Zero point drift compensating flowmeter

The invention claimed is: 1. A pressure sensor, comprising: a first pressure detection device configured to detect the pressure of fluid in a pipe line in which the fluid flows; and a second pressure detection device for compensation of a zero point drift configured to detect the pressure of fluid at a position different from a position of the first pressure detection device, wherein the zero point drift of a pressure of the first pressure detection device is compensated by substituting a value of a minimum pressure value obtained from an output of the first pressure detection device with a minimum pressure value obtained from a pulse wave propagation time and a pressure change amount, the pulse wave propagation time representing the time difference propagating between different two portions in the pipe line recorded between the first and second pressure detection devices, the pressure change amount being obtained from the output of the first pressure detection device. 2. A mass flowmeter, comprising: a first strain gauge disposed in a bent section in a pipe line in which a centrifugal force or a centripetal force of fluid is acted, the fluid flows in the pipe line, and configured to detect the centrifugal force or the centripetal force of fluid; and a second strain gauge which is disposed in the straight section in the pipe line different from the bent section; a third strain gauge for a static pressure compensation disposed in a straight section in the pipe line different from the second strain gauge, wherein a zero-point drift of a flow rate is compensated by substituting a value of a minimum pressure value obtained from an output of the first strain gauge with a minimum pressure value obtained from a pulse wave propagation time, a second pulse wave propagation time and a pressure change amount, the pulse wave propagation time represents the time difference propagating between different two portions in the pipe line recorded between the first and second strain gauges, the second pulse wave propagation time represents the time difference propagating between the two portions in the pipe line recorded between the second and third strain gauges, and the pressure change amount being obtained from each output of the first and third strain gauges. 3. The mass flowmeter according to claim 2 , wherein a tube of elastic material is formed in the different two points in the pipe line between the first and second strain gauges. 4. The mass flowmeter according to claim 2 , wherein a signal, after the zero point drift compensation using the pulse wave propagation time, is output as a pressure signal. 5. The mass flowmeter according to claim 4 , wherein the pipe line resistance is measured from the pressure signal and the flow rate measured using the bent section. 6. A mass flowmeter, comprising: a first strain gauge disposed in a bent section in a pipe line in which a centrifugal force or a centripetal force of fluid is acted, the fluid flows in the pipe line, and configured to detect the centrifugal force or the centripetal force of fluid; and a check valve provided in the straight section in the pipe line the check valve configured to open when a fixed pressure is applied to the pipe line, a third strain gauge for a static pressure compensation disposed in a straight section in the pipe line different from the second strain gauge, and wherein a third pulse wave propagation time is calculated based on a time of a fixed pressure change amount in the first strain gauge and an opening time of the check valve, the third pulse wave propagation time represents the time difference propagating between different two portions in the pipe line recorded between the first strain gauge and the check valve, a fourth pulse wave propagation time is calculated based on a time of a fixed pressure change amount in the third strain gauge and an opening time of the check valve, the third pulse wave propagation time represents the time difference propagating between the two portions in the pipe line recorded between the third strain gauge and the check valve, and a zero-point drift of a flow rate is compensated by substituting a minimum pressure value obtained from an output of the first pressure detection device with a minimum pressure value obtained from the third pulse wave propagation time, the fourth pulse wave propagation time and a pressure change amount, the pressure change amount being obtained based on each of the outputs of the first and third strain gauges.