Method for operating a printhead for a 3D printer and printhead for a 3D printer for carrying out the method

What is claimed is: 1 . A method ( 200 ) for operating a printhead ( 100 ) for a 3D printer, wherein the method ( 200 ) comprises the following steps: filling ( 210 ) a cavity ( 40 ) with printable material ( 10 ) by a feed device ( 2 ); closing ( 220 ) an opening cross-section ( 21 ) of a piston bushing ( 4 ) by advance of a piston ( 3 ) starting from a starting position ( 3 a ) in a direction of a nozzle ( 8 ) of the printhead ( 100 ); converting ( 230 ) the material from a solid phase ( 10 ) via a plastic phase ( 11 ) into a liquid phase ( 12 ); compressing ( 240 ) the material ( 10 , 11 , 12 ); determining ( 250 ) a spring constant of the liquid phase ( 12 ); print preparation ( 260 ) of the liquid phase ( 12 ); dispensing ( 270 ) the liquid phase ( 12 ) of the material ( 10 ) from the nozzle ( 8 ) for printing a three-dimensional component ( 9 ); returning ( 280 ) the piston ( 3 ) to the starting position ( 3 a ) and repeating ( 290 ) the steps ( 210 ) to ( 280 ) until terminating the method ( 200 ), wherein the compressing ( 240 ) of the material ( 10 , 11 , 12 ) comprises the following steps: pre-compressing ( 610 ) of the material ( 10 , 11 , 12 ) by advancing the piston ( 3 ), closing ( 620 ) the nozzle ( 8 ), compressing ( 630 ) of the material ( 10 , 11 , 12 ) by advancing the piston ( 3 ) and holding ( 640 ) the piston ( 3 ) in a holding position ( 3 d ). 2 . The method ( 200 ) according to claim 1 , wherein at least the closing ( 220 ), the converting ( 230 ), the compressing ( 240 ), the determining ( 250 ) of the spring constant, the print preparation ( 260 ) and the dispensing ( 270 ) are performed by an active regulation of an actuator device ( 110 ) by a control and regulation unit ( 113 ), wherein results from an evaluation unit ( 114 ) based on measured values of sensors ( 36 , 82 , 83 , 111 , 112 ) are transmitted to the control and regulation unit ( 113 ). 3 . The method ( 200 ) according to claim 1 , wherein filling ( 210 ) of the cavity ( 40 ) with printable material ( 10 ) by the feed device ( 2 ) comprises at least the following steps: feeding ( 310 ) the material ( 10 ) via an opening ( 23 ) of the feed device ( 2 ) into the printhead ( 100 ) and generating ( 320 ) air pulses ( 26 ) to detach granulate pieces ( 10 ) of the material 10 from each other. 4 . The method ( 200 ) according to claim 3 , wherein the filling ( 310 ) of the granulate pieces ( 10 ) is performed manually or automatically, wherein the granulate pieces ( 10 ) slide into a lower area ( 24 ) of the feed device ( 2 ) due to gravity. 5 . The method ( 200 ) according to claim 4 , wherein the generation ( 320 ) of air pulses ( 26 ) is carried out at intervals and the granulate pieces ( 10 ) are flung up in an area of the air pulses ( 26 ) in such a way that, as the granulate pieces ( 10 ) fall, they exert an impulse on the granulate pieces ( 10 ) lying underneath and encourage the granulate pieces ( 10 ) to slide into the cavity ( 40 ) of the printhead ( 100 ). 6 . The method ( 200 ) according to claim 1 , wherein the closing ( 220 ) of the opening cross-section ( 21 ) of the piston bushing ( 4 ) by the piston ( 3 ) comprises the following steps: advancing ( 410 ) the piston ( 3 ), starting from the starting position ( 3 a ) of a piston crown ( 35 ) of the piston ( 3 ) in the direction of the nozzle ( 8 ) until a position ( 3 b ) below a gate ( 44 ) of the piston bushing ( 4 ) is reached, wherein a shearing ( 420 ) of granulate pieces ( 10 ) is achieved by the piston crown ( 35 ) sliding past the gate ( 44 ). 7 . The method ( 200 ) according to claim 1 , wherein the converting ( 230 ) of the material from a solid phase ( 10 ) via a plastic phase ( 11 ) to a liquid phase ( 12 ) comprises the following steps: heating ( 510 ) the material ( 10 , 11 , 12 ) by heating elements ( 61 , 63 ) of a nozzle head ( 6 ) across state zones (A, B, C, D, E) of the printhead ( 100 ), wherein the state zones (A, B, C, D, E) represent an aggregate state of the material ( 10 ) depending on temperature T S , and an aggregate state of the material ( 10 , 11 , 12 ) is changed across the state zones (A, B, C, D, E) from a solid phase ( 10 ) via a plastic phase ( 11 ) into a liquid phase ( 12 ) by introduction of heating energy of the heating elements ( 61 , 63 ) and mixing ( 520 ) the material ( 11 , 12 ) during compressing ( 240 ). 8 . The method ( 200 ) according to claim 1 , wherein the pre-compressing ( 610 ) of the material ( 10 , 11 , 12 ) is performed by advancing the piston ( 3 ) in a pressure-and/or force-controlled manner, wherein pre-compressing is performed up to a position ( 3 c ) that is reached when a material-dependent gradient, and/or a material-dependent gradient angle of a force, and/or a pressure curve is reached and/or exceeded. 9 . The method ( 200 ) according to claim 1 , wherein the compressing ( 630 ) of the material ( 10 , 11 , 12 ) is performed in a pressure-controlled manner by advancing the piston ( 3 ) with the nozzle ( 8 ) closed, and the holding position ( 3 d ) is thereby approached until a peak pressure (p d ) is reached. 10 . The method ( 200 ) according to claim 1 , wherein, during compressing ( 630 ), the nozzle ( 8 ) is closed and a piston needle ( 32 ) dips into a melt cavity ( 81 ) of a nozzle head ( 6 ) such that a part of the liquid phase ( 12 ) from an upper area of the melting cavity ( 81 ) is thereby displaced through openings ( 71 ) of a kidney piece ( 7 ) from a melting zone (D) back into a mixing zone (C), whereby the part of the liquid phase ( 12 ) mixes with the plastic phase ( 11 ) from a plasticizing zone (B) in the mixing zone (C). 11 . The method ( 200 ) according to claim 1 , wherein a pressure (P L ) and a temperature (T L ) of the liquid phase ( 12 ) are measured during the holding process ( 640 ), and wherein the measurements of the pressure (P L ) and the temperature (T L ) of the liquid phase ( 12 ) are checked by an evaluation unit ( 114 ) for functional control of the compressing process ( 240 ). 12 . The method ( 200 ) according to claim 1 , wherein, while the piston ( 3 ) is held ( 640 ) in the holding position ( 3 d ), the nozzle ( 8 ) is closed and a piston needle ( 32 ) is immersed in a melt cavity ( 81 ) such that a part of the liquid phase ( 12 ) from an upper area of the melting cavity ( 81 ) is thereby displaced through openings ( 71 ) of a kidney piece ( 7 ) from a melting zone (D) back into a mixing zone (C), whereby the part of the liquid phase ( 12 ) mixes with the plastic phase ( 11 ) from a plasticizing zone (B) in the mixing zone (C). 13 . The method ( 200 ) according to claim 1 , wherein the determining ( 250 ) of a spring constant of the liquid phase ( 12 ) comprises the following steps: pressure-controlled return ( 710 ) from the holding position ( 3 d ) after terminating the holding process ( 640 ) to a target position ( 3 e ), which is reached when a melt pressure (P L ) reaches a target pressure (p e ), determining a pressure difference ( 720 ) between a peak pressure (p d ) and the target pressure (p e ), determining a distance ( 730 ) between the holding position ( 3 d ) and the target position ( 3 e ), and calculating the spring constant ( 740 ) of the liquid phase ( 12 ). 14 . The method ( 200 ) according to claim 1 , wherein the print preparation ( 260 ) of the liquid phase ( 12 ) comprises the following steps: active decompression ( 810 ) of the liquid phase ( 12 ) by retracting the piston ( 3 ) as a function of the spring constant, opening ( 820 ) nozzle ( 8 ) and compressing (