CN113184497A - Coal conveying system - Google Patents

Abstract

The invention relates to the field of fire coal detection of thermal power plants, in particular to a coal conveying system. The coal conveying system comprises a coal breaker, a vibrating screen, a coal hopper, a granularity and particle size distribution detection device and a conveying belt; the vibrating screen is arranged at the lower end of the coal crusher, the outlet end of the coal crusher is communicated with the inlet end of the coal dropping hopper, and the outlet end of the coal dropping hopper is positioned at the upper part of the conveying belt; the granularity and particle size distribution detection device comprises a detection channel, a granularity and distribution detector and a classification device; the grading device divides the coal flow bundle in the detection channel into a plurality of grades according to the particle size, and a granularity and distribution detector is arranged corresponding to the coal flow bundle of each grade; the inlet end of the detection channel is communicated with the upper end of the coal hopper, and the outlet end of the detection channel is communicated with the lower end of the coal hopper. The coal conveying system can realize the on-line detection of the granularity and the particle size distribution of the coal as fired. Can in time carry out the pertinence to the boiler and adjust according to this, improve boiler combustion efficiency.

Description

Coal conveying system

Technical Field

The invention relates to the field of fire coal detection of thermal power plants, in particular to a coal conveying system.

Background

The large circulating fluidized bed boiler (CFB) of the coal-fired power plant has the advantages of high efficiency, low pollution, suitability for various fuels, good load regulation performance, strong comprehensive ash availability and the like. However, the CFB boiler also puts forward strict requirements on the granularity and the grain composition of the fuel entering the boiler, and the granularity, the grain size distribution and the grain composition of the coal entering the boiler have great influence on ignition starting, operation control and combustion efficiency of the circulating fluidized bed boiler.

The basic requirements for the operation of the circulating fluidized bed boiler are that the dilute phase region and the dense phase region are normally distributed when the bed material is boiling, and the bed temperature is kept stable, so the granularity of the coal as fired must be guaranteed, and a proper screening proportion is required. If a large amount of coal blocks enter the fluidized bed to be combusted in operation, the coal blocks can deposit in the bed body to form a dead zone, the normal fluidized state is damaged, the temperature field in the furnace is not uniform, and the furnace is forced to be shut down due to coking caused by over-low bed temperature or over-high bed temperature. If the particle components of the coal are too fine, the amount of fine powder is educed, even the fine powder can not be captured by a separator, the fine powder enters a tail flue after being incompletely combusted, tail fly ash is increased, the carbon content of the fly ash is increased (more than 50% in serious cases), and the thermal efficiency of a boiler is reduced. Therefore, it is very important to sample and detect the granularity and particle size distribution of the coal as fired in time.

At present, most circulating fluidized bed power plants detect the granularity and the particle size distribution of coal as fired by adopting a laboratory test method after mechanical sampling or manual sampling; the general test time is 6-8 hours according to different coal types, and the test is carried out once per shift. Therefore, the current methods have the following disadvantages:

1) the real-time detection and timely analysis of the granularity effect of the outlet of the crusher cannot be realized, so that problems can be found and adjustment measures can be taken conveniently;

2) due to the influence of human factors and objective conditions, the detection result has deviation.

For a power plant without an intermediate grading coal bunker, the coal after being crushed by the secondary coal crusher directly enters a boiler for combustion through a belt, and because the manual sampling and testing time is long, the coal cannot be detected in time to obtain information feedback, and the coal is sent into a hearth for combustion, is unfavorable for operation regulation, and is not favorable for preventing and controlling the occurrence of boiler operation production accidents caused by excessive granularity in advance.

For detecting the granularity and the particle size distribution of coal as fired in a thermal power plant, the current common laboratory test method comprises the following steps: according to a GB/T477-. With the development of new technologies, the following particle size instruments and methods are available: dynamic light scattering method, nanoparticle tracking analysis technology, resonance quality measurement technology, laser diffraction technology, spatial filtering velocimeter, and automatic imaging technology.

However, the existing coal as fired detection is in the laboratory detection stage, and the online detection of the coal as fired cannot be realized.

Disclosure of Invention

The invention provides a coal conveying system, which solves the problem that as-fired coal cannot be detected on line in the prior art.

The technical scheme of the invention is realized as follows:

a coal conveying system, comprising: the device comprises a coal crusher, a vibrating screen, a coal hopper, a granularity and particle size distribution detection device and a conveying belt;

the vibrating screen is arranged at the lower end of the coal crusher, the outlet end of the coal crusher is communicated with the inlet end of the coal dropping hopper, and the outlet end of the coal dropping hopper is positioned at the upper part of the conveying belt;

the granularity and particle size distribution detection device comprises a detection channel, a granularity and distribution detector and a classification device;

the grading device divides the coal flow bundle in the detection channel into a plurality of grades according to the particle size, and a granularity and distribution detector is arranged corresponding to the coal flow bundle of each grade;

the inlet end of the detection channel is communicated with the upper end of the coal hopper, and the outlet end of the detection channel is communicated with the lower end of the coal hopper.

Preferably, the inlet end of the detection channel is communicated with the upper end of the coal hopper through a sampling and shunting device, and the outlet end of the detection channel is communicated with the lower end of the coal hopper through a lower connector;

the sampling and distributing device and the lower interface are obliquely arranged coal circulation channels, and the detection channel is vertically arranged coal circulation channels.

Preferably, the particle size and distribution detector comprises a laser phase array transmitting device and a laser phase array receiving device which are arranged oppositely.

Preferably, the coal-saving device also comprises a large-particle coal channel;

the lower end of the sampling and shunting device is provided with a detection channel feed opening, and the side wall of the sampling and shunting device is provided with a large-particle feed opening;

the feed opening of the detection channel is communicated with the sampling and shunting device of the detection channel;

the large-particle feed opening is communicated with a sampling and shunting device of the large-particle coal channel;

and the inlet end of the feed opening of the detection channel is provided with a large-particle filter sieve.

Preferably, the classification device comprises a sound wave generator and a gas source;

the sound wave generator is communicated with an air source;

a plurality of sound wave generators are arranged in the detection channel side by side from bottom to top.

Preferably, a coal outlet is arranged on the detection channel at a position corresponding to the opening end of each sound wave generator.

Preferably, the sound generators are arranged adjacently, and the sound wave power of the sound generator arranged at the low position is greater than the sound wave power of the sound generator arranged at the high position.

Preferably, the sound wave power of the plurality of sound wave generators arranged from top to bottom is gradually increased.

Preferably, the grading device further comprises an outer protecting shell and an outlet protecting shell;

the sound wave generator is arranged in the outer protective shell, and the outlet protective shell is arranged at the outlet end of the outer protective shell;

at least the outlet protective shell of the acoustic wave purging and grading device extends into the detection channel.

Preferably, the particle size and distribution detector further comprises an analyzer control station, and the particle size and distribution detector is electrically connected with the analyzer control station.

In the technical scheme of the invention, the grading device divides the coal stream as fired into different grades, then the coal stream of each grade is detected by the granularity and distribution detector, and the granularity and the particle size distribution of the coal as fired can be obtained according to the detection result. The operating personnel can in time carry out the pertinence to the boiler and adjust according to this, ensure that the boiler moves under the best operating mode, improve boiler combustion efficiency.

The invention can avoid the combustion operation accident of the circulating fluidized bed boiler caused by the large granularity of the coal as fired in time, reduce the operation accident of the boiler, directly reduce the power consumption of the station and bring direct economic benefit for the power plant.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a coal conveying system according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a device for detecting particle size and particle size distribution according to an embodiment of the present invention;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2;

FIG. 4 is a schematic view of another angle structure of the particle size and particle size distribution detecting apparatus according to the embodiment of the present invention

FIG. 5 is a cross-sectional view taken along line B-B of FIG. 4;

FIG. 6 is a schematic structural diagram of a grading apparatus provided in accordance with an embodiment of the present invention;

fig. 7 is a right side view of a grading apparatus provided in accordance with an embodiment of the present invention.

1: a coal crusher; 2: vibrating screen; 3: a coal dropping hopper; 4: a granularity and particle size distribution detection device; 5: a conveyor belt;

41: a detection channel; 42: a granularity and distribution detector; 43: a grading device; 44: a sampling and shunting device; 45: a lower interface; 46: a large particle coal passage;

411: a front side plate; 412: a rear side plate; 413: a left side plate; 414: a right side plate;

421: a laser phased array emitting device; 422: a laser array receiving device;

4211: a laser generator; 4212: an emission housing; 4213: a launch protection screen;

4221: a laser receiver; 4222: a receiving housing; 4223: receiving a protection screen;

431: an acoustic wave generator; 432: a gas source; 433: an outer protective shell; 434: an outlet protective shell;

441: a coal diversion port; 442: a feed opening of the detection channel; 443: a large particle feed opening; 444: a large-particle filter screen.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 to 7, in the present embodiment, there is provided a coal conveying system including: coal breaker 1, shale shaker 2, coal hopper 3, granularity and particle size distribution detection device 4 and conveyor belt 5.

The vibrating screen 2 is arranged at the lower end of the coal crusher 1, the outlet end of the coal crusher 1 is communicated with the inlet end of the coal dropping hopper 3, and the outlet end of the coal dropping hopper 3 is positioned at the upper part of the conveying belt 5.

The particle size and particle size distribution detecting apparatus 4 includes a detecting passage 41, a particle size and distribution detecting instrument 42, and a classifying apparatus 43.

The classifying device 43 divides the coal flow bundle in the detection passage 41 into a plurality of classes according to the particle size, and a granularity and distribution detector 42 is provided corresponding to the coal flow bundle of each class.

The inlet end of the detection channel 41 is communicated with the upper end of the coal hopper 3, and the outlet end of the detection channel 41 is communicated with the lower end of the coal hopper 3.

In the present embodiment, the classifying device classifies the stream of coal as fired into different classes, and detects the streams of coal of each class by the particle size and distribution detector, and the particle size and particle size distribution of the coal as fired can be obtained from the detection result. The operating personnel can in time carry out the pertinence to the boiler and adjust according to this, ensure that the boiler moves under the best operating mode, improve boiler combustion efficiency.

The invention can avoid the combustion operation accident of the circulating fluidized bed boiler caused by the large granularity of the coal as fired in time, reduce the operation accident of the boiler, directly reduce the power consumption of the station and bring direct economic benefit for the power plant.

Particle size and particle size distribution detection device 4

Referring to fig. 2 to 5, the inlet end of the detection channel 41 is communicated with the upper end of the coal hopper 3 through a sampling and shunting device 44, and the outlet end of the detection channel 41 is communicated with the lower end of the coal hopper 3 through a lower connector 45.

The sampling and flow-dividing device 44 and the lower interface 45 are both obliquely arranged coal flow channels, and the detection channel 41 is a vertically arranged coal flow channel.

The particle size and particle size distribution detection apparatus 4 further includes a large particle coal passage 46.

Specifically, the upper end of the sampling and flow-dividing device 44 is provided with a coal guide opening 441, the lower end of the sampling and flow-dividing device 44 is provided with a detection channel feed opening 442, and the side wall of the sampling and flow-dividing device 44 is provided with a large particle feed opening 443.

The coal guide opening 441 is communicated with the upper end of the coal hopper 3, the detection channel feed opening 442 is communicated with the upper interface of the detection channel 41, and the large-particle feed opening 443 is communicated with the upper interface of the large-particle coal channel 46. The lower port of the large-particle coal passage 46 is communicated with the lower end of the coal hopper 3. Wherein, the inlet end of the feed opening of the detection channel is provided with a large-particle filter screen 444.

Coal conveyed in the coal hopper 3, part of the coal can enter the sampling shunting device 44 through the coal guide opening 441, the coal entering the sampling shunting device 44 enters the detection channel 41 through the large-particle filter screen 444 and the detection channel feed opening under the screening action of the large-particle filter screen 444, and the rest part of the coal enters the large-particle coal channel 46 through the large-particle feed opening under the blocking action of the large-particle filter screen 444. The coal passing through the large particle coal passage 46 and the detection passage 41 is finally returned to the hopper 3.

The particle size and distribution detector 42 includes a laser array transmitter 421 and a laser array receiver 422, which are disposed opposite to each other.

The laser phased array emission device 421 includes a laser generator 4211, an emission housing 4212, an emission protection screen 4213, and an emission screen cleaning brush.

The laser generator 4211 is fixed in the launch housing 4212, and the launch protection screen 4213 is fixed at one side of the launch housing 4212.

One side of the emission housing 4212 having the emission protection screen 4213 is connected to the sensing passage 41, an emission end of the laser generator 4211 is disposed toward the emission protection screen 4213, and laser light emitted from the laser generator 4211 can enter the sensing passage 41 through the emission protection screen 4213.

The launch screen wiper is disposed on the launch protection screen 4213. The launch screen cleaning brush can clean the launch protection screen 4213 and can clean coal ash on the launch protection screen 4213.

The laser light array receiving device 422 comprises a laser receiver 4221, a receiving shell 4222, a receiving protection screen 4223 and a receiving screen cleaning brush.

The laser receiver 4221 is fixed in the receiving housing 4222, and the receiving protection screen 4223 is fixed on one side of the receiving housing 4222.

One side of the receiving housing 4222 having the receiving protection screen 4223 is connected to the detection passage 41, a receiving end of the laser receiver 4221 is disposed toward the receiving protection screen 4223, and the laser receiver 4221 can receive laser light emitted from the laser emitter 4211.

Further, the transmitting housing 4212 and the receiving housing 4222 are connected to the detecting channel 41 through a passage or an opening, and a transmitting protection screen 4213 and a receiving protection screen 4223 are respectively disposed on the corresponding passages or openings, so that the laser emitted from the laser generator 4211 can be received by the oppositely disposed laser receiver 4221.

The receiving screen wiper is provided on the receiving protection screen 4223. The receiving screen cleaning brush can clean the receiving protection screen 4223 and can clean coal ash on the receiving protection screen 4223.

It is emphasized that the laser array transmitter 421 and the laser array receiver 422 are provided in pairs. According to the number of grades of the coal flow beam particle size, a corresponding number of laser phased array emitting devices 421 and laser phased array receiving devices 422 are correspondingly arranged.

The detection passage 41 is a barrel-shaped structure surrounded by a plurality of side plates, and includes a front side plate 411, a rear side plate 412, a left side plate 413, and a right side plate 414.

A plurality of platforms for placing the laser phased array emitting devices 421 are disposed on the front side plate 411, and one laser phased array emitting device 421 is disposed on each platform of the front side plate 411.

The rear side plate 412 is provided with a plurality of platforms for placing the laser array receiving devices 422, and each platform of the rear side plate 412 is provided with one laser array receiving device 422.

Grading device 43

Referring to fig. 6, 7, the classifier 43 includes an acoustic wave generator 431 and a gas source 432, the acoustic wave generator 431 being in communication with the gas source 432.

A plurality of sound wave generators 431 are arranged in the detection channel 41 side by side from bottom to top, and a coal outlet is arranged on the side wall of the detection channel 41 corresponding to the opening end of each sound wave generator 431.

In the present embodiment, the coal as fired flows through the detection passage 41, and when the coal as fired passes through the sound wave generator, the sound wave generator 431 purges a part of the coal particles in the coal as fired to the coal outlet. By arranging a plurality of sound wave generators 431 in the detection channel 41, the coal as fired can be divided into a plurality of different coal particle grades by controlling the sound wave power of the sound wave generators 431. Namely, in the process of conveying the coal as fired, the classification of the coal as fired can be realized.

The sound wave generators are arranged adjacently, and the sound wave power of the sound wave generator at the low position is larger than that of the sound wave generator at the high position.

Specifically, the sound wave power of the plurality of sound wave generators arranged from top to bottom is gradually increased.

The larger the power of the sound wave generator is, the larger the coal particles are swept out. The sound wave generators arranged adjacently have the advantage that the power of the sound wave generator at the low position is larger than that of the sound wave generator at the high position, so that the coal as fired can be separated into the gradually enlarged particle size range from top to bottom. The gradual increase here is a linear increase, and may be a nonlinear increase.

Specifically, if it is necessary to classify the coal as fired in the detection channel 41 into seven grades, the particle size of the coal as fired in the detection channel is gradually increased, so that six sonic purging and classifying devices may be provided in the detection channel. The sonic generator 431 of each classifier 43 corresponds to a unique frequency band that generates sonic airflows that can produce coal particles of different particle sizes and particle size ranges (see table 1).

The staging device 43 also includes an outer shroud 433 and an outlet shroud 434. The acoustic wave generator 431 is disposed within an outer housing 433, and an outlet housing 434 is disposed at an outlet end of the outer housing 433.

And at least the outlet protective shell 434 of the acoustic purging grading device extends into the detection channel 41, by this arrangement it can be ensured that the acoustic waves emitted by the acoustic purging grading device can enter the detection channel 41.

The length of the outlet shielding shell 433 is gradually reduced from top to bottom. Typically, the detection channel 41 is arranged in a vertical direction. The coal as fired flows in the upward-downward direction in the detection passage 41. By setting the outlet shielding shell 433 to the above-described structure, it is possible to prevent the coal as fired from entering the acoustic wave purging classification device.

The acoustic wave generator 431 includes a straight tube section and a flare section, wherein an inlet end of the straight tube section is connected with the air source 432, and an outlet section of the straight tube section is connected with an inlet end of the flare section. Specifically, a branch pipe is connected to the inlet end of the straight pipe section of the sound wave generator 431 of each sound wave purging and classifying device. Each branch pipe is communicated with one main pipe and then communicated with an air source 432 through the main pipe.

The exit shield 434 has a plurality of uniformly arranged grid holes having a square, rectangular or diamond cross-section. The purpose of arranging the grid holes is to prevent the coal as fired from entering the sound wave purging and grading device. The specific shape of the grid holes can be set according to actual needs.

The detection passage 41 is a barrel-shaped structure surrounded by a plurality of side plates, and includes a front side plate 411, a rear side plate 412, a left side plate 413, and a right side plate 414.

Specifically, a plurality of platforms for placing the grading devices 43 are arranged on the left side plate 413 of the detection channel, and each platform of the left side plate 413 is provided with one grading device 43. The open end of the acoustic-wave generator 431 of the classifying means 43 is disposed toward the detection channel 41 and is capable of generating an acoustic wave like in the detection channel 41. Correspondingly, a coal outlet is arranged on the right side plate 414 corresponding to the open end of each sound wave generator of the grading device.

The on-line acoustic classifier also includes large particle coal channels for collecting the coal particles separated by the classifier 43. The detection channel is communicated with the large-particle coal channel through a coal outlet. The coal separated by the classifying means 43 eventually enters the large particle coal passage.

To further explain the above coal conveying system, in this embodiment, a method for detecting the particle size and particle size distribution of coal as fired is further provided, which includes the following steps:

the embodiment treats the coal as fired of the coal-fired system of the circulating fluidized bed boiler thermal power plant, and the specific steps are as follows:

coal as fired in a thermal power plant is processed by a coal crusher 1 and a vibrating screen 2 and then falls into a coal hopper 3. In the coal dropping hopper 3, part of the coal as fired is collected by the sampling and shunting device 44 and then enters the granularity and granularity distribution detection device 4, the granularity and granularity distribution detection device 4 carries out online dynamic detection on the granularity and granularity distribution of the coal as fired (the detection method mainly utilizes the existing laser diffraction method to determine the granularity and granularity distribution of solid particles in a sample to be detected, and similar methods are disclosed in the application numbers of CN201410195405.5 and CN201811391569. X), and the detection data are transmitted to an analyzer control station for processing through data and control cables; and the analyzer control station obtains the result data of the granularity and the particle size distribution of the coal as fired after calculation and provides the data for operators or an automatic control system.

The detected coal as fired returns to the lower channel of the coal hopper 3 through the lower interface 45, finally falls on the coal as fired conveying belt 5, and then is conveyed to a boiler room.

The coal as fired is sampled on line through the coal guiding opening 441 of the sampling and shunting device 44, the coal particles with the granularity larger than 6mm are separated after the coal as fired is sampled and shunted and passes through the large-particle filter sieve 444, and the coal particles with the granularity larger than 6mm directly enter the large-particle coal channel through the large-particle feed opening 443. The coal particles with the granularity less than or equal to 6mm fall into the detection channel 41 through the detection channel feed opening 442. The coal particles with the granularity larger than 6mm pass through the large particle feed opening 443, are detected on line through the large particle metering device, and data are transmitted to the analyzer control station through cables.

And equally dividing the detection channel into seven layers of areas along the upper and lower elevations. And a grading device 43 is arranged on each layer area of the right side plate 414 of the corresponding coal particle channel, the sound wave generator 431 of each grading device 43 corresponds to a unique frequency section, and the corresponding generated sound wave airflow can sweep and separate coal particles (see table 1) with different particle sizes and particle size ranges from the sampling coal flow entering the furnace to the large-particle coal channel 46.

Table 1: corresponding relation between coal granularity and frequency power

The swept and separated coal particles are converged and fall into a coal dropping hopper 3, and finally fall onto a coal conveying belt 5 through the coal dropping hopper 3.

The areas of the front layers are all provided with a grading device 43, the large-particle coal with the thickness of 4.5-6 mm on the lowest layer is not provided with a grading device, directly passes through the lower end of the detection channel, returns to enter the outlet lower channel of the coal hopper 3 at the rear end of the vibrating screen through a lower connector 45, and finally falls onto a coal conveying belt 5 of a transfer station.

When the sampling coal particle flow stream in the furnace passes through the detection channel 41, the grading device 43 can carry out on-line grading treatment on the sampling coal particle flow stream in the furnace; the coal as fired sampling flow beams with different granularity levels can be processed in a grading way in different detection channel layer areas, and basic guarantee is provided for improving the subsequent detection accuracy.

On the seven corresponding layers of platforms on the front side plate 411 of the detection channel 41, each layer is fixed with a laser phased array emitting device 421; on the seven corresponding layers of platforms on the rear side plate 412 of the detection channel 41, each layer is fixed with a laser light array receiving device 422; when the coal as fired passes through the detection channel 41, the laser beam emitted by each laser phased array emitting device 421 is received 422 by the corresponding laser phased array receiving device after passing through the coal-fired particles falling down instantly in the channel; the laser phased array receiver 422 transmits the received optical signal to the analyzer control station via data and control cables.

The single laser beam emitted by each laser phased array emitter 421 is focused, low-pass filtered and collimated to become parallel light with a diameter of 25-30 mm. A plurality of parallel lights emitted by the laser generator 4211 in each laser phased array emission device 421 are superposed to form a cross section: the width of the parallel array light beam is 200mm-400mm, and the height of the parallel array light beam is 100mm-200 mm.

The parallel phased array beam irradiates and passes through the coal particle beam in the detection channel 41, and then reaches the laser receiver 4221 in the corresponding laser phased array receiving device 422. As the coal as fired particle beams with different particle sizes block or refract the passing laser beams, the energy of the laser beam array beam passing through the gap of the coal particles is attenuated, and the intensity of the laser beam energy signal collected by the laser receiver 4221 in the laser beam array receiving device is weakened and is distributed in a specific intensity value range.

When the parallel phased array beam emitted by the laser phased array emitting device 421 transmits the sampled coal stream after the layered classification processing, since the sampled coal stream of each layer has been processed to different granularity levels, the intensity attenuation of the laser beam is different when the phased array beam transmits through the gaps between the coal particles of different granularity levels. Therefore, the intensity of the laser beam energy signal collected by the laser receiver 4221 in the laser phased-array receiving device 422 is also different, and the intensity of the laser beam energy signal collected by different granularities is distributed in different intensity value ranges. By establishing laser beam intensity attenuation calculation models corresponding to different granularities and performing simulation calculation in an analyzer control station through computer software, the layered granularity proportion of the coal as fired can be accurately calculated, and finally, a granularity distribution result is obtained, so that the practical application of online detection of the granularity of the inlet coal is realized.

In summary, in the present embodiment, in the process of online detecting the particle size and particle size distribution of the coal as fired in the circulating fluidized bed boiler, the classifying device can perform online classification treatment on the coal particle flow stream sampled as fired; the coal as fired sampling flow beams with different granularity levels can be processed in a grading way in different coal detection channel layer areas, and basic guarantee is provided for improving the follow-up detection accuracy.

In the embodiment, a laser phased array transmitting device is adopted to transmit parallel phased array beams; the emitted parallel phased array light beam has wide cross-sectional dimension, and the laser phased array receiving device has wide signal receiving range, so that a new method for establishing a corresponding calculation model of intensity attenuation of the sampling coal flow beams with different particle size distributions and the laser phased array light beams can be established, and the accuracy of online detection of the particle size and the particle size distribution can be improved.

The particle size and particle size distribution of the coal entering the furnace for sampling after the secondary coal crusher and the vibrating screen can be tracked on line in time, the online detection speed is high, the sampling detection of the full coal flow can be realized, and the influence of human factors is reduced; the working conditions of the coal crusher and the vibrating screen can be monitored by operators at any time, and the granularity of coal entering the furnace can be adjusted in time;

this embodiment can also in time provide into stove sample coal particle size and particle size distribution data on line, and the operation personnel can in time adjust the boiler pertinence in view of the above, ensures that the boiler moves under the best operating mode, improves boiler combustion efficiency.

The invention can avoid the combustion operation accident of the circulating fluidized bed boiler caused by the large granularity of the coal as fired in time, reduce the operation accident of the boiler, directly reduce the power consumption of the station and bring direct economic benefit for the power plant.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (10)

1. A coal conveying system, comprising: the device comprises a coal crusher, a vibrating screen, a coal hopper, a granularity and particle size distribution detection device and a conveying belt;

the vibrating screen is arranged at the lower end of the coal crusher, the outlet end of the coal crusher is communicated with the inlet end of the coal dropping hopper, and the outlet end of the coal dropping hopper is positioned at the upper part of the conveying belt;

the granularity and particle size distribution detection device comprises a detection channel, a granularity and distribution detector and a classification device;

the grading device divides the coal flow bundle in the detection channel into a plurality of grades according to the particle size, and a granularity and distribution detector is arranged corresponding to the coal flow bundle of each grade;

the inlet end of the detection channel is communicated with the upper end of the coal hopper, and the outlet end of the detection channel is communicated with the lower end of the coal hopper.

2. The coal conveying system of claim 1, wherein an inlet end of the detection channel is communicated with an upper end of the coal hopper through a sampling and shunting device, and an outlet end of the detection channel is communicated with a lower end of the coal hopper through a lower port;

the sampling and distributing device and the lower interface are obliquely arranged coal circulation channels, and the detection channel is vertically arranged coal circulation channels.

3. The coal conveying system of claim 1 or 2, wherein the particle size and distribution detector comprises a laser phase array emitting device and a laser phase array receiving device which are oppositely arranged.

4. The coal conveying system of claim 2, further comprising large particle coal passageways;

the lower end of the sampling and shunting device is provided with a detection channel feed opening, and the side wall of the sampling and shunting device is provided with a large-particle feed opening;

the feed opening of the detection channel is communicated with the sampling and shunting device of the detection channel;

the large-particle feed opening is communicated with a sampling and shunting device of the large-particle coal channel;

and the inlet end of the feed opening of the detection channel is provided with a large-particle filter sieve.

5. The coal handling system of claim 1, wherein the staging device includes a sonic generator and a gas source;

the sound wave generator is communicated with an air source;

a plurality of sound wave generators are arranged in the detection channel side by side from bottom to top.

6. The coal conveying system of claim 5, wherein the detection channel is provided with a coal outlet at a position corresponding to an open end of each of the acoustic wave generators.

7. The coal conveying system of claim 5, wherein the adjacently disposed acoustic generators, the acoustic generator at a low location having a greater acoustic power than the acoustic generator at a high location.

8. The coal conveying system of claim 7, wherein the sound wave power of the plurality of sound wave generators arranged from top to bottom is gradually increased.

9. The coal delivery system of claim 5, wherein the staging device further comprises an outer jacket and an outlet jacket;

the sound wave generator is arranged in the outer protective shell, and the outlet protective shell is arranged at the outlet end of the outer protective shell;

at least the outlet protective shell of the acoustic wave purging and grading device extends into the detection channel.

10. The coal delivery system of claim 1, further comprising an analyzer control station, the particle size and distribution detector being electrically connected to the analyzer control station.

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