JP2017042746A - Kneading system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a kneading system capable of constantly maintaining a compounding proportion of active material and binder in a mixture for electrode manufactured by a kneader.SOLUTION: A kneading system 1 includes: an active substance projection part 41 capable of adjusting a projection amount of an active substance; a binder projection part 43 capable of adjusting a projection amount of binder; a biaxial extruding kneader 10 which mixes the active substance projected from the active substance projection part and the binder projected the binder projection part, rotates a shaft part 13 to which a first agitator 23 is fixed and, thereby, performs thick kneading of the active substance and the binder; a driving part 11 which rotates the shaft part; a detector 15 which detects a load applied onto the driving part; and a control part 60 which controls a projection amount on the binder projection part such that the load detected by the detection part gets to a peak value.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a kneading system.

  Power storage devices such as secondary batteries and capacitors are widely used as power sources because they can be recharged and can be used repeatedly. Conventionally, lithium-ion secondary batteries, nickel-hydrogen secondary batteries, and the like are known as power storage devices mounted on vehicles such as EVs (Electric Vehicles) and PHVs (Plug-in Hybrid Vehicles). In these secondary batteries, an electrode having an active material layer formed by applying a paste-like or slurry-like active material mixture containing an active material to the surface of a metal foil is laminated or wound with a separator interposed therebetween. For example, the electrode assembly is formed, and the electrode assembly is housed in a case.

  Preparation of an electrode active material mixture in paste form or slurry (hereinafter simply referred to as “electrode mixture”) is performed by kneading at least an active material, a binder, and a solvent. Specifically, a method is used in which an active material and a binder are mixed and kneaded (solid kneaded), and then diluted with a solvent. For such kneading, for example, two rotating shafts are arranged in the kneading chamber, and the active material and binder introduced by the feed screw supported by the rotating shaft are supported by the rotating shaft while being sent from upstream to downstream. When the kneading of the raw material is completed once in the twin-screw extrusion kneader (for example, Patent Document 1) or a kneader tank stirred by a barrel (stirring body), the slurry-like electrode is used. A batch-type kneader capable of recovering the mixture (for example, Patent Document 2) is used.

JP 2011-83703 A JP 2009-22890 A

  The electrode mixture produced by the kneader is required to maintain a constant quality by keeping the blending ratio of the active material and the binder constant during solidification.

  Then, an object of this invention is to provide the kneading | mixing system which can maintain the mixing | blending ratio of the active material and binder at the time of solid mixing in the electrode mixture manufactured with a kneading machine constant.

  The kneading system of the present invention includes an active material input unit capable of adjusting an input amount of an active material, a binder input unit capable of adjusting an input amount of a binder, an active material input from the active material input unit, and a binder input unit. While mixing the binder to be charged, the kneading part for kneading the active material and the binder by rotating the shaft part to which the stirring body is fixed, the drive part for rotating the shaft part, and the load applied to the drive part The detection unit to detect and the load detected by the detection unit to be a predetermined value or a predetermined range between a first target value at which the peak value is reached and a second target value lower than the first target value. And a control unit for controlling the input amount in the material input unit and / or the input amount in the binder input unit.

  In this kneading system, when the active material and the binder are kneaded, the input of the active material is based on the phenomenon that the “load” reaches a peak value when the “mixing ratio of the binder and the active material” reaches a predetermined value. At least one of the input amount in the section and the input amount in the binder input section is controlled. In other words, if the blending ratio of the active material and the binder is adjusted so that the “load” has a peak value, the blending ratio of the active material and the binder becomes constant. In this kneading system, even when the blending ratio of the active material and the binder is not known in advance, the load is lower than the first target value and the first target value at which the load becomes a peak value (viscosity is a peak value). Since at least one of the input amount in the active material input unit and the input amount in the binder input unit is adjusted so as to be a predetermined value or a predetermined range between the second target value, the blending ratio of the binder and the active material is constant. Or it can be in a certain range. As a result, the mixing ratio of the active material and the binder in the electrode mixture produced by the kneader can be maintained in a constant or constant range.

  In the kneading system of the present invention, the kneading parts are respectively supported by the two shaft parts while feeding the active material and the binder in one direction by the feed bodies respectively supported by the two shaft parts arranged in parallel to each other. Alternatively, a twin-screw extrusion kneader that stirs the active material and the binder with a stirring body may be used.

  According to the kneading system having this configuration, the mixing ratio of the active material and the binder is kept constant even when the active material and the binder are kneaded using a twin-screw extrusion kneader to produce an electrode mixture. can do.

  In the kneading system of the present invention, the load applied to the drive unit may be detected as a current value or a power value supplied to the drive unit.

  According to the kneading system having this configuration, the load applied to the drive unit can be easily acquired.

  In the kneading system of the present invention, the control unit has a determination control unit and a preparation control unit, and the determination control unit is input to the kneading unit when the load by the detection unit falls outside the specified range. The first control for gradually or stepwise decreasing the ratio of the amount of the active material to be added to the binder, or gradually or stepwise increasing the ratio of the amount of the active material to be input to the kneading part. The active material input unit and / or the binder input unit are controlled so as to perform the second control, and the preparation control unit starts the second control when the load decreases when the first control is executed. The second control is continued until the load starts to decrease. When the load does not decrease, the first control is started, and the first control is continued until the load starts decreasing. To control the active material input part and / or the binder input part, When the load does not increase when the second control is executed, the first control is started. The first control is continued until the load starts to decrease, and when the load increases, the second control is started. The active material charging unit and / or the binder charging unit may be controlled to execute the second preparation, in which the second control is continued until the load starts to decrease.

  According to the kneading system having this configuration, the control content is such that the load applied to the drive unit becomes the above-described predetermined value or the predetermined range by the control by the determination control unit without storing the peak value of the load. (Adjustment content of input amount of active material and / or binder) is determined. Then, the preparation control unit continues the control content determined by the determination control unit until the load reaches the predetermined value or the predetermined range. As a result, at least one of the input amount in the active material input part and the input amount in the binder input part is adjusted so that the load (viscosity) becomes the above-mentioned predetermined value or a predetermined range. The ratio can be constant or in a certain range.

  In the kneading system of the present invention, the determination control unit may execute the first control by controlling the binder charging unit, and the preparation control unit may execute the first preparation by controlling the binder charging unit.

  Fine adjustment of the raw material supply amount can be performed more easily and accurately with liquid supplied by a pump or the like than powder supplied by a feeder or the like. According to the kneading system having this configuration, since the supply control of the binder supplied by a pump or the like is performed, the first preparation can be performed easily and accurately.

  ADVANTAGE OF THE INVENTION According to this invention, the mixture ratio of the active material and binder in the electrode mixture manufactured with a kneader can be maintained constant.

It is a lineblock diagram showing a schematic structure of a kneading system concerning one embodiment. It is a functional block diagram of the kneading system of FIG. It is a flowchart which shows an example of the kneading | mixing process control which concerns on one Embodiment. It is a flowchart which shows an example of the kneading | mixing process control which concerns on a modification. 5 is a graph showing the relationship between “ratio of input amount of active material to input amount of binder” and “current value”.

  Hereinafter, an embodiment will be described with reference to the drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted. The dimensional ratios in the drawings do not necessarily match those described.

  The kneading system 1 will be described by taking as an example the production of a positive electrode mixture (electrode mixture) for a lithium ion battery as a secondary battery. The raw material of the positive electrode mixture is, for example, a positive electrode active material made of a metal composite oxide of lithium and a transition metal, such as a lithium / manganese composite oxide, a lithium / cobalt composite oxide, or a lithium / nickel composite oxide, A conductive agent such as acetylene black, a binder such as polyvinylidene fluoride (PVDF), and a solvent such as N-methylpyrrolidone (NMP) are included. Moreover, a thickener etc. may be contained as needed. In addition, the raw material of the positive electrode mixture is not limited to the above-described substances, and may be appropriately changed.

  As shown in FIG. 1, the kneading system 1 includes a twin-screw extrusion kneader 10, a detector (detection unit) 15, an active material charging unit 41, a binder charging unit 43, a solvent charging unit 45, and a control. Part 60.

  The biaxial extrusion kneader 10 includes a pair of shaft portions 13 (the other shaft portion 13 is disposed on the back side in FIG. 1), a case 3, and a drive unit. 11, a first supply unit 5 </ b> A, a second supply unit 5 </ b> B, and a discharge unit 7.

  Case 3 supports a pair of axial parts 13 rotatably. The drive unit 11 drives the pair of shaft portions 13. The first supply unit 5 </ b> A is disposed below the active material input unit 41 and the binder input unit 43, and the active material input from the active material input unit 41 and the binder input from the binder input unit 43 are disposed in the case 3. Supply inside. The second supply unit 5 </ b> B is disposed below the solvent supply unit 45 and supplies the solvent supplied from the solvent supply unit 45 to the inside of the case 3. The discharge unit 7 discharges the electrode mixture produced inside the case 3 to the outside of the case 3.

  A first feed screw (feed body) 21, a first stirring body 23, a second feeding screw 25, and a second stirring body 27 are supported on the two shaft portions 13 arranged in parallel to each other. Has been. The 1st feed screw 21 conveys the active material and binder supplied from 5 A of 1st supply parts to the arrow D direction. The first stirrer 23 stirs while conveying the active material and binder supplied from the first supply unit 5A in the direction of arrow D. In other words, the active material and the binder are flown by the first stirrer 23 and dispersed by applying a shearing force to obtain a kneaded product in a desired kneaded state.

  The 2nd feed screw 25 conveys the active material and binder supplied from the 1st stirring body 23, and the solvent supplied from the 2nd supply part 5B in the arrow D direction. The second stirrer 27 stirs while conveying the active material and binder supplied from the first stirrer 23 and the solvent supplied from the second supply unit 5B in the direction of arrow D. In other words, the active material, the binder, and the solvent are flowed by the second stirrer 27, and the active material and the binder are diluted with the solvent and discharged from the discharge unit 7 as a slurry-like electrode mixture.

  The detector 15 detects a load applied to the drive unit 11 of the twin-screw extrusion kneader 10. In the present embodiment, the detector 15 detects the current value supplied to the drive unit 11. The load applied to the drive unit 11 is power consumed by the drive unit 11 and is proportional to the current value.

  The active material input unit 41 inputs the active material into the case 3 through the first supply unit 5A. The active material input unit 41 is, for example, a feeder. Adjustment of the input amount of the active material is performed by the control unit 60 controlling the rotation of the motor that drives the feeder.

  The binder loading unit 43 loads the binder into the case 3 via the first supply unit 5A. The binder charging unit 43 is, for example, a pump. Adjustment of the input amount of the binder is performed by the control unit 60 controlling the frequency of the motor that drives the pump.

  The solvent charging unit 45 charges the solvent into the case 3 via the second supply unit 5B. The solvent charging unit 45 is, for example, a pump. Adjustment of the input amount of the solvent is performed by the control unit 60 controlling the frequency of the motor that drives the pump.

  The control unit 60 is a part that executes various control processes in the kneading system 1, and is an electronic control unit including, for example, a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. As shown in FIG. 2, the control unit 60 includes an information acquisition unit 61, a determination control unit 63, and a preparation control unit 65 as conceptual parts for executing various control processes in the kneading system 1. ing. For such a conceptual part, for example, a program stored in the ROM is loaded onto the RAM and executed by the CPU.

  The information acquisition unit 61 acquires the current value supplied from the detector 15 to the drive unit 11. The information acquisition unit 61 may acquire the current value transmitted from the detector 15 or may issue a command to the detector 15 to transmit the current value.

  When the current value acquired by the information acquisition unit 61 is outside the specified range, the determination control unit 63 temporarily determines the ratio of the input amount to the binder of the active material input to the twin-screw extrusion kneader 10. Control that gradually decreases (or stepwise), in other words, temporarily controls (first control) to gradually decrease (or stepwise) the ratio of the active material in the electrode mixture. In addition, the binder loading unit 43 is controlled. Specifically, the determination control unit 63 controls the binder insertion unit 43 so that the amount of the binder supplied per unit time increases gradually (or stepwise).

  When the current value decreases when the control of the binder charging unit 43 by the determination control unit 63 is executed, the preparation control unit 65 determines the amount of the active material to be charged to the binder into the twin-screw extrusion kneader 10. Control for gradually increasing the ratio (or stepwise), in other words, control for gradually increasing the ratio of the active material in the electrode mixture (or stepwise) (second control) is executed. Specifically, the preparation control unit 65 controls the binder charging unit 43 so as to gradually (or stepwise) reduce the current supply amount of the binder per unit time. The preparation control unit 65 continues the execution of the second control until the current value starts to decrease.

  If the current value does not decrease when the control of the binder loading unit 43 by the determination control unit 63 is executed, the preparation control unit 65 throws the active material to the binder into the twin-screw extrusion kneader 10 Control that gradually decreases the ratio of the amount (or stepwise), in other words, executes control (first control) that gradually decreases (or stepwise) the ratio of the active material in the electrode mixture. . Specifically, the preparation control unit 65 controls the binder charging unit 43 so as to gradually (or stepwise) increase the amount of binder supplied per unit time. The preparation control unit 65 continues the execution of the first control until the current value starts to decrease.

  In addition to the above control, the control unit 60 adjusts the amount of solvent supplied per unit time in the solvent charging unit 45. For example, the supply amount of the solvent per unit time in the solvent supply unit 45 may be adjusted based on the viscosity of the slurry-like electrode mixture discharged from the discharge unit 7.

  Next, kneading control (first preparation) in the kneading system 1 of the embodiment will be described mainly with reference to FIG. First, the preparation control unit 65 sets the amount of binder input (hereinafter, also referred to as “initial setting value V0”) during the previous steady kneading (step S1). Specifically, when the equipment is activated, a setting is made such that the amount of binder input per unit time input from the binder input unit 43 becomes the initial setting value V0. Note that the input amount of the active material per unit time is constant at the input amount B0.

  The equipment is activated with the settings made in step S1. That is, the kneading of the active material and the binder by the twin-screw extrusion kneader 10 shown in FIG. 1 is started (step S2). The determination control unit 63 monitors that the current value acquired by the information acquisition unit 61 is within the specified range (step S3: NO). Here, when the current value acquired by the information acquisition unit 61 is out of the specified range (step S3: YES), the determination control unit 63 controls the binder input unit 43 to input the binder per unit time. Control (first control) is performed so as to temporarily increase the amount (step S4).

  The preparation control unit 65 monitors whether or not the current value acquired by the information acquisition unit 61 decreases due to the increase in the binder amount in step S4 (step S5). Here, when the current value decreases (step S5: YES), the preparation control unit 65 controls the binder charging unit 43 to gradually (or stepwise) decrease the amount of binder charged per unit time. Control (second control) is performed (step S6). Then, the preparation control unit 65 gradually (or stepwise) decreases the input amount of the binder per unit time until the current value acquired by the information acquisition unit 61 starts to decrease (step S7: NO). ).

  When the current value acquired by the information acquisition unit 61 starts to decrease (step S7: YES), the preparation control unit 65 causes the binder input unit 43 to change when the current value starts to decrease (a peak value is reached). The binder input amount V1 (<V0) per unit time supplied to the shaft extrusion kneader 10 is set as the binder input amount V1 (reset value V1) during steady kneading (step S10).

  If the current value does not decrease in step S5 (step S5: NO), the preparation control unit 65 controls the binder loading unit 43 to gradually (or step) the amount of binder charged per unit time. Control) (first control) to increase the amount (step S8). Then, the preparation control unit 65 gradually (or stepwise) increases the input amount of the binder per unit time until the current value acquired by the information acquisition unit 61 starts to decrease (step S9: NO). .

  When the current value acquired by the information acquisition unit 61 starts to decrease (step S9: YES), the preparation control unit 65 causes the binder input unit 43 to change when the current value starts to decrease (a peak value is reached). The binder input amount V2 (> V0) per unit time supplied to the shaft extrusion kneader 10 is set as the binder input amount V2 (reset value V2) during steady kneading (step S10).

  Thus, by performing the process of step S1-step S10, the mixture ratio of the active material and binder in the electrode mixture manufactured with the twin-screw extrusion kneader 10 can be maintained constant.

  Next, the effect of the kneading system 1 of the above embodiment will be described. In the kneading system 1, as shown in FIG. 5, when the active material and the binder are kneaded, the “current value” reaches the peak value when the “blending ratio of the binder and the active material” reaches a predetermined value. Based on this phenomenon, the input amount in the binder input unit 43 is controlled. That is, in the kneading system 1 of the above-described embodiment, even if the mixing ratio of the active material and the binder is not known in advance, the binder charging unit 43 so that the current value becomes a peak value (viscosity is a peak value). Since the input amount is adjusted, the blending ratio of the binder and the active material can be made constant.

  In FIG. 5, for example, when the current value A acquired by the information acquisition unit 61 is out of a predetermined range (for example, P1 <A <P), the determination control unit 63 temporarily stores the electrode mixture. Assume that control (first control) is performed to gradually (or stepwise) reduce the ratio of the active material. Thereby, when a current value falls, the state of the mixture ratio of a binder and an active material exists in the left side (for example, S1) rather than the case where it becomes a peak value. Therefore, when the preparation control unit 65 performs control (second control) in which the ratio of the active material in the electrode mixture is gradually (or stepwise) increased, the current value gradually approaches the peak value, and eventually. It starts to decline. In the present embodiment, control is performed so as to continue the state of the blending ratio of the binder and the active material when the current value starts to decrease. Thereby, the mixture ratio of an active material and a binder can be maintained constant.

  On the other hand, when the current value does not decrease due to the first control performed by the determination control unit 63, the state of the blending ratio of the binder and the active material is on the right side of the peak value (for example, S2). ) Therefore, when the preparation control unit 65 performs control (first control) to gradually (or stepwise) reduce the ratio of the active material in the electrode mixture, the current value gradually approaches the peak value, and eventually. It starts to decline. In the present embodiment, control is performed so as to continue the state of the blending ratio of the binder and the active material when the current value starts to decrease. Thereby, the mixture ratio of an active material and a binder can be maintained constant.

  In the kneading system 1 of the above embodiment, the supply amount of the binder supplied to the twin screw extrusion kneader 10 can be adjusted. Therefore, the active material and the binder are kneaded using the twin screw extrusion kneader 10 to combine the electrodes. Even when the agent is produced, the blending ratio of the active material and the binder can be kept constant.

  In the kneading system 1 of the above embodiment, the current value supplied to the drive unit 11 as a load applied to the drive unit 11 is acquired. Since the biaxial extrusion kneader 10 often has a function of monitoring the current value supplied to the drive unit 11, the drive unit can be provided without separately providing a device for measuring the load applied to the drive unit 11. 11 can be easily acquired.

  As mentioned above, although one Embodiment of this invention was described, this invention is not limited to the said embodiment, A various change is possible in the range which does not deviate from the meaning of invention.

<Modification 1>
In the said embodiment, although the example in which the kneading part was formed as a continuous biaxial extrusion kneader was mentioned and demonstrated, this invention is not limited to this. For example, a batch kneader may be used. An example of a batch-type kneader is a tank main body that contains raw materials including at least an active material, a binder, and a solvent, a stirring unit that kneads the raw materials in the tank main body, and discharges the raw materials after being kneaded in the tank main body. And a discharge portion to be provided. The stirring unit includes a plurality of blades, and the plurality of blades knead the active material, the binder, and the solvent while performing a planetary motion in the tank body. In such a batch-type kneader, the slurry-like electrode mixture can be recovered from the discharge port of the tank when the raw materials are kneaded once in the tank.

  For such a kneader, the above-described detector (detection unit) 15 provided in the twin-screw extrusion kneader 10, an active material charging unit 41, a binder charging unit 43, a solvent charging unit 45, and a control May be provided as a kneading system. Even in the kneading system having such a configuration, the mixing ratio of the active material and the binder in the electrode mixture produced by the kneader can be kept constant.

<Modification 2>
In the embodiment described above, an example in which the current value supplied to the drive unit 11 is acquired as the load applied to the drive unit 11 has been described. However, instead, for example, a power value may be acquired. Further, the torque applied to the drive unit 11 may be detected as the load applied to the drive unit 11. In this case, a torque sensor may be provided between the drive unit 11 and the case 3. Moreover, you may make it acquire the kneading | mixing stress at the time of kneading | mixing an active material and a binder as a load concerning the drive part 11. FIG.

<Modification 3>
In the said embodiment, when the electric current value acquired by the information acquisition part 61 becomes out of a regulation range, the determination control part 63 is with respect to the binder of the active material thrown into the twin-screw extrusion kneader 10 temporarily. Although the example which controls the binder injection | throwing-in part 43 so that the control (1st control) which reduces the ratio of input amount gradually (or stepwise) was given and demonstrated, it replaced with this and temporarily Further, the control (second control) of gradually (or stepwise) increasing the ratio of the input amount of the active material input to the twin-screw extrusion kneader 10 to the binder may be performed. Hereinafter, kneading control (second preparation) when the determination control unit 63 executes the second control will be described with reference to FIG.

  The determination control unit 63 performs control (second control) so as to temporarily reduce the input amount of the binder per unit time by controlling the binder input unit 43 (step S21). The unit 65 monitors whether or not the current value acquired by the information acquisition unit 61 decreases due to the decrease in the binder amount in step S21 (step S22). Here, when the current value increases (step S22: YES), the preparation control unit 65 controls the binder loading unit 43 to gradually (or stepwise) decrease the amount of loading of the binder per unit time. Control (second control) is performed (step S23). Then, the preparation control unit 65 gradually (or stepwise) reduces the input amount of the binder per unit time until the current value acquired by the information acquisition unit 61 starts to decrease (step S24: NO). .

  When the current value acquired by the information acquisition unit 61 starts to decrease (step S24: YES), the preparation control unit 65 causes the binder input unit 43 to change when the current value starts to decrease (a peak value is reached). The binder input amount V3 (<V0) per unit time supplied to the shaft extrusion kneader 10 is set as the binder input amount V3 (reset value V3) during steady kneading (step S27).

  If the current value does not increase in step S22 (step S22: NO), the preparation control unit 65 controls the binder insertion unit 43 to gradually (or step) the amount of binder input per unit time. Control) (first control) so as to increase (step S25). Then, the preparation control unit 65 gradually (or stepwise) increases the input amount of the binder per unit time until the current value acquired by the information acquisition unit 61 starts to decrease (step S26: NO).

  When the current value acquired by the information acquisition unit 61 starts to decrease (step S26: YES), the preparation control unit 65 causes the binder input unit 43 to change when the current value starts to decrease (a peak value is reached). The binder input amount V4 (> V0) per unit time supplied to the shaft extrusion kneader 10 is set as the binder input amount V4 (reset value V4) during steady kneading (step S27).

<Modification 4>
In the above-described embodiment or modification, an example in which the input amount in the binder input unit 43 is controlled in executing the first control or the second control has been described. For example, the input amount in the active material input unit 41 is controlled. It is also possible to control both the input amount in the active material input unit 41 and the input amount in the binder input unit 43.

<Other variations>
In the embodiment or the modification described above, an example in which the input amount in the active material input unit 41 and / or the input amount in the binder input unit 43 is controlled so that the current value becomes the peak value P has been described. As shown in FIG. 5, the active value is set to a predetermined value or a predetermined range between the first target value T1 at which the current value becomes the peak value P and the second target value T2 lower than the first target value T1. The input amount in the substance input unit 41 and / or the input amount in the binder input unit 43 may be controlled.

  Specifically, the input amount in the active material input unit 41 and / or the input amount in the binder input unit 43 is, for example, a predetermined value t1 between the first target value T1 and the second target value T2. It may be controlled. Further, in the active material charging unit 41, for example, a predetermined value t1 or more between the first target value T1 and the second target value T2, or a predetermined value t2 or more and a predetermined value t3 or less. The input amount and / or the input amount in the binder input unit 43 may be controlled.

  In the said embodiment or modification, although the kneading | mixing system 1 was demonstrated taking manufacture of the mixture for positive electrodes (electrode mixture) as an example, even if it is a case where the mixture for negative electrodes (electrode mixture) is manufactured, The kneading system 1 can be applied. The raw material of the negative electrode mixture in this case is, for example, an active material such as graphite, a thickener such as carboxycellulose (CMC), and water that can function as a binder such as styrene butadiene block copolymer (SBR). It may contain a polymer to be dispersed and a solvent such as water. In addition, the shear force applied during the kneading of the active material and the binder is greater in the case of producing the positive electrode mixture than in the case of producing the negative electrode mixture. Therefore, the kneading system according to the embodiment or the modified example is more effective when the positive electrode mixture is manufactured.

  DESCRIPTION OF SYMBOLS 1 ... Kneading system, 3 ... Case, 5A ... 1st supply part, 5B ... 2nd supply part, 7 ... Discharge part, 10 ... Biaxial extrusion kneader (kneading part), 11 ... Drive part, 13 ... Shaft part, DESCRIPTION OF SYMBOLS 15 ... Detector (detection part), 21 ... 1st feed screw (feed body), 23 ... 1st stirring body, 25 ... 2nd feeding screw, 27 ... 2nd stirring body, 41 ... Active material injection | throwing-in part, 43 ... Binder input unit, 45 ... solvent input unit, 60 ... control unit, 61 ... information acquisition unit, 63 ... determination control unit, 65 ... preparation control unit.

Claims (5)

An active material input unit capable of adjusting the input amount of the active material;
A binder input unit capable of adjusting the amount of binder input;
The active material charged from the active material charging unit and the binder charged from the binder charging unit are mixed, and the active material and the binder are fixed by rotating a shaft portion to which a stirrer is fixed. A kneading section to knead;
A drive section for rotating the shaft section;
A detection unit for detecting a load applied to the drive unit;
The active material input so that the load detected by the detection unit is a predetermined value or a predetermined range between a first target value that is a peak value and a second target value that is lower than the first target value. A control unit for controlling the input amount in the unit and / or the input amount in the binder input unit;
A kneading system.   The kneading part was supported by the two shaft parts while feeding the active material and the binder in one direction by a feed body respectively supported by the two shaft parts arranged in parallel to each other. The kneading system according to claim 1 which is a twin screw extrusion kneader which stirs said active material and said binder with a stirring body.   The kneading system according to claim 1, wherein the load applied to the driving unit is detected as a current value or a power value supplied to the driving unit. The control unit has a determination control unit and a preparation control unit,
The determination control unit gradually or stepwise reduces the ratio of the amount of the active material charged into the kneading unit to the binder when the load by the detection unit is out of a specified range. The active material charging unit and / or the binder are controlled so as to perform a first control or a second control of gradually or stepwise increasing the ratio of the amount of the active material charged into the kneading unit to the binder. Control the input part,
The preparation control unit
When the load is reduced when the first control is executed, the second control is started, the second control is continued until the load starts to decrease, and the load is not reduced. Starting the first control, continuing the first control until the load starts to decrease, controlling the active material charging unit and / or the binder charging unit to perform the first preparation,
When the load is not increased when the second control is executed, the first control is started, the first control is continued until the load starts to decrease, and the load is increased. Starting the second control and continuing the second control until the load starts to decrease; controlling the active material charging unit and / or the binder charging unit to perform a second preparation;
The kneading system according to any one of claims 1 to 3. The determination control unit executes the first control by controlling the binder charging unit,
The kneading system according to claim 4, wherein the preparation control unit executes the first preparation by controlling the binder charging unit.

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