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激光等级透镜

激光透镜用于在各种激光应用中聚焦来自激光束的准直光。激光透镜包括一系列透镜类型，包括平凸透镜，激光划线透镜或激光发生器透镜。激光头设计用于根据透镜类型以几种不同的方式聚焦光线，例如聚焦到一个点，一条线或一个环。许多不同的镜头类型可用于各种波长。

产品产地:
中国
航运港口:
中国福州
交付周期:
四周
付款:
银行电汇, 西联付款

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描述

1. 什么是激光透镜？

激光透镜主要用于根据透镜类型以几种不同的方式聚焦光线，例如聚焦到点，线或环。许多不同的透镜类型可用于各种波长。

2. 什么是UNI Optics主要类型的激光透镜？

UNI OPTICS激光透镜包括一系列透镜类型，包括PCX透镜，PCV透镜，双凹透镜，双凸透镜，弯月透镜，消色差透镜，柱面透镜或激光发生器透镜等。

3. 激光透镜的材料是什么？

光学无色玻璃，熔融石英，CaF2，蓝宝石，锗，硅，ZnSe，ZnS等

4. 激光透镜的主要用途是什么？

激光透镜用于在各种激光应用中聚焦来自激光束的准直光。

Laser Lens

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相关产品

激光等级反射镜

我司可提供带有特殊涂层的高损伤阈值的激光反射镜。

高功率激光窗片

1.什么是激光窗片

激光防护窗，也称为激光防护玻璃、防护滤光片或焊接防护窗，主要应用于保护高成本的激光光学元件，以节省资金。

2.激光窗的主要用途是什么？

这些窗口片通常用于激光切割、激光焊接等设备上，用以避免高精度的激光光学器件因加工时材料飞溅而造成的损坏。

3.优恩立激光窗口片的主要优势

高传输率

高损伤阈值

低散射

低吸收

优良的膜层密度

良好的环境稳定性

Laser Windows

常规规格：

尺寸：4-80毫米，圆形或方形

材质：BK7、熔融石英、ZnSe等

表面质量：10/5

面型：lambda/10@632.8nm

平行度：30''

粗糙度：3A

激光等级棱镜

棱镜是透明的光学装置，其折射或反射光。它们在激光技术中具有多种应用。

高精度菱形棱镜

菱形棱镜的应用是在不影响图像方向的情况下控制和重定向光路。它们可以用来取代光学中心线的光束折叠和不同尺寸的立体系统.

融石英

融石英由硅和氧的化学结合形成。熔融石英是一种完美的光学材料，因为它具有良好的紫外和红外透射率，低热膨胀系数。它具有高稳定性，耐大温度偏移，宽温度工作范围和高激光损伤阈值的热冲击。

IPL滤光片

IPL滤光片是IPL（强脉冲光）机器的关键光学元件，可阻挡紫外波，并为激光设备传输400nm至1200nm的有用波，如光子嫩肤脱毛、血管和痤疮治疗、皮肤再生。

30° - 60° - 90°色散棱镜

色散棱镜用于需要将入射光分离成其组成波长的应用中。例如，当白光进入色散棱镜时，它被分成三个部分:红、绿和蓝。色散棱镜是理想的光谱学或激光调谐。

高功率激光反射镜

激光反射镜用于要求苛刻的激光应用中的光束控制。激光线反射镜是专为特定激光类型或波长所设计的光学反射镜

机器视觉带通滤光片

带通滤光片是一种通过一定范围内的频率并拒绝（衰减）该范围之外频率的装置，它用于选择性地传输一部分光谱，同时拒绝所有其他波长。

镀增透膜有色玻璃窗片

有色玻璃改变了光辐射的光谱特性。因此，它们允许在需要改变的情况下进行科学实验和工业应用。您可以将彩色玻璃滤镜组合在一起以更改带通或增加衰减。

红外材料

1. Germanium (Ge)

Germanium (Ge) is the preferred lens and window material for high performance infrared imaging systems in the 8–12 μm wavelength band. Its high refractive index makes Ge ideal for low power imaging systems because of minimum surface curvature. Chromatic aberration is small, often eliminating the need for correction.

Crystallographic properties
Syngony	Cubic
Crystal Form	Poly or Single Crystal
Lattice Constant	5.66
Cleavability	<111>, non-perfect
Molecular Weight	72.6
Physical properties
Density, at 20 °C	5.33
Hardness, Mohs	6.3
Dielectric Constant for 9.37 × 109 Hz at 300 K	16.6
Melting	937
Thermal Conductivity, W/m·K at at 293 K	59
Thermal Expansion, 1/K at 298 K	6.1 × 10-6
Specific Heat Capacity, J/(kgK) at 273-373 K	0.074
Bandgap, eV	0.67
Knoop Hardness, kg/mm2	800
Youngs Modulus, Gpa	102.66
Shear Modulus, GPa	67.04
Bulk Modulus, GPa	77.86
Debye Temperature, K	370
Poissons Ratio	0.278
Elastic Coefficient	C11=129, C12=48.3, C44=67.1
Apparent Elastic Limit	89.6 MPa (13000psi)
Chemical properties
Solubility in water	None
Solubility in acids	Soluble
Molecular Weight	72.59

2. Silicon (Si)

Silicon (Si) is grown by Czochralski pulling techniques (CZ) and contains some oxygen that causes an absorption band at 9 microns.To avoid this, material can be prepared by a Float-Zone (FZ) process. Optical silicon is generally lightly doped (5 to 40 ohm cm) for best transmission above 10 microns, and doping is usually boron (P-type) and phosphorus (N-type). After doping silicon has a further pass band: 30 to 100 microns which is effective only in very high resistivity uncompensated material.

CZ Silicon is commonly used as substrate material for infrared reflectors and windows in the 1.5-8 micron region. The strong absorption band at 9 microns makes it unsuitable for CO2 laser transmission applications, but it is frequently used for laser mirrors because of its high thermal conductivity and low density. Application as window, lens in the 1.5 - 8 um region; Mirror for CO2 laser and spectrometer applications.

Crystallographic properties
Syngony	Cubic
Lattice Constant, A	5.43
Physical properties
Density	2.33g/cm3
Hardness, Mohs	7
Dielectric Constant for 9.37 x 109 Hz	13
Melting point, оС	1414
Thermal Conductivity, W/m·K at 313 K	163
Thermal Expansion, 1/K at 293 K	2.6x10-6
Specific Heat Capacity, J/(kg°C)	712.8
Bandgap, eV	1.1
Knoop Hardness, kg/mm2	1100
Youngs Modulus, Gpa	130.91
Shear Modulus, GPan	79.92
Bulk Modulus, GPa	101.97
Debye Temperature, K	640
Poissons Ratio	0.28
Chemical properties
Solubility in water	None
Molecular Weight	28.09

3、ZnS material:

ZnS MultiSpectral Under intense heat and pressure, defects within the crystalline lattice are virtually eliminated, leaving a water-clear material with minimal scatter and high transmission characteristics from 0.4 to 12 microns. This material is particularly well suited for high-performance common aperture systems that must perform across a broad wavelength spectrum.

Specifications:

Material: ZnS MultiSpectral
Diameter Tolerance: --------------------- +0.0, -0.1mm
Thickness Tolerance: -------------------- ±0.1mm
Clear Aperture: ---------------------------->85%
Parallelism: -----------------------------------3 arc minute
Surface Quality: ----------------------------80-50 scratch and dig
Wavefront Distortion: -------------------- λ /2 per 25mm @633mm
Bevel: -----------------------------------------Protective (<0.2mm x 45° )
Coating: -------------------------------------- Optional （Uncoated, AR Coating, etc.）

4. ZnSe material

ZnSe is a preferred material for lenses, windows, output couplers and beam expanders for its low absorptivity at infrared wavelengths and its visible transmission. For high-power applications, it’s critical that the material bulk absorption and internal defect structure be carefully controlled, that minimum-damage polishing technology be employed, and the highest quality optical thin-film coatings are used. The material absorption is verified by CO2 laser vacuum calorimetry. Our quality assurance department provides testing and specific optics certification on request.

ZnSe is non-hygroscopic and chemically stable, unless treated with strong acids. It’s safe to use in most industrial field, and laboratory environments.