CN104989152A - Crisscross overhead power transmission tower - Google Patents

Abstract

The invention provides a crisscross overhead power transmission tower, which comprises four upright posts 2, wherein the four upright posts 2 form corner posts; a plurality of groups of crisscross inclined supporters are vertically and sequentially arranged on the side surface of a tower; each group of crisscross inclined supporters is formed by crossing two inclined support rods 1; and the upper end and the lower end of each inclined support rod are connected onto the two upright posts 2 arranged at the same side surface of the tower. The crisscross overhead power transmission tower is characterized in that annular energy dissipation devicesarearranged in triangular regions, formed between the inclined support rods 1 and the upright posts 2, on the side surface of the tower in a position with the weak structure characteristics found out through structure analysis and field measurement; the diameters of the annular energy dissipation devicesare70 percent of internally tangent circles in the triangular regions; and the annular energy dissipation devicesareconnected in positions of the tangent points of the internally tangent circles, the upright posts 2 and the inclined support rods 1 through support rod elements 3. The crisscross overhead power transmission tower has the advantages that the integral rigidity and the local bearing force of the structure of the overhead power transmission tower can be improved; a part of energy can be dissipated under the effect of a typhoon load; and further, the integral performance of the overhead power transmission tower is improved.

Description

A kind of cruciform shape overhead power transmission shaft tower

Technical field

The present invention relates to a kind of cruciform shape overhead power transmission shaft tower being provided with dissipative member.

Background technology

Overhead power transmission shaft tower line system is the carrier of high load capacity electric energy conveying, is important lifeline engineering structures.Overhead power transmission shaft tower line system has the features such as housing structure is high, span large, overall structure is more soft.This structural system is comparatively responsive to wind load, and the dynamic collapse of (as under typhoon effect) under vibrating fatigue damage and extreme condition easily occurs.

(four root posts form shaft tower to the cruciform shape overhead power transmission shaft tower of past design-build, shaft tower side is multiple cruciform shape diagonal braces) there is the phenomenon of not establishing secondary diagonal brace, and wind load design load value is less in the design process, cause the type overhead power transmission shaft tower wind loading rating poor.How to reinforce the type overhead power transmission tower structure, improving it, to combat a natural disaster performance be one of problem demanding prompt solution in overhead power transmission shaft tower field.

Traditional structural wind resistance design method utilizes the ability of self to carry out dissipate vibrational energy, as strengthened the sectional dimension of component or improving the strength grade etc. of material.For reducing the vibratory response of overhead power transmission shaft tower, except the antivibration of studying bearing system itself and detailing requiments, also need to study vibration control technology.Structural vibration control can alleviate the damage under the effect of structure outer load effectively, and then improves the performance of taking precautions against natural calamities of structure.Vibration isolation can consume vibrational energy by vibration damping, isolation mounting, or offsets the impact of external load effect on structure by applying energy.Specifically install certain device, mechanism or minor structure at some position of structure, to change or the dynamic characteristics of adjust structure or dynamic action, make the dynamic response under the effect of structure outer load obtain conservative control.Therefore, can consider that on overhead power transmission tower structure, set up energy-dissipating device carries out wind dynamic control to it.

Metallic yield damper is constant and reduce in maintenance expense and have very outstanding feature, the advantages such as the annular energy consumer Maintenance free be made up of metal damper, has good endurance, and life cycle is long in Long-Time Service function.Therefore, annular energy consumer can be arranged on cruciform shape overhead power transmission tower structure as damper device, wind dynamic control is carried out to it.

Summary of the invention

Technical problem to be solved by this invention, is just to provide a kind of cruciform shape overhead power transmission shaft tower, can effectively controls wind and shake.

Solve the problems of the technologies described above, the technical solution used in the present invention is:

A kind of cruciform shape overhead power transmission shaft tower, described shaft tower comprises four root posts 2 forming corner post, shaft tower side is provided with many group cruciform shape diagonal braces up and down successively, often organize cruciform shape diagonal brace to be made up of two hounds 1 intersections, the upper and lower side of hound is connected on two root posts 2 of described shaft tower ipsilateral, it is characterized in that: on the shaft tower side of the architectural characteristic weak part found out by structural analysis and field measurement, by in the Delta Region formed between hound 1 and column 2, be provided with the annular energy consumer that diameter is 70% of described Delta Region inscribed circle, described Behavior of Circular Ring Energy Dissipator is connected to the cusp position of described hound 1 and column 2 and described inscribed circle by supporting rod 3.

Described Behavior of Circular Ring Energy Dissipator 4 is connected by coupling assembling with between supporting rod 3, coupling assembling is 2 band steels of overlapping laminating, hole is formed respectively to outside sweep in the middle of two band steels, described hole coordinates the rod member diameter of described Behavior of Circular Ring Energy Dissipator annulus, two band steel two ends all have bolt connection through hole, respectively in order to lock Behavior of Circular Ring Energy Dissipator annulus and to be connected supporting rod 3.

Described supporting rod 3 is Q235 steel band steel.

Described Behavior of Circular Ring Energy Dissipator refers to common Behavior of Circular Ring Energy Dissipator, dicyclo ringmild steel energy dissipator or Behavior of Circular Ring Energy Dissipator of putting more energy into.

Described tower structure characteristic weak part can be found out by the structural analysis of prior art and field measurement.

Such Behavior of Circular Ring Energy Dissipator is integrally formed with cruciform shape overhead power transmission shaft tower, and overhead power transmission Lifting Method in Pole Tower Integral Hoisting rigidity improves.

Owing to adopting such scheme, the invention has the beneficial effects as follows:

1) this shaft tower can improve integral rigidity and the local bearing capacity of structure.

2) under typhoon load action, Behavior of Circular Ring Energy Dissipator deforms, dissipation part energy, and then improves the overall performance of overhead power transmission shaft tower.

3) this tower structure is simple, and designability is strong, have employed metal energy consume mechanism, simple structure, process easy, easy to use.

4) take up room little, cost is low.

Accompanying drawing explanation

Fig. 1 a is the unguyed front schematic diagram of certain overhead power transmission shaft tower hypomere;

Fig. 1 b is the schematic diagram after certain overhead power transmission shaft tower hypomere is reinforced;

Fig. 2 is the supporting rod be connected with Behavior of Circular Ring Energy Dissipator for overhead power transmission shaft tower;

Fig. 3 is the common Behavior of Circular Ring Energy Dissipator figure for reinforcing built on stilts transmission tower;

Fig. 4 a is a kind of self-locking structure elevation designed for common Behavior of Circular Ring Energy Dissipator;

Fig. 4 b is the lateral view of Fig. 4 a;

Fig. 5 is the usage schematic diagram of self-locking structure shown in Fig. 4;

Fig. 6 is the common Behavior of Circular Ring Energy Dissipator having installed self-locking structure, and wherein the position of self-locking structure structure in Behavior of Circular Ring Energy Dissipator can regulate arbitrarily according to the installation site of Behavior of Circular Ring Energy Dissipator in overhead power transmission tower structure.

Reference numeral in figure: 1-overhead power transmission shaft tower hound, 2-overhead power transmission shaft tower column, the supporting rod that 3-Behavior of Circular Ring Energy Dissipator is connected with overhead power transmission shaft tower, 4-Behavior of Circular Ring Energy Dissipator, the through hole of 5-supporting rod, Behavior of Circular Ring Energy Dissipator self-locking structure designed by 6-, 7,8-self-locking structure through hole, 9,10-supporting rod is connected the bolt adopted with self-locking structure.

Detailed description of the invention

Below in conjunction with accompanying drawing, the invention will be further described.

Cruciform shape overhead power transmission shaft tower embodiment of the present invention, shaft tower comprises four root posts 2 forming corner post, shaft tower side is provided with many group cruciform shape diagonal braces up and down successively, often organize cruciform shape diagonal brace to be made up of two hounds 1 intersections, the upper and lower side of hound is connected on two root posts 2 of shaft tower ipsilateral.On the shaft tower side of the architectural characteristic weak part found out at structural analysis and the field measurement by prior art, by in the Delta Region formed between hound 1 and column 2, be provided with the annular energy consumer that diameter is 70% of described Delta Region inscribed circle, Behavior of Circular Ring Energy Dissipator is connected to the cusp position of hound 1 and column 2 and inscribed circle by coupling assembling by supporting rod 3.Supporting rod 3 is Q235 steel band steel, and two ends have connecting through hole.

Coupling assembling is 2 band steels of overlapping laminating, hole is formed respectively to outside sweep in the middle of two band steels, hole size coordinates the rod member diameter of Behavior of Circular Ring Energy Dissipator annulus, and two band steel two ends all have bolt connection through hole, respectively in order to lock Behavior of Circular Ring Energy Dissipator annulus and to be connected supporting rod 3.

Behavior of Circular Ring Energy Dissipator refers to common Behavior of Circular Ring Energy Dissipator, dicyclo ringmild steel energy dissipator or Behavior of Circular Ring Energy Dissipator of putting more energy into.

Figure 4 shows that the self-locking structure be arranged on Behavior of Circular Ring Energy Dissipator of design, corresponding adjustment can be carried out according to the installation site of designed Behavior of Circular Ring Energy Dissipator in overhead power transmission tower structure in its installation site, easy for installation, fast.Fig. 6 is the Behavior of Circular Ring Energy Dissipator having installed self-locking structure.

When wind action, under the effect of horizontal force, can there is relative displacement between column and hound in overhead power transmission tower structure.Behavior of Circular Ring Energy Dissipator is connected between overhead power transmission tower structure column and hound by supporting rod, not only can improve the local bearing capacity of overhead power transmission tower structure, rigidity and stability, and the part energy that can dissipate under typhoon load action, and then improve the overall wind resistance of overhead power transmission shaft tower.

Claims (3)

1. a cruciform shape overhead power transmission shaft tower, described shaft tower comprises four root posts (2) forming corner post, shaft tower side is provided with many group cruciform shape diagonal braces up and down successively, often organize cruciform shape diagonal brace to be made up of two hounds (1) intersection, the upper and lower side of hound is connected on two root posts (2) of described shaft tower ipsilateral, it is characterized in that: on the shaft tower side of the architectural characteristic weak part found out by structural analysis and field measurement, by in the Delta Region formed between hound (1) and column (2), be provided with the annular energy consumer (4) that diameter is 70% of described Delta Region inscribed circle, described Behavior of Circular Ring Energy Dissipator (4) is connected to the cusp position of described hound (1) and column (2) and described inscribed circle by supporting rod (3).

2. cruciform shape overhead power transmission shaft tower according to claim 1, it is characterized in that: described Behavior of Circular Ring Energy Dissipator (4) is connected by coupling assembling with between supporting rod (3), coupling assembling is (2) root Q235 steel band steel of overlapping laminating, hole is formed respectively to outside sweep in the middle of two band steels, described hole coordinates the rod member diameter forming described Behavior of Circular Ring Energy Dissipator annulus, two band steel two ends all have bolt connection through hole, respectively in order to lock Behavior of Circular Ring Energy Dissipator annulus and to be connected supporting rod (3).

3. cruciform shape overhead power transmission shaft tower according to claim 2, is characterized in that: described Behavior of Circular Ring Energy Dissipator refers to common Behavior of Circular Ring Energy Dissipator, dicyclo ringmild steel energy dissipator or Behavior of Circular Ring Energy Dissipator of putting more energy into.