Scheme Exploration and Performance Analysis of 800-Meter Superlarge Span Structure

Superlarge span structure is one of the important trends for future building development. Under the background of the 800-meter superlarge span dome project proposed by China Construction Group, this paper focuses on the structural optimization and performance analysis of this superlarge span structure. 'e previous ideas of the superdome and the maximum span of existed spatial structures are reviewed, and some structural form selection principles are put forward which lay foundation for structural selection. 'e applicability of high-strength steel and aluminum alloy is also discussed. It is demonstrated that the high-strength steel and aluminum alloy contribute little to structural comprehensive performances.'en, considering the effects of grid division, members topological relation, and surface shape, six kinds of rigid systems are contrastively studied to determine the optimal scheme.'e structural performances along with the increasing span are explored in detail. To further reduce the structural weight and improve mechanical performance, a new composite scheme and the cable-stayed megastructure are proposed and studied. 'e research methods and performance analysis results can provide significant references for the following research on the superlarge span structure.


Introduction
As new materials and advanced engineering technologies increasingly emerge, the development of the large span spatial structure has made great strides and the concept of the superlong span dome has been put forward.Such a superdome can keep a warm and humid climate inside even when built in the cold and dry area.Moreover, by unified planning in such a grander scale, the superdome can also make a significant contribution to energy saving and emission reduction of the modern cities.
From the 1960s, some leading architects began to dig into this field and raised a number of conceptual designs.Fuller put forward a famous project named "Manhattan dome" [1].A super geodesic dome in the size of 3200 m diameter and 1600 m height is designed to cover the Manhattan block.It not only provides a comfortable environment but also reduces the large expenses of air conditioning and winter snow removal.Frei Otto proposed a superdome project named "the Arctic city" [2], a 2000 m diameter inflatable membrane dome built in the Arctic, and aimed at improving the working condition for polar scientists, as shown in Figure 1(a).Besides, to resist hurricanes and heat waves, American engineers proposed to build a superdome in the size of 1600 m diameter and 450 m height over Houston [3], as shown in Figure 1(b).
e design consulted the three-layer structure of the Garden of Eden in Britain.An American company specializing in the design and installation of the cable membrane structure proposed the "Spantheon system" for the superlong span dome, as shown in Figure 1(c).It consists of a number of huge arch trusses covered by the light cable membrane structure [4].But this research field has just started in China.China Construction Group is carrying out the project named "TianQiong," as shown in Figure 1(d).e project is an 800meter span superdome isolating the external harsh natural condition and simulating the real climate inside.e tropical ocean even lifestyle can be created in severe cold regions. is paper initially explores the comprehensive performance of the 800-meter span structure.Some basic principles are put forward, and the applicability of highstrength steel and aluminum alloy is also discussed.Six rigid structural systems and two rigid-flexible composite schemes are studied by the numerical method.
e changes of structural performance along with the increasing spans are also given.en, the optimum scheme for the 800 m span superdome, in certain conditions, will be obtained through contrastive analysis.1 gives representative projects of the common spatial structure forms which have the largest spans.It can be seen clearly that the maximum span of the spatial structure has already exceeded 300 m, and the suspension bridge has reached nearly 2000 m.What kind of structural system is the best choice for the superdome?From the existing engineering practices, some basic principles can be summed up: (1) the transmission path of internal force should be simple and efficient.e components mainly in axial stress can make full use of material properties.(2) e light roofing material should be used to cover the larger area with less material and improve the daylighting.(3) e main structure should be landed on the ground, and the horizontal thrust needs to be reduced as far as possible to relieve the pressure of foundation.

Load Values and Design Combinations.
e loads in the design stage consider dead load, live load, wind load, and temperature effect.e dead load includes the roof load and the weight of structural components.e roof load is calculated by the developed area in the value of 100 kg/m 2 .e live load is calculated by the projection area in the value of 50 kg/m 2 .According to the Chinese load code for the design of building structures (GB50009-2012) [19], the wind load takes the B class of surface roughness.
e basic wind pressure is 0.5 kN/m 2 , and the wind vibration coefficient is 1.6.e shape coefficient is taken according to the rotating dome in Table 8.3.1 of the Chinese load code (GB50009-2012).e whole structure temperature effect is considered as ± 30 °C. e load combinations of the bearing capacity limit state are shown in Table 2.When it comes to structural serviceability limit state, load combinations only consider the combined factor in Table 2.

Structural Control Indexes.
Strength index is the stress ratio of member cross section in the full stress design, and the limit is 0.8 with the consideration of member stability.

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For the cables, the maximum axial force in the ultimate state of load capacity is not more than 0.5 times the minimum breaking force and cables in the main structure are not allowed to appear slack.In addition, according to the technical specification for space frame structures (JGJ7-2010) [20], the deflection limit of single-layer and doublelayer latticed shells are L/400 and L/250, respectively, and L is the structural span.In this study, the deflection limit is assumed to L/500.With the span increasing, the stability has gradually become the control factor of the design.e elastic-plastic stability coefficient is calculated under the standard combination of the dead load and live load, and the elastic stability coefficient is also used as a reference.

Material Selection.
Taken the double-layer reticulated shell in the span of 800 m and height of 200 m for instance, the applicability of high-strength steel and aluminum alloy is discussed.According to the code for the design of steel structures (GB50017-2003) [21], the code for the design of high-strength steel structures (under preparation) [22,23] and the code for the design of aluminum structures (GB50429-2007) [24], three types of high-strength steel including Q420, Q690, and Q960 and the high-strength aluminum alloy 6061 T6 are selected for the structural design.e Q420 type is designed according to the front two codes, respectively (Q420S for the steel structures code and Q420 for the high-strength steel structures code).
e material consumption, deflection, and stability performance are shown in Figure 2. Compared with Q420S, 6061 T6 type can almost reduce structural weight by half, but the deflection increases about 65.8%.e density and elastic modulus of the aluminum alloy is only about 1/3 of steel.e member section and material volume usage are both larger, and the structure stability becomes worse.Besides, the welding performance of the aluminum alloy is poor, and joint connection is more difficult.e material consumption of Q420 can be reduced by 7.7% compared with Q420S.
From Q420 to Q960, the material consumption only decreases by 7.0% which indicates that raising material strength contributes little to the economy.e deflection is almost inversely proportional to the material consumption.
e elastic stability coefficients decrease while the elasticplastic stability coefficients increase.Because the elastic stability coefficient is mainly affected by the member section, and the elastic-plastic stability coefficient is mainly affected by the yield point of the material.erefore, the application of high-strength steel and aluminum alloy has little improvement in the structural comprehensive performances.erefore, the Q420S type is used in the following scheme study.Besides, the cable in strength of 1860 MPa is used according to the technical specification of cable structures (JGJ257-2012) [25].

Rigid Structural Systems for the Superdome
Rigid structural systems are the most widely used forms in spatial structures.
e reticulated shell and reticulated Advances in Civil Engineering megastructure are all typical representatives.ey have the concise and e cient load transfer path, and the structures are mainly in the state of membrane stress while the components are axially loaded.

Structural Design.
e reticulated shell and reticulated megastructure are studied considering the e ects of grid division, members topological relation, and surface shape.As shown in Figure 3, six forms are involved in this study including Kiewitt pyramidal spherical reticulated shell (KPS), geodesic pyramidal spherical reticulated shell (GPS), Kiewitt pyramidal catenoid reticulated shell (KPC), Kiewitt spherical reticulated megastructure (KSM), rib-circle spherical reticulated megastructure (RSM), and rib-circlereinforced spherical reticulated megastructure (RRSM).e structural span is 800 m, and the height is 200 m.According to the technical speci cation for space frame structures (JGJ7-2010), the ratio of thickness to span is between 1/60 and 1/30, and the practical ratio decreases gradually with the increase of span.In this study, the ratio of thickness to span is 1/80.For the reticulated megastructure, the size and height of space truss are both 20 m while in the strengthened region, these values are both 10 m.Structures are all supported by xed hinge bearings of bottom chords and radial constraints are all released.Seen from the top view, the megastructure has better daylighting performance than the reticulated shell.
Figure 4 gives the statistical graphs for member section distribution of di erent schemes.For the reticulated shells, more than 98% of components have sections smaller than ϕ800 × 24 mm, and the biggest section is 2400 × 76 mm.For the reticulated megastructures, about 70% of components have section smaller than ϕ800 × 24 and the biggest section is 3600 × 120 mm. e element amount of RRSM is obviously more than the other two schemes.More than 83% of components have sections smaller than ϕ800 × 24 mm.For the member section design, more than 85% of members are controlled by the design load combination of the dead load and live load.e wind load and temperature e ect have little e ect on the design internal force.

Performance Analysis.
Figure 5 shows the analysis results of steel consumption, de ection, and stability performance.For the reticulated shells, the steel consumption of the geodesic type is 2.3% lower than the Kiewitt type, but the de ection is 12.3% larger than the latter.e catenoid reticulated shell consumes 3.9% more steel and has 5.6% smaller de ection than the spherical reticulated shell.ere is little di erence of stability performance among three schemes.For the reticulated megastructures, the steel consumption of the Kiewitt type is 3.1% higher than the ribcircle type, but the de ection is 5.9% smaller than the latter.e rib-circle-reinforced type consumes 12.3% more steel and has 6.0% smaller de ection than the rib-circle type.Moreover, the rib-circle type has the poorer stability performance than the other two schemes.On the whole, the reticulated shells have relatively smaller material consumption and de ection than the reticulated megastructures.
e stability performance is similar and little subjected to the in uence of imperfection.Considering the structural design and overall structural performance, the Kiewitt pyramidal spherical reticulated shell and Kiewitt spherical reticulated megastructure are the optimal schemes.For these two schemes, considering the structural span range from 100 m to 800 m with the increment of 100 m, the structural performances along with increasing spans are explored.Figure 6 shows the analysis results for steel consumption, de ection, and stability performance.e steel consumption and de ection of these two schemes both increase as the structural span becomes larger.e megastructure always consumes a little more steel material than the reticulated shell, and the former has larger de ection than the latter.As the structural span increases, the differences of steel consumption are almost invariants all  Advances in Civil Engineering around 20 kg/m 2 , while the differences of the deflection become larger changing from 25 to 125 mm.Besides, for the stability performance, the elastoplastic stability coefficient of the reticulated shell considering initial imperfection goes down faster than the megastructure.When the span is larger than 300 m, the megastructure has better stability performance.

Rigid-Flexible Composite Systems for the Superdome
From the rigid system above, the great structural weight is the most important load and even becomes a key factor for determining the feasibility of the scheme.To improve the structural performance and reduce the structural weight, the rigid-flexible composite systems consisting of rigid components and flexible cables are taken into consideration.Because of the enormous support reaction the shell has to be supported on the ground.In order to obtain enough service space, the combination of the central suspended lattice shell and double-reticulated shell around can be a new scheme.is new composite scheme and the cable-stayed megastructure are taken into consideration for the superdome.

Structural Design.
e rigid-flexible composite schemes are shown in Figures 7(a is 10 m, and the top 17 loops are replaced by the suspended lattice shell.ere are 16 groups of hoop cables in the horizontal distance of 12 m.From inside out, every group of hoop cables has a corresponding number from 1 to 16. e cablestayed megastructure is composed of rib-circle spherical reticulated megastructure and 9 groups of stay cables.e main ribs are made up of three-layer space truss, and each group of stay cables has four cables connected with adjacent nodes of intersection on main ribs.e structural spans are both 800 m, and the height is 200 m; they are both supported by xed hinge bearings, and radial constraints are all released.e design process of rigid-exible composite systems is shown in Figure 8. Fully stressed design and form-nding analysis should be carried out repeatedly and alternately until the structure gets to a steady state.e inverse iteration method is used to adjust the structural lofting state shape, and the tension compensation method is used to adjust the cable initial pretension of the lofting state [26].e control indexes of form-nding analysis are geometric con guration deviation and cable pretension design value deviation in the prestressed equilibrium state.9 gives the pretension design results and the ratio of pretension to breaking force for each hoop cable of the new composite scheme.e cable pretension increases from the inside out.e cables in external loops contribute more to the structure.e pretension design values of the cable-stayed megastructure are 7622 kN of inner stay cables and 10857 kN of outer stay cables.

Performance Analysis. Figure
e element ratio statistics of rigid components are shown in Figure 10.e steel usage of the new composite scheme is 170.1 kg/m 2 , which is 5.6% less than the doublelayer reticulated shell scheme.In the part of the double-layer

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Advances in Civil Engineering reticulated shell, more than 90% of components have sections smaller than ϕ600 × 20 mm.However, the central suspended lattice shell obviously has much bigger sections.More than 94% of components have sections greater than ϕ600 × 20 mm, and the biggest section is 2800 × 58 mm.For the cable-stayed megastructure, the steel consumption is 140.5 kg/m 2 , which is 29.2% less than the megastructure scheme.More than 71% of components have sections smaller than ϕ400 × 16 mm, and the biggest section is 1600 × 38 mm. Figure 11 shows the displacement under the load case of the dead and live loads under the limit state of serviceability.
e component weight is taken into consideration when solving the structural stretch-forming state, and the maximum deformations of the new composite scheme and cablestayed megastructure are 0.55 m and 1.19 m.Besides, the elastic-plastic stability coe cients of the new composite scheme and cable-stayed megastructure can reach 3.42 and 4.59.When L/300 initial imperfection is considered, these coe cients are 2.94 and 4.37, respectively.erefore, the cable-stayed megastructure has lower steel consumption and good daylighting performance.
e section size of steel members has also been reduced e ectively.But the height of the host tower, which is ignored in simulation, is over 200 m, and the di culty of construction increases overall.

Conclusions
is paper initially explores the suitable structural systems including rigid systems and rigid-exible composite systems for the 800 m span superdome.Some conclusions can be drawn as follows:      Advances in Civil Engineering (1) e application of the high-strength steel and aluminum alloy has little improvements in structural performances.High-strength improves the elasticplastic stability but contributes little to the material consumption.Aluminum alloy signi cantly reduces the structural weight, but the member section and material volume usage both increase and the structure stability becomes worse.(2) Considering the e ects of grid division, members topological relation, and surface shape, the Kiewitt pyramidal spherical reticulated shell and Kiewitt spherical reticulated megastructure are the optimal rigid systems.e steel consumptions are 180.1 kg/m 2 and 198.5 kg/m 2 , respectively.(3) As the structural span becomes larger, the steel consumption and de ection both increase and the megastructure always consumes a little more material and has larger de ection than the reticulated shell.When the span is larger than 300 m, the megastructure has better stability performance.(4) A new composite scheme and the cable-stayed megastructure are proposed for the superdome.e cable-stayed megastructure has lower steel consumption with the value of 140.5 kg/m 2 and better structure stability.
e section size of steel members has also been reduced e ectively.
Data Availability e data used to support the ndings of this study are available from the corresponding author upon request.

Figure 2 :
Figure 2: Comparison of di erent material types: (a) material consumption and de ection; (b) stability coe cient.
the reticulated shell Material consumption of the megastructure Deflection of the reticulated shell Deflection of the megastructure

Table 1 :
Representative works of different spatial structure forms.

Table 2 :
Load combinations of the bearing capacity limit state (partial factor × combined factor).