structure is directly presented on the imaging display part 38, the worker performs adjustment operation on the jet mill according to the image or data displayed on the display part, the particles directly enter the detection mechanism 3, the condition of the particles produced by the jet mill is obtained in real time, rapid adjustment is performed, and the high efficiency of the jet mill production is ensured.

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

1. The utility model provides a high-efficient fluid energy mill which characterized in that: the jet mill comprises a jet mill body (1), a feeding mechanism (2) and a detection mechanism (3), wherein the feeding mechanism (2) is arranged on one side of the jet mill body (1), the detection mechanism (3) is arranged on the other side of the jet mill body (1), the detection mechanism (3) comprises a detection cavity (35), an inlet of the detection cavity (35) is communicated with a second discharge pipe (21), an online sampler (36) is arranged on the outer annular surface of the detection cavity (35), a passage is formed in the detection cavity (35) and communicated to the inlet of the online sampler (36), an outlet of the online sampler (36) is connected with a laser detector (37), an output part of the laser detector (37) is provided with an imaging display part (38), and an outlet of the detection cavity (35) is directly connected with a material output pipeline externally.

2. A high efficiency jet mill as claimed in claim 1, wherein: feeding mechanism (2) are including carrying agitator tank (7), carry agitator tank (7) and install the top at support frame (6), support frame (6) are fixed on bottom plate (12), carry the first motor of left side fixedly connected with (8) of agitator tank (7), and the output shaft of first motor (8) runs through to the inner chamber and the fixedly connected with bull stick (9) of carrying agitator tank (7), and the surface of bull stick (9) is provided with delivery disc (10).

3. A high efficiency jet mill as claimed in claim 2, wherein: carry right side fixedly connected with filter (11) of agitator tank (7) inner chamber, the right side fixedly connected with power pump (13) at bottom plate (12) top, the discharge gate intercommunication of power pump (13) has first discharging pipe (14), the surface of first discharging pipe (14) is provided with bleeder valve (15), the top intercommunication of carrying agitator tank (7) has first inlet pipe (16), the left end of first discharging pipe (14) extends to the inner chamber of first inlet pipe (16).

4. A high efficiency jet mill as claimed in claim 3, wherein: the feed inlet intercommunication of power pump (13) has second inlet pipe (17), and the right-hand member of second inlet pipe (17) is provided with filter mantle (5), and the right side of bottom plate (12) is provided with storage case (4), and the right-hand member of second inlet pipe (17) runs through to the inner chamber of storage case (4), carries the top of agitator tank (7) to offer the through-hole with filter (11) looks adaptation, and the through-hole with second inlet pipe (17) looks adaptation is offered at the top of storage case (4).

5. A high efficiency jet mill as claimed in claim 1, wherein: bottom fixedly connected with support (19) of fluid energy mill body (1), the equal fixedly connected with sliding seat (23) in both sides of fluid energy mill body (1) inner wall, the logical groove with lug (24) looks adaptation is seted up on the surface of sliding seat (23), swing joint has bushing (25) between two sliding seat (23), the through-hole has been seted up on bushing (25), the equal fixedly connected with lug (24) in both sides of bushing (25), the bottom fixedly connected with elasticity piece (26) of sliding seat (23) inner chamber, the top of elasticity piece (26) and the bottom swing joint of lug (24).

6. A high efficiency jet mill as claimed in claim 5, wherein: the equal fixedly connected with spring post (27) in both sides at sliding seat (23) inner chamber top, the equal fixedly connected with clamp plate (28) in bottom of two spring posts (27), the top of clamp plate (28) and the top swing joint of lug (24), the inside of jet mill body (1) just is located bushing (25) and rotates under and is connected with pivot (18).

7. A high efficiency jet mill as claimed in claim 6, wherein: the fixed surface of pivot (18) is connected with cam (29), and cam (29) are provided with two, the top on two cam (29) surfaces all with the bottom swing joint of bushing (25), the inside of fluid energy mill body (1) just is located bushing (25) directly over fixedly connected with fixed plate (30), has seted up the through-hole on fixed plate (30), the top fixedly connected with second motor (31) of fixed plate (30).

8. A high efficiency jet mill as claimed in claim 7, wherein: the outside cover of second motor (31) is equipped with the dust cover, the one end fixedly connected with (mixing) shaft (32) of second motor (31) output shaft, and the bottom of (mixing) shaft (32) runs through the top of fixed plate (30) and extends to the bottom of fixed plate (30), and the fixed surface of (mixing) shaft (32) is connected with stirring blade (33), the bottom fixedly connected with high pressure air jet system (34) of jet mill body (1) inner chamber.

9. A high efficiency jet mill as claimed in claim 1, wherein: the bottom of the jet mill body (1) is communicated with a conveying stirring box (7), the top of the jet mill body (1) is communicated with a second discharging pipe (21), and the surface of the second discharging pipe (21) is fixedly connected with a discharging valve (22).

10. A high efficiency jet mill as claimed in claim 7, wherein: the right side of the jet mill body (1) is fixedly connected with a rotary motor (20), and the right end of the rotating shaft (18) extends to the outside of the jet mill body (1) and is fixedly connected with one end of an output shaft of the rotary motor (20).