Vapor column liquid accumulator

What is claimed is: 1. A liquid delivery system comprising: a pipe configured to transmit a liquid flow driven by a pump; and a liquid accumulator fluidically connected to the pipe, the liquid accumulator comprising: a chamber containing the liquid and a vapor column; a power source configured to input energy to the chamber to generate vapor from the liquid to form the vapor column, wherein the vapor column constitutes a gas spring to reduce pulsations of the liquid flow in the pipe; and a controller to supply power by the power source based on a duty cycle, wherein the duty cycle is determined based on a difference between a measured pulsation and a pre-set pulsation of the liquid flow in the pipe. 2. The liquid delivery system of claim 1 , wherein the pipe extends through the chamber so that a portion of the pipe is enclosed by the chamber, and the chamber is fluidically connected to the pipe through an orifice on the pipe. 3. The liquid delivery system of claim 1 , wherein the pipe is disposed outside of the chamber, the system further comprises a flange that fluidically connects the chamber and the pipe. 4. The liquid delivery system of claim 1 , wherein the power source includes a heater disposed inside the chamber. 5. The liquid delivery system of claim 1 , wherein the power source includes a heater disposed on an outer surface of the chamber. 6. The liquid delivery system of claim 1 , wherein the power source includes at least one of a piezoelectric actuator, an ultrasound actuator, or a mechanical stirrer. 7. The liquid delivery system of claim 1 , wherein the controller is to control an input energy level by the power source to the chamber, wherein the input energy level input to the chamber adjusts a spring rate of the vapor column. 8. The liquid delivery system of claim 7 , wherein the controller comprises: a comparator configured to compare the measured pulsation of the liquid flow in the pipe downstream of the liquid accumulator with the pre-set pulsation; a proportional-integral-derivative controller configured to determine the duty cycle based on the difference between the measured pulsation and the pre-set pulsation; and a pulse width modulation controller configured to supply the power by the power source based on the duty cycle. 9. The liquid delivery system of claim 7 , wherein the controller is configured to: determine a target spring rate based on a speed of the pump; determine a set point of a parameter which reflects the input energy level; and supply power by the power source based on the set point of the parameter. 10. The liquid delivery system of claim 9 , wherein the supplying power by the power source based on the set point of the parameter further comprises: comparing a measured value of the parameter with the set point of the parameter; in response to determining that the difference between the measured value and the set point is within a pre-defined threshold, maintaining the input energy level; and in response to determining that the difference between the measured value and the set point is beyond the pre-defined threshold, increasing or decreasing the input energy level. 11. The liquid delivery system of claim 9 , wherein the parameter is a temperature in the chamber. 12. An anesthesia agent delivery system comprising: a pump configured to drive an anesthesia agent liquid from a reservoir to a pipe; the pipe configured to transmit a flow of the anesthesia agent to an injector; a liquid accumulator fluidically connected to the pipe, the liquid accumulator comprising: a chamber containing the anesthesia agent liquid and a vapor column; and a power source configured to input energy to the chamber to generate vapor from the anesthesia liquid to form the vapor column, wherein the vapor column constitutes a gas spring to reduce pulsations of the flow in the pipe; and a controller to supply power by the power source based on a duty cycle, wherein the duty cycle is determined based on a difference between a measured pulsation and a pre-set pulsation of the flow in the pipe. 13. The anesthesia agent delivery system of claim 12 , wherein the pipe extends through the chamber so that a portion of the pipe is enclosed by the chamber, the chamber is fluidically connected to the pipe through an orifice on the pipe, the chamber and the pipe are constructed as a one-piece element. 14. The anesthesia agent delivery system of claim 12 , wherein the chamber is made of stainless steel, brass, or PPSU plastics. 15. The anesthesia agent delivery system of claim 12 , wherein the power source is at least one of a heater, a piezoelectric actuator, an ultrasound actuator, or a mechanical stirrer. 16. The anesthesia agent delivery system of claim 12 , wherein the controller is configured to control an input energy level by the power source to the chamber, wherein the input energy level input to the chamber adjusts a spring rate of the vapor column, the controller is further configured to: determine a target spring rate based on a speed of the pump; determine a set point of a parameter which reflects the input energy level; compare a measured value of the parameter with the set point of the parameter; and control the input energy level based on a difference between the measured value and the set point of the parameter. 17. A method for reducing pulsations of a liquid flow, the method comprising: inputting energy to a chamber of a liquid accumulator, wherein the chamber is fluidically connected to a pipe that transmits the liquid flow; generating vapor from the liquid flow to form a vapor column in the chamber; comparing a measured pulsation of the liquid flow with a pre-set pulsation; controlling an input energy level to the chamber based on a difference between the measured pulsation and the pre-set pulsation; and using the vapor column as a gas spring to reduce the pulsations of the liquid flow in the pipe. 18. The method of claim 17 , further comprising: determining a target spring rate based on a speed of the pump; determine a set point of a parameter which reflects the input energy level; and controlling the input energy level to the chamber based on the set point of the parameter.