This application claims priority on European Patent App. No. 04102661.8, Filed Jun. 11, 2004, the disclosure of which is incorporated by reference herein.
Not applicable.
The present invention relates to shoe presses for applying pressure to a running web of paper, paperboard, or the like. More particularly, the present invention relates to a shoe press of the type having a support which supports a press shoe adjacent to a cylindrical backing member such that the press shoe and backing member form an extended nip therebetween, and having a hydraulic device for urging the press shoe toward the backing member to apply pressure to the web running through the nip. The shoe press of the present invention can be used for example as a dewatering press in the press section of a paper or paperboard machine, as an extended nip calender or in a tissue machine where the backing member is formed by a Yankee dryer.
In a papermaking machine, a wet web of paper or the like from the forming section of the machine is typically carried through the nip of a shoe press of the above-described type, where the web is pressed between two layers of absorbent felt or the like for wicking moisture from the web. Such shoe presses can also be used for other purposes than dewatering. For example, a shoe press can be used as an extended nip calender. In an extended nip calender, the backing member may be a roll provided with heating means, e.g. an induction heater or internal channels for heated oil. When a shoe press is used in a tissue machine, the backing member may be a Yankee dryer. When a shoe press is used in the press section of a paper or paperboard machine to press water from a wet web, the backing member may be, for example, a deflection-compensated roll.
One of the difficulties encountered in shoe presses is thermal expansion of the shoe from frictional heating of the shoe by the belt that carries the paper web through the press, as well as from hot hydraulic fluid which is circulated through the shoe for various purposes. Thermal expansion of the shoe causes elongation of the shoe in the cross-machine direction. The shoe is typically urged by a hydraulic device toward the backing member. The hydraulic device may be formed by a pressure chamber which extends in the cross-machine direction the whole length of the shoe. The pressure chamber is limited by the press shoe at the radial outside of the chamber and a shoe bed beneath the shoe which rests on a stationary support member of the shoe press roll. Such a shoe press is disclosed in, for example, DE 44 02 595. However, the majority of the shoe presses that are currently produced are instead provided with a plurality of hydraulic cylinders that extend in the cross machine direction in one or several rows. In such a shoe press, the hydraulic cylinders must be able to allow thermal expansion of the shoe without damage to the cylinders and/or the shoe. Moreover, the operation of the shoe press must not be disturbed. In U.S. Pat, No. 6,083,352, a shoe press is disclosed that comprises a plurality of articulated hydraulic loading cylinders that are spaced apart in the cross-machine direction along the press shoe. Each loading cylinder includes a piston member disposed within a cylinder. One of the piston and cylinders comprises a two-piece member having a first member fixed relative to the press shoe and a second member fixed relative to the support and spaced from the first member. The other of the piston and cylinders comprises a coupler engaging both the first and second members. The coupler engages the respective first and second members at seals which enable the coupler to pivot relative to the first and second members about axes parallel to the machine direction. Thereby, the articulated hydraulic loading cylinders enable the press shoe to move in the cross-machine direction relative to the support.
For shoe presses, it can also be a problem that the hydraulic device or devices used for urging the press shoe toward a counter member can become pressurized even when no backing member is present. In U.S. Pat. No. 5,223,100, a shoe press is disclosed that has a shoe bed with a pressure chamber and a connecting element disposed between the shoe bed and a side of the press shoe. It is stated that the connecting element prevents the press shoe from unintentionally escaping from the shoe bed, for instance, under pressure prevailing in the pressure chamber or under the force of gravity. It is stated that the connecting element may include an auxiliary piston which is part of an additional cylinder-piston unit. A cylinder of the unit is fastened to the outside of the shoe bed. The auxiliary piston and the piston fastened to the shoe bed are described as forming a pair of stop surfaces that limits the stroke of the press shoe.
It is an object of the present invention to provide an improved shoe press with a plurality of hydraulic actuators spaced apart in the cross-machine direction that can accommodate thermal expansion of the shoe in the cross-machine direction and simultaneously allow pressurization of the hydraulic actuators even when no backing member is present. It is also an object of the invention to provide a shoe press that is easy to assemble and that allows easy access for service purposes. These and other objects of the invention are attained with the shoe press according to the present invention.
The present invention relates to a shoe press for applying pressure to a fibrous web. The shoe press comprises a concave press shoe adapted to be juxtaposed with a backing member such as for example a deflection compensated roll or a Yankee dryer such that the web can be carried through a nip defined therebetween. The press shoe extends in a cross-machine direction along substantially a full width of the web. The shoe press further comprises a support which supports the press shoe. The support can be, for example, a cast beam or a welded box-beam. A plurality of articulated hydraulic actuators are arranged on the support and spaced apart in the cross-machine direction along the press shoe such that the press shoe is movable in a loading direction toward the backing member for applying pressure to the web. At least one actuator includes a first cylinder connected to the press shoe, e.g. fixed relative to the press shoe, a second cylinder connected to, e.g. fixed to the support and a piston member having a first end received within the first cylinder and a second end received within the second cylinder. The piston ends have convex spherical surfaces and the cylinders have seats with concave spherical surfaces with a curvature that may correspond to the curvature of the piston ends. It should be understood that the curvature of the convex surfaces can be equal to the curvature of the concave spherical surfaces but that the curvature can also differ. For example, the radius of curvature of the convex surfaces may be somewhat smaller than the radius of curvature of the concave surfaces.
The piston sealingly engages both the first and second cylinders. The first cylinder is urged away from the second cylinder when the actuator is pressurized. The spherical surfaces of the piston ends allow the piston to pivot about axes parallel to the machine direction. In this context, the machine direction should be understood as the main direction of travel of the web through the nip. In other words, the piston can be inclined relative to the loading direction of the actuators. The concave spherical surfaces of the cylinders are arranged/adapted to be able to cooperate with the spherical surfaces of the piston ends to prevent the piston ends from leaving the cylinders but allow the piston to be inclined relative to the loading direction of the actuators even at fill stroke, i.e. when the actuators are at the limit of their stroke. This allows the piston to reach its end position when the piston is inclined because of thermal expansion of the shoe but the actuator can still take its own force due to the cooperating spherical surfaces of the piston ends and the cylinder seats. The cooperating spherical surfaces of the piston ends and the cylinder seats can distribute the force of the actuator over a larger area and thereby prevent damage to the actuator.
In preferred embodiments of the invention, the piston is divided in two parts adapted to be connected to or disconnected from each other.
Advantageously, each of the articulated cylinders has a first cylinder connected or fixed relative to the press shoe, a second cylinder connected or fixed relative to the support and a piston member having a first end received within the first cylinder and a second end received within the second cylinder, the piston ends having convex spherical surfaces and the cylinders having seats with concave spherical surfaces with a curvature substantially corresponding to the curvature of the piston ends so that the pistons are able to pivot about axes parallel to the machine direction but prevented pistons from leaving the cylinders.
Preferably, the piston(s) is/are provided with a through-hole such that the first cylinder(s) is/are in fluid communication with the second cylinder(s).
In preferred embodiments of the invention, the second cylinder has a serrated outer circumference.
The second cylinder may be rotated into locking engagement with the support such that the serrated outer circumference of the second cylinder is located at a lower end of the second cylinder adjacent the support. A fastener may then be removably secured to the support such that it engages the serrated outer circumference to prevent rotation of the second cylinder relative to the support.
In advantageous embodiments, each of the first and second cylinders may comprise an internal cylinder part and an external cylinder detachably secured to each other. The concave spherical surface of at least one cylinder is located on a part of the external cylinder. Preferably, the concave spherical surface of each cylinder is located on a part of the external cylinder.
Preferably, at least one of the cylinders may be provided with a venting opening.
Further objects, features and advantages of the invention will be apparent from the following detailed description when taken in conjunction with the accompanying drawings.
a is a cross section of a disassembled hydraulic actuator for a shoe press.
b is an exploded view of a hydraulic actuator for a shoe press.
a is a perspective view of a fastener for securing a cylinder.
b shows the fastener of
The present invention relates to a shoe press 1 for applying pressure to a fibrous web W. With reference to
A rotatable flexible jacket 3 loops the support 4 and the press shoe 2. The jacket 3 (often referred to as belt) is typically made of polyurethane but other materials can also be considered. The ends of the jacket 3 are secured to end walls 8, shown in
The shoe press 1 of the present invention can also be used as an extended nip calender.
When the shoe press is used for applying pressure to a web W, frictional heat is generated between the flexible jacket 3 and the shoe 2. Lubrication of the shoe 2 and the interior surface of the belt or jacket 3 is used to reduce friction but friction cannot be entirely eliminated. The shoe 2 is often made of steel or aluminum and will expand in the cross machine direction when it is heated due to friction. The hydraulic actuators 5 must be able to absorb this expansion.
The invention will now be explained with reference to
The piston spherical surfaces 15a, 15b of the piston ends allow the piston 12 to pivot in the first and second cylinders 10, 11 about axes parallel to the machine direction to accommodate thermal expansion of the shoe 2 in the cross-machine direction. Hence, the piston 12 will pivot in a plane perpendicular to the machine direction when the shoe is subjected to thermal expansion. In this context, the term “machine direction” should be understood as the direction in which the fibrous web passes the nip. Therefore, the “machine direction” is not necessarily horizontal although this would very often be the case. When the piston 12 pivots about an axis parallel to the machine direction, this means that it will become inclined relative to the loading direction of the shoe press.
The spherical surfaces 15a, 15b of the piston ends are adapted to cooperate with the concave surfaces 17a, 17b of the cylinders 10, 11 to prevent the piston 12 from leaving the cylinders 10, 11 when the piston 12 reaches the end of its stroke. At the same time, the cooperating spherical surfaces 15a, 15b, 17a, 17b allow the piston to be inclined relative to the loading direction of the actuators even at full (maximum) cylinder stroke of the actuator 5 when the spherical surfaces 15a, 15b of the piston contacts the spherical surfaces 17a, 17b of the cylinders 10, 11. If the piston is inclined at its end position, i.e. the position of maximum stroke, the force of the actuator will be distributed over the spherical surfaces 15a, 15b, 17a, 17b which significantly reduces the risk that the piston and/or the cylinders will suffer damage if the actuators 5 are pressurized when no backing member 6 is present.
Preferably, each of the articulated actuators 5 has cylinders 10, 11 with concave spherical surfaces 17a, 17b and a piston 12 with convex spherical surfaces 15a, 15b.
The components of the actuator can be seen in detail in
As indicated in for example
To assemble the actuator shown in
Preferably, the piston 12 is provided with a through-hole 20 such that the first cylinder 10 is in fluid communication with the second cylinder 11. As can be seen in
The function of the inventive shoe press will now be explained with reference to
With reference to
It should be understood that, during normal operation, thermal expansion of the shoe 2 will cause the piston 12 to pivot well before it has reached its full stroke length. It should also be understood that, during normal operation, the piston 12 may possibly never reach its full stroke length. The situation illustrated in
An alternative embodiment will now be explained with reference to
In
As can be seen in for example
During assembly of the shoe press 1, the serrated outer circumference 21 of the cylinder 11 can be used to obtain a good grip on the cylinder 11 when the cylinder 11 is secured to the support 4. The cylinder 11 is typically screwed to the support or support beam 4 by means of the threaded pin 24. During the screwing operation, the serrated outer circumference makes it easier to obtain a good grip in the cylinder 11.
Reference will now be made to
The dimensions of the actuators depend on the particular application of the shoe press. In a wet press, the shoe 2 is relatively wide in the machine direction. At a given nip pressure, the linear load must be correspondingly high. Therefore, relatively large dimensions are required when the shoe press 1 is used as a wet press. When the shoe press is used as an extended nip calender, i.e. a shoe calender, the linear load is typically lower and the dimensions of the actuators is normally smaller.
The invention confers, inter alia, the advantage that the actuators can take their own force, even at maximum stroke and also when the pistons have pivoted as a result of thermal expansion of the shoe. The cooperating spherical surfaces increases the ability of the actuators to take their own force. The inventor has found that the design according to the present invention allows the pistons to pivot to an angle of up to about 4° and possibly even more. The risk that the pistons leave their cylinders if the actuators are loaded when no backing member is present is eliminated.
If the piston is divided into two parts, this will confer the advantage that assembly of the actuator becomes easier. When the cylinders are divided into external and internal cylinder parts, this will also make it easier to assemble the actuator and connect it to the shoe and support.
The invention can also be defined in terms of a method for assembling the hydraulic actuator described above.
Number | Date | Country | Kind |
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04102661 | Jun 2004 | EP | regional |
Number | Name | Date | Kind |
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5099750 | Rebel | Mar 1992 | A |
5223100 | Schiel et al. | Jun 1993 | A |
6083352 | Snellman et al. | Jul 2000 | A |
6387219 | Snellman | May 2002 | B2 |
20030015306 | Aho et al. | Jan 2003 | A1 |
Number | Date | Country |
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44 02 595 | Jul 1994 | DE |
WO 0068497 | Nov 2000 | WO |
WO 0198584 | Dec 2001 | WO |
Number | Date | Country | |
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20050274476 A1 | Dec 2005 | US |