The invention is an improved tool for pulling a valve seat from a valve in a fluid end. The invention replaces the standard threaded nut and stem commonly used in such tools with a split nut comprising a plurality of removeably engageable split nut segments placed within a base and a stem configured to be used with the plurality of removeably engageable split nut segments. In the preferred embodiment, each split nut segment possesses a center-facing surface relative to the longitudinal axis of the invention comprising a set of horizontal v-grooves suitable to be disposed against complementary v-grooves of the stem. The base permits the plurality of split nut segments to be placed in an engaged position permitting the v-grooves of the split nut segments to removeably engage the v-grooves of the stem securely or to be placed in a disengaged position. The base containing the split nut segments is durable enough to be used in oil field work but lightweight enough to be used by individual or groups of workers safely.

The invention is an improved tool for pulling a valve seat from a valve in a fluid end. The invention replaces the standard threaded nut and stem commonly used in such tools with a split nut comprising a plurality of removeably engageable split nut segments placed within a base and a stem configured to be used with the plurality of removeably engageable split nut segments. In the preferred embodiment, each split nut segment possesses a center-facing surface relative to the longitudinal axis of the invention comprising a set of horizontal v-grooves suitable to be disposed against complementary v-grooves of the stem. The base permits the plurality of split nut segments to be placed in an engaged position permitting the v-grooves of the split nut segments to removeably engage the v-grooves of the stem securely or to be placed in a disengaged position. The base containing the split nut segments is durable enough to be used in oil field work but lightweight enough to be used by individual or groups of workers safely.

A radiation shielding overlay for a portion of a valve controller or a valve assembly. The radiation shielding overlay includes a layer including a base material and a second material infused within the base material. The base material has a first density and the second material has a second density higher than the first density, increasing a density of the layer. The layer is adapted to be disposed over a surface of a housing of a valve controller or a valve assembly, such that the layer blocks radiation from reaching a component disposed within the housing.

A radiation shielding overlay for a portion of a valve controller or a valve assembly. The radiation shielding overlay includes a layer including a base material and a second material infused within the base material. The base material has a first density and the second material has a second density higher than the first density, increasing a density of the layer. The layer is adapted to be disposed over a surface of a housing of a valve controller or a valve assembly, such that the layer blocks radiation from reaching a component disposed within the housing.

A flow rate adjusting valve includes: a casing including an inlet and an outlet and also including a channel connecting the inlet and the outlet to each other; a cylindrical valve port member disposed in the channel and having a valve port penetrating the valve port member in an upstream-downstream direction; and a valve body configured to move forward and backward to the valve port from a downstream side to thereby adjust an opening degree of a downstream opening of the valve port. The valve port includes a narrowing portion whose opening diameter is smaller than an opening diameter of an upstream opening, the valve body includes a tapered portion that enters the valve port when the valve body moves forward and a flange portion disposed at a downstream end of the tapered portion and having a contact surface that is parallel to an end surface of the valve port member and is brought into surface contact with the end surface while the valve port is fully closed, and when the downstream opening is at a predetermined opening degree, a passage area of the fluid in the valve port is at minimum in the narrowing portion.

A flow rate adjusting valve includes: a casing including an inlet and an outlet and also including a channel connecting the inlet and the outlet to each other; a cylindrical valve port member disposed in the channel and having a valve port penetrating the valve port member in an upstream-downstream direction; and a valve body configured to move forward and backward to the valve port from a downstream side to thereby adjust an opening degree of a downstream opening of the valve port. The valve port includes a narrowing portion whose opening diameter is smaller than an opening diameter of an upstream opening, the valve body includes a tapered portion that enters the valve port when the valve body moves forward and a flange portion disposed at a downstream end of the tapered portion and having a contact surface that is parallel to an end surface of the valve port member and is brought into surface contact with the end surface while the valve port is fully closed, and when the downstream opening is at a predetermined opening degree, a passage area of the fluid in the valve port is at minimum in the narrowing portion.

The invention relates to a control valve for adjusting a process fluid flow of a process plant, comprising a valve housing (8) with a valve seat (14) and a valve member (16) connected to a valve rod (18), which cooperates with the valve seat (14) for opening and closing the control valve (2), wherein the valve rod (18) is electrically connected to the valve housing (8) through a contact device (42, 43, 45). The invention is characterized in that a measuring device (26) for the ohmic transition resistance measurement of the contact device (42, 43, 45) is provided, and that the measuring device (26) is arranged in a measuring line (24) that connects the valve housing (8) to the valve rod (18).

The invention relates to a control valve for adjusting a process fluid flow of a process plant, comprising a valve housing (8) with a valve seat (14) and a valve member (16) connected to a valve rod (18), which cooperates with the valve seat (14) for opening and closing the control valve (2), wherein the valve rod (18) is electrically connected to the valve housing (8) through a contact device (42, 43, 45). The invention is characterized in that a measuring device (26) for the ohmic transition resistance measurement of the contact device (42, 43, 45) is provided, and that the measuring device (26) is arranged in a measuring line (24) that connects the valve housing (8) to the valve rod (18).

Disclosed is a flow device including an inlet, an outlet, and a plurality of fluid flow paths hydraulically connected in parallel to the inlet and the outlet, wherein the plurality of fluid flow paths forms a first ring of fluid flow paths circumferentially arranged at a first radial distance from a centerline of the fluid flow device a second ring of fluid flow patch circumferentially arranged at a second radial distance from the centerline of the fluid flow device, each of the plurality of fluid flow paths has a first hydraulic resistance in a forward flow direction and a second hydraulic resistance in a reverse flow direction, and the second hydraulic resistance is greater than the first hydraulic resistance.

Disclosed is a flow device including an inlet, an outlet, and a plurality of fluid flow paths hydraulically connected in parallel to the inlet and the outlet, wherein the plurality of fluid flow paths forms a first ring of fluid flow paths circumferentially arranged at a first radial distance from a centerline of the fluid flow device a second ring of fluid flow patch circumferentially arranged at a second radial distance from the centerline of the fluid flow device, each of the plurality of fluid flow paths has a first hydraulic resistance in a forward flow direction and a second hydraulic resistance in a reverse flow direction, and the second hydraulic resistance is greater than the first hydraulic resistance.