サンプル依頼リスト カート
  • English
  • Korean
  • Traditional Chinese
  • Simplified Chinese
表紙:分散型温度センシング(DTS)の世界市場の評価:ファイバータイプ別、動作原理別、用途別、地域別、機会、予測(2016年~2030年)
市場調査レポート
商品コード
1397906

分散型温度センシング(DTS)の世界市場の評価:ファイバータイプ別、動作原理別、用途別、地域別、機会、予測(2016年~2030年)

Distributed Temperature Sensing Market Assessment, By Fiber Type, By Operating Principle, By Application, By Region, Opportunities and Forecast, 2016-2030F
出版日: | 発行: Market Xcel - Markets and Data | ページ情報: 英文 225 Pages | 納期: 3~5営業日

● お客様のご希望に応じて、既存データの加工や未掲載情報(例:国別セグメント)の追加などの対応が可能です。  詳細はお問い合わせください。

価格
価格表記: USDを日本円(税抜)に換算
本日の銀行送金レート: 1USD=156.76円
分散型温度センシング(DTS)の世界市場の評価:ファイバータイプ別、動作原理別、用途別、地域別、機会、予測(2016年~2030年)
出版日: 2023年12月21日
発行: Market Xcel - Markets and Data
ページ情報: 英文 225 Pages
納期: 3~5営業日
  • 全表示
  • 概要
  • 図表
  • 目次
概要

世界の分散型温度センシング(DTS)の市場規模は、2022年の8億5,710万米ドルから2030年に16億7,058万米ドルに達し、2023年~2030年の予測期間にCAGRで8.7%の成長が見込まれています。市場は、政府規制の強化、データベースアナリティクスを導入する部門の拡大、安全性への関心の高まりによって拡大しています。発電や石油・ガスなどの部門における、資産管理を最適化し環境条件をモニターする要件も、DTSシステム需要の促進要因となっています。

上流の石油・ガス産業では、光ファイバー技術を利用して海上坑井からのリアルタイムデータを遠隔で把握・取得しており、市場の拡大を後押ししています。光ファイバーは坑井の全長にわたって温度を継続的にモニタリングできるため、温度生産ロギングツールサービスはもはや必要ありません。このシステムは、安全で手頃な価格のモニタリングソリューションを提供することで、人的危険、経営費用、生産損失を削減します。光ファイバーは、ダウンホールの可動部品や電子機器を必要とせず、リアルタイムに近い観測を提供することで、企業が生産の安全性を高め、完全性を確認し、コストを削減することを可能にします。DTSソリューションのニーズと市場の拡大は、石油・ガス産業の光ファイバーの展開によって促進されています。

先進の海洋掘削技術が市場の成長を促進

石油・ガス産業は、海洋掘削技術のアップグレードによって革命され、移動式海洋掘削ユニットの効率と精巧さが向上しました。これが分散型温度センシング(DTS)市場の拡大につながっています。しかし、こうした発展は、特にキック検知の部門で新たな困難をもたらしました。キック、すなわち坑井内へのガスや流体の突然の流入は、速やかに検知して制御しなければ重大な危険をもたらす可能性があります。このような場合こそ、キック検知に向けた先進技術が役立つときです。

早期キック検知システムは、ログ、測定、地震データから既に利用可能なデータを使用することにより、掘削とトリップ作業中のガス流入を検知することができます。これにより作業員の安全を確保し、潜在的な噴出を回避することができます。これらのシステムは、地下での測定、リアルタイムのガスモニタリング、地表のセンサーを使用し、脅威を正確かつ誤報の少ないかたちで検知しなければなりません。

分散型温度センシング(DTS)市場に寄与する海洋ライザー上の光ファイバー技術

干渉を最小限に抑えた海上ライザーでの光ファイバーセンシング技術の使用は、分散型温度センシング(DTS)市場の成長に寄与しています。この技術は、高い空間分解能でのリアルタイム計測を可能にし、海洋掘削作業中のガスキック検知を改善します。光ファイバーセンサーを利用することで、オペレーターはライザーとともに温度変化をモニタリングでき、ガス流入の早期発見と噴出リスクの最小化が可能になります。これは安全性を高め、環境を保護し、企業の評判を維持するのに役立ちます。石油・ガス産業における光ファイバー技術の採用は、DTSソリューションの需要を促進し、市場の成長を後押ししています。

分散型温度センシング(DTS)市場に寄与する発電所の温度モニタリング

分散型温度センサー市場は、発電所における効果的な温度モニタリングの必要性や、世界のエネルギー消費の増加など、多くの要因によって拡大しています。発電所の設備が安全かつ効果的に稼動するためには、正確でリアルタイムな温度モニタリングが必要です。発電所では、光ファイバーケーブルを使用し、その全長にわたって連続的な温度データを配信するため、分散型温度検知システムで温度の変動をモニタリングし、存在しうる問題や異常を検出することができます。発電所は、分散型温度センシング(DTS)を採用することで、安全性と生産性を向上させ、機器の故障を最小化し、メンテナンススケジュールを最適化し、運転効率を高めることができます。

当レポートでは、世界の分散型温度センシング(DTS)市場について調査分析し、市場規模と予測、市場力学、主要企業の情勢と見通しなどを提供しています。

目次

第1章 調査手法

第2章 プロジェクトの範囲と定義

第3章 世界の分散型温度センシング(DTS)市場に対するCOVID-19の影響

第4章 ロシア・ウクライナ戦争の影響

第5章 エグゼクティブサマリー

第6章 顧客の声

  • 製品と市場のインテリジェンス
  • ブランド認知の方式
  • 購入決定において考慮される要素
  • プライバシーと安全規制への配慮

第7章 世界の分散型温度センシング(DTS)市場の見通し(2016年~2030年)

  • 市場規模と予測
    • 金額
  • ファイバータイプ別
    • シングルモードファイバー
    • マルチモードファイバー
  • 動作原理別
    • OTDR
    • OFDR
  • 用途別
    • 石油・ガス生産
    • 地熱システム
    • スマートグリッドシステム
    • 火災検知
    • 環境モニタリング
    • プロセスとパイプラインのモニタリング
    • その他
  • 地域別
    • 北米
    • 欧州
    • アジア太平洋
    • 南米
    • 中東・アフリカ
  • 市場シェア:企業別(2022年)

第8章 世界の分散型温度センシング(DTS)市場の見通し:地域別(2016年~2030年)

  • 北米
    • 市場規模と予測
    • ファイバータイプ別
    • 動作原理別
    • 用途別
    • 米国
    • カナダ
    • メキシコ
  • 欧州
    • ドイツ
    • フランス
    • イタリア
    • 英国
    • ロシア
    • オランダ
    • スペイン
    • トルコ
    • ポーランド
  • アジア太平洋
    • インド
    • 中国
    • 日本
    • オーストラリア
    • ベトナム
    • 韓国
    • インドネシア
    • フィリピン
  • 南米
    • ブラジル
    • アルゼンチン
  • 中東・アフリカ
    • サウジアラビア
    • アラブ首長国連邦
    • 南アフリカ

第9章 市場マッピング(2022年)

  • ファイバータイプ別
  • 動作原理別
  • 産業別
  • 地域別

第10章 マクロ環境と産業構造

  • 需給分析
  • 輸出入の分析
  • バリューチェーン分析
  • PESTEL分析
  • ポーターのファイブフォース分析

第11章 市場力学

  • 成長促進要因
  • 成長抑制要因(課題、抑制要因)

第12章 主要企業情勢

  • マーケットリーダー上位5社の競合マトリクス
  • マーケットリーダー上位5社の市場収益分析(2022年)
  • 合併と買収/合弁事業(該当する場合)
  • SWOT分析(市場参入企業5社)
  • 特許分析(該当する場合)

第13章 価格分析

第14章 ケーススタディ

第15章 主要企業の見通し

  • AP Sensing GmbH
  • Bandweaver Technology Limited
  • Banner Engineering Corp.
  • Halliburton Energy Services, Inc.
  • NKT A/S
  • OFS Fitel, LLC
  • Schlumberger Limited
  • Sumitomo Electric Industries, Ltd.
  • Weatherford International Ltd.
  • Yokogawa Electric Corporation

第16章 戦略的推奨事項

第17章 当社について、免責事項

図表

List of Tables

  • Table 1. Pricing Analysis of Products from Key Players
  • Table 2. Competition Matrix of Top 5 Market Leaders
  • Table 3. Mergers & Acquisitions/ Joint Ventures (If Applicable)
  • Table 4. About Us - Regions and Countries Where We Have Executed Client Projects

List of Figures

  • Figure 1. Global Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 2. Global Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 3. Global Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 4. Global Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 5. Global Distributed Temperature Sensing Market Share (%), By Region, 2016-2030F
  • Figure 6. North America Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 7. North America Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 8. North America Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 9. North America Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 10. North America Distributed Temperature Sensing Market Share (%), By Country, 2016-2030F
  • Figure 11. United States Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 12. United States Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 13. United States Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 14. United States Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 15. Canada Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 16. Canada Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 17. Canada Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 18. Canada Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 19. Mexico Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 20. Mexico Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 21. Mexico Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 22. Mexico Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 23. Europe Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 24. Europe Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 25. Europe Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 26. Europe Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 27. Europe Distributed Temperature Sensing Market Share (%), By Country, 2016-2030F
  • Figure 28. Germany Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 29. Germany Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 30. Germany Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 31. Germany Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 32. France Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 33. France Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 34. France Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 35. France Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 36. Italy Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 37. Italy Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 38. Italy Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 39. Italy Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 40. United Kingdom Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 41. United Kingdom Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 42. United Kingdom Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 43. United Kingdom Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 44. Russia Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 45. Russia Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 46. Russia Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 47. Russia Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 48. Netherlands Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 49. Netherlands Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 50. Netherlands Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 51. Netherlands Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 52. Spain Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 53. Spain Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 54. Spain Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 55. Spain Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 56. Turkey Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 57. Turkey Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 58. Turkey Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 59. Turkey Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 60. Poland Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 61. Poland Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 62. Poland Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 63. Poland Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 64. South America Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 65. South America Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 66. South America Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 67. South America Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 68. South America Distributed Temperature Sensing Market Share (%), By Country, 2016-2030F
  • Figure 69. Brazil Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 70. Brazil Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 71. Brazil Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 72. Brazil Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 73. Argentina Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 74. Argentina Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 75. Argentina Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 76. Argentina Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 77. Asia-Pacific Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 78. Asia-Pacific Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 79. Asia-Pacific Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 80. Asia-Pacific Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 81. Asia-Pacific Distributed Temperature Sensing Market Share (%), By End-use Industry, 2016-2030F
  • Figure 82. Asia-Pacific Distributed Temperature Sensing Market Share (%), By Country, 2016-2030F
  • Figure 83. India Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 84. India Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 85. India Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 86. India Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 87. China Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 88. China Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 89. China Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 90. China Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 91. Japan Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 92. Japan Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 93. Japan Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 94. Japan Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 95. Australia Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 96. Australia Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 97. Australia Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 98. Australia Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 99. Vietnam Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 100. Vietnam Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 101. Vietnam Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 102. Vietnam Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 103. South Korea Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 104. South Korea Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 105. South Korea Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 106. South Korea Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 107. Indonesia Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 108. Indonesia Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 109. Indonesia Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 110. Indonesia Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 111. Philippines Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 112. Philippines Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 113. Philippines Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 114. Philippines Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 115. Middle East & Africa Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 116. Middle East & Africa Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 117. Middle East & Africa Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 118. Middle East & Africa Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 119. Middle East & Africa Distributed Temperature Sensing Market Share (%), By Country, 2016-2030F
  • Figure 120. Saudi Arabia Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 121. Saudi Arabia Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 122. Saudi Arabia Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 123. Saudi Arabia Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 124. UAE Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 125. UAE Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 126. UAE Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 127. UAE Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 128. South Africa Distributed Temperature Sensing Market, By Value, In USD Billion, 2016-2030F
  • Figure 129. South Africa Distributed Temperature Sensing Market Share (%), By Fiber Type, 2016-2030F
  • Figure 130. South Africa Distributed Temperature Sensing Market Share (%), By Operating Principle, 2016-2030F
  • Figure 131. South Africa Distributed Temperature Sensing Market Share (%), By Application, 2016-2030F
  • Figure 132. By Fiber Type Map-Market Size (USD Billion) & Growth Rate (%), 2022
  • Figure 133. By Operating Principle Map-Market Size (USD Billion) & Growth Rate (%), 2022
  • Figure 134. By Application Map-Market Size (USD Billion) & Growth Rate (%), 2022
  • Figure 135. By Region Map-Market Size (USD Billion) & Growth Rate (%), 2022
目次
Product Code: MX10755

Global distributed temperature sensing market size was valued at USD 857.1 million in 2022, expected to reach USD 1670.58 million in 2030, with a CAGR of 8.7% for the forecast period between 2023 and 2030. The market expansion of distributed temperature sensing (DTS) systems is fueled by several advantages. These systems are useful for power distribution, cable monitoring, and pipeline monitoring as they use optic sensor cables and the Raman effect to continually detect temperature along the cable's length. The market is expanding due to encouraging government regulations, growing sectors implementing data-based analytics, and increased safety concerns. The requirement to optimize asset management and monitor environmental conditions in sectors such as power production and oil and gas is another factor driving the demand for DTS systems.

The upstream oil and gas industry's use of fiber-optic technology to understand and retrieve real-time data from offshore wells remotely fuels the distributed temperature sensing market's expansion. Temperature production logging tool services are no longer necessary because fiber optics can continuously monitor the wellbore's temperature throughout its depth. The system reduces human danger, operating expenses, and production loss by providing safe, affordable monitoring solutions. Fiber optics allow businesses to boost production safely, verify integrity, and cut costs by offering near real-time observation without needing downhole moving parts or electronics. The need for DTS solutions and the market's expansion are driven by the oil and gas industry's deployment of fiber optics.

For instance, in June 2023, AP Sensing's N45-Series fiber optics Linear Heat Detection (LHD) system offered extended coverage capabilities, continuous monitoring, high sensitivity, and temperature resolution. It revolutionizes fire detection and monitoring by providing precise information on fire location, size, temperature, and spread.

Advanced Offshore Drilling Technology Promote the Market's Growth

The oil and gas industry has undergone a revolution owing to upgraded offshore drilling technology, which has increased the efficiency and sophistication of mobile offshore drilling units. It has led to the expansion of the distributed temperature sensing market. However, these developments bring with them new difficulties, particularly in the area of kick detection. Kicks, or sudden influxes of gas or fluids into the wellbore, may pose significant dangers if not detected and controlled promptly. It is when more advanced techniques for kick detection come into play.

Early kick detection systems can detect gas influxes during drilling and tripping operations by using the already available data from logs, measurements, and seismic data. It ensures worker safety and averts potential blowouts. These systems must use underground measurements, real-time gas monitoring, and surface sensors to detect threats accurately and with few false alarms.

For instance, in April 2022, the collaboration between Schlumberger and Sintela aims to enhance the performance and cost-efficiency of distributed temperature sensing systems by integrating fiber-optic solutions and distributed fiber-optic sensing technology.

Fiber-Optic Technology on Marine Riser Contributing to Distributed Temperature Sensing Market

The use of fiber-optic sensing technology on marine risers with minimal interference contributes to the growth of the distributed temperature sensing market. This technology enables real-time measurements with high spatial resolution, improving gas kick detection during offshore drilling operations. By utilizing fiber-optic sensors, operators can monitor temperature changes along with the riser, enabling early detection of gas influxes and minimizing the risk of blowouts. This enhances safety, protects the environment, and helps maintain a solid company reputation. The adoption of fiber-optic technology in the oil and gas industry drives the demand for DTS solutions, fueling the market's growth.

For example, in August 2021, Schlumberger launched Optiq fiber-optic solutions, offering distributed sensing capabilities for various energy applications. The solutions provide real-time measurements, actionable insights, and improved operational performance while reducing environmental impact.

Temperature Monitoring in Power Generation Plants Contributing to the Distributed Temperature Sensing Market

The market for distributed temperature sensors is expanding due to many factors, including the necessity for effective temperature monitoring in power plants and the world's rising energy consumption. For the equipment in power plants to operate safely and effectively, temperature monitoring that is both accurate and real-time is necessary. Power plants can monitor temperature swings and detect possible problems or anomalies with distributed temperature sensing systems since they use optical fiber cables to deliver continuous temperature data over their whole length. Power plants can improve safety and productivity, minimize equipment failures, optimize maintenance schedules, and increase operational efficiency by employing distributed temperature sensing.

For instance, in May 2023, AP Sensing presented their distributed fiber optic sensing solutions at Intersolar Europe, offering comprehensive monitoring for solar installations to ensure asset protection and safety.

Asia-Pacific Holds a Prominent Share in Global Distributed Temperature Sensing Market

Asia-Pacific dominates the distributed temperature sensing market for many reasons. Temperature monitoring systems are becoming increasingly crucial in various industries, including infrastructure construction, power generation, and the oil and gas. It is because the region is rapidly becoming more industrialized and urbanized. The existence of large economies like China, India, and Japan, which have made large investments in energy and infrastructure projects, further helps the Asia-Pacific market. In addition, DTS systems are being used rapidly in Asia-Pacific for uses such as fire, leak, and pipeline detection. The demand for DTS systems in the area is being driven by an increasing knowledge of their advantages, which include improved safety measures and real-time temperature monitoring. Furthermore, government measures to maintain environmental compliance and minimize accidents and strict safety requirements fuel the DTS market's expansion in Asia-Pacific.

For instance, in January 2023, AP Sensing, in collaboration with TECHFAB Systems, installed Linear Heat Detection (LHD) technology on a 6649m underground railroad line in Kolkata Metro. The LHD systems provide continuous temperature monitoring even during a system outage or cable fault, ensuring maximum safety in the tunnel.

Government Initiatives Boosting the Distributed Temperature Sensing Market Growth

Government initiatives play a crucial role in contributing to the growth of the distributed temperature sensing market. Governments worldwide recognize the importance of temperature monitoring for various industries and implement regulations to ensure safety and efficiency. These initiatives include the development of safety standards, guidelines, and regulations that mandate the use of DTS systems in critical applications such as oil and gas, power generation, and infrastructure. Governments are providing financial incentives and subsidies to encourage the adoption of DTS systems, making them more accessible to industries. These initiatives create a favorable environment for the DTS market, driving its growth and adoption in various sectors.

For instance, in October 2022, AP Sensing's DFOS solutions detected and located sabotage in real-time, enabling immediate countermeasures. Major European rail companies use the technology to help increase efficiency, save costs, and aid investigations.

Impact of COVID-19

The COVID-19 pandemic influenced several businesses, including the distributed temperature sensing market. Due to its use in power, transportation, and oil and gas sectors, the distributed temperature sensing market was growing steadily before the pandemic. On the other hand, the pandemic caused supply chain interruptions, project delays, and decreased infrastructure spending. The distributed temperature sensing market experienced a brief standstill as a result. During a pandemic, the distributed temperature sensing market is anticipated to pick up steam as sectors recuperate and start up again. The market for DTS solutions will be driven by the requirement for precise temperature monitoring across various industries, guaranteeing its rise in the upcoming years.

Impact of Russia-Ukraine War

The distributed temperature sensors market has been impacted by Russia-Ukraine war in several ways. The violence has caused supply chain disruptions, infrastructural development impediments, and an unsettling business climate. It may be difficult for businesses in the distributed temperature sensing market to enter significant marketplaces, find parts, or form alliances in the impacted areas. Geopolitical concerns might result in postponed or abandoned projects, lowering the need for DTS solutions in transportation, electricity generation, and the oil and gas industry. The war's effect on the market for distributed temperature sensors serves as a reminder of how interrelated world events are and how important it is to be resilient in the face of geopolitical threats.

Key Players Landscape and Outlook

The distributed temperature sensing market has leading players such as AP Sensing GmbH, Schlumberger Limited, Sumitomo Electric Industries, Ltd., Yokogawa Electric Corporation, and OFS Fitel, LLC dominating the landscape. These industry leaders offer advanced DTS technologies and solutions for various applications, including oil and gas, power, and industrial sectors. The market outlook for DTS is promising, driven by increasing demand for accurate temperature monitoring in critical infrastructure and industrial processes. The post-pandemic recovery and the need for efficient temperature monitoring systems are expected to further boost the growth of the DTS market in the coming years.

In November 2023, Halliburton and Sekal partnered to provide advanced well-construction automation solutions, combining Halliburton's integrated technology and Sekal's DrillTronics platform. The collaboration aims to achieve fully automated drilling operations and will be supported by remote operations centers.

In November 2023, Halliburton and Oil States Industries formed a strategic collaboration to offer advanced deepwater managed pressure drilling (MPD) solutions, enhancing operational efficiencies and safety for operators and drilling contractors.

Table of Contents

1. Research Methodology

2. Project Scope & Definitions

3. Impact of COVID-19 on Global Distributed Temperature Sensing Market

4. Impact of Russia-Ukraine War

5. Executive Summary

6. Voice of Customer

  • 6.1. Product and Market Intelligence
  • 6.2. Mode of Brand Awareness
  • 6.3. Factors Considered in Purchase Decisions
    • 6.3.1. Features and other value-added service
    • 6.3.2. IT Infrastructure Compatibility
    • 6.3.3. Efficiency of Solutions
    • 6.3.4. After-Sales Support
  • 6.4. Consideration of Privacy & Safety Regulations

7. Global Distributed Temperature Sensing Market Outlook, 2016-2030F

  • 7.1. Market Size & Forecast
    • 7.1.1. By Value
  • 7.2. By Fiber Type
    • 7.2.1. Single-mode Fiber
    • 7.2.2. Multimode Fiber
  • 7.3. By Operating Principle
    • 7.3.1. Optical Time Domain Reflectometry (OTDR)
    • 7.3.2. Optical Frequency Domain Reflectometry (OFDR)
  • 7.4. By Application
    • 7.4.1. Oil and Gas Production
    • 7.4.2. Geothermal System
    • 7.4.3. Smart Grid System
    • 7.4.4. Fire Detection
    • 7.4.5. Environmental Monitoring
    • 7.4.6. Process and Pipeline Monitoring
    • 7.4.7. Other
  • 7.5. By Region
    • 7.5.1. North America
    • 7.5.2. Europe
    • 7.5.3. Asia-Pacific
    • 7.5.4. South America
    • 7.5.5. Middle East and Africa
  • 7.6. By Company Market Share (%), 2022

8. Global Distributed Temperature Sensing Market Outlook, By Region, 2016-2030F

  • 8.1. North America*
    • 8.1.1. Market Size & Forecast
      • 8.1.1.1. By Value
    • 8.1.2. By Fiber Type
      • 8.1.2.1. Single-mode Fiber
      • 8.1.2.2. Multimode Fiber
    • 8.1.3. By Operating Principle
      • 8.1.3.1. Optical Time Domain Reflectometry (OTDR)
      • 8.1.3.2. Optical Frequency Domain Reflectometry (OFDR)
    • 8.1.4. By Application
      • 8.1.4.1. Oil and Gas Production
      • 8.1.4.2. Geothermal System
      • 8.1.4.3. Smart Grid System
      • 8.1.4.4. Fire Detection
      • 8.1.4.5. Environmental Monitoring
      • 8.1.4.6. Process and Pipeline Monitoring
      • 8.1.4.7. Other
    • 8.1.5. United States*
      • 8.1.5.1. Market Size & Forecast
      • 8.1.5.1.1. By Value
      • 8.1.5.2. By Fiber Type
      • 8.1.5.2.1. Single-mode Fiber
      • 8.1.5.2.2. Multimode Fiber
      • 8.1.5.3. By Operating Principle
      • 8.1.5.3.1. Optical Time Domain Reflectometry (OTDR)
      • 8.1.5.3.2. Optical Frequency Domain Reflectometry (OFDR)
      • 8.1.5.4. By Application
      • 8.1.5.4.1. Oil and Gas Production
      • 8.1.5.4.2. Geothermal System
      • 8.1.5.4.3. Smart Grid System
      • 8.1.5.4.4. Fire Detection
      • 8.1.5.4.5. Environmental Monitoring
      • 8.1.5.4.6. Process and Pipeline Monitoring
      • 8.1.5.4.7. Other
    • 8.1.6. Canada
    • 8.1.7. Mexico

All segments will be provided for all regions and countries covered:

  • 8.2. Europe
    • 8.2.1. Germany
    • 8.2.2. France
    • 8.2.3. Italy
    • 8.2.4. United Kingdom
    • 8.2.5. Russia
    • 8.2.6. Netherlands
    • 8.2.7. Spain
    • 8.2.8. Turkey
    • 8.2.9. Poland
  • 8.3. Asia-Pacific
    • 8.3.1. India
    • 8.3.2. China
    • 8.3.3. Japan
    • 8.3.4. Australia
    • 8.3.5. Vietnam
    • 8.3.6. South Korea
    • 8.3.7. Indonesia
    • 8.3.8. Philippines
  • 8.4. South America
    • 8.4.1. Brazil
    • 8.4.2. Argentina
  • 8.5. Middle East & Africa
    • 8.5.1. Saudi Arabia
    • 8.5.2. UAE
    • 8.5.3. South Africa

9. Market Mapping, 2022

  • 9.1. By Fiber Type
  • 9.2. By Operating Principal
  • 9.3. By Industry
  • 9.4. By Region

10. Macro Environment and Industry Structure

  • 10.1. Demand Supply Analysis
  • 10.2. Import Export Analysis
  • 10.3. Value Chain Analysis
  • 10.4. PESTEL Analysis
    • 10.4.1. Political Factors
    • 10.4.2. Economic System
    • 10.4.3. Social Implications
    • 10.4.4. Technological Advancements
    • 10.4.5. Environmental Impacts
    • 10.4.6. Legal Compliances and Regulatory Policies (Statutory Bodies Included)
  • 10.5. Porter's Five Forces Analysis
    • 10.5.1. Supplier Power
    • 10.5.2. Buyer Power
    • 10.5.3. Substitution Threat
    • 10.5.4. Threat from New Entrant
    • 10.5.5. Competitive Rivalry

11. Market Dynamics

  • 11.1. Growth Drivers
  • 11.2. Growth Inhibitors (Challenges and Restraints)

12. Key Players Landscape

  • 12.1. Competition Matrix of Top Five Market Leaders
  • 12.2. Market Revenue Analysis of Top Five Market Leaders (in %, 2022)
  • 12.3. Mergers and Acquisitions/Joint Ventures (If Applicable)
  • 12.4. SWOT Analysis (For Five Market Players)
  • 12.5. Patent Analysis (If Applicable)

13. Pricing Analysis

14. Case Studies

15. Key Players Outlook

  • 15.1. AP Sensing GmbH
    • 15.1.1. Company Details
    • 15.1.2. Key Management Personnel
    • 15.1.3. Products & Services
    • 15.1.4. Financials (As reported)
    • 15.1.5. Key Market Focus & Geographical Presence
    • 15.1.6. Recent Developments
  • 15.2. Bandweaver Technology Limited
  • 15.3. Banner Engineering Corp.
  • 15.4. Halliburton Energy Services, Inc.
  • 15.5. NKT A/S
  • 15.6. OFS Fitel, LLC
  • 15.7. Schlumberger Limited
  • 15.8. Sumitomo Electric Industries, Ltd.
  • 15.9. Weatherford International Ltd.
  • 15.10. Yokogawa Electric Corporation

Companies mentioned above DO NOT hold any order as per market share and can be changed as per information available during research work.

16. Strategic Recommendations

17. About Us & Disclaimer