According to a first aspect of the present invention, there is provided a method comprising drawing off fuel undesirably in gaseous form, and converting the fuel in gaseous form to a liquid form.
According to a second aspect of the present invention, there is provided apparatus which draws off fuel undesirably in gaseous form and converts the fuel in gaseous form to a liquid form.
Owing to these two aspects of the invention, the fuel [e.g. petrol, diesel oil, aviation fuel (such as jet Al fuel), or any other fuel that forms VOC (volatile organic compound) gas(es)] in gaseous form (i.e. in the form of a gas, of a vapour, or of a gas/vapour mixture) can be recovered in liquid form. If the method is performed at, for example, a liquid fuel filling site, the fuel recovered in liquid form at the site can be either used in liquid form at the site or transported in liquid form from the site.
According to a third aspect of the present invention, there is provided a method of converting an organic substance in gaseous form to a liquid form, comprising compressing the organic substance in gaseous form.
According to a fourth aspect of the present invention, there is provided an apparatus for converting an organic substance in gaseous form to a liquid form, comprising a compressor which serves to compress the substance in gaseous form.
Owing to these two aspects of the invention, the energy removal necessary to condense the organic substance in gaseous form can be performed at a higher temperature, e.g. at ambient temperature, reducing the amount of cooling which would otherwise be required.
According to a fifth aspect of the present invention, there is provided a method of compressing gaseous matter, comprising opening a plurality of inlets, operating a compressor to draw the gaseous matter through the inlets to an inlet duct of said compressor and to expel said gaseous matter through an outlet of said compressor, closing at least one of said inlets, and operating said compressor to draw the gaseous matter through the open inlet(s) to said inlet duct, to expel the gaseous matter through said outlet and to return at least part of that expelled gaseous matter to upstream of said compressor.
According to a sixth aspect of the present invention, there is provided apparatus for compressing gaseous matter, comprising a compressor, an inlet duct of said compressor, an outlet of said compressor, a plurality of individually closable inlets for the gaseous matter and leading to the inlet duct, a return duct by way of which said outlet communicates with said inlet duct, and a control device which controls communication between said outlet and said inlet duct via said return duct in dependence upon the number of said inlets which is open.
Owing to these two aspects of the invention, it is possible to avoid significantly higher negative pressures arising at (an) open inlet(s) during the times that the other inlet(s) is/are closed compared with the negative pressures at the inlets during the times that all of them are open.
According to a seventh aspect of the present invention, there is provided a method comprising sensing when a heavier fluid attains a predetermined height in a tank, removing at least part of said heavier fluid from said tank when said predetermined height is attained, sensing when a lighter fluid attains a predetermined height in said tank, and removing at least part of said lighter fluid from said tank when the latter predetermined height is attained.
According to an eighth aspect of the present invention, there is provided apparatus comprising a tank, a first sensor which serves to detect when a heavier fluid in said tank attains a predetermined height in said tank, a second sensor which serves to detect when a lighter fluid in said tank attains a predetermined height in said tank, a first device responsive to said first sensor and serving to cause removal of at least part of said heavier fluid from said tank when said heavier fluid attains the first-mentioned predetermined height, and a second device responsive to said second sensor and serving to cause removal of at least part of said lighter fluid from said tank when said lighter fluid attains the second-mentioned predetermined height.
Owing to these two aspects of the invention, it is possible to control the volumes of the heavier and lighter fluids present in the tank.
The heavier and lighter fluids will normally both be liquids and may have an even lighter fluid, which will normally be of gaseous form, above the lighter liquid, with that even lighter fluid being removed from the tank as desired. The fluids can be removed from the tank simply through the opening of valves, if subject to pressure in the tank.
In order that the invention may be clearly and completely disclosed, reference will now be made, by way of example, to the accompanying drawings, in which:—
Referring to
Referring to
In the heat exchanger 42 energy is released for the petrol and water vapours. A separate motor 44 operates a fan 46 for the heat exchanger 42. The fan 46 automatically stops when the ambient temperature drops to about 5° C.
Condensates and non-condensable gaseous matter, mainly air, flow into a multi-function tank 48 where the water W, denser than the petrol P, accumulates at the bottom, with the petrol P above it and the air A above that. If required, a heater cable 50 is provided to prevent water from freezing in the tank 48 at low temperatures.
A pressure controller 52 in a module 54 containing the multi-function tank 48 keeps the condenser pressure at a constant level.
A float switch 56 senses the levels of water and petrol in the tank 48 and operates solenoid valves 58, to drain off the water W and the petrol P under the action of the internal pressure in the tank 48. The petrol is drained off via a mud- and water-blocking filter 60 through the relevant solenoid valve 58 into the line 28.
Via a high pressure regulator 62 of the controller 52, air and minor amounts of petrol vapour and water vapour pass through to a receiver (an un-illustrated intermediate chamber) and are discharged through a combined bleeder nozzle/flame arrestor 64 to the ambient atmosphere. The water W is discharged to a drain 65.
The system described with reference to
There would be an insignificant amount of petrol vapour mixed with the air from the bleeder nozzle/flame arrestor 64. This amount could be about 2% to 3% of the total circulation capacity of the system, but the rate of recovered petrol vapour still exceeds all known requirements for petrol vapour recovery at petrol stations.
Referring to
Referring to
Petrol vapour and air enter the leak detector through the inlet connector 90 and leave through the outlet connector 92. The float switch 96 floats up and sends an electronic signal whenever a volume above, say, 25-30 ml. accumulates in the container 94. The signal is sent to the device 100 which then illuminates the lamp 102 and actuates the relay 104 to cut off the electrical supply to the compressor 34.
The unit shown in
The unit is usable with any vapour-recovery-equipped filling nozzle and any flexible hose having a vapour return line. It co-operates with one filling nozzle, or with two or more filling nozzles simultaneously, by means of mechanical, step-less adjustment.
The unit is installed alongside the fuel pump, bolted onto the ground. It is connected to the pump through an inlet connection pipe or hose that delivers the mixture of vapour and air into the unit. Furthermore, another connection through a pipe or hose ensures the return of liquid fuel into the suction side of the fuel pumping device of the fuel pump, the pressure side of that device, or return piping for VOC gas(es) if such piping is already present.
If feasible, the unit takes its operating power from the electricity supply of the fuel pump.
The unit is switched on and off with the start and stop signals of the pump, and operates whenever one or more filling nozzles on the pump are in operation. When no nozzles are in operation, the unit is automatically turned off.
The basic function of the unit is to transform fuel vapour into liquid fuel while separating the air (and water) and bleeding off the air. Basically, what takes place during the operation of the unit is that:—
The present system is applicable not only to fuel vapour recovery at fuel stations, but also to various other possibilities of recovery of substances, particularly organic substances, in gaseous form. For example, it could be employed for storage tanks or other vessels containing liquid that forms VOC gas(es).
Number | Date | Country | Kind |
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0202121.0 | Jan 2002 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB03/00405 | 1/30/2003 | WO | 6/16/2005 |