Patent Application
20230158573
This disclosure is directed to melted metal ejectors used in three-dimensional (3D) object printers and, more particularly, to the heating of the build platforms used in those systems.
Three-dimensional printing, also known as additive manufacturing, is a process of making a three-dimensional solid object from a digital model of virtually any shape. Many three-dimensional printing technologies use an additive process in which an additive manufacturing device forms successive layers of the part on top of previously deposited layers. Some of these technologies use ejectors that eject UV-curable materials, such as photopolymers or elastomers. The printer typically operates one or more extruders to form successive layers of the plastic material that form a three-dimensional printed object with a variety of shapes and structures. After each layer of the three-dimensional printed object is formed, the plastic material is UV cured and hardens to bond the layer to an underlying layer of the three-dimensional printed object. This additive manufacturing method is distinguishable from traditional object-forming techniques, which mostly rely on the removal of material from a work piece by a subtractive process, such as cutting or drilling.
Recently, some 3D object printers have been developed that eject drops of melted metal through one or more nozzles to form 3D objects. These printers have a source of solid metal, such as a roll of wire or pellets, that is fed into a chamber of an ejector head where an external heater is operated to melt the solid metal. The ejector head is positioned within the opening of an electrical coil. An electrical current is passed through the coil to produce an electromagnetic field that causes the meniscus of the melted metal at a nozzle of the chamber to separate from the melted metal within the chamber and be propelled from the one or more nozzles. This type of metal drop ejecting printer is called a magnetohydrodynamic (MHD) printer by some in the art.
A platform is positioned opposite the nozzle(s) of the ejector and the ejector head is moved in a X-Y plane parallel to the plane of the platform by a controller operating actuators so the melted metal drops ejected from the nozzle form metal layers of an object on the platform. Another actuator is operated by the controller to alter the position of the ejector head or platform in the vertical or Z direction to position the ejector head and an uppermost layer of the metal object being formed by a distance appropriate for continuation of the object formation.
One type of MHD printer builds parts with drops exiting the nozzle at ˜400 Hz. The bulk metals melted for ejection from the nozzle of this printer include Al 6061, 356, 7075 and 4043. The size of the ejected drops is ˜0.5 mm in diameter and these drops spread to a size of ˜0.7 mm in diameter upon contact with the part surface. The melting temperature of these aluminum alloys is approximately 600° C. Empirical studies have shown that the optimal receiving surface temperature needs to be from ˜400° C. to ˜550° C. for good adherence to the previously formed surface. At these temperatures the melted metal drops combine with the build part in a uniform way that results in a strong and consistent build structure.
Heater plates that heat a build platform come in a variety of configurations. Many of these have one or more heating elements that wind in the plane of the heater plate in a serpentine manner, a back and forth pattern, or a maze configuration. A problem that arises from these known heater plates is irregular heating of the build platform. Portions of the platform that are directly adjacent a heating element reach temperatures that are hotter than portions not directly adjacent a heating element. This non-uniform distribution of heat across the build platform hinders the drops from combining smoothly or from bonding to one another as strongly as they should. This lackluster bonding increases porosity in the part, forms uneven build surfaces, produces unwelded drops, and yields shape inconsistencies. All of these unwanted results lead to degraded physical properties, such as low fatigue strength and tensile strength, as well as poor appearance issues in the final part. Being able to maintain a uniform distribution of heat across the build platform within an appropriate temperature range would be beneficial.
A new heater for a build platform in a 3D metal object printer more uniformly distributes heat across the build platform in a temperature range that enables strong melted metal drop bonding and object layer formation. The heater includes a plurality of sections that are positioned with respect to one another to form a structure encompassed by a single perimeter, and each section including at least one independently controllable heating element and at least one temperature sensor.
A new 3D metal object printer includes a heater for the build platform that more uniformly distributes heat across the build platform in a temperature range that enables strong melted metal drop bonding and object layer formation. The 3D metal object printer includes an ejector head configured to eject drops of melted metal, a planar member positioned to receive the ejected drops of melted metal, a plurality of sections that are positioned with respect to one another to form a structure encompassed by a single perimeter, the plurality of sections supporting the planar member, and each section in the plurality of sections including at least one independently controllable heating element and at least one temperature sensor.
The foregoing aspects and other features of a build platform heater in a 3D metal object printer that uniformly distributes heat across the build platform in the printer in a temperature range that enables strong melted metal drop bonding and object layer formation are explained in the following description, taken in connection with the accompanying drawings.
For a general understanding of the environment for the build platform heater used in a 3D metal object printer and its operation as disclosed herein as well as the details for the build platform heater and its operation, reference is made to the drawings. In the drawings, like reference numerals designate like elements.
With continued reference to
Continuing with the discussion of the printer shown in
The ejector head 140 of
Moving the platform 112 of
The controller 148 operates the switches 152 selectively. One switch 152 can be selectively operated by the controller to provide electrical power from source 156 to the heater 160, while another switch 152 can be selectively operated by the controller to provide electrical power from another electrical source 156 to the coil 164 for generation of the electrical field that ejects a drop from the nozzle 108. Because the heater 160 generates a great deal of heat at high temperatures, the coil 164 is positioned within a chamber 168 formed by one (circular) or more walls (rectilinear shapes) of the ejector head 140. As used in this document, the term “chamber” means a volume contained within one or more walls in which a heater, a coil, and a removable vessel of a 3D metal object printer are located. The removable vessel 104 and the heater 160 are located within this chamber. The chamber is fluidically connected to a fluid source 172 through a pump 176 and also fluidically connected to a heat exchanger 180. As used in this document, the term “fluid source” refers to a container of a liquid having properties useful for absorbing heat. The heat exchanger 180 is connected through a return to the fluid source 172. Fluid from the source 172 flows through the chamber to absorb heat from the coil 164 and the fluid carries the absorbed heat through the exchanger 180, where the heat is removed by known methods. The cooled fluid is returned to the fluid source 172 for further use in maintaining the temperature of the coil in an appropriate operational range.
The controller 148 of the 3D metal object printer 100 requires data from external sources to control the printer for metal object manufacture. In general, a three-dimensional model or other digital data model of the object to be formed is stored in a memory operatively connected to the controller 148, the controller can access through a server or the like a remote database in which the digital data model is stored, or a computer-readable medium in which the digital data model is stored can be selectively coupled to the controller 148 for access. This three-dimensional model or other digital data model is processed by a slicer implemented with the controller to generate machine-ready instructions for execution by the controller 148 in a known manner to operate the components of the printer 100 and form the metal object corresponding to the model. The generation of the machine-ready instructions can include the production of intermediate models, such as when a CAD model of the device is converted into an STL data model, or other polygonal mesh or other intermediate representation, which can in turn be processed to generate machine instructions, such as g-code, for fabrication of the device by the printer. As used in this document, the term “machine-ready instructions” means computer language commands that are executed by a computer, microprocessor, or controller to operate components of a 3D metal object additive manufacturing system to form metal objects on the platform 112. The controller 148 executes the machine-ready instructions to control the ejection of the melted metal drops from the nozzle 108, the positioning of the platform 112, as well as maintaining the distance between the orifice 110 and the uppermost layer of the object on the platform 112.
The controller 148 can be implemented with one or more general or specialized programmable processors that execute programmed instructions. The instructions and data required to perform the programmed functions can be stored in memory associated with the processors or controllers. The processors, their memories, and interface circuitry configure the controllers to perform the operations previously described as well as those described below. These components can be provided on a printed circuit card or provided as a circuit in an application specific integrated circuit (ASIC). Each of the circuits can be implemented with a separate processor or multiple circuits can be implemented on the same processor. Alternatively, the circuits can be implemented with discrete components or circuits provided in very large scale integrated (VLSI) circuits. Also, the circuits described herein can be implemented with a combination of processors, ASICs, discrete components, or VLSI circuits. During metal object formation, image data for a structure to be produced are sent to the processor or processors for controller 148 from either a scanning system or an online or work station connection for processing and generation of the signals that operate the components of the printer 100 to form an object on the platform 112.
Using like reference numbers for like components, a new build platform heater 114' and platform 112 configuration is shown in
The cells are made of materials that have a high coefficient of thermal conductivity, such as molybdenum steel or other steel alloys provided the alloy withstands temperatures greater than 500° C. well. The material is divided into solid blocks and machined into a polygonal shape that can adjoin to the perimeters of adjacent cells. These shapes include, but are not limited to, hexagons, squares, rectangles, triangles, and the like. A channel for the heating element is drilled in the center of the cell and another channel is drilled offset from the center for the temperature sensor. The width of a cell corresponds to the heat output of the heating element. That is, the cell is sized so the portions of the cell further from the heating element reach an adequate temperature for supplying heat to the build platform without requiring the heating element to be driven by a 100% duty cycle signal continuously. The height of the cells can vary depending upon the location of the cell in the grid. For example, cells in the central portion of the grid can be more shallow since they receive heat from the adjacent cells surrounding them. Cells on the perimeter can have a greater height to maintain heat in the regions further from the build area, which is typically centralized on the build platform. A high temperature adhesive sealant capable of withstanding temperatures up to about 1260° C. is applied to the faces of the polygonal perimeter of the cells and the cells are joined together to form the grid and the frame is mounted about the grid.
In alternative embodiments, heater sections are cast of the thermal conductive material so that they are combined to form a heater configured to support a build platform. As used in this document, the term “section” means a volume of material that can be positioned adjacent to another volume of material to form a contiguous grid. As used in this document, the term “grid” means a plurality of sections that can be positioned adjacent to one another to form a structure encompassed by a single perimeter. For example, pie slice sectors, sections conforming to parts of a commonly manufactured part, or concentric rings can be formed. In these sections, which are larger than the cells discussed above, the heating elements and temperature sensors are distributed in the sections so that the temperature sensors can generate signals indicative of the temperatures in every portion of the sections. For example, as shown in
In the non-centered opening of the cell 216 shown in
The controller monitors the temperature sensors, that is, the thermocouples or thermistors, for each cell and generates a pulse width modulated (PWM) signal for operating the digital switch that connects the heating element to electrical power. Each switch, and therefore each heating element, is controlled independently of the other switches to regulate the temperature of the heater 114'. The signal from each temperature sensor is monitored and compared to a range set about the temperature setpoint for the heater grid. The temperature setpoint can be provided through an user interface operatively connected to the controller but a default temperature setpoint can be stored in a memory operatively connected to the controller. The temperature range need not be centered about the setpoint but the setpoint needs to be within the temperature range. If the temperature indicated by the signal exceeds the upper end of the range, then the duty cycle of the PWM signal for the switch connecting the heating element to electrical power is reduced. If the temperature indicated by the signal is below the lower end of the range, then the duty cycle of the PWM signal for the switch connecting the heating element to electrical power is increased. In one embodiment, the grid temperature setpoint is 550° C. and the temperature range is approximately 545-555° C.
A process for operating the build platform heater in a printer is shown in
It will be appreciated that variants of the above-disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems, applications or methods. Various presently unforeseen or unanticipated alternatives, modifications, variations or improvements may be subsequently made by those skilled in the art that are also intended to be encompassed by the following claims.
