The invention describes a method of printing onto a balloon that includes the steps of: coating the printable outer surface of a balloon with a primer material; attaching the balloon about a supporting substrate to form a balloon blank; flattening the printable outer surface of the balloon on the upper surface of the substrate; attaching a first tab on a first end of the balloon blank; attaching a second tab on a second end opposite the first end of the balloon blank; applying the balloon blank to a printer, via the first tab, which in use prints a first image onto the printable surface; and moving the balloon blank back through the printer via the second tab, which in use prints a second image onto the printable surface.

The invention describes a method of printing onto a balloon that includes the steps of: coating the printable outer surface of a balloon with a primer material; attaching the balloon about a supporting substrate to form a balloon blank; flattening the printable outer surface of the balloon on the upper surface of the substrate; attaching a first tab on a first end of the balloon blank; attaching a second tab on a second end opposite the first end of the balloon blank; applying the balloon blank to a printer, via the first tab, which in use prints a first image onto the printable surface; and moving the balloon blank back through the printer via the second tab, which in use prints a second image onto the printable surface.

A urea granulation process with a scrubbing system may involve at least one gaseous waste stream for removal of dust and ammonia whereby the waste stream may be processed through a combination of process steps. In some examples, the process steps may involve washing the dust and ammonia laden stream with water and/or an aqueous urea solution whereby a dust-laden liquid stream and a dust-reduced stream is generated. The process steps may further involve reacting the dust-reduced stream with formaldehyde to form a stream comprising hexamethylenetetramine and urea-formaldehyde and clean off-gas. In some cases, the gas stream may be directed first through the washing step and then through the reacting step.

A urea granulation process with a scrubbing system may involve at least one gaseous waste stream for removal of dust and ammonia whereby the waste stream may be processed through a combination of process steps. In some examples, the process steps may involve washing the dust and ammonia laden stream with water and/or an aqueous urea solution whereby a dust-laden liquid stream and a dust-reduced stream is generated. The process steps may further involve reacting the dust-reduced stream with formaldehyde to form a stream comprising hexamethylenetetramine and urea-formaldehyde and clean off-gas. In some cases, the gas stream may be directed first through the washing step and then through the reacting step.

Disclosed are methods of recovering urea from a urea/oil complex by drying the complex, combining the complex with water to form a urea solution, and removing water from the urea solution. Methods for recycling the urea in urea complexation processes are also disclosed. Also disclosed are methods of recovering polyunsaturated fatty acids or derivatives thereof from the urea/oil complexes.

Disclosed are methods of recovering urea from a urea/oil complex by drying the complex, combining the complex with water to form a urea solution, and removing water from the urea solution. Methods for recycling the urea in urea complexation processes are also disclosed. Also disclosed are methods of recovering polyunsaturated fatty acids or derivatives thereof from the urea/oil complexes.

A process for preparing urea comprises preparing formamide based on carbon dioxide, hydrogen, and ammonia, forming methyl formate or ammonium formate as an intermediate in a catalytic reaction, and preparing urea by reacting the formamide and possibly ammonia in the presence of a catalyst. The source of carbon dioxide is a liquid laden with chemically and/or physically bound carbon dioxide and selected from a methanol phase or an aqueous ammonia solution obtained by gas scrubbing of a syngas for removing carbon dioxide using a scrubbing fluid. The scrubbing fluid can be a methanol phase, or carbon dioxide is desorbed from the scrubbing fluid and absorbed into a methanol phase to give a carbon dioxide-laden methanol phase that is then reacted as carbon dioxide-containing stream with a hydrogen-containing stream in the presence of a catalyst to form methyl formate. The methyl formate is reacted with an ammonia-containing stream to form formamide.

A process for preparing urea comprises preparing formamide based on carbon dioxide, hydrogen, and ammonia, forming methyl formate or ammonium formate as an intermediate in a catalytic reaction, and preparing urea by reacting the formamide and possibly ammonia in the presence of a catalyst. The source of carbon dioxide is a liquid laden with chemically and/or physically bound carbon dioxide and selected from a methanol phase or an aqueous ammonia solution obtained by gas scrubbing of a syngas for removing carbon dioxide using a scrubbing fluid. The scrubbing fluid can be a methanol phase, or carbon dioxide is desorbed from the scrubbing fluid and absorbed into a methanol phase to give a carbon dioxide-laden methanol phase that is then reacted as carbon dioxide-containing stream with a hydrogen-containing stream in the presence of a catalyst to form methyl formate. The methyl formate is reacted with an ammonia-containing stream to form formamide.

A process for the co-production of methanol and ammonia is described comprising the steps of: (a) forming a first synthesis gas stream by reacting a first portion of a hydrocarbon feedstock and steam in a steam reformer, (b) forming a second synthesis gas stream in parallel to the first synthesis gas stream by reacting a second portion of the hydrocarbon feedstock with an oxygen-containing gas and steam in an autothermal reformer, (c) synthesising methanol from a first process gas comprising the first synthesis gas stream, and (d) synthesising ammonia from a second process gas prepared from the second synthesis gas stream, wherein a purge stream containing hydrogen is recovered from the methanol synthesis step (c) and a portion of the purge gas stream is fed to the autothermal reformer and/or the second synthesis gas in step (b).

A method of producing a polyamine compound, the method including: a first step of generating a polyurea compound by reacting a thiourethane resin and an amine compound A with each other; and a second step of generating a polyamine compound by reacting the polyurea compound and an amine compound B with each other.