CN215235900U - Super energy-saving dry coal dressing system with dust removal intelligent detection function - Google Patents

Abstract

The utility model provides a super energy-conserving dry process coal dressing system with dust removal intellectual detection system, it includes raw coal feed part, air feed part, selects separately part and dust removal part, wherein the dust removal part includes that intelligence transfers wind dust pelletizing system, and intelligence transfers wind dust pelletizing system to include dust removal pipeline, full sack cleaner, sack draught fan and intelligent control platform, and intelligent control platform carries out the intelligent control of wind speed amount of wind and carries out the early warning to the data anomaly in the production process according to sensor data. The utility model discloses can carry out real time monitoring to the dust, and can purify the dust removal according to the sorting index to it more is suitable for the sorting use of various occasions or mining areas.

Description

Super energy-saving dry coal dressing system with dust removal intelligent detection function

Technical Field

The utility model belongs to the technical field of the coal is selected separately, concretely relates to super energy-conserving dry process coal dressing system with dust removal intellectual detection system.

Background

Coal is a solid combustible mineral formed gradually by ancient plants buried underground and undergoing complex biochemical and physicochemical changes. Coal is known as black gold by people and is industrial food, which is one of main energy sources used in the human world since the eighteenth century, and since the twenty-first century, although the value of coal is not as high as before, coal is one of indispensable energy sources for production and life of human beings at present and in a long time in the future after all, the supply of coal is also related to the stability of the development of the industry of China and the aspect of the whole society, and the problem of the supply safety of coal is also the most important part in the energy safety of China.

Coal separation mainly comprises two directions of water washing and dry separation, the water washing basically adopts the processes of jigging, dense medium, flotation and the like, and the method has the advantages of mature process, high separation precision and high processing capacity. The disadvantages of large construction investment, long period, high production cost, large water resource consumption and waste, and the water consumption of washing 1 ton of raw coal is about 0.1m³In addition, low quality by-products such as coal slurry are also produced. The dry separation is a coal separation method which exists and develops slowly in the last two decades, has the advantages of no water, simple process, less investment and low production cost, and the main representative process is a wind power dry coal separation process. From the coal distribution region, the west accounts for 80.4% of the country, the middle accounts for 15.2% of the country, and the east accounts for 4.4% of the country. The western part is the main distribution area of the coal in China and is just the dry and little water area, so compared with water washing, dry separation has wider requirements and prospects, and large-area popularization is achieved in China and all over the world in a very short period. The water content, ash content and sulfur content of coal are important factors influencing the quality of coal. To improve the quality of coal, the coal must be dewatered andand (6) sorting. With the development of coal upgrading technology, coal drying and dry separation processes are widely applied in the coal upgrading technology, and remarkable success is achieved.

However, the existing wind-force dry coal separation technology has the defects of poor separation precision, small processing capacity, high requirement on coal types and the like. In addition, after the screening of coal is realized, the screening device for the existing intelligent coal dry separator needs to crush coal particles with larger particles so as to meet the subsequent processing requirement and greatly reduce the working efficiency; moreover, the coal screening device can generate a large amount of dust in the process of screening coal, the dust can pollute the surrounding environment, and the health of operators can be seriously affected when the operators work in the working environment for a long time. In addition, a large amount of energy is consumed in the process of treating the dust.

Therefore, a dry coal dressing device which can monitor dust in real time and can purify and remove dust is needed, so that the dry coal dressing device is more suitable for being used for sorting in various occasions or mining areas.

SUMMERY OF THE UTILITY MODEL

Based on the problem that exists among the prior art, the utility model provides a super energy-conserving dry process coal dressing system with dust removal intellectual detection system.

According to the technical scheme of the utility model, a super energy-conserving dry process coal dressing system with dust removal intellectual detection system is provided, it includes raw coal feed part, the air feed part, select separately part and dust removal part, wherein the dust removal part includes that intelligence transfers wind dust pelletizing system, intelligence transfers wind dust pelletizing system to include dust removal pipeline, full sack cleaner, sack draught fan and intelligent control platform, intelligent control platform carries out the intelligent control of wind speed amount of wind and carries out the early warning to the data anomaly in the production process according to sensor data.

Preferably, the super energy-saving dry coal preparation system with intelligent dust removal detection is provided with a wind speed sensor on a dust removal pipeline, and the wind speed sensor is used for detecting the wind speed of the impurity-containing gas; a first concentration sensor is arranged in the full-bag dust collector and is used for detecting the dust concentration in the full-bag dust collector; a second concentration sensor and a gas phase sensor are arranged on a chimney of the induced draft fan, the second concentration sensor is used for detecting the concentration of dust discharged into the atmosphere, and the gas phase sensor is used for detecting the gas components of the dust discharged into the atmosphere.

Wherein, a plurality of wind speed sensors are arranged on the dust removal pipeline. And a pressure sensor is arranged on the dust removal pipeline.

Further, a plurality of first concentration sensors are arranged at different positions of the full bag-type dust collector.

Preferably, first concentration sensors of different site densities are provided above different areas on the main bed. The main control system regulates and controls the running power of the left main fan and the right main fan according to the sorting index or the sorting requirement, and achieves intelligent regulation and control of dust removal.

Preferably, a left overhaul observation window is arranged on an air duct of the left main fan which is fed into the left air distributor through the air valve of the left main fan. And a right maintenance observation window is arranged on an air channel of the right main fan which is fed into the right air distributor through the air valve of the right main fan.

Preferably, the left overhaul observation window is arranged between the air valve of the left main fan and the left air distributor; or the right maintenance observation window is arranged between the air valve of the right main fan and the right air divider.

The utility model discloses a super energy-conserving dry process coal dressing system with dust removal intellectual detection system, it can carry out real time monitoring and can purify the dust removal according to the sorting index to it more is suitable for the sorting use of various occasions or mining area. The equipment is energy-saving and environment-friendly, intelligent control is realized, the unit area treatment capacity is large, intelligent field adjustment is further realized, and the coal sorting effect is improved.

Drawings

FIG. 1 is a schematic structural diagram of a super energy-saving dry coal preparation system with intelligent dust removal detection according to the present invention;

FIG. 2 is a top view of the intelligent vibratory primary cot of FIG. 1;

FIG. 3 is a schematic view of a bed surface through hole in the intelligent vibration main sorting bed of FIG. 2;

FIG. 4 is a schematic longitudinal side view of the intelligent vibratory primary cot of FIG. 1;

FIG. 5 is a schematic longitudinal side view of an intelligent vibratory primary sorting bed with mounted sorting bars;

FIG. 6 is a schematic view of the vibration direction of the backplate shown in FIG. 4;

FIG. 7 is a sectional view of a coal dry separation system with a main separation bed body of a product chute;

FIG. 8 is an external view of a super energy-saving dry coal preparation system with intelligent dust removal detection, equipped with a quick access door;

FIG. 9 is a schematic view of a loading conveyor system based on FIG. 8;

FIG. 10 is a partial view of a dust removal system of a super energy-efficient dry coal preparation system with intelligent detection of dust removal;

FIG. 11 is a schematic cross-sectional view of a dedusting air duct;

FIG. 12 is a schematic view of blast separation of a super energy-saving dry coal separation system with intelligent dust removal detection.

The reference numbers in the figures are as follows: 1. a left main blower; 2. a left main blower air valve; 3. a left air distributor; 4. a product grading chute; 5. a host support; 6. a right air distributor; 7. a right main blower air valve; 8. a right main blower; 9. an air inlet of the dust remover; 10. a full bag dust collector; 11. a fully-closed dust collecting hood; 12. a dust removal pipeline; 13. a left main fan air inlet pipeline; 14. a right main fan air inlet pipeline; 15. a main selection bed; 16. hanging a host; 17. an air inducing duct; 18. a cloth bag induced draft fan; 19. a chimney of the induced draft fan; 21. a material inlet; 22. a clean coal discharge chute; 23. a middling discharging chute; 24. a gangue discharge chute; 25. a waste rock discharge cylinder; 26. a gangue overflow outlet; 27. a gangue discharge area; 28. primary sorting area; 701. a left inspection observation window; 702. a right overhaul observation window; 91. a belt scale; 92. a belt conveyor; 1501. a longitudinal angle monitor; 1502. a lateral angle monitor; 1101. a quick access door; 1102. dust filtration cloth; 8-1, a horizontal air inlet pipe of the dust remover; 8-2, connecting an air inlet of the dust remover with a square pipe; 8-3, a dust remover air inlet inspection blind plate; 31. sorting air holes; 32. a bed panel; 41. a back plate; gradually-high lattice bars b1, b2, b3, … … and bn … ….

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, not all embodiments, of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative work belong to the scope of the present invention.

The utility model provides a super energy-conserving dry process coal dressing system with dust removal intellectual detection system, the term definition: "super energy-conservation" indicates under the condition that is used for the same main election bed area of selecting separately, the utility model discloses compare with conventional wedge main election bed, the utility model discloses the energy that selects separately the raw coal of unit weight and consume reduces 30%.

The present invention is further explained with reference to the attached drawing 1, and fig. 1 is a schematic structural diagram of a super energy-saving dry coal separation system with intelligent dust removal detection according to the present invention. As shown in fig. 1, the super energy-saving dry coal preparation system with intelligent dust removal detection comprises a raw coal feeding part, an air supply part, a separation part and a dust removal part, wherein the raw coal feeding part comprises a product conveyor, a buffer bin and an intelligent conveying device, the separation part comprises a host bracket, an intelligent vibration main bed selection device, a host hanging and discharging device, the air supply part comprises an intelligent air regulation system formed by a left main fan and a right main fan, and the dust removal part comprises an intelligent air regulation and dust removal system.

Further, raw coal (including but not limited to coal products or coal materials) is conveyed into a buffer bin by a raw coal product conveyor to wait for sorting, and the raw coal in the buffer bin is intelligently distributed to a sorting part through an intelligent conveying device to be sorted. The sorting part comprises a host bracket 5, an intelligent vibration main sorting bed device, a host hanger 16 and a discharging device, wherein the intelligent vibration main sorting bed device is arranged on the host bracket 5 through the host hanger 16, the intelligent vibration main sorting bed device comprises a main sorting bed 15, and the discharging device is a material receiving chute positioned at the lower part of the intelligent vibration main sorting bed device. The receiving chute is preferably a product chute 4.

The air supply part comprises an intelligent air adjusting system consisting of a left main fan 1 and a right main fan 8, the left main fan 1 is connected to a left air distributor 3 through a left main fan air valve 2, and the left air distributor 3 blows separation air into a first group of separation chambers; the right main blower 8 is connected to the right air distributor 6 via a right main blower air valve 7, and the right air distributor 6 blows the separation air into the second group of separation chambers.

The dust removing part comprises an intelligent air adjusting and dust removing system, the intelligent air adjusting and dust removing system comprises a dust removing pipeline 12, a full-bag dust remover 10, a bag-type induced draft fan 18 and an intelligent adjusting and controlling platform, a fully-closed dust collecting cover 11 arranged at the upper part of the sorting part conveys dust generated by the sorting part to a dust remover air inlet 9 through the dust removing pipeline 12, gas containing impurities or dust through the dust remover air inlet 9 enters the full-bag dust remover 10, the full-bag dust remover 10 is connected with a left main fan air inlet pipeline 13 and a right main fan air inlet pipeline 14, the air inlet pipeline 13 of the left main fan 1 conveys gas purified through the full-bag dust remover 10 back to the left main fan 1, and the air inlet pipeline 14 of the right main fan 8 conveys gas purified through the full-bag dust remover 10 back to the right main fan 8. The dust removal part further comprises a bag induced draft fan 18, the bag induced draft fan 18 is connected with an induced draft fan chimney 19 and an induced draft pipeline 17, the induced draft pipeline 17 introduces dust-containing gas into the full bag-type dust remover 10, and part of clean gas treated by the bag-type dust remover 10 is discharged into the atmosphere through the induced draft fan chimney 19. The intelligent control platform carries out intelligent control of wind speed and wind volume according to the sensor data and carries out early warning on data abnormity in the production process.

The super energy-saving dry coal dressing system with intelligent dust removal detection of the utility model is provided with a wind speed sensor on the dust removal pipeline 12 for detecting the wind speed of the impurity-containing gas; a first concentration sensor is arranged in the full-bag dust collector 10 and is used for detecting the dust concentration in the full-bag dust collector 10; a second concentration sensor and a gas phase sensor are arranged on the draught fan chimney 19, the second concentration sensor is used for detecting the concentration of dust discharged into the atmosphere, and the gas phase sensor is used for detecting the gas components of the dust discharged into the atmosphere. According to the length and the cross section area of the dust removal pipeline, a plurality of wind speed sensors can be arranged, and then the wind volume and the wind speed change can be judged according to the wind speed data of the wind speed sensors at different positions; furthermore, a pressure sensor is arranged on the dust removal pipeline to test the pressure bearing condition of the dust removal pipeline. Similarly, a plurality of first concentration sensors are arranged according to the volume of the full bag-type dust collector 10, and the first concentration sensors with different densities are further arranged above different areas on the main separation bed, so that the joint prevention and joint control of dust concentration is realized. Different data measured by the sensors are transmitted to a main control system through links, and the main control system regulates and controls the running power of the left main fan 1 and the right main fan 8 according to the sorting indexes or the sorting requirements, so that intelligent dust removal regulation and control are realized.

Corresponding to the intelligent regulation, a left overhaul observation window 701 is preferably arranged on an air channel of the left air distributor 3 fed by the left main fan 1 through the left main fan air valve 2. Similarly, a right inspection window 702 is preferably provided on the duct of the right air splitter 6 through the right main blower 8 via the right main blower air valve 7. More preferably, a left service viewing window 701 is provided between the left main blower damper 2 and the left air splitter 3 and a right service viewing window 702 is provided between the right main blower damper 7 and the right air splitter 6.

As shown in fig. 10, in the structure in which the dust enters the full bag dust collector 10 through the dust collector air inlet 9, the dust collector air inlet 9 is provided with a dust buffering device, preferably a pillow-shaped body for the dust buffering device, and the dust enters the full bag dust collector 10 after being buffered in the pillow-shaped body. Therefore, the blocky particles contained in the dust from the sorting space of the intelligent vibration main sorting bed can be buffered and fall in the pillow-shaped body and are gathered in the pillow-shaped body, the side part of the pillow-shaped body is provided with a dust collector air inlet inspection blind plate 8-3, the dust collector air inlet inspection blind plate 8-3 is detachably arranged on the side surface of the pillow-shaped body, and the gathered blocky particles can be cleaned by detaching the dust collector air inlet inspection blind plate 8-3. As shown in fig. 11, the air inlet pipe of the dust removal system of the super energy-saving dry coal separation system with intelligent dust removal detection comprises a horizontal dust collector air inlet pipe 8-1 and a square dust collector air inlet connecting pipe 8-2, the horizontal dust collector air inlet pipe 8-1 forms the main body of the pillow body, and the square dust collector air inlet connecting pipe 8-2 is connected between the horizontal dust collector air inlet pipe 8-1 and a full bag dust collector 10.

The utility model discloses a super energy-conserving dry process coal preparation system with dust removal intellectual detection system has set up the many wind regime systems that constitute by a plurality of main blowers, and then has realized intelligent accent wind. In the sorting process, the differentiated air supply requirements are realized according to different air quantities required by each part of the main sorting bed 15. Compared with the existing dry separator which only has one main fan, the air quantity and the air pressure of an air source are single and unadjustable, the area of the main separating bed of the super energy-saving dry coal separating system with the intelligent dust removal detection is very large, the number of the air chambers is more than ten, and the air quantity and the air pressure required by each air chamber also have different parameters according to different positions under the main separating bed; further, also solved and set up a main wind regime under the super large owner selects the bed surface, even the amount of wind is adjustable, also can not overcome the technical problem that the wind pressure still is same parameter. A multi-wind source system is adopted, so that the adjustment of the sorting parameters of the dry separator is realized; the air supply quantity of the air sources can be adjusted at any time, and the air sources can be distributed according to the separation parameters required by each air chamber, so that the separation precision can be improved, the energy consumption can be reduced from the environmental protection perspective, the energy and the electricity are saved, and unnecessary waste is avoided.

Furthermore, the utility model discloses a super energy-conserving dry process coal preparation system with dust removal intellectual detection system adopts the full sack cleaner, and gives up the scheme of the two double configurations of whirlwind dust removal and the sack dust removal that original coal dry separation system adopted. The original coal dry separator dust remover system is provided with a cyclone dust remover and a bag dust remover, the cyclone dust remover has large processing air volume and small occupied area, the processed air is used as circulating air for continuous use, the dust removing path trend is that a main fan leads the air out of an equipment dust hood and enters the cyclone dust remover through a pipeline, large particle dust is removed in the cyclone dust remover, then the large particle dust enters the main fan, the main fan feeds the air chamber, the air chamber feeds the main separation bed, the main separation bed enters the dust hood and is sucked away by the main fan again, and the process is repeated and circulated, so that the air path circulation of the dry separator equipment is ensured; the bag-type dust collector also draws air from the dust hood, so that negative pressure is generated on a balanced air path, and dust is prevented from overflowing. However, the cyclone dust collector can only remove large-particle dust in the air path, and the fine dust circulates in a closed circuit along with the wind, and more dust is discharged after the dry separator runs for a long time. The full-bag dust collector preferably adopts an intelligent air-adjusting dust-removing system.

The utility model discloses a super energy-conserving dry process coal preparation system with dust removal intellectual detection system adopts full sack cleaner, and all circulation wind paths are all through the sack cleaner, and the dust collection efficiency of sack cleaner can reach more than 99%, can detach 99% dust in the wind path, has realized the clear wind coal dressing completely, and the resistance of sack cleaner is far less than the resistance of cyclone dust remover moreover, can reduce the energy consumption of main fan motor, can the energy can be saved again.

As shown in figure 2, the super energy-saving dry coal separation system with the dust removal intelligent detection adopts a pentagonal intelligent vibration main separation bed surface with three right-angled sides, the movement direction of gangue is forwards pushed along the transverse direction of the intelligent vibration main separation bed, and the movement direction of clean coal is forwards pushed along the longitudinal direction of the intelligent vibration main separation bed. The discharging section of the clean coal adopts a trapezoidal frame. Coal materials are intelligently distributed to a material inlet 21 of the intelligent vibration main selection bed through an intelligent conveying device and are conveyed to a primary separation area 28 on a bed body of the intelligent vibration main selection bed through the material inlet 21, and a plurality of separation gradually-high grid bars b1, b2, b3, … … and bn … … are arranged on the intelligent vibration main selection bed; select separately gradually high check strip and lay on intelligent vibration main selection bed, select separately gradually high check strip and intelligent vibration main selection bed pan feeding frame and be certain separation contained angle N, wherein select separately contained angle N and be the acute angle, set up the size of this separation contained angle according to the coal composition or the moisture of equipment fixing mining area, and then realized selecting separately the index according to local conditions, furthest promotes the sorting precision. The material inlet 21 is arranged at the edge of the feeding frame of the intelligent vibration main separation bed, preferably, the highest point of the feeding frame of the intelligent vibration main separation bed is overlapped with the highest point of the material inlet 21, so that coal materials are vibrated and propelled to the waste rock discharging frame of the intelligent vibration main separation bed along the upper frame of the intelligent vibration main separation bed, a certain material propelling angle M is formed between each high point oblique connecting line of a plurality of separation gradually-high lattice bars b1, b2, b3, … … and bn … … and the upper frame of the intelligent vibration main separation bed, the material propelling angle M is set according to the impurity content of the waste rocks of coal carbons separated on site, and the separation degree of clean coal, medium coal and waste rocks is improved as much as possible. A gangue discharge channel is arranged close to the gangue discharge frame of the intelligent vibration main separation bed, gangue separated from the gangue discharge area 27 is discharged through a gangue discharge groove 24 along the gangue discharge channel, a gangue overflow outlet 26 is arranged at the top end of the gangue discharge frame of the intelligent vibration main separation bed, and the gangue overflow outlet 26 is used for quickly discharging large gangue or accumulated gangue; in addition, compared with the existing dry separation system, the super energy-saving dry coal separation system with the dust removal intelligent detection function has the advantages that the coal separation amount per unit time is higher than 30%, and a large amount of gangue is generated in a short time, so that a gangue discharge cylinder 25 is additionally arranged on the side face of a gangue discharge frame of the intelligent vibration main separation bed, and the gangue which cannot be discharged through a gangue discharge chute 24 and a gangue overflow outlet 26 can be discharged through the gangue discharge cylinder 25. The lower separation frame of the intelligent vibration main separation bed is respectively and sequentially provided with a clean coal discharging groove 22, a middlings discharging groove 23 and a gangue discharging groove 24, and the separation side length occupied by the clean coal discharging groove 22, the middlings discharging groove 23, the gangue discharging groove 24 and the like is determined according to the separation area of the bed body of the intelligent vibration main separation bed, the set vibration frequency of vibration separation and the impurity content and water content of coal. The utility model discloses an intelligence vibration primary election bed is selected separately the lower frame and is the broken line form, and partial intelligence vibration primary election bed is selected separately the lower frame and is perpendicular and be on a parallel with intelligence vibration primary election bed pan feeding frame and select separately the upper frame promptly, and partial intelligence vibration primary election bed is selected separately the lower frame and upwards folds and be the obtuse angle with intelligence vibration primary election bed row's waste rock frame in clean coal separation region, shortens waste rock and clean coal stroke, increase handling capacity in proper order.

The super energy-saving dry coal separation system with the dust removal intelligent detection adopts a pentagonal intelligent vibration main separation bed surface with three right-angle sides, firstly, the transverse distance of a discharge end of waste rock is shortened, and the retention time of the waste rock on the main separation bed is reduced; secondly, the longitudinal distance of the clean coal discharge end is shortened, and the distance of an air chamber is transversely prolonged from the foremost end of the main separation bed to the gangue end, so that the area of the clean coal discharge end can be basically kept unchanged, and the changes are all to reduce the retention time of materials on the main separation bed. The lower corner is modified into a broken line trapezoid, thereby shortening the travel of gangue and clean coal and increasing the treatment capacity.

As further shown in fig. 2, the length of the sorting lower frame of the part of the intelligent vibration main sorting bed, which is perpendicular to the feeding frame of the intelligent vibration main sorting bed and parallel to the sorting upper frame of the intelligent vibration main sorting bed, is a3, the length of the sorting lower frame of the other intelligent vibration main sorting beds is a4, the length ratio is set according to the sorting amount of clean coal and the sorting degree of clean coal, for example, sorting coal into super clean coal, middlings, miscellaneous middlings, gangue and the like, and at this time, the length ratio of the broken line of the sorting lower frame of the intelligent vibration main sorting bed is adjusted according to the user's needs; similarly, the length a5 of the frame of the gangue discharge of the intelligent vibration main separation bed is set according to the gangue moving speed and the drying speed of the separated coal; the intelligent vibration main sorting bed feeding frame is divided into a material inlet 21 part and a clean coal sorting side, the length of the material inlet 21 part is a1, the length of the clean coal sorting side is a2, and the proportion between a1 and a2 of the intelligent vibration main sorting bed feeding frame is set according to the amount of coal conveyed to the vibration sorting part in unit time. Arranging an upper frame of the intelligent vibration main separation bed at the gangue discharge port 26, wherein the length of the gangue discharge port 26 is a6, and the proportion between the length a6 and the length a7 of the rest part of the upper frame of the intelligent vibration main separation bed is set according to the amount of gangue; alternatively, the gangue discharge 26 may be closed for situations where the amount of gangue discharged is relatively small.

Furthermore, a plurality of gradually-high sorting grid strips b1, b2, b3, … … and bn … … are sequentially arranged in parallel, high points b12, b22, b32, … … and bn2 … … of each gradually-high grid strip form an oblique line (connecting line), each high point oblique connecting line and the upper frame of the intelligent vibration main sorting bed form a certain material propelling angle M, and low points b11, b21, b31, … … and bn1 … … of each gradually-high grid strip are respectively connected with the feeding frame of the intelligent vibration main sorting bed and the sorting lower frame of the intelligent vibration main sorting bed. As shown in fig. 5, the gradually-high bars are fixed on the bed panel, and the high point of each gradually-high bar is close to the intelligent vibration main selection bed back plate 41. The height of the high points of the gradually-high grating is greater than that of the low points of the gradually-high grating.

The utility model discloses intelligence vibration primary election bed panel gradually high check strip, for bed panel check strips such as current, the effect of check strip is that the material that density is big can upwards move along the check strip at primary election bed during operation for the material forms the boundary zone of an obvious high low density material separation on primary election bed. The utility model discloses the material volume that the primary election bed passed through is very big, and current check strip exists the thickness that highly is less than the bed material far away and leads to the unstable problem of the big material movement track of density, and current check strip is not suitable for the material of handling large treatment capacity to select separately. The utility model discloses a like the gradually high check strip that fig. 5 is shown, backplate to arranging material side direction check strip height and more low, be favorable to the high density material like this to move the orbit remain stable when pan feeding diffusion strikes, also do benefit to the quick row of low density material at the bin outlet.

As shown in fig. 2 and 3, the separation air holes 31 are distributed on the panel of the intelligent vibration main separation bed, and the diameter of the separation air hole close to the upper separation frame of the intelligent vibration main separation bed is gradually larger than that of the separation air hole close to the lower separation frame of the intelligent vibration main separation bed. Specifically, referring to fig. 3, the separation air hole 31 and the intelligent vibration main selection bed panel are arranged in an inclined manner, that is, the separation air hole 31 and the intelligent vibration main selection bed panel are not arranged vertically, the air direction of the intelligent vibration main selection bed panel passing through the bed panel is vertically incident to the intelligent vibration main selection bed panel, that is, the separation air flow is vertically incident to the intelligent vibration main selection bed panel, and the separation air flow passing through the separation air hole 31 is inclined out from the bed panel and is emitted to the separation coal material. Correspondingly, the partition plates of the bed panel are arranged between the separation air holes 31 at intervals and used for adjusting the distance between the separation air holes 31. The intelligent vibration main separation bed panel is preferably a bed panel 28 with separation air holes.

The existing traditional bed surface sorting air holes are vertical through holes, and air is blown out vertically through the small holes; the utility model discloses intelligence vibration main separation bed panel selects separately wind hole to change into the inclined hole, and the incline direction is the discharge end, and the air current blows off an effort of slope and ejection of compact direction occasionally from these select separately wind holes like this, and this power can accelerate the velocity of motion of material on the bed surface. Preferably, only the first bed surface hole at the feeding end of the bed panel of the intelligent vibration main separation bed is changed into an inclined hole, the inclined direction is the discharging end, and the separation air holes of other bed panels of the intelligent vibration main separation bed adopt vertical separation air holes.

Fig. 4 is a schematic longitudinal side view of the intelligent vibration main sorting bed of fig. 1, and fig. 5 is a schematic longitudinal side view of the intelligent vibration main sorting bed with the sorting grid bars installed. As shown in fig. 4 and 5, the super energy-saving dry coal preparation system with intelligent dust removal detection adopts a back plate structure, the back plate is perpendicular to the intelligent vibration main selection bed panel, and the back plate 41 is arranged on the upper sorting frame of the intelligent vibration main selection bed panel and is fixedly connected together. Optionally, the back plate 41 is detachably connected to the sorting upper rim of the intelligent vibration main sorting bed panel 32. As shown in fig. 6, the vibration direction of the back plate is parallel to the longitudinal thrust applied to the coal material, that is, the coal material is subjected to downward longitudinal thrust under the dual actions of the vibration of the bed surface and the back plate. The back plate and the ground form a certain included angle alpha.

The utility model discloses intelligence vibration main bed panel adopts the perpendicular backplate that sets up, directly provides a longitudinal thrust for the coal material of selecting. Compared with the traditional main sorting bed, the angle between the back plate and the main sorting bed surface is an acute angle of 60-70 degrees, and the existing back plate has the function of turning materials on the main sorting bed based on the sorting principle of a dry sorting machine; the utility model discloses change this backplate angle into vertically 90 for dry separation machine is at the sorting process, changes original upset effort into a thrust of material forward motion, accelerates the rate of motion of material on the bed surface.

Furthermore, as shown in fig. 4, a longitudinal angle monitor 1501 and a transverse angle monitor 1502 are installed on the main bed selector, the longitudinal angle monitor 1501 is used for monitoring the longitudinal vibration angle of the intelligent vibration main bed selector, and the transverse angle monitor 1502 is used for monitoring the transverse vibration angle of the intelligent vibration main bed selector; the angle parameters of the main separation bed body are displayed in real time, the automatic adjustment of the main separation bed body is completed by more effectively matching production, and the intellectualization of the super energy-saving dry coal separation system with intelligent dust removal detection is greatly improved.

As shown in fig. 7 and 8, the external view of the super energy-saving dry coal preparation system with intelligent dust removal detection and provided with the quick access door is shown, the super energy-saving dry coal preparation system with intelligent dust removal detection and provided with intelligent dust removal detection further comprises a fully-closed dust hood 11 and a quick access door 1101, and the fully-closed dust hood 11 is buckled on the separation part to realize fully-closed separation; the quick access door 1101 is arranged on the side face of the upper cover body of the sorting part, and the maintenance and inspection equipment is operated through the quick access door 1101 on a daily basis. A product chute 4 is arranged below the intelligent vibration main separation bed body, and the product chute 4 is divided into a clean coal discharging chute 22, a middlings discharging chute 23 and a gangue discharging chute 24 according to different types of received materials. Furthermore, four sides of the fully-closed dust hood 11 just correspond to four sides of the main selection bed 15, and two sides and the rear side of the fully-closed dust hood are connected with two sides and the rear side of the main selection bed 15 through dust filtering cloth 1102, so that no dust gas is emitted outside. The front of the fully-closed dust hood 11 is provided with a plurality of quick access doors 1101, the quick access doors 1101 can be opened to directly reach the bed surface of the main separation bed 15, the maintenance work can be conveniently carried out, in addition, the top of the fully-closed dust hood 11 is provided with a pipeline hole connected with the fully-bag dust collector 10, and gas mixed with dust can enter the fully-bag dust collector 10 through the pipeline hole to be filtered and circulated.

Furthermore, two sets of pipeline holes are arranged on the fully-closed dust collecting cover 11, the two sets of pipeline holes are respectively connected to the full-bag dust collector 10, and an independent dust collection power system is arranged in each pipeline hole and used for adjusting dust collection power of each pipeline hole of the independent dust collection power system according to dust concentration difference in the upper space of the intelligent vibration main separation bed.

As shown in fig. 9, an intelligent material transporting system is additionally installed on the basis of fig. 8, a belt weigher 91 is arranged below a belt conveyor 92 for conveying coal materials by power, and the belt weigher 91 is preferably an intelligent belt weigher with a wireless transmission function, and can transmit the real-time conveying amount of the coal materials to a central control platform of a central control room, so that the material data analysis and control of coal sorting are realized in real time on the central control platform of the central control room.

As shown in fig. 1, the dust from the sorting space of the intelligent vibration main sorting bed of the pipeline hole sequentially enters the full-bag dust collector 10 through the dust collector air inlet 9 via the dust collecting pipeline 12.

Fig. 12 is a schematic diagram of blast separation of a super energy-saving dry coal separation system with intelligent dust removal detection, wherein a blast passage is arranged below an intelligent vibration main separation bed, and an air passage is preferably adjacent to a separated material discharge opening. Therefore, the field power layout is conveniently and reasonably arranged, and the utilization rate of the field space is improved. Further, the utility model discloses in use two way wind sources at least for can adjust the air feed condition of each wind path respectively, and then realize the air feed as required. And according to the wind path that sets up as figure 12, its air inlet windage is very little, has promoted the efficiency with wind.

In summary, the above is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a super energy-conserving dry process coal dressing system with dust removal intellectual detection system, a serial communication port, it includes raw coal feed part, the air feed part, select separately part and dust removal part, wherein the dust removal part includes intelligent air regulation dust pelletizing system, intelligent air regulation dust pelletizing system includes dust removal pipeline (12), full sack cleaner (10), sack draught fan (18) and intelligent control platform, intelligent control platform carries out the intelligent control of wind speed amount of wind and data anomaly in the production process according to sensor data and carries out the early warning.

2. The super energy-saving dry coal preparation system with intelligent dust removal detection as claimed in claim 1, wherein the super energy-saving dry coal preparation system with intelligent dust removal detection is provided with a wind speed sensor on a dust removal pipeline (12) for detecting the wind speed of the impurity-containing gas; a first concentration sensor is arranged in the full-bag dust collector (10) and is used for detecting the dust concentration in the full-bag dust collector (10); a second concentration sensor and a gas phase sensor are arranged on a chimney (19) of the induced draft fan, the second concentration sensor is used for detecting the concentration of dust discharged into the atmosphere, and the gas phase sensor is used for detecting gas components of the dust discharged into the atmosphere.

3. The super energy-saving dry coal preparation system with intelligent dust removal detection function according to claim 2, wherein a plurality of wind speed sensors are arranged on the dust removal pipeline.

4. The super energy-saving dry coal preparation system with intelligent dust removal detection function according to claim 3, wherein a pressure sensor is arranged on the dust removal pipeline.

5. The super energy-saving dry coal preparation system with intelligent dust removal detection function according to claim 2, wherein a plurality of first concentration sensors are arranged at different positions of the full bag-type dust remover (10).

6. The super energy-saving dry coal preparation system with intelligent dust removal detection function according to claim 5, wherein the first concentration sensors with different position densities are arranged above different areas on the main separation bed.

7. The super energy-saving dry coal preparation system with intelligent dust removal detection as claimed in claim 1, wherein the main control system regulates and controls the operating power of the left main blower (1) and the right main blower (8) according to the separation index or the separation requirement, so as to realize intelligent dust removal regulation and control.

8. The super energy-saving dry coal preparation system with intelligent dust removal detection function according to claim 1, wherein a left overhaul observation window (701) is arranged on an air duct through which the left main fan (1) is fed into the left air distributor (3) through the left main fan air valve (2).

9. The super energy-saving dry coal preparation system with intelligent dust removal detection function according to claim 1, wherein a right overhaul observation window (702) is arranged on an air duct of the right main fan (8) which is fed into the right air distributor (6) through a right main fan air valve (7).

10. The super energy-saving dry coal preparation system with intelligent dust removal detection function according to claim 1, wherein a left overhaul observation window (701) is arranged between a left main fan air valve (2) and a left air distributor (3); or the right maintenance observation window (702) is arranged between the right main fan air valve (7) and the right air divider (6).

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