FI128250B - Coupling for a drying section of a fibre web machine, and arrangement using it - Google Patents

Abstract

The invention relates to a switch for a drying section of a fiber web machine comprising: - a rotatably mounted coupling body (21) comprising connections (13, 23) for condensate and / or steam at the end of the coupling body (21); movably guided by an axial cylindrical surface (21a), - a straight radial sealing surface (30a) associated with the ring piston (25), 0.75, most preferably 0.58 to 0.70 times the outer diameter Du of the carbon ring gasket (28) - a floating carbon ring gasket (28) arranged between said rotating spherical sealing surface (29a) and the sealing surface (30a) associated with the piston (25). and the back pressure pressing the seal faces (28a, 29a) together. The invention also relates to a corresponding arrangement.

Description

Fiber Machine Dryer Switch and Drive Application

The invention relates to a switch for the dryer section of a fiber web machine, in particular a steam and / or condenser switch, which maintains the cylinder of the fiber web machine pressure-tight while still allowing the , wherein the coupling includes a non-rotatably mounted coupling body including connections for condensate and / or steam at the end of the coupling body,

- a piston mounted on the coupling body of a non-rotatable but spring-loaded and axially movable actuated cylindrical surface, an abutment attached to said shaft and a rotary spherical sealing surface provided thereto,

- a dry seal arranged between said rotating spherical sealing surface and the ring piston when the sealing surfaces are pressed together by the piston spring and back pressure.

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Finnish patent 103907 discloses a steam coupling in which an integral part of the steam coupling includes an axially spring-loaded, coaxially cylindrical surface piston and a dry seal fixed thereto by screws. The shaft end, i.e. the rotary part of the steam coupling, has a transverse sealing plane against which the dry seal is seated. The structure allows small radial and angular deviations. The dry seal is usually carbon, which is a critical point on the piston and often breaks at the point of attachment. The inaccurate piston fitting caused a stall because the piston could pivot and wear the cylinder.

Like the above, a spring-loaded piston has been quite common. Frequently, the plunger-pressed springs also support it in the radial direction, intentionally providing some flexibility in the radial direction.

Finnish patent EI 99285 (US 5098135A) discloses a medium switch of the prior art. With its straight sealing surface, the plunger presses an annular seal with one spherical side 10. The spherical bearing surface opposite to this rotates at the end of the shaft. The solution also allows a small radial displacement.

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The old solutions employ two successive seals 15 having straight and / or spherical sealing surfaces in different configurations.

However, a single wear ring seal is desirable, whereby the same ring seal and piston must be able to be positioned20 radially along the axial deviations of the shaft.

In some solutions, the piston is supported by a bellows mechanism, allowing the bellows to handle both radial and angular deviations (US1718209, US1896062) while pressing axially on the piston.

In prior art solutions, the clutch body terminates before the piston structure, whereby a plurality of mutually ringed pieces of piston / counterparts with fasteners and seals are used.

It is an object of the present invention to provide a more reliable and easy to maintain switch. The objects of the invention are achieved by the solution of claim 1.

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The solution according to the invention completely avoids the fastenings causing point loads.

The combination according to the invention has proved to be reliable in trial runs. It has a spherical outwardly opening rotating sealing surface and a straight sealing surface on the axially guided piston side and a carbon seal floating therebetween. Preferably, a much smaller radius is used in the spherical sealing surface. The radius is only 55-75% most preferably 58-70% of the outer diameter of the ring seal.

The steep sphericity controls the ring seal well as it focuses it better than before.

In one embodiment of the invention, the piston includes a back pressure region for conducting vapor pressure behind the piston by depressing the carbon ring seal of the earth. The end of the ring piston then has a shoulder in the center of the shaft to form a sliding surface against the plane surface of the carbon ring seal. Between the center surface of the shoulder seal and the extension of the coupling body, there is a counterpressure range for the vapor pressure that loads the ren20 gas piston toward the carbon ring seal. It is also advantageous to provide the sliding surface of the annular piston to the extension of the coupling body with substantially the same diameter dimension (± 3%) as the outer diameter of the carbon ring seal. The extension of the coupling body is a protrusion on the inside of the annular piston which is bordered on its other surface by a steam space.

Here, a surprisingly compact combination has been achieved: the piston shoulder of the counter-pressure region of the formation of the counter-pressure region of the outer cylinder sliding surface carrying the inner sliding surface of the piston.

A particularly advantageous arrangement of the invention is obtained by applying a switch in connection with a wire-driven cylinder. Because the angular changes in the shaft and other deviations are smaller than in a gear driven cylinder, the steam coupling of the invention is better suited to smaller deviations. In a gear driven cylinder, the shaft extends further and all compensations are larger. However, the spherical sealing surface permits larger deflections and angular changes.

Such a precision-fit piston-clutch body assembly is also easier to seal with a single seal provided on the clutch extension, preferably adjacent to said recess. The arrangement as a whole is very compact and of short construction in the axial direction. There are a small number of parts here, which in turn contributes to reducing the number of parts fits and seals.

The piston material is preferably cast iron or chromium molybdenum steel and has at least an internal sliding surface and a sealing face on the carbon ring seal in a manner known per se. Here, the clamping force may have been increased from the previous one so that the characteristic quadratic force on the straight sealing surface 30a is 0.5 to 2.0 n / mm2.

The annular piston has an axial length of 25 to 40% of its outer diameter20.

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In the following, the invention will be described with reference to the accompanying drawings, which show a steam switch according to the invention and its application in connection with a paper machine cylinder.

Fig. 1 shows a switch according to the invention in connection with a drying cylinder in general view

Figure 2 shows a larger scale cross-section of the coupling

Figure 3 is an exploded view of the switch

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The arrangement of Fig. 1 corresponds to Figures 1a and 2a of patent 103907 by the way, but here the cylinder shaft does not have a drive gear. Figure 1 shows a drying machine 10 for a papermaking machine which rotates under the force of the wire means and in the bearing of the bearing 18. The steam is introduced into the steam / condenser switch 20 via the assembly 23 formed in the body 21 and the block is discharged through the end 13 of the body 21.

The drying cylinder 10 comprises a jacket 10a, an end 10b and a hollow shaft 10c connected thereto. It has a central cylindrical space C for mounting the coaxial steam pipe 12 and condensate pipe 11 between the non-rotary coupling 20 and the inner part of the cylinder 10 in a manner known per se.

The shaft 10c of the drying cylinder 10 is supported by said bearings 18 which, through the bearing housing 19, rest on the base 19c of the base 15, which further carries the coupling body 21 with its flange structure 19b.

Figure 2 shows the structure of the coupling in detail, more particularly the cross-section of the coupling. The coupling body 21 is supported by a flange 19b (securing bolt

31 is shown in the figure). The structure associated with the flange 19b protects the spring 27b and the carbon ring seal from dirt coming from the outside via a narrow passage to the ring space 22.

The one end of the coupling body may be according to said patent FI103907. Instead, in the coupling body 21, there is an annular space 22 in which the annular piston 25 is arranged to move axially so that the inner cylindrical surface 25a of the annular piston is supported by an external sliding surface 21a of the coupling body extension. These sliding surfaces 21a and 25a are formed by a precise sliding fit. The seal 21c seals the sliding surface of the interior of the steam 30 under pressure. The piston 25 is loaded by a spring 27a for which there is a recess in the piston which guides the spring 27a together with the pin 27b.

The vapor pressure behind the shoulder 30 provides, in addition to the spring force, an advantageous additional load which, as the pressure increases, increases the efficiency of the seal. In each case, the springs 27a provide a basic load on the sealing surfaces 29a, 30a.

The carbon ring seal 28 keeps the drying cylinder pressurized against the sealing surfaces 30a and 29a, but still allows rotation of the cylinder and passage of the stationary pipeline into the cylinder through the interior of its shaft. At the end of the shaft 10c is mounted an annular member 29 on which said spherical sealing surface 29a is machined.

The carbon ring seal 28, between its treads 28a and 28b, is positioned between the straight sealing surface 30a and the spherical sealing surface 29a according to the load. The carbon ring seal 28 can be displaced radially on the sealing surface 30a and the parallelism deviations of the shaft 10c 15 receive the displacements on the spherical surface 29a. Rotation takes place on both sealing surfaces, but mainly on the straight sealing surface 30a.

The surfaces 21a and 25a between the piston 25 and the extension of the clutch body 21 are machined to slide with respect to each other, for example 20 according to the gasket manufacturer's instructions. The effective axial length of the bearing surface 25a is 15 to 35%, most preferably 20 to 30%, of the outer diameter D _{u of the} carbon ring seal 28.

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The piston (25) is hardened on its sealing and sliding surface (30a, 21a) in a manner known per se.

As shown in Figure 3, the vapor switch comprises mainly coaxially spaced components. All components other than the annular member 29 and the carbon ring seal 28 to be attached to the shaft 10c are rotatable and the annular piston 25 is secured to the base through the clutch body 21. Figure 3 illustrates well a cylindrical support surface 21a supporting the piston 25 which forms a sliding surface 21a on the inner surface 25a of the piston 25. The carbon ring seal 21c is located in the recesses of the end of the support surface 21a.

The spring loading of the piston 25 comprises eight springs 27a, which are guided by the pin 27b, in addition to squeezing the springs into the cylindrical space formed in the piston (not shown). This number of springs distributes the load more evenly and reduces its inclination when compared to a smaller number of springs. The cylindrical pins F prevent the piston 25 from rotating.

Claims (11)

claim 1. The wiring portion of a fiber web machine, in particular a steam and / or condensate coupling, with the aid of which the fiber web machine The cylinder is kept pressure-tight and yet enables the rotation of the cylinder and the passage of the pipe system (11, 12) into the cylinder through the inner space (C) of its shaft (10c), where the coupling is intended to be mounted immediately outside the nearest bearing (18). carrying the cylinder (10), which The coupling comprises • a non-rotatably mounted coupling body (21) comprising connections (13, 23) for condensate and / or steam at the end of the coupling body (21) and • a ring piston (25) located non-rotatably in the coupling body. 15, but a spring loaded and axially movable guided by an axial cylinder surface (21a), a straight radial sealing surface (30a) connected to the ring piston (25), a counter support (29) connected to said shaft (10c) and a 20, a floating carbon ring seal (28) arranged between said rotating spherical seal surface (29a) and the sealing surface (30a) connected to the annular piston (25), where the piston (25) of the piston (25) compresses the sealing surface (28). , 29a), Characterized in that the radius r of the spherical seal surface (29a) is 0.55 - 0.75, most preferably 0.58 - 0.70 times the outer diameter D _{u of the} carbon ring seal (28). 2. A coupling according to claim 1, characterized in that the piston (25) comprises a backpressure region (30b) for conducting vapor pressure behind the collar (25) of the ring piston (25) for pressing the carbon ring seal (28). Coupling according to claim 1 or 2, characterized in that The support surface (25a) of the ring piston (25) has been designed as a continuous fit cylinder surface where its inner diameter is set against the extension of the outer cylinder surface (21a) formed by the coupling body (21). 4. Coupling according to claim 3, characterized in that the effective axial length of the support surface (25a) is 15 - 35%, most preferably 30% of the outer diameter D _u of the carbon ring seal (28). 10 5. A coupling according to any one of claims 1 to 4, characterized in that the material of the ring piston (25) is chrome molybdenum steel or cast iron. 6. A coupling according to claim 5, characterized in that The sliding surface (25a) of the member (25) is hardened. Coupling according to claim 6, characterized in that the sealing surface (30a) of the annular piston (25) is cured. 20 Coupling according to any one of claims 1-7, characterized in that the surface pressure provided by the annular piston (25) on the straight sealing surface (30a) is 0.5-2 N / mm 2. 9. A coupling according to any one of claims 1-8, characterized The axial length of the annular piston is 25 - 40% of its outer diameter. Arrangement at the end of a paper machine / board machine cylinder (10), wherein the shaft (10c) of the cylinder is stored with 30 (18) which permits angular deviation and which bearing (18) supports with its outer ring against a support, characterized in that there is in the arrangement a coupling according to any one of claims 1-9, which is connected to a frame (19) carrying up the bearing (18). Arrangement according to claim 10, characterized in that the radius r of the spherical surface is 15 - 40%, most preferably 15 - 25% of the axial distance L of the bearing (18) and the axial diameter of the bearing ring (28).