1/ weber.anc 5 BFX formerly Conrep.5 BFX PURE EPOXY ANCHORING RESIN IN CARTRIDGE PRODUCT weber.anc 5 BFX is a two-component high strength pure epoxy chemical anchoring resin system. It is especially recoended in heavy loads applications, for anchoring of rebar and studs in solid concrete. FEATURES High bond strength with High load resistance Use with all grades of threaded rod and rebar Solvent free odorless resin, no shrinkage High durability For deep embedment installations Longer working times for large holes Used in dry and wet concrete Used in flooded holes Used in corrosive environments Suitable for diamond drilled holes Used for elevated temperatures - temperature ranges I, II and III Used for rebar installations Low shrinkage enables large diameter installations Close edge distance and small spacing Manual cleaning up to diameter and embedment depths of 2 Use with potable water F0 fire resistant CHARACTERISTICS Compressive strength at 7 days Flexural Strength Flexural Modulus Bond strength at 14 days Water Absorption at hours Modulus of Elasticity at 7 days VOC Content N/2 (MPa).56* 52.79 4331 * 0.1%* 37* A+ Rating *in compliance with ASTM C1/1M- type I to VII requirements PACKAGING Lebanon Syria Jordan UAE Qatar Kuwait KSA Oman 0ml 0ml 0ml 0ml 0ml 0ml 0ml 0ml SCOPE OF USE Rebar anchoring (Doweling) in concrete Threaded rod and stud anchoring in concrete Horizontal, vertical and overhead applications Test Method ASTM D695 ASTM D790 ASTM D790 ASTM C2 ASTM D570 ASTM D695 Working Time and Minimum Curing Time Minimum curing Concrete Temperature Gel Working Time time in dry concrete 5 C 0 min 9 min 15 C min 0 min 25 C min 300 min 35 C min 1 min C 9 min 0 min 45 C 6 min 90 min Full cure hours. All specifications based on supplied mixer Minimum curing time in wet concrete x2 x2 x2 x2 x2 x2 STORAGE Can be stored up to 2 years from manufacturing date if stored away from heat and direct sunlight and protected from freezing temperatures. Product should be stored between +5 C and +25 C.
2/ weber.anc 5 BFX formerly Conrep.5 BFX Product Application Drilling hole and cleaning Drill hole in the substrate to the required embedment depth using the appropriately sized carbide drill bit.bore hole cleaning just before setting an anchor, the bore hole must be free of dust and debris. The manual pump shall be used for blowing out bore holes up to diameters do and embedment depths up to hef d. Blow out at least 4 times from the back of the bore hole, using an extension if needed. Brush 4 times with the specified brush (see table 6) by inserting the steel brush to the back of the hole (if needed with an extension) in a twisting motion and removing it. Blow out again with manual pump at least 4 times. Compressed air cleaning(cac) for all bore hole diameters do and all bore hole depths. Blow 2 times from the back of the hole(if needed with a nozzle extension) over the whole length with oil-free compressed air (min.6 bar at 6 m 3 /h). Brush 2 times with the specified brush size (see table 6) by inserting the steel brush to the back of the hole (if needed with an extension) in a twisting motion and removing it. x2 Blow out again with compressed air at least 2 times. Installation Remove the threaded cap from the cartridge.tightly attach the mixing nozzle.do not modify the mixer in any way. Made sure the mixing element is inside the mixer.use only the supplied mixer. Insert the cartridge into the dispenser gun. Discard the initial trigger pulls of adhesive. Discard the first ml of resin. Inject the adhesive starting at the back of the hole, slowly withdrawing the mixer with each trigger pull. Fill holes approximately 2/3 full, to ensure that the annular gap between the anchor and the concrete is completely filled with adhesive along the embedment depth. Before use, verify that the threaded rod is dry and free of contaminants. Install the threaded rod to the required embedment depth during the open gel time tgel has elapsed. The working time tgel is given in table 7. The anchor can be loaded after the required curing time tcure (see table7). The applied torque shall not exceed the values Tmax given in table 1.
3/ weber.anc 5 BFX formerly Conrep.5 BFX Consumption Rebar 14 1 22 25 2 32 36 15 22 25 27 30 35 44 Adhesive volume per cm of embedment ml 0.423 0.9 6 4 1.530 1.697 2.333 2.472 2.770 4.46 5.727 6.299.765 Example: 25 diameter rebar with an embedment of cm 2.77 cm3/cm. x cm = 27.7 ml/anchoring 0 ml/cartridge 27.7 ml/anchoring = 14 anchoring / cartridge Section 1: Design tensile resistance used with various stud strengths, material and rebar Section 2: Bond Strength Factors Section 3: Tension Edge and Spacing reduction factors
4/ weber.anc 5 BFX formerly Conrep.5 BFX Section 1- Design tensile resistance used with various stud strengths, material and rebar. Table 1: 5. Grade Steel ding H ef failure Depth () 14 7.5 11. 11.3 17.7 29.1 2.3 36.3 29.2 45.4 5 54.4 0 0 67 5 3 1.7.1 29.2 54.4 H ef failure 27 30 33 36 Depth () 2 32 35 3 2.7 35.9 39.5 44.5 47.4 53.3 62.2 0 53.9 66.7 74.1 77. 1.4 1 71.1.0.9 93.3 97.7 1 75.4 3 93.4 3.7.9 114.0 2 4.9 94. 6.7 11.5 4.4 130.3 2 11.5 133.4 14.2 155.5 2.9 300 2.4 155.6 172.9 11.5 190.0 3 159.1 194.5 7.4 217.2 0 2.6 2.6 4 23.2 0 237 3 35 394 464 522 4.9 2.4 159.1 194.5 2.6 23.2 = steel failure Recoended is obtained by multiplying Design resistance by 4 Data shown below the minimum embedment depth is for reference only. Please refer to manufacturer for advice. Table 2:. Grade Steel ding H ef failure Depth () 14 7.5 11. 11.3 17 15.1 29.0 23.6 2.3 36.3 19.5 29.5 35.3 45.4 5 30.9 45.0 5.1 0 72.6 0 3.7 2 4 131 159 231 19.5 30.9 45.0 3.7
5/ weber.anc 5 BFX formerly Conrep.5 BFX H ef failure 2 27 32 30 35 33 3 36 Depth () 35.9 39.5 44.5 47.4 53.3 0 53. 66.7 74.1 77. 1.4 1 71.1.0.9 93.3 97.7 1 75.4 3.0 93.4 6.1 7.6 94. 11.5 6.7 133.4 3.7 11.5 14.2.9 4.4 155.5 114.0 130.3 2.9 2 2 300 5.6 13.3 155.6 172.9 11.5 190.0 3 130.7 15.1 177. 197.6 7.4 217.2 0 1.3 213.4 237.1. 2.6 4 4. 296.4 311.1 325. 0 299.2 342.2 370.1 35.3 390.9 6 7 364 476 551 6 714 3 130.7 1.3 4. 299.2 370.1 435.7 = steel failure under tensile load Data shown below the minimum embedment depth is for reference only. Please refer to manufacturer for advice. Recoended is obtained by multiplying Design resistance by 4. Table 3:.9 Grade Steel ding H ef failure Depth () 14 7.5 11. 11.3 17 15.1 29.0 23.6 2.3 36.3 23.6 29.5 35.3 45.4 5 27.2 37.7 45.2 5.1 0 56.6 72.6 0 62.6 7.1 2 1.6 1.6 2 3 144 13 221 321 27.2 62.6 1.6 H ef failure 2 27 32 30 35 33 3 36 Depth () 2.7 35.9 39.5 44.5 47.4 53.3 62.2 0 53. 66.7 74.1 77. 1.4 1 71.1.0.9 93.3 97.7 1 75.4 6.1 3.0 94. 93.4 6.7 3.7 11.5.9 4.4 114.0 130.3 2 2 7.6 11.5 133.4 14.2 155.5 2.9 300 5.6 13.3 155.6 172.9 11.5 190.0 3 143.5 15.1 177. 197.6 7.4 217.2 0 19.7 213.4 237.1. 2.6 4 266.7 296.4 311.1 342.2 325. 35.3 390.9 0 6 7 7 664 767 44 994 111 12.0 262.2 341.0 4.7 515.5 6.9 = steel failure under tensile load Data shown below the minimum embedment depth is for reference only. Please refer to manufacturer for advice. Recoended is obtained by multiplying Design resistance by 4.
6/ weber.anc 5 BFX formerly Conrep.5 BFX Table 4: A4-70 Stainless Steel ding H ef failure Depth () 14 7.5 11. 11.3 17.0 13.7 29.0 21.7 2.3 36.3 31.6 45.4 5 5.1 0 5. 0 2 73 92 1 2 13.7 21.7 31.6 5. 2 27 32 30 35 33 3 36 Depth () 2.7 = steel failure under tensile load Recoended is obtained by multiplying Design resistance by 4 Data shown below the minimum embedment depth is for reference only. Please refer to manufacturer for advice. Table 5: A4- Stainless Steel ding 35.9 39.5 47.4 44.5 53.3 62.2 0 53. 66.7 74.1 77. 1.4 1 H ef failure 75.4 6.1 91.7 256 91.7 71.1 3.0 94. 11.5 132.1 334 132.1.2 *1 11.2.9 9.1 *1 199 9.1 93.3.9 1.3 *1 234 1.3 97.7 114.0 130.3 142. *1 263 142. 1 2 2 300 3 *1 = Tensile strength 0N/ 2 H ef failure 14 Depth () 7.5 11. 11.3 17.0 15.1 29.0 15.7 23.6 2.3 36.3. 35.3 45.4 5 36.1 5.1 0 67.2 0 2 3 5 15 15.7. 36.1 67.2 27 30 2 32 35 2.7 35.9 39.5 44.5 47.4 53.3 53. 66.7 74.1 71.1.2.9 75.4 3.0 9.1 6.1 94. 4. 11.5 132.1 *2 *1 *1 292 334 11 199 4. 132.1.2 9.1 33 36 3 77. 1.4 93.3 97.7.9 1.3 114.0 130.3 142. *1 *1 234 263 1.3 142. Depth () 0 1 1 2 2 300 3 *1=Tensile strength 0N/ 2 = steel failure under tensile load *2 = Tensile strength 700N/ 2 Recoended is obtained by multiplying Design resistance by 4 Data shown below the minimum embedment depth is for reference only. Please refer to manufacturer for advice.
7/ weber.anc 5 BFX formerly Conrep.5 BFX Table 6: High bond reinforcing bars F yk=0n/² H ef failure - 15 14 1 22 Depth () 11.2 14.0 15.1 14.0 17.5 21.4 23.7 25.9..9 25.7 2.5 31.1 0.9 26.2 2.3 32.1 35.6 3.9 1 21.9 31.4 33.9 3.5 42.7 46.7 1 34.1 39.6 44.9 49.9 54.4 2 45.2 51.3 57.0 62.2 2 49.2 64.1 71.2 77. 300 3.1 90.7 3 157 196 261 313 36 427 21.9 34.1 49.2 67.0 7.4 1.7 25 22 27 25 30 2 35 32 36 44 Depth () 23.9 2.7 31.6 35.9 37.7 0 35.9 39.5 44.9 47.1 53.9.6 1 47.4 53.9 56.6 72.7 1.3 55.3 62. 66.0 75.4 4. 2 57.5 63.2 71. 74.5 6.2 97.0 2 71.1. 4. 71. 79.0 9. 94.3 3. 92.2 4.7 1 97.0 7.7 5.7 9.11.2 141.4 113.15.7 146.6 270 300 3 95. 5.3 119.7 5.7 143.6 1.6 7.6 0 131.7 149.6 157.1 179.5 2.0 9.5 0 1.5 215.5 2.4 251.4 0 25.5 290.9 301.6 7 323.2 335.1 0 571 62 657 52 974 9 1304 136.6 5.3 196.5 267. 349.7 443.5 546.3 = steel failure under tensile load Data shown below the minimum embedment depth is for reference only. Please refer to manufacturer for advice. Recoended is obtained by multiplying Design resistance by 4.
/ weber.anc 5 BFX formerly Conrep.5 BFX Table 7: High bond reinforcing bars fyk= 4N/ 2 Rebar 15 25 25 30 2 35 32 36 44 Depth () H ef failure 70 90 1 0 130 1 0 0 2 2 3 0 0 5 6 7 0.4 9. 11.2.6 14.0 15.4. 1.2 1.4 132 1.4.5.2 13.2 14.0 15.1 19.0 19.2 15.7 17.5 17.0 21.4 21.5 23.7 23.9 29.9 19.2.9.7 26.1 26.3 32.9 34.6 2.5 2.7 35.9 37.7 22.7.5 30.9 31.1 3.9. 46.7.4 27.9 2.7 26.4 33.2 33.5 41.9 44.0.3 56.6 30.2 3.0 3.3 47.9.3 57.5 67.0 37.7 41.3 70 90 1 0 130 1 0 0 2 2 3 0 0 5 6 7 0 47.5 47.9 59. 62. 71.. 3. 57.0 66.5 73.4 57.5 71. 75.4 6.2 97.0.5 67.0 3..0.5 113.1 117.3 76.6 95..5 114.9 9.3 134.1 95. 119.7 149.6 5.7 157.1 176.0 143.6 1.6 7.6 179.5 2.0 9.5 1.1 229. 226.2 234.6 25.5 26.1 290.9 301.6 335.1 4 219 309 479 552 7 1 922 95 2.7 41.3 73.4 114. 5.1 225.0 293.7 372.5 45.9 = steel failure under tensile load Data shown below the minimum embedment depth is for reference only. Please refer to manufacturer for advice. Recoended is obtained by multiplying Design resistance by 4.
9/ weber.anc 5 BFX formerly Conrep.5 BFX Section 1-Notes Formulas used for design tensile resistance calculation: N rd(kn)= τd*π*d*hef where: N rd : Design tensile Resistance τd: Design Bond strength derived from test results from the Characteristic Bond Strength (N/ 2 ) τd=.5 N/ 2 for rebar - (non-cracked C/25 temp I dry and wet concrete, anchor spacing d, anchor edge d) τd =.3 N/ 2 for rebar - 30 (non-cracked C/25 temp I dry and wet concrete, anchor spacing d, anchor edge d) d= nominal diameter of anchor () hef = nominal embedment depth of anchor () N rds(kn) = A X fy,s/ɤms where: N rds :Design Steel tensile load () A: Cross sectional area of anchor Fy,s :Yield Strength of Anchor ɤMs: Safety Factor of 1.15 Safety factor is 1.4 for BSt 0 rebar Safety factor is 1.56 for stainless steel, up to M, M30 and M36 is 2.0 Safety factor is 1.5 for all carbon steel hef,s= N rds/(τd*π*d) where: hef,s: Depth of steel failure τd: Design Bond strength derived from test results from the Characteristic Bond Strength (N/ 2 ) d= nominal diameter of anchor (). Section 2- Bond Strength Factors 2.1 and threaded rod Influence of concrete strength on combined pull out and concrete cone resistance Concrete Strength N/ 2 (MPa) fc= C15/ 0.9 C/25 C25/30 1.02 C30/37 1.04 C35/45 1.06 C/ 1.0 C45/55 1.09 C/ 1. Influence of environmental conditions in non-cracked concrete Temp I C/ C Temp II C/43 C Ø Ø Ø Ø Ø 1 Ø Ø 22 Ø 25 Ø 2 Ø 32 0.94 0.7 0.79 0.57 0. 0.43 0.36 0.61 0.59 0.57 0.54 0.52 0. 0.4 0.46 Temp III 72 C/43 C 0.57 0.57 0.56 0.54 0.54 0.53 0.52 0.51 0.52 0. 0.51 0. 0.4 0.47 0.46 0.49 0.47 0.45 0.44 0.42
/ weber.anc 5 BFX formerly Conrep.5 BFX Influence of environmental conditions in cracked concrete Temp I C/ C Temp II C/43 C Ø Ø Ø Ø Ø Ø Ø 27 Ø 30 Ø 33 Ø 36 0. 0.4 0.46 0.45 0.43 0.41 0. 0.3 0. 0.42 0.3 0.3 0.32 0.2 0. 0. 0.32 0.32 0.31 0.29 0.30 0.2 0.29 0.27 0.2 0.25 0.27 0.23 0.22 0.25 0. Temp III 72 C/43 C 0.27 0.27 0.27 0.27 0.25 0.25 0. 0.23 0. 0.25 0.25 0. 0.23 0.22 Temperature Ranges Temperature Range Range I Range II Range III Concrete Service Temperature - C to + C - C to + C - C to +72 C Maximum Long Term Concrete Temp + C +43 C +43 C Maximum Short Term Concrete Temp + C + C +72 C Service temperature range: Range of ambient temperatures after installation and during the lifetime of the anchor. Short term temperature: Temperatures within the service temperature range which vary over short intervals,e.g. day/night cycles and freeze/thaw cycles. Long term temperature: Temperature, within the service temperature range, which will be approximately constant over significant periods of time. Long term temperatures will include constant or near constant temperatures, such as those experienced in cold stores or next to heating installations. 2.2- Rebar Influence of concrete strength on combined pull out and concrete cone resistance Concrete Strength N/ 2 (MPa) C15/ C/25 C25/30 C30/37 C35/45 C/ C45/55 C/ C55/67 C/75 C70/5 C/96 C90/5 fc= 0.9 1.02 1.04 1.06 1.0 1.09 1. 1. 1. 1.13 1.14 1.15 Influence of environmental conditions in non-cracked concrete Temp I C/ C Temp II C/43 C Ø Ø Ø Ø 14 Ø Ø 1 Ø Ø 22 Ø 25 Ø 2 Ø 32 0.94 0.90 0.7 0.5 0.2 0. 0.61 0. 0.62 0.59 0.62 0.59 0.61 0.5 0.61 0.57 0. 0.56 0. 0.55 0.59 0.47 Temp III 72 C/43 C 0. 0.5 0.5 0.56 0.57 0.57 0.53 0.52 0.56 0. 0.56 0.56 0.55 0.55 0.54 0.53 0.47 0.47 0.46 0.45 0.43 0.41
11/ weber.anc 5 BFX formerly Conrep.5 BFX Influence of environmental conditions in cracked concrete Temp I C/ C Temp II C/43 C Ø Ø Ø Ø 14 Ø Ø 1 Ø Ø 22 Ø 25 Ø 2 Ø 32 0.55 0.51 0.47 0.45 0.44 0.43 0.43 0.42 0.41 0.55 0.4 0.42 0.41 0. 0.39 0.3 0.36 0.35 0.30 0.30 0.29 0.2 0.2 0.27 0.27 0.25 0.25 0. 0. 0.23 0.23 0.22 0.23 0.22 Temp III 72 C/43 C 0.30 0.2 0.30 0.2 0.25 0.25 0. 0. 0.23 0.25 0. 0. 0.23 0.23 0.22 0.22 Temperature Ranges Temperature Range Range I Range II Range III Concrete Service Temperature - C to + C - C to + C - C to +72 C Maximum Long Term Concrete Temp + C +43 C +43 C Maximum Short Term Concrete Temp + C + C +72 C Service temperature range: Range of ambient temperatures after installation and during the lifetime of the anchor. Short term temperature: Temperatures within the service temperature range which vary over short intervals, e.g. day/night cycles and freeze/thaw cycles. Long term temperature: Temperature, within the service temperature range, which will be approximately constant over significant periods of time. Long term temperatures will include constant or near constant temperatures, such as those experienced in cold stores or next to heating installations. Section 3- Tension Edge and Spacing reduction factors 3.1 Effect of Anchor Spacing - Tension Anchor Spacing 70 90 0 1 0 175 0 225 2 2 275 2 300 3 3 0 4 4 5 0 6 7 0 0.79 0.2 0.7 0.96 0.79 0. 0.2 0.5 0.90 0.95 0. 0.4 0.7 0.91 0.95 / Rebar 0.77 0.79 0. 0.3 0.4 0.77 0.79 0.1 0.3 27 0.75 0.7 0. 0.2 0.7 0.91 0.94 30 0.7 0.2 0.5 0.93 33 0.77 0. 0.3 0.91 0.96 36 0.75 0.7 0.1 0.4 0.96 0.79 0.1 0.4 0.91 0.95
/ weber.anc 5 BFX formerly Conrep.5 BFX 3.2 Effect of Edge Distance - Tension Edge Distance 70 90 1 0 1 0 1 0 2 2 270 300 330 3 0 0.2 0.90 0.77 0.4 0.91 0. 0. 0.9 / Rebar 0.77 0.4 0.91 0.7 0.4 0.9 27 0.75 0.1 30 0.1 33 0.75 0. 0.7 0.94 36 0.7 0.2 0.7 0.93 0.9 0.75 0.7 0.3 0.93 0.9 PG: Edition: /14-A T +961 1 563/4 M +961 3 374 F +961 1 562 sodamco@sodamco.com www.sodamco-weber.com Lebanon. UAE. Syria. Qatar. KSA. Jordan. Kuwait. Oman