The present invention refers to an irrigation emitter with the potential of self-cleaning of the inlet water filter.
The emitter constitutes the most sensitive element of drip irrigation due to its well known sensitivity on blocking problems. Each known emitter like e.g. the WO 03/045131, as a certain protection system in the water inlet, that is usually a static filter of grid or sieve. Such a filter consists of a flat rectangular or circular surface for the inlet of the water, swept horizontally and vertically by thin rectilinear plastic rods-elements, with their edges fixedly connected to the opposite sides of the inlet surface that they bridge, dividing in this way the available inlet surface to a great number of much smaller rectangular fixed and rigid openings. The dimension of the openings characterizes the quality of filtering.
These rectangular openings, the basic elements of filtering, are structures without the potential of movement or bending, they obstruct the passage of foreign bodies larger than a specific granulometry, that is definitely smaller than the smaller cross section of the meander like water paths within the emitter.
The disadvantage of the rigid static filters is that whereas they initially offer protection to meander like paths, constant accumulation of a layer of foreign bodies in their inlet causes blocking of the same rigid and fixed rectangular openings, it interrupts the inlet of water and finally renders the emitter useless.
It is known that there is no potential of intervention to the emitters for the cleaning of the inlet filters and the restoration of their operation. The only measures that could be taken until now, have been preventive e.g. thorough water purification, that has high cost though.
There are also more sophisticated emitters like U.S. Pat. No. 3,780,946 A. This emitter does not have inlet water filter at all. The emitter has located transversely therein a number of spaced-apart resilient diaphragms each provided with a central orifice of a small cross-section in order to limit the flow in a low level, and capable of enlarging as a particle lodges in the orifice and causes a pressure differential between the two opposite surfaces of the diaphragm. As the orifice expands due to absolute resilient material, the particle is impelled through the orifice, there by unclogging the orifice. After that the particle is directed in to the next chamber and the process is repeated until the particle exits the emitter completely.
All the particles, small as well as large, proceed through the orifice until they exit the emitter because the same orifice is designed very narrow in order to limit the flow of the water.
Separated resilient diaphragms are needed which create first an additional cost for fixing and assembling and second are not compatible with the plastic material causing problems by the recycling process. Moreover these resilient diaphragms have to be assembled, a sophisticated and costly procedure.
In the same concept is also the U.S. Pat. No. 4,008,853 A, while in the EPO 0119181 the water inlet filter as well as the meander like path is much more sophisticated. The emitter consists at least of two separate parts of which one of them is resilient. These parts are detached from each other during the phase of stopping of irrigation due to the resilient material or to a blade spring, in order to create a large opening in the inlet as well as in the meander like path area for the foreign particles to pass through. By the following phase of starting of the irrigation and the water entering in the emitter, the two separated parts reunite again in order to create the water inlet filter as well as the meander like path necessary for the function of the emitter. In case of clogging, the function of the emitter is completely stopped till the next irrigation starting phase. The disadvantages are obvious.
The emitter of the present invention has an incorporated filter in the water inlet, that consists of rectangular or other openings with the potential of bending of the elements that create them if particular pressure is exercised from the one side of their surface.
In case of total blocking of the openings of the elements from foreign bodies that are transferred with water, a difference of pressure is developed between the two surfaces of the above mentioned elements. This difference of pressure exercises forces that bend certain points of these elements and as a consequence the continuity on the layer of foreign bodies that covers the filter is disturbed and interrupted and flow is restored. These forces are exercised constantly until the above mentioned difference of pressure is eliminated and the flow and the operation of the emitter is restored.
Due to the minimum deflection sag required for the restoring of the flow, the elements are bent slightly in the limits of elasticity of the plastic material and therefore they are restored immediately afterwards in their previous position. In most systems, the deflection sag and further the created opening is controlled and limited by terminal limits in order to avoid the undesirable penetration of greater dimension of foreign bodies in the internal part of the emitter.
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The available inlet surface of water with dimensions a*b, is divided to a great number of openings 2 that are created between the free successive elements 1 and 1a to the one edge and the walls 11 that enclose the filter.
Upon the proper operation of the system, where water is inserted freely in the emitter, the difference of pressure ΔP1−P1−P2, between areas 4 and 5 is minor, while the difference of pressure LPA=P1−PA, between areas 4 and 6, namely the network and the environment, has a fixed and high value that is provided from the water supply pump.
However, when the openings 2 of the filter are totally blocked from the accumulation of a layer of foreign bodies in their inlet, water does not flow in emitter 3, pressure P2 in area 5 is equal to atmospheric PA, and therefore the difference of pressure between areas 4 and 5 namely in front and behind the openings 2 is the following:
ΔP1=P1−P2=P1−PA=ΔPA.
Namely it has the value as maximum as possible.
This has as a consequence the development of forces from the side of area 4 on elements 1, 1a of the filter with the free edge, and as a consequence they are slightly bent to area 5 in the internal part of the emitter. By bending and this movement the continuity in the layer of foreign bodies that covers openings 2 of the filter is disturbed and interrupted, and as a consequence at a certain time water flows restored in the emitter and the difference of pressure ΔP1 is eliminated.
Due to the minimum deflection sag that is required for the restoration of the flow, elements 1 are bent within the limits of elasticity of the plastic material of the emitter, and therefore they are restored in their previous position by restoration of flow. It is evident that this procedure will be repeated automatically and constantly in any blocking and for as long as this endures.
In order to ensure the potential of bending elements that may be obstructed by foreign bodies wedged in certain points of openings 2, the support points of the free elements 1 and 1a on the one edge are totally independent the one from the other and they are alternated constantly in the longitudinal opposite sides of the walls so that their anticipated bending is counter-clockwise for the half and clockwise for the other. This fact together with the great number of elements, ensures great availability in movement and additionally the potential at least one of all to be able to be bent easily, with minimum force, freely and independently from the others.
In order to increase force and further the bending moment that is exercised, elements 1, 1a could be connected together by groups in common partial surfaces increasing the exercised force per section of support. Apart from bending, the forces that are developed upon blocking can simultaneously twist the free elements of the filter, as for instance it will happen in the asymmetric and bent 9, increasing the potential and the possibilities of a certain movement towards any direction.
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This variation can operate satisfactorily due to the three-dimensional form of the filter even if the elements did not have increased bending potentials. It is self-evident that a variation can arise with another three-dimensional form such as pyramid etc.
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In another variation, the entire composite system could not protrude, but to be downgraded and to be aligned with the back surface 16 of emitter 3. It has not been designed.
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In this case, as opposed to all previous cases, we do not have at our disposal a large free surface of a*b dimensions in order to divide it to a great number from smaller rectangular openings 2 and to protect hole 14. The problem is particularly difficult. However, we create a cavity 5 of larger extent than hole 14 that must be protected. In this case, free elements 1 are bent or arched in order to increase the inclination to bending and they are arrayed radially dividing the three-dimensional area over and around cavity 5 to smaller openings 2. Terminal limit for the path of elements in the phase of bending is the opposite respective element.
By the terminal limit of the bend, the system is generally controlled and openings 2 of specific and controlled dimensions are ensured after a bending or a possible blocking of one of the elements of the filter.
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The design of the data of any variation with emphasis on the inclination of easy bending together with the great number and the potential of their independent movement, ensures the operation of the system even in case of blocking of the greater number of elements.
It is clear that new variations can be created with combinations of the already described variations.
Number | Date | Country | Kind |
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20070100320 | May 2007 | GR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GR08/00043 | 5/28/2008 | WO | 00 | 11/27/2009 |