This invention relates to pressure regulators and more particularly to a bypass pressure regulator for controlling the pressure and flow rate of liquid.
In many liquid supply systems, and particularly fuel injection systems for combustion engines, it is desirable to supply liquid fuel to the fuel injectors from a fuel pump which continuously delivers a quantity of liquid fuel sufficient to supply the maximum fuel demand of the engine. Consequently, when the engine is operating under conditions which require less fuel, there is an excess of fuel being delivered from the fuel pump. This is especially true when the engine is idling and has an extremely low fuel demand while the fuel pump is still delivering a large quantity.
In such systems, a bypass pressure regulator is utilized to divert or bypass the excess fuel from the needed supply of fuel consumed by the engine. Preferably, the bypass liquid fuel is diverted back to the liquid supply source such as a fuel tank. In fuel system applications, the fuel pump is typically located inside the fuel tank. The bypass pressure regulator can be located in the tank and immediately downstream of the fuel pump thus diverting bypass fuel directly back into the fuel tank, or it can be located further downstream of the fuel pump and downstream of an injector fuel rail utilized as a manifold which communicates with the injectors. If the bypass pressure regulator is mounted downstream of the fuel injectors, a bypass fuel return line is needed to return the excess fuel back into the fuel tank. Whether the bypass pressure regulator is internal or external to the fuel tank, when utilizing a regulator, the fuel pump can operate continuously maintaining a high rate of fuel output to accommodate a rapidly changing demand for fuel at the engine.
Some previous bypass pressure regulators, such as that disclosed in U.S. Pat. No. 5,727,529, use a flexible diaphragm in a can which is spring biased to close a bypass passage. The diaphragm is responsive to an increase in fuel pressure acting thereon and when displaced, permits the fuel to flow through the bypass passage to be returned to the fuel tank. Although generally satisfactory in performance, and beneficial for the ability to accommodate thermally expanding or excess fuel, these bypass pressure regulators are expensive to manufacture because of the diaphragm and numerous parts. Furthermore, the diaphragm regulators are relatively large, and have a relatively slow response time causing undesirable fuel pressure pulsations which can affect the performance of the engine and can generate undesirable levels of noise in the fuel system or other liquid systems.
Other bypass pressure regulators, such as that disclosed in U.S. Pat. No. 5,975,061 and incorporated herein by reference, do not utilize a diaphragm. As best illustrated in
Furthermore and unfortunately, known bypass pressure regulators like regulator 20 do not maintain a constant pressure drop through the valve under varying flow rates. In operation, the spring force and generally the area of the exposed head 32 determine the fuel pressure at which the valve will “crack” or begin to open. When the valve assembly 30 first starts to open, flow through the annulus between the valve head 32 and seat 42 develops at high velocities relative to the surrounding fuel. This high velocity produces a low pressure region 50 exerting a force on the valve assembly 30 which is additive to the spring force and thus tends to close the valve assembly 30. In known bypass pressure regulators this low pressure region can lead to unstable oscillations of the valve assembly 30, fuel pressure flow rate fluctuations and noise of the valve assembly. In extreme cases, the regulator can be damaged by the hammering effect of the components. Yet further, known bypass pressure regulators are not easily integrated into other components of a typical fuel system or pump module of a combustion engine, are relatively complex, and relatively expensive to manufacture.
A low cost bypass pressure regulator for liquid fuel flowing preferably in a returnless fuel system for a combustion engine communicates operatively with a conduit or storage vessel which flows fuel from a fuel pump of the fuel system to at least one fuel injector of the combustion engine. The pressure regulator preferably has a valve head disposed at least in-part in a valve chamber defined by a circumferentially continuous inner surface carried by a valve body and which transitions radially outward with respect to a center axis and in a downstream direction. The valve head preferably tapers radially inward with respect to the center axis in an upstream direction and from a peripheral outer edge of the head.
When the valve head is in a closed position, the valve head is seated sealably against a seat carried by the body and the peripheral outer edge which is spaced radially downstream of the seat is radially spaced from, but fitted closely to the continuous inner surface of the body thus defining a close fit region there-between. When the valve head is in an open position, the tapered valve head is spaced appreciably away from the seat and the peripheral outer edge is spaced appreciably radially inward from the body continuous inner surface thus defining a free flow region there-between. The movement of the valve head from closed to open is in a downstream direction, hence the free flow region is generally located downstream of the continuous inner surface portion which defines in-part the close fit region when the valve head is closed. Because the flow cross section spaced axially downstream of the seat generally enlarges as the valve head opens, a high velocity of liquid flow is moved away from the seat thus reducing the otherwise low pressure at the seat. By reducing or eliminating low pressure at the seat, oscillation of the valve head is reduced or eliminated. This also reduces fuel pressure and flow rate fluctuations and noise.
Preferably, the continuous inner surface of the body has a circular crest generally formed by the congruent meeting of a substantially cylindrical portion and a substantially conical or tapered portion of the continuous inner surface. When the valve head is in the closed position, its peripheral outer edge is substantially aligned axially to the circular crest to form the close fit region. When the valve head is in the open position, the peripheral outer edge shifts downstream axially well into the conical portion of the continuous inner surface thus forming the larger free flow region.
Preferably and advantageously, the flow cross section represented by the close fit region remains substantially constant and accounts for valve head-to-seat wear and manufacturing tolerances because the continuous inner surface in this region is cylindrical. Thus any shifting of the closed valve head over an extended period of time (i.e. wear) would simply shift the peripheral outer edge slightly upstream and the edge remains aligned axially to the cylindrical portion.
Preferably, the valve head is biased closed, not by a conventional diaphragm, but by a compression spring compressed axially between the valve head and a guide member of the valve body generally located downstream of the valve head. A valve stem preferably projects from the head through the guide member and preferably through the spring.
Objects, feature, and advantages of this invention include a bypass pressure regulator which produces a more uniform regulated output pressure and flow rate, is relatively inexpensive and versatile, quieter and less prone to producing noise, has a valve head which is less likely to oscillate, is robust, reliable, durable, maintenance free, of relatively simple design, easy to assemble, of economical manufacture and assembly and in service has a long useful life.
These and other objects, features and advantages of this invention will be apparent from the following detailed description of the preferred embodiments and best mode, appended claims and accompanying drawings in which:
The bypass pressure regulator 120 is integrated or generally housed in the conduit 122 of the returnless fuel supply system 124. The versatility of the regulator 120 is generally contributed substantially by a valve body 150 of the regulator 120 which is preferably comprised of three components; an annular retainer 152 engaged sealably to the conduit 122 at an opening 154, a dome structure 156 disposed about a center axis 158 and having a continuous base or end rim 160 fitted sealably to the retainer 152, and a guide member 162 preferably engaged axially between the end rim 160 of the dome structure 156 and the retainer 154. The dome structure 156 projects axially from the base rim 160, through the opening 154 of the conduit 122 and generally into the channel 138 where it converges generally to a distal end or an annular shaped apex 164 of the structure 150.
As best illustrated in
A valve stem or shank 180, disposed concentrically to the center axis 158, projects axially in a downstream direction from the annular shelf 170 carried by the enlarged valve head 166 and generally through a bypass passage 182 in the dome structure 156 which communicates axially with the valve chamber 168 at an outlet port 184 of the chamber 168. The shank 180 extends through and is supported and guided by a substantially cylindrical collar portion 186 of the guide member 162 which is located in the bypass passage 182. A support structure 188 of the guide member 162 generally projects radially outward from a downstream end 246 of the collar portion 186, across a hole 190 of the retainer 152 which communicates with the bypass passage 182, and attaches rigidly to the dome structure 156 and/or retainer 152. The valve head 166 is biased closed against the valve seat 176 by a coiled compression spring 192 compressed between the annular shelf 170 of the enlarged valve head 166 and a distal annular end 193 of the collar portion 186 of the guide member 162.
The valve chamber 168 has an upstream bowl-shaped or rounded section 194 communicating directly with the inlet port 174, and a downstream conical frustum section 196 which generally expands radially outward from the rounded section 194 and communicates axially between the rounded section 194 and the outlet port 184. The bypass passage 182 is located concentrically to and directly downstream from the frustum section 196 and communicates with section 196 at the outlet port 184. The rounded section 194 is generally defined by an annular concave portion 198 and a cylindrical portion 200 of the inner surface 167. Portion 198 extends radially outward from the seat 176 as it extends axially in a downstream direction to the cylindrical portion 200. The frustum section 196 of the valve chamber 168 is generally defined by a radially expanding or frusto conical portion 202 of the inner surface 167 which extends axially, and radially expands in a downstream direction, from the cylindrical portion 200 and to a substantially cylindrical wall 204 of the dome structure 156 which defines the bypass passage 182 that extends axially to the end or base rim 160. For purposes of illustration, the union of the cylindrical wall 204 with the cylindrical portion 200 of the inner surface 167 is coaxial with the outlet port 184.
When the tapered valve head 166 is in the closed position 178, a peripheral outer edge 206, which generally defines the outer periphery of the valve head shelf 170, is aligned axially with the cylindrical portion 200 of the inner surface 167 preferably at or slightly upstream of a peripheral inner edge or circular crest 208 of the inner surface 167 formed by the congruent joining of the cylindrical portion 200 and the conical portion 202. The peripheral outer edge 206 of the valve head 166 and the cylindrical portion 200 of the dome structure 156 are slightly spaced apart radially from one-another just enough to prevent contact, thus providing interference-free seating of the valve head 166 with the seat 176. This small radial space or close fit region 210 between the peripheral outer edge 206 and the circular crest 208 generally enlarges to a free flow region 212 as the valve head 166 moves from the closed position 178 to an open position 214 (as best shown in
When fuel pressure in the channel 138 of the conduit 122 generally exceeds the biasing force of the coiled compression spring 192, compressed axially between the upstream end 193 of the collar portion 186 of the guide member 162 and the annular shelf 170 of the tapered valve head 166, the biased closed valve head moves axially away from the seat 176 toward the open position 214, cracking the valve open and slightly compressing the spring 216 axially. Also when opening, the peripheral outer edge 206 of the tapered head 166 moves axially past the circular crest 208 and into the frustum section 196 of the valve chamber 168. Hence, upon initial cracking open of the pressure regulator 120, the close fit region 210 begins to enlarge because the radial distance between the peripheral outer edge 206 and the dome structure 156 increases due to the tapered conical portion 202 of the inner surface 167. This shift of the close fit region 210 to the free flow region 212 moves the high velocity of fuel flow away from the valve seat 176 which would otherwise create a low pressure region causing the valve head 166 to repeatedly briefly close and open or oscillate. Thus, enlargement of the close fit region 210 to the free flow region 212 greatly reduces and substantially prevents oscillation of the valve head 166 and reduces valve noise and seat wear.
Also for reducing valve noise and improving wear and sealing between the seat 176 and the head 166, the head has a resilient leading cover or glove 220 which covers a base segment 222 of the head 166. The cover 220 has a circular shoulder 224 which projects radially inward and press fits into a circular groove 226 of the base segment 222 which is spaced axially upstream of the annular shelf 170 and opens radially outward to receive the shoulder 224. The shank 180 and base segment 222 are preferably unitary and formed preferably of metal for durability, but could also be formed of injection molded plastic or other rigid materials. The cover 220 is preferably made of a fuel resistant synthetic rubber or polymer material.
Preferably and advantageously, the flow cross section represented by the close fit region 210 remains substantially constant and compensates or allows for valve head-to-seat wear and manufacturing tolerances because the continuous inner surface 167 in this region 210 is cylindrical. Thus any axial shifting of the valve head 166 while generally in the closed position 178 over an extended period of time (i.e. wear) would simply shift the peripheral outer edge 206 slightly upstream and the edge remains aligned axially to the cylindrical portion 204.
As best illustrated in
Because the valve head 166 is tapered, a diameter 234 of the seat 176 which lies in the first imaginary plane 228 is substantially smaller than a diameter 236 of the peripheral outer edge 206. To create the close fit region 210 when the valve head 166 is closed, the peripheral outer edge diameter 236 is slightly smaller than a diameter 238 of the cylindrical portion 200 and circular crest 208 of the inner surface 167. Because the conical portion 202 of the inner surface 167 tapers radially outward in a downstream direction, the crest diameter 238 is appreciably smaller than a diameter 240 of the conical portion 202 which generally lies in the third imaginary plane 232. Preferably, and when the valve head 166 is in the fully open position 214, the annular flow area at the second imaginary plane 230 is generally equal to or larger than the annular flow area at the first imaginary plane 228, at the inlet port 174, and generally equal to or smaller than the annular flow area at the third imaginary plane 232 at the free flow region 212. This generally eliminates any pressure drop transients at the planes 230, 232, regardless of valve position, and thus generally places any fluid flow dynamics which may impact design considerations of the valve generally at the inlet port 174, simplifying sizing of the bypass pressure regulator 120 between varying applications.
The robust design of the valve head 166 and dome structure 156 has an axial tolerance which accounts for axial compression and/or wear of the resilient cover 220 with the seat 176. Slight wear or varying axial compression of the valve head cover 220 could cause the head 166 and peripheral outer edge 206 to shift slightly upstream essentially shifting the closed position 178 slightly upstream. The flow cross section of the close fit region 210, however, remains substantially constant because the peripheral outer edge 206 which is initially aligned axially to about the circular crest 208 can move slightly upstream due to wear, but remains aligned axially to the cylindrical portion 200 of the inner surface 167.
During assembly of the bypass pressure regulator 120, the cover 220 is preferably press fitted or overmolded into the circular groove 226 in the base segment 222 of the head 166. The shank 180 is then inserted axially through the coiled compression spring 216 and through the collar portion 186 of the guide member 162. The pre-assembled collar portion 186, the shank 180, the valve head 166 and the spring 192 are inserted in the dome structure 156 at the end rim 160 of the cylindrical wall 204. The collar portion 186 is easily centered to the center axis 158 by locating two chamfered distal ends 242 of two diametrically opposed legs 244 of the support structure 188 of the guide member 162, which project axially outward from a base end 246 of the collar portion, to the chamfered base end or rim 160 of the dome structure 156. When fitting the distal ends 242, the taper characteristic of the valve head 166 centers the head to the seat 176 and thus to the center axis 158. Also, the spring 192 which bears axially between the shelf 170 and the distal end 193 of the collar portion 186 axially compresses holding the head 166 on the seat 176. The base or rim end 160 of the dome structure 156 is then slid axially into a counter bore 248 of the retainer 152 until the base end 160 axially contacts a radially inward projecting annular shoulder 250 of the retainer 152. The shoulder 250 generally defines the bore or hole 190 for exiting bypass flow 142 from the bypass pressure regulator 120.
As thus assembled, the bypass pressure regulator 120 is a completed unit and is ready for integration into any variety of applications. Preferably, and as illustrated in
Referring to
Suspended rigidly from the flange 306 in the chamber 300 of the tank 130′ are two spring loaded shocks or vertical displacement struts 308 (one shown) which fit slidably into strut guides (not shown) of a structural pod 310 to yieldably support the pod 310 of the fuel pump module 302 so that a bottom or bottom cover plate 312 of the pod is generally located and held against a bottom wall of the tank 130′ even if the tank walls should slightly flex, expand, or contract. The pod 310 houses and supports numerous components including a fuel pump 128′, an electric motor 312 coupled to the pump, and a filter cartridge 314 having a filter element 316 and an integrated bypass pressure regulator 120′. Fuel flows generally between the components via the pod 310 thus eliminating the need for conventional hoses, tubes and fittings. Power leads or wires 318 are routed from the motor 312 and through a sealing grommet 320 of the flange 306.
The pod 310 carries an inner cylindrical first surface 322 defining a first bore 324 having a central axis 326 extending substantially vertically, and an inner cylindrical second surface 328 defining a second bore 330 spaced radially outward from the first bore 324 and having a central axis 158′ disposed substantially parallel to the central axis 326 of the first bore 324. The pump and motor 128′, 312 are assembled in the first bore 324 and the filter cartridge 314 is assembled in the second bore 330.
During manufacture, components of the fuel pump 128′ are preferably assembled into the first bore 324 through an open top end and are generally nestled against a continuous bottom shoulder 332 projecting radially and unitarily inward from the first cylindrical surface 322. After the fuel pump 128′ is assembled, the pump motor 312 which has a stator encircling an armature with a drive shaft 334 journaled for rotation by a pair of bearings is inserted into the first bore 324 from above and coupled mechanically to the pump 128′. The open end is then sealed-off by a cap 336 which preferably carries one set of the bearings. At least one electrical lead 318 extends through the end cap 336. When operating, fuel enters the pump 128′ through an inlet or bottom port 134′ generally defined by the shoulder 332 of the pod 310 and pressurized fuel exits the pump 128′ and flows into the second bore 330 via an outlet or fuel passage 136′ defined by the pod 310 and communicating through the first and second surfaces 322, 328.
The reversible filter cartridge 314 is preferably pre-assembled with the integral bypass pressure regulator 120′ located radially inward from the cylindrical fuel filter element 316. The filter element 316 is located axially between an inverted funnel-like primary end retainer 338 for flowing the supply fuel identified by arrow 140′ and a secondary end retainer 152′ of the cartridge 314 for flowing the bypass fuel identified by arrow 142′. Each disc-like retainer 338, 152′ defines a circular groove 340 (as best shown in
The primary end retainer 338 has an inverted bowl-like base portion 340 which carries a cylindrical inward face 342 that defines in-part a fuel cavity 344 of the channel 138′ held at system operating pressure by the bypass pressure regulator 120′, and a collar portion 346 which projects upward from the base portion 340 and defines a supply fuel outlet passage 350 of the channel 138′ that communicates axially with the cavity 344. The collar portion 346 projects into a counter bore 352 defined by a cylindrical third surface 354 carried by the pod 310. An outer radial face 356 of the base portion 340 defines a continuous slot 358 which seats a resilient seal or preferable O-ring 360 that seals to the second surface 328 of the second bore 330. An outer radial face 362 of the collar portion 346 also defines a continuous slot 364 which seats an O-ring 366 that seals to the third surface 354 of the counter bore 352, and likewise, an outer radial face 252′ of the secondary end retainer 152′ defines a continuous slot or groove 260′ which seats an O-ring 258′ that seals to the second surface 328 of the second bore 330. All three O-rings 360, 366, 258′ and the seating arrangement of the filter element 316 to the retainers 152′ 338 assure that all of the fuel flowing from the fuel passage 136′ is filtered before entering the pressurized fuel cavity 344 of the channel 138′.
After filtration, the fuel which enters the cavity 344 primarily flows upward through the fuel outlet passage 350 of the collar portion 346, through an upward projecting barbed nipple 368 of the pod 310 and into a flexible tube 370 of the conduit 122′ press fitted to the nipple 368 and extending upward to couple to a similar nipple 372 projecting downward from the flange 306 (as best shown in
A dome structure 156′ of the bypass pressure regulator 120′ projects axially and concentrically upward from the retainer 152′ and is spaced radially inward from and generally aligned axially to the filter element 316. The pressurized fuel cavity 344 is thus generally defined axially between the primary end retainer 338 and an annular face 372 of the retainer 152′ which spans radially between a continuous groove 374, which receives an end rim 160′ of the dome structure 156′, and the dome structure 156′. The cavity 344 is generally defined radially between the dome structure 156′ and the outer filter element 316.
When fuel system pressure is exceeded, the biased closed bypass pressure regulator 120′ opens, compressing a biasing spring 192′ axially as a valve head 166′ moves axially downward away from a seat 176′ carried by the dome structure 156′. Bypass fuel 142′ flows through an inlet port 174′ generally defined by the seat 176′ and downward through a valve chamber 168′ and communicating bypass passage 182′, both defined by the dome structure 156′. The bypass fuel 142′ then exits the second bore 330 through a hole 190′ of the retainer 152′ and through a slightly larger hole 374 of the cover 312 for holding the filter cartridge 314 axially in the second bore 330. During manufacture, at least one and preferably three upward projecting flex arms 378 of the cover 312 snap fit to the pod 310 to lock the cartridge 314 within the second bore 330. Preferably, the arms 378 each have a slot 380 which receives a ramped tab 382 projecting outward from the pod 310, thus locking the cover 312 in-place.
While the forms of the invention herein disclosed constitute presently preferred embodiments, many others are possible. For instance, the conduit 122 can be a liquid storage pressure vessel and the channel 138 can be a pressure chamber for the storage of liquid, and not necessarily the flow of liquid. In such an application, the bypass pressure regulator 120 will actually function as a pressure relief regulator. It is not intended herein to mention all the possible equivalent forms or ramification of the invention. It is understood that terms used herein are merely descriptive, rather than limiting, and that various changes may be made without departing from the spirit or scope of the invention as defined by the following claims.