All-solid-state batteries
The battery design addresses short circuits and strength issues by using insulating frames and an expandable negative electrode frame to enclose the solid electrolyte layer, improving structural integrity and reliability.
Patent Information
- Authority / Receiving Office
- JP · JP
- Patent Type
- Applications
- Current Assignee / Owner
- HONDA MOTOR CO LTD
- Filing Date
- 2026-05-11
- Publication Date
- 2026-07-09
AI Technical Summary
All-solid-state batteries face risks of short circuits and reduced strength due to misalignment of negative electrode current collector layers and lack of insulation frames, particularly at the outer edges.
The battery design includes positive and negative electrode insulating frames positioned to enclose the solid electrolyte layer peripheries, with the positive electrode insulating frame extending beyond the electrolyte layer, and a negative electrode insulating frame that can expand and contract, along with an intermediate layer to stabilize the interface.
This design effectively suppresses short circuits and enhances the structural integrity of the battery, ensuring reliable operation.
Smart Images

Figure 2026116571000001_ABST
Abstract
Description
[Technical Field]
[0001] This invention relates to a solid-state battery. [Background technology]
[0002] In recent years, research and development of rechargeable batteries that contribute to energy efficiency have been conducted to ensure that many people have access to affordable, reliable, sustainable, and advanced energy.
[0003] Patent Document 1 describes an all-solid-state battery comprising: a positive electrode current collector layer; a first positive electrode active material layer laminated on one side surface of the positive electrode current collector layer; a second positive electrode active material layer laminated on the other side surface of the positive electrode current collector layer; a first solid electrolyte layer laminated on one side surface of the first positive electrode active material layer; a second solid electrolyte layer laminated on the other side surface of the second positive electrode active material layer; a first negative electrode active material layer laminated on one side surface of the first solid electrolyte layer; a second negative electrode active material layer laminated on the other side surface of the second solid electrolyte layer; a first negative electrode current collector layer laminated on one side surface of the first negative electrode active material layer; and a second negative electrode current collector layer laminated on the other side surface of the second negative electrode active material layer. At least the positive electrode current collector layer extends outward beyond the first negative electrode active material layer and the second negative electrode active material layer, forming an extension, and an insulating resin layer is continuously provided across one side surface of the extension, the side surface of the extension, and the other side surface of the extension. [Prior art documents] [Patent Documents]
[0004] [Patent Document 1] Japanese Patent Publication No. 2020-4697 [Overview of the project] [Problems that the invention aims to solve]
[0005] When manufacturing all-solid-state batteries, it is conceivable to apply an automated stacking device. For example, the positive electrode sheet, negative electrode sheet, and solid electrolyte layer sheet, which are set in a stocker, are cut into any shape and stacked alternately in any number of layers.
[0006] However, when viewing the all-solid-state battery of Patent Document 1 from above, the outer edge of the solid electrolyte layer is not located outside the outer edge of the negative electrode current collector layer in the direction in which the extension extends. Therefore, if a θ shift occurs in the negative electrode current collector layer, there is a risk of a short circuit occurring. Furthermore, since a positive electrode insulating frame is not provided on the outer edge of the positive electrode active material layer, the strength of the all-solid-state battery is reduced.
[0007] The present invention aims to provide a solid-state battery that can suppress the occurrence of short circuits and improve strength. [Means for solving the problem]
[0008] One aspect of the present invention is a solid-state battery in which a positive electrode current collector is sandwiched between electrode laminates in which a solid electrolyte layer and a positive electrode composite layer are sequentially laminated on a negative electrode current collector, wherein the positive electrode composite layer is provided with a positive electrode insulating frame on its outer periphery, and when the solid-state battery is viewed from above, the outer periphery of the negative electrode current collector is located inside the outer periphery of the solid electrolyte layer, and the outer periphery of the positive electrode insulating frame is located at the same position as the outer periphery of the solid electrolyte layer, or outside the outer periphery of the solid electrolyte layer.
[0009] In the above-described solid battery, a positive electrode tab extends from the positive electrode current collector, and a negative electrode tab extends from the negative electrode current collector. The side from which the positive electrode tab extends is opposite to the side from which the negative electrode tab extends. When the solid battery is viewed from above, the outer peripheral end of the positive electrode insulating frame on the side from which the positive electrode tab extends may be located outside the outer peripheral end of the solid electrolyte layer.
[0010] The solid electrolyte layer may have an extended portion that extends toward the side to which the negative electrode tab extends.
[0011] On the negative electrode current collector, a negative electrode composite material layer, the solid electrolyte layer, and the positive electrode composite material layer may be sequentially laminated.
[0012] The negative electrode composite material layer is provided with a negative electrode insulating frame at its outer peripheral portion. When the solid battery is viewed from above, the outer peripheral end of the negative electrode tab of the negative electrode insulating frame on the side where the negative electrode tab extends may be located outside the outer peripheral end of the negative electrode current collector.
[0013] The negative electrode insulating frame may contain a material that can expand and contract.
[0014] An intermediate layer is further formed between the negative electrode composite material layer and the solid electrolyte layer of the electrode laminate. When the solid battery is viewed from above, the outer peripheral end of the intermediate layer may be located at the same position as the outer peripheral end of the negative electrode insulating frame, or may be located inside the outer peripheral end of the negative electrode insulating frame.
[0015] In the solid electrolyte layer, the strength of the region facing the negative electrode composite material layer and / or the positive electrode composite material layer may be higher than the strength of the region not facing the negative electrode composite material layer or the positive electrode composite material layer.
[0016] Another aspect of the present invention is a solid battery in which an electrode laminate in which a positive electrode composite material layer, a solid electrolyte layer, and a negative electrode composite material layer are sequentially laminated on a positive electrode current collector and a negative electrode current collector is sandwiched. The negative electrode composite material layer is provided with a negative electrode insulating frame at its outer peripheral portion. When the solid battery is viewed from above, the outer peripheral end of the positive electrode current collector is located inside the outer peripheral end of the solid electrolyte layer, and the outer peripheral end of the negative electrode insulating frame is located at the same position as the outer peripheral end of the solid electrolyte layer, or is located outside the outer peripheral end of the solid electrolyte layer.
Advantages of the Invention
[0017] According to the present invention, it is possible to provide a solid battery that suppresses the occurrence of short circuits and improves strength.
Brief Description of the Drawings
[0018] [Figure 1] It is a top view showing an example of the solid-state battery of the present embodiment. [Figure 2] It is a cross-sectional view showing the solid-state battery of FIG. 1. [Figure 3] It is a schematic diagram (part 1) explaining the manufacturing method of the solid-state battery of FIG. 1. [Figure 4] It is a schematic diagram (part 2) explaining the manufacturing method of the solid-state battery of FIG. 1. [Figure 5] It is a schematic diagram explaining the case of manufacturing the solid-state battery of FIG. 1 using an automatic laminating device.
Embodiments for Carrying Out the Invention
[0019] Hereinafter, embodiments of the present invention will be described while referring to the drawings.
[0020] FIGS. 1 and 2 show an example of the solid-state battery of the present embodiment. Note that FIGS. 2(a) and (b) are cross-sectional views in the A-A direction and B-B direction of FIG. 1, respectively.
[0021] The solid-state battery 10 is an electrode laminate 11 in which a negative electrode composite layer 11b, a solid electrolyte layer 11c, and a positive electrode composite layer 11d are sequentially laminated on a negative electrode current collector 11a, and a positive electrode current collector 12 is sandwiched. At this time, a negative electrode tab 11e extends from the negative electrode current collector 11a in the solid-state battery 10. Further, the positive electrode composite layer 11d is provided with a positive electrode insulating frame 11f at the outer peripheral portion. Furthermore, when the solid-state battery 10 is viewed from above, the outer peripheral end of the negative electrode current collector 11a is located inside the outer peripheral end of the solid electrolyte layer 11c. Therefore, even if θ displacement of the negative electrode current collector 11a occurs, the occurrence of a short circuit is suppressed. Also, when the solid-state battery 10 is viewed from above, the outer peripheral end of the positive electrode insulating frame 11f is located at the same position as the outer peripheral end of the solid electrolyte layer 11c, or outside the outer peripheral end of the solid electrolyte layer 11c. Therefore, the strength of the solid-state battery 10 is improved.
[0022] In addition, the electrode laminate 11 may have the negative electrode current collector 11a, the negative electrode composite layer 11b, the solid electrolyte layer 11c, and the positive electrode composite layer 11d in contact with each other, or other layers may exist between each of these layers.
[0023] The materials that constitute the positive electrode insulating frame 11f are not particularly limited, but examples include insulating oxides such as alumina, resins such as polyvinylidene fluoride (PVDF), and rubbers such as styrene-butadiene rubber (SBR).
[0024] The electrode laminate 11 only needs to have a negative electrode composite layer 11b, a solid electrolyte layer 11c, and a positive electrode composite layer 11d sequentially laminated on a negative electrode current collector 11a, and may have multiple positive and / or negative electrodes. Examples of laminated structures for an electrode laminate 11 having multiple positive and / or negative electrodes include a positive electrode current collector 12 / positive electrode composite layer 11d / solid electrolyte layer 11c / negative electrode composite layer 11b / negative electrode current collector 11a / negative electrode current collector 11a / negative electrode composite layer 11b / solid electrolyte layer 11c / positive electrode composite layer 11d, etc.
[0025] Furthermore, the electrode stack 11 that sandwiches the positive electrode current collector 12 may be the same or different.
[0026] Furthermore, the arrangement of the positive electrode, negative electrode, and electrode-related components in the solid-state battery 10 may be reversed.
[0027] In the solid-state battery 10, a positive electrode tab 13 extends from the positive electrode current collector 12, and the side from which the positive electrode tab 13 extends is opposite to the side from which the negative electrode tab 11e extends. Furthermore, when the solid-state battery 10 is viewed from above, the outer peripheral end of the positive electrode insulating frame 11f on the side from which the positive electrode tab 13 extends is located outside the outer peripheral end of the solid electrolyte layer 11c. In other words, the positive electrode insulating frame 11f is also formed on a part of the positive electrode tab 13 on the positive electrode current collector 12 side. As a result, the occurrence of short circuits is suppressed, and the strength of the solid-state battery 10 is improved.
[0028] Furthermore, when the solid battery 10 is viewed from above, the outer peripheral end of the positive electrode insulating frame 11f on the side from which the positive electrode tab 13 extends may be in the same position as the outer peripheral end of the solid electrolyte layer 11c.
[0029] The solid electrolyte layer 11c may have an extension portion 11g that extends to the side on which the negative electrode tab 11e extends, as shown by the dashed lines in Figures 1 and 2(a). This suppresses contact with the positive electrode tab 13 even when a load is applied to the negative electrode tab 11e.
[0030] Furthermore, the side on which the positive electrode tab 13 extends may be the same as the side on which the negative electrode tab 11e extends.
[0031] The negative electrode composite layer 11b has a negative electrode insulating frame 11h on its outer periphery. Furthermore, when the solid battery 10 is viewed from above, the outer periphery end of the negative electrode insulating frame 11h on the side from which the negative electrode tab 11e extends is located outside the outer periphery end of the negative electrode current collector 11a. In other words, the negative electrode insulating frame 11h is also formed on a part of the negative electrode tab 11e on the side of the negative electrode current collector 11a. As a result, the occurrence of short circuits is suppressed and the strength of the solid battery 10 is improved.
[0032] The materials constituting the negative electrode insulating frame 11h are not particularly limited, but examples include insulating oxides such as alumina, resins such as polyvinylidene fluoride (PVDF), and rubbers such as styrene-butadiene rubber (SBR).
[0033] The negative electrode insulating frame 11h may contain a material that can expand and contract. This absorbs the expansion and contraction of the negative electrode composite layer 11b that occurs during charging and discharging of the solid battery 10.
[0034] Materials capable of expanding and contracting are not particularly limited, but examples include rubbers such as fluororubber, silicone rubber, and isoprene rubber.
[0035] In the electrode laminate 11, an intermediate layer 11i is further formed between the negative electrode composite layer 11b and the solid electrolyte layer 11c. When the solid battery 10 is viewed from above, the outer edge of the intermediate layer 11i is located at the same position as the outer edge of the negative electrode insulating frame 11h, or it is located inside the outer edge of the negative electrode insulating frame 11h. Here, the intermediate layer 11i is formed on the negative electrode current collector 11a. As a result, the interface between the negative electrode composite layer 11b and the solid electrolyte layer 11c is stable.
[0036] The intermediate layer 11i has the function of uniformly depositing Li metal when the solid battery 10 is a lithium metal secondary battery. Here, the lithium metal secondary battery may not have a negative electrode composite layer 11b, i.e., it may be anode-free. In this case, a lithium metal layer is formed as the negative electrode composite layer 11b after the first charge and discharge. For this reason, if the solid battery 10 is not a lithium metal secondary battery, the intermediate layer 11i can be omitted.
[0037] The material constituting the intermediate layer 11i is not particularly limited, but examples include carbon on which a metal capable of alloying with Li (e.g., Ag) is supported.
[0038] The solid electrolyte layer 11c has a higher strength in the region facing the negative electrode composite layer 11b and / or the positive electrode composite layer 11d than in the region not facing the negative electrode composite layer 11b or the positive electrode composite layer 11d. This improves the strength of the solid battery 10. Here, the strength of the solid electrolyte layer 11c can be controlled by the composition of the solid electrolyte layer 11c (for example, the solid electrolyte content).
[0039] The manufacturing method of the solid battery 10 will be explained using Figures 3 and 4.
[0040] After forming the positive electrode composite layer 11d and the positive electrode insulating frame 11f on the positive electrode current collector 31 (see Figure 3(a)), the excess is cut off to obtain the positive electrode sheet 32 (see Figure 3(b)). Next, the nonwoven fabric 33 is impregnated with the solid electrolyte 34 (see Figure 3(c)), the excess is cut off to form an extended portion 11g, and the solid electrolyte layer sheet 35 is obtained (see Figure 3(d)). Next, the positive electrode sheet 32 and the solid electrolyte layer sheet 35 are stacked together and roll-pressed (see Figure 3(e)). Next, the excess is cut off to form the positive electrode tab 13 (see Figure 3(g)), and then it is cut to the size that constitutes the solid battery 10 to obtain the positive electrode-solid electrolyte layer laminate 36 (see Figure 3(h)).
[0041] Meanwhile, a negative electrode composite layer 11b and a negative electrode insulating frame 11h are formed on the negative electrode current collector 41 to obtain a negative electrode sheet 42 (see Figure 4(a)). Next, an intermediate layer 11i is formed on the substrate 43 to obtain an intermediate layer transfer sheet 44 (see Figure 4(b)). Next, the intermediate layer 11i is transferred to the negative electrode sheet 42 using the intermediate layer transfer sheet 44, and then roll-pressed (see Figure 4(c)). Next, the excess is cut to form a negative electrode tab 11e (see Figure 4(d)), and then it is cut to the size that constitutes the solid-state battery 10 to obtain a negative electrode-intermediate layer laminate 45 (see Figure 4(e)). Next, the positive electrode-solid electrolyte layer laminate 36 and the negative electrode-intermediate layer laminate 45 are stacked together and then roll-pressed to obtain a solid-state battery 10 (see Figure 4(f)).
[0042] Alternatively, the solid-state batteries 10 may be manufactured using an automated stacking device. In this case, as shown in Figure 5, the manufactured solid-state batteries 10 are transported by a belt conveyor 51 and then discharged onto a tray 52. At this time, the solid-state batteries 10 are aligned by the solid electrolyte layer 11c.
[0043] The following describes the case where the solid-state battery of this embodiment is an all-solid-state lithium secondary battery.
[0044] The positive electrode current collector is not particularly limited, but examples include aluminum foil.
[0045] The positive electrode composite layer contains a positive electrode active material and may further contain a solid electrolyte, a conductive assistant, a binder, etc.
[0046] The positive electrode active material is not particularly limited as long as it can occlude and release lithium ions. For example, LiCoO2, Li(Ni 5 / 10 Co 2 / 10 Mn 3 / 10 )O 2、 Li(Ni 6 / 10 Co 2 / 10 Mn 2 / 10 )O 2、 Li(Ni 8 / 10 Co 1 / 10 Mn 1 / 10 )O 2、 Li(Ni 0.8 Co 0.15 Al 0.05 )O 2、 Li(Ni 1 / 6 Co 4 / 6 Mn 1 / 6 )O 2、 Li(Ni 1 / 3 Co 1 / 3 Mn 1 / 3 )O 2、 LiCoO4, LiMn2O4, LiNiO2, LiFePO4, lithium sulfide, sulfur, etc. can be mentioned.
[0047] The solid electrolyte constituting the solid electrolyte layer is not particularly limited as long as it is a material capable of conducting lithium ions. For example, oxide-based electrolytes, sulfide-based electrolytes, etc. can be mentioned.
[0048] The negative electrode composite layer contains a negative electrode active material and may further contain a solid electrolyte, a conductive assistant, a binder, etc.
[0049] The negative electrode active material is not particularly limited as long as it can occlude and release lithium ions. For example, metallic lithium, lithium alloys, metal oxides, metal sulfides, metal nitrides, Si, SiO, carbon materials, etc. can be mentioned. Examples of carbon materials include artificial graphite, natural graphite, hard carbon, soft carbon, etc.
[0050] The negative electrode current collector is not particularly limited, but examples include copper foil.
[0051] Although embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and the above embodiments may be modified as appropriate within the scope of the spirit of the present invention. [Explanation of symbols]
[0052] 10 solid state battery 11 Electrode Stack 11a Negative electrode current collector 11b Negative electrode composite layer 11c solid electrolyte layer 11d Positive electrode composite layer 11e Negative Electrode Tab 11f Positive electrode insulating frame 11g extension 11h Negative electrode insulation frame 11i middle tier 12 Positive electrode current collector 13 Positive Tab 31 Positive electrode current collector 32 Positive electrode sheet 33 Nonwoven fabric 34 Solid electrolyte 35 Sheet for solid electrolyte layer 36. Cathode-Solid Electrolyte Layer Laminate 41 Negative electrode current collector 42 Negative electrode sheet 43 Base material 44. Intermediate layer transfer sheet 45. Negative electrode-intermediate layer laminate 51 Belt conveyor 52 trays
Claims
[Claim 1] An all-solid-state battery in which an electrode laminate is formed by sequentially stacking a positive electrode composite layer, a solid electrolyte layer, and a negative electrode composite layer on a positive electrode current collector, with the negative electrode current collector sandwiched between them, The aforementioned negative electrode composite layer has a negative electrode insulating frame provided in contact with its outer periphery. A negative electrode tab extends from the aforementioned negative electrode current collector, All-solid-state battery, when viewed from above, wherein the entire outer circumference of the positive electrode current collector is located inside the entire outer circumference of the solid electrolyte layer, the outer circumference of the negative electrode insulating frame on the side from which the negative electrode tab extends is located at the same position as the outer circumference of the solid electrolyte layer or outside the outer circumference of the solid electrolyte layer, and the outer circumference of the negative electrode insulating frame on the side from which the negative electrode tab does not extend is located at the same position as the outer circumference of the solid electrolyte layer.