JPH0446803Y2 - - Google Patents

Description

[Detailed description of the invention] (Field of industrial application) This invention relates to a water collection screen (also called a strainer) used for water extraction, oil extraction, etc. from water wells, oil wells, gas wells, geothermal wells, etc. It is something.

(Prior art) Conventionally, for example, when digging a water well and pumping up groundwater from an underground aqueous layer, a pipe is buried underground and the aqueous layer 12 is buried as shown in FIG.
In the past, countless holes 16 such as round holes and long holes were made around the pipe 15 to sample water.
In contrast, the aperture ratio of hole 16 was only about 10% at most.

Therefore, the water collection rate was lower than that of hole 16, and the effect of sampling well water was less.

Further, since the hole 16 is opened in parallel from the outside into the pipe 15, there is a drawback that gravel 17 becomes clogged at the entrance or middle of the hole 16, resulting in a decrease in water collection capacity.

Furthermore, there was a drawback that fine sand particles gathered around the pipe 15, further reducing the water collection effect. Therefore, overlayering could not occur.

Therefore, the idea was to continuously wrap a triangular wire 3, which is wide on the outside and narrow on the inside, around the rod 2 in a spiral shape, as shown in Figures 5 and 6 of the drawings. A slit width C designed according to the grain size of gravel in the underground water layer is provided between the wire 3 and the opening 5, and a triangular opening hole 6 is provided between the wires 3. The screen 11 was formed into a cylindrical shape.

Therefore, gravel and the like that have passed through the opening 5 are not caught in the opening hole 6, so that no clogging occurs.

Therefore, as the distance from the screen 11 increases, the grains of the gravel 13 gradually become smaller, creating a moderate overlayer 14 around the screen, which has the effect of naturally stabilizing the water layer.

Therefore, the opening ratio is 20 to 50% better than that of the pipe 15 with holes 16 as described above, the water collection area is increased, and the water collection capacity is improved.

However, even with this method, the water collection effect is still not perfect, so attempts are being made to increase the water collection effect by increasing the diameter of the screen or increasing the aperture ratio. Ta.

However, increasing the diameter or length of the screen had the disadvantage that the construction costs required for digging the well were extremely high.

Furthermore, if the wire forming the conventional screen is made thinner and the aperture ratio is increased, the strength of the wire becomes weaker, making it unsuitable for use as a screen.

(Problem to be solved by the invention) Therefore, in conventional screens, it is necessary to increase the water collection capacity by increasing the aperture ratio of the openings of the slit width set between the spirally wound wires. The only way to do this was to increase the diameter of the screen or increase the length of the screen.

Also, if the wire was made smaller, the strength would be weakened. As a result, construction costs were inevitably high.

This proposal was made to solve these problems.

(Means for solving the problem) (a) A triangular wire 3 with a wide outside and a narrow inside is wound in a spiral, and the wire width B is set according to the particle size of gravel, etc. in the water layer 12. will be established.

(b) A triangular partition wire 4, which is narrow on the outside and wide on the inside, is wound spirally between the wires 3 to provide two or more slit widths C.

(c) Provide an opening 5 on the outer periphery of the slit width C, and a V-shaped opening hole 6 with a wider inner side.

(d) The contact points between the rod 2, the wire 3, and the partition wire 4 are firmly and accurately fixed by welding, etc., and have a slit width C, and a circular cylindrical screen 1 is formed.
form 1.

(Function) A well is dug underground and a slit width C is set according to the grain size of the gravel 17 etc. in the water layer 12.
A circular cylindrical screen 11 provided with an opening 5 is formed.

The screen 11, the screw 8 provided on the ring 1
Connect the casing 7 by screwing it to the ring 1.
A casing 7 is connected to the casing 7 by welding or the like, and a screen 11 is buried in the underground water layer 12 to collect water.

(Embodiment) Hereinafter, an embodiment of the present invention will be described with reference to the drawings. Figure 1 is a general front view of the present invention, with a portion cut away to show the inside.

FIG. 2 is a sectional view taken along line A-A' in FIG. 1 of the present invention.

FIG. 3 is an enlarged sectional view and a perspective view of a portion of the present invention seen from inside.

FIG. 4 is an enlarged cross-sectional view of a portion of the present invention.

(a) Circular rings 1, 1' are provided at both ends, dozens of rods 2 are provided between them, and both ends of the rods 2 are welded to the rings 1, 1' to form a circular cylinder.

(b) A triangular wire 3 is formed with a wide outside and a narrow inside, and the wire 3 is wound continuously in a spiral around the outer circumference of each rod 2, and the wire 3 is wrapped around the outer circumference of each rod 2 in a spiral manner to match the particle size of gravel in the underground water layer. A wire width B is set accordingly.

(c) A triangular partition wire 4, narrow on the outside and wide on the inside, is wound between the wires 3 and 3, and two or more slit widths C are provided, each having a width C set according to the grain size of the gravel or the like.

(d) An opening 5 is provided on the outer periphery between the wires 3, 3 and the partition wire 4, and a V-shaped opening hole 6 with a wider inner side is provided.

(E) The contact points between the rod 2, the wire 3, and the partition wire 4 are firmly and accurately fixed by welding or the like, and have a slit width C.

(f) On the inside of the upper ring 1 is a casing 7.
A screw 8 is provided to connect the.

In some cases, the casing 7 is connected to the ring 1 by direct welding instead of the screw 8. This can be done in any way as long as it is connected.

(g) The screw 9 is provided on the lower outer side of the upper ring 1' because a cap 10 may be attached below.

In the case of an ordinary well, the cap 10 is not attached.

The screen 11 having the above structure has a circular cylindrical shape.

Therefore, when comparing the opening 5 with the same slit width C in FIGS. 3 and 4 of the present invention and the conventional drawings in FIGS. 5 and 6, it is found that the length of the wound wire 3 is In D, to give an example, the conventional one can provide five openings 5, but in the present invention, the partition wire 4 is wound around the wire width B between the wires 3, 3. Therefore, by making the wire width B a little wider and dividing the wire width B into two, eight slits with the width C of the opening 5 can be made at the same length D.
can be provided.

Therefore, although it varies depending on the slit width C,
Comparing the number of openings 5 according to the above-described example, the number of openings 5 in FIG. 5 is five, whereas the number of openings 5 in FIG. It is possible to provide 60% more openings 5 than before. Therefore, even if the screen 11 is the same size and the slit width C is the same, by increasing the area of the openings 5, the water collection area increases, and the water collection rate can be significantly increased. .

When using this, as shown in Figure 7 of the drawing, a well is dug and a screen 11 is placed in the underground water layer 12.
bury it.

The slit width C is designed and set according to the particle size of gravel, etc. in the water layer 12.

A partition wire 4 is provided between the wires 3, 3, and an opening hole 6 is V-shaped toward the inside of the screen 11 from the opening 5 of the slit width C on the outer periphery of the screen 11. Since the inner opening E is wide, gravel 13 such as gravel passing through the opening 5 does not get clogged in the opening hole 6.

Therefore, the area around the screen 11 is as shown in drawing No. 8.
As shown in the figure, as you move away from the periphery of the screen 11, the grains of gravel etc. gradually become smaller, naturally creating an overlayer 14 around the screen 11 that makes it easier for water to pass through, resulting in stable water flow. A layer is formed.

Next, as a different embodiment of the present invention, as shown in FIG. Providing the shaped partition wire 4 has the advantage that even if the wire width B is further narrowed, the slit width C can be kept the same, and the number of openings 5 can be increased.

Therefore, the water collection rate increases and the screen 11
can be made smaller.

Furthermore, although the embodiment has been described using a circular cylindrical screen as an example, this can also be applied as a flat screen, and can also be used to prevent mountains from collapsing by being buried in mountains, rivers, etc.

Further, although the partition wire 4 is narrow on the outside and wide on the inside, the V-shaped opening hole 6 can be provided even if the partition wire 4 is made into a plate shape with the same thickness on the outside and inside.

Therefore, the screen of the present invention can be used not only for water wells, but also as a screen for water and oil extraction in oil wells, gas wells, geothermal wells, and the like.

(Effects of the invention) (a) By providing the partition wire 4 between the wires 3, the opening 5 is larger than before in the length D where the wire 3 is wound.
Since the opening ratio is increased and the water collection area is large, the water collection efficiency is improved.

(b) Since the opening hole 6 is a V-shaped opening hole 6 that widens inward, there is no clogging with gravel or the like. Therefore, stable water collection is possible for a long period of time.

(C) Large gravel naturally gathers around the screen 11, and the particle size of the gravel becomes finer as you leave the screen 11, creating an overlayer that improves the passage of water. There is an action that can be taken.

(d) Since there are more openings 5 than in the past, the screen 11 as a whole can be made smaller and construction costs can be reduced.

(E) Since the wire 3 can be of the same size as the conventional wire, the strength will not be weakened.

(F) The slit width C can be freely designed and set according to the size of gravel, etc. in the underground water layer 12.

(g) In addition, since the overlayer is a V-shaped opening hole 6 in the present invention, pressure is applied from the ground surface into the screen 11, and water flows from the inside of the screen to the outside of the screen, which is called a backwashing method. By blowing out gravel, etc. around the screen 11, it is blown away to the far side of the water layer 12, leaving gravel with a large particle size around the screen 11, creating an even better overlayer. This has the effect of improving water collection efficiency. Therefore, the screen 11 once buried underground will not become clogged.

[Brief explanation of the drawing]

FIG. 1 is an overall front view of the present invention, with a portion cut away to show the inside. Figure 2 is A- in Figure 1 of the present invention.
FIG. FIG. 3 is an enlarged sectional view and a perspective view of a portion of the present invention seen from inside. FIG. 4 is an enlarged cross-sectional view of a portion of the present invention. Fifth
The figures are an enlarged cross-sectional view and a perspective view of a portion of a conventional device as seen from the inside for comparison with the present invention. FIG. 6 is an enlarged sectional view of a portion of the conventional device for comparison with the present invention. FIG. 7 is a reduced overall view showing an example of the use of the present invention. FIG. 8 is an enlarged sectional view showing an example of the use of a portion of the present invention. FIG. 9 is a cross-sectional view of a part of a conventional embodiment, showing an embodiment using a pipe. FIG. 10 shows a different embodiment of the present invention, and is a partially enlarged sectional view. 1 and 1' are rings, 2 is rod, 3 is wire,
4 is a partition wire, 5 is an opening, 6 is an opening hole,
7 is a casing, 8 is a screw, 9 is a screw, 10 is a cap, 11 is a screen, 12 is a water layer part, 13
is gravel, 14 is a concave bend, 15 is a pipe, 16
is the hole, 17 is the gravel, B is the wire width, C is the slit width, D is the length, and E is the inner opening.

Claims (1)

[Scope of utility model registration request] Wire 3 with a shape that is wide on the outside and narrow on the inside
A partition wire 4 is provided between the wire 3 and the wire 3, a predetermined slit width C is set, and the V is widened inward.
A screen 1 having a structure with a shaped opening hole 6
Water collection screen formed by 1.