DE2435325A1 - PUMP WITH SHAFT SEAL - Google Patents

Description

JACUZZI RESEARCH INC., A California company located at 1440 San Pablo Avenue, Berkeley , California, V.St.A.

Pump with shaft seal

Most pumps, especially centrifugal pumps with rotating impellers, are located between the housing and the drive shaft that connects the impeller to the pump motor, a seal is provided. With centrifugal pumps with impeller surrounds the seal in an annular and coaxial manner the drive shaft. Usually and especially with liquid pumps this ring seal is designed to rotate with the impeller while against a stationary one Seat section is pressed against the housing and at the same time against the drive shaft.

However, it has been found that when accelerating of the impeller during start-up by the pump motor and to a certain extent also when the impeller is braked while the pump is stopped, the known seals cause considerable wear on the seal itself as well as on the impeller. The mass of the ring seal

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would like to let this remain in the respective state of motion when the impeller accelerates strongly until the friction between the seal and the Laufred finally ensures that the seal is at the same speed how the impeller turns.

In a similar way, the drive shaft rotates in the ring seal when the impeller accelerates rapidly and provides slippage and friction between the seal and the drive shaft until the seal has the same angular velocity as assumed by the impeller and the drive shaft. These two causes of occurrence noticeable friction are responsible for significant wear and tear over periods of time that are perceived as being too short, so that the replacement of the seal or even the impeller becomes inevitable.

The invention is therefore, inter alia, to create a new and improved feed pump viewed as a whole; then a new and improved ring seal assembly for a pump is to be provided which is subject to wear and tear between the abutting parts of the sealing arrangement and the pump is significantly reduced; and Finally, the ring seal should be durable, easy to manufacture and easy to install.

Further advantages and features of the invention will emerge from the following description of a preferred embodiment thereof, in which on the attached Drawings reference is made. Show in detail:

Fig. 1 is a side view of a partially cut, partially broken away pump that embodies the features of the invention;

FIG. 2 shows an enlarged side view of a cross section through the ring seal according to FIG. 1; FIG. and

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FIG. 3 is a plan view of part of the end view along the line 3-3 from FIG.

The invention is embodied in a pump designated as a whole by 21 for pumping flowable media, especially liquids (water or the like). The pump 21 comprises a housing 23 with an impeller 25 which is in the Housing is rotatably mounted. Furthermore, a drive shaft 29 connects the impeller 25 to a motor 27, wherein In the present case, the drive shaft forms an integral component with the impeller 25 and extends outwards extends out of the housing 23. The drive shaft has a cylindrical bore 31 in which the output shaft 33 r'us is added to the pump motor. A ring seal 35, best seen in Figure 2, is near and preferably on or around the drive shaft 29 attached to this in coaxial alignment. This ring seal comprises a flexible tension spring, preferably in the form of a spiral spring 41 and an annular spring seat 43 which is pressed onto the impeller 25 will. At the opposite end, an annular cup 45 is attached to the interior of the coil spring and is used to accommodate sealing elements.

Two sealing elements are expediently provided, namely an O-ring 47. which is placed sealingly around the drive shaft is, and a ring seal 49, which is provided with a nose 51. An eye 53 is attached to the pump housing, which carries a ring bearing 55. Eye 53 and ring bearing 55 are stationary and stationary. The nose 51 of the ■ Sealing element 49 rotates together with the drive shaft and impeller.

D-is penetration of liquid from the housing to the Drive shaft is prevented by the ring seal by

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the rabbit 51 on the ring bearing 55th and the O-ring 47 on the Drive shaft 29 make contact. The ring bearing is expediently made 55 made of a ceramic material with a low coefficient of friction and high abrasion resistance, while the nose 51 is made of carbon, graphite or similar material exist know

In operation, for example, water is introduced through the inlet opening 61 sucked into the housing and through the impeller eye 63. The radially outwardly curved ones extending Impeller blades 65 then accelerate the water very strongly towards the peripheral outlet channel 67 of the housing, from which the liquid flows tangentially through the opening 69 is delivered.

While the main amount of the water through the outlet channel ~ oil 67 and the discharge opening 69 flows, a certain amount of water is unchanged through the gap 71 penetrate between the impeller and the housing (Fig.l) in the area 63 of the ring seal. The ring seal therefore prevents further penetration of the water along the drive shaft from the opening 75 between the drive shaft and housing.

Ken further noted that the spring force exerted by the coil spring 4Ί holds the impeller in the seat 77, which is formed on the opposite side of the pump housing. Thus, while a sealing action is effected on one side of the impeller, the coil spring urges the impeller into the impeller seat 77 so that it can properly rotate in the pump housing.

Centrifugal pumps of the type described so far usually work together with a motor that drives the impeller can drive relatively high angular velocity, so that As a result, the pump motor accelerates the impeller very strongly to full delivery capacity of the pump.

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In known pumps, however, the strong impeller acceleration causes a slip between the ring seal 35, or that the impeller 35 with respect to the ring seal rotates until the friction between the ring spring set 43 and the impeller 25, as well as the friction between the O-ring 47 and the drive shaft 29 ensures that the mass of the ring seal has the same angular velocity as the impeller and the drive shaft assume. Such slip happens despite the fact that the Spiral spring presses the spring seat against the impeller and the frictional force by increasing the normal force between the spring seat and impeller increased.

The spring seat, which is preferably made of metal, causes repeated switching on and off, that is to say in general Use of the pump considerable wear and tear on the end wall 83 of the impeller near the drive shaft, wherein the impeller is advantageously made of a high-strength glass fiber reinforced plastic. In a similar way, the drive shaft 29 works on the O-ring 47 and creates signs of wear there. the The result is that either the ring seal has to be replaced because the O-ring is worn or that the impeller must be replaced because the end wall of the same is abraded or grooved.

Now, to prevent excessive wear and tear and the need for periodic parts replacement, the Pump according to the invention and the ring seal provided with a device by virtue of the seal on one Rotary part can be anchored in the vicinity of the seal in order to positively relate in this way any rotation of the impeller exclude the seal when the impeller accelerates. The rotating part can either be the impeller or the drive shaft or even the motor drive shaft when it extends into the pump near the seal.

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While the general problem of slip avoidance can be released by positively anchoring the ring seal on the impeller, it turns out to be in individual cases as quite useful to anchor one end 85 of the spring 41 on the impeller to have the added benefit of a gain shock-absorbing function.

In detail, the near end 85 of the spring can pass through an opening 89 in the spring seat 43 and anchored in a recess or opening 87 in the impeller. Such a positive or arrested Attaching the ring seal to the impeller prevents slippage, i.e. slippage or rotation between the Spiral spring and especially the spring seat 43 and the impeller as well as between the O-ring 47 and the drive shaft 29, which will be explained in detail below.

When the relative slippage or rotation between the impeller and the ring seal is positive locking Intervention between the two was eliminated, the spring seat 43 would be superfluous, at least so far

its function to reduce the wear between the seal and the end wall of the impeller is in question. Of the However, the spring seat should also hold and locate the spring coaxial with the drive shaft. Also prevents the Spring seat local erosion in case the acceleration causes the spring to twist or untwist, if only to a small extent, during its shock-absorbing function. Hence it turns out to be expedient to retain the spring seat and only to form the opening 89 in this, which then on the Opening 87 in the end wall 83 of the impeller is aligned.

The positive locking of the ring seal can also be achieved by making a depression or opening

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in the drive shaft 29 for the impeller essentially perpendicular to the longitudinal axis of the impeller axis and impeller is provided. The end 85 of the spiral spring could then be designed so that it is inserted into the impeller axle can be. Since the impeller axle preferably forms an integral component with the impeller, or at least is firmly connected to the impeller for drive purposes, a connection of the seal 35 would be with the impeller shaft similarly prevent slippage and frictional abrasion or wear.

It should also be noted that a further advantage results from securing the seal to the impeller by means of a countersink 87 results in parallel to the axis of rotation of the impeller. This orientation of the end 85 of the coil spring and the opening in the impeller end wall 83 allows easy installation of the seal on the drive shaft and easy Locking on the impeller without the need for special tools or difficult manipulation of the components. would have to be made.

To depress the wear on the O-ring seal 47, is the end of the spiral spring 41 facing away from the device 85 for positively fixing the seal on the impeller designed so that an interference fit with the ring cup 45 results. In addition, the sealing element 49 is positively locked against rotation with the cup 45, by extending a lug 91 into an opening 93 in the cup, whereby the entire assembly rotates as a unit.

It can be seen specifically from FIG. 2 that the opening 93 in the annular cup 45 extends axially over a greater distance extends than the extension 91 of the sealing element 49 is long in the axial direction. This allows the sealing element be pushed backwards against the O-ring 47, the

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in turn presses against the beveled portion of the cup and at the same time inwardly on the Drive shaft 29 pushes on.

It would be possible, although that doesn't prove to be necessary has proven to provide an additional opening in the ring cup 45 into which the second end 95 of the Coil spring could be used. It would also be possible to fix the G-ring 47 on the ring cup 45; However, it has been found that the slip by the positive definition of the other end of the coil spring is effectively eliminated at the impeller.

From the above description it can be seen that the specific embodiment of the drive shaft or the like drive element is not critical from the point of view of the invention. As can be seen from the drawings, and particularly Fig.l, comprises the pump motor on a stepped output shaft 33 which mates with a threaded end in the stepped cylinder bore 31, and _i can be screwed in a threaded end in the drive shaft. The pump housing is bolted onto an end plate 99, which in turn is attached to the pump motor with fastening elements 101 or the like. is fixed.

The arrangement is made so that the drive shaft can be attached to the output shaft 33 and from this is driven. The pump housing is expediently designed in two halves, which are secured by fastening elements 103 can be bolted together with sealing washers 105, so that the sealing washers 105 between the housing halves effectively seal the pump channel 67.

Overall, a pump for a fluid medium was created

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described with a ring seal aimed at reducing wear between the pump impeller and the seal is designed while at the same time an effective seal between the pump housing and the drive shaft of the impeller is maintained. The ring seal has a device for its preferably elastic anchoring on a rotating component in order to prevent any rotation of the impeller with respect to the seal upon impeller acceleration to exclude. The ring seal can contain a spiral spring that presses the seal, while the elastic anchoring of the seal for shock absorption is preferably realized in such a way that a recess or opening in the impeller or in the drive device and an end or an extension the spiral spring are provided, which latter can be locked in the recess or opening.

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Claims (8)

Expectations / I l.J ring seal for use in a pump with a Housing in which an impeller is rotatably mounted and connected to an external drive source Drive shaft is drivable, the seal in the vicinity of the drive shaft and between the impeller and the housing is arranged so that a seal against penetrating, flowable medium conveyed by the pump between Housing and drive shaft is prevented, characterized in that the seal has an anchoring device (85), with which it can be fixed to a rotatable component in the vicinity of the seal in such a way that a Relative rotation between impeller (25) and seal (35) when the impeller accelerates is excluded and wear between seal (35) and impeller (25) is essentially prevented. 2. Seal according to claim 1, characterized in that they resiliently on a rotatable component (25) of the pump for shock absorption during the acceleration of the impeller is anchored. 3. Seal according to claim 1 or 2, characterized in that it is on the impeller and / or on the drive shaft (29) is anchored elastically. 4. Seal according to one of the preceding claims, characterized in that it has one on the drive shaft (29) has axially aligned spiral spring (95) with one end (85) in a recess in the impeller and / or the Drive shaft can be locked. 509823/05 ¹ K 5. Seal according to claim 4, characterized in that the recess as an opening (87) in the impeller is designed essentially parallel to the axis of rotation of the impeller. 6. Seal according to one of the preceding claims, characterized characterized in that it has a spiral spring and an annular cup (45) with sealing elements (47,49) has, which grip around the drive shaft in a sealing manner. 7. Seal according to one of the preceding claims, characterized marked that. a spiral spring (95) is provided, which is in a spring seat (43) on the impeller (25) supports; and that the spring seat (43) has an opening through which the end (85) of the spiral spring closes Locking purposes can be carried out on the impeller. 8. Seal according to one of claims 6 or 7, characterized in that at least one of the drive shaft (29) surrounding sealing elements (49) anchored in an opening (93) of a ring cup (45) of the seal is and rotates with the drive shaft and on a stationary Bearing (55) rubs under the pressure of the spiral spring. 509823 / 057-4