CN114408588A - Pneumatic conveying detection method and detection equipment for particulate matters - Google Patents

Pneumatic conveying detection method and detection equipment for particulate matters Download PDF

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Publication number
CN114408588A
CN114408588A CN202111666469.5A CN202111666469A CN114408588A CN 114408588 A CN114408588 A CN 114408588A CN 202111666469 A CN202111666469 A CN 202111666469A CN 114408588 A CN114408588 A CN 114408588A
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China
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particulate matter
flow
gas
particle
conveying
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CN202111666469.5A
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谭险峰
黄涛
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CHENGDU RUIKELIN ENGINEERING TECHNOLOGY CO LTD
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CHENGDU RUIKELIN ENGINEERING TECHNOLOGY CO LTD
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Priority to CN202111666469.5A priority Critical patent/CN114408588A/en
Publication of CN114408588A publication Critical patent/CN114408588A/en
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65GTRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
    • B65G53/00Conveying materials in bulk through troughs, pipes or tubes by floating the materials or by flow of gas, liquid or foam
    • B65G53/34Details
    • B65G53/66Use of indicator or control devices, e.g. for controlling gas pressure, for controlling proportions of material and gas, for indicating or preventing jamming of material

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Measuring Volume Flow (AREA)

Abstract

An object of the embodiment of the application is to provide a pneumatic conveying detection method and detection equipment for particulate matters, so as to solve the technical problem that the running condition of a pneumatic conveying system for the particulate matters is detected by detecting flowing particulate matters in pneumatic conveying of the particulate matters. The method is used for detecting the operation condition of the pneumatic particulate matter conveying system; the pneumatic particulate matter conveying system comprises a particulate matter fluidizer, a particulate matter conveying pipe and a particulate matter recoverer; the method comprises the following steps: acquiring basic operation state information of the pneumatic particulate matter conveying system, wherein the basic operation state information is used for determining a detection reference of the operation condition; acquiring dynamic information of the particulate matter flow in the particulate matter conveying pipe, wherein the dynamic information of the particulate matter flow is acquired by a dynamic monitoring part of the particulate matter flow arranged on the particulate matter conveying pipe; and combining the basic operation state information with the dynamic particulate matter flow information to obtain a detection result of the operation condition.

Description

Pneumatic conveying detection method and detection equipment for particulate matters
Technical Field
The embodiment of the application relates to a particulate matter conveying technology, in particular to a particulate matter sensing device, an air flow conveying system using the same, a particulate matter pneumatic conveying detection method and detection equipment, and a particulate matter recovery device.
Background
Pneumatic conveying of particulate matter is a technology for conveying particulate matter by pushing the particulate matter in a pipeline to flow by using air flow. A common pneumatic conveying mode for particulate matters is characterized in that gas fluidizes particulate matters to be conveyed to form gas-particulate matter mixed flow (commonly called gas-solid two-phase flow), then the gas-particulate matter mixed flow is conveyed to a destination through a pipeline, and gas brought by the gas-particulate matter mixed flow can be automatically led out and discharged into the atmospheric environment along with the arrival of the gas-particulate matter mixed flow at the destination.
The key to the success of pneumatic transport of particulate matter is to prevent the transported particulate matter from settling and stopping flow and plugging the pipeline. In the existing pneumatic conveying technology of particulate matters, in order to prevent the conveyed particulate matters from settling, the conventional idea is to endow the particulate matters entering a pipeline with a faster initial flow velocity. The idea is applied to the pneumatic conveying mode of the particles, namely the pressure of the gas-particle mixed flow is higher when the gas-particle mixed flow is released. When the pressure of the gas-particle mixed flow is higher when being released, it is equivalent to create a larger pressure difference between the releasing end and the receiving end of the gas-particle mixed flow, thereby ensuring that the initial flow rate of the particles is faster.
On the other hand, the bulk density of the particles also has a significant influence on the pneumatic transport of the particles. The higher the bulk density of the particles, the more easily the particles settle, and correspondingly, the more gas is required to fluidize a unit mass of particles (so that the pressure of the gas-particle mixed stream when released is higher); conversely, the lower the bulk density of the particles, the more easily the particles become suspended, and correspondingly, less gas is required to fluidize a unit mass of particles (so that the gas-particle mixed stream is at a lower pressure when released). Therefore, if the bulk density of the particulate matter to be transported is high, the pressure difference between the discharge end and the receiving end of the mixed gas-particulate matter flow tends to be further increased.
Based on the above, the existing pneumatic conveying technology for particulate matters has the following problems: because the pressure difference between the release end and the receiving end of the gas-particle mixed flow is large, correspondingly, the initial flow velocity of the particles is high, and therefore, the corresponding part of the pipeline is easily and rapidly abraded. The problem generally exists in the particulate pneumatic conveying system which is currently in practical use, and the common solution is to strengthen the pipeline against abrasion, so that the use cost is increased.
In addition, the existing pneumatic conveying technology for particulate matters aims at the particulate matters with different bulk densities, and the pressure of the gas-particulate matter mixed flow when the gas-particulate matter mixed flow is released is generally required to be adjusted, but the adjustment has great randomness and uncertainty, which easily results in that: either the particle flow rate is too high further exacerbating the pipe wear or the particle flow rate is too low settling and plugging the pipe.
In view of the above problems, the applicant of the present application discloses, in chinese patent publication No. CN113716347A (hereinafter referred to as "reference", the content of which is incorporated in the present application), a system, an apparatus, a method and a control apparatus for pneumatic conveying of particulate matters, in which a flow control pressure regulator disposed on an exhaust passage of a particulate matter recoverer applies resistance to air flow discharge in the exhaust passage, so that corresponding back pressure can be maintained on the pneumatic conveying passage during pneumatic conveying of the particulate matters, thereby facilitating better control of pneumatic conveying of the particulate matters, i.e., better controlling initial flow rate of the particulate matters during pneumatic conveying of the particulate matters under the condition of ensuring successful pneumatic conveying of the particulate matters, and further reducing wear on related equipment.
As can be seen from the reference, in one embodiment of the above system for pneumatic transport of particulate matter, the first particulate matter recoverer is disposed above the second particulate matter recoverer and the bottom of the first particulate matter recoverer is in communication with the chamber of the second particulate matter recoverer through a discharge mechanism. Although the floor area can be obviously saved in the mode, the bin pressure of the first particulate matter recoverer is higher than that of the second particulate matter recoverer, so that the speed is higher when the first particulate matter recoverer discharges materials to the second particulate matter recoverer, and related pipelines, valves and other facilities are easily damaged.
In addition, in the existing pneumatic conveying system for particulate matter including the reference, the problem that the dynamic physical process of the particulate matter in pneumatic conveying of the particulate matter is not known is still existed, especially, an objective detection and evaluation means is lacked for the flow speed of the particulate matter, the particulate matter concentration of the gas-particulate matter mixed flow (namely, the pneumatic conveying of the particulate matter belongs to the problem of so-called 'dense phase' or 'dilute phase'), and the like, so that the pneumatic conveying process of the particulate matter is difficult to be accurately quantified in real time, and the pneumatic conveying of the particulate matter is not accurately controlled.
Disclosure of Invention
An object of the embodiments of the present application is to provide a particulate matter sensing device and an airflow conveying system using the same, so as to solve the technical problem of detecting particulate matter flowing in an airflow conveying system (the pneumatic conveying of particulate matter can be regarded as one of the cases of airflow conveying) such as pneumatic conveying of particulate matter.
A second object of the embodiments of the present application is to provide a method and a device for detecting pneumatic transportation of particulate matters, so as to solve the technical problem of detecting the operation condition of a pneumatic transportation system of particulate matters by detecting flowing particulate matters during pneumatic transportation of particulate matters.
A third objective of the embodiments of the present application is to provide a particulate matter recycling device, so as to solve the technical problem of achieving smooth discharging between a first particulate matter recoverer (similar to the first particulate matter recoverer in the reference) and a second particulate matter recoverer (similar to the second particulate matter recoverer in the reference) that are vertically arranged and have different bin pressures.
In order to solve the above technical problem, according to a first aspect of the present application, a particulate matter sensing device is provided. The particle sensing device of the first aspect comprises a probe which is arranged in use in the airflow channel and generates and outputs a current signal when the particles in the airflow channel pass through the probe, the current signal being used as an input signal for a signal processing system, the probe being arranged in the airflow channel in such a way that the following conditions are met simultaneously: a) mounted on the outside of the inner wall surface of a tube shell constituting the gas flow channel, b) not electrostatically shielded on the side facing the gas flow channel, and c) insulated from the tube shell.
Optionally, if the probe is visible to the naked eye from the inside wall surface of the cartridge, the probe is substantially flush with the inside wall surface of the cartridge or the probe is located in a recess on the inside wall surface of the cartridge; if the probe is not visible to the naked eye from the inner wall surface of the envelope, the probe is hidden in a layer of non-electrostatic shielding material constituting the inner wall surface of the envelope, which may be made of a wear resistant material, preferably a ceramic material.
Optionally, the probe comprises a first structure formed by an inductor extending along the circumferential direction of the gas flow channel, and the first structure is a complete annular body or a non-complete annular body. Optionally, the probe includes a second structure formed by at least two inductors arranged at intervals in the axial direction of the airflow channel, and the current signals generated by the inductors in the second structure are output through the same or different probe output parts. Optionally, at least one inductor in each inductor in the second structure may adopt the first structure.
Optionally, the probe is installed in the tube shell through an insulating sheath, the insulating sheath forms a probe installation area matched with the shape of the probe, and the probe is wrapped in the probe installation area. The insulating sheath can be made of rubber, preferably polytetrafluoroethylene.
Optionally, the insulating sheath is a prefabricated annular member, an annular concave groove serving as the probe mounting region and adapted to the first structure is formed in an inner wall of the prefabricated annular member, and the first structure is placed in the annular concave groove.
Optionally, the particle sensing device of the first aspect includes a prefabricated particle sensing component, the prefabricated particle sensing component includes the probe and the tube shell assembled together, and two ends of the tube shell are respectively provided with a pipeline butt joint structure for placing the prefabricated sensing component on the airflow conveying pipeline to become a part of the airflow conveying pipeline. The pipeline butt joint structure preferably adopts a flange plate.
Optionally, the tube shell includes a basic layer formed by axially butting a first tube shell and a second tube shell, a splicing groove formed by the first tube shell and the second tube shell after axial butting is formed in the basic layer, and the probe is installed in the splicing groove.
Optionally, the end face of the first tube, which is used for being in butt joint with the second tube, comprises a first tube outer edge end face and a first tube inner edge end face, the end face of the second tube, which is used for being in butt joint with the first tube, comprises a second tube outer edge end face and a second tube inner edge end face, the first tube and the second tube are in butt joint in the axial direction, the first tube outer edge end face is in mutual contact with the second tube outer edge end face, and the first tube inner edge end face is separated from the second tube inner edge end face to form the splicing groove.
Optionally, the outer edge end face of the first tube shell is welded with the outer edge end face of the second tube shell. Optionally, the splicing groove is adapted to the prefabricated ring member, and the prefabricated ring member is placed in the splicing groove. Optionally, a non-electrostatic shielding material layer is mounted on an inner wall surface of the base layer. The layer of non-electrostatic shielding material may be comprised of a wear resistant material, preferably a ceramic material.
Optionally, a junction box having an electrostatic shielding function to the outside is installed on the outer wall surface of the tube shell, a first wire holder is arranged in the junction box, a current input end of the first wire holder is electrically connected with the probe in a manner of being insulated from the tube shell, and a current output end of the first wire holder is provided with a first wiring structure.
Optionally, a second wire holder is arranged in the junction box, a current input end of the second wire holder is electrically connected with the tube shell, and a current output end of the second wire holder is provided with a second wire connection structure.
Optionally, the signal processing system obtains information for characterizing the flow of the particulate matter by processing the input signal. Optionally, the particulate matter sensing device is a micro-charge sensing device. Optionally, the signal processing system employs a transmitter means of a micro-charge sensing device of the TRIBO series of the Auburn systems inc.
Optionally, the mechanical assembly gap on the cartridge, which may cause gas leakage due to the installation of the probe, is filled with a sealant.
Optionally, the probe is electrostatically shielded from the environment outside the enclosure. Optionally, the electrostatic shielding of the probe from the external environment of the tube housing is achieved by the tube housing itself as a shielding material.
In order to solve the above technical problem, according to a second aspect of the present application, there is provided an air flow delivery system. The air flow conveying system of the second aspect comprises an air flow conveying pipeline, and the particulate matter sensing device of the first aspect is arranged on the air flow conveying pipeline.
Optionally, the gas flow conveying system belongs to a pneumatic conveying system for particulate matter, and the gas flow conveying pipeline is used for conveying a gas-particulate matter mixed flow.
Optionally, the pneumatic conveying system for particulate matter comprises: a particulate matter fluidizer for fluidizing a first particulate matter to be conveyed with a fluidizing gas to generate and output a gas-particulate matter mixed flow; a particulate matter conveying pipe for conveying the gas-particulate matter mixed flow output from the particulate matter fluidizer along a set route, the particulate matter conveying pipe serving as the gas flow conveying pipe; and the particle recoverer is used for receiving the gas-particle mixed flow transmitted from the particle conveying pipe and discharging gas brought by the gas-particle mixed flow from an exhaust channel of the particle conveying pipe.
Optionally, the particulate matter sensing device is disposed on the particulate matter conveying pipe at a position close to the particulate matter recoverer.
In order to solve the technical problem, according to a third aspect of the present application, a pneumatic conveying and detecting method for particulate matter is provided. The pneumatic conveying and detecting method for the particulate matters is used for detecting the operation condition of a pneumatic conveying system for the particulate matters; the pneumatic particulate matter conveying system comprises a particulate matter fluidizer, a particulate matter conveying pipe and a particulate matter recoverer; the particles are used for fluidizing particles to be conveyed by using fluidizing gas so as to generate and output a gas-particle mixed flow; the particle conveying pipe is used for conveying the gas-particle mixed flow output from the particle fluidizer along a set route; the particle recoverer is used for receiving the gas-particle mixed flow transmitted from the particle conveying pipe and discharging gas brought by the gas-particle mixed flow from an exhaust channel of the particle conveying pipe; the method specifically comprises the following operations: acquiring basic operation state information of the pneumatic particulate matter conveying system, wherein the basic operation state information is used for determining a detection reference of the operation condition; acquiring dynamic information of the particulate matter flow in the particulate matter conveying pipe, wherein the dynamic information of the particulate matter flow is acquired by a dynamic monitoring part of the particulate matter flow arranged on the particulate matter conveying pipe; and combining the basic operation state information with the dynamic particulate matter flow information to obtain a detection result of the operation condition.
Optionally, the operation condition includes a particulate matter flow velocity level judgment indicator, in order to obtain a detection result of the particulate matter flow velocity level judgment indicator, the required basic operation state information includes a time point at which the particulate matter fluidizer outputs a gas-particulate matter mixed flow, and the required particulate matter flow dynamic information includes a time point at which particulate matter reaches to cause a flow sudden change.
Optionally, the operation condition includes a particulate matter pneumatic transmission end or non-end judgment indicator, in order to obtain a detection result of the particulate matter pneumatic transmission end or non-end judgment indicator, the required basic operation state information includes a time point when the particulate matter fluidizer outputs a gas-particulate matter mixed flow, and the required particulate matter flow dynamic information includes a time point when the particulate matter leaves to cause a flow rate mutation.
In order to solve the technical problem, according to a fourth aspect of the present application, a pneumatic conveying and detecting method for particulate matter is provided. The pneumatic conveying and detecting method for the particulate matters is used for detecting the operation condition of a pneumatic conveying system for the particulate matters; the pneumatic particulate matter conveying system comprises a particulate matter fluidizer, a particulate matter conveying pipe and a particulate matter recoverer; the particle fluidizer is used for fluidizing particles to be conveyed by using fluidizing gas so as to generate and output a gas-particle mixed flow; the particle conveying pipe is used for conveying the gas-particle mixed flow output from the particle fluidizer along a set route; the particle recoverer is used for receiving the gas-particle mixed flow transmitted from the particle conveying pipe and discharging gas brought by the gas-particle mixed flow from an exhaust channel of the particle conveying pipe; the method specifically comprises the following operations: acquiring dynamic information of the particulate matter flow in the particulate matter conveying pipe, wherein the dynamic information of the particulate matter flow is acquired by a dynamic monitoring part of the particulate matter flow arranged on the particulate matter conveying pipe; and analyzing the change situation of the particulate matter flow over time reflected by the dynamic information of the particulate matter flow, and obtaining a detection result of the running situation through the analysis.
Optionally, the operating condition includes a particulate matter concentration level judgment indicator of the gas-particulate matter mixed flow, and the shape of the waveform of the particulate matter flow with time is obtained by analyzing the time-varying condition of the particulate matter flow and is used as a detection result of the particulate matter concentration level judgment indicator of the gas-particulate matter mixed flow. The change trend of the particulate matter flow rate or concentration, the fluctuation rate of the particulate matter concentration (i.e., the difference between the particulate matter flow rate or concentration in a unit time), and the like can be obtained from the shape of the waveform of the particulate matter flow rate with time.
Optionally, the operating condition includes a particulate matter transportation amount judgment index, and a time integral of the particulate matter transportation amount is obtained by analyzing a change of the particulate matter transportation amount with time, and a result of the time integral is used as a detection result of the particulate matter transportation amount judgment index.
In order to solve the above technical problem, according to a fifth aspect of the present application, there is provided a pneumatic conveying and detecting apparatus for particulate matter. The pneumatic conveying and detecting equipment for the particulate matters is used for detecting the operation condition of a pneumatic conveying system for the particulate matters; the pneumatic particulate matter conveying system comprises a particulate matter fluidizer, a particulate matter conveying pipe and a particulate matter recoverer; the particle fluidizer is used for fluidizing particles to be conveyed by using fluidizing gas so as to generate and output a gas-particle mixed flow; the particle conveying pipe is used for conveying the gas-particle mixed flow output from the particle fluidizer along a set route; the particle recoverer is used for receiving the gas-particle mixed flow transmitted from the particle conveying pipe and discharging gas brought by the gas-particle mixed flow from an exhaust channel of the particle conveying pipe; the method specifically comprises the following steps: the particle flow dynamic monitoring component is arranged on the particle conveying pipe and is used for acquiring particle flow dynamic information in the particle conveying pipe; and the signal processing component is in communication connection with the dynamic particulate matter flow monitoring component and is used for processing the dynamic particulate matter flow information so as to obtain a detection result of the running condition.
Optionally, the signal processing component comprises a PLC controller and an upper computer, and the PLC controller is in communication connection with the dynamic particulate matter flow monitoring component and the upper computer respectively. Optionally, the signal processing component includes a PLC controller, and the PLC controller is in communication connection with the dynamic particulate flow monitoring component, respectively.
Optionally, the upper computer includes a processor, a memory and an output device, the memory stores a computer program or an instruction, and the computer program or the instruction can be executed by the processor to display the time variation of the particulate matter flow reflected by the dynamic information of the particulate matter flow and/or the result of analyzing the time variation of the particulate matter flow reflected by the dynamic information of the particulate matter flow on the output device. Optionally, the PLC controller includes a processor, a memory, and an output device, where the memory stores a computer program or instructions, and the computer program or instructions can be executed by the processor to display the time variation of the particulate matter flow reflected by the dynamic information of the particulate matter flow and/or the result of analyzing the time variation of the particulate matter flow reflected by the dynamic information of the particulate matter flow on the output device.
Optionally, the particulate matter pneumatic transmission detection method of the third aspect, the particulate matter pneumatic transmission detection method of the fourth aspect, and/or the particulate matter flow dynamic monitoring component of the particulate matter pneumatic transmission detection apparatus of the fifth aspect employs a micro-charge sensing device, and the micro-charge sensing device may be the particulate matter sensing device of the first aspect.
Optionally, in the pneumatic conveying and detecting method for particulate matter according to the third aspect, the pneumatic conveying and detecting method for particulate matter according to the fourth aspect, and/or the pneumatic conveying and detecting device for particulate matter according to the fifth aspect, the particulate matter recoverer is an industrial kiln or a particulate matter storage. Optionally, in the pneumatic particulate matter transportation and detection method according to the third aspect, the pneumatic particulate matter transportation and detection method according to the fourth aspect, and/or the pneumatic particulate matter transportation and detection apparatus according to the fifth aspect, the particulate matter recoverer is a blast furnace, and the particulate matter is fly ash. Optionally, in the pneumatic conveying and detecting method for particulate matter according to the third aspect, the pneumatic conveying and detecting method for particulate matter according to the fourth aspect, and/or the pneumatic conveying and detecting apparatus for particulate matter according to the fifth aspect, the pneumatic conveying system for particulate matter is a pneumatic conveying system for particulate matter used for conveying positive/negative electrode materials of a battery.
In order to solve the above technical problem, according to a sixth aspect of the present application, there is provided a particulate matter recovery device. The particulate matter recovery device of the sixth aspect described above includes: a first particulate matter recoverer for receiving a gas-particulate matter mixed flow transmitted by pneumatic transport of particulate matter and discharging gas brought by the gas-particulate matter mixed flow from an exhaust passage thereof, the first particulate matter recoverer having a first air pressure in a bin; a second particulate matter recoverer located below the first particulate matter recoverer and configured to receive particulate matter from the first particulate matter recoverer via a discharge mechanism, the second particulate matter recoverer having a chamber with a second air pressure therein independent of the first air pressure; the discharge mechanism comprises: the transfer bin is positioned between the first particulate matter recoverer and the second particulate matter recoverer and is used for receiving the particulate matters transmitted from the first particulate matter recoverer and releasing the particulate matters temporarily stored in the transfer bin to the second particulate matter recoverer; the bidirectional pressure equalizer comprises a first pressure equalizing mechanism and a second pressure equalizing mechanism, the first pressure equalizing mechanism conducts the bin of the transfer bin with the bin of the first particulate matter recoverer when being selectively opened, and the second pressure equalizing mechanism conducts the bin of the transfer bin with the bin of the second particulate matter recoverer when being selectively opened; and the discharge valve group comprises a first discharge valve system and a second discharge valve system, the first discharge valve system is arranged on a discharge channel between the first particulate matter recoverer and the transfer bin, and the second discharge valve system is arranged on a discharge channel between the second particulate matter recoverer and the transfer bin.
Optionally, the particulate matter recovery device comprises a flow control pressure regulator, which is arranged on the exhaust passage of the first particulate matter recovery device and is used for applying resistance to airflow discharge in the exhaust passage.
Optionally, the flow control voltage regulator is set as: when the pressure value of the air inlet of the flow control pressure regulator reaches a set threshold value, the valve is conducted to start exhaust, and when the pressure value of the air inlet of the flow control pressure regulator does not reach the set threshold value, the valve is blocked to stop exhaust.
Optionally, the flow control pressure regulator adopts a pre-valve pressure regulating valve; the pre-valve pressure regulating valve can be selected to be a self-operated pre-valve pressure regulating valve.
Optionally, the exhaust port of the flow control pressure regulator is communicated with the external atmospheric environment, and the pressure value of the air inlet of the flow control pressure regulator is higher than an atmospheric pressure value or a standard atmospheric pressure value of the location of the system.
Optionally, the pressure value of the air inlet of the flow control and pressure regulator is M times of an atmospheric pressure value or a standard atmospheric pressure value of the location of the system, where M is a real number greater than 1 and less than or equal to 6, preferably 1.2 to 5, and more preferably 1.2 to 3.
Optionally, a flow control and pressure regulation device is connected in series to an exhaust passage of the first particulate matter recoverer, and the flow control and pressure regulation device includes: the buffer tank is used for receiving the gas conveyed from the exhaust channel, enabling the gas to pass through a buffer cavity in the buffer tank and then be exhausted from an exhaust port of the buffer tank; and the air inlet of the flow control pressure regulator is connected with the air outlet of the buffer tank, the air outlet of the flow control pressure regulator is connected with a diffuser, and the diffuser preferably diffuses a silencer.
Optionally, a dust remover is connected in series to an exhaust passage of the first particulate matter recoverer, and the flow control and pressure regulation device is arranged at the downstream of an exhaust port of the dust remover.
Optionally, the dust remover is arranged at the top of the first particulate matter recoverer, and the bottom of a gas chamber to be dedusted of the dust remover is directly communicated with the bin of the first particulate matter recoverer.
Optionally, the flow control and pressure regulation device is arranged at the top of the first particulate matter recoverer, the bottom of the buffer tank is communicated with the bin of the first particulate matter recoverer through a discharge channel, and a discharge valve is arranged on the discharge channel.
Optionally, the first particulate matter recoverer is a pressure vessel adopting an arc-shaped bin top head structure; and a working platform is arranged on the first particulate matter recoverer, and the flow control and pressure regulation device is arranged on the working platform.
Optionally, a dust remover is connected in series to an exhaust channel of the first particulate matter recoverer, the flow control and pressure regulation device is arranged at the downstream of an exhaust port of the dust remover, and the dust remover is arranged at the top of the first particulate matter recoverer; the work platform has an area that is an operational service platform for the dust separator.
Optionally, a dust remover is connected in series to an exhaust channel of the first particulate matter recoverer, a dust remover is also connected in series to an exhaust channel of the second particulate matter recoverer, the first pressure equalizing mechanism conducts the chamber of the transfer bin with an exhaust port of the dust remover connected in series to the exhaust channel of the first particulate matter recoverer when selectively opened, and the second pressure equalizing mechanism conducts the chamber of the transfer bin with an exhaust port of the dust remover connected in series to the exhaust channel of the second particulate matter recoverer when selectively opened.
Optionally, the first discharge valve system comprises a mechanically driven discharge valve, a tapered reducing connection pipe, a flexible joint, a dust cut-off valve and a gas seal valve which are sequentially connected from top to bottom; optionally, the mechanically-driven discharge valve is an electric star-shaped discharge valve. Optionally, the gas-sealed valve is a dome valve.
Optionally, the second discharge valve system comprises a dust cut-off valve and a gas seal valve which are sequentially connected from top to bottom. Optionally, the gas-sealed valve is a dome valve.
Optionally, the two-way pressure equalizer is including installing well rotary warehouse top and being located first particulate matter recoverer with the vertical form pressure-equalizing filter of the side of the passageway of unloading between the well rotary warehouse, vertically install the tubulose filter core among the pressure-equalizing filter, pressure-equalizing filter's top is equipped with the air-purifying chamber, the air-purifying chamber through be equipped with first pressure-equalizing pipe of first pressure-equalizing valve and be equipped with the second pressure-equalizing pipe of second pressure-equalizing valve respectively with the bin of first particulate matter recoverer and the bin of second particulate matter recoverer switches on, pressure-equalizing filter's bottom is equipped with former air chamber, former air chamber with the bin of well rotary warehouse switches on.
Optionally, a steel bracket is arranged between the first particulate matter recoverer and the second particulate matter recoverer, and the first particulate matter recoverer is supported above the second particulate matter recoverer through the steel bracket.
Optionally, an overhaul platform is arranged in the steel bracket between the first particulate matter recoverer and the transfer bin.
Optionally, when the first particulate matter recoverer is used, the first particulate matter recoverer is connected with the particulate matter fluidizer through the particulate matter conveying pipe; the particle fluidizer is used for fluidizing particles to be conveyed by using fluidizing gas so as to generate and output a gas-particle mixed flow; the particle conveying pipe is used for conveying the gas-particle mixed flow output from the particle fluidizer along a set route; the particle recoverer is used for receiving the gas-particle mixed flow transmitted from the particle conveying pipe and discharging gas brought by the gas-particle mixed flow from an exhaust channel of the particle conveying pipe; the particle flow dynamic monitoring device is characterized in that a particle flow dynamic monitoring component used for collecting particle flow dynamic information in the particle conveying pipe is installed on the particle conveying pipe, the particle flow dynamic monitoring component is in communication connection with a signal processing component, and the signal processing component is used for processing the particle flow dynamic information to obtain a detection result of the operation condition.
Optionally, the particulate matter flow dynamic monitoring component adopts a micro-charge sensing device, and the micro-charge sensing device can be the particulate matter sensing device of the first aspect.
Optionally, the signal processing component comprises a PLC controller and an upper computer, and the PLC controller is in communication connection with the dynamic particulate matter flow monitoring component and the upper computer respectively; or, the signal processing part comprises a PLC controller, and the PLC controller is respectively in communication connection with the particulate matter flow dynamic monitoring part.
Optionally, the PLC controller is further in communication connection with a related instrument in the pneumatic particulate matter conveying system, where the related instrument is used to obtain basic operation state information of the pneumatic particulate matter conveying system and/or serve as a control object of the PLC controller.
Optionally, the PLC controller and/or the upper computer includes a processor, a memory, and an output device, where the memory stores a computer program or an instruction, and the computer program or the instruction can be executed by the processor to display the time variation of the particulate matter flow reflected by the dynamic information of the particulate matter flow and/or analyze the time variation of the particulate matter flow reflected by the dynamic information of the particulate matter flow on the output device.
The present application will be further described with reference to the following drawings and detailed description. Additional aspects and advantages provided by the present application will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice.
Drawings
The accompanying drawings, which are incorporated in and constitute a part of this specification, are included to assist in understanding the present application and are incorporated in and constitute a part of this specification, with the understanding that the present application is to be considered an exemplification of the principles of the invention and is not intended to be unduly limiting. In the drawings:
fig. 1 is a schematic field layout of a system for pneumatic transport of particulate matter according to the reference.
Fig. 2 is a schematic diagram of a system for pneumatic transport of particulate matter according to the reference.
Fig. 3 is a schematic structural diagram of a particle fluidizer of the reference.
Fig. 4 is a schematic structural diagram of a pneumatic conveying device for particulate matters in the reference.
Fig. 5 is a partial schematic structure diagram of a pneumatic conveying device for particulate matters in the reference.
Fig. 6 is a schematic structural diagram of a gas compensation node in the reference.
Fig. 7 is a schematic structural diagram of a gas supply node in this reference.
Fig. 8 is a schematic diagram of a control system of a system for pneumatic transport of particulate matter according to the reference.
Fig. 9 is a schematic structural diagram of a particulate matter recovery device according to an embodiment of the present application.
Fig. 10 is a schematic structural diagram of a particulate matter recovery device according to an embodiment of the present application.
Fig. 11 is a schematic structural diagram of a pneumatic conveying and detecting apparatus for particulate matter according to an embodiment of the present application.
Fig. 12 is a schematic structural diagram of a particle sensing device according to an embodiment of the present application.
Fig. 13 is a schematic structural diagram of a particle sensing device according to an embodiment of the present application.
Fig. 14 is a sectional view taken along line a-a in fig. 12.
Fig. 15 is a sectional view taken along line B-B in fig. 13.
Fig. 16 is an enlarged view of fig. 14.
Detailed Description
The embodiments of the present application will be described more fully hereinafter with reference to the accompanying drawings. Those of ordinary skill in the art will be able to implement the embodiments of the present application based on these descriptions. Before the embodiments of the present application are explained in conjunction with the drawings, it should be particularly pointed out that:
the technical solutions and features provided in the respective sections including the following description may be combined with each other without conflict. Furthermore, where possible, these technical solutions, technical features and related combinations may be given specific technical subject matter and are protected by the accompanying patent.
The embodiments of the present application referred to in the following description are generally only some embodiments, rather than all embodiments, and all other embodiments that can be derived by one of ordinary skill in the art based on these embodiments without making creative efforts shall fall within the scope of patent protection.
The terms "comprising," "including," "having," and any variations thereof in this specification and in the claims and following claims are intended to cover non-exclusive inclusions. In addition, the term "pressure" refers to the air pressure, and the values of the air pressure referred to, unless otherwise specified, refer to gauge pressure values. The term "particulate fluidizer" includes any device that uses a gas stream to generate and deliver a gas-particulate mixed stream, including what is commonly referred to in the art as a "particulate emitter". Other related terms and units can be reasonably construed based on the description to provide related contents.
Fig. 1 is a schematic field layout of a system for pneumatic transport of particulate matter according to the reference. As shown in fig. 1, a storage bin 11 is provided at one location of a plant site 10, the storage bin 11 stores particulate matters, and the particulate matters in the storage bin 11 need to be sent to another location, namely a destination, of the plant site 10. The transport of the particles in the silo 11 to the destination can be based on any possible reason or application scenario. Such as: the bin 11 is an ash bin of a dust remover and is used for storing dust collected by the dust remover; in this case, it is necessary to transport the dust in the dust bin to a dust bin of a destination so as to load the dust by collecting the dust in the dust bin by a vehicle. For another example: the silo 11 is a silo for storing granules serving as certain industrial raw materials; in this case, the aggregate in the silo 11 needs to be transported to the silo of the destination so as to be put into use in due time. Pneumatic conveying is used to transport the particles in the silo 11 to their destination.
Fig. 2 is a schematic diagram of a system for pneumatic transport of particulate matter according to the reference. To achieve pneumatic transport, as shown in fig. 1-2, a system for pneumatic transport of particulate matter is used, which comprises a first particulate matter transport system comprising a first particulate matter fluidizer 21, a first particulate matter transport pipe 22 and a first particulate matter reclaimer 23. The first particle fluidizer 21 is used for fluidizing the first particles to be conveyed (i.e. the particles in the bin 11) with fluidizing gas, and generating and outputting a gas-particle mixed flow. The first particulate transport pipe 22 is used to transport the gas-particulate mixed stream output from the first particulate fluidizer 21 along a set route. Since there are often obstacles 12 between the first particle-matter reclaimer 23 and the silo 11, such as the factory building in fig. 1 or other equipment built on the factory floor 10, the first particle-matter conveying pipe 22 is usually not completely arranged as a straight pipe, but one or more "turns" are needed depending on the situation (see fig. 1). The first particulate matter recoverer 23 is configured to receive the gas-particulate matter mixed flow delivered from the first particulate matter transport pipe 22 and to discharge gas brought by the gas-particulate matter mixed flow from an exhaust passage thereof.
As mentioned in the "background" section of this specification, the key to the success of pneumatic transport of particulate matter is to prevent the transported particulate matter from settling and stopping flow and thus plugging the pipeline. In the existing pneumatic conveying technology of particulate matters, in order to prevent the conveyed particulate matters from settling, a conventional idea is to endow the particulate matters entering a pipeline with a higher initial flow velocity. If this concept is applied to the pneumatic transport system of the first particulate matter, the pressure of the mixed gas-particulate matter stream when it is released (i.e., the internal pressure of the first particulate matter fluidizer 21 when it is ready to release the mixed gas-particulate matter stream) is relatively high. Therefore, as is conventionally done so far, it is necessary to set the internal gas pressure value at which the first particulate fluidizer 21 prepares to discharge the gas-particulate mixed flow at 0.5MPa or more. In addition, the bulk density of the particles can also have a significant effect on the pneumatic transport of the particles. The higher the bulk density of the particles, the more easily the particles settle, and correspondingly, the more gas is required to fluidize a unit mass of particles (so that the pressure of the gas-particle mixed stream when released is higher); conversely, the lower the bulk density of the particles, the more easily the particles become suspended, and correspondingly, less gas is required to fluidize a unit mass of particles (so that the gas-particle mixed stream is at a lower pressure when released). Therefore, when the bulk density of the particles in the silo 11 is high, as according to the present conventional practice, it is also necessary to further increase the internal gas pressure value at which the first particle fluidizer 21 is ready to release the gas-particle mixed flow. In summary, adjusting the internal gas pressure at which the first particulate fluidizer 21 is ready to release the gas-particulate mixture stream is currently the primary means of controlling the first particulate pneumatic conveying system; moreover, it is the current conventional practice to set the internal gas pressure value to be higher when the first particulate fluidizer 21 is ready to release the gas-particulate mixed flow, which results in a larger pressure difference between the releasing end and the receiving end of the gas-particulate mixed flow of the first particulate conveying system, so that the initial flow rate of the particulate is faster, and rapid wear of the corresponding part of the pipeline is easily caused.
In view of the above-mentioned problems associated with the single control means of the pneumatic conveying system for first particulate matter and the problems associated with such single control means, the reference provides an improved pneumatic conveying system for first particulate matter. As shown in fig. 1-2, the modified first particulate delivery system includes a first particulate fluidizer 21, a first particulate transport tube 22, a first particulate recoverer 23, and a flow control regulator 242. According to the foregoing, it can be seen that: the first particle fluidizer 21 is used for fluidizing the first particles to be conveyed (i.e. the particles in the bin 11) by using fluidizing gas, and generating and outputting a gas-particle mixed flow; the first particulate transport pipe 22 is used for transporting the gas-particulate mixed flow output from the first particulate fluidizer 21 along a set route; the first particulate matter recoverer 23 is configured to receive the gas-particulate matter mixed flow delivered from the first particulate matter transport pipe 22 and discharge gas brought by the gas-particulate matter mixed flow from an exhaust passage thereof. Further, the flow control regulator 242 is provided on the exhaust passage of the first particulate matter recoverer 23, and the flow control regulator 242 is configured to apply resistance to the exhaust of the airflow in the exhaust passage.
Conventionally, in the first pneumatic transport system for particulate matter, after the particulate matter is transported to the first particulate matter recoverer 23, it is desirable that the gas brought along with the particulate matter can be rapidly discharged through the exhaust passage of the first particulate matter recoverer 23 so as not to increase the resistance to the transport of the subsequent particulate matter. The improved first particulate matter conveying system skillfully breaks through the limit of conventional thinking, by providing the flow-control pressure regulator 242 on the exhaust passage of the first particulate matter recoverer 23, resistance is applied to the exhaust of the air flow in the exhaust passage, so that a corresponding back pressure can be maintained on the particulate matter pneumatic conveying passage (i.e., the particulate matter pneumatic conveying path), due to the presence of said back pressure, to achieve pneumatic transport of the particles, it is necessary to increase the internal gas pressure of the first particle fluidizer 21 in preparation for releasing the gas-particle mixed flow to counteract this back pressure, in this way, in the first particulate fluidizer 21, more gas is mixed per unit mass of particulate matter being fluidized, and both of the particulate matter having a low bulk density and the particulate matter having a high bulk density can be fluidized and suspended to achieve pneumatic conveyance. More importantly, although the internal gas pressure of the first particulate fluidizer 21 is increased when it is ready to discharge the gas-particulate mixture stream, the pressure difference between the internal gas pressure of the first particulate fluidizer 21 and the pressure at the gas inlet of the flow control regulator is not necessarily increased equally because of the back pressure, so that the initial flow rate of the particulate matter can be easily controlled to a relatively low level, which helps to reduce the wear on the related equipment. Therefore, the system, the device and the method for pneumatic conveying of the particles provide conditions for promoting pneumatic conveying of the particles, better controlling the initial flow rate of the particles during pneumatic conveying of the particles and improving the adaptability to the particles with different bulk densities.
The flow control regulator 242 may be further configured to: when the pressure value of the air inlet of the flow control pressure regulator 242 reaches a set threshold value, the valve is turned on to start exhaust, and when the pressure value of the air inlet of the flow control pressure regulator 242 does not reach the set threshold value, the valve is turned off to stop exhaust. On this basis, the flow control pressure regulator 242 may specifically adopt a pre-valve pressure regulating valve. More specifically, the pre-valve pressure regulating valve 242 may be a self-operated pre-valve pressure regulating valve. When the flow control pressure regulator 242 adopts a self-operated pre-valve pressure regulating valve, the self-operated pre-valve pressure regulating valve can automatically control the opening and closing of the self-operated pre-valve pressure regulating valve according to the preset pre-valve pressure, so that the self-operated pre-valve pressure regulating valve is closed when the actual pre-valve pressure does not reach the preset pre-valve pressure, the flow control pressure regulator 242 stops exhausting at the moment, and the flow control pressure regulator 242 starts exhausting when the actual pre-valve pressure reaches the preset pre-valve pressure. When the pressure value of the air inlet of the flow control pressure regulator 242 is set to be conducted to start exhaust when the pressure value of the air inlet of the flow control pressure regulator 242 reaches a set threshold value, and to be blocked to stop exhaust when the pressure value of the air inlet of the flow control pressure regulator 242 does not reach the set threshold value, the pressure value of the air inlet of the flow control pressure regulator 242 can be quickly and accurately made to reach the set threshold value. Thus, in some cases, for example, where it is necessary to make the entire pneumatic transport path for the particles, especially the first transport pipe 22, generate and maintain a certain pressure by charging (make-up air) before the first fluidizer 21 releases the gas-particle mixture flow, so as to better prevent the particles from settling in the pneumatic transport path for the particles, due to the long length of the first transport pipe 22 for the particles and/or the high bulk density of the particles to be transported, the required pressure can be quickly generated on the pneumatic transport path for the particles by the flow control and pressure regulator 242 and the amount of (make-up air) gas consumed to generate the pressure can be reduced at the same time.
Of course, the flow control regulator 242 may also implement the function of the flow control regulator 242 by other throttling methods. For example, the flow control and pressure regulator 242 may be a throttle plate; on this basis, flow rate adjustment can be realized by replacing the orifice plate, so that the pressure value set by the air inlet of the flow control pressure regulator 242 can be changed.
Generally speaking, the exhaust port of the flow control regulator 242 is in communication with the external atmosphere, so as to provide the most convenient and reasonable place for the air flow at the exhaust port of the flow control regulator. Therefore, in normal operation, the pressure value of the air inlet of the flow control and pressure regulator is higher than an atmospheric pressure value or a standard atmospheric pressure value of the location of the first particulate matter pneumatic conveying system. On this basis, generally speaking, the pressure value of the air inlet of the pressure control regulator 242 is M times an atmospheric pressure value or a standard atmospheric pressure value of the location of the first pneumatic transport system for particulate matter, where M is a real number greater than 1 and less than or equal to 6. When the multiple M is within the above range, the current use requirement (such as pneumatic conveying distance of particulate matter, conveying of particulate matter with high bulk density, etc.) can be satisfied, and meanwhile, the unnecessary energy consumption and other costs caused by excessively high pressure setting of the air inlet of the flow control and pressure regulator 242 are not caused. From such a viewpoint, the multiple M may be more preferably 1.2 to 5, and still more preferably 1.2 to 3.
As mentioned previously, according to current conventional practice, it is desirable to set the internal gas pressure of the first particulate fluidizer 21 above 0.5MPa in preparation for releasing the gas-particulate mixture stream. Since the existing pneumatic transportation technology for particulate matter does not have the flow control pressure regulator 242 in the present application, in fact, in the existing pneumatic transportation technology for particulate matter, the pressure difference between the releasing end and the receiving end of the mixed gas-particulate matter flow is very close to the pressure (0.5Mpa and above) of the mixed gas-particulate matter flow when the mixed gas-particulate matter flow is released. Because of the high pressure differential between the discharge end and the receiving end of the mixed gas-particulate stream, the initial flow rate of the particulate is high, resulting in rapid wear of the associated equipment. On the basis of adding accuse and flowing pressure regulator 242 in this application embodiment, in order to further solve the problem that the initial velocity of flow of particulate matter leads to the quick wearing and tearing of relevant equipment very fast, can with the ratio that the internal pressure value when first particulate matter fluidizer 21 prepares to release gas-particulate matter mixed flow sets for the pressure value of the air inlet of accuse and flowing pressure regulator 242 is 0.1-0.35Mpa, preferably 0.1-0.2Mpa high, just so can reduce the pressure differential between the release end that gas-particulate matter mixed flow flows and the receiving terminal to can reduce the initial velocity of flow of particulate matter, slow down the wearing and tearing of relevant equipment. Here, the reduction of the pressure difference between the discharge end and the receiving end of the mixed gas-particulate matter flow is based on a certain guarantee of the internal gas pressure value at the time when the first particulate matter fluidizer 21 is ready to discharge the mixed gas-particulate matter flow, because: since the flow-regulating pressure regulator 242 provided on the exhaust channel of the first particulate matter reclaimer 23 exerts a resistance against the exhaust of the gas flow in this exhaust channel, a corresponding back pressure can be maintained on the particulate matter pneumatic conveying channel, and due to the presence of said back pressure, it is necessary to ensure that the internal gas pressure value at which the first particulate matter fluidizer 21 is ready to release the gas-particulate matter mixed flow is sufficient to counteract this back pressure in order to achieve pneumatic conveying of the particulate matter.
Of course, in the pneumatic conveying system for the first particulate matter, at least one air supplementing node for providing axial pressure supplementing air flow for the air-particulate matter mixed flow conveyed by the first particulate matter conveying pipe 22 (referred to as the first particulate matter conveying pipe 22 itself) can also be arranged on the first particulate matter conveying pipe 22. Specifically, when the air supply nodes are arranged on the first particulate matter conveying pipe 22, the pressure value after air supply of any one air supply node on the first particulate matter conveying pipe 22 is not more than the pressure value after air supply of the previous adjacent air supply node and the internal pressure value when the first particulate matter fluidizer 21 is ready to release the gas-particulate matter mixed flow, and is not less than the pressure value after air supply of the next adjacent air supply node and is more than the pressure value of the air inlet of the flow control pressure regulator 242. By "axial make-up gas flow" is understood a gas flow filling the particle-transport duct in the direction of transport of the gas-particle mixed flow (axial direction of the particle-transport duct) during transport of the gas-particle mixed flow. The axial pressure-supplementing airflow is supplemented through the air supplementing node, so that the particles in the gas-particle mixed flow can be effectively prevented from settling, and a further realization condition is provided for reducing the pressure difference between the release end and the receiving end of the gas-particle mixed flow.
Generally, a dust remover 231 is also connected in series on the exhaust channel, and the flow control pressure regulator 242 is arranged at the downstream of the exhaust port of the dust remover 231. Because the mixture of the particles and the gas enters the first particle recoverer 23 through the first particle conveying pipe 22, when the gas brought by the gas-particle mixed flow is discharged through the exhaust passage of the first particle recoverer 23, the particles are entrained in the gas which is difficult to avoid, and the damage to subsequent equipment and/or the pollution to the environment are easily caused. In this regard, the dust collector 231 may be connected in series to the exhaust passage, and the flow control pressure regulator 242 may be disposed downstream of the exhaust port of the dust collector 231, so that the flow control pressure regulator 242 is protected first, the risk that the flow control pressure regulator 242 is damaged by particulate matter to affect normal operation is reduced, and the possibility of subsequent environmental pollution is also reduced.
Fig. 3 is a schematic structural diagram of a particle fluidizer of the reference. In the embodiment of the first granular fluidizer 21 shown in fig. 1-3, the first granular fluidizer 21 employs a bin pump 211, and a discharge valve 212 (herein, the discharge valve 212 is connected between the bottom of the bin 11 and the top of the bin pump 211 for discharging the granules in the bin 11 into the bin pump 211) at the top of the bin pump 211 is provided with an equalizing filter 213 at one side and an upwardly extending discharge pipe 214 at the other side. The pressure equalizing filter 213 can communicate the interior of the bin pump 211 with a pressure reference point (which can be in the bin 11), thereby playing a role in adjusting the pressure inside the bin pump 211, and further enabling the particulate matter in the bin 11 at the top of the discharge valve 212 to enter the bin pump 211 more smoothly when the discharge valve 212 is opened. In operation, after a certain amount of particles are stored in the bin pump 211, each fluidizing gas inlet on the bin pump 211 is opened, and compressed gas (e.g., compressed air) enters the bin pump 211 to mix with the particles to form a gas-particle mixed flow, which is referred to as fluidization, wherein the fluidization can suspend the particles for subsequent transportation. When the particles are sufficiently fluidized, the gas-particle mixture stream can be released from the first particle fluidizer 21 by opening a valve in the discharge pipe 214.
The first particle fluidizer 21, more specifically the bin pump 211, is configured such that the internal gas pressure when the gas-particle mixed flow is to be released is always the highest pressure reached by the bin pump 211 in the normal operation process, and in the process of opening the valve on the discharging pipe 214 to gradually release the gas-particle mixed flow from the bin pump 211, the internal gas pressure of the bin pump 211 gradually decreases, and when the internal gas pressure decreases to a certain value, it is determined that all the particles in the bin pump 211 are discharged, at this time, the valve on the discharging pipe 214 is closed, the bin pump 211 enters the particle loading process again, and after a certain amount of particles are stored in the bin pump 211, each fluidizing gas inlet on the bin pump 211 is opened again to fluidize, and the process is repeated.
The structure, position and number of the fluidizing gas inlets in the first particulate fluidizer 21 can be set as desired. In the first particulate fluidizer embodiment, the first particulate fluidizer 21 includes two fluidization gas inlets, one at the bottom surface of the first particulate fluidizer 21 and the other as a gas inlet by the connecting passage between the pressure equalizing filter 213 and the first particulate fluidizer 21. The air inlet on the bottom surface of the first particulate fluidizer 21 is a structure in which the opening area is as large as possible and an expanded polytetrafluoroethylene (e-PTFE) gas permeable membrane is laid in the air inlet, and this structure enables the compressed gas to be sufficiently dispersed into the first particulate fluidizer 21 so that the gas pressure in the first particulate fluidizer 21 can be kept low when the particulates are sufficiently fluidized. Expanded polytetrafluoroethylene breathable films are known materials and are commercially available. The air inlet which is formed by the connecting channel between the pressure equalizing filter 213 and the first particulate matter fluidizer 21 can enable back-blowing airflow to enter the bin pump 211 when the pressure equalizing filter 213 is subjected to back-blowing regeneration (namely, the filter element in the pressure equalizing filter 213 is subjected to back-blowing so that the filter element can recover the filtering performance), and the back-blowing airflow can play a role in fluidizing the particulate matters in the bin pump 211 after entering the bin pump 211, so that the fluidization in the bin pump 211 is realized or assisted to be realized by means of the back-blowing of the pressure equalizing filter 213.
In the first particle fluidizer embodiment, the discharge pipe 214 is arranged above the silo pump 211 from below and is connected to a three-way flow conducting element 215. The three-way flow guiding component 215 has two input channels and one output channel, wherein one input channel and one output channel are formed by a straight pipe, and the other input channel is a circular arc channel which is approximately tangent to the straight pipe and is connected to the side wall of the straight pipe. The inlet of the circular arc channel is connected to the tapping pipe 214. An input channel on the straight pipe of the three-way drainage component 215 is connected with the compressed air flow throttling and pressure reducing component 216 and is used for providing axial pressure supplementing air flow for the three-way drainage component 215 through the compressed air flow throttling and pressure reducing component 216. The outlet of the output channel on the straight pipe of the three-way flow guiding component 215 is butted with the first particle conveying pipe 22. Here, the "axial" direction in the axial flow of the make-up air is the direction of the output channel on the straight tube of the three-way flow directing member 215. The compressed air throttling and pressure reducing component 216 may include an air supply pipe with a pipe diameter generally 0.1-0.3 times that of the straight pipe diameter of the three-way flow guiding component 215, and the air supply pipe is connected with a compressed air source. The compressed air flow throttling and pressure reducing part 216 can also adopt a throttle valve and other structures. The inlet pressure of the compressed gas stream throttling depressurize unit 216 is preferably 1.5 to 3.5 times the internal gas pressure of the first particulate fluidizer 21 when it is ready to discharge the gas-particulate mixed stream.
The three-way flow diversion component 215 can be considered a first air make-up node on the first particulate delivery pipe 22, which is located between the first particulate delivery pipe 22 and the discharge pipe 214 of the bin pump 211. The process of outputting the axial pressure-supplementing gas flow to the gas-particle mixed flow through the first gas supplementing node can be regarded as pushing the gas-particle mixed flow to the flow direction of the gas-particle mixed flow through the axial pressure-supplementing gas flow to enter the first particle conveying pipe 22, so that the gas-particle mixed flow released from the discharge pipe 214 by the first particle fluidizer 21 can enter the first particle conveying pipe 22 under the condition that the first particle fluidizer 21 releases the high-speed gas-particle mixed flow without depending on the large internal gas pressure generated in the first particle fluidizer 21 in the particle fluidization process, thereby being helpful for enabling the internal gas pressure of the first particle fluidizer 21 to be at a lower level when preparing to release the gas-particle mixed flow, and effectively reducing the equipment abrasion generated in the first particle fluidizer 21 and when the first particle fluidizer 21 outputs the gas-particle mixed flow .
To better avoid the first particulate transport pipe 22 from becoming clogged by settling of the particulates as they flow through the first particulate transport pipe 22, in an embodiment of the first particulate transport pipe 22, the first particulate transport pipe 22 utilizes a dual-casing pneumatic transport channel. The double-sleeve pneumatic conveying channel belongs to the prior art, for example, a turbulent conveying double sleeve disclosed in the patent document with the publication number of CN203229205U, a double-sleeve concentrated phase turbulent conveying system disclosed in the patent document with the publication number of CN205838022U and the like, which relate to the double-sleeve pneumatic conveying channel. The double-sleeve pneumatic conveying channel is basically characterized in that an inner bypass pipe communicated with a main pipe in a certain mode is arranged in the main pipe, and when the main pipe is blocked, more airflow in the double sleeves enters the inner bypass pipe of the blocking section and then flows out from an outlet near the blocking section on the inner bypass pipe to form turbulent flow so as to play a role in clearing the blockage.
In addition, the first particle transport pipe 22 is provided with at least one air supply node for providing an axial pressure supply air flow for the gas-particle mixed flow transported by the first particle transport pipe. Fig. 6 is a schematic structural diagram of a gas compensation node in the reference. As shown in fig. 6, a three-way flow directing member 221, similar to the three-way flow directing member 215 described above as the first air make-up node, is employed as at least one air make-up node subsequent to the first air make-up node. The three-way flow guiding component 221 also has two input channels and one output channel, wherein one input channel and one output channel are formed by a straight tube, and the other input channel is a circular arc channel approximately tangent to the straight tube and connected to the side wall of the straight tube. The inlet of the circular arc shaped channel is butted against the outlet of a segment of double-sleeve pneumatic conveying channel in the first particle conveying pipe 22. An input channel on the straight pipe of the three-way drainage component 221 is connected with the compressed air flow throttling and pressure reducing component 222 and is used for providing axial pressure supplementing air flow into the three-way drainage component 221 through the compressed air flow throttling and pressure reducing component 222. The outlet of the output channel on the straight pipe of the three-way drainage component 221 is butted with the inlet of the next section of double-sleeve pneumatic conveying channel of the first particle conveying pipe 22. The "axial" in the axial pressure-compensating air flow here is, of course, the direction of the output channel on the straight tube of the three-way flow-guiding component 221. The compressed air throttling and pressure reducing component 222 comprises an air supplementing pipe with the pipe diameter generally 0.1-0.3 times that of the straight pipe of the three-way drainage component 221, and the air supplementing pipe is connected with a compressed air source. Similarly, the compressed air flow throttling and depressurizing part 222 can also adopt a throttle valve and other structures. It is preferable that the inlet pressure of the compressed gas stream throttling decompression section 222 is set to 1.5 to 3.5 times the internal gas pressure of the first particulate fluidizer 21 when it is ready to discharge the gas-particulate mixed stream.
Since the gas-particulate mixture flow must "turn" during its passage through the three-way flow directing member 221, the three-way flow directing member 221 is particularly suited for being positioned at a predetermined corner of the first particulate transport pipe 22. The preset angle of rotation of the first particulate matter conveying pipe 22 is usually intended to bypass the obstacle 12, and therefore, the preset angle of rotation of the first particulate matter conveying pipe 22 is not necessarily required depending on the position of the obstacle 12. In addition, the position of the preset corner is not necessarily a proper position for setting the air supplement node. Thus, in an alternative embodiment of the air make-up junction, an air make-up junction design different from the three-way flow directing member 215 or the three-way flow directing member 221 described above is employed to position the air make-up junction on the straight section of the first particulate transport pipe 22. For convenience of description, the air supply node provided on the straight pipe section of the first particulate matter conveying pipe 22 (or the second particulate matter conveying pipe 32) will be referred to as a straight pipe section air supply node hereinafter.
Fig. 7 is a schematic structural diagram of a gas compensation node in the reference. As shown in FIG. 7, the straight pipe section air supplement node is used for supplementing air to the corresponding straight pipe section of the particulate matter conveying pipe through a nozzle 223 which is arranged on the inner wall of the corresponding straight pipe section of the particulate matter conveying pipe and faces the particulate matter conveying direction. In an alternative embodiment, the straight section air make-up node comprises a first pipe fitting 224 and a second pipe fitting 225. Wherein the front part of the first pipe joint 224 is used for butting against the front section of the first particulate matter conveying pipe 22, the end surface of the rear part of the first pipe joint 224 is a conical surface, and the side part of the first pipe joint 224 is provided with a first connecting structure 2241; a second connecting structure 2251 is arranged at the front part of the second pipe joint 225, the rear part of the second pipe joint 225 is used for abutting against the next section of the first particle conveying pipe 22, and a tapered reducer pipe is arranged between the front part and the rear part of the second pipe joint 225; the first connecting structure 2241 and the second connecting structure 2251 are designed to be connected to each other in an axially adjustable manner, after the connection, the second pipe joint 225 forms an annular air distribution chamber outside the first pipe joint 224, the annular air distribution chamber is used to connect an air supply source (as shown in fig. 7, an air inlet connector 2252 is provided on the annular air distribution chamber, and the air inlet connector 2252 may also be connected to the air supply source through a compressed air flow throttling and depressurizing component), and after the connection, an annular oblique slit communicating with the annular air distribution chamber is formed by a fit clearance between the conical surface and the inner wall of the conical reducer, and the annular oblique slit constitutes the nozzle 223.
The straight pipe section air supplement node is arranged on the straight pipe section of the first particulate matter conveying pipe 22 through a simple structure, and more importantly, the size of the annular inclined seam (the nozzle 223) can be adjusted by adjusting the axial relative distance between the first connecting structure 2241 and the second connecting structure 2251, so that the size of the nozzle 223 can be conveniently adjusted at any time according to the field requirements. In addition, the size of the annular oblique slot (the nozzle 223) can be determined during the connection process of the first connecting structure 2241 and the second connecting structure 2251, namely during the installation process of the straight pipe section gas supplementing node, so as to simplify the operation.
Optionally, the central axis of the annular oblique slit and the central axis of the first particulate matter conveying pipe 22 intersect after the straight pipe section air supplementing node. Thus, the annular inclined seam and the first particle conveying pipe 22 can be arranged coaxially, and the air supplementing pressure of the straight pipe section air supplementing node is more uniform.
Optionally, an arcuate deflector lip 2253 is formed on the inner wall of the second adapter 225 at the exit section of the annular slanted slit. The arcuate deflector lip 2253 can reduce the dynamic losses of the compressed gas stream and facilitate the axial movement of the compressed gas stream along the first particulate transport conduit 22.
Optionally, the first connecting structure 2241 adopts a first flange, the second connecting structure 2251 adopts a second flange, the first flange is connected to the second flange through a bolt, a sealing ring is arranged between the first flange and the second flange, and the thickness of the sealing ring is variable. The sealing ring has a sealing effect, and the size of the annular inclined seam (the nozzle 223) can be adjusted by selecting the thickness of the sealing ring.
In addition, optionally, the front end and the rear end of the straight pipe section air supplement joint are respectively butted with the first particle conveying pipe 22 and the second particle conveying pipe 22 through an intermediate connecting pipe 226 with the inner wall made of wear-resistant material. The front end and the rear end of the straight pipe section air supplement node are high in airflow, and the middle connecting pipe 226 is arranged, so that rapid abrasion of the pipelines at the front end and the rear end of the straight pipe section air supplement node can be prevented. The intermediate connection pipe 226 may be a pipe lined with a wear-resistant material (e.g., a wear-resistant ceramic), or may be a pipe integrally formed of a wear-resistant material (e.g., a wear-resistant ceramic).
Wherein the front end of the first pipe joint 224 is butted against the first particle delivery pipe 22 through the corresponding middle connecting pipe 226, and a third flange 2261 can be arranged on the corresponding middle connecting pipe 226, and the third flange 2261 is bolted together with the first flange and the second flange. Since the third flange 2261 is connected to the first flange and the second flange, the size of the adjustment annular inclined gap (nozzle 223) can be determined by selecting the thickness of the sealing ring during the process of connecting the front end of the first pipe joint 224 with the corresponding intermediate connection pipe 226.
Similarly, the rear end of the second adapter 225 is connected to the rear first particle delivery pipe 22 via the corresponding intermediate connecting pipe 226, and the second adapter 225 is also connected to the corresponding intermediate connecting pipe 226 by a flange (see fig. 7).
Since the first particulate matter recoverer 23, the flow control pressure regulator 242 and the related devices are closely connected, for convenience of description, the first particulate matter recoverer 23, the flow control pressure regulator 242 and the related devices are classified as a device for pneumatic transportation of particulate matter. Fig. 4 is a schematic structural diagram of a pneumatic conveying device for particulate matters in the reference. Fig. 5 is a partial schematic structure diagram of a pneumatic conveying device for particulate matters in the reference. As shown in fig. 4 to 5, in the apparatus for pneumatic transportation of particulate matter, a dust collector 231 is connected in series to an exhaust passage of a first particulate matter recoverer 23, a flow control and pressure regulating device 24 (the flow control and pressure regulator 242 is a part of the flow control and pressure regulating device 24) is disposed downstream of an exhaust port of the dust collector 231, and the flow control and pressure regulating device 24 and the dust collector 231 are integrated on the first particulate matter recoverer 23.
As shown in fig. 4-5, the dust collector 231 is disposed at the top of the first particulate recoverer 23, and the bottom of the gas chamber 2311 to be dedusted of the dust collector 231 is directly communicated with the bin of the first particulate recoverer 23 (as shown in fig. 5), so that the connection between the dust collector 231 and the first particulate recoverer 23 is more compact. The dust collector 231 may use a filter bag 2312 as a filter element, and the filter bag 2312 may be suspended below a filter bag mounting plate of the dust collector 231, such that a gas chamber 2311 to be dedusted is formed below the filter bag mounting plate and a gas cleaning chamber 2313 is formed above the filter bag mounting plate in the dust collector 231, and the exhaust port of the dust collector 231 is disposed on the housing of the gas cleaning chamber 2313. In addition, a blowback device can be arranged in the air purifying chamber 2313, and the blowback device is in the prior art and is used for blowback and ash removal of the filter bag 2312 so as to recover the air permeability of the filter bag 2312. It will be appreciated that the specific configuration described above with respect to the dust catcher 231 is for example only, and that the dust catcher is used as a general term in the art, and should be construed to cover any possible dust removing device.
As shown in fig. 4 to 5, the flow control and pressure regulating device 24 is arranged at the top of the first particulate matter recoverer 23 and beside the dust remover 231. The flow control and pressure regulation device 24 comprises a buffer tank 241 and the flow control and pressure regulator 242. The buffer tank 241 is used for receiving the gas transmitted from the exhaust port of the dust remover 231, and then the gas passes through the buffer cavity in the buffer tank 241 and then is exhausted from the exhaust port of the buffer tank 241; the air inlet of the flow control pressure regulator 242 is connected with the air outlet of the buffer tank 241, and the air outlet of the flow control pressure regulator 242 is connected with the diffuser. The diffuser preferably diffuses the muffler 243. The diffuser or diffuser muffler 243 may be commercially available. The provision of the buffer tank 241 may improve the stability of the operation of the system and also may promote the settling of the particulate matter that passes through the dust separator 231 but is not filtered clean to protect the flow control pressure regulator 242. The bottom of the buffer tank 241 can also be communicated with the chamber of the first particle recoverer 23 through a discharge channel 2411, and a discharge valve 2412 is arranged on the discharge channel 2411. The discharge valve 2412 is in a normally closed state, and the particles in the buffer tank 241 can be discharged into the bin of the first particle recoverer 23 by opening the discharge valve 2412.
As shown in fig. 4-5, a stop valve 244 can be further disposed on the exhaust pipe between the dust collector 231 and the buffer tank 241, and the stop valve 244 can be opened when the first particulate matter conveying system performs pneumatic conveying of particulate matter and closed when the dust collector 231 performs blowback dust cleaning. Since the stop valve 244 can be opened when the first particulate matter conveying system conveys the particulate matter pneumatically and closed when the dust remover 231 performs blowback ash removal, the exhaust duct between the dust remover 231 and the buffer tank 241 is cut off, and the blowback ash removal air flow cannot flow to the buffer tank 241 to affect the blowback ash removal effect.
As shown in fig. 4 to 5, the buffer tank 241 may be further connected to a safety valve 245 for automatically opening the exhaust when the air pressure in the buffer tank 241 reaches a set threshold. The exhaust of relief valve 245 may be connected to the diffuser by exhaust conduit 246 in parallel with flow control regulator 242. Relief valve 245 may direct gas from surge tank 241 to the diffuser in the event flow control regulator 242 fails to vent as required, ensuring operational safety of the first particulate delivery system.
In addition, since a certain pressure needs to be maintained in the first particulate recoverer 23, the first particulate recoverer 23 is generally a pressure vessel adopting an arc-shaped top head structure. At this time, it is inconvenient to provide the flow control and pressure regulation device 24 at the top of the first particulate matter recoverer 23 and to maintain the dust collector 231. For this purpose, a working platform 232 may be disposed on the first particulate matter recoverer 23, and the flow control and pressure regulation device 24 is mounted on the working platform 232; in addition, the working platform 232 may also be designed as an area for operating the service platform 233 of the dust separator 231. As shown in fig. 4, the work platform 232 may be built on a support structure 234 around the first particulate matter reclaimer 23. Stairs may also be provided in the support structure 234, which may lead to the work platform 232 and the operation and service platform 233.
In addition, in the device for pneumatic conveying of particulate matter, the cross-sectional area of any one of the exhaust passages from the exhaust port of the first particulate matter recoverer 23 to the air inlet of the dust collector 231, from the exhaust port of the dust collector 231 to the air inlet of the buffer tank 241, and from the exhaust port of the buffer tank 241 to the air inlet of the flow control pressure regulator 242 on the exhaust passage of the first particulate matter recoverer 23 is not less than the cross-sectional area of the first particulate matter conveying pipe 22, so that the parts capable of exerting resistance on air flow discharge are more concentrated on the flow control pressure regulator 242 on the exhaust passage of the first particulate matter recoverer 23, and the influence range of the flow control pressure regulator 242 on the first particulate matter conveying system is further increased.
Specifically, as shown in fig. 4 to 5, since the dust collector 231 is disposed at the top of the first particulate matter recoverer 23, and the bottom of the gas chamber 2311 to be dedusted of the dust collector 231 is directly communicated with the bin of the first particulate matter recoverer 23, the exhaust passage from the exhaust port of the first particulate matter recoverer 23 to the inlet port of the dust collector 231 is actually formed by the gas chamber 2311 to be dedusted of the dust collector 231, that is, the cross-sectional area of the gas chamber 2311 to be dedusted is equal to or larger than the cross-sectional area of the first particulate matter conveying pipe 22. As shown in FIGS. 4 to 5, the exhaust port of the dust collector 231 and the inlet port of the surge tank 241 are connected by a duct, and therefore, the exhaust passage from the exhaust port of the dust collector 231 to the inlet port of the surge tank 241 is constituted by the duct, so that the cross-sectional area of the duct should be equal to or larger than the cross-sectional area of the first particulate matter transporting pipe 22. Similarly, the cross-sectional area of the pipeline from the exhaust port of the buffer tank 241 to the inlet port of the flow control and pressure regulator 242 should be greater than or equal to the cross-sectional area of the first particulate matter conveying pipe 22.
Because the flow control pressure regulator 242 is disposed on the exhaust passage of the first particulate matter recoverer 23 and is used for applying resistance to the exhaust gas flow in the exhaust passage, the pressure in the chamber of the first particulate matter recoverer 23 is increased, which may cause inconvenience to the discharge of the particulate matter in the first particulate matter recoverer 23, and therefore, a second particulate matter conveying system may be further provided to convey the particulate matter in the first particulate matter recoverer 23 to another chamber independent of the first particulate matter recoverer 23, so that the discharge of the particulate matter in the chamber independent of the first particulate matter recoverer 23 does not affect the operation of the first particulate matter conveying system.
The second particulate matter delivery system can generally include a particulate matter delivery mechanism and a second particulate matter reclaimer 33. The particulate matter conveying mechanism is used for outputting the particulate matter collected in the first particulate matter recoverer 23 as the particulate matter to be conveyed along a set route; the second particulate matter recoverer 33 is configured to receive the particulate matter from the particulate matter transporting mechanism, and the chamber of the second particulate matter recoverer 33 has an air pressure independent of the chamber of the first particulate matter recoverer 23. Normally, the exhaust passage of the second particulate matter recoverer 33 is open to the outside atmospheric environment; more specifically, the exhaust passage of the second particulate matter recoverer 33 is connected in series with a dust collector 331, and an exhaust port of the dust collector 331 is directly communicated with the outside atmosphere.
In the second particulate matter conveying system, the particulate matter conveying mechanism may comprise a second particulate matter fluidizer 31 and a second particulate matter conveying pipe 32, wherein the second particulate matter fluidizer 31 is connected with a discharge opening of the first particulate matter recoverer 23 through a discharge valve, and is used for fluidizing the particulate matter from the first particulate matter recoverer 23 by using fluidizing gas so as to generate and output a gas-particulate matter mixed flow; the second particulate transport pipe 32 is used to transport the gas-particulate mixed stream output from the second particulate fluidizer along a set path. Because the second particulate matter conveying system comprises the second particulate matter fluidizer 31, the second particulate matter conveying pipe 32 and the second particulate matter recoverer 33, the working principle of the second particulate matter conveying system is similar to that of the first particulate matter conveying system before improvement, and the description is omitted here.
In another embodiment of the second particle transporting system, the first particle recoverer 23 can be disposed above the second particle recoverer 33, and the bottom of the first particle recoverer 23 is communicated with the bin of the second particle recoverer 33 through a discharging mechanism, and the discharging mechanism is provided with a discharging valve. The discharge mechanism is to be understood as a general term in the art and the scope is intended to cover any possible discharge device, such as a discharge tube. Obviously, the second particulate matter conveying system of this embodiment has a simpler structure, and contributes to cost saving and floor space saving, but because the chamber pressure of the first particulate matter reclaimer 23 is greater than the chamber pressure of the second particulate matter reclaimer 33, the speed of discharging from the first particulate matter reclaimer 23 to the second particulate matter reclaimer 33 is faster, and it is easy to cause damage to related pipes, valves and other facilities.
Fig. 8 is a schematic diagram of the control system of a system for pneumatic transport of particulate matter according to the reference. As shown in fig. 8, the control system includes a control device 41 and various sensors and actuators in signal connection with the control device 41.
As shown in fig. 8, the control device 41 includes a processor 411, a memory 412, and a communication interface 415. The processor 411 and the memory 412 are connected to a communication interface 415, for example, via various interfaces, transmission lines or buses. Optionally, the control apparatus 41 may further comprise an input device 413 and an output device 414. Alternatively, the control device 41 may employ a PLC Controller (Programmable Logic Controller). In addition, the control device 41 can also be connected with an upper computer, and the upper computer can be deployed remotely, so that remote monitoring is realized. The upper computer may include an upper computer dedicated processor, memory, output device, and the like.
The processor 411 may include a Central Processing Unit (CPU), a Digital Signal Processor (DSP), a microprocessor, an Application Specific Integrated Circuit (ASIC), a Microcontroller (MCU), a Field Programmable Gate Array (FPGA), or one or more Integrated circuits for implementing logical operations. The processor 411 can be used to perform the required functions for the control system, for example for controlling the entire system for pneumatic transport of particulate matter, executing software programs, processing data of software programs, etc. The software may be software for implementing the particulate matter pneumatic conveying method, process of the embodiments of the present application.
The memory 412 may include mass storage for data or instructions. By way of example, and not limitation, memory 412 may include a Hard Disk Drive (HDD), a floppy Disk Drive, flash memory, an optical Disk, a magneto-optical Disk, tape, or a Universal Serial Bus (USB) Drive or a combination of two or more of these. Memory 412 may include removable or non-removable (or fixed) media, where appropriate. The memory 412 may be internal or external to the processor 411, where appropriate. In a particular embodiment, the memory 412 is a non-volatile solid-state memory. In particular embodiments, memory 412 includes Read Only Memory (ROM); where appropriate, the ROM may be mask-programmed ROM, Programmable ROM (PROM), Erasable PROM (EPROM), Electrically Erasable PROM (EEPROM), electrically rewritable ROM (EAROM), or flash memory or a combination of two or more of these.
The communication interface 415 is used to connect the control device 41 to various sensors and actuators (which may also be collectively referred to as "instrumentation") via communication links. The communication link may be a wired communication link or a wireless communication link. The wireless communication link may be implemented by a wireless transmission network supporting wireless communication technologies such as Zig-zag, Bluetooth (Bluetooth), wireless broadband (Wi-Fi), Ultra Wideband (UWB), General Packet Radio Service (GPRS), Code Division Multiple Access (CDMA), Long Term Evolution (LTE), or New Radio (NR).
The input device 413 is in communication with the processor 411 and can accept user input in a variety of ways. For example, the input device 413 may be a mouse, a keyboard, a touch screen device, or a sensor. An output device 414 is in communication with the processor 411 and may display information in a variety of ways. For example, the output device 414 may be a liquid crystal display, a light emitting diode display device, a cathode ray tube display device, a projector, or the like.
As shown in fig. 8, the various sensors and actuators in signal communication with the control device 41 may include a plurality of pressure sensors as well as a discharge actuator 424, a fluidization actuator 425, and a release actuator 426. The plurality of pressure sensors include pressure sensors respectively disposed at different locations in the first particulate matter delivery system, that is, a first pressure sensor 421, a second pressure sensor 422, and a third pressure sensor 423. Wherein, the first pressure sensor 421 is arranged on the first particle fluidizer 21 and is used for detecting the internal air pressure value of the first particle fluidizer 21; the second pressure sensors 422 are arranged at the air replenishing nodes of the first particulate matter conveying pipe 22 (the second pressure sensors 422 are correspondingly arranged at each air replenishing node of the first particulate matter conveying pipe 22 one by one) and used for detecting the pressure values after air replenishing of the corresponding air replenishing nodes; the third pressure sensor 423 is disposed at an air inlet of the flow control regulator 242, and is configured to detect a pressure value of the air inlet of the flow control regulator 242. The pressure value after air supply by taking the three-way drainage component 215 or the three-way drainage component 221 as the air supply node can be detected by a pressure sensor arranged in an input channel on the straight pipe corresponding to the three-way drainage component; the pressure value after being supplemented with air through the straight pipe section air supplementing node can be detected through a pressure sensor arranged in the straight pipe section air supplementing node and behind the nozzle 223. The discharge actuator 424 includes an actuator that controls the operation of the discharge valve 212 between the bin 11 and the first particulate fluidizer 21. The fluidization actuator 425 includes an actuator for controlling the valve operation of the fluidization gas inlets of the bin pump 211 of the first particulate fluidizer 21. The release actuator 426 includes an actuator that controls actuation of a valve on the outlet pipe 214 of the first particulate fluidizer 21.
Based on the above control system, during the operation of the first particulate matter transporting system, before the first particulate matter fluidizer 21 releases the gas-particulate matter mixed flow, the first particulate matter transporting pipe 22 is charged and the gas charged into the first particulate matter transporting pipe 22 is restricted by the flow control pressure regulator 242 to be discharged through the first particulate matter recoverer 23 and the exhaust passage thereof, so that the pressure in the first particulate matter transporting pipe 22 can be controlled within a set range. During specific operation, the flow control pressure regulator 242 is set, specifically, a set threshold value of a pressure value of an air inlet of the flow control pressure regulator 242 is set to be 0.2Mpa, so that when the pressure value of the air inlet of the flow control pressure regulator 242 reaches 0.2Mpa, the air is conducted to start exhaust, and when the pressure value of the air inlet of the flow control pressure regulator 242 does not reach 0.2Mpa, the air is blocked to stop exhaust; then, with the valves on the offtake pipe 214 closed, an axial flow of make-up air is provided to the first particulate matter transport pipe 22 via respective make-up air nodes on the first particulate matter transport pipe 22, so that the pressure in the first particulate matter transport pipe 22 will increase rapidly.
During or after the process of charging the first pm conveying pipe 22 and controlling the pressure in the first pm conveying pipe 22 to be within the set range by restricting the gas charged in the first pm conveying pipe 22 from being discharged through the first pm recoverer 23 and its exhaust passage by the flow control regulator 242, the control device 41 issues a command to cause the discharge actuator 424 to control the operation of the discharge valve 212 between the bin 11 and the first pm fluidizer 21, so that the pm (with a bulk density of 2 kg/m) in the bin 11 is caused to flow3) Discharged into a first particulate fluidizer 21. Then, the control device 41 gives a command to the fluidization actuator 425 to control the valves of the fluidization gas inlets of the bin pumps 211 of the first particulate matter fluidizer 21 to open according to the discharge completion feedback signal, and the first particulate matter fluidizer 21 starts fluidizing the particulate matter. When the first pressure sensor 421 detects that the internal air pressure P0 of the first particulate fluidizer 21 reaches 0.4Mpa, the first pressure sensor 421, the second pressure sensor 422 and the third pressure sensor 423 detect that: p0 is more than or equal to P1 is more than or equal to P2 is more than or equal to … … is more than Pm is more than or equal to 0.2Mpa (P1 is the pressure value detected by the second pressure sensor 422 corresponding to the first air supplement node, P2 is the pressure value detected by the second pressure sensor 422 corresponding to the second air supplement node, Pn is the second pressure sensor 422 corresponding to the nth air supplement nodeThe detected pressure value Pm is the pressure value detected by the third pressure sensor 423), the control device 41 sends out a command to enable the release actuator 426 to control the opening of the valve on the discharge pipe 214 of the first particulate fluidizer 21. When the internal gas pressure of the first particle fluidizer 21 drops to a set value (e.g., 0.24MPa), it is assumed that the particle output of the first particle fluidizer 21 is completed, which causes the valve on the discharge pipe 214 of the first particle fluidizer 21 to close. Thus, the first particulate matter conveying system completes the pneumatic conveying of the particulate matter.
After a certain amount of particulate matter is contained in the first particulate matter recoverer 23, the particulate matter in the first particulate matter recoverer 23 is conveyed to the second particulate matter recoverer 33 by the second particulate matter conveying system.
Although the control system can realize the control of the pneumatic conveying of the particulate matters, the objective detection and evaluation of the flow speed of the particulate matters and the particulate matter concentration of the gas-particulate matter mixed flow are difficult to carry out, and meanwhile, the accurate real-time quantification of the pneumatic conveying process of the particulate matters is difficult to carry out, so that the pneumatic conveying of the particulate matters is not accurately controlled, particularly the closing time of each air supplementing node is difficult to accurately control, and the starting time of the air supplementing nodes is easy to overlong, thereby causing unnecessary waste. In addition, the control system relies on the detection data provided by each pressure sensor, so that a large number of pressure sensors need to be deployed; and these pressure sensors need to be spaced along the particulate matter transport pipe, the cost of installing the pressure sensors for wiring is high.
The embodiment of the application provides a particulate matter recovery device aiming at the problem that when the bin pressure of the first particulate matter recoverer 23 is greater than that of the second particulate matter recoverer 33, the speed is high, so that related pipes, valves and other facilities are easily damaged when the first particulate matter recoverer 23 discharges materials to the second particulate matter recoverer 33. Fig. 9 is a schematic structural view (perspective view) of a particulate matter recovery device according to an embodiment of the present application. Fig. 10 is a schematic structural diagram (front projection view) of a particulate matter recovery device according to an embodiment of the present application. The particulate matter recovery apparatus shown in fig. 9 to 10 includes: a first particulate matter recoverer 23 and a second particulate matter recoverer 33; the first particulate matter recoverer 23 is used for receiving a gas-particulate matter mixed flow transmitted by particulate matter pneumatic transmission and discharging gas brought by the gas-particulate matter mixed flow from an exhaust channel of the first particulate matter recoverer 23, and a bin of the first particulate matter recoverer 23 has a first air pressure; a second particulate recoverer 33 located below the first particulate recoverer 23 and configured to receive particulate matter from the first particulate recoverer 23 via a discharge mechanism, the second particulate recoverer 33 having a chamber with a second air pressure independent of the first air pressure; wherein, discharge mechanism includes: a transfer bin 511, located between the first particle recoverer 23 and the second particle recoverer 33, for receiving the particles from the first particle recoverer 23 and releasing the particles temporarily stored in the transfer bin to the second particle recoverer 33; the bidirectional pressure equalizer 512 comprises a first pressure equalizing mechanism 5121 and a second pressure equalizing mechanism 5122, the first pressure equalizing mechanism 5121 selectively opens to communicate the chamber of the transfer bin 511 with the chamber of the first particulate matter recoverer 23, and the second pressure equalizing mechanism 5122 selectively opens to communicate the chamber of the transfer bin 511 with the chamber of the second particulate matter recoverer 33; and the discharge valve group 513 comprises a first discharge valve system and a second discharge valve system, the first discharge valve system is installed on a discharge channel between the first particulate matter recoverer 23 and the middle rotary bin 511, and the second discharge valve system is installed on a discharge channel between the second particulate matter recoverer 33 and the middle rotary bin 511.
When the first pressure equalizing mechanism 5121 is selectively opened and the second pressure equalizing mechanism 5122 is selectively closed, the pressure of the chamber of the intermediate bin 511 is balanced with the pressure of the chamber of the first particulate matter recoverer 23, and at this time, the first unloading valve system is opened to unload the particulate matter in the first particulate matter recoverer 23 into the intermediate bin 511, so that the damage of facility equipment such as the first unloading valve system caused by the high-speed movement of the particulate matter can be avoided due to the balance between the pressure of the chamber of the intermediate bin 511 and the pressure of the chamber of the first particulate matter recoverer 23. When the first pressure equalizing mechanism 5121 is selected to be closed and the second pressure equalizing mechanism 5122 is selected to be opened, the pressure of the bin of the middle rotating bin 511 is balanced with the pressure of the bin of the second particulate matter recoverer 33, and at this time, the second unloading valve system is opened to unload the particulate matters in the middle rotating bin 511 into the second particulate matter recoverer 33, so that the damage of facility equipment such as the second unloading valve system caused by the high-speed movement of the particulate matters can be avoided due to the balance between the pressure of the bin of the middle rotating bin 511 and the pressure of the bin of the second particulate matter recoverer 33. Thus, the problem that facilities such as related ducts and valves are easily damaged when the discharge speed is high when the bin pressure of the first particulate matter recoverer 23 is higher than the bin pressure of the second particulate matter recoverer 33 and the discharge is performed from the first particulate matter recoverer 23 to the second particulate matter recoverer 33 can be effectively solved.
The first pressure equalizing mechanism 5121 may adopt a first pressure equalizing pipe provided with a first pressure equalizing valve, and the second pressure equalizing mechanism 5122 may also adopt a second pressure equalizing pipe provided with a second pressure equalizing valve. When a dust collector 231 is connected in series to the exhaust channel of the first particulate matter recoverer 23 and a dust collector (not shown) is also connected in series to the exhaust channel of the second particulate matter recoverer 33, the first equalizing mechanism 5121 selectively opens to conduct the chamber of the middle rotary bin 511 and the exhaust port of the dust collector 231 connected in series to the exhaust channel of the first particulate matter recoverer 23 (i.e., the first equalizing pipe of the first equalizing mechanism 5121 is connected between the chamber of the middle rotary bin 511 and the exhaust port of the dust collector 231 connected in series to the exhaust channel of the first particulate matter recoverer 23, and the first equalizing valve of the first equalizing mechanism 5121 is opened), and the second equalizing mechanism 5122 selectively opens to conduct the chamber of the middle rotary bin 511 and the exhaust port of the dust collector connected in series to the exhaust channel of the second particulate matter recoverer 33 (i.e., the pipe of the second equalizing mechanism 5122 is connected between the chamber of the middle rotary bin 511 and the second particulate matter recoverer 33) Between the exhaust ports of the dust collectors connected in series on the exhaust passage of the particulate matter recoverer 33, while the second pressure equalizing valve on the second pressure equalizing pipe of the second pressure equalizing mechanism 5122 is opened). In addition, the bidirectional pressure equalizer 512 can also include and install the transit bin 511 top and be located the first particulate matter recoverer 23 with the vertical form pressure-equalizing filter 5123 of the side of the discharge passage between the transit bin 511, vertically install the tubulose filter core in the pressure-equalizing filter 5123, the top of pressure-equalizing filter 5123 is equipped with the air-purifying chamber, the air-purifying chamber through be equipped with the first pressure-equalizing pipe of first pressure-equalizing valve and be equipped with the second pressure-equalizing pipe of second pressure-equalizing valve respectively with the bin of first particulate matter recoverer 23 and the bin of second particulate matter recoverer 33 switches on, the bottom of pressure-equalizing filter 5123 is equipped with former air chamber, former air chamber with the bin 511 switches on. When the bi-directional pressure equalizer 512 adopts the above structure, the blockage or damage caused by the particles entering the first pressure equalizing mechanism 5121 and the second pressure equalizing mechanism 5122 can be avoided. In addition, the pressure equalizing filter 5123 is located beside the discharge channel between the first particulate matter recoverer 23 and the transfer bin 511, and is vertical, so that the pressure equalizing filter 5123 can fully utilize the space between the first particulate matter recoverer 23 and the transfer bin 511, and the space is fully utilized.
In order to facilitate the arrangement of the first particulate matter recoverer 23 above the second particulate matter recoverer 33, a steel bracket 514 may be arranged between the first particulate matter recoverer 23 and the second particulate matter recoverer 33, and the first particulate matter recoverer 23 may be supported above the second particulate matter recoverer 33 by the steel bracket 514. In addition, a maintenance platform 5141 can be further disposed between the first particulate matter recoverer 22 and the middle rotating bin 511 in the steel bracket 514, so as to facilitate maintenance and repair of the bidirectional pressure equalizer 512 and the first discharge valve system.
The first discharge valve system can comprise a mechanical drive discharge valve 5151, a conical reducing connection pipe 5152, a flexible joint 5153, a dust cut-off valve 5154 and a gas seal valve 5155 which are sequentially connected from top to bottom; optionally, the mechanically-driven discharge valve 5151 is an electric star-shaped discharge valve; optionally, the gas sealing valve 5155 is a dome valve. The second discharge valve system can comprise a dust cut-off valve 5161 and a gas sealing valve 5162 which are sequentially connected from top to bottom; optionally, the gas sealing valve 5162 is a dome valve.
The first discharge valve system and the second discharge valve system are reasonable in design. The reason is that: firstly, they all contain dust trip valve and gas seal valve and the dust trip valve is located corresponding gas seal valve top, when needing to close the gas seal valve, can cut off the dust source through the dust trip valve earlier, just so can effectively avoid receiving the influence of dust when the gas seal valve is closed and lead to the fact sealed effect not good, cause the leakage. Secondly, the first discharge valve system is also provided with a mechanical driving discharge valve 5151, a conical reducing connection pipe 5152 and a flexible joint 5153 from top to bottom in sequence above a dust cut-off valve 5154, and the three are combined together to achieve the effect that the diameters of a discharge channel between the first particulate matter recoverer 23 and the intermediate rotary bin 511 and a discharge channel between the intermediate rotary bin 511 and the second particulate matter recoverer 33 can be consistent through the conical reducing connection pipe 5152, the installation of the conical reducing connection pipe 5152 is facilitated through the flexible joint 5153, and then the flow of particulate matters in the conical reducing connection pipe 5152 is promoted through the mechanical driving discharge valve 5151 (such as an electric star-shaped discharge valve) to avoid blockage.
In order to facilitate the detection and control of the pneumatic conveying of the particulate matters, the system for the pneumatic conveying of the particulate matters is also provided with a pneumatic conveying detection device of the particulate matters. Fig. 11 is a schematic structural diagram of a pneumatic conveying and detecting apparatus for particulate matter according to an embodiment of the present application. As shown in fig. 11, the pneumatic conveying and detecting equipment for particulate matter comprises a particulate matter flow dynamic monitoring component 43, which is installed on the first particulate matter conveying pipe 22 and is used for collecting the dynamic information of the particulate matter flow in the first particulate matter conveying pipe 22; and the signal processing component is in communication connection with the dynamic particulate matter flow monitoring component and is used for processing the dynamic particulate matter flow information so as to obtain a detection result of the running condition. The signal processing means may be the same device as the control device 41 (e.g., PLC controller). The dynamic pm flow monitoring means 43 is used to acquire dynamic pm flow information in the first pm conveying pipe 22, and the dynamic pm flow monitoring means 43 can be a commercially available pm flow detector. Although the currently available particulate matter flow meters generally have low detection accuracy, they may still help control device 41 perform some of the innovative detection and/or control functions.
For example, the current pneumatic conveying system for particulate matter, including the references, cannot accurately detect the flow rate of particulate matter in the particulate matter conveying pipe (e.g., the first particulate matter conveying pipe 22). Even if the particulate matter flow dynamic monitoring part 43 with low detection precision can still find the sudden change of the particulate matter flow in the first particulate matter conveying pipe 22, therefore, as long as the control device 41 obtains the time point of the gas-particulate matter mixed flow output by the first particulate matter fluidizer 21 (the information can be obtained by the release executing mechanism 426), and obtains the time point (i.e. the time point of the flow increase) of the flow sudden change caused when the particulate matter reaches the particulate matter flow dynamic monitoring part 43 through the particulate matter flow dynamic monitoring part 43, in this way, the particulate matter flow speed height judgment index can be accurately detected, and therefore, the particulate matter flow height can be accurately judged.
For example, in the existing pneumatic conveying system for particulate matter, including the reference documents, it is not possible to accurately detect the pneumatic conveying termination judgment index of particulate matter in the particulate matter conveying pipe (e.g., the first particulate matter conveying pipe 22). Even if the particulate matter flow dynamic monitoring part 43 with low detection precision can still find the sudden change of the particulate matter flow in the first particulate matter conveying pipe 22, therefore, as long as the control device 41 obtains the time point of the gas-particulate matter mixed flow output by the first particulate matter fluidizer 21 (the information can be obtained by the release actuating mechanism 426), and obtains the time point of the flow sudden change (namely the time point of the flow reduction) caused when the particulate matter leaves the particulate matter flow dynamic monitoring part 43 through the particulate matter flow dynamic monitoring part 43, in this way, the judgment index of whether the particulate matter pneumatic conveying is finished or not can be accurately detected, and the time of the particulate matter pneumatic conveying is accurately judged. After the pneumatic conveying of the particles in the first particle conveying pipe 22 is judged to be finished, the control device 41 can instruct each air supply node of the first particle conveying pipe 22 to stop supplying air, so that the air consumption is saved.
The two examples above show that: during pneumatic conveying of particulate matters, basic operation state information of the pneumatic conveying system of the particulate matters is obtained (the basic operation state information is used for determining a detection reference of the operation condition), dynamic information of particulate matters flow in the particulate matter conveying pipe is obtained (the dynamic information of the particulate matters flow is collected by a dynamic monitoring component of the particulate matters flow mounted on the particulate matter conveying pipe), and finally, the basic operation state information and the dynamic information of the particulate matters flow are combined to obtain a detection result of the operation condition, so that the detection result is often timely and accurate.
In addition, the pneumatic conveying and detecting method of the particulate matters can also comprise the following steps: acquiring dynamic information of the particulate matter flow in a particulate matter conveying pipe, wherein the dynamic information of the particulate matter flow is acquired by a dynamic monitoring part of the particulate matter flow arranged on the particulate matter conveying pipe; and analyzing the change situation of the particulate matter flow over time reflected by the dynamic information of the particulate matter flow, and obtaining a detection result of the operation situation of the pneumatic particulate matter conveying system through the analysis.
For example, if the operation condition of the pneumatic particulate matter conveying system includes a particulate matter concentration level judgment indicator of the gas-particulate matter mixed flow, the shape of the waveform of the particulate matter flow rate with time is obtained by analyzing the time-varying condition of the particulate matter flow rate, and the shape is used as a detection result of the particulate matter concentration level judgment indicator of the gas-particulate matter mixed flow. It is apparent that the higher the waveform height of the change with time of the particulate matter flow rate caused when the particulate matter reaches the particulate matter flow rate dynamic monitoring means 43, the higher the particulate matter concentration, and vice versa. Therefore, the particle concentration of the gas-particle mixed flow can be objectively reflected through the waveform of the change of the particle flow along with the time.
For another example, if the operating condition of the pneumatic particulate matter conveying system includes a particulate matter conveying amount judgment index, the time-dependent integration of the particulate matter flow rate is obtained by analyzing the time-dependent variation of the particulate matter flow rate, and the integration result is used as the detection result of the particulate matter conveying amount judgment index. It is apparent that the more accurate the particulate matter flow rate versus time integration result of the particulate matter flow rate dynamic monitoring means 43, the more accurately the particulate matter transport amount can be reflected. When the particulate matter flow dynamic monitoring component 43 is accurate enough, the above integration result can be relied on completely to judge the particulate matter delivery amount, and then whether the particulate matter delivery pipe is blocked can be further judged.
The control device 41 and/or the host computer communicatively connected to the control device 41 includes a processor, a memory, and an output device, where the memory stores therein a computer program or instructions executable by the processor to display the time-varying changes in the particulate matter flow rate reflected by the particulate matter flow rate dynamics information and/or the results of analyzing the time-varying changes in the particulate matter flow rate reflected by the particulate matter flow rate dynamics information on the output device.
The inventors believe that it is most desirable to have the particulate flow dynamics monitoring device 43 mounted on the first particulate matter transport pipe 22 near the first particulate matter reclaimer 23 (i.e., at the end of the particulate matter transport pipe of a pneumatic particulate matter transport system). This makes it possible to make the detection of the particulate matter flow rate level judgment index, the particulate matter pneumatic conveyance completion judgment index, and the particulate matter conveyance amount judgment index more meaningful for the subsequent control by the control device 41.
Preferably, the particulate matter flow dynamic monitoring component 43 adopts a micro-charge sensing device. A micro-charge sensing device (micro-electric sensor) is a device that detects particles (solid particles or liquid particles) in an air flow by micro-charge sensing to obtain information such as particle flow rate. The commercial available commercial product is the TRIBO series of Auburn systems. The micro-charge sensing device is very sensitive and has high accuracy, and is very suitable for serving as the dynamic monitoring part 43 for the particle flow.
The conventional micro-charge sensing device mainly comprises a Probe (Probe) and a signal processing system. The probe is designed into a probe with a short length, is inserted into the airflow channel when in use, and generates and outputs a current signal when particulate matters in the airflow channel pass through the probe, wherein the current signal is used as an input signal of the signal processing system. Since the current signal generated and outputted by the probe is weak enough to be processed by a subsequent device (e.g., the control device 41 or the PLC controller), and at the same time, to ensure that the current signal is affected by as low interference as possible and/or other adverse effects that may cause signal distortion, it is necessary to process the current signal generated and outputted by the probe through a signal processing system to output an accurate signal that can be processed by the subsequent device (e.g., the control device 41 or the PLC controller). US5448172 discloses a signal processing system comprising a transducer (converter means) which basically amplifies the current signal generated and output by the probe. Typically, signal processing systems are used to output standard industry signals such as 4-20 milliamp current or 1-5 volts. The output signal of the signal processing system may be generally indicative of the flow of particulate matter detected by the micro-charge sensing device.
Fig. 12 is a schematic structural diagram of a particulate matter sensing device (specifically, a micro-charge sensing device) according to an embodiment of the present application. Fig. 13 is a schematic structural diagram of a particulate matter sensing device (specifically, a micro-charge sensing device) according to an embodiment of the present application. Fig. 14 is a sectional view taken along line a-a in fig. 12. Fig. 15 is a sectional view taken along line B-B in fig. 13. As shown in fig. 12 to 15, the particle sensing device comprises a probe 431, the probe 431 is arranged on an airflow channel when in use, and generates and outputs a current signal when particles in the airflow channel pass through the probe 431, the current signal is used as an input signal of a signal processing system, wherein the probe 431 is arranged on the airflow channel in a way that the following conditions are met simultaneously: a) mounted on the outside of the inner wall surface of the case 432 constituting the gas flow passage, b) not electrostatically shielded on the side facing the gas flow passage, and c) insulated from the case 432. Since the probe 431 is attached to the outside of the inner wall surface of the tube case 432 constituting the airflow passage, is not electrostatically shielded on the side facing the airflow passage, and is connected to the tube case 432 in an insulated manner, the probe 431 is not inserted into the airflow passage to hinder the flow of the particulate matter as in the conventional probe.
Specifically, the probe 431 may include a first structure formed by an inductor extending along a circumferential direction of the gas flow channel, and the first structure is a complete annular body or a non-complete annular body. The probe also comprises a second structure formed by at least two inductors which are arranged at intervals along the axial direction of the airflow channel, and the current signals generated by the inductors in the second structure are output through the same or different probe output parts. In addition, at least one inductor in each inductor in the second structure may also adopt the first structure. In addition, in order to connect the probe 431 in an insulated manner with the pipe shell 432, the probe 431 can be installed in the pipe shell 432 through an insulating sheath 433, and the insulating sheath 433 forms a probe installation area matched with the shape of the probe 431, and the probe is wrapped in the probe installation area. The insulating sheath can be made of rubber, and is preferably made of polytetrafluoroethylene. If the probe 431 includes the first structure, the insulating sheath 433 may be a prefabricated annular member, an annular concave groove serving as the probe mounting region and adapted to the first structure is formed on an inner wall of the prefabricated annular member, and the first structure is placed in the annular concave groove.
The particle sensing device can also be designed as a prefabricated particle sensing component, the prefabricated particle sensing component comprises the probe 431 and the pipe shell 432 which are assembled together, and two ends of the pipe shell 432 are respectively provided with a pipe butt joint structure 4321 which is used for placing the prefabricated sensing component on an airflow conveying pipe to form a part of the airflow conveying pipe. The pipeline butt joint structure 4321 preferably adopts a flange. Obviously, design into prefabricated particulate matter response subassembly with above-mentioned particulate matter induction system and can make things convenient for particulate matter induction system's installation.
In addition, to facilitate installation of the probe 431 in the tube housing 432, the tube housing 432 may include a base layer formed by axially abutting a first tube 4322 shell and a second tube 4323, the base layer having a splice groove therein formed by the first tube 4322 and the second tube 4323 after the axial abutment, the probe 431 being installed in the splice groove. The electrostatic shielding of the probe 431 from the environment outside the cartridge 432 is achieved here by the cartridge 432 itself being a shielding material. Optionally, the end surface of the first tube shell 4322, which is used for being in butt joint with the second tube shell 4323, includes a first tube shell outer edge end surface and a first tube shell inner edge end surface, the end surface of the second tube shell 4323, which is used for being in butt joint with the first tube shell 4322, includes a second tube shell outer edge end surface and a second tube shell inner edge end surface, and after the first tube shell 4322 and the second tube shell 4323 are in axial butt joint, the first tube shell outer edge end surface and the second tube shell outer edge end surface are in mutual contact, and the first tube shell inner edge end surface and the second tube shell inner edge end surface are separated from each other to form the splicing groove. Optionally, the outer edge end face of the first tube shell is welded with the outer edge end face of the second tube shell. Furthermore, the splicing groove may be adapted to fit the preformed annular member, which is placed in the splicing groove. Typically, a layer 434 of non-electrostatic shielding material is also mounted on the inner wall surface of the base layer. The layer 434 of non-electrostatic shielding material may be composed of a wear resistant material, preferably a ceramic material.
The particle sensing device is assembled to create a mechanical fit gap, so that the mechanical fit gap created by the mounting of the probe on the cartridge 432, which may result in gas leakage, can be filled with a sealant 436.
Optionally, a junction box 435 having an electrostatic shielding function for the outside may be further mounted on the outer wall surface of the tube housing 432, a first wire holder 4351 is disposed in the junction box 435, a current input end of the first wire holder is electrically connected to the probe 431 in a manner of being insulated from the tube housing under the protection of an insulating structure (such as a sealant 436), and a current output end of the first wire holder is provided with a first wire connection structure. In addition, a second wire holder 4352 can be further arranged in the connection box, a current input end of the second wire holder is electrically connected with the tube shell, and a current output end of the second wire holder is provided with a second wiring structure.
The contents related to the present application are explained above. Those of ordinary skill in the art will be able to implement the present application based on these teachings. All other embodiments made by those skilled in the art without any inventive step based on the above description shall fall within the scope of the present application.

Claims (10)

1. A pneumatic conveying detection method for particulate matters is characterized by comprising the following steps: the system is used for detecting the operation condition of the pneumatic particulate matter conveying system;
the pneumatic particulate matter conveying system comprises a particulate matter fluidizer, a particulate matter conveying pipe and a particulate matter recoverer;
the particle fluidizer is used for fluidizing particles to be conveyed by using fluidizing gas so as to generate and output a gas-particle mixed flow;
the particle conveying pipe is used for conveying the gas-particle mixed flow output from the particle fluidizer along a set route;
the particle recoverer is used for receiving the gas-particle mixed flow transmitted from the particle conveying pipe and discharging gas brought by the gas-particle mixed flow from an exhaust channel of the particle conveying pipe;
the method specifically comprises the following operations:
acquiring basic operation state information of the pneumatic particulate matter conveying system, wherein the basic operation state information is used for determining a detection reference of the operation condition;
acquiring dynamic information of the particulate matter flow in the particulate matter conveying pipe, wherein the dynamic information of the particulate matter flow is acquired by a dynamic monitoring part of the particulate matter flow arranged on the particulate matter conveying pipe; and
and combining the basic operation state information with the dynamic particulate matter flow information to obtain a detection result of the operation condition.
2. The pneumatic conveying and detecting method for particulate matter according to claim 1, characterized in that: the operation condition comprises a particulate matter flow velocity high-low judgment index, the required basic operation state information comprises a time point of outputting a gas-particulate matter mixed flow by the particulate matter fluidizer, and the required particulate matter flow dynamic information comprises a time point of causing flow mutation when the particulate matter reaches to obtain a detection result of the particulate matter flow velocity high-low judgment index; and/or the operation condition comprises a particulate matter pneumatic transmission ending or non-ending judgment index, the required basic operation state information comprises a time point of outputting a gas-particulate matter mixed flow by the particulate matter fluidizer, and the required particulate matter flow dynamic information comprises a time point of flow mutation caused by particulate matter leaving, so as to obtain a detection result of the particulate matter pneumatic transmission ending or non-ending judgment index.
3. A pneumatic conveying detection method for particulate matters is characterized by comprising the following steps: the system is used for detecting the operation condition of the pneumatic particulate matter conveying system;
the pneumatic particulate matter conveying system comprises a particulate matter fluidizer, a particulate matter conveying pipe and a particulate matter recoverer;
the particle fluidizer is used for fluidizing particles to be conveyed by using fluidizing gas so as to generate and output a gas-particle mixed flow;
the particle conveying pipe is used for conveying the gas-particle mixed flow output from the particle fluidizer along a set route;
the particle recoverer is used for receiving the gas-particle mixed flow transmitted from the particle conveying pipe and discharging gas brought by the gas-particle mixed flow from an exhaust channel of the particle conveying pipe;
the method specifically comprises the following operations:
acquiring dynamic information of the particulate matter flow in the particulate matter conveying pipe, wherein the dynamic information of the particulate matter flow is acquired by a dynamic monitoring part of the particulate matter flow arranged on the particulate matter conveying pipe;
and analyzing the change situation of the particulate matter flow over time reflected by the dynamic information of the particulate matter flow, and obtaining a detection result of the running situation through the analysis.
4. The pneumatic conveying and detecting method for particulate matter according to claim 3, characterized in that: the operation condition comprises a particulate matter concentration height judgment index of the gas-particulate matter mixed flow, and the shape of the particulate matter flow along with the time change waveform is obtained by analyzing the particulate matter flow along with the time change condition and is used as a detection result of the particulate matter concentration height judgment index of the gas-particulate matter mixed flow; and/or the operating condition comprises a particulate matter delivery quantity judgment index, and the particulate matter flow rate-time integral is obtained by analyzing the change condition of the particulate matter flow rate over time, and the integral result is used as the detection result of the particulate matter delivery quantity judgment index.
5. The pneumatic conveying and detecting method for particulate matter according to any one of claims 1 to 4, characterized in that: the dynamic particulate matter flow monitoring part is arranged on the particulate matter conveying pipe and close to the particulate matter recoverer; and/or the dynamic monitoring part of the particulate matter flow adopts a micro-charge sensing device, the micro-charge sensing device comprises a probe, the probe is arranged on an airflow channel of the particulate matter conveying pipe when in use and generates and outputs a current signal when the particulate matter in the airflow channel passes through the probe, and the current signal is used as an input signal of a signal processing system; optionally, the probe is arranged on the airflow channel in a manner that the following conditions are met simultaneously: a) mounted on the outside of the inner wall surface of the tube shell forming the gas flow channel, b) not shielded by static electricity on the side facing the gas flow channel, and c) connected with the tube shell in an insulating way; optionally, the probe comprises a first structure formed by an inductor extending along the circumferential direction of the airflow channel, and the first structure is a complete annular body or a non-complete annular body; optionally, the probe is installed in the tube shell through an insulating sheath, the insulating sheath forms a probe installation area matched with the shape of the probe, the probe is wrapped in the probe installation area, and the insulating sheath can be made of rubber, preferably polytetrafluoroethylene; optionally, the insulating sheath is a prefabricated annular member, an annular concave groove serving as the probe mounting region and adapted to the first structure is formed in an inner wall of the prefabricated annular member, and the first structure is placed in the annular concave groove; optionally, the micro-charge sensing device includes a prefabricated particulate matter sensing component, the prefabricated particulate matter sensing component includes the probe and the tube shell assembled together, and two ends of the tube shell are respectively provided with a pipeline butt joint structure for placing the prefabricated sensing component on an airflow conveying pipeline to become a part of the airflow conveying pipeline; the pipeline butt joint structure preferably adopts a flange plate; optionally, the tube shells include a base layer formed by axially butting a first tube shell and a second tube shell, a splicing groove formed by axially butting the first tube shell and the second tube shell is formed in the base layer, and the probe is installed in the splicing groove; optionally, the end surface of the first tube shell, which is used for being in butt joint with the second tube shell, comprises a first tube shell outer edge end surface and a first tube shell inner edge end surface, the end surface of the second tube shell, which is used for being in butt joint with the first tube shell, comprises a second tube shell outer edge end surface and a second tube shell inner edge end surface, and after the first tube shell and the second tube shell are in axial butt joint, the first tube shell outer edge end surface is in mutual contact with the second tube shell outer edge end surface, and the first tube shell inner edge end surface is separated from the second tube shell inner edge end surface to form the splicing groove; optionally, the outer edge end face of the first tube shell is welded with the outer edge end face of the second tube shell; optionally, the splicing groove is adapted to the prefabricated ring member, and the prefabricated ring member is placed in the splicing groove; optionally, a non-electrostatic shielding material layer is mounted on the inner wall surface of the base layer; optionally, the signal processing system obtains information for characterizing the flow rate of the particulate matter by processing the input signal; optionally, the signal processing system adopts a transmitter converter means of a micro-charge sensing device of the TRIBO series of the Auburn systems company of the austen system; optionally, the particulate matter recoverer is an industrial kiln or a particulate matter storage; optionally, the particulate matter recoverer is a blast furnace, and the particulate matter is fly ash; optionally, the pneumatic particulate conveying system is used for conveying positive/negative electrode materials of the battery.
6. The utility model provides a particulate matter air conveying check out test set which characterized in that: the system is used for detecting the operation condition of the pneumatic particulate matter conveying system;
the pneumatic particulate matter conveying system comprises a particulate matter fluidizer, a particulate matter conveying pipe and a particulate matter recoverer;
the particle fluidizer is used for fluidizing particles to be conveyed by using fluidizing gas so as to generate and output a gas-particle mixed flow;
the particle conveying pipe is used for conveying the gas-particle mixed flow output from the particle fluidizer along a set route;
the particle recoverer is used for receiving the gas-particle mixed flow transmitted from the particle conveying pipe and discharging gas brought by the gas-particle mixed flow from an exhaust channel of the particle conveying pipe;
the method specifically comprises the following steps:
the particle flow dynamic monitoring component is arranged on the particle conveying pipe and is used for acquiring particle flow dynamic information in the particle conveying pipe;
and the signal processing component is in communication connection with the dynamic particulate matter flow monitoring component and is used for processing the dynamic particulate matter flow information so as to obtain a detection result of the running condition.
7. The pneumatic conveying and detecting equipment for particulate matter according to claim 6, characterized in that: the dynamic particulate matter flow monitoring part is arranged on the particulate matter conveying pipe and close to the particulate matter recoverer; and/or the dynamic monitoring part of the particulate matter flow adopts a micro-charge sensing device, the micro-charge sensing device comprises a probe, the probe is arranged on an airflow channel of the particulate matter conveying pipe when in use and generates and outputs a current signal when the particulate matter in the airflow channel passes through the probe, and the current signal is used as an input signal of a signal processing system; optionally, the probe is arranged on the airflow channel in a manner that the following conditions are met simultaneously: a) mounted on the outside of the inner wall surface of the tube shell forming the gas flow channel, b) not shielded by static electricity on the side facing the gas flow channel, and c) connected with the tube shell in an insulating way; optionally, the probe comprises a first structure formed by an inductor extending along the circumferential direction of the airflow channel, and the first structure is a complete annular body or a non-complete annular body; optionally, the probe is installed in the tube shell through an insulating sheath, the insulating sheath forms a probe installation area matched with the shape of the probe, the probe is wrapped in the probe installation area, and the insulating sheath can be made of rubber, preferably polytetrafluoroethylene; optionally, the insulating sheath is a prefabricated annular member, an annular concave groove serving as the probe mounting region and adapted to the first structure is formed in an inner wall of the prefabricated annular member, and the first structure is placed in the annular concave groove; optionally, the micro-charge sensing device includes a prefabricated particulate matter sensing component, the prefabricated particulate matter sensing component includes the probe and the tube shell assembled together, and two ends of the tube shell are respectively provided with a pipeline butt joint structure for placing the prefabricated sensing component on an airflow conveying pipeline to become a part of the airflow conveying pipeline; the pipeline butt joint structure preferably adopts a flange plate; optionally, the tube shells include a base layer formed by axially butting a first tube shell and a second tube shell, a splicing groove formed by axially butting the first tube shell and the second tube shell is formed in the base layer, and the probe is installed in the splicing groove; optionally, the end surface of the first tube shell, which is used for being in butt joint with the second tube shell, comprises a first tube shell outer edge end surface and a first tube shell inner edge end surface, the end surface of the second tube shell, which is used for being in butt joint with the first tube shell, comprises a second tube shell outer edge end surface and a second tube shell inner edge end surface, and after the first tube shell and the second tube shell are in axial butt joint, the first tube shell outer edge end surface is in mutual contact with the second tube shell outer edge end surface, and the first tube shell inner edge end surface is separated from the second tube shell inner edge end surface to form the splicing groove; optionally, the outer edge end face of the first tube shell is welded with the outer edge end face of the second tube shell; optionally, the splicing groove is adapted to the prefabricated ring member, and the prefabricated ring member is placed in the splicing groove; optionally, a non-electrostatic shielding material layer is mounted on the inner wall surface of the base layer; optionally, the signal processing system obtains information for characterizing the flow rate of the particulate matter by processing the input signal; optionally, the signal processing system adopts a transmitter converter means of a micro-charge sensing device of the TRIBO series of the Auburn systems company of the austen system; optionally, the particulate matter recoverer is an industrial kiln or a particulate matter storage; optionally, the particulate matter recoverer is a blast furnace, and the particulate matter is fly ash; optionally, the pneumatic particulate conveying system is used for conveying positive/negative electrode materials of the battery.
8. The pneumatic conveying and detecting equipment for particulate matters according to claim 6 or 7, characterized in that: the signal processing component comprises a PLC (programmable logic controller) and an upper computer, and the PLC is respectively in communication connection with the dynamic particulate matter flow monitoring component and the upper computer; or, the signal processing part comprises a PLC controller, and the PLC controller is respectively in communication connection with the particulate matter flow dynamic monitoring part.
9. The pneumatic conveying and detecting equipment for particulate matter according to claim 8, characterized in that: the PLC is also in communication connection with related instruments in the pneumatic conveying system of the particulate matters, and the related instruments are used for acquiring basic operation state information of the pneumatic conveying system of the particulate matters and/or serving as control objects of the PLC.
10. The pneumatic conveying and detecting equipment for particulate matter according to claim 8, characterized in that: the upper computer and/or the PLC controller comprises a processor, a memory and an output device, wherein a computer program or an instruction is stored in the memory, and the computer program or the instruction can be executed by the processor to display the change situation of the particulate matter flow reflected by the dynamic information of the particulate matter flow along with time and/or analyze the change situation of the particulate matter flow reflected by the dynamic information of the particulate matter flow along with time on the output device.
CN202111666469.5A 2021-12-31 2021-12-31 Pneumatic conveying detection method and detection equipment for particulate matters Pending CN114408588A (en)

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