子分类:
- F42B3/103: ..起爆器中装起爆头的;密封塞
- F42B3/11: ..以使用的材料为特征的,例如用于起爆器壳或电导线的(F42B3/107优先)
- F42B3/113: ..用光学,例如激光、闪光手段激发的
- F42B3/117: ..用摩擦激发的
- F42B3/12: ..桥式起爆器{(F42B3/103, F42B3/11, F42B3/195 优先;推进物装药的电点火入 F42C19/12)}
- F42B3/14: ..火花起爆器{F42B3/195 优先}
- F42B3/16: ..{烟火的}延时起爆器(F42B3/195 优先;可编程电子延时起爆器入 F42C11/065)
- F42B3/18: ..能防止因静电或干扰电流而过早点火的安全起爆装置
- F42B3/192: ..为与水接触时平衡而设计的
- F42B3/195: ..制造
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 181 | System and method for safely conducting explosive operations in a formation | US13981530 | 2012-09-13 | US09593548B2 | 2017-03-14 | Jim T. Hill; Clinton C. Quattlebaum; John D. Burleson; Tony F. Grattan |
| Method and system that permits explosive operations to be conducted concurrently with drilling and other wellsite operations involving an electrical top drive mechanism or other components that utilize electricity are disclosed. A platform is placed at a location where subterranean operations are to be performed. A first well bore is drilled in a formation using drilling equipment on the platform by activating a top drive. Concurrently with drilling the first well bore, a perforating operation is performed in a second well bore extending from the platform. The perforating operation is performed using a perforating gun that comprises at least one of an electric isolator and an explosive isolator. The perforating gun is activated when the perforating gun reaches a safe depth. | ||||||
| 182 | Explosive matrix assembly | US14936363 | 2015-11-09 | US09506733B2 | 2016-11-29 | Jon K. Mitchell |
| The present disclosure is an explosive matrix assembly that has a first single detonating cord formed into a first grid. The grid has a first plurality of detonating cord portions lying in a first plane and a second plurality of detonating cord portions lying in a second plane and the first plurality of detonating cord portions perpendicularly overlay the second plurality of detonating portions. The explosive matrix assembly further has a second single detonating cord formed into a second grid. The second grid has a third plurality of detonating cord portions lying in the first plane and a fourth plurality of detonating cord portions lying in the second plane and the third plurality of detonating cord portions perpendicularly overlay the second plurality of detonating portions. The first grid is coupled to the second grid via a fastener. | ||||||
| 183 | Layered energetic material having multiple ignition points | US14213750 | 2014-03-14 | US09464874B1 | 2016-10-11 | Timothy Mohler; Jonathan Mohler; Kevin R. Coffey |
| An energetic material having thin, alternating layers of metal oxide and reducing metal is provided. The energetic material may be provided in the form of a sheet, foil, cylinder, or other convenient structure. A method of making the energetic material resists the formation of oxide on the surface of the reducing metal, allowing the use of multiple thin layers of metal oxide and reducing metal for maximum contact between the reactants, without significant lost volume due to oxide formation. An ignition system for the energetic material includes multiple ignition points, as well as a means for controlling the timing and sequence of activation of the individual ignition points. The combination of the energetic material and ignition system provides a means of charge and blast shaping, ignition timing, pressure curve control and maximization, and safe neutralization of the energetic material. | ||||||
| 184 | BASE CHARGE EXPLOSIVE SYSTEM APPLICATION | US14916868 | 2014-08-28 | US20160216094A1 | 2016-07-28 | Hendrik Cornelius Bezuidenhout; Pieter Stephanus Jacobus Halliday |
| A detonator which includes a tubular housing with a bore in which is formed a compartment that houses a first frangible container with a first quantity of a first material inside the first container, a second frangible container with a second quantity of a second material inside the second container, and an actuating mechanism which is operable to break the first container and the second container thereby to allow the first material to contact the second material and form an explosive composition inside the compartment. | ||||||
| 185 | Detonation command and control | US14878969 | 2015-10-08 | US09354029B2 | 2016-05-31 | Jonathan L. Mace; Gerald J. Seitz; John A. Echave; Pierre-Yves Le Bas |
| The detonation of one or more explosive charges and propellant charges by a detonator in response to a fire control signal from a command and control system comprised of a command center and instrumentation center with a communications link therebetween. The fire control signal is selectively provided to the detonator from the instrumentation center if plural detonation control switches at the command center are in a fire authorization status, and instruments, and one or more interlocks, if included, are in a ready for firing status. The instrumentation and command centers are desirably mobile, such as being respective vehicles. | ||||||
| 186 | METHOD OF UNDERGROUND ROCK BLASTING | US14757560 | 2015-12-24 | US20160146588A1 | 2016-05-26 | Stuart Patrick THOMSON; Sean Michael FREEMAN |
| A method of blasting rock at an underground blast site in which boreholes (11a, b, c) are drilled in a rock mass 10 from a drive defining face 12, each borehole is loaded with at least one charge of explosive material (13a-c, 14a-c, 15a-c), at least one detonator is placed in operative association with each charge, and a sequence of at least two initiation events is conducted to blast the rock mass, in each of which only some of the charges are initiated, by sending firing signals to only the detonators associated with said charges and in which each initiation event is a discrete user-controlled initiation event. In one of the at least two initiation events a stranded portion of the rock mass such as a pillar is created that has already been drilled and charged, and the stranded portion of the rock mass is blasted in a subsequent one or more of the at least two initiation events without personnel accessing said stranded portion. First explosive charges (13a, b, c and 15a, b, c) may be blasted in the one initiation event, leaving a pillar of stranded ore with the preloaded borehole 11b extending through it. The detonators may be wireless. | ||||||
| 187 | Non-energetics based detonator | US14151926 | 2014-01-10 | US09347755B2 | 2016-05-24 | Roger F. Backhus; Richard W. Givens; Jerome A. Klein; Ronald L. Loeser; Jason E. Paugh; Walter G. VanCleave, III; Isaac Thomas Zimmer |
| A detonator system is provided for use with explosives that utilizes two subsystems. A first subsystem functions as a non-explosives based detonator, which does not contain any explosives. The second subsystem is an initiating subsystem, which includes an initiating pellet. To set off an explosive event, the non-energetics based detonator is coupled to the initiating subsystem and the non-energetics based detonator is commanded to provide a suitable signal to the initiating subsystem that is sufficient to function the initiating pellet. Further, the initiating subsystem can be integrated directly into an associated explosive such as a booster that has been configured to receive the initiator subsystem without changing the hazard class of the booster. | ||||||
| 188 | Explosive Matrix Assembly | US14938225 | 2015-11-11 | US20160116266A1 | 2016-04-28 | Jon K. Mitchell |
| The present disclosure is an explosive matrix assembly that has a first single detonating cord formed into a first grid, and the first grid has a first plurality of detonating cord portions lying in a first plane and a second plurality of detonating cord portions lying in a second plane and the first plurality of detonating cord portions perpendicularly overlay the second plurality of detonating portions. Additionally, the matrix assembly has a second single detonating cord formed into a second grid, and the second grid has a third plurality of detonating cord portions lying in a third plane and a fourth plurality of detonating cord portions lying in a fourth plane and the third plurality of detonating cord portions perpendicularly overlay the fourth plurality of detonating portions. Further, the matrix assembly has a third single detonating cord formed into a third grid, and the third grid has a fifth plurality of detonating cord portions lying in a fifth plane and a sixth plurality of detonating cord portions lying in a sixth plane and the fifth plurality of detonating cord portions perpendicularly overlay the sixth plurality of detonating portions. The matrix assembly also has a first fastener coupling the first grid perpendicular to the second grid, a second fastener coupling the first grid perpendicular to the third grid, and a third fastener coupling the second grid perpendicular to the third grid thereby forming a partial cube. | ||||||
| 189 | Explosive Matrix Assembly | US14936363 | 2015-11-09 | US20160116265A1 | 2016-04-28 | Jon K. Mitchell |
| The present disclosure is an explosive matrix assembly that has a first single detonating cord formed into a first grid. The grid has a first plurality of detonating cord portions lying in a first plane and a second plurality of detonating cord portions lying in a second plane and the first plurality of detonating cord portions perpendicularly overlay the second plurality of detonating portions. The explosive matrix assembly further has a second single detonating cord formed into a second grid. The second grid has a third plurality of detonating cord portions lying in the first plane and a fourth plurality of detonating cord portions lying in the second plane and the third plurality of detonating cord portions perpendicularly overlay the second plurality of detonating portions. The first grid is coupled to the second grid via a fastener. | ||||||
| 190 | Explosive Matrix Assembly | US14936248 | 2015-11-09 | US20160116264A1 | 2016-04-28 | Jon K. Mitchell |
| The present disclosure is an explosive matrix assembly that has a single detonating cord formed into a grid. The grid has a first plurality of detonating cord portions lying in a first plane and a second plurality of detonating cord portions lying in a second plane, and the first plurality of detonating cord portions perpendicularly overlay the second plurality of detonating portions. Additionally, the explosive matrix comprises a sheet of adhesive material coupled to the grid to retain a grid shape of the detonating cord. | ||||||
| 191 | INITIATOR MODULES, MUNITIONS SYSTEMS INCLUDING INITIATOR MODULES, AND RELATED METHODS | US13854632 | 2013-04-01 | US20160097623A1 | 2016-04-07 | James D. Lucas; Denny L. Kurschner; Thomas E. MacPherson |
| Initiator modules for munitions control systems include a mounting portion for receiving a portion of an initiation device, a detonator device disposed within the initiator module, a connection portion configured to connect the initiator module with a munitions control system, and an electronics assembly configured to electronically couple with a munitions control system and transmit a signal to the detonator device. Munitions systems may include initiator modules received in a socket of a munitions control system. Methods of igniting explosive devices include coupling a shock tube to an explosive device, connecting an initiator module to a munitions control system, mounting a portion of the shock tube to the initiator module, and igniting the shock tube with a detonator device disposed within the initiator module. | ||||||
| 192 | Explosive Matrix Assembly | US13786682 | 2013-03-06 | US20160097622A1 | 2016-04-07 | Jon K. Mitchell |
| An explosive matrix includes a grid structure formed from a single length of detonating cord with one set of spaced-apart detonating cord sections lying in one plane that perpendicularly overlays a second set of spaced-apart sections lying in a second plane such that at each section crossing location the crossing consists of no more than two perpendicular sections of detonating cord. | ||||||
| 193 | NON-ENERGETICS BASED DETONATOR | US14151926 | 2014-01-10 | US20150260496A1 | 2015-09-17 | Roger F. Backhus; Richard W. Givens; Jerome A. Klein; Ronald L. Loeser; Jason E. Paugh; Walter G. VanCleave III; Isaac Thomas Zimmer |
| A detonator system is provided for use with explosives that utilizes two subsystems. A first subsystem functions as a non-explosives based detonator, which does not contain any explosives. The second subsystem is an initiating subsystem, which includes an initiating pellet. To set off an explosive event, the non-energetics based detonator is coupled to the initiating subsystem and the non-energetics based detonator is commanded to provide a suitable signal to the initiating subsystem that is sufficient to function the initiating pellet. Further, the initiating subsystem can be integrated directly into an associated explosive such as a booster that has been configured to receive the initiator subsystem without changing the hazard class of the booster. | ||||||
| 194 | Piezoelectric pebble explosive | US14572121 | 2014-12-16 | US09103635B1 | 2015-08-11 | S. Mill Calvert |
| An explosive device includes a hollow container having an inner volume holding an explosive. A piezoelectric ceramic connected to the container also has an electrical connection to the explosive. A deformation of the container applies mechanical stress to the piezoelectric ceramic which produces a potential difference or an electric current discharged using the electrical connection. The discharge detonates the explosive. The piezoelectric ceramic may be inside the container or on an outer surface and may be later inserted into the container to arm the explosive device. The container may have an outer surface that is an electrical insulator to prevent accidental electrostatic detonation. The explosive is optionally a plastic explosive. The electrical connection to the explosive optionally includes electrical conductors spaced apart to form a gap that is dimensioned to enable a spark to cross the gap when the piezoelectric ceramic deforms a pre-designated amount. | ||||||
| 195 | Explosive Matrix Assembly Tool | US13798887 | 2013-03-13 | US20150192398A1 | 2015-07-09 | Jon K. Mitchell |
| An explosive matrix includes a grid structure formed from a single length of detonating cord with one set of spaced-apart detonating cord sections lying in one plane that perpendicularly overlays a second set of spaced-apart sections lying in a second plane such that at each section crossing location the crossing consists of no more than two perpendicular sections of detonating cord. A tool for forming the matrix includes a frame comprising four side members, each having identical castellated edges in which are defined a plurality of notches for receiving a section of detonating cord. | ||||||
| 196 | Surface blasting product | US13639556 | 2011-04-06 | US09010246B2 | 2015-04-21 | Jarmo Uolevi Leppanen |
| 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. | ||||||
| 197 | Explosive device booster assembly and method of use | US13879316 | 2012-05-03 | US08985023B2 | 2015-03-24 | Justin Lee Mason |
| An apparatus for perforating a wellbore comprises a housing, at least one perforating charge disposed within the housing, a detonation cord coupled to the at least one perforating charge, and a booster coupled to an end of the detonation cord. The booster comprises a booster body having a first end and a second end, a cavity defined within the booster body between the first end and the second end, an explosive material disposed within the cavity adjacent the first end, and a locking feature disposed adjacent the second end, where the locking feature is configured to allow the booster to engage the end of the detonation cord in a first direction and resist movement in a second direction. | ||||||
| 198 | ELECTRONIC DETONATOR | US14381970 | 2013-01-09 | US20150013560A1 | 2015-01-15 | Craig Charles Schlenter; Herman Van Der Walt |
| An electronic detonator (10) which includes a housing (12) which contains an explosive charge (18), an initiating element (20), a control circuit (24), at least one coil (32) having a plurality of windings (30) in a tubular configuration, and a magnet (40) wherein passage of the magnet (40) through the coil (32) creates voltage to which the control circuit (24) is responsive, and a connector (46) for connecting a shock tube (48) to the housing (12). | ||||||
| 199 | Security detonator | US13557889 | 2012-07-25 | US08915188B2 | 2014-12-23 | Hervé Le Breton; Nathalie Raffin-Barril; Didier Cazajous |
| A detonator includes a flying plate propelled by a squib stage including at least one first pyrotechnic composition and/or one first explosive, the plate being propelled onto a relay stage including at least one secondary explosive, wherein the detonator is provided with thermal insulation surrounding the squib stage for delaying the temperature rise thereof. | ||||||
| 200 | DETONATION COMMAND AND CONTROL | US14370209 | 2013-01-14 | US20140338552A1 | 2014-11-20 | Jonathan L. Mace; Gerald J. Seitz; John A. Echave; Pierre-Yves Le Bas |
| The detonation of one or more explosive charges and propellant charges by a detonator in response to a fire control signal from a command and control system comprised of a command center and instrumentation center with a communications link therebetween. The fire control signal is selectively provided to the detonator from the instrumentation center if plural detonation control switches at the command center are in a fire authorization status, and instruments, and one or more interlocks, if included, are in a ready for firing status. The instrumentation and command centers are desirably mobile, such as being respective vehicles. | ||||||
QQ群二维码
意见反馈
意见反馈