Systems and methods for manufacturing pigmented radiation curable inks for ink-based digital printing

What is claimed is: 1. A method of continuously producing radiation-curable liquid ink, comprising: heating a first section of a mixing chamber of a mixer to a first temperature of at least 60 degrees Celsius to 90 degrees Celsius; continuously providing ink ingredients to a first end of the mixing chamber, the ingredients being selected for forming a pigment concentrate liquid paste of a radiation-curable liquid ink product; blending the ink ingredients at the first section of the mixing chamber downstream the first end toward a second end of the mixing chamber to form the pigment concentrate liquid paste in the mixing chamber, the pigment concentrate liquid paste being a blended combination of all ingredients provided to the mixing chamber while keeping all ingredients in the mixing chamber, the pigment concentrate liquid paste having a pigment particle diameter of about 1 micron or less; conveying the pigment concentrate liquid paste to a second section of the mixing chamber downstream the first section towards the second end and opposite the first end; cooling the second section of the mixing chamber to a second temperature less than the first temperature; conveying the pigment concentrate liquid paste to a third section of the mixing chamber downstream the second section toward the second end of the second mixing chamber; feeding additional ink ingredients into the third section of the mixing chamber, the ingredients comprising at least one of low-viscosity monomers, oligomers, mixtures thereof, and leveling agent; heating the third section of the mixing chamber to the first temperature; and blending the pigment concentrate liquid paste and the additional ink ingredients in the third section to produce the radiation-curable liquid ink product by conveying the ink ingredients toward the second end for continuous output from the mixer. 2. The method of claim 1 , the providing ingredients further comprising: feeding the ingredients into a mixing chamber of the mixer at a feed port at the first end of the mixing chamber, the ingredients comprising pigment and at least one of monomers, oligomers, dispersant, thermal stabilizer, and viscosity modifier, the viscosity modifier being selected from at least one of clay and silica. 3. The method of claim 1 , where the heating the mixing chamber to the first temperature of at least 60 degrees Celsius to 90 degrees Celsius includes: pre-heating the mixing chamber to a temperature lying in range of at least 60 degrees Celsius to 90 degrees Celsius. 4. The method of claim 1 , wherein the mixing chamber first temperature lies in a range of at least 60 degrees Celsius to 90 degrees Celsius during the blending, and wherein a die head pressure of the mixing chamber lies in a range of 2 to 100 psi. 5. The method of claim 1 , the method being a continuous method without limit to a particular batch amount with the ink ingredients provided to the first end being output from the second end in less than one minute. 6. The method of claim 1 , further comprising outputting the radiation-curable liquid ink product from the mixing chamber at the second end. 7. The method of claim 1 , further comprising cooling the mixing chamber back to the second temperature for discharge of the cooled radiation-curable liquid ink product. 8. The method of claim 1 , the providing ink product ingredients to a first end of a mixing chamber further comprising: feeding at least one of low-viscosity monomers, oligomers, mixtures thereof, and leveling agent to the mixing chamber. 9. The method of claim 1 , further comprising: cooling the radiation-curable liquid ink product by cooling the mixing chamber to the second temperature; and outputting the cooled radiation-curable liquid ink product from the mixer. 10. The method of claim 9 , comprising: processing the radiation-curable liquid ink product using a 3-roll mill. 11. The method of claim 1 , the providing ingredients further comprising: feeding the ingredients into a mixing chamber of the mixer at a feed port at the first end of the mixing chamber, the ingredients including pigment and a viscosity modifier, the viscosity modifier including a monomer. 12. The method of claim 1 , further comprising: feeding additional ink ingredients to the mixing chamber for mixing with the pigment concentrate liquid paste, the additional ink ingredients including a low viscosity monomer added to the pigment concentrate liquid paste to decrease a viscosity of the pigment concentrate liquid paste; and blending the additional ink ingredients with the pigment concentrate liquid paste in the mixing chamber to produce the radiation-curable liquid ink product having a lower viscosity than the pigment concentrate liquid paste, the radiation-curable liquid ink product being a blended combination of the pigment concentrate liquid paste and the additional ink ingredients while keeping all of the ingredients in the mixing chamber. 13. A method of continuously producing radiation-curable liquid ink, comprising: heating a mixing chamber of a mixer to a first temperature of at least 60 degrees Celsius to 90 degrees Celsius; providing ink ingredients to a first end of the mixing chamber, the ingredients being selected for forming a pigment concentrate liquid paste of a radiation-curable liquid ink product, the providing ink ingredients including continuously feeding the ingredients into a mixing chamber of the mixer at a feed port at the first end of the mixing chamber, the ingredients including pigment and a viscosity modifier, the viscosity modifier including a monomer; blending the ink ingredients by conveying the ingredients toward a second end of the mixing chamber to form the pigment concentrate liquid paste in the mixing chamber, the pigment concentrate liquid paste being a blended combination of all ingredients provided to the mixing chamber while keeping all of the ingredients in the mixing chamber, the pigment concentrate liquid paste having a pigment particle diameter of about 1 micron or less; cooling the second end of the mixing chamber to a second temperature less than the first temperature to cool the pigment concentrate liquid paste; conveying the pigment concentrate liquid past from the second end to the mixing chamber to the feed port at the first end of the mixing chamber; reheating the mixing chamber to the first temperature; feeding additional ink ingredients to the mixing chamber for mixing with the pigment concentrate liquid paste, the additional ink ingredients including a low viscosity monomer added to the pigment concentrate liquid paste to decrease a viscosity of the pigment concentrate liquid paste; blending the additional ink ingredients with the pigment concentrate liquid paste in the mixing chamber to produce the radiation-curable liquid ink product at the second end of the mixing chamber, the radiation-curable liquid ink product configured for ink-based digital printing, the radiation-curable liquid ink product having a lower viscosity than the pigment concentrate liquid paste and being a blended combination of the pigment concentrate liquid paste and the additional ink ingredients without disposal of any ingredients out of the mixing chamber; and cooling the second end of the mixing chamber to the second temperature for cooling and continuous discharge of the radiation-curable liquid ink product, wherein the ink ingredients provided to the first end of the mixer are discharged from the second end in less than one minute.