RU181043U1 - PUMP SHAFT SEAL - Google Patents

Abstract

The utility model relates to the construction of a mechanical seal designed to ensure tightness in the places where the shaft passes through the cover of a pump for general industrial use. The mechanical seal includes a rotating friction ring mounted on the shaft and a non-rotating friction ring spring-loaded to it, located in the housing, and at least 8 recesses are made on the outer cylindrical surface of each aforementioned ring, placed uniformly over the entire cylindrical surface with the depth of the recess not more than 30% of the thickness of the ring and the width of the recess of not more than 25% of the thickness of the ring. The proposed utility model allows to reduce the heating of the friction surfaces of the rotating rings and to increase the reliability of the mechanical seal. 4 s.p. f-ly.

Description

The utility model relates to the construction of a mechanical seal designed to ensure tightness in the places where the shaft passes through the cover of a pump for general industrial use.

Known mechanical seal type 231/231 (Industry standard OST 26-06-1493-87, Seals mechanical shafts of the pumps, Fig. 25), in which two pairs of friction. Each friction pair consists of two rings, fixed and rotating. When the shaft rotates, the surfaces of the above rings are in contact with each other. Upon contact, heat is generated and if this heat is not removed, the temperature in the seal chamber may increase. Sealing (coolant) enters the seal chamber, removes part of the heat from the heated surfaces of the friction rings of the friction pair and then goes to the heat exchanger for cooling.

The disadvantage of this seal design is the loss of tightness due to overheating of the stationary and rotating rings.

It is known that the mechanical seal of a rotating shaft is adopted as a prototype (ed. St. No. 1762064, op. 15.09.90, IPC F16J 15/34), which contains a non-rotating friction ring located in the housing, spring-loaded to a rotating friction ring mounted on the shaft. In this case, blind holes are made on the end surface of the rotating ring, and radial recesses are made on the end surface of the non-rotating ring, extending to the periphery of the ring and staggered

The known invention is aimed at uniform distribution of cooling oil with abrasive metal particles formed during friction of the rings, and thereby ensures uniform wear of the end surfaces of the friction rings, however, the known device does not prevent heating of the friction surfaces of the rings, leading to their wear and subsequent depressurization of the mechanical seal.

The objective of the utility model is to increase the reliability of the mechanical seal by reducing the heating of the friction rings by increasing the heat transfer area, as well as by bringing the sealing (cooling) liquid closer to the zone of maximum temperatures.

This problem is solved by mechanical seal of the rotating pump shaft, including a rotating friction ring mounted on the shaft, and a non-rotating friction ring spring-loaded to it, located in the housing, and on the surface of the non-rotating ring there are recesses in which, according to a utility model, the aforementioned recesses are made on the outer the cylindrical surface of a non-rotating friction ring, while the rotating ring is also provided with recesses made on the outer cylindrical surface.

The recesses are placed evenly over the entire outer cylindrical surface of the rotating and non-rotating rings.

The number of recesses is 8.

The depth of the recess is not more than 30% of the thickness of the ring.

The width of the recess is not more than 25% of the thickness of the ring, but not less than 2 mm

The implementation of the recesses on the outer cylindrical surfaces of the non-rotating and rotating friction rings allows you to increase the heat transfer area and provide additional heat removal from the above rings, which will reduce the heating of the friction surfaces of the rings and increase the reliability of the mechanical seal. In FIG. 1 shows the proposed seal, a General view, in FIG. 2 is a view aa of FIG. 1 of a rotating ring with recesses, in FIG. 3 is a view BB of FIG. 1, non-rotating rings with recesses.

The mechanical seal consists of a non-rotating friction ring 1 installed in the housing 2 and a rotating friction ring 3, spring-loaded to the non-rotating ring 1 by a spring 4. The friction rings 1 and 3 are placed on the shaft 5 and sealed by seals 6 and 7. On the outer cylindrical surface of the non-rotating ring of friction 1, recesses 8 are made, and on the outer cylindrical surface of the rotating friction ring 3, recesses 9 are made.

Sealing works as follows. The cooling fluid enters the rubbing end surfaces of the rings 1 and 3 and enters the recesses 8 and 9 of the outer cylindrical surfaces of the rings, while the heat exchange surface increases and heat is removed additionally, which reduces the heating of the rubbing end surfaces of the rings.

The calculation of the length of the recesses is shown below.

The length of the recess is 3L, where L is the distance between the recesses.

The circumference is 2PR.

You can calculate the length of the recess and the distance between the recesses with a radius of the ring R = 50 mm and the number of recesses equal to 8.

8⋅3L + 8L = 2PR

2PR = 2⋅3.14⋅50 = 314 mm

32L = 314

L = 9.81 mm.

Thus, due to the recesses made on the outer cylindrical surface of the rotating and non-rotating rings, the sealing (cooling) liquid more effectively cools the friction end surfaces of the rings, which improves the reliability and safety of the mechanical seal.

Claims (5)

1. The mechanical seal of the rotating pump shaft, including a rotating friction ring mounted on the shaft and a non-rotating friction ring spring-loaded to it, located in the housing, and grooves are made on the surface of the non-rotating ring, characterized in that the aforementioned grooves are made on the outer cylindrical surface of the non-rotating ring friction, while the rotating ring is also provided with recesses made on the outer cylindrical surface. 2. The mechanical seal according to claim 1, characterized in that the recesses are evenly distributed over the entire outer cylindrical surface of the rotating and non-rotating rings. 3. The mechanical seal according to claim 1, characterized in that the number of recesses on each ring is 8. 4. The mechanical seal according to claim 1, characterized in that the depth of the recess is not more than 30% of the thickness of the ring. 5. The mechanical seal according to claim 1, characterized in that the width of the recess is not more than 25% of the thickness of the ring, but not less than 2 mm

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