Patent Description:
During the coating of an electrode plate of a battery, the electrode plate needs to be dried in an oven. To ensure a good drying effect and high production efficiency, the oven is usually long in shape, and a plurality of guide rollers are disposed inside the oven. Therefore, a relatively large section of the electrode plate is located in the oven during the coating, thereby increasing the probability of breaking off the electrode plate inside the oven.

For example, international patent application <CIT> discloses an electrode plate drying device that can sufficiently dry electrode plates without raising the temperature inside a drying furnace to a high temperature. <CIT> discloses an apparatus for stripping or peeling metallic layers, especially electro deposited metal in the form of sheets, from sheet-like metallic supports, e.g. an electrodeposition cathode. International patent application <CIT> discloses a rope conveyor system in which a conveyor belt is suspended from a flexible elongate member.

When the electrode plate breaks inside the oven, due to the great length of the oven, a side door of the oven has to be opened, and the broken electrode plate is manually pulled out of the oven for connecting. In this process, because a part of the electrode plate is pulled out of the oven, the pulling force direction deviates from a movement direction of the electrode plate in the oven, thereby resulting in misalignment or even repeated breakage of the electrode plate. In addition, if the broken electrode plate is manually reconnected from a side of the oven, the production efficiency is not high.

In view of the above situation, it is necessary to provide a conveyor and a baking device to solve the problem of inconvenience of handling breakage of an electrode plate occurring during coating and drying of the electrode plate.

According to a first aspect, this application provides a conveyor, configured to convey an electrode plate and including: a main body, a guide mechanism, and a driving mechanism. The main body includes a transport space for accommodating the electrode plate. The guide mechanism is disposed in the transport space and includes a traction rope. The traction rope extends along a conveyance direction of the electrode plate and is connected to the electrode plate to bring the electrode plate to move. The driving mechanism is drivingly connected to the traction rope, so as to drive the traction rope to bring the electrode plate to move along the conveyance direction. The conveyor comprises a supporting roller disposed under the traction rope along a gravity direction, a guide slot that extends along the conveyance direction is made on the supporting roller, and the traction rope is disposed in the guide slot. The conveyor comprises a pressure roller, the pressure roller is disposed corresponding to the supporting roller, a limiting space is defined between the pressure roller and the supporting roller, and the traction rope is disposed in the limiting space. The conveyor comprises a floating mechanism, and the floating mechanism comprises a fastener, fixedly connected to the main body; and an elastomer. One end of the elastomer is connected to the fastener, and another end of the elastomer is connected to the pressure roller, so as to change a distance between the pressure roller and the supporting roller.

In the technical solution in an embodiment of this application, the guide mechanism can fix the electrode plate and bring the electrode plate to move along the conveyance direction. In this way, the electrode plate can be automatically conveyed in the transport space to facilitate reconnection of the electrode plate that has broken. In addition, the traction rope is of high flexibility, and therefore, can more smoothly bring the electrode plate to move along a specified path in the oven, thereby avoiding derailment or jamming during movement and conveying the electrode plate more smoothly and steadily in the oven.

In the technical solution of the foregoing embodiments of this application, the supporting roller serves to support the traction rope. The guide slot can limit the position of the traction rope on the horizontal plane along a direction perpendicular to the conveyance direction of the electrode plate, thereby preventing the traction rope from detaching from the supporting roller.

In some embodiments, the supporting roller includes a first sub-roller and a second sub-roller. The first sub-roller and the second sub-roller are spaced apart in a horizontal plane that intersects the conveyance direction. The traction rope includes a first sub-rope and a second sub-rope. The first sub-rope and the second sub-rope are disposed in the guide slot of the first sub-roller and the second sub-roller respectively. A conveyance space for accommodating the electrode plate is formed between the first sub-rope and the second sub-rope. The guide mechanism includes a connecting assembly. Two ends of the connecting assembly are connected to the first sub-rope and the second sub-rope respectively, so as to fix the electrode plate in the conveyance space.

In the technical solution of the foregoing embodiments of this application, the first sub-rope is accommodated in the guide slot of the first sub-roller, the second sub-rope is accommodated in the guide slot of the second sub-roller, and the electrode plate is fixed in the conveyance space between the first sub-rope and the second sub-rope. In this way, the electrode plate can be more stably disposed in the conveyance space, and the electrode plate is stressed more uniformly on both sides during movement and can be conveyed more smoothly.

In some embodiments, the connecting assembly includes a connecting body and at least one fixing portion disposed on the connecting body. The fixing portion is configured to fix the first sub-rope and/or the second sub-rope, so as to connect the connecting assembly and the traction rope.

In the technical solution of the foregoing embodiments of this application, the fixing portion can implement connection between the first sub-rope and/or the second sub-rope and the connecting assembly, so that the first sub-rope and/or the second sub-rope can be threaded through the fixing portion. In addition, the fixing portion is fixedly connected to the connecting assembly, and then the connecting assembly is connected to the electrode plate, so that the electrode plate can be conveyed through the traction ropes.

In some embodiments, the fixing portion is structured as a clamping piece and is configured to clamp the first sub-rope and/or the second sub-rope.

In the technical solution of the foregoing embodiments of this application, the clamping piece can more flexibly implement the connection between the first sub-rope and/or the second sub-rope and the connecting assembly. To convey the electrode plate, the clamping piece clamps the traction rope, so that the traction rope brings the electrode plate to run. Upon completion of conveying the electrode plate, the clamping piece releases the traction rope, so that the electrode plate can be removed from the guide mechanism.

In the technical solution of the foregoing embodiments of this application, the pressure roller generates a downward pressure on the first sub-rope and the second sub-rope, and limits the first sub-rope and the second sub-rope to a position in the corresponding guide slot, thereby avoiding a jam or even breakage of the electrode plate caused by derailment when the first sub-rope or the second sub-rope is detached from the guide slot.

In the technical solution of the foregoing embodiments of this application, the elastomer can adjust the distance between the pressure roller and the supporting roller according to the extent of upward and downward floating of the first sub-rope and the second sub-rope, so that the first sub-rope and the second sub-rope can pass through the limiting space more smoothly.

In some embodiments, the connecting assembly includes a first subsection and a second subsection that are spaced apart. A clamping position configured to clamp the electrode plate is formed between the first subsection and the second subsection.

In the technical solution of the foregoing embodiments of this application, the electrode plate is clamped in the clamping position, so that the connection between the electrode plate and the connecting assembly is more stable.

In some embodiments, the connecting assembly includes an adjusting piece connected between the first subsection and the second subsection. The adjusting piece is configured to adjust a distance between the first subsection and the second subsection in a gravity direction.

In the technical solution of the foregoing embodiments of this application, by controlling the adjusting piece, the dimensions of the clamping position can be adjusted according to an actual thickness of the electrode plate, so as to clamp the electrode plate more firmly in the clamping position and ensure stability of conveyance of the electrode plate.

In some embodiments, the driving mechanism includes a driving roller and a driving source that are drivingly connected. The traction rope is wound around the driving roller end-to-end along the conveyance direction, so as to move along the conveyance direction as driven by the driving source.

In the technical solution of the foregoing embodiments of this application, the driving roller can rotate as driven by the driving source, thereby bringing the first sub-rope and the second sub-rope to move along the conveyance direction of the electrode plate and implementing conveyance of the electrode plate.

According to a second aspect, this application provides a baking device. The baking device is configured to dry an electrode plate and includes an oven and the conveyor described above. An accommodation space configured to dry the electrode plate is provided in the oven. The conveyor is disposed in the accommodation space.

In the conveyor and the baking device, the traction rope brings the electrode plate to move in the transport space. The traction rope is of high flexibility and can more smoothly bring the electrode plate to move in various complex environments such as an arcuate oven, thereby effectively avoiding derailment or jamming of the conveyor in the oven and conveying the electrode plate more smoothly in the oven.

The foregoing description is merely an overview of the technical solutions of this application. Some specific embodiments of this application are described below illustratively to enable a clearer understanding of the technical solutions of this application, enable implementation of the technical solutions based on the subject-matter hereof, and make the foregoing and other objectives, features, and advantages of this application more evident and comprehensible.

By reading the following detailed description of embodiments, a person of ordinary skill in the art becomes clearly aware of various other advantages and benefits. The drawings are merely intended to illustrate the embodiments, but not to limit this application. In all the drawings, the same reference numeral represents the same component. In the drawings:.

Some embodiments of the technical solutions of this application are described in detail below with reference to the drawings. The following embodiments are merely intended as examples to describe the technical solutions of this application more clearly, but not intended to limit the protection scope of this application.

Unless otherwise defined, all technical and scientific terms used herein bear the same meanings as what is normally understood by a person skilled in the technical field of this application. The terms used herein are merely intended to describe specific embodiments but not to limit this application. The terms "include" and "contain" and any variations thereof used in the specification, claims, and brief description of drawings of this application are intended as non-exclusive inclusion.

In the description of the embodiments of this application, the technical terms "first" and "second" are merely intended to distinguish between different items but not intended to indicate or imply relative importance or implicitly specify the number of the indicated technical features, specific order, or order of precedence. In the description of the embodiments of this application, unless otherwise expressly specified, "a plurality of" means two or more.

Reference to an "embodiment" herein means that a specific feature, structure or characteristic described with reference to this embodiment may be included in at least one embodiment of this application. Reference to this term in different places in the specification does not necessarily represent the same embodiment, nor does it represent an independent or alternative embodiment in a mutually exclusive relationship with other embodiments. A person skilled in the art explicitly and implicitly understands that the embodiments described herein may be combined with other embodiments.

In the description of embodiments of this application, the term "and/or" merely indicates a relationship between related items, and represents three possible relationships. For example, "A and/or B" may represent the following three circumstances: A alone, both A and B, and B alone. In addition, the character "/" herein generally indicates an "or" relationship between the item preceding the character and the item following the character.

In the description of embodiments of this application, the term "a plurality of" means two or more (including two). Similarly, "a plurality of groups" means two or more groups (including two groups), and "a plurality of pieces" means two or more pieces (including two pieces).

In the description of embodiments of this application, a direction or a positional relationship indicated by the terms such as "center", "longitudinal", "transverse", "length", "width", "thickness", "up", "down", "before", "after", "left", "right", "vertical", "horizontal", "top", "bottom", "in", "out", "clockwise", "counterclockwise", "axial", "radial", and "circumferential" is a direction or positional relationship based on the illustration in the drawings, and is merely intended for ease or brevity of description of embodiments of this application, but not intended to indicate or imply that the indicated device or component is necessarily located in the specified direction or constructed or operated in the specified direction. Therefore, such terms are not to be understood as a limitation on embodiments of this application.

In the description of the embodiments of this application, unless otherwise expressly specified and defined, the technical terms such as "mounting", "concatenation", "connection", and "fixing" need to be understood in a broad sense, for example, understood as a fixed connection or a detachable connection or integrally formed; or understood as a mechanical connection or an electrical connection; understood as a direct connection, or an indirect connection implemented through an intermediary; or understood as internal communication between two components or interaction between two components. A person of ordinary skill in the art can understand the specific meanings of the terms in the embodiments of this application according to specific situations.

Currently, as can be seen from the market trend, the application of power batteries is increasingly extensive. Power batteries are not only used in energy storage power systems such as hydro, thermal, wind, and solar power stations, but also widely used in electric means of transport such as electric bicycles, electric motorcycles, and electric vehicles, and used in many other fields such as military equipment and aerospace. The market demand for power batteries keeps soaring with the increase of the application fields of the power batteries.

A production process of a power battery includes a coating step. In the coating step, a coated electrode plate of the battery needs to be dried in an oven before a next step of processing. However, in order to ensure a good drying effect and high production efficiency, the oven is usually in a long shape so that the electrode plate can be sufficiently dried. For this reason, during the movement of the electrode plate in the oven, the electrode plate is prone to break off due to a nonuniform force exerted on the electrode plate.

To cope with the problem of breakage of the electrode plate, in a case that no auxiliary apparatus is in use, a conventional method is that an operator stops heating the oven. After the temperature in the oven drops to an appropriate level, the operator opens a side door of the oven after wearing labor protection clothes, and manually pulls the electrode plate in the oven from a side to pass the electrode plate through the oven. After the electrode plate is pulled out of the oven, a broken section of electrode plate is connected to another broken section by the operator, and is wound up through slow conveyance. This period is time-consuming. Specifically, it takes a long time to cool the oven, and to heat up the oven after restart. In addition, when a part of the electrode plate is manually pulled out of the oven, the pulling force direction is prone to deviate from the movement direction of the electrode plate in the oven, thereby resulting in misalignment or even repeated breakage of the electrode plate. In addition, due to a narrow space in the oven, the operation of manually pulling the electrode plate out of the oven is inconvenient, time-consuming, and labor-consuming.

Therefore, currently, an auxiliary conveyance structure is disposed inside the oven. For example, a guide rail and a movable piece located in the guide rail are disposed, so that the movable piece brings the electrode plate to run along the guide rail. The inner space of some ovens is not completely flat and straight, but is arcuate. For the arcuate oven, in the prior art, a chain is usually used to bring the electrode plate to move in the oven. The chain is mounted in the oven in two manners. One of the mounting manners is to use a chain in conjunction with a guide rail, so that the chain moves in the guide rail to bring the electrode plate to move. In this manner, the mounting process is demanding. If the chain is not mounted properly, the chain is prone to jamming in the arcuate oven, thereby being adverse to practical applications. The other manner is to use sprockets to support the chain. In this manner, due to the heavy weight of the chain, the chain is prone to derail and result in breakage of the electrode plate, and the mounting process is complicated.

Through research based on the above situation, the applicant hereof finds that the electrode plate may be pulled by a traction rope to move in the arcuate oven. Due to the low weight of the traction rope, the traction rope is not prone to derail during the movement, thereby more stably bringing the electrode plate to move. In addition, due to higher flexibility of the traction rope, the mounting of the traction rope inside the oven is more flexible and convenient. The traction rope can pull the electrode plate to move smoothly in a complicated environment.

Based on the above considerations, in order to solve the problem that the conveyor is prone to derailment or jamming when bringing the electrode plate to move in an arcuate oven and results in low production efficiency and probable breakage of the electrode plate, the applicant has designed a conveyor and a baking device through in-depth research, in which a traction rope brings the electrode plate to move so that the electrode plate is conveyed more smoothly.

Referring to <FIG> and <FIG>, <FIG> is a schematic structural diagram of a conveyor according to an embodiment of this application, and <FIG> is a schematic diagram of a partial structure of a conveyor according to an embodiment of this application. This utility model provides a conveyor <NUM>, configured to convey an electrode plate. The conveyor <NUM> includes: a main body (not shown in the drawing), a guide mechanism <NUM>, and a driving mechanism <NUM>. The main body includes a transport space for accommodating the electrode plate. The guide mechanism <NUM> is disposed in the transport space. In addition, the guide mechanism <NUM> includes a traction rope <NUM>. The traction rope <NUM> extends along a conveyance direction of the electrode plate and is connected to the electrode plate to bring the electrode plate to move. The driving mechanism <NUM> is drivingly connected to the traction rope <NUM>, so as to drive the traction rope <NUM> to bring the electrode plate to move along the conveyance direction.

It is hereby noted that the traction rope <NUM> may be a steel wire rope. The steel wire rope is of high rigidity and can reduce the risk of breaking off during the conveyance, and therefore, can serve to stably support the electrode plate. In addition, metal particles are prone to be generated by friction of the steel wire rope in motion. The metal particles are prone to adhere to and pollute the electrode plate in a high-temperature environment inside the oven. Therefore, the steel wire rope is coated with a non-metallic protection layer. The non-metallic protection layer not only protects the steel wire rope to some extent, but also prevents the electrode plate from being polluted by the metal particles generated during the movement, thereby ensuring high quality of the electrode plate.

Understandably, in some other embodiments, the traction rope <NUM> may be another similar rope structure other than the steel wire rope, or be directly a rope structure made of a non-metallic material, details of which are omitted here.

Specifically, in this embodiment, the conveyor <NUM> is configured to convey the electrode plate in the oven. Therefore, the conveyor <NUM> is disposed inside the oven. That is, the transport space is located inside the oven. The traction rope <NUM> is fixedly connected to the electrode plate. As driven by the driving mechanism <NUM>, the traction rope <NUM> may bring the electrode plate to move along a specified path. The traction rope <NUM> is of high flexibility, and therefore, can more smoothly bring the electrode plate to move along a specified path in the oven, thereby avoiding derailment or jamming during movement and conveying the electrode plate more smoothly and steadily in the oven.

In addition, the traction rope <NUM> is fixed to the electrode plate by being indirectly connected to the electrode plate. To be specific, the electrode plate may be fixed to the traction rope <NUM> by means of a connecting piece, thereby implementing stable connection between the electrode plate and the traction rope <NUM>.

According to the present invention and as shown in <FIG>, the conveyor <NUM> includes a supporting roller <NUM> disposed under the traction rope <NUM> along a gravity direction. A guide slot <NUM> that extends along the transport space is made on the supporting roller <NUM>. The traction rope <NUM> is disposed in the guide slot <NUM>.

Specifically, the guide slot <NUM> is disposed along a circumferential direction of the supporting roller <NUM>, and the guide slot <NUM> is in a middle-recessed shape. The supporting roller <NUM> is fixed onto an inner sidewall of the oven through an axle of the supporting roller, and can rotate around the axle. When the traction rope <NUM> is accommodated in the guide slot <NUM>, the supporting roller <NUM>, on the one hand, serves to support the traction rope <NUM> and prevents the traction rope <NUM> from drooping due to its own gravity. In addition, the middle-recessed guide slot <NUM> prevents the traction rope <NUM> from coming out of the guide slot, and ensures stability of movement of the traction rope <NUM> in the guide slot <NUM>.

Further, in practical applications, the supporting roller <NUM> is fixed onto the inner sidewall of the oven, and a plurality of supporting rollers are disposed along the conveyance direction. The guide slots <NUM> on all supporting rollers <NUM> jointly form a discontinuous guide path, so that the steel wire rope can bring the electrode plate to move along the guide path. In addition, the guide slot <NUM> can limit the steel wire rope to a specified position to prevent the steel wire rope from detaching from the supporting roller <NUM>, and in turn, reduce the risk of breaking the electrode plate.

In some embodiments, the supporting roller <NUM> includes a first sub-roller and a second sub-roller. The first sub-roller and the second sub-roller are spaced apart in a horizontal plane that intersects the conveyance direction. The traction rope <NUM> includes a first sub-rope <NUM> and a second sub-rope <NUM>. The first sub-rope <NUM> and the second sub-rope <NUM> are disposed in the guide slot <NUM> of the first sub-roller and the second sub-roller respectively. A conveyance space <NUM> for accommodating the electrode plate is formed between the first sub-rope and the second sub-rope. The guide mechanism <NUM> includes a connecting assembly <NUM>. Two ends of the connecting assembly <NUM> are connected to the first sub-rope <NUM> and the second sub-rope <NUM> respectively, so as to fix the electrode plate in the conveyance space <NUM>.

Specifically in this embodiment, the first sub-roller and the second sub-roller are disposed on two sides of the electrode plate respectively along a width direction of the electrode plate, and the first sub-rope <NUM> and the second sub-rope <NUM> are disposed on the two sides of the electrode plate along the width direction. The first sub-roller and the second sub-roller on the two sides of the electrode plate are fixed onto two opposite inner sidewalls in the oven respectively, and therefore, are disposed opposite to each other so that the first sub-rope <NUM> and the second sub-rope <NUM> can be accommodated in the guide slot <NUM> of the first sub-roller and the second sub-roller respectively.

Further, a plurality of sets of first sub-rollers and second sub-rollers are arranged along the conveyance direction of the electrode plate. In each set, the first sub-roller and the second sub-roller are disposed corresponding to each other. Therefore, the traction rope <NUM> can extend along the arrangement path of the first sub-rollers and second sub-rollers, so as to bring the electrode plate to move along the path.

A conveyance space <NUM> is formed between the first sub-rope <NUM> and the second sub-rope <NUM>. The electrode plate is located in the conveyance space <NUM>. In addition, the connecting assembly <NUM> is a conveyance rod. Two ends of the conveyance rod are fixedly connected to the first sub-rope <NUM> and the second sub-rope <NUM> respectively, and the conveyance rod is fixed to the electrode plate. In this way, when the first sub-rope <NUM> and the second sub-rope <NUM> move in the guide slot <NUM> as driven by the driving mechanism <NUM>, the conveyance rod can bring the electrode plate to move synchronously.

In some embodiments, the connecting assembly <NUM> includes a connecting body <NUM> and at least one fixing portion <NUM> disposed on the connecting body <NUM>. The fixing portion <NUM> is configured to fix the first sub-rope <NUM> and/or the second sub-rope <NUM>, so as to connect the connecting assembly <NUM> and the traction rope <NUM>.

Specifically in this embodiment, two fixing portions <NUM> are disposed at the two ends of the connecting body <NUM> respectively. The connecting body <NUM> is a rod body of the conveyance rod. The fixing portions <NUM> located at the two ends of the rod body are configured to fix the first sub-rope <NUM> and the second sub-rope <NUM>.

Further, the two ends of the rod body may be fixedly connected to the first sub-rope <NUM> and the second sub-rope <NUM> by the fixing portion <NUM>. That is, the first sub-rope <NUM> and the second sub-rope <NUM> are directly threaded through the fixing portion <NUM>, as shown in <FIG>, so as to implement fixed connection between the rod body and the sub-ropes. This method makes the connection more stable.

In addition, the two ends of the fixing portion <NUM> are chamfered, so that the fixing portion <NUM> forms a trapezoidal structure. In this way, the fixing portion <NUM> can pass between the supporting roller <NUM> and the pressure roller <NUM> that corresponds to the supporting roller, and avoid jamming caused when the fixing portion <NUM> passes between the supporting roller <NUM> and the pressure roller <NUM>.

Referring to <FIG> is a schematic diagram of a partial structure of a conveyor according to another embodiment of this application. In some embodiments, the fixing portion <NUM> is structured as a clamping piece and is configured to clamp the first sub-rope <NUM> and/or the second sub-rope <NUM>. Specifically, the clamping piece includes two plate-shaped fittings spaced apart. A fixing position is formed between the two plate-shaped fittings. The two plate-shaped fittings can move toward each other or away from each other to change the size of the fixing position. The fixing position may be configured to accommodate the traction rope <NUM>. To clamp the traction rope <NUM>, the traction rope <NUM> is placed in the fixing position, and the two plate-shaped fittings are caused to move toward each other until the traction rope <NUM> is clamped and fixed. To unclamp the traction rope <NUM>, the two plate-shaped fittings are just caused to move away from each other to enlarge the fixing position between the two plate-shaped fittings, so that the traction rope <NUM> is released from between the two plate-shaped fittings.

During the conveyance of the electrode plate in the oven, the clamping piece can clamp and fix the first sub-rope <NUM> and the second sub-rope <NUM> separately to implement the connection between the electrode plate and the conveyance rod, thereby bringing the electrode plate to move. When the electrode plate stops moving or needs to undergo another operation, the clamping piece may release the first sub-rope <NUM> and the second sub-rope <NUM> to separate the electrode plate from the traction rope, thereby being more flexible and convenient.

Referring to <FIG> again, and according to the present invention, the conveyor <NUM> includes a pressure roller <NUM>. The pressure roller <NUM> is disposed corresponding to the supporting roller <NUM>. A limiting space is defined between the pressure roller and the supporting roller. The traction rope <NUM> is disposed in the limiting space.

Specifically, the pressure roller <NUM> is fixed onto an inner sidewall of the oven through an axle of the pressure roller, and can rotate around the axle. In addition, the pressure roller <NUM> is disposed above the supporting roller <NUM> along the gravity direction, and the pressure roller <NUM> is disposed in one-to-one correspondence with the supporting roller <NUM>. A limiting space is formed between the pressure roller <NUM> and the corresponding supporting roller <NUM> in each set along the gravity direction. The first sub-rope <NUM> and the second sub-rope <NUM> can be positioned in the limiting space.

When the first sub-rope <NUM> and the second sub-rope <NUM> move in the guide slot <NUM> on the corresponding supporting roller <NUM>, the first sub-rope <NUM> and the second sub-rope <NUM> may be detached from the guide slot <NUM> along the width direction of the electrode plate, thereby resulting in derailment. The derailment of the first sub-rope <NUM> and the second sub-rope <NUM> will stress the electrode plate nonuniformly during conveyance, thereby leading to breakage of the electrode plate.

After the pressure roller <NUM> is disposed, the pressure roller <NUM> generates a downward pressure on the first sub-rope <NUM> and the second sub-rope <NUM>, and limits the first sub-rope <NUM> and the second sub-rope <NUM> to a position in the corresponding guide slot <NUM> along the gravity direction, thereby preventing the first sub-rope <NUM> and the second sub-rope <NUM> from detaching from the guide slot <NUM>.

According to the present invention, the conveyor <NUM> includes a floating mechanism <NUM>. The floating mechanism <NUM> includes a fastener <NUM> and an elastomer <NUM>. The fastener <NUM> is fixedly connected to the main body. One end of the elastomer <NUM> is connected to the fastener <NUM>, and another end of the elastomer is connected to the pressure roller <NUM>, so as to change a distance between the pressure roller <NUM> and the supporting roller <NUM>.

In a specific embodiment, the elastomer <NUM> may be a spring. The spring is connected between the fastener <NUM> and the pressure roller <NUM> to adjust the distance between the pressure roller <NUM> and the supporting roller <NUM>. Understandably, the elastomer <NUM> may be of another structure similar to a spring, details of which are omitted here.

Specifically, the fixing piece <NUM> is fixedly disposed on the inner wall of the oven. The elastomer <NUM> is connected between the fastener <NUM> and the pressure roller <NUM>. Therefore, when the first sub-rope <NUM> and the second sub-rope <NUM> are located in the limiting space, because the mounting error is inevitable, the first sub-rope <NUM> and the second sub-rope <NUM> will float up and down during the movement. The elastomer <NUM> can adjust the distance between the pressure roller <NUM> and the supporting roller <NUM> according to the extent of upward and downward floating of the first sub-rope <NUM> and the second sub-rope <NUM>, so that the first sub-rope <NUM> and the second sub-rope <NUM> can pass through the limiting space more smoothly.

Referring to <FIG> is a schematic structural diagram of a conveyor according to an embodiment of this application, and <FIG> is a schematic structural diagram of a connecting assembly according to an embodiment of this application. To fix the connecting assembly <NUM> to the electrode plate more firmly, the connecting assembly <NUM> includes a first subsection <NUM> and a second subsection <NUM> that are spaced apart. A clamping position <NUM> configured to clamp the electrode plate is formed between the first subsection <NUM> and the second subsection <NUM>.

Specifically, the rod body of the conveyance rod is divided into a first subsection <NUM> and a second subsection <NUM>. The first subsection <NUM> and the second subsection <NUM> are disposed apart along the gravity direction. In this way, a clamping position <NUM> is formed between the first subsection <NUM> and the second subsection <NUM>, and the electrode plate is clamped in the clamping position <NUM>, so that the connection between the electrode plate and the conveyance rod is more stable.

In some embodiments, the connecting assembly <NUM> includes an adjusting piece <NUM> connected between the first subsection <NUM> and the second subsection <NUM>. The adjusting piece <NUM> is configured to adjust a distance between the first subsection <NUM> and the second subsection <NUM> in a gravity direction.

Specifically in this embodiment, the adjusting piece <NUM> is an adjusting bolt disposed between the first subsection <NUM> and the second subsection <NUM>. The adjusting bolt can change the distance between the first subsection <NUM> and the second subsection <NUM> in the gravity direction. In this way, the clamping position <NUM> between the first subsection <NUM> and the second subsection <NUM> can adapt to electrode plates of different thicknesses, and prevent the electrode plate from being damaged by unduly tight clamping of the electrode plate by the first subsection <NUM> and the second subsection <NUM> or prevent detachment of the electrode plate caused by loose clamping.

Therefore, by controlling the adjusting piece <NUM>, the dimensions of the clamping position <NUM> can be adjusted according to an actual thickness of the electrode plate, so as to clamp the electrode plate more firmly in the clamping position <NUM> and ensure stability of conveyance of the electrode plate.

Referring to <FIG> again, in some embodiments, the driving mechanism <NUM> includes a driving roller <NUM> and a driving source (not shown in the drawing) that are drivingly connected. The traction rope <NUM> is wound around the driving roller <NUM> end-to-end along the conveyance direction, so as to move along the conveyance direction as driven by the driving source.

Specifically, two driving rollers <NUM> are disposed at a start end of the oven, and at a terminating end of the oven, separately. The two driving rollers are spaced along the width direction of the electrode plate. The first sub-rope <NUM> and the second sub-rope <NUM> each are wound around the driving rollers <NUM> end-to-end along the conveyance direction of the electrode plate, where the driving rollers are located at the start end and the terminating end of the oven respectively. The driving rollers <NUM> can rotate as driven by the driving source, thereby bringing the first sub-rope <NUM> and the second sub-rope <NUM> to move along the conveyance direction of the electrode plate and implementing conveyance of the electrode plate.

Due to scanty space available in the oven, the driving rollers <NUM> are usually disposed outside the oven and located at a start entrance and a terminating entrance of the oven respectively, and bring the first sub-rope <NUM> and the second sub-rope <NUM> to move.

Based on the same conception as the conveyor <NUM> described in the preceding embodiments, this application provides a baking device configured to dry an electrode plate. The baking device includes an oven and the conveyor <NUM> described above. The oven includes an accommodation space configured to dry the electrode plate, and the conveyor <NUM> is disposed in the accommodation space.

In a practical implementation of this application, the driving roller <NUM> rotates as driven by the driving source, thereby bringing the first sub-rope <NUM> and the second sub-rope <NUM> to move along the conveyance direction of the electrode plate. Inside the oven, the first sub-rope <NUM> and the second sub-rope <NUM> move along the guide slot <NUM> on the corresponding supporting roller <NUM>. The pressure rollers <NUM> located above the first sub-rope <NUM> and the second sub-rope <NUM> can prevent the first sub-rope <NUM> and the second sub-rope <NUM> from detaching from the guide slot <NUM>.

When the conveyance rod passes between the supporting roller <NUM> and the pressure roller <NUM>, the supporting roller <NUM> and the pressure roller <NUM> can roll over the fixing portion <NUM>. At the same time, the spring adjusts the distance between the supporting roller <NUM> and the pressure roller <NUM> in the gravity direction, so that the conveyance rod can pass through the limiting space smoothly.

The conveyor <NUM> and the baking device in the foregoing embodiments have at least the following advantages:.

Claim 1:
A conveyor (<NUM>), configured to convey an electrode plate and comprising:
a main body, wherein the main body comprises a transport space for accommodating the electrode plate;
a guide mechanism (<NUM>), wherein the guide mechanism (<NUM>) is disposed in the transport space and comprises a traction rope (<NUM>), and the traction rope (<NUM>) extends along a conveyance direction of the electrode plate and is connected to the electrode plate to bring the electrode plate to move; and
a driving mechanism (<NUM>), wherein the driving mechanism (<NUM>) is drivingly connected to the traction rope (<NUM>), so as to drive the traction rope (<NUM>) to bring the electrode plate to move along the conveyance direction,
wherein the conveyor (<NUM>) comprises a supporting roller (<NUM>) disposed under the traction rope (<NUM>) along a gravity direction, a guide slot (<NUM>) that extends along the conveyance direction is made on the supporting roller (<NUM>), and the traction rope (<NUM>) is disposed in the guide slot (<NUM>),
wherein the conveyor (<NUM>) comprises a pressure roller (<NUM>), the pressure roller (<NUM>) is disposed corresponding to the supporting roller (<NUM>), a limiting space is defined between the pressure roller (<NUM>) and the supporting roller (<NUM>), and the traction rope (<NUM>) is disposed in the limiting space,
wherein the conveyor (<NUM>) comprises a floating mechanism (<NUM>), and the floating mechanism (<NUM>) comprises:
a fastener (<NUM>), fixedly connected to the main body; and
an elastomer (<NUM>), wherein one end of the elastomer (<NUM>) is connected to the fastener (<NUM>), and another end of the elastomer (<NUM>) is connected to the pressure roller (<NUM>), so as to change a distance between the pressure roller (<NUM>) and the supporting roller (<NUM>).