Capelli C, Pendergast D R, Termin B
Dipartimento di Scienze e Tecnologie Biomediche, Facoltà di Medicina e Chirurgia, Udine, Italy.
Eur J Appl Physiol Occup Physiol. 1998 Oct;78(5):385-93. doi: 10.1007/s004210050435.
The energy cost per unit of distance (Cs, kilojoules per metre) of the front-crawl, back, breast and butterfly strokes was assessed in 20 elite swimmers. At sub-maximal speeds (v), Cs was measured dividing steady-state oxygen consumption (VO2) by the speed (v, metres per second). At supra-maximal v, Cs was calculated by dividing the total metabolic energy (E, kilojoules) spent in covering 45.7, 91.4 and 182.9 m by the distance. E was obtained as: E = Ean + alphaVO2maxtp - alphaVO2maxtau(1 - e(-(tp/tau))), where Ean was the amount of energy (kilojoules) derived from anaerobic sources, VO2max litres per second was the maximal oxygen uptake, alpha( = 20.9 kJ x 1 O2(-1)) was the energy equivalent of O2, tau (24 s) was the time constant assumed for the attainment of VO2max at muscle level at the onset of exercise, and tp (seconds) was the performance time. The lactic acid component was assumed to increase exponentially with tp to an asymptotic value of 0.418 kJ x kg(-1) of body mass for tp> or =120 s. The lactic acid component of Ean was obtained from the net increase of lactate concentration after exercise (delta[La]b) assuming that, when delta[La]b = 1 mmol x 1(-1) the net amount of metabolic energy released by lactate formation was 0.069 kJ x kg(-1). Over the entire range of v, front crawl was the least costly stroke. For example at 1 m x s(-1), Cs amounted, on average, to 0.70, 0.84, 0.82 and 0.124 kJ x m(-1) in front crawl, backstroke, butterfly and breaststroke, respectively; at 1.5 m x s(-1), Cs was 1.23, 1.47, 1.55 and 1.87 kJ x m(-1) in the four strokes, respectively. The Cs was a continuous function of the speed in all of the four strokes. It increased exponentially in crawl and backstroke, whereas in butterfly Cs attained a minimum at the two lowest v to increase exponentially at higher v. The Cs in breaststroke was a linear function of the v, probably because of the considerable amount of energy spent in this stroke for accelerating the body during the pushing phase so as to compensate for the loss of v occurring in the non-propulsive phase.
对20名优秀游泳运动员的自由泳、仰泳、蛙泳和蝶泳每单位距离的能量消耗(Cs,千焦/米)进行了评估。在次最大速度(v)下,通过将稳态耗氧量(VO2)除以速度(v,米/秒)来测量Cs。在超最大v时,Cs通过将在45.7米、91.4米和182.9米距离内消耗的总代谢能量(E,千焦)除以距离来计算。E的计算公式为:E = Ean + alphaVO2maxtp - alphaVO2maxtau(1 - e(-(tp/tau))),其中Ean是无氧来源产生的能量(千焦),VO2max(升/秒)是最大摄氧量,alpha(= 20.9千焦×1 O2(-1))是O2的能量当量,tau(24秒)是运动开始时肌肉水平达到VO2max所假设的时间常数,tp(秒)是运动时间。假设乳酸成分随tp呈指数增加,当tp≥120秒时达到渐近值0.418千焦×千克(-1)体重。Ean的乳酸成分是从运动后乳酸浓度的净增加量(delta[La]b)获得的,假设当delta[La]b = 1毫摩尔×1(-1)时,乳酸形成释放的代谢能量净量为0.069千焦×千克(-1)。在整个v范围内,自由泳是能量消耗最少的泳姿。例如,在1米×秒(-1)时,自由泳、仰泳、蝶泳和蛙泳的Cs平均分别为0.70、0.84、0.82和0.124千焦×米(-1);在1.5米×秒(-1)时,四种泳姿的Cs分别为1.23、1.47、1.55和1.87千焦×米(-1)。Cs在所有四种泳姿中都是速度的连续函数。在自由泳和仰泳中它呈指数增加,而在蝶泳中,Cs在两个最低v时达到最小值,在较高v时呈指数增加。蛙泳中的Cs是v的线性函数,可能是因为在这个泳姿中,在推水阶段为加速身体花费了大量能量,以补偿在非推进阶段发生的v的损失。
