COMMENTS ABOUT THE DESIGN OF RUNWAY GIRDERS ACCORDNG TO NEW EN STANDARDS

COMMENTS ABOUT THE DESIGN OF RUNWAY GIRDERS ACCORDNG TO NEW EN STANDARDS Helmuth Köber, Bogdan Ştefănescu & Şerban Dima Steel Structures Department Technical University of Civil Engineering Bucharest

The present paper is intended to illustrate some particular aspects in using the new European standard EN 1993-6: 2007 (Eurocode 3: Design of steel structures Part 6: Crane supporting structures) and the other involved Eurocodes regarding the design of runway beams for travelling cranes. References are also made to the Romanian and German design regulations in this matter. Two kind of simply supported runway girders were analyzed to show these particular aspects: - 9 meters span girders for two overhead travelling cranes, having each a hoist load of 20 tons; - 6 meters span girders for an underslung travelling crane, having a 5 tons hoist load. 2

Two overhead traveling cranes: - hoist load of 20tons HC2, S-class S4; - 16.5m crane girder span; - both traveling cranes are working together. 3

An underslung traveling crane: - hoist load of 5tons, HC4, S-class S7; - 6.0m girder span; - a single crane is working on the girder. 4

STAS 10101/2A2-78, Actions due to the exploitation process, Loads due to travelling cranes Eurocode 1, EN 1991-3: Actions on structures, Part3: Actions induced by cranes and machinery Maximum vertical wheel load, Q r,max Longitudinal forces caused by acceleration and deceleration of the crane, H L Longitudinal buffer forces related to movements of the crane, H B,1 Transverse forces caused by acceleration and deceleration of the hoist block, H T,3 Transverse forces caused by skewing of the crane, H S 5

Groups of loads according to STAS 10101/0-78 Actions for Constructions. Classification of Actions. Groups of Actions Σn i P i + Σn i C i + n g Σn i V i n i = 1,2 for vertical crane loads n i = 1,3 for horizontal crane loads n g = 1,0 for a single considered traveling crane n g = 0,9 for two considered traveling cranes Groups of loads according to EN 1990:2002 Basis of Structural Design respectively CR0 2005 Basis of Design. Basis of Structural Design for Construction γ Q,1 = 1,5 1,35ΣG j + 1,5Q 1 + 1,05ΣΨ 0,i Q6 i

Dynamic factors STAS 10101/2A -78 20tons traveling cranes (Hoisting Class HC2): Ψ = 1,3 0,1 = 1,2 for vertical crane loads (two traveling cranes acting together), Respectively Ψ = 1,3 (for a single considered traveling crane) α = 1,8 for horizontal crane loads 5tons traveling crane (Hoisting Class HC2): Ψ = 1,5 for vertical crane loads (for a single considered traveling crane) α = 2,2 for horizontal crane loads 7

Groups of loads considered as one characteristic crane action (extracted from EN 1991 3:2006 table 2.2) The self-weight of the crane Qc and the hoist load Qh are 8 amplified by different dynamic factors.

The greatest value of the bending moment on the runway girder is generally obtained with group 1 of loads. For this group the self-weight of the crane Qc and the hoist load Qh are amplified by different dynamic factors (for Qc, respectively for Qh). Most of travelling cranes producers offer only the characteristic values for the relevant vertical wheel loads, where the influences of Qc and Qh are not separated. Following this, these producer s values cannot be used for the procedure recommended by EN 1991 3:2006. 9

MAXIMUM VERTICAL WHEEL LOADS 200 160 120 80 Poduri 20tf - Apăsări maxime pe roată 26,48% for two 20t cranes 5,07% for one 20t crane Ψ = 1,2 φ 2 = 1,12 ; φ 1 = 1,0 40 0 STAS 10101 SR EN grup1 SR EN grup5 (kn) 154.41 195.30 178.71 γ Q,1 = 1,5 n i = 1,2 Ψ = 1,5 φ 2 = 1, 27 ; φ 1 = 1,0 75 60 45 30 15 Pod 5tf - Apăsări maxime pe roată 6,26% for one 5t crane 0 STAS 10101 SR EN grup1 SR EN grup5 10 (kn) 62.39 58.73 48.82

VALUES OF THE DYNAMIC FACTOR φ 5 The proper choice of the values for the dynamic factor according to table 2.6 from EN could be argued. There is a lack of information for choosing a value between the limits given in that table (the limit between smoothly and sudden changes of the 11 forces is not defined).

Longitudinal buffer forces related to movements of the crane Pod 20tf - Lovire pod în opritori SR EN 1990 31.76 2,68 times bigger STAS 10101 11.84 for the 20t crane 0 6 12 18 24 30 36 (kn) Pod 5tf - Lovire pod în opritori SR EN 1990 6.48 2,52 times bigger for the 5t crane STAS 10101 2.57 0.0 1.2 2.4 3.6 4.8 6.0 12 7.2 (kn)

Transverse forces caused by crab acceleration or deceleration EN 1991 3:2006 13

Transverse forces caused by crab acceleration or deceleration STAS 10101/2A -78 14

Transverse forces caused by crab acceleration or deceleration Poduri 20tf - Demarare/frânare cărucior SR EN varianta1 12.78 SR EN varianta2 20.49 11% for variant 1 78% for variant 2 STAS 10101 11.50 0 4 8 12 16 20 24 (kn) Pod 5tf - Demarare/frânare cărucior 10% for variant 1 12,6% for variant 2 SR EN varianta1 SR EN varianta2 STAS 10101 4.36 4.8 5.01 0 1 2 3 4 515 6 (kn)

CRANE TRANSVERSE SKEWING FORCES STAS 10101/2A -78 EN 1991 3:2006 The horizontal forces H S,i,j,k, caused by crane skewing, are acting as a single force (on a single crane wheel) on each runway beam according to EN 1991. In the appropriate Romanian and German code it is considered that the skewing of the crane generates a couple of forces on each runway girder. 16

Forces used for the design of the runway girders Two 20tons overhead traveling cranes A single 5tons underslung traveling crane 17

The vertical wheel loads generated by crane operations for lower hoisting classes (HC1 and HC2) were greater in the calculations according to the European standard [5], compared to those ones obtained with the Romanian code [1]. For higher hoisting classes (HC3 and HC4) bigger values were obtained for the loads given by the Romanian standard.

RUNWAY GIRDERS CROSS-SECTIONS Two 20tons overhead traveling cranes acting together + 5,0% according to old Romanian code design 19

RUNWAY GIRDERS CROSS-SECTIONS A single 5tons underslung traveling crane + 5,0% according to old Romanian code design 20

Effective loaded length l eff The limit between rigidly fixed and not rigidly 21 fixed connection is not clearly established.!

Local buckling checks of the web: A frequent loading state of the webs of runway beams is when they are simultaneously subjected to bending moment (M y,ed ), shear force (V z,ed ) and transversal force (F Ed ). European codes do not specify an interaction checking relation for this loading state and they do not make any reference to such a relation. The Romanian code provides such an interaction relation. 22

Checks against local web buckling for the 20tf traveling cranes runway girder: 23

Recommended partial safety factors values γ Mf for fatigue checks The fatigue check requires the use of the partial safety factors γ Mf given in table above, depending on concepts like low and high failure consequence, damage tolerant 24 and safe life, which are not clearly defined and delimited.

The cross-sections designed according to the new European standards were checked according to the in charge Romanian codes in order to ensure an objective comparison (to avoid the influence of the different load estimation procedures) between the two sets of European and Romanian norms used for the design of runway girders. The results are presented in the tables below.

General Conclusion Based on our calculations the checks according to the old Romanian code are one the safe side in a range of about 10% (excepting the fatigue limit state checks which had no influence on the designed crosssections). The European codes cover the different design situations more accurately.

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