Proceedings of the First nternational Congress on Construction History Madrid 20th-24th January 2003 ed. S. Huerta Madrid:. Juan de Herrera SEdHC ETSAM A. E. Benvenuto COAM F. Dragados 2003. Development of composite columns. Empergers effort Holger Eggemann Todays composite columns are made of structural steel concrete and reinforcing steel. Three basic types of composite columns can be distinguished completely encased composite columns Figure la panially encased composite columns Figure lb and fijled composite columns Figures d and le. Although composite columns were rarely used from the end of W orld War l until the early 1970 s (Viest et al. 1997 1.13) research had started a long time before at the beginning of the 20th century. Combining of these material s had a number of motivations steel columns were often encased in concrete lo protect them from fire while concrete columns were combined with structural steel as a reinforcement. One predecessor of the completely encased column type was the so called Emperger-Column. t consisted of a cast-iron section embedded in spiral-reinforced concrete and had been used frequently in the construction of high-rise buildings in the United States. The anicle describes Empergers activities in the field of composite columns and proves his influence on the construction which can still be felt today. Another type of todays composite columns the column with a solid steel core reminds us of the Emperger-Column and can be considered as successor. t wijl be proved that Emperger was not only a pioneer in concrete construction but also a pioneer in composite construction who tried to link both steel and concrete construction techniques. y ~. y _. y f~ bc* Cy / / / / / 1: / tw/ / / / / / / o) \z d e) ~z lo -c::: - "- -c:::l.> ~. lo T y i""" l. b) - d) b=b b z f) z ~ u ~ ~ -<::. ~- Figure 1 Types of Composite Columns (DNV ENV 1994-1-1 Fig. 4.9)
788 H. Eggemann FRTZ VON EMPERGER (1862-1942) This paragraph is based on a curriculum by Kleinlogel dedicated to Empergers 70th birthday (Kleinlogel 1932). Emperger was born on January 11th 1862 in Beroun (at that time Austria today Czech Republic).When he began his studies in Prague in 1879 the first effects of Monier s patents had become visible in France and evoked Empergers interest in the new technology. His first professional activities were in the field of railway and bridge construction. n 1890 he settled down in Chicago as a consultant engineer where he worked on the planning of New Yorks and Bostons subways built the first American concrete bridge in Cincinatti Ohio and designed high-rise buildings. After his return to Vienna in 1897 he took his Doctor of Engineering degree in 1903. Previously he had founded the journal «Beton und Eisen» in 1901 today known as "Beton- und Stahlbetonbau«since 1906 published by Wilhelm Ernst & Sohn Berlin. n 1906 he gave the idea to Germanys "Beton- Kalender«of which he became the editor and in 1909 he published the «Handbuch für Eisenbeton» with the same company. n 1913 Emperger was honoured by his Majesty the Emperor of Austria with the Knight s Cross of the lron Crown and in the same year received the honorary membership of the British Concrete nstitute (Beton u. Eisen 1913 187 290). n 1932 after years of intensive research on almost every aspect of reinforced concrete and design and construction of many buildings he became Doctor honoris causa of Dresden s Faculty of Civil Engineering Figure 2 and al so honorary member of Austrias Committee on Reinforced Concrete (Beton u. Eisen 1932 50). Emperger died on February 7th 1942 in Vienna. RESEARCH AND DESGN OF COMPOSTE COLUMNS First steps n the winter of 1901/1902 Emperger started research on concrete columns mostly reinforced with structural steel. For several reasons he had to wait until 1908 to have the specimens tested in Stuttgart with Bach. AJthough Emperger didnt give explicit evidence for the problems it can be supposed that there had been internal rivalry with his colleagues in Vienna (Emperger 1908b Foreword). n 1907 Emperger tested three steel columns to determine their buckling loads (Emperger 1907a). After testing one of those specimens Figure 3 was bent back to its original shape by Emperger himself and filled with concrete (Emperger 1907b 172). Emperger wanted to give evidence for the importance of concrete filling for steel columns. He estimated that the design formula P = Oh (Fb + 15 F) Figure 2 Medal of Honour to Empergers 70th Birthday (Beton u. Eisen 193250) of Prussias Building Regulations was unsuitable to cajculate the ultimate load of a concrete-filled steel column. The number 15 defined the relation between
Developrnent of cornposite colurnns. Ernpergers effort 789 the rnodulus of elasticity of steel and concrete. Ernperger found out that the ultirnate load of a concrete-filled steel colurnn didnt depend on that nurnber. reinforced concrete column was dictated by the surn of the strength of both steel and concrete and did not depend on the rnodulus of elasticity. A design formula of the Addition-Law for reinforced concrete colurnns was given first by (Morsch [1902] 1912 93) with syrnbols as described in the next paragraph: P = Fb0h + Feo Empergers Patent 1911 n 1911 Ernperger applied for a Patent clairning «Hohle GuBeisensaule rnit einem Mantel aus urnschnürtern Beton [Colurnn of hollow cast-iron section encased in hooped concrete]» (Pat. 291068). The spacing of the hooping had to be equal to or less than the thickness of the surrounding concrete shell Figure 4. Because of an objection frorn the cornpany WayB & Freytag A.-G. it took five years until the patent was granted in 1916 (Beton u. Eisen 191647). n 1913 Ernperger published a design formula for the ultirnate load of such a colurnn: P = Fb0b + Feo + Fpg Figure 3 Steel Colurnn filled with Concrete (Emperger 1907b 173) Empergers addition-law n 1908 Emperger published the results of numerous tests on reinforced concrete colurnns arnong those the specimen tested by Bach (Ernperger 1908). Reinforcernent was realized by both reinforcement bars and structural steel elernents. According to (Gehler 1933266) Ernperger was the first to verbalise the later well known Addition-Law: "Nach meiner Meinung ist die Bruchlast einer Eisenbetonsaule die Summe zweier Festigkeiten die von dern Verhaltnis der beiden Elastizitatskoeffizienten nicht abhangt» (Ernperger 19082). n Empergers opinion the u1timate oad of a where is the compres sive strength of the cast-iron in consicteration " of buckling of the complete section e is the yield point of the mi d steel and 0b is the cornpressive strength of the concrete (Ernperger 1913 34). n the sarne book Ernperger reported various test results of encased cast-iron colurnns. The colurnn sections were varied in rnany ways and solid cores were tested too Figure 5. During the following years nurnerous buildings in Austria Czechoslovakia and the United States had been built with Emperger- Colurnns but not in Gerrnany (Kleinlogel 1928 53). For Kleinlogel the reason had been that Gerrnanys building authorities rejected the application of Ernperger-Colurnns because of missing regulations and official tests had been refused because of Ernperger s patent clairn. So in 1928 Ernperger decided to give up his clairns (Kleinlogel 1928 53). Emperger-columns in the United States n 1915 Ernperger gave a report on hooped concrete calurnns with salid cores at an engineering congress
790 H. Eggemann p2mmna#mm Fig.2. Figure 5 Emperger-Columns with Solid Cast-Tron Cores (Emperger ]9135356) in San Francisco USA. He presented his Addition- Law and pointed out that the strength of the core material was not of great importance both cast-iron and mild steel were possible. n 1920 Emperger- Columns were regulated in the US Standard Specifications No. 23 Standard Building Regulations for the Use of Reinforced Concrete (AC 1920). Paragraph 50 stated: f Figure 4 Emperger-Column (Pat. 291068 Fig. 2) "!T Composite columns having a cast -iron core or center surrounded by concrete which is enclosed in a spiral of not less than one-half of ] per cent of the core area and with a pitch of not more than three inches may be figured for a stress of 12000-60 L/R but not over 10000 lb. per sq. in. [69 N/mm~] on the cast-iron section and not more than 25 per cent of the compressive strength... on the concrete within the spiral or coreo The diameter of the cast-iron core shall not exceed one-half of the diameter of the spiral (ACT ] 920 302). Empergers Addition-Law was applied in a modified form using a specified Tetmajer-Formula. This was the first official building regulation for Emperger-Coumns. The maximum allowed compressive strength of the concrete was 3000 lb. per sq. in. (20.7 N/mm") so a column could be calculated with a maximum stress on the concrete of 4. N/m m". n 1928 the paragraph was amended and cores of mild steel were permitted too (AC 1928 824). This building regulations made it possible to use Emperger- Columns in the design of many high-rise buildings in the United States above all in Chicago: Buildings having the Emperger typc of column include the following: Surf-Hotel Chicago eleven storeys; two sixteen-storey apartment buildings at
Development of composite columns. Emperger s effort 791 3730-40 Sheridan Road Chicago; Aragon Hotel Chicago twelve storeys; Krolick Department Store Detroit 150"200 ft. [46"61 m] twelve storeys with co1umn loads of 2000000 lb. [9 MN] and a building of the same size for the Detroit Pressed Steel Company. Of these the Surf Hotel and the Krolick Store have hollow cast-iron cores (ENR 1930 278). Type 1. 1 <~/" Typell Two other buildings in Chicago had been mentioned before the 16-storey McGraw- Hill Building see Building Case Histories and the 30- storey Trustees Building also known as Corn Products Building. n 1930 test results on composite columns were published by (Mensch 1930). Tests were made for the new Building Code Committee of the City of Chicago to verify Empergers results under American conditions. Mensch figured out «that Dr. Emperger s claim of the strength of the composite column being greater than the sum of its components has been verified by every test» (Mensch 1930 270). Composite Columns in Europe Emperger complained several times about the lack of building regulations for composite columns in Europe. «Für die beiden... Saulenformen bestehen in keinem europaischen Staate Vorschriften [There are no regulations for these two types 01 columns in any of the European countries]» (Emperger 1931a 265; similar 1930 1931 b). Emperger meant the encased steel column and his own type. At the First Congress of the nternational Association for Bridge and Structural Engineering in Paris in 1932 Emperger mentioned more than 1000 tests on composite columns in Europe and about 570 in North America. He distinguished four different types of composite columns Figure 6. Type was called structural steel column with concrete core Type was a steel column encased in rein1orced concrete with lateral ties Type 1l was called steel column encased in strongly hooped concrete the Emperger type and Type V was a steel column with slight hooping. Type and Type are in use today of course with modern types 01 structural steel elements. Type now is called partially encased composite column and Type is known as completely encased composite column. Columns with spiral reinforcement are neither used in concrete nor in composite construction today..t)]~ LmT"e\ Figure 6 Composite Columns 1932 (Emperger 1932 596) n 1931 Rudol1 Saliger Professor at Vienna University reported several test series on composite columns of the Bauer-Type (Saliger 1931; Bauer 1930). These Columns were examined as an alternative to steel or concrete columns in two highrise buildings in Vienna. Saliger can be considered Empergers rival as he strictly avoided calling Emperger s name in his article. Later on Emperger had a dispute with Saliger about the application of the Addition-Law (Bauingenieur 1931656). During the 1930s additional tests in Germany were made by (Memmler Bierett and Grüning 1934) on steel columns 1illed with comete and by (Gehler and Amos 1936) on concrete columns rein1orced with structural steel. The latter ones led to the 1irst German building regulations on composite columns. They were passed in 1943 (DN 1045-1943). 27 d) dealt with concrete columns reinforced with structural steel Figure 7. This paragraph existed until 1972 when the design of rein1orced concrete columns was based on the ultimate load theory and officials decided that structural steel members encased in concrete should be designed to carry the loads alone without considering the strength of the concrete (Bonzel Bub and Funk 1972 49). But lack 01 steel during war and post-war period prevented the use of composite columns in Germany. n 1act engineers were instructed to save steel by using concrete columns with a minimum 01 reinforcement: «zur Einsparung von Stahl... Saulen... zu wahlen deren Bewehrungszahl f.l in der Nahe der unteren Grenze liegt» (DN 1045-194321).
792 H. Eggemann.... l ~ ~. l ~ " 1 l 1 " V ~ Al étlmlllet" tkiget Figure 7 Concrete Columns reinforced with Structural Steel (DN 1045-1943 Fig. 23) Composite columns with solid steel core- Successor of the Emperger-Column n 1965 Boll applied for a patent claiming a column with a solid steel core with its core bearing the load and the surrounding concrete shell providing buckling safety and fire protection (Off. 1559482). Later in 1969 he tried to execute such columns in a high-rise building in Hamburg. Lack of time prevented the approval by building authorities meaning the building had to be constructed with regular columns (Boll and Vogel 1969 259). The connection to Empergers column is obvious. A solid core is surrounded by reinforced concrete preventing the core from buckling. Strong hooping is provided too. Lateral reinforcement was to be realized using bars of 12 mm spacing 7.5 cm Figure 8. This type of column was first realised in 1976 in a hospital in Vienna (Krapfenbauer 1976). There are two recent examples of buildings with steel core columns one is a high-rise building in Cologne the so-called «Kolnturrn» where steel core columns were used in the lower floors. The other is the Millenium- Tower in Vienna completed in 1999. Because of Empergers connection to Vienna this building will be described in paragraph Building Case Histories. Today this type of column es within the scope of Eurocode 4. ~ ;1ZmmSfmb Rippenlofólahj OZmm 8oW!oJ fgewebe SO.JSlíNS mm ~ Jlo/ llrern ;ZZOmmSJ7 8auóla/ lgewe/;e Ng. Sp.SQ.ZS./Smm ;1Zmmsfmb Figure 8 Composite Column with Solid Steel Core (Boll and Vogel 1969260) Simplified Design Method of Eurocode 4 for Composite Columns The simplified design method of Eurocode 4 is based on the method developed at Bochum University by (Roik et al. 1976). Similar to Empergers Addition- Law the ultimate load of a composite column is: Npl.Rd =A/Yd + Aca/cd + A/d where fyd is the yield strength of the structural steel fcdis the compressive strength of the concrete and fsd is the yield strength of the reinforcing steel. Buckling safety is provided by a factor k by which the ultimate load has to be multiplied. The factor k is given by European buckling curves of Eurocode 3. t has to be ca!culated as a function of the non-dimensional slendemess A.. An even more simplified design method for composite columns for the specific needs of architects and structural engineers during predimensioning was developed at Aachen U niversity by (Eggemann 2002). t determines the factor k as a function of the slenderness ratio L/R where L is the length of the column and R is the effective radius of gyration. Furtherrnore numerous means are provided to ca!culate the effective radius of gyration of a composite column with the radius of the steel section multiplied by a correction factor a.
DeveJopment of composite cojumns. Empergers etfort 793 BULDNG CASE HSTORES The application of composite columns especially of the Emperger type is illustrated in this paragraph by two old buildings and one recent example. McGraw-Hill Building Chicago 1929 Architect: Thielbar & Fugard Chicago Engineer: James B. Black Chicago The McGraw-Hill Building in Chicago Figure 9 was builtin 1929.lt was 30to 38 m (looto \25 ft.) in plan and 58 m (190 f.) high with 16 storeys over ground confer to typical floor plan Figure 10. Emperger- Columns were used with a sol id core of cast-iron: Cored Concrete C01umns- To conserve space the designers adopted a composite column known as the Emperger type in which the use of a solid cast-iran core permits a relatively smal cross-section. The core is supplemented by the usual vertical bars and spiral reinforcement (ENR 1929 129). n designing the McGraw-Hil Building the columns were made of uniform section (24 and 26 in. square [61 and 66 cm]) from basement to roof for economy convenience and rapidity in construction... The variation in carrying capacity was obtained by reducing the cast-iron cores gradualy fram 12ft to 3 in. [32.4 to 7.6 cm] in diameter. For the upper floors where cores were not needed standard hooped concrete was used (ENR J930 277). A special detail of a column joint was developed Figure 11. The cores were milled to be truly square with the axis. Each core extended 5 in. (12.7 cm) above floor level then a pipe sleeve was placed over the coreo The pipe was filled with grout and the next core was set into the pipe adjusted and fixed in the formwork before the comete was poured. One curiosity has to be mentioned: n 1998 the building was demolished and by 2000 it had been 1 111~\!f~. ~~ ~f "p t~." r~..~ ~ ~... ~-- -.~. -."-- ~ "54.~ ~:~--~.-- ~~~~~l~ LOflme-" 32 Tí < i ~1 "! 1 : L : ó ">.9 "~ Court Above Jrd Floor....28" Corridor.J. 1118. 10 18 26 d í.- ~C ~ ; ú- : ;. : 1! " 11 íll " t j ~ lí 1.. 1 " " ; H " ~~" " ". C~l" "tu. 1111::<1 " :~~..-~ -.--4S19f. -".- " J 41 34 Offíce Space *y 39 :;] 46 " 45 43 17 25 33 4Q Mic.higan Ave. Figure 9 McGraw-Hill Building Chicago 1929 (ENR 1929 129) Figure 10 Typical Floor Plan McGraw-Hill Building (ENR 1929 130)
794 H. Eggemann Figure 11 Detail of Column-Joint in McGraw-Hill Building (ENR 1929 130) Figure 12 View in First Floor of Telephone-Factory Budapest (Enyedi 1931244) rebuilt with the original facade attached to a new structure. The feat was demanded by preservationists and City Hall. The lower part of the building now contains a shopping mall where one can see large Lego models ofthe building itself and five others e.g. Chicagos Sears Tower and John Hancock Center (skyscrapers 2002). Telephone-Factory Budapest 1930 Architect: N. N. Engineer: Béla Enyedi Budapest o; CJi 2Q...! i wr; 1Qi.1M Schnitt mz-m2 The Telephone-Factory in Budapest Hungary is one of the few documented buildings in Europe designed with Emperger-Columns. Built in 1930 it has got a framed structure with a column spacing of about 560 m square. For the reason of transparency and cable assembly the structure was built without floorbeams using flared heads instead Figure 12. To achieve the smallest possible column proportionsthe company wanted columns of less than 40 cm square with the option of adding another storey-the columns were designed according to the Emperger type but with a core of mild steel instead of cast-iron: «[Es] wurden umschnürte Stützen mit steifen FluBeiseneinlagen System Dr. Emperger gewahlt» (Enyedi 1931 242). The columns were made of octagonal sections 39 cm in view and with a strong hooping (spiral reinforcement). The columns on the basement made of ordinary reinforced concrete 66 cm square had more than double the cross-section area Figure 13. Figure 13 - r} -.39 _.r!1.l 1o.f/ _r:!!l ""S" ~_LOQ~ 6060 \.1Q~ 66 _.-!1L j6.~~qf..m ~"@""" 8i./ : "-.. y< : 39""[ ~ ~ Schnitt m-m ~ 1 ~:J~~ t:::j"f. Í<_..6.L Column Section of Telephone-FactOry Budapest (Enyedi 1931 243) ~.. ~;
Development of composite columns. Emperger s effort 795 Millenium-Tower Vienna 1999 Architect: Peichl Podrecca and Weber nnsbruck Engineer: Tschemmernegg Obholzer and Baumann nnsbruck The 50-storey Millenium Tower in Vienna is the tallest building in Austria with a height of 202 m Figure 14. After construction had been started in 1998 it took less than one year until its completion in 1999. The structure consists of a reinforced concrete core while composite construction was used for the ceilings and columns in the office areas (Tschemmernegg 1999 607). The exterior columns are made of comete filled hollow sections with solid steel cores Figure 15. The columns themselves have a diameter of 406.4 mm fram first to 14th floor and 323.9 mm above. The cores were gradually reduced Figure 15 Composite Column with Solid Steel Core Millenium Tower (Angerer Rubin and Taus 1999642) fram 220 mm to 85 mm and above the 39th floor no cores were needed. Euracode 4 was used for the design of both structure and fire-resistance. Shear connection between concrete and structural steel was realised by special nails. ABSTRACT AND CONCLUSON Figure 14 Millenium Tower under Construction 1999 (Tschemmemegg 1999610) During the first half of the 20th century a lot of research was done on composite columns. The combination of materials had different motivations steel columns were often encased in concrete to pratect them fram fire while concrete columns were combined with structural steel as a reinforcement. n 1911 the Austrian engineer Fritz von Emperger (1862-1942) applied for a patent on the later socalled Emperger-Column granted in 1916. This column was made of a hollow cast-iran section embedded in spiral-reinforced concrete. Until the 1930s this type of column had been used in several buildings in the United States one of them beeing the 30-storey Trustees Building in Chicago. n the Krolick-Warehouse in Detrait columns reached a load-bearing capacity of 9 MN. n 1932 Emperger gave a report on composite columns at the First Congress of the nternational Association for Bridge and Structural Engineering. He mentioned more than 1500 tested specimens in Europe and North America among those were 138 tests done by himself. Emperger classified four different types of composite colurnos. The load
796 H. Eggemann carrying capacity of a composite column was given according to the Addition-Law drawn up by Emperger as the sum of the strength of the steel increased by that of the concrete. Emperger complained about the lack of design rules for composite columns in Europe. He mentioned the American building regulations which gave explicit formulas for both the Emperger-Column and the stee column encased in concrete: «Für die beiden... Saulenformen bestehen in keinem europaischen Staate Vorschriften [There are no regulations for these two types of columns in any of the European countries]» (Emperger 1931 265). The research program of (Gehler and Amos 1936) led to the first german building regulations for composite columns defined in the German code for reinforced concrete DN 1045 in 1943. t can be said that Emperger was not only a pioneer in concrete construction but also a pioneer in composite construction. Emperger s influence on the construction is obvious. His Addition-Law can still be found in the design method of todays Eurocode 4 and the composite column type of an encased solid steel core used e.g. in the construction of Viennas Millenium Tower reminds us of the so-called Emperger-CoJumn and can be accounted to be its successor. REFERENCE LST AC. 1920. American Concrete nstitute. Standard Specifications No. 23. Standard Building Regulations for the Use of Reinforced Concrete. in: Proceedings. AC. Vol. 16: 283-302. AC. 1928. American Concrete nstitute. Tentative Building Regulations for Reinforced Concrete (E-A-28T). in: Proceedings. AC. Vol. 24: 791-828. Angerer. T.. D. Rubin. and M. Taus. 1999. Verbundstützen und Querkraftanschlüsse beim Millenium Tower. Stahlbau 68: 641-46. Bauer. Bruno. 1930. Eine neuartige Herstellung von Eisenbetonbauten. Beton u. Eisen 29: 3] 2-15. Bol. K.. and U. Vogel. 1969. Die Stahlkernstütze und ihre Bemessung. Bautechnik 46: 253-62 303-09. Bonzel. J.. H. Bub. and P. Funk. 1972. ErHiuterungen zu den Stahlbetonbestimmungen. Band. 7. Auflage. Berlin München. Düsseldorf: Wilhelm Ernst & Sohn. DlN 1045. 1943. A. Bestimmungen für die Ausführung von Bauwerken aus Stahlbeton. 4. Ausg. 1943. Berlin: Beuth 1943. DlNV ENV 1994-1-1. Eurocode 4: Bemessung und Konstruktion von Verbundtragwerken aus Stahl und Beton Teil ]-1: Algemeine Bemessungsregeln - Bemessungsregeln für den Hochbau. Februar 1994. Eggemann. Ho]ger. 2002. Vereinfachte Bemessung von Verbundstützen im Hochbau. Entwicklung historische Bemessung und Her]eitung eines Naherungsverfahrens. Dr.-ng. diss.. Aachen University. Emperger. Fritz von. 1907a. Drei Versuche mit Eisenbetonsaulen. Beton u. Eisen 6: ]01-04. -. 1907b Welche statische Bedeutung hat die Einbetonierung einer Eisensaule? Beton u. Eisen 6: 172-74. -. 1908. Versuche mit Saulen aus Eisenbeton und mit einbetonierten Eisensaulen in Stuttgart und Wien. Forscherarbeiten auf dem Gebiete des Eisenbetons. Heft V. Berlin: Wi]helm Ernst & Sohn. -. 1913. Neuere Bogenbrücken aus umschnürtem GuBeisen System Dr. ng. Fritz Edler von Emperger. Berlin: Wilhelm Ernst & Sohn. -. ]930. Der Wettbewerb zwischen Eisen und Eisenbeton im Hochbau. Zentralblatt der Bauverwaltung 50. Supplement «Konstruktion und Ausführung»: K81-84. -. 193 la. Die Saule im amerikanischen Hochhausbau. Beton u. Eisen 30: 264--65. -. 1931b. Die umschnürte Stahlsaule. Stahlbau 4: 188-89. -. 1932. Verbundsaulen. in: First Congress ofnternationaj Association for Bridge and Structural Engineering. Zurich. ABSE. Preliminary Publication. Vol 1: 595-6] 6. ENR. ]929. Cast-ron Cores used in Co]umns of 16-Storey Concrete Building. Engineering News-Record Ju]y 25: 129-31. ENR. 1930. Reinforced-Concrete Co]umns with Cast-lron Cores. Engineering News-Record Feb. 13: 277-78. Enyedi Béla. 1931. Telephonfabrikgebaude bei Budapest. Beton u. Eisen 30: 241-45. Geh]er. Willy. ] 933. Erlauterungen zu den Eisenbeton- Bestimmungen 1932 mit Beispie]en. 5. neub. u. erg. Autl. Berlin: Wilhelm Ernst & Sohn. Gehler. W.. and H. Amos. 1936. Versuche an Saulen mit Walzprofilbewehrung. Deutscher AusschuB für Eisenbeton. Heft 8]. Berlin: Wilhelm Ernst & Sohn. Kleinlogel. A. ] 932. Zum 70. Geburtstage F. von Empergers. Beton u. Eisen 31: 1-4. Krapfenbauer. R. 1976. Die Verwenduug von Kernb]ockstützen beim Neubau des Algemeinen Krankenhauses in Wien. Bauingenieur 51: 307-]0. Memm]er. K. G. Bierett. and G. Grüning. 1934. Tragfahigkeit von Stah]stützen mit Betonkern bei mittigem Kraftangriff. Stah]bau 7: 49-53. 61-64. Mensch. L. J. 1930. Composite Columns. Journal. AC. No. 23. Nov. ]930: 263-80. Mbrsch. Emi1. []902] ]9]2. Der Eisenbetonbau seine Theorie und Anwendung. 4. vollst. neu bearb. und verm. Aufl. Stuttgart: Konrad Wittwer.
Development of composite columns. Emperger s etfort 797 Offenlegungsschrift Nr. 1559482. DeUtsches Patentamt. Dipl.-ng. Kuno Bol1 Stuttgart. Stahlkernstützen. Offenlegungstag: 5. Marz 1970. Patentschrift Nr. 291068. Kaiserliches Patentamt. Dr.-ng. Fritz von Emperger in Wien. Hohle GuBeisensaule mit einem Mantel aus umschnürtem Beton. Patentiert im Deutschen Reiche vom 24. anuar 1911 ab. Roik K. R. Bergmann H. Bode and G. Wagenknecht. 1976. Tragfahigkeit von einbetonierten Stahlstützen. lnstitut für konstruktiven lngenieurbau Bochum University Mitteilung 76-4. Saliger Rudolf. 1931. Versuche an betonumschnürten Stahlsaulen. Bauingenieur 12: 255-58 282-86. Skyscrapers. 2002. www.skyscrapers.comlengjish/worldmap/ building/0.9/ 02644/index.html Tschemmernegg F. 1999. nnsbrucker Mischbautechnologie im Wiener Millenium-Tower. Stahlbau 68: 606--1]. Viest1. M.. P. Colaco R. W. Furlong L. G. Griffis R. T. Leon and L. A. Wyl1ie r. 1997. Composite Construction Design for Buildings. New York: McGraw-Hill and ASCE.