清华大学3D打印新突破！速度提升50倍

快科技

Feb 12

快科技2月12日消息，清华大学今天发文称，该校戴琼海院士团队历经五年攻关，研发出计算全息光场（DISH）三维打印技术，相关成果发表于《自然》。

该技术将传统体积3D打印的曝光速度提升50倍，毫米尺寸复杂结构的曝光时间仅需0.6秒，远超传统体积三维打印技术曝光的30秒水平。

打印过程实拍，不到一秒即可完成毫米尺寸物体打印

传统3D打印技术各有短板，逐点、逐层打印精度高但效率极低，毫米级物体加工动辄数十分钟；现有体积打印虽提升速度，却受景深、材料粘度限制，精度和适用范围大打折扣。

团队创新将计算光学反向应用于3D打印，通过操纵高维光场构建三维实体，改写了传统打印的底层逻辑，还攻克了光场高速调控、光路高精度矫正等多项技术难题。

这项新技术实现了多重突破，不仅打印速度大幅提升，还兼容从近水粘度稀溶液到高粘度树脂的各类材料，解决了传统技术材料选择单一的问题。

打印容器无需特殊设计，可在流体管道内实现批量连续打印，拓展了应用场景。

同时，技术将打印景深从50微米拓展至1厘米，1厘米范围内光学分辨率保持11微米，打印最细特征达12微米，实现速度与精度的双重提升。

该技术整合多学科优势，未来在生物医学、工程制造等领域应用前景广阔，可实现生物组织原位打印、微型组件批量生产等等。

DISH技术系统设计图

Disclaimer: Investing carries risk. This is not financial advice. The above content should not be regarded as an offer, recommendation, or solicitation on acquiring or disposing of any financial products, any associated discussions, comments, or posts by author or other users should not be considered as such either. It is solely for general information purpose only, which does not consider your own investment objectives, financial situations or needs. TTM assumes no responsibility or warranty for the accuracy and completeness of the information, investors should do their own research and may seek professional advice before investing.

Most Discussed

1
2
3
4
5
6
7
8
9
10

{"basename":"","ssrTDKData":{"titleTemplate":"%s - Tiger Brokers","title":"Tiger Brokers | Global Stocks, Options & Futures Trading App","description":"Tiger Brokers, one-stop investment in US stocks, SGX stocks, HK stocks, A-shares & other global assets. One of the best stock trading platforms in Singapore.","keywords":"tiger brokers,tiger trade,tiger brokers singapore,broker online,stock trading in singapore,share trading singapore,brokerage firm singapore,trading app,stock broker singapore,stock trading platforms,trading account","social":{"ogDescription":"Tiger Brokers, one-stop investment in US stocks, SGX stocks, HK stocks, A-shares & other global assets. One of the best stock trading platforms in Singapore.","ogImage":"https://c1.itigergrowtha.com/portal5/static/media/og-logo.be62fbe1.png","ogUrl":"https://www.itiger.com/news/2610943944"},"companyName":"Tiger Brokers"},"pageData":{"isMobile":false,"isTiger":false,"isTTM":true,"region":"SGP","license":"TBSG","edition":"fundamental"},"isCrawlerRequest":true,"__swrFallback__":{"@#url:\"https://stock-news.skytigris.cn/v3/news\",params:#id:\"2610943944\",edition:\"fundamental\",auth_exemption:1,,,undefined,":{"share":"https://ttm.financial/m/news/2610943944?lang=en_US&edition=fundamental","thumbnail":"","is_english":false,"pubTime":"2026-02-12 15:51","share_image_url":"https://static.laohu8.com/e9f99090a1c2ed51c021029395664489","id":"2610943944","market":"us","top_or_hot":-1,"title":"清华大学3D打印新突破！速度提升50倍","media":"快科技","content":"<html><body><p>快科技2月12日消息，<strong>清华大学今天发文称，该校戴琼海院士团队历经五年攻关，研发出计算全息光场（DISH）三维打印技术</strong>，相关成果发表于《自然》。</p><p><strong>该技术将传统体积3D打印的曝光速度提升50倍，毫米尺寸复杂结构的曝光时间仅需0.6秒</strong>，远超传统体积三维打印技术曝光的30秒水平。</p><p><img src=\"https://x0.ifengimg.com/res/2026/9D271598F2D426E318CE26C0DF5BA29BD16A77C2_size655_w400_h225.gif\"/></p><p>打印过程实拍，不到一秒即可完成毫米尺寸物体打印</p><p>传统3D打印技术各有短板，逐点、逐层打印精度高但效率极低，毫米级物体加工动辄数十分钟；现有体积打印虽提升速度，却受景深、材料粘度限制，精度和适用范围大打折扣。</p><p><img src=\"https://x0.ifengimg.com/res/2026/AC7771D21F5C1D25204A40010F7985CDA29FDC08_size86_w600_h212.png\"/></p><p>团队创新将计算光学反向应用于3D打印，<strong>通过操纵<a href=\"https://laohu8.com/S/02086\">高维</a>光场构建三维实体，改写了传统打印的底层逻辑，还攻克了光场高速调控、光路高精度矫正等多项技术难题。</strong></p><p>这项新技术实现了多重突破，不仅打印速度大幅提升，还兼容从近水粘度稀溶液到高粘度树脂的各类材料，解决了传统技术材料选择单一的问题。</p><p>打印容器无需特殊设计，可在流体管道内实现批量连续打印，拓展了应用场景。</p><p>同时，技术将打印景深从50微米拓展至1厘米，1厘米范围内光学分辨率保持11微米，打印最细特征达12微米，实现速度与精度的双重提升。</p><p>该技术整合多学科优势，未来在<a href=\"https://laohu8.com/S/000504\">生物</a>医学、工程制造等领域应用前景广阔，可实现生物组织原位打印、微型组件批量生产等等。</p><p><img src=\"https://x0.ifengimg.com/res/2026/88D6B5E7A7B05AFB9A1132E767C8263584DA094D_size263_w600_h367.png\"/></p><p>DISH技术系统设计图</p></body></html>","source":"fenghuang_stock","html":"<!DOCTYPE html>\n<html>\n<head>\n<meta http-equiv=\"Content-Type\" content=\"text/html; charset=utf-8\" />\n<meta name=\"viewport\" content=\"width=device-width,initial-scale=1.0,minimum-scale=1.0,maximum-scale=1.0,user-scalable=no\"/>\n<meta name=\"format-detection\" content=\"telephone=no,email=no,address=no\" />\n<title>清华大学3D打印新突破！速度提升50倍</title>\n<style type=\"text/css\">\na,abbr,acronym,address,applet,article,aside,audio,b,big,blockquote,body,canvas,caption,center,cite,code,dd,del,details,dfn,div,dl,dt,\nem,embed,fieldset,figcaption,figure,footer,form,h1,h2,h3,h4,h5,h6,header,hgroup,html,i,iframe,img,ins,kbd,label,legend,li,mark,menu,nav,\nobject,ol,output,p,pre,q,ruby,s,samp,section,small,span,strike,strong,sub,summary,sup,table,tbody,td,tfoot,th,thead,time,tr,tt,u,ul,var,video{ font:inherit;margin:0;padding:0;vertical-align:baseline;border:0 }\nbody{ font-size:16px; line-height:1.5; color:#999; background:transparent; }\n.wrapper{ overflow:hidden;word-break:break-all;padding:10px; }\nh1,h2{ font-weight:normal; line-height:1.35; margin-bottom:.6em; }\nh3,h4,h5,h6{ line-height:1.35; margin-bottom:1em; }\nh1{ font-size:24px; }\nh2{ font-size:20px; }\nh3{ font-size:18px; }\nh4{ font-size:16px; }\nh5{ font-size:14px; }\nh6{ font-size:12px; }\np,ul,ol,blockquote,dl,table{ margin:1.2em 0; }\nul,ol{ margin-left:2em; }\nul{ list-style:disc; }\nol{ list-style:decimal; }\nli,li p{ margin:10px 0;}\nimg{ max-width:100%;display:block;margin:0 auto 1em; }\nblockquote{ color:#B5B2B1; border-left:3px solid #aaa; padding:1em; }\nstrong,b{font-weight:bold;}\nem,i{font-style:italic;}\ntable{ width:100%;border-collapse:collapse;border-spacing:1px;margin:1em 0;font-size:.9em; }\nth,td{ padding:5px;text-align:left;border:1px solid #aaa; }\nth{ font-weight:bold;background:#5d5d5d; }\n.symbol-link{font-weight:bold;}\n/* header{ border-bottom:1px solid #494756; } */\n.title{ margin:0 0 8px;line-height:1.3;color:#ddd; }\n.meta {color:#5e5c6d;font-size:13px;margin:0 0 .5em; }\na{text-decoration:none; color:#2a4b87;}\n.meta .head { display: inline-block; overflow: hidden}\n.head .h-thumb { width: 30px; height: 30px; margin: 0; padding: 0; border-radius: 50%; float: left;}\n.head .h-content { margin: 0; padding: 0 0 0 9px; float: left;}\n.head .h-name {font-size: 13px; color: #eee; margin: 0;}\n.head .h-time {font-size: 11px; color: #7E829C; margin: 0;line-height: 11px;}\n.small {font-size: 12.5px; display: inline-block; transform: scale(0.9); -webkit-transform: scale(0.9); transform-origin: left; -webkit-transform-origin: left;}\n.smaller {font-size: 12.5px; display: inline-block; transform: scale(0.8); -webkit-transform: scale(0.8); transform-origin: left; -webkit-transform-origin: left;}\n.bt-text {font-size: 12px;margin: 1.5em 0 0 0}\n.bt-text p {margin: 0}\n</style>\n</head>\n<body>\n<div class=\"wrapper\">\n<header>\n<h2 class=\"title\">\n清华大学3D打印新突破！速度提升50倍\n</h2>\n\n<h4 class=\"meta\">\n\n\n2026-02-12 15:51 北京时间&nbsp;&nbsp;&nbsp;<a href=https://tech.ifeng.com/c/8qgZwhKjvvg><strong>快科技</strong></a>\n\n\n</h4>\n\n</header>\n<article>\n<div>\n<p>快科技2月12日消息，清华大学今天发文称，该校戴琼海院士团队历经五年攻关，研发出计算全息光场（DISH）三维打印技术，相关成果发表于《自然》。该技术将传统体积3D打印的曝光速度提升50倍，毫米尺寸复杂结构的曝光时间仅需0.6秒，远超传统体积三维打印技术曝光的30秒水平。打印过程实拍，不到一秒即可完成毫米尺寸物体打印传统3D打印技术各有短板，逐点、逐层打印精度高但效率极低，毫米级物体加工动辄数十分钟...</p>\n\n<a href=\"https://tech.ifeng.com/c/8qgZwhKjvvg\">Source Link</a>\n\n</div>\n\n\n</article>\n</div>\n</body>\n</html>\n","isBrief":false,"type":0,"news_type":1,"symbol":"BK4588","symbol_name":"碎股","start_time":0,"source_url":"https://tech.ifeng.com/c/8qgZwhKjvvg","article_id":"2610943944","we_media_id":null,"thumbnails":[],"rights":null,"url":"https://stock-news.laohu8.com/highlight/detail?id=2610943944","pubTimestamp":1770882689,"columns":[],"sourceInfo":{"source_id":"fenghuang_stock","name":"凤凰网"},"weMediaInfo":null,"summary":"团队创新将计算光学反向应用于3D打印，通过操纵高维光场构建三维实体，改写了传统打印的底层逻辑，还攻克了光场高速调控、光路高精度矫正等多项技术难题。","collect":0,"end_time":0,"defaultTopTitle":"ifeng.com","property":[],"viewcount":null,"language":"zh","relate_stocks":{"BK4588":"碎股","BK4100":"有线和卫星","BK4585":"ETF&股票定投概念","DISH":"Dish Network"},"translate_title":"A new breakthrough in 3D printing at Tsinghua University! 50 times faster","themeId":null,"isJumpTheme":false,"ttsUrl":null,"symbols_score_info":{"DISH":1},"content_text":"快科技2月12日消息，清华大学今天发文称，该校戴琼海院士团队历经五年攻关，研发出计算全息光场（DISH）三维打印技术，相关成果发表于《自然》。该技术将传统体积3D打印的曝光速度提升50倍，毫米尺寸复杂结构的曝光时间仅需0.6秒，远超传统体积三维打印技术曝光的30秒水平。打印过程实拍，不到一秒即可完成毫米尺寸物体打印传统3D打印技术各有短板，逐点、逐层打印精度高但效率极低，毫米级物体加工动辄数十分钟；现有体积打印虽提升速度，却受景深、材料粘度限制，精度和适用范围大打折扣。团队创新将计算光学反向应用于3D打印，通过操纵高维光场构建三维实体，改写了传统打印的底层逻辑，还攻克了光场高速调控、光路高精度矫正等多项技术难题。这项新技术实现了多重突破，不仅打印速度大幅提升，还兼容从近水粘度稀溶液到高粘度树脂的各类材料，解决了传统技术材料选择单一的问题。打印容器无需特殊设计，可在流体管道内实现批量连续打印，拓展了应用场景。同时，技术将打印景深从50微米拓展至1厘米，1厘米范围内光学分辨率保持11微米，打印最细特征达12微米，实现速度与精度的双重提升。该技术整合多学科优势，未来在生物医学、工程制造等领域应用前景广阔，可实现生物组织原位打印、微型组件批量生产等等。DISH技术系统设计图","kind":"news","is_publish_news":true,"is_publish_highlight":false,"is_publish_live":false,"is_publish_wemedia":null,"editions":null,"column":"","sentiment":"0","news_tag":"","news_rank":0,"symbols":[],"gpt_button":1,"need_auth":false,"code":"91000000","status":"200"}}}