Method for pressure measurement using a Coriolis mass flowmeter and Coriolis mass flowmeter

What is claimed is: 1. A method for pressure measurement using a Coriolis mass flowmeter that has at least one measuring tube, at least one oscillation generator, at least two oscillation sensors, at least one temperature sensor, at least one tension sensor, at least one display unit and at least one control and evaluation unit, wherein the measuring tube has medium flowing through it, wherein the temperature sensor is arranged such that it measures the temperature of the measuring tube and forwards it as a measured temperature value T to the control and evaluation unit, wherein the tension sensor is configured and arranged such that the tension sensor measures the mechanical tension of the measuring tube in an axial direction and in a circumferential direction and forwards a measured axial tension value S a and a measured tension value S h of the circumferential direction to the control and evaluation unit, the method comprising the steps of: measuring the temperature value T with the temperature sensor, measuring a reference temperature T 0 under reference conditions, measuring a tension value S a and S h , measuring reference tension values S a0 and S h0 under reference conditions, recording a pressure p 0 under reference conditions, determining a pressure value within the measuring tube based on the pressure p 0 using an algorithm, and wherein the algorithm takes into account the difference between the measured temperature value T and the reference temperature value T 0 and between the measured tension values S a and S h and reference tension values S a0 and S h0 , and issuing the pressure value determined by means of the algorithm via the at least one display unit, wherein a difference ΔT between the measured temperature value T and the reference measured value T 0 is linearly and/or quadratically implemented into an algorithm for determining the pressure of the medium and wherein a difference ΔS h between the measured tension value S h and the reference measured value S h0 and the difference ΔS a between the measured tension value S a and the reference measured value S a0 is linearly and/or quadratically implemented into the algorithm for determining the pressure of the medium. 2. The method according to claim 1 , wherein the reference conditions comprise the state of the measuring tube in which no medium is flowing through the measuring tube. 3. The method according to claim 1 , wherein the algorithm for determining the pressure of the medium is comprised of the following formula: p=p 0 +c 1 ΔT+c 2 ΔS h , with Δ T=T−T 0 and Δ S h =S h −S h0 and wherein c 1 and c 2 are proportionality factors that determined in the scope of a regression and p and p 0 are pressure values, p being the pressure of the medium measured inside the measuring tube and p 0 being a known pressure. 4. The method according to claim 1 , wherein the algorithm is comprised of the following formula: p=p 0 +c 1 ΔT+c 2 ΔS h +c 3 ΔS a , with Δ T=T−T 0 and Δ S h =S h −S h0 and Δ S a =S a −S a0 , and wherein c 1 , c 2 and c 3 are proportionality factors are determined in the scope of a regression and p and p 0 are pressure values, p being the pressure of the medium measured inside the measuring tube and p 0 being a known pressure. 5. The method according to claim 1 , wherein the algorithm is comprised of the following formula: p=p 0 +c 1 ΔT+c 2 ΔS h +c 4 ΔT 2 , with Δ T=T−T 0 and Δ S h =S h −S h0 , and wherein c 1 , c 2 and c 4 are proportionality factors that are determined in the scope of a regression and p and p 0 are pressure values, p being the pressure of the medium measured inside the measuring tube and p 0 being a known pressure. 6. The method according to claim 1 , wherein the algorithm is comprised of the following formula: p=p 0 +c 1 ΔT+c 2 ΔS h +c 3 ΔS a +c 4 ΔT 2 , with Δ T=T−T 0 and Δ S h =S h −S h0 and Δ S a =S a −S a0 , and wherein c 1 , c 2 , c 3 and c 4 are proportionality factors are determined in the scope of a regression and p and p 0 are pressure values, p being the pressure of the medium measured inside the measuring tube and p 0 being a known pressure. 7. A Coriolis mass flowmeter, comprising: at least one measuring tube through which a medium is flowable, at least one oscillation generator, at least two oscillation sensors, at least one temperature sensor, at least one tension sensor, at least one display unit, and at least one control and evaluation unit, wherein the temperature sensor is configured and arranged for measuring temperature of the measuring tube and for forwarding a measured temperature value T to the control and evaluation unit, wherein the tension sensor is configured and arranged for measuring mechanical tension of the measuring tube in an axial direction and in a circumferential direction and for forwarding a measured axial tension value S a and a measured circumferential tension value S h to the control and evaluation unit, wherein the control and evaluation unit is adapted for determining pressure of the medium based on at least one of the measured temperature value T or at least the measured tension values S a and S h , wherein the control and evaluation unit is adapted for determining pressure within the measuring tube based on a reference pressure p 0 using an algorithm that algorithm takes into account a difference between the measured temperature value T and the reference measured value T 0 and between the measured tension values S a and S h and the reference values S a0 and S h0 , wherein the reference measured values T 0 and/or S a0 and/or S h0 were measured under reference conditions, wherein the control and evaluation unit is connected to a display device for displaying the pressure value determined, wherein the difference ΔT between the measured temperature value T and the reference measured value T 0 is linearly and/or quadratically implemented into the algorithm for determining the pressure of the medium and wherein the difference ΔS h between the measured tension value S h and the reference measured value S h0 and the difference ΔS a between the measured tension value S a and the reference measured value S a0 is linearly and/or quadratically implemented into the algorithm for determining the pressure of the medium.