Glass today, has become an integral part of modern day architecture. Using glass in a building instantly adds a touch of modernity to the living space. It not only gives the designers the choice of finish & a manifestation to their design aspirations, but also a wonderful chance to participate with the outside world. Glass, in fact, is the only building material which can not only give see-through properties but also the desired structural strength to be used in facades.

Glass ensures that the building gets ample natural light – making interiors look brighter and livelier reducing the need for artificial lighting and saving energy, or in other words, reducing the electricity bill. Ample light inside the home makes spaces look more spacious and roomy, an important factor to consider given today‘s shrinking living spaces in urban areas.

These Energy Efficient Glasses provide the benefit of reducing the heat gain in buildings due to its excellent energy saving properties without compromising on the natural light coming inside the building or the brilliant aesthetics that add value to the façade. And in winter, they ensure solar gain. So that no matter what the season, people inside stay comfortable at all times. Using energy-efficient glass also helps in ensuring that the interiors – and the occupants of the home – feel more comfortable. Ideal for solar and thermal insulating parameters, these glasses combine aesthetics with environmental sensibility and conform to all International and National Green Standards, making it the natural choice as a Green Building solution. Performance parameters of glasses like Visual Light Transmission, Solar Factor, U-Value and Internal Reflection make buildings more efficient and ecologically viable.

Energy efficient glasses, when used properly can reduce the total energy consumption by anywhere between 8~10% of the total energy consumed & hence the accrued benefits of using these glasses keep growing over the years. Furthermore, it is not just the recurring savings but also the reduction in the capex because of the lower energy loads required for conditioning the building. Typically the heat gained/lost through Glazing in a normal building in India is anywhere between 40~50% and using the right type of glass can bring down the energy consumption by 30~40% (only Glazing). The incremental cost for the high performance glazing can be recovered in a time span of 3~4 years.

Illustration (Cost Benefit Analysis): 


  • The above mentioned rates are assumptions used for energy and payback calculations only.
  • However the market rate will differ and include taxes and wastage charges.
  • HP refers to High Performance Glass

Post the detailed Building Analysis on Energy Performance and comparing with a base case, it is very clear  that HP 4is performing best with a payback period of 7.4 months and 67 % energy saving.

Until a few years back energy efficiency was neither a practice nor a fad in the country. However with the launch of the Energy Conservation Building Codes (ECBC), concurrently accompanied by the gain in popularity of the Green Building practices, users alike, builders & architects started looking at ways to reduce energy consumption in buildings.

So no matter which perspective you look at it from – aesthetics, modernity, elegance, adding a sense of space to interiors and of course, monetary savings – making homes energy efficient with glass makes perfect sense.

Source Asahi India


Smart Glass Market Growth will be driven by rising Global Energy Consumptions

By 2020 Global demand for High performance glass is set to rise as with the current trend & scenario with rising Environmental Issues in the Country. On one hand we want to build smart cities but on other hand existing Metros have very poor Air Quality.

Optimal Energy Savings is driving the smart glass market in the Commercial sector with few developers realizing the need of the country to save energy consumption for the occupied premises & save the Country’s Environment.

Despite high Energy cost the energy supply demand Gap is increasing. Switching to smart Glass for Government Building, Commercial Complex, and Residential Buildings, Schools, Hotels & even Shop fronts will optimize the consumptions.

Today’s smart glass helps a developer to achive more Light in & block the heat to largest extent.

Benefits of Smart Glass

  • Less Heat coming inside thereby increasing efficiency of the Building.
  • Saves Money on day to day Electricity consumptions.
  • More Light Entering helping in daylight planning.
  • Very Less Payback period against the initial capital investments.
  • Blocks UV rays thereby not fading the interiors like Curtains, Paints & furniture of the occupants.
  • Increases efficiency of the Façade on long term basis.




  Current Options in Efficient Glass Category

The current range available in the country for Energy Efficient Glasses from Manufacturers like Asahi are Brook Series with Blue, green & clear option with better Light transmittance & low Solar factors.

Saint Goban provides Coolite Series, Evo series, Nano Series & various other combinations of advanced products.

Pilkington offers glasses which are imported from its various manufacturing locations across North America, Europe, Middle East, South America. Pilkington Eclipse Advantage, Solar E & Solar E plus are effective in Single & double forms.

Currently Guardian being 4th Aggressive player offering SunGuard Solar Series, High performance series & high selective series from their respective plants across the globe.

With this various options available which can be easily Tempered, Double Glazed, laminated from processors across India.



One has to know that using a Energy Efficient Glass on their project, One not only reduced the consumption of Electricity but also is part of global Environment Policy as an Individual participant to save Earth.


For any further assistance mail us at

Whatsapp on 09324789080 your Requirement we can help you build a efficient façade.

 Source – AIS, Saint gobain , Pilkington & Guardian Catalogue.

Toughened or tempered glass is a type of safety glass processed by controlled thermal or chemical treatments to increase its strength compared with normal glass. Tempering puts the outer surfaces into compression and the inner surfaces into tension. Such stresses cause the glass, when broken; to crumble into small granular chunks instead of splintering into jagged shards as plate glass (i.e. annealed glass) creates. The granular chunks are less likely to cause injury.

Properties: Toughened glass is physically and thermally stronger than regular glass. The greater contraction of the inner layer during manufacturing induces compressive stresses in the surface of the glass balanced by tensile stresses in the body of the glass.

In such glasses, the surface compressive stress exceed 100 megapascals (15,000 psi), for as greater the surface stress, the smaller the glass particles will be when broken.

It is this compressive stress that gives the toughened glass increased strength. This is because any surface flaws tend to be pressed closed by the retained compressive forces, while the core layer remains relatively free of the defects which could cause a crack to begin.

As per the nature of the glass, any cutting or grinding must be done prior to tempering because Cutting, grinding, and sharp impacts after tempering will cause the glass to fracture.

Now here we will be discussing the issues related to optical defect:

roller waves

The surface of tempered glass does exhibit distortion or surface waves caused by contact with flattening rollers. This Optical issue of waviness is a significant problem in manufacturing high-end façade projects.

The strain pattern resulting from tempering can be observed with polarized light or by using a pair of polarizing sun glasses.

There are three main reasons causing the roller wave effect:

High exit temperature of glass from furnace:

While tempering the glass, heat treatment requires uniform heating of the glass to 621 +/- 3 deg C, while holding the glass in a flat state.

The glass softens and is prone to cause internal bending as it approaches the critical temperature closer to 650 ˚C. So hotter the glass that exits the furnace, the worse is the quality.

The colder the glass, the better is the quality. However, the risk of breakage increases. Sometimes, overheating is needed to compensate for bad edge work or hole finishing.

Corrections: Although the furnace is designed to control thermodynamic conditions, variations are difficult to eliminate.

So for perfection precisely enough heat is added to relieve stress without making the glass too soft. But in reality, such as glass type, glass thickness, coatings, furnace temperature, atmospheric temperature, ambient humidity etc. define the final outcome.

Key rule is:

“Decrease the furnace temperature and increase the heating time.”

Any roll eccentricity imparts deformation to the glass.

The leading and trailing edges of each lite form a cantilever as the glass leaves a roll. The glass sags under this load. Overheating causes sag between the rollers. Uneven heating and inconsistent loading exacerbate the problems due to hot spots in the furnace.

Large roller pitch:

There are differences in roller settings in tempering furnaces. When the distance between consecutive rollers is longer, the glass travels a longer distance unsupported. Longer roller pitch results in a larger peak-to-valley roller wave value, thus creating a visually more noticeable distortion.

Roller shape accuracy along the whole roller length also plays an important role in roller wave quality.


This problem is mechanical, related to the roller pitch of a furnace and should be taken care while opting for new tempering line. Later it is extremely challenging to change it.

For better quality results the total indicated run out (TIR) of rollers is checked and measured and high-quality rollers should be used in the process. They have a direct impact on the quality.

Better accuracy with high-quality rollers, improves the overall flatness of the roller bed and thus prevents roller “vibrations” and level differences, which can greatly affect the overall roller wave values.

The oscillation speed is too low.

Lower oscillation movement in the end of the heating cycle increases the time that the glass is without roller support, and thus causes optical distortion. A faster oscillation speed has the better result to improve roller wave effects.


Since glass as a material changes during the heating, it’s good to have dynamic control of the oscillation speed. New control systems can control the conveying process more accurately and at different speeds. Such system makes it possible to set different oscillation speeds for the various heating cycle stages to improve roller wave defect.

: Pay attention to pre-processing quality :

Accurate cutting, grinding and drilling processes will allow colder glasses to exit the furnace and improve the roller wave quality. It is to be assured that pre-processing is not a bottleneck for the tempered glass quality and yield.


The need for higher quality, distortion-free, heat-treated glass is creating both challenges and opportunities for the glass industry. While furnace technologies are advancing to meet more stringent requirements, improved measurement of roll distortion is required for process control of the furnace.

A new machine-vision technology has been developed and is now available to accurately measure roll distortion. The LiteSentry Roll Wave Distortion Measurement system, measures the peak-to-valley optical distortion on-line as glass exits the furnace. This system provides the tool necessary to improve and maintain the quality of heat-treated glass, thereby opening new markets for tempered and laminated glass.

(The float glass process can be used to provide low-distortion sheets with very flat and parallel surfaces.)


Quality Issues & Solutions in a Laminated Glass

Day by day usage of Laminated Glass is increasing in the façade & Railing systems.Laminated glass is glass which is manufactured using multiple panes of glass and a flexible interlayer which is bonded in between the panes of glass. The interlayer could be

PVB, Sentry layer, Saflex DG& many other interlayer’s’.

Multiple panes panes mostly are Heat Strengthened or Tempered needs a high level of  accuracy during processing in order to deliver a Perfect product.


                    Quality Problems in a Laminated Glass

Excessive Moisture & Water Ingression

  • PVB is hygroscopic & absorbs moisture. If the panes are exposed to excessive moisture adjacent to the edge of the interlayer, the bond to the glass is reduced and Delamination can occur.
  • This is often poor detailing allowing moisture to collect or poor installation where measures intended to reduce moisture build up negated.

Compatibility of Edge Silicone Application

  • Very few silicone sealants have compatibility with PVB, Incorrect seals can lead to edges delaminating.
  • Vendors needs to address this issue as major silicone failures happen at edges gradually after 2nd or 3rd year of Installation.
  • If you are using laminated glass in Spider Glazing especially in fins where Fin acts as Structural members one has to ensure right thickness of PVB to be used & even tightening of the bolts also have to be done rightly else too much pressure on glass can lead to lamination failure.

 Poor Quality of tempered Glass

  • Toughened or heat strengthened) glass exhibits distortion within the glass caused by the rollers during the manufacturing process. This distortion is commonly known as roller wave or edge dip. If the distortion within the glass plies is not ‘matched’ peak to peak and trough to trough then there can be stresses applied to the interlayer, particularly at the edges. Delamination could occur if the interlayer is unable to withstand the stresses applied by the glass plies.


  Where Delamination Occurs

  •  Occurs usually at the edge of glass.
  • Bolted Position of the Glass Fin in event of tightening issues.
  • Exposed edge Applications in railings.
  • Failure in compatibility of Structural & weather Silicones.
  • Mismatch of 2 glasses due to poor processing due to roller distortion


                     Solutions to get the Right Laminated Glass


  •  Technical acceptable limits of roller wave distortion have to be specified to the vendor so that during pre process bonding is good.
  • Force of bonding should be uniformly applied equally over the glass & QC must check it continuously.
  • No tightening of at one particular locations before going into autoclave else those areas will not bond properly.

 Quality Control during processing

  •  Glass pane alignment plays important role.
  • Interlayer storage must be rightly done with correct moisture & humidity conditions.
  • Right water Ph values needs to be maintained during cleaning of the glass prior to lamination.
  • Pre autoclave process needs to be followed in accordance with Interlayer manufacturer’s guidelines.

 Quality Aspects during Installation

  •  Don’t apply any weather silicone or structural silicone. Get written approval from the interlayer vendors.
  • Ensure Panels are rightly ventilated & no particular area has moisture or water ingression.
  • Ensure no compressions beyond acceptable limits in Application processes.



  •  Always discuss laminated glass applications with Interlayer manufacturers & Glass processors.
  • Randomly check production quality audits at factory.
  • Insist on Product warranty in writing from Interlayer & Processor based on your applications, so that in event of failures they too are equally responsible.
  • Get a complete application guide from the Interlayer manufacturers or visit their websites before concluding your sale.

Spontaneous Breakages in Tempered Glass

About the Author:

Sharanjit Singh

Founder Chairman

GSC Glass Ltd

Sharanjit Singh is the Founder Chairman of GSC Glass Ltd., a technology driven company, leader and pioneer in glass processing. GSC has many firsts to its credit including the first architectural tempering, laminating, ceramic fritting, hardware, processing machines etc. It is also the first company to design and supply glass with design, systems and solutions for many European airports and rail stations, where quality and safety requirements are very high. He is an accomplished engineer and a third generation glass-man and regarded as one of the most knowledgeable person on glass in India. He has conducted many seminars and training workshops and has also written and compiled ‘Architectural glass guide’ for Federation of Safety Glass (FOSG), which is a comprehensive and complete book on the subject.


Spontaneous breakages: Most of us have come across a situation where a tempered (toughened) glass has broken without a provocation or any apparent reason. Non-tempered glasses do also break and sometimes, without any visible reason. Any non-tempered glass will normally break as a single crack or multiple cracks, which develop or propagate from origin either spontaneously or gently. Spontaneous breakage in tempered glass is however much more dramatic, as the whole pane of tempered glass breaks with a loud noise and high visibility as it breaks into thousands of small pieces.

Most of the times, a tempered glass will disintegrate and fall out of the fixing, but the cause of breakage can be assessed with reasonable fairness, if it stays in fixing. Breakages due to impact or wind loading are less likely to stay in frame. A tempered laminated glass will almost always stay in place after breakage and makes it easier to identify and analyze the cause. By simply looking at the point of origin of breakage and its pattern, the cause can be identified in most cases.


Causes of breakages: There can be several causes or reasons for spontaneous breakages in tempered glass like impact load, poor glazing, glass to glass contact, glass to metal contact, very hard setting blocks etc. Any of these can result in creating a concentrated point load on the edge or corner of the glass. In such cases, the point of origin of breakage will generally give a clue.

Improper or uneven tempering can also cause a post installation breakage. This will happen only if the stress differences on the same pane of glass are very large and this can be easily identified from such breakage. The breakage pattern will be highly non-uniform with some large islands of non-fragmented glass, enclosed or surrounded by much smaller fragments. (See Image-1)

Image 1: Breakage due to uneven tempering


Breakages due to Nickel Sulfide: While the causes mentioned in previous section, can be attributed to errors in designing, manufacturing or glazing, there is one cause, which cannot be attributed to any of these and cannot be fully eliminated or fully addressed. It is the breakage caused by Nickel sulfide inclusions. Looking at the broken glass will give an initial impression of glass being hit by a sharp object and the point of origin of breakage will be obvious. On closer examination, at the origin, there will be at least two fragments in the shape of wings of the butterfly. (see image-2) This is often called ‘butterfly pattern’ or ‘double D Pattern’. The origin of breakage is generally away from the edge of glass.


Image 2: The origin of breakage, caused by Nickel sulfide inclusions


The phenomenon was first acknowledged in 1940 but the first documentation happened in 1961. Since then, there has been extensive research by many companies, institutes and scientists to identify, prevent and resolve the issue. Standards have evolved and many extensive publications have been made on the subject. There have been a number of case studies on manufacturing processes and on glazed building as well. The entire community of designers, specifiers, manufacturers, fabricators and glaziers etc are now broadly aware of the problem. The industry has come a long way and has made rapid strides in addressing the problem, but the problem still remains to be fully resolved.

To understand this phenomenon of spontaneous breakages due to nickel sulfide, we need to briefly understand the manufacturing process of float glass and its heat treatment namely tempering, heat strengthening and heat soak testing.


Annealed Glass: Float Glass or annealed flat glass is the most basic form of glass. This is made of five basic ingredients namely silica sand, soda ash, dolomite, limestone, and salt cake. These are heated in huge furnaces to 1400-1500 degrees C, and then made to float out on a pool of molten tin in controlled atmosphere. The large sheets are pulled onto a conveyor, and taken through an annealing tunnel called lehr, where it is cooled very slowly for an evenly controlled heat dissipation rate. If it is allowed to cool rapidly or in uneven manner, it will result into cracking while manufacturing or in service due to uneven stresses. The cooled glass is cut into large sheets, and then sent to other processing locations for finishing, such as cutting to size, strengthening, or insulating. A large glass furnace can easily produce from 500 to 800 tons of glass each day.


Heat Strengthened and Tempered Glass: Heat Strengthened and tempered glass are created through the same process. At a processing plant,large sheets of annealed glass are cut to the appropriate sizes and shapes. The edges are ground and any holes or cutouts required in the panels are created. It is then heated in a furnace to a temperature of 600-700 degrees C. This temperature is held until the glass softens slightly, at which time it is rapidly cooled through the use of air jets, a process called quenching. Quenching reduces the temperature of the surfaces of the glass quickly and significantly, but due to the low thermal conductivity of glass, the core of the panel remains at a much higher temperature. As this core cools, it induces compression in the already-cooled outer layers, and a balancing tension force is formed in the core of the panel. (See diagrams –3a and 3b)

The difference between heat-strengthened and tempered glass is the speed at which they are cooled, which results in different surface compression and therefore different overall glass strengths and properties, which are compared as under:


Diagram 3a: Process of Tempering

Diagram 3b: Stress Distribution in Tempered glass

NiS in the Glass Production Process: Some microscopic imperfections, known as inclusions, are inherent in the glass production process. Inclusions are microscopic particles that are incorporated into the structure of the glass in the initial melting process of silica sand and other ingredients. There are approximately 50 different types of dirt or other inclusions recognized, but almost all of them are completely harmless. Nickel sulfide is the only exception, and it is a problem in tempered glass only.

There is a reasonable consensus in the industry as to how NiS is formed, from the compounds that are initially introduced into the glass. Assuming that the nickel enters in the form of a nickel-alloy metal (like stainless steel), which is the most commonly accepted explanation for its origin, nickel sulfide forms in a three-step process. First, the nickel separates from the other materials in the alloy, then it bonds with sulfur in the high heat of the melting furnace, and finally is trapped in the glass as the glass cools to its sheet form. Major studies have been made in reducing the contamination of rawmaterials, and great care is taken to avoid the contact between the raw materials and any nickel-containing alloys but it is practically impossible to prevent some microscopic quantities finding the way into the melt, from other sources of Nickel.

Nickel sulfide, like many compounds, exists in different phases at different temperatures. There are two specific phases of NiS, known as the alpha-phase and the beta-phase. This would have no effect on glass whatsoever were it not for the fact that when the NiS changes from alpha-phase to beta-phase, it increases in volume by 2-4 per cent. At temperatures below 3800C, nickel sulfide is stable in the beta-phase form. Above this temperature, it is stable in the alpha-phase. Therefore, when glass is produced in the furnace, it is overwhelmingly likely that any NiS inclusions will be in the alpha-phase. In typical annealed glass, the slow cooling process provided by the annealing lehr, allows the NiS, ample time to transform to its beta-phase as the glass cools.

Image 4: NiS Particle causing Micro         Image 5 – Nis Particle Photographed after

               cracks                                                         spontaneous breakages 


In the fast cooling process used in tempered glass, and also heat strengthened glass, there is insufficient time to complete the phase transition of NiS from alpha to beta. The inclusions therefore are trapped in the glass in their high temperature alpha-phase.

Once the glass cools past the phase change temperature, the NiS inclusion seeks to re-enter its lower energy beta-phase. For “trapped” inclusions, this process takes anywhere from months to years. This expansion creates localized tensile stresses that are estimated to be as high as 125,000 psi (860 MPa) at the glass-NiS Interaction surface. The magnitude of this stress drops off sharply away from the face of the inclusion, but is sufficient at the face to cause micro-cracking. (See image 4 and 5).

In compression zones, even this large of a stress is not a concern due to its extreme localization. However, in the core tension zone of the glass, these micro-cracks are propagated by stress concentrations at the tip of the crack until the structure of the glass is undermined completely and the tempered glass undergoes its characteristic shattering, which causes the seemingly spontaneous failure.

For simplified explanation, one can imagine tempered glass as akin to an inflated balloon, which can take substantial loads but when pricked or triggered by a sharp object, it will burst very easily. If there is a NiS particle sitting in the tensile zone or very close to it, the phase change from alpha to beta, can act as a trigger and cause the spontaneous breakage. Tempered glass with higher stresses, will have higher probability of NiS breakage as compared to tempered glass with lower stresses, just as a more pressurized balloon will need lesser provocative force to trigger its bursting. It has been observed that the incidences of NiS breakages are more in thicker tempered glasses (8mm-19mm) as compared to thinner glasses (4mm-6mm).

Heat strengthened glass has substantially lower stresses than tempered glass and therefore have very little possibility of NiS breakages.

Critical vs. Sub-Critical Inclusions: Research has created a theoretical equation that predicts the smallest diameter of a NiS inclusion that would cause failure as 50 microns (0.05mm) in diameter. Inclusions larger than this are typically referred to as “critical” inclusions, whereas smaller inclusions are classified as “sub-critical” inclusions. The relationship between stress and diameter of NiS inclusion has been scientifically proven and field studies have also examples of such small inclusions causing the spontaneous breakages.

It is important to note that sub-critical inclusions of size substantially lower than 0.05mm (say 0.02mm) are generally not capable of creating enough localized tensile stresses, to be able to break the glass, but these can cause a failure if the glass is placed under additional tensile stress due to bending or thermal loading. It has been shown that when glass undergoes deflections that are in excess of 75 per cent of the panel thickness, the stresses in the glass due to lateral loads change from a bending stress profile to a membrane stress profile. Under this condition, lateral loads may increase the tensile stresses at the center of the glass.

Breakage Frequency and Timeline: NiS breakage occurrences are not very significant if we consider the total volume of tempered glass produced globally or nationally, and the volume of glass broken due to NiS. There are many buildings with no report of NiS breakages. There are quite a few which have experienced an occasional failure, but there are some examples, which have repeated failures.

It has not been possible to put exact numbers on frequency and timeline since the results of various studies are all different in units. One study puts the number of NiS occurring as 1 in 500 glass panes. Another study by a prominent Indian float manufacturer puts the no. as 1 critical occurrence in 13 tons of glass. Many other studies have come out with different numbers and though the numbers do not match, it seems clear that failures due to NiS inclusions are incredibly rare. Buildings that have seen multiple instances of NiS failures often have huge expanses of glass, which automatically increases the odds of such a failure occurring. It is also possible for a particularly bad batch of float glass to be produced, which would have a higher failure rate.

Another aspect of nickel sulfide failure is the fact that these failures rarely occur upon installation or even within the first few months following installation. Even so, the overwhelming trend is that most panels break in the first 2 to 7 years, after which the number of breakages tapers off with what is commonly considered as logarithmic decay.

Preventive Measures: The industry is pursuing several courses of action in order to reduce the risks and costs associated with nickel sulfide in tempered glass. For the purposes of comparing various preventive or corrective methods, three criteria were selected which seem to be a fair evaluation of the effectiveness of a solution. In order to be a successful solution, the method must be cost-effective to implement, eliminate the costs of replacement of panels upon breakage, and prevent any injury to bystanders in a failure. So far, no solution has adequately fulfilled all three criteria, and thus the industry is still searching. However, a summary of preventative measures already in use or development in the industry is discussed here.

Image -Heat Soaking Oven


Controlling NiS in Annealed Glass: It might seem the simplest solution to nip the problem at its origin by ensuring that there is no nickel or its alloys entering the glass-melting furnace. Responsible float manufacturers are supposed to take every precaution to control this but it is very difficult to prevent it altogether and in spite of best efforts, small amounts of nickel will find its way through inclusions in raw materials itself or their handling/ storage equipment etc. There is a need for float manufacturers to further strengthen the quality procedures to include necessary steps for its prevention and to subject their quality procedures to internal and external quality audits.

Heat Soak Testing: Tempered glasses can be heat soaked by heating the glass panels for a third time to a temperature below the phase change temperature of NiS and maintaining it or soaking it at that elevated temperature for a set time. Maintaining an elevated temperature facilitates faster conversion of any particle of NiS, if present, from alpha-phase to beta-phase, and therefore the idea is that any panel, which has a possibility of failure from NiS, should fail in the HST oven rather than on the building. The process was introduced in 1982 and the first standard that evolved was DIN 18516. The most common standard, currently being followed is EN 14179. This standard requires glass to be heated to 290 100C and held at this temperature for 2 hours, which is a shorter duration than 8 hours for DIN 18516. The Ŧ reduction in time was based on recommendations from research, which indicated that less than 1 break in 10,000 panes of glass was expected to occur after 2 hours.

There are costs associated to HST which are the processing costs, cost of glass breakages due to NiS in HST oven, and damage by broken glass to the neighbouring panels in HST oven, potentially even causing them to break as well and propagating the problem.

Another issue is that the secondary heating of tempered glass relaxes surface compression slightly without a corresponding decrease in core tension, which reduces the strength of the glass, though marginally. This was more evident in the 8 hours soaking specified in DIN than in the 2 hours soaking as per EN. The designers should keep a small safety margin to account for the same.

In spite of all the issues with the process, it is still the only method the industry has, to eliminate a large portion of nickel sulfide inclusions in batches that are compatible with large-volume production. The success rate of HST is hard to define because of the difficulty of accurate data collection on resulting nickel sulfide failures, which are very rare occurrences. But it can be safely said that appropriately done HST, would eliminate 95 to 98.5 per cent of such glasses as could have caused a spontaneous breakage post installation.

Smart specification and selection: The most logical solution to the problem is by avoiding the use of tempered glass where there are other options like

  • Use heat-strengthened glass instead of tempered glass where technically feasible.
  • Heat strengthened laminated glass is the best option for most applications, except for point fixedglazing

Nickel Sulfide Breakage

  • In applications, where tempered glass cannot be avoided due to load considerations or code requirements, it is advised to get it HST.
  • Alternately one should be prepared for such occurrences and for replacing NiS broken glasses.
  • Annealed Laminated glass will have no occurrence of NiS breakage.

Other methods for detection: There are other methods such as laser-imaging and ultra-sound which are non destructive but these methods will need a scan of each panel of glass which will show up all inclusions and not only NiS and thereafter, it will separately need an assessment of each inclusion in each panel to decide which ones are fatal types of NiS and located in the risk zone. The exercise is prohibitively expensive and not feasible on production scales. A person must interpret the results of ultrasound and laser imaging, glass by glass and the margin of user error might be quite large when searching for such a small problem.

Conclusions: Spontaneous breakage due to NiS is not due to any manufacturing defect but is an inherent risk or problem associated with use of tempered glass. As of now, 100 per cent success in eliminating nickel sulfide from tempered glass cannot be guaranteed by any method. Therefore this is an issue which designers should be aware of, and take into account when deciding the use of tempered glass in their building and adopt smart specifications. Glass is a fragile material and no glass supplier can warranty breakages, as there can be numerous causes of breakages and NiS breakages is just one amongst many.


Traditionally, the materials used to design and decorate homes have been wood, metal or cloth furnishings. Few people realize that delightfully beautiful effects can be achieved with glass. Available in a stupendous variety of styles, colors, designs and textures, glass has the potential to create stunning ambiences that have the power to transform living and elevate lifestyle.

It is a smart, adaptable and versatile material, offering itself to endless possibilities both in terms of design and functionality, across exterior and interior applications. All in all, glass stands in a league of its own. The inherent beauty of glass as a material, when combined with contemporary design sensibilities, makes for an irresistible combination, one that mesmerises and enthrals in equal measure. Delightfully beautiful effects can be achieved with glass.

Glass flooring and stair trends continue to be a popular design choice. Glass flooring can become an artistic showpiece. With recent innovation in glass and glass fittings, any design can be executed for glass stairways and floors. Glass floors enhance the visual appeal of living spaces, and add a touch of modernity. Glass floors and staircases help create illusion of space. A simple glass floor adds life to a room. It also brightens up the space.

Various applications include glass stair tread, ramps and footbridges. Glass flooring adds a design element. The visual appeal of glass tiles can be enhanced further with LED lighting. This is common feature in clubs, restaurants and hotels.

Safety is very important when glass is used for floorings. A commonly perceived notion is that glass compromises safety and security. However, continuous research and technology advances have made glass safer and more secure that it ever was. The range of specialized laminated glass from Asahi India Glass Ltd. ( AIS) includes – Value glass (heat-strengthened laminated glass with 1.14mm PVB interlayer), Security glass (Intrusion-resistant laminated glass with 1.52 mm PVB interlayer), Securityplus (Dupont Sentry Glass interlayer makes it 5 times stronger and 100 times stiffer than conventional laminating materials).

The first step while designing the glass floors is calculating the glass size and thickness depending on the loading or foot traffic on the application. Also, the support systems for the glass should be adequate to prevent distortion under load.

Designing surfaces to be walked on is different as issue related to impact resistance and slip and scratch resistance come into the picture. Many architects are concerned with maintenance and the potential of glass flooring scratching due to normal foot traffic and wear and tear. Anti-slip glass flooring and glass stair trend products are available in the market. Etched or printed surfaces help in improving grip. Imbedded textures provide an anti-skid surface that is scratch- proof and easily hides any smudges or streaks. Anti-scratch glass floorings reduce the opportunity and need for cleaning.

To maintain the aesthetic beauty of your glass flooring, it is important to keep the glass panel clean. A soft, clean, non-abrasive cloth and a mild detergent, or non-abrasive glass cleaning solution is suitable for cleaning. After cleaning, the water should be rinsed immediately. Abrasive cleaners, bleach, scouring powder or pads should not be used as they can scratch and damage glass flooring.

Source: Asahi India


Low emissivity (low e or low thermal emissivity) refers to a surface condition that emits low levels of radiant thermal (heat) energy. All materials absorb, reflect and emit radiant energy but here, the primary concern is a special wavelength interval of radiant energy, namely thermal radiation of materials with temperatures approximately between 40 to 60 degrees Celsius.

  1. Emissivity is the value given to materials based on the ratio of heat emitted compared to a black body, on a scale from zero to one. A blackbody would have an emissivity of 1 and a perfect reflector would have a value of 0.


  1. Reflectivityis inversely related to emissivity and when added together their total should equal 1 for an opaque Therefore, if asphalt has a thermal emissivity value of 0.90, its thermal reflectance value would be 0.10. This means that it absorbs and emits 90 percent of radiant thermal energy and reflects only 10 percent. Conversely, a low-e material such as aluminium foil has a thermal emissivity value of 0.03 and a thermal reflectance value of 0.97, meaning it reflects 97 percent of radiant thermal energy and emits only 3 percent.

Low-emissivity building materials include window glass manufactured with metal-oxide coatings as well as house wrap materials, reflective thermal insulations and other forms of radiant thermal barriers.


The thermal emissivity of various surfaces is listed in the following table.


Materials surface Thermal emissivity
Aluminium foil 0.03
Asphalt 0.88
Brick 0.90
Concrete, rough 0.91
Glass, smooth (uncoated) 0.91
Limestone 0.92
Marble, Polished or white 0.89 to 0.92
Paper, roofing or white 0.88 to 0.86



                             Pyrolytic vs. sputtered

Window glass is by nature highly thermally emissive, so to improve thermal efficiency (insulation properties), ultra thin, invisible film coatings are applied to the raw soda-lime glass. There are two primary methods in use:

           Pyrolitic (CVD): Magnetron sputtering (MSVD):
Involves deposition of fluorinated tin oxide (SnO2) at high temperatures. It involves depositing thin silver layers with antireflection layers.
Such coatings are usually applied at the float glass plant when the glass is manufactured. It uses large vacuum chambers with multiple deposition chambers depositing 5 to 10 or more layers in succession.
Since the coating is covalently bonded to the glass; Pyrolitic low-E is extremely durable and can be handled, transported and stored just like clear glass.



Silver-based films are environmentally unstable and must be enclosed in insulated glazing or an Insulated Glass Unit (IGU) to maintain their properties Specially designed coatings are applied to one or more surfaces of insulated glass over time.


For years, MSVD coating technology and sputtered low-E have been the only widely available options. However, the inherent handling sensitivity and limited shelf-life of sputtered low-E render it ill-suited for transport and use in regions with developing infrastructures. Moreover, the dominant glazing in these regions is often a single lite, while sputtered low-E can only be used in a multiple lite IG unit assembly.

These low emissivity coatings reflect radiant infrared energy, thus tending to keep radiant heat on the side of the glass where it originated, while letting visible light pass. This results in more efficient windows because radiant heat originating from indoors in winter is reflected back inside, while infrared heat radiation from the sun during summer is reflected away, keeping it cooler inside.

Solar Pattern

The higher solar heat gain coefficient of Pyrolitic low-E coatings can result in significantly lower heating costs and provide a greener alternative, making Pyrolitic low-E coatings an ideal substitute.

“Naturally” low thermal emissivity is found in some formulations of borosillicate or Pyrex. Naturally low-e glass does not have the property of reflecting near infrared (NIR)/thermal radiation; instead, this type of glass has higher NIR transmission, leading to undesirable heat loss (or gain) in a building window.

Setbacks of low-E windows:

Since energy-efficient windows reflect much more sunlight than simple glass windows, when these windows are somewhat concave they can focus sunlight and cause damage. Damage to the sidings of homes and to automobiles has been reported in news stories.

Low-E windows may also block radio frequency signals. Buildings without distributed antenna systems may then suffer degraded cell phone reception.


Recent trends:

Recent trends show that Pyrolitic low-E coatings are attracting more and more attention in both the commercial and residential glass coatings markets due to the strong focus on Energy Star and Green Building programs

Reflective insulation thermal:

Reflective thermal insulation is typically fabricated from aluminium foil with a variety of core materials such as low-density polyethylene foam, polyethylene bubbles, fibreglass, or similar materials. Each core material presents its own set of benefits and drawbacks based on its ability to provide a thermal break, deaden sound, absorb moisture, and resist combustion during a fire. When aluminium foil is used as the facing material, reflective thermal insulation can stop 97% of radiant heat transfer.

Reflective thermal insulation can be installed in a variety of applications and locations including residential, agricultural, commercial, and industrial structures. Some common installations include house wraps, duct wraps, pipe wraps, under radiant floors, inside wall cavities, roof systems, attic systems and crawl spaces.

By façade experts


Issues in Window Selection: Energy-related

Heat Transfer Mechanisms | Measuring Properties | Overview of Energy Use | Codes and Standards

Measuring Energy-related Properties

There are four energy performance characteristics of windows used to portray how energy is transferred and are the basis for how energy performance is quantified. They are:

  • U-factor. When there is a temperature difference between inside and outside, heat is lost or gained through the window frame and glazing by the combined effects of conduction, convection, and radiation. The U-factor of a window assembly represents its insulating value.
  • Solar Heat Gain Coefficient. Regardless of outside temperature, heat can be gained through windows by direct or indirect solar radiation. The ability to control this heat gain through windows is measured in terms of the solar heat gain coefficient (SHGC) or shading coefficient (SC) of the window.
  • Visible Transmittance. Visible transmittance (VT) is an optical property that indicates the amount of visible light transmitted through the glass (also referred to as visible light transmittance – VLT). It affects energy by providing daylight that creates the opportunity to reduce electric lighting and cooling loads.
  • Air Leakage. Heat loss and gain also occur by air leakage through cracks in the window assembly. This effect is measured in terms of the amount of air (cubic feet or cubic meters per minute) that passes through a unit area of window (square foot or square meter) under given pressure conditions. In reality, infiltration varies slightly with wind-driven and temperature-driven pressure changes. Air leakage also contributes to summer cooling loads by raising the interior humidity level.

Insulating Value (U-factor)
Heat flow from the warmer side to the colder side of a window and frame is a complex interaction of all three basic heat transfer mechanisms–conduction, convection, and radiation. The ability of the window assembly to resist this heat transfer is referred to as its insulating value. Heat flows from warmer to cooler bodies, thus from inside to outside in winter, and reverses direction in summer during periods when the outside temperature is greater than indoors. Conduction occurs directly through the glazing material itself as well as through the solid parts of the spacers and frames.

Determining Insulating Value
The U-factor (also referred to as U-value) is the standard way to quantify insulating value. It indicates the rate of heat flow through the window. The U-factor is the total heat transfer coefficient of the window system (in Btu/hr-sq ft-°F or W/sq m-°C), which includes conductive, convective, and radiative heat transfer. It therefore represents the heat flow per hour (in Btus per hour or Watts) through each square foot (or square meter) of window for a 1°F (1°C) temperature difference between the indoor and outdoor air temperature. The R-value is the reciprocal of the total U-factor (R=1/U). As opposed to an R-value, the smaller the U-factor of a material, the lower the rate of heat flow.

Overall U-factor
Since the U-factors are different for the glass, edge-of-glass zone, and frame, it can be misleading to compare U-factors if they are not carefully described. In order to address this problem, the concept of a total window U-factor is utilized by the National Fenestration Rating Council (NFRC). A specific set of engineering assumptions and procedures must be followed to calculate the overall U-factor of a window unit using the NFRC method. Originally developed for manufactured window units, there is a new method for certifying site-built assemblies. The whole unit U-factor will vary, of course, depending on the glass-to-frame ratio. Figure 2-7 indicates the center-of-glass U-factor and the overall U-factor for several types of window units. Since Windows A-G in Figure 2-7 have a thermally broken aluminum frame, the center of glass U-factor is always lower than the whole unit. The whole window and center-of-glass U-factors for Windows H and I are closer because of the insulated frames.

Solar Radiation Control
The second major energy-performance characteristic of windows is the ability to control solar heat gain through the glazing. Solar heat gain through windows is a significant factor in determining the cooling load of many commercial buildings. The origin of solar heat gain is the direct and diffuse radiation coming from the sun and the sky or reflected from the ground and other surfaces. Some radiation is directly transmitted through the glazing to the space, and some may be absorbed in the glazing and then indirectly admitted to the space. Other thermal (nonsolar) heat transfer effects are included in the U-factor of the window. Sunlight is composed of electromagnetic radiation of many wavelengths, ranging from short-wave invisible ultraviolet, to the visible spectrum, to the longer, invisible near-infrared waves. About half of the sun’s energy is visible light; the remainder is largely infrared with a small amount of ultraviolet. While reducing solar radiation through windows is a benefit in some climates and during some seasons, maximizing solar heat gain can be an energy benefit under winter conditions.

Determining Solar Heat Gain
There are two means of indicating the amount of solar radiation that passes through a window. These are solar heat gain coefficient (SHGC) and shading coefficient (SC). In both cases, the solar heat gain is the combination of directly transmitted radiation and the inward-flowing portion of absorbed radiation (Figure 2-9). However, SHGC and SC have a different basis for comparison.

Shading Coefficient
Until recently, the shading coefficient (SC) was the primary term used to characterize the solar control properties of glass in windows. Although it is being replaced by the solar heat gain coefficient (SHGC), it is still referenced in books and product literature.

The shading coefficient (SC) is only defined for the glazing portion of the window and does not include frame effects. It represents the ratio of solar heat gain through the system relative to that through 1/8-inch (3 mm) clear glass at normal incidence. The shading coefficient is expressed as a dimensionless number from 0 to 1. A high shading coefficient means high solar gain, while a low shading coefficient means low solar gain.

For any glazing, the SHGC is always lower than the SC. To perform an approximate conversion from SC to SHGC, multiplying the SC value by 0.87.

Solar Heat Gain Coefficient
Window standards are now moving away from use of shading coefficient to solar heat gain coefficient (SHGC), which is defined as that fraction of incident solar radiation that actually enters a building through the window assembly as heat gain. The SHGC is influenced by all the same factors as the SC, but since it can be applied to the entire window assembly, the SHGC is also affected by shading from the frame as well as the ratio of glazing and frame. The solar heat gain coefficient is expressed as a dimensionless number from 0 to 1. A high coefficient signifies high heat gain, while a low coefficient means low heat gain. Typical SHGC values for the whole window unit and center of glass are shown in Figure 2-10.

Visible Transmittance
Visible transmittance (VT), also referred to as visible light transmittance (VLT), is the amount of light in the visible portion of the spectrum that passes through a glazing material. A higher VT means there is more daylight in a space which, if designed properly, can offset electric lighting and cooling loads due to lighting. Visible transmittance is influenced by the glazing type, the number of layers, and any coatings that might be applied to the glazings. Visible transmittance of glazings ranges from above 90 percent for water-white clear glass to less than 10 percent for highly reflective coatings on tinted glass. Typical visible transmittance values for the whole window unit and center of glass are shown in Figure 2-12.

Air Leakage (Infiltration)
Air leakage (infiltration) can be defined as ventilation that is not controlled and usually not wanted. It is the leakage of air through cracks in the building envelope. Air leakage leads to increased heating or cooling loads when the outdoor air entering the building needs to be heated or cooled. Operating windows can be responsible for a significant amount of the air leakage in buildings. Tight sealing and weatherstripping of windows, sashes, and frames is of paramount importance in controlling air leakage.

Cracks and air spaces left between the window unit and the building wall can also account for considerable infiltration. Insulating and sealing these areas during construction or renovation can be very effective in controlling air leakage. A proper installation ensures that the main air barrier of the wall construction, is effectively sealed to the window or skylight assembly so that continuity of the two air barriers is maintained.

The amount of air that leaks through all of the cracks in and around a window sash and frame is a function of crack length, tightness of the seals and joints, and the pressure differential between the inside and outside. Window manufacturers currently report air leakage test values as cfm/sq ft (cubic feet per minute per square foot of window area). In the past, air leakage may have been reported as cfm/lf (cubic feet per minute per lineal foot of sash crack) but this form of reporting is no longer supported.

Author – Mrs. Nidhi Dixit

B.arch,M.Arch (Environmental architecture)

LEED & GRIHA trained Professional

Building simulation & LCA expert)



50 times More Solar Electricity from Façade Glass than conventional Roof top systems.

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