市场调查报告书
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1235912
全球地面激光扫描市场:到 2028 年的预测——按解决方案、按激光类型、按应用、按地区Terrestrial Laser Scanning Market Forecasts to 2028 - Global Analysis By Solution, Laser Type, Application and Geography |
根据 Stratistics MRC 的数据,2022 年全球地面激光扫描市场规模将达到 48.8 亿美元,预测期内以 9.7% 的复合年增长率增长,2028 年将达到 85 亿美元。预计达到美元。
使用安装在三脚架上的激光扫描仪扫描大型环境和物体,这一过程称为地面激光扫描。 该技术常用于建筑、测量和林业等领域。 与其他可以安装在车辆上或使用手持设备从不同角度收集数据的激光扫描仪相比,地面激光扫描,也称为远程激光扫描,需要将扫描仪放置在固定位置才能进行。 与传统的计量技术相比,地面激光扫描系统提供更高的精度、更快的数据采集和更容易的定位。
根据英国遗产公制测量技术的分类,直接法和间接法主要应用于文化遗产记录领域。
製造和建筑等行业越来越需要实时数据收集。 这些地区受益于地面激光扫描系统提供的时间和成本节约。 地面激光扫描系统在数据传输速度、准确性和容量方面也表现出色。 因此,由于需要准确和大容量的数据传输,地面激光扫描系统的市场正在增长。 此外,地面激光扫描在空间数据采集效率方面优于传统大地测量方法。
与手动测量相比,3D 激光扫描的成本很高。 然而,根据项目的规模,手动测量可能比使用测量激光更昂贵。 激光扫描仪可以提供完美的数据,可以通过多种方式修改和使用,如多边形网格模型、实体表面模型、实体CAD模型等,但用户需要适当的计算机技术来支持对内存的高要求。数据,我在做 技术公司,例如工程和製造公司,通常没有这个问题。 但对于不使用商业计算机系统的企业,如警察局或小型设计工作室,问题可能会出现。
随着基础设施对 3D 激光扫描仪的需求不断增长,研发预计将成为市场扩张的主要驱动力。 预计整体市场增长将受到采用激光扫描技术进行快速库存创建和绘图,以及基础设施领域全球资本支出增加的推动。 此外,通过比较激光和照射光束的传播时间,可以即时提供物体表面准确详细的 3D 数据。 这将使 3D 模型能够快速且经济地创建,从而进一步增加其市场价值。
各种技术用于文物,展示了记录对象的许多选项。 然而,没有一种方法足以获得所需的精度,每种方法都有优点和缺点。 成本、持续时间、对像大小和復杂性、访问权限、个人才能和设备能力是确定哪种调查方法最佳的重要因素。 说到采集数据,激光扫描仪并不一定像相机那么灵活多变。 如果需要高分辨率,则获取数据的周期可能比预期的要长。
在 COVID-19 情景中,宣布的封锁和政府对公众集会的限制推迟了地面激光扫描技术的研发。 各州搁置或推迟建设项目,损害了对地面激光扫描系统的需求。 由于基本组件的供应链中断,COVID-19 旅行限制对地面激光扫描系统的生产产生了重大的负面影响。 随着全球旅行限制的放宽以及员工逐渐重返工作岗位,对地面激光扫描的需求将显着增加。
建筑信息模型部分预计在预测期内将占最大份额。 建筑信息模型使工程、建筑和施工专业人员能够设计、规划和管理施工生命週期。 随着世界人口的增长,需要更有效的规划、设计和建设方式。 这些解决方案有助于收集用于维护和运营优化的数据,从而提高效率。 使用激光扫描的公司可以在建筑物建成之前看到它们。 这最终将为您节省时间和金钱。 这些因素正在推动这一细分市场的增长。
相移扫描部分预计在预测期内实现利润丰厚的增长。 使用从扫描仪发射的恆定激光束执行相移扫描。 相移扫描仪的数据采集速率高达每秒 100 万点。 但是,它的作用范围只有大约 80m。 基于相位的扫描仪的主要应用是工厂操作和建筑物内部扫描。 由于其远距离高精度以及建筑、石油和天然气、加工和农业等行业不断增长的需求,预计该市场将会增长。
亚太地区将在 2021 年主导全球地面激光扫描市场份额,预计在预测期内仍将占据主导地位。 增长的主要驱动力之一是该地区蓬勃发展的建筑行业的需求份额不断上升。 在亚太地区,中国、澳大利亚和马来西亚对地面激光扫描仪的强劲需求,以及这些国家蓬勃发展的建筑业,正在推动这些工具的市场。
美国和加拿大的基础设施建设正在取得进展,预计北美在预测期内将录得较大的复合年增长率。 工业、石油和天然气以及建筑等行业对高效实时数据收集设备的需求不断增长,预计将支持该地区的市场扩张。 由于可以通过缩短项目完成时间来降低流程成本,因此美国地面激光扫描系统的销量正在增加。
地面激光扫描市场的主要参与者是: 3D System Inc.、Basic Software Inc.、Blom ASA、Carl Zeiss Optotechnik GmbH、Creaform Inc.、FARO Technologies、Fugro N.V.、General Electric、Harvey-Lynch, Inc.、Hexagon Geosystems、Leica Geosystems HDS, LLC 、Maptek、Merrett Survey、RIEGL Laser Measurement Systems、Teledyne Technologies Inc、Topcon Corporation 和 Trimble Inc.Ametek, Inc.
2023 年 1 月,3D Systems 和 Stewart-Haas Racing 今天宣布,他们已建立技术合作伙伴关係以取得胜利。 赢得冠军的 NASCAR 团队使用 3D Systems 的 ProX(R) 800 立体光刻技术和 Figure 4(R) Standalone 3D 打印机来显着提高赛车的速度和性能。 与 3D Systems 的这一为期三年的技术合作伙伴关係将使 Stewart-Haas Racing 能够快速製造耐用部件,包括更快的设计、原型製作和生产迭代。
2022 年 11 月,3D Systems 宣布与瑞典 3D 打印机製造商 Wematter 建立战略合作伙伴关係,以扩展 3D Systems 的选择性激光烧结 (SLS) 产品组合。 通过此次合作,3D Systems 将成为 Gravity 的全球独家经销商,支持 Wematter 的整体市场扩张。 作为全球分销商,3D Systems 可以为最终用途零件製造提供可靠且经济实惠的 SLS 解决方案,从而吸引更多客户。
2022 年 11 月,3D Systems 和 ALM 宣布建立合作伙伴关係,以扩大对行业领先的 3D 打印材料的访问。 ALM 计划将 3D Systems 的 DuraForm(R) PAx 材料添加到其产品组合中,使客户能够获得专门用于现有选择性激光烧结 (SLS) 技术的专有共聚物。 这将使 ALM 的客户能够访问更广泛的材料组合,使他们能够选择最适合其应用的材料。 该合作伙伴关係标誌着 3D Systems 和 ALM 迈出了第一步,使用来自各种设备製造商的 SLS 技术来满足客户的材料需求。
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根据产品组合、地理分布和战略联盟对主要参与者进行基准测试
According to Stratistics MRC, the Global Terrestrial Laser Scanning Market is accounted for $4.88 billion in 2022 and is expected to reach $8.50 billion by 2028 growing at a CAGR of 9.7% during the forecast period. Large-scale environments and objects are scanned using tripod-mounted laser scanners in a process known as terrestrial laser scanning. The technique is frequently used in the construction, surveying, and forestry industries. In contrast to other laser scanners that can be mounted to vehicles or used as handheld devices to collect data from a wider variety of angles, terrestrial laser scanning, also known as long-range laser scanning, involves placing a scanner in a fixed location. When compared to traditional measurement techniques, terrestrial laser scanning systems offer higher accuracy, faster data capture, and easier positioning.
According to the classification of metric survey techniques by English Heritage, direct and indirect techniques are mainly applied in cultural heritage documentation field (Heritage, 2011; Ulvi & Yakar, 2014; YIlmaz & Yakar, 2006)).
Real-time data collection is becoming more and more necessary in sectors like manufacturing and construction. These sectors benefit from the time and cost savings provided by terrestrial laser scanning systems. Additionally, terrestrial laser scanning systems offer excellent data transfer rates, precision, and volume. Therefore, the market for terrestrial laser scanning systems is expanding due to the necessity for accurate, large volume data transfer. Furthermore, Terrestrial Laser Scanning is better to conventional geodetic methods in terms of the effectiveness of spatial data collection.
Compared to manual surveying, 3D laser scanning is more expensive. However, hand surveying may be more expensive than employing survey lasers, depending on the size of the project. Users still need the right computer technology to support the data's high memory requirements, even while laser scanners offer flawless data that can be changed and used in a variety of ways using polygon mesh models, solid surface models, and solid CAD models. Technical companies like engineering organisations and manufacturing companies typically don't have this issue. However, businesses like police departments and small design studios that don't employ commercial-grade computer systems may experience problems.
Research and development will likely emerge as the main driver of market expansion, combined with the expanding need for 3D laser scanners in infrastructure. The market's overall growth is anticipated to be aided by the adoption of laser scanning technologies for quick inventory creation and mapping, as well as a rise in capital spending worldwide from the infrastructure sector. Additionally, it provides instantaneous, accurate, dense three-dimensional data on an object's surface by comparing the laser's propagation time to emitted beam. This makes creating 3D models quickly and affordably, which will aggravate their market worth.
The multiplicity of options for documenting an object was demonstrated by the large array of technology used in cultural heritage. A single method, however, is insufficient to achieve the requisite accuracy, and each method has its own benefits and drawbacks. Cost, duration, the size and complexity of the object, accessibility, individual talents, and instrument capabilities all play a key role in determining which survey approach is best. When it comes to gathering data, laser scanners are not always as versatile or varied as cameras. The period for obtaining data can take a lot longer than anticipated if high resolution is necessary.
The COVID-19 scenario has slowed down research and development of terrestrial laser scanning technologies due to the announced lockdowns and government restrictions on public gatherings. States have put construction projects on hold or delayed them, which has hurt the demand for terrestrial laser scanning systems. Due to disruptions in the supply chain for essential components, COVID-19 travel restrictions have had a significant negative impact on the production of terrestrial laser scanning systems. When travel restrictions start to loosen up around the world and employees start to gradually return to their places of employment, there will be a significant increase in the need for Terrestrial Laser Scanning.
Over the course of the forecast period, the building information modeling segment is anticipated to witness largest share. Building information modeling allows engineering, architecture, and construction professionals to design, plan, and manage the construction lifecycle. As the world's population expands, better and more efficient methods of planning, designing, and building are needed. The assistance provided by these solutions in data collection for maintenance and operation optimization results in efficiency gains. A company that uses laser scanning can see a building before it is built. This ultimately saves time and money. Such factors are fueling the segments growth.
The phase shift scanning segment is anticipated to experience lucrative growth during the forecast period. Phase shift scanning is performed using a constant laser beam that is emitted from the scanner. Phase-based scanners have a data collection rate of up to one million points per second. However, their range is only about 80 metres. The main uses for phase-based scanners are industrial plant work and interior building scanning. Due to its high precision over long distances and the consistently rising demand from the construction, oil and gas, fabrication, and agricultural industries, the market is predicted to expand.
Asia Pacific dominated the global terrestrial laser scanning market share in 2021 and is estimated to remain dominant throughout the forecast period. One of the main causes of the growth is the escalating rate of demand in the region's booming construction sector. The Asia Pacific market for these tools is being driven by the significant demand for terrestrial laser scanners in China, Australia, and Malaysia, as well as the rapidly growing construction industries in those nations.
Owing to the regions' growing infrastructure development in the United States and Canada, North America is anticipated to experience a significant CAGR during the forecast period. It is anticipated that the demand for efficient real-time data-gathering equipment in the industrial, oil and gas, and construction sectors will rise, supporting regional market expansion. Due to their ability to reduce process costs by reducing project completion times, terrestrial laser scanning systems are seeing an increase in sales in the U.S.
Some of the key players in Terrestrial Laser Scanning market include: 3D System Inc., Basic Software Inc., Blom ASA, Carl Zeiss Optotechnik GmbH, Creaform Inc., FARO Technologies, Fugro N.V, General Electric, Harvey-Lynch, Inc, Hexagon Geosystems, Leica Geosystems HDS, LLC, Maptek, Merrett Survey, RIEGL Laser Measurement Systems, Teledyne Technologies Inc., Topcon Corporation and Trimble Inc. Ametek, Inc.
In January 2023, 3D Systems and Stewart-Haas Racing, today announced they have entered a technical partnership built for victory. The championship-winning NASCAR team has relied on 3D Systems' ProX® 800 stereolithography and Figure 4® Standalone 3D printers to dramatically improve speed and performance in its racecars. With the help of 3D Systems and this three-year technical partnership, Stewart-Haas Racing can rapidly create durable parts, including design and prototyping with faster iteration, and production.
In November 2022, 3D Systems announced a strategic partnership with Wematter, a Swedish 3D printer manufacturer that will broaden 3D Systems' Selective Laser Sintering (SLS) portfolio. Through this partnership, 3D Systems will become the exclusive worldwide distributor of the Gravity, thus helping Wematter expand its total market. As the global distributor, 3D Systems will be able to reach additional customers with a high-reliability, affordable SLS solution for the production of end-use parts.
In November 2022, 3D Systems and ALM announced they have entered into a partnership to expand access to industry-leading 3D printing materials. ALM will add 3D Systems' DuraForm® PAx material to its portfolio, providing its customers access to a unique copolymer specifically designed for use with available Selective Laser Sintering (SLS) technologies. As a result, ALM's customers will have access to an expanded materials portfolio enabling them to choose the best material for their application. This partnership is the first step between 3D Systems and ALM to address the material needs of customers who may use SLS technologies from a variety of equipment manufacturers for their application needs.
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Benchmarking of key players based on product portfolio, geographical presence, and strategic alliances