Comparative Analysis of Estimating and Costing Between Beam Supported Structure and Flat Plate Structure for a Resedential Building

Comparative Analysis of Estimating and Costing Between Beam Supported Structure and Flat Plate Structure for a Resedential Building

Shamim Ara Bobby

Senior Lecturer, Department of Civil Engineering Stamford University Bangladesh

Dhaka, Bangladesh

AbstractDhaka has experienced an extremely rapid growth in population. This vast population is putting serious pressure on housing facilities. As a result, significant numbers of buildings are being constructed in Dhaka city. Different real estate companies are investing a huge amount of money in the construction industry.

This research work presents a comparative study on the basis of cost of two six storied building structure having beam supported floor system and another is flat plate floor system. Two buildings were provided with same shape, size and loadings. As standard amenities and modern facilities, passenger lift, stairs, ramps were provided. The buildings considered are with same floor area. Conventional Finite component package was used to perform 3D linear elastic study for the building frame. After 3D analysis, the structural members of the building were designed by USD method. The cost per unit area for finishing items will remain same for all cases. After that, the volume of concrete and steel are estimated and finally, their cost are determined. After performing estimation, cost analyses and comparison, the study concluded that beam column structure is more economical. Flat plate structure method can be used with conditions and care should be taken in design, quality of materials should be ensured and design specifications should be followed perfectly.

KeywordsBeam supported structure, flat plate structure,estimation of cost.

1. INTRODUCTION

   Over the history of building structures, the changes in technology have been tremendous. Part of this comes from the daily strategies of human living. In recent year, the trend is the construction of mixed-uses structures as limited natural resources, the expenses, time and stresses of commuting draw people back into the city center. As a result, urban center include now mostly structures with a storefront next to the street, offices in the stories immediately above and finally in the upper levels, apartment for city dwellers. But these types of building are difficult to arrange to take total advantages of structural and mechanical systems. Offices need large open spaces with large loads from mechanical and electrical systems. The living quarters, with their intimate spaces, need closer column spacing and have fewer vents, weirs required meeting needs of comfort. Shallow floor-to-floor heights in the apartment areas are possible since they can be accommodated by a flat plate slab design. Offices need grid or pan systems covered by drop ceilings to allow HVAC and electrical systems to be delivered to desired locations within each square. Hence, according to the need of rentable spaces, owner desires,

   aesthetics, cost, safety and comfort, architects and engineers are now facing the challenges of structural design to accommodate peoples total daily life in one single structure. As outcome, six storied structures are now being constructed with different types of concrete floor systems.

   The choice of type of slab for a particular floor depends on many factors. Economy of construction is obviously an important consideration, but this is a qualitative argument until specific cases are discussed and is a geographical variable. The design loads, required spans, serviceability requirements and strength requirements are all important. As cost is a major concern in all projects, so it is necessary to design and construct quality apartment buildings at low costs. So the comparison is necessary to select the most efficient one Considering these points of view, the choice between a beam slab and flat plate slab floor systems becomes usually a matter of great confusion to users.

   Based on the above considerations, this study focuses on the analysis of two structures having beamed supported structures and another one flat plate structures and finally presents a comparative analysis of estimating and costing. This will give a comparative picture about the advantages and disadvantages, suitability and feasibility, particularly in terms of economy so as to enable someone to choose the suitable option.

2. OBJECTIVE OF THE STUDY

   The objective of the study were

   • To develop models of structure with beam supported slab and a structure with flat plate slab for analysis and design by finite element method using software ETABS.

   • To compare the concrete and steel requirement of the two types of building.

   • To compare the total cost between the two types of building.

3. METHOLOGY OF THE STUDY

   Step 1: Two types of six storied building structure having beam supported floor system and another is flat plate floor system had been considered. Two buildings were provided with same shape, size and loadings. As standard amenities and modern facilities, passenger lift, stairs, ramps were provided.

   Step 2: Based code on design/specification of ACI/BNBC, material properties (compressive strength of concrete, yield stress of steel, unit weight of concrete, soil, brick etc.) and loadings (standard dead loads, live loads, floor finish etc.) were selected. Wind and earthquake loads were also considered.

   Step 3: We have done cost analysis of column, grade beam, floor beam and slab of beam supported structure and column, grade beam and slab of flat plate structure. We have analyzed costing to compare the column, grade beam and slab of beam supported structure and flat plate structure. As the result, this can help someone in terms of economy to choose the suitable option.

   Description

   • Ultimate Strength Design (USD)

   • American Concrete Institute (ACI) Building design code, ACI 318-99

   • Bangladesh National Building Code (BNBC)

   • Uniform Building Code (UBC), 1994

   • Beam supported structure: Six (6) storied having 12X14; 12X18; 12X24; (inch) columns size.

   • Flat plate structure: 14X20; 14X28; 24X30 (inch) column size.

   • Both of Structure having 60 Grade reinforcement.

   • Both of Structure having 3.5 Grade concrete.

   • Framed structure.

   • Residential.

   • Dead load = 147.5 psf

   • Live load = 40 psf

   • Considering wind load & earthquake load

   • Slab type = Flat plate structure & Beam supported structure

   • Beam type = Rectangular

   • Column type = Tide

   • Reinforcing bars, fy = 60 ksi

   • Concrete compressive strength, fc = 3.5 ksi

   • Normal density concrete having = 150 psf

4. ANALYTICAL STUDY

   The building geometries are as following:

   1. Beam Supported Structure:All the floors have 19 columns. All the slabs of the structure are beam supported. Story height is 10 ft. column and beam size is different.

   2. Flat plate structure:All the floors have 19 columns. All the slabs are directly supported on column (flat plate structure). Column size is different.

   3. The load considered (with factor):

   Self weight of slab = 62.5 psf, Partition wall = 60 psf

   Floor finish= 25 psf, Dead load = 147.5 psf, Total Dead load,

   D.L = 206.5 psf ,Live load = 40 psf, Live load, L.L = 68 psf.

   Fig1: Building Plan

5. DESIGN OF STRUCTURE

   After analyzing the two types of structures, we got the required value to pursue the design process. We did slab flexural design, beam flexural and shear design and column main steel calculation and tie bar design using USD method

   .Getting the result of design we found out the costing of the two types of buildings.

6. COST ANALYSIS

   The buildings are analyzed for the best condition which can be constructed economically. We use the good materials. We use BSRM steel in 60 grades which steel rate is 65 Tk. per kg as market price in December 2013. Cement use is Shah Cement and its market price is 450 Tk. per bag in December 2013. Stone chips used in column and its market price is 135 Tk. per cft in December 2013 and brick chips used in beam & slab and its market price is 85 Tk. per cft. Sylhet sand is used all structure work and its market price is 35 Tk. in December 2013.

   1. Cost Estimation:

      1. Estimate of Floor Beam:

         1	2	3	4	5	6	7=3* 5*6	8	9=7* 8
         Name of beam	Bar description	No.of beam	Size of bar (mm)	Nos of bar	Length of bar	Total lengt h of bar(ft )	Bar weig ht = kg/ft	Total weig ht kg
         FB1	Main bar Ext .top Ext. bottom Stirrups	4 4 4 4	16 16 16 10	4 2 1 28	18-4 8-7 5-2 4-2	293.2 68.6 20.6 467.0	0.5 0.5 0.5 0.2	140.8 32.9 9.9 224.2
         FB2	Main bar Ext .top Stirrups	2 2 2	16 16 10	4 1 24	14-3 7-2 3-10	114 14.3 183.8	0.5 0.5 0.2	54.7 6.9 34.9
         	Main bar Ext .top Stirrups	2 2 2	16 16 10	4 1 23	14-0 7-6 3-10	112 15 176.1	0.5 0.5 0.2	53.8 7.2 33.5
         FB3	Main bar Ext .top Stirrups	2 2 2	16 16 10	4 1 18	11-8 3-5 3-10	93.3 6.8 137.8	0.5 0.5 0.2	44.8 3.3 26.2
         	Main bar Ext .top Stirrups	2 2 2	16 16 10	4 1 28	18-4 4-3½ 3-10	146.6 8.5 214.4	0.5 0.5 0.2	70.1 4.1 40.7
         FB4	Main bar Ext .top Stirrups	5 5 5	16 16 10	4 1 24	14-3 7-2 4-10	285 35.8 579.6	0.5 0.5 0.2	136.8 17.2 110.1

         a) Beam supported structure:

         FB5	Main bar Stirrups	1 1	16 10	4 163	103- 0 3-10	412.0 624.2	0.5 0.2	197.8 118.6
         							Total	1368. 5

         Table1: Bar schedule of beam

         Total 6 floors:

         Reinforcement = 1368.56*6 = 8211.36 kg

         Name of beam	Length of beam(L)	Width of beam (B)	Depth of beam (H)	Nos of beam	Total volume = L*B*H cft
         FB1	17-0	1-0	1-3	4	90.44
         FB2	14-1	0-10	1-3	2	29.22
         FB3	17-0	0-10	1-3	2	35.28
         FB4	14-7	1-0	1-6	5	109.35
         FB5	11-3	0-10	1-3	4	46.68
         FB5	10-5	0-10	1-3	2	21.62
         FB5	14-3	0-10	1-3	2	29.57
         FB5	8-6	0-10	1-3	2	17.64
         FB5	16-2	1-0	1-3	1	16.77
         FB1	14-3	1-3	1-3	2	35.63
         FB3	11-3	1-3	1-3	2	23.34
         				Total =	455.54

         Table.2: Casting of floor beam

         Total volume = 455.54 cft Ratio: 1:2:4

         Wet volume: 455.54*1.5 = 683.31 cft

         Cement = 683.31/7 = 97.62/1.25 = 78.09 ~ 78 bag.

         Sand = 97.62*2 = 195.24 cft.

         Brick chips = 97.62*4 = 390.48 cft.

         Total 6 floors:

         Cement = 78*6 = 468 bag Sand = 195.24*6 = 1171.44 cft

         Brick chips = 390.48*6 = 2342.88 cft

      2. Estimation of Grade Beam:

         1. Beam Supported structure:

            1	2	3	4	5	6	7=3*5 *6	8	9=7* 8
            Name of beam	Bar descrip tion	Nose of beam	Size of bar (mm)	No of bar	Length of bar	Total length of bar(ft)	Bar weig ht = kg/ft	Total weigh t kg
            Short	Main	6	16	4	32-2	772.1	0.5	370.6
            Beam	bar Stirrup	6	10	62	4-4	268.5	0.2	51
            	s
            Long	Main	3	16	4	61-3	245.1	0.5	117.6
            Beam	bar Stirrup	3	10	119	3-10	455.1	0.2	87.0
            	s
            							Total	626.5

            Table3:Bar schedule of beam

            Name of beam	Length of beam(L)	Width of beam (B)	Depth of beam (H)	Nos of beam	Total volume = L*B*H cft
            GB1	17-0	1-0	1-6	6	153
            GB2	14-1	1-0	1-6	7	148
            GB3	11-3	1-0	1-3	6	85
            GB3	10-5	1-0	1-3	2	26
            GB3	10-10	1-0	1-3	1	14
            GB4	8-6	1-0	0-10	1	7
            GB4	6-4	1-0	0-10	1	6
            GB2	14-3	1-0	1-6	4	86
            				Total =	525

            Table4:Casting of Grade beam

            Total volume = 525 cft Ratio: 1:2:4.

            Wet volume = 525*1.5 = 787.5cft

            Cement = 787.5/7 = 112.5/1.25 cft = 90 bag Sand = 112.5*2 = 225 cft

            Brick chips = 112.5*4 = 450 cft

         2. Flat Plate Structure:

         1	2	3	4	5	6	7=3*5 *6	8	9=7* 8
         Name of beam	Bar descripti on	No of beam	Size of bar (mm)	Nos of bar	Length of bar	Total length of bar(ft)	Bar weig ht = kg/ft	Total weig ht kg
         Short	Main	6	16	4	32-2	772.1	0.5	370.6
         Beam	bar Stirrups	6	10	62	4-4	268.5	0.2	51.0
         Long	Main	3	16	4	61-3	245.1	0.5	117.6
         Beam	bar Stirrups	3	10	119	3-10	455.1	0.2	87.0
         							Total	626.5

         Table5:Bar schedule of beam

         Name of beam	Length of beam(L)	Width of beam (B)	Depth of beam (H)	Nos of beam	Total volume = L*B*H cft
         GB1	17-0	1-0	1-6	6	153
         GB2	14-1	1-0	1-6	7	148
         GB3	11-3	1-0	1-3	6	85
         GB3	10-5	1-0	1-3	2	26
         GB3	10-10	1-0	1-3	1	14
         GB4	8-6	1-0	0-10	1	7
         GB4	6-4	1-0	0-10	1	6
         GB2	14-3	1-0	1-6	4	86
         				Total =	525

         Table6: Casting of Grade beam

         Total volume = 525 cft Ratio: 1:2:4.

         Wet volume = 525*1.5 = 787.5cft

         Cement = 787.5/7 = 112.5/1.25 cft = 90 bag Sand = 112.5*2 = 225 cft

         Brick chips = 112.5*4 = 450 cft

      3. Estimation of Column:

         1. Beam Supported structure:

            1	2	3	4	5
            Name of column	Bar description	Nose of column	Size of bar(mm)	Nose bar	of
            C1,C7,C14,	Main rod	4	16mm	6
            C19	stirrups
            		4	10mm	65
            C2,C3,C4,	Main rod	11	16mm	8
            C5,C6,C8,	stirrups
            C13,C15,		11	10mm	65
            C16,C17,
            C18
            C10,C11,	Main rod	3	16mm	10
            C12	stirrups
            		3	10mm	65
            C9	Main rod	1	20mm	10
            	Main rod
            	stirrups	1	16mm	8
            		1	10mm	65

            6	7=3*5*6	8	9=7*8
            Length of bar	Total length of bar(ft)	Bar weight = kg/ft	Total weight kg
            84-7	2030	0.48	974.4
            4-2	1084	0.19	205.96
            84-7	7444	0.48	3573.12
            4-2	2982	0.19	566.58
            84-7	2538	0.48	1218.24
            4-2	813.15	0.19	154.50
            42-3.5	423	0.75	317.25
            42-3.5	339	0.48	162.72
            4-2	271.05	0.19	51.50
            		Total	7224.27

            Table7 (a): Bar schedule of column (1st half0

            Table7(b): Bar schedule of column (2nd Half)

            Name of column	Length of column (L)	Width of column (B)	Depth of column (H)	Nos of colum n	Total volume = L*B*H cft
            C1,C7,C14,C19	1-0	1-2	68-6	4	321
            C2,C3,C4,C5,C6,C	1-0	1-6	68-6	12	1233
            8,C9,C13,C15,
            C16,C17,C18
            C10,C11,C12	1-0	2-0	68-6	3	411
            				Total	1965

            Table.8:Casting of Column

            Total volume = 1965 cft Ratio: 1:1.5:3.

            Wet volume = 1965*1.5 = 2947.5 cft

            Cement = 2947.5/5.5 = 535.9/1.25 cft = 429 bag Sand = 535.9*1.5 = 804 cft

            Brick chips = 535.9*3 = 1608 cft

         2. Flat Plate structure:

         1	2	3	4	5
         Name of column	Bar description	Nose of column	Size of bar(mm)	Nose bar	of
         C1,C2, C6,C7, C14,C15, C16,C17, C18,C19	Main rod stirrups	10 10	20mm 10mm	14 66
         C3,C4,C5,	Main rod	7	25mm	12
         C9,C10, C11,C12	stirrups
         		7	10mm	57
         C8,C13	Main rod	2	16mm	10
         	stirrups
         		2	10mm	79

         Table 9(a) :Bar schedule of column (1st half)

         6	7=3*5*6	8	9=7*8
         Length of bar	Total length of bar(ft)	Bar weight = kg/ft	Total weight kg
         84-7 10-2	11841.2 6712.2	0.75 0.19	8880.9 1275.32
         84-7 54-1	7104.72 6420.48	1.17 0.19	8312.52 1219.89
         84-7 8-10	1691.6 1395.14	0.48 0.19	812 265
         		Total	20765.63

         Table 9(b) :Bar schedule of column (2nd half)

         Name of column	Length of column (L)	Width of colum n (B)	Depth of column (H)	Nos of colu mn	Total volu me = L*B *H cft
         C1,C2,C6,C7,C14,C15,C1 6,C17,C18,C19 C3,C4,C5,C9,C10,C11,C1 2 C8,C13	1-2 2-0 1-2	2-4 2-6 1-8	69-0 69-0 69-0	10 7 2	1881 2415 270
         				Total =	4566

         Table 10: Casting of Column

         Total volume = 4566 cft Ratio: 1:1.5:3.

         Wet volume = 4566*1.5 = 6849 cft

         Cement = 6849/5.5 = 1245.27/1.25 cft = 996 bag Sand = 1245.27*1.5 = 1868 cft

         Brick chips = 1245.27*3 = 3735.81 cft

      4. Estimation of slab:

   1. Beam supported structure:

      Brick chips = 161.14*4 = 644.56 cft

      Total 6 slabs:

      Cement = 128*6 = 768 bag Sand = 322.28*6 = 1933.68 cft

      Brick chips = 644.56*6 = 3867.36 cft

   2. Flat plate structure:

   1	2	3	4	5	6=4*5	7	9=7* 6
   Bar directi on	Bar descripti on	Size of bar(m m)	Nose of bar	Lengt h of bar	Total length of bar(rft)	Bar weig ht = kg/ft	Total weig ht kg
   long	Top bar	12	55	37- 11	2085.6	–	–
   	Bottom bar	12	55	37- 11	2085.6	–	–
   	Ext. top	12	54	7-6	405	–	–
   	Ext. top	12	54*2	7-6	810	–	–
   	Ext. top	12	9	3-4	-30	–	–
   	Straight bar	12	10*2	13- 7	-271.6	–	–
   Short directi on	Top bar	12	29	59- 6	1725.5	–	–
   	Bottom bar	12	29	59- 6	1725.5	–	–
   	Ext. top	12	28*2	2-8	150	–	–
   	Ext. top	12	13*2 *2	5-3	273	–	–
   	Ext. top	12	15*4	6-3	375	–	–
   	Ext. top	12	15*4	5-8	340	–	–
   	Top & bottom	12	13*2	10- 10	-281.58
   				Total =	10558. 38	0.27	2850

   Table 12: Bar schedule of slab

   Table 11: Bar schedule of slab

   Total 6 Slabs:

   Reinforcement = 2510*6 = 15060 kg

   Estimation casting of slab:

   30-1*59-06*0-5 = 752 cft

   Total volume = 752 cft Ratio: 1:2:4.

   Wet volume = 752*1.5 = 1128cft

   Cement = 1128/7 = 161.14/1.25 cft = 128 bag Sand = 161.14*2 = 322.28 cft

   Total 6 Slabs:

   1	2	3	4	5	6=4*5	7	9=7*6
   Bar directio n	Bar description	Size of bar( mm)	Nos e of bar	Length of bar	Total length of bar (rft)	Bar weig ht = kg/ft	Total weigh t kg
   long	Straight bar	10	30	58-3	3495	–	–
   	Crank bar	10	30	60-1	1802	–	–
   	Ext. top	10	58* 2	3-3 ½	391	–	–
   	Ext. top	10	58* 2	6-3	725	–	–
   	Ext. top	10	32* 2	5-8 ½	364	–	–
   	Ext. top	10	26	7-10 ½	205	–	–
   	(-)Straight bar	10	27	10-9	291	–	–
   	Straight bar	10	60	30- 10	1850	–	–
   	Crank bar	10	59	32-8	1928	–	–
   	Ext. top	10	60	7-8	461	–	–
   	Ext. top	10	60* 2	7-6	900	–	–
   	(-)Straight bar	10	32	13-7	435	–	–
   	(-) Ext. top	10	16	22-8	363	–	–
   				Total =	13210	0.19	2510

   Reinforcement = 6*2850 kg = 17100 kg.

   Estimation casting of flat plate slab:

   30-1*59-06*0-8 = 1200 cft

   Total volume =1200cft Ratio: 1:2:4.

   Wet volume = 1200*1.5 = 1800cft

   Cement = 1800/7 = 257.14/1.25 cft = 206 bag Sand = 257.14*2 = 514.28cft

   Brick chips = 257.14*4 = 1028.56 cft

   Total 6 Slabs:

   Cement = 206*6 = 1236 bag Sand = 514.38*6 = 3086.28 cft

   Brick chips = 1028.56*6 = 6171.36 cft

   1. Cost analysis:

      1. Beam supported structure

         Column

         Reinforcement cost of column = 7224.27*65 Tk. /Kg = 469577.55 Tk.

         Cement of column = 429*450 Tk. /bag = 193050.00 Tk.

         Sand of column = 804*35 Tk. /cft = 28140.00 Tk.

         Stone chips of column = 1608*135 Tk. /cft = 217080.00 Tk.

         Grade beam

         Reinforcement cost of grade beam = 626.54*65 Tk. /Kg = 40725.10 Tk.

         Cement of grade beam = 90*450 Tk. /bag = 40500.00 Tk. Sand of grade beam = 225*35 Tk. /cft = 7875.00 Tk.

         Brick chips of grade beam = 450*85 Tk. /cft = 3825

         Floor beam

         Reinforcement cost of floor beam = 8211.36*65 Tk. /Kg = 533738.40 Tk.

         Cement of floor beam = 468*450 Tk. /bag = 210600.00 Tk. Sand of floor beam = 1171.44 *35 Tk. /cft = 41000.40 Tk. Brick chips of floor beam = 2342.88 *85 Tk. /cft = 199144.80 Tk.

         Floor slab

         Reinforcement cost of floor slab = 15060*65 Tk. /Kg = 978900.00 Tk.

         Cement of floor slab = 768*450 Tk. /bag = 345600.00 Tk. Sand of floor slab = 1933.68 *35 Tk. /cft = 67678.80 Tk.

         Brick chips of floor slab = 3867.36 *85 Tk. /cft = 328275.60 Tk.

         Influence of Reinforcement of Beam supported structure & Flat plate structure on all Column, Grade Beam and Slab

         25000

         20000

         15000

         10000

         5000

         0

         Beam supported structure

         Flat plate structure

         Column Grade Slab Beam

         Elements of structures

         total cost(tk)

         Fig 2: Reinforcement of all floors on Column, Grade beam and Slab of all

         Quantity(ft3)

         structures

         Influence of Cement, Sand and Stone chips on all Column

         4000

         3500

         3000

         2500

         2000

      2. Flat plate structure

   Column

   Total = 3740585.65 Tk.

   Reinforcement cost of column = 20765.63*65 Tk. /Kg = 1349765.95 Tk.

   Cement of column = 996*450 Tk. /bag = 448200.00 Tk. Sand of column = 1868*35 Tk. /cft = 65380.00 Tk.

   Stone chips of column = 3735.81 *135 Tk. /cft = 504334.35 Tk.

   Grade beam

   Reinforcement cost of grade beam = 626.54*65 Tk. /Kg = 40725.10 Tk.

   Cement of grade beam = 90*450 Tk. /bag = 40500.00 Tk. Sand of grade beam = 225*35 Tk. /cft = 7875.00 Tk.

   Brick chips of grade beam = 450*85 Tk. /cft = 38250.00 Tk.

   Floor slab

   Reinforcement cost of floor slab = 17100*65 Tk. /Kg = 1111500.00 Tk.

   Cement of floor slab = 1236*450 Tk. /bag = 556200.00 Tk. Sand of floor slab = 3086.28 *35 Tk. /cft = 108019.80 Tk. Brick chips of floor slab = 6171.36 *85 Tk. /cft = 524565.60 Tk.

   Material properties

   1500 Beam supported

   1000 structure

   500

   0 Flat plate structure

   Cement Sand Stone

   chips

   Fig 3: Cement, Sand & Stone chips of all floors on Column of all

   structures

   Quantity(ft3)

   Influence of Cement, Sand & Brick chips of Beam supported structure and Flat plate structure on all Slab

   7000

   6000

   5000

   4000

   3000 Beam supported

   2000 structure

   1000 Flat plate structure

   0

   Cement Sand Brick

   chips

   Material properties

   Total = 4795315.80 Tk

   Fig 4: Cement, Sand & Brick chips of all floors on Slab of all structures

7. SUMMARY OF THE COMPARATIVE STUDY

   Finally the total cost is Total = 4795315.80 Tk. of Flat plate structure & Total = 3740585.65 Tk. of Beam supported structure. It is 28.2% above on flat plate structure than beam supported structure.

8. CONCLUSION

   After performing analysis of the structures as well as the comparative study of beam supported structure and flat plate structure, we gathered knowledge that:

   1. Flat plate slab is thicker and more heavily reinforced than slabs with beams and girders. Almost 24% more reinforcement are used for flat plate structure than beam supported structure.

   2. Almost 28% more concrete are used for flat plate structure than beam supported structure.

   3. And finally increased the cost of flat plate structure about 28.2% than beam supported structure.

   4. So from economic point of view, beam supported structure is more economical than flat plate structure

   .But from aesthetic point of view, flat plate structure is better.

9. RECOMMENDATION FOR FUTURE USE

For further study in this field, the following recommendations are put forward:

• For further study estimation of cost of footing, stair, overhead tank and lift core are required.

• Cost analysis for finishing work & upper design are required for better result.

• In the further study, soil test reports nearer projects of that area should have been collected and used in foundation design for the proposed project.

• This research work has been conducted on slab of a six storied residential building but it can be conducted on all the components of the building as well as for other high and low rise buildings.

• For analysis ETABS design software was used, so it may be cheeked by other reliable softwares.

REFERENCES

1. ACI Code, 2008, USA.

2. BNBC, (1993): Bangladesh National Building Code, 1st Edition, City Art Press, Dhaka, Bangladesh.

3. PWD, (2008): Schedue of Rate for Civil Works, 12th Edition, Public Works Department, Govt. of People Republic of Bangladesh.

4. Nilson A.H.; Darwin D.;Dolan C.W. (2003): Design of Concrete Structure, 13th Edition, McGraw-Hill International editions, New Delhi, India.

5. Auto CAD-2010.

6. Das.B.M, Principles of Foundation Engineering, Fifth, edition.

7. Hassan.M.N, Structural Concrete Theory & Deign.

8. 8.LIN.T.Y&BURNS.N.H, Design of Prestressed Concrete Structures, Third, edition

9. 9.D.S.Hatcher, M.A.Sozen, and C.P.Siess, (1965) Test of a Reinforced Concrete Flat Plate.