BEKA Schréder - Smart and sustainable lighting solutions

Design & Construction Details

Material The pole is constructed by the filament winding process to achieve optimum results for strength and rigidity. The filament winding process is continuously applied with uniform tension onto a rotating mandrel, resulting in a minimum mass glass to resin ratio of 70:30. The surface is seamless, smooth and tapered. Finishing coat The material of the finishing coat is a gel coat that complies to SANS 1749 and is applied to a uniform thickness of between 250 and 500 microns, providing a weatherproof, UV-resistant, flame-resistant and impact- strong surface in the colour specified. Mechanical properties A standard pole supporting a luminaire with a wind surface of 0.20m 2 may not have a pole top deflection of more than 5% of its height above ground when subjected to a basic wind pressure of 500 Pa. A safety factor of 2.5 times the total maximum windload is applicable. Material system The pole is manufactured in accordance with SANS 1749 under the ISO 9002 quality system.

Access opening If an access opening is required, the cut-out is covered by an access door cover manufactured from glass filled nylon impregnated in the same colour as that of the surface coat. It is secured to the pole by two stainless steel Allen head captive screws into M4 brass inserts embedded in the pole. Cable entry A cable entry with a minimum diameter of 34mm is provided at a minimum depth of 400mm below the ground surface. Glandplate A hot dipped galvanised glandplate, suitable for gland no. 0 or 1, complete with terminal block and DIN rail for a miniature circuitbreaker, is provided and is mounted to a bolt provided in the access opening. Baseplate Poles for direct embedment in the ground can be provided with a square hot dipped galvanised baseplate complete with 2 x hot dipped galvanised steel hookbolts and nuts. Base-mounted poles have a hot dipped galvanised flange plate that can be bolted to a foundation which is designed to withstand the forces the pole will experience in service.

Relevant Pole Data and Other Factors

Corresponding Calculated Key Values

Load to be applied in pole-top deflection test (N)

Maximum permitted deflection in pole-top deflection test (mm)

Diameter of pole at ground level (mm)

Mounting height (m)

Total length of pole (m)

2.0

2.6

110

135.4

100

2.5

3.1

120

143.4

125

3.0

3.6

128

152.0

150

3.5

4.1

135

161.0

175

4.0

4.6

146

171.6

200

4.5

5.2

155

182.3

225

5.0

5.7

164

193.6

250

5.5

6.3

173

205.4

275

6.0

6.9

170

213.7

300

6.5

7.4

178

225.9

325

7.0

8.0

186

238.6

350

7.5

8.6

194

251.8

375

8.0

9.2

202

265.5

400

8.5

9.8

210

279.7

425

9.0

10.4

218

294.3

450

9.5

11.0

226

309.4

475

10.0

11.6

237

326.8

500

11.5

13.4

290

463.4

575

12.0 600 1. Relevant pole data is based on a shape factor of 0.7 and a calculated wind pressure of 500.14 Pa (relating to a wind speed of 103.9km/h). 2. Corresponding calculated key values are based on a luminaire surface area of 0.2m 2 with a shape factor of 1. NOTES: 14.0 300 504.0

Century City Square, Cape Town

Hout Bay Harbour, Cape Town

Amphitheatre, Durban

168

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