The present invention relates to a sluice gate installed in a sluice for water flow or ships. The gate accommodates high tide water, tsunami, high water (reverse flow from a main river to a tributary stream), ocean waves, floodwood flow etc. and includes a land lock gate.
A large scale gate provided against high tide water, tsunami etc. is well known.
The gate of Patent Document 1 is a flap gate, which includes a gate leaf (torsion structure) that has a thin wall closed cross-section, and axle type supports supporting the gate leaf. The gate leaf is supported by a foundation ground via the axle type supports and rotates around the axles.
Reference numeral 6 denotes a gate leaf (solid line, in a closed position), 7 denotes the gate leaf (dotted line, in an open position), 8 denotes a bottom support, 9 denotes a rotation axle, and 10 denotes a bracket.
The gate leaves 6 and 7 are fixed by welding etc. to the bracket 10 that is connected to the rotation axle 9. The bottom support 8 is sustained by a foundation ground.
When the gate is not in use, the gate leaf (in its open position) 7 is stored horizontally underwater as the dotted line shows. When in use, the gate leaf (in its open position) 7 rotates around the rotation axle 9, rises up, and moves to the position of the gate leaf (in its closed position) 6 of the solid line.
A characteristic in the deformation of the bending type structure is the parallel displacement of its cross-section while that of the torsion structure is the in-plane rotation of its cross-section. The rotation center of the cross-section is the axle type support that restricts the displacement of the cross-section. The torsion structure is distinguished from the bending type structure by whether or not there is a restriction point on the cross-section.
Structural characteristics of both of the structural types are remarkably different when their cross-section is a thin wall closed cross-section. In short, the torsion structure is characterized by (1) the thin wall closed cross-section and (2) the cross-sectional restriction.
The torsion structure resists a load by square of its closed cross-sectional area while the bending type structure and the axial type structure resist by the cross-sectional secondary moment and axial rigidity of their members, respectively.
A load applied to the torsion structure is transmitted to a sectional restriction point, and a torsion moment composed by the load and the reaction force at the restriction point is transmitted to the support span terminal of the structure due to a sectional torsion rigidity while the loads applied to the bending and axial type structures are directly transmitted to their support span terminals due to a sectional shearing rigidity and an axial rigidity, respectively.
The bending type and axial type structures are 3-dimensional structures whereas the torsion structure may be classified as 2.5-dimensional structure.
The torsion structure has various advantages due to the structural differences described above, and these advantages become more remarkable as the structure support span gets longer. In the case of a 400 m span class super large gate, for instance, its steel weight will be ½ to ⅓ or less of other structural types. The lower gate weight results in lower construction costs.
Although the torsion structure has an overwhelming advantage in cost, its application to a gate has been limited to a flap gate that is fixed on the foundation ground via axle type supports. This invention enables application of the torsion structure to, for instance, a tidal gate that moves laterally. The application is also applicable to a super large tidal gate having a structure support span between 200 to 600 m and more.
This invention shows resolutions to the following problems, contributing to implementation of a tidal gate of the torsion structure.
Problem 1: Lateral movement of a torsion tidal gate
Problem 2: Uneven settlement of a rail foundation
Problem 3: Alleviation of bending torsion
The invention implements the following gate functions: (1.1) Free twisting deformation, (1.2) Water pressure support while the gate is completely closed and (1.3) Water pressure support during gate movement. Following are explanations of each function.
A twisting deformation occurs in the torsion structure due to an applied load like water pressure, its own weight etc. As an additional bending deformation will occur in the structure if the center line of twisting in the structure is not straight, linearity of the line should be maintained so that a free twisting deformation without any additional restriction is possible.
(1.2) Water Pressure Support while the Gate is Completely Closed
When the gate is completely closed, maximum water pressure works on it, resulting in a twisting deformation of the torsion structure. In this condition, the working water pressure is surely transmitted from the gate rollers to the rail supporting the rollers.
The gate moves laterally while it is subjected to water pressure that corresponds to a gate operation condition. The lateral movement is made without the rollers running off the rail.
While a rail is installed for lateral movement of a torsion tidal gate, the rail foundation may be deformed due to uneven settlement of the foundation ground after construction of the gate has started. Lateral movement of the gate is made possible even if any uneven settlement occurs in the rail foundation.
Twisting of a structure includes simple torsion and bending torsion. Simple torsion generates the simple torsion moment, thereby generating the shearing stress of the simple torsion on a cross-section of the structure while bending torsion generates the bending-torsion moment, resulting in adding the shearing stress of the bending torsion to the shearing stress of the simple torsion. As the shearing stress of the simple torsion distributes uniformly over the cross-section whereas the shearing stress of the bending torsion distributes nonuniformly like big waveforms over the cross-section, resulting in increase in the maximum stress of their sum.
The sectional stress of the torsion sluice gate increases substantially due to existence of the bending torsion.
As the bending-torsion moment does not contribute much to transmission of the torsion moment since its magnitude is small, alleviation of the bending torsion leads to cost reduction of the torsion structure.
A sluice gate, which is equipped with a gate leaf of the torsion structure, a rail, and a plurality of axle type supports that works as a restriction point and moves along the rail, is proposed to implement a laterally sliding type opening/closing gate of the torsion structure at a reasonable cost. The axle type support includes a roller, cross-sectional form of the head region of the rail is a convex circular arc, and cross-sectional form of the tread surface of the roller is a concave circular arc whose radius corresponds to the radius of the convex circular arc of the head region of the rail. The roller and the rail work as an axle type support due to their good fit.
Alternatively, a plurality of rollers arranged so as to sandwich the head region of the rail may be provided.
1 denotes a gate leaf in a completely closed state. 2 denotes a gate leaf in a completely opened state. The sluice gate of
3 denotes a storage dock, 4 denotes a rail foundation and 5 denotes a lateral center line of the tidal gate. 100 denotes an axle type support that works as a restriction point of the gate leaf 1 (may be referred to as “torsion structure 1” hereafter) and moves along the rail described later. A plurality of the axle type support 100 is provided at the gate leaf bottom. The plurality of the axle type support 100 is aligned according to the rail arrangement (for instance, in a linear fashion). Refer to
The gate leaf 2 in the completely opened state is stored in the storage dock 3. During use, the gate is moved laterally up to the position of the gate leaf 1 in the completely closed state.
The rail foundation 4 in
The torsion structure is defined for this embodiment.
L denotes the span of the torsion structure. 11 denotes a thin wall closed cross-section, and 12 denotes a sectional restriction point (the rotation axle of the axle type support 100). Solid lines at both ends of the support span and dotted lines sandwiched by the solid lines in the elevation view 13a correspond to the locations of the thin wall closed cross-section 11, and the sectional restriction point 12 indicates a restriction point for in-plane displacement of the nearest cross-section.
Dotted lines in
Dotted lines in
a is an elevation view and
13 denotes a cross-section of a member (it may be written as “thin wall” hereafter) composing the torsion structure 1.
The thin wall closed cross-section 11 is in an upright position as shown in
The torsion structure 1 is deformed as shown in
The sectional restriction point 12 restricts the in-plane parallel displacement of the cross-section shown in the figure but does not restrict the rotation of the cross-section.
The torsion structure according to this Specification is characterized by the thin wall closed cross-section 11 composed by the thin wall 13 that is continuous and closed and the sectional restriction point 12 that restricts in-plane parallel displacement of the cross-section.
The axle type support 100 of Embodiment 1 is described according to
The head of the rail 14 supported by the rail foundation 4 is the circular arc 15 around the rail head center 16. The tread surface of the roller 17 is the circular arc 20 with a corresponding radius to radius of the rail head circular arc 15. The roller 17 is fixed to the gate leaf 1 (torsion structure 1) through the axle center 19 thereof.
Although nominal radii of the rail head circular arc 15 and the roller tread circular arc 20 are the same, a proper difference between the radii is necessary to realize a smooth fit between the rail 14 and the roller 17 while the roller 17 is moving laterally. The “corresponding radius” means a radius that has proper difference between the roller tread and the rail head.
a shows a state before deformation and
A free twisting deformation of the gate leaf 1 (corresponding to previously mentioned “(1.1) Free twisting deformation” of Problem 1) is possible without any additional bending deformation since the roller 17 rotates around the rail head center 16 and linearity of the twisting center line of the structure is maintained.
The roller load 21 will surely be transmitted to the rail 14 through the contact surface 22 since the roller load is directed at the rail head center 16 (corresponding to previously mentioned “(1.2) Water pressure support while the gate is completely closed” of Problem 1).
Running of the roller 17 off the rail 14 while the gate leaf 1 is moving laterally with an applied load is described according to
In
a shows the case where A is 0 degrees,
A rotational plane of the roller 17 including the center of the contact surface 22 is parallel to the cross-section including the roller center line 18 and the rail head center 16.
Force to make the roller 17 run off the rail 14 is a friction force on the contact surface 22 created by a downward component of movement of a point on the rotation plane due to the rotation of the roller 17. This friction force is given by Formula (1). On the other hand, an off-running prevention force or a force to prevent the roller from running off the rail is a component parallel to the roller center line 18 of the roller load 21 and given by Formula (2).
Friction force=roller load×cos(90−θ)×friction coefficient of contact surface (1)
Off-running prevention force=roller load×sin(90−θ) (2)
According to this result, it is clear that the roller 17 will not run off the rail 14 if A is less than 45 degrees.
It is possible that friction coefficient of the contact surface 22 in water will be 10% or less of the preliminary calculation since water can be expected to be a good lubricant. It is also possible that direction of the roller load 24 is much closer to the roller center line 18 than the case of θ=45 degrees. Accordingly, it is quite possible that the gate moves laterally without rollers running off the rail while water pressure corresponding to the gate operation condition is applied (corresponding to previously mentioned “(1.3) Water pressure support while the gate is moving” of Problem 1).
Embodiment 2 is explained while referencing
b shows a relationship between load during gate movement 25 and roller load 21 that are in equilibrium.
In
Embodiment 3 is explained while referencing
A plurality of the roller 17 normally stays on the rail 14 but some of them lift up off from the rail due to the uneven settlement. They are shown by blank rollers in the figure.
In the case of
In the case of
Therefore, let the gate leaf 1 be divided lengthwise into so many number of leaf blocks such that following capacity to the uneven settlement of the roller is improved. In the case of a bi-block gate leaf as shown on
A suitable division number should be selected according to anticipated amount of uneven settlement, number of rollers, roller strength etc., which are conditions concerning safety of a roller. This can prevent a roller from losing its function due to uneven settlement. The smallest division number is desired since gate leaf division is a cause of structural cost increase.
26 denotes a divided face, 27 denotes a torsion moment transmission bar, 28 denotes a torsion moment receiving hole, and 29 denotes a coupling force.
The torsion moment transmission bar 27 is fixed to a gate leaf 1R on the right side of the divided face 26. The tip thereof fits a gate leaf 1L on the left side of the divided face 26. Torsion moment of the gate leaf 1R on the right side of the divided face 26 is transmitted to the gate leaf 1L on the left side of the divided face 26 through the torsion moment transmission bar 27.
The tip of the torsion moment transmission bar 27 and the torsion moment receiving hole 28 have fit each other well. The torsion moment is transmitted in the form of a coupling force 29 from the tip of the torsion moment transmission bar to a sidewall of the torsion moment receiving hole 28. The torsion moment transmission bar 27 and the torsion moment receiving hole 28 move differently in order to follow uneven settlement of the rail foundation 14. In light thereof, the torsion moment receiving hole 28 is made to be a vertically long hole. It should be long enough so that the tip of the torsion moment transmission bar 27 and the torsion moment receiving hole 28 fit together well.
While there may be many alternatives for the mechanism of the coupling for transmission of the torsion moment of the divided face 26, the transmission is generally carried out in the form of a coupling force.
An additional device to make opposing divided faces 26 watertight is required.
Distance between the opposing divided faces 26 needs to be maintained while the divided blocks are moving, completely closed, and stored. The maintaining method depends upon pulling type, push type, self-propelling type etc., which are well-known lateral movement methods. Number of division is arbitrary but fewer is cost effective.
A warping alleviation method for the torsion structure is explained while referencing
30 denotes an s coordinate set along a center line of the thin wall closed cross-section 11, 31 denotes a positive direction of the s coordinate 30, and 32 denotes a shearing center of the thin wall closed cross-section 11.
ds denotes a small distance on the s coordinate 30. t denotes thickness of the thin wall at ds, 35 denotes a tangent line of ds, and rs denotes the length of a normal from the shearing center 32 to the tangent line 35.
Warping of the thin wall closed cross-section 11 is expressed by function ψ of Formula (3). As included in Formula (3) denotes area of the thin wall closed cross-section 11. ψ0 (warping constant) is the value of ψ at its contour integration starting point and is expressed by Formula (4). Integration of Formula (3) and Formula (4) is executed on the s coordinate 30.
t denotes “thickness at an arbitrary point on the thin wall closed cross-section.” rs denotes “the length of a normal from the shearing center of thin wall closed cross-section to the tangent line at the point.”
The value of (wall thickness at arbitrary point on the thin wall closed cross-section)×(length of a normal from the shearing center of thin wall closed cross-section to the tangent line at the point) is a constant.
t×rs=constant on each cross-section=C (5)
Both ψ and ψ0 are zero when Formula (5) is substituted for Formula (3) and Formula (4) and integration of these formulas is executed. As a warp of the cross-section is zero as long as the warping function ψ0 and the warping constant ψ0 are zero, vertical stress proportional to the warp is also zero, and bending-torsion shearing stress in equilibrium with the vertical stress is also zero. In short, alleviation of bending torsion is realized (Problem 3).
A result of the warping alleviation method proposed in this embodiment is explained using a specific cross-sectional shape.
The left side of
Lf denotes half of flange width, Lw denotes half of web height. tf denotes thickness of the flange, and tw denotes thickness of the web.
Formula (5) on the zero-warp condition becomes Formula (6) since the shearing center 32 coincides with the center of the figure.
tf=tw×Lw÷Lf (6)
tf is approximately 12.4 mm when calculated by Formula (6) based on Lf, Lw and tw shown on the right side of
tf is 34 mm in
Bending-torsion shear flow as well as warping function ψ approach zero as tf approaches 12.4 mm. Bending-torsion shear flow corresponds to shearing stress distribution due to bending-torsion moment.
ψ0 and qw0 relating to magnitude of warping and bending-torsion shearing stress respectively decrease rapidly toward a zero-warp point. Cbd and Jt also decrease. Impact of decrease in Jt is very important. As Jt takes a main role in deformation control of the torsion structure, its decrease leads to increase in deformation, and cancellation of the warping (form coefficient) reduction effect due to the relationship: bending-torsion stress=form coefficient×deformation×spring constant may be made. Jt may be compensated by change in the closed cross-sectional form.
For instance, cut in gate weight is possible by increasing Lf. While theoretical gate weight becomes minimal when zero-warp condition is achieved, an object of warping reduction in optimum design is cost reduction. As cost component factors include material, fabrication, transportation, site construction, maintenance, operation etc., the minimum gate weight does not necessarily mean the minimum cost. For instance, there is an option that a high tensile steel plate having a custom-ordered thickness is fit in the stress increased zone so as to keep the minimum gate weight. However, it may be a better idea in terms of cost to increase the gate weight so as to maintain the material strength since the cost of material and fabrication rises.
So far, stress generated by overall structural deformation due to simple torsion, bending torsion, warping, bending etc. is considered a sectional stress. But partial stresses, such as bending of gate plates and their stiffeners due to applied water pressure, partial bending due to reaction forces applied to supports and support ends etc., must also be considered. Accordingly, a torsion structure designed according to zero-warp condition is not assured a minimum weight. Since an actual conventional means for finding an optimum design in cost is to select the best one among multiple plans, a planar range of optimum design selections composed by a line approaching the zero-warp point and a sectional form change line so as to compensate Jt is targeted. This idea is the background of a proposal, according to the present invention, that the value of (thickness at an arbitrary point on the thin wall closed cross-section)×(length of a normal from the shearing center of thin wall closed cross-section to the tangent line at the point) must be kept near a constant point within the range required by the optimum design. The optimum design denotes an advantageous design mainly in cost, nearly satisfying the zero-warp condition.
Hg denotes lens gate height, r denotes thin wall radius, β denotes thin wall angle, t denotes thin wall thickness, s denotes shearing center, and i and o both denote the center of the thin wall radius r.
As the shearing center s coincides with the center of the figure, Formula (5) of the zero-warp condition can be converted to Formula (7).
η(α)=(r−L(s,i)÷(r−L(s,i)×cos(α)) (7)
where η(α) denotes a ratio of thickness for the zero-warp condition to the thin wall thickness. a denotes an angle between the thin wall radius r and a line segment oi, and 0≦α≦β. L (s, i) denotes a line segment si.
The right side of
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2012/072416 | 9/4/2012 | WO | 00 | 4/6/2015 |