DE2900543A1 - MECHANICAL SEAL - Google Patents

Description

Borg-Warner Corporation

200 South Michigan Ave. 4 "January 1979

Chicago, 111.60604, U.S. Attorney File M-4824

Mechanical seal

Summary

A mechanical seal for separating fluids is specified, which can be used together with a fixed housing and a rotating shaft. The mechanical seal has a stationary sealing ring and a circumferential sealing ring on “The stationary sealing ring is pretensioned by a control pressure medium in the direction of the rotating sealing ring «The pressure of the control pressure medium can be modified to alter the balance of forces in the seal.

In order to maintain a service life of more than 2 years for mechanical seals, soft are operated at pressures of more than 100 psi (corresponds to 7 at), mechanical seals with force compensation must be used be used. Such mechanical seals are known to those skilled in the art and are designed so that the unit load is expressed in psi at the contact surfaces of the sealing surfaces is smaller than the pressure from which the seal in the sealing chamber or

socket is surrounded. The smaller unit load is obtained by that one chooses an appropriate ratio between two areas, namely between the size of the contact area and the effective size of the pressurized area. The contact area is the area over which the two sealing surfaces of the Sealing rings are in contact with each other. The effective pressurized area is that which corresponds to that in the stuffing box prevailing pressure is applied, by which the sealing surfaces are held in contact with one another.

To with the known force-wise balanced mechanical seals To reduce the unit load on the contact surfaces of the sealing surfaces, the effectively pressurized surface must always be smaller than the contact area. The ratio between the area effectively pressurized and the contact area is given Expressed in percent, the balance of forces in the mechanical seal.

The present invention relates to a force-balanced mechanical seal with a circumferential sealing ring and a stationary one Sealing ring. These sealing rings have sealing surfaces that lie against one another. The stationary sealing ring is towards the circumferential sealing ring to be biased by a control pressure medium. In this way one obtains an equilibrium of forces in the seal, which is predetermined by a fraction, which of the pressure of the control pressure medium and the pressure of the pressure in the stuffing box Fluid is given. Since the pressure of the control pressure medium is adjustable, you can balance the forces Varying and modifying the seal as long as the device provided with the seal, e.g. a pump, is working.

909820/0691

- 7 - 2300543

You can also detect the leakage current through the sealing surfaces and the Adjust the pressure of the control pressure medium in such a way that a desired leak rate is obtained over the sealing surfaces and so the work the seal can pretend. Another advantage obtained with the invention is that the pressure of the control pressure medium when starting up the associated device can be reduced. In this way you get a lower torque when starting, which leads to a reduction in the wear of the sealing surfaces in contact with one another.

The mechanical seal according to the invention has a very simple structure; nevertheless it can be adapted to the most varied of conditions of use, and its work can either be done manually or automatically depending on what instruments are used for control.

The invention is explained in more detail below on the basis of exemplary embodiments with reference to the accompanying drawings. In this show:

Fig. 1 is an axial section through part of a conventional, force-balanced mechanical seal;

Fig. 2 is an axial section through an inventive Mechanical seal; and

3, 4 further developments of the mechanical seal according to FIG. 2 with respect to the storage of the stationary sealing ring.

Fig. 1 shows a conventional, force-balanced mechanical seal. The figure itself is labeled. The contact area is the ring surface, which between the radii R.,

and R "lies. The effective pressurized area is the ring area, which lies between the radii R "and R_. The balance of forces the mechanical seal depends on the quotient effectively pressurized Area divided by the size of the contact area. If you use the sizes used in the drawing, you get one the

R ₂ -R ₃

Forces equal to the seal (%) = χ 100.

R ₂ -R ₁

In order to increase the unit load at the contact surfaces of the sealing surfaces reduce, the effective-pressurized area must always be smaller than the contact area over which the circumferential Sealing ring is supported on the stationary sealing ring.

Fig. 2 shows a force-balanced mechanical seal according to the present invention. The mechanical seal is designated as a whole by 10 and is shown together with a housing 12, which can consist of a plurality of housing parts. The mechanical seal 10 serves to seal a rotating shaft 14 via which a drive M arranged at one end and a load provided at its other end, for example a pump P, are connected to one another. The housing 12, together with the mechanical seal 10, forms a stuffing box and, together with the shaft 14, delimits an interior 16. In the further description, the pressure prevailing in the interior 16 is referred _{to as P 1.}

909829/0691

The mechanical seal 1O has a circumferential sealing ring 18, which strikes against a shoulder 2O formed on the shaft 14. The circumferential sealing ring 18 is through a sleeve 21 and an O-ring seal 22 is sealed against the shaft 14. The O-ring seal 22 is received in a groove 24 of the shaft 14. The circulating one Sealing ring 18 consists of conventional materials and has a sealing surface 26. The circumferential sealing ring 18 is essentially with applied to the fluid located in the interior 16.

The mechanical seal IO also has a stationary sealing ring 28, which is received in a recess 30 of the housing 12. The sealing ring 28 has a sealing surface 32 _r which rests against the sealing surface 26 of the circumferential sealing ring 18. O-ring seals 34 and 36 are arranged in grooves 38 and 4O of the stationary sealing ring 28 and seal the sealing ring 28 within the recess 3O, but allow a certain axial movement of the sealing ring 28, as will be described in more detail below.

Through the sealing ring 28 is inside the recess 30 with Control pressure acted upon working space 42 limited, v / elcher via a channel 44 and an external line with a control pressure source is connected, for example to that shown schematically in Figs Pump 46. Due to the control pressure prevailing in the working chamber 42, the stationary sealing ring 28 is in the direction of the circumferential sealing ring 18 preloaded »A pressure control valve 48 is connected between the pump 46 and the working space 42. The pressure regulating valve 48 can be programmable, so that the pressure of the control pressure medium, designated in the drawing by P ", is reduced or can increase and so the respective operating conditions

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Can take into account.

This is effective for the mechanical seal described here pressurized surface the surface of the stationary sealing ring 28, which is acted upon by the control pressure medium. The contact area the seal is the same as the end face of the sealing ring 28, so it has the same size as the sealing surface 32. These two In the exemplary embodiment shown in the drawing, areas therefore have the same size. You can see them under the present Invention but also choose different sizes. The force balance of the seal is thus given by the following equation:

P ₂ χ effective pressurized area

Force compensation (%) = χ 100.

P ₁ χ size of the contact area

Is the area effectively pressurized and the contact area equal, the balance of forces in the seal depends on the ratio of the pressures P "and P-.

The force compensation of the mechanical seal described above can be adjusted to different modes of operation. E.g. you can use the Modify the force balance by applying the pressure while it is still in operation of the control pressure medium modified. The pressure of the control pressure medium can be programmed so that it starts when the is reduced by the shaft 14 driven pump. So that will achieves that the drive M only has to provide a lower starting torque when the pump is started. That way will too the wear of the sealing surfaces is reduced. You can also use the leak

909829/0691

Control current over the sealing surfaces in the desired manner by changing the pressure of the control pressure medium accordingly.

In the drawing, only a single mechanical seal is shown; it goes without saying, however, that multi-stage mechanical seals can also be provided within the scope of the present invention, each of which is controllable by a separate control pressure medium. The mechanical seals can be connected in parallel or in series be, and the control pressure means can either be the same, so be under the same pressure and / or the same Have fluid, or the control pressure means may be different from each other, as desired in each case.

If desired, a pin 50 (see Fig. 3) can be used, in order to fix the stationary sealing ring 28 on the housing 12 in a rotationally fixed manner. The pin 50 is in turn attached to the housing 12 and is located in FIG an elongated axial slot 52 of the sealing ring 28 receptacle, so that the latter is movable in the axial direction.

In a further modification of the mechanical seal described above can a spring 54 can be provided in order to obtain a minimum prestress of the sealing ring 28 in the direction of the sealing ring 18. The feather 54 is arranged in the recess 30 in the mechanical seal shown in FIG. 4.

Cure perfect sealing of the various parts of the mechanical seal Further seals or O-rings are provided against each other, for example the O-ring 56, which is located between the housing 12 and a sealing flange 31 is located.

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Claims (10)

Borg-Warner Corporation South Michigan Ave. Jan. 4, 1979 Chicago, 111.60604, U.S. Attorney File M-4824 Claims 1. / Mechanical seal for use on a rotating shaft and on a fixed housing, which different fluids keeps separated from each other, with a stationary sealing ring and a circumferential sealing ring, which have sealing surfaces that bear against one another, characterized by a recess (30) in which the stationary sealing ring (28) is supported; by a control pressure source (46), which with a through the Recess (30) and the stationary sealing ring (28) bounded working space (42) is in connection and serves the annular To keep the sealing surface (32) of the stationary sealing ring (28) in close contact with the sealing surface (26) of the circumferential sealing ring (18)? and by a connector (20-22) for the rotationally fixed connection of the circumferential sealing ring (18) to the shaft (14), whereby the circumferential sealing ring (18) is acted upon by a different fluid than the control pressure medium delivered by the control pressure source (46) = 909829/0691 2. Mechanical seal according to claim 1, characterized in that the equilibrium of forces of the seal is given by where mean: P "pressure of the control pressure medium, P ₁ pressure of the fluid different from the control fluid, A is the annular surface of the seal, which is acted upon by the control pressure medium, and B the common contact surface of the two sealing surfaces. 3. Mechanical seal according to claim 2, characterized in that A is equal to B. 4. Mechanical seal according to claim 2, characterized in that A and B are different from one another. 5. Mechanical seal according to claim 1, characterized by a Device (48) for setting the pressure of the control pressure medium, 6. Mechanical seal for separating two fluids with a stationary sealing ring, which is fixed to a housing, which contains one of the fluids, and with a circumferential sealing ring which is connected to a rotating shaft (14) is and rotates with this, which in turn drives a pump which is surrounded by the other fluid, where- 909829/0691 in which the sealing rings have abutting and running sealing surfaces, characterized by a recess (30), which receives the stationary sealing ring (28) and together with it delimits a pressure chamber (42); and through a control pressure source (46, 48) which communicates with the pressure chamber (42) and provides a control pressure medium through which the stationary sealing ring (28) is pretensioned in the direction of the circumferential sealing ring (18), so that the sealing surfaces (26,32) of the sealing rings (18,28) are held in contact with one another. 7. Mechanical seal according to claim 6, characterized by a Device (48) for adjusting the pressure of the control pressure medium 8. Mechanical seal according to claim 6, characterized in that the equilibrium of forces of the seal is equal ^AP 2
BP ₁ is, where mean: P _? Pressure of the control pressure medium, P .. pressure of the other fluid, A Size of the annular area of the seal, which is connected to the Control pressure medium is applied, and B the size of the contact area over which the sealing surfaces of the two sealing rings are in contact. 9. Common ring seal according to claim 8, characterized in that 909829/0691 the area A is equal to the area B, so that the equilibrium of forces in the seal is equal to the ratio V ^ fB. is. 10. Mechanical seal according to claim 8, characterized in that the areas A and B are different from each other. 909829/0691