Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge Lens

Product Details
Customization: Available
After-sales Service: Return or Replacement
Warranty: 2 Years
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Plant Area
>2000 square meters
Management System Certification
ISO 9001
  • Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge Lens
  • Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge Lens
  • Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge Lens
  • Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge Lens
  • Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge Lens
  • Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge Lens
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Basic Info.

Model NO.
AW558
Usage
Lighting, Medical, Optical, Photography
Type
Convex Lens
Transmittance
90%-95%
Shape
Cylindrical Shaped Lens
Material
Optical Glass
Lenses Color
Clear
Certification
RoHS, ISO9001, CE
Customized
Customized
Focal Length Tolerance
< ± 1%
Thickness Tolerance
Thickness Tolerance ± 0.1
Eccentricity
3′
Designed Wavelength
632.8nm
Scratch/Dig
60/40
Diameter Tolerance
0/-0.1
Clear Aperture
>90%
Coating Coating
Ar or Bbar
Dimensions
Customized
Transport Package
Air Cushion Wrapped Carton Packaging.
Specification
Customized
Trademark
Coating: Ar or Bbar
Origin
Fuzhou Fujian China
HS Code
9001909090
Production Capacity
200000PCS/Month

Product Description

Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge LensOptics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge LensHere provide all kinds of customized optical lens which according to your drawings, sample products or detailed requirements. Any inquiry please feel free to contact us, thanks!
 

  Wedge prisms
Wedge prisms can be used individually to deviate a laser beam a set angle, or two wedge prisms can be used together for beam steering applications. A single wedge prism's ability to deviate the angle of an incident beam is measured in Diopters with 1 diopter deviating the beam 1cm at a 1m working distance.
 
Wedge prisms,Wedge windows
Wedge prisms can be used individually to deviate a laser beam a set angle, or two wedge prisms can be used together for beam steering applications.
A single wedge prism's ability to deviate the angle of an incident beam is measured in Diopters with 1 diopter deviating the beam 1cm at a 1m working distance.
Two wedge prisms can be used as an anamorphic pair for beam shaping (to correct the elliptical shape of diode outputs). Or, a pair of wedge prisms can steer a beam anywhere within a circle described by the full angle 4θ, where θ is the deviation from a single prism. This beam steering is accomplished by rotating the two wedge prisms independently of each other, and is typically used to scan a beam to different locations in imaging applications. Note: Beam deviation is shown in degrees and diopters. One diopter is 1cm of deviation at a distance of 1m from the prism.
Welcome to inquiry
Product Name
Wedge prism
Material
sapphire 
Color
Transparent
Dimension Tolerance
±0.01mm
Thickness Tolerance
±0.01~0.1mm
Angle Tolerance
3''~5''
Surface Quality
60/40,40/20
Coating
AR coating/custom
Used
digital equipment, science and technology, medical equipment and other fields
 

Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge LensOptics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge LensOptics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge LensOptics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge LensSmall aspheric glass lenses can be made by molding, which allows cheap mass production. Due to their low cost and good performance, molded aspheres are commonly used in inexpensive consumer cameras, camera phones, and CD players.They are also commonly used for laser diode collimation, and for coupling light into and out of optical fibers.

Larger aspheres are made by grinding and polishing. Lenses produced by these techniques are used in telescopes, projection TVs, missile guidance systems, and scientific research instruments. They can be made by point-contact contouring to roughly the right form which is then polished to its final shape. In other designs, such as the Schmidt systems, the aspheric corrector plate can be made by using a vacuum to distort an optically parallel plate into a curve which is then polished "flat" on one side. Aspheric surfaces can also be made by polishing with a small tool with a compliant surface that conforms to the optic, although precise control of the surface form and quality is difficult, and the results may change as the tool wears.

Aspherical Lenses
Aspheric Lenses are used to eliminate spherical aberration in a range of applications, including bar code scanners, laser diode collimation, or OEM or R&D integration. Aspheric lenses utilize a single element design which helps minimize the number of lenses found in multi-lens optical assemblies. 
Products are widely used in optical equipment, teaching, industrial lenses, camera, video shooting, automation, medical, measuring and surveying equipment, aviation, astronomy, etc.. So it requires different materials for different work range.Our products cover ultraviolet, visible light and infrared band. 


A sphere is defined by a single radius of curvature. Aspheric Lens have at least one aspherical surface. Optical engineers generally think of aspheric surfaces as aspheric, rotationally symmetric surfaces. The radius of curvature of the aspheric surface varies gradually from the center of the lens to the edge.

   The surface profiles of aspheric lenses are not a portion of a sphere or cylinder. Their curvature radius varies with the central axis. Aspheric lenses have unique advantages over spherical lenses. For example, they can improve optical quality, reduce optical components and design costs. They are widely used in optical instruments, images and optoelectronics industries, such as digital cameras, CD players and high-end microscopic instruments.

Difference between aspheric lenses & spherical lenses:

   Aspheric Lenses: Advantages & Disadvantages In a nutshell, aspheric lenses have the following advantages:
They provide a thinner profile
They are lightweight and comfortable
They could be fit into most frames so you have a wide choice of styles
They have a more natural and pleasing appearance
They don't make your eyes look too big or too small
They provide a better peripheral vision by eliminating distortion



Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge Lens
Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge LensOptics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge Lens
Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge LensOptics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge Lens

Cylindrical lens
 is used to correct astigmatism in the optical system, and, in rangefinders, to produce astigmatism, stretching a point of light into a line. It is usually used in barcode scanners, objective systems and other optical systems.


Feature:
Optics K9 Crystal Sapphire Infrared Quartz Glass Wedge Angle Lens Wedge Lens
Applications:

1 . Correcting Astigmatism

One of the main applications of cylindrical lenses is in ophthalmology, specifically, to correct astigmatic vision.  When a person presents astigmatic vision, it is usually the result of a corneal deformation. An astigmatic cornea will have different focal points at different axes. It is then possible to use a cylindrical lens to change the focal point of one of the axes to overlap the second one.

2 . 
Laser Line Scanning

This is a technique that is used to capture the  shape of a 3D object into a digital copy.  It is particularly useful in manufacturing, prototyping, landscaping, and architecture.  This scanning technique measures the deformation of a straight line created by a cylindrical lens when it is incident into a non-flat surface.  By using cameras and triangulation, it is possible to measure the changes in the shape of our laser line and therefore estimate the shape of the object that we are measuring.  If you would like to learn more about Laser Line Scanning please leave a comment.

3. 
Laser Scanning Microscopy


They are usually used in combination with acousto-optic deflectors, where the focal point of a variable lens (the acousto-optical elements) can change its position laterally without the use of movable parts.  The cylindrical lens corrects the image and helps focus the light spot onto the correct plane for laser scanning microscopy.
 

FAQ?

Q1:Can you send me free samples or Can i have an sample order ?

A: Yes, We accept sample orders, and we're also willing to send you free sample to  test and check its quality . if we don't have the item in stock , then you could place an sample order.

Q2: How many days can i get my package after placing order?

A: If the order needs customized also the quantity is big. it will take around 10-30 wroking days to produce then shipping.

Q3: OEM services available?

A: Sure, please send us your design paper on platform to confirm more details information.

Q4:We have a commercial project,Can you help me offer an optical design solution ?

A:Yes, we have professional experts who are engaged in optical design for more than 25 years , please send us more detail of your project,we will supply our most suitable solutions for you.

Q5: What shipping methods do you have?

A: For small quanities or sample could by express such as: Fedex, UPS, DHL, EMS, etc. Large scale quantity in your demands:by sea/train ,or by air.In your requests.

 

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