16 C.F.R. § 1207.5
(2) Angle. Swimming pool slide ladders not using rungs shall be designed and installed in such a manner that the user's center of gravity will be approximately positioned directly over each step during the use of the ladder. When tread design ladders are used, the minimum installed angle shall be not less than 15° from a plumbline dropped from a ladder step as shown in figure A. If stairs or ramps are used to ascent to the top of the slide, they shall be designed in accordance with reference (c) of § 1207.11, pages 457-463.

(3) Steps—(i) Dimensions. Slide ladder treads may have flat or curved tread surfaces and shall be designed so that they have a minimum tread width of 2 inches (5.08 cm) and a minimum length of 12 inches (30.48 cm) (reference (c) of § 1207.11). The riser height of slide ladder treads shall be no more than 12 inches (30.5 cm) nor less than 7 inches (17.8 cm) and shall be constant over the entire height of the ladder (reference (c) of § 1207.11).

(B) Performance test. A wooden block shall be prepared in accordance with figure C. The contact surface area of the block shall be 8 square inches (51.61 square cm) to simulate the ball of the foot (reference (d) of § 1207.11). It shall be covered with 1/4± 1/8 inch (.64±.32 cm) of natural or silicone rubber sponge capped with porous soft leather as shown in figure C.

The tests shall be carried out on a slide assembled and installed according to the manufacturer's instructions. The block shall be soaked in pool water for at least 3 minutes and placed at the midpoint of the wet step with the centroid of load of the block on the longitudinal axis of the step. The block shall be loaded symmetrically on its upper bearing surface with a weight of 300±2 pounds (136.1±.9 kg). A controlled and measured force shall be applied at the tangential load ring of the block tangent to the horizontal and increased at a rate of no more than 20 pounds (88.96 newtons) per second. If the block does not move at the point that the tangential load is equal to 105 pounds (467.1 newtons), the tread surface passes this performance test. Other force-creating means that produce equal forces on the block (300±2lbs, 1,334 newtons) may be substituted for weights if they result in substantially identical slip-resistance measurements.
(d) Handrails. Swimming pool slide ladders shall be equipped with handrails to aid the slider in safely making the transition to the runway. The handrails shall extend no more than 18 inches (45.72 cm) above the top of the slide runway platform (see figure D1).

(2) Extent of handrails—(i) Maximum angle ladder. If ladder handrails for a ladder inclined 15 degrees or less from the vertical extend below the slide transition area, they shall be parallel to the ladder rails at a perpendicular distance from them of 4 to 6 inches (10.16 to 15.24 cm) (see figure D2). The handrail shall begin 3 to 5 feet (0.91 to 1.52 meters) above the pool deck. Handrails should not provide a means of entrapment.

(ii) Extent of handrails for ladders, steps, stairs, or ramps. For slides not using the minimum angle ladder (15 degrees or less from the vertical), the perpendicular distance between the ladder handrails and the ladder rails below the slide transition area shall be the distance “l” as shown in table 1.
| Ladders: 15°<θ<40° | L=(34.09θrad−3.86) ±1″=(86.59θrad−9.80)±2.54 cm |
| Stairs: 40°<θ<70° | l = 34″ ±1″= 86.36 ±2.54 cm |
| Ramps: θ<70° | l = 42″ ±1″= 106.68±2.54 cm |
(4) Attachment and strength of handrails. Handrails and their fasteners shall withstand allowable shear, bending, and cyclical loading in intended use and reasonably foreseeable abuse. All fasteners for handrail connections shall be vibrationproof, selflocking, and tamperproof. Threaded fasteners shall be capable of withstanding a 1-foot-pound (1,356-newton meter) back-off torque.
(i) Sockets performance test. If handrail sockets are used, the handrail end shall be permanently fixed in the socket so that it cannot be pulled out or bent at the socket by a moment of 233 foot-pounds (316 newton-meters) applied clockwise around point A in figure E. The socket shall not permanently deform under the maximum applied loads.

(ii) Side forces. If the handrail is in a socket or attached to the side of the slide runway rail, the attachment methods must be capable of withstanding all shear and bending forces induced by a 172-foot-pound (233-newton-meter) moment counterclockwise around point A in figure F.

(iii) Performance tests—(A) Strength for climbing and falls. (1) Attach a pull loop to point C of the upper handrail (figure E). Point C is the point where a perpendicular to the axis of the handrail passes through point A, the socket, or other attachment point. Attach a stranded steel cable or wire rope to point C. All cables and ropes shall have at least a 1,000-pound (4,448-newton) tensile capacity. Attach a 162-pound (73.5-kg) weight to this cable at least 4 feet (1.22 meters) below point C. Observe any permanent deformation or bending on the hand-rail at point A. If none exists, the handrail passes this performance test.
(2) Lift the weight one foot (30.48 cm) from its maximum static position and drop it. Observe any permanent deformation of the handrail or its attachments at point A. If each handrail will still support the 162-pound (73.5-kg) weight for a period of 15 minutes and has not been bent more than 45° from its original direction, it passes this performance test.
(2) Dynamic equilibrium.
(4) Runway side-rail heights. Runway side-rail heights shall be designed as a function of the maximum slide-slope angle (as shown in figure H). Table 2 that follows shows side-rail height versus maximum slide-slope angle. If the maximum slide-slope angle is not shown in table 2, the next higher side-rail height must be used. Maximum slide-slope angles shall not exceed 75°. (See figure H.)

| ψ = Maximum slide-slope angle | Runway side-rail height inches (centimeters) |
|---|---|
| <60° | 2 (5.08) |
| 60-70° | 3 (7.62) |
| 70-75° | 31⁄2 (8.89) |

(5) Slide geometry. Swimming pool slide runways shall have a smooth transition section and have geometry such that the path of the center of gravity of the slider is not more than ±10° from the horizontal at the center of gravity's exit off the slide and such that the slider's angle of attack (α), shown in figure I and defined below, shall be at least + 15° when the slider's feet leave the slide. (See figure I.)
(i) Performance tests. Measurement of the 50th-percentile adult male (71±2 inches and 162±5 pounds, 180.34±5.08 cm and 73.5±2.3 kg) 1 slider's angle of attack shall be made using any of the following methods or their equivalent:
(ii) Measurements shall be made from the still water level as the horizontal. The path angle shall be determined by measuring the angle between a tangent to the path of the center of gravity (line X) and the horizontal taken through the center of gravity (line Y). At least five consecutive runs with the same subject shall be made in order that an average may be computed. 2 Angle of attack shall be taken as the angle between the slider's longitudinal axis (Z) and the tangent to the path of his center of gravity (X). The slider's longitudinal axis shall be located by the vertical line that passes through his center of gravity when he stands erect. The slider shall wear usual swimming attire. The angle-of-attack measurement shall be made after the slider's feet have cleared the slide, the distance between the end of the slide and his feet being less than 8 inches (20.3 cm). The slider's descent must be headfirst, prone, belly-down, and with arms extended in front. Except when starting, the slider shall not augment the slide trip by forcibly reacting with the slide through the use of his hands, arms, feet and/or legs. The slider's starting reactions with the slide shall be only as strong as necessary to start him moving. If the average angle of attack measured and computed in the above manner is equal to or greater than + 15°, the slide passes this performance test.

(6) Runway exit lips. All runway exit lips of swimming pool slides shall be smoothly faired into the runway surface with a radius of curvature at the exit lip of the slide of at least 2 1/4 inches (5.72 cm) (see figure J).

(8)
(iii) Performance tests—(A) Static loads. Assemble and install a slide according to the manufacturer's instructions. Prepare a 20-square-inch (129.03 square cm) load-bearing pallet according to figure K. Place the loaded pallet on the upper slide platform, positioned between the runway rails, until the scale on the hoist line reads between 0 and 10 pounds (0 and 44.48 newtons). Keep the pallet in this position for 10 minutes. Remove the loaded pallet and observe the runway for any significant structural failure such as permanent deformations or cracks. If there are none, the slide passes the test. Repeat the same test on the lower runway exit ramp.

(B) Dynamic loads. (1) Assemble and install a slide according to the manufacturer's instructions. Use the hardwood load pallet shown in figure K and set it up under dynamic load guides fabricated as shown in figure L, or an equivalent impact-testing machine.

(2) Fabricate a 45-pound (20.4-kg) billet of 4.900±0.005-inch (12.45±.01 cm) steel rod as shown in figure M, or equivalent, and load into the pipe above the trigger slot. The length of the pipe from the trigger slot to the impact pallet shall be 10.0±0.1 feet (3.05 meters±3.05 cm).

(3) Drop the billet onto the pallet and observe the slide for any permanent deformations or cracks. If the slide runway can still support a static load of 350 pounds (1,557 newtons) on the pallet without further crack propagation, it passes this test.
(4) Perform the test on the entrance and exit platforms of the slide runway.
(Note: To convert the English system values given in the figures to metric values, the following conversion factors should be used: 1 inch = 2.54 cm., 1 foot = 30.48 cm., 1 square inch = 6.452 sq. cm., 1 lb. (mass) = 0.4536 kg., 1 lb. (force) = 4.448 newtons, and 1 ft.-lb. = 1.356 newton-meters.)
1 See reference (f) of § 1207.11 for full discussion.
2 Maximum measurement variation of ±15 percent.
[41 FR 2751, Jan. 19, 1976; 41 FR 9307, Mar. 4, 1976; 41 FR 10062, Mar. 9, 1976, as amended at 41 FR 12638, Mar. 26, 1976; 41 FR 13911, Apr. 1, 1976]