FR2709314A1 - Automatic, autonomous and lifting sluicegate - Google Patents

Abstract

The automatic, autonomous and lifting sluicegate for new spillways, for spillways constructed initially without sluicegates with the aim of raising the normal holding level and increasing the volume (capacity) of the reservoir, as well as for spillways reconstructed with the aim of increasing their capacity, is a sluicegate the operation of which is completely automatic and autonomous of any machine, external energy and human factor, lifting to allow the water to pass. Visible in the figure are: the cylindrical main supporting shaft (8) formed of a two-part cylinder, one part inserted into the support (20) of the fixed articulation linked to the spillway pier (2), concrete sill (1) with a top (3), by means of the fixed articulation support (20) in a horizontal upstream-downstream direction, the three-dimensional metal latticework framework (4) which rotates about the axis of the shaft (8) with the metal sheet (5) which intercepts the passage of the water or allows it to pass, the tie (7), the support (10) which acts as a rest when the sluicegate is closed, the reinforced concrete beam (11) which supports the supports (10), the seal (12) at the bottom of the sluicegate, the spillway bridge (13), the slab counterweight (6) with rib forming part of the three-dimensional latticework (4) and thereby forming a hybrid structure.

Description

The present invention relates to automatic, autonomous and ascending valves of dam weirs. They are intended for the three cases which we have to do in the practice of weirs.

 1. These valves are intended for new weirs which need valves: (a) automatic and autonomous, (b) of increased resistance to very strong earthquakes, (c) the most economical.

2. These valves relate to existing free-flowing weirs, ie weirs initially built without valves. Automatic valves are installed to raise the level of normal retention in order to increase the useful volume of the tank.

These valves lift automatically to let in all the floods planned by the initial weir project: with an insignificant elevation, with an admissible or tolerable elevation.

3. These valves are also very suitable in the case where it is necessary to reconstruct and adapt the spillway when it is desired to considerably increase its capacity by means of automatic and autonomous valves according to this invention.

 There are valve weirs in which it is best, if an increase in the normal level is required, to install automatic valves according to this invention above the valves which already exist. They are based on the latter during closure.

Regarding the valves for new weirs, the new type of automatic and autonomous valves has several advantages, the cost included.

With these valves, the operational safety of the reservoir is considerably increased while reducing the cost of the valves. This makes them much more economical than any other valve satisfying the same conditions. By comparing them to other types of valves and structures designed to raise the level of normal restraint they are
many the safest and most suitable in operation. They respond to all the forces that may arise and to which the valves must be calculated (self-weight, hydrostatic pressure, hydrodynamic pressures, earthquakes, waves, ice). They will respond economically to a whole series of floods, even maximum floods, by making a good regulation - the reservoir having to retain as much water as possible.
optimally transforming inlet floods into outlet floods.

Defects in structures installed to raise the level of normal restraint and to
increase the useful volume of the tank, used and known up to now, are eliminated with the valves of the present invention.

Three vertical sections of the same automatic, autonomous and
rising which relates to the same invention. The valves of all three vertical sections differ only in the type of frame. In the first case, FIG. 1, the framework is a three-dimensional lattice (4) with the hooked counterweight (18). In the second case, Figure 2, the frame is a three-dimensional lattice (4) with the counterweight (6) incorporated in the lattice (4).

In the third case, the framework is formed by a cylinder (23) which connects the two battery supports and which replaces the three-dimensional trellis, Figure 8. The counterweights are linked to the
cylinder by means of levers.

Figures 1 to 7 show the first two cases of this valve. On these figures
we see: - the weir threshold (1),
- the weir stacks (2) which form the bay of pertuis,
- the top (3) of the threshold,
- the three-dimensional wire mesh frame (4), which rotates around the shaft axis
support (8) which can also be in the form of a three-dimensional gantry, - the sheet (5) which intercepts the passage of water,
- the slab (6) with reinforced concrete ribs as a counterweight forming part of the three-dimensional lattice and thus forming a mixed structure which can be moved
downstream; this slab with reinforced concrete ribs replaces each other with the
counterweight (18) which is imperative in cases where the valve must withstand strong earthquakes, - the steel tie (7) which passes through the sheet (5) with a plastic gasket;
the tie rod can be removed in case the displacements at the bottom of the valve without
tie rods were admissible from the point of view of sealing,
- the main cylindrical support shaft (8) formed of a cylinder in two parts, one more
large diameter embedded in the trellis (4), the other of smaller diameter :, this part, in the first case, introduced into the fixed support (20) of the joint, in the second case introduced
in the support which transmits the horizontal forces downstream while rolling upstream,
- the rolling surface (9) (Figures 4 and 5) on which the part of the cylinder is supported
support (8) of larger diameter which moves upstream when the valve opens,
- the support (10) fixed in vertical direction and free in horizontal direction, which does not serve as support
that when the valve is closed,
- the reinforced concrete beam (11) embedded at the ends in the spillway piles, with expansion joints, if necessary,
- the seal (12) at the bottom of the valve which rests on the threshold a few decimetres
downstream of its summit (3), without transmitting forces to the weir threshold,
- the bridge (13) over the weir,
- the normal restraint level (14),
- the maximum restraint level (15),
- the upper ply (16) of the discharge jet, - the variable level (17) which can be seen only with the valve open, FIG. 5, - the counterweight (18) in reinforced concrete attached to the lattice structure so preventing the transmission of horizontal seismic forces to the lattice frame, replacing each other with the slab with reinforced concrete ribs (6); the counterweight being imperative in the case where the valve must resist strong earthquakes, - the bar (19) carrying the counterweight and articulated at both ends, - the support (20) of fixed articulation in the horizontal without upstream-downstream, by means of which the framework is linked and supported on the pile, exists on the structure of FIGS. 1, 2, 3 and 6, and does not exist on those of FIGS. 4 and 5, - the tooth (21) for removing the aperture opening, which can be seen in Figures 6 and 7, for anchoring the seal (22) to the bajoyer and whose bearing surface of the seal changes direction in the part high so as not to prevent the normal opening of the valve, the space between the seal and the sheet (5) being filled with a reinforced sheet perpendicular to the sheet (5), - seal (22 ) to bajoyer.

In Figures 1 to 5, we can see various frameworks in vertical section of the same type of valve, as follows:
- Figure 1, lattice frame with fixed main support and earthquake-resistant device,
counterweight (18), - figure 2, lattice frame with fixed main support and slab counterweight with rib
in reinforced concrete incorporated in the trellis, forming a mixed structure,
- Figure 3, lattice frame with fixed main support, the counterweight as in Figure 2
with a valve opening of 30,
- Figure 4, lattice frame with main rolling support with counterweight as in
figure2,
- figure 5, as in figure 4 with a 30 "valve opening.

Figure 6 shows the upstream elevation of the lattice frame of Figure 1, with the
slab counterweight with ribs.

Figure 7 shows a detail of the gasket to the bajoyer.

Figures 8 to 15 relate to valves of the same type in case the frame is in
form of pipe and which are used for small heights.

In Figure 8 we see:
- the shaft (23), the axis of rotation made with a sheet metal pipe of sufficient stiffness, the others
parts of the shaft shown in Figures 10, 12 and 15, - the part of the valve (24) which intercepts the passage of water or lets it pass by turning
with the shaft, the rotary movement being effected by the difference of the moments due to water and
counterweight (friction included),
- the bottom seal (25) made of synthetic material fixed to (24),
- the counterweight (26) and (27) which makes a moment of rotation balancing that of the pressure
of water on the valve, in reinforced concrete with location to adjust the counterweight,
- the lever (28) of the counterweight, made of steel,
- the concrete of the weir (29),
-The support (30) in steel profiles, of the seal,
- the top of the weir threshold (31),
- the contact line (32) in section, between the seal (25) and the steel support (30),
- the level of normal restraint (33),
- the level of the axis of rotation (34) of the shaft at the top of the valve,
- the part (24), being a steel structure, and the lever (28) are embedded in the shaft (23)
by means of welding.

Figure 9 shows a vertical cross section of the valve lifted to leave
pass the water.

FIG. 10 represents an upstream view of the automatic valve according to the invention. We
sees:
- the tree (23),
- the part (24) of the valve proper,
- the rotary support cylinder (36) of the shaft, consisting of two parts: one (36) resting on the support (37) to transmit the vertical forces and the other (38) in gear
partial transmitting the horizontal forces to a rack (39) inked on the stack,
- the support (37) on a stack of the cylinder overflow (36),
- the partial gear cylinder (38),
- the side seal (40) made of synthetic material,
- the side stack (41) of the weir,
- the sliding plate (42) of the lateral seal (40).

Figure 1 1 shows an automatic valve in plan according to the invention, only, without batteries
side. We see:
- the shaft (the axis of rotation) (23),
- the lever (28) of the counterweight,
- the rotary support cylinder of the shaft (36),
- the counterweight (26) and (27),
- the partial gear cylinder (38).

Figure 12 shows the support of the valve shaft in some detail on the side stack which
supports it. The parts we see are as follows:
- the valve shaft (23),
- the support stiffener (35) of the valve shaft (of the pipe), - the rotary support cylinder (36), - the support (37) of the valve transmitting the vertical and friction forces on the lateral stack, - the partial gear cylinder (38) with a central angle of 35 to 45 "(or the gear wheel) with straight teeth serving as a safety against sliding intended to transmit any horizontal forces exceeding the friction, the valve being open, - the rack (39) with straight teeth also serving to limit the rotation of the shaft upstream, - the lateral plastic seal between the valve and the stack, fixed to the
valve, sliding on an inked sheet on the stack, - the side stack (41) of the weir, - the sheet (42) for sliding the lateral seal embedded in the side surface of the stack, - the downstream stop (43 ), shoulder limiting the downstream rotation of the support cylinder of the
valve, - the upstream stop (44), shoulder limiting the upstream rotation of the support cylinder and at the same time protecting the support, can also be done with a cam upstream of the gear.

Figure 13 shows a cross section of a valve with intermediate piles added to the initial weir to reduce the span of the tree. The intermediate support does not cut the valve, it crosses it through an opening, up to which the normal retention arrives.

In this figure we see, in addition to the parts that we have seen in Figure 8: - the intermediate stack (46) added to the weir, - the support (47) of the shaft transmitting the vertical and horizontal forces by friction, this support passing through the part (24) of the valve, - the downstream stop (48) of the intermediate stack transmitting the horizontal forces when the valve is closed, - the supports (49) made of sheet metal between the valve shaft and are support (47), - the bars (50) of steel for anchoring the intermediate pile (46) added to the initial weir,
the boreholes are filled with epoxy resin mortar.

Figure 14 shows an upstream view of a weir with the automatic counterweight valve, according to this invention with two intermediate piles (46) added.

Figure 15 shows the downstream elevation of a weir with the automatic counterweight valve with two intermediate piles added. We see:
- the supports (47) of the valve shaft on the intermediate stacks, - the stops (48) of the valve shaft, - the support (35) and intermediate (45) stiffeners of the shaft.

The level of the normal retainer (33) can vary from the highest level of the shaft to the level below the cylinder. fi it is possible to change the normal containment level according to the needs and circumstances in the reservoir or downstream of the dam. Changing the normal restraint level is done by removing or adding counterweight, which is not difficult. The same procedure is followed to calibrate the valve operation.

By placing the counterweight above the level of the valve axis in the closed position, the curve of the rotational moments is changed, which makes them decrease faster than in the case of the horizontal lever. The opposite happens when the counterweight is placed below
of the axis level.

The PC computer software for the complete calculation with the dimensioning of automatic and autonomous valves, according to the present invention can be provided on request.

In the case where the threshold of the existing weir is not well horizontal and in a straight line, a correction is made which is not complicated.

In the case of the curvilinear weir it can be transformed into a polygonal weir by adding intermediate stacks and by correcting the line of the threshold.

To increase the capacity of the weir without raising the level of the maximum reservoir, we can lower the threshold of the weir (1) or (31) and install valves according to this invention.

The first calibration of the valves can be done by replacing the water with cylinders
hydraulic transmitting forces at the bottom of the valve and at the weir threshold.

Instead of one span of the automatic and autonomous valve according to this invention, several can be made by repeating the solution of FIGS. 8 to 12.

Another combination for small dimensions is possible: the spillway divided into several valves and each of these valves divided into a span with intermediate piles as shown in Figures 13 to 15.

In the case of annoying oscillations of small valves during the discharge it is possible to add a device which attenuates them.

The automatic, autonomous and rising valve with a lattice frame or in gantry and beam system can be used for vents of all heights, while the same valve in pipe frame is used for small heights of this this especially with the counterweight above the horizontal passing through the axis of rotation.

The arrangement of the automatic, autonomous and rising valve must be made so that the rotary movement is effected by the difference of the moments due to the water and the counterweight, the dead weight and the friction included.

Claims (9)

 1. Automatic, autonomous and rising valve for new weirs, for  weirs initially built without valves in order to increase the level of containment  normal and to increase the volume of the tank, as well as for weirs rebuilt in order to increase their capacity characterized by the fully automatic and autonomous operation of any device, external energy and human factor, amount to leave  pass the water, the main support shaft (8) cylindrical, formed of a cylinder in two parts, one of larger diameter, embedded in the trellis (4), the other of smaller diameter, this  part introduced into the support (20) of the fixed articulation linked to the stack (2) of weir, threshold  (1) in concrete with top (3), by means of support (20) of fixed articulation in horizontal direction upstream-downstream, the three-dimensional wire mesh frame (4), which rotates around the axis  shaft (8) with the sheet (5) which intercepts the passage of water or lets it pass, pulling it  (7), the support (10) which serves as a support when the valve is closed, the beam (11) in reinforced concrete  which supports the supports (10), the seal (12) at the bottom of the valve, the seal  seal (22) inked to the tooth (21) of the bajoyer, the bridge (13) of the weir, the counterweight  (18) attached to the lattice frame (4) by means of the bar (19) so as to prevent  the transmission of horizontal seismic forces to this framework and resist strong  earthquakes.  2. Automatic, autonomous and rising valve for new weirs, for  weirs built initially without valves in order to increase the normal level of retention and to increase the volume of the tank, as well as for weirs reconstructed in  purpose of increasing their capacity characterized by fully automatic operation  and autonomous from any device, from external energy and from the human factor, amount to leave  pass the water, the main support shaft (8) cylindrical, formed of a cylinder in two parts,  one of larger diameter, embedded in the trellis (4), the other of smaller diameter, this part introduced into the support (20) of the fixed articulation linked to the stack (2) of weir, threshold  (1) concrete with top (3), by means of support (20) of fixed articulation in horizontal direction  upstream-downstream, the three-dimensional wire mesh frame (4), which rotates around the axis  shaft (8) with the sheet (5) which intercepts the passage of water or lets it pass, pulling it  (7), the support (10) which serves as a support when the valve is closed, the beam (11) in reinforced concrete  which supports the supports (10), the seal (12) at the bottom of the valve, the seal  seal (22) inked to the tooth (21) of the bajoyer, the bridge (13) of the weir, the counterweight  (6) of slab with rib forming part of the trellis (4) three-dimensional and forming of this  a mixed structure.  3. Automatic, autonomous and rising valve for new weirs, for  weirs initially built without valves in order to increase the level of containment  normal and to increase the volume of the tank, as well as for weirs rebuilt in order to increase their capacity characterized by the fully automatic and autonomous operation of any device, external energy and human factor, amount to let pass the water, the main support shaft (8) cylindrical, formed of a cylinder in two parts, one of larger diameter, embedded in the trellis (4), the other of smaller diameter, this part introduced into the '' support which transmits horizontal forces downstream by rolling upstream and resting with the larger diameter part on the surface (9) of the weir stack, threshold (1) concrete with top ( 3), by means of support (20) of fixed articulation in a horizontal upstream-downstream direction, the three-dimensional wire mesh frame (4), which rotates around the shaft axis (8) with the sheet ( 5) which intercepts the passage of water or lets it pass, the tie (7), the support (10) which serves as a support that and the valve is closed, the beam  (11) in reinforced concrete which supports the supports (10), the seal (12) at the bottom of the valve, the seal (22) inked with the tooth (21) of the bajoyer, the bridge (13 ) of the weir, the counterweight (6) of slab with rib forming part of the trellis (4) three-dimensional and thus forming a mixed structure.  4. Automatic, autonomous and rising valve for new weirs, for  weirs initially built without valves in order to increase the normal level of retention and to increase the volume of the tank, as well as for weirs reconstructed in order to increase their capacity characterized by fully automatic operation  and autonomous from any device, from external energy and from the human factor, amount to let water pass, the main support shaft (8) cylindrical, formed by a cylinder in two parts, one of larger diameter, embedded in the frame in the form of a three-dimensional gantry, the other of smaller diameter, this part introduced into the support (20) of the fixed joint linked to the stack (2) of weir, threshold (1) in concrete with top (3), at  support means (20) for fixed articulation in the upstream-downstream horizontal direction, the portal frame  three-dimensional metal, which rotates around the shaft axis (8) with the sheet (5) which  intercepts the passage of water or lets it pass, the tie (7), the support (10) which serves as support  when the valve is closed, the beam (11) in reinforced concrete which supports the supports (10), the seal (12) at the bottom of the valve, the seal (22) inked with the tooth (21 )  of the bajoyer, the bridge (13) of the weir, the counterweight (18) hung on the frame in gantry  by means of the bar (19) so as to prevent the transmission of seismic forces  horizontal to this framework and withstand strong earthquakes.  5. Identical device as in claim 4 with the counterweight (6) in slab  rib instead of counterweight (18).  6. Automatic, autonomous and rising valve for new weirs, for  weirs initially built without valves in order to increase the level of containment  normal and to increase the volume of the reservoir, as well as for weirs rebuilt in  purpose of increasing their capacity characterized by fully automatic operation  and autonomous from any device, from external energy and from the human factor, rising to let water pass, the main support shaft (8) cylindrical, formed by a cylinder in two parts, one of larger diameter, embedded in the trellis (4), the other of smaller diameter, this part introduced into the support (20) of the fixed articulation linked to the stack (2) of weir, of threshold (1) in concrete with top ( 3), by means of support (20) of fixed articulation in the horizontal direction  upstream-downstream, the three-dimensional wire mesh frame (4), which rotates around the axis  shaft (8) with the sheet (5) which intercepts the passage of water or lets it pass, the support (10)  which serves as a support when the valve is closed, the beam (11) of reinforced concrete which supports the  supports (10), the seal (12) at the bottom of the valve, the seal (22) inked with the tooth (21) of the bayonet, the bridge (13) of the weir, the counterweight (6) of slab with rib  forming part of the three-dimensional lattice (4) and thereby forming a structure  mixed.  7. Automatic, autonomous and rising valve for new weirs, for  weirs built initially without valves in order to increase the normal level of retention and to increase the volume of the tank, as well as for weirs reconstructed in  purpose of increasing their capacity characterized by fully automatic operation  and autonomous from any device, from external energy and from the human factor, amount to leave  pass the water, the axis of rotation (34) at the top of the valve, the shaft (23) of the sheet metal valve  of sufficiently rigid steel, the part (24) in steel structure, which intercepts the passage  water, the bottom seal (25) fixed to the part (24), the counterweight constituted  a steel box (26) and counterweight (27), steel levers (28) welded to the shaft  (23) and to the box (26), a support (30) for the seal, the support stiffeners of the shaft  (35), intermediate shaft stiffeners (45), a rotary support cylinder (36) of  at each end of the shaft, the support (37) of the cylinder (36) on the stacks of the weir, the partial gear cylinder (38) on each of the side stacks, the side seals (40),  the rack (39) on each of the side stacks, the sheet (42) for sliding the seals  lateral, the downstream (44) and upstream (43) stops of the support cylinders.  8. Automatic, autonomous and rising valve device according to claim 7  characterized by two or more spans of automatic, autonomous and rising valves constituted according to the device of claim 7 which is repeated as many times as  what there are spans, the intermediate piers serving as supports for two adjacent valves.  9. Automatic, autonomous and rising valve device according to claim 7  characterized by intermediate piles (46) which do not cut the valve shaft, the  supports (47) of the shaft and the stops (48) of the shaft, the support (49) between the shaft and its support, the steel bars (50) for anchoring the intermediate stack (46 ) added to the weir  initial.