This disclosure relates to generally to bearing assemblies for drive shafts for pumps and more specifically to a lubricant retainer for a pump shaft bearing assembly.
Centrifugal pumps are typically comprised of a pump housing having an axially positioned pump inlet, a discharge outlet and an opening into the pump housing for positioning a pump shaft. An impeller is positioned to rotate within the pump chamber and the impeller is connected to an end of the drive shaft for rotation.
The drive shaft extends from the impeller, housed within the pump housing, to a drive motor that is located usually to the rear of the pump housing. The drive shaft is typically supported by two bearing assemblies to balance the considerable weight of the drive shaft. The bearing assemblies may each include a bearing housing that operates to provide means for cooling and/or lubricating the bearings highly viscous materials such as grease, or lower viscous materials such as oil or other suitable fluid. The different viscosities of these lubricants provide different problems in distribution through the bearing housing.
In many pump assemblies, the pump shaft and bearing assemblies are supported on a pedestal, frame or support and the pump housing is cantilevered from the pedestal or frame. The pedestal or frame is located between the pump housing and the drive motor.
In a first aspect, embodiments are disclosed of a lubricant retainer for use in a pump bearing assembly, the bearing assembly which in a first operating configuration is lubricated by a relatively highly viscous lubricant, and which in a second operating configuration is lubricated by a less-viscous lubricant, the bearing assembly comprising a bearing housing having a bore extending therethrough for receiving a pump drive shaft, spaced-apart bearing mounting zones within said bore with a chamber therebetween, each bearing mounting zone arranged for the in use receipt of a bearing therein, each zone having associated therewith one lubricant retainer, said lubricant retainer being adapted to be mounted within said bore adjacent the bearing mounting zone with which it is associated so as to form a barrier between the bearing mounting zone and the chamber when the pump bearing assembly is in the first operating configuration, the retainer being removed when the pump bearing assembly is in the second operating configuration.
In some embodiments, the lubricant retainer comprises an annular barrier wall which abuts in use against an inner surface of the bore.
In some embodiments, the pump bearing assembly comprises a sump arranged in the chamber, a drainage slot in each bearing mounting zone, and a drainage channel between each drainage slot and the sump and the lubricant retainer further includes a barrier flange extending laterally from the annular barrier wall and being adapted to provide a barrier between the drainage slot and drainage channel.
In some embodiments, the annular barrier wall is ring-shaped. In some embodiments, the ring-shaped barrier wall has an outer peripheral edge which is securable within a slot in the bore of the bearing housing.
In some embodiments, the barrier flange has a free edge which abuts against the bearing when fitted. In some embodiments, the barrier wall is deformable so that it can be snap-fitted into the slot. In some embodiments, the barrier flange extends laterally from each side of the annular barrier wall.
In a second aspect, embodiments are disclosed of a pump bearing assembly which in a first operating configuration is lubricated by a relatively highly viscous lubricant, and which in a second operating configuration is lubricated by a less-viscous lubricant, the bearing assembly comprising a bearing housing having a bore extending therethrough for receiving a pump drive shaft, spaced-apart bearing mounting zones within said bore with a chamber therebetween, each bearing mounting zone arranged for the in use receipt of a bearing therein, each zone having associated therewith one lubricant retainer, said lubricant retainer being adapted to be mounted within said bore adjacent the bearing mounting zone with which it is associated so as to form a barrier between the bearing mounting zone and the chamber when the pump bearing assembly is in the first operating configuration, the retainer being removed when the pump bearing assembly is in the second operating configuration, the lubricant retainer being in accordance with the first aspect described above.
In some embodiments, the bearing assembly is secured to or integral with a pump housing support.
Notwithstanding any other forms which may fall within the scope of the methods and apparatus as set forth in the Summary, specific embodiments will now be described, by way of example, and with reference to the accompanying drawings in which:
Referring to the drawings,
The pump housing 20 further comprises a pump housing inner liner 32 arranged within the outer casing 22 and which includes a main liner (or volute) 34 and two side liners 36, 38. The side liner (or back liner) 36 is located nearer the rear end of the pump housing 20 (that is, nearest to the pedestal or base 10), and the other side liner (or front liner) 38 is located nearer the front end of the pump housing 20.
As shown in
When the pump 8 is assembled, the side openings in the volute 34 are filled by the two side liners 36, 38 to form a continuously-lined chamber disposed within the pump outer casing 22. A seal chamber housing encloses the side liner (or back liner) 36 and is arranged to seal the space between the shaft 42 and the pedestal or base 10 to prevent leakage from the back area of the outer casing 22. The seal chamber housing takes the form of a circular disc with a central bore, and is known in one arrangement as a stuffing box 70. The stuffing box 70 is arranged adjacent to the side liner 36 and extends between the pedestal 10 and the shaft sleeve and packing that surrounds the shaft 42. An impeller 40 is positioned within the volute 34 and is mounted to the drive shaft 42 which has a rotation axis. A motor drive (not shown) is normally attached by pulleys to the exposed end 44 of the shaft 42, in the region behind the pedestal or base 10. The rotation of the impeller 40 causes the fluid (or solid-liquid mixture) being pumped to pass from the pipe which is connected to the inlet hole 28, through the chamber which is defined by the volute 34 and the side liners 36, 38, and then out of the pump 8 via the outlet hole 30.
Referring to
The ring-shaped body 56 comprises a radially-extending mounting flange 58 and an axially-extending, annular locating collar (or spigot) 60 extending therefrom, the mounting flange 58 and the spigot 60 serving to locate and secure various elements of the pump housing 20 to the pedestal or base 10, as is described more fully below. While the mounting flange 58 and annular locating collar or spigot 60 are shown in the drawings as continuous ring-like members, in other embodiments the mounting member need not always include a ring-shaped body 56 in the form of a continuous, solid ring which is attached to, or formed integrally with the main body 52, and in fact the flange 58 and/or the spigot 60 may be formed in a broken or non-continuous ring form. The pedestal 10 includes four apertures 62 that are formed through the mounting flange 58, and spaced thereabout, for receiving liner locating and fixing pins 63 for locating the main liner or volute 34 and the pump outer casing 22 relative to one another. There are four of these apertures 62 arranged circumferentially around the ring-shaped body 56 and positioned in between the plurality of screw-receiving apertures 64 which are also positioned through the mounting flange 58. The screw-receiving apertures 64 are arranged for receipt of securing members for securing the side casing part 24 of the pump casing 22 to the mounting flange 58 of the pedestal 10. The screw receiving apertures 64 co-operate with threaded apertures located in the side casing part 24 of the pump casing 22 to receive mounting screws.
The annular locating collar or spigot 60 is formed with a second locating surface 66 corresponding to the outer circumference of the annular locating collar 60 and a first locating surface 68 corresponding to the inner circumference of the annular locating collar 60, facing inwardly towards the shaft 42 rotation axis. These respective inner and outer locating surfaces 66, 68 are parallel to one another and parallel to the rotation axis of the drive shaft 42. This feature is best seen in
Reference is made to
The pump casing 22 is provided with an inner main liner 34, which may be a single piece (typical of metal liners) as shown in
The stuffing box 70 is shown in
The stuffing box 70 has a radially-extending portion 78 that registers against an inner shoulder 80 of the locating collar or spigot 60 of the pedestal 10 and against the first locating surface 68 of the spigot 60. The casing side liner (or back liner) 36 is also structured with a radially-extending portion 82 that is positioned adjacent the extending portion 78 of the stuffing box 70 and registers against the first locating surface 68 of the collar or spigot 50. The inner main liner 34 has a radially-inwardly extending annular portion 84 that registers against the extending portion 82 of the casing side liner 36 and is aligned in place accordingly. Thus a portion of the casing side liner 36 is disposed between the stuffing box 70 and the inner main liner 34. In the case of metal parts, gaskets or o-rings 86 are used to seal the spaces between the respective parts.
The inner main liner 34 is configured with an axially-extending annular flange or follower 88 that is sized in diameter to be received about the outer circumference or second locating surface 66 of the annular locating collar or flange 60. The annular follower 88 is also sized in circumference to be received within an annular space 90 formed in the annular flange 74 of the side casing part 24. The follower 88 is formed with a radially-extending lip 92 that has a face 94 that is oriented away from the mounting flange 58 of the pump base 10. The face 94 of the lip 92 is angled from a plane that is perpendicular to the rotational axis of the pump 8.
A liner locating and fixing pin 63 is received through the bore 62 in the mounting flange 58 and into the aperture 96 of the side casing part 24 to engage the lip 92 of the inner main liner 34. A head 98 of the fixing pin 63 may be configured to engage the lip 92 of the follower 88. The head 98 of the fixing pin 63 may also be formed with a configured terminal end 168 locating section that seats against the side casing part 24 in a blind end cavity 100 such that rotation of the fixing pin 63 exerts a thrust force that provides movement of the inner main liner 34 relative to the side casing part 24 and locks the fixing pin 63 in place.
The arrangement of the pump pedestal 10 and the pump elements is such that mounting member 56 and its associated mounting flange 58 and annular locating collar or flange 60, having the first locating surface 68 and second locating surface 66, provide for proper alignment of the pump casing part 24, inner main liner 34, casing side liner 36 and stuffing box 70. The arrangement also properly aligns the drive shaft 42 and impeller 40 relative to the pump housing 20. These interfitting parts become properly concentrically aligned when at least one of the components is in contact with a respective one of the first locating surface 68 and the second locating surface 66. For example, of primary importance is the alignment of the annular follower 88 of the inner main liner 34 with the second locating surface 66 (to position the main liner in concentric alignment in relation to the pedestal 10), as well as the alignment of the stuffing box 70 with the first locating surface 68 (to provide good concentric alignment of the stuffing box bore with the shaft 42). Many of the alignment advantages of the pump apparatus can be achieved if these two components are located at the respective locating surfaces of the spigot or collar 60. In other embodiments if there is at least one component positioned on either side of the annular locating collar or flange 60, then it is envisaged that other shapes and arrangements of components parts can be developed to interfit with one another and maintain the advantages of concentricity offered by the arrangement shown in the embodiment shown in the drawings.
The use of the annular locating collar or flange 60 allows the pump casing 22 and casing side liner 36 to be aligned accurately with the stuffing box 70 and the drive shaft 42. Consequently, the impeller 40 can rotate accurately within the pump chamber 72 and the inner main liner 34 to thereby allow much closer operating tolerances between the interior of the inner main liner 34 and the impeller 40, especially at the front side of the pump 8 as will shortly be described.
Furthermore, the arrangement is an improvement on conventional pump housing arrangements because both the stuffing box 70 and the pump liner 34 are positioned relative to the pump pedestal 10 directly, thus improving the concentricity of the pump in operation. In prior art arrangements, the shaft turns in a shaft housing which is itself attached to a pump housing support. The pump housing support is associated with the casing of the pump. Finally, the stuffing box is linked to the pump casing. Therefore the link between the shaft housing and the stuffing box in prior art arrangements is indirect, leading to a stacking of tolerances which often is a source of problems such as leakage, necessitating the use of complicated packing, and so on.
In summary, without limitation the embodiment of the pump base or pedestal 10 described herein has at least the following advantages:
1. a single spigot to attach and align both the pump casing, pump liners and the stuffing box to the pump shaft axis without relying on the alignment of these through a number of associated parts, which invariably cause misalignment due to the normal stack-up of tolerances.
2. a spigot which can be machined in the same operation with the part set-up in the machine in the one operation as the bore for the shaft, and so has true parallel outer and inner diameters.
3. a unitary (one piece) pump pedestal or base, which is easier to cast and then machine finish.
4. a pump with overall improved concentricity—if a metal liner is used, it in turn aligns the pump front entry liner 38 (throatbush) to the pump shaft. That is, the shaft 42 is aligned concentrically with the pedestal 10 and with the flange 58 and spigot 60, which in turn means that the casing 24 and the main liner 34 are aligned directly with the shaft 42, which in turn means that the front casing 28 and the main liner 34 are aligned with the shaft 42, so that the front liner 38 and shaft 42 (and impeller 40) are in better alignment. As a result, the gap between the pump impeller 40 and the front liner 38 at the inlet of the pump can therefore be maintained concentric and parallel—that is, the front side liner inner wall is parallel to the front rotating face of the impeller, which results in improved pump performance and reduced incidence of erosive wear. The improvement in concentricity therefore extends across the whole pump.
5. In the arrangement shown, the shaft 42 is fixed in position (i.e., to prevent sliding toward or away from the pump housing 20). The slurry pump industry standard conventionally provides a shaft position that is slidingly adjustable in an axial direction to adjust the pump clearance (between the impeller and front liner), however this method increases the number of parts, and the impeller cannot be adjusted while the pump is operating. Also, in industry practice, adjusting the shaft position affects the drive alignment which should also be realigned, but is seldom realigned because of the extra maintenance time required to make the adjustments. The configuration shown herein provides a non-sliding shaft, offers fewer parts and less maintenance. Further, the bearings used can take thrust in either direction depending on the pump application, and no special thrust bearing is required.
During assembly of a pump for the first time, the stuffing box 70 and then the casing side liner 36 are positioned on the first locating surface 68 and in contact with one another, and fitting of the outer casing 24 by screwing to the mounting flange 58 can occur before, in between, or after those two steps. Thereafter the main liner 34 can be positioned by sliding along the second locating surface 66 towards the pedestal 10 until the extending annular portion 84 of the inner main liner (which is arranged beyond the free end of the annual locating collar 60) registers against the extending portion 82 of the casing side liner 36 and is aligned in place accordingly, so that the casing side liner 36 is located in close interfitting relation between the stuffing box 70 and the inner main liner 34. This same procedure can be followed in reverse during maintenance or retrofitting of new pump components onto the pedestal or base 10.
Referring to
As best seen in
The chamber 104 of the main body 52 is arranged to provide a retainer for a lubricant to lubricate the bearing assemblies 75, 77. A sump 106 is provided at the bottom of the chamber 104. As best seen in
The pump pedestal or base 10 may be adapted to retain different types of lubricants. That is, the chamber 104 and the sump 106 may accommodate the use of fluid lubricants, such as oil. Alternatively, more viscous lubricants such as grease may be used to lubricate the bearings and, to that end, lubricant retaining devices 114 may be positioned within the main body 52, adjacent the first annular space 73 and second annular space 79 to assure proper contact between a more viscous lubricant and the bearing assemblies 75, 77 housed within the respective annular spaces 73, 79 by forming a partial barrier between the bearing assemblies 75, 77 located in the respective annular spaces 73, 79 and the sump 106, as will now be described.
The first annular space 73 is demarcated from the chamber 104 by a first wall shoulder portion 118 that extends from the interior wall 116 toward the axial centreline of the housing base 10. The second annular space 79 is demarcated from the chamber 104 by a second wall shoulder 120 portion that also extends from the interior wall 116 toward the centreline of the housing base 10.
Each lubricant retaining device comprises an annular barrier wall in the form of a ring portion 126, as best shown in
Each lubricant retaining device 114 is also formed with a basal flange 134 which extends laterally from the ring portion 126 and which, as best illustrated in
In operation it is desirable that a relatively more highly viscous lubricant material such as grease is maintained in circulation in the area of the bearing assemblies 75, 77 and does not collect in the sump 106 of the base or pedestal 10. Lubricant that is in contact with the bearing assembly 75 housed within the first annular space 73 normally travels, by gravity, toward the first drain slot 140 and then travels into a first channel 136 that is in fluid communication with the sump 106. Likewise, lubricant that is in contact with the bearing assembly housed within the second annular space 79 normally travels, by gravity, towards the second drain slot 142 and then travels into a second channel 138 that is in fluid communication with the sump 106. When in position the lubricant retaining devices 114 are designed to retain lubricant in contact with the respective bearing assemblies 75, 77 in the first and second annular spaces 73, 79. That is, the ring portion 126 of the lubricant retaining devices 114 acts to retain grease in contact with the bearing assembly so that the grease is not displaced into the sump 106. The basal flange 134 restricts the flow of fluid entering into the first 136 or second 138 channels. Consequently, the bearings are properly lubricated by assuring sufficient contact time and retention between the bearing assembly and the grease (or grease-like substance).
Alternatively, if a flowable fluid, such as oil, is used as the lubricant, the lubricant retaining devices 114 are removed entirely to allow a flowable fluid, such as oil, to be used as the lubricant for lubrication of the bearing assemblies 75, 77. This enables oil or another flowable lubricant to be in free contact with the bearing assemblies 75, 77, which may be appropriate and desirable in certain applications.
The present arrangement of removable lubricant retainers 114 means that the same bearings can be lubricated either with grease or with oil. In order to achieve this, because the volume inside the frame is typically large and grease lubrication would be too easily lost from the bearings (which could lead to reduced bearing life), the snap-in lubricant retainers 114 (also known as grease retainers) are positioned to contain the grease in close proximity to the respective bearing assemblies 75, 77. Oil on the other hand, requires space to flow and to form a bath that will partially submerge a bearing in use. In such instances, the grease retainers 114 are not required at all and, if present, could cause the oil to bank up in the region of the bearing, thus causing excess churning and heating. Both of these conditions would reduce the bearing life.
Referring to the drawings, further details of the features of the pump inner main liner 34 and the details of the fixing pin 63 will now be described.
As previously described, to locate the inner main liner 34 in relation to the pedestal 10 as well as to the side casing part 24, four separate locating and fixing pins 63 are provided. In other embodiments it is envisaged that more or less than four fixing pins 63 can be used. As shown in the drawings the inner main liner 34 is positioned within the pump casing 22 and generally lines the central chamber of the pump 8 in which an impeller 40 is positioned for rotation, as is known in the art. The inner main liner 34 may be made of a number of different materials that impart wear-resistance. An especially commonly used material is an elastomer material.
As has already been described, the annular follower 88 is formed with a radially-extending lip 92 that has a face 94 that is oriented away from the mounting flange 58 of the pedestal 10. The face 94 of the lip 92 is angled from a plane that is perpendicular to the rotational axis of the pump 8. As shown in
The structural configuration of the fixing pin 63 is shown in
As shown in
When deployed in use, the fixing pin 63 is inserted through the aperture 62 of the mounting flange 58, and the flat surface section 166 is dimensioned to allow the head 98 to pass over the outer rim of the radially extending lip 92 on the side of the inner main liner 34 when the fixing pin 63 is in the correct orientation. The fixing pin 63 has a profiled locating free end 168 which is conical in shape which corresponds to the conical bottom of the blind end 100 of the aperture 92. When the fixing pin 63 is inserted, its terminal end 168 registers against and seats in the bottom of the blind end 100, and the fixing pin 63 can then be turned with a spanner or similar tool. The contact between the free end 168 of the fixing pin 63 and the blind end 100 assures proper positioning of the cammed surface 156 relative to the lip 92 of the inner main liner 34, and provides a locating device for the fixing pin 63.
As the fixing pin 63 is rotated, the helically-shape cammed surface 156 engages with the outer end of the groove 170 on the side flange of the inner main liner 34. Because the groove 170 has a sloping inside face 94, as the fixing pin 63 is rotated, the helically-shape cammed surface 156 commences to make contact on, and bear against, the inner main liner 34 causing movement relative to the side casing part 24 (to draw the inner main liner 34 closer toward the side casing part 24 in an axial displacement). The resulting thrust also forces the end of the fixing pin 63 into contact with the bottom of the blind end 100 in the aperture 92 of the pump casing part 24 and to rotate. Consequently the fixing pin 63 becomes locked in place as the shoulder 164 of the head 98 contacts the lip 92 to stop its rotation. The groove 170 and the head end 98 of the fixing pin 63 are dimensioned such that the fixing pin 63 locks, after only around 180 degrees of rotation. The slower pitch on the end portion 162 of the cammed surface 156 assists with locking the fixing pin 63, and also prevents loosening.
The fixing pin 63 is self-locking and does not loosen until released by counter-rotation of the fixing pin 63 by use of a tool. For the purpose of rotation of the fixing pin 63, the tool-receiving end 66 may be configured to receive a tool, and as illustrated, the tool-receiving end 66 may be formed as a hex-head to receive a spanner or wrench. The tool-receiving end 66 may be configured with any other suitable shape, dimension or device for receiving a tool that can rotate the fixing pin 63.
A plurality of openings 62 are formed about the mounting flange 58 of the pedestal 10, and a plurality of apertures 96 are formed in the pump side casing part 24 to accommodate a plurality of fixing pins 63 being position therethrough to secure the inner main liner 34 in place as described. While the fixing pin 63 is described and illustrated herein with respect to securing the inner main liner 34 on the drive side of the pump casing part 24, the fixing pin 63 and cooperating elements are also adapted to secure the opposite side of the inner main liner 34 to the pump casing part 26, as shown in
The inner main liner 34 shown in
Each of the side openings 31 and 32 of the main liner 34 are surrounded by like, continuous, circumferential, outwardly projecting flanges which each have a radially extending lip 92 and a groove 170 defined by the lip 92. The grooves 170 have an inclined side face 94 which can act as a follower 88 and the inclined side face is adapted to cooperate with a fixing pin 63 as illustrated in
As shown in
Referring to the drawings, further details of the features of the pump seal chamber housing will now be described. In one form of this,
A centralised bore 182 extends through the central section 174 of the stuffing box 70 and has an axially-extending inner surface 184 (also shown in
An annular space 188 is provided between the outer surface 190 of the shaft sleeve 186 and the inner surface 184 of the bore 182. The annular space 188 is adapted to receive packing material, shown here as packing rings 192 as just one exemplar packing material. A lantern ring 194 is also positioned in the annular space 188. At least one fluid channel 196 is formed in the stuffing box 70, having an external opening 198 positioned near the central section 174, as best illustrated in
A packing gland 202 is disposed at the outer end of the bore 182 and is adapted to contact the packing material 192 to compress the packing material within the annular space 188. The packing gland 202 is secured in place relative to the annular space 188 and packing material 192 by adjustable bolts 204 that engage the packing gland 202 and attach to saddle brackets 206 that are formed on the central section 174 of the stuffing box 70, as best seen in
The stuffing box 70 is configured with means for lifting and transporting it into position about the drive shaft 42 when the pump 8 is being assembled or disassembled. The stuffing box 70 is structured with a holding member 208 that encircles the centralised bore 182, as shown in
As shown in
It is further noted in
It is envisaged that the same type of holding member that encircles the centralised bore in a general ring formation can also be applied to other forms of seal housing, for example in an expeller ring, and can also be applied to facilitate the lifting and movement of the back liner 36.
Three clamping arms or jaws 232, 234, 236 are operatively mounted to and extend outwardly from the main body 226. The lowermost clamping jaws 234 and 236 are fixedly secured to respective angle beams 224 of the main body 226, as shown in
It can be seen from
It can further be seen from
Referring to the drawings, further features of the pump outer casing 22 will now be described. In one form of this,
As previously mentioned in relation to
The first side casing 24 is configured with an outer peripheral edge 254 having a radial face 256, and the second side casing 26 is also configured with an outer peripheral edge 258 having a radial face 260. When the first side casing 24 and second side casing 26 are joined, the respective peripheral edges 254, 258 are brought into proximity and the respective faces 256, 258 are brought into registration and abutment.
As shown in
The side casings 24, 26 are further structured with locating apparatus 266, as best seen in
The locating apparatus 266 may comprise any form, design, configuration or element that limits radial movement of the two side casings 24, 26 relative to each other. By way of example, and in a particularly suitable embodiment as shown, the locating apparatus 266 comprise a plurality of alignment members 268 that are positioned at several of the bosses 262, in proximity to the aperture 264 of that boss 262. Each boss 262 may be provided with an alignment member 268, or, as illustrated, less than all of the bosses may have an alignment member 268 associated therewith.
Each alignment member 268 is configured with a contact edge 270 that is oriented in general parallel alignment with the circumference 272 of the peripheral edge 254, 258 such that when the contact edge 270 of cooperating alignment members 268 are registered together at assembly of the pump casing, the two side casings 24, 26 cannot move in a radial plane relative to each other (that is, in a plane perpendicular to the central axis 35-35 of the pump casing 10, shown in
As best seen in
It can further be seen from
The provision of the co-operating projections and recesses allows for ready alignment of the two side casings 24, 26 and of the mounting apertures 264 which receive the bolts 46. This simplifies the assembly of the pump casing 22. Furthermore the proper alignment of the two casing parts 24, 26 can also ensures that the pump inlet is aligned to the pump shaft access. Alignment of the pump inlet with the shaft access ensures that the gap between the pump impeller 40 and front liner 38 is maintained substantially concentric and parallel thereby resulting in good performance and wear.
Other embodiments of interfitting or cooperating projections and recesses on the inner faces of the side casings which can function to facilitate the proper alignment of the two side casings 24, 26 are envisaged.
The invention is particularly useful when the pump housing includes elastomeric liners because the elastomeric material does not have sufficient strength to align the two side parts (unlike the situation when a single piece metal volute liner is used). The co-operating projections and recesses can also enhance the strength of the outer casing 22 by transferring forces, shock or vibration which may occur in use of the pump directly back to the mounting pedestal or base 10 to which the pump casing 22 is mounted.
Referring to the drawings, further features of the pump liner adjustment will now be described. In one form of this,
In the embodiment shown in
The adjustment assembly 278 further includes complementary threaded sections 292 and 294 on the ring-shaped member 284 and on the housing 280. The arrangement is such that rotation of the ring-shaped member 284 will cause axial displacement thereof as a result of relative rotation between the two threaded sections 292 and 294. The side liner 289 (which is attached to the mounting flange 288 on the ring-shaped member 284) is therefore caused to be displaced axially as well as rotatably relative to the main casing part 282.
The adjustment assembly 278 further includes a transmission mechanism comprising a gear wheel 296 on the ring-shaped member 284 of the drive device and a pinion 298 rotatably mounted on a pinion shaft. A bearing 300 within the housing 280 supports the pinion shaft. An actuator in the form of a manually operable knob 302 is mounted for rotation in the end cover 304 of the housing 280, and is arranged so that rotation thereof causes rotation of the pinion shaft and thereby rotation of the drive device via gear wheel 296. The knob 302 includes an aperture 304 for receiving a tool such as an allen key type tool or the like for assisting in the rotation of the pinion 298.
Further example embodiments will hereinafter be described and in each case the same reference numerals have been used to identify the same parts as described with reference to
This mechanism can also include an arrangement to lock the inner and outer parts of the drive device together, so that they cannot move relative to one another. As shown a lever 334 with a pin 336 configured such that when turned 180 degrees, it permits the force from a spring plate to push against a pin plate, urging pins into engagement such that the inner component is locked in relation to the outer component. Turning the worm gear with inner and outer components locked together causes both inner and outer components to turn, thus causing rotational displacement only.
A further example embodiment is illustrated in
To make the adjustment more controlled a plurality of raised bosses 346 and studs 348 are attached to the casing side part with nuts 350 and a collar 352. To effect adjustment in this case, the nuts 350 are loosened the same set amount, fluid pressure is applied via port 344, thereby pushing the casing side liner part 289 into the pump by the same set amount until the nuts 350 abut against the outer surface of the housing. The travel studs 348 would then be screwed outwards so that the collar 352 abuts against the inner surface of the housing and the nuts 348 are retightened. The fluid pressure would then be released. The above described arrangement provides for axial adjustment of the side liner part 289 only.
A further example embodiment is illustrated in
There would normally be a plurality of studs 354 and associated pressure chambers 362 spaced generally evenly around the casing side part. All chambers could be pressurised evenly at the one time by interconnecting the studs 354 by pressure tubing connected in place of the individual valves 360. The chambers and pressure would be designed such as to overcome the internal pressure loads inside the pump when running. The amount of travel would be set by pressurising all chamber 362 equally, loosening the nuts 364 evenly by a set amount, then applying further pressure to move the casing side part 289 inwards by the set amount. Other arrangements would also be possible to mechanically fix the casing side part in position and not rely on the fluid and pressure in the chambers during extended periods of running without adjustment.
A further example embodiment is illustrated in
The assembly further includes a second tube or sleeve 372 having a threaded inner base which is disposed over sleeve 370. A chain sprocket 376 is secured to an inner end of sleeve 372, the sprocket 376 being mounted within a chamber in the housing 282. A protective rubber boot 378 is disposed at the outer end of the assembly. Rotation of outer sleeve 372 will cause rotation of inner sleeve 370 which in turn causes axial displacement of the stud 368 and, as such, the casing side part 289. Desirably a plurality of assemblies are provided with the chain sprockets 376 being driven by a common drive chain ensuring constant displacement of each of the studs.
It is conceivable that any of these axial displacement mechanisms could also be applied sequentially with a mechanism for rotational displacement of the side liner 289 relative to the remainder of the pump casing and the outer housing. That is, the method for rotational and axial displacement of the side liner part could be achieved in a step-wise manner, using a procedure and apparatus which combines the two stages or modes of (a) axial displacement followed by (b) rotational displacement to achieve the desired result of closing the gap between the front of the side liner and the impeller. Of course, the reverse step-wise procedure can also be followed of (a) rotational displacement of the side liner, followed by (b) axial displacement, to achieve the same overall desired result: The embodiments of apparatus already disclosed in
Referring to
The pump casing 20 has a liner arrangement including a main liner (or volute) part 34 and a side liner (front liner) part 38. The side part 38 which in the form shown is a front pump inlet component includes a disc-shaped side wall section 380 and an inlet section or conduit 382. A seal 384 is provided in a groove 386 in a flange 388 of the main volute liner 34.
In this embodiment the adjustment assembly comprises a drive device which includes a ring-shaped coupling member 390 which is securable to the side part 38. The coupling member 390 is adapted to cooperate with support ring 392 which is mounted to the front outer casing housing 26. Support ring 392 has a thread (not shown) on its outer rim surface 394 which cooperates with a thread (not shown) on the inner surface 396 of coupling member 390. The arrangement is such that rotation of the member 390 will cause axial displacement thereof as a result of relative rotation between the two threaded sections. The casing side part 38 is therefore caused to be displaced axially as well as rotatably relative to front casing housing 26.
The adjustment assembly further includes a gear wheel 398 which is keyed to the ring shaped member 390 of the drive device via key 400 and key way 402 and a pinion 404 rotatably mounted on a pinion shaft. An actuator in the form of a manually operable knob 406 mounted for rotation and is arranged so that rotation thereof causes rotation of the pinion 404 and thereby rotation of the drive device via gear wheel 398.
Referring to
The side liner part 38 is shown in a fitted position in the particular embodiments illustrated in
For centrifugal pumps at any one fixed speed, the head normally decreases with flow. Shown on the one graph is the performance of a prior art pump (shown in dashed line) as well as one of the new pumps of the type described in the present disclosure (shown in solid line). The speed of the prior art and new pump is plotted so their head versus flow curves are nearly coincident.
Shown plotted on the same graph is the efficiency curve for a prior art pump and new pump. In each case, the efficiency curve increases to a maximum and then falls away in concave fashion. With both pumps producing approximately the same pressure energy at any flow, the efficiency of the new pump is higher than that of the prior art. The efficiency is a measure of output power (in terms of head and flow) divided by the input power and is always less than 100%. The new pump is more efficient and can produce the same output as the prior art pump but with less input power.
Cavitation in a pump occurs when the inlet pressure reduces to the boiling point of the fluid. The boiling fluid can dramatically impact a pumps performance at any flow. In the worst case, the performance can collapse. The new pump is able to keep operating with a lower inlet pressure than the same capacity prior art pump, which means that it can be applied to a wider range of applications, elevation above sea level and fluid temperatures before its performance becomes impacted by cavitation.
The pump assembly and its various component parts and arrangements as described with reference to the specific embodiments illustrated in the drawings offers many advantages over conventional pump assemblies. The pump assembly has been found to provide an overall improved efficiency which can lead to a reduction in power consumption and a reduction in the wear of some of the components compared with conventional pump assemblies. Furthermore its assembly provides for ease of maintenance, longer maintenance intervals.
Turning now to the various components and arrangements the pump housing support and the manner of attachment of the pump assembly and its various components thereto ensures that the parts are concentrically arranged relative to one another and ensures that the pump shaft and impeller are coaxial with the front liner side part. Conventional pump assemblies are prone to misalignment of these components.
Furthermore the pump bearing assembly and lubricant retainers associated therewith which are secured to or integral with the pump housing support provide a versatility enabling optional use of relatively high and low viscosity lubricants.
Conventional arrangements normally only offer one type of lubrication as the design of the bearing housing depend somewhat on the whether the lubricant is highly viscous such as grease or lower viscous such as oil. To change from one type of lubricant to another normally requires a total replacement of the bearing housing, shaft and seals. The new arrangement allows both types of lubricant to be used in the same bearing housing without any need to change the housing, shaft or seals. Only one component that is required to be changed, that being the lubricant retainer.
When bearings are lubricated with oil, there is normally a sump and the bearings dip in and are lubricated by the oil. The oil is also flung around the housing to generally assist the overall lubrication. A return channel or similar is needed for oil since the oil normally will be trapped between the bearing and the bearing housing end cover and end cover seal and needs a path to allow it to return to the sump. If the oil does not return to the sump, the pressure can build-up and then the oil can breech the seal.
Grease lubrication is different in that it must be keep in close proximity to the bearing to be effective. If flung off the bearing and into the centre void of the bearing housing it is lost, and the bearing could well fail due to lack of lubrication. Therefore it is important to provide side walls around the bearing to keep the grease in close proximity to the bearing. This is achieved in the new arrangement by the lubricant retainers on the inboard side of the bearing to prevent the grease escaping to the central chamber void. The grease is retained on the opposite side to the lubricant retainers by bearing housing end covers and bearing housing seals. The lubricant retainer as well as providing a barrier to the grease that can escape from the side of the bearing, also blocks the oil channel and prevents loss of grease in that region.
The retainers can be fitted when grease is used and then removed if oil lubricant is required. This is the only change to allow both types of lubricants to be used in the same bearing assembly.
Furthermore the new arrangement by which an inner pump liner is secured to the pump housing as described herein offers significant advantages over conventional techniques.
Slurry causes wear in slurry pumps and it is normal to line the pump housing with hard metal or elastomer liners that can be replaced after a period of service. Worn liners affect the pumps performance and wear life but replacing the liners at regular intervals returns the pump performance back to new condition. During assembly it is necessary to fix the pump liners to the outer casing both to provide location as well as fixing so that the parts are held securely. Conventional arrangements use studs or bolts that are screwed into the liners and the stud goes through the pump casing and a nut is used to fix it on the outside of the casing. Studs and bolts attached to the liner have the disadvantage that they reduce the wearing thickness of the liners. Inserts in liners for threaded holes can also cause casting difficulties. Furthermore studs and bolt threads can become blocked or broken in service and are difficult to maintain.
The new arrangement as described uses a coupling pin that does not reduce the wearing thickness of the liner and also avoids the issues with thread maintenance. The coupling pin is easier to use for fixing and locating the pump liners and is applicable for use on some or all liners in any suitable wearing material.
Furthermore the arrangement of the pump seal housing assembly and the lifting device for use therewith also contributes to the advantageous nature of the pump assembly.
Seal assemblies for slurry pumps need to be made from wear resistant and/or corrosion resistant materials. Seal assemblies also need to be strong enough to withstand the pump internal pressure and generally require a smooth inside shape and contour to prevent wear. Wear will reduce the seal assemblies pressure capability. Seal assemblies are normally installed and removed with a lifting tool and during lifting the seal assemblies must be securely attached to the lifting tool. Prior art was to provide an insert and/or a tapped hole to enable the seal assembly to the bolted to the lifting tool to secure it. However, the tapped hole is a weakness for pressure rating and also is a corrosion and wear point.
The new arrangement provides a holder that can be positively located and locked into the adjustable jaws of a lifting device. This holder can be smooth so does not compromise the wear or the pressure capability of the seal assembly.
Furthermore the new pump housing and manner of connection of the two parts thereof offer significant advantages over conventional arrangements.
Conventional arrangements typically have a smooth joint on the two mating vertical faces of the pump casing halves. The only alignment is therefore via casing bolts and with the clearance between the casing bolts and their respective holes, it is likely that the front casing half can be shifted relative to the back casing half Misalignment of the two casing halves causes the pump intake axis to move off centre relative to the back casing half The off-centre inlet will result in the front or inlet side liner being eccentric to the running centre of the rotating impeller. An eccentric liner will impact the gap between the impeller and the front liner causing increased recirculation and higher than normal internal losses.
Misalignment of the two casing halves will also affect the matching of the internal liner joints between two elastomer liners, such that there will be a step created between the two liners which otherwise would be smooth. Steps in the liner joints will cause extra turbulence and higher wear than if the joint line was smooth without steps. Misalignment of the two casing halves will also cause a step in the discharge flange which can affect the alignment of internal components inside the casing as well as any sealing components on the discharge side.
By locating the casing halves with precisely machined alignment sections, alleviates the issues due to the misalignment when using loose fitting casing bolts.
Finally the new adjustment devices as described offer significant advantages over conventional arrangements.
A pumps performance and wear life relates directly to the gap that exists between the rotating impeller and the front side liner. The larger the gap, the higher the recirculating flow from the high pressure region in the pump casing back to the pump inlet. This recirculating flow reduces the pump efficiency and also increases the wear rate on the pump impeller and the front side liner. With time, as the front gap becomes wider, the greater the fall off in performance and the higher the wear rate. Some conventional side liners can be adjusted axially, but if the wear is localised, this does not assist a lot. Localised wear pockets will just become larger.
The new arrangements allow for both axial and rotational movement of the pumps front liner. The axial movement minimises the gap width and the rotation spreads the wear more evenly on the front liner. A consequence is that the minimum gap geometry can be maintained over a longer time causing far less performance fall-off and wear. The axial movement and/or rotation movement can be arranged to best suit the pumps application as well as the materials of construction to minimise the local wear. Ideally, the side liner adjustment needs to be carried out whilst the pump is running to avoid loss of production.
The apparatus referred to herein can be made of any material suitable for being shaped, formed or fitted as described, such as an elastomeric material; or hard metals that are high in chromium content or metals that have been treated (for example, tempered) in such a way to include a hardened metal microstructure; or a hard-wearing ceramic material, which can provide suitable wear resistance characteristics when exposed to a flow of particulate materials. For example, the outer casing 22 can be formed from cast or ductile iron. A seal 28 which may be in the form of a rubber 0 ring is provided between the peripheral edge of side liners 36, 38 and the main liner 34. The main liner 34 and side liners 36, 38 can be made of high-chromium alloy material.
In the foregoing description of preferred embodiments, specific terminology has been resorted to for the sake of clarity. However, the invention is not intended to be limited to the specific terms so selected, and it is to be understood that each specific term includes all technical equivalents which operate in a similar manner to accomplish a similar technical purpose. Terms such as “front” and “rear”, “above” and “below” and the like are used as words of convenience to provide reference points and are not to be construed as limiting terms.
The reference in this specification to any prior publication (or information derived from it), or to any matter which is known, is not, and should not be taken as an acknowledgment or admission or any form of suggestion that that prior publication (or information derived from it) or known matter forms part of the common general knowledge in the field of endeavour to which this specification relates.
Finally, it is to be understood that various alterations, modifications and/or additional may be incorporated into the various constructions and arrangements of parts without departing from the spirit or ambit of the invention.
Number | Date | Country | Kind |
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2008903030 | Jun 2008 | AU | national |
2008904162 | Aug 2008 | AU | national |
2008904165 | Aug 2008 | AU | national |
2008904166 | Aug 2008 | AU | national |
2008904167 | Aug 2008 | AU | national |
2008904168 | Aug 2008 | AU | national |
Number | Date | Country | |
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Parent | 12737165 | Mar 2011 | US |
Child | 14632711 | US |