DE2205195C2 - Sliding ring seal - made of PTFE with garter springs in elasticity slots near sealing-lips - Google Patents

Abstract

Sec. seal ring of PTFE for use on rotating shafts with sliding ring seals can have a circular, or a rectangular cross-section with two or four sealing lips. The sealing lips are separated by slots with spreader elements near their mouth so that the sealing pressure of the spreaders is assisted by the elasticity of the slots. This creates simple seal rings with single or double action which have a high functional reliability even at high temps.S Specifically a double-acting seal ring (6) has two pairs of sealing lips (6a,6b) and two additional lips (6c) to produce a six-point line seal. Two elasticity slots (6f) on two sides have near the mouth the grooves (6e) in which two garter springs (6d) are enclosed as spreader elements.

Description

The invention relates to secondary sealing rings for a mechanical seal, which is used to seal media and w) substances on rotating shafts, the secondary seals made of durable material having slots and operating mechanisms in a selected arrangement, which are intended to ensure that the sealing unit to be readjusted for wear on the pair of sliding rings Seals functionally reliable even with axial play of the shaft.

There are a variety of mechanical seals known in which the secondary seals from the There are various elastic materials that have different cross-sectional profiles. One of these constructions shows that. the elastic intermediate rings are square in the unloaded state Shaped with rounded corners and indented sides, with symmetrical lobes develop. The lobes arranged in the direction of the conical king surface grip into the concave ones Grooves of the retaining ring and the sliding ring in such a way that they can with axial displacement of the machine parts towards each other around their axis and thereby deformed in a diamond shape. Another version has an elastic intermediate ring, which shows the shape of a narrow parallelogram in cross section and in rectangular grooves of the adjacent ring engages as well as the narrow surfaces of the parallelogram on their Engage the entire surface in cylindrical mating surfaces. Mechanical seals are also known, where in axial leakage paths sucking seals in Form of round rings made of elastomers and Teflon-coated Rubber rings and Teflon wedge rings are installed. These mechanical seals have the Disadvantages that these have inadequate heat dissipation at the sliding ring pairings and are prone to failure are made of elastomers by inserted diaphragm elements. The susceptibility to failure is based on the fact that all rubber qualities in the form of round rings and others Constructively designed designs are subject to swelling and deformation, which is subject to wear and tear of the slip rings that are mechanically and hydraulically readjusted parts of the seal are often blocked will. In uncontrolled operating cases, these secondary seals are chemically attacked and cause Failures.

Teflon-coated round rings have the disadvantage that after an unavoidable deformation of the inserted O-ring also Gumi..ioualitäten on the Overlap vapors and liquids penetrate, attack them, causing leakage and likewise Failures occur. Other disadvantages of numerous seals are that they are exposed to vibrations the sealing gap tears open.

A PTFE ring is known which has an annular ring in the middle Has a recess with a side slot, the lip of which slips out centrically in it arranged hose spring prevented. This ring is mounted in a machine groove with axial play.

A round sealing ring made of PTFE for stationary or mutually moving machine parts in Gbit ring seals with an axially parallel one extending beyond the cross-sectional center extending slot is provided. in which an adapted wedge ring engages. The wedge ring is either from a helical spring loaded pressure or additionally sealing to another elastic O-ring arranged adjacently, which also ensures the readjustment process in the event of wear on the sliding ring pair shall be.

Is disadvantageous. that due to the wear on the sliding ring pair, the helical spring or the elastic Round ring is relaxed and the expansion effect does not remain constant. The entire surface of the slotted round ring on the engaging incompressible wedge and also the centrally arranged Hose springs can prevent this PTFE ring with its insufficient elasticity, the expansion resistance. the poor thermal conductivity and the flowability

Do not make supply in this pressed position more elastic.

The purpose of the invention is to remedy the deficiency described on mechanical seals and thus to meet an urgent need of the operator.

The object of the invention is for a mechanical seal to develop elastic secondary sealing elements with expansion elements that can be used in both simple and can be used in double-acting mechanical seals and high operational reliability even with higher Degrees of warmth guaranteed.

In the case of secondary sealing rings made of PTFE for mechanical seals that have a slot running on the cross-sectional area, which partially divides the ring and in which an expansion element is arranged, the secondary sealing ring being arranged in an annular space formed by several, predominantly stationary elements of the mechanical seal, the sealing rings have with round or rectangular cross-sectional profiles according to the invention sealing beads in operative connection with the Schülz mouths. The expansion element is fixed 2ΰ in the mouth of the slot with a line, ier support and the eccentrically arranged expansion element is followed by an elasticity slot the sealing beads are located. A pretensioned hose spring with oversize is arranged in the groove as an expansion element, the seal allowing the sealing beads to be installed in the corner position. jo

In the case of the sealing ring of rectangular profile with the sealing beads pointing diagonally outward at the edges, an elasticity slot running axially parallel to the center of the cross-section is formed in each of its end faces, in whose mouth, which is widened to a groove , is arranged as a v, expansion element, a pre-tensioned tube spring with oversize. The sealing beads are designed as a double bead on the inner edges.

In the case of another sealing ring with a rectangular profile, which has a conical recess leading to the cross-sectional center on one end face, which results in two uniform legs, between which a conical extension worked on the counter-ring receptacle extends in a known manner as a spreading element, close at ₄ -> The end face of the legs is followed by the sealing bulges pointing radially outward and inward and the sealing bulges delimiting the conical recess, the elasticity slot

In the annular grooves of the machine elements, elastic secondary seals are arranged which have grooves into which, interchangeably, endless tubular springs, prestressed against a spring steel ring opening in a V-shaped cross-section, are pressed. The diameter of the hose spring exceeds the width Ϊ5 of the groove, the groove being followed by an elasticity slot of selected depth. The combination of these PTFE secondary sealing rings with methods of heat dissipation via an increase in the surface area of the outer circumference through the t> o arrangement of cooling and pressure gaps on the one hand between the sliding ring receiving ring and the guide sleeve and on the other hand between the counter ring seat and the shaft sleeve is particularly advantageous. A similar secondary seal equipment in double-acting mechanical seals on the product side of these / seals is a sliding ring made of metal oxide, the outer leg of which is sealingly mounted in a U-shaped PTFE ring, on the drive side to lead. A coolant pipe is passed through the wall of this sealing housing and opens out in front of the flow openings of the sliding ring. In the case of a circular cross-sectional profile of the secondary sealing ring, the groove is arranged diagonally, with sealing beads being arranged on both sides at the outlet of the groove and this seal being exchangeable for known round rings. A sealing ring with a rectangular shape in cross-section shows sealing beads pointing diagonally outward on the outer frontal boundary and also sealing beads arranged in the horizontal plane and radially inward. In the horizontal plane of the gasket groove with depressed biased endless helical spring is arranged on both sides which seal is' i and circular cross-section may be exchanged for seals with square Querschn ^ A ur, cross-section a rectangular shape having Direction sealing ring indicates the one end face in the horizontal plane, a conical recess, the two legs of which have sealing beads radially outward and inward and the sealing ring mounted in the pressure ring can be pushed onto a conical projection worked on the counter-ring receptacle and a greater play is selected at the point of the well-known fine fit between the counter-ring receptacle and the shaft sleeve.

The advantages of the invention are that compared to the previously known mechanical seals a significant improvement in terms of the stability of the mechanical seal is achieved. By the arrangement of the secondary sealing rings according to the invention with embedded, pre-tensioned, endless tube springs, the provided cooling and pressure gaps for improved heat dissipation? from the slip rings and simultaneous compensation of the Operating pressure and the arrangement of a counter-slip ring equipped with internal cooling on the product side and the materials used now allow a long service life simultaneous pumping of media in a high temperature range.

The invention will be explained in more detail below using an exemplary embodiment. In the drawing shows

Fig. 1 longitudinal section through the single-acting mechanical seal,

Fig. 2 longitudinal section through the double-acting mechanical seal,

F i 3.3 Cross section of the PTFE circular sealing ring according to FIG. 1 and 2,

Fig. 4 Cross section of the PTFE rectangular sealing ring according to FIG. 1 and 2,

F i g. 5 Cross-section of the PTFE rectangular sealing ring according to FIG. 1.

In Fig. 1 is in the upper half of the sectional drawing between the housing flange 1 and the Guide sleeve 2 of the sealing ring 3 arranged from the circular cross-section for sealing. The slip ring receiving ring 4, into which the sliding ring 5 is shrunk, slides sealingly on the sealing ring 6, from the rectangular Profile, which by means of a clamping washer 7 for sealing in the machine groove 8 in the guide sleeve 2 is seated. The group springs 9 press the sliding ring plane-parallel via the sliding ring receiving ring 4 against the Gegengleitririg 10, which is in the mating ring

would take 11 is shrunk. The pins 12 provide security against rotation. The shaft neck 14 sits on the shaft 13. In the machine groove 15 of the shaft sleeve 14, the sealing ring 16 is arranged, which ensures the sealing effect through the turned-on conical projection 17 on the counter-ring receptacle 11 by the sealing beads 166 of the sealing ring 16 on the inside against both sides of the projection 17 and the sealing beads 166 arranged on the outside are pressed onto the walls of the machine groove 8. The pins 18 are arranged to prevent rotation. For cooling or heat dissipation, the cooling and pressure gap 20 is arranged between the sliding ring mounting ring 4 and the guide sleeve 2 and the cooling and pressure gap 21 between the counter-ring mounting 11 and the roller sleeve 14 so that the frictional heat can be transferred from the sliding rings and thus dissipated. Due to the gap 22 created on the front side of the sliding ring pairs, the frictional heat can be safely dissipated and the sliding rings can also be cooled during operation with media such as oil, for example, which have an approximately tenfold poorer thermal conductivity than water, since the surfaces 23 and 25 are also cooled can be. Due to the specially created pressurized surfaces 19 and 25 on the sliding ring mounting ring 4, the maximum pressure compensation with the best possible damping factor enables high operating pressures to be safely controlled when pressure surges occur at the start-up moment, when the vapor phase occurs in the sealing gap due to operational reasons or in the different composition of products, as in the phenol synthesis in operation at 180 ⁰ C already components reach the boiling point at 80 ° C and under certain circumstances cause cavitation-like conditions in the sealing gap. The same vibration damping effect is achieved by the pressurized ramps 23 and 24 of the counter-ring receptacle 11, which compensate for the pressure that occurs.

According to FIG. 2 shows the sectional drawing of the seal according to FIG. 1 in tandem as a double-acting Mechanical seal, where 26 represents the product-side and 27 the atmosphere-side seal.

The installation space on the product side can be designed to be so large that media and substances alternate that are pure on the one hand and polymerizing and crystallizing on the other Settle residues or where icing substances such as liquefied gas cause before starting with built-in heating elements can be thawed. Another advantage is that the group springs 9 No contaminating product substances: to avoid blocking the springs, because these lie in a dry zone in the single-acting mechanical seal and also only on the product side in the double-acting mechanical seal of the carbon-free, clean barrier fluid circuit 28 s are washed around.

The counter sliding ring 29 made of metal oxide with the exchange flow channel 30 and the flow openings 31 is arranged on the shaft sleeve 32 and Secured against rotation with pins 33. For the Sealing of the coolant sits on the outside Leg in a PTFE U-ring 34, the outside against cold flow through the angle ring 35 and inside through a U-shaped recess 36 is secured on the shaft sleeve. The locking ring 37 avoids with the angle ring

is 35 an axial displacement. The coolant pipe 38 is in the bore 39 in the seal housing 40, consisting of 2 parts, attached. The main connection for the The barrier fluid circuit is the bore 41 and the drain sits in the seal housing offset by 180 °. the Bore 42 is arranged for the control of the leakage. The sealing ring 16 with a rectangular profile seals the thrust bearing and, at the same time, the groove bearing against the penetration of the barrier liquid. Face side is the complete ^{Gle: i} ring seal with the flange 43 completed and secures the disc seal 44 and 44 atßen and the sealing ring 16 inside the outlet of lubricant.

3 shows in cross section the sealing ring 3 of the circular cross section with the particularly shaped th sealing beads 3a. which by the elasticity slot 3c and the tubular spring 3b pressed in with bias in the groove 3d makes the sealing ring 3 flexible and presses the sealing bulges 3a firmly against the sealing points through the 4-point seal. If the sealing ring 3 with the groove 3d and tube spring 3b installed against the barrier fluid, the sealing effect is increased by the barrier fluid pressure, since the sealing beads 3a are pressed more firmly against the sealing surfaces.

In cross section, Figure 4 shows the seal 6 from

•• ο rectangular profile, which 2 elasticity slots 6 / "and has a 6-point seal with the sealing beads 6a above, 66 on the side in the machine groove and on the Sliding ring receiving ring 4 with the sealing bulges 6c provide a double-secure seal with a damping effect

■ »5, since the tube springs 6d spread the sealing ring 6 apart with the corresponding pretension in the grooves 6e.

In Figure 5, the sealing ring 16 is shown by the conical extension 17 are about the Dichtwü '~ »e 16a the sealing beads 166 on the machine groove surfaces pressed on.

For this purpose 3 sheets of drawings

Claims (4)

Patent claims: 1. Secondary sealing ring made of PTFE for mechanical seals, which has a slot running on the cross-sectional area, which partially divides the ring and in which a spreading element is arranged, wherein the secondary sealing ring is arranged in an annular space formed by several, predominantly stationary elements of the mechanical seal, characterized in that, that the sealing rings (3; 6; 16) with round or rectangular cross-sectional profiles sealing beads (3a, 6a, b, c-, 16a, b) have in operative connection to the slot mouths, the spreading element each with lined Support is fixed in the mouth of the slot and the eccentrically arranged expansion element an elasticity slot (3c, 6/7 is arranged downstream 2. Secondary sealing ring according to claim 1, characterized in that in the case of a sealing ring (3) of circular cross-section the diagonally arranged slot expands at its mouth to form a groove (3d) next to the outlet of which the sealing beads (3a) are located on both sides and in the groove ( 3d) a pre-tensioned hose spring (3b) with oversize is arranged as the expansion element and the seal allows the sealing beads (3a) to be installed in the corner position. 3. Secondary sealing ring according to claim 1, characterized in that in the case of a sealing ring (6) of rectangular profile with the "sealing beads (6a) _{pointing diagonally outward at the edges j0} " each one of its end faces axially parallel to the center of the cross-section is formed In its mouth, which is widened to form a groove (6e), an α pretensioned hose spring (6d) is arranged as an expansion element and the sealing beads are designed as double beads (6b, 6c) on the inner edges. 4. Secondary sealing ring according to claim 1, characterized in that with a sealing ring (16) mi * rectangular profile, which shows a conical recess leading to the cross-sectional center on one end face, whereby two uniform legs result, between which a spreading element in a known manner The conical projection (1) attached to the mating ring seat extends into it, the sealing beads (16f>, J) pointing radially outwards and inwards and the sealing beads (15b) protruding into the conical recess adjoin the end face of the legs and the sealing beads delimiting the conical recess (löajder elasticity slot is subordinate. 55