Pump, a homogenizer comprising said pump and a method for pumping a liquid product

The invention claimed is: 1. A membrane-based piston pump for pumping a liquid product, wherein said pump is provided with a device for maintaining a pre-defined hydraulic fluid volume in the pump, said device comprises: a hydraulic fluid reservoir, a bushing element attached in a passage between a piston cavity and a membrane cavity, said bushing element having a radial opening in fluid connection with the hydraulic fluid reservoir, an axle element arranged such that a first axial end thereof is attached to a first membrane provided in the membrane cavity, and such that at least a portion of said axle element is journalled, and adapted for axial movement, in the bushing element, said axle element being provided with a first recess proximate the first axial end and formed as a cut extending axially along an outer surface of the axle element, wherein if the first membrane is displaced beyond a first operational turning point, to a point at, or in close vicinity of, a first extreme point, the first recess of the axle element is in fluid connection with the radial opening of the bushing element and the membrane cavity, whereby the hydraulic fluid reservoir and the membrane cavity are fluidly connected, and if the first membrane is displaced beyond a second operational turning point, to a point between the second turning point and a second extreme point, a second axial end of the axle element is axially moveable away from a blocking position in which the second axial end blocks fluid communication between the radial opening and the piston cavity, and the radial opening of the bushing element is in fluid connection with the piston cavity, wherein fluid flows between the piston cavity and the hydraulic fluid reservoir past the second axial end, thereby forming a fluid connection between the hydraulic fluid reservoir and the hydraulic fluid volume of the pump. 2. The membrane-based piston pump according to claim 1 , wherein the first operational turning point and the first extreme point are suction stroke points, and the connection between the first recess of the axle element and the radial opening of the bushing element, at or in the vicinity of, the first extreme point, will allow a flow of hydraulic fluid from the hydraulic fluid reservoir to the hydraulic fluid volume of the pump. 3. The membrane-based piston pump according to claim 1 , wherein the second operational turning point and the second extreme point are pump stroke points, and the connection between the radial opening of the bushing element and the piston cavity, or the connection between the radial opening of the bushing element and the second recess of the axle element, at a point between the second operational turning point and the second extreme point, will allow a flow of hydraulic fluid from the hydraulic fluid volume of the pump to the hydraulic fluid reservoir. 4. The membrane-based piston pump according to claim 1 , wherein a first axial end of the bushing element ends in the membrane cavity, and a second axial end of the bushing element ends in the piston cavity. 5. The membrane-based piston pump according to claim 1 , wherein the first recess is a cut extending on an outer surface of the axle element, and which cut is adapted to provide fluid connection between the radial opening of the bushing element and the membrane cavity, at or in the vicinity of, the first extreme point. 6. The membrane-based piston pump according to claim 1 , wherein the first axial end of the axle element is attached to a centrally arranged reinforcement disc attached to the first membrane. 7. The membrane-based piston pump according to claim 1 , wherein the pump is adapted to increase the pump pressure from approximately 3 bar up to 250 bar and down to approximately 3 bar during the course of a pump stroke followed by a suction stroke. 8. The membrane-based piston pump according to claim 1 , wherein the bushing element and the axle element are made of a ceramic material. 9. The membrane-based piston pump according to claim 8 , wherein the ceramic material comprises zirconium oxide. 10. The membrane-based piston pump according to claim 1 , wherein a gap between an outer envelope surface of the axle element and an inner envelope surface of the bushing element is in the range of 1-15 micrometers. 11. The membrane-based piston pump according to claim 1 , wherein a second membrane is interconnected to the first membrane by means of a rod, said rod providing an axial distance between the first and the second membranes, and forming a membrane interior space. 12. The membrane-based piston pump according to claim 11 , wherein the membranes and the membrane interior space divide the membrane cavity into at least first and second membrane cavity portions, said first and second membrane cavity portions being sealed from each other, said first membrane cavity portion being adapted to receive the hydraulic fluid, and said second membrane cavity portion being adapted to receive a liquid product. 13. The membrane-based piston pump according to claim 11 , wherein the first and second membranes are coaxially arranged, the rod is arranged at the centres of the membranes, and the rod is axially aligned with the axle element. 14. The membrane-based piston pump according to claim 1 , wherein one or more channels are provided between the membrane cavity and the piston cavity, the one or more channels being adapted for passage of hydraulic fluid. 15. A homogenizer comprising a membrane-based piston pump according to claim 1 . 16. The membrane-based piston pump according to claim 1 , wherein the axle element is solid. 17. The membrane-based piston pump according to claim 1 , wherein the first recess has a first end that is chamfered and a second end opposite the first end that has a radius. 18. A method for pumping a liquid product in a pump, said pump comprising: a hydraulic fluid reservoir, a bushing element attached in a passage between a piston cavity and a membrane cavity, said bushing element having a radial opening in fluid connection with the hydraulic fluid reservoir, an axle element arranged such that a first axial end thereof is attached to a first membrane provided in the membrane cavity, and such that at least a portion of said axle element is journalled, and adapted for axial movement, in the bushing element, said axle element being further provided with a first recess proximate the first axial end and formed as a cut extending axially along an outer surface of the axle element, wherein the method comprises the steps of filling a second membrane cavity portion, of the membrane cavity, with the liquid product by moving the first membrane to a first operational turning point, emptying the liquid product from the second membrane cavity portion by moving the first membrane to a second operational turning point, wherein the method further comprises the step of, if the first membrane is displaced beyond the first operational turning point, to a point at, or in close vicinity of, a first extreme point, creating a fluid connection between the hydraulic fluid reservoir and a hydraulic fluid volume of the pump for introducing hydraulic fluid into the pump by letting the first recess of the axle element come into fluid connection with the radial opening of the bushing element and the membrane cavity, whereby the hydraulic fluid reservoir and the membrane cavity are fluidly connected, and if the first membrane is displaced beyond a second operational turning point, to a point between the second operational turning point and