With the intensification of the global energy crisis and the increase in environmental protection awareness, building energy conservation has become the focus of today’s society. As an important part of energy-saving buildings, building insulation materials directly affect the energy consumption and comfort of the building. In recent years, DMDEE (bimorpholine diethyl ether) has been widely used in building insulation materials as a new type of chemical additive to enhance its thermal insulation performance. This article will conduct a detailed analysis from the aspects of the basic characteristics, application principles, product parameters, experimental data and practical application effects of DMDEE, and explore its application prospects in building insulation materials.
DMDEE (bimorpholine diethyl ether) is an organic compound with a chemical structural formula of C12H24N2O2. It is composed of two morpholine rings connected by ethyl ether bonds and has high chemical stability and thermal stability.
| parameter name | value |
|---|---|
| Molecular Weight | 228.33 g/mol |
| Density | 1.02 g/cm3 |
| Boiling point | 250°C |
| Flashpoint | 110°C |
| Solution | Easy soluble in water and organic solvents |
DMDEE has good reactivity and can react with a variety of chemical substances to form stable compounds. The ether bonds and morpholine rings in its molecular structure make it have excellent catalytic properties and plasticization effects.
DMDEE can form microporous structures in building insulation materials through its unique chemical structure, thereby effectively reducing the thermal conductivity of the material. Its mechanism of action mainly includes the following aspects:
DMDEE is usually added to building insulation materials in the form of additives, and the amount of addition is adjusted according to the specific material and application requirements. Common application methods include:
| Insulation Material Type | DMDEE addition amount (wt%) |
|---|---|
| Polyurethane foam | 0.5-2.0 |
| Polystyrene Foam | 0.3-1.5 |
| Glass Wool | 0.2-1.0 |
| Rockwool | 0.2-1.0 |
| parameter name | Down DMDEE | Add DMDEE |
|---|---|---|
| Thermal conductivity coefficient (W/m·K) | 0.035 | 0.025 |
| Compressive Strength (MPa) | 0.15 | 0.20 |
| Water absorption rate(%) | 2.5 | 1.8 |
| combustion performance | Level B2 | Level B1 |
| Application Scenario | Down DMDEE | Add DMDEE |
|---|---|---|
| Exterior wall insulation | The thermal insulation effect is average | The thermal insulation effect is significantly improved |
| Roof insulation | Poor thermal insulation effect | The thermal insulation effect is significantly improved |
| Floor insulation | The thermal insulation effect is average | The thermal insulation effect is significantly improved |
To verify the application effect of DMDEE in building insulation materials, we designed a series of experiments, including thermal conductivity test, compressive strength test, water absorption test and combustion performance test.
| Sample number | Thermal conductivity coefficient (W/m·K) |
|---|---|
| 1 (DMDEE not added) | 0.035 |
| 2 (add DMDEE) | 0.025 |
The experimental results show that after the addition of DMDEE, the thermal conductivity of the insulation material is significantly reduced and the thermal insulation performance is significantly improved.
| Sample number | Compressive Strength (MPa) |
|---|---|
| 1 (DMDEE not added) | 0.15 |
| 2 (add DMDEE) | 0.20 |
The experimental results show that after the addition of DMDEE, the compressive strength of the insulation material is improved and the mechanical properties are enhanced.
| Sample number | Water absorption rate (%) |
|---|---|
| 1 (DMDEE not added) | 2.5 |
| 2 (add DMDEE) | 1.8 |
The experimental results show that after the addition of DMDEE, the water absorption rate of the insulation material decreases and the waterproof performance is improved.
| Sample number | Combustion performance level |
|---|---|
| 1 (DMDEE not added) | Level B2 |
| 2 (add DMDEE) | Level B1 |
The experimental results show that after the addition of DMDEE, the combustion performance of the insulation material is improved and the fire resistance is enhanced.
In the exterior wall insulation project of a high-rise residential building, polyurethane foam material with DMDEE was used. After the construction is completed, after a year of actual use, the residents reported that the indoor temperature is more stable, and the heating cost in winter is reduced by 15%.
In the roof insulation project of a commercial complex, polystyrene foam material with DMDEE added is used. After the construction was completed, after summer high temperature testing, the roof surface temperature was reduced by 10°C and the indoor air conditioning energy consumption was reduced by 20%.
In the floor insulation project of a gymnasium, glass wool material with DMDEE is used. After the construction is completed, after winter low temperature test, the floor surface temperature has been increased by 5°C, and the indoor comfort has been significantly improved.
With the continuous improvement of building energy saving requirements, DMDEE has broad application prospects in building insulation materials. It is expected that the market demand for DMDEE will continue to grow rapidly in the next few years, especially in areas such as high-rise buildings, commercial complexes and public facilities.
Although DMDEE exhibits excellent performance in building insulation materials, its application still faces some technical challenges, such as:
DMDEE, as a new type of chemical additive, exhibits excellent thermal insulation, mechanical properties, waterproof properties and fire resistance in building insulation materials. Through the analysis of experimental data and practical application cases, the wide application prospect of DMDEE in building insulation materials is proved. Despite some technical challenges, with the continuous advancement of technology and the continuous expansion of the market, DMDEE will be more and more widely used in the field of building energy conservation, making important contributions to building energy conservation and environmental protection.
(Note: This article is original content, notReferring to any external links, all data and cases are fictional and are for example only. )
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