The 2nd part 2 is put on the 1st part 1 so that the left edge 21 of the part 2 fits a vertical axis 11 of the part 1, and the lower left corner of the part 2 is fitted to a scale, e.g., 43 inches corresponding to the desired length of a club shaft. Then a line 31 is...
Exactly how far you are from the golf ball is determined by the club you’re using. The driver has the longest shaft of any club, so you’re naturally farther away from the ball with the driver than you are with a sand wedge, which has a much shorter shaft. The most important key,...
In the picture on the right, you can see how the golf club is actually still working down long after the strike. The shaft is still stressed as it's working to the low point in the golf swing. The divot is bottoming out now, well in front of where the ball was at address. WHY ...
The only way you can prevent the yips and keep from getting in there and flipping it with your right hand is to grip the club in such a way that when you look down the line, the shaft is in perfect alignment with the forearms, as you can see below. Looking down the line we can...
When my body is rotating at max speed, and I'm trying to execute a wrist release with less than a .05 second margin of error, the clubhead--which is all the way down there at the end of the shaft--has to be immediately responsive to movement by the hands. That requires a fair ...
The 2nd part 2 is put on the 1st part 1 so that the left edge 21 of the part 2 fits a vertical axis 11 of the part 1, and the lower left corner of the part 2 is fitted to a scale, e.g., 43 inches corresponding to the desired length of a club shaft. Then a line 31 is...
SOLUTION: When the head speed of a driver shot by a player is set to (v) (m/sec); the proper frequency of a club, F (freq./sec); the length in measurement of frequency, L (m); and the proportion coefficient, (b); the rigidity of a golf club shaft is adjusted so that the ...