Fitting element with hydraulic grip force element

The invention claimed is: 1. A fitting element, in particular for an HPLC application, configured for providing a fluidic coupling of a tubing to a fluidic device, the fitting element comprising: a gripping piece configured to exert, upon coupling of the tubing to the fluidic device, a grip force (G) between the fitting element and the tubing, wherein the gripping piece comprises a hydraulic element configured to transform an axial force (S) into a hydraulic pressure (P) within the hydraulic element; a housing for housing the hydraulic element and for retaining the hydraulic element in a certain space, wherein the gripping piece at least partially defines the housing; a rigid piston movable in an axial direction of an elongation of the tubing for contacting the hydraulic element and exerting the axial force (S) on the hydraulic element; and a first joint element movable in the axial direction for contacting the piston and pushing the piston in the axial direction and into contact with the hydraulic element, wherein: the first joint element is configured for movably engaging a second joint element of the fluidic device by a screw connection, such that movably engaging the second joint element moves the first joint element in the axial direction; and the hydraulic pressure (P) in the hydraulic element causes the grip force (G). 2. The fitting element of claim 1 , wherein the hydraulic element is an isotropic hydraulic element, comprising at least one of: the isotropic hydraulic element is configured to transform an applied force into an isotropic pressure within the hydraulic element; the isotropic hydraulic element is configured to transform an applied force into an isotropic pressure within the hydraulic element, at least after a given time period or at a given time constant; the isotropic hydraulic element is configured so that pressure at a boundary surface of the hydraulic element is substantially equal over the boundary surface; the isotropic hydraulic element is configured to exert substantially the same force on each respective standardized surface element of a boundary surface. 3. The fitting element of claim 1 , wherein the hydraulic element is an anisotropic hydraulic element, comprising at least one of: the anisotropic hydraulic element is configured to transform an applied force into a pressure distribution within the hydraulic element; the anisotropic hydraulic element is configured to transform an applied force into a pressure distribution within the hydraulic element at least after a given time period or at a given time constant; the anisotropic hydraulic element is configured so that pressure at a boundary surface of the hydraulic element varies in accordance with a pressure distribution; the anisotropic hydraulic element is configured so that a force exerted on a respective standardized surface element at a boundary surface varies in accordance with a pressure distribution. 4. The fitting element of claim 1 , wherein the hydraulic element is selected from the group consisting of: a fluid, a liquid, an oil, a pressure oil, grease, a gel, polysiloxane, a silicone gel, a solid material having elasticity, an elastomer, a plastic material, a polymer having plasticity, rubber, polyurethane, and polytetrafluoroethylene. 5. The fitting element of claim 1 , wherein the hydraulic element has a configuration selected from the group consisting of: the hydraulic element has a viscosity in a range of 250 to 100,000 mPa*s; the hydraulic element has a viscosity in a range of 1000 to 25,000 mPa*s; the hydraulic element has a hardness in a range of 10 to 100 Shore A and 30 to 100 Shore D; the hydraulic element has a hardness in a range of 70 Shore A to 80 Shore D; the hydraulic element comprises a polyurethane elastomer; the hydraulic element comprises a polyurethane elastomer having a hardness of about 90 Shore A; the hydraulic element has an elasticity measured in elongation before break in a range of 10 to 1000%; and the hydraulic element has an elasticity measured in elongation before break in a range between 30% and 100%. 6. The fitting element of claim 1 , wherein: the hydraulic element has an active contact surface directed towards the tubing, the active contact surface transforms the hydraulic pressure (P) into the grip force (G), and the size of the contact surface is configured to adjust to at least one of a desired magnitude and a desired profile of the grip force (G). 7. The fitting element of claim 6 , comprising at least one of: the hydraulic element has a surface abutting to the tubing, and the plane surface substantially represents the active contact surface; the hydraulic element has one of a plane surface, a cylindrical surface, or a surface slotted along the direction of the axis; the active contact surface exerts a substantially homogeneous profile of the grip force (G) along the axial direction. 8. The fitting element of claim 1 , wherein: the gripping piece is configured for generating, upon coupling of the tubing to the fluidic device, a spring-biased force. 9. The fitting element claim 8 , comprising at least one of: the spring-biased force is exerted in an axial direction being a direction of an axial elongation of the tubing or parallel thereto; the spring-biased force is exerted in a radial direction being a direction perpendicular to an axial elongation of the tubing or parallel thereto. 10. The fitting element of claim 8 , comprising at least one of: the gripping piece is configured for exerting the spring-biased force in a radial direction on the tubing in order to provide a spring-biased grip force (G) onto the tubing; the gripping piece is configured for exerting the spring-biased force in an axial direction on the tubing in order to provide a spring-biased coupling of the tubing to the fluidic device; the gripping piece is configured for exerting the spring-biased force in an axial direction on a sealing piece in order to provide a spring-biased sealing between the sealing piece and the fluidic device. 11. The fitting element of claim 8 , wherein the spring-biased force is generated by at least one of: a mechanical spring element, a spring washer, a disk spring, or a Belleville spring washer; a multiple spring configuration, or a spring configuration comprising two disk springs in parallel or mirrored; an elastic shaping configured to generate the spring-biased force, or a collar elastically expanding its diameter. 12. The fitting element of claim 8 , wherein the spring-biased force is generated by the hydraulic element, and the hydraulic element comprises, for exerting the spring-biased force, at least one of: one or more gas inclusions; a material having a compressibility at the working pressure in a range of 5 to 30%; an at least partly elastic housing; an elastic shaping configured to generate the spring-biased force. 13. The fitting element of claim 1 , comprising at least one of: a sealing piece configured to provide, upon coupling of the tubing to the fluidic device a sealing between the sealing piece and the fluidic device; a front sealing configured to provide, upon coupling of the tubing to the fluidic device a sealing between a front side of the tubing coupling to the fluidic device and the fluidic device. 14. A fitting configured for coupling a tubing to a fluidic device, the fitting comprising: a fitting element according to claim 1 , configured for providing a fluidic coupling of the tubing to the fluidic device, and wherein a receiving cavity of the fluidic device is configured for receiving the fitting element, and upon coupl