Process for coating and impregnating hmx with additional materials

SUBSTANCE PULVERULENT AND MANUFACTORING PROCESS Of SUCH a SUBSTANCE.

PROCESS FOR COATING AND IMPREGNATING HMX WITH ADDITIONAL MATERIALS

A composition comprising alpha-HMX particles has at least one second material coated on the particles. A variety of second materials can be used, including mixtures of two, three, or more different such materials. One suitable example of a second material is an energetic material, such as beta-HMX, RDX, TNT, ammonium nitrate, or a mixture thereof. Another suitable example of a second material is a fuel, such as aluminum, lithium hydride, lithium aluminum hydride, or a mixture thereof. Yet another suitable example of a second material is one or more polymerizable monomers. Durable alpha-HMX containing articles can be formed from a plurality of particles, the particles comprising alpha-HMX coated and/or impregnated with a second material.

Способ получения нанокапсул тринитротолуола

FIELD: nanotechnologies. SUBSTANCE: invention relates to nanotechnology, specifically to a method of producing nanocapsules of trinitrotoluene. Method is characterized by that nanocapsules are represented by kappa-carrageenan and trinitrotoluene as a nucleus, wherein trinitrotoluene is slowly added to a suspension of kappa-carrageenan in hexane in presence of 0.01 g of preparation E472c as a surfactant while stirring at 650 rpm. Weight ratio of core: shell in terms of dry substance is 1:3, or 1:1, or 1:2, or 2:1. Then, coolant-113 is added, obtained suspension is filtered and dried at room temperature. EFFECT: disclosed method enables to obtain nanocapsules of trinitrotoluene in a kappa-carrageenan shell. 1 cl, 4 ex РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2 699 014 C1 (51) МПК B82B 1/00 (2006.01) B82B 3/00 (2006.01) C06B 45/20 (2006.01) C07C 205/06 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ На основании пункта 1 статьи 1366 части четвертой Гражданского кодекса Российской Федерации патентообладатель обязуется заключить договор об отчуждении патента на условиях, соответствующих установившейся практике, с любым гражданином Российской Федерации или российским юридическим лицом, кто первым изъявил такое желание и уведомил об этом патентообладателя и федеральный орган исполнительной власти по интеллектуальной собственности. (52) СПК (21)(22) Заявка: 2018137752, 25.10.2018 (24) Дата начала отсчета срока действия патента: (73) Патентообладатель(и): Кролевец Александр Александрович (RU) Дата регистрации: 03.09.2019 (56) Список документов, цитированных в отчете о поиске: B.V.N. NAGAVARMA ET AL. Different techniques for preparation of polymeric nanoparticles, ASIAN J. PHARM. CLIN. RES., 2012, Vol. 5, Suppl. 3, 16-23. RU 2646482 C2, 05.03.2018. Приоритет(ы): (22) Дата подачи заявки: 25.10.2018 (54) Способ получения нанокапсул тринитротолуола (57) Реферат: Изобретение относится к области нанотехнологии, конкретно к способу ...

Способ получения нанокапсул тринитротолуола

Изобретение относится к области нанотехнологии, конкретно к способу получения нанокапсул тринитротолуола. Способ характеризуется тем, что в качестве оболочки нанокапсул используют гуаровую камедь, а в качестве ядра - тринитротолуол, при этом тринитротолуол медленно добавляют в суспензию гуаровой камеди в петролейном эфире в присутствии 0,01 г препарата Е472с в качестве поверхностно-активного вещества при перемешивании 700 об/мин. Массовое соотношение ядро : оболочка при пересчете на сухое вещество составляет 1:3, или 1:1, или 1:2, или 2:1. Далее приливают хладон-112, полученную суспензию отфильтровывают и сушат при комнатной температуре. 4 пр. РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2 697 253 C1 (51) МПК B82B 1/00 (2006.01) B82B 3/00 (2006.01) C06B 45/20 (2006.01) C07C 205/06 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ На основании пункта 1 статьи 1366 части четвертой Гражданского кодекса Российской Федерации патентообладатель обязуется заключить договор об отчуждении патента на условиях, соответствующих установившейся практике, с любым гражданином Российской Федерации или российским юридическим лицом, кто первым изъявил такое желание и уведомил об этом патентообладателя и федеральный орган исполнительной власти по интеллектуальной собственности. (52) СПК (21)(22) Заявка: 2018132160, 07.09.2018 (24) Дата начала отсчета срока действия патента: (73) Патентообладатель(и): Кролевец Александр Александрович (RU) Дата регистрации: 13.08.2019 (56) Список документов, цитированных в отчете о поиске: B.V.N. NAGAVARMA ET AL., Different techniques for preparation of polymeric nanoparticles, ASIAN J. PHARM. CLIN. RES., 2012, Vol. 5, Suppl. 3, 16-23. RU 2646482 C2, 05.03.2018. Приоритет(ы): (22) Дата подачи заявки: 07.09.2018 (54) Способ получения нанокапсул тринитротолуола (57) Реферат: Изобретение относится к области нанотехнологии, конкретно к способу получения нанокапсул тринитротолуола. Способ характеризуется тем, что в ...

Verfahren zur Herstellung von Komposit-Partikeln aus kristallinen Explosivstoffen

Es wird ein Verfahren zur Herstellung von Komposit-Partikeln aus wenigstens einer ersten und wenigstens einer zweiten Komponente jeweils eines kristallinen Explosiv-, Treibstoffes und/oder Oxidators mittels Kühlungs- oder Verdampfungskristallisation vorgeschlagen. Dabei wird die erste Komponente in wenigstens einem Lösungsmittel gelöst, in welchem die zweite Komponente nicht oder nur gering löslich ist. Ferner wird dem Lösungsmittel und/oder der Lösung die zweite Komponente unter Bildung einer Fest-/Flüssigdispersion in partikulärer Form zugesetzt. Anschließend wird die Dispersion bis unterhalb der Sättigungstemperatur der ersten Komponente in dem Lösungsmittel abgekühlt oder wird das Lösungsmittel bis oberhalb der Sättigungskonzentration der ersten Komponente in dem Lösungsmittel verdampft und wird dabei die erste Komponente unter Bildung der Komposit-Partikel an der Oberfläche der partikulären zweiten Komponente abgeschieden.

Improvements in or relating to blasting agents

... 827,448. Ammonium nitrate blasting composition. DU PONT DE NEMOURS & CO., E. I. May 16, 1958 [June 11, 1957], No. 15841/58. Class 9(2) A blasting agent comprises a plurality of geodes of a blend comprising ammonium nitrate. and sodium nitrate having a melting point below 128‹C., the interiors and surfaces of the geodes containing a carbonaceous fuel liquid at a temperature below the melting point of said blend Specified fuels include motor oils, kerosene and dinitrotoluene. The blend may include melting point depressants such as urea, and also potassium nitrate. As shown, the blend A is melted and maintained molten in a melt tank 1 by means of heating coils 2. The molten blend flows through the dropping tip 3, leaving the tip in the form of separate drops. The fuel C surrounding the tip is heated by coils 5 to a temperature above the melting point of the blend. As the drop falls down column 4 it solidifies to form a geode B which is carried by the flow of fuel through tube 7 into receiver ...

CARRIER PROJECTILE WITH UEBUNGSSUBMUNITIONSGESCHOSSEN.

Improvements brought to the explosive mixtures containing of aluminium and their manufactoring processes

DESENSITIZING BY CRYSTAL COATING OF EXPLOSIVE ENERGY SUBSTANCES; CRYSTALS OF SUCH SUBSTANCES COAT, ENERGY MATERIALS.

La présente invention a pour objet :- un procédé de désensibilisation par enrobage de cristaux d'une substance énergétique explosive : ledit procédé comprend le dépôt, mis en oeuvre au sein d'un fluide, en dehors des conditions normales de température et de pression, de préférence en conditions supercritiques, d'un film métallique et/ou polymère, avantageusement d'un film métallique ou d'un film polymère, à la surface desdits cristaux;- les cristaux d'une substance énergétique explosive enrobés, susceptibles d'être obtenus par ledit procédé ; ainsi que- les matériaux énergétiques renfermant lesdits cristaux enrobés et/ou les cristaux désensibilisés par ledit procédé. The subject of the present invention is: a process for desensitising by coating crystals with an explosive energy substance: said process comprises the deposition, carried out in a fluid, outside the normal conditions of temperature and pressure, preferably under supercritical conditions, a metallic and / or polymeric film, advantageously a metal film or a polymer film, on the surface of said crystals - the crystals of a coated explosive energy substance, which may be obtained by said method; and energetic materials containing said coated crystals and / or crystals desensitized by said method.

СПОСОБ НАПЫЛЕНИЯ МЕТАЛЛИЧЕСКОГО ПОКРЫТИЯ НА ЧАСТИЦЫ ИЗ ОРГАНИЧЕСКИХ МАТЕРИАЛОВ

Изобретение относится к области модифицирования органических материалов, в частности, к способу напыления металлического покрытия на частицы из органического материала - окислителя или энергоемкого соединения, и может быть использовано для изготовления компонентов функциональных и высококалорийных компонентов энергетических конденсированных систем (ЭКС), например порохов, твердых ракетных топлив и взрывчатых составов. Перед напылением металлического покрытия на частицы из органических материалов производят сушку частиц, их предварительную очистку выдержкой в течение 10 мин. Осуществляют напыление металлического покрытия на частицы ионно-плазменным вакуумным магнетронным методом, предварительно разместив частицы на предметном столике с одновременным перемешиванием частиц. Напыление осуществляют на частицы из органических материалов размерами от 10 до 2000 мкм, изготовленные в виде порошкообразного материала, предварительно обработанные в термошкафу при температуре не более 60°С, вакуумированные ...

Способ получения нанокапсул циклотриметилентринитроамина (гексогена)

FIELD: chemistry. SUBSTANCE: invention relates to a method for producing nanocapsules of hexogen, in which the nucleus used is hexogen and as a shell of nanocapsules – kappa-carrageenan. Process is carried out by slow addition of hexogen to a suspension of kappa-carrageenan in petroleum ether in presence of 0.01 g of preparation E472c as a surfactant while stirring at 600 rpm, wherein mass ratio of core : shell in terms of dry substance is 1:3, or 1:1, or 1:2, or 2:1, then adding butyl chloride, obtained suspension is filtered and dried at room temperature. EFFECT: simplification and acceleration of the process of nanocapsules production and increase of mass output. 1 cl, 4 ex РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2 698 192 C1 (51) МПК B82B 3/00 (2006.01) B82B 1/00 (2006.01) C06B 25/34 (2006.01) C06B 45/20 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ На основании пункта 1 статьи 1366 части четвертой Гражданского кодекса Российской Федерации патентообладатель обязуется заключить договор об отчуждении патента на условиях, соответствующих установившейся практике, с любым гражданином Российской Федерации или российским юридическим лицом, кто первым изъявил такое желание и уведомил об этом патентообладателя и федеральный орган исполнительной власти по интеллектуальной собственности. (52) СПК (21)(22) Заявка: 2019106177, 04.03.2019 (24) Дата начала отсчета срока действия патента: (73) Патентообладатель(и): Кролевец Александр Александрович (RU) Дата регистрации: 23.08.2019 Приоритет(ы): (22) Дата подачи заявки: 04.03.2019 (54) Способ получения нанокапсул циклотриметилентринитроамина (гексогена) (57) Реферат: Изобретение относится к способу получения мин, при этом массовое соотношение ядро : нанокапсул гексогена, в котором в качестве ядра oболочка при пересчете на сухое вещество используют гексоген и в качестве оболочки составляет 1:3, или 1:1, или 1:2, или 2:1, далее нанокапсул - каппа-каррагинан. Процесс приливают ...

SUBSTANCE PULVERULENT AND MANUFACTORING PROCESS Of SUCH a SUBSTANCE.

L'invention a pour objet une substance pulvérulente, notamment une substance pyrotechnique, caractérisée en ce qu'elle comporte au moins un premier matériau formé de grains (2) enrobés par une couche de liant (3) incorporant des granules (4) d'un second matériau de granulométrie nanométrique.L'invention a également pour objet un procédé permettant de fabriquer une telle substance.

NITROCELLULOSE BASE PROPELLANT COATED WITH GRAPHITE, PLASTICIZER, AND INORGANIC PIGMENT

СНИЖЕНИЕ ЧУВСТВИТЕЛЬНОСТИ КРИСТАЛЛОВ ВЗРЫВЧАТЫХ ЭНЕРГЕТИЧЕСКИХ ВЕЩЕСТВ ПУТЕМ НАНЕСЕНИЯ НА НИХ ПОКРЫТИЯ, КРИСТАЛЛЫ ТАКИХ ВЕЩЕСТВ С ПОКРЫТИЕМ И ЭНЕРГЕТИЧЕСКИЕ МАТЕРИАЛЫ

FIELD: process engineering. SUBSTANCE: invention relates to method of reducing sensitivity of energy explosive crystals by applying coating thereon. Proposed method comprises deposition of metal and/or polymer film on the surface of crystals conducted in fluid, preferably, in supercritical conditions. Note here that metal (metals) and/or polymer (polymers, were pre-dissolved in solvent. EFFECT: reduced sensitivity. 22 cl, 11 dwg, 6 tbl РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) 2 484 887 (13) C2 (51) МПК B01J 2/00 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ (72) Автор(ы): МАРРО Кристин (FR), МАРР Самюэль (FR), КАНСЕЛЛЬ Франсуа (FR), ЭМОНЬЕ Сирил (FR) (21)(22) Заявка: 2010128085/05, 18.12.2008 (24) Дата начала отсчета срока действия патента: 18.12.2008 (43) Дата публикации заявки: 27.01.2012 Бюл. № 3 (73) Патентообладатель(и): СНПЕ МАТЕРИО ЭНЕРГЕТИК (FR), ЭРАНКО (FR) 2 4 8 4 8 8 7 (45) Опубликовано: 20.06.2013 Бюл. № 17 (56) Список документов, цитированных в отчете о поиске: WO 9919085 A1, 22.04.1999. WO 2004091571 A2, 28.10.2004. DE 19742034 A1, 25.03.1999. SU 220955 A1, 01.01.1968. RU 2267010 C1, 27.12.2005. (86) Заявка PCT: FR 2008/052353 (18.12.2008) C 2 C 2 (85) Дата начала рассмотрения заявки PCT на национальной фазе: 19.07.2010 R U 2 4 8 4 8 8 7 (87) Публикация заявки РСТ: WO 2009/081048 (02.07.2009) Адрес для переписки: 191186, Санкт-Петербург, а/я 230, "АРСПАТЕНТ", пат.пов. С.В.Новоселовой (54) СНИЖЕНИЕ ЧУВСТВИТЕЛЬНОСТИ КРИСТАЛЛОВ ВЗРЫВЧАТЫХ ЭНЕРГЕТИЧЕСКИХ ВЕЩЕСТВ ПУТЕМ НАНЕСЕНИЯ НА НИХ ПОКРЫТИЯ, КРИСТАЛЛЫ ТАКИХ ВЕЩЕСТВ С ПОКРЫТИЕМ И ЭНЕРГЕТИЧЕСКИЕ МАТЕРИАЛЫ (57) Реферат: Настоящее изобретение относится к способу снижения чувствительности кристаллов взрывчатого энергетического вещества путем нанесения на них покрытия. Способ включает осаждение, проводимое в жидкости за пределами нормальных значений температуры и давления, предпочтительно в сверхкритических условия. Пленки металла и/или полимерной пленки, на ...

Способ получения нанокапсул циклотриметилентринитроамина (гексогена)

FIELD: technological processes. SUBSTANCE: invention relates to a method of producing nanocapsules of hexogen, in which the nucleus used is hexogen and as a nanocapsule shell – sodium carboxymethyl cellulose. Process is carried out by slow addition of hexogen to a suspension of sodium carboxymethyl cellulose in hexane in presence of 0.01 g of preparation E472c as a surfactant while stirring at 600 rpm, wherein mass ratio of core : shell in terms of dry substance is 1:3, or 1:1, or 1:2, or 2:1, then adding chladone-113, obtained suspension is filtered and dried at room temperature. EFFECT: simplification and acceleration of the process of nanocapsules production and increase of mass output. 1 cl, 4 ex РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2 717 075 C1 (51) МПК B82B 3/00 (2006.01) B82B 1/00 (2006.01) C06B 25/34 (2006.01) C06B 45/20 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ На основании пункта 1 статьи 1366 части четвертой Гражданского кодекса Российской Федерации патентообладатель обязуется заключить договор об отчуждении патента на условиях, соответствующих установившейся практике, с любым гражданином Российской Федерации или российским юридическим лицом, кто первым изъявил такое желание и уведомил об этом патентообладателя и федеральный орган исполнительной власти по интеллектуальной собственности. (52) СПК (21)(22) Заявка: 2019127144, 27.08.2019 (24) Дата начала отсчета срока действия патента: (73) Патентообладатель(и): Кролевец Александр Александрович (RU) Дата регистрации: 18.03.2020 (56) Список документов, цитированных в отчете о поиске: RU 2698192 C1, 23.08.2019. RU 2697842 C1, 21.08.2019. Приоритет(ы): (22) Дата подачи заявки: 27.08.2019 (54) Способ получения нанокапсул циклотриметилентринитроамина (гексогена) (57) Реферат: Изобретение относится к способу получения мин, при этом массовое соотношение ядро : нанокапсул гексогена, в котором в качестве ядра оболочка при пересчете на сухое вещество ...

EXERCISE FIRING PROJECTILE

ABSTRACT OF THE DISCLOSURE An exercise firing projectile containing a plurality of pyrotechnic fragmentation devices are expelled from the projectile casing above the target area by an ejection charge, and delay tubes of the fragmentation devices are ignited at the same time by this charge through a central igniter tube contained within the projectile. The active charge of the devices consist of a grainy composite with quick reaction time.

Granulation process

A process for forming granules (e.g., alpha-HMX containing granules) from at least one particulate material comprises the steps of:(a) selecting particulates (e.g., alpha-HMX particulates) having a particle size distribution; and(b) fluidizing the particulates, whereby particulates agglomerate to form granules.Optionally, the particulates can be coated with one or more second materials, such as energetic materials or fuels. If one or more of the second materials comprise polymerizable monomers, the process can optionally further comprise the step of polymerizing those monomers in situ, either before or after the granule is formed.

Pyrotechnic material and method for manufacturing

Powder useful as pyrotechnic material comprises cores of first material coated with binder layer containing nanoparticles of second material Powder comprising cores of a first material coated with a binder layer containing nanoparticles of a second material is new. - An INDEPENDENT CLAIM is also included for producing a powder as above by preparing a solution of the binder in a first solvent (S1), preparing a bath of carrier liquid immiscible with S1, dispersing particles of the first material in the bath, adding nanoparticles of the second material while stirring the bath, adding the binder solution, adding a surfactant, stirring, removing S1 by washing with a second solvent, and filtering and/or drying the resulting powder.

Способ получения нанокапсул 2,4-динитроанизола

FIELD: nanotechnologies. SUBSTANCE: invention relates to nanotechnology, specifically to a method of producing 2,4-dinitroanisole nanocapsules. Method is characterized by that nanocapsule shells are represented by kappa-carrageenan and 2,4-dinitroanisole as nucleus, wherein 2,4-dinitroanisole is slowly added to a suspension of kappa-carrageenan in hexane in presence of 0.01 g of preparation E472c as a surfactant while stirring at 600 rpm. Weight ratio of core:shell in terms of dry substance is 1:3, or 1:1, or 1:2, or 2:1. Then, coolant-113 is added, obtained suspension is filtered and dried at room temperature. EFFECT: disclosed method enables efficient production of 2,4-dinitroanisole nanocapsules. 1 cl, 4 ex РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2 697 842 C1 (51) МПК B82B 1/00 (2006.01) B82B 3/00 (2006.01) B82Y 99/00 (2011.01) C06B 45/20 (2006.01) C07C 205/37 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ На основании пункта 1 статьи 1366 части четвертой Гражданского кодекса Российской Федерации патентообладатель обязуется заключить договор об отчуждении патента на условиях, соответствующих установившейся практике, с любым гражданином Российской Федерации или российским юридическим лицом, кто первым изъявил такое желание и уведомил об этом патентообладателя и федеральный орган исполнительной власти по интеллектуальной собственности. (52) СПК (21)(22) Заявка: 2018133735, 24.09.2018 24.09.2018 (73) Патентообладатель(и): Кролевец Александр Александрович (RU) Дата регистрации: 21.08.2019 (56) Список документов, цитированных в отчете о поиске: B.V.N. NAGAVARMA ET AL., Different techniques for preparation of polymeric nanoparticles, ASIAN J. PHARM. CLIN. RES., 2012, Vol. 5, Suppl. 3, 16-23. RU 2646482 C2, 05.03.2018. Приоритет(ы): (22) Дата подачи заявки: 24.09.2018 Адрес для переписки: 305018, г. Курск, а/я 1011, Кролевцу Александру Александровичу R U (54) Способ получения нанокапсул 2,4-динитроанизола (57) Реферат: ...

Способ получения нанокапсул 2,4-динитроанизола

FIELD: nanotechnologies.SUBSTANCE: invention relates to nanotechnology, specifically to a method of producing 2,4-dinitroanisole nanocapsules. Method is characterized by that guar gum is used as a shell of nanocapsules, and 2,4-dinitroanisole as a nucleus. 2,4-dinitroanisole is slowly added to a suspension of guar gum in sulfuric ether in presence of 0.01 g of preparation E472c as a surfactant while stirring at 600 rpm. Weight ratio of core:shell in terms of dry substance is 1:3, or 1:1, or 1:2, or 2:1. Then petroleum ether is poured, obtained suspension is filtered and dried at room temperature.EFFECT: disclosed method enables to obtain 2,4-dinitroanisole nanocapsules in a guar gum shell.1 cl, 4 ex РОССИЙСКАЯ ФЕДЕРАЦИЯ (19) RU (11) (13) 2 708 618 C1 (51) МПК B82B 1/00 (2006.01) B82B 3/00 (2006.01) B82Y 99/00 (2011.01) C06B 45/20 (2006.01) C07C 205/37 (2006.01) ФЕДЕРАЛЬНАЯ СЛУЖБА ПО ИНТЕЛЛЕКТУАЛЬНОЙ СОБСТВЕННОСТИ (12) ОПИСАНИЕ ИЗОБРЕТЕНИЯ К ПАТЕНТУ На основании пункта 1 статьи 1366 части четвертой Гражданского кодекса Российской Федерации патентообладатель обязуется заключить договор об отчуждении патента на условиях, соответствующих установившейся практике, с любым гражданином Российской Федерации или российским юридическим лицом, кто первым изъявил такое желание и уведомил об этом патентообладателя и федеральный орган исполнительной власти по интеллектуальной собственности. (52) СПК (21)(22) Заявка: 2019101287, 15.01.2019 15.01.2019 (73) Патентообладатель(и): Кролевец Александр Александрович (RU) Дата регистрации: 10.12.2019 (56) Список документов, цитированных в отчете о поиске: B.V.N. NAGAVARMA ET AL., Different techniques for preparation of polymeric nanoparticles, ASIAN J. PHARM. CLIN. RES., 2012, Vol. 5, Suppl. 3, 16-23. RU 2676677 C1, 10.01.2019. Приоритет(ы): (22) Дата подачи заявки: 15.01.2019 Адрес для переписки: 305018, г. Курск, а/я 1011, Кролевцу Александру Александровичу R U (54) Способ получения нанокапсул 2,4-динитроанизола (57) Реферат: Изобретение ...

Graphene/metal or metalloid core-shell composite and manufacturing method thereof

The present invention relates to a manufactured graphene/metal or metalloid core-shell composite and manufacturing method thereof. The method comprising: using a modified graphene oxide as a base, then performing concentration and steam drying followed by organic solvent replacement to obtain a modified graphene oxide organic solvent; using a liquid-phase self-assembly method to coat the modified graphene oxide onto a surface of the metal or metalloid to form a graphene/metal or metalloid coated particle solution, then filtering and drying to obtain the graphene metal/metalloid core-shell composite. The method improves upon a conventional organic and inorganic material coating technique, and reduces an impact of a water-based solvent and high temperature on a highly reactive metal and metalloid, thereby expanding the feasibility of the coating technique and addressing a barrier of applicability of graphene and reactive metal or metalloid in the field of energetic materials.

СНИЖЕНИЕ ЧУВСТВИТЕЛЬНОСТИ КРИСТАЛЛОВ ВЗРЫВЧАТЫХ ЭНЕРГЕТИЧЕСКИХ ВЕЩЕСТВ ПУТЕМ НАНЕСЕНИЯ НА НИХ ПОКРЫТИЯ, КРИСТАЛЛЫ ТАКИХ ВЕЩЕСТВ С ПОКРЫТИЕМ И ЭНЕРГЕТИЧЕСКИЕ МАТЕРИАЛЫ

1. Способ снижения чувствительности кристаллов взрывчатого энергетического вещества путем нанесения на них покрытия, отличающийся тем, что этот способ включает: ! - приготовление раствора, содержащего в растворенном состоянии: ! по меньшей мере один предшественник материала покрытия, причем материал покрытия выбран из металлов и смесей металлов, и/или ! материал покрытия, выбранный из полимеров и смесей полимеров; ! - суспендирование кристаллов в растворе; и ! - осаждение, проводимое в жидкости, за пределами нормальных значений температуры и давления, предпочтительно в сверхкритических условиях, пленки металла и/или полимерной пленки, предпочтительно пленки металла или полимерной пленки, на поверхность кристаллов. ! 2. Способ по п.1, отличающийся тем, что жидкость представляет собой СO2. ! 3. Способ по п.1 или 2, отличающийся тем, что: ! - масса осажденной металлической или полимерной пленки для каждого кристалла с нанесенным на него покрытием составляет от 0,3 до 6% от его общей массы, и тем, что ! - предпочтительно масса осажденной металлической или полимерной пленки для каждого кристалла с нанесенным на него покрытием составляет от 2 до 4% от его общей массы. ! 4. Способ по п.1 или 2, отличающийся тем, что способ включает осаждение металлической пленки, состоящей из по меньшей мере одного металла, выбранного из никеля, меди, алюминия, титана и циркония, и/или по меньшей мере одного оксида такого металла. ! 5. Способ по п.3, отличающийся тем, что способ включает осаждение металлической пленки, состоящей из по меньшей мере одного металла, выбранного из никеля, меди, алюминия, титана и циркония, и/или по меньшей мере одного оксида т�

Process for improving the pressure dependence of the combustion of solid-grains or firearms propellants, and their application as components of solid-grains or firearms propellants

Verfahren zur Herstellung von Komposit-Partikeln aus kristallinen Explosivstoffen und deren Verwendung

Verfahren zur Herstellung von Komposit-Partikeln aus wenigstens einer ersten und wenigstens einer zweiten Komponente jeweils eines kristallinen Explosiv-, Treibstoffes und/oder Oxidators mittels Kühlungskristallisation, dadurch gekennzeichnet, daß – die erste Komponente in wenigstens einem Lösungsmittel gelöst wird, in welchem die zweite Komponente nicht oder nur gering löslich ist; – daß die zweite Komponente aus der Gruppe der Nitramine gewählt wird, wobei dem Lösungsmittel vor dem Lösen der ersten Komponente oder der Lösung aus dem Lösungsmittel und der ersten Komponente die zweite Komponente aus der Gruppe der Nitramine unter Bildung einer Fest-/Flüssigdispersion in partikulärer Form zugesetzt wird; und – daß die Dispersion anschließend bis unterhalb der Sättigungstemperatur der ersten Komponenten in dem Lösungsmittel abgekühlt und die erste Komponente dabei unter Bildung der Komposit-Partikel an der Oberfläche der partikulären zweiten Komponente aus der Gruppe der Nitramine abgeschieden wird. Process for the production of composite particles from at least one first and at least one second component each of a crystalline explosive, fuel and / or oxidizer by means of cooling crystallization, characterized in that - the first component is dissolved in at least one solvent in which the second component is not or only slightly soluble; - That the second component is selected from the group of nitramines, the second component from the group of nitramines being added to the solvent prior to dissolving the first component or the solution from the solvent and the first component to form a solid / liquid dispersion in particulate form is added; and that the dispersion is then cooled to below the saturation temperature of the first components in the solvent and the first component is deposited on the surface of the particulate second component from the group of nitramines with the formation of composite particles.

Hmx compositions and processes for their preparation

Granulation process

NANOENERGETIC MATERIAL COMPOSITE AND GAS GENERATOR FOR THERMAL IGNITION THEREOF

The present invention relates to a nanoenergetic material composite which is used with azide-based sodium azide (NaN_3)/nanoenergetic material (nEMs) to reduce internal pressure when gas is generated and effectively control a gas generation time, a gas burning rate, and temperatures, and to a gas generator for thermal ignition thereof. An azide-based material used for a reaction material for generating gas and the nEMs used for a heat energy source for making the azide-based material thermally react are mixed and compose a composite powder, and the composite powder generates gas while decomposing microparticles of the azide-based material used for a reaction material by heat energy generated by ignition and explosion. COPYRIGHT KIPO 2016 ...

HMX COMPOSITIONS AND PROCESSES FOR THEIR PREPARATION

Ce procédé de préparation d'alpha-HMX (1,3,5,7-tétranitro-1,3,5,7-tétraazacyclooctane, de structure alpha) comprend les étapes suivantes consistant: (a) à combiner du pentoxyde de phosphore et de l'acide nitrique à une température comprise entre 0 et 25 °C, de façon à former un mélange de réaction, et (b) à ajouter à ce mélange de réaction un composé possédant la formule (VI) dans laquelle R représente un alkyle à chaîne droite ou ramifiée, possédant 1 à 5 atomes de carbone, de manière à former un produit comprenant alpha-HMX.

DESENSITIZING BY CRYSTAL COATING OF EXPLOSIVE ENERGY SUBSTANCES; CRYSTALS OF SUCH SUBSTANCES COAT, ENERGY MATERIALS.

PROCESS FOR COATING AND IMPREGNATING HMX WITH ADDITIONAL MATERIALS

A composition comprising alpha-HMX particles has at least one second material coated on the particles. A variety of second materials can be used, including mixtures of two, three, or more different such materials. One suitable example of a second material is an energetic material, such as beta-HMX, RDX, TNT, ammonium nitrate, or a mixture thereof. Another suitable example of a second material is a fuel, such as aluminum, lithium hydride, lithium aluminum hydride, or a mixture thereof. Yet another suitable example of a second material is one or more polymerizable monomers. Durable alpha-HMX containing articles can be formed from a plurality of particles, the particles comprising alpha-HMX coated and/or impregnated with a second material.

Process for making an hmx product

DESENSITISATION BY COATING CRYSTALS OF EXPLOSIVE ENERGY SUBSTANCES, COATED CRYSTALS OF SUCH SUBSTANCES, AND ENERGY MATERIALS

PROCESS FOR MAKING AN HMX PRODUCT

L'invention concerne un procédé de préparation d'un produit cyclotétraméthylène-tétranitramine (HMX), qui consiste: a) à fournir un granule comprenant plusieurs particules d'alpha-HMX et des vides internes, et b) à provoquer l'absorption d'au moins un second matériau dans les vides du granule. Le second matériau peut être absorbé dans les granules au moyen d'une dépression servant à aspirer une phase gazeuse, contenant ledit matériau, dans le granule. Le second matériau peut éventuellement être absorbé dans les granules par dissolution ou dispersion de ce matériau dans un solvant liquide, par mise en contact du solvant avec les granules, et par évaporation du solvant, le second matériau étant ainsi absorbé dans les granules. Divers matériaux peuvent être utilisés, telles que des matériaux énergétiques ou des combustibles.

GRANULATION PROCESS

Ce procédé de formation de granules (par exemple des granules contenant alpha-HMX (1,3;5;7-tétranitro-1,3,5,7-tétraazacyclooctane, de structure alpha) à partir d'au moins un matériau particulaire, comprend les étapes suivantes consistant: (a) à choisir des particules (par exemple des particules d'alpha-HMX) possédant une certaine distribution granulométrique, et (b) à fluidifier les particules, de manière que celles-ci s'agglomèrent afin de former des granulés. Eventuellement, on peut enrober les particules à l'aide d'un ou de plusieurs matériaux additionnels, tels que des matériaux énergétiques ou des carburants. Si l'un au moins des matériaux additionnels comprend des monomères polymérisables, le procédé peut comprendre, le cas échéant, l'étape de polymérisation in situ de ces monomères, soit avant, soit après la formation des granules.

Improvements in explosive mixtures containing aluminium and in the methods of manufacturing such mixtures

... 801,193. Explosive compositions containing aluminium. MAGNASCA, Ltd. Feb. 1, 1957 [Feb. 9, 1956], No. 3641/57. Class 9(2) An explosive mixture comprises a main explosive, aluminium in the grit state and at least one supplementary explosive of higher shattering power than the main explosive, the particles of the said supplementary explosive being coated with finely divided aluminium. In preparing the composition the supplementary explosive is treated with a solvent to make the surface of the particles sticky and then treating with finely divided aluminium and drying. Suitable solvents are acetone and glycol, and it is preferred to saturate the solvent with the explosive to be treated to 80 per cent saturation. The main explosive and the grit aluminium may be mixed in the presence of a binder e.g. collodion. The two mixtures so obtained may then be mixed and granulated. In an example trinitrotoluol, grit aluminium and barium nitrate are mixed with collodion as a binder and then mixed with ...

High-energy crystalline explosives - using polyurethane desensitising agent to coat the granules

Crystalline high-energy explosives, esp. hexogen or octogen are described in which the individual granules are coated with a polyurethane as densensitising agent. Used for casting of explosive charges, esp. hollow charges, from mixts. of high energy explosive and less brisant explosive, e.g. T.N.T. The polyurethane retains some elasticity after hardening and shows better adhesion to the granules than polyester coatings. The polyurethane m.pt. or decompsn. pt. is well above the temp. to which the charge is exposed during mfr. or use. It reduces sensitivity of the charge to shot or cracking in the field and ensures absolute homogeneity, giving increase in explosive force and efficiency.

PROCESS FOR IMPROVING THE PRESSURE DEPENDENCE OF THE COMBUSTION OF SOLID-GRAINS OR FIREARMS PROPELLANTS, AND THEIR APPLICATION AS COMPONENTS OF SOLID-GRAINS OR FIREARMS PROPELLANTS

ELECTRICALLY-IGNITABLE CASELESS PROPELLANT, AND THE PRODUCTION AND USE OF SAME

The invention relates to an electrically-ignitable caseless propellant in the form of a caseless propellant tablet (5), characterised in that it is obtainable by mixing at least one current-conductive material in dissolved, dispersed or powdered form, and graphite in powdered form, together with nitrocellulose, with or without the addition of further additives, and subsequently compressing this to obtain a propellant tablet. The invention also relates to the production and the use of same as well as to related subject matter of the invention. The following uses are covered: the use of the propellant in a nail gun device for inserting nails, as an explosive in a warning shot device, as a gas-generating element in airbags, for driving cutting devices, for driving pressing devices (e.g. for pressing claw-like elements together), or as a propellant in low-calibre weapons for sports purposes or stunning devices for animal slaughter.

Process for improving the pressure dependence of the combustion of solid-grains or firearms propellants, and their application as components of solid-grains or firearms propellants

1. Method for improving the pressure dependence of the burn-off behaviour of solid fuels or barrel weapon propellants which contain nitrocellulose and other monomeric or polymeric nitro or nitrate compounds, resp., as well as stabilizers and other additives as well as metals or metal compounds as burn-off influencing component, characterized in that the propellant is homogeneously distributed in a liquid and that then the metals or metal compounds are precipitated by chemical or physical precipitation on the nitrocellulose and the other solid monomeric or polymeric nitro or nitrate compounds, resp., and that thereafter the normal processing is carried out.

Purification process

A process for separating a nitramine or nitramine intermediate from water and volatile organic compounds comprises the steps of:(a) feeding a liquid stream comprising a liquid nitramine or nitramine intermediate, water, and at least one volatile organic compound, into the upper half of a stripper column;(b) feeding a gas stream having a temperature of at least about 120° C. into the lower half of the stripper column, whereby the gas stream and the liquid stream come into countercurrent contact in the stripper column;(c) withdrawing a nitramine or nitramine intermediate stream from the bottom of the stripper column; and(d) withdrawing a waste stream comprising gas and one or more of water vapor, water, formaldehyde, and acetic acid, from the top of the column.

DESENSITISATION BY COATING CRYSTALS OF EXPLOSIVE ENERGY SUBSTANCES, COATED CRYSTALS OF SUCH SUBSTANCES, AND ENERGY MATERIALS

The invention relates to a desensitisation method that involves coating crystals of an explosive energy substance, wherein said method comprises depositing, in a fluid and not in normal temperature and pressure conditions, preferably in supercritical conditions, a metal and/or polymer film, advantageously a metal film or a polymer film at the surface of said crystals, wherein the metal(s) and/or polymer(s) used have been previously dissolved in a solvent. The invention also relates to coated crystals of an explosive energy substance that can be obtained by said method, and to energy materials containing said coated crystals and/or crystals desensitised by said method.

DESENSITIZATION BY COATING OF CRYSTALS OF EXPLOSIVE ENERGETIC SUBSTANCES, COATED CRYSTALS OF SUCH SUBSTANCES, AND ENERGETIC MATERIALS

VERFAHREN ZUR VERBESSERUNG DES ABBRANDVERHALTENS VON FESTTREIBSTOFFEN ODER EXPLOSIVSTOFFEN

Process for improving the pressure dependence of the combustion of solid-grains or firearms propellants, and their application as components of solid-grains or firearms propellants

... 1. Method for improving the pressure dependence of the burn-off behaviour of solid fuels or barrel weapon propellants which contain nitrocellulose and other monomeric or polymeric nitro or nitrate compounds, resp., as well as stabilizers and other additives as well as metals or metal compounds as burn-off influencing component, characterized in that the propellant is homogeneously distributed in a liquid and that then the metals or metal compounds are precipitated by chemical or physical precipitation on the nitrocellulose and the other solid monomeric or polymeric nitro or nitrate compounds, resp., and that thereafter the normal processing is carried out.

TRAEGERGESCHOSS MIT UEBUNGSSUBMUNITIONSGESCHOSSEN.

DESENSITISATION BY COATING CRYSTALS OF EXPLOSIVE ENERGY SUBSTANCES, COATED CRYSTALS OF SUCH SUBSTANCES, AND ENERGY MATERIALS

The invention relates to a desensitisation method that involves coating crystals of an explosive energy substance, wherein said method comprises depositing, in a fluid and not in normal temperature and pressure conditions, preferably in supercritical conditions, a metal and/or polymer film, advantageously a metal film or a polymer film at the surface of said crystals, wherein the metal(s) and/or polymer(s) used have been previously dissolved in a solvent. The invention also relates to coated crystals of an explosive energy substance that can be obtained by said method, and to energy materials containing said coated crystals and/or crystals desensitised by said method.

Device for controlling a rate of gas pressure increase in a gun barrel

A device is disclosed for controlling a rate of gas pressure increase generated by a propellant for propelling a projectile from an upstream towards a downstream end of a gun barrel. The device includes a first surface area defined by the propellant and a deterrent applied to a second surface area defined by the first surface area, the second surface area being less than the first surface area. The arrangement is such that the second surface area defines a deterrent free third surface area of the propellant. A primer is operatively disposed relative to the third surface area such that when the primer is activated, the third surface area of the propellant is ignited. The arrangement is such that firstly, while the third surface area is burning and generating gas between the upstream end of the gun barrel and the projectile, the rate of gas pressure increase begins to propel the projectile towards the downstream end of the gun barrel. Secondly, the third surface area of the propellant while ...

BOMB PROJECTILE

PURPOSE: To provide a bomb body with which practices can be performed as realistic to actual battles as possible and can be manufactured economically without risk, by forming the effective explosive of the bomb body in a firework set composed of nitrocellulose, magnesium, and a binder, and igniting the explosive with an explosive charge through a fire introducing hole formed in a central inner tube by using a delaying member for an igniter. CONSTITUTION: When a bomb body is discharged from a gun barrel, a delaying igniter ignites the ejection igniting powder 23 of the body while the body is in the orbit of a target area. When the igniting powder 23 is ignited, the flame beam of the power 23 reaches the fire introducing hole 14 of a bomb 10 through fire introducing holes 22 and 22a and ignites the igniting portion 15a of a delaying small tube 15 by breaking through a cover film 16. In addition, a high gas pressure is formed in the ball 10 by the ignited powder 23 and bursts the bottom section ...

END-BURNING PROPELLANT GRAIN WITH AREA-ENHANCED BURNING SURFACE

An end-burning grain of a solid rocket motor or other gas-generating device is supplemented with one or more sticks of high-burn-rate propellant embedded in a matrix of a relatively low-burn-rate propellant. The sticks increase the burning surface area as the grain burns by forming conical indentations in the surface.

Exercise firing projectile

An exercise firing projectile containing a plurality of pyrotechnic fragmentation devices are expelled from the projectile casing above the target area by an ejection charge, and delay tubes of the fragmentation devices are ignited at the same time by this charge through a central igniter tube contained within the projectile. The active charge of the devices consist of a grainy composite with quick reaction time.

Pyrotechnic material and method for manufacturing

Exercise firing projectile

An exercise firing projectile containing a plurality of pyrotechnic fragmentation devices are expelled from the projectile casing above the target area by an ejection charge, and delay tubes of the fragmentation devices are ignited at the same time by this charge through a central igniter tube contained within the projectile. The active charge of the devices consist of a grainy composite with quick reaction time.

Carrier projectile and training submissiles therefor

A graphene/metal or semi-metal shell - nuclear structure composite material and its preparation method

Process for making composite particles from crystalline explosives

Composite crystalline particles, for propellants and explosives, are produced by cooling or evaporation crystallizing with first component dissolved in solvent where second component is insoluble The composite particles of crystalline explosives are of two crystalline explosive or propellant and/or oxidator components, formed by cooling or evaporation crystallizing. The second component is taken from a nitramine group and the first component is dissolved in a solvent where the second component is either insoluble or is difficult to dissolve. The second component is added to the solvent first as a dispersion. For cooling crystallizing, the solution temperature is lowered below the saturation temperature of the first component. For evaporation crystallizing, the solvent is evaporated above the saturation concentration of the first component in the solvent so that it is deposited on the surfaces of the particles of the second component. The first component is an amine, amide, nitro, nitrate ...

Carrier projectile and training submissiles therefor

An exercise firing projectile containing a plurality of pyrotechnic fragmentation devices are expelled from the projectile casing above the target area by an ejection charge, and delay tubes of the fragmentation devices are ignited at the same time by this charge through a central igniter tube contained within the projectile. The active charge of the devices consist of a grainy composite with quick reaction time.

END-BURNING PROPELLANT GRAIN WITH AREA-ENHANCED BURNING SURFACE

An end-burning grain of a solid rocket motor or other gas-generating device is supplemented with one or more sticks of high-burn-rate propellant embedded in a matrix of a relatively low-burn-rate propellant. The sticks increase the burning surface area as the grain burns by forming conical indentations in the surface.

Method for in-situ generation of carbon fiber explosive and explosive using same

DETERRENT COATING FOR PROPELLENT GRAINS

Pyrotechnic material and method for manufacturing

L'invention a pour objet une substance pulvérulente, notamment une substance pyrotechnique, caractérisée en ce qu'elle comporte au moins un premier matériau formé de grains (2) enrobés par une couche de liant (3) incorporant des granules (4) d'un second matériau de granulométrie nanométrique. L'invention a également pour objet un procédé permettant de fabriquer une telle substance.

Progressive burning smokeless powder

Single walled carbon nanotubes activated with hydrazoic acid

The present invention relates generally to carbon nanotubes, and more particularly to the interaction of single wall carbon nanotubes with hydrazoic acid to introduce energetic azide groups into the nanotubes to form activated carbon nanotubes.

Method for preparing graphene-coated spheroidization ammonium dinitramide

HMX compositions and processes for their preparation

A process for making alpha-HMX comprises the steps of:(a) combining phosphorus pentoxide and nitric acid at a temperature of about 0-25° C., forming a reaction mixture; and(b) adding a compound having the formula:wherein R is straight chain or branched alkyl having 1-5 carbon atoms, to the reaction mixture, whereby a product comprising alpha-HMX is produced.

End-burning propellant grain with area-enhanced burning surface

An end-burning grain of a solid rocket motor or other gas-generating device is supplemented with one or more sticks of high-burn-rate propellant embedded in a matrix of a relatively low-burn-rate propellant. The sticks increase the burning surface area as the grain burns by forming conical indentations in the surface.

Encapsulated, particulate energetic composition and the making of same

An encapsulated, particulate energetic composition includes one of explosive particles of a known size, oxidizer particles of a known size, and a mixture of explosive particles and oxidizer particles of known sizes, in which particles of one of the explosive particles, the oxidizer particles, and the mixture of the explosive and the oxidizer particles, are encapsulated by a combustible fuel of a known thickness to enhance the energy output. A method of making the encapsulated, particulate energetic composition includes placing one of explosive particles, oxidizer particles, and a mixture of explosive particles and oxidizer particles within a deposition chamber, mixing one of the explosive particles, the oxidizer particles, and the mixture of explosive particles and the oxidizer particles, and depositing, to a known encapsulating thickness, a combustible fuel onto the one of the explosive particles, the oxidizer particles, and the mixture of explosive particles and oxidizer.

Device for controlling a rate of gas pressure increase in a gun barrel.

A device is disclosed for controlling a rate of gas pressure increase generated by a propellant for propelling a projectile from an upstream towards a downstream end of a gun barrel. The device includes a first surface area defined by the propellant and a deterrent applied to a second surface area defined by the first surface area, the second surface area being less than the first surface area. The arrangement is such that the second surface area defines a deterrent free third surface area of the propellant. A primer is operatively disposed relative to the third surface area such that when the primer is activated, the third surface area of the propellant is ignited. The arrangement is such that firstly, while the third surface area is burning and generating gas between the upstream end of the gun barrel and the projectile, the rate of gas pressure increase begins to propel the projectile towards the downstream end of the gun barrel. Secondly, the third surface area of the propellant while burning exposes a progressively increasing surface area of the propellant for burning together with an associated increased generation of gas, the increasing surface area of the propellant defining a concave crater, the crater having a wall which progressively increases in surface area during the burning such that the rate of increase in gas pressure continues to increase for accelerating the projectile towards the downstream end of the gun barrel.

爆発エネルギー材の複数の結晶にコーティングを施すことにより感度を抑制する方法、このような物質のコーティングが施された結晶、及びエネルギー材

... 本発明の主題は、常温常圧の範囲外の、好ましくは臨界状態の流体内において、溶媒中に予め溶解された金属又は重合体の膜、有利には金属の膜又は重合体の膜を、前記結晶の表面上に堆積する工程を含む、コーティングによりエネルギー爆発物質の結晶の感度を抑制する方法と、上記の方法により得られる、コーティングが施されたエネルギー爆発物質の結晶と、上記方法によりコーティングが施された結晶及び/又は前記方法により、感度の抑制された前記結晶とである。 【選択図】なし ...

End-burning propellant grain with area-enhanced burning surface

An end-burning grain of a solid rocket motor or other gas-generating device is supplemented with one or more sticks of high-burn-rate propellant embedded in a matrix of a relatively low-burn-rate propellant. The sticks increase the burning surface area as the grain burns by forming conical indentations in the surface.

Method for making single walled carbon nanotubes by activation with hydrazoic acid

The present invention relates generally to methods of making carbon nanotubes, and more particularly to the interaction of single wall carbon nanotubes with hydrazoic acid to introduce energetic azide groups into the nanotubes to form activated carbon nanotubes.

Metal binders for insensitive munitions

An explosive composition, an insensitive munition with a metal eutectic binder, and a method include using a metal eutectic binder with metal coated explosive particles. The metal eutectic binder concept represents novel melt-cast solid mixtures having explosives such as RDX (cyclonite) or HMX (octogen) distributed in an alloy including, for example, eutectic bismuth (Bi)/tin (Sn). Eutectic alloys are particularly considered to provide a melting point of the mixture below the exothermic point of the explosive so that vented munitions disarm by melting without exploding in the event of fire or other elevated heating. Particularly novel is the pre-coating of crystals of explosive (RDX/HMX) with a metal to promote wetting and bonding during melt fabrication of the final mixture. Copper, aluminum, and other metals are considered for use as coating.

Graphene/Metal or Metalloid Core-Shell Composite and Manufacturing Method Thereof

The present invention relates to a manufactured graphene/metal or metalloid core-shell composite and manufacturing method thereof. The method comprising: using a modified graphene oxide as a base, then performing concentration and steam drying followed by organic solvent replacement to obtain a modified graphene oxide organic solvent; using a liquid-phase self-assembly method to coat the modified graphene oxide onto a surface of the metal or metalloid to form a graphene/metal or metalloid coated particle solution, then filtering and drying to obtain the graphene metal/metalloid core-shell composite. The method improves upon a conventional organic and inorganic material coating technique, and reduces an impact of a water-based solvent and high temperature on a highly reactive metal and metalloid, thereby expanding the feasibility of the coating technique and addressing a barrier of applicability of graphene and reactive metal or metalloid in the field of energetic materials.

Process for making a 1,3,5,7-tetraalkanoyl-1,3,5,7-tetraazacyclooctane

A process for making a 1,3,5,7-tetraalkanoyl-1,3,5,7-tetraazacyclooctane comprises the steps of:(a) reacting a compound having the formulawherein R is straight chain or branched alkyl having 1-5 carbon atoms, with an alkanoic acid anhydride having the formula (RCO)2O, where R is as defined above, thereby producing a compound having the formula:wherein R is as defined above; and(b) reacting the compound having the formula (II) with the alkanoic acid anhydride in the presence of water and a catalytic amount of at least one transition metal oxide, thereby producing a compound having the formulawhere R is as defined above.

燃焼表面積が拡大された端面燃焼推進剤グレイン

Bomb bullet

An exercise firing projectile containing a plurality of pyrotechnic fragmentation devices are expelled from the projectile casing above the target area by an ejection charge, and delay tubes of the fragmentation devices are ignited at the same time by this charge through a central igniter tube contained within the projectile. The active charge of the devices consist of a grainy composite with quick reaction time.

Polyethyleneimine-enhanced graphene insensitive energetic material and preparation method thereof

本发明公开了一种聚乙烯亚胺增强石墨烯钝感化含能材料及其制备方法，包括以下步骤：将含能材料分散于水相中，搅拌条件下加缓慢加入聚乙烯亚胺水溶液得到第一混合液，含能材料与聚乙烯亚胺的质量比为98：(0.05～1.95)；搅拌条件下，将石墨烯的分散水溶液加入到第一混合液中，得到第二混合液，其中聚乙烯亚胺与石墨烯的质量比为1.95:0.05～0.05:1.95；将第二混合溶液持续搅拌2～10小时得到悬浮液；将悬浮液过滤、洗涤、干燥即得聚乙烯亚胺增强石墨烯钝感化含能材料。该方法可以增强钝感剂与含能材料间的相互作用，降低了含能材料的机械感度。

Desensitisation by coating of crystals of explosive energetic substances, coated crystals of such substances, and energetic materials

Device for controlling a rate of gas pressure increase in a gun barrel

A device is disclosed for controlling a rate of gas pressure increase generated by a propellant for propelling a projectile from an upstream towards a downstream end of a gun barrel. The device includes a first surface area defined by the propellant and a deterrent applied to a second surface area defined by the first surface area, the second surface area being less than the first surface area. The arrangement is such that the second surface area defines a deterrent free third surface area of the propellant. A primer is operatively disposed relative to the third surface area such that when the primer is activated, the third surface area of the propellant is ignited. The arrangement is such that firstly, while the third surface area is burning and generating gas between the upstream end of the gun barrel and the projectile, the rate of gas pressure increase begins to propel the projectile towards the downstream end of the gun barrel. Secondly, the third surface area of the propellant while burning exposes a progressively increasing surface area of the propellant for burning together with an associated increased generation of gas, the increasing surface area of the propellant defining a concave crater, the crater having a wall which progressively increases in surface area during the burning such that the rate of increase in gas pressure continues to increase for accelerating the projectile towards the downstream end of the gun barrel.

Preparation method of polyepichlorohydrin

The present invention relates to a preparation method of polyepichlorohydrin, a precursor of a glycidyl azide polymer which is a high energy binder for a solid propellant, by polymerizing epichlorohydrin in the presence of boron trifluoride etherate. According to the present invention, boron trifluoride etherate is used as a catalyst. Thus, the preparation method of polyepichlorohydrin is environment-friendly, has low manufacturing costs, and can minimize effects of manufacturing a propellant to a urethane curing reaction.

A kind of method of in-situ preparation carbon fiber explosive and the explosive using this method

本发明公开了一种原位生成碳纤维炸药的方法及使用该方法的炸药，尤其涉及一种使用耐高温材料包覆固体单质炸药并原位生成碳纤维炸药的方法。按重量份数主要由下述组分组成：固体单质炸药75‑95份、耐高温包覆剂2‑6份、导电聚合物5‑15份、二茂铁10‑30份。本发明通过四步法制备出碳纤维炸药，在微波作用下耐高温材料包覆后的炸药颗粒外表面会原位生成碳纤维，使炸药颗粒之间形成统一体，大大改善了炸药的力学性能和爆轰性能。并且工艺简单、原材料来源广泛、成本低廉，具有良好的应用前景。

End-burning propellant grain with area-enhanced burning surface

一种炸药包覆降感的方法

本发明公开了一种炸药包覆降感的方法，包括以下步骤：步骤一、将高能硝胺炸药溶于溶剂Ⅰ中，搅拌，配制质量分数为0.1～50％的炸药溶液；步骤二、将聚合氯化铝溶于溶剂Ⅱ中，搅拌，得到质量分数为0.2～0.5％的聚合氯化铝溶液；步骤三、将聚合氯化铝溶液加入到炸药溶液中，在20～70℃下，搅拌，过滤，干燥，得到包覆后的高能硝胺炸药。本发明通过在高能炸药中引入聚合氯化铝，利用其不敏感性，制备了包覆炸药，有效的降低了高能炸药的机械感度。本发明采用溶剂‑非溶剂的方法，利用聚合氯化铝自聚合作用，可有效的控制炸药的结晶粒度，改善其表面光滑度，实现结晶控制及钝感包覆的目的。本发明工艺简单，原料易得，易于实现。

나노고에너지물질 복합체 및 그의 열적 점화를 위한 가스 발생기

본 발명은 아자이드(azide)계열인 아지드화나트륨(NaN 3 )/나노고에너지물질과 함께 혼합 사용하여 가스발생시 내압을 낮추고 기체 발생시간 및 연소 속도와 온도의 제어가 효율적으로 이루어지도록 한 나노고에너지물질 복합체 및 그의 열적 점화를 위한 가스 발생기에 관한 것으로, 가스를 발생시키기 위한 반응 물질로 사용되는 아자이드(azide)계열의 물질;상기 아자이드(azide)계열의 물질을 열적으로 반응시키기 위한 열에너지 공급원(heat energy source)으로 사용되는 나노고에너지물질(nEMs)이 혼합되어 복합체 분말을 구성하고, 상기 복합체 분말은 점화 및 폭발에 의해 생성되는 열에너지에 의해서 반응 물질로 사용되는 아자이드(azide)계열의 물질의 마이크로입자는 분해되면서 기체를 발생시키는 것이다.

一种炸药包覆降感的方法

本发明公开了一种炸药包覆降感的方法，包括以下步骤：步骤一、将高能硝胺炸药溶于溶剂Ⅰ中，搅拌，配制质量分数为0.1～50％的炸药溶液；步骤二、将聚合氯化铝溶于溶剂Ⅱ中，搅拌，得到质量分数为0.2～0.5％的聚合氯化铝溶液；步骤三、将聚合氯化铝溶液加入到炸药溶液中，在20～70℃下，搅拌，过滤，干燥，得到包覆后的高能硝胺炸药。本发明通过在高能炸药中引入聚合氯化铝，利用其不敏感性，制备了包覆炸药，有效的降低了高能炸药的机械感度。本发明采用溶剂‑非溶剂的方法，利用聚合氯化铝自聚合作用，可有效的控制炸药的结晶粒度，改善其表面光滑度，实现结晶控制及钝感包覆的目的。本发明工艺简单，原料易得，易于实现。

一种钙钛矿含能材料dap-4基微纳核壳结构及其制备方法

本发明公开了一种钙钛矿含能材料DAP‑4基微纳核壳结构的制备方法，向DAP‑4中加入乙酸乙酯并超声分散，得到第一溶液；第一溶液进行磁力搅拌，并匀速加入EVA‑二氯乙烷溶液，持续加热搅拌，得到第二溶液；取不敏感炸药或者金属粉，加入第二溶液后继续加热搅拌，得到第一产物；使用无水乙醇冲将第一产物冲出，随后烘干，即得一种钙钛矿含能材料DAP‑4基微纳核壳结构。本发明使用DAP‑4为内核敏感含能材料，有机复合物EVA作为中间修饰剂，不敏感炸药或者金属粉为外壳材料，采用溶剂‑非溶剂法制备出DAP‑4基微纳核壳结构。

End-burning propellant grain with area-enhanced burning surface

An end-burning grain of a solid rocket motor or other gas-generating device is supplemented with one or more sticks of high-burn-rate propellant embedded in a matrix of a relatively low-burn-rate propellant. The sticks increase the burning surface area as the grain burns by forming conical indentations in the surface.

End-burning propellant grain with area-enhanced burning surface

3-硝基-1,2,4-三唑-5-酮/二氧化锆复合纳米含能材料及其制备方法

本发明涉及一种3‑硝基‑1,2,4‑三唑‑5‑酮/二氧化锆复合纳米含能材料及其制备方法，该材料由“核”、“壳”两部分构成。“核”为NTO颗粒，经喷雾干燥得到粒径为500～5000nm的3‑硝基‑1,2,4‑三唑‑5‑酮颗粒。“壳”为粒径5～300nm的纳米二氧化锆粒子。利用超声混合作用制备得3‑硝基‑1,2,4‑三唑‑5‑酮/二氧化锆复合纳米含能材料。本发明制备得到的复合纳米含能材料同时具有3‑硝基‑1,2,4‑三唑‑5‑酮的高能量密度，二氧化锆的导电性，以及复合纳米材料优异的钝感性和强抗金属腐蚀性的优点。此方法制备过程简单，成本较低，纳米二氧化锆能够均匀的包覆在含能材料3‑硝基‑1,2,4‑三唑‑5‑酮的颗粒上，复合材料的粒径和厚度可调控，应用前景良好。

Al2O3-氧化石墨/NTO复合核壳结构含能材料及其制备方法

本发明涉及了一种Al 2 O 3 ‑氧化石墨/NTO复合核壳结构含能材料及其制备方法，首先通过溶胶‑凝胶法制备得到Al 2 O 3 ‑氧化石墨纳米杂化物，然后将纳米杂化物颗粒通过超声作用均匀分散在溶液中，并逐渐滴加到NTO悬浊液中，用过超声混合作用，制备得到Al 2 O 3 ‑氧化石墨/NTO复合核壳结构含能材料。通过以Al 2 O 3 ‑氧化石墨纳米杂化物作为抑酸包覆层，以Al 2 O 3 ‑氧化石墨纳米杂化物作为“壳”，将“核”层材料NTO颗粒均匀的包覆起来，由于纳米Al 2 O 3 和氧化石墨表面具有巨大的比表面积和大量O‑H基团，因此二者都可以以强相互作用与NTO表面的N‑H键结合，形成包覆强度大且分布均匀的核壳结构，有效的抑制了NTO的酸性；另一方面，氧化石墨具有优异的导热性能，得到的复合材料有效的优化了NTO的热性能。

一种具有强抑酸包覆层结构的炸药及其制备方法

本发明公开了一种具有强抑酸包覆层结构的炸药及其制备方法，将纳米Fe 2 O 3 粉末分散在热溶剂中，形成均匀的分散液，加入到过饱和的炸药悬浊液中，搅拌均匀，得到混合浆料。然后经过喷雾干燥工艺，通氮气，进行细化造粒，最后经过洗涤、干燥，制备具有强抑酸包覆层结构的炸药。同时本发明还公开了一种具有强抑酸包覆层结构的炸药，通过在炸药表面制备的包覆层结构，实现抑酸、降感、导热等综合功效，解决现有高能炸药安全性差的矛盾问题。

一种钙钛矿含能材料dap-4基微纳核壳结构及其制备方法

本发明公开了一种钙钛矿含能材料DAP‑4基微纳核壳结构的制备方法，向DAP‑4中加入乙酸乙酯并超声分散，得到第一溶液；第一溶液进行磁力搅拌，并匀速加入EVA‑二氯乙烷溶液，持续加热搅拌，得到第二溶液；取不敏感炸药或者金属粉，加入第二溶液后继续加热搅拌，得到第一产物；使用无水乙醇冲将第一产物冲出，随后烘干，即得一种钙钛矿含能材料DAP‑4基微纳核壳结构。本发明使用DAP‑4为内核敏感含能材料，有机复合物EVA作为中间修饰剂，不敏感炸药或者金属粉为外壳材料，采用溶剂‑非溶剂法制备出DAP‑4基微纳核壳结构。

微纳米TiO2@NTO复合含能材料及其制备方法

本发明涉及一种微纳米TiO 2 @NTO复合含能材料及其制备方法，以不敏感含能材料3‑硝基‑1，2，4‑三唑‑5‑酮和改性的纳米TiO 2 粉末作为原材料，合成一种以高能低感度含能材料作为核，纳米TiO 2 作为壳的核壳复合材料，在不影响NTO颗粒本身粒径和其它性能的前提下，通过超声混合的方式成功制备得到一种抑制NTO表面酸性，增强其使用安全性能的复合含能材料，大大减少了其酸性对金属产生的腐蚀作用。本发明提供的制备方法简单，成本低，操作便捷，具有实际应用价值。

微纳米结构Al2O3/NTO抑酸导热复合不敏感含能材料及其制备方法

本发明公开了一种微纳米结构Al 2 O 3 /NTO抑酸导热复合不敏感含能材料及其制备方法，材料包括如下重量百分数的组分：0.5～5％的纳米Al 2 O 3 和95～99.5％的3‑硝基‑1，2，4‑三唑‑5‑酮；制备方法先按比例制备得到过饱和的NTO悬浊液和纳米Al 2 O 3 分散液，然后通过加热作用下的超声混合得到微纳米结构Al 2 O 3 /NTO抑酸导热复合不敏感含能材料。本发明中微纳米结构Al 2 O 3 /NTO抑酸导热复合不敏感含能材料不仅抑制了NTO颗粒本身的酸性，降低对金属的腐蚀性，而且优化了NTO颗粒的导热性能；制备方法简单，操作简便，具有实际应用价值。

微纳米结构Al2O3/NTO抑酸导热复合不敏感含能材料及其制备方法

本发明公开了一种微纳米结构Al 2 O 3 /NTO抑酸导热复合不敏感含能材料及其制备方法，材料包括如下重量百分数的组分：0.5～5％的纳米Al 2 O 3 和95～99.5％的3‑硝基‑1，2，4‑三唑‑5‑酮；制备方法先按比例制备得到过饱和的NTO悬浊液和纳米Al 2 O 3 分散液，然后通过加热作用下的超声混合得到微纳米结构Al 2 O 3 /NTO抑酸导热复合不敏感含能材料。本发明中微纳米结构Al 2 O 3 /NTO抑酸导热复合不敏感含能材料不仅抑制了NTO颗粒本身的酸性，降低对金属的腐蚀性，而且优化了NTO颗粒的导热性能；制备方法简单，操作简便，具有实际应用价值。

微纳米TiO2@NTO复合含能材料及其制备方法

本发明涉及一种微纳米TiO 2 @NTO复合含能材料及其制备方法，以不敏感含能材料3‑硝基‑1，2，4‑三唑‑5‑酮和改性的纳米TiO 2 粉末作为原材料，合成一种以高能低感度含能材料作为核，纳米TiO 2 作为壳的核壳复合材料，在不影响NTO颗粒本身粒径和其它性能的前提下，通过超声混合的方式成功制备得到一种抑制NTO表面酸性，增强其使用安全性能的复合含能材料，大大减少了其酸性对金属产生的腐蚀作用。本发明提供的制备方法简单，成本低，操作便捷，具有实际应用价值。

3-硝基-1,2,4-三唑-5-酮/二氧化锆复合纳米含能材料及其制备方法

本发明涉及一种3‑硝基‑1,2,4‑三唑‑5‑酮/二氧化锆复合纳米含能材料及其制备方法，该材料由“核”、“壳”两部分构成。“核”为NTO颗粒，经喷雾干燥得到粒径为500～5000nm的3‑硝基‑1,2,4‑三唑‑5‑酮颗粒。“壳”为粒径5～300nm的纳米二氧化锆粒子。利用超声混合作用制备得3‑硝基‑1,2,4‑三唑‑5‑酮/二氧化锆复合纳米含能材料。本发明制备得到的复合纳米含能材料同时具有3‑硝基‑1,2,4‑三唑‑5‑酮的高能量密度，二氧化锆的导电性，以及复合纳米材料优异的钝感性和强抗金属腐蚀性的优点。此方法制备过程简单，成本较低，纳米二氧化锆能够均匀的包覆在含能材料3‑硝基‑1,2,4‑三唑‑5‑酮的颗粒上，复合材料的粒径和厚度可调控，应用前景良好。

一种具有强抑酸包覆层结构的炸药及其制备方法

本发明公开了一种具有强抑酸包覆层结构的炸药及其制备方法，将纳米Fe 2 O 3 粉末分散在热溶剂中，形成均匀的分散液，加入到过饱和的炸药悬浊液中，搅拌均匀，得到混合浆料。然后经过喷雾干燥工艺，通氮气，进行细化造粒，最后经过洗涤、干燥，制备具有强抑酸包覆层结构的炸药。同时本发明还公开了一种具有强抑酸包覆层结构的炸药，通过在炸药表面制备的包覆层结构，实现抑酸、降感、导热等综合功效，解决现有高能炸药安全性差的矛盾问题。

核壳结构SiO2@NTO复合材料及制备方法

本发明提供一种核壳结构SiO 2 @NTO复合材料及其制备方法，在微米级NTO颗粒表面包覆纳米尺寸的二氧化硅颗粒，通过利用二氧化硅的Si‑O键与NTO分子上的N‑H键之间的键合作用，减少NTO颗粒溶解在水溶液中的氢离子，从而降低NTO颗粒本身在水溶液中的酸性。本发明中酸性抑制型不敏感复合材料不仅能有效抑制NTO分子中的酸性逸出过程，大大减少了其酸性对金属产生的腐蚀作用。制备方法简单，利用超声分散法将水溶液中的纳米二氧化硅进行分散，再通过进一步的超声作用将NTO与纳米二氧化硅制备得到抑酸型的复合含能材料，具有实际应用价值。

Al2O3-氧化石墨/NTO复合核壳结构含能材料及其制备方法

本发明涉及了一种Al 2 O 3 ‑氧化石墨/NTO复合核壳结构含能材料及其制备方法，首先通过溶胶‑凝胶法制备得到Al 2 O 3 ‑氧化石墨纳米杂化物，然后将纳米杂化物颗粒通过超声作用均匀分散在溶液中，并逐渐滴加到NTO悬浊液中，用过超声混合作用，制备得到Al 2 O 3 ‑氧化石墨/NTO复合核壳结构含能材料。通过以Al 2 O 3 ‑氧化石墨纳米杂化物作为抑酸包覆层，以Al 2 O 3 ‑氧化石墨纳米杂化物作为“壳”，将“核”层材料NTO颗粒均匀的包覆起来，由于纳米Al 2 O 3 和氧化石墨表面具有巨大的比表面积和大量O‑H基团，因此二者都可以以强相互作用与NTO表面的N‑H键结合，形成包覆强度大且分布均匀的核壳结构，有效的抑制了NTO的酸性；另一方面，氧化石墨具有优异的导热性能，得到的复合材料有效的优化了NTO的热性能。

原位制备抑酸型复合含能材料及其制备方法

本发明提供了一种原位制备抑酸型复合含能材料的方法，通过利用Stober法在NTO颗粒的表面原位生成纳米的SiO 2 粒子，得到的复合材料具有很强的包覆强度和很高的包覆率，一方面生成的纳米粒子均匀的包覆在NTO表面，有效抑制住了NTO表面的游离出来H离子，降低了NTO的酸性，减少了接触金属的腐蚀，另一方面，生成的SiO2颗粒为薄薄一层，不影响NTO颗粒本身的性能。本发明得到的NTO/SiO 2 复合材料结合作用力强，有效包覆NTO，抑制其酸性逸出。

一种钙钛矿含能材料dap-4基微纳核壳结构及其制备方法

本发明公开了一种钙钛矿含能材料DAP‑4基微纳核壳结构的制备方法，向DAP‑4中加入乙酸乙酯并超声分散，得到第一溶液；第一溶液进行磁力搅拌，并匀速加入EVA‑二氯乙烷溶液，持续加热搅拌，得到第二溶液；取不敏感炸药或者金属粉，加入第二溶液后继续加热搅拌，得到第一产物；使用无水乙醇冲将第一产物冲出，随后烘干，即得一种钙钛矿含能材料DAP‑4基微纳核壳结构。本发明使用DAP‑4为内核敏感含能材料，有机复合物EVA作为中间修饰剂，不敏感炸药或者金属粉为外壳材料，采用溶剂‑非溶剂法制备出DAP‑4基微纳核壳结构。

核壳结构SiO2@NTO复合材料及制备方法

本发明提供一种核壳结构SiO 2 @NTO复合材料及其制备方法，在微米级NTO颗粒表面包覆纳米尺寸的二氧化硅颗粒，通过利用二氧化硅的Si‑O键与NTO分子上的N‑H键之间的键合作用，减少NTO颗粒溶解在水溶液中的氢离子，从而降低NTO颗粒本身在水溶液中的酸性。本发明中酸性抑制型不敏感复合材料不仅能有效抑制NTO分子中的酸性逸出过程，大大减少了其酸性对金属产生的腐蚀作用。制备方法简单，利用超声分散法将水溶液中的纳米二氧化硅进行分散，再通过进一步的超声作用将NTO与纳米二氧化硅制备得到抑酸型的复合含能材料，具有实际应用价值。

原位制备抑酸型复合含能材料及其制备方法

本发明提供了一种原位制备抑酸型复合含能材料的方法，通过利用Stober法在NTO颗粒的表面原位生成纳米的SiO 2 粒子，得到的复合材料具有很强的包覆强度和很高的包覆率，一方面生成的纳米粒子均匀的包覆在NTO表面，有效抑制住了NTO表面的游离出来H离子，降低了NTO的酸性，减少了接触金属的腐蚀，另一方面，生成的SiO2颗粒为薄薄一层，不影响NTO颗粒本身的性能。本发明得到的NTO/SiO 2 复合材料结合作用力强，有效包覆NTO，抑制其酸性逸出。

一种聚乙烯亚胺增强石墨烯钝感化含能材料及其制备方法

本发明公开了一种聚乙烯亚胺增强石墨烯钝感化含能材料及其制备方法，包括以下步骤：将含能材料分散于水相中，搅拌条件下加缓慢加入聚乙烯亚胺水溶液得到第一混合液，含能材料与聚乙烯亚胺的质量比为98：(0.05～1.95)；搅拌条件下，将石墨烯的分散水溶液加入到第一混合液中，得到第二混合液，其中聚乙烯亚胺与石墨烯的质量比为1.95:0.05～0.05:1.95；将第二混合溶液持续搅拌2～10小时得到悬浮液；将悬浮液过滤、洗涤、干燥即得聚乙烯亚胺增强石墨烯钝感化含能材料。该方法可以增强钝感剂与含能材料间的相互作用，降低了含能材料的机械感度。

一种炸药包覆降感的方法

本发明公开了一种炸药包覆降感的方法，包括以下步骤：步骤一、将高能硝胺炸药溶于溶剂Ⅰ中，搅拌，配制质量分数为0.1～50％的炸药溶液；步骤二、将聚合氯化铝溶于溶剂Ⅱ中，搅拌，得到质量分数为0.2～0.5％的聚合氯化铝溶液；步骤三、将聚合氯化铝溶液加入到炸药溶液中，在20～70℃下，搅拌，过滤，干燥，得到包覆后的高能硝胺炸药。本发明通过在高能炸药中引入聚合氯化铝，利用其不敏感性，制备了包覆炸药，有效的降低了高能炸药的机械感度。本发明采用溶剂‑非溶剂的方法，利用聚合氯化铝自聚合作用，可有效的控制炸药的结晶粒度，改善其表面光滑度，实现结晶控制及钝感包覆的目的。本发明工艺简单，原料易得，易于实现。

一种石墨烯包覆球形化二硝酰胺铵的制备方法

本发明公开了一种石墨烯包覆球形化二硝酰胺铵的制备方法，包括以下步骤：第一步：在超声波‑硝胺炸药共同诱导作用下，采用常温或低温重结晶法制备球形化二硝酰胺铵；第二步：采用超声‑反溶剂法制备石墨烯包覆球形化二硝酰胺铵复合材料。本发明改进了采用常规高温融化二硝酰胺铵球形化工艺，降低了高温下材料局部过热或聚集带来的危险，拓展了球形化‑包覆方法的工艺实现性；采用与之具有相互作用的高活性氧化石墨烯进行包覆，增加了二者之间结合力，显著降低了二硝酰胺铵的吸湿性。