JP5785918B2 - Heating roll, roll press machine, roll press method - Google Patents

Description

  The present invention relates to a heating roll, a roll press machine, and a roll press method.

  The roll press is used for compression processing of a continuous sheet-like electrode material for a secondary battery. Moreover, in the roll press machine for shaping | molding electrode materials for secondary batteries etc., warm press work is performed. A heating roll such as a drilled roll is used for warm pressing.

  Thermal expansion occurs in the heating roll by heating the roll itself. And in a heating roll, temperature distribution generate | occur | produces inside a roll by the heat radiation from the contact surface with external air. The temperature distribution is formed so that the temperature of the roll end face is low. Due to the temperature difference based on the temperature distribution in the roll width direction (roll axis direction), the amount of thermal expansion of the heating roll varies in the roll width direction, with the central portion being large and the both ends being small. For this reason, the heating roll undergoes thermal deformation having a convex crown shape (generation of a thermal crown).

  As a technique corresponding to such a thermal crown, for example, there is a technique described in Patent Document 1. In Patent Literature 1, both ends in the axial direction of the roll are covered with a heat insulating material to suppress heat radiation from both end faces, and the temperature distribution in the axial direction inside the roll is made uniform to reduce the amount of thermal crown generated. It is described to do.

JP 2005-288535 A

  By applying a heat insulating material to the roll end surface as described in Patent Document 1, it is possible to reduce the amount of heat dissipation as compared with the case where there is no heat insulating material, but it is difficult to make heat dissipation zero.

  On the other hand, in compression processing of electrode materials for secondary batteries and the like, the required thickness accuracy after compression processing of materials is strict, for example, about ± 2 μm, and in recent years, higher accuracy is desired (± 1-2 μm). . Therefore, in order to perform highly accurate compression processing, it is important to make the convex crown generated on the heating roll as small as possible.

  An object of the present invention is to provide a heating roll, a roll press machine, and a roll press method capable of reducing the convex crown generated in the heating roll.

The present invention were provided with a heater on the roll end face of the axially opposite sides of the heating roll, characterized in that spaced apart from the end surfaces of the rolls facing each heater.

  According to the present invention, it is possible to positively suppress the temperature decrease of the roll end face, and to effectively reduce the convex crown generated on the heating roll. As a result, it is possible to suppress a change in roll accuracy due to thermal deformation of the roll in the heating roll, and to perform highly accurate compression processing.

  Problems, configurations, and effects other than those described above will be clarified by the following description of embodiments.

Sectional drawing of the heating roll which is one Example of this invention. Sectional drawing of the heating roll which is another Example of this invention. The front view of the roll press machine with which the heating roll of this invention is used. The front view of the other roll press machine in which the heating roll of this invention is used. The line general view of the roll press equipment in which the roll press machine of this invention is used.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a sectional view of a heating roll according to an embodiment of the present invention. The press working is performed using a pair of upper and lower rolls as shown in FIGS. The heating roll of the present invention is used for either one or both (basically used for both).

  A roll used for compression molding of an electrode material for a secondary battery or the like is important in terms of cylindricity, roundness, and runout accuracy, and is configured to have an accuracy of about 1 to 4 μm. Moreover, since it is used also for the compression process by a high linear pressure, high rigidity is required, Therefore The solid roll is employ | adopted as a structure of a roll. And since it uses for a warm press process, a temperature rising mechanism is used for a roll. Although the illustration of the temperature raising mechanism is omitted in FIG. 1, for example, as described in Patent Document 1, a heat medium flow path for allowing a heat medium such as oil to flow inside the roll is formed inside the roll. Such a heating roll is called a drilled roll.

  In such a heating roll, if the temperature distribution in the roll width direction (including the internal temperature distribution) can be made uniform, the occurrence of a convex crown can be prevented. In other words, the thermal expansion difference is caused by the difference in the roll radial temperature distribution in the roll width direction, and the temperature inside the roll in the roll end surface side is caused by the heat radiation from the roll end surface to the axial central portion side of the roll. Since it is caused by lowering the temperature inside the roll in the radial direction, it is possible to prevent the occurrence of a convex crown by eliminating heat radiation from the roll end face.

  Ideally, if the roll is long enough not to be affected by temperature spots due to heat dissipation from the end face, the temperature distribution in the width direction will not change substantially. Although it can be made, such a structure is not feasible.

  As a practical method, conventionally, as described in Patent Document 1, a method of installing a heat insulating material on the roll end surface has been considered. However, with a heat insulating material, heat dissipation is reduced to zero with only a small amount of heat dissipation. I can't do it.

  Therefore, in the present invention, the roll end surface is heated from the outside, and the temperature decrease of the roll end surface (inside the radial direction of the roll) is positively suppressed. In this embodiment, specifically, the heater 20 is provided to face the roll end face. The heater 20 is provided in an annular shape so as to face the entire circumference of the roll. In this embodiment, the heater is set apart from the roll end face and heated mainly by radiation. An electric heater is used as the heater, but is not limited thereto.

  In this embodiment, the heater is disposed away from the roll end face, but may be attached to the roll end face. When a heater is attached to the roll end face, the heater rotates together with the roll, and thus a device (sliding contact or the like) is required for wiring or the like. Such a device is not necessary when the heater is installed away from the roll end face.

  In this embodiment, an annular heating plate (soaking plate) 23 is interposed in order to reduce heating spots on the roll end face. That is, if there is variation in the heat of the heater, it will lead to roll heating spots, so it is desirable that the heating surface temperature be within ± 2 ° C. Soaking the heating surface to about ± 2 ° C. can be performed relatively easily by installing a heating plate (soaking plate) 23 on the heating surface of the heater. When the heating plate 23 is interposed, the heating plate surface serves as a heating surface for the rotor end surface. In order to equalize the temperature of the heating surface, it is desirable that the heating plate has a certain thickness or more. For the purpose of temperature equalization, the thickness of the heating plate is preferably about 5 mm to 30 mm, assuming a roll diameter of about φ300 mm to φ1000 mm, for example. However, it is not limited to this. As the heating plate, aluminum or the like having a relatively good thermal conductivity is used. Thereby, it becomes possible to heat a roll end surface from the temperature-equalized surface.

  In addition to installing the heating plate (soaking plate) 23 or instead of installing the heating plate (soaking plate) 23, the heater is divided into two or more in the vertical direction of the roll end face. Each may be temperature controlled. Since there is a temperature difference in the upper and lower planes, the in-plane temperature distribution is easily adjusted by dividing and adjusting the in-plane output. Instead of the upper and lower divisions, or in addition to the upper and lower divisions, the heaters may be divided in the left-right direction so as to control the temperature of each.

  When the heater is installed away from the roll end face, even if there is some temperature spots on the heater heating face, the other party roll rotates, so the temperature is averaged and transmitted within the target face. When installing the heater, the temperature variation of the contact surface to the roll end face of the heater is directly transmitted to the surface of the roll end face (because it is greatly affected by the heat variation of the heater). It can be said that the significance of dividing and controlling the temperature is particularly great.

  Heating by the heater is performed so that the surface temperature of the heating plate is, for example, about roll surface temperature +0 to 50 ° C.

  Moreover, when installing a heater apart from a roll end surface, it is desirable for the clearance gap between a roll end surface and a heater (a heating plate when providing a heating plate) to be about 3-20 mm.

  In addition, when installing the heater away from the roll end face, if air flows in the gap between the roll and the heater (or the heating plate if a heating plate is provided), temperature fluctuations on the end face of the roll may occur due to partial temperature drop. Occur. In order to prevent this, it is difficult for air to flow in the gap between the roll and the heater (a heating plate when a heating plate is provided), and the air in the gap between the roll and the heater (a heating plate when a heating plate is provided) is retained. It is desirable to install an annular cover 22. The distance between the tip end facing the end face of the cover 22 and the roll end face is set to about 1 mm, for example. In addition, a resin bush 24 may be installed so that air does not flow in the gap between the rotor shaft and the heater (or a heating plate if a heating plate is provided), and so that rotation of the rotor shaft is not hindered. desirable.

  When the heater is installed away from the roll end face, a roll end face heating device such as a heater is attached and fixed to the main bearing box 4 or a housing (not shown).

  Further, as shown in FIG. 2, by providing a heat insulating plate 25 on the opposite side of the surface facing the roll end surface of the heater, the temperature decrease of the roll end surface can be effectively suppressed, and supplied to the heater. Less energy to do. In the embodiment shown in FIG. 2, the bush 24 is not installed, but the bush 24 may be installed.

  By using the heating roll mentioned above, the temperature fall of a roll end surface can be suppressed actively and the convex crown which generate | occur | produces in a heating roll can be made small effectively. As a result, it is possible to suppress a change in roll accuracy due to thermal deformation of the roll in the heating roll, and to perform highly accurate compression processing.

  Next, the example of the roll press machine using the above-mentioned heating roll is demonstrated.

  As shown in FIG. 3, the roll press machine in the roll press facility includes an upper roll 1, a lower roll 2, a main bearing box 4 that holds a main bearing that pivotally supports the upper roll and the lower roll, and a main bearing for the lower roll. A press cylinder 5 for applying a load to the box and generating a press load on the material 3 between the upper roll 1 and the lower roll 2 is provided. The above-mentioned heating roll is used for the upper roll 1 and the lower roll 2.

  The main bearing box 4 and the press cylinder 5 of the upper roll 1 are supported by a housing (not shown). Each of the upper roll and the lower roll is provided with a roll drive mechanism (not shown). Each of the upper roll and the lower roll is provided with a heating medium supply mechanism (not shown). The roll press machine is also provided with a bend mechanism that corrects the deflection of the roll, which includes a bend cylinder 7 and a bend bearing box 6 that holds and holds the bend bearing.

  This deflection correction corrects the deflection of the roll due to the reaction force received from the material 3 during compression. If the deflection of the roll is not corrected, there will be variations in the width direction of the finished thickness, such that both edges of the material 3 will be thinner than near the center, so correcting the deflection will reduce the thickness variation in the width direction of the material. Suppressing and processing with high accuracy.

  The press cylinder 5 is a main component of the press mechanism that adjusts the roll gap. The press cylinder 5 is configured to be position-controllable by a control command from a control panel (not shown). That is, the press cylinder has a position detector (not shown) such as a magnescale inside or outside, and a system capable of position control using a servo valve in the hydraulic system is employed.

  The bend cylinder 7 can be set with a pressing force by a control command from the control panel. The bend cylinder employs a proportional control valve (solenoid valve) for pressure setting. The bend bearing housing 6 is provided on both outer sides of the main bearing housing 4. The bend mechanism for correcting the deflection of the roll according to this embodiment is a bend tension type, and a bend cylinder 7 is provided between the bend bearing box of the upper roll and the bend bearing box of the lower roll, and the roll according to the processing load on the material. The deflection of the roll is corrected by applying a load to the roll in the opposite direction to the deflection. The arrows in the figure are images of the direction and magnitude of the load applied by each cylinder. Each cylinder uses hydraulic pressure. Hydraulic cylinders can handle high loads and can be processed stably by using incompressible fluid (hydraulic fluid).

  As shown in FIG. 4, the bend cylinder 7 may be a bend tension type in which the bend cylinder 7 is provided above the upper roll bend bearing box and below the lower roll bend bearing box.

  FIG. 5 shows an overall line diagram of a roll press facility in which the above-described roll press machine is arranged. On the entry side of the roll press machine, there is provided an unwinder 12 for mounting a pre-press coil 8 in which a material 3 such as a lithium ion secondary battery electrode material is wound in a coil shape, and on the exit side of the roll press machine main body. Is provided with a winder 13 that winds the material after pressing to form a coil 9 after pressing. Further, a thickness meter 10 for measuring the thickness of the pressed material 3 is installed on the exit side of the roll press machine main body. Based on the thickness measurement value from the thickness gauge 10, the control panel 11 performs an operation for obtaining the control value (correction amount) of the press cylinder position control and the bend cylinder pressure control, and the control value is output to the roll press machine. Controls the hydraulic pressure of the press cylinder and bend cylinder. Further, when the measured value at the center of the three measured thickness values is smaller than the measured values on the driving side and the operating side as described later, the bend cylinder pressure is set near the lowest value of the adjustable range. When it is below the threshold value, that is, when a thermal crown (convex crown) is generated in the roll and the shape of the roll itself has a significant influence on the thickness accuracy in the width direction of the material, the heater in the control panel 11 The energization amount (control value) is determined, and the output of the heater is controlled based on the obtained control value.

  In the present embodiment, the thickness gauge 10 has three points (three regions or three locations) on the operation side (side without the roll drive mechanism) Td, the center Tc, and the drive side (side with the roll drive mechanism) Tw in the width direction. It is comprised so that thickness may be measured by. The thickness measurement points may be at least two points in the width direction (center and operation side or drive side), and it is desirable to measure the thickness at three points. Further, the thickness may be measured by fixing the measuring device at three places, or the thickness may be measured by moving the measuring device in the width direction. When continuously measuring in the width direction, three regions of the operation side, the center, and the drive side may be set, and the average value of the measured values in the range may be used for control.

  The thickness meter 10 is not specified in the measurement method as long as the material thickness can be measured continuously or intermittently during line operation. For example, as a thickness gauge measurement method, the top surface position of the material on the guide roll is detected by a laser sensor, and the position of the guide roll is detected by a magnetic sensor, and the material thickness is measured from the positional relationship. And a method of measuring the position of both surfaces of the material with a laser sensor and measuring the thickness of the material from the positional relationship.

  In this embodiment, the thermal crown is finally adjusted when the production line is in a steady condition. That is, the adjustment is made when the roll or the like is sufficiently heated and the temperature does not rise.

  As described above, the deflection of the roll due to the reaction force received from the material 3 during compression occurs. This deflection of the roll deforms the roll in the opposite direction to the thermal crown. In compression processing at a high linear pressure, the thermal crown is offset by roll deflection, and the deflection of the roll is corrected by a bend cylinder.

  However, when the linear pressure during roll pressing is reduced (for example, 100 kg / cm or less), the reaction force from the material is small, and the deflection of the roll due to the reaction force from the material is small. If it does so, a thermal crown will not be canceled by the bending of the roll received from a material at the time of compression, and the shape of the roll itself by a thermal crown will influence a product thickness precision notably. This convex thermal crown cannot be corrected by a roll deflection correction mechanism that applies a bender force (force in a direction to separate the upper and lower rolls) to the outside of the main bearing box.

  When the production line is in a steady condition, it is determined that the thickness in the width direction of the material has a convex shape based on the thickness measurement value from the thickness gauge 10 shown in FIG. When the pressure is below the threshold value set near the lowest value of the adjustable range, the heater is heated by energizing the heater. The heater heating may be automatically performed using the control panel 11 or may be performed manually by an operator by visually observing the measured value. Moreover, you may make it adjust separately the heater respectively arrange | positioned at the left and right end surface of a roll based on the thickness measurement value (Td, Tc, Tw) of the width direction. That is, for example, when the measured value of Td is larger than the measured value of Tw, the heater heating on the roll end surface on the driving side is made stronger than the heater heating on the roll end surface on the operation side.

  In this way, by grasping the state of the roll crown when the production line is in steady conditions and performing heater heating, the energy supplied to the heater and the energy that drives the bend cylinder are compared to the case where the heater is always heated. Can be minimized.

  In the above-described embodiment, the heating roll of the present invention is used for the upper roll and the lower roll (the heater is installed on the roll end face). The effect can also be obtained by using (not installed).

  In addition, this invention is not limited to an above-described Example, Various modifications are included. For example, the above-described embodiments have been described in detail for easy understanding of the present invention, and are not necessarily limited to those having all the configurations described. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. Moreover, it is possible to add, delete, and replace other configurations for a part of the configuration of each embodiment.

  For example, in each of the above-described embodiments, the rolls are arranged up and down, but the present invention can be similarly applied to a roll press apparatus in which a pair of rolls (first roll and second roll) are arranged in the horizontal direction. . In this modification, the upper roll in each of the above-described embodiments is read as the first roll, and the lower roll as the second roll.

  Further, for example, as a mechanism for applying a load to each bearing housing, operability and the like are inferior to those of the hydraulic cylinder system of the embodiment, but a load applying mechanism using a screw mechanism can also be applied.

  DESCRIPTION OF SYMBOLS 1 ... Upper roll, 2 ... Lower roll, 3 ... Material, 4 ... Main bearing box, 5 ... Press cylinder, 6 ... Bend bearing box, 7 ... Bend cylinder, 8 ... Coil before press, 9 ... Coil after press, 10 ... Thickness gauge, 11 ... control panel, 12 ... unwinding machine, 13 ... winder, 20 ... heater, 22 ... cover, 23 ... heating plate (soaking plate), 24 ... bush, 25 ... heat insulating plate.

Claims (11)

It is a heating roll for warm press used in a roll press machine that compresses a continuous sheet-like material by a pair of opposed rolls,
Heaters are respectively provided facing the roll end surfaces on both axial sides of the heating roll,
Each of the heaters is provided apart from the facing roll end surface. The heating roll according to claim 1 , further comprising a cover that covers a gap formed between the heater and the roll end surface from the outer periphery of the heater. The heating roll according to claim 1 , wherein a resin bush is provided between the heater and a roll shaft portion of the roll. 2. The heating roll according to claim 1 , wherein a temperature-equalizing plate is provided on the roll end face side of the heater. It is a heating roll for warm press used in a roll press machine that compresses a continuous sheet-like material by a pair of opposed rolls,
Heaters are respectively provided facing the roll end surfaces on both axial sides of the heating roll,
A heating roll characterized in that the heater is divided into a plurality of parts in a surface facing the end face of the roll and the temperature is individually controlled. 2. The heating roll according to claim 1 , wherein the heater is divided into a plurality of parts in a plane facing the roll end face, and the temperature is individually controlled. The heating roll according to claim 1 , wherein a heat insulating plate is provided on a side opposite to the roll end face side of the heater. A roll press machine that compresses a material with a pair of opposed rolls,
A roll press machine using the heating roll according to any one of claims 1 to 7 for either one or both of the rolls. The roll deflection correction mechanism according to claim 8 , further comprising a roll deflection correction mechanism that corrects the deflection of the roll by applying a load to the roll shaft portion in a direction to reduce the roll deflection due to a reaction force from the material when the material is pressed. Roll press machine. A roll press method using the roll press according to claim 9 ,
When the thermal crown generated in the heating roll is not offset by the deflection of the roll due to the reaction force from the material during press working, the roll end surface is heated by the heater ,
A roll press characterized by correcting the roll deflection by the roll deflection correction mechanism when the thermal crown generated in the heating roll is offset by the deflection of the roll due to the reaction force from the material during press working. Method. A roll press method using a roll press machine that compresses a material with a pair of opposed rolls,
A heating roll for warm pressing is used for either one or both of the rolls,
The heating rolls are respectively provided with heaters facing the roll end faces on both axial sides,
The roll press machine includes a roll deflection correction mechanism that corrects the deflection of the roll by applying a load to the roll shaft in the direction of reducing the roll deflection due to the reaction force from the material when pressing the material,
When the thermal crown generated in the heating roll is not offset by the deflection of the roll due to the reaction force from the material during press working, the roll end surface is heated by the heater,
A roll press characterized by correcting the roll deflection by the roll deflection correction mechanism when the thermal crown generated in the heating roll is offset by the deflection of the roll due to the reaction force from the material during press working. Method.

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