RU43323U1 - FACE SEAL - Google Patents

Abstract

The invention relates to the field of seals and can be used to seal the rotating shafts of pumps pumping neutral liquids or oil. Expanding the arsenal of mechanical seals and achieving an increase in the degree of sealing of the sleeve on the shaft, increasing the life of the rings of friction pairs, and accordingly, increasing the period of the planned overhaul period to 50%, increasing the convenience of dismantling became possible due to the fact that in the known mechanical seal, including a sleeve installed on the pump shaft and the fifth one facing the pump, the seal housing, an axially movable cage, at least one rubber o-ring and a circular friction pair and a friction pair in the form of rings, made of wear-resistant material in contact with each other by flat end working surfaces, one of which is installed in the sleeve, the second in an axially movable cage, the rings are made of wear-resistant silicon carbide used for pumping oil in the form of self-bonded Sic-sL, when pumping oil products and neutral liquids - in the form of a hot-pressed Sic-GP, a chamfer is made in the fifth sleeve, which allows installing a rubber o-ring under the heel, and in the seal housing Navka to set the capture puller.

Description

The utility model relates to the field of seals and can be used to seal the rotating shafts of pumps pumping neutral liquids, oil products and oil.

A mechanical seal is known that contains a stationary sealing ring in the form of a disk mounted in the housing and a rotating sealing ring in the form of a disk located on the shaft, which are pressed against each other by a spring and contacting the conical contact surfaces and secondary seals. In the known device, the reliability of the seal is achieved by shifting the contact zone as the radial wear of the sealing ring. To achieve the specified technical result, the rotating o-ring is fixedly mounted on the shaft, and the stationary o-ring in the form of a disk is spring-tightened to the rotating o-ring. The inner surface of the disk is conical, and the ring itself is made of less wear-resistant material than a rotating o-ring. The plane of the end surface of the stationary sealing ring facing the rotating sealing ring passes through the conical contact surface [As. 1703770 BI No. 3 dated 01/23/92]. The disadvantages of the known device include increased heating of the contacting sealing rings due to the difference in the linear speeds of the rubbing surfaces along their conical length.

Also known is a double mechanical seal according to the application No. 2000121239, comprising a housing, a rotating sealing ring mounted on a shaft, two fixed sealing rings in contact with both sides of the rotating sealing ring and forming a sealing plane with the housing, while the fixed sealing rings are fixed in movable sleeves, in the grooves of which the ends of the pins are located, fixing them from turns and fixed in the housing. IN

of the sealed cavity there is a sleeve with annular bores on the periphery and in the inner diameter, in which damping elements are installed in the form of rings of materials with different pliability, while the fixing pins of the stationary sealing rings are made stepwise with the sealed part located in the grooves of the bushings. Damping rings are made, for example, of rubber and fluoroplast-4. The disadvantages of the device include the fact that this design does not guarantee reliable contact between the sealing surfaces of the friction rings and thus does not ensure the tightness of the internal cavity of the pump, since there are no additional efforts to press the stationary sealing rings to the movable (except for the hydrostatic pressure of the liquid being sealed).

The closest in technical essence analogue selected as a prototype is the used mechanical seal (type TM), which is a sealing device with flat end surfaces in contact with each other at the ends of the rotating ring and the stationary ring. In this case, the movable ring of the friction pair is mounted on the sleeve, and the torque from the rotating sleeve to this ring is transmitted by two pins.

The second ring of the friction pair is mounted in an axially movable cage. An axially movable cage is mounted on the seal housing and assembled with the seal housing. The device also includes a mounting bracket secured by a screw. All places of possible fluid leak are sealed with O-rings [TU26-06-968-75 from 12.25.75].

The contact between the flat end working surfaces of the rings of the friction pair, which ensures the tightness of the internal cavity of the pump, is created due to the force of the springs and the hydrostatic pressure of the liquid being sealed. The planned overhaul period is 8000 hours

for mechanical compaction in oil, oil products and 6000 hours in media: condensate, fresh and waste water.

The disadvantage of the prototype is the significant wear of the rings of the friction pair associated with the properties of graphite HACK 55/40 used in the prototype for the manufacture of these rings.

The task of creating the claimed utility model is to expand the arsenal of mechanical seals.

Technical results that can be obtained by implementing the inventive utility model are:

- creating a mechanical seal, ensuring the tightness of the internal cavity of the pump;

- improving the reliability of the sealing sleeve on the shaft;

- increase the life of the rings of friction pairs;

- increase in the planned overhaul period;

- increase the convenience of dismantling.

The solution of this problem and the achievement of the above technical results became possible due to the fact that in the well-known mechanical seal, including a sleeve mounted on the pump shaft and facing the pump fifth, the seal housing, an axially movable cage, at least one rubber ring O-ring and a friction pair made up of two rings made of wear-resistant material in contact with each other by flat end working surfaces, one of which is installed in the sleeve, Fifth - in an axially movable cage, the rings of the friction pair are made of wear-resistant silicon carbide, in the fifth heel of the sleeve is made at an angle of 45 (chamfer with the possibility of tightly installing a sealing O-ring under the fifth rubber ring, and in the seal housing from the end side remote from the pump, an annular groove is made with the possibility of installing a gripper for the puller.

In a particular use case, when pumping oil, wear-resistant silicon carbide is used in the form of self-bonded Sic-si, and when pumping neutral liquids, it is used in the form of hot-pressed Sic-GP.

The claimed utility model is illustrated by the following figures:

Figure 1. General view of the mechanical seal in section along AA;

Figure 2. An annular groove for installing a gripper puller. The claimed mechanical seal includes a sleeve 1 mounted on the shaft 2 of the pump; the heel 3 of this sleeve 1 is facing the pump and a chamfer 4 is made in it at an angle of 45 °, which makes it possible to transfer and tightly install a rubber sealing ring 5 of round cross-section under the heel 3, which increases the efficiency of its sealing on the shaft 2. The mechanical seal also contains an axially movable ferrule 6 and the housing 7 of the seal. The seal body 7 with the springs 8 installed therein is assembled with an axially movable cage 6, mounted on the sleeve 1 and fixed with a mounting bracket 9.

A friction pair, which ensures tightness of the seal, is made by flat end faces contacting each other at the ends of the ring 10 rotating together with the shaft 2 and the stationary ring 11. To ensure rotation, the ring 10 is installed in the sleeve 1, and the torque from the rotating sleeve is transmitted to it by two pins 12. The fixed ring 11 is mounted in an axially movable yoke 6. From rotation, the axially movable yoke 6 is fixed in the seal housing 7 with two screws 13.

Reliable contact between the flat end working surfaces of the ring 10 and the ring 11 of the friction pair is ensured by the force of the springs 8 and the hydrostatic pressure of the fluid being sealed, and the dynamic forces arising in the friction pair prevent leakage of the medium being sealed.

The ring 10 and the ring 11 of the friction pair are made of silicon carbide. Moreover, in the particular case of execution, when pumping oil, silicon carbide was used in the form of a self-connected Sic-si, and when pumping oil products and neutral liquids, silicon carbide was used in the form

hot-pressed Sic-GP, which allows to increase the service life and the overhaul period of the mechanical seal.

For the convenience of dismantling the mechanical seal from the pump shaft 2, an annular groove 14 for the puller grips is made on the seal body 7 (Fig. 2).

The claimed mechanical seal operates as follows. The surface of the shaft 2 is lubricated at the installation site of the mechanical seal and the seating surface of the housing with paste VNIINP-232 GOST 14068-79 or graphite grease. Install a mechanical seal on the shaft 2 of the pump with a rubber o-ring 5 of circular cross-section on the heel 3 of the sleeve 1 installed in the chamfer 4 and fix it with a nut (not shown in Fig.), Remove the mounting bracket 9. Fill the pump with pumped liquid, ensuring air is discharged from the chamber seals (not shown in FIG.). Check the tightness of the seals. Start the pump. The sleeve 1 begins to rotate together with the pump shaft 2 and the ring 10 installed in the sleeve 1 begins to rotate. The torque from the rotating sleeve 1 to the ring 10 is transmitted through the pins 12. A friction pair consists of two rings, in which the flat end face of the ring 10 rubs against the flat end face of the ring 11 that is in contact with it, mounted in an axially movable yoke 6, kept from turning by two screws 13. The tightness of the internal cavity of the pump is created due to reliable contact between the flat ends high surfaces of the ring 10 and the ring 11, which provide the force of the springs 8 installed in the housing 7 of the seal and the hydrostatic pressure of the liquid being sealed.

At the end of work, the pump is stopped. Dismantling of the mechanical seal is carried out with the mounting bracket 9 installed by grabbing the mechanical seal at the location of the groove 14 with the puller (not shown in Fig.).

The practical applicability and the ability to achieve the claimed technical results is shown in the following examples of specific performance.

Example 1

The inventive mechanical seal includes a sleeve with a fifth, dressed on a pump shaft, an axially movable cage, a seal housing and a friction pair. The friction pair, which provides tightness, is composed of two rings. One ring is installed in the sleeve, the torque of which is transmitted to the ring through the pins. The second ring is mounted in an axially movable cage, held against rotation by two screws. The contact between the flat end faces of the rings of the friction pair ensures the tightness of the internal cavity of the pump. The friction pair rings are made of silicon carbide in the form of a self-bonded Sic-si. Under the heel of the sleeve, a rubber o-ring is installed in a chamfer made at an angle of 45 °, eliminating the possibility of fluid leakage. An annular groove is made in the seal housing for mounting the pick-up of the puller during dismantling.

Sealable medium oil Maximum pressure drop, MPa (kg / cm ² ), no more 5.5 (55) Temperature, K (° C) from 258 (-15) to 353 (80) Rotational speed C ^-1 (rpm) 50 (3000) Leakage, m ³ / s (l / h) 6.94 · 10 ^-8 (0.25) The planned overhaul period, h 12000

Example 2

According to example 1.

The friction pair rings are made of silicon carbide in the form of a hot-pressed Sic-GP.

Sealable medium fresh water Maximum pressure drop, KGS / cm), no more 5.5 (55) Temperature, K (° C) from 258 (-15) to 353 (80) Rotational speed C ^-1 (rpm) 50 (3000)

Leakage, m ³ / s (l / h) 6.94 · 10 ^-8 (0.25) The planned overhaul period, h 15,000

Example 3 (prototype)

Friction pair rings are made of graphite GAKK-55/40

Sealable medium oil Maximum pressure drop, KGS / cm), no more 5.5 (55) Temperature, K ° (C) from 258 (-15) to 353 (80) Rotational speed C ^-1 (rpm) 50 (3000) Leakage, m ³ / s (l / h) 9.94 · 10 ^-8 (0.25) Planned overhaul period, hour 8000

As can be seen from the above examples of specific performance, a workable mechanical seal has been created that provides tightness of the internal cavity of the pump. Due to the design features, the reliability of the sleeve seal on the shaft is increased, the life of the rings of friction pairs is increased and, accordingly, the period of the planned overhaul period (for example, when pumping oil is increased by 50%) is increased compared to the mechanical seal according to the prototype, as well as due to the convenience of the gripper installation puller increased ease of dismantling.

Thus, the combination of the claimed features allows you to create a workable, competitive mechanical seal, convenient in operation and has a long service life and overhaul period.

Achieved high consumer properties allow you to expand the arsenal of mechanical seals with a new competitive product.

Claims (3)

1. Mechanical seal, including a sleeve mounted on the pump shaft and facing the fifth pump, seal housing, axially movable cage, at least one rubber O-ring and a friction pair in the form of rings made of wear-resistant material in contact with each other flat end working surfaces, one of which is installed in the sleeve, the second in the axially movable cage, characterized in that the friction pair rings are made of wear-resistant silicon carbide, in the fifth of the sleeve is made Chamfer angle 45 ° with the possibility of establishing dense under fifth rubber sealing ring of circular cross section, and a sealing body at the end face remote from the annular groove of the pump is to be mounted gripping puller. 2. The mechanical seal according to claim 1, characterized in that when pumping oil, wear-resistant silicon carbide is used in the form of self-bonded Sic-si. 3. The mechanical seal according to claim 1, characterized in that when pumping oil products and neutral liquids, wear-resistant silicon carbide is used in the form of a hot-pressed Sic-GP.