{"title":"用银导电材料印制的柔性可穿戴三齿状 UWB 天线","authors":"Wendong Yang, Xi Cheng, Xun Zhao, Jia Wang","doi":"10.1021/acsomega.4c05071","DOIUrl":null,"url":null,"abstract":"The advancement of Internet of Things and associated technologies has led to the widespread usage of smart wearable devices, greatly boosting the demand for flexible antennas, which are critical electromagnetic components in such devices. Additive manufacturing technologies provide a feasible solution for the creation of wearable and flexible antennas. However, performance reliability under deformation and radiation safety near the human body are two issues that need to be solved for such antennas. Currently, there are few reports on compact, flexible ultrawideband (UWB) antennas with more notch numbers, reliable bendability, and radiation safety. In this paper, a UWB antenna with trinotched characteristics for wearable applications was proposed and developed using printable conductive silver materials consisting of silver microflakes or silver nanoparticles. The antenna has a compact size of 18 × 20 × 0.12 mm<sup>3</sup> and adopts a gradient feeder and a radiation patch with three folding slots. It was fabricated on transparent and flexible poly(ethylene terephthalate) film substrates, using screen printing and inkjet printing. The measurement results demonstrated that the fabricated antennas could cover the UWB band (2.35–10.93 GHz) while efficiently filtering out interferences from the C-band downlink satellite system (3.43–4.21 GHz), wireless local area networks (4.66–5.29 GHz), and X-band uplink satellite system (6.73–8.02 GHz), which was consistent with the simulation results. The bendability and radiation safety of the antennas were evaluated, proving their feasibility for usage under bending conditions and near the human body. Additionally, it was found that the screen-printed antenna performed better after bending. The research is expected to provide guidance on designing flexible antennas that are both safe to wear and easily conformable.","PeriodicalId":22,"journal":{"name":"ACS Omega","volume":null,"pages":null},"PeriodicalIF":3.7000,"publicationDate":"2024-09-12","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Flexible Wearable Trinotched UWB Antenna Printed with Silver Conductive Materials\",\"authors\":\"Wendong Yang, Xi Cheng, Xun Zhao, Jia Wang\",\"doi\":\"10.1021/acsomega.4c05071\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"The advancement of Internet of Things and associated technologies has led to the widespread usage of smart wearable devices, greatly boosting the demand for flexible antennas, which are critical electromagnetic components in such devices. Additive manufacturing technologies provide a feasible solution for the creation of wearable and flexible antennas. However, performance reliability under deformation and radiation safety near the human body are two issues that need to be solved for such antennas. Currently, there are few reports on compact, flexible ultrawideband (UWB) antennas with more notch numbers, reliable bendability, and radiation safety. In this paper, a UWB antenna with trinotched characteristics for wearable applications was proposed and developed using printable conductive silver materials consisting of silver microflakes or silver nanoparticles. The antenna has a compact size of 18 × 20 × 0.12 mm<sup>3</sup> and adopts a gradient feeder and a radiation patch with three folding slots. It was fabricated on transparent and flexible poly(ethylene terephthalate) film substrates, using screen printing and inkjet printing. The measurement results demonstrated that the fabricated antennas could cover the UWB band (2.35–10.93 GHz) while efficiently filtering out interferences from the C-band downlink satellite system (3.43–4.21 GHz), wireless local area networks (4.66–5.29 GHz), and X-band uplink satellite system (6.73–8.02 GHz), which was consistent with the simulation results. The bendability and radiation safety of the antennas were evaluated, proving their feasibility for usage under bending conditions and near the human body. Additionally, it was found that the screen-printed antenna performed better after bending. 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引用次数: 0
摘要
物联网及相关技术的发展带动了智能可穿戴设备的广泛应用,极大地促进了对柔性天线的需求,而柔性天线是此类设备中的关键电磁元件。增材制造技术为制造可穿戴柔性天线提供了可行的解决方案。然而,变形下的性能可靠性和人体附近的辐射安全性是此类天线需要解决的两个问题。目前,关于具有更多凹口数、可靠的可弯曲性和辐射安全性的紧凑型柔性超宽带(UWB)天线的报道很少。本文利用由银微片或银纳米颗粒组成的可印刷导电银材料,提出并开发了一种具有三凹槽特性的 UWB 天线,用于可穿戴应用。该天线尺寸为 18 × 20 × 0.12 mm3,采用梯度馈线和带三个折叠槽的辐射贴片。该天线采用丝网印刷和喷墨打印技术,在透明柔性聚对苯二甲酸乙二醇酯薄膜基底上制作而成。测量结果表明,所制作的天线可覆盖 UWB 频段(2.35-10.93 GHz),同时能有效滤除来自 C 波段下行卫星系统(3.43-4.21 GHz)、无线局域网(4.66-5.29 GHz)和 X 波段上行卫星系统(6.73-8.02 GHz)的干扰,这与仿真结果一致。对天线的可弯曲性和辐射安全性进行了评估,证明了其在弯曲条件下和靠近人体使用的可行性。此外,研究还发现丝网印刷天线在弯曲后性能更好。这项研究有望为设计既可安全佩戴又易于贴合人体的柔性天线提供指导。
Flexible Wearable Trinotched UWB Antenna Printed with Silver Conductive Materials
The advancement of Internet of Things and associated technologies has led to the widespread usage of smart wearable devices, greatly boosting the demand for flexible antennas, which are critical electromagnetic components in such devices. Additive manufacturing technologies provide a feasible solution for the creation of wearable and flexible antennas. However, performance reliability under deformation and radiation safety near the human body are two issues that need to be solved for such antennas. Currently, there are few reports on compact, flexible ultrawideband (UWB) antennas with more notch numbers, reliable bendability, and radiation safety. In this paper, a UWB antenna with trinotched characteristics for wearable applications was proposed and developed using printable conductive silver materials consisting of silver microflakes or silver nanoparticles. The antenna has a compact size of 18 × 20 × 0.12 mm3 and adopts a gradient feeder and a radiation patch with three folding slots. It was fabricated on transparent and flexible poly(ethylene terephthalate) film substrates, using screen printing and inkjet printing. The measurement results demonstrated that the fabricated antennas could cover the UWB band (2.35–10.93 GHz) while efficiently filtering out interferences from the C-band downlink satellite system (3.43–4.21 GHz), wireless local area networks (4.66–5.29 GHz), and X-band uplink satellite system (6.73–8.02 GHz), which was consistent with the simulation results. The bendability and radiation safety of the antennas were evaluated, proving their feasibility for usage under bending conditions and near the human body. Additionally, it was found that the screen-printed antenna performed better after bending. The research is expected to provide guidance on designing flexible antennas that are both safe to wear and easily conformable.
ACS OmegaChemical Engineering-General Chemical Engineering
CiteScore
6.60
自引率
4.90%
发文量
3945
审稿时长
2.4 months
期刊介绍:
ACS Omega is an open-access global publication for scientific articles that describe new findings in chemistry and interfacing areas of science, without any perceived evaluation of immediate impact.