In order that the invention may be readily understood, embodiments of the invention are illustrated by way of example in the accompanying drawings.
Further details of the invention and its advantages will be apparent from the detailed description included below.
In the following description of various embodiments of the invention, references to the accompanying drawings are by way of illustration of an example by which the invention may be practiced. It will be understood that other embodiments may be made without departing from the scope of the invention disclosed.
Now referring to
The filtration system 6 comprises an inlet port 8, a chamber 16 and an outlet port 10.
The chamber 16 comprises means for creating a turbulent flow and trapping means located downstream of the means for creating a turbulent flow.
More precisely, the chamber 16 comprises a first baffle for creating a turbulent flow 18, a second baffle for creating a turbulent flow 20, and a third baffle for creating a turbulent flow 22. The chamber 16 further comprises a first trapping means 24, a second trapping means 26 and a third trapping means 28.
The inlet port 8 receives a fluid comprising particles and is in fluid communication with the chamber 16.
The outlet port 10 discharges a filtered fluid originating from the chamber 16 and is in fluid communication with the chamber 16. Each of the first baffle for creating a turbulent flow 18, the second baffle for creating a turbulent flow 20 and the third baffle for creating a turbulent flow 22 creates a corresponding turbulent flow in the incoming fluid.
Some particles, because of their respective inertia created by their corresponding weight, cannot navigate as rapidly as the fluid and are regrouped into at least one region located downstream of the corresponding baffle for creating a turbulent flow.
By positioning the trapping means adequately, it is therefore possible to collect the particles.
Now referring back to
In the embodiment disclosed in
It will be therefore appreciated by the skilled addressee that in this embodiment there is disclosed a three-stage filtration system. It should be clearly understood, however, that the filtration system may have any number of stages depending on a particular application.
Moreover, in the embodiment disclosed in
It will be further appreciated that in the embodiment disclosed in
The priming port 14 comprises an inlet 30 and a pressure relief valve 32. Both the inlet 30 and the pressure relief valve 32 are in fluid communication with the chamber 16. A priming pump may discharge water to the filtration system 6 via the outlet 30.
On the other hand, the pressure relief valve 32 ensures that during shut-off conditions the pumping unit is not damaged, because allowing the pump to operate at shut-off for an extended period of time would result in the pumping unit being damaged. “Shut-off” is a condition wherein the pumping unit is operating but the flow of water has been stopped, for example by closing a nozzle or valve at the end of the discharge hose. When the flow of water is stopped but the pump continues to operate, friction between the water and the pump's internal spinning components increases resulting in a higher temperature, which further results in an increase of pressure. If this condition persists, the pumping unit could be damaged and the hose may rupture.
Alternatively, the filtration system 6 may be primed by removing the removable cover 12 and filling the filtration system 6 with the liquid. The check valve 34 prevents the liquid from draining out through the inlet port 8.
Still referring to the embodiment disclosed in
Each of the first trapping means 24, the second trapping means 26 and the third trapping means 28 comprises at least one particle trap in the embodiment disclosed in
The skilled addressee will appreciate that various shapes may be used for the baffle for creating a turbulent flow.
It will be further appreciated that the filtration system 6 may be opened or disassembled by an operator for cleaning purposes.
Now referring to
The pumping system 39 comprises the filtration system 6, a pumping unit 44 comprising an engine 41 and pump-end 43, a filtration system suction hose 36, a pumping unit suction hose 40 and a pumping unit discharge hose 42.
The filtration system 6 is located upstream of the pumping unit 44 and is connected with it using the pumping unit suction hose 40. The filtration system 6 drafts the water from the water source 38 using the filtration system suction hose 36.
It will be appreciated that in order to operate the pumping system 39 various methods may be used to prime the pumping system 39 as explained above.
For instance, an operator may attach a priming pump to the system.
The filtration system suction hose may further comprise an optional foot valve at its end to enable the priming of the pumping system 39.
Alternatively, in a second embodiment, the pumping system 39 may be primed by an operator by removing the removable cover 12 shown in
Alternatively, in a third embodiment, the filtration system 6 may be primed using the built-in check valve 34 shown in
Now referring to
In this embodiment, the filtration system 51 comprises an inlet port 52, a chamber 66, and an outlet port 54.
The chamber 66 comprises a first means for creating a turbulent flow which is a first turbine element 56, a first trapping means 58, a second means for creating a turbulent flow which is a second turbine element 60 and a second trapping means 62.
In the embodiment disclosed in
The inlet port is in fluid communication with the chamber 66. The outlet port 54 is in fluid communication with the chamber 66. The incoming fluid enters at the inlet port 52 and flows into the chamber 66. The fluid then enters the first turbine 56 which creates a vortex. Because of the vortex, the particles comprised in the liquid are projected towards the inside wall of the chamber 66 and are trapped in the first trapping means 58 which is positioned on the wall of the chamber 66. The fluid then enters a second turbine 60 which creates another vortex, which again projects the particles towards the inside wall of the chamber 66. The particles are then trapped in the second trapping means 62, which is positioned on the inside wall of the chamber 66. The fluid is discharged from the chamber 66 through the outlet port 54. It will be appreciated by the skilled addressee that a pressure relief valve and a priming port which may or not have a built-in check valve, may be used as part of the filtration system 51.
Now referring to
Moreover, the skilled addressee will appreciate that because the turbine element 56 is immobile in the chamber, the filtering out of the particles before entering the pumping unit does not reduce the performance of the pump.
It should be further appreciated that while a priming port and a check valve are not shown in
Now referring to
According to step 70, a fluid is provided. In one embodiment, the fluid is water.
According to step 72, a turbulent flow is created in the fluid. In one embodiment, the turbulent flow is generated using means for generating a turbulent flow. The means for generating the turbulent flow may be a turbine, a baffle, or any suitable element for disturbing the flow of the fluid.
According to step 74, the particles are collected. Again, it will be appreciated by the skilled addressee that various elements may be used to collect the particles. It will be appreciated by the skilled addressee that providing a filtration apparatus without a filtering element is of great advantage. Moreover, the skilled addressee will appreciate that in this embodiment, the filtration system may be cleaned after each use or as needed. The skilled addressee will also appreciate that a built-in check valve may be used in order to adequately prime the filtration apparatus.
It will be appreciated that the location of the trapping means provided depends on the size or weight of the particles to be collected.
Accordingly, various trapping means may be positioned strategically, each for collecting a given type of particles.
It will be further appreciated that the filtration system disclosed may be made of various materials such as, but not limited to, aluminum, polyvinyl chloride (PVC) or the like.
Although the above description relates to a specific preferred embodiment as presently contemplated by the inventor, it will be understood that the invention in its broad aspect includes mechanical and functional equivalents of the elements described herein.
This application claims the benefit of U.S. Provisional patent application Ser. No. 60/808,186 entitled “Filtration system” that was filed on May 24, 2006, and which is hereby incorporated by reference.
Number | Date | Country | |
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60808186 | May 2006 | US |