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.

A 3D shaped packaging product (20) for cushioning and/or thermal insulation of packaged goods is formed by hot pressing at an average pressure equal to or below 200 kPa of an air-laid blank (10) comprising natural fibers at a concentration of at least 70% by weight of the air-laid blank (10) and a thermoplastic polymer binder at a concentration selected within an interval of from 4 up to 30% by weight of the air-laid blank (10). The 3D shaped packaging product (20) has a density that is less than four times a density of the air-laid blank (10) and the density of the 3D shaped packaging product (20) is selected within an interval of from 15 to 240 kg/m.sup.3. The 3D shaped packaging product (20) maintains at least a significant portion of the porosity of the air-laid blank (10) even after hot pressing and therefore provides excellent shock absorbing and damping properties and thermal insulation.

A 3D shaped packaging product (20) for cushioning and/or thermal insulation of packaged goods is formed by hot pressing at an average pressure equal to or below 200 kPa of an air-laid blank (10) comprising natural fibers at a concentration of at least 70% by weight of the air-laid blank (10) and a thermoplastic polymer binder at a concentration selected within an interval of from 4 up to 30% by weight of the air-laid blank (10). The 3D shaped packaging product (20) has a density that is less than four times a density of the air-laid blank (10) and the density of the 3D shaped packaging product (20) is selected within an interval of from 15 to 240 kg/m.sup.3. The 3D shaped packaging product (20) maintains at least a significant portion of the porosity of the air-laid blank (10) even after hot pressing and therefore provides excellent shock absorbing and damping properties and thermal insulation.

Container insulation including a batt comprised of large paper particles, at least 90% of which by weight are greater than 10 mm in diameter. Less than 5% by weight binder fibers are used, which have a length of at least 20 mm. Most preferably, no binder fibers are used. Where the batts are faced with paper, the paper is coated with a biodegradable coating. The resulting product is repulpable and recyclable in accordance with Fiber Box Association (FBA) testing protocols.

Container insulation including a batt comprised of large paper particles, at least 90% of which by weight are greater than 10 mm in diameter. Less than 5% by weight binder fibers are used, which have a length of at least 20 mm. Most preferably, no binder fibers are used. Where the batts are faced with paper, the paper is coated with a biodegradable coating. The resulting product is repulpable and recyclable in accordance with Fiber Box Association (FBA) testing protocols.

Container insulation including a batt comprised of large paper particles, at least 90% of which by weight are greater than 10 mm in diameter. Less than 5% by weight binder fibers are used, which have a length of at least 20 mm. Most preferably, no binder fibers are used. Where the batts are faced with paper, the paper is coated with a biodegradable coating. The resulting product is repulpable and recyclable in accordance with Fiber Box Association (FBA) testing protocols.

Container insulation including a batt comprised of large paper particles, at least 90% of which by weight are greater than 10 mm in diameter. Less than 5% by weight binder fibers are used, which have a length of at least 20 mm. Most preferably, no binder fibers are used. Where the batts are faced with paper, the paper is coated with a biodegradable coating. The resulting product is repulpable and recyclable in accordance with Fiber Box Association (FBA) testing protocols.

A single-walled disposable cooler is provided and generally includes a body and a lid. The body is generally made from a pulp-based material or fiber-based material and includes a base and a plurality of support walls coupled to the base. At least one of the plurality of support walls includes a substantially planar surface. The plurality of support walls and the base define an interior cavity of the body, while the plurality of support walls extend upwardly from the base to form an opening at an upper terminus of the body in fluid communication with the interior cavity. The lid is also made from the pulp-based material or fiber-based material and corresponds with the body. The lid is shaped to cover the opening of the body.

A single-walled disposable cooler is provided and generally includes a body and a lid. The body is generally made from a pulp-based material or fiber-based material and includes a base and a plurality of support walls coupled to the base. At least one of the plurality of support walls includes a substantially planar surface. The plurality of support walls and the base define an interior cavity of the body, while the plurality of support walls extend upwardly from the base to form an opening at an upper terminus of the body in fluid communication with the interior cavity. The lid is also made from the pulp-based material or fiber-based material and corresponds with the body. The lid is shaped to cover the opening of the body.

A process for the manufacture of lignocellulosic fiber-based insulation boards that includes: applying a binder composition to lignocellulosic fibers; forming a lignocellulosic fiber mat by compressing the lignocellulosic fibers impregnated with the binder composition; and heating the compressed lignocellulosic fiber mat so as to obtain a lignocellulosic fiberboard bound by an insoluble and infusible thermoset binder, where the binder composition is an emulsion of a poly(methylene diphenyl isocyanate) (pMDI) in an aqueous phase comprising water and a polyol in dissolved form.