Sunday, December 13, 2009
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warm edge technology
Up to 80% of heat loss occurs through the edge of the window. Warm edge products help to minimize this heat loss.
Warm Edge Technology refers to the construction of the edge of the Double Glass Waterproof unit that conducts less heat or cold than a traditional window and traditional construction of the unit DVH.
DVH are constructed with traditional aluminum spacer to keep the glass separator. However, aluminum is highly conductive and also has an exceptionally high heat loss.
comparison, DVH windows built with warm edge spacer has a temperature in the edge that can be up to 65% more which helps to warm the window's thermal efficiency by reducing the risk of condensation.
Also, the warm edge significantly reduces the temperature differential between the center and edge of the unit and up to 94% DVH reduce external heat loss at the edge of your window.
While making a real contribution to the environment, these savings can help reduce consumption of home heating which reduces carbon emissions and save money in the energy bill for heating.
Also, warm edge technology can help reduce condensation by up to 70%. This moisture reduction virtually eliminates the possibility of mold growth and potential harmful bacteria.
Up to 80% of heat loss occurs through the edge of the window. Warm edge products help to minimize this heat loss.
Warm Edge Technology refers to the construction of the edge of the Double Glass Waterproof unit that conducts less heat or cold than a traditional window and traditional construction of the unit DVH.
DVH are constructed with traditional aluminum spacer to keep the glass separator. However, aluminum is highly conductive and also has an exceptionally high heat loss.
comparison, DVH windows built with warm edge spacer has a temperature in the edge that can be up to 65% more which helps to warm the window's thermal efficiency by reducing the risk of condensation.
Also, the warm edge significantly reduces the temperature differential between the center and edge of the unit and up to 94% DVH reduce external heat loss at the edge of your window.
While making a real contribution to the environment, these savings can help reduce consumption of home heating which reduces carbon emissions and save money in the energy bill for heating.
Also, warm edge technology can help reduce condensation by up to 70%. This moisture reduction virtually eliminates the possibility of mold growth and potential harmful bacteria.
Window with warm edge spacer.
Window with aluminum spacer.
Source / Source: http://www.thermosealgroup.com/warm-edge.cfm
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DT012-edge separator vs warm.
The double glazed sealed units, DVH, or thermo, are one of the most common types glazing used today in construction. Patented in 1865, DVH units were implemented in applications architecture after World War II. Due to the excellent thermal and acoustic properties, these units have completely replaced the monolithic glass windows basic.
Over the decades the DVH thermal performance has been improved with the introduction of glass with a layer of low emissivity (Low-E) and low conductivity gases. Then the attention was on the edge and reducing heat loss caused by highly conductive materials.
DVH Today the most common is composed of two glass plates and an aluminum spacer around the edge of the glass. The aluminum containing a desiccant moisture remover d ela. The major benefits of aluminum spacer are: low weight, durability and relative low cost. The disadvantage of the aluminum spacer is the conductive property of aluminum, which sometimes causes the edge of the unit DVH lose more heat than the center of the glass.
To overcome this limitation, the glass industry developing so-called low-conductivity spacers or warm edge spacers (Warm Edge). These are designed to improve the thermal performance of the window, reduce condensation and allow the appropriate machinery manufacturing faster and easier for the DVH. There have been several attempts to position these products in the market. However, the change was highly anticipated, big and a higher cost to the system of aluminum with a small improvement in U value of DVH.
When they took out the new legislation on energy saving in Europe in 1977, became the interest of low-conductivity spacers. Currently, there are several low-conductivity spacers on the market, however due to the facts mentioned above the classic aluminum spacer still remain the number 1 choice for DVH.
Source: http://www.glassonweb.com/articles/article/213/ 
The double glazed sealed units, DVH, or thermo, are one of the most common types glazing used today in construction. Patented in 1865, DVH units were implemented in applications architecture after World War II. Due to the excellent thermal and acoustic properties, these units have completely replaced the monolithic glass windows basic.
Over the decades the DVH thermal performance has been improved with the introduction of glass with a layer of low emissivity (Low-E) and low conductivity gases. Then the attention was on the edge and reducing heat loss caused by highly conductive materials. DVH Today the most common is composed of two glass plates and an aluminum spacer around the edge of the glass. The aluminum containing a desiccant moisture remover d ela. The major benefits of aluminum spacer are: low weight, durability and relative low cost. The disadvantage of the aluminum spacer is the conductive property of aluminum, which sometimes causes the edge of the unit DVH lose more heat than the center of the glass.
To overcome this limitation, the glass industry developing so-called low-conductivity spacers or warm edge spacers (Warm Edge). These are designed to improve the thermal performance of the window, reduce condensation and allow the appropriate machinery manufacturing faster and easier for the DVH. There have been several attempts to position these products in the market. However, the change was highly anticipated, big and a higher cost to the system of aluminum with a small improvement in U value of DVH.
When they took out the new legislation on energy saving in Europe in 1977, became the interest of low-conductivity spacers. Currently, there are several low-conductivity spacers on the market, however due to the facts mentioned above the classic aluminum spacer still remain the number 1 choice for DVH.
Source: http://www.glassonweb.com/articles/article/213/
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aluminum separator DT007-Dura Platform; Compare
The following table shows the result of comparing platform performance Dura (Duraseal-Duralite) with the traditional aluminum spacer.
The following table shows the result of comparing platform performance Dura (Duraseal-Duralite) with the traditional aluminum spacer.
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DT005-performance double-glazed sealed Separators
The sealed unit double glazing or thermo is one of the most common types of glass used in construction. Due to their excellent thermal and acoustic properties DVH units have replaced the core with monolithic glass windows. One of the important elements of a DVH is the separator.
The most common sealed unit double glazing, DVH, are composed of two pieces of glass and a spacer around the edge profile of the unit DVH. Profile inside separator has a silica compound that acts as a moisture remover space between the glass pieces. The problem with aluminum separators is that aluminum is an excellent thermal conductor, allowing the cold outer reaches of the interior of the unit DVH. To prevent heat loss caused by traditional aluminum spacer units DVH, more and more consumers are demanding low-conductivity materials to separate glass panels. The call to this problem was WARM EDGE SPACER (warm edge). The warm edge spacers refer to a type of material separator used to separate glass panels in a unit DVH. If the material conducts less heat than a traditional aluminum separator glass edge is called warm edge spacer. Many of the new spacers are less conductive and higher performance than aluminum. Warm edge spacers improve the thermal performance of windows, reduce condensation, and proper machinery, allows quick easy production of DVH. The big problem with this type of separator is even a higher price than conventional aluminum spacer.
Source / Source: http://www.glassonweb.com/articles/article/183/?myKeyword=warm edge 
The sealed unit double glazing or thermo is one of the most common types of glass used in construction. Due to their excellent thermal and acoustic properties DVH units have replaced the core with monolithic glass windows. One of the important elements of a DVH is the separator.
The most common sealed unit double glazing, DVH, are composed of two pieces of glass and a spacer around the edge profile of the unit DVH. Profile inside separator has a silica compound that acts as a moisture remover space between the glass pieces. The problem with aluminum separators is that aluminum is an excellent thermal conductor, allowing the cold outer reaches of the interior of the unit DVH. To prevent heat loss caused by traditional aluminum spacer units DVH, more and more consumers are demanding low-conductivity materials to separate glass panels. The call to this problem was WARM EDGE SPACER (warm edge). The warm edge spacers refer to a type of material separator used to separate glass panels in a unit DVH. If the material conducts less heat than a traditional aluminum separator glass edge is called warm edge spacer. Many of the new spacers are less conductive and higher performance than aluminum. Warm edge spacers improve the thermal performance of windows, reduce condensation, and proper machinery, allows quick easy production of DVH. The big problem with this type of separator is even a higher price than conventional aluminum spacer.
Source / Source: http://www.glassonweb.com/articles/article/183/?myKeyword=warm edge
Thursday, December 10, 2009
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DT004 "That is exactly warm edge spacer?
To reduce heat loss caused by the conventional aluminum spacer in the sealed double glazed units, more and more consumers are looking for materials that break the thermal bridge between the two panes. Discover the benefits and uses of the technology of warm edge spacers.
separators technology DVH Warm Edge (Warm.Edge) is a key issue in the manufacture of DVH. The idea of \u200b\u200breplacing the metal separator to improve the performance of double glazed sealed unit was developed in 1970. In those years, the concept was too innovative and offered several disadvantages. In 80 'this suffered a breakthrough technology that allowed the 90 'was adopted for the efficient production of DVH. Today, warm edge spacers improve the defroster heat of the windows, reduce condensation, and proper machinery for quick and easy to manufacture DVH units. As a result of these advantages, nearly 50% of about 90 million units sold DVH in the United States are made with warm edge spacers.
Source / source: http://www.glassonweb.com/articles/article/31/ 
To reduce heat loss caused by the conventional aluminum spacer in the sealed double glazed units, more and more consumers are looking for materials that break the thermal bridge between the two panes. Discover the benefits and uses of the technology of warm edge spacers.
separators technology DVH Warm Edge (Warm.Edge) is a key issue in the manufacture of DVH. The idea of \u200b\u200breplacing the metal separator to improve the performance of double glazed sealed unit was developed in 1970. In those years, the concept was too innovative and offered several disadvantages. In 80 'this suffered a breakthrough technology that allowed the 90 'was adopted for the efficient production of DVH. Today, warm edge spacers improve the defroster heat of the windows, reduce condensation, and proper machinery for quick and easy to manufacture DVH units. As a result of these advantages, nearly 50% of about 90 million units sold DVH in the United States are made with warm edge spacers.
Source / source: http://www.glassonweb.com/articles/article/31/
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DT003-How to save energy with windows?
heat loss in buildings means a rise in energy costs. A lot of wasted energy occurs in the form of heat escaping through the windowpanes. Therefore, the selection of a thermally efficient window is essential to reduce heat loss.
A principal function of the window is to allow the passage of light (and eventually the fresh air) and allow a view outside for the occupants. However, the windows will also perform several other functions such as thermal comfort, noise protection, security, etc. The thermal comfort of a window (heat loss) is expressed by its value U. A low U value means a lower loss of heat from inside to outside the building while a high U value means the opposite. Pata increase the thermal performance of a window the following improvements can be applied:
Multi (Double) laminated glass
Two glass panels are better than one. The purpose of multiple (double) glass panels in a window is to create an air space between the glass to act as an insulator. Double glazed windows are better than simple glass windows because they reduce air convection heat (air movement is caused by the difference in temperature between the glass surface and room air).
air gap width Senior
air spaces insulate better than narrow, but an increase too in the air gap width produces a convective flow between the glass and does not provide a gain of insulation.
Filled with low-conductivity gas
Filling the gap formed between the glass having a low conductivity gas such as argon or krypton at atmospheric pressure improves thermal performance and reduces heat loss.
low emissivity glass (Low-E)
Introduced during the energy crisis of the 70's, low emissivity coating applied over a glass of double glazed unit hermetic, allowing the short-wavelength light of the sun entering the room and at the same time prevent the heat from the exhaust air from the room. This means a warm home more energy gain.
warm edge spacers, low conductivity
To prevent heat loss caused by the spacers on DVH units, more and more consumers use low-conductivity materials to separate glass panels using the so-called warm edge spacers .
window frame
The window frames are available in different styles and can be made of different materials. Each material (wood, PVC) offers several thermal performance.
Source: http://www.glassonweb.com/articles/article/238/?myKeyword=warm edge 
heat loss in buildings means a rise in energy costs. A lot of wasted energy occurs in the form of heat escaping through the windowpanes. Therefore, the selection of a thermally efficient window is essential to reduce heat loss.
A principal function of the window is to allow the passage of light (and eventually the fresh air) and allow a view outside for the occupants. However, the windows will also perform several other functions such as thermal comfort, noise protection, security, etc. The thermal comfort of a window (heat loss) is expressed by its value U. A low U value means a lower loss of heat from inside to outside the building while a high U value means the opposite. Pata increase the thermal performance of a window the following improvements can be applied:
Multi (Double) laminated glass
Two glass panels are better than one. The purpose of multiple (double) glass panels in a window is to create an air space between the glass to act as an insulator. Double glazed windows are better than simple glass windows because they reduce air convection heat (air movement is caused by the difference in temperature between the glass surface and room air).
air gap width Senior
air spaces insulate better than narrow, but an increase too in the air gap width produces a convective flow between the glass and does not provide a gain of insulation.
Filled with low-conductivity gas
Filling the gap formed between the glass having a low conductivity gas such as argon or krypton at atmospheric pressure improves thermal performance and reduces heat loss.
low emissivity glass (Low-E)
Introduced during the energy crisis of the 70's, low emissivity coating applied over a glass of double glazed unit hermetic, allowing the short-wavelength light of the sun entering the room and at the same time prevent the heat from the exhaust air from the room. This means a warm home more energy gain.
warm edge spacers, low conductivity
To prevent heat loss caused by the spacers on DVH units, more and more consumers use low-conductivity materials to separate glass panels using the so-called warm edge spacers .
window frame
The window frames are available in different styles and can be made of different materials. Each material (wood, PVC) offers several thermal performance.
Source: http://www.glassonweb.com/articles/article/238/?myKeyword=warm edge
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Water hardness DT002-DT001-Making
1. What is the limit of hardness of water to clean glass?
Water with a hardness greater than 200 ppm of dissolved solids is the limit for separate lists in the glass washing. Water with a higher value should be treated or purchase treated water. Notes
QA (Quality Audit = audit quality):
For areas where water quality is hard (high level of dissolved solids => 200 ppm), use of deionized or demineralized water for flushing system final. The dissolved solids in water can cause the formation of a film on the glass surface, which can interfere with adhesion of sealant to glass.
A simple test to control the hardness of the water is wet with water drops a piece of clear glass. Air dry. Once the water has evaporated, if there are stains or marks on the glass drops because the water contains a high amount of dissolved solids.
2. What are the top three water treatment systems?
This is a complicated question, depending on what is in the water supply, although only referred to the hardness of water, then the following treatment systems would be the best:
a) DI = deionized water (deionized water): (THE BEST)
This water treatment system will completely remove all minerals from water. TDS = 0 ppm. This can be a very expensive solution if the water has high TDS. Mostly used a recirculation system with an activated carbon filter in the final rinse to reduce water loss and the cost of operation.
This is above what is needed for the manufacture of DVH.
b) RO with DI = Reverse Osmosis (RO) with final rinse of deionized water (VERY GOOD)
treatment system by reverse osmosis remove ~ 95% of mineral water. TDS ~ 0 - 30ppm. Most systems will be of 0 - 20ppm. The activated carbon and final rinse with deionized water recirculated, have 0 ppm.
Note:
Water "clean (free spot)" is 20 or less.
This is the preferred treatment system for dual-insulating glass manufacturers, as the RO system will minimize the calcification in the washing system and heater, while the final rinse with deionized water and recirculated carbon filter enabled is 0 ppm, considering that is the last touch glass water before drying and use. The recirculation system will keep the system operating costs under control. This system has a high initial cost, but long term is very competitive. The RO system can also leased some water treatment companies.
c) RO = Reverse Osmosis (RO): (GOOD)
The water treatment system for reverse osmosis remove ~ 95% of mineral water. TDS ~ 0 - 30ppm. Most systems give 0 - 20ppm.
Note:
Water "clean (free spot)" is 20 or less.
This is a good system if the water treatment needs do not exceed the capacity of the treatment system. Generally, this system only uses treated water for final rinse.
This system has a significant initial cost, but over time it becomes very competitive. The RO system can also be leased to a water treatment company.
Comments:
Smoothing Water: (Not recommended for the manufacture of insulating glass)
The water softener, softened water does not reduce the level of TDS in the water, but simply exchanges a sodium ion and calcium, etc. The sodium ion is more soluble and therefore reduces the accumulation in the spray bars in the washing section and the heater.
solubility becomes a problem for the manufacturer when a film of mineral is left in the glass and is likely to be re-dissolved if water does get in the pocket placement, resulting in seal failure faster than if Untreated water.
Filtering filtration does not reduce the TDS, as only the suspended particles are filtered. The filters are good for pre-wash sections re-circulated and washing, because that is where most of the particles or waste materials are washed glass and recycle this water can be deposited again. Filtration in the first rinse recirculation systems not harmful, but is less effective because the rinse water should be clean. As treated water saving measure, it is recommended to use filters to trap the first washing. This will increase the life of the water and reduce waste is 
1. What is the limit of hardness of water to clean glass?
Water with a hardness greater than 200 ppm of dissolved solids is the limit for separate lists in the glass washing. Water with a higher value should be treated or purchase treated water. Notes
QA (Quality Audit = audit quality):
For areas where water quality is hard (high level of dissolved solids => 200 ppm), use of deionized or demineralized water for flushing system final. The dissolved solids in water can cause the formation of a film on the glass surface, which can interfere with adhesion of sealant to glass.
A simple test to control the hardness of the water is wet with water drops a piece of clear glass. Air dry. Once the water has evaporated, if there are stains or marks on the glass drops because the water contains a high amount of dissolved solids.
2. What are the top three water treatment systems?
This is a complicated question, depending on what is in the water supply, although only referred to the hardness of water, then the following treatment systems would be the best:
a) DI = deionized water (deionized water): (THE BEST)
This water treatment system will completely remove all minerals from water. TDS = 0 ppm. This can be a very expensive solution if the water has high TDS. Mostly used a recirculation system with an activated carbon filter in the final rinse to reduce water loss and the cost of operation.
This is above what is needed for the manufacture of DVH.
b) RO with DI = Reverse Osmosis (RO) with final rinse of deionized water (VERY GOOD)
treatment system by reverse osmosis remove ~ 95% of mineral water. TDS ~ 0 - 30ppm. Most systems will be of 0 - 20ppm. The activated carbon and final rinse with deionized water recirculated, have 0 ppm.
Note:
Water "clean (free spot)" is 20 or less.
This is the preferred treatment system for dual-insulating glass manufacturers, as the RO system will minimize the calcification in the washing system and heater, while the final rinse with deionized water and recirculated carbon filter enabled is 0 ppm, considering that is the last touch glass water before drying and use. The recirculation system will keep the system operating costs under control. This system has a high initial cost, but long term is very competitive. The RO system can also leased some water treatment companies.
c) RO = Reverse Osmosis (RO): (GOOD)
The water treatment system for reverse osmosis remove ~ 95% of mineral water. TDS ~ 0 - 30ppm. Most systems give 0 - 20ppm.
Note:
Water "clean (free spot)" is 20 or less.
This is a good system if the water treatment needs do not exceed the capacity of the treatment system. Generally, this system only uses treated water for final rinse.
This system has a significant initial cost, but over time it becomes very competitive. The RO system can also be leased to a water treatment company.
Comments:
Smoothing Water: (Not recommended for the manufacture of insulating glass)
The water softener, softened water does not reduce the level of TDS in the water, but simply exchanges a sodium ion and calcium, etc. The sodium ion is more soluble and therefore reduces the accumulation in the spray bars in the washing section and the heater.
solubility becomes a problem for the manufacturer when a film of mineral is left in the glass and is likely to be re-dissolved if water does get in the pocket placement, resulting in seal failure faster than if Untreated water.
Filtering filtration does not reduce the TDS, as only the suspended particles are filtered. The filters are good for pre-wash sections re-circulated and washing, because that is where most of the particles or waste materials are washed glass and recycle this water can be deposited again. Filtration in the first rinse recirculation systems not harmful, but is less effective because the rinse water should be clean. As treated water saving measure, it is recommended to use filters to trap the first washing. This will increase the life of the water and reduce waste is
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DVH curve
TruSeal separators allow the fabrication of a hermetic glass unit double curve. The spacers are EDGETHERM DVH curve or Microseal DS. Not recommended to use the system to have a flexible DURA reduced side.
separator also use requires the application tool PEAK TOOL, especially for such applications.
Because it is difficult to obtain the same curve in both glasses, we recommend the use of secondary seal.
1 - Apply the spacer on the edge of 1 of the curved glass. Peak use tool Tool
2 - Check the correct application of the separator at the 4 edges of curved glass.
3 - Assemble second curved glass. Take care that both are framed.
4 - Apply the clamps on the edge of the unit.
5 - Place the clips every 150 mm to ensure a charge pair in the perimeter.
6 - Place the unit curve in a position that allows the heating of the 4 edges.
With the heat gun to heat the unit until its edge reaches 45 ° C. Check the temperature with an infrared thermometer. Then, with one foot underground control the total thickness of the unit. Reheat
the fourth corner to proceed to seal the unit, use the Teflon block.
Allow unit to cool until it reaches 24 ° C, then you can apply the secondary seal. If in doubt, ask your agent TruSeal. 
TruSeal separators allow the fabrication of a hermetic glass unit double curve. The spacers are EDGETHERM DVH curve or Microseal DS. Not recommended to use the system to have a flexible DURA reduced side.
separator also use requires the application tool PEAK TOOL, especially for such applications.
Because it is difficult to obtain the same curve in both glasses, we recommend the use of secondary seal.
1 - Apply the spacer on the edge of 1 of the curved glass. Peak use tool Tool 
2 - Check the correct application of the separator at the 4 edges of curved glass. 
3 - Assemble second curved glass. Take care that both are framed. 
4 - Apply the clamps on the edge of the unit. 
5 - Place the clips every 150 mm to ensure a charge pair in the perimeter. 
6 - Place the unit curve in a position that allows the heating of the 4 edges. With the heat gun to heat the unit until its edge reaches 45 ° C. Check the temperature with an infrared thermometer. Then, with one foot underground control the total thickness of the unit. Reheat
the fourth corner to proceed to seal the unit, use the Teflon block.
Allow unit to cool until it reaches 24 ° C, then you can apply the secondary seal. If in doubt, ask your agent TruSeal.
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