| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 表面爆破产品 | CN201180016900.X | 2011-04-06 | CN102869948A | 2013-01-09 | 亚尔莫·奥莱维·莱佩宁 |
| 一种表面爆破产品(10),其包括容器(60)、接收器和炸药,该接收器包含可移位以将容器附着到岩石的粘合剂,炸药在容器内部,该炸药能够被引燃以碎裂或移位岩石。 | ||||||
| 2 | 一种导爆管网路快速接线装置 | CN201710314710.5 | 2017-05-06 | CN107036496A | 2017-08-11 | 余红兵; 任少峰; 岳梦蕾; 周建敏; 李杰; 刘强; 刘磊; 张亮; 莫豹 |
| 本发明公开了一种导爆管网路快速接线装置,包括雷管卡套和底座卡套,在雷管卡套上部内壁设置有至少两条凸棱A,在雷管卡套上部管壁上设置有开口A,在底座卡套内壁设置凸棱B,所述雷管卡套下端装配于底座卡套内,雷管卡套部分外壁与底座卡套内壁凸棱B紧密接触,在底座卡套上部管壁上也设置有开口B,雷管卡套部分外壁与底座卡套内壁之间的间隙与导爆管相适配,在雷管卡套部分外壁与底座卡套内壁之间的间隙可以设置多个导爆管。本发明可以将导爆管快速固定在雷管周围,并且雷管和导爆管之间位置确定,操作方便快捷。 | ||||||
| 3 | 表面爆破产品 | CN201180016900.X | 2011-04-06 | CN102869948B | 2015-09-02 | 亚尔莫·奥莱维·莱佩宁 |
| 一种表面爆破产品(10),其包括容器(60)、接收器和炸药,该接收器包含可移位以将容器附着到岩石的粘合剂,炸药在容器内部,该炸药能够被引燃以碎裂或移位岩石。 | ||||||
| 4 | 爆破筒 | CN200580008579.5 | 2005-03-02 | CN100504280C | 2009-06-24 | 简-阿克·本特森 |
| 爆破筒包括:大致圆柱形的套管(2),具有密封其第一端的端壁(6);端部单元(3),其在套管第二端插入套管一定深度,具有面对套管内部的内侧(4)和处于端部单元相对侧的外侧(5);在套管中处于端壁和内侧之间的腔室(7),其填充有爆炸剂(8);在外口(11)和内口(12)之间延伸穿过端部单元的通道(10),包括用于起爆筒(11)的底座(13);以及容纳在该底座中的起爆筒,其容纳用于对腔室中的爆炸剂进行点火的引爆炸药。至少一个轴向突出的间隔构件(20)设置在爆破筒第一端的端壁(6)的外侧和/或爆破筒第二端的端部单元上,使得当使两个爆破筒进入钻孔(24)中以待引爆时,中间空间(28)形成于第一下爆破筒的外侧(5)和置于第一爆破筒上的第二上爆破筒的端壁的下侧之间,并且至少一个通路(21)设置在径向上、通过所述间隔构件、允许所述中间空间和钻孔中的环绕空间(27)之间连通。 | ||||||
| 5 | 一种新型深孔水压爆破装置 | CN201710078578.2 | 2017-02-14 | CN106679520A | 2017-05-17 | 张义平; 周俊; 田浩; 王建楠; 杨静; 严鸿海 |
| 本发明公开了一种新型深孔水压爆破装置,包括外腔、导火索和密封盖,所述外壳和内隔板之间的空腔为外腔,所述外腔内安装有四个炸药箱,所述炸药箱的两端分别连接有一根外固定条,所述两根外固定条的另一端分别固定在外壳和内隔板上,所述内隔板内的空腔为内腔,所述内腔内安装有一个炸药箱,所述炸药箱的上下左右四个万向各有一根内固定条和内隔板连接,所述共五个炸药箱上都连接有一根导火索,所述外壳的顶部安装有一个密封盖,所述导火索穿过密封盖向外伸出。该新型深孔水压爆破装置设有五个炸药箱,且按回字形结构排列外壳为球形结构,球形结构更加坚固,不容易破碎或变形。 | ||||||
| 6 | 一种电子雷管快速施工装置及其使用方法 | CN201510864584.1 | 2015-11-30 | CN105423833A | 2016-03-23 | 汤大勇 |
| 本发明公开一种电子雷管起爆系统,包括无线终端和与无线终端连接的检测编程器以及受检测编程器控制的电子雷管网路,检测编程器包括第一微控制器模块以及与第一微控制器模块连接的电源管理模块、第一无线通讯模块、第一输入模块、非易失性存储模块和第一显示模块,无线终端包括第二微控制器模块以及与第二微控制器模块连接的第二输入模块、第二显示模块和第二无线通讯模块,第一无线通讯模块通过总线与电子雷管网路连接,第一无线通讯模块与第二无线通讯模块连接。本发明采用检测编程器和无线终端,在电子雷管网路连接的同时完成电子雷管身份信息ID的识别和连接序号的检测,提高了电子雷管使用的便利性。 | ||||||
| 7 | 地质破裂方法以及结果形成的破裂地质结构 | CN201380014104.1 | 2013-01-14 | CN104285123A | 2015-01-14 | J·L·马斯; C·R·布拉德利; D·W·斯蒂德曼; D·R·格瑞宁 |
| 在一个示例性方法中,通过沿着钻孔的节段定位多个间隔开的装料来实现沿着地下钻孔的节段使地下地质形成物破裂。这些装料可以包括多个间隔开的非理想高能量爆炸物装料和/或推进剂装料。惰性材料(诸如卤水或低密度液体爆炸物)的一个或多个容器也可以被包括在一串间隔开的装料中,诸如在这些装料中间。所述装料的引爆可以是同时的或独立定时的。所述装料理想地被配置成产生包括沿着所述钻孔的节段的碎石化区的独特地下破裂岩石结构,该碎石化区包括径向向外延伸(诸如,以盘状样式)一个距离的多个间隔开的区,该距离大于所述间隔开的区之间的碎石化区的径向向外延伸的距离。 | ||||||
| 8 | 爆破筒 | CN200580008579.5 | 2005-03-02 | CN1934408A | 2007-03-21 | 简-阿克·本特森 |
| 爆破筒包括:大致圆柱形的套管(2),具有密封其第一端的端壁(6);端部单元(3),其在套管第二端插入套管一定深度,具有面对套管内部的内侧(4)和处于端部单元相对侧的外侧(5);在套管中处于端壁和内侧之间的腔室(7),其填充有爆炸剂(8);在外口(11)和内口(12)之间延伸穿过端部单元的通道(10),包括用于起爆筒(11)的底座(13);以及容纳在该底座中的起爆筒,其容纳用于对腔室中的爆炸剂进行点火的引爆炸药。至少一个轴向突出的间隔构件(20)设置在爆破筒第一端的端壁(6)的外侧和/或爆破筒第二端的端部单元上,使得当使两个爆破筒进入钻孔(24)中以待引爆时,中间空间(28)形成于第一下爆破筒的外侧(5)和置于第一爆破筒上的第二上爆破筒的端壁的下侧之间,并且至少一个通路(21)设置在径向上、通过所述间隔构件、允许所述中间空间和钻孔中的环绕空间(27)之间连通。 | ||||||
| 9 | Surface blasting equipment | JP2013504027 | 2011-04-06 | JP2013525725A | 2013-06-20 | ウオレビ レッパネン ジャーモ |
| A surface blasting product which includes a container, a receptacle which contains adhesive which is displaceable to adhere the container to a rock, and an explosive charge, inside the container, which can be ignited to fragment or displace the rock. | ||||||
| 10 | Cobbing blasting method in same pit | JP11567383 | 1983-06-27 | JPS608700A | 1985-01-17 | SHIGEMITSU KEISUKE |
| 11 | Surface blasting equipment | JP2013504027 | 2011-04-06 | JP5480443B2 | 2014-04-23 | ウオレビ レッパネン ジャーモ |
| 12 | JPH0350199B2 - | JP11567383 | 1983-06-27 | JPH0350199B2 | 1991-07-31 | SHIGEMITSU KEISUKE |
| 13 | Use of post-blast markers in the mining of mineral deposits | EP14200719.4 | 2008-05-26 | EP2889572A3 | 2015-09-02 | Spathis, Alexander Theofile; Dare-Bryan, Peter Conran; Appleby, Rodney Wayne; Goodridge, Richard John |
A method of mining a mineral deposit, including: |
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| 14 | USE OF POST-BLAST MARKERS IN THE MINING OF MINERAL DEPOSITS | EP08756862.2 | 2008-05-26 | EP2153163B1 | 2015-03-18 | SPATHIS, Alexander Theofile; DARE-BRYAN, Peter Conran; APPLEBY, Rodney Wayne; GOODRIDGE, Richard John |
| 15 | SELECTIVE CONTROL OF WIRELESS INITIATION DEVICES AT A BLAST SITE | EP10735419.3 | 2010-01-11 | EP2391864A1 | 2011-12-07 | MCCANN, Michael John; STEWART, Ronald F. |
| Disclosed herein are methods for selective control of groups of wireless initiation devices such as wireless electronic boosters at a blast site. Such methods may be applied to a wide variety of blasting techniques that would benefit from the use of wireless control and initiation of explosive charges at the blast site. | ||||||
| 16 | ROCK-BLASTING CARTRIDGE AND BLASTING METHOD | EP07701852.1 | 2007-02-02 | EP2108103B1 | 2011-04-20 | MATTSON, Thomas |
| A blasting cartridge (10;20a;20b) comprising an elongated sleeve (12) extending along an axis (A) and having a first end (121) and a second end (122);the first end (121) has a first sleeve closure (121a) with an opening for holding a detonator (15); the second end (122) has a second sleeve closure (122b); a space (17) is provided between the first sleeve closure (121a) and the second sleeve closure (122b) for holding a blasting explosive (170); according to the invention the second end (122) is provided with a connector means (14) for releasably connecting the second end (122;222a)) of the cartridge (10;20a) with a first end (221b) of an adjacent cartridge (20b) and comprising a firing pin means (140) for impinging upon a detonator (25b) in the first end (221b) of the adjacent cartridge (20b) when the blasting explosive (170) is detonated by actuation of the detonator (15) in the first end (121) of the cartridge (10). | ||||||
| 17 | EXPLOSIVE CARTRIDGE | EP05711154.4 | 2005-03-02 | EP1725827A1 | 2006-11-29 | BENGTSSON, Jan-Åke |
| An explosive cartridge includes a substantially cylindrical sleeve (2) having an end wall (6) sealing a first end of the sleeve, an end unit (3) inserted in the sleeve to a certain depth in a second end of the sleeve, said end unit having an inner side (4) facing the interior of the sleeve and an outer side (5) on the opposite side of the end unit, a chamber (7) in the sleeve between said end wall and said inner side, said chamber being filled with a blasting agent (8), a channel (10) extending through the end unit between an outer mouth (11) and an inner mouth (12), said channel comprising a seat (13) for a priming cartridge (14), and a priming cartridge accommodated in the seat, said priming cartridge containing a detonating explosive for the firing of the blasting agent in said chamber. At least one spacing member (20), protruding in the axial direction, is provided on the outer side of the end wall (6) in the first end of the explosive cartridge and/or on the end unit in the second end of the explosive cartridge, such that an intermediate space (28) is formed between the outer side (5) of a first, lower explosive cartridge and the under side of the end wall of a second, upper explosive cartridge resting on the first explosive cartridge, when the two cartridges are entered in a drill hole (24) in order to be detonated, and at least one passage (21) is provided in the radial direction, passing said spacing member, allowing communication between said intermediate space and the surrounding space (27) in the drill hole. | ||||||
| 18 | A perforating gun having a plurality of charges | EP95302074.0 | 1995-03-28 | EP0675262A1 | 1995-10-04 | Parrot, Robert A.; Brooks, James E.; Aseltine, Clifford L.; Lerche, Nolan C.; Rozek, Kenneth E. |
A perforating apparatus adapted to be disposed in a wellbore includes a plurality of shaped charges, an electrical current carrying conductor, and a plurality of exploding foil or exploding bridgewire initiators disposed, respectively, between the the plurality of charges and the current carrying conductor for simultaneously detonating thereby simultaneously detonating all of the plurality of shaped charges of the perforating apparatus in response to a current flowing in the conductor. Each of the shaped charges include a new secondary explosive primer disposed in the apex of the charge for detonating in response to a detonation of the exploding foil or exploding bridgewire initiator. The electrical conductor may include a flat cable having a plurality of such initiators spaced apart at predetermined intervals along the cable and adapted to wrap helically around the perforating apparatus until each of the initiators abut against a shaped charge of the plurality of charges in the perforating apparatus. In an alternate embodiment, the electrical current carrying conductor may include a flat sheet having a specific length and width and including a plurality of such initiators. The flat sheet is adapted to wrap around the entire circumference of the perforating apparatus until each of the initiators in the sheet abut against a shaped charge of the plurality of charges in the perforating apparatus. The current in the conductor may originate from a compressed magnetic flux (CMF) current pulse generator or from a charging capacitor of a conventional system including one or more charging capacitors and associated discharge switches. When the perforating apparatus includes a first and second perforator separated by an adaptor, the adaptor includes a pressure bulkhead adapted to seal the first perforator from the second perforator, an explosive disposed in contact against one side of the bulkhead and a piezoelectric ceramic disposed in contact against the other side of the bulkhead. |
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| 19 | SELECTIVE CONTROL OF WIRELESS INITIATION DEVICES AT A BLAST SITE | EP10735419.3 | 2010-01-11 | EP2391864B1 | 2016-07-06 | MCCANN, Michael John; STEWART, Ronald F. |
| 20 | GEOLOGIC FRACTURING METHOD AND RESULTING FRACTURED GEOLOGIC STRUCTURE | EP13772317 | 2013-01-14 | EP2802840A4 | 2016-01-06 | MACE JONATHAN L; BRADLEY CHRISTOPHER R; STEEDMAN DAVID W; GREENING DORAN R |
| Detonation control modules and detonation control circuits are provided herein. A trigger input signal can cause a detonation control module to trigger a detonator. A detonation control module can include a timing circuit, a light-producing diode such as a laser diode, an optically triggered diode, and a high-voltage capacitor. The trigger input signal can activate the timing circuit. The timing circuit can control activation of the light-producing diode. Activation of the light-producing diode illuminates and activates the optically triggered diode. The optically triggered diode can be coupled between the high-voltage capacitor and the detonator. Activation of the optically triggered diode causes a power pulse to be released from the high-voltage capacitor that triggers the detonator. | ||||||
