The acceleration due to gravity will always be present. It appears you are subtracting that value from one of the axes when the device is in a particular orientation.
What you will need to do to detect gestures is to detect the tiny difference that momentarily appears from the acceleration due to gravity as the devices begins moving. You won't be able to detect if the device is stationary or moving at a constant velocity, but you will be able to determine if it is turning or being accelerated.
The (x,y,z) values give you a vector, which gives the direction of the acceleration. You can compute the (square of the) length of this vector as x^2 + y^2 + x^2. If this is the same as when the device is at rest, then you know the device is unaccelerated, but in a certain orientation. (Either at rest, or moving at a constant velocity.)
To detect movement, you need to notice the momentary change in the length of this vector as the device begins to move, and again when it is brought to a stop. This change will likely be tiny compared to gravity.
You will need to compare the orientation of the acceleration vector during the movement to determine the direction of the motion. Note that you won't be able to distinguish every gesture. For example, moving the device forward (and stopping there) has the same effect as tilting the device slightly, and then bringing it back to the same orientation.
The easier gestures to detect are those which change the orientation of the device. Other gestures, such as a punching motion, will be harder to detect. They will show up as a change in the length of the acceleration vector, but the amount of change will likely be tiny.
The above discussion is for normalized values of x, y, and z. You will need to determine the values to subtract from the readings to get the vector. From a comment above, it looks like 766 are the "zero" values to subtract. But they might be different for the different axes on your device. Measure the readings with the devices oriented in all six directions. That is get the maximum and minimum values for x, y, and z. The central values should be halfway between the extremes (and hopefully 766).
Certain gestures will have telltale signatures.
Dropping the device will reduce the acceleration vector momentarily, then increase it momentarily as the device is brought to a stop.
Raising the device will increase the vector momentarily, before decreasing it momentarily.
A forward motion will increase the vector momentarily, but tilt it slightly forward, then increase it again momentarily, but tilted backward, as the device is brought to a stop.
Most of the time the length of the vector will equal the acceleration due to gravity.