AU709638B2 - Flow control valve - Google Patents

Flow control valve Download PDF

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AU709638B2
AU709638B2 AU85189/98A AU8518998A AU709638B2 AU 709638 B2 AU709638 B2 AU 709638B2 AU 85189/98 A AU85189/98 A AU 85189/98A AU 8518998 A AU8518998 A AU 8518998A AU 709638 B2 AU709638 B2 AU 709638B2
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Prior art keywords
valve
suction
accordance
discharge
liquid
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AU8518998A (en
Inventor
William K Morgan
James C. Tiffany
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Reynolds Metals Co
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Reynolds Metals Co
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Priority claimed from US08/222,746 external-priority patent/US5636975A/en
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Description

Sla FLOW CONTROL VALVE TECHNICAL
FIELD
The present invention relates to high-pressure, plunger-type liquid pumps adapted for continuous operation at pressures at or above about 15,000 psi., and to an improved, long-life flow control valve for regulating the flow of liquid onto and out of the plunger cylinder of a high-pressure, plungertype liquid pump.
BACKGROUND
ART
*Positive displacement, high-pressure liquid pumps have been in use for 10 some time. However, it has been found that commercially available pumps .fail rapidly when operated continuously at liquid pressures exceeding about "8,000 psi. and at flow rates of about 10 gpm. per plunger (47 hydraulic horsepower equivalent). In order to increase the relatively short operating time between failures for such liquid pumps the pressures and flow rates at which the pumps can be effectively operated must be limited, which thereby limits the number and types of applications for such pumps.
Investigation has revealed that failures of the preexisting high-pressure pumps and valves was often caused by a cross-port structural arrangement, *.:."wherein, when the high-pressure liquid underwent abrupt changes in flow .e 20 direction and pressure, and transferred this pressure change to the pump housing the result was erosion and stress cracking of the metal at the port areas of the valve and pump housing or casing. Accordingly, the pumps and valves when operated at high pressures, especially pressures of over about 10,000 psi., would be required to be removed from service and repaired on a frequent basis, and consequently the use of the pumps at such high pressures resulted in very high maintenance costs per pump operating hour.
One form of pump and valve structure that was devised in an effort to improve the operating life of high-pressure pumps at high-pressure conditions is disclosed in U.S. Patent No. 4,878,875, which issued on November 7, 1989 to J. Edward Stachowiak. That patent identifies some of the earlierissued patents that disclose the right angle, or cross-port bore arrangements in the prior art pumps, and it also identifies patents that have valve bores that are arranged coaxially with the pump plunger bore access.
The above-identified Stachowiak patent discloses a pump structure that includes a liquid manifold, or "fluid-end", as it is referred to in the art, that receives a cartridge-type valve that is carried within the manifold and is positioned coaxially with the pump plunger axis. The valve is readily replaceable, but only upon separation of the liquid manifold from the pump housing. Additionally, the disclosed valve also seats on the outermost surface of a stuffing box that defines the pump plunger chamber. Removal of the cartridge valve requires removal of the manifold block from the pump drive housing.
The manifold block is pivotally carried by a flange plate that is secured to the pump drive housing structure, and it surrounds a removable stuffing box that includes the pump plunger. Furthermore, the Stachowiak cartridge valve, although an improvement for high-pressure pumps having relatively low liquid output rates, cannot effectively be 4* 15 scaled up to higher liquid output rates of beyond about 50 hydraulic horsepower per cylinder because the valve structure includes a relatively large diameter discharge valve, which upon scaling up to higher output rates results in a larger valve cavity diameter that would be subjected to stresses that exceed the strength of the steel available for the manufacture of fluid ends for such pumps. Therefore, the Stachowiak valve and pump design, although an improvement over the previously-existing valve and pump designs, has limited applicability because of the limitations caused by the structural configuration of the cartridge valve.
It is an object of the present invention to overcome or ameliorate at least one of the disadvantages of the prior art, or to provide a useful alternative.
DISCLOSURE OF THE INVENTION Accordingly, the invention provides a cartridge-type valve for controlling the flow of low pressure inlet liquid and high-pressure outlet liquid to and from a plunger cylinder of a high-pressure liquid pump, the valve including a tubular valve housing having a longitudinal axis, wherein the valve housing includes a suction valve chamber for axially removably receiving a suction valve, a discharge valve chamber spaced from *the suction valve chamber for axially removably receiving a discharge valve, the valve housing further including a suction inlet passageway extending transversely through the valve housing to a first axial position relative to the valve housing longitudinal axis, a discharge outlet passageway extending transversely through the valve housing to a second axial position relative to the valve housing longitudinal axis, wherein the second axial position is axially spaced along the valve housing longitudinal axis from the first °°15 axial position, a suction valve seating surface positioned within the valve housing, and a discharge valve seating surface positioned within the valve housing and spaced axially along the valve housing longitudinal axis from the suction valve seat, a suction valve axially slidably received within the valve housing for movement toward and away from the suction valve seating surface, and a discharge valve axially slidably received within the valve housing for movement toward and away, from the discharge valve seating surface and spaced axially from the suction valve.' 4 The present invention at least in a preferred embodiment provides a high-pressure pump design that is easily maintainable and that provides rapid accessibility to the flow control valves for servicing.
The present invention preferably provides a pre-assembled cartridge-type valve that can be readily installed and removed from the pumping cylinder of a high-pressure liquid pump for rapid servicing.
In yet other forms, the present invention provides a pre-assembled cartridge type valve in which all moving parts are internal to the valve.
In yet another form, the present invention provides a pre-assembled cartridge type valve in which the outside of the valve housing contains the required drilling and plenum chambers leaving the bore(s) in the pump housing essentially free of abrupt diametrical changes which can be a source of stress concentration and failures.
°The present invention at least in a preferred embodiment provides a preassembled cartridge type valve in which the principal stresses are contained within the cartridge, a replaceable and repairable item, and not transferred to the valve housing, a much larger and generally unrepairable item.
The present invention preferably provides a high-pressure liquid flow control cartridge valve that has a relatively loose fit in a liquid manifold and that includes simple seals and requires no close tolerance, metal-to-metal contact.
BRIEF DESCRIPTION OF THE DRAWINGS A preferred embodiment of the invention will now be described, by way of example only, with reference to the accompanying drawings in which: Figure 1 is a perspective view of a high-pressure liquid pump that includes a liquid manifold and a high-pressure valve structure.
Figure 2 is a bottom view of the liquid manifold structure shown in Figure 1.
4e 4 4 6 Figure 3 is an end elevational view of the liquid manifold structure shown in Figure 1.
Figure 4 is a cross-sectional view of the liquid manifold taken along the line 4-4 of Figure 3.
Figure 5 is a longitudinal cross-sectional view of a closure plug for closing the outermost end of the valve compartment of the liquid manifold shown in Figures 2 through 4.
Figure 6 is a longitudinal cross-sectional view taken through a cartridae valve in accordance with the present invention.
Figure 7 is a fragmentary cross-sectional view taken along the line 7-7 of Figure 6.
~Figure 8 is a fragmentary transverse cross-sectional view taken along the line 8-8 of Figure 6.
Figure 9 is an end view of the fluid inlet passageway in the valve 15 housing at the interior end thereof.
Figure 10 is a sectional view, in perspective, through the axis of the valve chamber within the liquid manifold shown in Figures 2 through 4, and shows the valve and valve chamber closure plug in partially exploded form.
Figure 11 is a view similar to that of Figure 10, showing the internal structure of the valve body, and with the valve body and valve chamber closure plug in operative position within the manifold.
Figure 12 is a longitudinal cross-sectional view of another embodiment of a cartridge valve in accordance with the present invention.
Figure 13 is an end view of a valve guide forming part of the suction valve structure for the cartridge valve shown in Figure 12.
Figure 14 is an elevational view of the discharge valve forming part of the cartridge valve structure shown in Figure 12.
Figure 15 is a top end view of the discharge valve structure shown in Figure 14.
Figure 16 is a view similar to that of Figure 11, showing the alternative valve embodiment in position within the liquid manifold.
BEST MODE FOR CARRYING OUT THE INVENTION Referring now to the drawings, and particularly to Figure 1 thereof, there is shown a horizontally-disposed, high-pressure liquid pump 10 for pressurizing liquids to pressures up to the order of about 15,000 psi. Pump 10 includes a pump drive housing 12 having a vertically disposed liquid manifold mounting surface 14. A liquid manifold 16 is securely bolted to pump drive housing 12 by a plurality of mounting bolts (not shown). Pump drive housing 12 receives input power that is delivered in rotary form from a suitable source of power to an input shaft 18 which, through a crankshaft and 10 connecting rod arrangement of a type known to those having skill in the art and positioned within pump drive housing 12, converts the rotary input power to linear, reciprocating power that is imparted to the several pump plungers that are axially slidably supported in respective plunger sleeves 22. The pump structure illustrated includes three pump plungers, although more or fewer such plungers can be provided, if desired.
Liquid manifold 16 is shown in Figures 1 through 4, and is in the form of a one-piece structure that includes a plurality of plunger cylinders 24 to slidably receive respective plungers 20 for reciprocating movement 'therewithin. Manifold 16 also carries within it and in communication with the plunger cylinders individual flow control valves, one for each plunger cylinder, for admitting low pressure liquid into the respective plunger cylinders and for *permitting the flow from the plunger cylinders of high pressure liquid after the pressure of the liquid has been significantly increased, to the order of about 10,000 to about 15,000 psi. Liquid is introduced into manifold 16 through a plurality of suction inlets 28, one for each plunger cylinder, that are positioned on lowermost surface 26 (see Figures 3 and A liquid outlet is provided at each of lateral end surfaces 32 and 34 of manifold 16 to carry away the pressurized liquid for subsequent use. A plurality of closure plugs 36, the structure of which will be hereinafter described, are received in respective bores that extend inwardly from the front surface 38 of manifold 16.
8 Referring now to Figures 2 and 4, liquid manifold 16 includes three laterally spaced plunger cylinders 24 that have their respective longitudinal axes parallel with each other and that extend inwardly from manifold rear surface 40. Plungers 20 extend outwardly of pump drive housing 1 2 at manifold mounting surface 14, to which manifold rear surface 40 is securely mounted in contacting, liquid-tight relationship. Within manifold 16 and in axial alignment with and in communication with plunger cylinders 24 are respective cartridge valve chambers 42 and a portion of 44 for containing respective cartridge-type valves having a structure to be hereinafter described.
99* 10 Extending inwardly from manifold front surface 38 and axially aligned with 9 "and in communication with cartridge valve chambers 42 and a portion of 44 9o9*** are respective closure plug chambers occupying the remaining portion of 44 for removably receiving a suitable closure plug 36 (see Figures 1 and Each of plunger cylinder 24, cartridge valve chamber 42, and cartridge valve and 15 closure plug chamber 44 are in coaxial alignment with each other and are of circular cross section.
Plunger cylinders 24 each have an inner diameter that is slightly larger, *for instance than the outer diameter of plungers 20. The diametrical 9599 "'"clearance can be greater or less and the pump will still work. Cartridge valve chambers 42 each have a larger diameter than that of corresponding plunger cylinders 24, and that diameter is defined by a counterbore that extends outwardly toward manifold front surface 38 and terminates in an enlarged counterbore 46 to receive the outermost end flange 48 of closure plug 36.
Additionally, as best seen in Figures 3 and 4, each cartridge valve chamber 42 and 44 is in communication with a suction passageway 50 that extends inwardly from and communicates with a respective suction inlet 28 for admitting low-pressure liquid from a low-pressure liquid source (not shown) into cartridge valve chamber 42 and subsequently through the valve and into plunger cylinder 24. As shown in Figure 4, suction inlet 28 and suction passageway 50 are axially spaced along valve chamber axis 52 from and offset by 900 from the axis of discharge passageway 54.
The structure of closure plug 36 is shown in cross section in Figure Plug 36 includes a plug body 58 that has an external seal ring 60 and is adapted to be received into the outer end portion of closure plug chamber 44 for closing and sealing plug chamber 44 to prevent the passage of liquid therethrough and to prevent liquid pressure from acting on the outer end of closure plug chamber 44. The innermost end of closure plug 36 includes a central recess 62, and a surrounding annular land 64 that includes a plurality of radially disposed flow passageways 66 that extend from recess 62 to annular outer surface 68 that has a smaller outer diameter than the plug 10 diameter at 60, to form part of an annular discharge plenum chamber within valve chamber 42, as will hereinafter be described. Closure plug 36 also •includes an internally threaded blind bore 70 at its outermost end for receiving a suitable plug removal tool (not shown) to facilitate removal of plug 36 from *444liquid manifold 16.
15 One form of cartridge-type flow control valve in accordance with the present invention for controlling the flow of liquid to and from plunger cylinder 24 is shown in cross section in Figure 6. Valve 72 includes a tubular valve 4444 .4 4 -housing 74 that carries a pair of externally disposed, axially spaced annular sealing rings 76, 78 that are received in annular sealing grooves 80, 82, respectively. Valve housing 74 has a central longitudinal axis 84, and to* includes a plurality of radially disposed inlet passageways shown in part as 86, 88 that extend from an outer, annular recessed surface 90 on the outermost surface of valve housing 74 to an inner, inclined suction valve seating surface 92 of frustoconical form that defines an inner wall of suction valve chamber 93. Similarly, a plurality of radially disposed outlet passageways shown in part as 94, 96 are provided in valve housing 74 at a position spaced axially from the position at which inlet passageways 86 and 88 are provided. An external, annular, recessed surface 98 is provided at the axial position corresponding with the outlets defined by the multiple discharge passageways shown in part as 94 and 96. Although as shown in Figure 3 suction inlets 28 have their axes offset by 900 from the transverse axis on which the axes of outlets 30 and 54 lie, annular recessed surfaces 90 and 98 provide flow channels to permit communication between manifold inlet 28 and valve inlet passageways shown in part as 86 and 88, and between manifold outlets 30 and 54 and valve outlet passageways shown in part as 94 and 96, respectively.
Positioned within suction valve chamber 93 and between respective inlet passageways 86, 88 is a suction valve 100 that includes an annular suction valve body 102 from which extends an axially extending valve sleeve 104. Each of valve body 102 and valve sleeve 104 is of tubular form and includes a central throughbore 106. Valve body 102 includes an outer, 10 frustoconical surface 103 that includes a pair of axially spaced, inclined annular sealing surfaces 108 and 110, and a recessed, annular pressure equalization groove 112 between sealing surfaces 108 and 110. Valve body o 0@102 also includes a laterally extending bearing surface 114 against which one end of a helical compression spring 116 rests.
15 A suction valve guide 118 is carried within valve housing 74 adjacent the outer portion of suction valve chamber 93 and at the end of housing 74 that faces plunger cylinder 24 within liquid manifold 16. Valve guide 118 includes a central tubular body 120 that has an inner bore 122 that slidably receives suction valve sleeve 104. Extending radially outwardly from tubular body 120 is an annular flange 124 (also see Figure 7) that includes a plurality of peripheral recesses 126, preferably defined by circular arcs, to permit the passage therethrough of liquid between the interior of valve housing 74 and plunger cylinder 24 when valve 72 is positioned within liquid manifold 16.
Annular flange 124 rests against inner annular shoulder 128 and is retained in position by a snap ring 129 that is received in annular slot 131 formed on the inner surface of the valve housing at a distance from shoulder 128 corresponding with the axial thickness of flange 124.
Positioned axially inwardly of suction valve chamber 93 is a relatively short axial connecting bore 130 that provides communication between suction valve chamber 93, plunger cylinder 24 and discharge valve chamber 132.
Connecting bore 130 has a smaller diameter than the maximum diameter of either of suction valve chamber 93 or of discharge valve chamber 132.
Forming a part of discharge valve chamber 132 is an inner, inclined discharge valve seating surface 134 of frustoconical form. As shown in Figure 6, the axial length of inclined discharge valve seating surface 134 is substantially less than that of inclined suction valve seating surface 92. The remainder of discharge valve chamber 132 is of cylindrical form.
A discharge valve is received within discharge valve chamber 132 and includes a generally disc-shaped discharge valve member 136 having an annular, frustoconical sealing surface 138 adapted to engage with discharge valve seating surface 134 to block flow of liquid from axial bore 130 into discharge valve chamber 132. Extending axially into discharge valve chamber *132 from one transverse face of disk-shaped valve member 136 is a *°cylindrical discharge valve stem 140 that is slidably received in a discharge valve guide 142.
Discharge valve guide 142 is structurally similar to suction valve guide 118 in that it includes a tubular body portion 144 having an inner cylindrical surface 146 and having a radially outwardly extending annular flange 148 (also see Figure 7) that includes a plurality of peripheral recesses 150, preferably defined by circular arcs, to permit the passage therethrough of high pressure liquid from the interior of discharge valve chamber 132 into recess 62 of closure plug 36 when valve 76 is positioned within liquid manifold 16.
Annular flange 148 rests against inner annular shoulder 152 and discharge valve guide 142 is retained in position by a snap ring 154 that is received in an annular slot 1-56 formed on the inner surface of-discharge valve chamber 132 at a distance from shoulder 152 corresponding with the axial thickness of flange 148.
Valve housing 74 also includes an externally threaded surface 166 for receiving a suitable valve removal tool (not shown) to facilitate removal of valve 72 from chambers 42 and 44.
Figure 9 shows the structural configuration at the innermost ends of each of multiple inlet passageways shown as 86 and 88. A relief or transition between passageway 86 and suction valve chamber 93 is provided by a counterbore 87 that has its axis transversely offset from the axis of passageway 86. A planar land 89 is provided in suction valve seating surface 92 substantially tangent to passageway 86 and extends transversely relative to valve housing axis 84. The illustrated structure results in an enlarged area transition chamber at the innermost end of the inlet passageway. As can be seen in Figure 6, the transition chamber extends within the outermost axial edges of each of inclined annular sealing surfaces 108 and 110. This structure reduces or prevents metal fatigue at the intersection of suction holes numbered 86 and 88 and surface 92.
Referring now to Figure 10, which is a cutaway view of liquid manifold 16 along the longitudinal axis of a plunger cylinder 24, there is shown plunger cylinder 24, cartridge valve chamber 42, and closure plug chamber 44, with valve housing 74 and closure plug 36 each separated from and spaced ooeooo outwardly of manifold 16. Figure 11 is another cutaway view, similar to that of Figure 10, but with valve housing 74 and closure plug 36 in their operative position within manifold 16. As is apparent from Figures 10 and 11, the 0 present invention permits easy and rapid access to the cartridge valve, permitting removal of the valve from the manifold merely by removing closure plug 36, and without the necessity for removing liquid manifold 16 from the *c *pump drive housing, thereby considerably simplifying and reducing the time for flow control valve replacement.
Also apparent from Figure 11 are the relative positions of an annular suction liquid plenum chamber 158 transversely opposite suction valve 100 and of an annular discharge liquid plenum chamber 160 transversely opposite discharge valve guide 142. Suction plenum chamber 158 is defined -by annular recess 90 between valve housing 74 and the inner wall of manifold 16 defining cartridge valve chamber 42. Similarly, discharge plenum 160 is defined by the space between annular outer surface 98 and the inner wall of manifold 16 adjacent discharge passageways 54 and An alternative embodiment 161 for the cartridge valve structure is shown in Figures 12 through 15. In general, the valve structure and orientation shown in Figures 12 through 15 are similar to those of the valve embodiment shown in Figures 6 through 9. The principal differences between 13 the two embodiments reside in the support arrangement for supporting and guiding the movement of the suction valve within the valve housing, and the support arrangement for supporting and guiding the discharge valve within the valve housing.
Referring to Figure 12, a disc-shaped discharge valve 162 includes first, a cylindrical discharge valve stem 164 that extends axially from transverse surface 163 of discharge valve 162, and a second, elongated suction valve guide portion 166 that extends axially from the opposite transverse side 165 of discharge valve 162. Discharge valve stem 164 is slidably received for axial movement along inner cylindrical surface 146 of discharge valve stem :guide 142, which has the same structure and function as the corresponding guide structure in the embodiment illustrated in Figures 6 through 9.
Suction valve guide portion 166, which takes the place of suction valve o.o guide 118 in the embodiment illustrated in Figures 6 through 9, extends axially through central axial bore 130 within valve housing 170, into suction valve chamber 172, and is received within a central bore 174 of suction valve S 176. A suction valve sleeve 178 extends axially from suction valve 176, but has a shorter axial length than suction valve sleeve 104 of the valve S•embodiment illustrated in Figures 6 through 9. In all other respects, suction valve 176 has the same structure as suction valve 100 in the valve embodiment illustrated in Figure1 1.
Suction valve 176 is urged into the closed condition by helical compression spring 180 that has a first end that bears against transversely extending shoulder 182 of suction valve 176, and a second end that bdars against and is retained by substantially disk-shaped suction valve spring retainer 184. An axially extending lip 186 on spring retainer 184 limits lateral movement of the end of helical spring 180. Additionally, spring retainer 184 includes a plurality of spaced, axially extending throughbores 188 (also see Figure 13) to permit the passage therethrough of liquid between suction valve chamber 172 and plunger cylinder 24 when valve housing 170 is positioned within liquid manifold 16. Retainer 184 also includes a central bore 190 to receive a correspondingly sized cylindrical stub end 192 of guide portion 166.
14 A snap ring 194 is received in an annular slot 196 provided in stub end 192 to limit outward axial movement of spring retainer 184 relative to discharge valve 162.
As best seen in Figures 14 and 15, suction valve guide portion 166 includes three axially elongated, equally angularly spaced and radially extending guide arms 168. The space between adjacent guide arms 168 is provided to allow high-pressure liquid to flow from plunger cylinder 24 within liquid manifold 16 to discharge valve chamber 132. The radial length of the several guide arms 168 corresponds substantially with the radius of central bore 174 so that suction valve 176 can freely slide axially along the S:outermost edges of each of guide arms 168.
Figure 16 shows the alternative cartridge valve embodiment 161 in operative position within liquid manifold 16. As illustrated in Figure 16, the housing of valve 161 is shown in perspective in longitudinal section, while the remaining valve elements are shown in full perspective.
In operation, and referring to the structural elements illustrated in Figures 1 through 11, crankshaft 18 of pump 10 is rotated by an external power source (not shown) to cause each of plungers 20 to reciprocate within 99their respective plunger cylinders 24.
20 On the withdrawal stroke of a plunger 20, as the plunger moves in a direction away from fluid manifold 16, the pressure within plunger cylinder 24 decreases resulting in an unbalanced force acting on suction valve 100. The unbalanced force results from the larger force imposed on valve 100 by the inlet liquid that is to be pressurized, which flows through suction port 28, into suction passageway 50, and then into suction plenum chamber 158. The liquid exerts on the frustoconical surface of annular pressure equalization groove 112 a force greater than the combined forces acting on bearing surface 114 and on the outer transverse end of sleeve 104 to provide an unbalanced force that urges suction valve 100 to move axially away from its seat within the valve body and against the opposing force of suction valve spring 116. Low pressure inlet liquid flows through suction valve chamber 93, as well as into axial bore 130, the bore contained within surface 106, and into plunger cylinder 24 to fill plunger cylinder 24 as plunger 20 retracts.
When plunger 20 has reached the limit of its withdrawal or suction stroke it then changes direction and moves axially outwardly into liquid manifold 16. As plunger 20 moves outwardly it displaces the liquid, raising the pressure in plunger cylinder 24 until it is equal to the pressure of the liquid in suction inlet 28. At this point spring 116 urges suction valve 103 toward its seat in valve housing 74. Once suction valve 100 is closed and plunger continues to displace the liquid, the increasing pressure acts against bearing surface 114 and against the outer transverse end of sleeve 104 to tighten the closure of valve surfaces 108 and 110 against seating surface 92 thereby closing each of the inlet passageways shown as 86 and 88.
Continued movement of plunger 20 toward valve 72 further increases the pressure of the liquid within plunger cylinder 24. When the liquid which 15 is contained within suction valve chamber 93 and within the volume defined by axial bore 130 reaches a pressure which will apply a force to high pressure valve face 165 sufficient to overcome the force exerted by the fluid pressure in cavity 62 and discharge valve chamber 132 acting against surfaces 163 and 167 plus the force of spring 143 high pressure valve 136 will be urged 20 away from its seating surface 134. Pressurized liquid from plunger cylinder 24 will then flow into discharge valve chamber 132, through multiple passageways shown as 96 and 98 into discharge plenum chamber 160 thence into liquid outlets 30 and 54 in liquid manifold 16.
As plunger 20 commences its inward movement the pressure within the volume defined by axial bore 130 and suction valve chamber 93 becomes equal to the pressure in discharge plenum chamber 160. At this time high pressure valve 136 will be urged closed by spring 143 with sealing surface 138 fitting against valve seating surface 134.
As plunger 20 continues its inward movement the pressure in plunger cylinder 24 will decrease until the force exerted by the suction water pressure against the annular pressure equalization groove 112 is sufficient to lift the valve against the force exerted by spring 116 and the remaining plunger 16 cylinder pressure acting against bearing surface 114 and the end of valve sleeve 104. Fluid will now flow into suction valve chamber 93, the volume defined by axial bore 130, central throughbore 106 and plunger cylinder 24.
Fluid will continue to fill these cavities until plunger 20 reaches its full inward position.
When plunger 20 has reached the limit of its inward withdrawal or suction stroke it then changes direction and moves axially outward and into liquid manifold 16 thus completing the cycle. The cycle is repeated with each rotation of crankshaft 18.
The cartridge valve embodiment having the structure illustrated in Figures 12 through 16 operates in a similar manner. However, that valve structure provides the advantage of more rapid suction valve movement, in part because of the lighter weight of that element by virtue of the shorter axial length and consequent smaller size of suction valve sleeve 178 shown 9" 15 in Figure 12 as compared with suction valve sleeve 104 as shown in Figure 6. Another factor causing the more rapid closing of suction valve 176 of Figure 12 as compared with that of suction valve 102 of Figure 6 is the additional spring force acting on surface 182 of suction valve 176 because of the movement of spring retainer 184 toward suction valve 176 as discharge valve 162 is caused to open and to move away from suction valve 176.
The valve structures herein described have been found to provide significantly increased service life as compared with the prior art devices. In tests at discharge pressures ranging from 10,000 to about 15,000 psi., plunger pumps having the manifold structure and valve structures of the first embodiment herein described underwent over 10 million stress cycles without failure, aggregating over 5,000 pump operating hours at a crankshaft rotation speed of approximately 83 rpm. Among the reasons for the extended service life of the valves and liquid manifold having the structure herein disclosed is the fact that the wide range of liquid pressure fluctuations are retained within the replaceable cartridge valve and in the plunger chamber, and they do not 17 act against the valve chamber wall or the cross-port area as included in and as part of the prior art high pressure liquid pump arrangements.
The low-pressure or suction valve of the present valve structure invention can be characterized as a balanced design. That design permits the low pressure or suction valve to open and to admit liquid at low positive suction pressure as soon as the high-pressure valve begins to seat, thereby avoiding cavitation and maximizing pump efficiency.
Additionally, the high-pressure valve has a narrow seating area and a smaller projected area to minimize the liquid pressure required to open it against the system back pressure. That construction contributes to early opening and closing of the high-pressure valve during each pumping stroke, *.o thereby additionally improving volumetric efficiency, and also improving valve .operating life by reducing the effect of pressure and flow pulsations in the C. discharge liquid, and consequent reduction in fatigue loading of the valve body and internal parts. The intensified pressures at which the present valves S 5are capable of sustained operation, and the accompanying pressure 5:.fluctuations, are contained within the plunger chamber and within the replaceable cartridge. Consequently, valve wear is limited to the valve body o° and valve seat contact areas, and easy replaceability and correction for any such wear can be readily accomplished.
The long, cylindrical shape of the valves in accordance with the present invention, as opposed to a shorter, flatter design, permits effective spring design so that the suction and discharge valves will not have metal-to-metal contact upon opening, thus further prolonging valve operating life. The long, cylindrical shape also permits design of the hydraulic valve manifold block with minimal internal stresses, as compared with shorter, larger diameter valves,'-which require larger manifold bores, thereby increasing the internal stresses within the manifold and limiting the volumetric capability of the pump. The valve structures in accordance with the present invention provide for linear flow of the pressurized liquid through the valve structure, which thereby reduces erosive wear caused by cavitation that can occur when high pressure fluids flow past sharp corners.
18 The alternative valve embodiment provides increased volumetric efficiency in that the high pressure discharge valve more rapidly attains full face seating, immediately upon flow reversal within the valve housing as the plunger direction changes from movement into the plunger cylinder to retraction from the plunger cylinder. Additionally, the high pressure discharge valve is double guided, in that it includes guide means at each end thereof, and assembly and disassembly of the valve are simpler.
Finally, it has been found that improved long term performance can be enhanced by replacing the more commonly used nickel plated carbon steel manifold with one made from Carpenter custom 450 stainless steel that has been heat treated to condition H1050, 37 Rockwell C hardness, yield strength of 152,000 psi., and tensile strength of 160,000 psi. Advantageously, the valve seats are also made from that material. With regard to the discharge and suction valves, and also the discharge and suction valve guides, the preferred material is AISI type 440 C stainless steel, quenched and tempered at 500 0 F to obtain a Rockwell C hardness of 57, a yield strength of 275,000 o psi., and a tensile strength of 285,000 psi.
~It is therefore apparent that the valve, manifold, and pump structures ~herein disclosed provide distinct advantages over the prior art devices, particularly the significantly improved operating life.
"INDUSTRIAL
APPLICABILITY
The present invention is applicable to the pumping of liquids at high output pressures of at or above about 15,000 psi. by means of a plunger-type pump. The pump in accordance with the invention provides a long operating life without the pump failures characterized by erosion and stress cracking of the metal at the port areas of the pump housing and flow control valve that are common with existing high-pressure liquid pump structures. The flow control valve forming a part of the present invention is an improved, long-life, cartridge-type valve characterized by linear flow of the high pressure liquid through the valve structure. Additionally, the structure of the valve in accordance with the present invention is easily replaceable in the pump body, 19 and is so configured that it does not require a close tolerance fit within the pump housing.
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SSS 555 THE CLAIMS DEFINING THE INVENTION ARE AS FOLLOWS:- 1. A cartridge-type valve for controlling the flow of low pressure inlet liquid and high-pressure outlet liquid to and from a plunger cylinder of a high-pressure liquid pump, the value including a tubular valve housing having a longitudinal axis, wherein the valve housing includes a suction valve chamber for axially removably receiving a suction valve, a discharge valve chamber spaced from the suction valve chamber for axially removably receiving a discharge valve, the valve housing further including a S. suction inlet passageway extending transversely through the valve housing to a first axial .position relative to the valve housing longitudinal axis, a discharge outlet passageway o 10 extending transversely through the valve housing to a second axial position relative to the valve housing longitudinal axis, wherein the second axial position is axially spaced along the valve housing longitudinal axis from the first axial position, a suction valve seating surface positioned within the valve housing, and a discharge valve seating 0. a surface positioned within the valve housing and spaced axially along the valve housing 15 longitudinal axis from the suction valve seat, a suction valve axially slidably received within the valve housing for movement toward and away from the suction valve seating surface, and a discharge valve axially slidably received within the valve housing for movement toward and away from the discharge valve seating surface and spaced axially from the suction valve.
2. A valve in accordance with claim 1, wherein the valve housing includes an inner, suction valve chamber having an inner, inclined annular suction valve seating surface.

Claims (25)

  1. 3. A valve in accordance with claim 1, wherein the valve housing includes an inner, discharge valve chamber including an inner, inclined annular discharge valve seating surface.
  2. 4. A valve in accordance with claim 1, wherein the valve housing includes an inner, suction valve chamber having an inner, inclined annular suction valve seating surface, and wherein the valve housing includes an inner, discharge valve chamber including an inner, inclined annular discharge valve seating surface.
  3. 5. A valve in accordance with claim 4, wherein the suction valve seating surface and the discharge valve seating surface are each inclined inwardly relative to the housing a 10 axis. 0
  4. 6. A valve in accordance with claim 1, wherein the suction valve includes a central axial bore for permitting liquid to flow axially through the suction valve.
  5. 7. A valve in accordance with claim 2, wherein the suction inlet passageway opens to and intersects with the suction valve seating surface.
  6. 8. A valve in accordance with claim 3, wherein the discharge outlet passageway is 0.00 spaced axially along the valve housing axis from the discharge valve seating surface.
  7. 9. A valve in accordance with claim 1, wherein the suction valve chamber has a diameter greater than that of the discharge valve chamber. A valve in accordance with claim 1, wherein the discharge valve chamber has a smaller diameter than that of the suction valve chamber.
  8. 11. A valve in accordance with claim 1, wherein the valve includes an interconnecting bore coaxial with the valve housing longitudinal axis and interconnecting the suction valve chamber and the discharge valve chamber. 22
  9. 12. A valve in accordance with claim 1, wherein the valve housing includes a first peripheral external recess in communication with the suction inlet passageway to define an external annular suction liquid plenum chamber.
  10. 13. A valve in accordance with claim 12, wherein the valve housing includes an annular sealing means positioned on each side of the first peripheral external recess.
  11. 14. A valve in accordance with claim 12, wherein the valve housing includes a second peripheral external recess in communication with the discharge outlet passageway to define an external annular discharge liquid plenum chamber.
  12. 15. A valve in accordance with claim 1, wherein the suction valve includes a central 10 axial throughbore having its axis coincident with the valve housing longitudinal axis.
  13. 16. A valve in accordance with claim 15, wherein the valve housing includes an interconnecting bore coaxial with the valve housing longitudinal axis and interconnecting the suction valve chamber and the discharge valve chamber, and wherein a: the suction valve throughbore has a diameter substantially equal to the diameter of the interconnecting bore within the valve housing.
  14. 17. A valve in accordance with claim 1, wherein the valve housing includes suction valve guide means positioned within the suction valve chamber for axially guiding movement of the suction valve as it moves toward and away from the suction valve seating surface.
  15. 18. A valve in accordance with claim 17, wherein the valve housing includes spring biasing means extending between the suction valve guide means and the suction valve for resiliently urging the suction valve into sealing engagement with the suction valve seating surface. 23
  16. 19. A valve in accordance with claim 17, wherein the suction valve guide means includes a tubular guide sleeve positioned coaxially within the suction valve chamber, and the suction valve includes a tubular sleeve slidably received within the tubular guide sleeve.
  17. 20. A valve in accordance with claim 17, wherein the suction valve guide means includes a positioning flange extending transversely within the valve housing for contact with the valve housing, and a plurality of flow apertures extend through the flange to permit liquid flow therethrough. A valve in accordance with claim 1, wherein the suction valve includes a C* 10 frustoconical sealing surface engageable with the suction valve seating surface for preventing flow of fluid into the valve housing.
  18. 22. A valve in accordance with claim 21, wherein the sealing surface is defined by a pair of axially spaced, inclined annular sealing surfaces. C °23. A valve in accordance with claim 22, wherein the sealing surface includes a recessed annular groove between the sealing surfaces.
  19. 24. A valve in accordance with claim 1, wherein the discharge valve includes a frustoconical sealing surface engageable with the discharge valve seating surface for preventing flow of liquid from the suction valve housing to the discharge passageway. A valve in accordance with claim 1, wherein the valve includes discharge valve guide means positioned within the discharge valve chamber for axially guiding movement of the discharge valve as it moves toward and away from the discharge valve seat. 24
  20. 26. A valve in accordance with claim 25, wherein the valve includes spring biasing means extending between the discharge valve guide means and the discharge valve for resiliently urging the discharge valve into sealing engagement with the discharge valve seating surface. S27. A valve in accordance with claim 25, wherein the discharge valve guide means includes a tubular guide sleeve positioned coaxially within the discharge valve chamber, and the discharge valve includes a cylindrical extension that is slidably received within the tubular guide sleeve.
  21. 28. A valve in accordance with claim 25, wherein the discharge valve guide means includes a positioning flange extending transversely within the valve housing for contact with the valve housing, and a plurality of flow apertures extending through the positioning flange to permit liquid flow therethrough.
  22. 29. A valve in accordance with claim 17, wherein the valve includes an interconnecting bore coaxial with the valve housing longitudinal axis and 15 interconnecting the suction valve chamber and the discharge valve chamber, wherein the ~suction valve guide means includes an axial guide member connected with the discharge valve and extending through the interconnecting bore and into the suction valve chamber. A valve in accordance with claim 29, wherein the suction valve includes an axial throughbore defining an inner annular surface, and the axial guide member includes a plurality of elongated, circumferentially spaced, radially extending arms for freely slidably contacting the inner annular surface of the suction valve for guiding axial movement of the suction valve relative to the valve housing axis.
  23. 31. A valve in accordance with claim 29, wherein the suction valve chamber surrounds a spring retainer for retaining a suction valve spring between the spring retainer and the suction valve.
  24. 32. A valve in accordance with claim 31, wherein the spring retainer includes a plurality of axially extending through-bores to permit axial flow of liquid therethrough.
  25. 33. A cartridge-type valve for controlling the flow of low pressure inlet liquid and high pressure outlet liquid to and from a plunger cylinder of a high pressure liquid pump 0 substantially as herein described with reference to any one of the embodiments of the 00 invention illustrated in the accompanying drawings and/or examples. DATED THIS 9th Day of February 1999 REYNOLDS METALS COMPANY Attorney: RUSSELL J. DAVIES Fellow Institute of Patent Attorneys of Australia of BALDWIN SHELSTON WATERS 00 0 0060 66 60 0 ABSTRACT A cartridge-type flow control valve (72, 161) for controlling the flow of low pressure inlet liquid and high-pressure outlet liquid to and from a plunger cylinder (24) of a high- pressure liquid pump The cartridge-type valve (72, 161) is slidably received in the valve chamber (42) for enabling removal of the cartridge-type valve (72, 161) from a liquid manifold (16) without the need for separating the liquid manifold (16) from the pump drive housing The cartridge-type valve (72, 161) is of a structure that includes in-line, axially spaced suction (100, 176) and discharge (136, 162) valves that S*:i 10 are each spring biased into closed positions. High-pressure liquid is confined within a valve housing body (72, 160) that contains the suction and discharge valves, to minimize damage to the liquid manifold (16) as a result of pressure fluctuations and high-pressure flows. The cartridge-type valve (72, 161) is removable from the manifold (16) without the necessity of removing or even separating the manifold (16) from the pump drive 15 housing (12).
AU85189/98A 1994-04-04 1998-09-16 Flow control valve Ceased AU709638B2 (en)

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
US222746 1994-04-04
US08/222,746 US5636975A (en) 1994-04-04 1994-04-04 Inlet and discharge valve arrangement for a high pressure pump
AU22014/95A AU694503B2 (en) 1994-04-04 1995-04-04 High-pressure liquid pump and flow control valve

Related Parent Applications (1)

Application Number Title Priority Date Filing Date
AU22014/95A Division AU694503B2 (en) 1994-04-04 1995-04-04 High-pressure liquid pump and flow control valve

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Publication Number Publication Date
AU8518998A AU8518998A (en) 1998-11-05
AU709638B2 true AU709638B2 (en) 1999-09-02

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Publication number Priority date Publication date Assignee Title
CN117346064B (en) * 2023-11-30 2024-04-09 龙口市华科电子有限公司 Intelligent pressure reducing valve with pressure monitoring function for liquefied gas tank

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4878815A (en) * 1988-05-18 1989-11-07 Stachowiak J Edward High pressure reciprocating pump apparatus
US5299921A (en) * 1992-09-10 1994-04-05 Halliburton Company Manifold for a front-discharge fluid end reciprocating pump
US5302087A (en) * 1993-04-29 1994-04-12 Butterworth Jetting Systems, Inc. High pressure pump with loaded compression rods and method

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4878815A (en) * 1988-05-18 1989-11-07 Stachowiak J Edward High pressure reciprocating pump apparatus
US5299921A (en) * 1992-09-10 1994-04-05 Halliburton Company Manifold for a front-discharge fluid end reciprocating pump
US5302087A (en) * 1993-04-29 1994-04-12 Butterworth Jetting Systems, Inc. High pressure pump with loaded compression rods and method

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