Stratistics MRC¿¡ µû¸£¸é, ¼¼°è °ø±âÁú ¸ð´ÏÅ͸µ Àåºñ ½ÃÀåÀº 2025³â 63¾ï ´Þ·¯ ±Ô¸ð¿¡ À̸£°í, ¿¹Ãø ±â°£ µ¿¾È CAGR 9.5%·Î ¼ºÀåÇÏ¿© 2032³â¿¡´Â 119¾ï ´Þ·¯¿¡ ´ÞÇÒ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù.
°ø±âÁú ¸ð´ÏÅ͸µ ÀåÄ¡´Â ÀÏ»êÈź¼Ò, ÀÌ»êÈź¼Ò, ÀÌ»êÈÁú¼Ò, ÀÌ»êÈȲ, ¿ÀÁ¸, ÀÔÀÚ»ó ¹°Áú(PM2.5 ¹× PM10)°ú °°Àº °¡½º¸¦ Æ÷ÇÔÇÑ ´ë±â Áß ¿À¿°¹°ÁúÀ» °¨ÁöÇÏ°í ÃøÁ¤ÇÏ´Â µ¥ »ç¿ëµÇ´Â ´Ù¾çÇÑ ÀåÄ¡ ¹× Àåºñ¸¦ ¸»ÇÕ´Ï´Ù. ÀÌ·¯ÇÑ ½Ã½ºÅÛÀº ȯ°æ ±ÔÁ¦ Áؼö¸¦ º¸ÀåÇÏ°í °øÁß º¸°ÇÀ» º¸È£Çϱâ À§ÇØ ÁÖº¯ °ø±âÀÇ ÁúÀ» Æò°¡ÇÏ´Â µ¥ µµ¿òÀÌ µË´Ï´Ù. ½Ç³»¿Ü ´ë±â ¿À¿° ¼öÁØÀ» ¸ð´ÏÅ͸µÇϱâ À§ÇØ Á¤ºÎ ±â°ü, »ê¾÷°è, ¿¬±¸ ±â°ü µî¿¡¼ ³Î¸® »ç¿ëµÇ°í ÀÖ½À´Ï´Ù.
½Ç³» °ø±âÁú(IAQ) ¸ð´ÏÅ͸µ ¼Ö·ç¼Ç È®Àå
ÁÖ°Å¿ë, »ó¾÷¿ë, »ê¾÷¿ë °Ç¹°¿¡¼ °Ç°ÇÑ ½Ç³» ȯ°æ À¯Áö¿¡ ´ëÇÑ °ü½ÉÀÌ ³ô¾ÆÁö¸é¼ IAQ ¸ð´ÏÅ͸µ ½Ã½ºÅÛ¿¡ ´ëÇÑ ¼ö¿ä°¡ Áõ°¡ÇÏ°í ÀÖÀ¸¸ç, VOC, CO2, ¹Ì¸³ÀÚ ¹°Áú°ú °°Àº ½Ç³» ¿À¿°¹°ÁúÀÌ °Ç°¿¡ ¹ÌÄ¡´Â ¿µÇâ¿¡ ´ëÇÑ ÀνÄÀÌ ³ô¾ÆÁö¸é¼ ½ÃÀå ¼ºÀå¿¡ ¿µÇâÀ» ¹ÌÄ¡°í ÀÖ½À´Ï´Ù. ±â¼úÀÇ ¹ßÀüÀ¸·Î Áö¼ÓÀûÀÎ °ø±â ¸ð´ÏÅ͸µÀ» À§ÇÑ º¸´Ù Á¤È®ÇÏ°í ÄÄÆÑÆ®ÇÏ¸ç »ç¿ëÀÚ Ä£ÈÀûÀÎ IAQ Àåºñ°¡ °¡´ÉÇØÁ³½À´Ï´Ù. ¶ÇÇÑ, ½º¸¶Æ® Ȩ Æ®·»µå¿Í °Ç¹° ÀÚµ¿È´Â HVAC ¹× º¸¾È ½Ã½ºÅÛ¿¡ IAQ ¼¾¼ÀÇ ÅëÇÕÀ» ÃËÁøÇÏ°í ÀÖ½À´Ï´Ù.
±³Á¤ ¹× µ¥ÀÌÅÍ Á¤È®µµ ¹®Á¦
°ø±âÁú ¸ð´ÏÅ͸µ ½Ã½ºÅÛÀº Á¾Á¾ ¼¾¼ÀÇ µå¸®ÇÁÆ®¿Í Á¤È®µµ¸¦ À¯ÁöÇϱâ À§ÇÑ ÀæÀº Àç±³Á¤ÀÇ Çʿ伺À̶ó´Â ¹®Á¦¿¡ Á÷¸éÇÏ°Ô µË´Ï´Ù. Àú°¡Çü ¼¾¼´Â °¡°ÝÀÌ Àú·ÅÇÏÁö¸¸, ´Ù¾çÇÑ È¯°æ Á¶°Ç¿¡¼ ÀÏ°ü¼ºÀÌ ¾ø°Å³ª ½Å·ÚÇÒ ¼ö ¾ø´Â µ¥ÀÌÅ͸¦ »ý¼ºÇÒ ¼ö ÀÖ½À´Ï´Ù. ¼¾¼ÀÇ Ãâ·Â°ú ½ÇÁ¦ ¿À¿°¹°Áú ³óµµÀÇ ºÒÀÏÄ¡´Â ±ÔÁ¦³ª Á¶»ç¿¡ »ç¿ëµÇ´Â µ¥ÀÌÅÍÀÇ ½Å·Ú¼ºÀ» ¶³¾î¶ß¸³´Ï´Ù. ÀÌ·¯ÇÑ ÇÑ°è´Â ¿î¿µ ºñ¿ëÀ» Áõ°¡½ÃÅ°°í, ƯÈ÷ ºñ¿ë¿¡ ¹Î°¨ÇÑ ÀÀ¿ë ºÐ¾ß¿¡¼ ±¤¹üÀ§ÇÑ ½ÃÀå ħÅõ¸¦ ÀúÇØÇÒ ¼ö ÀÖ½À´Ï´Ù.
ÈÞ´ë¿ë ¿þ¾î·¯ºí ¸ð´ÏÅÍ¿¡ ´ëÇÑ ¼ö¿ä Áõ°¡
°³ÀÎÀÇ °Ç°°ú ¾ÈÀü¿¡ ´ëÇÑ ¼ÒºñÀÚÀÇ °ü½ÉÀÌ ³ô¾ÆÁö¸é¼ ¼ÒÇü ÈÞ´ë¿ë °ø±âÁú ¸ð´ÏÅÍÀÇ Ã¤ÅÃÀÌ °¡¼Óȵǰí ÀÖ½À´Ï´Ù. ÀÌ·¯ÇÑ ±â±â´Â ¿À¿° ¹°Áú ¼öÁØÀ» ½Ç½Ã°£À¸·Î Á¦°øÇÏ¿© °³ÀÎÀÌ ÁÖº¯ ȯ°æ¿¡ ´ëÇÑ Á¤º¸¿¡ ÀÔ°¢ÇÑ ÆÇ´ÜÀ» ³»¸± ¼ö ÀÖµµ·Ï µµ¿ÍÁÝ´Ï´Ù. µµ½Ã¿¡ °ÅÁÖÇÏ´Â »ç¶÷µé, ƯÈ÷ È£Èí±â ÁúȯÀ» ¾Î°í ÀÖ´Â »ç¶÷µéÀº °³ÀÎ¿ë °ø±â ¼¾¼¸¦ »ç¿ëÇÏ¿© ÀÏ»óÀûÀÎ ³ëÃâÀ» ÃßÀûÇÏ°í ÀÖ½À´Ï´Ù. ¶ÇÇÑ, ¿©ÇàÀÚ, Çлý, À̵¿ÀÌ ÀæÀº Á÷ÀåÀÎµé ¼ö¿ä·Î ÀÎÇØ ÈÞ´ë¿ë ¼Ö·ç¼ÇÀÇ ¼ÒºñÀÚ ±â¹ÝÀÌ È®´ëµÇ°í ÀÖ½À´Ï´Ù.
´ëü ±â¼ú
À§¼º ±â¹Ý °ø±âÁú ¸ð´ÏÅ͸µ Ç÷§ÆûÀÇ ÃâÇöÀº ´ë±Ô¸ð ȯ°æ ¸ð´ÏÅ͸µÀ» À§ÇÑ ±¤¹üÀ§ÇÏ°í ºñ¿ë È¿À²ÀûÀÎ ´ë¾ÈÀ» Á¦°øÇÕ´Ï´Ù. À§¼º µ¥ÀÌÅÍÀÇ Á¢±Ù¼ºÀÌ Çâ»óµÇ°í Á¤È®µµ°¡ ³ô¾ÆÁü¿¡ µû¶ó °íÁ¤½Ä ¶Ç´Â ±¹ÁöÀû ¸ð´ÏÅ͸µ ½ºÅ×À̼ǿ¡ ´ëÇÑ ÀÇÁ¸µµ°¡ ³·¾ÆÁú ¼ö ÀÖ½À´Ï´Ù. ¿ø°Ý °¨Áö µ¥ÀÌÅ͸¦ ȯ°æ Á¤Ã¥ ¼ö¸³¿¡ ÅëÇÕÇÏ¸é ±âÁ¸ Àåºñ¿¡ ´ëÇÑ ÀÇÁ¸µµ¸¦ ³·Ãâ ¼ö ÀÖ½À´Ï´Ù. ÀÌ·¯ÇÑ ±â¼úÀû ¼±È£µµÀÇ º¯È´Â ±âÁ¸ ´ë±â ¸ð´ÏÅ͸µ Àåºñ Á¦Á¶¾÷ü ½ÃÀå Á¡À¯À²¿¡ µµÀüÀÌ µÉ ¼ö ÀÖ½À´Ï´Ù.
Äڷγª19 »çÅ·ΠÀÎÇØ ½Ç³» °ø±âÁúÀÇ Á߿伺, ƯÈ÷ È¥ÀâÇÑ °ø°ø½Ã¼³°ú ÀÇ·á ȯ°æ¿¡¼ÀÇ ½Ç³» °ø±âÁú¿¡ ´ëÇÑ °ü½ÉÀÌ ³ô¾ÆÁ³½À´Ï´Ù. ±×·¯³ª ÀûÀýÇÑ È¯±â¸¦ º¸ÀåÇÏ°í ¹ÙÀÌ·¯½º °¨¿° À§ÇèÀ» ÁÙÀ̱â À§ÇØ ½Ç³» ¸ð´ÏÅ͸µ ½Ã½ºÅÛÀÇ ¼³Ä¡°¡ ±ÞÁõÇß½À´Ï´Ù. Á¦Á¶¾÷üµéÀº »õ·Î¿î ÀÛ¾÷Àå ¹× °Ç¹° ¾ÈÀü Ç¥ÁØ¿¡ ÀûÀÀÇϱâ À§ÇØ IoT ±â¹Ý ¿ø°Ý °ø±â ¸ð´ÏÅ͸µ ¼Ö·ç¼Ç¿¡ ÁßÁ¡À» µÎ¾ú½À´Ï´Ù. ÆÒµ¥¹ÍÀº ¶ÇÇÑ °ø±â Á¤È ½Ã½ºÅÛ¿¡ ´ëÇÑ °ü½ÉÀ» ºÒ·¯ ÀÏÀ¸ÄÑ °£Á¢ÀûÀ¸·Î ¼º´ÉÀ» Æò°¡Çϱâ À§ÇÑ °ø±âÁú ¼¾¼ÀÇ Çʿ伺ÀÌ ³ô¾ÆÁ³½À´Ï´Ù.
¿¹Ãø ±â°£ µ¿¾È ½Ç³» ¸ð´ÏÅÍ ºÐ¾ß°¡ °¡Àå Ŭ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù.
½Ç³» ¸ð´ÏÅ͸µ ºÐ¾ß´Â ¿À¿° ¼öÁØ Áõ°¡¿Í ½Ç³»¿¡¼ º¸³»´Â ½Ã°£ Áõ°¡·Î ÀÎÇØ ¿¹Ãø ±â°£ µ¿¾È °¡Àå Å« ½ÃÀå Á¡À¯À²À» Â÷ÁöÇÒ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù. µµ½ÃÈ°¡ ÁøÇàµÇ°í °Ç¹° ¿Üº®ÀÌ ¾ö°ÝÇØÁü¿¡ µû¶ó Áö¼ÓÀûÀÎ ½Ç³» ¿À¿°¹°Áú ÃßÀûÀÇ Çʿ伺ÀÌ Áõ°¡ÇÏ°í ÀÖ½À´Ï´Ù. ±ÔÁ¦ ±â°ü°ú ÀÛ¾÷Àå ¾ÈÀü ±âÁØÀº ÀÎÁõµÈ ½Ç³» ¸ð´ÏÅ͸µ ¼Ö·ç¼ÇÀÇ Ã¤ÅÃÀ» ÃËÁøÇÏ°í ÀÖÀ¸¸ç, IAQ¿¡ ´ëÇÑ ÀνÄÀÌ ³ô¾ÆÁü¿¡ µû¶ó Á¦Á¶¾÷üµéÀº »ç¿ëÀÚ Ä£ÈÀûÀÌ°í ´Ù±â´ÉÀûÀÎ ½Ç³» ¸ð´ÏÅ͸µ ½Ã½ºÅÛ¿¡ ÃÊÁ¡À» ¸ÂÃß¾ú½À´Ï´Ù.
¿¹Ãø ±â°£ µ¿¾È ¾×Ƽºê/¿¬¼Ó ¸ð´ÏÅ͸µ ºÐ¾ß°¡ °¡Àå ³ôÀº CAGRÀ» ³ªÅ¸³¾ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù.
¿¹Ãø ±â°£ µ¿¾È ´Éµ¿Çü/¿¬¼ÓÇü ¸ð´ÏÅ͸µ ºÐ¾ß´Â »ç¹«½Ç, Çб³, º´¿ø, ±³Åë ¿äÃæÁö¿¡¼ ¼ö¿ä·Î ÀÎÇØ °¡Àå ³ôÀº ¼ºÀå·üÀ» ³ªÅ¸³¾ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù. ½Ç³» °ø±âÁú ¸ð´ÏÅ͸µÀº ºÎ°¡°¡Ä¡ ±â´ÉÀ¸·Î °í±Þ ºÎµ¿»ê ¹× ¼÷¹Ú¾÷ ºÐ¾ß¿¡¼µµ Àα⸦ ²ø°í ÀÖ½À´Ï´Ù. Á¤ºÎ ÁÖµµÀÇ ±×¸°ºôµù À̴ϼÅƼºê¿Í LEED¿Í °°Àº ÀÎÁõÀº IAQ ÅõÀÚ¸¦ ´õ¿í ÃËÁøÇÏ°í ÀÖ½À´Ï´Ù. ¹«¼± ¿¬°á ¹× Ŭ¶ó¿ìµå ±â¹Ý µ¥ÀÌÅÍ ºÐ¼®°ú °°Àº ±â¼úÀû °³¼±À¸·Î ½Ç³» ½Ã½ºÅÛÀº ´õ ½±°Ô »ç¿ëÇÒ ¼ö ÀÖ°í È®ÀåÇÒ ¼ö ÀÖ°Ô µÇ¾ú½À´Ï´Ù.
¿¹Ãø ±â°£ µ¿¾È ¾Æ½Ã¾ÆÅÂÆò¾çÀº ½Ç½Ã°£ µ¥ÀÌÅÍ ¹× µ¿Ç⠺м® ±â´ÉÀ» Á¦°øÇÏ´Â ´É·ÂÀ¸·Î ÀÎÇØ °¡Àå Å« ½ÃÀå Á¡À¯À²À» Â÷ÁöÇÒ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù. ÀÌ·¯ÇÑ ½Ã½ºÅÛÀº ´ë±â ÁúÀÌ ºü¸£°Ô º¯ÈÇÏ´Â »ê¾÷, µµ½Ã, ÀÇ·á ºÐ¾ß¿¡¼ ƯÈ÷ °¡Ä¡°¡ ³ô½À´Ï´Ù. Áö¼ÓÀûÀÎ ½Ã½ºÅÛÀº ȯ°æ ±ÔÁ¤ Áؼö, Á¶±â °æº¸ ½Ã½ºÅÛ, ÀÛ¾÷ ¾ÈÀüÀ» À§ÇØ Ã¤Åõǰí ÀÖÀ¸¸ç, AI ±â¹Ý ºÐ¼® µµ±¸¿ÍÀÇ ÅëÇÕÀº ±× ±â´É¼º°ú ½ÃÀå ¸Å·ÂÀ» ´õ¿í ³ô¿©ÁÖ°í ÀÖ½À´Ï´Ù.
¿¹Ãø ±â°£ µ¿¾È ºÏ¹Ì´Â À¯ÇØ °¡½º ¹× ¹Ì¸³ÀÚ¿¡ ´ëÇÑ Á÷¾÷Àû ³ëÃâ¿¡ ´ëÇÑ ¿ì·Á°¡ Áõ°¡ÇÔ¿¡ µû¶ó °¡Àå ³ôÀº CAGRÀ» º¸ÀÏ °ÍÀ¸·Î ¿¹ÃøµË´Ï´Ù. ¿¬¼Ó ÃøÁ¤ Àåºñ´Â ¼öµ¿ÀûÀÎ ´ëü Àåºñ¿¡ ºñÇØ º¸´Ù »ó¼¼ÇÏ°í Àå±âÀûÀÎ ÅëÂû·ÂÀ» Á¦°øÇÕ´Ï´Ù. Á¤ºÎ ¹× ȯ°æ ±â°üÀº ¶ÇÇÑ ´õ ³ªÀº ¿À¿° Á¦¾î¸¦ À§ÇØ »ó¼³ ´ë±â ¸ð´ÏÅ͸µ ³×Æ®¿öÅ© ¼³Ä¡¿¡ ÀÚ±ÝÀ» Áö¿øÇÏ°í ÀÖ½À´Ï´Ù. ÀÌ·¯ÇÑ ½Ã½ºÅÛÀÌ Á¦°øÇÏ´Â Çâ»óµÈ ½Å·Ú¼º°ú µ¥ÀÌÅÍ Åõ¸í¼ºÀº ¼ºÀåÀ» °¡´ÉÇÏ°Ô ÇÏ´Â Áß¿äÇÑ ¿ä¼ÒÀÔ´Ï´Ù.
According to Stratistics MRC, the Global Air Quality Monitoring Equipment Market is accounted for $6.3 billion in 2025 and is expected to reach $11.9 billion by 2032 growing at a CAGR of 9.5% during the forecast period. Air quality monitoring equipment refers to a range of devices and instruments used to detect and measure pollutants in the air, including gases like carbon monoxide, nitrogen dioxide, sulfur dioxide, ozone, and particulate matter (PM2.5 and PM10). These systems help assess ambient air quality, ensuring compliance with environmental regulations and safeguarding public health. They are widely used by government agencies, industries, and research institutions to monitor indoor and outdoor air pollution levels.
Expansion of indoor air quality (IAQ) monitoring solutions
The growing focus on maintaining healthy indoor environments in residential, commercial, and industrial buildings is driving demand for IAQ monitoring systems. Increased awareness of the health impacts of indoor pollutants such as VOCs, CO2, and particulate matter is influencing market growth. Technological advancements have enabled more accurate, compact, and user-friendly IAQ devices for continuous air monitoring. Additionally, smart home trends and building automation are promoting integration of IAQ sensors into HVAC and security systems.
Calibration and data accuracy issues
Air quality monitoring systems often face challenges related to sensor drift and the need for frequent recalibration to maintain accuracy. Low-cost sensors, while affordable, can produce inconsistent or unreliable data under varying environmental conditions. Discrepancies between sensor output and actual pollutant concentration reduce trust in data for regulatory and research use. These limitations increase the operational costs and hinder broader market penetration, especially in cost-sensitive applications.
Rising demand for portable and wearable monitors
The increasing consumer interest in personal health and safety has accelerated the adoption of compact, portable air quality monitors. These devices provide real-time pollutant levels, empowering individuals to make informed decisions regarding their surroundings. Urban dwellers, especially those with respiratory conditions, are turning to personal air sensors for daily exposure tracking. Furthermore, demand from travelers, students, and mobile workers is expanding the consumer base for these portable solutions.
Substitute technologies
The emergence of satellite-based air quality monitoring platforms offers a broad and cost-efficient alternative for large-scale environmental surveillance. As satellite data becomes more accessible and accurate, reliance on fixed or localized monitoring stations may decline. Integration of remote sensing data into environmental policymaking may reduce the dependency on traditional equipment. This shift in technological preference can challenge the market share of conventional air monitoring device manufacturers.
The COVID-19 pandemic brought increased attention to the importance of indoor air quality, especially in crowded public and healthcare settings. However, there was a surge in installations of indoor monitoring systems to ensure proper ventilation and reduce virus transmission risk. Manufacturers shifted focus toward remote, IoT-enabled air monitoring solutions to adapt to new workplace and building safety standards. The pandemic also sparked interest in air purification systems, indirectly boosting the need for air quality sensors to evaluate performance.
The indoor monitors segment is expected to be the largest during the forecast period
The indoor monitors segment is expected to account for the largest market share during the forecast period due to rising pollution levels and increased time spent indoors. Growing urbanization and tighter building envelopes have heightened the need for continuous indoor pollutant tracking. Regulatory bodies and workplace safety standards are pushing adoption of certified indoor monitoring solutions. As IAQ awareness grows, manufacturers are focusing on user-friendly, multifunctional indoor monitoring systems.
The active/continuous monitoring segment is expected to have the highest CAGR during the forecast period
Over the forecast period, the active/continuous monitoring segment is predicted to witness the highest growth rate due to demand across offices, schools, hospitals, and transport hubs. Indoor air quality monitoring is also gaining traction in luxury real estate and hospitality sectors as a value-added feature. Government-led green building initiatives and certifications such as LEED further encourage IAQ investments. Technological improvements, including wireless connectivity and cloud-based data analysis, are making indoor systems more accessible and scalable.
During the forecast period, the Asia Pacific region is expected to hold the largest market shareue to their ability to provide real-time data and trend analysis. These systems are particularly valuable for industrial, urban, and healthcare applications where air quality can change rapidly. Continuous systems are being adopted for environmental compliance, early warning systems, and operational safety. Their integration with AI-driven analytics tools is further enhancing their functionality and market attractiveness.
Over the forecast period, the North America region is anticipated to exhibit the highest CAGR due to growing concerns over occupational exposure to hazardous gases and particulates. Continuous devices provide greater granularity and long-term insights compared to passive alternatives. Governments and environmental agencies are also funding the installation of permanent air monitoring networks for better pollution control. Enhanced reliability and data transparency offered by these systems are key growth enablers.
Key players in the market
Some of the key players in Air Quality Monitoring Equipment Market include 3M, General Electric, HORIBA Scientific, Aeroqual, Emerson Electric Co., Siemens, Merck KGaA, Teledyne Technologies Incorporated, Testo SE & Co. KGaA, Thermo Fisher Scientific Inc., KUNAK TECHNOLOGIES SL, Airthings, Honeywell International Inc., CODEL International LTD and Modcon Systems Ltd.
In March 2025, Thermo Fisher Scientific Inc. launched the AeroTrace 5000, a next-generation air quality monitoring system designed for real-time detection of ultrafine particulate matter (PM1) and volatile organic compounds (VOCs). The system delivers results in under 5 minutes and integrates IoT connectivity for seamless data reporting, targeting urban municipalities and industrial sectors in North America and Europe.
In February 2025, Honeywell International Inc. introduced the AirSense Pro, a compact, portable air quality monitor with advanced AI-driven analytics. Capable of measuring CO2, NO2, and PM2.5 levels with 10% higher accuracy than previous models, it's designed for residential and commercial applications, with a focus on smart city initiatives in Asia-Pacific.
In January 2025, HORIBA Scientific unveiled the EcoMonitor AQ-200, a modular air quality monitoring solution optimized for continuous ambient air analysis. Featuring a 20% reduction in calibration time and enhanced sensor durability, it caters to environmental agencies and research institutes, particularly in Japan and the European Union.