EP1932817A1 - Nitratoethyl nitroamine propellant for automobile safety systems - Google Patents

Abstract

The propellant comprises a binder, a nitratoethylnitroamine softener, preferably butyl nitratoethylnitroamine (Butyl NENA) and an oxidizer, which is free from heavy metals. The binder is a mixture of inert and energetic cellulose derivatives, which is present in 5-30 wt.%, particularly 10-25 wt.% of the mixture. The inert cellulose derivative is a derivative of acetate butyrate and energetic cellulose is a derivative of nitrocellulose.

Description

Technical area

An extruded propellant for use in automotive safety systems comprising a binder, a plasticizer of the chemical group of nitratoethylnitroamines, and an oxidizer.

State of the art

Gas generators are today used in large quantities, among other things for safety devices for vehicles (airbag, belt tensioners, activators, etc.). This is located in an encapsulation an energetic propellant (also known as fuel or propellant), which is ignited in an emergency by an igniter and which generates the necessary amount of gas to inflate, for example, the airbag or trigger the mechanics of a belt tensioner. The detonator is initiated by an external accelerometer. Such gas generators are available in different embodiments. By way of example, reference is made to the gas generator device US 5,062,365 directed.

Modern propellants for safety devices in vehicles require that they contain no toxic components or that no polluting substances are produced during their combustion. The latter condition requires careful balancing of the oxygen balance of the propellant. The term "oxygen balance" is understood to mean that amount of oxygen in% by weight which is free or required in the case of complete conversion of a compound or composition into CO ₂ , H ₂ O, Al ₂ O _3, etc. For example, the proportions of toxic nitrogen oxides (NO _x ) and carbon monoxide (CO) are below the specified limit values of 80 and 461 ppm in the vehicle compartment only when the oxygen balance is balanced or slightly underbalanced.

During the entire life cycle of a motor vehicle, a propellant must remain fully functional. Particularly in the case of new pedestrian protection applications in the hot engine compartment, very high thermal stability is required. The required temperature storage of up to 1000 h at 90 and 107 ° C can only be met by consistent elimination of thermally labile compounds and incompatibilities of a composition.

In the automotive industry today, an increased miniaturization of all systems including the safety devices is required. Therefore, an almost particle-free and gas-rich combustion of the blowing agent is desirable, which allows the waiver of filter devices in the gas generator and a reduction of the amount of gas generator, so that the size and weight of the gas generators can be further reduced. A similar reduction can be achieved by simplifying the igniter chain with more propellant propellants.

Most of the airbag propellants consist of pourable oxygen-balanced pyrotechnic mixtures, which are ground, mixed and pressed into pills. However, due to the limited variability of vivacity and low gas yields, pyrotechnic propellants have not yet prevailed in rapid implementations such as in belt tensioners. In these applications with significantly lower gas volumes, largely non-oxygenated nitrogen-based propellants based on nitrocellulose are still used today. (H. Andres, J. Rebetez, A. Skriver, B. Stucki, C. Wagner, Nitrochemie's New Genereration of nitrocellulose-based and polymer-bounded Propellants, Proceedings of the 7 ^th International Symposium and Exhibition of Sophisticated Car Occupant Safety Systems, 2004). The oxygen sub-balancing must be compensated by a high proportion of oxidizing agents. In the EP 1 205 459 A1 For example, a gas-generating mixture for pretensioner systems based on a thermally stabilized binder, an oxidizing agent and optionally a chlorine-neutralizing additive is described as the main components. Among others, cellulose derivatives with common inert and energetic plasticizers are known as thermally stabilized binders. The proportion of the binder is 7-30 wt.%, That of the oxidizing agent in the range 70-93 wt.%. To stabilize the binder, derivatives of diphenylamine, aromatic urea compounds, resorcinol and mixtures thereof are added proportionally to 1.2% by weight. The plasticizers used are predominantly inert phthalates, citrates, adipates and glycolates up to 5% by weight. The only known energetic plasticizer is diethylene glycol dinitrate, a pure nitrate ester compound with moderate stability properties.

For defense technology propellants and explosives energetic plasticizers from the class of Nitratoethylnitroamine have proven to be advantageous ( US 6,997,996 and US 5,507,893 ). Compared with conventional energetic plasticizers, they are safer to handle, but at the same time have very good softening properties and a high energy content.

In der US 6,875,295 werden extrudierte schüttbare Treibmittel für Airbags auf der Basis von Celluloseacetatbutyrat mit Butyl-Nitratoethylnitroamin mit einem Gehalt von mindestens 50 Gew. % an basischem Kupfernitrat beschrieben. Im Weiteren enthält das Treibmittel Guanidinnitrat und/oder Cobalt(II)-Hexaminnitrat. Der Anteil des Binders beträgt zwischen 5 und 20 Gew. %. Bei der Verbrennung von basischem Kupfernitrat entsteht vorerst flüssiges Kupfer, und nach Abkühlung unter 1000 °C festes Kupferoxid. Mit einem Massenanteil des Kupfers von bis zu 25 Gew. % reduziert sich aber die Gasausbeute beträchtlich. Dergleichen gilt für den Einsatz von Cobalt(II)-Hexaminnitrat, welches zudem noch toxische Feststoffe nach der Verbrennung bilden kann. Über die thermische Stabilität der Stoffzusammensetzungen in Bezug auf die Anforderungen für Sicherheitssysteme in Kraftfahrzeugen wird nichts berichtet. Es ist jedoch bekannt, dass Schwermetalle wie Kupfer nur beschränkte Verträglichkeit mit Nitratestern wie Butyl-Nitratoethylnitroamine aufweisen ( Beat Vogelsanger, Chemical Stability, Compatibility and Shelf Life of Explosives, Chimia 2004, 58 (6), 401-408 ). Es ist daher davon auszugehen, dass die verlangte thermische Stabilitätsanforderung mit der beschriebenen Zusammensetzung nicht erfüllt werden kann.Nitratoethylnitroamines have a nitramine and a nitrate ester functionality as well as an alkyl radical which can be adapted to the polymer's polarity to optimize plasticiser properties. The three most important representatives are methyl-nitratoethylnitroamine (1), ethyl-nitratoethylnitroamine (2) and butyl-nitratoethylnitroamine (3).

In the US 6,875,295 EP-A-0 470 865 describes extruded airbag blown propellants based on cellulose acetate butyrate with butyl-nitratoethylnitroamine containing at least 50% by weight of basic copper nitrate. In addition, the propellant contains guanidine nitrate and / or cobalt (II) hexamine nitrate. The proportion of the binder is between 5 and 20 wt.%. The combustion of basic copper nitrate initially produces liquid copper, and after cooling below 1000 ° C solid copper oxide. However, with a copper content of up to 25% by weight, the gas yield is considerably reduced. The same applies to the use of cobalt (II) hexamine nitrate, which can also form toxic solids after combustion. Nothing is reported about the thermal stability of the compositions in relation to the requirements for safety systems in motor vehicles. However, it is known that heavy metals such as copper have only limited compatibility with nitrate esters such as butyl-Nitratoethylnitroamine ( Beat Vogelsanger, Chemical Stability, Compatibility and Shelf Life of Explosives, Chimia 2004, 58 (6), 401-408 ). It can therefore be assumed that the required thermal stability requirement can not be met with the described composition.

There is therefore still a need for a flowable propellant, which does not have the aforementioned negative properties in terms of toxicity, stability and / or gas yield and can also be produced more cost-effectively.

Presentation of the invention

The object of the invention is to provide a blowing agent associated with the technical field mentioned above, which is particle-free and environmentally harmless burnable at high gas yield and also has a high thermal long-term stability at elevated temperatures.

The solution of the problem is defined by the features of claim 1. According to the invention, the propellant contains a binder, a plasticizer of the chemical group of nitratoethyl nitroamines and an oxidizer free of heavy metals.

In the present invention, heavy metal-free is understood to mean that the blowing agent contains less than 100 ppm (parts per million) of heavy metals.

• • Überraschenderweise wurde gefunden, dass sich durch den Einsatz von energetischen Nitratoethylnitroaminen als Weichmacher in Kombination mit nichtschwermetallhaltigen Oxidatoren in Treibmitteln sehr gute Werte bezüglich Langzeitstabilität bei hohen Temperaturen darstellen lassen; teilweise deutlich höher als bei der Verwendung von herkömmlichen inerten Weichmachern. Trotz der vorhandenen Nitratestergruppe erfüllen die gefertigten Treibmittel die Langzeitlagerung bis zu 1000 h bei 90 und 107 °C. Aufgrund der chemischen Ähnlichkeit mit den Nitratester der Nitrocellulose erwartete man eine autokatalytische Zersetzung nach 250 h bei 107 °C.
• • Durch die Zusammensetzung der erfindungsgemässen Treibmittel wird eine bestmögliche umwelttoxikologische Entlastung erreicht, da sämtliche Verbrennungsprozesse nur schwach negative Sauerstoffbilanzen aufweisen und vollständig auf schwermetallhaltige Komponenten im Treibmittel verzichtet wird.
• • Die partikelfreie Verbrennung der erfindungsgemässen Treibmittel ermöglicht den Verzicht auf Filtervorrichtungen in Automobilsicherheitssystemen, wodurch das Gewicht und die Baugrösse des Gasgenerators reduziert werden kann.
• • Durch die Extrudierbarkeit während des Herstellungsprozesses wird eine kostengünstige Produktion möglich, da die erfindungsgemässen Treibmittel auf bestehenden Produktionsanlagen verarbeitet werden können.

Compared with the prior art, the present invention offers, inter alia, the following advantages:

• Surprisingly, it has been found that the use of energetic nitratoethylnitroamines as plasticizers in combination with non-heavy metal-containing oxidizers in blowing agents makes it possible to obtain very good values with respect to long-term stability at high temperatures; sometimes significantly higher than with the use of conventional inert plasticizers. Despite the existing nitrate ester group, the manufactured propellants fulfill long-term storage for up to 1000 h at 90 and 107 ° C. Due to the chemical similarity with the nitrate esters of nitrocellulose was expected to autocatalytic decomposition after 250 h at 107 ° C.
• The composition of the blowing agents according to the invention achieves the best possible environmental toxicological relief, since all the combustion processes have only weakly negative oxygen balances and completely omit heavy metal-containing components in the blowing agent.
• • The particle-free combustion of the inventive blowing agent makes it possible to dispense with filter devices in automotive safety systems, whereby the weight and the size of the gas generator can be reduced.
• • Due to the extrudability during the manufacturing process, a cost-effective production is possible because the inventive blowing agent can be processed on existing production equipment.

Suitable binders are a variety of polymeric materials, inert variants as they are used in the plastics industry and energetic variants as they are known from military technology. Examples of inert binders are cellulose acetate (CA, CAS #: 9004-35-7), cellulose acetate butyrate (CAB, CAS #: 9004-36-8), sodium carboxymethylcellulose (Na-CMC, CAS #: 9004-32-4), hydroxyethylcellulose (HEC, CAS #: 9004-62-0), hydroxypropylcellulose (HPC, CAS #: 9004-64-2), methylcellulose (MC, CAS #: 9004-67-5 Ethylcellulose (EC, CAS #: 9004-57-3), ethyl 2-hydroxyethylcellulose (EHC, CAS #: 9004-58-4), carboxymethylethylcellulose (CMEC, CAS #: 37205-99- 5), starch (CAS #: 9005-25-8), guar gum (CAS #: 9000-30-0), polyvinyl alcohol (PVA, CAS #: 9002-89-5), polyacrylamide (CAS #: 9003-05-8), silicone (CAS #: 7440-21-3), acrylic rubber (CAS #: 9006-04-6), polystyrenes (PS, CAS #: 9003-53-6), polybutadiene ( PB, CAS #: 9003-17-2), polyethyleneglycol (PEG; CAS #: 25322-68-3), polyisobutylene (PIB, CAS #: 9003-27-4), polyvinyl chloride (PVC; CAS # : 9002-86-2), polyurethane (PU, CAS #: 9009-54-5), hydroxyl-terminated polybutadiene (HTPB), and carboxyl-terminated polybutadiene (CTPB). Examples of energetic binders include nitrocellulose (NC, CAS #: 9004-70-0); Glycidyl azide polymer (GAP, CAS #: 143178-24-9), polyvinyl nitrate (PVN), 3-nitratomethyl-3-methyl-oxetane (poly-NIMMO; CAS #: 84051-81-0), bis-nitrato-methyl Oxetane (poly-BNMO), poly-3-azidomethyl-3-methyl-oxetane (poly-AMMO; CAS #: 90683-29-7), poly (3,3-bis-ethoxymethyl-oxetane (poly -BEMO), poly-3,3-bis-azidomethyl-oxetane (poly-BAMO; CAS #: 17607-20-4), poly-2,2-bisazidomethyl-1,3-propanediol glutarate (PAP-G), Dinitropropanediol polyadipate (PAD), polyacrylonitrile (PAC, CAS #: 25014-41-9), polynitrophenylene (PNP), petrin acrylate and polyformal (CAS #: 9002-81-7).

Preference is given to binder materials which can be plastically deformed in a solvent process or by heating with addition of plasticizer.

Inert and energetic cellulose derivatives have proven to be suitable; Particularly suitable are cellulose acetate, cellulose acetate butyrate, hydroxypropyl cellulose and nitrocellulose. All of these binder materials are available in finely ground form and can be processed using non-aqueous solvents; which is particularly suitable for the processing of water-sensitive oxidants.

Advantageously, a mixture of inert and energetic cellulose derivatives has been found, this results in a better oxygen balance, higher gas yield and good ignition properties.

Particularly advantageous is a mixture of cellulose acetate butyrate and nitrocellulose, which complement each other in terms of mechanical properties.

The proportion of the binder is chosen as low as possible due to its negative oxygen balance. However, in order to bind high solids content, a binder content of 5 to 30% has been found to be suitable. A proportion between 10 and 25% by weight has proven particularly suitable.

The proportion of the energetic binder is preferably between 1 and 15 wt.%, Particular preference is given to proportions between 2 and 10 wt.%.

Depending on the type of binder used stabilizing and softening additives must be added. The former to ensure a sufficient long-term stability at high temperatures for energetic cellulose derivatives and energetic plasticizers and to make the latter easier to process.

Suitable stabilizers for nitrate esters are in particular derivatives of diphenylurea and diphenylamine. Typical conventional stabilizers for energetic cellulose derivatives are, for example, acardite I (CAS #: 605-54-3), acardite II (CAS #: 13114-72-2), acardite III (CAS #: 18168-01- 9), diphenylamine (CAS #: 122-39-4), 2-nitrodiphenylamine (CAS #: 119-75-5), triphenylamine (CAS #: 603-34-9), resorcinol (CAS #: 108-46-3), Centralit-I (CAS #: 85-98-3) and Centralit-II (CAS #: 611-92-7). As advantageous, the use of Akardit II has been found to be a stabilizer of nitrocellulose, since Akardit II in contrast to diphenylamine forms virtually no carcinogenic N-nitrosamines during aging and generally shows a higher stabilizing effect.

Typically, a stabilizer content of 0.5 to 5 wt.% Based on the energetic components used. In the present case, a higher content up to 20 wt.% Has proven to be suitable. Optimal is a proportion of 3 to 15 wt.% Based on the nitrate ester compounds used.

As inert plasticizers are typically suitable polyoxo compounds, as they are known in the plastics industry and are industrially used for plasticizing mass plastics. Examples of these are, for example, a polyester or a polyether compound having an average molecular weight of 100-10,000 g / mol. Preference is given to citrate esters, adipic acid esters, sebacic acid esters and phthalic acid esters (or hydrogenated cyclohexyl derivatives thereof) or combinations thereof. Examples include acetyl triethyl citrate (CAS #: 77-89-4), triethyl citrate (CAS #: 77-93-0), tri-n-butyl citrate (CAS - #: 77-94-1), tributyl acetyl citrate ( 77-90-7), acetyltri-n-butyl citrate (CAS #: 77-90-7), acetyltri-n-hexyl citrate (CAS #: 24817-92-3), n-butyryltri-n-hexyl citrate (CAS - #: 82469-79-2), di-n-butyl adipate, diisopropyl adipate (CAS #: 6938-94-9), diisobutyl adipate (CAS #: 141-04-8), di- ethylhexyl adipate (CAS #: 103-23-1), nonyl undecyl adipate, n-decyl n-octyl adipate (CAS #: 110-29-2), dibutoxyethoxy ethyl adipate, Dimethyl adipate (CAS #: 627-93-0), hexyl octyl decyl adipate, diisononyl adipate (CAS #: 33703-08-1), di-n-butyl sebacate (CAS #: 109-43-3), dioctyl sebacate (CAS #: 122-62-3), dimethyl sebacate (CAS #: 106-79-6), di-n-butyl phthalate (CAS #: 84 -74-2), di-n-hexyl phthalate (CAS #: 84-75-3), di-nonyl undecyl phthalate (CAS No. 111381-91-0), nonyl undecyl phthalate ( 685-15-43-5), mixtures of substantially linear C4-C11 alkyl phthalates (CAS #: 85507-79-5, 111381-91-0, 68515-45-7, 68 515-44-6, 68515-43-5, 111381-89-6, 111381-90-9, 28553-12-0), dioctyl terephthalate (CAS #: 6422-86-2), dioctyl isophthalates (CAS). #: 137-89-3), 1,2-cyclohexanedicarboxylic acid sononyl ester (CAS #: 166412-78-8), dibutyl maleate (CAS #: 105-76-0), dinonyl maleate (CAS #: 2787 -64-6), diisooctyl maleate (CAS #: 1330-76-3), dibutyl fumarate (CAS #: 105-75-9), dinonyl fumarate (CAS #: 2787-63-5) , Dimethyl sebacate (CAS #: 106-79-6), dibutyl sebacate (CAS #: 109-43-3), diisooctyl sebacate (CAS #: 27214-90-0), dibutyl azelate ( CAS #: 2917-73-9), diethylene glycol dibenzoate (CAS #: 120-55-8), Trioctyl trimellate (CAS #: 89-04-3), trioctyl phosphate (CAS #: 78-42-2), butyl stearate (CAS #: 123-95-5), glycerol triacetate (CAS #: 102 -76-1), epoxidized soybean oil (CAS #: 8013-07-8), epoxidized linen seed oil (CAS #: 8016-11-3). Some of the inert plasticizing additives are also available under the following trade names: Hexamoll Dinch from BASF, Citroflex types from Reilly-Morflex Inc., Greensboro, North Carolina USA, and others A-2, A-4, A-6, C- 2, C-4, C6, B-6, Paraplex types from CP Hall Co. Chicago, Illinois USA, including G25, G30, G51, G54, G57, G59, Santicizer types from Ferro Corporation, Cleveland, Ohio USA, 261 . 278 , Palatinol types of BASF, Germany.

Energetic plasticizers are typically used in propellant powders to accelerate projectiles; On the one hand, these can be distributed homogeneously over the grain matrix, as in the case of bivalent and polybasic propellant charge powders, or, on the other hand, they can be concentrated in the near-surface layers after a surface treatment. Examples of this are e.g. aliphatic nitrate esters, nitro compounds, nitramines and azides or combinations thereof having an average molecular weight of 100-1000 g / mol. Examples include nitroglycerin (NGL, CAS #: 55-63-0), diethylene glycol dinitrate (DEGN, CAS #: 693-210), triethylene glycol dinitrate (TEGN, CAS #: 111-22-8), ethylene glycol dinitrate (EGDN , CAS #: 628-96-6), 1,2,4-butanetriol trinitrate (BTTN, CAS #: 6659-60-5), nitropentaglycerol (MTN; CAS #: 3032-55-1), propanediol trinitrate ( NIBTN, CAS #: 20820-44-4), bis (2,2-dinitropropyl) acetal (BDNPA, CAS #: 5108-69-0), bis (2,2-dinitropropyl) formally (BDNPF, CAS) #: 5917-61-3), 2,4-Dintro-2,4-diazapentane (DNDA 5, CAS - #: 13232-00-3), 2,4-Dintro-2,4-diazahexane (DNDA 6) , 3,5-dinitro-3,5-diazapentane (DNDA 7), 1,5-diazido-3-nitroazapentane (DANPE, CAS # 89130-65-4), azido-polyglycine azide (GAPA), methyl-nitratoethylnitroamine ( Methyl-NENA, CAS # 17096-47-8), ethyl-nitratoethylnitroamine (ethyl-NENA, CAS # 85068-73-1), propyl-nitratoethylnitroamine (propyl-NENA, CAS # 82486-83-7), butyl-nitratoethylnitroamine (Butyl-NENA, CAS # 8246-82-6), pentyl-nitratoethylnitroamine (pentyl-NENA, CAS # 85954-06-9), and 1-azido-3- Nitrazapentane (ETAENA).

Particularly suitable for use with cellulose derivatives are the energetic plasticizers due to their weakly negative oxygen balance. As preferred the Nitratoethylnitroamine have been found because they have shown an additional stabilizing effect in addition to the plasticizing properties, the complete combustibility and the high gas yield. Butyl-Nitratoethylnitroamin is particularly suitable due to the strongest plasticizing effect and the low flame temperature.

Typically, the proportion of plasticizer is between 1 and 10 wt.%, In particular, proportions of 2 to 5 wt.% Prove to be optimal.

Preferably usable oxidizing agents are ammonium, alkali metal and alkaline earth metal salts of hydrochloric acid, perchloric acid, chromic acid, nitric acid and nitrous acid. Examples include barium chlorate (CAS #: 13477-00-4), ammonium perchlorate (CAS #: 7790-98-9), potassium perchlorate (CAS #: 7778-74-7), sodium perchlorate (CAS #: 7601- 89-0), barium chlorate (CAS #: 10294-40-3), ammonium nitrate (CAS # 6484-52-2), barium nitrate (CAS #: 10022-31-8), potassium nitrate (CAS #: 7757-79-1), copper nitrate (CAS #: 3251-23-8); Sodium nitrate (CAS #: 7361-99-4), strontium nitrate (CAS #: 10042-76-9), iron oxide (CAS #: 1309-37-1 and 1317-61-9, respectively). In principle, any substance with a positive oxygen balance can supply the necessary oxygen for a balanced balance in the propellant. In general, the oxidizing agents are solid; However, a processing of liquid oxidants is also possible.

Particularly suitable are those oxidants which burn completely residue-free and have good compatibility with the binder material. Particularly suitable are ammonium perchlorate and / or ammonium nitrate. For the phase stabilization of ammonium nitrate, it may be necessary to add further oxidizing agents. Particularly suitable are mixtures of the ammonium nitrate with potassium nitrate, which demonstrably suppresses the critical phase transformation of the ammonium nitrate by the processing method used.

The average particle diameter of the oxidizing agent is preferably less than 100 .mu.m, particularly preferred mean particle sizes below 50 .mu.m. This facilitates the incorporation into the binder material and the subsequent extrusion, in addition it increases the burning rate of the blowing agent.

The proportion of the oxidizing agent is preferably between 70 and 95 wt.%. Particular preference is given to using fractions of between 75 and 85%. This high proportion of oxidizer makes it possible to compensate for the negative oxygen balance of the remaining blowing agent components.

The propellant may additionally contain nitrogen-rich compounds to increase the gas yield. Suitable compounds are guanidine, tetrazole, bitetrazole, tritetrazole, hydrazine, triazine, azodicarbonamide, hydrazodicarbonamides, dicyanamides or nitramine compounds and combinations thereof. Examples include guanidine nitrate (CAS #: 506-93-4), nitroguanidine (CAS #: 556-88-7), 1,1-diamino-2,2-dinitroethylene (FOX-7), N-guanyl urea dinitramide ( FOX-12), 5-aminotetrazole (CAS #: 5378-49-4), hexogen (RDX, CAS # 121-82-4 :), octogen (HMX, CAS # 2691-41-0) and ethylenedinitramine (EDNA, CAS #: 505-71-5). On account of the availability and the price, in particular the nitramine compounds which are produced in large quantities for explosives are suitable. Hexogen proves to be particularly suitable. In addition to a high gas yield, the burning rate can be significantly increased by the incorporation. By limiting the oxygen balance, the suitable range of use is between 1 and 30% by weight; Preferably, the range is from 5 to 20 wt.%.

Furthermore, the propellant may contain chlorine-neutralizing additives. Chlorine-neutralizing additives are added, in particular, to chlorate- and perchlorate-containing formulations for neutralizing the hydrochloric acid in the combustion clouds. Suitable chlorine-neutralizing additives are found among the alkali and alkaline earth salts. These can be used individually or in combination. Examples include sodium carbonate (CAS #: 5968-11-6), sodium nitrate (CAS #: 7631-99-4), sodium oxide (CAS #: 1313-59-3), sodium oxalate (CAS #: 62- 76-0), strontium carbonate (CAS #: 1633-05-2), strontium silicate (CAS #: 13451-00-8), strontium oxide (CAS #: 1314-11-0), strontium oxalate (CAS #: 814-95-9), stontrium peroxide (CAS #: 1314-18-7), calcium silicate (CAS #: 1344-95-2), calcium nitrate (CAS #: 10124-37-5), calcium oxalate (CAS). #: 563-72-4), calcium peroxide (CAS #: 1305-79-9), magnesium oxide (CAS #: 1309-48-4), magnesium peroxide (CAS #: 1335-26-8). Oxalate compounds in particular are suitable as chlorine-neutralizing additives because of their complete combustibility and low flame temperature. Particularly suitable is sodium oxalate due to the low molecular weight of the cation. The range of use depends on the percentage of chlorate and / or perchlorate salts. A proportion of between 5 and 50% by weight is suitable. Shares of between 5 and 20% by weight are particularly suitable.

Further, a propellant may contain additives for reducing the combustion flame. Such additives preferably originate from the group of sulfates, nitrates and / or cryolites. Examples are sodium sulfate (CAS #: 7757-82-6), potassium sulfate (CAS #: 7778-80-5), barium nitrate (CAS #: 10022-31-8), and sodium aluminum fluoride (CAS #: 15096-52 -3). The proportion is preferably in the range of 0.1-5 wt.%, Particularly preferably in the range of 1 to 2 wt.%.

Further, the blowing agent can be polished to improve the flowability graphite (CAS #: 7782-42-5). This method is common for nitrocellulose-based blowing agents; As a result, the bulk material is electrically conductive and minimizes the risk of electrostatic ignition. Typically, a graphite content of between 0.01 to 1 wt.% Is polished; optimally, the proportion is between 0.02 to 0.5 wt.%. In addition to graphite, the blowing agent can be further polished with additives such as primers.

The blowing agents of the present invention can be prepared without limitation by conventional methods. For example, all components binder, stabilizers, plasticizers, oxidizers and other additives can be mixed with suitable solvents to form a homogeneous dough. When using water-sensitive oxidants such as ammonium nitrate and / or perchlorate, it is recommended to use a non-aqueous solvent. After sufficient gelation, the dough may preferably be extruded through a given die and cut to length. The final shape is obtained after removal of the solvents and any postpolymerization. On the one hand, extruded forms can be grains or perforated grains. For perforated grains, either 1, 7 or 19 holes are common. The decisive factor for the burnup is the wall thickness, defined as the shortest burning distance (eg between hole and outer wall, etc.). Another type of processing by means of melting of the binder, incorporation of the solids and subsequent continuous extrusion is explicitly not excluded.

The size of the grains depends on the application. For propellants for fast applications such as in the belt tensioner range, the wall thickness is usually between 0.2 to 3 mm, preferably wall thicknesses in the range 0.5 to 2 mm. For slower applications such as airbags, the wall thickness is usually between 0.5 and 5 mm, preferably wall thicknesses in the range 1 to 3 mm. The outer diameter of the perforated grains is in a preferred variant of the order of the length of the grains. More preferably, the length is about 1.1 times the outer diameter of the grain.

The manufactured propellant can now be encapsulated in a gas generator and provides at initiation the necessary amount of gas to inflate, for example, the airbag or trigger the mechanics of the belt tensioner.

From the following detailed description and the totality of the claims, further advantageous embodiments and feature combinations of the invention result.

Brief description of the drawings

Fig. 1

Tabelle beinhaltend die Sauerstoffbilanz, die Flammtemperatur und die Gasausbeute ausgewählter Weichmacher.

Fig. 2

Zeitlicher Verlauf der Gewichtsverluste herkömmlicher (Beispiel C) und erfindungsgemässer (Beispiel D) Treibmittel bei offener Lagerung und einer Temperatur von 107°C.

The drawings used to explain the embodiment show:

Fig. 1

Table contains the oxygen balance, the flame temperature and the gas yield of selected plasticizers.

Fig. 2

Time course of the weight losses of conventional (Example C) and inventive (Example D) propellant in open storage and a temperature of 107 ° C.

Ways to carry out the invention

In Fig. 1 For illustration, the oxygen balance, the flame temperature and the gas yield of each of six inert and energetic plasticizers are listed in tabular form. The flame temperature and gas yield were determined by thermodynamic calculations. The inert plasticizers with oxygen balances of -300 to -150% have gas yields of not more than 750 ml / g. In the case of energetic plasticizers with oxygen balances greater than -100%, the gas yields are in the range 800-1000 ml / g. Butyl-NENA shows the highest gas yield with an acceptable oxygen balance and low temperatures for energetic softeners.

In the following, several embodiments are given.

Production Example A: (Single-base belt tensioner powder without plasticizer and without oxidizer)

A conventional monobasic propellant for belt tensioner applications is prepared as follows: 97% by weight of nitrocellulose, 2% by weight of acardite II and 1% by weight of sodium oxalate are placed in a kneader in a solvent-wet state. The mass is kneaded in about 2 hours until a consistent dough is formed. Subsequently, the dough is extruded through dies and cut to length. After complete removal of the solvent, the bulk material is graphitized and sieved. The finished 1-hole powder grains have an outer diameter of 1.4 mm, a hole diameter of 0.2 mm, a length of 2.2 mm, a gravimeter of 981 g / l and an explosion heat of 3911 J / g. The average vivacity of the propellant between 30-80% of the maximum pressure is 31 × 10 ^-2 / bar × s.

Production Example B: (Plastic-bonded belt tensioner powder with plasticizer and oxidizer)

A plastic-bound propellant for belt tensioner applications is manufactured as follows: 14% by weight of cellulose acetate butyrate, 4% by weight of alcohol-wet nitrocellulose, 5% by weight of sodium oxalate, 3% by weight of butyl NENA and 1% by weight of acardite II are charged in a kneader and mixed for 5 minutes. Subsequently, 56% by weight of ammonium perchlorate and 6% by weight of hexogen are added in a solvent-moist state. The mass is kneaded in about 2 hours until a consistent dough is formed. The dough is then extruded and cut to length. After complete removal of the solvent, the bulk material is graphitized and sieved. The finished powder grains have an outer diameter of 1.1 mm, a length of 1.3 mm, a gravimeter of 946 g / l and an explosion heat of 5177 J / g. The average vivacity of the propellant between 30-80% of the maximum pressure is 40.10 ^-2 / bar · s.

Gas Generation / Ignitability: Each 1000 mg of the propellants of Examples A and B were placed in a microgas generator with Squib ignition and inflamed in a 10 ml bomb. For both propellants, the maximum pressure occurs after 8 ms. With the same amount of charge is the monobasic propellant (Example A), a maximum pressure of 800 bar, the plastic-bonded propellant (Example B) reaches a maximum pressure of 725 bar. Compared with monobasic propellants, the propellants according to the invention thus have only a 10% low pressure level. Measurements at -40, +21 and +85 ° C show for both propellants comparably small variations in the maximum pressure; these are between 1.8 and 1.9%.

CO measurement: In each case 1000 mg of the blowing agents from Examples A and B were ignited in a micro gas generator with Squib ignition and in a 10 ml pressure bomb. The resulting noxious gases were collected within a 60 l jug and quantified by means of infrared and / or Dräger tubes. The monobasic propellant (Example A) has a carbon monoxide content of 7362 ppm; the plastic-bound propellant (Example B) is 1628 ppm.

Aging: In each case 1000 mg of the blowing agents from Examples A and B were used in a microgas generator with Squib ignition. After thermal aging, the weight of the monobasic propellant (Example A) is reduced by 17% after 408 h at 107 ° C due to the autocatalytic decomposition; in the case of the plastic-bonded propellant (Example B) by 2% after 408 h at 107 ° C. As a result of aging, the maximum pressure is reduced by 30% (propellant from Example A) and 7% (propellant from Example B).

Production Example C: (Airbag pattern with inert plasticizer and oxidizer)

A plastic-bound propellant for airbag applications is manufactured as follows: 13% by weight of cellulose acetate butyrate, 2% by weight of tributyl citrate and 0.3% by weight of acardite II are charged in a kneader and mixed for 5 minutes. Subsequently, 76% by weight of ammonium nitrate and 9% by weight of potassium nitrate are added in a solvent-moist manner. The mass is kneaded for about 2 hours until a consistent dough is formed. The dough is then extruded and cut to length. After complete removal of the solvent, the bulk material is graphitized and sieved. The finished 1-hole powder grains have an outer diameter of 2.2 mm, a hole diameter of 0.7 mm, a length of 3.0 mm, a gravimeter of 777 g / l and an explosive heat of 3982 J / g. The average vivacity of the propellant between 30-80% of the maximum pressure is 9.1 × 10 ^-2 / bar · s.

Production Example D: (Airbag pattern with energetic nitratoethylnitramine plasticizer and oxidizer)

Analogously to Example C, a plastic-bonded blowing agent for airbag applications was manufactured. Butyl NENA was used instead of the inert plasticizer tributyl citrate. The finished 1-hole powder grains have an outer diameter of 2.1 mm, a hole diameter of 0.8 mm, a length of 3.0 mm, a gravimeter of 749 g / l and an explosion heat of 4054 J / g. The average vivacity of the propellant between 30-80% of the maximum pressure is 9.6 × 10 ^-2 / bar · s.

Gas Generation / Ignition: Each 1000 mg of the propellants of Examples C and D were placed in a microgas generator with Squib ignition and inflamed in a 10 ml bomb. The blowing agent with the inert plasticizer (Example C) reaches a maximum pressure of 440 bar after 59 ms. By using Butyl-NENA (example D), a 7% higher pressure maximum of 472 bar is achieved already after 35 ms.

CO measurement: In each case 1000 mg of the blowing agents from Examples C and D were put into a microgas generator and ignited in a 10 ml pressure bomb. The resulting noxious gases were collected within a 60 l jug and quantified by means of infrared and / or Dräger tubes. The inert plasticizer propellant (Example C) has a carbon monoxide content of 872 ppm; the propellant with butyl-NENA (Example D) is 566 ppm.

Aging: Each 1000 mg of the blowing agent from Example C and D were stored in a gas ampule at 107 ° C. The measured weight loss as a function of storage time is in Fig. 2 for the blowing agents of Examples C and D shown. By using the energetic plasticizer Butyl-NENA a significant improvement in stability is achieved.

In summary, it has been found that a new propellant for automotive safety systems has been found, which is especially characterized by a minimized environmental toxic load during burning and improved long-term stability. The blowing agent is based on the novel combination of a plasticizer from the family of nitratoethylnitroamine and a heavy metal-free oxidizer. Due to the given during production extrudability can be formed with the blowing agent grains with and without perforation with any desired dimension. This allows use in applications with a wide variety of burn behavior.

Claims (17)

Propellants for use as gas generators in safety systems in motor vehicles, comprising a binder, a plasticizer of the chemical group of nitratoethylnitroamines and an oxidizer, characterized in that the oxidizer is free of heavy metals. Propellant according to claim 1, characterized in that the plasticizer is butyl-nitratoethylnitroamine. Propellant according to one of claims 1 - 2, characterized in that are contained as binder cellulose derivatives. Propellant according to claim 3, characterized in that the binder is a mixture of inert and energetic cellulose derivatives. Propellant according to claim 4, characterized in that the intact cellulose derivative is cellulose acetate butyrate and the energetic cellulose derivative nitrocellulose. Propellant according to one of Claims 3 to 5, characterized in that the binder is present in an amount of 5 to 30% by weight, in particular 10 to 25% by weight. Propellant according to one of claims 4-6, characterized in that the proportion of energetic cellulose derivative 1-15 wt.%, In particular 2-10 wt.% Is. Propellant according to one of Claims 1 to 7, characterized in that the proportion of plasticizer is 1 to 10% by weight, in particular 2 to 5% by weight. Propellant according to one of claims 1-8, characterized in that the oxidizer is potassium perchlorate, ammonium perchlorate, ammonium nitrate, phase-stabilized ammonium nitrate, sodium nitrate, potassium nitrate or a mixture thereof. Propellant according to one of claims 1 - 9, characterized in that the oxidizer has an average particle size of not more than 100 microns, in particular of not more than 50 microns. Propellant according to one of claims 1 to 10, characterized in that the oxidizer is present in an amount of 70-95% by weight, in particular 75-85% by weight. Propellant according to one of Claims 1 to 11, characterized in that nitramine compounds are present in an amount of 1 to 30% by weight, in particular 5 to 20% by weight. Propellant according to one of Claims 1 to 12, characterized in that chlorine-neutralizing compounds are present in an amount of 5 to 50% by weight, in particular 5 to 20% by weight. Propellant according to one of Claims 1 to 13, characterized in that compounds for reducing the combustion flame are present in an amount of 0.1 to 5% by weight, in particular 1 to 2% by weight. Propellant according to one of Claims 1 to 14, characterized in that graphite is present in an amount of between 0.01 and 1% by weight, in particular 0.02-0.5% by weight. Propellant according to one of claims 1-15, characterized in that it is in the form of perforated grains having a wall thickness between 0.2 - 3 mm, in particular 0.5 - 2 mm, and in particular that the perforated grains have an outer Have diameter that is of the order of a length of the perforated grains. Propellant according to one of claims 1-15, characterized in that it is in the form of perforated grains having a wall thickness between 0.5 - 5 mm, in particular 1 - 3 mm and that the perforated grains in particular have an outer diameter, of the order of magnitude the perforated grains lie.

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