HU196645B - Water producing apparatus - Google Patents

Abstract

The present invention is a water-producing apparatus having a lined tubing having a filamentous section and a submersible pump in the liner. The essence of this is that the submersible pump (l) is located in a suction cup (3), the suction opening (9) of which is located under the haired section (6) and is sealed over the suction opening (II) of the submersible pump (I), (6) the inflow water is forced downstream, the drainage area is below the haired section (6), and the submersible pump (l) can be placed in any depth within the suction tube (3). -1-

Description

The present invention relates to a water generating apparatus having a lining tube with a hairy section and a submersible pump located in the lining tube.

In water-producing installations, such as bored or excavated wells, where water is taken up by a submersible pump, the submersible pump is, as is known in the art, positioned so that the inlet is located below the operating water level above the filtered area. The pump arranged in this way conveys upstream flow of water entering the filtered section. The suction of the well and the proportional water production is limited by the location of the submersible pump, since the suction must not be such that the resulting operating water level reaches or falls below the suction port of the pump, since in this case the cooling of the pump this would lead to damage to the overheating engine. In the known solution described above, a sandbag should be provided in the well below the haired section, where incoming sand particles may be deposited. As the level of sand accumulated in the sandbag increases over time, periodic cleaning of the well is required, during which the water production falls out, so a place where a continuous supply of water is a prerequisite (eg fire water supply) must be provided.

In case of depression changes in old wells, as well as in new wells due to more than expected depression, there is often a need, both from the hydrogeological and the operational side, for urine extraction during the filtered phase of the well. (It should be noted here that in no case may water be taken up within the filtered section, as this would result in a structural rearrangement of the aquifer in the vicinity of the filtered section which would adversely affect water production). This requirement could only be met if the suction port of the dive pump was located below the filtered section, which would require the pump to be lowered into a sandbag. However, in this solution, the reliability of the pump is adversely affected by the risk of engine embedding, i.e., fine sand and sludge settling in the well surrounding the submersible pump drive motor and thereby reducing the cooling, which has the disadvantage mentioned above.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a water generating device that enables the location of water intake from a well to be independent of the location of the diving pump suction port.

The present invention is based on the discovery that when the submersible pump is placed in a structural member which forces the water entering the well into the well to be downwardly flowing, then suctioning upwardly from the area below the filtered area into the structure of the submersible pump we can place the submersible pump anywhere in the element, even in the area of the hairy section, and the well suction! we can make the most of it.

Based on this discovery, the object of the present invention has been solved by a water generating device having a lining tube with a filtered section and a diving pump located in the lining tube, the essence of which is that the diving pump has a suction opening under the suction hole.

According to a preferred feature of the invention, the suction jacket has a sealing device over the suction opening of the submersible pump. Preferably, the suction jacket pipe is secured to the pressure pipe of the submersible pump.

In a preferred embodiment of the invention, the suction jacket tube is formed with a reduced diameter (d) at the end of the suction port, and the diameter (d) of this suction port is smaller than the diameter (D) of the submersible pump. Finally, it is expedient that the suction opening of the suction tube is guided below the filtered section at a distance (m) substantially equal to the diameter (d) of the suction opening.

The invention will now be described in detail with reference to an exemplary embodiment, based on the accompanying drawings.

In the drawing:

Figure I is a drawing of a water-producing apparatus with a suction tube according to the invention, while Figure 2 is a detail of Figure 1.

In Figure I, the submersible pump as a whole is designated by reference numeral I, and the lining tube of the water generating device (well) is designated by reference numeral 2. The submersible pump 1 suspended in the liner 2 is connected to a pressure pipe 4 with a flange 5 in which the flow direction is illustrated by an arrow A. The well is provided with a screened section 6 inserted into the lining tube and a bottom stopper 7, which is formed from the material of the surrounding soil.

The submersible pump 1 has a suction opening 11, a plurality of impellers 12 located above the suction opening 11, and a drive motor 14 below. Λ 11 inlet diameters, denoted by the same reference letter /) as the diameter of the entire submersible pump. The submersible pump I has a non-return valve 13 arranged above the impellers 12, which is connected to the flange 5 of the pressure pipe 4 by a flange 5 '.

As shown in Figure 1, the submersible pump I is concentricly housed in a suction jacket which is closed above the submersible pump 1 by a structure generally designated 8 (illustrated in more detail in Fig. 2), and secured to the discharge pipe 4. The end extending into the suction space 10 has 9 suction openings. Although the suction jacket 3 may have the same diameter over its entire length, it is desirable that it is narrowed downwardly below the drive motor 14 of the submersible pump I as shown in Figure 1 so that its suction port 9 is denoted by reference d 11 is the diameter of the manhole. The tapered section of the stator jacket 3 extends below the filtered section 6 into the suction space 10, optimally at a distance m substantially equal to the diameter d of the narrowed section. The water flow directions resulting from the use of the suction tube 3 are illustrated by the arrows indicated by the reference letter B at the filtered section 6 and the reference letter C at the suction port 9.

196,645

Figure 2 shows a larger scale of !. 1A, which includes the structure 8 in more detail. As can be seen in the figure, the main parts of the structure 8 on the pressure pipe 4 have a broken connection, e.g. The closure plate 15 secured by welding seam 17 and the cap 16 of the suction jacket 3 also secured to the upper end by, for example, welding. The two lids 15 and 16 are secured to one another by means of a releasable connection, such as screws 18, and a seal 21 is provided between them for airtight sealing. The power cable 19 for supplying power to the submersible pump 1 is routed through both closures 15 and 16 and is provided with an airtight sealing ring 20 at its passage.

The water-producing apparatus according to the invention with suction jacket 3 functions as follows:

water flowing into the well through the haired section 6 in the direction of the arrows R flows downwardly through the suction jacket 3 receiving the submersible pump I and then upwardly through the suction opening 9 with a diameter d in the direction of the arrows C into the suction jacket 3. Since the diameter of the suction opening 9 is smaller than the diameter of the suction opening 11 of the submersible pump, the flow rate of water entering the suction tube 3 through the suction opening 9 is relatively high, therefore fine sand and sludge particles in water cannot settle. This eliminates the need for sandbags, so this section - usually about 10 meters - can be saved when constructing a well. The upwardly flowing water in the suction jacket 3 passes by the water-cooled drive motor 14 of the submersible pump 1 and then enters the discharge pipe 4 by entering the suction opening 11 of the submersible pump 1. Because of the constant, intense water flow along the drive motor 14, cooling of the engine is improved.

The suction of the well may be maximal due to the use of the suction jacket 3, i.e. the operating water level can be adjusted to the level indicated by reference letter H _{2 in} Figure 1, corresponding to the height of the upper end of the filtered section. For the sake of illustration, the operating water level 7 /, is also indicated in the figure, whereby the suction of the well without the use of the suction jacket 3 can be achieved by the safe, harmless operation of the submersible pump 1. The distance Λ between the operating water level 77 and 77 ₂ illustrates the extraction yield that can be achieved by the present invention. Because the suction tube 3 is aided by the structure 8! the submersible pump I is sealed, the water in the suction jacket pipe 3 provides for the cooling of the pump drive motor 14 at all times during the operation of the pump.

The advantage of the invention is that, regardless of the location of the water intake, the submersible pump can be suspended at any depth into the well, so that the suction potential of the well can be maximized. The water intake location within the suction space may also be of any depth. Since the upper end of the suction jacket pipe is sealed to the pressure pipe, the operating water level may fall below this connection point and the suction rate will cease to be a well utilization limit. For this reason, it is not necessary for the prior art solutions to employ a desiccator recommended to prevent unacceptable levels of water subsidence, which is much more complicated and expensive than the suction jacket used in the present invention. However, it is a significant advantage that the submersible pump is constantly safely cooled and that the absence of sandbags does not require periodic cleaning of the well, so no downtime is due to failure of the drive motor due to embedding or during the cleaning operation.

According to experience and calculations, the additional losses resulting from the use of a suction tube are very small, up to a few centimeters of water column. Since the essence of the invention is precisely that the positioning of the pump is independent of the location of the water intake, it is not a problem that the pump is placed slightly lower to compensate for the slight excess loss.

The invention is, of course, not limited to the exemplary embodiment shown in the drawings and described above, but may be embodied in many variations within the scope of the claims.

Claims (6)

Claims A water generating device having a lining tube with a filtered section and a submersible pump located in the lining tube, characterized in that it has a suction tube (3) extending below the haired section (6) with its suction opening (9). Water production device according to Claim I, characterized in that the suction jacket tube (3) has a sealing device (8) over the suction opening (11) of the submersible pump (1). Water production device according to Claim 1 or 2, characterized in that the suction jacket tube (3) is fixed to the discharge pipe (4) of the submersible pump (I). Water production device according to any one of claims 1 to 3, characterized in that the suction tube (3) is formed with a reduced diameter (d) at the end of the suction opening (9). 5. A water production device according to any one of claims 1 to 3, characterized in that the diameter (d) of the suction opening (9) of the suction jacket (3) is smaller than the diameter (D) of the suction opening (11) of the submersible pump (1). Water production device according to any one of claims 1 to 5, characterized in that the suction opening (9) of the suction tube (3) is guided under the filtered section (6) at a distance (m) substantially equal to the diameter (d) of this suction opening (9). .