CLOG RESISTANT PRINT HEAD METHOD FOR HIGH SPEED CEMENTITIOUS MATERIAL 3D PRINTING

Abstract

An Advanced Additive Construction device to extrude layers of cementitious material consistently and accurately with an anti-clogging method is disclosed. The device introduces low continuous frequency sonic vibrations with frequency range of 20- to 10000 Hz to slow cement or binding agents from curing the mixture inside the extruder and to get rid of air bubbles trapped in the mixture. Buildup of early cured mixtures inside the extruder tract especially in large volume or long period prints result in accumulation of material inside the extruder tract which causes extruder clogging. A shaker plate coupled with four miniature shakers excite the material mixture inside the extruder orthogonal to the inner casing direction. Furthermore, four more miniature shakers equipped with extension rods excite the material mixture inside the extruder orthogonal to the top mount, thereby preventing any cementitious material sticking within the extruder casing and around the central flight auger. Moreover, increasing the print speed and flow rate of the extruder by 60% which results in cutting the print time to more than 70% when counting the elimination of clogging. Also, it allows the extruder to accommodate a wider range of cementitious mixtures without the need to adjust admixtures and setting times especially for mixtures that have a rapid setting rate. The shaker's vibrating system, FIG. 7, functions within the upper chamber of the extruder casing, the upper chamber has the largest diameter as it operates as a flow control reservoir, which has less pressure compared to the lower chamber of the extruder. The vibrating rods and inner wall system prevent cementitious material from sticking to the extruder inner walls and allows smooth continuous flow of material.

Claims

1. An extruder for cementitious material 3D printing, comprising: a. Motor-driven flight auger for extrusion; b. An extruder casing body with transitioning cones; and, c. Vibration modules with decouplers that isolate the vibration from the rest of the system.

2. The vibration modules of claim 1 for the application of: a. Introduce Sonic perturbations excited via the vibration modules with a frequency range of 20-10000 Hz. b. The vibrations slow cementitious material curing and hence from clogging the extruder tract for the purpose of 3D printing; c. Control and tune the translation velocity of materials inside the extruder from the inlet to the outlet; and, d. Smoother extrusion of materials due to vibrations within extruder inner parts which makes it possess anti-sticking ability where the mixtures will not stick to the inner walls of the extruder casing; and e. Introducing vibrations to the cementitious material inside the extruder without affecting the overall print head motion via decouplers. f. Exciting the mixtures increases motion of the mixture particles and thus, the ability to perform high speed extrusion for mixtures with fast setting rate.

3. The integration of and the method of integrating the vibration modules of claim 1 to a flight auger-based extruder for 3D printing, where the induced vibration is: a. At localised region of the extruder for effective coverage; and, b. Adjustable for different materials properties, operational environment, and purposes

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

[0013] FIG. 1 Isometric view of the final assembly of the extruder

[0014] FIG. 2 Wireframe view of the extruder assembly without the feeding duct, central flight auger and auger motor module

[0015] FIG. 3 Cross sectional view of the extruder assembly

[0016] FIG. 4 Outer view of the extruder assembly

[0017] FIG. 5 Wireframe view of the complete extruder assembly

[0018] FIG. 6 Cross sectional view of the extruder assembly highlights the vibration system

[0019] FIG. 7 Component concerning the vibration system.

DETAILED DESCRIPTION OF THE INVENTION

[0020] In the following detailed description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. Well-known methods, procedures, components and skills will not be described in detail.

[0021] The described extruder is a single assembly with one opening 507 on the side with an interface 107,204 for a standard material feeding duct/hose 106,305,405,506. The cable for the electric components on the extruder may be bundled with the material feeding duct/hose 106,305,405,506. The extruder may be mounted on a robotic arm, slider, gantry crane, or any other mobile platform. The extruder is designed for cementitious 3D printing; it may be used for structural, artistic, agricultural and other purposes.

[0022] The design of the extruder has a series of gradually reducing conduits with transitioning cones 307. That helps in compressing the material and allows the upper chamber 110,206,510 to operate as a reservoir, and then the material is compressed through the cone 307 to the lower conduit 109,205,409,509 for a more consistent flow rate and uniform quality.

[0023] A tube for cable routing 304 around the top extruder mounting plate 104,303 allows better wire management and reduces the chance of failure caused by tripping on loose cable. It is also a housing to protect the cable from external hazards during operation, deployment, handling, transportation and storage.

[0024] The central flight auger 308,504 is the main driving mechanism to transfer the cement from the upper chamber 110,206,510 to the lower conduit 109,205,409,509 then out the extruder nozzle 108,508. The motor module 101,301,401,501 driving the central flight auger 308,504 is controlled by an electronics device that adjusts the speed and torque for better quality extrusion given the mixture mechanical properties.

[0025] The motor module 101,301,401,501 is mounted to the top plate 104,303 of the extruder with a supporting structure 309,402 that houses the coupler 310 connecting the central flight auger 308,504 to the motor shaft. The supporting structure 309,402 is designed and sealed to protect its content against intrusion, dust, accidental contact, and water.

[0026] The top mounting plate 104,303 also accommodates the four shakers 302,403,601,707 used to introduce the vibration inside the enclosure and keep the cement inside the extruder from curing, which will be elaborated in the next paragraphs. The mounts 208,404,706 for shakers are made viable for easier and quicker assembly. The top plate 104,303 is secured to the extruder casing with toggle lock mechanisms 111,511 placed around the top of the extruder casing. The locking latch 407 is toggled by a mechanical trigger 408.

[0027] The four shakers 302,403,601,707 around the auger 308,504 on the top mount of the extruder 104,303 and the four shakers 105,202,604,701 on the outer wall of the upper chamber 110,206,510 are proposed to introduce vibration in the cementitious material flowing from a hose connected to the upper chamber 110,206,510 the shakers' vibrations will get rid of the air bubbles trapped within the material mixture and this prevents material's early curing, furthermore the vibrations will ease the sliding of materials downwards from the upper chamber 110,206,510 inner walls, for a long period of operation which is expected in the application of 3D printing such as structural and civil projects. This principal could also be used for cementitious material with faster curing time.

[0028] Each top shaker 302,403,601,707 comprises a casing 102, an actuation source 103, an extension rod 203,306,603,705. The shaker casing 102 protects its content against intrusion, dust, accidental contact, and water. The actuation source 103 generates vibration with tunable frequency monitored and controlled by additional electronics devices. The extension rod 203,306,603,705 extends from the actuation source to the inside of the extruder's upper chamber 110,206,510 near the inner wall 201,606,704 and transmits the perturbations to the cementitious material in the region where movement is slow. The shakers 302,403,601,707 are placed evenly across the top region of the upper chamber so that the introduced vibration is spreaded out to cover a larger effective area. The decoupler 602 served the purpose of isolating the vibrations of each shaker from the rest of the extruder. The shaker induces movement only to the cement mixture inside the extruder via the extension rod 203,306,603,705, and not the rest of the system. The vibration induced by the shaker has minimal effect on the motion of the extruder head. The control of the extruder is free of the noise induced by the added vibration.

[0029] The shakers at the casing outer circumference 105,202,604,701 are joined with an inner plate 201,606,704 inside the upper chamber 110,206,510. These shakers are mounted 112,512 on the outer circumference of the extruder's upper chamber110,206,510 casing to isolate their vibrations similar to the top shakers. The connection 607,703 will transmit the vibrations to the inside of the upper chamber 201,606,704 where the vibrations prevent cement from curing and accumulating inside the wall, and further remove air bubbles within the material for better flow rate and print quality. These shakers 105,202,604,701 also include decoupler at the connection, at the outer wall of the upper chamber 110,206,510 and thus the rest of the extruder is not influenced by the vibrations.

[0030] The induced vibration by the shakers increases the print speed and flow rate of the extruder by 60% in comparison with the extruder performance when the vibrations are not present as the material mixtures are not able to cure inside the casing due to the perturbations. Further, considering the elimination of clogging, the invention also significantly reduces the down time from maintenance, service, and other operational tasks during printing. As a result, the disclosed invention reduced the print time more than 70% overall.

[0031] Also, the controllable vibration allows the extruder to accommodate a wider range of cementitious mixtures without the need to chemically adjust the mixtures setting times, especially for mixtures that have a rapid setting rate.