BE892617A - Irrigation system discharging via solid porous plugs - to control output by the length of plug exposed - Google Patents

Abstract

A system for distributing controlled small quantities of water to various individual plants uses plugs of porous material exposed for appropriate lengths from the ends of spur distribution pipes. The plug may be of a porous foam (I), or of a fibrous material, or of parallel bristle or needle-like profiles for passing water by capillary action alongside and between the bristles. Adjustment of the length of plug exposed controls the outlet back pressure and hence the rate of discharge. The plug is fixed in position by a transverse pin through the plug and its supporting sleeve, or by an annular clamp, if sleeve and plug are sufficiently compressible, or by having a helical thread interface between the plug and its sleeve. Pref. (I) is polyurethane or polyester foam. Simpler in construction and/or adjustment than use of individual capillary jets or outlets with chicane baffles or throttle valves. The porous plug acts as an integral filter to prevent clogging. The outlets may be laid on the surface or at least partly buried.

Description

       

  The present invention relates to improvements in irrigation or drip irrigation systems.

  
We know the growing importance that irrigation or drip irrigation systems are taking on today, whether it is their application to crops in our countries or to crops in more or less arid soils. than in North Africa, Israel, etc.

  
This increasingly frequent use is justified by the fact that the drip feeding system offered to plants has many advantages, giving each plant, at regular and close frequency, and in precise quantity, water or solution. nutritious it needs during its development. The savings made with such facilities are obvious.

  
The organs for distributing drops stuck on a general supply line are generally called drippers. As we have built them to date, however, they are not without faults, which explains the multiplicity of forms we have given them. All drippers must necessarily drop the pressure of the water prevailing in the distribution line to atmospheric pressure. They consist each time of a mount to be connected to the pipe and of a pressure drop generator established in or on this mount. The pressure drop generator can have one or more narrow holes or passages which are naturally very prone to plugging. Therefore, facilities, which include them, must be equipped with expensive filters.

   It has been imagined to constitute the pressure drop generating members by channels of a certain length, which makes it possible to achieve the same pressure drop with passages of larger diameter, and therefore under more favorable conditions vis-à-vis -vis the causes of obstruction. Various embodiments have been imagined, in particular comprising capillary tubes with a diameter of the order of 0.8 mm for example. However, these long channels still tend to become blocked, and their arrangement hardly lends itself to adjusting their flow.

  
It has also been proposed, in several forms, channels with baffles or labyrinth more or less analogous to the labyrinths of cable glands used in steam engines. These very effective devices are unfortunately very expensive to manufacture.

  
The invention provides a particularly simple dripping device, of inexpensive construction,

  
suitable for easy adjustment, comprising as usual a mount to be connected to a pressurized water pipe and a pressure drop generator established in this mount and allowing the passage of water at reduced pressure from the pipe outwards, characterized in that the pressure drop generating member is a substantially rigid porous plug.

  
Preferably, means are provided for fixing the plug in the sleeve in different positions, by exposing to the outside air a greater or lesser extent of the surface of the porous plug and thus regulating the flow rate of the dripper.

  
In all the description of the invention which will be given, the use of pure water is envisaged for feeding the plants. It goes without saying that this water can be loaded with various nutritive substances, suitably dosed, as it is well known to do in drip irrigation systems.

  
The invention will be described below by several embodiments, given by way of examples, with the aid of the drawings in which:
- Figure 1 is an elevational view, partly in section, of a dripper according to the invention;
- Figure 2 is an elevational view, partly in section, of another embodiment of a dripper according to the invention;
- Figure 3 is a perspective view of the dis-. Figure 2 positive;
- Figure 4 is a perspective view of a third embodiment of a dripper according to the invention;
- Figure 5 is a schematic plan view of an installation of drippers supplying plants arranged in lines;
- Figure 6 is a schematic plan view of another installation; - Figure 7 is a semi-schematic view of another installation.

  
In all the figures, the same reference indices indicate identical parts or the same functions.

  
In FIG. 1, we see at 1 a sprinkler water line in which a T 2 has been inserted. On one

  
 <EMI ID = 1.1>

  
the present plastic case, the right end of which, not tapped, contains a plug 4 of substantially rigid, porous polyurethane with open cells. At its left end, this body has a surface 4 'in contact with the water to be dispensed. At its right end, the plug 4 carries a metal head 5. By means of this head, the plug 4 can be manipulated

  
without touching its lateral surface.

  
The porous body 4 is impregnated with the pressurized water contained in the pipe 4. The circulating water

  
in the body 4, from the pipe to the outside, passes from one to the other of the open cells of the body 4 and comes to exude on the lateral surface 4 "of the body, exposed to air or to another medium This water has undergone a considerable pressure drop in the mass of the porous body 4. In fact, the pressure of the water in the pipe, which may be 3 bars for example, must drop

  
 <EMI ID = 2.1>

  
less extensive. You can adjust the flow rate of each dripper by pushing the plug 4 more or less into the sleeve

  
 <EMI ID = 3.1>

  
considered suitable because corresponding to the desired flow rate, the plug is blocked in the sleeve by crossing one

  
and the other by a needle 6. This is obviously possible only if the material of the sleeve 3, and that of the plug 4, are fairly tender.

  
Figure 2 shows a partial section of a sleeve 3 of less tender but elastically deformable material, which surrounds a clamp 7 blocked by a screw 8. We could also use a notched band. Figure 3 clearly shows this collar 7 and also shows, on the surface of the body. 4, parallel or equidistant lines or streaks 9. The number of visible lines makes it possible to judge the degree of depression of the plug, and each of these lines corresponds to a particular flow rate of the dripper. This flow naturally depends on the pressure of the water in the pipe and the temperature so that it would be meaningless to enter a value,

  
next to each line, but the number of visible lines nonetheless gives a relative indication of the flow

  
of each dripper, under otherwise fixed conditions.

  
Figure 4 shows yet another means of fixing the plug, and of adjusting its position. We see that here the plug 4 carries external threads which corresponds to a suitable tapping of the sleeve 3. By more or less screwing the plug into the sleeve, the extent of the exposed part of the porous material is varied

  
and therefore the flow rate of the dripper.

  
The material of the plug 4 can be

  
of many kinds. It must have open cells in order to allow passage to the liquid, or capillary passages. Such passages exist for example between the fibers of the felts. These passages will usually be tangled but they can too. be parallel as it will be if the felt is made

  
of parallel fibers. Such an arrangement exists in certain commercial markers.

  
Instead of felt, polyurethane or polyester rods or other materials can be used, provided that these have the suitable qualities specified above.

  
We can generally do without filters,

  
but it is not excluded to use, upstream of the porous plugs, other removable plugs serving as local filters. Such a filter plug is indicated at 11 in FIG. 1.

  
Figures 5, 6 and 7 schematically show various plans of sprinkler or drip irrigation installations. In FIG. 5, the pipe 1 comprises branches 2 ′ supplying plugs 4 (represented by X) in line with aligned plants 10. These could for example be plants grown in a greenhouse.

  
In Figure 6, the pipe 1 has been looped at various points around successive plants 10. Each loop has one or more dripper plugs 4, so as to meet the specific needs of each particular plant.

  
As shown in Figure 7, the pipe 1 can itself be arranged in a loop, to ensure a supply of the drippers from both sides at the same time.

  
The distribution pipes and the drippers can be partially or totally overhead. These structures can also be entirely buried, which can have various advantages, in particular from the point of view of the variation in flow rates caused by the variation in outside air temperatures.

CLAIMS

  
1.- Dripper comprising a mount to be connected to a pressurized water pipe and a pressure drop generator established in this mount and allowing the

  
 <EMI ID = 4.1>

  
exterior, characterized in that the pressure drop generating member is a substantially rigid porous plug.


    

Claims (1)

2. Dripper according to claim 1, characterized in that the frame consists of a cylindrical sleeve to be connected at one end to a point of the pipe and receiving at the other end the substantially rigid porous plug, and in that means - are provided to fix the plug in the sleeve in different positions, exposing to outside air a greater or lesser extent of the surface of the porous plug and thus regulating the flow rate of the dripper. 3. Dripper according to claims 1 and 2, characterized in that the means for fixing the plug in the sleeve are constituted by a needle capable of being pressed into the sleeve and into the plug, in a direction transverse to their common axis. . 4. Dripper according to claims 1 and 2, characterized in that the means for fixing the plug in the sleeve are constituted by a clamp applied externally to the sleeve. 5. Dripper according to claims 1 and 2, characterized in that the means for fixing the plug in the sleeve are constituted by a thread cut in the lateral surface of the plug and by a cooperating thread obtained by tapping the sleeve. 6. Dripper according to any one of the preceding claims, characterized in that the plug externally bears marks making it possible to measure the degree of depression of the plug in the sleeve and thus constituting means for locating the flow rate of the dripper. 7. Dripper according to any one of the preceding claims, characterized in that the material of the stopper is of felt with entangled fibers. 8. Dripper according to any one of claims 1 to 6, characterized in that the material of the stopper is felt with parallel fibers establishing between them capillary passages. 9.- Dripper according to any one of the resellers <EMI ID = 5.1> at its free end a waterproof stop surface. 10.- Dripper according to any one of the resellers  <EMI ID = 6.1> dications 1 to 6, characterized in that the material of the stopper is an open pore polyester foam. 12.- Drip irrigation or watering installation comprising drippers according to any one of claims 1 to 11, connected to a distribution pipe, characterized in that the pipe carries, at particular points, one or several drippers with porous plugs, arranged and adjusted according to the needs of a particular plant. 13.- Installation according to claim 12, characterized in that the pipe comprises, at particular points, local loops carrying one or more drippers. 14.- Drip irrigation or watering installation comprising drippers according to any one of claims 1 to 11, connected to a distribution pipe, characterized in that the pipe produces at least one closed loop, so that each dripper be supplied on both sides simultaneously. 15.- Drip irrigation or watering installation comprising drippers according to any one of claims 1 to 11, connected to a distribution pipe, characterized in that it is at least partially buried.