The present invention relates to a mobile delivery platform for flowable explosive.
Flowable explosive, such as emulsion explosive, is conventionally delivered in surface and underground applications using gravity tanks. Gravity tanks have a high centre of gravity and are not easily transportable. They also require a top access structure for cleaning and maintenance of the inside walls to prevent crystallization of the emulsion explosive. The top access structure limits tank capacity and is a fall hazard for workers.
A need therefore exists for a mobile, self-cleaning delivery platform for flowable explosive.
According to the present invention, there is provided apparatus for storing and dispensing flowable explosive, the apparatus including an explosive pump for pumping flowable explosive into an explosive tank having a fluid pressure-actuated piston movable therein for expelling flowable explosive out of the explosive tank through a delivery hose fitted with an injector through which one or more additives from one or more additive tanks can be pumped by an additive pump.
The explosive tank and the piston therein can be cylindrical with a common horizontal longitudinal axis.
The piston can have one or more circumferential seals for cleaningly wiping the inner surface of the explosive tank.
The piston can be a concave piston that is radially expandable to sealingly engage the inner surface of the explosive tank.
The explosive tank can have a detector therein for detecting displacement of the piston and/or monitoring quantities of flowable explosive in the explosive tank.
The one or more additives can be lubricant stored in a lubricant tank, and explosive additive stored in an explosive additive tank.
The delivery hose can be wound on a hose reel.
The tanks, pumps, and hose reel can be arranged on a transportable platform.
The flowable explosive can be selected from emulsion explosive, gel explosive, slurry explosive, blended explosive, and doped explosive.
The present invention also provides a method delivering flowable explosive using the above apparatus.
The invention will be further described by way of example only with reference to the accompanying drawings, in which:
Referring, to the
The explosive tank 1 is cylindrical and is made, for example, of a corrosion resistant or a suitable pressure vessel material. The explosive tank 1 has a capacity, for example, of 3 tonne. A cylindrical piston 6 is axially movable inside the explosive tank 1. The explosive tank 1 and piston 6 have a common longitudinal axis horizontal to the transportable platform 24. The piston 6 is a concave piston that is radially expandable when pressurised to sealingly engage the inner surface of the explosive tank 6. Two circumferential seals 7 are provided on the piston 6. The piston seals 7 cleaningly, wipe the inner surface of the explosive tank 1 during axial movement therein of the piston 6. Together, the piston 6 and the piston seals 7 provide a “self-cleaning” action that prevents build-up of towable explosive on the inner surface of the explosive tank 1. Other equivalent “self-cleaning” piston and seal arrangements may also be used. The piston 6 is made of, for example, corrosion resistant material. The piston seals 7 and the delivery hose 23 are made of, for example, rubber. Together, the piston 6 and piston seals 7 sealingly divide the explosive tank 1 into opposed pressure and explosive ends.
The pressure end of the explosive tank 1 is provided with an inlet manifold 5, a pressure relief valve 2, and a piston displacement sensor 4. The pressure inlet manifold 5 includes a pressure regulator and a pressure gauge. The piston displacement sensor 4 is, for example, a laser detector.
The explosive end of the explosive tank 1 is provided with a pressure relief valve 3 and a selector valve 8 to control flow of flowable explosive to and from an inlet outlet port in the explosive tank 1. The flowable explosive is, for example, emulsion explosive, gel explosive, slurry explosive, blended explosive, doped explosive, etc. The flowable explosive has a viscosity of between around 20,000 and 90,000 centipoise (cP), for example, 40,000 cP.
Flowable explosive is drawn from an external supply (not shown) via selector valves 9, 18 by the explosive pump 10 and pumped via selector valves 11, 8 into the explosive end of the explosive tank 1. This displaces the piston 6 backwardly toward the pressure end of the explosive tank 1. The backward displacement of the piston 6 is monitored by the piston displacement sensor 4. The pressure relief valve 2 acts as a bleed valve to maintain backpressure against the piston 6 so that it is positively retained next to flowable explosive pumped into the explosive tank 1. A flow meter 12 is connected to the explosive pump 10 to indicate the flow rate of flowable explosive pumped into the explosive tank 1. The explosive pump 10 is for example, a high pressure diaphragm pump.
Flowable explosive is discharged from the explosive tank 1 via the selector valves 8, 11 to the delivery hose 23 by applying fluid pressure to the piston 6 via the pressure inlet manifold 5. The fluid pressure is, for example, air pressure from a source of compressed air, for example, a truck compressed air system. The air pressure displaces the piston 6 forwardly toward the explosive end of the explosive tank 1. The forward displacement of the piston 6 is monitored by the piston displacement sensor 4, the discharge pressure of flowable explosive is indicated by a pressure meter 13. The delivery hose 23 is unwound from the hose reel 22 and positioned to deliver the flowable explosive from the explosive tank 1 to a surface or underground delivery site, for example, a blast hole. The delivery rate of the flowable explosive is, for example, up to around 1100 litres per minute. The flowable explosive is substantially fully discharged from the explosive tank 1 by the piston 6 as the “self-cleaning” action of the piston 6 and the piston seals 7 leaves less than around 0.05% by weight of the initial load of flowable explosive remaining in front of the piston 6.
The pressure required to discharge flowable explosive is selectively reduced by injecting flowable lubricant stored in the lubricant tank 16 into the delivery hose 23. The lubricant is, for example, water, oil, polymeric lubricant, etc. The flowable lubricant is pumped from the lubricant tank 16 via selector valve 17 by the additive pump 14 to an injector 19 fitted to the delivery hose 23. The pressure and flow rate of lubricant injected into the delivery hose 23 are respectively indicated by a flow meter 20 and a pressure meter 21. The additive pump 14 is, for example, a piston pump. The lubricant tank 16 is filled with flowable lubricant via a filler or from an external source (not shown) via the selector valves 9, 18. Lubricant, such as water, is selectively pumped by the additive pump 14 from the lubricant tank 16 through the explosive pump 10 for cleaning the explosive pump 10, injector 19 and delivery nose 23 after flowable explosive has been discharged from the explosive tank 1. A check valve between the lubricant tank 16 and the selector valve 18 prevents backup of water into the lubricant tank 16 during cleaning.
Explosive additive stored in the explosive additive tank 15 is selectively injectable into the delivery hose 23 by the additive pump 14 via the selector valve 17. The explosive additive is, for example, gassing solution. The explosive additive tank 15 is filled with explosive additive via a filler. The flow and pressure meters 20, 21 measure the flow and pressure of explosive additive injected into the delivery hose 23.
Referring to
The mobile delivery platform 26 can form part of a mobile manufacturing unit (MMU), an underground delivery system, or a plant storage unit.
It will be appreciated that embodiments of the invention advantageously provide a mobile, self-cleaning delivery platform for flowable explosive.
The embodiments have been described by way of example only and modifications are possible within the scope of the claims which follow.
Number | Date | Country | |
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61022902 | Jan 2008 | US |
Number | Date | Country | |
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Parent | 12864066 | Aug 2010 | US |
Child | 13607060 | US |