Valve

What is claimed: 1 . A valve comprising: a housing; and a valve element, the housing comprising a cylindrical bore defining an axial direction and an annular shoulder extending into the cylindrical bore, wherein the valve element is axially moveable within the cylindrical bore so as to move the valve element between a closed position in which the valve element engages with the annular shoulder and an open position in which the valve element is spaced from the annular shoulder, wherein, in the open position, fluid flowing into the valve in a first axial direction may flow through one or more apertures provided in the valve element and through the valve, wherein the valve element and the annular shoulder are configured to be in continuous contact along an annular contact surface when in the closed position so as to seal against fluid flow through the valve. 2 . The valve as claimed in claim 1 , wherein the valve element comprises a conical or frustoconical portion for engaging with the annular shoulder. 3 . The valve as claimed in claim 2 , wherein the annular shoulder comprises a chamfered surface for engaging with the valve element. 4 . The valve as claimed in claim 3 , wherein the angle of the conical or frustoconical portion relative to a radial direction is greater than the angle of the chamfered surface relative to the radial direction. 5 . The valve as claimed in claim 1 , wherein the continuous contact along the annular contact surface between the valve element and the shoulder is provided by rotating the valve element and the shoulder relative to each other whilst pushing the valve element and the shoulder together during manufacture of the valve, wherein, optionally, an abrasive is placed between the valve element and the shoulder whilst rotating the valve element and the shoulder relative to each other. 6 . The valve as claimed in claim 1 , wherein at least one of the housing or the valve element are made of metal. 7 . The valve as claimed in claim 1 , further comprising biasing means for biasing the valve element into engagement with the annular shoulder. 8 . The valve as claimed in claim 1 , further comprising an annular skirt projecting axially from the valve element and extending parallel to and into the cylindrical bore of the housing. 9 . The valve as claimed in in claim 1 , the valve element further comprising: a radially outer axial wall; one or more grooves in the radially outer axial wall; and/or a surface extending substantially perpendicular to the axial direction and radially inward from the radially outer axial wall so as to stop or reduce contaminant particles becoming stuck between the valve element and the housing. 10 . The hydraulic system comprising a valve as claimed in in claim 1 . 11 . The hydraulic system as claimed in claim 10 , wherein the hydraulic system comprises a hydraulic aircraft wheel braking system, wherein, optionally, the valve connects a hydraulic power source to a hydraulic accumulator. 12 . A method of manufacturing a valve comprising: forming a housing comprising a cylindrical bore defining an axial direction and an annular shoulder extending into the cylindrical bore; forming a valve element configured to be axially moveable within the cylindrical bore so as to move the valve element between a closed position in which the valve element engages with the annular shoulder and an open position in which the valve element is spaced from the annular shoulder, wherein, in the open position, fluid flowing into the valve in a first axial direction may flow through one or more apertures provided in the valve element and through the valve, wherein the valve element and the annular shoulder are configured to be in continuous contact along an annular contact surface when in the closed position so as to seal against fluid flow through the valve; positioning the valve element in the cylindrical bore; and rotating the valve element and the shoulder relative to each other whilst pushing the valve element and the shoulder together so as to configure the valve element and the shoulder to be in continuous contact along the annular contact surface when the valve is in the closed position. 13 . The method of manufacturing a valve as claimed in claim 12 , further comprising: applying an abrasive between the valve element and the shoulder prior to rotating the valve element and the shoulder relative to each other. 14 . The method of manufacturing a valve as claimed in claim 13 , wherein the abrasive is applied to at least one of the valve element or the shoulder. 15 . The method of manufacturing a valve as claimed in claim 14 , wherein the abrasive is applied along the annular contact surface. 16 . The valve as claimed in claim 6 , wherein the hardness of the valve element is greater than the hardness of the annular shoulder at least along the annular contact surface between the valve element and the shoulder