CN113883869B - Drying device - Google Patents

Abstract

The invention relates to a drying device, which comprises a main body module, wherein a drying main body unit of the main body module comprises a transmission assembly and a heating unit, the heating unit is provided with an air inlet mechanism and an air outlet mechanism to dry a solvent contained in a target product, a sensing unit can acquire physical and chemical parameters of different parts of the drying main body unit, an auxiliary module can respectively establish an automatic evolution model which can be changed at least based on time variation and/or position variation through a graphic processing unit and/or a module processing unit, the establishment of the automatic evolution model is based on the physical and chemical parameters of the drying main body unit acquired by the sensing unit, wherein the auxiliary module can at least perform the data analysis according to different variation conditions of the position variation of an actual moving part in the drying main body unit acquired by the sensing unit in the operation process, and adjusting the virtual moving part corresponding to the actual moving part in the established automatic evolution model in a visual mode.

Description

Drying device

Technical Field

The invention relates to the technical field of drying equipment, in particular to a drying device.

Background

The drying device is industrial equipment which is heated by utilizing ambient air through power generated by electric power, diesel power, wind power, inflammable materials and the like, is conveyed to the periphery and further achieves proper temperature for dehumidification treatment. The drying device vaporizes and escapes moisture (generally, moisture or other volatile liquid components) in the material through heating so as to obtain solid material with specified moisture content, thereby meeting the requirement of material use or further processing.

For example, CN102744189A discloses a special drying device for coating, which is used for transferring and drying a coated substrate, and includes a box and a press roll assembly disposed in the box, the press roll assembly is correspondingly disposed on two sides of the box, the press roll assembly includes an upper press roll and a lower press roll disposed vertically, the upper press roll and the lower press roll are driven by a power device to rotate, a gap for clamping a blank portion on a side of the substrate is disposed between the upper press roll and the lower press roll, and the blank portion with a certain width on the edge of the substrate is clamped by a transmission of a clamping roller type, so that the liquid slurry is prevented from flowing due to bending and drifting of the foil material to affect the uniformity of the thickness, a single-layer oven can dry both sides of the substrate, thereby saving energy consumption by more than 50%, saving the time for replacing the material, having a compact structure, and improving the operation efficiency of the device.

For example, CN111076531B discloses a control method of a drying device, a drying device and a controller, the control method of the drying device includes: acquiring environmental information of an environment where the drying device is located; determining a target air inlet speed required by the drying device according to the environmental information; and controlling the air inlet speed of an air inlet of the drying device to be the target air inlet speed. The control method of the invention determines the target air inlet speed required by the drying device according to the environmental information of the environment where the drying device is located, and realizes the real-time monitoring and adjustment of the indoor environment humidity by controlling the air inlet speed of the air inlet of the drying device.

In the technical scheme of the prior art, the temperature/humidity of the drying device is monitored in real time to realize the adjustment of the drying method and the drying mode, but on an industrial flow line for continuously performing the drying process, the drying device often needs a large span, a large number of sensors are arranged for monitoring the internal whole temperature/humidity, so that the production cost is increased, and the working conditions of all parts in the drying device, especially moving parts, cannot be grasped in time, so that the drying effect or even the whole production process can be influenced due to the failure or invalidation of the parts. Therefore, scientific and accurate monitoring of the operation state of the drying apparatus based on the technical innovation of the industrial manufacturing industry is required to realize the wide application of the drying apparatus in modern, digital and intelligent plants.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a drying device to solve the problems in the prior art.

The invention relates to a drying device which comprises a main body module, wherein a drying main body unit of the main body module comprises a conveying assembly used for conveying a target product along a preset conveying path, a heating unit used for drying the target product conveyed to a specific area by the conveying assembly, and an air inlet mechanism used for introducing air into a drying box and an air outlet mechanism used for leading out air from the drying box are configured on the heating unit so as to dry a solvent contained in the target product. The drying main body unit can input external air into the drying box at least through the first air inlet mechanism and/or the second air inlet mechanism, and the drying main body unit can output internal air out of the drying box at least through the first air exhaust mechanism and/or the second air exhaust mechanism.

The induction unit can collect the physicochemical parameters of corresponding positions from different parts of the drying main body unit, and the physicochemical parameters are respectively established by the auxiliary module through the graphic processing unit and/or the module processing unit into an automatic evolution model which can be changed at least based on time variation and/or position variation. The auxiliary module can adjust the virtual moving part corresponding to the actual moving part in the established automatic evolution model in a visual mode at least based on the change condition of the position variation data of the actual moving part in the drying main body unit acquired by the sensing unit in the operation process. The auxiliary module can visually display the change condition in real time in a rendering mode based on the physicochemical parameters of different parts of the drying main body unit collected by the sensing unit.

The technical scheme has the advantages that: the drying main body unit of the drying device is provided with a drying box used for providing a drying place, and the drying box realizes the exchange of gas and heat with the outside through the linkage of the air inlet mechanism and the air outlet mechanism. The auxiliary module can be used for rendering based on the physical and chemical parameters collected by the sensing unit, so that the distribution forms of the physical and chemical parameters such as gas and temperature in the drying box can be displayed in different colors and/or different shades, and the rendered colors can be adjusted in real time based on the change of time variation and/or position variation, so that the internal distribution condition of the drying main body unit can be visually monitored in real time in a differentiated rendering mode;

the drying device at least comprises a main body module and an auxiliary module, the auxiliary module can establish a plane technical model and/or a three-dimensional technical model based on physical and chemical parameters acquired by the sensing unit in the main body module to different parts of the drying main body unit, and a user can directly and quickly acquire the operating state of the drying main body unit in a visual mode through the established automatic evolution model. The sensing unit can at least monitor the actual moving part in the drying main body unit, so that the virtual moving part corresponding to the actual moving part in the established automatic evolution model through the auxiliary module can visually display the moving condition of the actual moving part in the moving process of the drying main body unit, thereby realizing the real-time display of the flow field condition in the drying main body unit and/or the moving condition of the actual moving part, and the drying device is a real drying device based on process production, real-time and multidimensional.

The auxiliary module can perform classification based on different time variation of the received physical and chemical parameters. Preferably, the auxiliary module can be configured as one or more combinations of the first auxiliary module, the second auxiliary module and the third auxiliary module to process data in the first physicochemical parameter database, the second physicochemical parameter database and/or the third physicochemical parameter database respectively.

The auxiliary module can receive real-time physicochemical parameters of the drying main body unit collected by the sensing unit through the control module, and visually display the established plane technology model and/or three-dimensional technology model based on time variation and/or position variation through the tail end.

The historical record, the current record and the prediction record can be respectively stored by a first physical and chemical parameter database, a second physical and chemical parameter database and a third physical and chemical parameter database in an overlapping or replacing mode. The assistance module can view historical, current, and/or predicted records based on the amount of time change and/or the amount of location change.

The automatic evolution model constructed by the auxiliary module can be mapped to the drying main body unit in a one-to-one corresponding mode, and a mapping relation can be established between the plane technology model and the three-dimensional technology model in the automatic evolution model. Based on the components in any one automatic evolution model, it is possible to position to the components in the respective other automatic evolution model and/or to dry the components in the main body unit.

The technical scheme has the advantages that: each part in the drying main body unit is provided with different unique codes, and the individual unique codes can be correspondingly arranged based on the sensors of the sensing units required to be arranged by different parts, so that the auxiliary module can construct a mapping relation with the drying main body unit based on the plane technical model and the three-dimensional technical model established by the drying main body unit, and the mapping relation can also be constructed between the plane technical model and the three-dimensional technical model, so that any part can be positioned in different modules in a one-to-one mapping mode. Further, the sensors may also be provided with corresponding individual unique codes, so that each site and its corresponding sensor can be grouped in a table to be located to the corresponding component and/or sensor by means of a look-up table.

The technical scheme has the advantages that: the auxiliary module can be configured as a first auxiliary module and is used for processing historical records in a first physical and chemical parameter database; and the second auxiliary module is used for processing the current record in the second performance database and the third auxiliary module is used for processing the prediction record in the third performance database, so that the operation processes of the drying main body unit at different time variation and/or position variation can be visually checked based on the auxiliary modules of different types, and the historical working state, the current working condition and/or the future working plan of the drying main body unit can be obtained by adjusting the time variation and/or the position variation, wherein the auxiliary modules can establish a plane technology model and/or a three-dimensional technology model based on the drying main body unit, so that a user can more quickly and intuitively master the performance and/or the state of the drying main body unit through various display ways.

The control module can drive the auxiliary module to adjust the corresponding virtual moving part in a visual mode based on the change situation of the position change data of the actual moving part based on the time change in the operation process, which is acquired by the sensing unit arranged at the position corresponding to the actual moving part of the drying main unit, wherein the main unit at least comprises a transmission assembly, a blowing device and/or a valve assembly.

The technical scheme has the advantages that: the sensing unit can all correspond to all actual motion parts that probably set up in the stoving main part unit and be provided with corresponding sensor, wherein, be provided with the attitude sensor that can monitor actual motion part position variation data at least, change the condition based on time variation with the actual motion part of monitoring through attitude sensor, thereby make the auxiliary module can make corresponding virtual motion part carry out synchronous motion in the automatic evolution model that establishes based on the removal of actual motion part, in order to realize the visual show of actual motion part, and make the user can obtain the removal process of actual motion part based on using the terminal removal of observing virtual motion part, thereby avoid actual motion part probably to appear blocking in the removal process, slide, not hard up the condition such as becoming flexible.

The command module is able to adjust the operating state and/or setting parameters of the body module based on the control signal carrying the initial conditions confirmed by the user. The main body module can respond to a control signal of the dominating module carrying an initial condition confirmed by the user, and starts to operate based on the initial condition after completing the adaptation.

The dominance module can drive the first auxiliary module, the second auxiliary module and/or the third auxiliary module to perform corresponding model building based on different control signals using the tail end. The third auxiliary module can complete the establishment of a third physical and chemical parameter database in a preset time variation and/or position variation range based on the control signal carrying the initial condition. Preferably, the user can repeatedly adjust the setting condition of the initial condition according to the predicted record in the predetermined time variation and/or the position variation range in the third physical and chemical parameter database established based on the control signal carrying the initial condition until the confirmation is carried out.

The first auxiliary module can be driven by the dominating module at least when the performance of the drying main body unit is reduced or fails, a historical record is called from the first physical and chemical parameter database, and fault tracing is further carried out based on the variation range of time variation and/or position variation.

The real-time physicochemical parameters of the drying main body unit sent by the control module can be responded by the second physicochemical parameter database, and then the second physicochemical parameter database enables the automatic evolution model of the second auxiliary module to complete the replacement of the image based on the replacement of the data in a mode of replacing the physicochemical parameters at the previous time or the previous position.

The physicochemical parameters of the previous time or the previous position, which are replaced in the second physicochemical parameter database, can be sent to the first physicochemical parameter database by the domination module to complete data accumulation, so that an automatic evolution model established by the first auxiliary module based on the historical records in the first performance database can be checked based on the adjustment of time variation and/or position variation.

The technical scheme has the advantages that: the user can send different control signals to the domination module by using the tail end, so that the domination module can drive the third auxiliary module to perform simulation calculation based on unconfirmed initial conditions to obtain a prediction record for establishing the third physical and chemical parameter database, and therefore the user can know the operation condition in the plan of the drying main body unit in advance based on the prediction record in the third physical and chemical parameter database within the range of the preset time variation and/or the position variation and judge the reasonability of the initial condition setting. The user can adjust or confirm the initial condition by using the end so that the dominant module can drive the third auxiliary module to perform the analog calculation again based on the adjusted initial condition in response to the adjustment control signal or drive the main module to adjust and operate based on the confirmed initial condition in response to the confirmation control signal, thereby enabling the main module to start operating based on the appropriate initial condition. The drying main body unit in the running state can acquire real-time physicochemical parameters through the sensing unit, so that the second auxiliary module can complete real-time simulation based on the real-time physicochemical parameters, and the first auxiliary module can complete data superposition based on the physicochemical parameters of the previous moment and/or the previous position replaced by the second auxiliary module, so that a user can visually check the historical working state and/or the current working condition of the drying main body unit after the drying main body unit starts running based on the confirmed initial condition.

Drawings

FIG. 1 is a schematic structural diagram of a drying apparatus according to a preferred embodiment of the present invention;

FIG. 2 is a signal transmission diagram of a drying apparatus according to a preferred embodiment of the present invention;

FIG. 3 is a partial signal connection diagram of a drying apparatus according to a preferred embodiment of the present invention;

fig. 4 is a control flow diagram of a drying apparatus according to a preferred embodiment of the present invention.

List of reference numerals

100: main body module	110: drying main unit
		111: transmission assembly	113: drying cabinet
1131: transfer port	1132: delivery port
		114: first air inlet mechanism	1141: first air inlet
1142: first air-intake blower	1143: first heating member
		115: second air intake mechanism	1151: second intake airMouth piece
1152: second air-intake blower	1153: second heating member
		116: first exhaust mechanism	1161: first exhaust port
1162: first exhaust blower	117: second exhaust mechanism
		1171: second exhaust port	1172: second exhaust blower
118: valve assembly	130: induction unit
		200: auxiliary module	201: first auxiliary module
202: second auxiliary module	203: auxiliary module III
		210: graphics processing unit	220: modular processing unit
300: domination module	400: use the end
		410: visual unit	420: operating unit

Detailed Description

The following detailed description is made with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of a drying apparatus in a preferred embodiment, fig. 2 is a signal transmission diagram of a drying apparatus in a preferred embodiment, fig. 3 is a partial signal connection diagram of a drying apparatus in a preferred embodiment, and fig. 4 is a block diagram of a control flow of a drying apparatus in a preferred embodiment.

The invention discloses a drying device, which at least comprises a main body module 100 which is mutually associated, wherein the main body module 100 can establish signal connection with an auxiliary module 200 through a dominating module 300, the drying device also comprises the auxiliary module 200, and the auxiliary module 200 can establish signal connection with at least one using terminal 400, so that signal interaction of bidirectional circulation can be at least realized in the drying device.

According to a preferred embodiment, the auxiliary module 200 may include the graphic processing unit 210 and/or the module processing unit 220, the main body module 100 may include the drying main body unit 110 and the sensing unit 130, the auxiliary module 200 may be capable of establishing a corresponding planar technology model and/or a stereoscopic technology model in the corresponding graphic processing unit 210 and/or the module processing unit 220 based on the physicochemical parameters of the drying main body unit 110 in a certain time state and a certain space state, which are acquired by the sensing unit 130, under the signal transmission of the domination module 300, wherein the initial state of the drying main body unit 110 corresponding to the initialization model data may be set based on an initial time and/or an initial position, for example, the initial time and/or the initial position may be set based on a start time after the end of the pause process in the time state or a fixed position after the end of the migration process in the space state or a customized time and/or a customized space state Etc. to determine the initialization model data corresponding to the drying body unit 110 in the initial state. Further, the planar technology model and the stereoscopic technology model respectively established by the graphics processing unit 210 and the module processing unit 220 of the auxiliary module 200 can be output in a form of a combination of numbers and shapes and can be synchronously changed in real time based on the change of the time variation, so that the auxiliary module 200 can implement mapping at least on the drying main unit 110 in a multi-dimensional model, wherein a mapping relationship can be established between the planar technology model and the stereoscopic technology model, so that a user can locate to another automatic evolution model or the body of the drying main unit 110 based on one automatic evolution model. The plane technical model and/or the stereoscopic technical model established by the supplementary module 200 based on the initialized model data can be dynamically adjusted in response to the changes of physicochemical parameters of the drying body unit 110 in different time states and/or space states monitored by the sensing unit 130, and can be displayed on at least one of the use terminals 400 in an independent or parallel manner based on the needs of the corresponding user, so that the user can visually acquire the operation conditions of the drying body unit 110 through the corresponding use terminal 400, thereby determining the manner of adjustment of the drying body unit 110. Preferably, the usage tip 400 may be provided with a visual unit 410 for enabling at least display of the automatic evolution model and a manipulation unit 420 for outputting a control signal, so that after a user acquires visual data of the drying body unit 110 through the visual unit 410, the control signal may be transmitted to the control module using the manipulation unit 420 based on a relationship between the visual data and a set threshold value, so that the control module responding to the control signal may adjust a designated component within the drying body unit 110, wherein the usage tip 400 may be provided with a touch display screen integrating the visual unit 410 and the manipulation unit 420.

According to a preferred embodiment, the plurality of auxiliary module 200 establishment signals can be connected by any one of the body modules 100 through the governing module 300, so that the physicochemical parameters corresponding to the drying body unit 110 can be respectively sent by the governing module 300 to different auxiliary modules 200 based on different types of the physicochemical parameters to obtain the corresponding automatic evolution models. Preferably, the plurality of auxiliary modules 200 may be configured as an auxiliary module 201 based on a first physicochemical parameter database, an auxiliary module 202 based on a second physicochemical parameter database, and an auxiliary module 203 based on a third physicochemical parameter database according to physicochemical parameters corresponding to the drying main unit 110 in different time states, wherein the first physicochemical parameter database may be configured as a historical record collection of the drying main unit 110 obtained by the sensing unit 130 in a time period from a current time to any time corresponding to or earlier than the initial time, the second physicochemical parameter database may be configured as a current record collection of the drying main unit 110 obtained by the sensing unit 130 at the current time, and the third physicochemical parameter database may be configured as a prediction record collection of the drying main unit 110 obtained by the sensing unit 130 at the initial time after the initial physicochemical parameters of the drying main unit 110 at the initial time and preset initial input conditions are operated or obtained by the sensing unit 130, the physical and chemical parameters of the drying main unit 110 at the designated time and the input conditions at the designated time are calculated to obtain a prediction record set. Further, the first auxiliary module 201 can construct a first automatic evolution model for the drying main unit 110 in different time states and/or space states based on the first physicochemical parameter database, so that a user can visually check physicochemical parameter changes of the drying main unit 110 in a preset time period all around at all times by receiving the use terminal 400 with the first automatic evolution model, thereby facilitating history record checking and/or fault source tracing of the user; the second auxiliary module 202 can construct a second automatic evolution model for the drying main unit 110 of different time status and/or space status based on the second physicochemical parameter database, because the second physical and chemical parameter database can continuously generate the current record of the next time/position which can cover the data of the previous time/position along with the continuous transition of the current time, so that the second automatic evolution model exhibited using the tip 400 can be changed synchronously according to the real-time change of the drying body unit 110, thereby enabling the user to confirm the real-time status of the current drying body unit 110 operation in a non-free and flexible manner by using the tip 400, whether various components in the drying main unit 110 are adjusted or not and the degree of adjustment can be judged based on the relation between the real-time physicochemical parameters and the preset threshold value, so that the drying main unit 110 can be always in a normal operation state; the third auxiliary module 203 can construct a third automatic evolution model for the drying main body unit 110 in different time states and/or space states by using the third physical and chemical parameter database, and since the third physical and chemical parameter database is an expected prediction record obtained by the domination module 300 through iterative operation based on the initial physical and chemical parameters and the initial input conditions, the user can visually check the third automatic evolution model at the use end 400 to obtain the change condition of the physical and chemical parameters of the drying main body unit 110 in the initial state within a period of time after the preset conditions are input, so that the user can timely adjust the initial input conditions or other conditions based on the difference between the simulation condition and the expected condition.

According to a preferred embodiment, the auxiliary module 200 is capable of responding to the physicochemical parameters collected from the drying main unit 110 sent by the sensing unit 130 to synchronously adjust and/or render the established automatic evolution model based on different types of the physicochemical parameters, wherein the auxiliary module 200 is capable of synchronously adjusting the virtual moving part corresponding to the actual moving part in the automatic evolution model based on at least the change of the position variation data of the actual moving part collected by the sensing unit 130 during the operation process, so that the virtual moving part can be visually displayed based on the motion state of the actual moving part in the drying main unit 110; the auxiliary module 200 can be displayed in a rendering manner on the visual automatic evolution model based on at least real-time physicochemical parameters such as temperature data, image data and/or flow data of different parts in the drying main unit 110 collected by the sensing unit. Preferably, the auxiliary module 200 is at least capable of synchronous adjustment and/or rendering by the module processing unit 220. Further, the visualization presentation by the auxiliary module 200 based on the synchronous adjustment and/or rendering can be implemented by using the visual unit 410 of the terminal 400, wherein the visualization automatic evolution model presented by the visual unit 410 is a two-dimensional model image and/or a three-dimensional model image which is subjected to model weight reduction processing before being received, so as to reduce the workload of using the terminal 400, and improve the display speed of the visual unit 410 on at least the three-dimensional model image, thereby improving the working efficiency. According to a preferred embodiment, in the case that the drying main unit 110 is in the initial state, the initial physicochemical parameters of the drying main unit 110 are acquired by the sensing unit 130 to be provided as the initial model data to the auxiliary module 200 for automatic evolution model establishment, wherein the auxiliary module No. one 201, the auxiliary module No. two 202 and/or the auxiliary module No. three 203 can respectively establish corresponding initial automatic evolution models in a two-dimensional virtual modeling manner and/or a three-dimensional virtual modeling manner based on the initial model data. Preferably, the first auxiliary module 201, the second auxiliary module 202 and the third auxiliary module 203 are each capable of establishing a corresponding initial automatic evolution model in a two-dimensional virtual modeling manner and a three-dimensional virtual modeling manner, respectively, so that the related information of the drying main unit 110 can be more comprehensively acquired using the tip 400. The logic process when the drying body unit 110 is in the initial state may be configured to:

s1, the sensing unit 130 sends the various initial physicochemical parameters obtained based on the monitoring of the drying main unit 110 in the initial state to the control module;

s2, the control module can respectively send the received initial physicochemical parameters to the first auxiliary module 201, the second auxiliary module 202 and/or the third auxiliary module 203 based on the setting type of the auxiliary module 200;

s3, the first auxiliary module 201, the second auxiliary module 202 and/or the third auxiliary module 203 can use the initial physicochemical parameters as the initial model data to build a two-dimensional and/or three-dimensional automatic evolution model, and visually display the model to the user using the terminal 400.

Further, before the drying main unit 110 is started, a user may utilize the manipulating unit 420 of the using terminal 400 to transmit a preset initial input condition to the dominating module 300 in the form of an input signal, so that the dominating module 300 can extract control information carried by the input signal and then transmit a control signal to the main module 100 and the auxiliary module 200 in a preset logic process to respond to the input signal sent by the user, wherein the logic process before the drying main unit 110 is started may be configured to:

s4, the dominating module 300 responding to the input signal transmitted by the using terminal 400 and outputting different control signals based on the type of information carried by the input signal;

s5, when the third auxiliary module 203 is arranged, the control signal with the initial input condition can be sent to the third auxiliary module 203 by the domination module 300, so that the third auxiliary module 203 can obtain the simulation physicochemical parameters within an expected period of time through iterative operation processing based on the initial automatic evolution model established by the initial physicochemical parameters and the control information with the initial input condition;

s6, the third auxiliary module 203 may be displayed at the use terminal 400 in a visual automatic evolution model manner based on the acquired simulation physicochemical parameters, and synchronously feed back the relationship between the difference between the simulation physicochemical parameters and the expected physicochemical parameters and the preset threshold to the use terminal 400, so that the user may judge the rationality of the initial input condition setting according to the feedback information of the third auxiliary module 203, and may transmit the input signal of the change information or the confirmation information to the domination module 300;

s7, when the domination module 300 receives the input signal carrying the modification information, the third auxiliary module 203 can be driven by the steps S5 and S6 based on the modified input condition, until the domination module 300 receives the input signal carrying the confirmation information;

s8, based on the difference of the setting conditions of the third auxiliary module 203, the control module 300 can send a control instruction to the corresponding components at least included in the drying main unit 110 when receiving an input signal carrying confirmation information or an input signal carrying initial input conditions, so that the corresponding components respond to the control instruction to set and start the drying main unit 110 in a manner of meeting the initial input conditions.

Further, during the operation of the drying main unit 110, the sensing unit 130 captures the variation of the physicochemical parameters of the drying main unit 110 in different time states and/or space states and sends the variation to the corresponding auxiliary module 200 through the dominating module 300 based on the logic process, so that the corresponding auxiliary module 200 can perform synchronous mapping on the established automatic evolution model, thereby facilitating the user to visually acquire the operation conditions of the drying main unit 110 in different time states and/or space states by using the terminal 400. In the actual operation process of the drying main unit 110, an emergency such as an equipment failure or a change in operation conditions may occur, and a user can determine different emergency based on a feedback signal of the auxiliary module 200 to determine a regulation and control manner. Preferably, the domination module 300 can start an emergency state to bypass the simulation unit and directly send an alarm signal to the use terminal 400 in a signal connection manner with the use terminal 400 when the collected data transmitted by the sensing unit exceeds the limit threshold, so that the user can timely grasp the abnormal condition. The logic process of the drying main unit 110 during operation may be configured as follows:

s9, the physical and chemical parameters of the drying main unit 110 in each time state and/or space state can be monitored by the sensing unit 130, and the real-time physical and chemical parameters obtained by monitoring are sent to the second auxiliary module 202 through the domination module 300 by the sensing unit 130;

s10, the physical and chemical parameters of the next time/location can be received by the second auxiliary module 202 to cover the physical and chemical parameters of the previous time/location, so that the second auxiliary module 202 synchronously changes the corresponding automatic evolution model based on the change of the real-time physical and chemical parameters, wherein the covered physical and chemical parameters of the previous time/location can be sent to the first auxiliary module 201 through the domination module 300 to complete the storage and the stacking in the first auxiliary module 201;

s11, the user end can be used by the user to obtain the real-time synchronous automatic evolution model of the second auxiliary module 202, so that the user can master the real-time operation status of the drying main unit 110, and then determine the possible emergency of the drying main unit 110 based on the relationship between the difference between the real-time physicochemical parameter and the expected physicochemical parameter and the preset threshold;

s12, when the drying main unit 110 fails to work and the performance is reduced or even fails, the first auxiliary module 201 stores a plurality of automatic evolution models arranged based on a certain logic sequence in different time states and/or space states according to the first physicochemical parameter database as history information, and the models can be invoked by the user to obtain the physicochemical parameter change condition of the failed component in a period of time before the failure, so as to determine a suitable regulation and control manner;

s13, when the operation condition of the drying main unit 110 changes or even changes suddenly, the user can drive the third auxiliary module 203 to establish a temporary automatic evolution model based on the physicochemical parameters of the first auxiliary module 201 stored when the drying main unit 110 is in a steady operation state, and iterate the processing operation in a manner of adding to the changed operation condition, so as to obtain the operation condition of the drying main unit 110 within a period of time, thereby enabling the user to quickly understand the consequences caused by the change of the operation condition and determine a suitable regulation and control manner;

s14, when a corresponding regulation and control mode is made in response to an emergency situation of the drying main body unit 110, the third auxiliary module 203 can be used for carrying out iterative operation processing based on the adjusted physical and chemical parameters and operation conditions, judging the rationality of the regulation and control mode in a visual mode, and modifying the regulation and control mode until the rational regulation and control mode appears when the regulation and control mode is unreasonable;

s15, the drying main unit 110 is based on the original physicochemical parameters and operation conditions or the adjusted physicochemical parameters and operation conditions to realize the corresponding functions under normal working conditions.

According to a preferred embodiment, the user device is formed by a hand-held portable terminal with a visual terminal, the planar technical model output by the graphic processing unit and the stereoscopic technical model output by the module processing unit are displayed in succession on the user device in a time-sharing and alternative manner, wherein the selected and listed moving parts on the planar or stereoscopic technical model are displayed in a manner corresponding to at least one known appearance part of the body module 100. Because the air inlet mechanism channel of the main body module 100 has the characteristic of easy blockage, the filter screen and the shaft of the air inlet mechanism are often set to be detachable structures, and only by adopting a mode of displaying components related to faults on a plane and a three-dimensional model, a maintenance worker cannot accurately find the access channel and even can hardly understand the specific position of the access channel. And because the field maintenance personnel only have a very small display screen, the plane or three-dimensional technical model can only be enlarged in display area by selecting a display mode in a time-sharing mode, and the maintenance personnel cannot be assisted to accurately find the channel which enters the blockage. Therefore, the present invention provides that the third auxiliary module disposed on the moving component inside the main module 100 can store the components forming the dependency relationship with the disassembly thereof in an associated manner, so that the moving component displayed alternatively on the main module 300 in a time-sharing manner will also display the structural components related thereto in an associated manner, in particular at least one component forming the dependency relationship with the disassembly thereof observable on the outer surface. For example, the internal filter device located inside the intake mechanism is stored in association with its filter frame and the filter screen by the number three auxiliary module as a second filter kit, which is located inside the region where the surface is not visible, unlike the external filter element located in the outer region of the intake mechanism, but is in an upstream-downstream relationship with the first filter kit, which is constituted by the external filter kit located in the outer region of the intake mechanism. When the internal filter element is blocked and not normally ventilated, the auxiliary module No. three judges that the internal filter element is in an abnormal operating state based on a blocking signal given by a steep increase in the motor current, and at this time, the moving part (the internal filter element, i.e., the first filter kit) on the user device 301 is highlighted (for example, red) in a time-sharing manner, wherein displaying the first filter kit as red on the user device 301 in a kit manner sometimes does not allow the maintenance personnel to understand the problem that the user is facing, particularly the position of the object that needs to be cleared. To this end, the invention provides that the selected moving part (the part or kit to be debugged) on the planar or stereoscopic technical model is displayed in a manner corresponding to at least one known external part of the body module 100, which external part is located externally of the body module 100 in a macroscopic manner, wherein preferably said external part is constituted by parts located in at least two positions of the body module 100 "diametrically opposite" the selected moving part, so that, when the moving part displayed on the governing module 300 is selected in a time-sharing manner, the governing module 300 will poll at least two stereoscopic technical models different from each other in a time-sharing manner, including not only the selected moving part, at least one part in dependency relationship with its disassembly, but also at least one external part located externally of the body module 100 in a macroscopic manner, the three-dimensional technical model is thus an image of at least two viewing angles that differ from each other, thereby facilitating the maintenance personnel to find out exactly the faulty component, kit and jointly determine its disassembly path and approach from the displayed planar technical model.

According to a preferred embodiment, the sensing unit 130 is provided with a plurality of sensors capable of monitoring different physicochemical parameters at corresponding positions based on the structure of the drying body unit 110, for example, a temperature sensor for monitoring the temperature inside the drying body unit 110, an image sensor for capturing an image of the drying body unit 110, a flow sensor for monitoring the gas flow rate of the drying body unit 110, and the like may be provided. Further, a temperature sensor may be installed at least between the exhaust port and the exhaust blower to collect the temperature of the mixture flowing through the exhaust mechanism, an image sensor may collect at least the target product image of the inlet 1131 and/or the outlet 1132 of the drying box 113, and a flow sensor may collect at least the flow rate of the blower. Preferably, the sensing unit 130 can also perform dynamic monitoring based on actual moving parts in the drying body unit 110, wherein the sensing unit 130 can dynamically capture at least the operation process of the blower device including the first intake blower 1142, the second intake blower 1152, the first exhaust blower 1162 and/or the second exhaust blower 1172, so as to collect position variation data such as speed, frequency, direction and/or distance and the like in the operation process of an impeller or a piston or a screw or a slip sheet and other actual moving parts in the air blowing equipment at least through an attitude sensor, based on the combination of the position variation data and the flow data collected by the flow sensor, the image data collected by the image sensor and/or the temperature data collected by the temperature sensor, the position variation data is sent to the auxiliary module 200, and the real-time working state of the air blowing equipment can be displayed in a visual mode; the sensing unit 130 can capture the dynamic state of the valve assembly 118 during operation, so as to at least use the attitude sensor to capture the position variation data such as the rotating speed, the rotating angle, the direction and/or the position of different closure member collectors corresponding to different types of valve assemblies 118 such as a stop valve, a plug valve, a ball valve or a butterfly valve during operation, and send the position variation data to the auxiliary module 200 based on the combination of the position variation data and the flow data collected by the flow sensor, the image data collected by the image sensor and/or the temperature data collected by the temperature sensor, and the real-time working state of the valve assembly 118 can be displayed in a visual manner. Further, the sensing unit 130 may dynamically capture the conveying process of the conveying assembly 111 along the preset conveying path based on the target product, so as to collect position variation data such as the rotating direction and speed and/or the moving direction and speed of the conveying assembly 111 at least through the attitude sensor, so that the auxiliary module 200 can visually display the real-time working state of the conveying assembly 111.

According to a preferred embodiment, the drying body unit 110 for removing the solvent remaining solid content from the target product in the body module 100 may include a transmission assembly 111 and a heat generating unit, wherein the heat generating unit includes at least a drying box having an inlet 1131 and an outlet 1132, so that the preset conveying path of the transmission assembly 111 can penetrate through the drying box 113 through the inlet 1131 and the outlet 1132 at least partially. Preferably, the conveying assembly 111 may convey the target product by being configured as a conveyor belt or a conveying roller way, etc., so that the target product can move based on a preset conveying path of the conveying assembly 111 and can pass through the drying box 113 for a period of time to complete the drying process. Further, the drying box 113 may be configured such that the position variation parameter is not changed with the change of the time variation, so that the target product moving along the preset conveying path based on the driving of the conveying assembly 111 can complete the relative motion with the fixed drying box 113, wherein the target product can be continuously carried on the conveying assembly 111 in batches, and sequentially passes through the drying box 113 in the direction from the incoming opening 1131 to the outgoing opening 1132 with the increase of the time variation parameter, so as to achieve the continuous proceeding of the target product drying process. Preferably, the heat generating unit is configured with a plurality of air inlet mechanisms and/or air outlet mechanisms arranged along the extension direction of the preset conveying path of the conveying assembly 111 to dry the target product entering the drying box 113, wherein the number of the air inlet mechanisms for providing air into the drying box 113 and/or the air outlet mechanisms for leading out the air in the drying box 113 is determined based on the influence factors such as the drying requirement, the overall structure and/or the physical and chemical properties of the target product. The air inlet mechanism is provided with a plurality of air inlets communicated with the air inlet blower in the drying box 113, so that the output air of the air inlet blower can be blown to the surface of the target product from the corresponding air inlets through the temperature rise of the heating element, and the heated air is provided for the target product through the air inlets arranged at different positions in the drying box 113 under different time variation parameters and/or position variation parameters, so that the vaporization of the solvent contained in the target product is realized. The exhaust mechanism is provided with a plurality of exhaust ports communicated with the exhaust blower in the drying oven 113, so that the mixed gas containing the vaporized solvent vapor in the drying oven 113 can be led out under the entrainment action of the exhaust blower, thereby realizing the circulation of the gas in the drying oven 113 and the completion of the drying process. Further, the air intake mechanism may be respectively provided with a first air intake mechanism 114 and a second air intake mechanism 115 at two opposite sides based on the conveying direction of the target product, wherein the first air intake mechanism 114 and the second air intake mechanism 115 may be provided with the same or different numbers of air inlets based on different drying air intake requirements, for example, when two opposite sides of the target product have different drying air intake requirements, the number of second air inlets 1151 provided at the side with the relatively lower drying air intake requirement may be less than the number of first air inlets 1141 to reduce the installation cost, or the number of second air inlets 1151 provided at the side with the relatively lower drying air intake requirement may be adjusted and controlled by the valve assembly 118 in a manner that at least part of the second air inlets 1151 is connected to the valve assembly 118, so as to improve the air intake efficiency while saving the operation cost; the exhaust mechanism may be respectively provided with the first exhaust mechanism 116 and the second exhaust mechanism 117 at opposite sides based on the conveying direction of the target product, wherein the first exhaust mechanism 116 and the second exhaust mechanism 117 may be provided with the same or different numbers of exhaust ports based on different drying requirements, for example, when the opposite sides of the target product have different drying exhaust requirements, the number of the second exhaust ports 1171 provided at a side with a relatively lower drying exhaust requirement may be less than the number of the first exhaust ports 1161 to reduce the purchase and installation costs, or the number of the second exhaust ports 1171 opened relative to the first exhaust ports 1161 may be adjusted by the valve assembly 118 in such a manner that at least part of the second exhaust ports 1171 provided at the side with a relatively lower drying exhaust requirement is connected to the valve assembly 118, thereby improving the exhaust efficiency while saving the operation costs. Preferably, the second exhaust outlet 1171 may be provided only upstream and/or downstream of the second inlet 1151 along the predetermined transport path of the transfer assembly 111 within the dry box 113, so that the second exhaust assembly can draw only the mixed gas in the vicinity of the inlet 1131 and/or the outlet 1132. The first heating member 1143 installed at the first air inlet blower 1142 and the first air inlet 1141 and the second heating member 1153 installed at the second air inlet blower 1152 and the second air inlet 1151 may heat the introduced external air to different degrees based on different drying requirements to blow the heating gas reaching a preset temperature to the target product at the corresponding air inlet, thereby achieving vaporization of the solvent by means of the heating gas exceeding the corresponding boiling point of the solvent contained in the target product.

It should be noted that the above-mentioned embodiments are exemplary, and that those skilled in the art, having benefit of the present disclosure, may devise various arrangements that are within the scope of the present disclosure and that fall within the scope of the invention. It should be understood by those skilled in the art that the present specification and figures are illustrative only and are not limiting upon the claims. The scope of the invention is defined by the claims and their equivalents.

Claims (10)

1. A drying apparatus, comprising:

a main body module (100), wherein the drying main body unit (110) of the main body module (100) comprises a conveying assembly (111) for conveying a target product along a preset conveying path, a heating unit for drying the target product conveyed by the conveying assembly (111) to a specific area, the heating unit comprises an air inlet mechanism for introducing air into a drying box (113) and an air outlet mechanism for leading air out of the drying box (113) so as to dry a solvent contained in the target product, the main body module (100) further comprises an induction unit (130) capable of acquiring physical and chemical parameters of different parts of the drying main body unit (110), and the main body module is characterized in that,

the auxiliary module (200) can respectively establish an automatic evolution model based on time variation and/or position variation at least through a graphic processing unit (210) and/or a module processing unit (230), the modeling process is based on physicochemical parameters collected by the sensing unit (130) for different parts of the drying main unit (110),

wherein the auxiliary module (200) can at least adjust the virtual moving parts corresponding to the actual moving parts in the established automatic evolution model in a visual manner, the adjusting process is based on the change situation of the position change quantity data of the actual moving parts in the drying main unit (110) collected by the sensing unit (130) during the operation process,

the auxiliary module (200) can visually display the variation in real time in a rendering manner, and the display process is based on physicochemical parameters of different parts of the drying main unit (110) collected by the sensing unit (130);

the control signal with the initial input condition can be sent to the third auxiliary module (203) by the dominating module (300), so that the third auxiliary module (203) can obtain the simulated physicochemical parameters in an expected period of time through iterative operation processing based on an initial automatic evolution model established by the initial physicochemical parameters and the control information with the initial input condition;

the third auxiliary module (203) of the auxiliary module (200) can be displayed at a use terminal (400) in a visual automatic evolution model mode based on the acquired simulation physical and chemical parameters, the relation between the difference value between the simulation physical and chemical parameters and the expected physical and chemical parameters and a preset threshold value is synchronously fed back to the use terminal (400), and after rationality judgment of initial input condition setting, an input signal for changing information or confirming information can be transmitted to a domination module (300);

when the domination module (300) receives an input signal carrying change information, the third auxiliary module (203) can be used for repeatedly finishing the judgment process of the change information or the confirmation information based on the changed input condition until the domination module (300) receives the input signal carrying the confirmation information;

based on the difference of the setting conditions of the third auxiliary module (203), the control module (300) can send a regulation and control instruction to corresponding components at least comprising the drying main body unit (110) when receiving an input signal carrying confirmation information or an input signal carrying initial input conditions, so that the corresponding components respond to the regulation and control instruction to set and start the drying main body unit (110) in a manner of meeting the initial input conditions;

when the operation condition of the drying main body unit (110) changes or even changes suddenly, a user can drive the third auxiliary module (203) to establish a temporary automatic evolution model based on physicochemical parameters, stored by the first auxiliary module (201), of the drying main body unit (110) in a stable operation state, and iterate processing operation in a mode of being attached to the changed operation condition to obtain the operation condition of the drying main body unit (110) within a period of time, so that the user can quickly know the consequences caused by the change of the operation condition and determine a proper regulation and control mode;

the user can acquire the moving process of the actual moving part based on observing the movement of the virtual moving part using the tip (400).

2. The drying apparatus of claim 1, wherein a command module (300) is used by the auxiliary module (200) to receive the real-time physicochemical parameters of the drying body unit (110) collected by the sensing unit (130), and the established planar and/or stereoscopic models that can be changed based on time and/or position variation are visually displayed at the use terminal (400) by the auxiliary module (200).

3. The drying apparatus according to claim 2, wherein the dominating module (300) is capable of driving the auxiliary module (200) to adjust the corresponding virtual moving component in a visual manner based on a change of position change data based on a time change during operation of the actual moving component acquired by a sensing unit (130) provided at a position corresponding to the actual moving component of the main body module (100) including at least the transport assembly (111), the blower device and/or the valve assembly (118) within the drying main body unit (110).

4. The drying apparatus according to claim 3, wherein the drying main unit (110) can input external air into the drying cabinet (113) at least through a first air intake mechanism (114) and/or a second air intake mechanism (115), and the drying main unit (110) can output internal air out of the drying cabinet (113) at least through a first air exhaust mechanism (116) and/or a second air exhaust mechanism (117).

5. The drying apparatus according to claim 4, wherein the automatic evolution model constructed by the auxiliary module (200) is mappable to the drying body unit (110), and the planar technology model and the stereoscopic technology model in the automatic evolution model are mappable to each other, wherein components based on any one of the automatic evolution models are locatable to components in the respective other automatic evolution model and/or components in the drying body unit (110).

6. The drying apparatus according to claim 5, wherein the dominating module (300) is capable of driving a number one auxiliary module (201), a number two auxiliary module (202) and/or a number three auxiliary module (203) for model building, the model building process is based on different control signals of the use terminal (400) to correspond to the model, the number three auxiliary module (203) is capable of completing the building of a number three physicochemical parameter database within a predetermined time variation and/or position variation range, the model building process is based on the control signals carrying initial conditions.

7. The drying apparatus according to claim 6, wherein said dominating module (300) is capable of performing fault tracing based on a variation range of a time variation and/or a position variation at least in a manner of driving said first auxiliary module (201) to retrieve a history from a first physicochemical parameter database when said drying main unit (110) is degraded or failed.

8. Drying apparatus according to claim 7, characterized in that said command module (300) is able to make adjustments to the operating conditions and/or setting parameters of said body module (100), said adjustments being based on said control signal carrying said initial conditions confirmed by the user.

9. Drying apparatus according to claim 8, characterised in that the auxiliary module (200) can be divided into auxiliary modules with different labels according to the time variation to which the received physicochemical parameter belongs, wherein the auxiliary module (200) can be configured as one or more combinations of auxiliary module number one (201), auxiliary module number two (202) and auxiliary module number three (203) to process the data in the physicochemical parameter database number one, second and/or third respectively.

10. Drying apparatus according to claim 9, wherein the physicochemical parameter database i, the physicochemical parameter database ii and the physicochemical parameter database iii are able to store a history, a current record and a prediction record in an overlapping or alternative manner, respectively, wherein the assistance module (200) is able to view the history, the current record and/or the prediction record based on a time variation and/or a location variation.

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