全球地雷探测市场（2024-2034）

预计2024年全球地雷探测市场规模将达63.6亿美元，预计2034年将达101.8亿美元，在预测期内（2024-2034年）复合年增长率为4.82%。

全球地雷探测市场概况

地雷对军事人员和平民都构成重大威胁。这些隐藏的爆炸物可能伤害或杀死手无寸铁的人，阻碍军事行动，并减缓衝突后重建工作。防御性地雷探测包括用于定位和消除这些致命装置的方法和技术，确保部队安全通行并促进人道主义排雷行动。

地雷探测是一项复杂且多方面的任务。地雷有多种形式，并采用多种爆炸机制，包括压力板、绊线和磁力触发器。地雷埋藏深度不同，进一步增加了难度。传统的地雷探测方法严重依赖体力劳动，常常使士兵面临危险。然而，技术的进步带来了更安全、更有效的检测方法。

国防地雷探测采用各种针对识别和消除埋藏爆炸物的具体课题而客製化的方法：

手动勘探仍然是基本方法，使用金属探测器和刺针对地面进行物理检查以查找地雷。这种方法适用于浅层地雷，但它是劳动密集型的，并且存在固有风险，因为它可能会被意外引爆。地雷探测犬利用其高度灵敏的嗅觉在探测爆炸物方面发挥重要作用。特别是在树木繁茂的地区或能见度有限的崎岖地形中，经过专门训练的狗可以提供移动且可靠的检测能力。

机械排雷方法使用滚雷滚筒、惰轮等专用工具。这些工具施加压力或产生受控爆炸，以引爆或清除地面上的地雷。这些方法虽然有效，但有时会损坏基础设施并留下未爆弹，对军事人员和平民带来风险。防御地雷探测的每种方法都响应特定的作战要求和环境条件，不断提高安全性、效率和有效性，以应对不同作战地形中埋藏爆炸物的威胁。

科技对全球探雷市场的影响

国防地雷探测的技术进步正在透过几种创新方法来改变这些操作的有效性和安全性：现代金属探测器提高了灵敏度和识别能力，它已经发展到显着改善埋在地雷中的金属部件的探测。探地雷达 (GPR) 技术对此进行了补充，透过将电磁脉衝传输到地下来检测非金属地雷，并分析反射讯号以定位隐藏的威胁。

电磁感应 (EMI) 探测器可根据周围地形的电导率识别地雷内的金属成分。此方法透过有效区分埋藏金属物体与自然环境来增强检测过程。声学和地震探测方法使用声波或振动来识别地下的异常情况，这些异常情况可能表明埋有地雷的存在。这些技术提供了额外的检测功能，特别是在地形或条件可能使其他方法无效的环境中。

配备先进感测器的无人地面车辆 (UGV) 代表了地雷探测领域的技术飞跃。这些远端操作车辆可以在危险区域中航行并自主搜索地雷，从而最大限度地减少人类在排雷作业期间面临的潜在风险。总的来说，这些创新透过提高准确性、扩展检测能力以涵盖非金属威胁以及提高整体操作安全性，正在彻底改变国防地雷检测。随着军方不断投资和采用这些先进技术，地雷探测行动预计将提高危险环境中的有效性、降低风险并改善结果。

全球地雷探测市场的关键驱动因素

新地雷探测技术的发展和采用是由几个关键因素推动的，每个因素都应对现代衝突和衝突后场景中的不同课题和需求。首先，出于人道主义需要，迫切需要有效的地雷探测技术。在敌对行动停止很久之后，地雷仍持续危害受衝突影响地区的平民。创新技术对于加快排雷行动、清除危险区域以及确保当地社区的安全和生计至关重要。

日益复杂的地雷威胁，包括由塑胶和复合材料等非金属材料製成的地雷，凸显了对先进检测方法的需求。仅靠传统金属探测器可能不足以探测这些现代地雷，必须开发技术来可靠地识别埋藏在不同地形中的非金属威胁。对参与排雷行动的军事人员的安全的担忧需要能够最大限度地减少人类直接暴露于危险的技术。无人系统和先进感测器辅助的远端侦测能力可以实现更安全、更有效率的排雷作业，并降低从事这些危险任务的人员所面临的风险。成本效益是影响新地雷探测技术采用的另一个极为重要的驱动因素。国防机构和人道主义组织都在寻求解决方案，以优化资源并最大限度地降低与排雷行动相关的营运成本。创新技术可望简化流程、减少排雷作业所需的时间、减少所需人员数量，最终提高排雷行动的效率和经济性。随着技术不断进步，新的地雷探测技术的开发将有助于满足人道主义需求，减轻不断变化的威胁，并在全球消除地雷威胁的努力中提高人员安全，对于实现具有成本效益的解决方案仍然至关重要。

全球地雷探测市场的区域趋势

由于技术进步程度、预算限制和具体业务需求不同，地雷探测工作的重点因地区而异。美国、欧洲等已开发国家正大力投资尖端探雷技术。这包括配备先进感测器和人工智慧（AI）演算法的无人系统。也着重于开发先进的对抗技术来应对简易爆炸装置（IED），这些装置在现代衝突场景中构成了重大威胁。这些国家优先考虑技术优势和创新，以提高地雷探测作业的有效性和安全性。

相反，发展中国家经常遇到影响其探雷方法的预算限制。这些国家可能依赖传统方法和更实惠的技术相结合，例如基本的金属探测器或简单的机械清除工具。财务限制强调务实地强调可以利用现有资源实施的具有成本效益的解决方案。此外，这些国家可能会优先考虑培训拆弹小组安全处理和处置地雷，并强调人员专业知识和当地能力。在衝突后地区，探雷行动的主要目标往往是快速排雷，以促进重建和重新安置。在这种情况下，速度和效率对于消除地雷和未爆炸弹药造成的直接威胁至关重要。通常使用能够快速部署和清除的技术，例如机械排雷系统。在这些地区，我们优先清除危险地区，以使流离失所者安全返回并支持长期稳定和发展。

整体而言，已开发国家注重尖端技术和对策，而发展中国家则以务实的方式应对财政困难，衝突后地区则优先考虑出于人道主义恢復目的的快速撤离。这种方法的多样性反映了与世界各地地雷探测行动相关的复杂课题和优先事项。

主要地雷探测项目

L3 TEchnologies 子公司将为美国陆军开发一个地雷探测平台，合约预计为期五年，价值 8,390 万美元。美国国防部週四宣布，AN/PSS-14 反地雷系统还将获得 L3 安全和侦测系统部门的支援服务。此固定价格协议有效期限至 2023 年 11 月 20 日。AN/PSS-14 使用地面雷达、金属探测器、软体和微处理器阵列软体来检测杀伤人员地雷和反坦克地雷。在下达每个任务订单时，承包活动（陆军承包司令部）将确定融资和工作地点。

Promoteq 和 Minelab 反地雷部门很高兴能够帮助瑞典武装部队提高探测地雷、未爆弹和简易爆炸装置的能力。该合约有效期至 2024 年，并授权瑞典武装部队、瑞典国防物资管理局和瑞典民事紧急事务局进一步订购。

本报告分析了全球地雷探测市场，研究了整体市场规模的前景、依地区和国家划分的详细趋势、关键技术概述和市场机会。

目录

地雷探测市场：报告定义

地雷探测市场区隔

• 依地区
• 依平台
• 依类型

地雷探测市场分析（未来10年）

地雷探测市场的市场技术

全球地雷探测市场预测

地雷探测市场：依地区划分的趋势和预测

• 北美
  • 促进/抑制因素和课题
  • PEST分析
  • 市场预测与情境分析
  • 大公司
  • 供应商层级状况
  • 企业标竿管理
• 欧洲
• 中东
• 亚太地区
• 南美洲

地雷探测市场：国家分析

• 美国
  • 防御计划
  • 最新趋势
  • 专利
  • 该市场目前的技术成熟度水平
  • 市场预测与情境分析
• 加拿大
• 义大利
• 法国
• 德国
• 荷兰
• 比利时
• 西班牙
• 瑞典
• 希腊
• 澳大利亚
• 南非
• 印度
• 中国
• 俄罗斯
• 韩国
• 日本
• 马来西亚
• 新加坡
• 巴西

地雷探测市场：市场机会矩阵

地雷探测市场：专家对研究的看法

结论

关于Aviation and Defense Market Reports

The Global Mine Detection market is estimated at USD 6.36 billion in 2024, projected to grow to USD 10.18 billion by 2034 at a Compound Annual Growth Rate (CAGR) of 4.82% over the forecast period 2024-2034.

Introduction to Mine Detection Market:

Landmines pose a significant threat to both military personnel and civilians. These hidden explosives can maim or kill unsuspecting individuals, hindering military operations and delaying reconstruction efforts in post-conflict zones. Defense mine detection encompasses the methods and technologies employed to locate and neutralize these deadly devices, ensuring safe passage for troops and facilitating humanitarian demining activities.

Mine detection is a complex and multifaceted task. Mines come in various forms, employing different detonation mechanisms like pressure plates, tripwires, or magnetic triggers. They can be buried at varying depths, adding another layer of difficulty. Traditional methods of mine detection relied heavily on manual techniques, often putting soldiers at risk. However, advancements in technology have led to a range of safer and more efficient detection methods.

Defense mine detection employs various approaches tailored to the specific challenges of identifying and neutralizing buried explosives:

Manual probing remains a fundamental method, utilizing metal detectors and prodders to physically inspect the ground for mines. Effective for shallow mines, this approach is labor-intensive and carries inherent risks due to the potential for accidental detonation. Mine detection dogs play a crucial role, utilizing their highly sensitive sense of smell to detect explosives. Particularly effective in areas with dense foliage or rugged terrain where visibility is limited, these specially trained dogs provide a mobile and reliable detection capability.

Mechanical mine clearance methods involve the use of specialized equipment such as mine rollers and flailing devices. These tools apply pressure or create controlled explosions to either detonate or clear mines from the ground. While effective, these methods can sometimes damage infrastructure and may leave behind unexploded ordnance, posing risks to both military personnel and civilians. Each approach in defense mine detection addresses specific operational requirements and environmental conditions, reflecting ongoing efforts to enhance safety, efficiency, and effectiveness in countering the threat of buried explosives across diverse operational landscapes.

Technology Impact in Mine Detection Market:

Technological advancements in defense mine detection are transforming the effectiveness and safety of these operations through several innovative approaches: Modern metal detectors have evolved to offer enhanced sensitivity and discrimination capabilities, significantly improving the detection of buried metallic components in mines. Ground penetrating radar (GPR) technology complements this by detecting non-metallic mines through the transmission of electromagnetic pulses into the ground, analyzing the reflected signals to pinpoint hidden threats.

Electromagnetic Induction (EMI) detectors contribute by identifying metallic components within mines based on the electrical conductivity of the surrounding terrain. This method enhances the detection process by effectively distinguishing buried metal objects from the natural environment. Acoustic and seismic detection methods utilize sound waves or vibrations to identify anomalies in the ground that may indicate the presence of buried mines. These techniques provide additional layers of detection capability, particularly in environments where other methods may be less effective due to terrain or conditions.

Unmanned Ground Vehicles (UGVs) equipped with advanced sensors represent a significant technological leap in mine detection. These remotely operated vehicles can navigate hazardous areas and autonomously search for mines, minimizing the exposure of human personnel to potential risks during clearance operations. Collectively, these technological innovations are revolutionizing defense mine detection by improving accuracy, expanding detection capabilities to include non-metallic threats, and enhancing overall operational safety. As military forces continue to invest in and adopt these advanced technologies, the effectiveness of mine detection efforts is expected to increase, mitigating risks and improving outcomes in hazardous environments.

Key Drivers in Defense Mine Detection Market:

The development and adoption of new mine detection technologies are driven by several critical factors, each addressing distinct challenges and imperatives in modern conflict and post-conflict scenarios. Firstly, the humanitarian imperative underscores the urgent need for effective mine detection technologies. Landmines continue to endanger civilian populations in areas affected by conflict long after hostilities cease. Innovative technologies are essential to expedite demining efforts, clear hazardous areas, and ensure the safety and livelihoods of local communities.

Evolving threats from sophisticated mines, including those constructed from non-metallic materials such as plastics and composites, highlight the necessity for advanced detection methods. Traditional metal detectors alone may not suffice in detecting these modern mines, necessitating the development of technologies that can reliably identify non-metallic threats buried in diverse terrain types. Safety concerns for military personnel engaged in mine clearance operations drive the demand for technologies that minimize direct human exposure to risk. Remote detection capabilities, facilitated by unmanned systems and advanced sensors, enable safer and more efficient mine clearance operations, reducing the danger posed to personnel involved in these hazardous tasks. Cost-effectiveness is another pivotal driver influencing the adoption of new mine detection technologies. Defense agencies and humanitarian organizations alike seek solutions that optimize resources and minimize operational costs associated with demining efforts. Innovative technologies promise to streamline processes, reduce the time required for clearance operations, and decrease the manpower needed, ultimately enhancing the efficiency and affordability of demining initiatives. As advancements in technology continue to evolve, the development of new mine detection technologies remains crucial for addressing humanitarian needs, mitigating evolving threats, enhancing safety for personnel, and achieving cost-effective solutions in global efforts to eradicate the threat of landmines.

Regional Trends in Defense Mine Detection Market:

The focus on mine detection efforts varies significantly across different regions, driven by varying levels of technological advancement, budgetary constraints, and specific operational needs. In developed nations such as the United States and countries in Europe, there is a substantial investment in cutting-edge technologies for mine detection. These include unmanned systems equipped with advanced sensors and artificial intelligence (AI) algorithms. The emphasis is also on developing sophisticated countermeasures to address improvised explosive devices (IEDs), which pose a significant threat in modern conflict scenarios. These nations prioritize technological superiority and innovation to enhance the effectiveness and safety of mine detection operations.

Conversely, developing nations often encounter budget limitations that affect their approach to mine detection. These countries may rely on a combination of traditional methods and more affordable technologies, such as basic metal detectors and simple mechanical clearance tools. Due to financial constraints, there is a pragmatic focus on cost-effective solutions that can be implemented with available resources. Additionally, these nations may prioritize the training of bomb disposal teams to safely handle and dispose of mines, emphasizing human expertise and local capabilities. In post-conflict regions, the primary objective of mine detection efforts is often rapid demining to facilitate reconstruction and resettlement initiatives. Speed and efficiency are critical in these scenarios to remove the immediate threat posed by landmines and unexploded ordnance. Technologies that enable quick deployment and clearance, such as mechanical mine clearance systems, are commonly utilized. These regions prioritize clearing hazardous areas to enable the safe return of displaced populations and support long-term stability and development.

Overall, while developed nations focus on cutting-edge technologies and countermeasures, developing nations navigate financial constraints with pragmatic approaches, and post-conflict regions prioritize rapid clearance for humanitarian and reconstruction purposes. The diversity in approaches reflects the complex challenges and priorities associated with mine detection efforts worldwide.

Key Mine Detection Program:

Under a prospective five-year, $83.9M deal, an L3 Technologies subsidiary will create mine detection platforms for the U.S. Army. The AN/PSS-14 countermine system will also receive support services from L3's Security and Detection Systems division, the Department of Defense announced on Thursday. The firm-fixed-price contract will be in effect through November 20, 2023. Antipersonnel and antitank mines are detected by AN/PSS-14 using a ground radar, metal detector, software, and microprocessor array software. At the time each task order is awarded, Army Contracting Command, the contracting activity, will decide on the finances and work sites.

Promoteq and Minelab Countermine Division are happy to help the Swedish Armed Forces improve their capacity for mine, UXO, and IED detection. The agreement, which is valid until 2024, permits further call-off orders from the Swedish Armed Forces, the Swedish Defence Materiel Administration, and the Swedish Civil Contingencies Agency.

Table of Contents

Mine Detection Market Report Definition

Mine Detection Market Segmentation

By Region

By Platform

By Type

Mine Detection Market Analysis for next 10 Years

The 10-year Mine Detection Market analysis would give a detailed overview of Mine Detection Market growth, changing dynamics, technology adoption overviews and the overall market attractiveness is covered in this chapter.

Market Technologies of Mine Detection Market

This segment covers the top 10 technologies that is expected to impact this market and the possible implications these technologies would have on the overall market.

Global Mine Detection Market Forecast

The 10-year Mine Detection Market forecast of this market is covered in detailed across the segments which are mentioned above.

Regional Mine Detection Market Trends & Forecast

The regional Mine Detection Market trends, drivers, restraints and Challenges of this market, the Political, Economic, Social and Technology aspects are covered in this segment. The market forecast and scenario analysis across regions are also covered in detailed in this segment. The last part of the regional analysis includes profiling of the key companies, supplier landscape and company benchmarking. The current market size is estimated based on the normal scenario.

North America

Drivers, Restraints and Challenges

PEST

Market Forecast & Scenario Analysis

Key Companies

Supplier Tier Landscape

Company Benchmarking

Europe

Middle East

APAC

South America

Country Analysis of Mine Detection Market

This chapter deals with the key defense programs in this market, it also covers the latest news and patents which have been filed in this market. Country level 10 year market forecast and scenario analysis are also covered in this chapter.

US

Defense Programs

Latest News

Patents

Current levels of technology maturation in this market

Market Forecast & Scenario Analysis

Canada

Italy

France

Germany

Netherlands

Belgium

Spain

Sweden

Greece

Australia

South Africa

India

China

Russia

South Korea

Japan

Malaysia

Singapore

Brazil

Opportunity Matrix for Mine Detection Market

The opportunity matrix helps the readers understand the high opportunity segments in this market.

Expert Opinions on Mine Detection Market Report

Hear from our experts their opinion of the possible analysis for this market.

Conclusions

About Aviation and Defense Market Reports

List of Tables

• Table 1: 10 Year Market Outlook, 2024-2034

• Table 2: Drivers, Impact Analysis, North America

• Table 3: Restraints, Impact Analysis, North America

• Table 4: Challenges, Impact Analysis, North America

• Table 5: Drivers, Impact Analysis, Europe

• Table 6: Restraints, Impact Analysis, Europe

• Table 7: Challenges, Impact Analysis, Europe

• Table 8: Drivers, Impact Analysis, Middle East

• Table 9: Restraints, Impact Analysis, Middle East

• Table 10: Challenges, Impact Analysis, Middle East

• Table 11: Drivers, Impact Analysis, APAC

• Table 12: Restraints, Impact Analysis, APAC

• Table 13: Challenges, Impact Analysis, APAC

• Table 14: Drivers, Impact Analysis, South America

• Table 15: Restraints, Impact Analysis, South America

• Table 16: Challenges, Impact Analysis, South America

• Table 17: Scenario Analysis, Scenario 1, By Region, 2024-2034

• Table 18: Scenario Analysis, Scenario 1, By Platform, 2024-2034

• Table 19: Scenario Analysis, Scenario 1, By Type, 2024-2034

• Table 20: Scenario Analysis, Scenario 2, By Region, 2024-2034

• Table 21: Scenario Analysis, Scenario 2, By Platform, 2024-2034

• Table 22: Scenario Analysis, Scenario 2, By Type, 2024-2034

List of Figures

• Figure 1: Global Mine Detection Market Forecast, 2024-2034

• Figure 2: Global Mine Detection Market Forecast, By Region, 2024-2034

• Figure 3: Global Mine Detection Market Forecast, By Platform, 2024-2034

• Figure 4: Global Mine Detection Market Forecast, By Type, 2024-2034

• Figure 5: North America, Mine Detection Market, Market Forecast, 2024-2034

• Figure 6: Europe, Mine Detection Market, Market Forecast, 2024-2034

• Figure 7: Middle East, Mine Detection Market, Market Forecast, 2024-2034

• Figure 8: APAC, Mine Detection Market, Market Forecast, 2024-2034

• Figure 9: South America, Mine Detection Market, Market Forecast, 2024-2034

• Figure 10: United States, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 11: United States, Mine Detection Market, Market Forecast, 2024-2034

• Figure 12: Canada, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 13: Canada, Mine Detection Market, Market Forecast, 2024-2034

• Figure 14: Italy, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 15: Italy, Mine Detection Market, Market Forecast, 2024-2034

• Figure 16: France, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 17: France, Mine Detection Market, Market Forecast, 2024-2034

• Figure 18: Germany, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 19: Germany, Mine Detection Market, Market Forecast, 2024-2034

• Figure 20: Netherlands, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 21: Netherlands, Mine Detection Market, Market Forecast, 2024-2034

• Figure 22: Belgium, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 23: Belgium, Mine Detection Market, Market Forecast, 2024-2034

• Figure 24: Spain, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 25: Spain, Mine Detection Market, Market Forecast, 2024-2034

• Figure 26: Sweden, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 27: Sweden, Mine Detection Market, Market Forecast, 2024-2034

• Figure 28: Brazil, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 29: Brazil, Mine Detection Market, Market Forecast, 2024-2034

• Figure 30: Australia, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 31: Australia, Mine Detection Market, Market Forecast, 2024-2034

• Figure 32: India, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 33: India, Mine Detection Market, Market Forecast, 2024-2034

• Figure 34: China, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 35: China, Mine Detection Market, Market Forecast, 2024-2034

• Figure 36: Saudi Arabia, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 37: Saudi Arabia, Mine Detection Market, Market Forecast, 2024-2034

• Figure 38: South Korea, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 39: South Korea, Mine Detection Market, Market Forecast, 2024-2034

• Figure 40: Japan, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 41: Japan, Mine Detection Market, Market Forecast, 2024-2034

• Figure 42: Malaysia, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 43: Malaysia, Mine Detection Market, Market Forecast, 2024-2034

• Figure 44: Singapore, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 45: Singapore, Mine Detection Market, Market Forecast, 2024-2034

• Figure 46: United Kingdom, Mine Detection Market, Technology Maturation, 2024-2034

• Figure 47: United Kingdom, Mine Detection Market, Market Forecast, 2024-2034

• Figure 48: Opportunity Analysis, Mine Detection Market, By Region (Cumulative Market), 2024-2034

• Figure 49: Opportunity Analysis, Mine Detection Market, By Region (CAGR), 2024-2034

• Figure 50: Opportunity Analysis, Mine Detection Market, By Platform (Cumulative Market), 2024-2034

• Figure 51: Opportunity Analysis, Mine Detection Market, By Platform (CAGR), 2024-2034

• Figure 52: Opportunity Analysis, Mine Detection Market, By Type (Cumulative Market), 2024-2034

• Figure 53: Opportunity Analysis, Mine Detection Market, By Type (CAGR), 2024-2034

• Figure 54: Scenario Analysis, Mine Detection Market, Cumulative Market, 2024-2034

• Figure 55: Scenario Analysis, Mine Detection Market, Global Market, 2024-2034

• Figure 56: Scenario 1, Mine Detection Market, Total Market, 2024-2034

• Figure 57: Scenario 1, Mine Detection Market, By Region, 2024-2034

• Figure 58: Scenario 1, Mine Detection Market, By Platform, 2024-2034

• Figure 59: Scenario 1, Mine Detection Market, By Type, 2024-2034

• Figure 60: Scenario 2, Mine Detection Market, Total Market, 2024-2034

• Figure 61: Scenario 2, Mine Detection Market, By Region, 2024-2034

• Figure 62: Scenario 2, Mine Detection Market, By Platform, 2024-2034

• Figure 63: Scenario 2, Mine Detection Market, By Type, 2024-2034

• Figure 64: Company Benchmark, Mine Detection Market, 2024-2034