認可人士、註冊結構工程師及註冊岩土工程師作業備考 APP PDF Free Download

2009 年 8 月按新分類方法重新發布的認可人士註冊結構工程師及註冊岩土工程師作業備考 APP-142 屋宇署認可人士及註冊結構工程師作業備考 296 2004 年混凝土的結構使用作業守則 2004 年混凝土的結構使用作業守則 ( 下稱守則 ") 於 2004 年 12 月公布業界如使用整套守則, 並符合守則的要求, 便可視作符合建築物 ( 建造 ) 規例 ( 下稱規例 ") 下有關混凝土設計的規定如於 2006 年 12 月 15 日後就新建築發展計劃或改動及加建工程呈交結構或基礎圖則以申請批准, 有關工程的混凝土設計必須以守則為依據 2. 守則載列了規例下某些條文的可作替代規定建築事務監督在接獲以指明表格填寫的申請後, 會批准對規例的相關條文作出變通, 以准許改用這些替代規定附錄 A 載列了規例內可能須予變通的相關條文一覽表 3. 自 2004 年守則公布以來, 根據使用守則的經驗顯示, 守則某些內容須予修訂和改良, 以臻完善守則的各項修訂詳列於附錄 B 主要的更改事項如下 : (a) 混凝土的分類改為 (i)c45 或以下的等級 ( 以往為 C40 或以下的等級 );(ii)c45 以上至 C70 級 ( 以往為 C40 以上至 C70 級 ); 以及 (iii)c70 以上至 C100 級 ) C45 是業界通常使用的等級, 對於已達到 C45 級的混凝土而言, 許多沿用的設計工具和電腦程式仍可繼續使用, 無須更改設計程式 (b) 守則圖 6.1 載示了混凝土處於極限狀態時的簡化應力區, 圖表內容已經修訂, 藉以清楚顯示上文 (a) 段提述的 3 類混凝土的應力區 (c) 其他改動大多數是由於上述修訂, 或是勘正印刷和圖表錯誤所致

- 2-4. 上述各項修訂會納入來次編印的守則內守則的更新版本已上載屋宇署網頁 http://www.bd.gov.hk 中, 刊物 " 欄下作業守則和設計手冊 " 部分, 以供瀏覽在不違反網站條款及規則的情況下, 市民可隨意下載建築事務監督張孝威檔號 : BD GR/1-125/58 初版 : 2007 年 6 月 ( 助理署長 / 拓展 2) 編入索引 : 混凝土的結構使用作業守則混凝土 - 結構使用作業守則

附錄 A ( 認可人士及註冊結構工程師作業備考 296) (APP-142) 建築物 ( 建造 ) 規例內可能須予變通的條文一覽表建築物 ( 建項目造 ) 規例 1 第 56(2) 條事項水泥含量限於每立方米 550 公斤守則的相關段落 / 列表第 4.2.6 段備註如每立方米混凝土的水泥含量超過 550 公斤, 則須就規例進行變通 2 第 57 條及表 6 訂明最低水泥含量表 4.2, 以及第 4.2.5.4 段如水泥含量低於指明下限, 則須就規例進行變通 3 第 58 條混凝土立方塊須為 150 毫米第 10.3.4.2 段如使用 100 毫米的混凝土立方塊, 則須就規例進行變通 4 第 59 條及表 8 混凝土立方塊的接受準則表 10.2 如使用守則表 10.2 的 C2 準則, 便須就規例進行變通 (2007 年 6 月 )

- 1 - 附錄 B ( 認可人士及註冊結構工程師作業備考 296) (APP-142) 2004 年混凝土的結構使用作業守則的各項修訂 Clause 1.2 (page 1) Delete Hong Kong Code of Practice for Dead and Imposed Loads for Buildings Clause 2.3.1.1 (page 8) Replace the first and second bullet points the following: characteristic dead load, G k, which shall be taken as the dead loads calculated in accordance Building (Construction) Regulation 16; characteristic imposed load, Q k, which shall be taken as the imposed loads stipulated in Building (Construction) Regulation 17; and Clause 2.3.1.4 (d) (page 9) Replace the clause the following: (d) Vehicular impact Where vertical elements are to be designed for vehicular impact the nominal design load shall be as specified in Building (Construction) Regulation 17. Figure 3.3 (page 17) At the Y-axis, : Shrinkage K c : Creep/shrinkage K c Figure 3.5 (page 17) At the Y-axis, : Shrinkage K j : Creep/shrinkage K j

- 2 - Clause 3.1.8 (page 18) In the definition of c s, : 4.0 : 3.0 Figure 3.8 (page 19) Replace : See table 3.2 fcu : 3.46 + 3.21 kn/mm 2 γ m Replace : 2.4 10 4 : f cu γ m 1.34( f cu /γ m ) E c Clause 4.2.7.1 (page 29) Replace : section 10 : Table 4.5 Clause 5.2.1.1 (e) (page 33) Delete and the height is at least 3 times the section depth. Clause 5.2.1.2 (b) (page 36) In the pen-ultimate paragraph: : taken as the elastic or redistributed values : taken as the greater of the elastic or redistributed values Figure 6.1 (page 41) Replace : 0.9x : 0.9x for f cu 45 N/mm 2, 0.8x for 45< f cu 70 N/mm 2, or 0.72x for 70< f cu 100 N/mm 2.

- 3 - Equation 6.1 (page 41) Replace the existing equation the following : x 0.5d for f cu 45 N/mm 2 ; Equation 6.2 (page 41) Replace the existing equation the following : x 0.4d for 45 < f cu 70 N/mm 2 ; or Equation 6.4 (page 41) Replace the existing equation the following : x (β b - 0.4)d for f cu 45 N/mm 2 ; or Equation 6.5 (page 41) Replace the existing equation the following : x (β b - 0.5)d for 45 < f cu 70 N/mm 2 Equation 6.8 (page 42) Replace the existing equation the following : K = 0.156 for f cu 45 N/mm 2 ; or 0.120 for 45< f cu 70 N/mm 2 ; or 0.094 for 70< f cu 100N/mm 2 and no moment redistribution. Equation 6.9 (page 42) Replace the existing equation the following : K = 0.402(β b -0.4) - 0.18(β b -0.4) 2, for f cu 45 N/mm 2 ; or 0.357(β b -0.5) - 0.143(β b -0.5) 2, for 45< f cu 70 N/mm 2.

- 4 - Equations 6.11 and 6.14 (page 42) Replace the existing equations the following : x = (d - z)/0.45, for f cu 45 N/mm 2 ; or (d - z)/0.40, for 45< f cu 70 N/mm 2 ; or (d - z)/0.36, for 70< f cu 100 N/mm 2. Equation 6.17 (page 42) Replace the existing equation the following : A s = M + k1 f cubwd( k2d h f ) 0.87 f y (d 0.5h f ) where k 1 = 0.1 for f cu 45 N/mm 2, 0.072 for 45< f cu 70 N/mm 2 and 0.054 for 70<f cu 100 N/mm 2 ; and k 2 = 0.45 for f cu 45 N/mm 2, 0.32 for 45< f cu 70 N/mm 2 and 0.24 for 70<f cu 100 N/mm 2. Equation 6.18 (page 43) Replace the existing equation the following: h f b h w f b β = 0.45 1 1 + K' w f d b 2d b Table 6.3 (page 44) In the last column, : 400 : 400 Clause 6.1.2.5 (page 45) In line 9 under item (e): : αand βare both greater than 45 º : α and β are both equal to or greater than 45 º.

- 5 - Table 6.8 (page 55) In third column, : A sb > : A sb Figure 6.12 (page 67) Replace : 1.4ν t (see clause 6.1.5.6(b) : 1.4ν t (see clause 6.1.5.6(c)) Clause 6.1.5.7(e) (page 69) In the last sentence: Replace : 0.4ud/087f yv. : v r ud/087f yv, where ν r is defined in Table 6.2. Clause 6.2.1.3 (page 75) In line 3 under item (c), : 6.49 : 6.48 Figure 6.17 (page 77) Interchange all k 1 and k 2. Interchange all M 1 and M 2. Clause 6.3.2 (page 84) In the second paragraph, : St. Venant torsional stiffness : torsional constant

- 6 - Equation 6.64 (page 84) Replace the existing equation the following : 1 C = βh 3 minh max. 2 Table 6.17 (page 85) In the last line, : N/mm 3 : N/mm 2 Table 6.18 (page 85) Replacing the existing Table 6.18 the following: v v c + v r v > v c + v r v t v t min v t > v t min Minimum shear reinforcement; no torsion reinforcement Designed shear reinforcement; no torsion reinforcement Notes: v is defined in Table 6.2. r Table 6.18 - Reinforcement for shear and torsion Designed torsion reinforcement but not less than the minimum shear reinforcement Designed shear and torsion reinforcement Clause 6.7.2.2 (page 91) In line 7, : L c : l c

- 7 - Figure 6.19 (page 92) Replace the existing Figure 6.19 the following new Figure 6.19. Figure 6.19 Critical section for shear check in a pile cap Clause 7.1.5 (page 96) In line 6, : at the ends of the ranges : in table 3.2 Clause 7.2.3 (page 97) Before the definition of a under equation 7.2, add: ε 1 is the strain at the level considered, calculated ignoring the stiffening effect of the concrete in the tension zone,

- 8 - Clause 7.2.3 (page 97) In the paragraph after equation 7.2, : In this 7.2 : In equation 7.2 Table 7.4 (page 101) In Notes 2, : clause 6.1.2.4(c) : clause 6.1.2.4(b) Table 7.5 (page 101) In Notes 2, : A : A s,prov Clause 7.3.6(a) (page 105) Under the third bullet point, : 1/(1+φ) times the short-term modulus where φ : 1/(1+φ c ) times the short-term modulus where φ c Figure 7.1a) (page 106) In the strain diagram, : f s / E : f / E s s Clause 8.6 (page 114) In the paragraph after the definitions of notations for equation 8.7, : equation 8.5 : equation 8.7

- 9 - Figure 8.5 (page 116) Replace the existing Figure 8.5 the following new Figure 8.5. < s s s s < s s s φ = diameter of the lapped reinforcement s = 75 mm or 6φ, whichever is the greater Note : For laps in bottom of section as cast minimum * cover criteria applies to corner bars only Figure 8.5 Factors for lapping bars Figure 8.6 (page 118) Replace the existing Figure 8.6 the following new Figure 8.6. Figure 8.6 Transverse reinforcement for lapped splices

- 10 - Clause 8.8 (pages 118-119) In the line preceding Figure 8.7, : In figure 8.7a, n 1 =1, n 2 =1 : In figure 8.7a, n 1 =1, n 2 =2 In the second and last paragraphs, delete (see clause 9.2.4). At the end of the last paragraph, insert the following: A ct,ext denotes the area of the tensile concrete external to the links, defined by Figure 8.7c. Figure 8.7 (page 118) Replace the existing Figure 8.7 the following new Figure 8.7. Figure 8.7 Additional reinforcement for large diameter bars

- 11 - Clause 9.1 (page 128) Add the following paragraphs at the end of the clause 9.1: Detailing of members should normally comply both the general detailing rules given in clauses 9.2 to 9.8 and the particular rules for ductility given in clause 9.9. However, members not contributing in the lateral load resisting system do not need to conform to the requirements of clause 9.9. Equation 9.4 (page 131) Replacing the existing equation 9.4 the following: A sv v r b v s v /(0.87f yv ) 9.4 where v r is defined in Table 6.2. Clause 9.4.3 (page 133) Replace : A full anchorage length beyond the centreline of the supporting member should be provided for top tension reinforcement of a cantilevered projecting structure. : A full anchorage length should be provided for the top tension reinforcement of a cantilevered projecting structure. Where full rotational restraint is provided at the near face of the supporting member, i.e. the face at which the bar enters the supporting member, the anchorage shall be deemed to commence at 1/2 the width of the supporting member or 1/2 the effective depth of the cantilevered projecting structure whichever is the less, from the near face of the supporting member. Where the cantilevered projecting structure is a continuous slab or beam and the support is not designed to provide rotational restraint in the analysis of the continuous structure, the anchorage shall be deemed to commence at the far face of the supporting member. Clause 9.9.1.1(d) (page 138) Before the definition for f yt, add: n number of bars uniformly spaced around circular sections, or the number of longitudinal bars in the layer through which a potential plane of splitting would pass,

- 12 - Clause 9.9.2.1(a) (page 139) Replace : The area of longitudinal reinforcement shall not be greater than 4% of the gross concrete area except that at laps the area may increase to 5.2%. : The area of longitudinal reinforcement for strength design shall not be greater than 4% of the gross concrete area except that at laps the area may increase to 5.2%. Clause 10.3.4.1 (page 143) In the first bullet point in paragraph 2, : clause 13.1.8.1 : clause 12.1.8.1 Clause 10.3.6.1 (page 147) In line 4 of the last paragraph, : all concrete mixes of grade C60 or above : all concrete mixes of grade greater than C60 Table 12.1 (page 166) In the second column, : C30 : C35 Clause 12.3.4.3 (page 166) In line 5 of the second paragraph, : class 1 and class 2 : groups a) and b) In line 6 of the second paragraph, : class 3 : group c)

- 13 - Table 12.2 (page 166) In the third column, : C30 : C35 Clause 12.3.7.1 (page 168) Replace the second bullet point (including the Note) the following : the design stresses in the concrete in compression are derived either from the stress-strain curve given in figure 3.8 or from the simplified stress block given in figure 6.1, γ m = 1.5 in both cases; Equations 12.2 and 12.3 (page 168) Replace the existing equations the following: 70000λ 1 f pu A ps f pb = f pe + 1 0.7λ l 2 f d cubd 12.2 f pu A ps f pb x = λ 2 d f cubd f pu 12.3 2 where λ 1 = 1 for fcu 60 N/mm, or 1 0.017 f cu 60 for f cu >60N/mm 2, and 2 λ 2 = 2.58 for f cu 45 N/mm, 2.78 for 45 < fcu 70 N/mm 2 100 N/mm 2., or 3.09 for 70 < f cu Table 12.5 (page 171) In the second column, : 30 N/mm 2 : 35 N/mm 2 Clause 12.3.8.7 (page 171) In the caption, : where V r = 0.4fcub v d for f cu 40N/mm 2 or 0.4(f cu /40) : where V r = v r b v d and v r is as defined in Table 6.2. 2/3 bvd for f cu >40N/mm. 2

- 14 - Equation 12.7 (page 172) Replace the existing equation the following : A sv s v Vr = 12.7 0.87 f yv d ANNEX A In the first paragraph, : the Code of Practice for the Structural Use of Concrete (Limit State Approach) : this Code of Practice ANNEX A Delete the second bullet point, i.e. Hong Kong Code of Practice for Dead and Imposed Loads for Buildings (6/2007)

認可人士、註冊結構工程師及註冊岩土工程師作業備考 APP-142