JP2019181318A - Control method of water treatment plant accompanied by coagulation and control device - Google Patents

Abstract

To reduce a repeating number of a jar test irrespective of the level of skills or the like of a worker when deciding an injection rate of a coagulant in a water treatment plant.SOLUTION: Date through a learning process being data of a value which is obtained with respect to one or more items by an analysis or measurement, and coagulant injection rates are accumulated in a record calculation device with a plurality of the coagulant injection rates for use in a one-time jar test as an injection rate group, and a relational expression indicating a relation between a value of one or more certain items and the coagulant injection rates is created. The coagulant injection rates of the injection rate group are decided from the relational expression on the basis of an input value. In the learning process, when a correlation coefficient of the coagulant injection rate corresponding to a new result with respect to a theoretical injection rate in the relation expression is a prescribed multiple of a correlation coefficient of a coagulant injection rate in the accumulated data with respect to the theoretical injection rate or higher in a certain relational expression, the data corresponding to the new result are additionally accumulated in the record calculation device on the basis of the new result by the jar test.SELECTED DRAWING: Figure 4

Description

  The present invention relates to control of a water treatment plant in which a flocculant is introduced and agglomerates and separates impurities, and more particularly to a control method and a control apparatus for determining an injection amount of the flocculant in the water treatment plant.

  In water treatment plants such as water purification plants and wastewater treatment plants, in order to settle and remove suspended suspended matters contained in raw water, a flocculant is added to the raw water to increase the sedimentation rate and promote the removal of suspended suspended matters. I am letting. As the flocculant, for example, polyaluminum chloride (PAC) is widely used. Since the optimum addition amount of the flocculant to the raw water greatly varies depending on the quality of the raw water, it is necessary to determine the optimum addition amount of the flocculant by performing a jar test. In the jar test, after analyzing the water quality of the raw water, the raw water is collected and used as the sample water. The flocculant is added to the sample water in the beaker, and the mixture is stirred and allowed to stand. The turbidity and chromaticity are measured, and the sample water remaining in the beaker is filtered to measure the turbidity and chromaticity of the filtered water. Actually, for example, three to ten jar testers capable of simultaneously stirring and standing in a plurality of beakers are used, and different amounts of flocculant are added to each beaker containing sample water. Jar test is performed on sample water in a plurality of beakers in parallel. For example, if six jar testers are used, different amounts of flocculant are added to the sample water poured into each of the six beakers. Then, based on which of the plurality of beakers achieves the target water quality value and shows the best result, the input amount of the flocculant to the raw water in the water treatment plant is determined. In water treatment plants, jar tests are performed periodically, and also when a sudden change in the quality of raw water is detected or when the source of raw water is changed.

  By the way, before carrying out the jar test, it is necessary to determine the conditions for carrying out the jar test, in particular, the amount of the flocculant added to the sample water of each beaker and the stirring time. FIG. 1 is a flowchart showing a conventional execution procedure of a jar test. First, in step 101, the quality of raw water is analyzed. The water quality analysis items include, for example, turbidity (or suspended matter amount (SS)), chromaticity, pH, TOC (total organic carbon), COD (chemical oxygen demand), etc. An analysis item is selected. Next, in step 102, the conditions for performing the jar test are determined based on the water quality analysis results (mainly turbidity and chromaticity) of the raw water, literature values, and past results and experiences. In step 103, a jar test is performed under the conditions set in step 102, and the supernatant water and filtered water are analyzed. Then, in step 104, it is determined whether or not the flocculant injection rate or range that is the target treated water quality is obtained as a result of the jar test. If the injection rate or range of the flocculant that is the target treated water quality is obtained, the jar test is terminated. If not, the procedure returns to step 102 to change the condition setting and repeat the jar test. .

  A jar test using a jar tester gives results for different flocculant injection rates at once. In order to be the optimum flocculant injection rate, not only the target treated water quality is satisfied, but also in a single test by the jar tester, for an injection rate larger than the flocculant injection rate. The result and the result for the injection rate should be better than the result for the injection rate smaller than the coagulant injection rate. Therefore, in order to obtain the optimum flocculant injection rate, not only whether or not the target treated water quality is satisfied in step 104, but also the flocculant injection rate showing the best result is determined by the jar tester. It is necessary to confirm that the coagulant injection rate used in the test is neither the maximum nor minimum value.

  In the above-described conventional method, the jar test condition setting is performed depending on the operator's experience. If you are an experienced engineer or researcher, you can set the jar test conditions to include the optimal flocculant injection rate from the raw water quality, especially from visually obtained information such as turbidity and chromaticity. However, an engineer with little experience may not be able to obtain an optimal flocculant injection rate with a single jar test by a jar tester. In that case, the jar test will be repeated until the optimum injection rate is obtained.

  Attempts have been made to determine the injection amount of a chemical such as an aggregating agent using AI (artificial intelligence). When a human determines a drug injection amount, the drug injection amount is determined to be excessive, and an AI that learns such a drug injection amount also determines the drug injection amount excessively. Therefore, Patent Document 1 obtains a statistical injection rate by statistically processing raw water quality information, chemical information, and treated water quality information in order to avoid excessive chemical injection. Disclosed is to obtain a model injection rate using a water quality reaction model that models the reaction and to generate operating conditions for controlling the chemical injection rate in a water treatment plant based on the statistical injection rate and the model injection rate is doing.

JP 2017-140595 A

  The optimum injection rate when injecting a flocculant such as PAC in a water treatment plant is uniquely determined by calculation from the results of water quality analysis at present, even if a technique such as that described in Patent Document 1 is used. It is difficult to determine the optimal injection rate by performing a jar test with a jar tester. However, the condition setting in the jar test largely depends on the experience of the worker, and in the case of an unskilled worker, the optimum flocculant injection rate cannot be obtained unless the jar test is performed many times.

  An object of the present invention is a control method and control apparatus for a water treatment plant that determines an optimal flocculant injection rate, and can control the number of repetitions in a jar test regardless of the skill level of an operator. It is to provide a method and a control device.

  The control method of the present invention is a control method for determining a flocculant injection rate for a jar test using raw water as sample water in a water treatment plant for treating raw water by adding a flocculant to raw water. Multiple flocculant injection rates used in one jar test are taken as the injection rate group, and the value obtained by analyzing or measuring one or more items for sample water and treated water after jar test and flocculant injection A recording arithmetic device that accumulates data with a rate and that has undergone a learning process is used, and in the recording arithmetic device, the relationship between the value of any one or more items and the coagulant injection rate based on the accumulated data In the recording arithmetic unit, the coagulant injection rate constituting the injection rate group is determined from the relational expression based on the input value, and the learning step uses the determined injection rate group Based on the results of the test, for any one of the relational expressions, the flocculant injection rate calculated from the relational expression is used as the theoretical injection rate. When the correlation coefficient with the rate is equal to or greater than the correlation coefficient with the coagulant injection rate used to generate the relational expression for the theoretical injection rate, data corresponding to the result is added to the recording arithmetic unit. And accumulating.

  The control device according to the present invention is a control device for determining a flocculant injection rate for a jar test using raw water as sample water in a water treatment plant for adding raw flocculant to raw water to treat the raw water. Multiple flocculant injection rates used in one jar test are taken as the injection rate group, and the value obtained by analyzing or measuring one or more items for sample water and treated water after jar test and flocculant injection A data storage unit that stores data on the rate, and a relational expression that represents the relationship between the value of any one or more items and the coagulant injection rate based on the data stored in the data storage unit, and data storage A data learning unit that executes a learning process on the data stored in the unit, and a condition determination unit that determines an injection rate of a coagulant constituting an injection rate group from a relational expression based on an input value. place The result of the jar test with respect to the theoretical injection rate, with the flocculant injection rate calculated from the relational equation as the theoretical injection rate based on the result of the jar test using the determined injection rate group When the correlation coefficient with the coagulant injection rate in the injection rate group corresponding to is greater than or equal to a predetermined multiple of the correlation coefficient with the coagulant injection rate used to generate the relational expression with respect to the theoretical injection rate, Data corresponding to the result is added and accumulated in the data storage unit.

  According to the present invention, the number of repetitions in the jar test can be reduced regardless of the skill level of the operator.

It is a flowchart which shows the conventional execution procedure of a jar test. It is a block diagram which shows the structure of the control apparatus of one Embodiment of this invention. (A), (b) is a graph which shows the relationship between PAC injection | pouring rate and supernatant water turbidity. It is a flowchart which shows the execution procedure of the jar test in one Embodiment. It is a figure explaining determination of the coagulant | flocculant injection rate based on turbidity. It is a sequence diagram which shows operation | movement of a recording arithmetic unit and a terminal. It is a sequence diagram which shows operation | movement of a recording arithmetic unit and a terminal.

  Next, embodiments of the present invention will be described with reference to the drawings. FIG. 2 shows the configuration of the control apparatus according to the embodiment of the present invention.

  The control device shown in FIG. 2 is used to determine the conditions of a jar test performed when determining the coagulant injection rate in a water treatment plant such as a water purification plant or a wastewater treatment plant. And an input unit 21 and an output unit 22 connected to the recording arithmetic device 10. For example, a terminal 40 made of a smartphone or the like may be connected to the recording arithmetic apparatus 10 via the network 30. The recording arithmetic device 10 is configured by a computer such as a personal computer or a server computer, for example, and logically stores a data storage unit 11 that stores data and the data stored in the data storage unit 11. A data learning unit 12 that generates a relational expression to be described later based on the data and performs machine learning on the data, and a condition determination unit 13 that determines a jar test condition based on the relational expression stored in the data storage unit 11. I have. The area of the data storage unit 11 is secured in the storage device of the computer, and the functions of the data learning unit 12 and the condition determination unit 13 are realized by the computer CPU (central processing unit) operating based on the software program. Is done.

This control device has a plurality of flocculants used in a single jar test by a jar tester based on an input value when a value for any of various input items or a combination of these values is input. The injection rate is determined and output. In the following description, a plurality of flocculant injection rates (that is, the number corresponding to the number of beakers in the jar tester) used in one jar test by the jar tester are referred to as an injection rate group. At this time, the control device
(1) The injection rate group includes a flocculant injection rate that achieves the target treated water quality.
(2) The flocculant injection rate that showed the best results is neither the maximum nor the minimum of the flocculant injection rates included in the injection rate group,
The injection rate group is determined so as to satisfy these two conditions.

  3 (a) and 3 (b) show the relationship between the PAC injection rate and the turbidity of the obtained supernatant when a jar test is performed with PAC added as a flocculant to a certain sample water. Yes. Here, six jar testers are used. Therefore, the injection rate group in one jar test is composed of six PAC injection rates. The target supernatant water turbidity shall be 1 degree or less. Fig.3 (a) has shown the case where 40, 60, 80, 100, 120, 140 mg / L is used as a PAC injection rate which comprises an injection rate group. When the PAC injection rate is 120 mg / L or less, the supernatant turbidity exceeds 1 degree. However, when the PAC injection rate is 140 mg / L, the supernatant water turbidity is 0.8 degree and satisfies the condition (1). ing. However, from the results shown in FIG. 3 (a), it is unclear whether the PAC injection rate of 140 mg / L is optimal, and the possibility of obtaining better results at a higher injection rate cannot be denied. The PAC injection rate of 140 mg / L showing the best result is the largest of the PAC injection rates included in the injection rate group, and does not satisfy the condition (2). Therefore, the injection rate group used in the jar test is not appropriate as shown in FIG. On the other hand, FIG. 3B shows a case where 100, 120, 140, 160, 180, and 200 mg / L are used as the PAC injection rate constituting the injection rate group as a black square. In FIG. 3B, the white square indicates the result shown in FIG. 3A as it is. The result shown in black in FIG. 3 (b) indicates that both of the above conditions (1) and (2) are satisfied, and the PAC injection rate of 160 mg / L is appropriate. That is, the control device should determine the injection rate group indicated by a black square in FIG.

  Actually, it is difficult to know in advance a relational expression that determines an injection rate group satisfying the two conditions (1) and (2) from the values input to the control device. Machine learning is performed to gradually generate better relational expressions and obtain better results. Therefore, the data storage unit 11 stores data indicating the relationship between the values of the input items or a combination thereof and the corresponding injection rate group. The evaluation value for the data is treated water quality. Further, in the water treatment plant, the smaller the flocculant injection rate, the more advantageous in terms of cost. Therefore, the flocculant injection rate itself may be included in the evaluation value. Data used for learning is accumulated in the data storage unit 11.

  Therefore, when performing a jar test using the control apparatus of this embodiment, first, as shown in FIG. Examples of water quality analysis include turbidity, SS, chromaticity, UV absorbance, particle concentration, temperature, pH, TOC, COD, iron concentration, manganese concentration, aluminum concentration, arsenic concentration, cadmium concentration, etc. One or more analysis items are selected from the list. Next, in step 112, a relational expression in the recording arithmetic apparatus 10 is referred to based on the value obtained by the analysis, and in step 113, a jar test condition is set based on the referenced relational expression. Specifically, the injection rate group used in the jar test is determined. There are many analysis items that can be used in Step 111, but not all of these analysis items are analyzed. Generally, turbidity or chromaticity is often measured. The injection rate group to be used is determined mainly by turbidity or chromaticity.

  Subsequently, in step 114, a jar test of the sample water is executed by the jar tester using the determined injection rate group, and the supernatant water and the filtered water are analyzed. The analysis items for supernatant water and filtered water are the same as those described in step 111, but it is particularly preferable to measure at least one of turbidity and chromaticity. Then, in step 115, as a result of the jar test, it is determined whether or not the flocculant injection rate or range that achieves the target treated water quality exists in the used injection rate group. That is, in step 115, it is determined whether or not the condition (1) is satisfied. Of course, it is particularly preferable to determine whether or not the condition (2) is satisfied at the same time. If there is a coagulant injection rate that achieves the target treated water quality, the process proceeds to step 116, and learning of data in the recording arithmetic unit 10 is performed based on the analysis results in steps 111 and 116 and the coagulant injection rate used. To finish the jar test process. Learning will be described later. On the other hand, when there is no flocculant injection rate that achieves the target treated water quality in the injection rate group in step 115, in step 117, learning is performed in the same manner as in step 116, and the condition setting is performed. Return to step 112 and change the jar test.

  Since this embodiment is premised on machine learning, initial data is required, but as initial data, the relationship between the value of the input item and the corresponding evaluation value is determined by cluster analysis or the like based on experiments or the like. It can be obtained and stored in the data storage unit 11. Or when performing a jar test for the first time, you may use the value arbitrarily determined by the user from the relationship between the visual turbidity or visual chromaticity and the amount of the flocculant injected as the injection rate group. When using turbidity, as shown in FIG. 5, sample water is poured into the predetermined transparent container 50, and turbidity is determined visually. In the determination of the turbidity by visual observation, a plurality of color samples (color charts), that is, turbidity samples each corresponding to the turbidity may be prepared, and the turbidity may be determined by comparing with the turbidity sample. As shown in FIG. 5, when the visual turbidity is classified into five stages of # 1 to # 5, an injection rate group can be defined as shown in Table 1.

  When the first injection rate group is determined by visual chromaticity, the same procedure as in the case of turbidity described here may be followed.

Next, learning in steps 116 and 117 will be described. In the present embodiment, the data learning unit 12 accumulates only data corresponding to positive examples in the data storage unit 11, and based on the accumulated data, the value of one or more input items and the coagulant injection A relational expression indicating the relationship with the rate is generated, and the generated relational expression is also stored in the data storage unit 11. When generating a relational expression using a plurality of input items, a weight may be set between the input items. Whether or not it is a positive example, when new data is generated based on the result of the jar test, with respect to the relational expression corresponding to the data, the correlation coefficient _{RA in the} data already accumulated in the data storage unit 11 and the new data determining based on the correlation coefficient result of comparing the R _B for such data. In the case of this embodiment, since the relational expression cannot be said to be a linear expression, the correlation coefficient cannot simply be obtained. Therefore, assuming that the target relational expression is represented by a function f (x), that is, when the value of the item is x, the coagulant injection rate y is represented by y = f (x). The coagulant injection rate determined by (x) is called the theoretical injection rate. At this time, the data y ′ already stored in the data storage unit 11 with respect to the relational expression varies from the relation y = f (x). Therefore, instead of obtaining a correlation coefficient between x and y ′, a correlation coefficient between y ′ and y is obtained and set as _RA . Since the new data is based on the result of the jar test, if six jar testers are used, it corresponds to six flocculant injection rates (that is, injection rate groups). Therefore, as in the case of the correlation coefficient _RA , a correlation coefficient for a plurality of (for example, six) coagulant injection rates constituting the injection rate group with respect to the theoretical injection rate is obtained. This is defined as a correlation coefficient R _B. If R _B / R _A is equal to or greater than a predetermined value, for example, 0.5 or greater, new data is accumulated in the data storage unit 11 as a positive example. The data learning unit 12 includes a relational expression representing the relationship between the value of any one or more items and the coagulant injection rate based on the data accumulated in the data storage unit 11 including newly accumulated data. Is regenerated.

  Through the processing described above, learned data and relational expressions are accumulated in the data storage unit 11 of the recording arithmetic apparatus 10. This stored relational expression can be used from outside the recording arithmetic apparatus 10, thereby making it possible to show an optimum jar test to the outside. In the case of the present embodiment, the jar test conditions determined based on the relational expression can also be obtained at the terminal 40 connected to the recording arithmetic device 10 via the network 30. Hereinafter, the form using the terminal 40 will be described. FIG. 6 shows processing in the recording arithmetic device 10 and the terminal 40 when the terminal 40 is used.

A smartphone is assumed as the terminal 40. In general, a smartphone is equipped with a camera in addition to a communication function. Therefore, it is assumed that the terminal 40 is operated by a user in a water treatment plant that is remote from the installation location of the recording arithmetic device 10.
In step 121, the sample water injected into a predetermined container is photographed by the terminal 40. The container is defined so that turbidity and chromaticity can be accurately determined. Since the shooting results may vary depending on the shooting light source and ambient light, the container is shot with a test chart printed in standard colors, and the shooting results are corrected based on the color tone and brightness of the test chart in the shooting results. Is preferred. Correction methods based on light sources and ambient light are well known. From the photographing result, for example, information such as turbidity, chromaticity, particle concentration, and transparency can be extracted and digitized. In step 122, if there is auxiliary data such as temperature, pH, TOC, and various metal concentrations for the sample water, auxiliary data of the terminal 40 is also input. By using the auxiliary data, a more preferable injection rate group can be obtained. In step 123, the photographing result (or data based thereon) and auxiliary data are sent from the terminal 40 to the recording arithmetic apparatus 10 via the network 30. Correction based on the light source and ambient light, and extraction and digitization of information from the photographing result may be performed on the terminal 40 side, or may be performed on the recording arithmetic apparatus 10 side.

  Receiving data from the terminal 40, the recording arithmetic unit 10 generates a jar test condition in step 124 using the relational expression in the data storage unit 11 based on the value of the received data in the same manner as described above. The test condition is transmitted to the terminal 40. The terminal 40 that has received the jar test condition displays the jar test condition on the screen of the terminal 40 in step 126. A user who confirms the jar test conditions displayed on the screen, particularly the extraction rate group, can perform a jar test of the sample water according to the jar test conditions.

  Even when the terminal 40 is used, learning of data stored in the data storage unit 11 can be performed. In that case, as shown in FIG. 7, the terminal 40 inputs the jar test result in step 131. Since an environment in which only a jar tester and a smartphone exist is also conceivable, the jar test result is, for example, a photographed image of sample water immediately after completion of stirring in the jar tester and a photographed image after standing for 10 minutes. Combinations may be used, and turbidity and chromaticity may be derived from these captured images. In step 132, jar test result data is transmitted from the terminal 40 to the recording arithmetic device 10. Receiving the jar test result, the recording operation device 10 performs data learning in step 133 as described above.

  According to the present embodiment described above, by using machine learning, even a less experienced worker can efficiently perform a jar test, and work time can be shortened. In addition, since the flocculant injection rate can be determined from image data taken with a smartphone or the like, water quality analysis and the like can be omitted.

  The water treatment plant targeted by the present invention is, for example, a water purification plant or a wastewater treatment plant. In the case of a water purification plant, it is known that the behavior indicated by the relationship between the value obtained by analysis or measurement and the preferred flocculant injection rate varies depending on which river water the raw water is or which area groundwater. Yes. Similarly, in the case of a wastewater treatment plant, the behavior varies depending on what the wastewater source is. Therefore, in the case of a water purification plant, data and relations are stored in the data storage unit 11 according to the water system such as the A river water system or the B river water system, and in the case of a waste water treatment plant, depending on what process the waste water is from. It is preferable to manage the equations and perform learning by water system and process. Thus, by implementing the control method based on the present invention by distinguishing between water systems and processes, a more appropriate flocculant injection rate can be obtained by short-term learning.

DESCRIPTION OF SYMBOLS 10 Record arithmetic unit 11 Data storage part 12 Data learning part 13 Condition determination part 30 Network 40 Terminal

Claims (12)

A control method for determining a flocculant injection rate for a jar test using the raw water as a sample water in a water treatment plant for treating the raw water by adding a flocculant to the raw water,
Multiple flocculant injection rates used in a single jar test by a jar tester are used as an injection rate group.
A record for storing data obtained by analyzing or measuring one or more items with respect to the sample water and the treated water after the jar test, and the flocculant injection rate, which has been subjected to a learning process. Use the arithmetic unit,
In the recording arithmetic device, based on the accumulated data, generate a relational expression representing the relationship between the value of any one or more items and the coagulant injection rate,
In the recording arithmetic device, the flocculant injection rate constituting the injection rate group is determined from the relational expression based on the input value,
The learning step is based on a result of a jar test using the determined injection rate group, and for any relational expression, a coagulant injection rate calculated from the relational expression is set as a theoretical injection rate with respect to the theoretical injection rate. The correlation coefficient with the coagulant injection rate in the injection rate group corresponding to the result is not less than a predetermined multiple of the correlation coefficient with the coagulant injection rate used to generate the relational expression with respect to the theoretical injection rate. A control method including a step of adding and storing data corresponding to the result in the recording operation device.   The control method according to claim 1, wherein the predetermined multiple is 0.5 times.   The one or more items include turbidity, suspended solid content, chromaticity, ultraviolet absorbance, particle concentration, temperature, pH, total organic carbon, chemical oxygen demand, iron concentration, manganese concentration, aluminum concentration, arsenic concentration, and The control method according to claim 1, comprising at least one of cadmium concentrations.   The control method according to any one of claims 1 to 3, wherein when the jar test is performed for the first time, a predetermined injection rate group is used for visual turbidity or chromaticity. Photograph the sample water with a terminal,
In the recording operation device, the injection rate group is determined by applying a value obtained from the imaging result to the relational expression relating to an item obtained from the imaging result sent from the terminal,
The control method according to any one of claims 1 to 4, wherein the determined injection rate group is notified from the recording operation device to the terminal.   The control method according to claim 5, wherein the learning step is performed in the recording arithmetic device based on data transmitted from the terminal. A control device for determining a flocculant injection rate for a jar test using the raw water as sample water in a water treatment plant for treating the raw water by adding a flocculant to the raw water,
Multiple flocculant injection rates used in a single jar test by a jar tester are used as an injection rate group.
A data storage unit for accumulating data of the value obtained by analyzing or measuring one or more items with respect to the sample water and the treated water after the jar test and the flocculant injection rate;
Based on the data stored in the data storage unit, a relational expression representing the relationship between the value of any one or more items and the coagulant injection rate is generated, and learning is performed on the data stored in the data storage unit A data learning unit that executes processing;
A condition determining unit for determining a flocculant injection rate constituting the injection rate group from the relational expression based on an input value;
Have
In the learning process, based on the result of the jar test using the determined injection rate group, for any relational expression, the coagulant injection rate calculated from the relational expression is set as the theoretical injection rate, and the theoretical injection rate The correlation coefficient with the coagulant injection rate in the injection rate group corresponding to the result is not less than a predetermined multiple of the correlation coefficient with the coagulant injection rate used to generate the relational expression with respect to the theoretical injection rate. Sometimes, the control device adds and stores data corresponding to the result in the data storage unit.   The control device according to claim 7, wherein the predetermined multiple is 0.5 times.   The one or more items include turbidity, suspended solid content, chromaticity, ultraviolet absorbance, particle concentration, temperature, pH, total organic carbon, chemical oxygen demand, iron concentration, manganese concentration, aluminum concentration, arsenic concentration, and The control device according to claim 7 or 8, comprising at least one of the cadmium concentrations.   The control device according to any one of claims 7 to 9, wherein when the jar test is performed for the first time, a predetermined injection rate group is used for visual turbidity or chromaticity. A terminal is connected to the control device;
When the imaging result is sent from the terminal that images the sample water, the condition determining unit applies the value obtained from the imaging result to the relational expression relating to the item obtained from the imaging result, and the injection rate The control device according to any one of claims 7 to 10, wherein a group is determined and the determined injection rate group is notified to the terminal. The control device according to claim 11, wherein the data learning unit performs the learning process in the recording arithmetic device based on data transmitted from the terminal.

Images