The disclosure discloses a method for preparing a multifunctional ecological exterior wall, including: preparing a ceramic board of a ceramic thermal insulation waterproof layer; preparing a ceramic sound-absorbing board of a sound-absorbing layer; and installing a ecological exterior wall: leveling a surface of the wall of a building with cement slurry, and applying a cement bonding layer thereon; laying the ceramic thermal insulation waterproof board on the cement bonding layer, and applying the cement bonding layer on the ceramic board; laying the ceramic sound-absorbing board on the cement bonding layer and reserving a gap used to place a pipe; driving the screw-thread steel bolt from the surface of the ceramic sound-absorbing board into the wall obliquely; installing and fixing the pipe in the gap, which is reserved at the upper of the ceramic sound-absorbing board; planting a green plant on the surface of the ceramic board of the sound-absorbing layer.

The present invention relates to thermal insulation materials, particularly to environmentally friendly thermal insulation materials, manufacturing of which involves recycled raw materials and hemp fibres. The thermal insulation material described in the invention further comprises bi-component binder and conservation additive.

Disclosed is an insulation product comprising hemp fibres bonded together using one or more biopolymers. Hemp fibres having lengths of between 5 and 100 mm amount to at least 50% by weight of the product. A hemp containing insulating batt or board may be made from opened hemp fibres, opened biopolymer binder fibres, mixing to produce a mixture in which the components are dispersed, air-laying the mixture, heating to above the melting point of the biopolymer binder fibres, forming to a desired thickness or density; and cooling

Disclosed are biodegradable insulation materials comprising a structural scaffold; and at least one temperature resilient fungus. Also disclosed are methods of making and using biodegradable insulation materials comprising a structural scaffold; and at least one temperature resilient fungus. For example, disclosed are methods of insulating an infrastructure comprising administering the disclosed biodegradable insulation materials to an infrastructure.

A construction material structure, comprising a plurality of inner support columns, the support columns being fixtured at the top end portion and/or the bottom end portion in a generally parallel, spaced apart arrangement, a polymeric film stretched across a first side and an opposite second side of the support columns, a quick cure polymeric fibrous material formed on the outer surface of the stretched polymeric film, and a polymeric foam disposed between the support columns and the stretched polymeric film.

A composite stone panel (1) is provided. The composite stone panel (1) comprises a front panel and a backing panel. The back of the front panel comprises a counter-relief image (11) filled with a light-transmitting reinforcing filler and is attached to the backing panel. The backing panel comprises a light source (6) or an opening for receiving the light source (6). The light source (6) or opening is positioned to transmit light towards the counter-relief image (11). A relief (3) is then formed at the front of the composite stone panel (1). The relief (3) is positioned opposite to the counter-relief image (11).

A method of making a structural lightweight and thermal insulating concrete is described. The concrete has a coarse aggregate partly replaced by recycled plastic pieces. This enables the concrete to maintain a high compressive strength, low thermal conductivity, and low weight, while providing a use for waste plastic. The waste plastic pieces may comprise polyethylene in the form of flakes, fibers, or granules. Due to its low unit weight, adequate compressive strength and high thermal resistance the developed concrete can be used as a structural lightweight and thermal insulating concrete. The use of this concrete leads to economic and environmental benefits.

The summary of the utility model describes a light mineral organic insulation product that is characterized by the modification of elements found in nature and the environment which, through the process described above, lead us to obtain this insulation which Due to its characteristics and composition of the elements described and its great advantages in the use of resources that are polluting to the environment, it will generate a great impact in the construction industry because, among other advantages, costs are considerably reduced, as well as the times of installation which will optimize human resources saving man-hours because its installation is extremely simple and the materials are light and manageable.

This isolation aims to strongly promote a new generation of less aggressive proposals for the planet that will have repercussions for the benefit of future generations.

A method of recycling expanded polystyrene foam into flexible insulation elements that are made from 100% recycled material.

The invention relates to a heat insulating element (4) for an interior insulation, a facade insulation, a roof insulation, or the like at a building (1), comprising an insulating body (41) which is of diffusion-open design. The heat insulating element (4) is characterized in that it further comprises a fabric (42), especially a fleece, which is of capillary-active design, and that the fabric (42) is arranged on a surface of the insulating body (41). Furthermore, the invention relates to a building construction, to a method for avoiding moisture damage at a building (1), and to the use of a heat insulating element of this type. This achieves an improved heat insulating element (4) for avoiding moisture damage at a building (1) by means of which it is possible to accelerate drying of the region concerned in the case of the accumulation of water, especially condensation water, with simple means. Furthermore, an appropriate building construction is provided in which moisture damage can be avoided more reliably, and an improved method for avoiding moisture damage at a building (1) is provided.