DE10330590A1 - Sinter powder for selective laser-sintering, useful for the production of molded articles, comprises a polyamide having an excess of carboxylic end groups - Google Patents

Abstract

A sinter powder (I) for selective laser-sintering comprises a polyamide having an excess of carboxylic end groups - a so-called regulated polyamide. Independent claims are included for: (1) a process for the production of sinter powder (I) by treatment of an unregulated polyamide with a carboxylic acid regulator; (2) a process for the production of molded articles by selective laser-sintering of the sinter powder (I) and; (3) the resulting molded articles.

Description

The invention relates to a laser sinter powder based on regulated polyamide, preferably polyamide 12 Process for using this powder and molded articles by selective laser sintering of laser sinter powders.

The rapid provision of prototypes is one in the youngest Time often task. A process that is particularly good for the purpose suitable for rapid prototyping is laser sintering. With this Plastic powder in a chamber is selectively short exposed to a laser beam, causing the powder particles that melted by the laser beam. The melted Particles run into each other and solidify again relatively quickly to a solid mass. By repeatedly exposing new applied layers can complex three-dimensional bodies can be produced quickly and easily using this process become.

The process of laser sintering (rapid prototyping) for the production of moldings from powdered polymers is described in detail in the patents US 6,136,948 and WO 96/06881 (both DTM Corporation). A variety of polymers and copolymers are claimed for this application, such as polyacetate, polypropylene, polyethylene, ionomers and polyamide 11.

The laser sintering process creates a block-like body, the one from the desired Components consist, on the other hand and mostly the majority, of not exposed powder, so-called back powder, which until demoulding or unpacking with the components remains in this block. It has a supportive Effect on the components, so that overhangs and undercuts with the laser sintering process without support structures are realizable. Depending on the type of powder used, this can unexposed powder after sieving and adding new powder in be used in another construction process (recycling).

In practice, laser sintering especially polyamide 12 powder for the production of technical components has proven itself. The made from PA12 powder Parts are enough high mechanical loads and come with their properties particularly close to the later ones Series parts by injection molding or extrusion.

A polyamide 12 with a melting temperature of 185-189 ° C, a melting enthalpy of 112 ± 17 kJ / mol and a solidification temperature of 138-143 ° C, as described in EP 0 911 142 is described. Powders with an average grain size of 50 to 150 μm are preferably used, such as those according to DE 197 08 946 or DE 44 21 454 receives.

A disadvantage of the prior art is that the unexposed parts of inserted polyamide powder under the conditions given in the installation space of the laser sintering machine (high temperatures, very low humidity) for post-condensation tend.

The recovered polyamide powder show, as our own studies have shown, a significantly increased solution viscosity and let only limited in the next Use the building process.

For consistently good results To achieve in laser sintering is according to the prior art recovered Powder always mixed with significant amounts of new powder. The required amounts of new powder are considerably higher than the for the components consumed quantities. Therefore, there is a surplus of powder, that cannot be reused and must be disposed of. Especially in the case of filigree components, considerable falls are made in this way Amounts of powder that can no longer be used in other construction processes.

Object of the present invention it was therefore to provide a laser sinter powder that was suitable is, by adding small amounts of new powder or even without The addition of new powder is used again directly as a laser sinter powder to be and thus the amount of powder that is disposed of must be reduced.

Surprisingly it has now been found that adding regulators, in particular of organic carboxylic acids to produce polyamides, polyamide powder with almost constant solution viscosity let and that laser sinter powder which these regulated polyamides have, without the addition of new powder or with only a small addition of new powders can be used several times in the laser sintering process can.

Object of the present invention is therefore a sinter powder for selective laser sintering, which characterized in that it is a polyamide with an excess of carboxyl end groups, a so-called regulated polyamide.

The present invention also relates to a process for the production of moldings by selective laser sintering of sintered powder, which is characterized in that a sintered powder which has polyamide with an excess of carboxyl end groups, a so-called regulated polyamide, is used.

In addition, the subject of present invention molded body, produced by selective laser sintering, which is characterized by are that they have a regulated polyamide.

The sinter powder according to the invention has the advantage that it is as powder only mixed with small amounts of new powder, or even unmixed can be used again for laser sintering. Because of of these excellent recycling qualities, is a disposal of rear powders frequently not necessary anymore.

The excellent recycling qualities are based among other things, that no increase in thermal stress the solution viscosity occurs. This depends presumably together with the fact that the inventive sinter powder according to the invention existing regulated polyamide is less prone to post-condensation as unregulated polyamides. The phenomenon of post-condensation applies in principle to all polymers that are formed by condensation, i.e. polyester, Polyamides etc. PA is particularly reactive in this regard: It it was found that at approximately same number of carboxyl and amino end groups post-condensation can occur and thus the solution viscosity of the polyamide changed becomes. Uncontrolled side reactions also have a proven effect the end group titration of the used powder in many cases an over-stoichiometric one Loss of amino groups Carboxyl groups, which is an indication of thermo-oxidative crosslinking reactions is evaluated, the fluidity of the used powder.

Conventional new powder used for laser sintering has a solution viscosity according to ISO 307 of approximately η _rel = 1.6. Due to the thermal and thermo-oxidative stress (post-condensation + crosslinking) during laser sintering over a construction period of several hours - in extreme cases a few days - the unexposed sintered powder (return powder) shows poorer flow properties in many cases and when this return powder is used directly in laser sintering defects and unwanted pores increasingly appear in the molded articles produced. The moldings have a rough and sunken surface (orange peel) and have significantly poorer mechanical properties in terms of elongation at break, tensile strength and modulus of elasticity, as well as a reduced density.

To flawless and specification-compliant To get components of consistent quality, the return powder according to the status the technology mixed with not inconsiderable amounts of new powder become. Usually becomes the return powder in amounts of 20 - 70% at the next Building process reused. contains the return powder additionally fillers, such as glass balls, can usually be a maximum of 50% back powder deploy. To the one mentioned above Exclude orange peel safely to be able to recommend For example, the company EOS in its product information (material data sheet "Fine polyamide PA 2200 for EOSINT P ", booth March 2001) a relationship of powder for new powder of 1: 1, maximum of 2: 1.

The sinter powder according to the invention is clear less sensitive to the thermal stress of laser sintering and can therefore be used as a back powder directly or with significantly lower admixtures of new powder be used again in laser sintering. This also applies to the case that the sinter powder fillers having. In all of these cases shows the sinter powder according to the invention significantly improved recycling properties. A special advantage is in particular that the sintered powder is completely recycled can.

The reuse of thermal aged powder according to the invention is also very possible because because surprisingly no decrease in the thermal aging of powder according to the invention Recrystallization temperature, even in many cases Rise in the recrystallization temperature can be determined. As a result, when installing aged powder according to the invention almost the same crystallization behavior as with new powder. So far common aged powder only crystallizes at significantly lower temperatures as new powder, which is why sink marks when installing old powder occur.

Another advantage of the sinter powder according to the invention is that it can be in any amount (0 to 100 parts) with a conventional one Mix laser sinter powder based on unregulated polyamide leaves. The powder mixture obtained is based on the sintered powder of unregulated polyamide a reduced increase in solution viscosity and thus also an improved recyclability.

The sinter powder according to the invention and a method in which this powder is used, is described below, without the invention being intended to be limited thereto.

The sinter powder according to the invention for selective Laser sintering is characterized by the fact that it is made with a polyamide an excess of carboxyl end groups, a so-called regulated polyamide. It can be beneficial be when the carboxyl end group excess is at least 20 mmol / kg is.

The chemical analysis of a conventional powder that is thermally stressed in the laser sintering process shows a significant increase in the solution viscosity, due to a molecular weight build-up and a more than stoichiometric decrease in the amino end groups in relation to the converted carboxyl end groups. This is explained on the one hand by the fact that under the conditions of laser sintering, free amino and Carboxyl end groups in polyamide powder can react with each other with elimination of water, the so-called post-condensation. Secondly, the decrease in the amino functions is due to the thermooxidative elimination of these groups with subsequent crosslinking. During the polymerization, the regulator has the effect that the number of free amino end groups is reduced. Therefore, carboxyl end groups are present in excess in the polyamide to be used according to the invention.

By the excess according to the invention at carboxyl end groups in the polyamide of the sinter powder, the increase in Solution viscosity as well Thermooxidative end group loss of polyamides in sinter powders according to the invention significantly reduced or avoided.

The sinter powder according to the invention preferably has a polyamide, which is preferably 0.01 parts to 5 parts, preferably Has 0.1 to 2 parts of a mono- or dicarboxylic acid as a regulator.

The sinter powder according to the invention particularly has preferably a polyamide which has a ratio of carboxyl end group to amino end group of 2: 1 or greater. The content of Amino end groups in this polyamide can be below 40 mmol / kg, preferably are below 20 mmol / kg and very preferably below 10 mmol / kg. The Solution viscosity of the polyamide is preferably according to ISO 307 from 1.4 to 2.0, particularly preferably from 1.5 to 1.8.

The sinter powder can also be a mixture made of regulated and unregulated polyamide. Preferably the sinter powder has a mixture of regulated and unregulated Polyamide, the proportion of regulated polyamide in the mixture from 0.1 to 99.9%, preferably from 5 to 95% and very particularly is preferably from 10 to 90%. Because the sinter powder is also a mixture of regulated and can have unregulated sintered powder, a user of Sinter powder the possibility old stocks if necessary continue to be used on unregulated sinter powder or unregulated back powder.

In principle, all polyamides can be used as regulated polyamides in the sinter powders. However, it can be advantageous if the sintered powder has a regulated polyamide 12 or polyamide 11. In particular, it can be advantageous if the sintered powder has precipitated polyamide 12. The production of precipitated polyamide 12 can e.g. B. DE 29 06 647 be removed. The sintering powder according to the invention particularly preferably has polyamide 12 precipitation powder with a round grain shape, such as that used, for. B. according DE 197 08 946 or DE 44 21 454 can be produced. The sinter powders according to the invention very particularly preferably have a regulated polyamide 12 with a melting temperature of 185 to 189 ° C., a melting enthalpy of 112 ± 17 kJ / mol and a solidification temperature of 138 to 143 ° C., as is unregulated in EP 0 911 142 is described on.

The sinter powder according to the invention preferably has polyamide with an average particle size d ₅₀ of 10 to 250 μm, preferably of 30 to 100 μm and very particularly preferably of 40 to 80 μm.

The controlled sintered powder according to the invention has preferably after heat aging of the powder a recrystallization temperature (recrystallization peak in the DSC) and / or an enthalpy of crystallization that not compared to smaller values moved to the new powder. Under heat aging it becomes a Exposing the powder to a few minutes to several days of a temperature in the range of Recrystallization temperature up to a few degrees below the melt temperature Roger that. A typical artificial aging can e.g. B. at a temperature with a deviation of approx. plus minus 5 K corresponds to the recrystallization temperature, for 5 to 10, preferably for 7 days. Aging occurs when the powder is installed typically at a temperature of 1 to 15, preferably of 3 to 10 K below the melt temperature for a few minutes up to two Days, depending on how long the construction time for the respective component is. The heat aging happens in laser sintering that powder, which in layers Structure of the three-dimensional object not detected by the laser beam will while of the construction process in the construction space temperatures of only a few degrees below exposed to the melt temperature. Preferred regulated according to the invention Sinter powder shows after heat aging of the powder a recrystallization temperature (a recrystallization peak) and / or an enthalpy of crystallization that results in larger values moves there. Both the recrystallization temperature preferably shift as well as the crystallization enthalpy to larger values. Most notably preferably has a powder according to the invention, which as a new powder has a recrystallization temperature greater than 138 ° C, a recrystallization temperature as waste powder, obtained by aging for 7 days at 135 ° C was, which from 0 to 3, preferably from 0.1 to 1 K above the Recrystallization temperature of the new powder is.

The sintered powder can at least in addition a regulated polyamide at least one other filler exhibit. Such fillers can z. B. glass, metal or ceramic particles. In particular, can the sinter powder glass balls, steel balls or grits as fillers exhibit.

The filler particles preferably have a smaller or approximately the same average particle size as the particles of the polyamides. The average particle size d _{50 of} the fillers should preferably not exceed the average particle size d _{50 of} the polyamides by more than 20%, preferably by no more than 15% and very particularly preferably by no more than 5%. The particle size is particularly limited by the permissible layer thickness in the respective laser sintering apparatus.

The sinter powder according to the invention is preferably produced by the process described below ren to produce a sinter powder. In this method, a sintered powder is produced based on a polyamide, a polyamide being used which is regulated, that is to say that it has an excess of carboxyl end groups. It has surprisingly been found that a completely recyclable sintered powder is obtained which, in terms of its structural properties, almost corresponds to a new powder if a starting base polyamide with an excess of carboxyl end groups is used for the powder production of the new powder. This polyamide preferably has from 0.01 part to 5 parts, preferably 0.1 to 2 parts, of a mono- or dicarboxylic acid as regulator. The regulated polyamide preferably has a ratio of carboxyl end group to amino end group of 2: 1 or greater, preferably from 5: 1 to 500: 1 and particularly preferably from 10: 1 to 50: 1. It can be advantageous to use a polyamide for the production of the sinter powder which has an amino end group content of less than 40 mmol / kg polyamide, preferably less than 20 mmol / kg polyamide and very preferably less than 10 mmol / kg polyamide.

The preparation of the regulated polyamides is described below. The main features of the production of the regulated polyamides are already over DE 44 21 454 and DE 197 08 946 known. In these documents, these polyamides are described as insert granules for the reprecipitation into fluidized bed powders.

As a controller are z. B. linear, cyclic and branched, organic mono- and dicarboxylic acids with 2 - 30 Carbon atoms. As non-limiting examples of dicarboxylic acids Succinic acid, glutaric, adipic acid, 2,2,4-trimethyl, suberic, sebacic, dodecanedioic, Brassylic acid, and terephthalic acid as well as mixtures of corresponding dicarboxylic acids. Suitable monocarboxylic acids are for example benzoic acid, butyric acid, Valeric acid, caproic, caprylic, Capric acid, Lauric acid, myristic, palmitic and stearic acid. Mono- or dicarboxylic acids, the carbon chains, are particularly suitable with a length have from 6 to 30 carbon atoms. So that the polyamides in Laser sintering can be used without problems, are preferred as regulators no volatile Carboxylic acids, especially no carboxylic acids with a boiling point less than 150 ° C, particularly preferably less than 180 ° C. and very particularly preferably less than 190 ° C. The use of volatile carboxylic acids can be particularly annoying when laser sintering if it is still not in chemically bound form in the sinter powder because they evaporate during the sintering process and the laser optics through smoke impair and in the worst case, the device to damage can.

The concept of mono, respectively dicarboxylic acid both the functional group of the free carboxylic acid and also include all functional derivatives of the respective carboxylic acid, such as acid halides, Ester functions, amide functions, anhydrides, nitriles or the corresponding Carboxylate salts operating under the conditions of a polymerization / polycondensation each in the free carboxylic acid can be converted.

The controller is already advantageous introduced into the polyamide during the polymerization. The polymerization can both from the respective lactam, for. B. Laurinlactam or of the corresponding ω-aminocarboxylic acid, e.g. B. ω-aminododecanoic acid.

However, it is also possible within the meaning of the invention to implement the regulator in the melt or in the solid phase or in solution with a high molecular weight polyamide, provided the amino end groups are reacted to the extent described above under the reaction conditions. The implementation of the polyamide with the regulator is fundamentally also during the production of the polyamide after the in DE 29 06 647 described felling process possible. In this precipitation process, polyamide 12 is dissolved in a solvent, preferably ethanol, and crystallized from this solution under certain conditions. The addition of the controller can z. B. in the solution of polyamide 12.

If a polyamide based on diamines and dicarboxylic acids, so-called AABB polyamides, is used, the synthesis is carried out in a known manner from solutions of the corresponding nylon salts or from melts of the diamines and dicarboxylic acids. It can be advantageous if the molten dicarboxylic acids are used to prevent discoloration by adding primary amines DE 43 171 89 are stabilized.

According to the invention, the AABB type is also a polyamide made with an excess of carboxyl end groups, which is 0.01 part to 5 parts, preferably 0.1 to 2 parts Mono- or dicarboxylic acid has as a controller. The regulated polyamide preferably has a AABB type a ratio from carboxyl end group to amino end group of 2: 1 or larger, preferably from 5: 1 to 500: 1 and particularly preferably from 10: 1 to 50 : 1 on. In this case too, it can be advantageous if a AABB-type polyamide used to manufacture the sinter powder which has an amino end group content of less than 40 mmol / kg polyamide, preferably less than 20 mmol / kg polyamide and very preferably less 10 mmol / kg polyamide. All of the above can be used for regulation carboxylic acids be used, the one used for control with the AABB polyamide carboxylic acid also of dicarboxylic acid of the polyamide can correspond.

The controlled polyamide obtained is granulated and then either ground or, advantageously, appropriately DE 29 06 647 . DE 19 708 946 or DE 4 421 454 (Hüls AG) processed into a powdered precipitate.

The new powders based on polyamide used for laser sintering and produced according to the method of the invention typically have a solution viscosity according to ISO 307, with 1% phosphorus acid-doped m-cresol as solvent and 0.5 wt .-% polyamide based on the solvent, from η _rel. = 1.4 to 2.0, preferably a solution viscosity of η _rel. = 1.5 to 1.8. In the laser sinter powder according to the invention, which contains 0.01 part to 5 parts, preferably 0.1 to 2 parts, of a mono- or dicarboxylic acid as regulator, the solution viscosity and the amino end group content of the return powder hardly changes compared to the new powder, so that the protective powder can be processed again after protective screening.

Preferably the powder remains, obtained from the use of a new powder produced according to the invention, a content of amino end groups less than 40 mmol / kg polyamide, preferably less than 20 mmol / kg polyamide and very particularly preferably less 10 mmol / kg polyamide, according to the selected specifications of the new powder.

For the production of the sinter powder it can be advantageous to create a mixture that is in addition to regulated Polyamide powder as new powder also regulated polyamide powder as recycling powder having. A mixture can also be produced as sinter powder, which, in addition to regulated polyamide powder, also unregulated polyamide powder having. Moreover it can be advantageous if a mixture is produced as the sinter powder which, in addition to regulated polyamide, also various fillers such as B. glass particles, ceramic particles or metal particles. Typical fillers are z. B. metal grit, steel or glass balls.

The filler particles preferably have a smaller or approximately the same average particle size as the particles of the polyamides. The average particle size d _{50 of} the fillers should preferably not exceed the average particle size d _{50 of} the polyamides by more than 20%, preferably by no more than 15% and very particularly preferably by no more than 5%. The particle size is particularly limited by the permissible overall height or layer thickness in the laser sintering apparatus. Glass spheres with an average diameter of 20 to 80 μm are typically used.

The sinter powder according to the invention is preferred in a process for the production of moldings by selective laser sintering sintered powder, which is characterized in that a sintered powder, which polyamide with a carboxyl end group excess, a so-called has regulated polyamide, is used, used.

Preferably, the one used Sinter powder in this process is a regulated polyamide with a relationship from carboxyl end groups to amino end groups of greater than 2: 1, with an amino end group content less than 40 mmol / kg and a relative solution viscosity according to ISO 307 from 1.4 to 2.0. The sinter powder can be polyamide 11 and / or Have polyamide 12.

It can be advantageous if at this process, a sinter powder is used, which is mixed with mono- or dicarboxylic acids or derivatives thereof regulated polyamide. The sinter powder can be one with one or more linear, cyclic or branched organic mono- or dicarboxylic acids or derivatives thereof with 2 to 30 carbon atoms regulated polyamide exhibit.

Preferably in the method according to the invention For laser sintering, a sinter powder is used, which is a polyamide powder with a relative solution viscosity according to ISO 307 from 1.5 - 1.8 having.

It has proven to be particularly beneficial proven if a sintered powder in the inventive method is used, which the carboxylic acid used for control with a content of 0.01 to 5% by weight, preferably 0.1 to 2% by weight has based on the polyamide used and its content of Amino end groups below 20 mmol / kg, preferably less than 10 mmol / kg Polyamide.

The procedure can be carried out that a sinter powder is used, which is a mixture of has regulated and unregulated polyamide powder, in which the proportion of controlled powder from 0.1 to 99.9%, preferably from 5 to 95%, particularly preferably from 25 to 75%.

That in the method according to the invention sintered powder used, which has a regulated polyamide, can new powder, return powder or a mixture of new powder and return powder. It can be beneficial if the process is carried out in this way, the back powder or mixtures of return powder and new powder, the proportion of new powder less than 50%, preferably is less than 25% and very particularly preferably less than 10% Sinter powder can be used. Sintered powder is particularly preferred used which has at least 40 wt .-% return powder.

The sinter powder used can Moreover Packing, preferably have inorganic packing. As such inorganic packing z. B. glass particles, ceramic particles or glass balls can be used.

By the method according to the invention and by the use and application of the sinter powder according to the invention are shaped bodies, Made by selective laser sintering, which is a regulated polyamide have accessible. In particular, they are molded articles which have a regulated polyamide 12 accessible. Molded bodies are also available have a mixture of regulated and unregulated polyamide, where the proportion of regulated polyamide in the polyamide blend Is 0.1 to 100%.

The moldings according to the invention can in particular also be produced by using a sinter powder according to the invention as aged material (aging as described above), this having a recrystallization peak and an enthalpy of crystallization, which are in each case not less than that of the non-aged material. A molded body according to the invention is preferably used tion of an aged material which has a higher recrystallization peak and a higher enthalpy of crystallization than the non-aged material. Despite the use of waste powder, the moldings have almost the same properties as moldings made from new powder.

Molded parts, the regulated polyamide, have regulated polyamide 12 in particular, are much more ecological and more economical in their manufacture since it is possible is all of the back powder for the production of moldings use.

The following examples of aging behavior of the polyamide powder are intended to describe the invention in more detail without being based on it restrict the examples.

Example 1: Reprecipitation of unregulated polyamide 12 (PA 12), according to DE-OS 35 10 690

400 kg of uncontrolled PA12 produced by hydrolytic polymerization of laurolactam with a relative solution viscosity η _rel. of 1.60 (in acidified m-cresol) and with an end group content of [COOH] = 72 mmol / kg and [NH ₂ ] = 68 mmol / kg are mixed with 2500 1 ethanol, denatured with 2-butanone and 1% water content, within 5 Hours in a 3 m ³ stirred kettle (d = 160 cm) at 145 ° C. and left under stirring (blade stirrer, d = 80 cm, speed = 85 rpm) at this temperature for 1 hour.

Then the jacket temperature to 124 ° C reduced and with continuous distillation of the ethanol with a cooling rate of 25 K / h at the same stirrer speed the internal temperature to 125 ° C brought. From now on, the jacket temperature will be the same at the same cooling rate Keep 2K to 3K below the internal temperature until the precipitation is recognizable at 109 ° C on the heat development, starts. The distillation speed is increased to such an extent that the inside temperature does not exceed 109.3 ° C increases. After 20 minutes falls the inside temperature, which indicates the end of the precipitation. By further Distill off and cool over the The temperature of the suspension is brought to 45 ° C. and the suspension then transferred to a paddle dryer. The ethanol becomes at 70 ° C / 400 mbar distilled off, and the residue subsequently at 20 mbar / 85 ° C 3 hours after drying.

A sieve analysis showed the following values:
<32μm: 8% by weight
<40μm: 17% by weight
<50μm: 26% by weight
<63μm: 55% by weight
<80μm: 92% by weight
<100μm: 100% by weight

The product had a bulk density from 433 g / l.

Example 2: reprecipitation of regulated PA 12

The experiment from Example 1 was repeated with a PA 12 granulate which had been obtained by hydrolytic LL polymerization in the presence of 1 part of dodecanedioic acid per 100 parts of laurolactam: η _rel. = 1.55, [COOH] = 132 mmol / kg, [NH ₂ ] = 5 mmol / kg. With the exception of the stirrer speed (100 rpm), the dissolving, precipitation and drying conditions correspond to those selected in Example 1. The product had a bulk density of 425 g / l.

A sieve analysis showed the following values:
<32μm: 8% by weight
<40μm: 27% by weight
<50μm: 61% by weight
<63μm: 97% by weight
<90μm: 100% by weight

Example 3: (according to the invention)

The unregulated polyamide powder from Example 1 was mixed with the regulated polyamide powder from Example 2 in a ratio of 1: 1. The mixture has an η _rel. = 1.58.

Example 4: (comparative example)

The powder from Example 1 was mixed with Glass balls (40 - 80μm) as filler in relation to 3: 2 added and mixed.

Example 5

The powder was analogous to Example 4 from Example 2 with glass balls (40 - 80μm) as filler in the ratio 3 : 2 offset and mixed.

Example 6:

The thermal effects during laser sintering were simulated in time lapse by temperature tests in a drying cabinet at 160 ° C. The sintered powders from Examples 1 to 5 were used. The η _rel values for post-condensation as a function of the duration of the tempering tests are summarized in Table 1: Table 1: tempering tests at 160 ° C. in a drying cabinet (example 6)

Using the examples can be very good can be recognized that the sintered powder according to the invention according to the examples 2, 3 and 5, all of which have a regulated polyamide, clearly one show less increase in solution viscosity, as sinter powder according to the state of the technique. The sinter powder according to the invention have a solution viscosity of less even after a test time of 8 hours 2 on, and would be with it as powder can be used again for laser sintering.

The following examples 7 and 8 show the change the solution viscosity of regulated and non-regulated polyamide 12 powder depending on the construction time the implementation of laser sintering. Example 8 shows the change in solution viscosity for a mixture from regulated and unregulated material when carrying out the Laser-sintering.

Example 7: (comparative example)

A sinter powder was produced according to Example 1 and used in a laser sintering system (EOSINT P 350, EOS GmbH, Planegg). After a construction time of 30 h, the solution viscosity is η _rel. = 1.94, after 65 h at 2.10.

Example 8

A sinter powder was produced according to Example 2 and used in a laser sintering system (EOSINT P 350, EOS GmbH, Planegg). After a construction time of 70 h, the solution viscosity of the back powder is η _rel. = 1.59.

It is clear to see that that recycling powder from Example 8 after a protective screening with a sieve with a Mesh size of 200 μm in contrast to the back powder from Example 7 can be used again for laser sintering can.

Example 9

It is a mixture in a weight ratio of 1: 1 from controlled sinter powder according to Example 2 and unregulated material produced according to Example 1 and used according to Examples 7 and 8. The mixture has a solution viscosity of η _rel. = 1.57. After a construction time of 45 h, the solution viscosity is η _rel. = 1.74.

It is clear to see that the Mixture of sinter powder with regulated polyamide and sinter powder with unregulated polyamide has a much greater stability of the solution viscosity than the sinter powder according to the example 7th

Examples 10a-c (Comparative Examples) 10 d (according to the invention) annealing and thermal load in the rotary piston:

For example 10a, a powder prepared in accordance with example 1 was used unchanged. For Examples 10b and c, 0.1% by weight of hypophosphorous acid and 0.5% by weight of orthophosphoric acid are added to the suspension during drying. For example 10 d, a sample according to example 2 is provided with the same acid equipment. For the model tests, a 100 g sample of the dried powder was kept in a rotary flask under a constant nitrogen flow of 5 l / h for 24 hours at 165 ° C. The structure of the solution viscosities in neutral or phosphoric acid-doped m-cresol is monitored (Table 2, 1 - 3 ) and the consumption of acidic or basic end groups compared (Table 2). As with the table and figures 1 to 3 It can be seen that only the sample according to the invention according to Example 10d does not change its end group contents or solution viscosity over the entire exposure time.

The figures 1 to 3 show the course of the solution viscosities depending on the annealing time. 1 shows the curve for the powder according to Example 10a. 2 shows the curve for the powder according to Example 10 b. 3 shows the curve for the powder according to Example 10 c. The graphical representation of the results from Example 10d was omitted, since no significant change in the solution viscosity could be found over the test period.

Table 2: Tempering tests at 165 ° C according to Example 10:

Example 11: Aging attempts

For an artificial one heat aging was the powder from Example 1 and Example 2 in a vacuum drying cabinet for 7 days at 135 ° C artificially aged.

For further investigation of powder according to the invention were both made according to the invention Powder as well as on samples of components according to DSC investigations DIN 53765 with a DSC device (Perkin Elmer DSC 7). The results of these tests are summarized in Table 3.

Table 3: Results of the aging tests

As based on the results in the table 3 can be clearly seen, the powder according to the invention according to example 2 a recrystallization temperature (recrystallization peak) after the aging process on that even higher is the recrystallization temperature of the new material. The known unregulated reference powder according to the example 1 shows a clear decrease in the recrystallization temperature after going through the aging process.

Claims (30)

Sinter powder for selective laser sintering, characterized in that it has a polyamide with an excess of carboxyl end groups, a so-called regulated polyamide. Sinter powder according to claim 1, characterized in that it has a polyamide which has a ratio of carboxyl end group for amino end group greater than 2: 1, an amino end group content below 40 mmol / kg and a relative Solution viscosity according to ISO 307 from 1.4 to 2.0. Sinter powder according to claim 1 or 2, characterized in that that it has a regulated polyamide 12. Sinter powder according to one of claims 1 to 3, characterized in that that it has a mixture of regulated and unregulated polyamide. Sinter powder according to claim 4, characterized in that it has a mixture of regulated and unregulated polyamide, the proportion of regulated polyamide in the mixture of 0.1 is up to 99.9%. Sinter powder according to one of claims 1 to 5, characterized in that there is at least one in addition to at least one regulated polyamide further filler having. Sinter powder according to claim 6, characterized in that it is as a filler Has glass particles. Sinter powder according to at least one of claims 1 to 7, characterized in that it is from 5 to 100% return powder, unexposed powder from a previous laser sintering process, having. Sinter powder according to at least one of claims 1 to 7, characterized in that after heat aging of the powder Recrystallization peak and / or the enthalpy of crystallization Powder does not shift to smaller values. Sinter powder according to at least one of claims 1 to 8, characterized in that after heat aging of the powder Recrystallization peak and / or the enthalpy of crystallization itself to larger values shifts. Process for the production of moldings by selective laser sintering of sinter powder, thereby characterized in that a sintered powder which has polyamide with an excess of carboxyl end groups, a so-called regulated polyamide, is used A method according to claim 11, characterized in which is a sinter powder, which polyamide with a ratio of Carboxyl end groups to amino end groups of greater than 2: 1, with an amino end group content less than 40 mmol / kg and a relative solution viscosity according to ISO 307 from 1.4 to 2.0, is used. Method according to claim 11 or 12, characterized in that that a sinter powder is used, which polyamide 11 and / or Has polyamide 12. Method according to at least one of claims 11 to 13, characterized in that a sinter powder is used, which is regulated with mono- or dicarboxylic acids or derivatives thereof Has polyamide. A method according to claim 14, characterized in that a sinter powder is used, which one with or several linear, cyclic or branched organic mono- or dicarboxylic acids or Derivatives thereof regulated polyamide with 2 to 30 carbon atoms having. Method according to one of claims 11 to 15, characterized in that that the sintered powder used is a polyamide powder with a relative Solution viscosity according to ISO 307 from 1.5 to 1.8. Method according to one of claims 11 to 16, characterized in that that a sinter powder is used, which is used for regulation carboxylic acid used with a content of 0.01 to 5 wt .-% based on the used Has polyamide and its content of amino end groups below 20 mmol / kg polyamide. A method according to claim 17, characterized in that a sinter powder is used. which is to regulate carboxylic acid used with a content of 0.1 to 2 wt .-% based on the used Has polyamide and its content of amino end groups below 10 mmol / kg polyamide. Method according to one of claims 11 to 18, characterized in that that a sinter powder is used, which is a mixture of has regulated and unregulated polyamide powder, in which the Proportion of regulated powder from 0.1 to 99.9%. Method according to one of claims 11 to 19, characterized in that that the sintered powder has inorganic packing. A method according to claim 20, characterized in that as filler glass balls be used. Method according to one of claims 11 to 21, characterized in that that a sinter powder is used, which is from 5 to 100% return powder having. Moldings, produced by selective laser sintering of sinter powder, thereby characterized that the molded body has a regulated polyamide. moldings according to claim 23, characterized in that the molded body has regulated polyamide 12. moldings according to claim 23, characterized in that the molded body a Mixture of regulated and unregulated polyamide and that that the proportion of regulated polyamide in the polyamide mixture 0.1 is up to 100%. moldings according to one of the claims 23 to 25, characterized in that the molded body using of aged material that has a recrystallization peak and has an enthalpy of crystallization, each not less than that of the non-aged material. Shaped body according to claim 26, characterized in that the shaped body is produced using aged material which has a higher recrystallization peak and a higher crystallization enthalpy of ion than the non-aged material. Process for the production of sinter powder according to at least one of the claims 1 to 9, characterized in that a regulated Polyamide powder is used, which by treatment of a unregulated polyamide is obtained with a carboxylic acid as a regulator. A method according to claim 28, characterized in that the treatment by reacting the unregulated polyamide during the Polymerization takes place. A method according to claim 28, characterized in that the treatment of the unregulated polyamide by reacting a high molecular polyamide with a regulator in the melt, in solid Phase or in solution he follows.