CN102536301B - Protective layer exploitation and gas pumping-exhaust management system and using method thereof - Google Patents
Protective layer exploitation and gas pumping-exhaust management system and using method thereof Download PDFInfo
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Abstract
The invention provides a protective layer exploitation and gas pumping-exhaust management system and a using method thereof. The protective layer exploitation and gas pumping-exhaust management system comprises a knowledge database, a receiving module and a processing module, wherein the knowledge database is used for storing construction schemes corresponding to various state parameters of a coal and gas co-exploitation working face; the receiving module is used for receiving the state parameters of the coal and gas co-exploitation working face; and the processing module is used for acquiring the construction schemes corresponding to the state parameters from the knowledge database. By adopting the technical scheme, certain guidance can be given to the outburst prevention operation in the coal and gas co-exploitation operation, the coal and gas co-exploitation aim is fulfilled, and the occurrence rate of accidents is reduced.
Description
Technical field
The present invention relates to mine extraction technical field, relate in particular to a kind of topping exploitation and gas exhaust management system and using method thereof.
Background technology
The major tasks that existing coal and gas are adopted work altogether are protrusion-dispelling work.According to " control coal and Gas Outburst regulation " that State Administration of Quality and Technical Supervision promulgates, the judgement important indicator of Coal Seam Outburst Hazard is coal-bed gas pressure, gas bearing capacity etc.And the main purpose of protrusion-dispelling is to eliminate Coal Seam Outburst Hazard (being extinction).Usually the outburst prevention measures that adopts is mainly the topping exploitation and regionality is taken out in advance, and its protrusion-dispelling effect assessment parameter mainly includes remaining gas pressure, gas bearing capacity and coal seam dilatancy coefficient etc. parameter.
At present, the method of the evaluation of measuring parameter that industry adopts is mainly labor measurement, exist consuming timely take a lot of work, data are discontinuous, data accuracy is not high, bring certain difficulty for colliery safe working science decision, thus can't coal supply and the gas protrusion-dispelling work of adopting altogether in the work give certain directiveness.
Summary of the invention
The invention provides a kind of topping exploitation and gas exhaust management system and using method thereof, use and think that the protrusion-dispelling work that existing coal and gas are adopted in the work altogether provides certain directiveness, thereby guarantee the purpose that coal and gas are adopted altogether.
The invention provides a kind of topping exploitation and gas exhaust management system, comprising:
Knowledge data base is for storing the altogether constructure scheme corresponding to various state parameters of mining face of coal and gas;
Receiver module is used for receiving the altogether state parameter of mining face of coal and gas;
Processing module is used for obtaining constructure scheme corresponding to described state parameter from described knowledge data base.
The invention provides the using method of a kind of topping exploitation and gas exhaust management system, comprising:
Receive the altogether state parameter of mining face of coal and gas;
From knowledge data base, obtain constructure scheme corresponding to described state parameter; Store constructure scheme corresponding to various state parameters in the described knowledge data base.
Topping exploitation of the present invention and gas exhaust management system and using method thereof by receiving the altogether state parameter of mining face of coal and gas, are obtained constructure scheme corresponding to this state parameter from knowledge data base; Wherein store constructure scheme corresponding to various state parameters in the knowledge data base.Adopt technical scheme of the present invention, can be from the knowledge data base of pre-stored Obtaining Accurate to constructure scheme corresponding to state parameter.Changed the not convenient property that needs to carry out on-site measurement in the prior art.Adopt technical scheme of the present invention, can coal supply and the gas protrusion-dispelling work of adopting altogether in the work give certain directiveness, reach the purpose that coal and gas are adopted altogether, the incidence of minimizing accident.
Description of drawings
In order to be illustrated more clearly in the embodiment of the invention or technical scheme of the prior art, the below will do one to the accompanying drawing of required use in embodiment or the description of the Prior Art and introduce simply, apparently, accompanying drawing in the following describes is some embodiments of the present invention, for those of ordinary skills, under the prerequisite of not paying creative work, can also obtain according to these accompanying drawings other accompanying drawing.
The topping that Fig. 1 provides for the embodiment of the invention one is exploited the structural representation with the gas exhaust management system;
The topping that Fig. 2 provides for the embodiment of the invention two is exploited the structural representation with the gas exhaust management system;
The topping exploitation that Fig. 3 provides for the embodiment of the invention three and the flow chart of the using method of gas exhaust management system;
The topping exploitation that Fig. 4 provides for the embodiment of the invention four and the flow chart of the using method of gas exhaust management system.
The specific embodiment
For the purpose, technical scheme and the advantage that make the embodiment of the invention clearer, below in conjunction with the accompanying drawing in the embodiment of the invention, technical scheme in the embodiment of the invention is clearly and completely described, obviously, described embodiment is the present invention's part embodiment, rather than whole embodiment.Based on the embodiment among the present invention, those of ordinary skills belong to the scope of protection of the invention not making the every other embodiment that obtains under the creative work prerequisite.
The topping that Fig. 1 provides for the embodiment of the invention one is exploited the structural representation with the gas exhaust management system.As shown in Figure 1, the exploitation of the topping of the present embodiment and gas exhaust management system specifically can comprise: knowledge data base 1, receiver module 2 and processing module 3.
Wherein knowledge data base 1 is total to the constructure scheme corresponding to various state parameters of mining face for storage coal and gas.Wherein these constructure scheme all are the constructure scheme of expert under the various state parameter conditions that practical operation is summed up according to actual conditions of this mine extraction technical field.The state parameter here can comprise that gas composes at least a in content, crack coefficient, the rock stratum degree of depth, gas permeability of coal seam and the rock matter.Therefore, can say that in fact this knowledge data base is exactly the knowledge and experience Information Number value with the colliery expert level, and according to each state parameter the constructure scheme of correspondence be stored.A state parameter can corresponding a plurality of constructure scheme in the reality.Constructure scheme wherein can comprise boring layout constructure scheme, digging constructure scheme, ventilation constructure scheme, supporting construction scheme and keep away calamity constructure scheme etc.Receiver module 2 is used for the altogether state parameter of mining face of coal and gas.As mentioned above, state parameter is that gas under the mine is composed one or more in content, crack coefficient, the rock stratum degree of depth, gas permeability of coal seam and the rock matter.The receiver module 2 here specifically can receive the attendant of topping exploitation and gas exhaust management system by the state parameter of human-machine interface module input by people's connection interface module.Processing module 3 is connected with receiver module with knowledge data base 1 respectively and is connected.Processing module 3 is used for obtaining constructure scheme corresponding to state parameter that receiver module 3 receives from knowledge data base 1.
Particularly, the processing module 3 in the present embodiment similarly is a rule-interpreter, is used for the state parameter according to receiver module 2 receptions, removes to mate constructure scheme corresponding to this state parameter from knowledge data base 1.Processing module 3 specifically can get access to constructure scheme corresponding to state parameter that receiver module 2 receives from knowledge data base 1; for this topping exploitation and gas exhaust management system; the coal of receiver module 2 receptions here and gas altogether the state parameter spy of mining face can be referred to as outside factor of determination; outside factor of determination can also be subdivided into a lot of decisive factors, and each decisive factor can have certain restriction to constructure scheme.Adopt such scheme to obtain corresponding constructure scheme according to this outside factor of determination.
Topping exploitation and the gas exhaust management system of the present embodiment by being received as state parameter, are obtained constructure scheme corresponding to this state parameter from knowledge data base; Wherein store constructure scheme corresponding to various state parameters in the knowledge data base.Adopt the technical scheme of the present embodiment, can be from the knowledge data base of pre-stored Obtaining Accurate to constructure scheme corresponding to state parameter.Changed the not convenient property that needs to carry out on-site measurement in the prior art.Adopt the technical scheme of the present embodiment, can coal supply and the gas protrusion-dispelling work of adopting altogether in the work give certain directiveness, reach the purpose that coal and gas are adopted altogether, the incidence of minimizing accident.
The topping that Fig. 2 provides for the embodiment of the invention two is exploited the structural representation with the gas exhaust management system.As shown in Figure 2, the exploitation of the topping of the present embodiment and gas exhaust management system are on above-mentioned basis embodiment illustrated in fig. 1, and wherein processing module 3, can comprise: N processing unit; N is positive integer, and more than or equal to 2.The number of plies that the value of N equals constructure scheme corresponding to state parameter determines.Wherein the first processing unit is for the first floor constructure scheme that obtains from knowledge data base 1 constructure scheme corresponding to state parameter.The i processing unit is used for the i-1 layer constructure scheme that obtain according to state parameter and i-1 processing unit, obtains the i layer constructure scheme in constructure scheme corresponding to state parameter from knowledge data base 1; Wherein i is positive integer, and 2≤i≤N.
As shown in Figure 2, take N>3 as example.Processing module 3 specifically can comprise the first processing unit 31, the second processing unit 32 ..., i processing unit 33 ... and N processing unit 34, altogether N processing unit.Wherein i is positive integer, and 2<i<N.
The first processing unit 31 is connected with receiver module 2, and the first processing unit 31 is used for obtaining first floor constructure scheme constructure scheme corresponding to state parameter that receiver module 2 receives from knowledge data base 1.The second processing unit 32 respectively with receiver module 2 be connected processing unit 31 and be connected, the second processing unit 32 obtains the 2nd layer of constructure scheme in constructure scheme corresponding to state parameter for the first floor constructure scheme that state parameter and the first processing unit 31 according to receiver module 2 receptions obtain from knowledge data base 1; The like, i processing unit 33 is connected with the i-1 processing unit with receiver module 2 respectively, i-1 layer constructure scheme for state parameter and i-1 processing unit according to receiver module 2 receptions obtain obtains the i layer constructure scheme in constructure scheme corresponding to state parameter from knowledge data base 1.The like, N processing unit 34 is connected with the N-1 processing unit with receiver module 2 respectively, N-1 layer constructure scheme for state parameter and N-1 processing unit according to receiver module 2 receptions obtain obtains the N layer constructure scheme in constructure scheme corresponding to state parameter from knowledge data base 1;
Particularly, here the constructure scheme in the knowledge data base 1 can be divided into multilayer, from knowledge data base 1, obtain first first floor constructure scheme in constructure scheme corresponding to state parameter that receiver module 2 receives by the first processing unit 31, from knowledge data base 1, obtain second layer constructure scheme in constructure scheme corresponding to state parameter by the second processing unit 32 according to first floor constructure scheme and state parameter again, by that analogy, i processing unit 33 can get access to the i layer constructure scheme in constructure scheme corresponding to state parameter from knowledge data base 1; The N processing unit can get access to the N layer constructure scheme in constructure scheme corresponding to state parameter from knowledge data base 1.In the practical application, the multilayer constructure scheme that constructure scheme can be comprised is according to tree-structured hierarchical.First according to the state parameter that receives, obtain the constructure scheme of the superiors corresponding to this state parameter, then according to constructure scheme and the state parameter of the superiors, obtain the constructure scheme of the corresponding second layer, the rest may be inferred, can progressively get access to the 3rd layer constructure scheme, constructure scheme of the 4th layer etc. is until get access to the whole constructure scheme that distributes according to tree structure.Can become and the succession mode to obtain for the above-mentioned mode of obtaining constructure scheme, can in layer progressively obtain more detailed constructure scheme.This mode of obtaining constructure scheme in knowledge data base 1 can become and can the succession mode obtain.Namely at first obtain the first floor constructure scheme, can get access to second layer technical scheme according to first floor constructure scheme and state parameter, the rest may be inferred, can get access to N layer technical scheme according to N-1 layer technical scheme and state parameter.Each layer constructure scheme just looks like that tree structure is the same like this, and one deck one deck of ining succession is as long as get access to the first floor constructure scheme, just can progressively get access to all technical schemes of other each layers.Accordingly, when generating knowledge data base 1, also need to remove to store each layer constructure scheme according to this logic.
Certainly, in actual the use, can be with constructure scheme regardless of level, fairly simple constructure scheme for example is stored together corresponding to the constructure scheme of a certain state parameter.Can directly obtain all corresponding constructure scheme according to state parameter like this.The mode of obtaining constructure scheme in this can be called and can not the succession mode obtain.
Constructure scheme in the present embodiment can comprise boring layout, digging, ventilation, supporting and keep away the constructure scheme such as calamity or comprise the constructure scheme of construction technology.
Need to prove, the exploitation of the topping of the present embodiment and receiver module 2 in the gas exhaust management system also are used for this state parameter of reception and corresponding first floor constructure scheme.Processing module 3 also is used for obtaining other constructure scheme corresponding to state parameter according to first floor constructure scheme and state parameter.Processing module 3 also is used for this state parameter, first floor constructure scheme and other constructure scheme are stored in knowledge data base 1 according to the corresponding relation between them.Other corresponding constructure scheme can be according to the tree storage of multilayer.For example the first floor constructure scheme is direct and this state parameter corresponding stored; Second layer constructure scheme respectively with first floor constructure scheme and state parameter corresponding stored.The tri-level construction scheme respectively with second layer constructure scheme and state parameter corresponding stored.The rest may be inferred.So just, can be according to above-mentioned processing module 3 get access to from level to level corresponding constructure scheme according to inheriting obtain manner.
For the simple constructure scheme of construction, can be only with the storage of one deck constructure scheme in knowledge data base 1.Particularly, according to the method described above, all constructure scheme that can state parameter is corresponding are stored in the knowledge data base 1 according to the corresponding relation between them.
Constructure scheme described in the present embodiment can comprise the basic theories knowledge in mine field, can also comprise the knowledge that the summary according to the expert in mine field or scholar's experience obtains, for the staff according to the coal at mine scene and gas altogether the mining face state parameter get access to some the guiding constructure scheme of storage in the knowledge data base 1.
Topping exploitation and the gas exhaust management system of the present embodiment by receiving the altogether state parameter of mining face of coal and gas, are obtained constructure scheme corresponding to this state parameter from knowledge data base; Wherein store constructure scheme corresponding to various state parameters in the knowledge data base.Adopt the technical scheme of the present embodiment, can be from the knowledge data base of pre-stored Obtaining Accurate to constructure scheme corresponding to state parameter.Changed the not convenient property that needs to carry out on-site measurement in the prior art.Adopt the technical scheme of the present embodiment, can coal supply and the gas protrusion-dispelling work of adopting altogether in the work give certain directiveness, reach the purpose that coal and gas are adopted altogether, the incidence of minimizing accident.
Need to prove, the topping exploitation of above-described embodiment can be connected with computer with the gas exhaust management system, after processing module 3 gets access to constructure scheme corresponding to state parameter, the result who gets access to can be shown by computer display.In order to increase the convenience of topping exploitation and gas exhaust management system; on the basis of above-described embodiment; can also directly with the gas exhaust management system display module be set in the topping exploitation, for example this display module is specifically as follows a display screen.This display module is connected with processing module 3, and this display module is used for constructure scheme corresponding to state parameter that Graphics Processing module 3 gets access to.By adopting this technical scheme, can strengthen the convenience that the topping exploitation is used with the gas exhaust management system.
The topping exploitation of above-described embodiment can arrange intuitively cross section with the display module of gas exhaust management system; for example can show the altogether state parameter of mining face of coal that receiver module 2 receives and gas at display module, the state parameter that coal and the gas of staff by the human-machine interface module input is total to mining face can show at display module.For example can also be set to touch-screen by display module, directly touch the input state parameter by touch-screen.From knowledge data base 1 obtain corresponding constructure scheme with the processing module 3 in the gas exhaust management system according to the state parameter that receives by the topping exploitation, and the result that the Graphics Processing module is obtained on display module.Particularly, for adopting the constructure scheme that can the succession mode gets access to, display module can be used for according to the hierarchical sequence of constructure scheme corresponding to state parameter tree structure order for example, and with different levels constructure scheme with integral body shows.
The state parameter that for example receives when receiver module 2 is " low-permeable, high gas and negative pole coal seam ", the state parameter " low-permeable, high gas and negative pole coal seam " that this moment, processing module 3 bases received, the first floor constructure scheme that can get access to is: the Gas Outburst possibility (a) is arranged; (b) can't be directly based on the surface drilling mash gas extraction.
According to first floor constructure scheme (a) and state parameter " low-permeable, high gas and negative pole coal seam ", can further can get access to second layer constructure scheme: (aa) need to carry out gas pre-drainage and process, to guarantee exploitation safety.
According to second layer constructure scheme (aa) and state parameter " low-permeable, high gas and negative pole coal seam ", can further get access to tri-level construction scheme (aaa): head and adopt the key stratum roof and floor and wear a layer hole mash gas extraction.Particularly, this tri-level construction scheme can be obtained according to second layer constructure scheme (aa) associating first floor constructure scheme (b) inference by the expert of this area in the practical application.When in knowledge data base 1, storing, can be directly according to this level storage.
If receiver module 2 has also received a state parameter " work plane is deposited the gas accumulated on upper corner phenomenon " except receiving state parameter " low-permeable, high gas and negative pole coal seam ".
Tri-level construction scheme (aaa) will united state parameter " work plane is deposited the gas accumulated on upper corner phenomenon " acquire the 4th layer of constructure scheme (aaaa): can use the Y type to ventilate and make wind flow field stable.And then can directly obtain layer 5 constructure scheme (aaaaa) according to the 4th layer of constructure scheme (aaaa) and state parameter " work plane is deposited the gas accumulated on upper corner phenomenon ": can use gob side entry retaining to save the tunnel cost in the mining process.Can also acquire layer 6 constructure scheme (aaaaaa) according to layer 5 constructure scheme (aaaaa): can arrange up and down layer-through drilling based on gob side entry retaining.The layer 6 constructure scheme (aaaaaa) here can be that reasoning obtains according to layer 5 constructure scheme (aaaaa) associating first floor constructure scheme (a) for the expert of this area.
The topping exploitation that Fig. 3 provides for the embodiment of the invention three and the flow chart of the using method of gas exhaust management system.As shown in Figure 3, the using method of the exploitation of the topping of the present embodiment and gas exhaust management system specifically can comprise:
Step 101, from knowledge data base, obtain constructure scheme corresponding to state parameter; Store the coal constructure scheme corresponding with the various state parameters of the common mining face of gas in this knowledge data base.
The state parameter of the present embodiment comprises that gas composes at least a in content, crack coefficient, the rock stratum degree of depth, gas permeability of coal seam and the rock matter.
The topping exploitation of the present embodiment and the using method of gas exhaust management system can with reference to the associated description of above-mentioned topping exploitation with the gas exhaust management system, not repeat them here in detail.
The topping exploitation of the present embodiment and the using method of gas exhaust management system by being received as state parameter, are obtained constructure scheme corresponding to this state parameter from knowledge data base; Wherein store constructure scheme corresponding to various state parameters in the knowledge data base.Adopt the technical scheme of the present embodiment, can be from the knowledge data base of pre-stored Obtaining Accurate to constructure scheme corresponding to state parameter.Changed the not convenient property that needs to carry out on-site measurement in the prior art.Adopt the technical scheme of the present embodiment, can coal supply and the gas protrusion-dispelling work of adopting altogether in the work give certain directiveness, reach the purpose that coal and gas are adopted altogether, the incidence of minimizing accident.
The topping exploitation that Fig. 4 provides for the embodiment of the invention four and the flow chart of the using method of gas exhaust management system.Suppose in the present embodiment that constructure scheme corresponding to state parameter includes the N layer altogether in the knowledge data base.As shown in Figure 4, the using method of the exploitation of the topping of the present embodiment and gas exhaust management system specifically can comprise:
By adopting such scheme can get access to N layer constructure scheme in constructure scheme corresponding to state parameter.
Particularly, be to comprise that N layer constructure scheme is that example illustrates in the present embodiment.Obtain first the first floor constructure scheme in constructure scheme corresponding to state parameter, then obtain second layer constructure scheme in constructure scheme corresponding to state parameter according to first floor constructure scheme and state parameter, the rest may be inferred, until get access to all constructure scheme of this state parameter.At last at this topping exploitation all constructure scheme corresponding with this state parameter of demonstration screen display of gas exhaust management system; and when showing, can show whole constructure scheme according to the hierarchical sequence of the N layer constructure scheme in constructure scheme corresponding to state parameter.
The state parameter of the present embodiment comprises that also gas composes at least a in content, crack coefficient, the rock stratum degree of depth, gas permeability of coal seam and the rock matter.
The topping exploitation of the present embodiment and the using method of gas exhaust management system by being received as state parameter, are obtained constructure scheme corresponding to this state parameter from knowledge data base; Wherein store constructure scheme corresponding to various state parameters in the knowledge data base.Adopt the technical scheme of the present embodiment, can be from the knowledge data base of pre-stored Obtaining Accurate to constructure scheme corresponding to state parameter.Changed the not convenient property that needs to carry out on-site measurement in the prior art.Adopt the technical scheme of the present embodiment, can coal supply and the gas protrusion-dispelling work of adopting altogether in the work give certain directiveness, reach the purpose that coal and gas are adopted altogether, the incidence of minimizing accident.
Need to prove and before the step 100 or step 200 of above-described embodiment, can also comprise:
(1) the N layer constructure scheme in the constructure scheme of accepting state parameter and correspondence;
(2) the N layer constructure scheme in the constructure scheme of state parameter, correspondence is stored in the knowledge data base according to the corresponding relation between them.
Particularly, also need in the present embodiment in advance each state parameter and corresponding each layer constructure scheme thereof to be stored in the knowledge data base according to the corresponding relation between them.When constructure scheme comprises multilayer, still according to constructure scheme between the layers corresponding relation be stored in the knowledge data base, in order to follow-up state parameter according to receiving, in layer obtain constructure scheme corresponding to this state parameter.
Device embodiment described above only is schematic, wherein the unit as the separating component explanation can or can not be physically to separate also, the parts that show as the unit can be or can not be physical locations also, namely can be positioned at a place, perhaps also can be distributed at least two network element.Can select according to the actual needs wherein some or all of module to realize the purpose of the present embodiment scheme.Those of ordinary skills namely can understand and implement in the situation that do not pay performing creative labour.
It should be noted that at last: above embodiment only in order to technical scheme of the present invention to be described, is not intended to limit; Although with reference to previous embodiment the present invention is had been described in detail, those of ordinary skill in the art is to be understood that: it still can be made amendment to the technical scheme that aforementioned each embodiment puts down in writing, and perhaps part technical characterictic wherein is equal to replacement; And these modifications or replacement do not make the essence of appropriate technical solution break away from the spirit and scope of various embodiments of the present invention technical scheme.
Claims (8)
1. a topping is exploited and the gas exhaust management system, it is characterized in that, comprising:
Knowledge data base is for storing the altogether constructure scheme corresponding to various state parameters of mining face of coal and gas;
Receiver module is used for receiving the altogether state parameter of mining face of coal and gas;
Processing module is used for obtaining constructure scheme corresponding to described state parameter from described knowledge data base;
Described processing module comprises N processing unit, and N is positive integer, and more than or equal to 2;
The first processing unit wherein is used for obtaining first floor constructure scheme described constructure scheme corresponding to described state parameter from described knowledge data base;
The i processing unit is used for the i-1 layer constructure scheme that obtain according to described state parameter and i-1 processing unit, obtains the i layer constructure scheme in described constructure scheme corresponding to described state parameter from described knowledge data base; Wherein i is positive integer, and 2≤i≤N.
2. topping exploitation according to claim 1 and gas exhaust management system is characterized in that:
Described receiver module also is used for receiving the N layer constructure scheme of described state parameter and corresponding described constructure scheme;
Described processing module also is used for the N layer constructure scheme of described state parameter, corresponding described constructure scheme is stored in the described knowledge data base according to the corresponding relation between them.
3. topping exploitation according to claim 1 and gas exhaust management system is characterized in that, also comprise:
Display module is used for showing described constructure scheme according to the hierarchical sequence of the N layer constructure scheme of described constructure scheme corresponding to described state parameter.
4. arbitrary described topping exploitation and gas exhaust management system is characterized in that according to claim 1-3, and described state parameter comprises that gas composes at least a in content, crack coefficient, the rock stratum degree of depth, gas permeability of coal seam and the rock matter.
5. the using method of topping exploitation and gas exhaust management system is characterized in that, comprising:
Receive the altogether state parameter of mining face of coal and gas;
From knowledge data base, obtain constructure scheme corresponding to described state parameter; Store the coal constructure scheme corresponding with the various state parameters of the common mining face of gas in the described knowledge data base;
The described constructure scheme that state parameter described in the described knowledge data base is corresponding includes the N layer; From described knowledge data base, obtain constructure scheme corresponding to described state parameter, specifically comprise:
From described knowledge data base, obtain the first floor constructure scheme in described constructure scheme corresponding to described state parameter;
From i=2, according to i-1 layer constructure scheme and described state parameter, from described knowledge data base, obtain the i layer constructure scheme in described constructure scheme corresponding to described state parameter; Then i is updated to i+1, repeats this step, until i=N finishes; Wherein N is the number of plies of the constructure scheme that comprises in the described knowledge data base, and N is positive integer, and more than or equal to 2; I also is positive integer, and 2≤i≤N.
6. the using method of topping exploitation according to claim 5 and gas exhaust management system is characterized in that, also comprises:
Receive the N layer constructure scheme in described state parameter and the corresponding constructure scheme;
N layer constructure scheme in the described constructure scheme of described state parameter, correspondence is stored in the described knowledge data base according to the corresponding relation between them.
7. the using method of topping according to claim 5 exploitation and gas exhaust management system is characterized in that, also comprises: the hierarchical sequence according to the N layer constructure scheme of described constructure scheme corresponding to described state parameter shows described constructure scheme.
8. the using method of arbitrary described topping exploitation and gas exhaust management system is characterized in that according to claim 5-7, and described state parameter comprises that gas composes at least a in content, crack coefficient, the rock stratum degree of depth, gas permeability of coal seam and the rock matter.
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| DE29703151U1 (en) * | 1997-02-21 | 1997-06-19 | Siemens Ag | Device for early detection of possible fires for use in the underground area |
| RU2288359C1 (en) * | 2005-11-14 | 2006-11-27 | Открытое акционерное общество "Газпром"(ОАО"Газпром") | Filter-separator for cleaning and coarse drying of methane gas |
| CN101436041A (en) * | 2007-11-15 | 2009-05-20 | 上海宝信软件股份有限公司 | Production executive system |
| CN101787897A (en) * | 2009-12-30 | 2010-07-28 | 西安西科测控设备有限责任公司 | System and method for predicting coal and gas outburst risk of mine in real time |
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| DE29703151U1 (en) * | 1997-02-21 | 1997-06-19 | Siemens Ag | Device for early detection of possible fires for use in the underground area |
| RU2288359C1 (en) * | 2005-11-14 | 2006-11-27 | Открытое акционерное общество "Газпром"(ОАО"Газпром") | Filter-separator for cleaning and coarse drying of methane gas |
| CN101436041A (en) * | 2007-11-15 | 2009-05-20 | 上海宝信软件股份有限公司 | Production executive system |
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