Manifold and methods of manufacturing same

What is claimed is: 1 . A manifold through which fluid is adapted to flow, the manifold comprising: an elongated member at least partially defining an internal region through which the fluid is adapted to flow, a longitudinal axis, and a first inside surface, the elongated member comprising: one or more inlets via which the fluid flows into the internal region; and one or more outlets via which the fluid flows out of the internal region; and a fluid liner disposed within the internal region and permanently bonded to the first inside surface of the elongated member, wherein the fluid liner dynamically responds to pressure fluctuations within the internal region during fluid flow therethrough while the permanent bond between the fluid liner and the first inside surface of the elongated member is maintained. 2 . The manifold of claim 1 , wherein the one or more outlets of the elongated member comprise two outlets; wherein the manifold further comprises two radially-extending openings formed through the fluid liner and generally aligned with the two outlets, respectively; and wherein the two radially-extending openings are axially spaced from each other so that a portion of the fluid liner extends axially between the two radially-extending openings. 3 . The manifold of claim 2 , further comprising two tubes axially spaced from each other and extending from the elongated member, the two tubes defining two fluid passages, respectively; wherein the two fluid passages are generally aligned with the two outlets, respectively, and thus with the two radially-extending openings, respectively, so that each of the two fluid passages are in fluid communication with the internal region. 4 . The manifold of claim 3 , further comprising two helical vanes disposed in the two fluid passages, respectively; wherein the two helical vanes are adapted to induce vortices in fluid flow through the two fluid passages, respectively. 5 . The manifold of claim 1 , further comprising: a first plug opening formed through the fluid liner; and a first liner plug extending within the first plug opening. 6 . The manifold of claim 5 , wherein the first liner plug dynamically responds to pressure fluctuations within the internal region during fluid flow therethrough. 7 . The manifold of claim 5 , further comprising: a first stem extending from the elongated member; and first bull plug assembly connected to the first stem, the first plug assembly comprising: the first liner plug; and a first head from which the first liner plug extends. 8 . The manifold of claim 7 , wherein the first plug assembly further comprises a first post extending from the head and into the first liner plug. 9 . The manifold of claim 5 , further comprising: a second plug opening formed through the fluid liner and axially spaced from the first plug opening so that a portion of the fluid liner extends axially between the first and second plug openings; and a second liner plug extending within the second plug opening. 10 . The manifold of claim 1 , wherein the fluid liner is formed of a resilient material that comprises a nitrile rubber material; and wherein the fluid liner is permanently bonded to the first inside surface using at least a vulcanizable adhesive compound. 11 . The manifold of claim 1 , further comprising an end cap connected to the elongated member, the end cap defining a second inside surface to which the fluid liner is permanently bonded; wherein the fluid liner defines a third inside surface within the internal region. 12 . The manifold of claim 11 , wherein a first thickness of the fluid liner is defined between the first inside surface of the elongated member and the third inside surface of the fluid liner; wherein a second thickness of the fluid liner is defined between the second inside surface of the end cap and the third inside surface of the fluid liner; and wherein the second thickness of the fluid liner is greater than the first thickness of the fluid liner. 13 . The manifold of claim 11 , wherein the portion of the fluid liner permanently bonded to the first inside surface of the elongated member has a longitudinally-extending taper, the longitudinally-extending taper defining a taper angle between the longitudinal axis and the third inside surface, the taper angle ranging from greater than 0 degrees to less than about 70 degrees measured from the longitudinal axis. 14 . The manifold of claim 1 , wherein the manifold is adapted to be connected to a fluid cylinder of a reciprocating pump. 15 . A manifold through which fluid is adapted to flow, the manifold comprising: an elongated member, the elongated member defining a longitudinal axis and a first inside surface; an end cap connected to the elongated member, the end cap defining a second inside surface; an internal region at least partially defined by the elongated member and the end cap; and a fluid liner disposed within the internal region and engaged with each of first and second inside surfaces, the fluid liner defining a third inside surface within the internal region; wherein the fluid liner dynamically responds to pressure fluctuations within the internal region during fluid flow therethrough; wherein a first thickness of the fluid liner is defined between the first inside surface of the elongated member and the third inside surface of the fluid liner; wherein a second thickness of the fluid liner is defined between the second inside surface of the end cap and the third inside surface of the fluid liner; and wherein the second thickness of the fluid liner is greater than the first thickness of the fluid liner. 16 . The manifold of claim 15 , wherein the fluid liner is permanently bonded to each of the first and second inside surfaces; and wherein the fluid liner dynamically responds to pressure fluctuations within the internal region during fluid flow therethrough while the permanent bond between the fluid liner and each of the first and second inside surfaces is maintained. 17 . The manifold of claim 15 , wherein the portion of the fluid liner engaged with the first inside surface has a longitudinally-extending taper, the longitudinally-extending taper defining a taper angle between the longitudinal axis and the third inside surface, the taper angle ranging from greater than 0 degrees to less than about 70 degrees measured from the longitudinal axis. 18 . The manifold of claim 15 , wherein the elongated member comprises two outlets; wherein the manifold further comprises two radially-extending openings formed through the fluid liner and generally aligned with the two outlets, respectively; and wherein the two radially-extending openings are axially spaced from each other so that a portion of the fluid liner extends axially between the two radially-extending openings. 19 . The manifold of claim 18 , further comprising: two tubes axially spaced from each other and extending from the elongated member, the two tubes defining two fluid passages, respectively, wherein the two fluid passages are generally aligned with the two outlets, respectively, and thus with the two radially-extending openings, respectively, so that each of the two fluid passages are in fluid communication with the internal region; and two helical vanes disposed in the two fluid passages, respectively. 20 . The manifold of claim 15 , further comprising: a first plug opening formed through the fluid liner; a first stem extending from the el