DE102021001685A1 - Method for creating a material process data set for a material and method for manufacturing an additively manufactured component from a material using a material process data set of the material - Google Patents

Abstract

The invention relates to a method for creating a material process data set (1) for a material, wherein - a first test component is produced from the material at a test temperature by means of additive manufacturing, wherein - the first test component undergoes a first artificial aging test at a first artificial aging temperature for a first Artificial aging period (tA) is subjected, with- after the first artificial aging test, a first strength of the first test component is determined at room temperature, with- the first strength of the first test component depending on the first artificial aging temperature and the first artificial aging period (tA) in the material process data set (1) is saved.

Description

The invention relates to a method for creating a material process data set for a material and a method for producing an additively manufactured component from a material using a material process data set of the material.

Methods are known in which a component, in particular a metallic component, is subjected to heat treatment, in particular artificial aging, in a separate, in particular downstream, process, in particular after the component has been produced. An increase in strength can be achieved by means of heat treatment, in particular artificial aging. A disadvantage of these methods is that the production and the heat treatment, in particular the artificial aging, take place in separate processes, in particular separate from one another.

The invention is therefore based on the object of creating a method for creating a material process data set for a material and a method for creating an additively manufactured component from a material using a material process data set of the material, the disadvantages mentioned being at least partially eliminated, are preferably avoided.

The object is achieved by providing the present technical teaching, in particular the teaching of the independent claims and the embodiments disclosed in the dependent claims and the description.

The object is achieved in particular by creating a method for creating a material process data record for a material, with a first test component being produced from the material at a test temperature by means of additive manufacturing. The first test component is subjected to a first artificial aging trial at a first artificial aging temperature for a first artificial aging period. After the first artificial aging test, a strength of the first test component is determined at room temperature. The first strength of the first test component is stored in the material process data set as a function of the first artificial aging temperature and the first artificial aging period. Advantageously, a first strength as a function of the first artificial aging temperature and the first artificial aging period can thus be made easily accessible for the material. It is advantageously possible to use the material process data set to carry out a method in which additive manufacturing and heat treatment, in particular artificial aging, can be combined in a process-optimized manner. The combination of manufacturing, in particular additive manufacturing, and heat treatment, in particular artificial aging, can shorten the total duration of the manufacturing process of a component.

In the context of the present technical teaching, the test temperature is a temperature to which the test component is heated during additive manufacturing. In addition, a temperature of the test device is maintained at the test temperature during manufacture. In a preferred embodiment, a temperature of a work platform on which the test component is additively manufactured is kept at the test temperature. Alternatively or additionally, a temperature of a construction space in which the component is produced is preferably kept at the test temperature. Alternatively or additionally, a temperature of a powder from which the component is produced additively is preferably kept at the test temperature.

In the context of the present technical teaching, an artificial aging test of a component is a heat treatment, in particular an artificial aging, of the component. The component is exposed to a preferably constant artificial aging temperature for a predetermined period of artificial aging. An increase in strength can advantageously be achieved by means of heat treatment, in particular artificial aging. Alternatively, the artificial aging temperature may preferably be varied during artificial aging.

Preferably the test temperature is less than a melting temperature of the material. Alternatively or additionally, the first artificial aging temperature is preferably lower than the melting temperature of the material.

According to a development of the invention, it is provided that a plurality of test components are produced from the material at the first test temperature by means of additive manufacturing. The plurality of test components are each subjected to an artificial aging test at different artificial aging temperatures for different artificial aging periods. In each case one strength of the plurality of test components is stored in the material process data record as a function of the respective artificial aging temperature and the respective artificial aging period. The material process data record advantageously includes a plurality of artificial aging temperatures and artificial aging periods with the respective associated strength. Preferably, the different Warm aging temperatures - in particular up to the first artificial aging temperature - are each greater than the test temperature.

In a preferred embodiment, an artificial aging temperature and a strength can be determined in the material process data record for a predetermined artificial aging period.

A plurality of strengths for a plurality of different artificial aging periods are preferably stored in the material process data record for an artificial aging temperature of the plurality of artificial aging temperatures, preferably for each artificial aging temperature of the plurality of artificial aging temperatures. Alternatively or additionally, a plurality of strengths for a plurality of different artificial aging temperatures are preferably stored in the material process data set for an artificial aging period of the plurality of artificial aging periods, preferably for each artificial aging period of the plurality of artificial aging periods.

According to a development of the invention, it is provided that the first strength at room temperature of the test component is determined as a hardness at room temperature and/or as a 0.2% yield point. The strength of the plurality of test components at room temperature of the respective test component is preferably determined as the hardness at room temperature and/or as the 0.2% proof stress.

According to a development of the invention, it is provided that the test temperature is selected in such a way that the first strength of the first test component in the first artificial aging test at the first artificial aging temperature, which is equal to the test temperature, for the first artificial aging period of 30 hours, preferably 50 hours, almost remains constant.

In particular, the temperature of the test component is kept at the test temperature during and after, in particular for 30 hours, preferably 50 hours, the additive manufacturing of the test component.

According to a development of the invention, it is provided that the first artificial aging temperature and the second artificial aging temperature are selected in such a way that the first artificial aging temperature and the second artificial aging temperature differ by at most 30 °C, preferably at most 20 °C, particularly preferably at most 10 °C.

According to a development of the invention, it is provided that a strength-artificial aging duration diagram is used as the material process data record. All strengths determined for a specific artificial aging temperature are plotted as a strength curve as a function of the respective artificial aging period in the strength-artificial aging period diagram.

The object is also achieved by a method for producing an additively manufactured component from a material using a material process data set of the material, in particular using a material process data set according to the invention of the material or a material process data set of the material according to one or more of the above described embodiments, is provided. First, a process duration for the additive manufacturing of the component from the material is determined. A process temperature is determined using the material process data set based on the process duration. The component is manufactured using additive manufacturing at the process temperature. Advantageously, the additive manufacturing of the component and the heat treatment, in particular the artificial aging, of the component can be combined in one process step by a suitable choice of the process temperature. A shorter manufacturing process than in known methods can thus advantageously be implemented, as a result of which the manufacturing costs for a component decrease. Furthermore, given the known process duration, the process temperature can advantageously be selected in such a way that a desired strength of the component is achieved.

In particular, the additively manufactured component has a plurality of component layers that are produced in a predefined time sequence. According to this predefined time sequence, each component layer of the plurality of component layers is exposed to the process temperature for a different duration. This results in particular for each component layer of the plurality of component layers, a different artificial aging period and thus in particular a different strength.

A strength gradient which forms between the plurality of component layers can preferably be reduced by means of an additional heat treatment, in particular a local heat treatment, in particular artificial aging. Alternatively or additionally, the component can be placed in the installation space in such a way that the strength gradient runs along a desired direction in the component.

In a preferred embodiment, the component is produced entirely by means of additive manufacturing. Alternatively, the component is partially produced by means of additive manufacturing, in particular as a so-called hybrid component, wherein a further component section is applied, in particular attached, to an already existing shell component by means of additive manufacturing.

According to a development of the invention, it is provided that an artificial aging temperature is determined from the material process data set based on the process duration, in particular by evaluating the material process data set with the process duration as an artificial aging duration. The process temperature is determined based on the artificial aging temperature, with the process temperature preferably being set equal to the artificial aging temperature.

According to a development of the invention, it is provided that, based on the material process data set, each strength curve in the strength-artificial aging time diagram is integrated up to the process time—assumed as the artifical aging time. The strength curve associated with a maximum integral value is selected, with the artificial aging temperature associated with the selected strength curve being selected.

The additively manufactured component thus advantageously has maximum average strength.

According to a development of the invention, it is provided that a material is used as the material that has at least one metal and/or can be treated by means of precipitation hardening. Such a material is advantageously suitable for achieving an increase in strength of the component made from the material by means of a heat treatment, in particular artificial aging.

An aluminum alloy, in particular the aluminum-based alloy AlSi10Mg, is preferably used as the material, ie an aluminum-based alloy with at least 9 and at most 11 percent by weight silicon and with at least 0.25 and at most 0.45 percent by weight magnesium

The invention is explained in more detail below with reference to the drawing.

• 1 eine schematische Darstellung eines Ausführungsbeispiels eines Werkstoffprozess-Datensatzes eines Werkstoffs, insbesondere in Form eines Festigkeits-Warmauslagerungsdauer-Diagramms,
• 2 eine schematische Darstellung eines Zeit-Temperatur-Diagramms bei der additiven Fertigung eines Bauteils aus dem Werkstoff,
• 3 eine schematische Darstellung des Ausführungsbeispiels des Werkstoffprozess-Datensatzes des Werkstoffs mit einer Mehrzahl an Festigkeits-Kurven und drei unterschiedlichen Prozessdauern,
• 4 eine schematische Darstellung des Ausführungsbeispiels des Werkstoffprozess-Datensatzes des Werkstoffs mit der Mehrzahl an Festigkeits-Kurven mit einem ersten Integralwert bezüglich einer ersten Prozessdauer,
• 5 eine schematische Darstellung des Ausführungsbeispiels des Werkstoffprozess-Datensatzes des Werkstoffs mit der Mehrzahl an Festigkeits-Kurven mit einem zweiten Integralwert bezüglich einer zweiten Prozessdauer, und
• 6 eine schematische Darstellung des Ausführungsbeispiels des Werkstoffprozess-Datensatzes des Werkstoffs mit der Mehrzahl an Festigkeits-Kurven mit einem dritten Integralwert bezüglich einer dritten Prozessdauer.

show:

• 1 a schematic representation of an exemplary embodiment of a material process data set of a material, in particular in the form of a strength-artificial aging duration diagram,
• 2 a schematic representation of a time-temperature diagram in the additive manufacturing of a component made of the material,
• 3 a schematic representation of the embodiment of the material process data set of the material with a plurality of strength curves and three different process durations,
• 4 a schematic representation of the exemplary embodiment of the material process data set of the material with the plurality of strength curves with a first integral value with regard to a first process duration,
• 5 a schematic representation of the exemplary embodiment of the material process data set of the material with the plurality of strength curves with a second integral value with regard to a second process duration, and
• 6 a schematic representation of the exemplary embodiment of the material process data set of the material with the plurality of strength curves with a third integral value with regard to a third process duration.

1 shows a schematic representation of an exemplary embodiment of a material process data set 1 of a material, in particular in the form of a strength-artificial aging duration diagram 3.

To create the material process data record 1 of the material, a first test component is produced from the material at a test temperature by means of additive manufacturing. The first test component is subjected to a first artificial aging test at a first artificial aging temperature for a first artificial aging period t _A , in particular subsequent to the additive manufacturing. After the first artificial aging test, the strength of the first component is determined at room temperature. The first strength of the first test component is stored in the material process data record as a function of the first artificial aging temperature and the first artificial aging period t _A .

The test temperature is preferably selected in such a way that the first strength of the first test component in the first artificial aging test at the first artificial aging temperature, which is equal to the test temperature, remains almost constant for the first artificial aging period t _A of 30 hours, particularly preferably 50 hours.

A plurality of test components are preferably each subjected to an artificial aging test at different artificial aging temperatures and different artificial aging periods t _A . In each case one strength of the plurality of test components is stored in the material process data record 1 as a function of the respective artificial aging temperature and the respective artificial aging period t _A .

The strength at room temperature of the test component is preferably determined as a hardness at room temperature and/or as a 0.2% yield point in the room temperature tensile test.

The strength-artificial aging period diagram 3 preferably has a plurality of strength curves 5, with the plurality of strength curves 5 representing all the strengths determined for a specific artificial aging temperature as a function of the respective artificial aging period t _A .

The first strength is preferably represented as a data point 7 in the strength-artificial aging time diagram 3, in particular in the plurality of strength curves 5.

the inside 1 The material process data record 1 shown has, in particular, 24 data points 7 . Six data points 7 each are assigned to a specific artificial aging temperature. A connecting line of the respective six data points 7, which belong to the identical artificial aging temperature, form a strength curve 5 of the plurality of strength curves 5. The in 1 The material process data record 1 shown can also have more or fewer than the data points 7 shown.

A first strength curve 5.1 shows the course of the strength as a function of the artificial aging period t _A at the first artificial aging temperature. The first artificial aging temperature is preferably selected in such a way that the strength of the component after a first artificial aging period t _A of 30 hours, particularly preferably 50 hours, remains almost constant. Alternatively or additionally, the first artificial aging temperature preferably corresponds to the test temperature.

A second strength curve 5.2 represented the course of the strength as a function of the artificial aging period t _A at a second artificial aging temperature. The second artificial aging temperature is preferably selected in such a way that the first artificial aging temperature and the second artificial aging temperature differ by at most 30 °C, preferably at most 20 °C, particularly preferably at most 10 °C. Alternatively or additionally, the second artificial aging temperature is preferably higher than the first artificial aging temperature.

A third strength curve 5.3 represented the course of the strength as a function of the artificial aging period t _A at a third artificial aging temperature. The third artificial aging temperature is preferably selected in such a way that the second artificial aging temperature and the third artificial aging temperature differ by at most 30 °C, preferably at most 20 °C, particularly preferably at most 10 °C. Alternatively or additionally, the third artificial aging temperature is preferably higher than the second artificial aging temperature.

A fourth strength curve 5.4 represented the course of the strength as a function of the artificial aging period t _A at a fourth artificial aging temperature.

The fourth artificial aging temperature is preferably selected in such a way that the third artificial aging temperature and the fourth artificial aging temperature differ by at most 30°C, preferably at most 20°C, particularly preferably at most 10°C. Alternatively or additionally, the fourth artificial aging temperature is preferably higher than the third artificial aging temperature.

2 shows a schematic representation of a time-temperature diagram 9 in the additive manufacturing of a component from the material.

The process temperature T _P is reached after a heating phase. The component is manufactured during a process duration t _P at the process temperature T _P . Alternatively, the process temperature T _P can be variable during the process duration t _P . After the component has been manufactured, the temperature drops again.

A material is preferably used as the material that has at least one metal and/or can be treated by means of precipitation hardening.

the 3 until 6 show a preferred embodiment for determining the process temperature T _P .

3 shows a schematic representation of the exemplary embodiment of the material process data record 1 of the material in the form of the strength-artificial aging period diagram 3 with the strength curves 5 with a first process period t _P1 , a second process period t _P2 and a third process period t _P3 .

The process temperature T _P is determined using the material process data record 1 based on the process duration tp.

An artificial aging temperature is preferably determined from the material process data set 1 on the basis of the process duration tp to be expected for the respective planned printing process. The process temperature T _P is preferably determined on the basis of the artificial aging temperature, with the process temperature T _P particularly preferably being set equal to the artificial aging temperature.

Different process temperatures T _P , in particular T _P1 , T _P2 and T _P3 , preferably result for the plurality of process durations t _P , in particular t _P1 , t _P2 and t _P3 .

Each strength curve 5 in the strength test duration diagram 3 is preferably integrated up to the process duration tp on the basis of the material process data set 1 . The strength curve 5 that is assigned a maximum integral value 11 is selected, with the artificial aging temperature assigned to the selected strength curve 5 being selected.

4 shows a schematic representation of the exemplary embodiment of the material process data set 1 of the material with the plurality of strength curves 5 with a first integral value 11.1 with regard to the first process duration t _P1 .

In 4 it can be clearly seen that with regard to the first process duration t _P1 the first integral value 11.1, which results from the integral of the fourth strength curve 5.4, is at its maximum. A first process temperature T _P1 , which is used to produce the component during the first process duration t _P1 , is therefore preferably selected to be equal to the fourth artificial aging temperature in order to maximize an average strength of the component.

5 shows a schematic representation of the exemplary embodiment of the material process data record 1 of the material with the plurality of strength curves 5 with a second integral value 11.2 with regard to the second process duration t _P2 .

In 5 it can be clearly seen that with regard to the second process duration t _P2 the second integral value 11.2, which results from the integral of the third strength curve 5.3, is at its maximum. A second process temperature T _P2 , which is used to produce the component during the second process duration t _P2 , is therefore preferably chosen to be equal to the third artificial aging temperature in order to maximize an average strength of the component.

6 shows a schematic representation of the exemplary embodiment of the material process data set 1 of the material with the plurality of strength curves 5 with a third integral value 11.3 with regard to the third process duration t _P3 .

In 6 it can be clearly seen that with regard to the third process duration t _P3 the third integral value 11.3, which results from the integral of the second strength curve 5.2, is at its maximum. A third process temperature T _P3 , which is used to produce the component during the third process duration t _P3 , is therefore preferably chosen to be equal to the second artificial aging temperature in order to maximize an average strength of the component.

Claims (10)

Method for creating a material process data set (1) for a material, wherein - a first test component is produced from the material at a test temperature by means of additive manufacturing, wherein - the first test component undergoes a first artificial aging test at a first artificial aging temperature for a first artificial aging period (t _A ) is subjected, wherein - after the first artificial aging test, a first strength of the first test component is determined at room temperature, wherein - the first strength of the first test component as a function of the first artificial aging temperature and the first artificial aging period (t _A ) in the material process data set (1 ) is saved. procedure after claim 1 , wherein - a plurality of test components are each subjected to an artificial aging test at different artificial aging temperatures for different artificial aging periods (t _A ), wherein - in each case a strength of the plurality of test components depending on the respective artificial aging temperature and the respective artificial aging period (t _A ) in the material process- Data record (1) is saved. Method according to one of the preceding claims, wherein the first strength at room temperature of the test component is determined as a hardness at room temperature and/or as a 0.2% yield strength. The method according to any one of the preceding claims, wherein the test temperature is chosen such that the first strength of the first test component in the first artificial aging test at the first artificial aging temperature, which is equal to the test temperature for the first artificial aging duration (t _A ) of 30 hours, preferably 50 hours, remains almost constant. Method according to one of the preceding claims, wherein the first artificial aging temperature and the second artificial aging temperature are chosen such that the first artificial aging temperature and the second artificial aging temperature differ by at most 30 °C, preferably at most 20 °C, particularly preferably at most 10 °C. Method according to one of the preceding claims, wherein - a strength-artificial aging period diagram (3) is used as the material process data set (1), wherein - all strengths determined for a specific artificial aging temperature as a strength curve (5) depending on the respective period of artificial aging (t _A ) in the strength-artificial aging time diagram (3). Method for producing an additively manufactured component from a material using a material process data set (1) of the material, in particular using the material process data set (1) of the material obtained according to one of the preceding claims, wherein - a process duration (tp) for the additive manufacturing of the component from the material is determined, wherein - by means of the material process data set (1) based on the process duration (t _P ), a process temperature (T _P ) is determined, wherein - the component by means of additive manufacturing at the process temperature (T _P ) will be produced. procedure after claim 7 , wherein - an artificial aging temperature is determined based on the process duration (t _P ) from the material process data set (1), wherein - the process temperature (T _P ) is determined based on the artificial aging temperature, wherein - the process temperature (T _P ) is preferably set equal to the artificial aging temperature . procedure after claim 7 or 8th , wherein - on the basis of the material process data set (1), each strength curve (5) in the strength-artificial aging duration diagram (3) is integrated up to the process duration (tp), wherein - that strength curve (5) is selected, to which a maximum integral value (11) is assigned, wherein - the artificial aging temperature assigned to the selected strength curve (5) is selected. Procedure according to one of Claims 7 until 9 , wherein a material is used as the material that has at least one metal and/or can be treated by means of precipitation hardening.

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