JP4359089B2 - Method and system for calculating production of mineral resources - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method and a system for calculating the production of mineral resources, specifically, for the production of a limestone mine, automatically correcting the apparent expansion weight of the mining amount due to the weather (for example, rain) and the size of the mining stone, The present invention relates to a system that corrects an accurate production volume and correctly calculates a production volume depreciation expense.
[0002]
[Prior art]
For the depreciation of mining assets such as mines, the production proportional method can be adopted in addition to the general straight-line method and declining-balance method. in this case,
Mining amount x (Acquisition price-Residual price) / (Scheduled mining quantity of the asset's useful life) (1)
Thus, the depreciation expense to be recorded in proportion to the output can be obtained.
[0003]
Conventionally, at business establishments that can use the unit-of-production method, production is measured by counting the number of trucks, the number of ships, etc., and the daily weather is recorded. A correction value of 3% reduction is calculated, and depreciation costs are calculated by taking time and man-hours. In addition, the correction by the weather for obtaining an accurate production amount is determined by the “presence or absence of rain”, because the correction by the rain amount and the size of each quarry stone is not easy.
[0004]
This kind of technology is still an undeveloped field and there is no prior patent document. There is a technique relating to an apparatus for measuring the load weight of a vehicle (for example, JP-A-9-304167).
[0005]
[Problems to be solved by the invention]
As described above, in the conventional technology, it takes a great amount of man-hours to calculate the depreciation cost of a mine-related establishment that can employ the proportional production method instead of the straight-line method or the declining-balance method. In addition, there was a problem in the accuracy in grasping the output. That is, the correction of the production amount due to the weather is only correction based on the presence or absence of rain, and it has not been corrected accurately according to the amount of rain and the size of the mining stone.
[0006]
This invention is made | formed in view of such a subject, Comprising: It aims at providing the production amount calculation method and system of a mineral resource which can calculate the production amount of a mineral resource correctly.
[0007]
[Means for Solving the Problems]
(1) The invention described in claim 1 is as follows. FIG. 1 is a flowchart showing the principle of the method of the present invention. The present invention includes a production amount detecting means for detecting a production amount of a mineral resource, a rain amount measuring means for measuring a rainfall amount, a size detecting means for detecting an average value of individual sizes of the mined mineral resources, and the production It is composed of storage means for storing the height, the amount of rainfall, and the individual size of the mineral resource, and a control unit for controlling the overall operation, and the control unit is configured to detect the detected value of the production amount detection means, Based on the average value of the rainfall and the individual size of the mineral resource, the output of the output detection means is multiplied by the correction value obtained from the size of the mineral resource and the characteristics of the moisture content, and the output of the mineral resource is calculated. In the method for calculating the production amount of mineral resources, the control unit calculates the detection value of the production amount detection means based on an average value of the rainfall and the individual magnitudes of the mineral resources. Correction obtained from characteristics of size and moisture content And characterized by correcting the production of mineral resources by multiplying the output of the output detecting means.
[0008]
If constituted in this way, since the production amount of mineral resources can be accurately calculated, it is possible to accurately calculate the depreciation expense by the production volume proportional method using the equation (1). .
(2) The invention according to claim 2 is characterized in that the production of the mineral resource is the production of limestone.
[0009]
If constituted in this way, the amount of production about limestone can be computed correctly.
(3) The invention according to claim 3 further includes an input unit for inputting an expense item, stores the depreciation expense inputted from the input unit in the storage means, and adds the daily corrected mining amount. The annual mining amount is calculated, and the production proportional depreciation cost is calculated using the following formula using the acquisition price of the asset, the residual price, and the planned mining amount of the asset's useful life. .
Mining amount x (Acquisition price-Residual price) / (Scheduled mining amount of the useful life of the asset)
[0010]
If comprised in this way, the annual production proportional depreciation expense can be calculated correctly.
(4) The invention according to claim 4 is characterized in that, in the step 3, the daily production of mineral resources is corrected by using a correction value that varies depending on the measured value of rainfall.
[0011]
If comprised in this way, since a different correction value is used according to the measured value of rainfall, the production amount of mineral resources can be calculated accurately irrespective of the amount of rainfall.
(5) The invention according to claim 5 is characterized in that, in the step 3, the daily production amount of the mineral resource is corrected by using a correction value which varies depending on the measured value of the individual size of the mineral resource.
[0012]
If configured in this way, since different correction values are used depending on the measured values of the individual sizes of the mineral resources, it is possible to accurately calculate the output of the mineral resources regardless of the individual sizes of the mineral resources. it can.
(6) The invention according to claim 6 is a production amount detecting means for detecting a production amount of a mineral resource, a rainfall measuring means for measuring a rainfall amount, and a magnitude for detecting an average value of individual sizes of the mined mineral resources. And a storage unit for storing individual sizes of the mineral resources, and a control unit for controlling the overall operation. The control unit detects the production amount. The detection value of the means is multiplied by the output of the output detection means by a correction value obtained from the characteristics of the mineral resource size and moisture content based on the average value of the rainfall and the individual size of the mineral resource. It is characterized by correcting the production of mineral resources .
[0013]
If comprised in this way, the production amount of a mineral resource can be calculated correctly irrespective of the amount of rainfall and the individual size of the mineral resource.
(7) The invention according to claim 7 is characterized in that the production amount detection means is a limestone production amount detection means.
[0014]
If constituted in this way, the amount of production about limestone can be computed correctly.
(8) The invention according to claim 8 further includes an input unit for inputting an expense item, stores the depreciation expense inputted from the input unit in the storage means, and adds the daily corrected mining amount. The annual mining amount is calculated , and the production proportional depreciation cost is calculated using the following formula using the acquisition price of the asset, the residual price, and the planned mining amount of the asset's useful life. .
Mining amount x (Acquisition price-Residual price) / (Scheduled mining amount of the useful life of the asset)
[0015]
If comprised in this way, the production proportional depreciation expense according to an annual mining amount is computable.
(9) The invention according to claim 9 sets a threshold value for the rainfall, and uses a characteristic curve indicating a relationship between a stone size and inclusion moisture to determine the inclusion moisture from the rainfall threshold. An accurate production amount is obtained by multiplying the contained moisture amount by the output of the production amount detecting means .
[0016]
If comprised in this way, the production amount of mineral resources can be calculated correctly.
(10) The invention according to claim 10 sets a threshold value for each size of the mineral resource, and uses a characteristic curve indicating the relationship between the size of the mineral resource and the moisture content, and uses the characteristic curve to indicate the size of the mineral resource. Then, the moisture content is obtained, and the precise moisture content is obtained by multiplying the moisture content by the output of the production amount detecting means .
If comprised in this way, it will become possible to calculate the production amount of a mineral resource correctly.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0018]
FIG. 2 is a block diagram showing an embodiment of the present invention. In the figure, 1 is a belt conveyor sensor for measuring the weight of mineral resources loaded on a belt conveyor for loading mineral resources on a ship 26 with a belt conveyor, and 2 is a weight for measuring the weight of mineral resources loaded on a truck 32. It is a sensor. The belt conveyor sensor 1 and the weight sensor 2 constitute a production amount detecting means for detecting the production amount of mineral resources.
[0019]
FIG. 3 is an explanatory diagram of the belt conveyor sensor 1. In the figure, 21 is a plurality of rollers, and 22 is a belt wound around these rollers 21. When the roller 21 rotates in the direction of the arrow in the figure, the belt 22 moves in the direction of the arrow in the figure. A mineral resource 23 is placed on the belt 22, and when it reaches the end of the belt 22, the mineral resource falls. In this way, the carried mineral resource 23 is loaded on the ship 26. Reference numeral 24 denotes a metal flat plate on which the belt conveyor portion is placed. Reference numeral 25 denotes a weigh scale (unit: T (ton)) attached to the flat plate 24. The weight scale 25 notifies the control unit 10 of the measurement result.
[0020]
The weigh scale 25 measures the weight (W1) of the belt conveyor when the mineral resources 23 are not loaded, and then measures the weight (W2) of the belt conveyor when the mineral resources 23 are loaded. Therefore, the weight of the mineral resource 23 can be obtained by (W2-W1).
[0021]
Thus, by measuring the weight of the mineral resource 23 mounted on the belt conveyor a plurality of times, the total weight of the mineral resource mounted on the ship 26 can be calculated. In addition, when loading a mineral resource on the ship 26, the amount of the ship 26 before loading the mineral resource is measured as W3, and the amount of the ship 26 when the mineral resource is loaded is measured as W4 (W4-W3). There is also a method to obtain from.
[0022]
FIG. 4 is an explanatory diagram of the weight sensor 2. As shown in the figure, there is a metal flat plate 30 on which a track 32 rides, and a weight scale 31 (unit is T (ton)) is attached to the flat plate 30. First, the weight (W5) of the empty truck 32 is measured, and then the weight (W6) of the truck 32 loaded with mineral resources is measured. Therefore, the weight of the mineral resource can be obtained by (W6-W5). The weighing scale 31 notifies the control unit 10 of the measurement result.
[0023]
Returning to the description of FIG. 2, 3 is a size sensor for measuring the average value of the individual sizes of the mineral resources installed on the belt conveyor side, and 4 is an individual size of the mineral resources provided on the weight sensor 2 side. It is a size sensor that measures the average value of.
[0024]
FIG. 5 is an explanatory diagram of the size sensor. A sampled mineral resource stone 41 is placed on a metal flat plate 40. A weight scale 42 is attached to the flat plate 40. The weighing scale 42 measures the weight and notifies the calculation unit 44 of the result. On the other hand, the number counter 43 counts the number of sampling stones 41 placed on the flat plate 40. The count result is notified to the calculation unit 44. The calculation unit 44 divides the total weight notified from the weighing scale 42 by the number notified from the number counter 43. That is, the average value of individual sizes of mineral resources is obtained. As a result, the calculation unit 44 outputs (weight / number) and notifies the control unit 10. This (weight / number) is the average value of the individual sizes of the mineral resources.
[0025]
Returning to FIG. 2, reference numeral 5 denotes a rain sensor (so-called rain gauge) that measures rainfall. Reference numeral 6 denotes a storage unit for storing the production value of the mineral resource, the rainfall, and the average value of the individual sizes of the mineral resource. A management information database (DB) 7 stores information stored in the storage unit 6 as management information. Reference numeral 7a denotes a limestone mining management table provided in the management information database 7 for storing data such as the production amount of mineral resources, the amount of rainfall, and the size of crushed stones of mineral resources.
[0026]
8 is an input unit for inputting the cost of depreciation, 9 is an output unit for outputting the production amount corrected according to the measured rainfall and individual sizes of mineral resources, and 10 is a control unit for controlling the overall operation. It is. For example, a computer is used as the control unit 10. The operation of the apparatus configured as described above will be described as follows.
[0027]
FIG. 6 is a flowchart showing an example of the operation of the present invention. The control unit 10 first receives and records the weight value (mining sensor value) of daily mineral resources (here, limestone is taken as an example) from the belt conveyor sensor 1 or the weight sensor 2 (S1). Here, the weight value indicates the output of claim 1. Next, the control unit 10 receives and records daily rainfall from the rainfall sensor 5 (S2). Next, the control unit 10 receives and records the size of the average sample mining stone from the size sensor 4 (S3). The control unit 10 stores these daily mining sensor values, daily rainfall, and average sample mining stone sizes (average values of individual sizes of limestone) in a limestone mining management table 7a (details will be described later).
[0028]
Next, the control unit 10 receives the output of the rainfall sensor 5 and checks whether there is rainfall, that is, whether it has rained (S4). When it rains, the control unit 10 checks whether the rainfall is 50 mm or more (S5). Then, regardless of whether the rainfall is 50 mm or more, it is checked whether the average value of the individual sizes of the mined stone (hereinafter simply referred to as the size) is 500 g or more.
[0029]
Here, the reason why the threshold value for the rainfall is 50 mm and the threshold value for the stone size is 500 g will be described. FIG. 7 is a diagram showing the relationship between the size of stones and the moisture content. The horizontal axis is the stone size, and the vertical axis is the moisture content (%). Referring to the characteristics shown in the figure, the moisture content has changed abruptly with a stone size of 500 g as a boundary. f1 indicates the characteristics when the rainfall is 50 mm or more, and f2 indicates the characteristics when the rainfall is less than 50 mm. In any of the characteristics, as the stone size increases, the moisture content decreases, and as the stone size decreases, the moisture content increases. The reason is that the rock excavated by a rock drill is not a spherical body but a polyhedron, and the smaller the stone size, the larger the gap between adjacent stones, and the more water enters the gap. Because.
[0030]
For example, in the case of the characteristic f1, when the stone size is larger than 500 g, the moisture content is 3.0%, but when the stone size is smaller than 500 g, the moisture content is 4.0. It increases with%. In the case of the characteristic f2, when the stone size is larger than 500 g, the moisture content is 2.5%. However, when the stone size is smaller than 500 g, the moisture content is 3.5%. To rise. As described above, it can be seen that the moisture content changes with a stone size of 500 g as a boundary, and the moisture content changes depending on the rainfall (when the rainfall is 50 mm or more and less than 50 mm). Therefore, the stone size of 500 g and the rainfall of 50 mm are used as threshold values.
[0031]
Returning again to the operation of FIG. The control unit 10 checks whether the rainfall is 50 mm or more (S5), and if the rainfall is 50 mm or less, checks whether the size of the mining stone is 500 g or more (S6). As described with reference to FIG. 7, even when the rainfall is 50 mm or less, the moisture content differs from the mining stone size of 500 g.
[0032]
Therefore, when the mining stones are 500 g or more on average, since the moisture content is small, the value reduced corresponding to the amount of rainfall is recorded in the limestone mining management table 7a as the total on the day (S7). In this case, specifically, the weight obtained by subtracting 2.5% from the total on the day is recorded in the limestone mining management table 7a as the corrected total.
[0033]
In step S6, when the mined stones are 500 g or less on average, the moisture content increases, so the value reduced corresponding to the rainfall is recorded in the limestone mining management table 7a as the total on the day (S8). Specifically, the weight obtained by reducing 3.5% of the total on the day is recorded in the limestone mining management table 7a as the corrected total.
[0034]
In step S5, when the rainfall is 50 mm or more, it is checked whether or not the mining stone is 500 g or more on average (S9). As described with reference to FIG. 7, even when the rainfall is 50 mm or more, the moisture content of the mining stone differs from 500 g as a boundary.
[0035]
Therefore, when the mining stone is 500 g or more, since the moisture content is small, the value reduced corresponding to the rainfall is recorded in the limestone mining management table 7a as the total on the day (S10). Specifically, the weight obtained by subtracting 3.0% from the total on the day is recorded in the limestone mining management table 7a as the corrected total.
[0036]
In step S9, if the mined stone is 500 g or less on average, the amount of moisture included increases, and the value reduced with respect to the rainfall is recorded in the limestone mining management table 7a as the total on the day (S11). Specifically, the weight obtained by subtracting 4.0% from the total on the day is recorded in the limestone mining management table 7a as the corrected total.
[0037]
FIG. 8 is a diagram showing a configuration example of the limestone mining management table 7a. As shown in the figure, the date of production, the measured weight (ton) of the belt conveyor sensor 1, the measured weight (ton) of the weight sensor 2, the provisional total (ton) that is the total value of these sensors, The rainfall, the average size (weight (unit: g)) of limestone, the corrected total (tons), and the annual total (tons) are stored. Here, the total after correction stores the corrected weight corrected in steps S7, S8, S10, and S11. The corrected weight data is output from the output unit 9.
[0038]
When the weight of the limestone after correction is found in this way, or when there is no rainfall in step S4, the control unit 10 records the mining year total and registers it in the limestone mining management table 7a (S12). Next, when the depreciation item is input from the input unit 8, the control unit 10 reads the depreciation item (S13). FIG. 9 is an explanatory diagram of depreciation expenses. Expenses are, for example, an acquisition price of a set of crushers of 10,000 (thousand yen), a residual price of 5,000 (thousand yen), a useful life of four years, and a planned mining quantity of 40,000 (thousand tons). The same applies to the other items of excavator set, belt conveyor and crane. The expense item read in this way is stored in the management information database 7.
[0039]
Next, the control part 10 calculates a depreciation value based on (1) Formula using the inputted expense item (S14). The calculated cost amortization cost is output from the output unit 9. Here, as the output unit 9, for example, a printer, a display, or the like can be used.
[0040]
Next, the depreciation cost is calculated using the equation (1) by using the production proportional method for the cost crusher. For example, assuming that the mining amount is 25,000 (thousand tons), the acquisition price is 10,000 (thousand yen), the remaining price is 5,000 (thousand yen), and the expected mining quantity for the useful life of the asset is 40,000. (Thousand tons). Substituting these values into equation (1) gives
Depreciation cost = 25000 × (10000−5000) / 40000
= 3125 (thousand yen)
It becomes.
[0041]
As described above, according to the present invention, the production amount of mineral resources can be accurately calculated. Therefore, even when calculating the depreciation cost by the unit-of-production method using the equation (1), it is accurate. Can be calculated.
[0042]
Moreover, according to the present invention, when the mineral resource is limestone, the production amount can be accurately calculated.
[0043]
In addition, according to the present invention, the annual cumulative production of mineral resources is obtained, and the production proportional depreciation cost corresponding to the production is calculated, thereby accurately calculating the production proportional depreciation expense for one year. Can do.
[0044]
In addition, according to the present invention, it is possible to accurately calculate the yield of mineral resources regardless of the amount of rainfall by using different correction values depending on the measured value of rainfall.
[0045]
Further, according to the present invention, it is possible to accurately calculate the production amount of the mineral resource regardless of the individual size of the mineral resource by using a correction value that varies depending on the measured value of the individual size of the mineral resource. Can do.
[0046]
Moreover, according to this invention, based on the depreciation expense input from the input part, the production proportional depreciation expense according to an annual mining amount is computable.
[0047]
In the embodiment described above, limestone has been described as an example of the mineral resource. However, the present invention is not limited to this, and can be similarly applied to, for example, iron ore, copper ore, and coal.
[0048]
【The invention's effect】
As described above, according to the present invention, the following effects can be obtained.
(1) According to the invention described in claim 1, since the production of mineral resources can be accurately calculated, even when calculating the depreciation cost by the production proportional method using the equation (1) Can be calculated.
(2) According to the invention described in claim 2, the output of limestone can be accurately calculated.
(3) According to the invention as set forth in claim 3, it is possible to accurately calculate the annual production proportional depreciation expense.
(4) According to the invention described in claim 4, since different correction values are used depending on the measurement value of the rainfall, the production of mineral resources can be accurately calculated regardless of the amount of rainfall.
(5) According to the invention described in claim 5, since different correction values are used depending on the measured values of the individual sizes of the mineral resources, the output of the mineral resources can be increased regardless of the individual sizes of the mineral resources. It can be calculated accurately.
(6) According to the invention described in claim 6, the production amount of the mineral resource can be accurately calculated regardless of the amount of rainfall and the individual size of the mineral resource.
(7) According to the invention as set forth in claim 7, the output of limestone can be accurately calculated.
(8) According to the invention described in claim 8, it is possible to calculate the output proportional depreciation cost according to the annual mining amount.
(9) According to the invention described in claim 9, the production of mineral resources can be accurately calculated.
(10) According to the invention described in claim 10, it is possible to accurately calculate the production of mineral resources.
[0049]
Thus, according to the present invention, it is possible to provide a mineral resource production amount calculation method and system capable of accurately calculating the mineral resource production amount.
[Brief description of the drawings]
FIG. 1 is a flowchart showing the principle of the method of the present invention.
FIG. 2 is a block diagram showing an embodiment of the present invention.
FIG. 3 is an explanatory diagram of a belt conveyor sensor.
FIG. 4 is an explanatory diagram of a weight sensor.
FIG. 5 is an explanatory diagram of a size sensor.
FIG. 6 is a flowchart showing an example of the operation of the present invention.
FIG. 7 is a diagram showing the relationship between stone size and moisture content.
FIG. 8 is a diagram showing a configuration example of a limestone mining management table.
FIG. 9 is an explanatory diagram of depreciation expenses.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Belt conveyor sensor 2 Weight sensor 3 Size sensor 4 Size sensor 5 Rain amount sensor 6 Storage part 7 Management information database 7a Limestone mining management table 8 Input part 9 Output part 10 Control part 24 Butt storage means 25 Output means

Claims (10)

A production detection means for detecting the production of mineral resources;
Rain measurement means for measuring rainfall;
A size detecting means for detecting an average value of individual sizes of mined mineral resources;
Storage means for storing the output, the rainfall, and the individual sizes of the mineral resources;
A control unit that controls the overall operation;
The control unit comprises a correction value obtained from the characteristics of the mineral resource and the moisture content based on the average value of the rainfall and the individual size of the mineral resource. In the method for calculating the production of mineral resources, the output of the production detection means is multiplied to correct the production of mineral resources.
The control unit uses the production value detection means as a correction value obtained from the characteristics of the mineral resource size and moisture content based on the average value of the rainfall and the individual size of the mineral resource. A method for calculating the production amount of a mineral resource, wherein the production amount of the mineral resource is corrected by multiplying the output of the high detection means .   2. The method for calculating the production of mineral resources according to claim 1, wherein the production of the mineral resources is a production of limestone. An input unit for inputting the cost item is further provided, the depreciation cost input from the input unit is stored in the storage unit, the daily mining amount is calculated by adding the daily corrected mining amount, and the acquisition price of the asset The production of mineral resources according to claim 1 or 2, wherein the production amount proportional depreciation is calculated using the following formula using the remaining price and the planned mining amount of the asset's useful life: High calculation method.
Mining amount x (Acquisition price-Residual price) / (Scheduled mining amount of the useful life of the asset)   The method for calculating the production amount of a mineral resource according to any one of claims 1 to 3, wherein a daily production value of the mineral resource is corrected using a correction value that varies depending on the measured value of the rainfall.   The amount of mineral resource production according to any one of claims 1 to 4, wherein the amount of mineral resource production is corrected using a correction value that varies depending on the measured value of the individual size of the mineral resource. Calculation method. A production detection means for detecting the production of mineral resources;
Rain measurement means for measuring rainfall;
A size detecting means for detecting an average value of individual sizes of mined mineral resources;
Storage means for storing the output, the rainfall, and the individual sizes of the mineral resources;
A control unit that controls the overall operation;
The control unit comprises a correction value obtained from the characteristics of the mineral resource and the moisture content based on the average value of the rainfall and the individual size of the mineral resource. Is multiplied by the output of the production amount detecting means to correct the production amount of the mineral resource.   The system for calculating the production amount of mineral resources according to claim 6, wherein the production amount detection means is a limestone production amount detection means. An input unit for inputting the cost item is further provided, the depreciation cost input from the input unit is stored in the storage unit, the daily mining amount is calculated by adding the daily corrected mining amount, and the acquisition price of the asset The production amount proportional depreciation cost is calculated using the following formula using the remaining price and the planned mining amount of the asset's useful life. High calculation system.
Mining amount x (Acquisition price-Residual price) / (Scheduled mining amount of the useful life of the asset) A threshold value is set for the rainfall amount, and an inclusion moisture amount is obtained from the rainfall threshold value using a characteristic curve indicating a relationship between a stone size and inclusion moisture, and the inclusion moisture amount is determined by the yield detection means. The system for calculating the production amount of a mineral resource according to any one of claims 6 to 8, wherein an accurate production amount is obtained by multiplying the output . A threshold value is set for each individual size of the mineral resource, and an inclusion moisture amount is obtained from the individual size of the mineral resource using a characteristic curve indicating a relationship between the size of the mineral resource and the included moisture. The system for calculating the production amount of mineral resources according to any one of claims 6 to 8 , wherein an accurate production amount is obtained by multiplying the amount of water by the output of the production amount detection means .

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