WO 2014/006631 PCT/IN2012/000731 PARTITIONED POOL FIELD OF INVENTION 5 This invention relates to the improvements in the design of a swimming pool used for the competitive swimming races such as in national, international championships and Olympic games. BACKGROUND OF INVENTION 10 The present using swimming pool has some draw-backs. Even though, it is being used in all the above said championships. Due to this faulty design so many efficient swimmers (sometimes few previous Olympic champions) had been disqualified at the preliminary stages in their own countries and they were being made as patients of mental depression. Competitive swimming is a sport like that 15 of running races (sprint events). But, there are some notable differences between swimming and running events. 1. In running races even the athletes are covered by the medium (air) they will have grip on the earth. With that grip only they use their muscle 20 power and run. In swimming events swinuners are suspended in the medium (water) itself. So, they will have no grip to move forward. Hence, they use their energy to float on the medium and then displace the medium to their sides and move forward (Newton's Third Law of Motion). 25 2. Water is 11 times more resistant, 55 times more viscous and 777 times denser than air. 3. In running races we cannot find the boundaries of the medium because, air is everywhere on our planet. 1 WO 2014/006631 PCT/IN2012/000731 In aquatics swimmers are confined to a closed medium where, they find specific boundaries (i.e. side walls and bottom). 4. In running events other athletes are not disturbed by a particular athlete. 5 In aquatics side lane swimmers to a particular swimmer are very much disturbed by the waves produced by him. Draw-backs of the existing swimming pool design 10 The present swimming pool used for competitive swimming has a closed medium. While conducting a competitive race in a closed medium all the participant swimmers must have equal and identical conditions (or) parameters. Parameters: 15 1. Temperature ---------- same to all swimmers. 2. Surface tension-------------same to all swimmers. 3. Density----------------------same to all swimmers. 4. Specific gravity------------same to all swimmers. 20. 5. Depth of the medium-------same to all swimmers 6. Viscosity or fluid friction---same to all swimmers. 7. Boundary conditions-------not same to all swimmers. 8. Wave disturbance-----------not same to all swimmers. 25 Boundary conditions Since, the medium (water) is a Newtonian fluid it obeys the Newton's law of fluid friction (or) Newton's law of viscosity. 2 WO 2014/006631 PCT/IN2012/000731 di T (tau) p dy Where, x(tau)= shear stress p = coefficient of viscosity (or) dynamic viscosity. 5 u = velocity of the swimmer. y = distance from the nearer side wall. -- = velocity gradient dy F = T(tau)xA Where, 10 F = force required by a swimmer to move forward with a velocity of u. A = total wetted area of the swimmer. F =Fi +F 2 15 Where,
F
1 , F 2 are forces with respect to the two side walls. Therefore, dlu dtu F =ptA-+pAdyi dy2 20 yi = nearer side wall distance from the swimmer. Y2 = farer side wall distance from the swimmer. F = ptAu (1/yi+1/y2) = piAu (l/y+l/b-y) 25 Where, b = total width of the pool See Fig- 1 and 2 3 WO 2014/006631 PCT/IN2012/000731 1 =b, 2 = y, 3 = b-y, 4 velocity distribution, 5 nearer side wall, 6 = farer side wall. In the above equation (piAu) is a constant for a particular swimmer in any lane. Therefore, F is inversely proportional to y. 5 So, the swimmers distance from the side wall increases, the force (F) required to move forward will be decreased. The above equation is applicable where, the velocity distribution is linear. For larger widths where, the velocity distribution is parabolic the equation will become as U (= ) (by-y 2 ) plane Poiseuille Flow equation 10 (Fundamental rule of fluid mechanics is whether the object moves through the stationary water or the water moves around the stationary object is alike.) U= - @ (b -y)y Where, dp = Pressure gradient dx 15 (b-y) farer side wall distance from the swimmer. y= nearer side wall distance from the swimmer. In the above equation the value of dx I for a particular swimmer is 20 constant in all lanes. Therefore u M y Velocity of the swimmer is directly proportional to the distance between the swimmer and the side wall of the swimming pool. 25 So, the two side wall distances from a lane play an important role in determining the velocity of a swimmer. 4 WO 2014/006631 PCT/IN2012/000731 As, the swimming race conducting authorities are measuring the race time to an 1 accuracy of Too of a second, the minor variations in velocity should also be taken into account. 5 Several attempts have been made to overcome the above mentioned drawbacks. One such attempt is to provide an extra lane at each end of the pool (extra widening by 5 meters) to rectify the velocity irregularities of the swimmers. Accordingly the swimming pool in the recent Olympics was constructed with 10 10 lanes each of 2.5 meters wide. Only 8 swimmers participated in all the races leaving the end lanes without swimmers. However, the drawbacks still exist. Further it is very important to know about the lane coefficient to understand the boundary conditions in a better way. 15 LANE COEFFICIENT(L.C)- Lane coefficient is the ratio of the distance from the farer side wall to the distance from the nearer side wall(both distances measured from the centre of a lane). L.C of a lane= farer side wall distance / nearer side wall distance 20 L.C of 8thand 1 4t lanes (W+7Lw) / (W-7Lw) L.C of 7thand2"dlanes = (W+5Lw) / (W-5Lw) L.C of 6 t and3rlanes = (W+3Lw) / (W-3Lw) L.C of 5 t h and4'lanes = (W+Lw) / (W-Lw) Where, 25 W = width of the pool Lw = lane width 20 Meter wide swimming pool boundary conditions 1" and 8'h lane coefficient (20+17.5)/(20-17.5) =15.00 30 2 and 7 lane coefficient = (20+12.5)/(20-12.5) = 4.3333 5 WO 2014/006631 PCT/IN2012/000731 3 rd and 6 'h lane coefficient = (20+7.5)/(20-7.5) = 2.2 4 ' and 5'h lane coefficient = (20+2.5)/(20-2.5) = 1.2857 25 Meter wide swimming pool boundary conditions 5 1s and 8 th lane coefficient (25+17.5)/(25-17.5) 5.6666 2 "d and 7th lane coefficient = (25+12.5)/(25-12.5) = 3.0 3rd and 6th lane coefficient (25+7.5)/ (25-7.5) = 1.8571 4 I and 5h lane coefficient (25+2. 5) / (25-2.5)= 1.2222 10 Still, there is a difference between first and fourth lanes after extra widening. So the concept and practice of extra widening is wrong. So, the concept extra widening of the pool by 5 meters does not eliminate the differences in boundary conditions of the participant swimmers. 15 Velocity of the swimmer is inversely proportional to the lane coefficient. Lane coefficient values of all lanes with different pool widths: Pool width 1 and 8 lanes 2 and 7 lanes 3 and 6 lanes 4 and 5 lanes (in meters) 20 15.00 4.3333 2.2000 1.2857 25 5.6666 3.00 1.8571 1.2222 30 3.80 2.4285 1.6666 1.1818 35 3.000 2.111 1.5454 1.1538 40 2.5555 1.9090 1.4615 1.1333 45 2.2727 1.7692 1.4000 1.1176 50 2.0769 1.6666 1.3529 1.1052 55 1.9333 1.5882 1.3157 1.0952 60 1.8235 1.5263 1.2857 1.0869 65 1.7368 1.4761 1.2608 1.0800 70 1.6666 1.4347 1.2400 1.0740 6 WO 2014/006631 PCT/IN2012/000731 75 1.6086 1.400 1.2222 1.0689 80 1.5600 1.3703 1.2068 1.0645 85 1.5185 1.3448 1.1935 1.0606 90 1.4827 1.3225 1.1818 1.0571 95 1.4516 1.3030 1.1714 1.0540 100 1.4242 1.2857 1.1621 1.0512 110 1.3783 1.2564 1.1463 1.0465 120 1.3414 1.2325 1.1333 1.0425 130 1.3111 1.2127 1.1224 1.0392 140 1.2857 1.1960 1.1132 1.0363 150 1.2641 1.1818 1.1052 1.0338 160 1.2456 1.1694 1.0983 1.0317 170 1.2295 1.1587 1.0923 1.0298 180 1.2153 1.1492 1.0869 1.0281 190 1.2028 1.1408 1.0821 1.0266 200 1.1917 1.1333 1.0779 1.0253 250 1.1505 1.1052 1.0618 1.0202 300 1.1238 1.0869 1.0512 1.0168 350 1.1052 1.0740 1.0437 1.0143 400 1.0915 1.0645 1.0382 1.0125 450 1.0809 1.0571 1.0338 1.0111 500 1.0725 1.0512 1.0304 1.010O 550 1.0657 1.0465 1.0276 1.0091 600 1.0600 1.0425 1.0253 1.0083 650 1.0553 1.0392 1.0233 1.0077 700 1.0512 1.0363 1.0216 1.0071 750 1.0477 1.0338 1.0202 1.0066 800 1.0447 1.0317 1.0189 1.0062 850 1.0420 1.0298 1.0178 1.0058 900 1.0396 1.0281 1.0168 1.0055 7 WO 2014/006631 PCT/IN2012/000731 950 1.0375 1.0266 1.0159 1.0052 1,000 1.0356 1.0253 1.0151 1.0050 1,500 1.0236 1.0168 1.0100 1.0033 2,000 1.0176 1.0125 1.0075 1.0025 2,500 1.0140 1.0100 1.0060 1.0020 3,000 1.0117 1.0083 1.0050 1.0016 3,500 1.0100 1.0071 1.0042 1.0014 4,000 1.0087 1.0062 1.0037 1.0012 4,500 1.0078 1.0055 1.0033 1.0011 5,000 1.0070 1.0050 1.0030 1.0010 6,000 1.0058 1.0041 1.0025 1.0008 7,000 1.0050 1.0035 Y.0021 1.0007 8,000 1.0043 1.0031 1.0018 1.0006 9,000 1.0038 1.0027 1.0016 1.0005 10,000 1.0035 1.0025 1.0015 1.0005 15,000 1.0023 1.0016 1.0010 1.0003 20,000 1.0017 1.0012 1.0007 1.0002 25,000 1.0014 1.0010 1.0006 1.0002 30,000 1.0011 1.0008 1.0005 1.0001 35,000 1.0010 1.0007 1.0004 1.0001 If, there has to be no difference in the boundary conditions (up to 3 decimal points) between first and fourth lanes, the pool must be widened up to 35 kilo meters. 5 The discussed above plane Poiseuille flow equation can be written in terms of W and Lw. 8 WO 2014/006631 PCT/IN2012/000731 In 1 "t and 8 t' lanes t- u = W(- )[V 2 - (7Lw) 2 In 2 "d and 7 ' lanes--- = () W2 - (5Lw)2] 8Pd In 3 d dand 6 t' lanes--- u (- ) [ W2 - (3Lw)2] 81L dx In 4"' and 5 ' lanes--- u d.' (- )[ W - (Lw) 2] sp x Wave disturbances 5 The waves produced by the centre lane swimmers move across the lanes and cause disturbance to side lane swimmers. To avoid this problem in 1960's Adolph Kiefer invented wave-crushing [or] wave-eating lane ropes and got patent for them. These lane ropes diminish the waves and make the pool less turbulent. However these also have drawbacks. Actually lane ropes diminish the superficial 10 waves only. They do not prevent the underwater currents because water moves as a continuum. The details are given in Fig. no-3. 1.water surface. 2.top layers of wave. 3. lane rope.4. Middle layers of wave.5. 15 Pool bottom. So, the wave disturbance is not eliminated completely by installing lane ropes. Due to improper boundary conditions and partial elimination of wave disturbances, the final pictures of 200m, 400m, 800m and 1500m races are looked 20 like in inverted "v" shape which is given in Fig.no-4. Where,1 to 8 numbers are lane numbers. 9 WO 2014/006631 PCT/IN2012/000731 The swimmers in 1,2,7,8 lanes have no chances to win a race.(Unless they have extraordinary swimming power among all participant swimmers)Their chances are limited to a little. 5 Therefore, there exists a long felt need to provide swimming pools for competitive swimming which overcomes the above drawbacks and provides equal opportunity to the swimmers in all lanes of winning the race. SUMMARY OF THE INVENTION 10 Accordingly, the present invention provides a new partitioned pool wherein all the lanes are separated by partitions. The partitioned pool according to the present invention do not have wave disturbances (to or from the side lane swimmers) in any of the lanes in the pool. Further, the partitioned pool according to the present invention each lane acts like an individual swimming pool and have a lane 15 coefficient value of 1.00. Furthermore, the partitioned pool according to the present invention provides to all the athletes equal and identical boundary conditions and there would be no splashes from side lanes. Also, according to the present invention it is easy to modify the older pools to partitioned pools as described in herein and it is easy to remake the original pool 20 by removing the partitions. In the partitioned pools according to the present invention the expensive wave eating lane ropes are discarded. DESCRIPTION OF DRAWINGS 25 The present invention will be understood and appreciated more fully from the following detailed description taken in conjunction with the appended drawings in which: Fig. I illustrates the linear velocity distribution. Fig.2 illustrates the parabolic velocity distribution. 10 WO 2014/006631 PCT/IN2012/000731 Fig.3 illustrates the wave movement. Fig.4 inverted " V " shaped final picture of a race. Fig.5 illustrates the plan of the pool as claimed in the present invention. Fig.6 illustrates the cross section of the pool at x-x as claimed in the present 5 invention. DETAILED DESCRIPTION OF THE INVENTION In the following detailed description, numerous specific details are set forth in order to provide a thorough understanding of the invention. However, it will be 10 understood by those skilled in the art that the present invention may be practiced without these specific details. In other instances, well-known methods, procedures, and components have not been described in detail so as to not obscure the present invention. According to one embodiment, the present invention provides a partitioned pool 15 wherein all the lanes are separated by partitions. The partitioned pool according to the present invention does not have wave disturbances (to or from the side lane swimmers) in any of the lanes in the pool. Further, the partitioned pool according to the present invention each lane acts like an individual swimming pool and has a lane coefficient value of 1.00. Furthermore, the partitioned pool according to the 20 present invention provides to all the athletes equal and identical boundary conditions and there would be no wave disturbances and even no splashes from side lanes. According to another embodiment of the present invention the length of the pool is 50m and the width of the pool is 30m. The pool has 8 lanes, 9 partitions. Each 25 lane is 3.66m (12 feet) wide because it is twice the average wing span length of a swimmer to facilitate free swimming action and 1.83m (6 feet) deep to provide a hydraulically most efficient section. (The hydraulically most efficient section is the one which has the minimum wetted perimeter for a particular cross sectional area). To get this section, depth must be half of the lane width.In this type of 11 WO 2014/006631 PCT/IN2012/000731 section drag force will be minimum and velocity is maximum.The Partition height is 2.2m to leave a free board of 0.37m to prevent the splashes from the adjacent lanes. The partitions are made of transparent material (irrespective of the material). If not the partitions must be transparent at least at the top 1.1 m portion 5 to watch the relative positions of the other swimmers by a particular swimmer when race is going on. The number of partitions can be changed depending on the number of lanes. The bottom half partitions are provided (if necessary) with 1 cm dia holes to maintain the water level and water temperature the same in all lanes. According to another embodiment the partition is transparent and can be made of 10 glass, fibre glass, plastic, metal, wood or a combination of these. The partition thickness is about 5 to 20 cms, preferably 8 cms. The free board is 20 to 40 cm preferably 37 cm. The water depth is between 150 to 300 cm preferably 183cm and the width of the lane is between 300 to 400 cm preferably 366 cm. Example: 15 In fig .no -5(plan of the pool). - scale (1:250) Width of the pool - 3000cm.(30m) Length of the pool - 500Ocm.(50m) Lanes - 8 Partitions - 9 20 Lane markings - 8 Starting pads - 8 In fig.no-6 (cross section at x-x). - Scale. (1:50) Partition thickness - 8cm Free board - 37cm 25 Water depth - 183cm Width of the lane - 366cm 12