RU2141590C1 - End-face sealing unit - Google Patents

Abstract

FIELD: seals producing technology. SUBSTANCE: end-face sealing unit can be used in chemical industry and refrigeration engineering. End-face sealing unit has intermediate cover, hollow body accommodating sealing assembly which is made up of two stationary sealing rings made of antifriction material. Also provided are two rotating counter-rings which are in contact with stationary sealing rings over end-face. Two rotating counter-rings are given possibility of axial displacement due to action of springs located in rotation cage. Sealing assembly is provided with two auxiliary sealing rings having sealing inserts which are kept in contact with rotating counter-rings. End-face sealing unit is provided with leakage outflow system which is made in the form of circular bore in internal side of hollow body, and two holes made in hollow body which are connected with circular bore. Aforesaid embodiment of end-face sealing unit substantially enhances its operational efficiency and cuts power loss due to friction. EFFECT: higher efficiency. 3 cl, 1 dwg

Description

 The invention relates to mechanical engineering and can be used in the petrochemical industry and refrigeration, where piston, screw and turbocompressor units are used.

 Known mechanical seals operating on low-viscosity fluids and containing a housing, a shaft, a sealing and cooling system / Mayer E. Mechanical Seals: Trans. with him. - M.: Mechanical Engineering, 1978. - p. 216-223 /. The design of these mechanical seals is complex and not sufficiently reliable. It is not possible to expand the range of application of such structures to the field of refrigeration due to the specific thermophysical and thermodynamic properties of the working fluids used (ammonia, chladones, propane).

 The closest device of the same purpose to the claimed invention in terms of features is a mechanical seal used to seal the crankshaft of the compressor / Kondrashova N.G. Refrigeration and technological equipment of fishing vessels. -M.: Food Industry, 1979, p. 63 - 64 /. The structure of this mechanical seal includes an intermediate cover and a hollow body of the mechanical seal, covering the shaft of the unit and fixedly attached to the body of the unit. Inside the hollow body of the mechanical seal there is a sealing assembly containing two stationary sealing rings made of graphite and two rotating metal counter rings in contact with them at the end (mechanical sealing belt), which have the possibility of axial movement under the action of springs located in the separator rotating together with the unit shaft . To prevent leaks on the outer surface of the shaft, the mechanical seal in the sealing assembly contains two elastic sealing rings and a fixed seal at the output of the unit shaft from the mechanical seal housing. As a locking and cooling fluid, oil is used, which is supplied inward through the hole in the hollow body of the mechanical seal and is returned to the housing of the unit through the hole in the shaft of the unit on which the mechanical seal is installed. For monitoring and lowering leaks in the lower part of the mechanical seal housing there is a tube.

This design of the mechanical seal has a number of significant disadvantages:
the use of a lubricating oil with a high viscosity as a locking and cooling fluid leads to large losses of friction power;
sufficiently high frictional power losses cause an increase in the temperature of the lubricating oil and, as a result, a decrease in its lubricating ability, which leads to increased wear of the rubbing surfaces in the mechanical sealing belt and the need for cooling the oil before feeding it to the mechanical seal;
the lubricating oil in the crankcase of the unit, due to the specific purpose of the unit (supply of refrigerant to the evaporative system of the refrigeration unit), is saturated with refrigerant. When the unit is stationary, the refrigerant evaporates from the oil and the pressure in the unit crankcase rises and becomes greater than the pressure inside the hollow body of the mechanical seal. The refrigerant under pressure squeezes the counter rings from the o-rings and has the ability to go outside through the stationary seal to the room where the unit is installed, which leads to unjustified loss of refrigerant, and most importantly to a deterioration of the sanitary condition in the room.

 All of the above disadvantages lead to a decrease in the efficiency of the mechanical seal.

 When creating the invention, the task was to increase the efficiency of the mechanical seal and reduce friction power losses in it due to the transfer of its work to the use of the refrigerant circulating in the refrigeration unit as a working fluid.

 The task is achieved in that in the known mechanical seal covering the shaft of the unit, fixedly attached to the body of the unit and containing an intermediate cover, a hollow body with a hole for supplying the working fluid, a sealing assembly located therein, including two stationary sealing rings of antifriction material and in contact with them at the end, two rotating counter rings having the possibility of axial movement under the action of springs located in the rotating separator, as well as sistent with a pair of resilient seal rings and a fixed gland proposed to make improvements described below. A feature of the inventive mechanical seal is that it is equipped with two auxiliary sealing rings with sealing inserts in contact with two rotating counter-rings, and the conjugation has a conical shape in cross section. In addition, the inventive mechanical seal has an opening in the hollow body for draining the working fluid and a leakage system, made in the form of an annular groove on the inside of the hollow body and two holes in the hollow body connected with it, while the upper hole is designed to drain the gaseous component of the leaks , and the bottom hole is designed to drain the liquid component of the leaks.

 The implementation of these distinguishing features allows the use of refrigerant circulating in a refrigeration unit as a locking and cooling fluid, the viscosity of which is much lower than lubricating oil, which leads to a decrease in friction power losses and saving of lubricating oil.

 To prevent leaks, the auxiliary sealing rings on radial surfaces in the mates, respectively, with the intermediate cover and the hollow body contain elastic seals.

 Auxiliary sealing rings are made with the possibility of axial movement, and on the outer sides of the auxiliary sealing rings and, accordingly, on the inner sides of the intermediate cover and the hollow body, the springs are fixed by the ends.

 The implementation of auxiliary sealing rings with the possibility of moving in the axial direction prevents leakage during parking through a stationary seal outside to the room where the unit is installed, when the pressure in the crankcase of the unit is greater than inside the hollow body of the mechanical seal, and the refrigerant evaporating in the crankcase squeezes the rotating control rings from the sealing rings and enters the hollow body.

 A feature of the claimed mechanical seal is that the stationary sealing rings and inserts of the auxiliary sealing rings are made of cermet material. The use of cermet material can reduce wear and ensure reliable operation of the friction surfaces of the mechanical seal when refrigerant is used as a working fluid, the lubricity of which is significantly lower than the lubricating oil.

 The invention is illustrated in the drawing, which shows a General view of the mechanical seal. The composition of the mechanical seal includes an intermediate cover 1 and a hollow body 2 of the mechanical seal, covering the shaft of the unit 3 and fixedly attached to the body of the unit 4. Inside the hollow body 2 of the mechanical seal there is a sealing assembly containing two stationary sealing rings 5 made of cermet material and in contact with them at the end (mechanical sealing belt) two rotating counter rings 6, which have the possibility of axial movement under the action of springs 7 located in the separator 8, rotating a place with the shaft of the unit 3. To prevent leaks on the outer surface of the shaft, the mechanical seal in the sealing assembly contains two elastic sealing rings 9, and at the output of the shaft of the unit 3 from the hollow body 2 of the mechanical seal - a stationary seal 10, pressed by the seal 11. The mechanical seal contains also two auxiliary sealing rings 12 with sealing inserts 13 made of cermet material and in contact with rotating counter rings 6, and the mating has a conical shape in cross section. The hollow body 2 for supplying a working fluid contains a hole 14 and a hole 15 for draining the working fluid. The mechanical seal has a leakage removal system made in the form of an annular groove 16 on the inner side of the hollow body 2 and connected with it by two holes in the hollow body, while the upper hole 17 is for the removal of the gaseous component, and the lower hole 18 is for the removal of the liquid component. Auxiliary sealing rings 12 on radial surfaces in conjugations with the intermediate cover 1 and the hollow body 2 respectively comprise elastic seals 19. Auxiliary sealing rings 12 are rotationally limited by pins 20 and are able to move axially under the action of the working fluid and springs 21 fixed at one end on the outer sides of the auxiliary sealing rings 12, and other ends, respectively, on the inner sides of the intermediate cover 1 and the hollow body 2.

 The mechanical seal operates as follows.

 When starting the unit through the hole 14 in the hollow body 2, the working fluid (liquid refrigerant) is supplied inside the mechanical seal and there is a short-term dry friction process in the conjugation of the conical shape "the inner surface of the ceramic-metal sealing inserts 13 is the outer surface of the rotating counter rings 6". As the pressure of the working fluid in the inner space of the mechanical seal located between the inner ends of the auxiliary sealing rings 12 increases, hydraulic forces begin to act on the inner end surface of the auxiliary sealing rings 12, and when these forces exceed the pressure force of the springs 21 on the outer end surface of the auxiliary sealing rings rings 12, they will receive axial movement relative to the hollow body 2 and the rotating counter rings 6. As a result, in conjugation conical shape "the inner surface of the ceramic-metal sealing inserts 13 - the outer surface of the rotating counter rings 6" a gap is formed along which the working fluid enters the interface of the ends of the stationary sealing rings 5 and the rotating counter rings 6. A part of the incoming working fluid is drawn into the contact zone of the ends of the stationary sealing rings 5 and rotating counter rings 6, where the optimal clearance is set. The optimal clearance is maintained due to the equilibrium axial position of the rotating counter rings 6 under the action of the forces on the outer end surfaces of the working fluid and the hydrodynamic pressure in the gap, and the forces on the inner end surfaces from the springs 7 located in the separator 8. At this moment, the mechanical seal begins to function in the optimal steady state operation at low viscosity fluid. Due to the special thermophysical properties of the liquid refrigerant and the design features, leaks are possible that accumulate in the annular groove 16 inside the hollow body 2 located in the area of the stationary seal 10. From the annular groove 16, the steam component of the leaks through the upper hole 17 enters the compressor (not indicated in the drawing) and the liquid component of the leaks through the upper hole 18 enters the pump (not indicated in the drawing).

 When the unit stops, the flow of the working fluid through the hole 14 in the hollow body 2 is stopped, as well as its discharge through the hole 15. The pressure inside the hollow body 2 of the mechanical seal drops, and the auxiliary sealing rings 12 under the action of the pressure force of the springs 21 receive axial movement relative to the hollow body 2 and rotating counter rings 6. As a result, the gap in the conjugation of the conical shape "the inner surface of the ceramic-metal sealing inserts 13 - the outer surface of the rotating counter rings 6" overlaps interior of the mechanical seal is sealed, except for leakage flow to the static seal 10.

 The proposed mechanical seal, in comparison with the previously known ones, can significantly increase the efficiency of the mechanical seal and reduce friction power losses due to the use of low-viscosity refrigerant circulating in the refrigeration unit as a working fluid, while eliminating refrigerant leakage into the atmosphere, reducing the consumption of lubricating oil and cooling fluid during the operation of the unit and thermal stress of the mechanical seal parts.

Claims (4)

 1. An end seal comprising an intermediate cover, a hollow body with an opening for supplying a working fluid, a sealing assembly disposed therein, including two stationary sealing rings of antifriction material and two rotating counter rings in contact with them at the end, having the possibility of axial movement under the action springs located in a rotating separator, as well as including two elastic sealing rings and a stationary seal, characterized in that it is additionally equipped with two auxiliary sealing rings with sealing inserts in contact with rotating counter rings, the conjugation being conical in cross section, with a hole in the hollow body for draining the working fluid, a leakage drain system made in the form of an annular groove on the inside of the hollow body and two associated holes in the hollow housing.  2. The mechanical seal according to claim 1, characterized in that the auxiliary sealing rings on the radial surfaces respectively in conjugated with the intermediate cover and the hollow body contain elastic seals.  3. The mechanical seal according to claim 1 or 2, characterized in that the auxiliary sealing rings are axially movable, with springs fixed to the outer sides of the auxiliary sealing rings and accordingly to the inner sides of the intermediate cover and the hollow body.  4. The mechanical seal according to any one of claims 1 to 3, characterized in that the stationary sealing rings and the sealing inserts of the auxiliary sealing rings are made of cermet material.