Embodiments of the present invention generally relate to well perforation in oil and gas recovery. Specifically, embodiments of a downhole ignition assembly are described.
Hydraulic fracturing is a practice among geologic resource producers in which a geologic formation underground is subjected to a hydraulic shock to loosen tight formations and ease production of resources from the formation. Commonly, the resource is hydrocarbon liquids and/or gases.
A perforation tool, sometimes called a perforating gun, is used to prepare the formation for fracturing. The wall of the drilled well is perforated by activation of explosive charges. A jet of material creates an opening in the wall of the well that is a few inches to a few feet long, depending on the explosive discharge and the local structure and composition of the formation. Hydraulic fluid can then be provided to the opening and used to deliver the hydraulic shock.
Perforation is one example of a downhole tool that uses explosive charges. All such tools need ignition. An electrically activated ignition assembly is typically used to activate explosive tools downhole. A wireline delivers electrical energy to a combustible element, thus activating a ballistic discharge that, in turn, sets off the explosives in the tools. An ignition assembly is commonly used once, and then pulled out of the well and reassembled for another use. Speed and ease of reassembly is of paramount interest to avoid the need for numerous spare assemblies and time and effort to reassemble used assemblies. There is a need for improved downhole ignition assemblies that are reliable and easy to reassemble after use.
Embodiments described herein provide a downhole ignition assembly, comprising a switch container having a longitudinal axis, the switch container having a first portion that accommodates a switch circuit in an orientation transverse to the longitudinal axis, and a second portion that contacts an igniter disposed in the second portion, the first portion having a contact that makes electrical contact with a tool coupled to the downhole ignition assembly.
Other embodiments described herein provide a downhole ignition assembly, comprising an ignition module coupled to a feedthrough module, the ignition module comprising an ignition housing with an igniter and a switch assembly disposed in the ignition housing, the switch assembly comprising a switch container housing a switch circuit, the switch container in electrical contact with the igniter and the feedthrough module; an igniter contact in electrical contact with the switch circuit and the igniter; and a feedthrough contact electrically connected between the switch circuit and a feedthrough member of the feedthrough module.
Other embodiments described herein provide an ignition module for a downhole ignition assembly, the ignition module comprising an ignition housing having a receptacle and a central passage extending from a floor of the receptacle; and a switch assembly disposed in the receptacle and extending along the central passage for energizing an igniter, the switch assembly having a ground path that bypasses the ignition housing.
So that the manner in which the above recited features of the present disclosure can be understood in detail, a more particular description of the disclosure, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only exemplary embodiments and are therefore not to be considered limiting of its scope, may admit to other equally effective embodiments.
To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. It is contemplated that elements and features of one embodiment may be beneficially incorporated in other embodiments without further recitation.
The switch 110 includes a circuit plate 114 that carries the electrical circuitry that makes up the switch. The circuit plate 114 generally rests within the first portion 109 in an orientation transverse to the longitudinal axis 120. An igniter contact 116 extends from a first side of the circuit plate 114 and a feedthrough contact 118 extends from a second side of the circuit plate 114 opposite from the first side. The feedthrough contact 118 generally connects the circuit plate 114 to a power source. In this case, the feedthrough contact 118 connects to a feedthrough member 122 of the feedthrough module 124 that carries electrical impulses and/or signals to other electrical switching and/or signaling apparatus. The feedthrough member 122 is surrounded by an insulator 123, and both are contained within a feedthrough housing 125, defining the main members of the feedthrough module 124. Here, the feedthrough module 124 is shown as a purely electrical feedthrough member separate from the ignition module 101, but the feedthrough module 124 can be part of a discharge tool, such as a perforating gun tool. The feedthrough module 124 nests with the switch assembly 104 and the ignition housing 102, and may nest with other tools.
An optional backing plate 115 may be included to enclose the circuit plate 114 in the first portion 109 of the switch container 108. The backing plate 115 in
To assemble the downhole ignition assembly 100, the igniter contact 116 is coupled to the switch container 108, and the igniter 106 is attached to the igniter contact 116 form a sub-assembly. In one embodiment, the igniter contact 116 is a threaded member and the igniter 106 is screwed onto the igniter contact 116. The sub-assembly is disposed in the switch container 108, and the feedthrough contact 118, and a feedthrough plug 230 (
The first portion 109 has a diameter larger than a diameter of the second portion 112. The ignition housing 102 has a receptacle 210 that accommodates the first portion 109 of the switch container 108. The central passage 202 of the ignition housing 102 extends from a central area of the receptacle 210, so that the switch container 108 fits within the receptacle 210. Here, the receptacle 210 is fashioned with a diameter that matches an outer diameter of the first portion 109, such that the first portion 109 nests within the receptacle 210. A floor portion 212 of the first portion 109 generally contacts a floor portion 214 of the receptacle 210, while the second portion 112 of the switch container 108 extends into the central passage 202.
The igniter 106 is fashioned with a contact flange 218, which may be an integral part of the igniter 106 or a separate member. The contact flange 218 can also be a ridge that extends radially outward from a core of the igniter 106. In this case, the contact flange 218 has frustoconical shape with diameter that increases in a direction away from the igniter contact 116. A wide end 222 of the contact flange 218 is disposed against a lip 224 at an end 226 of the second portion 112 opposite from the first portion 109. A narrow end 228 of the contact flange 218, opposite from the wide end 226, contacts the core of the igniter 106. The lip 224 may be omitted, if desired, and the contact flange 218 can just contact the inner wall of the second portion 112 without the lip 224.
The feedthrough contact 118 is a generally cylindrical member. A first end 234 of the feedthrough contact 118 contacts the circuit plate 114. The feedthrough plug 230 is nested with a second end 236 of the feedthrough contact 118, opposite from the first end 234. The feedthrough plug 230 is a conductive member with a frustoconical shape that accommodates a contact end 232 of the feedthrough member 122. The feedthrough plug 230 has a first end 238 with a diameter greater than a largest diameter of the contact end 232 to accommodate accurate and easy connection of the contact end 232 with the feedthrough plug 230. The feedthrough plug 230 has a flange 240 at the first end 238 to maintain reliable contact with the second end 236 of the feedthrough contact 118. The diameter of the feedthrough plug 230 declines from first end 238 to a second end 242 of the feedthrough plug 230 to provide reliable electrical contact with the contact end 232 of the feedthrough member 122. The optional backing plate 115 is shown installed just inside the first portion 109 of the switch container 108. The backing plate 115 may be held in place by friction with the wall of the first portion 109.
The contact flange 218 contacts the igniter 106 and the switch container 108. In this case, the contact flange 218 and the switch container 108 are electrically conductive. The switch container 108 has a flange 244, at an edge of the first portion 109 thereof, which contacts the feedthrough housing 125 when assembled. Referring again to
Referring again to
The flange 244 extends a short distance radially outward from the first portion 109 of the switch container 108 but does not contact the ignition housing 102. The flange 244 is also shown in
A contact cap 330 may be disposed at the second end 336 of the elastic member 342 to provide enhanced electrical contact with the elastic member 342. The contact cap 330 is electrically conductive and has a frustoconical shape, with a flange, to nest within the generally circular second end 336 of the elastic member 342. The flange supports the contact cap 330 at the second end 336 of the elastic member 342. The contact cap 330 makes electrical contact with the feedthrough member 122 when the feedthrough module 124 and the ignition module 101 are assembled. As the feedthrough module 124 is moved into attachment position with the ignition housing 102, the feedthrough member 122 depresses the contact cap 330 and compresses the elastic member 342. The reaction force of the compressed elastic member 342 maintains secure electrical contact of the elastic member 342, contact cap 330, feedthrough member 122 and circuit plate 114.
The elastic member 342 may be a spring of any convenient type. A coil spring or leaf spring member can be used. The leaf spring member has laterally flexing members to provide elasticity as the elastic member 342 changes in length. In alternate embodiments, the elastic member 342 may be electrically coupled to the circuit plate 114, and the igniter contact 116, by a conductive contact disposed in the circuit plate between the elastic member 342 and the igniter contact 116.
The contact cap 330 and second end 336 can be shaped in any beneficial way to enhance contact. The contact cap 330 could have a cylindrical extension portion topped by a flange, for instance. In another example, the contact cap 330 could be longer than that shown in
The support extension 318 of the backing plate 315 may have a ledge 320 at a free end thereof that restrains movement of the contact cap 330. When a switch assembly featuring the contact cap 330 and support extension 318 is assembled, the contact cap 330 is positioned in the end of the elastic member 342 and the backing plate 315 is installed with the support extension 318 surrounding the elastic member 342. The ledge 320 contacts the contact cap 330 around an edge thereof, depresses the contact cap 330, and compresses the elastic member 342 such that the contact cap 330 rests against the ledge 320. When the feedthrough module 124 is then assembled to the ignition module 101, with the switch assembly 104 installed, the contact end 232 of the feedthrough member 122 is urged against the contact cap 330 into the support extension 318 of the backing plate 315, depressing the contact cap 330 and compressing the elastic member 342 further, such that a space develops between the contact cap 330 and the ledge 320, as shown in
In all the embodiments shown herein, grounding of the igniter 106, and the circuit that energizes the igniter 106, is provided through the second portion 112 of the switch container 108, and through the flange 244 to the feedthrough housing 125. The structures herein simplify field operations by allowing quick reassembly and reuse of the ignition module 101 without the need for substantial cleaning when the assembly is surfaced, since grounding of the ignition circuit does not depend on connectivity with the housing of the ignition assembly.
While the foregoing is directed to embodiments of the present invention, other and further embodiments of the present disclosure may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
This application claims the benefit of U.S. Provisional Application No. 63/011,046, entitled “DOWNHOLE IGNITION ASSEMBLY,” filed Apr. 16, 2020, the disclosure of which is hereby incorporated herein by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/US2021/027452 | 4/15/2021 | WO |
Number | Date | Country | |
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63011046 | Apr 2020 | US |