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--- efficiency_now:building_envelope:interiorinsulation:blow_in_interiorinsulation [2022/10/26 12:12] – wfeist
+++ efficiency_now:building_envelope:interiorinsulation:blow_in_interiorinsulation [2022/10/26 12:27] (current) – [Typical connection details: airtight and thermal bridge minimised] wfeist
@@ Line 22: / Line 22: @@
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-Step 4: cover the inner side with OSB or chipboards. This can also be done quite quickly today using a cordless screwdriver, dismantling again can then be done easily if needed. For even faster work, an electric stapler can be used since there is no reason why the construction should ever be dismantled. It will become an integral part of the exterior wall and in Germany such walls often remain functional for more than a hundred years. The materials used here are not "disposable products"((Like a single-use plastic or paper cup which is thrown away after 10 minutes. In the present discussion, this difference is a fundamental error. Large sections of the industry will obviously desire short usage durations, and our tutorials here aim for exactly the opposite: permanent solutions, which provide benefits even for many generations. Unfortunately, this is often misunderstood even by environmentalists: durability is rarely emphasised, even then only when  it comes to products like natural stones. Meanwhile, this is the (second) most important goal (according to the ppp) for sustainable construction. )) . Interestingly, the most important resource here is recycled paper - that is a product that has already been used  (once, for a short time) - which is now "stored" and therefore escapes being burnt (CO2!) and in this way contributes even further to climate protection. \\
+Step 4: cover the inner side with OSB or chipboards. This can also be done quite quickly today using a cordless screwdriver, dismantling again can then be done easily if needed. For even faster work, an electric stapler can be used since there is no reason why the construction should ever be dismantled. It will become an integral part of the exterior wall and in Germany such walls often remain functional for more than a hundred years. The materials used here are not "disposable products"((Like a single-use plastic or paper cup which is thrown away after 10 minutes. In the present discussion, this difference is a fundamental error. Large sections of the industry will obviously desire short usage durations, and our tutorials here aim for exactly the opposite: permanent solutions, which provide benefits even for many generations. Unfortunately, this is often misunderstood even by environmentalists: durability is rarely emphasised, even then only when  it comes to products like natural stones. Meanwhile, this is the (second) most important goal (according to life cycle analysis of green house gas emissions) for sustainable construction. )) . Interestingly, the most important resource here is recycled paper - that is a product that has already been used  (once, for a short time) - which is now "stored" and therefore escapes being burnt (CO2!) and in this way contributes even further to climate protection. \\
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-Step 6: Drill holes for the loose-fill insulation. This can also be left to the company that will install the loose-fill insulation, because it is very fast and these experts know best where holes should be placed and what size they need to be. \\ \\ \\ \\ \\ \\
+Step 6: Drill holes for the blown-in insulation. This can also be left to the company that will install the insulation, because it is very fast and these experts know best where holes should be placed and what size they need to be. \\ \\ \\ \\ \\ \\
 Step 7: Commission the company for installation of capillary-active insulation material (e.g. cellulose flakes). This is usually a small self-employed trade business that works in the region. If it is an established company it will probably be a member of a [[https://www.fved.net/|professional association for cavity insulation (German only)]]((The Passive House Institute does not have commercial interests in any suppliers or providers of services, neither small businesses (usually family enterprises which have our support) nor large scale industries e.g. manufacturers of floatglass. However, these are businesses whose products and services do actually constribute to sustainability, and are not just a "greenwash" like "sustainable natural gas" for example.)) .
-Loose-fill insulation can now be blown-in:
+The insulation can now be blown-in:
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-Apart from the detail connections and the "finishing" (wallpaper or coat of paint), the interior insulation is now complete. ((Note: This was carried out by a team of normally sedentary/desktop scientists at the PHI within a few days. Measurements (temperature and humidity) were also carried out once again inside the constructions; however, we know from previous projects that this works as executed and recommended due to long-term monitoring of interior insulation. Rumours about structural damage are due to the following: 1) extremely incorrectly implemented measures, often unintentionally (e.g. "air flow behind interior insulation", a planned disaster which was even recommended by some building ecologists for a while in ignorance of the elementary laws of physics), and intractable myths relating to construction (which likewise are based on the  refusal to acknowledge physical facts and make effective use of these in practice). Entirely independently from us, Rüdiger Paschotta has examined these issues again in detail. However, since Maxwell's book "Theory of Heat", this has been established knowledge for many decades in building physics and thermodynamics generally. As Claas Bankvall, [Bankvall, C. (1969) Research in heat transfer] once said: "Haven't we done anything or can't they read?" ))
+Apart from the detail connections and the "finishing" (wallpaper or coat of paint), the interior insulation is now complete. ((Note: This was carried out by a team of normally 'desktop' scientists at the PHI within a few days. Measurements (temperature and humidity) were also carried out once again all along theconstruction; however, we know from previous projects that this works as executed and recommended due to long-term monitoring of interior insulation. Rumours about structural damage are due to the following: 1) extremely incorrectly implemented measures, sometimes even intentionally (e.g. "air flow behind interior insulation", a planned disaster which was even recommended by some 'building-biologists' for a while in ignorance of the elementary laws of physics), and intractable myths relating to construction (which likewise are based on the  refusal to acknowledge physical facts and make effective use of these in practice). Entirely independently from us, Rüdiger Paschotta has examined these issues again in detail. However, since Maxwell's book "Theory of Heat", this has been established knowledge for many decades in building physics and thermodynamics generally. As Claas Bankvall, [Bankvall, C. (1969) Research in heat transfer] once said: "Haven't we done anything or can't they read?" ))
 ==== Typical connection details: airtight and thermal bridge minimised  ====
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 === Connection: Interior wall to interior insulation of exterior wall ===
-Key word: 40 cm flanking insulation  or insulation ((But this would require a lot of effort)) wedge; an insulation wedge made of wood fibre insulation or some other capillary-active material can be used in this case!
+Key word: 20 to 40 cm flanking insulation  or insulation ((But this would require a lot of effort in this case if made in the same type of construction; what we do not recommend)) wedge; an insulation wedge made of wood fibre insulation or some other capillary-active material can also be used in this case; even any conventional insulation wdge will be a solution, because we do nat have an vapour diffusion issue here, it is all just about interior surface temperatures.
 === Connection: Ceiling to interior insulation of exterior wall ===
-Key word: The most obvious solution here is again a capillary-active insulation wedge!
+Key word: The most obvious solution here is again an  insulation wedge!
 === Connection: Window to interior insulation of the window reveal ===
-Key word: basically the window reveal must ALSO be insulated when interior insulation is carried out. The wall surfaces would otherwise become too cold - causing damp spots. Space is always available for 20 mm capillary-active insulation material; but even if that is not possible, the capillary-active insulation wedge is a solution for this as well.
+Key word: basically the window reveal must ALSO be insulated when interior insulation is carried out. The wall surfaces would otherwise become too cold - causing damp spots. Space is always available for 20 mm capillary-active insulation material; but even if that is not possible, any insulation wedge is a solution for this as well.
 === No abrupt end with interior insulation! ===