Two Way Mirror Glass Technical Specifications

Material Description
Glass Two Way Mirror
 

Substrate
Standard float glass
 

Dimensions
Maximum Size: 95"x130"
Thickness: 1/4" (6mm) only
 

Edgework
Polished edges: flat & pencil polishes available
Beveling up to 1.5" width (removes mirror finish)
 

Durability
Pyrolytic coating can be tempered for 5-10x strength
Can also be insulated and laminated


Applications
Ideal for surveillance, security and administrative applications, correctional institutions, child care, interior design. Two way mirror glass creates a visual barrier between subjects and their observers, performing like an ordinary mirror on one side and a tinted window on the other.


Product Features

HIGH REFLECTIVITY AND LIGHT TRANSMITTANCE allow privacy with crisp, unobtrusive vision into the observed room.

DURABLE, PYROLYTICALLY DEPOSITED COATING offers significantly better scratch and abrasion resistance than vacuum-coated products. A transparent mirror is created by applying a reflective silver-colored coating on 1/4" (6mm) float glass.

POST HEAT-TREATABLE for maximum strength, it can be handled, cut, insulated, laminated and tempered.

EXCELLENT AVAILABILITY for ease of inventory and replenishment. Pyrolytic coating allows for easy handling, fabrication and storage.

IDEAL FOR SURVEILLANCE, security in commercial settings, correctional institutions and child care businesses, hospital observation, worker monitoring and distinctive interior designs.


Design Considerations

ORIENTATION: Install transparent mirror with the reflective surface facing the brightly lit subject-side. Due to improved properties, this glass allows a wall to be completely glazed from floor to ceiling when there is no lighting on the viewing side.

TYPE OF LIGHTING: Subject-side lighting should be bright and evenly distributed over all walls and furnishings, but should not shine directly onto the transparent mirror. Observer-side lighting should be dim with no open light sources. Opaque lamp shades are
recommended for best results.

BACKGROUND COLORS: Subject-side should be bright and light in color and shade to create a bright reflected image. Observer-
side décor should be subdued, non-reflective, dark and uniform.

DISTANCES AND LIGHT LEVELS:
On the observer-side, keep people, objects and light sources at a distance from the
transparent mirror area. An 8:1 light ratio is recommended, with the subject-side brightly lit.

CLEANING: Use standard glass cleaners or mild detergents. Do not use abrasives, opaque liquid cleaners, razor blades or acid-based cleaners.


Vision Area Coating Quality Specifications
The reflective coating shall meet the performance specifications as published. Coating quality will meet ASTM C 1376. A light level ratio of at least 8:1 from bright (subject) side to dark (observer) side shall be maintained for effective operation.

Light Ratios
Two way mirror glass is developed to provide the highest level of performance in the market (requires only an 8:1 light ratio), this glass produces the optimal mix of tint and reflectivity, perfect for enhanced security and undetected
observation.


Two Way Mirror Mirror Guidelines

The use of transparent mirrors (often referred to as one-way or two-way mirrors) for security, unobserved observation, and surveillance involves several unique design considerations. A transparent mirror consists of a silver color, partially reflective, partially transparent coating, usually applied to ¼” (6 mm) thick, grey tinted glass. When viewed from the reflective surface coated side, two way mirror
 Transparent Mirror appears to be a normal mirror, provided the light level on the other side is at least 8 times lower. When viewed from the glass side, with the same lighting as above, the viewer can easily observe what is happening on the other, brighter, side without being distracted by masking or veiling reflections. two way mirror  Transparent Mirror has improved performance properties (it only needs an 8:1 light ratio across the window) compared to the previous two way mirror E.P.® product which required a greater difference in light levels (10 to 1) to achieve satisfactory masking and observation performance.


Optical Ratios; Masking and Observation

All glasses display two images simultaneously: a transmitted image, and a reflected image. This gives a viewer an effect similar to that of a double exposure in a camera. For a transparent mirror application it is generally required to have the glass appear fully reflective from one side, and to be a transparent viewing window, with little distraction from reflections, from the other side. This is achieved by balancing the
glass properties of: Reflection (different from each side for a coated product); Transmission; and relative Light Levels on either side of the glass. When one of the two simultaneously observed images is at least 50 times brighter than the other one, only the bright image is perceived. This is the required property on the “Subject” side of a transparent mirror where a “Subject” seeing their reflected image and that of the room, should not be aware of the very faint image of an “Observer” on the other side. When one of the images is about 5 times brighter than the other, then the bright image is easily observed with little distraction from the fainter image. This is the required property on the “Observer” side of a transparent mirror where the presence of a faint reflected self-image of the observer is not an issue.

Note the following formulas apply to any glass type, in any installation. For example, even a single light of plain clear glass can be seen to act as an effective transparent mirror when the room side lighting is 600 times brighter than the exterior light level. This can be sometimes observed on a dark night in a residence with normal interior lighting and where there are no exterior lights.

Two ratios are defined to illustrate the effectiveness of a transparent mirror: the Masking Ratio measures how well the observer’s image is hidden; the Observation Ratio measures how easily the observer sees the subject.

Definition of terms used in the diagram:
Id = Illumination level on the dark side (observer side)
Ib = Illumination level on the bright side (subject side)
T = Light transmittance through the transparent mirror (equal in either direction)
Rf = Film (coated) side reflectance of the transparent mirror
Rg = Glass side reflectance of the transparent mirror

OBSERVER SIDE
Illumination = Id (Dark)

SUBJECT SIDE
Illumination = Ib (Bright)


The transparent mirror must be installed with the reflective surface (coated side) towards the subject side.
Note also that this side must have the higher level of illumination. The optical ratios are defined as
follows:

Transmission in either direction (T)	Film (coated) Side Reflection (Rf)	Glass Side Reflection (Rg)
0.109	0.681	0.160

 The formulae give the following Masking and Observation ratios for 8:1 light level.

These numbers indicate that with an 8 to 1 light ratio, the reflected image of the subject is 50 times brighter than the transmitted image of the observer and hence it will be nearly impossible for the subject to perceive the image of the observer. The observer will see an image of the subject over 5 times brighter than their own reflection and will not be distracted by the observer’s own faint reflected image.


Application

A successful two-way mirror application involves the careful use of light levels, direct and indirect illumination, and fabric and wall color choices. Light levels:
A minimum 8 to 1 light level is recommended and should be adhered to if possible. Less critical applications may allow lower ratios but the masking and observation properties will be diminished. Pilkington’s new two way mirror  Transparent Mirror has improved properties which allow a wall to be completely glazed, from floor to ceiling. With no illumination on the dark side, the light coming through the glass from the bright side will automatically create a 9 to 1 light ratio. Where an 8 to 1 light ratio cannot be achieved, an additional light of grey glass can be added, to the glass side of the transparent mirror, by either multiple glazing or lamination, to obtain a satisfactory Masking Ratio. This will however, reduce the brightness of the observer’s image of the subject.

Type of Lighting:
Subject side lighting should be bright and evenly distributed over the subject and all walls and furnishings, but should not shine directly onto the transparent mirror. Beyond this, lighting may be consistent with decor and function of the room. The intent is to brighten the reflected image seen by the subject.

Note:
Do not shine subject side lights directly onto the glass because they will only shine through the glass and illuminate the observer and the dark observation room behind the transparent mirror. Observer side lighting should be dim with no open light sources (such as unshaded high intensity desk lamps), or reflections from bright objects such as chrome furniture, visible by the subject in a direct line of sight through the transparent mirror. Opaque lamp shades on the observer side are recommended for best results.

Background Colors:
Subject side decor should be bright and light in color or shade to create a bright reflected image. Observer side decor should be subdued, dark and uniform. Patterns should be minimized in favor of plain materials. Bright reflecting chrome furnishings should not be used on the observer side.

Distances:
Note that if the subjects are very close to the transparent mirror, less than 2 ft. (600 mm), it may be easier for them to see an observer especially if the observer is also very close to their side of the transparent mirror. On the observer side, it is important to keep people, objects and light sources (such as lamps, flashlights or lit cigarettes) as far back as possible from the transparent mirror area.


Safety

Two way mirror glass can be tempered for safety glazing or increased impact resistance. The emissivity of the coating is the same as that of glass. Tempering furnace settings and quench flow rates should be those used for ¼” (6 mm) thick Optifloat™ Grey Glass. Two way mirror glass can be laminated as long as the coated surface is to the outside of the laminated assembly. Note that Laminating will change the optics, and hence the Observation and Masking Ratios. Laminating with the coating against the interlayer would have a “wetting” effect which would reduce the reflectivity and increase the visible transmission.


Maintenance

Two way mirror glass has a pyrolytically deposited hard coating. It has significantly better scratch and abrasion resistance than vacuum coated products. Routine cleaning
should make use of standard glass cleaners or mild detergents. Stubborn deposits may be removed by gentle use of a cerium oxide solution. Do not use abrasives, opaque liquid cleansers, steel wool, razor blades, or Fluorine or acid-based cleaners.


Exterior Glazing

Two way mirror glass is not intended for use in first surface exterior glazing applications (coating to the exterior). In such installations the coating would not become dirtier from natural weathering any faster than ordinary glass, but because of its high reflectivity it would show the dirt faster and so would need more frequent cleaning to preserve a bright, clean appearance.

Two way mirror glass is suitable for exterior glazing when the reflective surface is glazed to the interior. A thermal stress analysis should be performed where the glazing will be exposed to direct sunlight.


Sealant Compatibility

Two way mirror glass has been shown to be compatible with most construction and insulating glass sealants. Contact sealant manufacturers for details.


Sample Specification

All transparent mirrors designated on the drawings shall be two way mirror glass in the sizes noted. The reflective coated glass shall meet the performance specifications as published by the manufacturer. The quality of the coating shall meet the requirements of ASTM C 1376-03 "Standard Specification for Pyrolytic and Vacuum Deposition Coatings on Flat Glass". The transparent mirror shall be installed with the coated surface facing the observed or subject side of the glazing. A light level ratio of at least 8 to 1 from bright (subject) side to dark (observer) side shall be maintained for effective operation.


Disclaimer
The information contained in this bulletin is offered for assistance in the application of two way mirrors, but IT DOES NOT CONSTITUTE A WARRANTY OF
MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE. Actual performance may vary in particular applications.


Contact

twowaymirrors.com
4731 South Ave #13
Toledo OH 43615
United States
Phone: (419) 842-4554
Fax: (419) 754-2327