Method of monitoring an impeller pump used in a medical application

The invention claimed is: 1. A method of monitoring an impeller pump used in a medical application by structure-borne noise analysis comprising the following steps: measuring the structure-borne noise arising in the impeller pump; comparing the measured structure-borne noise of the impeller pump with a first reference curve and/or with a first limit value; concluding a disturbance of the operation of the impeller pump when the measured structure-borne noise of the impeller pump differs from the reference curve and/or exceeds the limit value; outputting a signal as a characteristic for a disturbance of the operation of the impeller pump; detecting the air quantity in the impeller pump; and venting the impeller pump when the detected air quantity and/or the measured structure-borne noise of the impeller pump differs from the reference curve and/or exceeds the limit value. 2. A method in accordance with claim 1 wherein, for which purpose of venting the impeller pump, collected air is led off via a venting opening of the impeller pump chamber. 3. The method in accordance with claim 1 , characterized in that collisions of the impeller with the housing of the impeller pump are detected in the impeller pump. 4. The method in accordance with claim 1 , wherein the measurement of the structure-borne noise takes place during the operation of the impeller pump. 5. The method in accordance with claim 1 , wherein the impeller pump is arranged in a medical apparatus. 6. A medical apparatus, in particular a blood treatment apparatus, comprising a control and processing unit which is programmed and configured for carrying out the method of monitoring the at least one impeller pump by structure-borne noise analysis in accordance with claim 1 . 7. The medical apparatus in accordance with claim 6 , characterized in that the control and processing unit has a data memory in which a computer program having a program code is stored, with the program code being programmed so that the measured structure-borne noise signals can be evaluated and/or stored. 8. The medical apparatus in accordance with claim 6 , characterized in that the blood treatment apparatus has at least one drive unit for driving the at least one impeller pump. 9. The medical apparatus in accordance with claim 6 , comprising a structure-borne noise sensor, wherein the structure-borne noise sensor is connected to the control and processing unit by a signal line. 10. The medical apparatus in accordance with claim 9 , further comprising a coupling point for the structure-borne noise sensor. 11. The medical apparatus in accordance with claim 6 , characterized in that it is a dialysis machine which is configured for carrying out hemodialysis and/or hemofiltration and/or hemodiafiltration and/or peritoneal analysis. 12. A computer program product comprising a program code for a control and processing unit of the blood treatment apparatus wherein the control and processing unit is programmed and configured for carrying out the method of monitoring at least one impeller pump by the structure-borne noise analysis of claim 1 . 13. The method in accordance with claim 1 , wherein the impeller pump is arranged in an extracorporeal blood circuit of a dialysis machine or in a dialysate circuit of a dialysis machine. 14. A method for monitoring a first impeller pump arranged in an extracorporeal blood circuit for carrying out hemodialysis or hemofiltration or hemodiafiltration and/or a second impeller pump arranged in a dialysate circuit for carrying out hemodialysis or hemofiltration or hemodiafiltration or peritoneal dialysis by a structure-borne noise analysis comprising the following steps: operating the extracorporeal blood circuit by controlling the first impeller pump and/or operating the dialysate circuit by controlling the second impeller pump; measuring the structure-borne noise arising in the first impeller pump and/or measuring the structure-borne noise arising in the second impeller pump; comparing the measured structure-borne noise of the first impeller pump with a first reference curve and/or with a first limit value; and/or comparing the measured structure-borne noise of the second impeller pump with a second reference curve and/or with a second limit value; concluding a disturbance of the operation of the first impeller pump when the measured structure-borne noise of the first impeller pump differs from the first reference curve and/or exceeds the first limit value; and/or concluding a disturbance of the operation of the second impeller pump when the measured structure-borne noise of the second impeller pump differs from the second reference curve and/or exceeds the second limit value; outputting a signal as a sign for a disturbance of the operation of the first impeller pump and/or outputting a signal as a sign for a disturbance of the operation of the second impeller pump. 15. A medical apparatus, in particular a blood treatment apparatus, comprising a control and processing unit which is programmed and configured for carrying out the method of monitoring the at least one impeller pump by structure-borne noise analysis in accordance with claim 14 . 16. An impeller pump for a medical application, in particular for a medical apparatus comprising a control and processing unit which is programmed and configured for carrying out a method of monitoring at least one impeller pump by structure-borne noise analysis comprising the following steps: measuring the structure-borne noise arising in the impeller pump; comparing the measured structure-borne noise of the impeller pump with a first reference curve and/or with a first limit value; concluding a disturbance of the operation of the impeller pump when the measured structure-borne noise of the impeller pump differs from the reference curve and/or exceeds the limit value; outputting a signal as a characteristic for a disturbance of the operation of the impeller pump; the impeller pump comprising an impeller pump chamber, characterized in that the impeller pump chamber has a venting opening and at least one of a structure-borne noise sensor and a coupling point for a structure-borne noise sensor. 17. The impeller pump in accordance with claim 16 , comprising a valve by which the venting of the impeller pump chamber can be controlled via the venting opening. 18. The impeller pump in accordance with claim 17 , wherein the valve is arranged in a coupling area of a cassette into which the impeller pump is integrated. 19. A disposable cassette comprising the impeller pump in accordance with claim 16 .