Many friends may think that only traditional industrial fields can use thermal imaging cameras, but now they are also useful in digital, medical industries, and even in our daily lives. For example, the infrared thermal cameras we see in subways, shopping malls, and office buildings are primarily used to measure body temperature. Additionally, in recent years, the market has seen the introduction of mini thermal cameras for phones, which can be attached to smartphones to detect hidden cameras in hotels.
When the temperature of an object in nature is above absolute zero (-273°C), it continuously emits infrared radiation carrying the characteristic information of the object. This infrared radiation also carries the object's characteristic information, resulting from the thermal motion of the molecules within the object. An infrared thermal camera uses an infrared detector and an optical imaging lens to receive the infrared radiation energy of the target being measured. It transfers the energy distribution pattern to the photosensitive element of the infrared detector, thus obtaining an infrared thermographic image that corresponds to the thermal distribution field of the object's surface.
Simply put, a thermal camera converts the invisible infrared energy emitted by an object into a visible thermal image. The different colors on the thermal image represent different temperatures of the object being measured. It has the characteristics of non-contact and high resolution, making it widely used in various industrial measurement and control, healthcare, and security fields.
High Integration
OEM thermal cameras usually have a high level of integration, making them easy to integrate into various equipment or systems, such as drones, robots, and security surveillance. This integration allows OEM thermal cameras to be flexibly applied in different scenarios and needs.
Customization Services
OEM manufacturers typically provide customized services, designing and producing thermal cameras according to the specific needs of customers. This customization ensures that the performance and functions of the thermal cameras fully meet customer expectations and requirements.
Advanced Thermal Imaging Technology
OEM thermal cameras often adopt advanced thermal imaging technologies, such as uncooled focal plane arrays (FPA), to generate high-quality thermal images. These thermal images have clear details and accurate temperature information, helping users better understand and analyze the thermal characteristics of target objects.
High Stability and Reliability
OEM thermal cameras undergo strict testing and quality control during production to ensure high stability and reliability. This stability and reliability enable OEM thermal cameras to work normally in various harsh environmental conditions and provide accurate, reliable thermal imaging data for users.
Cost-Effectiveness
Compared to developing and producing thermal cameras independently, choosing OEM manufacturers can significantly reduce research and production costs. OEM manufacturers typically have large-scale production capabilities and mature supply chain systems, offering more cost-effective thermal imaging products.
Market Competitiveness
By selecting OEM thermal imaging products, customers can launch new competitive products or services more quickly. These new products or services can respond to market demands faster and help customers gain an advantageous position in the intense market competition.
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