Ultraviolet lamps can be used for ultraviolet sterilization, excitation fluorescence (fluorescence microscope, banknote detection), trapping and killing insects, and printing. Curing three-dimensional parts of different shapes and sizes, angles and bends, edges and bumps requires light to be projected onto all surfaces and should have sufficient energy. Generally, the lamp is composed of a lamp tube and a reflecting cover. The reflecting cover is used to collect and direct the beam onto the object. The reflecting cover is generally oval or parabolic.
However, due to the divergence of light, after this point, the irradiance decreases rapidly. With the parabolic lampshade, parallel ultraviolet beams can be obtained in a wide range, but the irradiance is low and shadows can be added to three-dimensional objects. Many three-dimensional objects in the industry require curing of “optically thick” coatings, which are coatings with high UV absorption. However, the energy density of ultraviolet light decreases rapidly as it passes through the coating, which is extremely detrimental to curing. To ensure adequate curing, the bottom of the coating also needs to be fully illuminated. And the thick coating contains a lot of pigments and additives, which is not conducive to light transmission. Complete curing is only possible with high-irradiance UV light. When painting flat substrates, an elliptical reflector can be used to focus the highest radiometric area (ie the focal point) on the coating. However, the curing of three-dimensional objects is much more difficult to achieve.
With a compact modular luminaire system, you can track the outline of an object or illuminate certain areas. Correcting the concave portion of the elliptical surface of the microwave power lamp can change the focus of the light, make the focus farther from the lamp surface, and thus make the focusing surface wider. Although this will reduce the peak value of radiance, it can make the intensity of the light more uniform, and you can get enough irradiation far away from the lamp, while maintaining the advantages of concentrated and divergent light, and reducing the appearance of shadows. See Table 1 for comparison. Table 1-Comparison of radiometric peaks (unit: watts / cm2), lamps with 240 watts / cm (600 watts / feet) Distance between lamp and object: reflector type
In view of the above functions of the UV lamp, the parameters of the UV lamp and how to test the UV lamp are particularly important. LISUN LPCE-2(LMS-9000BUV) Sustav za testiranje na UV lampu is used to test the UV lamp (light source) Spectrum, Radiant, Efficiency, CRI, CCT, UVA, UVB, UVC radiant and electric parameters.Spectral Range Wavelength: 200-400nm(UV). The whole system includes the LMS-9000BUV High Precision UV Spectroradiometer,CFS-1.2M Silica Fiber,CASE-UV036 Dark Case for UV Test ,SLS-UV UV Standard Light Source with Calibrate Current (Optional).
Here is photo below shows the test system:
The following is the test report of this product for your reference:
Lisun Instruments Limited osnovala je LISUN GROUP 2003. godine. Sustav kvalitete LISUN strogo je certificiran prema ISO9001: 2015. Kao članovi CIE-a, proizvodi LISUN-a osmišljeni su na temelju CIE, IEC i drugih međunarodnih ili nacionalnih standarda. Svi proizvodi prošli su CE certifikat i ovjerili ih u laboratoriju treće strane.
Naši glavni proizvodi su Goniophotometer, spektroradiometra, Integrirajući sferu, LED ispitni instrumenti, CFL ispitni instrumenti, Fotometar i kolorimetar, EMC i EMI testiranje, Napredni generator, Ispitivanje električne sigurnosti, Komora za ispitivanje okoliša, IP Vodootporno ispitivanje Oprema, Ispitna komora protiv prašine, Komora za vlagu visokih i niskih temperatura, Ispitivanje utikača i sklopki, Naizmjenično i istosmjerno napajanje.