Metering device and system for processing a bulk material
Patent Information
- Authority / Receiving Office
- EP · EP
- Patent Type
- Applications
- Current Assignee / Owner
- K TRON TECHNOLOGIES INC
- Filing Date
- 2024-08-15
- Publication Date
- 2026-06-24
Smart Images

Figure IB2024057924_27022025_PF_FP_ABST
Abstract
Description
Dosing device and system for processing bulk material Description
[0001] The invention relates to a dosing device for bulk material. Furthermore, the invention relates to a system for processing bulk material.
[0002] Dosing devices are known for the metered dispensing of bulk material, such as powder, which comprise a bulk material container and a dispensing device with the associated drive. For example, such dosing devices can be designed as screw conveyors having a conveyor screw. The screw threads of the conveyor screw result in portion-by-portion dispensing, so that while dosing accuracy is still maintained over long periods of time, it is relatively inaccurate over short periods of time. Screw conveyors cannot therefore be used for fine dosing. Furthermore, the conveyor screw subjects the material to be dosed to mechanical stress, e.g. through shearing, compression and / or friction. This can destroy the material to be dosed or cause it to clump. An evenly distributed supply of the material to be dosed is therefore no longer possible. This can also lead to unwanted changes in the material properties.This is particularly disadvantageous when dosing sensitive bulk material that must be evenly distributed into a subsequent processing device.
[0003] For example, in the production of a battery cell, a carrier material, such as a carrier foil, is coated with a dry powder (so-called "dry coating battery production"). The powder has several components, including an active material that is specific either for the anode or for the cathode of a battery cell. For example, the active material can be graphite (e.g. for the anode) or a lithium nickel manganese cobalt oxide or lithium iron phosphate (e.g. for the cathode). The challenge here is that the material, e.g. nickel manganese cobalt (NMC) or lithium iron phosphate (LFP), must not only be fed precisely, but also distributed as precisely as possible across the entire production width. However, the material is prepared in such a way that it can form a uniform and elastic layer in the calender rolls and therefore contains binding agents, e.g. Polytetrafluoroethylene (PTFE), polyvinylidene fluoride (PVDF), or other binders, which are mixed to form fibrils / fibers. When pressure is applied, for example, by a screw conveyor of a dosing device, the material begins to clump. A uniformly distributed and metered feed of such a powder or dry electrode material onto the surface of a plate-shaped or film-shaped carrier material or to a calendering and / or coating device for electrode production would therefore be desirable. Furthermore, short-term dosing accuracy can be important to minimize the amount of material deposited in the gap.
[0004] The invention is based on the object of structurally and / or functionally improving a dosing device mentioned above. Furthermore, the invention is based on the object of structurally and / or functionally improving a system for processing a bulk material, in particular a dry electrode material, mentioned above.
[0005] For example, it is an object of the present invention to provide a dosing device for bulk material, in particular for electrode material, which can reduce or eliminate the problems identified in connection with the prior art. In particular, it is an object of the present invention to enable a uniformly distributed and metered supply of the material in order to form a thin layer of material. This also prevents clumping of the material.
[0006] The object is achieved by a dosing device having the features of claim 1. Furthermore, the object is achieved by a system having the features of claim 16. Advantageous embodiments and / or further developments are the subject of the subclaims, the description and / or the accompanying figures. In particular, the independent claims of one claim category can also be further developed and / or combined analogously to the dependent claims of another claim category. Likewise, the following described Device and process features are combined and / or further developed.
[0007] One aspect relates to a dosing device for the dosed dispensing of a bulk material. The dosing device can be designed in particular for the dosed and evenly distributed dispensing of the bulk material. The bulk material can in particular be a dry material, e.g. dry electrode material. The electrode material can be for an electrode of a battery cell. For example, the bulk material can comprise nickel manganese cobalt (NMC) or lithium iron phosphate (LFP). In addition, the bulk material can contain a binder, e.g. polytetrafluoroethylene (PTFE), polyvinylidene fluoride (PVDF) or other binders. Depending on the particle size and / or particle shape, the bulk material can be in the form of a powder, granulate, flakes or fibers, for example.
[0008] The dosing device comprises a dosing roller and a counter-roller. The dosing roller and the counter-roller are arranged in such a way that a gap region is formed between the dosing roller and the counter-roller. Furthermore, the dosing roller is rotatably mounted and can be driven in at least one direction of rotation. For this purpose, a drive, such as a motor or electric motor, can be provided which drives the dosing roller. The dosing roller and the counter-roller can be arranged in such a way that a gap is formed between them, in particular in the gap region, in particular such that the dosing roller and the counter-roller do not touch and / or do not overlap and / or do not mesh with one another. The gap can be defined by a fixed distance between the dosing roller and the counter-roller. For example, the gap can be provided between the outer circumferential surface of the dosing roller and the outer circumferential surface of the counter-roller. The outer surfaces orThe outer peripheral surfaces of the metering roller and counter-roller can therefore be spaced apart from each other. In one variant, the outer surfaces or the outer peripheral surfaces of the metering roller and counter-roller can be circular or substantially circular. The gap or distance can be a few millimeters. In one variant, the gap or distance can be approximately zero or zero. With a gap or distance of zero, the metering roller and counter-roller can touch and / or slide past each other. For example, the outer surfaces or outer peripheral surfaces of the metering roller and counter roller can touch and / or be in sliding contact. However, an overlap or intermeshing of the metering roller and counter roller should not be provided.
[0009] The counter roll can be made of a solid and / or hard material. For example, the counter roll is made of a metal, e.g., aluminum, steel, or stainless steel. The counter roll can thus be a metal roll. The outer surface of the counter roll can have a defined and / or predetermined roughness, such as surface roughness. The counter roll can be a friction roll. For example, the outer surface of the counter roll can be glass bead blasted or sandblasted. In a preferred variant, the counter roll can be rotatably mounted. The counter roll can be driven in at least one direction of rotation. For this purpose, a drive, such as a motor or electric motor, can be provided that drives the counter roll. In one variant, the metering roller and the counter roll can be driven in the same direction of rotation or can be driven in rotation, for example, such that an opposing movement results in the gap area between the metering roller and the counter roll.This allows excess material to be easily stiffened. The metering roller and the counter roller can therefore be designed so that they can be driven in the same direction of rotation. This means that the metering roller and the counter roller can both rotate clockwise at the same time or both counterclockwise at the same time. The drives can be designed and / or controlled so that the metering roller and the counter roller rotate at the same or different speeds, such as the rotational speed. Alternatively, the counter roller can be stationary. The metering roller and the counter roller can be arranged parallel to one another. The axes, e.g. axes of rotation, of the metering roller and the counter roller can be parallel to one another. The metering device can also have a control system.The controller can be configured to control a direction of rotation and / or a speed, such as rotational speed or peripheral speed, of the metering roller and / or the counter roller. For example, the controller can be configured to control a speed, such as rotational speed or peripheral speed, of the metering roller. control so that it is greater or smaller than a speed, such as rotational speed or peripheral speed, of the counter-roller. In particular, the control system can be set up such that it controls the metering roller and the counter-roller, e.g. by means of the drives, so that the metering roller and the counter-roller rotate in the same direction, i.e. in the same direction of rotation. In one variant, the control system can be set up such that it controls the metering roller and the counter-roller such that the ratio of the two speeds, in particular the two peripheral speeds, is kept essentially constant. The ratio can be understood in particular as the ratio of the metering roller speed and the counter-roller speed to one another.
[0010] The dosing device can comprise a bulk material container. The bulk material container can be a hopper, such as a filling hopper. The bulk material container can have an inlet opening provided at its upper end. The bulk material can be fed to the bulk material container via the inlet opening. Furthermore, the bulk material container can have an outlet opening. The outlet opening is provided at the lower end of the bulk material container. The dosing roller can protrude at least partially into the outlet opening to receive bulk material. In the axial direction, the length of the outlet opening of the bulk material container can essentially correspond to the length of the gap region and / or essentially to the length of the dosing roller. Furthermore, the bulk material container can widen towards the lower end, for example, widen conically downwards.In one variant, the bulk material container may have a portion that extends substantially along a portion of the outer circumference or outer circumferential surface of the dosing roller.
[0011] Unless otherwise stated or the context indicates otherwise, the terms "axial," "radial," and "in the circumferential direction" refer to a direction of extension of the metering roller's axis of rotation. "Axial" then corresponds to a direction of extension of the metering roller's axis of rotation. "Radial" then is a direction perpendicular to the direction of extension of the metering roller's axis of rotation and intersecting the metering roller's axis of rotation. "In the circumferential direction" then corresponds to a circular arc direction around the metering roller's axis of rotation.
[0012] The dosing roller can have at least one cavity or recess for receiving and / or transporting the bulk material. The cavity or recess can be a cell or material receiving cell. In one variant, the dosing roller can have at least one longitudinal groove for receiving and / or transporting the bulk material. The at least one longitudinal groove can also be referred to as a cell, e.g. as a material receiving cell. The dosing roller can be designed to transport the bulk material to the counter-roller and / or into the gap between the dosing roller and counter-roller. The bulk material can be received from the bulk material container by means of the at least one cavity or recess and / or the at least one longitudinal groove and transported to or into the gap between the dosing roller and counter-roller. The dosing device can further have a discharge opening through which the bulk material can be discharged.After the metering roller has transported the bulk material through the gap between the metering roller and the counter-roller, the bulk material can fall through the discharge opening and is thus metered and evenly distributed and made available to a downstream device. In one variant, the metering roller can have a plurality of cavities or recesses and / or longitudinal grooves for receiving the bulk material. A longitudinal web can be formed between each two longitudinal grooves. The metering roller can therefore have a plurality of longitudinal webs. The longitudinal webs and / or longitudinal grooves can extend in the longitudinal direction of the metering roller. The longitudinal direction can be the direction of the axis of rotation of the metering roller. The longitudinal webs and / or longitudinal grooves can be provided on the circumferential surface and / or define it. For example, the longitudinal webs can protrude from the metering roller in the radial direction.The outer circumferential surface of the metering roller can be formed and / or defined by the radially outer surface of the longitudinal web and / or by the radially outer surfaces of the longitudinal webs. In the circumferential direction, the width of the longitudinal grooves can be greater than the width of the longitudinal webs. For example, in the circumferential direction, the width of the longitudinal grooves can essentially correspond to twice, three times, four times, five times or more the width of the longitudinal webs. The longitudinal grooves can be formed and / or delimited by the circumferential surface of the metering roller and the longitudinal webs. In one variant, the longitudinal webs can be continuous or interrupted several times in the axial direction or longitudinal direction. The longitudinal webs can. Each of them has a plurality of web sections spaced apart from one another in the axial direction or longitudinal direction. The web sections of two circumferentially adjacent longitudinal webs can be offset from one another in the circumferential direction or arranged in alignment one behind the other. Furthermore, the web sections can have vertical or wedge-shaped flanks in the axial direction or longitudinal direction.
[0013] In one variant, the counter-roller can be designed to strip off any excess bulk material picked up by the metering roller in the gap area, for example, so that it is fed back into the bulk material container. Furthermore, the metering device can have at least one stripping device. The stripping device can be designed to strip off bulk material adhering to the metering roller or the counter-roller. The at least one stripping device can have a brush element. The brush element can be arranged such that an edge or end face of the brush element rests against the metering roller or the counter-roller. For example, a first stripping device can be provided for the metering roller and a second stripping device for the counter-roller.
[0014] The dosing device can be a volumetrically and / or gravimetrically operated dosing device. The dosing device can be designed to detect the material weight. The dosing device can be configured to regulate the weight loss and / or weight gain of the material. For this purpose, the dosing device can comprise a scale. The dosing device can be designed to detect the material flow, the volume, and / or the weight of the material to be dosed, in particular precisely. Furthermore, a sensor device can be provided which is designed to detect the bulk material height above the dosing roller and / or the fill level of the bulk material container. The sensor device can comprise a scale, an ultrasonic sensor, a camera, and / or a laser sensor, for example, a scale for monitoring the fill level, a laser distance sensor, such as a time-of-flight laser sensor, or a sensor based on laser triangulation.
[0015] A further aspect relates to a plant for processing a bulk material, for example a bulk material as described above and / or below, in particular, a dry electrode material. The plant may be a calendering and / or coating plant. For example, the plant may be an electrode manufacturing plant, a battery cell manufacturing plant, or a part thereof.
[0016] The system comprises at least one dosing device for the metered and evenly distributed dispensing of a bulk material. The at least one dosing device is designed as described above and / or below. Furthermore, the system comprises a calendering and / or coating device. The system can be used and / or designed to produce dry electrodes for battery cells. The electrodes can be or will be implemented in battery cells.
[0017] The at least one metering device is arranged upstream of the calendering and / or coating device, or the calendering and / or coating device is arranged downstream of the at least one metering device. The metering device is designed to meter bulk material to the calendering and / or coating device and to supply it evenly distributed, particularly in the axial direction / longitudinal direction of the metering roller.
[0018] The system or its calendering and / or coating device can have a plurality of calender rolls, for example a first calender roll and a second calender roll. Furthermore, the system can have a control system. The second calender roll can be designed and / or arranged such that it forms a first nip between the first calender roll and the second calender roll. The first nip can be designed such that it receives / accommodates the bulk material, e.g. the dry electrode material, from the at least one dosing device and forms a material film, e.g. a dry electrode film, from the bulk material, e.g. from the dry electrode material. The control system can be designed to control a speed, such as a rotational speed, of the first and second calender rolls. For this purpose, drives, e.g. motors or electric motors, can be provided to drive the calender rolls in rotation.For example, the controller may be configured to control a speed, such as rotation speed. of the second calender roll so that it is greater or less than a speed, such as rotation speed, of the first calender roll.
[0019] The invention enables consistent dosing over time and across the width. This allows for evenly distributed and metered material delivery, allowing for the formation of a thin layer of material. Clumping of the material can also be prevented or at least significantly minimized.
[0020] In the following, embodiments of the invention are described in more detail with reference to figures, which show schematically and by way of example: Fig. 1 is a sectional view of a dosing device; Fig. 2 is a perspective view of the dosing device according to Fig. 1; Fig. 3 is a perspective sectional view of the dosing device according to Fig. 1; and Fig. 4 shows a plant for processing a bulk material with a dosing device according to Fig. 1.
[0021] Figs. 1 to 3 show a dosing device 100 for the metered dispensing of a bulk material in a sectional view (Fig. 1), a perspective view (Fig. 2), and a perspective sectional view (Fig. 3). In the present embodiment, the bulk material is a dry electrode material 102, which can be evenly distributed and dispensed or provided in metered amounts by the dosing device 100. The electrode material can be in powder form.
[0022] The dosing device 100 has a dosing roller 104 and a counter-roller 106, which are arranged relative to one another in such a way that a gap region 108 is formed between the dosing roller 104 and the counter-roller 106. The dosing roller 104 and the counter-roller 106 are rotatably mounted and can be driven in one direction of rotation by means of drives, such as motors. A control system can be provided for this purpose. In the present variant, the dosing roller 104 and the counter-roller 106 can be driven in the same direction of rotation (illustrated by the arrows in Fig. 1), in such a way that in the gap region 108 A counter-rotating movement results between the metering roller 104 and the counter-roller 106. This means that the metering roller 104 and the counter-roller 106 rotate in the same direction, clockwise in Fig. 1. The counter-roller 106 is further configured to strip off any excess bulk material picked up by the metering roller 104 in the gap region 108, in particular so that it is returned to the bulk material container 110.
[0023] Furthermore, the dosing device 100 comprises a bulk material container 110 designed as a hopper, at the upper end of which is provided an inlet opening through which the bulk material can be fed to the bulk material container 110, and at the lower end of which is provided an outlet opening 114 into which the dosing roller 104 projects at least partially to receive bulk material. As shown in Figs. 2 and 3, the length of the outlet opening 114 of the bulk material container 110 in the axial direction essentially corresponds to the length of the gap region 108 and essentially to the length of the dosing roller 104. Furthermore, the bulk material container widens towards the lower end. As a result, the outlet opening 114 can be larger than the inlet opening 112.
[0024] As shown in Figs. 1 to 3, the metering roller 104 has a plurality of longitudinal grooves 116 for receiving the bulk material, with a longitudinal web 118 being formed between each two longitudinal grooves 116. In the circumferential direction, the width of the longitudinal grooves 116 is greater than the width of the longitudinal webs 118, so that a sufficiently large cell is formed for receiving the bulk material from the bulk material container 110.
[0025] In the present embodiment according to Figs. 1 to 3, the longitudinal webs 118 are interrupted several times in the axial direction and each have a plurality of web sections 120 spaced apart from one another in the axial direction. The web sections 120 have wedge-shaped flanks in the axial direction. Furthermore, the web sections 120 of two circumferentially adjacent longitudinal webs 18 are arranged offset from one another in the circumferential direction.
[0026] The dosing device 100 further comprises two stripping devices 122, wherein one stripping device 122 is designed to strip off bulk material adhering to the dosing roller 104 and the other stripping device 122 is designed to To strip off bulk material adhering to the counter roller 106. For this purpose, the stripping device 122 each has a brush element 124 that rests against the metering roller 104 or the counter roller 106.
[0027] Fig. 4 shows a system 200 for processing a bulk material, in particular the aforementioned dry electrode material 102. For example, the system 200 can be an electrode manufacturing system, a battery cell manufacturing system, or a part thereof. The system can serve and / or be designed to produce dry electrodes for battery cells.
[0028] The system 200 comprises the dosing device 100 described above for Equip. 1 to 3 for the metered and evenly distributed dispensing of the dry electrode material 102. Furthermore, the system 200 comprises a calendering device 202. The calendering device 202 is connected downstream of the dosing device 100. The dosing roller 104 of the dosing device 100 is designed to transport the dry electrode material 102 to the counter-roller 106 and into the gap 108 between the dosing roller 104 and the counter-roller 106. The dry electrode material 102 can be picked up from the bulk material container 110 by means of longitudinal grooves 116 and transported to or into the gap 108 between the dosing roller 104 and the counter-roller 106.After the metering roller 104 has transported the dry electrode material 102 through the gap 108 between the metering roller 104 and the counter roller 106, the dry electrode material 102 falls through a discharge opening 126 of the metering device 100 and is thus provided or fed in a metered manner to the downstream calendering device 202, in particular in the axial direction / longitudinal direction of the metering roller 104.
[0029] The calendering device 202 may comprise a plurality of calender rolls, for example, a first calender roll 204 and a second calender roll 206. The second calender roll 206 is designed and arranged to form a first nip 208 between the first calender roll 204 and the second calender roll 206. The first nip 208 is designed to receive / accommodate the dry electrode material 102 from the metering device 100 and to form a dry electrode film from the dry electrode material 102. A controller may be designed to control a speed, such as the rotational speed, of the first and second calender rolls. For this purpose, drives, e.g., motors or electric motors, can be provided to rotate the calender rolls. For example, the controller may be configured to control a speed, such as rotational speed, of the second calender roll to be greater or less than a speed, such as rotational speed, of the first calender roll.
[0030] Furthermore, reference is made in particular to Eign. 1 to 3 and the associated description.
[0031] "May" refers in particular to optional features of the invention. Accordingly, there are also further developments and / or embodiments of the invention that additionally or alternatively have the respective feature or features.
[0032] If necessary, isolated features may also be selected from the combinations of features disclosed here and used in combination with other features to define the subject matter of the claim, dissolving any structural and / or functional connection that may exist between the features. Reference symbol Dosing device Electrode material Dosing roller Counter roller Gap area Bulk container Inlet opening Outlet opening Longitudinal grooves Longitudinal webs Web sections Scraper devices brush element Dispensing opening Plant Calendering device first calender roll second calender roll gap
Claims
Patent claims 1 . Dosing device (100) for the metered dispensing of a bulk material (102), in particular a dry electrode material (102), with a dosing roller (104) and a counter-roller (106), which are arranged relative to one another in such a way that a gap region (108) is formed between the metering roller (104) and the counter-roller (106), wherein the metering roller (104) is rotatably mounted and can be driven in at least one direction of rotation.
2. Dosing device (100) according to claim 1, characterized in that the counter roller (106) is rotatably mounted and can be driven in at least one direction of rotation.
3. Dosing device (100) according to at least one of the preceding claims, characterized in that the dosing roller (104) and the counter-roller (106) are rotatably driven or driven in the same direction, in particular such that an opposite movement results in the gap region (108) between the dosing roller (104) and the counter-roller (106).
4. Dosing device (100) according to claim 1, characterized in that the counter roller (106) is stationary.
5. Dosing device (100) according to at least one of the preceding claims, characterized by a bulk material container (110) at the lower end of which an outlet opening (114) is provided, into which the dosing roller (104) projects at least partially for receiving bulk material (102).
6. Dosing device (100) according to claim 5, characterized in that in the axial direction the length of the outlet opening (114) of the bulk material container (110) corresponds substantially to the length of the gap region (108) and / or substantially to the length of the dosing roller (104).
7. Dosing device (100) according to at least one of the preceding claims 5 to 6, characterized in that the bulk material container (1 10) widens towards the lower end.
8. Dosing device (100) according to at least one of the preceding claims, characterized in that the dosing roller (104) has a plurality of longitudinal grooves (116) for receiving the bulk material (102), wherein a longitudinal web (118) is formed between each two longitudinal grooves (116).
9. Dosing device (100) according to claim 8, characterized in that in the circumferential direction the width of the longitudinal grooves (1 16) is greater than the width of the longitudinal webs (1 18).
10. Dosing device (100) according to at least one of the preceding claims 8 to 9, characterized in that the longitudinal webs (1 18) are continuous or interrupted several times in the axial direction. 1 1. Dosing device (100) according to at least one of the preceding claims 8 to 10, characterized in that the longitudinal webs (1 18) each have a plurality of web sections (120) spaced apart from one another in the axial direction.
12. Dosing device (100) according to claim 1 1, characterized in that the web sections (120) of two circumferentially adjacent longitudinal webs (1 18) are arranged offset from one another in the circumferential direction or aligned one behind the other.
13. Dosing device (100) according to at least one of the preceding claims 11 to 12, characterized in that the web sections (120) have vertical or wedge-shaped flanks in the axial direction.
14. Dosing device (100) according to at least one of the preceding claims, characterized in that the counter roller (106) is designed to strip off excess bulk material (102) taken up by the dosing roller (104) in the gap region (108), in particular in such a way that it is fed back to the bulk material container (110).
15. Dosing device (100) according to at least one of the preceding claims, characterized in that the dosing device (100) has at least one stripping device (122) which is designed to strip off bulk material (102) adhering to the metering roller (104) or to the counter roller (106).
16. Plant (200) for processing a bulk material (102), in particular a dry electrode material (102), with a dosing device (100) according to at least one of the preceding claims and a calendering and / or coating device (202) connected downstream of the dosing device (100), wherein the dosing device (100) is designed to feed bulk material (102) to the calendering and / or coating device (202) in a dosed manner and evenly distributed, in particular in the axial direction.