Patent Description:
The present invention relates to the technical field of batteries, and in particular to a stacking device and a method for manufacturing a stacked type electrode assembly.

Due to the advantages of high rate and high energy density of stacked type cells compared with wound cells, batteries made of stacked type cells are widely used.

A stacking device attaches separators on two sides of a negative electrode sheet, and then attaches a positive electrode sheet on the side of each separator away from the negative electrode sheet, and finally the negative electrode sheet, the separators and the positive electrode sheets that are attached to one another are repeatedly folded and stacked by means of a stacking platform to form a stacked type cell. The attachment process of the negative electrode sheet, the separators and the positive electrode sheets is relatively complicated, so that the entire structure of the stacking device is complicated and the material waste is serious, thus increasing the manufacturing cost.

Therefore, how to simplify the structure and reduce the material waste of the stacking device has become an urgent problem to be solved in the technical field of batteries. <CIT>, on which the preamble of claim <NUM> is based, relates to a laminating machine. The laminating machine comprises a heating device, a first sheet material device, a second sheet material device and a first compounding device. <CIT> relates to a pre-oven thermal composite lamination device, and relates to the technical field of lithium ion battery manufacturing.

The present invention provides a stacking device and a method for manufacturing a stacked type electrode assembly, so as to simplify the structure of the stacking device and reduce the material waste.

In a first aspect, the present invention provides a stacking device according to claim <NUM>.

Thanks to the fact that the first heating mechanism is arranged downstream of the separator delivery mechanism, the first heating mechanism is used to heat the negative electrode sheet and the separators, and the positive delivery mechanism for delivering the positive electrode sheets to the two sides of the negative electrode sheet is arranged downstream of the first heating mechanism, the first heating mechanism can heat the negative electrode sheet and the separators that are arranged in a laminated manner before the positive electrode sheets are attached to the separators, so as to soften glue or adhesives on surfaces of the separators, so that the separators have bonding properties, and the positive electrode sheets can be directly bonded to the separators and delivered to the next station along with the separators. There is no need to provide a PET film (Polyester Film) feeding apparatus for supplying PET films and to fix the positive electrode sheets by means of the PET films, so that the positive electrode sheets are static relative to the PET films, the positive electrode sheets do not shift during a delivery process of the PET films, and the positive electrode sheets are transported to the next station under the drive of the PET films. The entire structure of the stacking device is simplified, and the production cost of the stacked type electrode assembly is reduced. Moreover, no PET film is provided, which also shortens the path through which heat passes, and has a stronger ability to soften the glue or adhesives on the separators, thereby improving the attachment quality.

The second heating mechanism is used to heat the separators before the separators are attached to the negative electrode sheet, so that the glue or adhesives on the separators are softened, the separators then have bonding properties before being attached to the negative electrode sheet, and the separators can be bonded to the negative electrode sheet and conveyed to the first heating mechanism, facilitating the subsequent attachment of the positive electrode sheets to the negative electrode sheet.

The second heating assembly heats the side of the separator that is used to attach to the negative electrode sheet, so that the side of the separator that is used to attach to the negative electrode sheet can be sufficiently heated, the glue on the side of the separator that is used to attach to the negative electrode sheet can be thus sufficiently softened, and the side of the separator that is used to attach to the negative electrode sheet has stronger bonding properties.

The pressing mechanism is used to flatten the bent segments of the stacked type structure, so as to make the structure of the stacked type structure more compact in a laminating direction and improve the quality of the stacked type structure.

In some embodiments of the first aspect of the present invention, the first heating mechanism comprises two first heating assemblies respectively located on the two sides of the negative electrode sheet and respectively used for heating the separators on the two sides of the negative electrode sheet and the negative electrode sheet.

In the above technical solution, thanks to the fact that the first heating mechanism includes two first heating assemblies respectively located on the two sides of the negative electrode sheet for heating the separators on the two sides of the negative electrode sheet, the two separators are both sufficiently heated, so that the glue or adhesives on the surfaces of the two separators are sufficiently softened to provide stronger bonding properties.

In some embodiments of the present invention, glue is provided on the two sides of each separator to bond the separator to the negative electrode sheet and to bond the separator to the respective positive electrode sheet.

In the above technical solution, thanks to the fact that glue is provided on the two sides of each separator, the first heating mechanism can heat the separator to soften the glue on the separator, so that the glue can be sufficiently joined with the negative electrode sheet and the positive electrode sheet, so that a stronger ability to bond the separator to the negative electrode sheet, and the separator to the positive electrode sheet is provided.

Glue is provided on the two sides of the negative electrode sheet to bond the separators to the negative electrode sheet.

In the above technical solution, thanks to the fact that glue is provided on the two sides of the negative electrode sheet, the first heating mechanism can heat the negative electrode sheet to soften the glue on the negative electrode sheet, and the glue can be sufficiently joined with the separators, so that a stronger ability to bond the separators to the negative electrode sheet is provided.

In some embodiments of the first aspect, the second heating mechanism comprises two second heating assemblies respectively configured to heat the two separators.

In the above technical solution, both sides of the negative electrode sheet need to be attached to the separators, so there are two separators, and the second heating mechanism includes two second heating assemblies respectively for heating the two separators, so that the glue or adhesives on the surfaces of the separators can be sufficiently softened and the uniformity of heating of the two separators can be improved, thereby improving the attachment quality of the separators and the negative electrode sheet.

In some embodiments of the first aspect of the present invention, the separator delivery mechanism further comprises a first pressing roller assembly arranged downstream of the second heating mechanism and upstream of the first heating mechanism and configured to press the separators against the negative electrode sheet such that the separators are attached to the two sides of the negative electrode sheet.

In the above technical solution, the negative electrode sheet is bonded to the separators in advance, thereby avoiding the deflection phenomenon caused by the instantaneous tension loss of the negative electrode sheet after cutting. Moreover, the separators located on the two sides of the negative electrode sheet are pressed against the negative electrode sheet by the first pressing roller assembly, so that firmer connections are provided between the separators and the negative electrode sheet, and the attachment quality of the separators and the negative electrode sheet is improved.

In some embodiments of the first aspect of the present invention, the positive delivery mechanism comprises a third heating mechanism configured to heat the positive electrode sheets before the positive electrode sheets are attached to the separators.

In the above technical solution, the third heating mechanism is used to heat the positive electrode sheets before the positive electrode sheets are attached to the separators, so that the glue or adhesives on the surfaces of the positive electrode sheets are softened, and the positive electrode sheets also have a bonding ability to facilitate the attachment of the positive electrode sheets to the separators. In addition, providing heat to the positive electrode sheets during attachment can compensate for the heat loss during the conveying of the separators to the positive electrode sheets to be attached thereto, and reduce the heat loss of the separators, so that the glue or adhesives on the separators remain in a softened state, facilitating the provision of stronger bonding properties for the surfaces of the separators that are used to attach to the positive electrode sheets, and improving the attachment quality of the positive electrode sheets attached to the separators.

In some embodiments of the first aspect of the present invention, the third heating mechanism comprises two third heating assemblies respectively configured to heat the corresponding positive electrode sheet.

In the above technical solution, the separators are attached to the two sides of the negative electrode sheet, a respective positive electrode sheet is attached to the side of each separator away from the negative electrode sheet, and the third heating mechanism includes two third heating assemblies respectively configured to heat the corresponding positive electrode sheets, so that each positive electrode sheet can be sufficiently heated, and the glue or adhesives on the surfaces of the separators are sufficiently softened. Each positive electrode sheet has a relatively high heat when it is attached to the corresponding separator, which compensates for the heat loss during the conveying of the separator to the positive electrode sheet to be attached thereto, so that the glue or adhesive on the separator remains in a softened state, and the separator thus has better bonding properties.

In some embodiments of the first aspect of the present invention, the third heating assembly is configured to heat two sides of the corresponding positive electrode sheet.

In the above technical solution, thanks to the fact that the third heating assembly is configured to heat the two sides of the corresponding positive electrode sheet, each positive electrode sheet can be sufficiently heated in a thickness direction of the positive electrode sheet, so that the glue or adhesive on the positive electrode sheet is softened and has a bonding ability. Heating the positive electrode sheet can also make the positive electrode sheet have higher heat, which can effectively compensate for the heat loss of the corresponding separator.

In some embodiments of the first aspect of the present invention, the positive electrode sheets are provided with glue to bond the separators to the positive electrode sheets.

In the above technical solution, thanks to the fact that the positive electrode sheets are provided with glue, the third heating mechanism heats the positive electrode sheets such that the glue on the positive electrode sheets is softened, the softened glue can be sufficiently joined with the separators, and a stronger ability to bond the separators and the positive electrode sheets is provided.

In some embodiments of the first aspect of the present invention, the positive delivery mechanism further comprises a positive cutting mechanism arranged downstream of the third heating mechanism and configured to cut the positive electrode sheet.

In the above technical solution, thanks to the fact that the positive cutting mechanism is arranged downstream of the third heating mechanism, it is possible that after the positive electrode sheet is heated, the positive electrode sheet is cut to form positive electrode sheets with a smaller length so that a plurality of positive electrode sheets with a smaller length are arranged at intervals on the side of the separator away from the negative electrode sheet, or that the positive electrode sheet is indented, so as to form a stacked type electrode assembly having better electrical properties. The positive cutting mechanism is arranged downstream of the third heating mechanism, and the positive electrode sheets are softer after being heated, and are easier to cut or indent.

In some embodiments of the first aspect of the present invention, the positive delivery mechanism further comprises a second pressing roller assembly configured to press the positive electrode sheets against the separators such that the positive electrode sheets are attached to the separators.

In the above technical solution, the positive electrode sheets are pressed against the separators by the second pressing roller assembly, so that firmer connections are provided between the positive electrode sheets and the separators, and the attachment quality of the positive electrode sheets and the separators is improved.

In some embodiments of the first aspect of the present invention, the stacking device further comprises a fourth heating mechanism arranged downstream of the negative delivery mechanism and configured to heat the negative electrode sheet before the two separators are attached to the negative electrode sheet.

In the above technical solution, the fourth heating mechanism is used to heat the negative electrode sheet before the separators are attached to the negative electrode sheet, so that the glue or adhesives on the surfaces of the negative electrode sheet are softened, and the negative electrode sheet thus also has a bonding ability to facilitate the attachment of the separators on the two sides of the negative electrode sheet. In addition, heat is provided to the negative electrode sheet during attachment, and the heat of the negative electrode sheet can help to soften the glue or adhesives on the surfaces of the separators, so that the surfaces of the separators that are used to attach to the negative electrode sheet have bonding properties, facilitating the attachment of the separators to the negative electrode sheet.

In some embodiments of the first aspect of the present invention, the pressing mechanism comprises two rotating portions arranged opposite to each other, the rotating portions being rotatably mounted to the stacking platform and configured to flatten the bent segments.

In the above technical solution, each bent segment is flattened by the corresponding rotating portion, so that the structure of the stacked type structure in the laminating direction is more compact, so as to improve the quality of the stacked type structure.

In some embodiments of the first aspect of the present invention, the rotating portion comprises a brush and a main body, wherein the main body is rotatably mounted to the stacking platform, and the brush is configured to flatten the bent segments.

In the above technical solution, the material of the brush is soft, and the brush is less likely to damage the stacked type structure when the bent portion is flattened.

In some embodiments of the first aspect of the present invention, the stacking device includes a driving mechanism and two stacking platforms, wherein the driving mechanism is configured to switch the positions of the two stacking platform such that one of the stacking platforms is located in a stacking position and the other stacking platform is in a non-stacking position.

In the above technical solution, the driving mechanism can switch the positions of the two stacking platforms such that when one of the stacking platforms is located in the stacking position, the other stacking platform is in the non-stacking position, that is, the two stacking platforms work alternately, and the stacking operation will not be suspended, improving the production efficiency.

In a second aspect, the present invention provides a method for manufacturing a stacked type electrode assembly, according to claim <NUM>.

Accordingly, the separators and the negative electrode sheet that are attached to each other are first heated so that the separators have bonding properties, the positive electrode sheets are then attached to the separators, and the glue or adhesives on the surfaces of the separators are softened before the positive electrode sheets are attached to the separators, so that the separators have bonding properties, and the positive electrode sheets can be directly bonded to the separators and delivered to the next station along with the separators. There is no need to provide a PET film feeding apparatus for supplying PET films and to fix the positive electrode sheets by means of the PET films, so that the positive electrode sheets are static relative to the PET films, the positive electrode sheets do not shift during a delivery process of the PET films, and the positive electrode sheets are transported to the next station under the drive of the PET films. The entire structure of the stacking device is simplified, and the production cost of the stacked type electrode assembly is reduced. Moreover, no PET film is provided, which also shortens the path through which heat passes, and has a stronger ability to soften the glue or adhesives on the separators, thereby improving the attachment quality.

To more clearly describe the technical solutions of the embodiments of the present application, the drawings to be used in the embodiments will be briefly introduced below, and it should be understood that the following drawings only show some embodiments of the present application, and therefore should not be considered as limiting the scope of the present invention.

List of reference signs: <NUM>', <NUM> - Stacking device; <NUM> - Negative delivery mechanism; <NUM> - Negative roll spool; <NUM> - Negative rectifying deviation sensor; <NUM> - Negative strip splicing mechanism; <NUM> - Negative tension balance mechanism; <NUM> - Negative rectifying deviation mechanism; <NUM> - Separator delivery mechanism; <NUM> - Second heating mechanism; <NUM> - Second heating assembly; <NUM> - First pressing roller assembly; <NUM> - First pressing roller; <NUM> - Second pressing roller; <NUM> - Separator roll spool; <NUM> - Separator rectifying deviation sensor; <NUM> - Separator strip splicing mechanism; <NUM> - Separator tension balance mechanism; <NUM> - First heating mechanism; <NUM> - First heating assembly; <NUM> - Positive delivery mechanism; <NUM> - Third heating mechanism; <NUM> - Third heating assembly; <NUM> - Heating unit; <NUM> - Positive cutting mechanism; <NUM> - Second pressing roller assembly; <NUM> - Third pressing roller; <NUM> - Fourth pressing roller; <NUM> - First cleaning mechanism; <NUM> - Negative cutting mechanism; <NUM> - Second cleaning mechanism; <NUM> - Fourth heating mechanism; <NUM> - Fourth heating assembly; <NUM> - Stacking mechanism; <NUM> - Transmission mechanism; <NUM> - Swing mechanism; <NUM> - Blowing mechanism; <NUM> - Stacking platform; <NUM> - Pressing mechanism; <NUM> - Rotating portion; <NUM> - Brush; <NUM> - Main body; <NUM> - Driving mechanism; <NUM> - First driving member; <NUM> - Second driving member; <NUM> - Separator makeup sealing mechanism; <NUM> - Positive and negative relative position detection mechanism; <NUM> - Electrode assembly; <NUM> - Laminated segment; <NUM> - Bent segment; <NUM> - Indentation; a - Negative electrode sheet; b - Separator; c - Positive electrode sheet; d - PET film; e - Heating mechanism.

In order to make the objectives, technical solutions and advantages of the present invention clearer, embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. The described embodiments are some of, rather than all of, the embodiments of the present invention, and are not intended to limit the scope of protection of the present invention which is defined by the appended claims.

A stacked type electrode assembly includes a negative electrode sheet, separators connected to two sides in a thickness direction of the negative electrode sheet, and a positive electrode sheet connected to the side of each separator away from the negative electrode sheet, and then a laminated strip formed by connecting the negative electrode sheet, the separators and the positive electrode sheets is repeatedly laminated to form a stacked type electrode assembly.

The inventors have found that, as shown in <FIG>, in an existing stacking device <NUM>', a negative electrode sheet a is supplied by a negative delivery mechanism (not shown in <FIG>), separators b are supplied by a separator delivery mechanism (not shown in <FIG>) respectively to two sides in a thickness direction of the negative electrode sheet a, and the separators b on the two sides in the thickness direction of the negative electrode sheet a are respectively connected to the negative electrode sheet a, so that a first laminated strip including the negative electrode sheet a and the two layers of separators b is formed; then positive electrode sheets c are supplied to two sides in a thickness direction of the first laminated strip by a positive delivery mechanism (not shown in <FIG>), and the positive electrode sheets c supplied on the two sides in the thickness direction of the first laminated strip are fixed by means of PET films (polyester films) d positive electrode sheets c, so that the positive electrode sheets c are located on the two sides in the thickness direction of the first laminated strip; and under the drive of the PET films d, the positive electrode sheets c and the first laminated strip are conveyed together to a heating mechanism e, and the heating mechanism e heats the positive electrode sheets c and the first laminated strip, so that glue or adhesives on surfaces of the separators b of the first laminated strip are softened, and the positive electrode sheet c can be connected to the separators b via the glue softened on the surfaces of the separators b to form a second laminated strip including the negative electrode sheet a, the two layers of separators b and the two layers of positive electrode sheets c. Therefore, the device for manufacturing a stacked type electrode assembly needs to be provided with a device for supplying the PET films d, which makes the entire manufacturing device larger in size and complicated in structure. The PET films d are consumables and need to be replaced frequently, which increases the production cost. Furthermore, due to the existence of the PET films d, heat from heating mechanism e needs to pass through the PET films d and the positive electrode sheets c to reach the separators b, so that a heat transfer path and time are longer, the heat loss is greater, and the heating effect on the separators b is poor. The glue or adhesives on the separators b cannot be softened sufficiently, thereby affecting the combination quality of the positive electrode sheets c and the separators b.

On this basis, the present invention provides a stacking device, in which a negative electrode sheet a and separators b arranged in a laminated manner are heated before positive electrode sheets c are attached to the separators b, so that glue or adhesives on surfaces of the separators b are softened, the separators b thus have bonding properties, and the positive electrode sheets c can be directly bonded to the separators b and delivered to the next station along with the separators b. There is no need to provide a PET film d feeding apparatus for supplying PET films d and to fix the positive electrode sheets c by means of the PET films d, so that the positive electrode sheets c are static relative to the PET films d, the positive electrode sheets c do not shift during a delivery process of the PET films d, and the positive electrode sheets c are transported to the next station under the drive of the PET films d. The entire structure of the stacking device is simplified, and the production cost of the stacked type electrode assembly <NUM> is reduced. Moreover, no PET film is provided, so that the path through which heat passes is also shortened, and a stronger ability to soften the glue or adhesives on the separators is provided, thereby improving the attachment quality.

<FIG> is a schematic structural diagram of a stacking device <NUM> provided in some embodiments of the present invention. The stacking device <NUM> includes a negative delivery mechanism <NUM>, a separator delivery mechanism <NUM>, a first heating mechanism <NUM> and a positive delivery mechanism <NUM>. The negative delivery mechanism <NUM> is configured to deliver a negative electrode sheet a. The separator delivery mechanism <NUM> is configured to deliver separators b to two sides of the negative electrode sheet a, such that the separators b are attached to the negative electrode sheet a. The first heating mechanism <NUM> is arranged downstream of the separator delivery mechanism <NUM>, and the first heating mechanism <NUM> is configured to heat the negative electrode sheet a and the separators b. The positive delivery mechanism <NUM> is arranged downstream of the first heating mechanism <NUM>, and the positive delivery mechanism <NUM> is configured to deliver positive electrode sheets c to the two sides of the negative electrode sheet a, such that the positive electrode sheets c are attached to the separators b.

The separator delivery mechanism <NUM> attaches the separators b to the negative electrode sheet a, which may mean that the separators b are in contact with the negative electrode sheet a but not connected thereto, or that the separators b are connected to the negative electrode sheet a. The positive delivery mechanism <NUM> attaches the positive electrode sheets c to the separator b, which may mean that the positive electrode sheets c are in contact with the separators b but not connected thereto, or that the positive electrode sheets c are connected to the separators b.

It should be noted that the terms "upstream" and "downstream" mentioned above and below in the embodiments of the present disclosure refer to orders in a production sequence, and are not intended to limit spatial positions of the respective components. Upstream refers to an earlier production sequence, and downstream refers to a later production sequence.

The glue or adhesives on the surfaces of the separators b may be a mixture of PVDF (poly(<NUM>,<NUM>-difluoroethylene), polyvinylidene fluoride) and styrene butadiene rubber. Of course, glue of other materials may also be used. In some embodiments, glue may also be provided on the two sides, to which the separators b are attached, of the negative electrode sheet a.

The heating method of the first heating mechanism <NUM> may be thermal radiation, contact-type flat-pressing or rolling.

Thanks to the fact that the first heating mechanism <NUM> is arranged downstream of the separator delivery mechanism <NUM>, the first heating mechanism <NUM> is used to heat the negative electrode sheet a and the separators b, and the positive delivery mechanism <NUM> for delivering the positive electrode sheets c to the two sides of the negative electrode sheet a is arranged downstream of the first heating mechanism <NUM>, the first heating mechanism <NUM> can heat the negative electrode sheet a and the separators b that are arranged in a laminated manner before the positive electrode sheets c are attached to the separators b, so as to soften glue or adhesives on surfaces of the separators b, so that the separators b have bonding properties, and the positive electrode sheets c can be directly bonded to the separators b and delivered to the next station along with the separators b. There is no need to provide a PET film (Polyester Film) feeding apparatus for supplying PET films d (shown in <FIG>) and to fix the positive electrode sheets c by means of the PET films d, so that the positive electrode sheets c are static relative to the PET films d, the positive electrode sheets c do not shift during a delivery process of the PET films d, and the positive electrode sheets c, the separators b and the negative electrode sheet a are transported to the next station under the drive of. The entire structure of the stacking device <NUM> is simplified, and the production cost of the stacked type electrode assembly <NUM> is reduced. Moreover, no PET film is provided, so that the path through which heat passes is also shortened, and a stronger ability to soften the glue or adhesives on the separators is provided, thereby improving the attachment quality. Furthermore, the first heating mechanism <NUM> also heats the negative electrode sheet a, if there is glue or adhesives on the two sides, to which the separators b are attached, of the negative electrode sheet a, the glue or adhesives may also be softened, so that the negative electrode sheet a also has bonding properties, and the negative electrode sheet a and the separators b are bonded to each other.

It should be noted that in the present invention, a class of organic or inorganic, natural or synthetic substances that can connect the same or two or more homogeneous or heterogeneous parts (or materials) together and have sufficient strength after curing are collectively referred to as pastes, adhesives, or binders, and are customarily referred to as glue.

Referring to <FIG> and <FIG> is a schematic diagram of the relative relationship between the negative electrode sheet a, the separators b and two first heating assemblies <NUM>. In some embodiments, the first heating mechanism <NUM> comprises two first heating assemblies <NUM>. The two first heating assemblies <NUM> are respectively located on the two sides of the negative electrode sheet a, and the two first heating assemblies <NUM> are respectively used for heating the separators b on the two sides of the negative electrode sheet a and the negative electrode sheet a.

The two first heating assemblies <NUM> are respectively located on the two sides of the negative electrode sheet a, which means that the two first heating assemblies <NUM> are each located on the side, away from the negative electrode sheet a, of a respective one of the separators b on the two sides of the negative electrode sheet a. That is, the first heating assembly <NUM> is arranged on the side of the corresponding separator b away from the negative electrode sheet a. The heating method of the first heating mechanism <NUM> may be thermal radiation, contact-type flat-pressing, rolling, etc. The first heating mechanism <NUM> adopts thermal radiation heating, which may be heating by means of a resistance wire and a metal plate, or infrared heating, or UV (ultraviolet radiation) furnace heating, or heating by means of a heating silicone rubber sheet. In other embodiments, the first heating mechanism <NUM> may include only one first heating assembly <NUM>, and the separators b on the two sides of the negative electrode sheet a are heated by the one first heating assembly <NUM>.

When the first heating mechanism <NUM> includes two first heating assemblies <NUM> and the two first heating assemblies <NUM> are respectively located on the two sides of the negative electrode sheet a for heating the separators b on the two sides of the negative electrode sheet a, the two separators b are both sufficiently heated, so that the glue or adhesives on the surfaces of the two separators b are sufficiently softened to provide stronger bonding properties.

Referring to <FIG> and <FIG>, according to the invention, the separator delivery mechanism <NUM> includes a second heating mechanism <NUM>. The second heating mechanism <NUM> is configured to heat the two separators b before the two separators b are attached to the negative electrode sheet a.

The heating method of the second heating mechanism <NUM> may be thermal radiation, contact-type flat-pressing, rolling, etc. The second heating mechanism <NUM> adopts thermal radiation heating, which may be heating by means of a resistance wire and a metal plate, or infrared heating, or UV (ultraviolet radiation) furnace heating, or heating by means of a heating silicone rubber sheet.

The second heating mechanism <NUM> is used to heat the separators b before the separators b are attached to the negative electrode sheet a, so that the glue or adhesives on the separators b are softened, the separators b then have bonding properties before being attached to the negative electrode sheet a, and the separators b can be bonded to the negative electrode sheet a and conveyed to the first heating mechanism <NUM>, facilitating the subsequent attachment of the positive electrode sheets c to the negative electrode sheet a.

It is necessary to attach the separators b to both sides of the negative electrode sheet a, so two separators b are provided. In some embodiments, the second heating mechanism <NUM> includes two second heating assemblies <NUM>. The two second heating assemblies <NUM> are respectively configured to heat the two separators b.

The two second heating assemblies <NUM> respectively heat the two separators b, which means that each separator b is provided with a corresponding second heating assembly <NUM>, and the separator b is heated by the corresponding second heating mechanism <NUM> to soften the glue on the surfaces. The second heating mechanism <NUM> adopts thermal radiation heating, which may be heating by means of a resistance wire and a metal plate, or infrared heating, or UV (ultraviolet radiation) furnace heating, or heating by means of a heating silicone rubber sheet. In other embodiments, the second heating mechanism <NUM> may also include only one second heating assembly <NUM>, and the two separators b are heated by the one second heating assembly <NUM>.

When the second heating mechanism <NUM> includes two second heating assemblies <NUM> and the two second heating assemblies <NUM> respectively heat the two separators b, the glue or adhesives on the surfaces of the separators b can be sufficiently softened and the uniformity of heating of the two separators b can be improved, thereby improving the attachment quality of the separators b and the negative electrode sheet a.

According to the invention, the second heating mechanism <NUM> is configured to heat the side of the separator b that is used to attach to the negative electrode sheet a.

The second heating mechanism <NUM> is configured to heat the side of the separator b that is used to attach to the negative electrode sheet a, which means that the second heating mechanism <NUM> is arranged on the side of the separator b that is used to attach to the negative electrode sheet a, to sufficiently heat the side of the separator b that is used to attach to the negative electrode sheet a.

One side in a thickness direction of the separator b is used to connect to the negative electrode sheet a. In the embodiment where the second heating mechanism <NUM> includes two second heating assemblies <NUM>, each second heating assembly <NUM> is arranged on the side of the corresponding separator b that is used to attach to the negative electrode sheet a, so that the side of the separator b that is used to attach to the negative electrode sheet a can be sufficiently heated, the glue or adhesive on the side of the separator b that is used to attach to the negative electrode sheet a can be thus sufficiently softened, and the side of the separator b that is used to attach to the negative electrode sheet a has stronger bonding properties.

In some embodiments, the second heating mechanism <NUM> may also be used to heat the two sides of the separator b. That is, the second heating mechanism <NUM> is used to heat the side of the separator b that is used to attach to the negative electrode sheet a and the side of the separator b away from the negative electrode sheet a. The two sides of each separator b may be respectively provided with corresponding second heating assemblies <NUM>, so as to heat the two sides of the separator b.

Referring to <FIG> and <FIG>, in some embodiments, the separator delivery mechanism <NUM> further includes a first pressing roller assembly <NUM>. The first pressing roller assembly <NUM> is arranged downstream of the second heating mechanism <NUM> and upstream of the first heating mechanism <NUM>, and the first pressing roller assembly <NUM> is configured to press the separators b against the negative electrode sheet a such that the separators b are attached to the two sides of the negative electrode sheet a.

The first pressing roller assembly <NUM> includes a first pressing roller <NUM> and a second pressing roller <NUM>. The first pressing roller <NUM> and the second pressing roller <NUM> are respectively located on the two sides of the negative electrode sheet a, and each of the first pressing roller <NUM> and the second pressing roller <NUM> is located on the side of a respective one of the two separators b away from the negative electrode sheet a, so that the negative electrode sheet a and the two separators b are attached to form a first laminated strip.

The separators b are heated by the corresponding second heating mechanism <NUM> to soften the glue or adhesives on the surfaces, and are rolled by the first pressing roller assembly <NUM> so that the separators b and the negative electrode sheet a are adhered together by means of the glue. The first pressing roller assembly <NUM> has a rolling pressure in the range of <NUM> - <NUM>. The advantage of this process is that the negative electrode sheet a is bonded to the separators b in advance, thereby avoiding the deflection phenomenon caused by the instantaneous tension loss of the negative electrode sheet a after cutting. The separators b located on the two sides of the negative electrode sheet a are pressed against the negative electrode sheet a by the first pressing roller assembly <NUM>, so that firmer connections are provided between the separators b and the negative electrode sheet a, and the attachment quality of the separators b and the negative electrode sheet a is improved. After the first pressing roller assembly <NUM> presses the separators b against the negative electrode sheet a, the two separators b are attached to the two sides of the negative electrode sheet a, which means that the two separators b are bonded to the two sides of the negative electrode sheet a.

Since there is glue on the surfaces of the separators b, during the process of pressing the separators b against the negative electrode sheet a by the first pressing roller assembly <NUM>, the glue will be adhered to peripheral surfaces of the first pressing roller <NUM> and the second pressing roller <NUM> when the first pressing roller <NUM> and the second pressing roller <NUM> of the first pressing roller assembly <NUM> come into contact with the separators b, resulting in that the first pressing roller <NUM> and the second pressing roller <NUM> may be both bonded to and pull the separators b, and after the first pressing roller assembly <NUM> operates for a long time, dust will be adhered to the peripheral surfaces of the first pressing roller <NUM> and the second pressing roller <NUM>, which will affect the compression effect of the first pressing roller assembly <NUM> on the separators b and the negative electrode sheet a. As shown in <FIG> and <FIG>, in some embodiments, the stacking device <NUM> further includes a first cleaning mechanism <NUM>. The first cleaning mechanism <NUM> is used to clean the dust and the glue adhered to the first pressing roller assembly <NUM>. The first cleaning mechanism <NUM> may include a scraper for scraping off the glue or the dust on the first pressing roller <NUM> and the second pressing roller <NUM>, and a sweeping brush for sweeping the glue or the dust on the first pressing roller <NUM> and the second pressing roller <NUM>.

As shown in <FIG> and <FIG>, in some embodiments, the positive delivery mechanism <NUM> includes a third heating mechanism <NUM>. The third heating mechanism <NUM> is configured to heat the positive electrode sheets c before the positive electrode sheets c are attached to the separators b.

The third heating mechanism <NUM> is used to heat the positive electrode sheets c before the positive electrode sheets c are attached to the separators b, so that the glue or adhesives on the surfaces of the positive electrode sheets c are softened, and the positive electrode sheets c also have a bonding ability to facilitate the attachment of the positive electrode sheets c to the separators b. In addition, providing heat to the positive electrode sheets c during attachment can compensate for the heat loss during the conveying of the separators b to the positive electrode sheets c to be attached thereto, so that the glue or adhesives on the separators b remain in a softened state, facilitating the provision of stronger bonding properties for the surfaces of the separators b that are used to attach to the positive electrode sheets c, and improving the attachment quality of the positive electrode sheets c attached to the separators b.

Since each positive electrode sheet c is attached to the side of a respective one of the two separators b away from the negative electrode sheet a, in some embodiments, the third heating mechanism <NUM> includes two third heating assemblies <NUM>, and the two third heating assemblies <NUM> are respectively configured to heat the corresponding positive electrode sheets c.

The two third heating assemblies <NUM> respectively heat the corresponding positive electrode sheets c. In other words, each positive electrode sheet c is provided with a corresponding third heating assembly <NUM>, and the positive electrode sheet c is heated by the corresponding third heating mechanism <NUM> to soften the glue or adhesives on the surface.

The third heating mechanism <NUM> adopts thermal radiation heating, which may be heating by means of a resistance wire and a metal plate, or infrared heating, or UV (ultraviolet radiation) furnace heating, or heating by means of a heating silicone rubber sheet. In other embodiments, the third heating mechanism <NUM> may include only one third heating assembly <NUM>, and the two positive electrode sheets c are heated by the one third heating assembly <NUM>.

When the third heating mechanism <NUM> includes two third heating assemblies <NUM>, the two third heating assemblies <NUM> are respectively configured to heat the corresponding positive electrode sheet c, so that each positive electrode sheet c can be sufficiently heated, and the glue or adhesives on the surfaces of the separators b are sufficiently softened. Each positive electrode sheet c has a relatively high heat when it is attached to the corresponding separator b, which compensates for the heat loss during the conveying of the separator b to the positive electrode sheet c to be attached thereto and reduces the heat loss of the separator b, so that the glue or adhesive on the separator b remains in a softened state, and the separator b thus has better bonding properties.

In some embodiments, the third heating assembly <NUM> is configured to heat two sides of the corresponding positive electrode sheet c.

The third heating assembly <NUM> includes two heating units <NUM>, and the two heating units <NUM> are respectively located on the two sides in a thickness direction of the corresponding positive electrode sheet c, so that the two heating units <NUM> heat the two sides in the thickness direction of the corresponding positive electrode sheet, and the positive electrode sheet c is thus heated evenly in the thickness direction.

The third heating assembly <NUM> is configured to heat the corresponding positive electrode sheet c on the two sides of the positive electrode sheet c, so that each positive electrode sheet c can be sufficiently heated in the thickness direction of the positive electrode sheet c, and the glue or adhesive on the positive electrode sheet c is thus softened and has a bonding ability. Heating the positive electrode sheet c can also make the positive electrode sheet c have higher heat, which can compensate for the heat loss during the conveying of the separators to the positive electrode sheets to be attached thereto, and reduce the heat loss of the separators, so that the glue or adhesives on the separators remain in a softened state, facilitating the provision of stronger bonding properties for the surfaces of the separators that are used to attach to the positive electrode sheets, and improving the attachment quality of the positive electrode sheets attached to the separators.

Referring to <FIG> and <FIG>, in some embodiments, the positive delivery mechanism <NUM> further includes a positive cutting mechanism <NUM>. The positive cutting mechanism <NUM> is arranged downstream of the third heating mechanism <NUM>, and the positive cutting mechanism <NUM> is configured to cut the positive electrode sheet c.

The positive cutting mechanism <NUM> is configured to cut the positive electrode sheet c, which means that the positive cutting mechanism <NUM> is used to cut the positive electrode sheet c to form positive electrode sheets c with a smaller length, or to indent the positive electrode sheet c on the surface of the positive electrode sheet c, to facilitate subsequent bending to form the stacked type electrode assembly <NUM>.

Since the positive electrode sheets c are provided on the two sides of the negative electrode sheet a, each positive electrode sheet c may be provided with a corresponding positive cutting mechanism <NUM>.

The positive cutting mechanism <NUM> can adopt mechanical knife cutting, laser cutting, dust gun cutting, electron beam cutting, ultrasonic knife cutting, and other methods capable of cutting the electrode sheet. After the positive electrode sheet c is cut off, the positive electrode sheet c is attached to the side of the respective separator b away from the negative electrode sheet a. The structure of the positive cutting mechanism <NUM> can refer to the existing cutting mechanism, and will not be repeated here.

Thanks to the fact that the positive cutting mechanism <NUM> is arranged downstream of the third heating mechanism <NUM>, it is possible that after the positive electrode sheet c is heated, the positive electrode sheet c is cut to form positive electrode sheets c with a smaller length so that a plurality of positive electrode sheets c with a smaller length negative at intervals on the side of the separator b away from the negative electrode sheet a, or the positive electrode sheet c is indented, so as to form a stacked type electrode assembly <NUM> having better electrical properties. The positive cutting mechanism <NUM> is arranged downstream of the third heating mechanism <NUM>, and the positive electrode sheets c are softer after being heated, and are easier to cut or indent.

Referring to <FIG> and <FIG>, in some embodiments, the stacking device <NUM> further includes a negative cutting mechanism <NUM>. The negative cutting mechanism <NUM> is arranged downstream of the negative delivery mechanism <NUM> and upstream of the first pressing roller assembly <NUM>. The negative cutting mechanism <NUM> is configured to cut the negative electrode sheet a, and cut off the negative electrode sheet a after the negative electrode sheet a completes the feeding of one stacked type electrode assembly <NUM>. Alternatively, the negative cutting mechanism <NUM> is used to form an indentation <NUM> (shown in <FIG> ) on the negative electrode sheet a, on the surface of the negative electrode sheet a, so as to facilitate subsequent bending to form the stacked type electrode assembly <NUM>. The negative cutting mechanism <NUM> forms the indentation <NUM> on the negative electrode sheet a in such a way that the indentation <NUM> may be formed by laser cleaning a coating, laser cutting, mechanical knife punching, mechanical sharp edge pressing, dust gun, electron beam/ultrasonic knife, etc..

Referring to <FIG> and <FIG>, in some embodiments, the positive delivery mechanism <NUM> further includes a second pressing roller assembly <NUM>. The second pressing roller assembly <NUM> is configured to press the positive electrode sheets c against the separators b such that the positive electrode sheets c are attached to the separators b.

The second pressing roller assembly <NUM> is used to press the positive electrode sheets c against the separators b after the negative electrode sheet a and the separators b are heated by the first heating mechanism <NUM> and the positive electrode sheets c are cut by the positive cutting mechanisms <NUM>. The second pressing roller assembly <NUM> includes a third pressing roller <NUM> and a fourth pressing roller <NUM>. The third pressing roller <NUM> and the fourth pressing roller <NUM> are respectively located on the two sides of the negative electrode sheet a, and each of the third pressing roller <NUM> and the fourth pressing roller <NUM> is located on the side of the respective positive electrode sheet c away from the separator b, so that the first laminated strip and the positive electrode sheets c on the two sides are attached to form a second laminated strip. In other words, the negative electrode sheet a, the two separators b and the two layers of positive electrode sheets c are attached to form a second laminated strip. During the process of pressing the positive electrode sheets c against the surfaces of the separators b, the second pressing roller assembly <NUM> can also assist in delivering the negative electrode sheet a, the separators b and the positive electrode sheets c to the next station.

The separators b are heated by the first heating mechanism <NUM> to soften the glue or adhesives on the surfaces, and are rolled by the second pressing roller assembly <NUM> so that the separators b and the positive electrode sheets c are adhered together by means of the glue. When the second pressing roller assembly <NUM> presses the positive electrode sheets c against the separators b, the pressing force provided by the second pressing roller assembly <NUM> may refer to the first pressing roller assembly <NUM> or may be set according to actual requirements. After the second pressing roller assembly <NUM> presses the positive electrode sheets c against the separators b, each positive electrode sheet c is attached to the side of the corresponding separator b away from the negative electrode sheet a, which means that each positive electrode sheet c is bonded to the side of the corresponding separator b away from the negative electrode sheet a. During the process of pressing the separators b against the surfaces of the negative electrode sheet a, the first pressing roller assembly <NUM> can also assist in delivering the negative electrode sheet a and the separators b to the next station.

The positive electrode sheets c are pressed against the separators b by the second pressing roller assembly <NUM>, so that firmer connections are provided between the positive electrode sheets c and the separators b, and the attachment quality of the positive electrode sheets c and the separators b is improved.

Since there may be glue on the surfaces of the positive electrode sheets c, during the process of pressing the positive electrode sheets c against the separators b by the second pressing roller assembly <NUM>, the glue will be adhered to peripheral surfaces of the third pressing roller <NUM> and the fourth pressing roller <NUM> when the third pressing roller <NUM> and the fourth pressing roller <NUM> of the second pressing roller assembly <NUM> come into contact with the positive electrode sheets c, resulting in that the third pressing roller <NUM> and the fourth pressing roller <NUM> may be both bonded to and pull the separators b, and after the second pressing roller assembly <NUM> operates for a long time, dust will be adhered to the peripheral surfaces of the third pressing roller <NUM> and the fourth pressing roller <NUM>, which will affect the compression effect of the second pressing roller assembly <NUM> on the separators b and the positive electrode sheets c. As shown in <FIG> and <FIG>, in some embodiments, the stacking device <NUM> includes a second cleaning mechanism <NUM>. The second cleaning mechanism <NUM> is used to clean the dust and the glue adhered to the second pressing roller assembly <NUM>. The first cleaning mechanism <NUM> may include a scraper for scraping off the glue or the dust on the third pressing roller <NUM> and the fourth pressing roller <NUM>, and a sweeping brush for sweeping the glue or the dust on the third pressing roller <NUM> and the fourth pressing roller <NUM>.

Referring to <FIG> and <FIG>, in some embodiments, the stacking device <NUM> further includes a fourth heating mechanism <NUM>. The fourth heating mechanism <NUM> is arranged downstream of the negative delivery mechanism <NUM>, and the fourth heating mechanism <NUM> is configured to heat the negative electrode sheet a before the two separators b are attached to the negative electrode sheet a.

The fourth heating mechanism <NUM> may include two fourth heating assemblies <NUM>. The two fourth heating assemblies <NUM> are respectively located on the two sides in the thickness direction of the negative electrode sheet a, so that the two fourth heating assemblies <NUM> respectively heat the two sides in the thickness direction of the negative electrode sheet a. In other embodiments, the fourth heating mechanism <NUM> may also include only one fourth heating assembly <NUM>, and the negative electrode sheet a is heated by the one fourth heating assembly <NUM>.

The fourth heating mechanism <NUM> adopts thermal radiation heating, which may be heating by means of a resistance wire and a metal plate, or infrared heating, or UV (ultraviolet radiation) furnace heating, or heating by means of a heating silicone rubber sheet.

The fourth heating mechanism <NUM> is used to heat the negative electrode sheet a before the separators b are attached to the negative electrode sheet a, so that the glue or adhesives on the surfaces of the negative electrode sheet a are softened, and the negative electrode sheet a thus also has a bonding ability to facilitate the attachment of the separators b on the two sides of the negative electrode sheet a. In addition, heat is provided to the negative electrode sheet a during attachment, and the heat of the negative electrode sheet a can help to soften the glue or adhesives on the surfaces of the separators b, so that the surfaces of the separators b that are used to attach to the negative electrode sheet a have bonding properties, facilitating the attachment of the separators b to the negative electrode sheet a.

Referring to <FIG> is a schematic structural diagram of a stacked type electrode assembly <NUM> provided in some embodiments of the present invention. The stacked type structure includes a plurality of bent segments <NUM> and a plurality of laminated segments <NUM> arranged in a laminated manner. Each bent segment <NUM> is used to connect two adjacent laminated segments <NUM>, the laminated segments <NUM> are laminated in a first direction, two adjacent laminated segments <NUM> are connected to each other via one bent segment <NUM>, and the bent segments <NUM> are bent portions where the negative electrode sheet a, the two layers of separators b and the two layers of positive electrode sheets c that are attached to one other are repeatedly folded. In the embodiment in which a plurality of positive electrode sheets c with a smaller length arranged at intervals are attached to the side of the separator b away from the negative electrode sheet a, the positive electrode sheet c is part of the laminated segment <NUM>.

As shown in <FIG>, in some embodiments, the stacking device <NUM> includes a stacking mechanism <NUM>, a stacking platform <NUM>, and a pressing mechanism <NUM>. The stacking mechanism <NUM> is arranged downstream of the positive delivery mechanism <NUM>, and the stacking mechanism <NUM> is configured to arrange the negative electrode sheet a, the separators b and the positive electrode sheets c on the stacking platform <NUM> in a laminated manner to form a stacked type structure. The stacked type structure includes a plurality of bent segments <NUM> and a plurality of stacked laminated segments <NUM> arranged in a laminated manner, and each bent segment <NUM> is used to connect two adjacent laminated segments <NUM>. The stacking platform <NUM> is configured to carry the stacked type structure. The pressing mechanism <NUM> is arranged at the stacking platform <NUM>, and the pressing mechanism <NUM> is configured to flatten the bent segments <NUM>.

The stacked type structure is part or all of the stacked type electrode assembly <NUM>.

There are many ways to realize the repeated folding of the negative electrode sheet a, the two layers of separators b and the two layers of positive electrode sheets c that are attached to one other. For example, as shown in <FIG>, in some embodiments, the stacking mechanism <NUM> includes a transmission mechanism <NUM> and a swing mechanism <NUM>. The swing mechanism <NUM> is arranged downstream of the transmission mechanism <NUM>. The transmission mechanism <NUM> is used to convey the second laminated strip to the swing mechanism <NUM>. The swing mechanism <NUM> is used to drive the second laminated strip to swing left and right to realize repeated folding, and the transmission mechanism <NUM> is used to convey the second laminated strip from top to bottom. <FIG> shows a schematic diagram of the swing mechanism <NUM> in an initial position. When the swing mechanism <NUM> is in the initial position, the swing mechanism <NUM> is located directly below the transmission mechanism <NUM>. The transmission mechanism <NUM> can convey the second laminated strip to the swing mechanism <NUM>. <FIG> shows a schematic diagram of the swing mechanism <NUM> in a first position. As shown in <FIG>, the swing mechanism <NUM> drives the second laminated strip to swing to the left from the initial position to the first position, and a laminated segment <NUM> is formed during the swinging process. <FIG> shows a schematic diagram of the swing mechanism <NUM> in a second position. As shown in <FIG>, the swing mechanism <NUM> drives the second laminated strip to swing to the right from the first position to the second position, and a further laminated segment <NUM> is formed during the swinging process. Under the combined action of the transmission mechanism <NUM>, the gravity of the second laminated strip and the swing mechanism <NUM>, the second laminated strip forms a stacked type structure on the stacking platform <NUM>.

For another example, as shown in <FIG>, in some embodiments, the stacking mechanism <NUM> further includes a transmission mechanism <NUM> and blowing mechanisms <NUM>. The blowing mechanisms <NUM> are arranged downstream of the transmission mechanism <NUM>, the transmission mechanism <NUM> is used to convey the second laminated strip to the blowing mechanisms <NUM>, and the blowing mechanisms <NUM> are each arranged on one side in a thickness direction of a second composite mechanism, and the blowing mechanisms <NUM> blow air to the second laminated strip, so that the second laminated strip repeatedly swings in a direction in which the two blowing mechanisms <NUM> are arranged. Under the combined action of the transmission mechanism <NUM>, the gravity of the second laminated strip and the blowing mechanisms <NUM>, the second laminated strip forms a stacked type structure on the stacking platform <NUM>. <FIG> shows a schematic structural diagram of the blowing mechanism <NUM> not blowing air to the second laminated strip, with the transmission mechanism <NUM> being used to convey the second laminated strip from top to bottom. <FIG> shows a schematic diagram of the blowing mechanism <NUM> blowing air to the right to the second laminated strip and deflecting a part of the second laminated strip by a certain angle, and <FIG> shows a schematic structural diagram of the blowing mechanism <NUM> blowing air to the right to the second laminated strip, and the second laminated strip folded downward under the action of a conveying mechanism and its own gravity.

The structure of the newly formed stacked type structure is fluffy and uneven, especially in the bent segments <NUM> (shown in <FIG> ), where the fluffy and uneven phenomena are more serious. The pressing mechanism <NUM> is used to flatten the bent segments <NUM> of the stacked type structure, so as to make the structure of the stacked type structure more compact in a laminating direction and improve the quality of the stacked type structure.

In some embodiments, the pressing mechanism <NUM> includes two rotating portions <NUM> arranged opposite to each other. The rotating portions <NUM> are rotatably mounted to the stacking platform <NUM>, and the rotating portions <NUM> are configured to flatten the bent segments <NUM>.

As shown in <FIG>, in a width direction of the laminated segments <NUM>, the stacked type structure has two groups of bent segments <NUM> arranged opposite to each other, and the indentations <NUM> formed on the negative electrode sheet a by the negative cutting mechanism <NUM> are located at the bent segments <NUM>. It can be understood that the second laminated strip is folded along the indentations <NUM>. The pressing mechanism <NUM> includes two rotating portions <NUM> arranged opposite to each other. A direction in which the two rotating portions <NUM> are arranged is the same as the width direction of the laminated segments <NUM>. The two rotating portions <NUM> are respectively used to flatten the two groups of bent segments <NUM> arranged opposite to each other in the width direction of the laminated segments <NUM>. It should be noted that the width direction of the laminated segments <NUM> is consistent with the reciprocating direction of the swing mechanism <NUM> (shown in <FIG>), and the width direction of the laminated segments <NUM> is consistent with the blowing direction of the blowing mechanism (shown in <FIG>).

Each bent segment <NUM> is flattened by the corresponding rotating portion <NUM>, so that the structure of the stacked type structure in the laminating direction is more compact, so as to improve the quality of the stacked type structure.

As shown in <FIG>, in some embodiments, the rotating portion <NUM> includes a brush <NUM> and a main body <NUM>. The main body <NUM> is rotatably mounted to the stacking platform <NUM>, and the brush <NUM> is configured to flatten the bent segments <NUM>.

The rotating portion <NUM> includes a plurality of brushes <NUM>. The plurality of brushes <NUM> are arranged on the main body <NUM> at intervals around a rotation axis of the main body <NUM>. The rotation of the main body <NUM> drives the rotation of the brushes <NUM>. During the rotation, the brushes <NUM> will beat the corresponding bent segments <NUM> to flatten the bent segments <NUM>. The rotation of the main body <NUM> should make the brushes <NUM> beat the bent segments <NUM> from top to bottom.

The material of the brush <NUM> is soft, and the brush <NUM> is less likely to damage the stacked type structure when the bent segment <NUM> is flattened.

In some embodiments, the pressing mechanism <NUM> may also be a thin steel sheet or a beating plate.

As shown in <FIG>, in some embodiments, the stacking device <NUM> includes a driving mechanism <NUM> and two stacking platforms <NUM>. The driving mechanism <NUM> is configured to switch the positions of the two stacking platforms <NUM> such that one of the stacking platforms <NUM> is located in a stacking position and the other stacking platform <NUM> is in a non-stacking position.

In some embodiments, the driving mechanism <NUM> includes a first driving member <NUM> and a second driving member <NUM>. The first driving member <NUM> is used to drive one of the stacking platforms <NUM> in a vertical direction so that the stacking platform <NUM> is moved in the vertical direction, and the second driving member <NUM> is used to drive the other stacking platform <NUM> to move in a horizontal direction, so as to switch between the stacking position and the non-stacking position. In <FIG>, the first driving member <NUM> drives the corresponding stacking platform <NUM> to move downward so that the stacking platform <NUM> can move to the non-stacking position, and the first driving member <NUM> drives the corresponding stacking platform <NUM> to move upward so that the stacking platform <NUM> can move to the stacking position. The second driving member <NUM> drives the corresponding stacking platform <NUM> to move horizontally to the left so that the stacking platform <NUM> can move to the non-stacking position, and the second driving member <NUM> drives the corresponding stacking platform <NUM> to move horizontally to the right so that the stacking platform <NUM> can move to the stacking position.

When the first driving member <NUM> drives the corresponding stacking platform <NUM> to move to the non-stacking position, the stacking position is made available for the stacking platform <NUM> corresponding to the second driving member <NUM>, so that the second driving member <NUM> drives the corresponding stacking platform <NUM> to move to stacking position. When the second driving member <NUM> drives the corresponding stacking platform <NUM> to move to the non-stacking position, the stacking position is made available for the stacking platform <NUM> corresponding to the first driving member <NUM>, so that the first driving member <NUM> drives the corresponding stacking platform <NUM> to move to stacking position.

The first driving member <NUM> and the second driving member <NUM> may be air cylinders, hydraulic cylinders, linear motors, etc. In other embodiments, the driving mechanism <NUM> may also drive the two stacking platforms <NUM> to switch between the stacking position and the non-stacking position in other ways or in other driving directions.

The driving mechanism <NUM> can switch the positions of the two stacking platforms <NUM> such that when one of the stacking platforms <NUM> is in the stacking position, the other stacking platform <NUM> is in the non-stacking position, that is, the two stacking platforms <NUM> work alternately, and the stacking operation will not be suspended, improving the production efficiency.

In some embodiments, the stacking device <NUM> further includes a separator makeup sealing mechanism <NUM>. The separator makeup sealing mechanism <NUM> is arranged downstream of the second rolling assembly and upstream of the stacking mechanism <NUM>, and the separator makeup sealing mechanism <NUM> is used for partial makeup sealing on two sides of the fold (the bent portion when forming the stacked type electrode assembly <NUM>) between the negative electrode sheet a and each separator b, so as to prevent the separator b from turning inward during the folding process. The makeup sealing method may be flat pressing or rolling.

Referring to <FIG> and <FIG> is a schematic structural diagram of a negative delivery mechanism <NUM> provided in some embodiments of the present invention. In some embodiments, the negative delivery mechanism <NUM> includes a negative roll spool <NUM>, a negative rectifying deviation sensor <NUM>, a negative strip splicing mechanism <NUM>, a negative tension balance mechanism <NUM> and a negative rectifying deviation mechanism <NUM>.

The negative roll spool <NUM> may adopt single-roll negative unrolling. In practical applications, in order to increase the time for assisting in replacing the roll, the negative roll spool <NUM> may also be a multi-roll spool. Multi-roll refers to two or more rolls. The negative roll spool <NUM> is driven to rotate by a servo motor to achieve the purpose of unrolling the negative electrode sheet a. The negative roll spool <NUM> may refer to an existing winding machine, and will not be repeated here.

The negative rectifying deviation sensor <NUM> is arranged downstream of the negative roll spool <NUM>. The negative rectifying deviation sensor <NUM> is used to detect whether the negative electrode sheet a deviates from a preset conveying path. It is necessary to adjust the conveying path of the negative electrode sheet a when deviating from the preset conveying path. For example, the negative roll spool <NUM> may be moved to rectify the deviation. For example, the negative roll spool <NUM> may be moved in a direction perpendicular to a strip running direction to achieve rectifying deviation.

The negative strip splicing mechanism <NUM> is arranged upstream of the negative rectifying deviation sensor <NUM>. The negative strip splicing mechanism <NUM> is used to connect the end of a negative electrode sheet a of a negative roll that is completely unrolled to the end of a negative electrode sheet a of another negative roll, so as to realize strip splicing.

The negative tension balance mechanism <NUM> is arranged downstream of the negative rectifying deviation sensor <NUM>, and is used to adjust the tension of the negative electrode sheet a, so that the tension of the negative electrode sheet a is kept within a certain range. The negative tension balance mechanism <NUM> may refer to a tension balance mechanism of a winding machine, and will not be repeated here.

The negative rectifying deviation mechanism <NUM> is arranged downstream of the negative tension balance mechanism <NUM>, and may adjust the position of the negative electrode sheet a in a direction perpendicular to the conveying direction. The negative rectifying deviation mechanism <NUM> may refer to an electrode sheet rectifying deviation mechanism of a winding machine, and will not be repeated here.

The negative delivery mechanism <NUM> changes the negative electrode sheet a from the shape of a roll into the shape of a straight strip having a certain tension, such that the negative electrode sheet stably enters the next station.

Referring to <FIG> and <FIG> is a schematic structural diagram of a separator delivery mechanism <NUM> provided in some embodiments of the present invention. In some embodiments, each separator delivery mechanism <NUM> includes a separator roll spool <NUM>, a separator rectifying deviation sensor <NUM>, a separator strip splicing mechanism <NUM> and a separator tension balance mechanism <NUM>.

The separator b roll spool may adopt single-roll separator b unrolling. In practical applications, in order to increase the time for assisting in replacing the roll, the separator roll spool <NUM> may also be a multi-roll spool. Multi-roll refers to two or more rolls. The separator roll spool <NUM> is driven to rotate by a servo motor to achieve the purpose of unrolling the separator b. The separator b roll spool may refer to an existing winding machine, and will not be repeated here.

Since it is necessary to deliver separators b to the two sides of the negative electrode sheet a, in some embodiments, the separator delivery mechanism <NUM> includes two separator roll spools <NUM>. The separator roll spools <NUM> are respectively located on the two sides in the thickness direction of the negative electrode sheet a, and the two separator delivery mechanisms <NUM> respectively deliver the separators b to the two sides in the thickness direction of the negative electrode sheet a. Of course, in some embodiments, it is also possible to deliver the separators b to the two sides in the thickness direction of the negative electrode sheet a by means of one separator roll spool <NUM>.

The separator rectifying deviation sensor <NUM> is arranged downstream of the separator roll spool <NUM>. The separator rectifying deviation sensor <NUM> is used to detect whether the separator b deviates from a preset conveying path. It is necessary to adjust the conveying path of the separator b when deviating from the preset conveying path. For example, the negative roll spool <NUM> may be moved to rectify the deviation. For example, the negative roll spool <NUM> may be moved in a direction perpendicular to a strip running direction to achieve rectifying deviation.

The separator strip splicing mechanism <NUM> is arranged downstream of the separator rectifying deviation sensor <NUM>. The separator strip splicing mechanism <NUM> is used to connect the end of a separator b of a separator b roll that is completely unrolled to the end of a separator b of another separator b roll, so as to realize strip splicing.

The separator tension balance mechanism <NUM> is arranged downstream of the separator strip splicing mechanism <NUM>, and is used to adjust the tension of the separator b, so that the tension of the separator b is kept within a certain range. The separator tension balance mechanism <NUM> may refer to a tension balance mechanism of a winding machine, and will not be repeated here.

Since the separators b are attached to the two sides in the thickness direction of the negative electrode sheet a, the positive electrode sheet c may be delivered to the side of each separator b away from the negative electrode sheet a. In some embodiments, the stacking device <NUM> includes two positive delivery mechanisms <NUM>. The two positive delivery mechanisms <NUM> are respectively located on the two sides in the thickness direction of the negative electrode sheet a, and each of the two positive delivery mechanisms <NUM> delivers the positive electrode sheet c to the side, away from the negative electrode sheet a, of a respective one of the separators b on the two sides in the thickness direction of the negative electrode sheet a. Of course, in some embodiments, it is also possible to deliver the positive electrode sheets c to the two sides in the thickness direction of the negative electrode sheet a by means of one positive delivery mechanism <NUM>.

The separator delivery mechanism <NUM> changes the separator from the shape of a roll into the shape of a straight strip having a certain tension, such that the separator is fed stably.

The positive delivery mechanism <NUM> may refer to the negative delivery mechanism <NUM> or the separator delivery mechanism <NUM>, and will not be repeated here. The positive delivery mechanism <NUM> changes the positive electrode sheet c from the shape of a roll into the shape of a straight strip having a certain tension, such that the positive electrode sheet stably enters the next station.

Still referring to <FIG>, in some embodiments, the stacking device <NUM> further includes a positive and negative relative position detection mechanism <NUM>. The positive and negative relative position detection mechanism <NUM> is arranged downstream of the second rolling assembly. The positive and negative relative position detection mechanism <NUM> is used to detect the positions of the positive electrode sheets c and the negative electrode sheet a in the width direction of the electrode sheets. The positive electrode sheet c needs to be rejected if its width exceeds the width of the negative electrode sheet a. In this way, the safety performance of the electrode assembly <NUM> is guaranteed.

As shown in <FIG>, some embodiments of the present invention provide a stacking device <NUM> that includes a negative delivery mechanism <NUM>, separator delivery mechanisms <NUM>, a first heating mechanism <NUM>, positive delivery mechanisms <NUM>, a first cleaning mechanism <NUM>, a negative cutting mechanism <NUM>, a second cleaning mechanism <NUM>, a fourth heating mechanism <NUM> and a stacking mechanism <NUM>.

The fourth heating mechanism <NUM> is arranged downstream of the negative delivery mechanism <NUM>, and the negative cutting mechanism <NUM> is arranged downstream of the fourth heating mechanism <NUM>. The negative delivery mechanism <NUM> is used to supply a negative electrode sheet a, the fourth heating mechanism <NUM> is used to heat the negative electrode sheet a, and the negative cutting mechanism <NUM> is used to form an indentation <NUM> on the heated negative electrode sheet a.

The separator delivery mechanism <NUM> includes a separator roll spool <NUM>, a second heating mechanism <NUM> and a first pressing roller assembly <NUM>. The second heating mechanism <NUM> is arranged downstream of the separator roll spool <NUM>, and the first pressing roller assembly <NUM> is arranged downstream of the second heating mechanism <NUM>.

Separators b supplied from the separator roll spools <NUM> is heated by the second heating mechanism <NUM>, and the first pressing roller assembly <NUM> presses the heated separators b against the negative electrode sheet a having the formed indentation <NUM>, so that the separators b are attached to two sides of the negative electrode sheet a, so that the negative electrode sheet a and the two layers of separators b are bonded to form a first laminated strip.

The first pressing roller assembly <NUM> is cleaned by the first cleaning mechanism <NUM>.

The first heating mechanism <NUM> is arranged downstream of the first pressing roller assembly <NUM>, and the first heating mechanism <NUM> is used to heat the first laminated strip (the negative electrode sheet a and the two separators b).

The positive delivery mechanism <NUM> includes a third heating mechanism <NUM>, a positive cutting mechanism <NUM>, and a second pressing roller assembly <NUM>. The positive cutting mechanism <NUM> is arranged downstream of the third heating mechanism <NUM>, and the second pressing roller assembly <NUM> is arranged downstream of the positive cutting mechanism <NUM>.

A positive electrode sheet c is heated by the third heating mechanism <NUM> before being attached to the separator b, and the positive electrode sheet c heated by the third heating mechanism <NUM> is cut by the positive cutting mechanism <NUM> to form positive electrode sheets c with a smaller length, and the heated positive electrode sheet c is pressed against either side of the first laminated strip (the side of each separator b away from the negative electrode sheet a) by the second pressing roller assembly <NUM>, so that the positive electrode sheet c is attached to the separator b. In this way, the negative electrode sheet a, the separators b and the positive electrode sheets c are bonded to form a second laminated strip.

The second pressing roller assembly <NUM> is cleaned by the second cleaning mechanism <NUM>.

The stacking mechanism <NUM>, the stacking platform <NUM> and the pressing mechanism <NUM> jointly laminate the second laminated strips to form a stacked type electrode assembly <NUM>.

As shown in <FIG>, some embodiments of the present invention provide a method for manufacturing a stacked type electrode assembly <NUM> that includes the following steps.

In step S100, separators b are supplied to two sides of a negative electrode sheet a, and the separators b are attached to the negative electrode sheet a.

In step S200, the separators b and the negative electrode sheet a that are attached to each other are heated.

In step S300, positive electrode sheets c are delivered to the two sides of the negative electrode sheet a, and the positive electrode sheets c are attached to the separators b.

The separators b and the negative electrode sheet a that are attached to each other are first heated so that the separators b have bonding properties, the positive electrode sheets c are then attached to the separators b, and the glue on the surfaces of the separators b are softened before the positive electrode sheets c are attached to the separators b, so that the separators b have bonding properties, and the positive electrode sheets c can be directly bonded to the separators b and delivered to the next station along with the separators b. There is no need to provide a PET film d feeding apparatus for supplying PET films d and to fix the positive electrode sheets c by means of the PET films d, so that the positive electrode sheets c are static relative to the PET films d, the positive electrode sheets c do not shift during a delivery process of the PET films d, and the positive electrode sheets c are transported to the next station under the drive of the PET films d. The entire structure of the stacking device <NUM> is simplified, and the production cost of the stacked type electrode assembly <NUM> is reduced. Moreover, no PET film is provided, so that the path through which heat passes is also shortened, and a stronger ability to soften the glue or adhesives on the separators is provided, thereby improving the attachment quality.

Claim 1:
A stacking device (<NUM>), comprising:
a negative delivery mechanism (<NUM>) configured to deliver a negative electrode sheet (a);
a separator delivery mechanism (<NUM>) configured to deliver separators (b) to two sides of the negative electrode sheet (a) such that the separators (b) are attached to the negative electrode sheet (a);
a first heating mechanism (<NUM>) arranged downstream of the separator delivery mechanism (<NUM>) and configured to heat the negative electrode sheet (a) and the separators (b); and
a positive delivery mechanism (<NUM>) arranged downstream of the first heating mechanism (<NUM>) and configured to deliver positive electrode sheets (c) to the two sides of the negative electrode sheet (a) such that the positive electrode sheets (c) are attached to the separators (b);
wherein the stacking device (<NUM>) comprises a stacking mechanism (<NUM>), a stacking platform (<NUM>) and a pressing mechanism (<NUM>), wherein
the stacking mechanism (<NUM>) is arranged downstream of the positive delivery mechanism (<NUM>) and configured to arrange the negative electrode sheet (a), the separators (b), and the positive electrode sheets (c) on the stacking platform (<NUM>) in a laminated manner to form a stacked type structure, the stacked type structure comprises a plurality of bent segments (<NUM>) and a plurality of laminated segments (<NUM>) arranged in a laminated manner, and each of the bent segments (<NUM>) is used to connect two adjacent laminated segments (<NUM>); the stacking platform (<NUM>) is configured to carry the stacked type structure; and the pressing mechanism (<NUM>) is arranged at the stacking platform (<NUM>) and configured to flatten the bent segments (<NUM>);
wherein the separator delivery mechanism (<NUM>) comprises a second heating mechanism (<NUM>) configured to heat the two separators (b) before the two separators (b) are attached to the negative electrode sheet (a);
characterized in that the second heating mechanism (<NUM>) is configured to heat the side of the separator (b) that is used to attach to the negative electrode sheet (a).