SE515926C2 - Method and apparatus for oil evacuation from a shoe press unit - Google Patents

Abstract

The invention relates to a device and a method for oil evacuation from a shoe press unit, which shoe press unit comprises a beam (1), a shoe element (2) arranged movably on said beam (1) by means of a pressing unit (3, 5) and having a pressing surface (21), an oil evacuation arrangement (4) with at least one inlet opening (41) which is moved with the shoe element (2), a number of evacuation ducts (48) and an outlet pipe (49), and also a flexible belt (6) interacting with said shoe element (2), oil being supplied during operation to lubricate between said pressing surface (21) and said belt (6), an oil excess with kinetic energy being pressed out at an upstream edge region (21A) of said pressing surface (21), and an oil excess being evacuated from said shoe press unit by said oil evacuation arrangement (4), in which said inlet opening (41) is arranged in such a manner in a container (43A, 43B, 44, 45, 46) connected firmly to the shoe element (2) that a large part of said oil excess is squirted directly into said inlet opening (41), said outlet pipe (49) is connected firmly to said beam (1), and at least a first part of said evacuation duct (48) is arranged movably in relation to said outlet pipe (49).

Description

20 25 30 35 the air from the oil before reuse. In addition, the known arrangement means that an undesired heat dissipation takes place from the hot, extruded excess oil before it is evacuated, which leads to an undesired increased temperature inside the shoe press unit. Also from an operational economic point of view, it is a disadvantage to have an accumulation of oil inside the shoe press unit, as this requires an increased power input.

BRIEF DESCRIPTION OF THE INVENTION It is an object of the present invention to eliminate or at least minimize at least some of the above-mentioned disadvantages, which is achieved by means of a method for oil evacuation from a shoe press unit, which shoe press unit comprises a beam, a means of a pressing unit at said beam movable. arranged shoe element with a pressing surface, an oil evacuation arrangement with at least one inlet opening which is moved with shoe elements, a number of evacuation channels and an outlet pipe and a flexible belt cooperating with said shoe element, wherein during operation oil surface with kinetic energy is squeezed out at an upstream edge area of said pressing surface, and that an excess oil is evacuated from said shoe press unit with said oil evacuation arrangement, wherein at least, characterized in that said inlet opening is arranged in a position fixed to the shoe element. holder in such a way that a large part of said excess oil is injected directly into said inlet opening, that said outlet pipe is fixedly connected to said beam and that at least a first part of said evacuation channel is movably arranged relative to said outlet pipe.

With the help of the achievement, you gain many benefits. Firstly, the placement and arrangement of the inlet opening means that a large part of the kinetic energy from the extruded oil is used for the evacuation of excess oil.

Furthermore, the construction of the oil evacuation arrangement means that an effective evacuation is achieved. In addition, the invention means that the temperature in the shoe press unit can be kept at a lower level, since a large part of the hot oil is evacuated without having time to dissipate its heat inside the shoe press unit. Furthermore, the efficient evacuation reduces the energy consumption for operation of the shoe press unit, since no or only insignificant amount of excess oil accumulates inside the shoe press unit.

According to further aspects of the method according to the invention it holds that: - said evacuation channel comprises a first, preferably substantially rigid, tubular part which is fixedly connected at said inlet opening, 10 15 20 25 30 35 nu a co nu 1000 I o! u o g p q. 926 - that said tubular part is movably arranged inside a through hole in the beam and has a sufficient length to project on the other side of said through hole, - that the end of said through hole movable tubular member is sealingly movably disposed relative to said outlet pipe, - that an ibable means, preferably a rubber bellows, is used to provide said seal, - that said fl visible means with one end is connected to said movable tubular channel and with its second end with a second tubular channel fixedly arranged at said outlet pipe, - that said shoe press unit consists of a closed shoe press which is arranged with an internal overpressure, said overpressure being between 10-500 mbar, preferably lower than 200 mbar and more preferably less than 50 mbar, - that said outlet pipe is connected to a negative pressure acting from the shoe press in order to be able to more easily evacuate said oil surplus.

The invention also relates to a device at a shoe press unit, which shoe press unit comprises a beam, a shoe element movably arranged by means of a pressing unit at said beam with a pressing surface comprising an upstream edge area, an oil leveling arrangement with an inlet opening, wherein said inlet opening said shoe element, a number of evacuation channels and an outlet pipe and a flexible belt cooperating with said shoe element, characterized in that said inlet opening is arranged in a container fixedly connected to the shoe element in such a way that a large part of said oil inlet is injected directly into the said outlet pipe is fixedly connected to said beam and that at least a part of an evacuation channel is movably arranged in relation to said outlet pipe.

According to further aspects of a device according to the invention it applies that: - said inlet opening is arranged at a container at which said movable part of said evacuation channel is sealingly connected, which container preferably comprises enclosing wall elements and a bottom, - that at least one evacuation channel cooperates with a sealing means, which creates a substantially tight connection between said inlet opening and said outlet pipe, - that said sealing means consists of a flexible tubular device, preferably a rubber bellows, which with its one end sealingly connects around said movable part of the evacuation channel and with its other end to a device which is fixedly connected to said outlet pipe, - that said device consists of a tubular socket, preferably a metal pipe, which is sealingly connected to said outlet pipe, - that movable part of the evacuation channel at its end with its outer surface directly cooperates with a sealing means , preferably containing at least one O-ring, arranged at the inlet opening of the evacuation channel, - said sealing means comprising two tubular, telescopically arranged sub-elements which cooperate in a sealing manner, - that the area between a lower limiting surface of the inlet opening and the shoe element is arranged by means preferably extends substantially rectilinearly, - that the shortest distance between the upper limiting surface of said inlet opening and the inner surface of the belt is between 0-10 mm, preferably less than 5 mm, - that the longitudinal extension of said container is between 500 -1500 mm, - that said first evacuation channel has a diameter between 30-100 inm, preferably 50-70 mm, - that at least two such containers are arranged next to each other inside said shoe press unit.

It will be appreciated that many advantages are obtained with a device according to the invention.

DESCRIPTION OF THE DRAWINGS In the following, the invention will be described in more detail with reference to the accompanying figures, in which: Fig. 1 shows a preferred embodiment of the invention in section, Fig. 2 shows a preferred embodiment of the invention partly in section, mounted in a closed shoe press unit, and Fig. 3 shows a perspective view of a preferred detail according to the invention.

DETAILED DESCRIPTION Fig. 1 shows in section the principles of a shoe press unit according to the invention.

According to principles known per se, the shoe press unit comprises a support beam 1, in which a recess for a pressing unit 3, 5 for a shoe element 2 is arranged. 15 20 25 30 35 5 šlo '5: a:: '15 ..'. '- .. 51% 92. 5 D 0 0 I o Q n U n o ø no ...__ i; X. . . . inside a hydraulic cylinder 5, so that the shoe element 2 can be moved hydraulically back and forth in a direction which is perpendicular to the extent of the shoe element 2 in the longitudinal direction. A support lug 9 is arranged at one short end of the shoe element 2.

An endless belt / jacket 6 is arranged in a manner known per se to cooperate with its one surface 6A with a pressing surface 21 of the shoe element 2 and with its other surface 6B with a counter-roller 10. The endless belt 6 rotates counterclockwise, as illustrated in picture. Thus, the lug 9 is arranged at the downstream end of the shoe element 2. To the left in the picture of the upstream end of the shoe element there is arranged a distribution chamber 7, which in a known manner via channels 71 supplies the pressing surface 21 with oil. An oil evacuation arrangement 4 is also shown, which comprises an inlet opening 41 arranged at a trough-shaped container (see Fig. 3), a first evacuation channel 48A, a rubber bellows 48C, an upper connection channel 48C and an outlet pipe 49. Further shown in Figs. 1 that the shoe press unit is provided with a secondary oil evacuation arrangement 11, which is suitably used as an oil evacuation system at standstill. The figure also shows that the shoe press unit is arranged with belt draping guides 12, which are arranged at a support plate 13, which have the purpose of being able to enable application / removal of the belt / jacket 6.

Fig. 2 shows in more detail certain parts of a shoe press unit according to the invention. It is shown that the shoe element 2 is symmetrically designed, according to the preferred embodiment shown, in each edge region of said pressing surface 21. In the upstream end of the shoe element 2 a marked area ZI-Zg is marked, which constitutes an area with a positively curved surface 21A. As can be seen, the extent L of this edge area 21A is considerably shorter than the concave portion 21 of the pressing surface. Within this edge area 21A there is a line X in which contact first occurs between the belt 6 and the pressing surface 21 of the shoe element.

At the distribution chamber 7, the lower part of the oil evacuation arrangement 4 is arranged. This comprises a hinge plate 42, a container 45, 44, 46, 43A, 43B, an evacuation channel 148 and the inlet opening 41, which is slit-shaped. The container consists of a first longitudinal wall element 45, a flat bottom 44, a second longitudinal wall element 46 and two end walls 43A, 43B. The upstream longitudinal wall 46 is divided into a lower 46A and an upper 46B section. The lower wall section 46A is arranged at an acute angle to the bottom 44 and a plane P comprising the flat bottom 44. According to the preferred embodiment, the angle X is about 60-70 °.

The upper section 46B is arranged with an even smaller acute angle in relation to said plane P. Hereby the upper section 46B is given a slope which deviates by only a few degrees from the tangent of the belt 6 in the area of said upper section 46B. The upper section therefore converges slightly towards the inner surface of the belt. Its end 41B forms the upper boundary surface of the inlet opening 41. It is advantageous if this upper boundary surface 41B is located close to, or in some cases t.o.m. in contact with the inner surface of the belt 6, so that as small a gap as possible is formed between them. The downstream wall element 45 is also arranged at an acute angle in relation to said plane P.

According to the preferred embodiment, it forms an angle ß which is substantially the same as the angle X of the second wall element 46A. End walls 43 A, 43B are arranged in each short end of the container. The lower boundary surface 41A of the inlet opening 41 is formed by the upper edge of the longitudinal wall element 45 located downstream.

All details included in the container are made of thin-walled sheet metal. In the preferred case, the plate is about 2 mm thick. At a right angle from said lower limiting surface 41A, a hinge plate 42 extends in the direction towards and up to the shoe element 2. The hinge plate 42 is also made of thin-walled plate and suitably this and the container are made of one and the same piece of plate, which is preferably first punched and then bent. to the desired final shape, after which the end walls 43A, 43B, suitably by means of welding, are sealingly connected to the parts of the container to which they have been bent up. At the bottom of the container a circular hole 44A is arranged in which in an sealing manner, suitably welded, an evacuation tube 48A is arranged. The container is fixed by means of screw connections 50 to the distribution chamber 7, which in turn is connected (usually screw) to one longitudinal side wall 23 of the shoe element. Thus the evacuation arrangement 4 is firmly anchored to the shoe element 2, so that they are movable as a unit. In order to enable shoe elements and the evacuation arrangement 4 to be moved, the support beam has a recess 1A inside which the evacuation tube 48A can move freely upwards and downwards.

As already mentioned, the evacuation arrangement 4 is positioned with its upper limiting surface 41B of the inlet opening 41, relatively close to the surface of the belt, so that the distance between them during operation is small enough to prevent any significant amount of oil from penetrating between the inlet opening 41 and the belt 6. should preferably not be allowed to exceed 10 mm. In addition, the inlet opening 41 should be located in such a way that the amount of excess oil that can be squeezed out can spray directly into the inlet opening 41. According to the preferred embodiment, this is achieved by the TX key for the positively curved surface at the contact line X between the belt 6 and the shoe element 2 between the lower 41A and the upper boundary surface 41B. In any case, the geometries between said edge region 21A and the inlet opening should be arranged so that the key Tx (which can be considered to represent a kind of median vector for the normally in divergent form, projecting excess oil) for said contact line X deviates a maximum of 15 ° from at least one of the imaginary straight lines Y1 and Y2, respectively, extending 10 15 20 25 30 35 an n. n. n ll o 0 novn '' 7 "'o en c: z: u' '' 'H0 ff:' zuo: nuss: snpop: o between said contact line X and the lower 41A and the upper 4lB boundary surface of the inlet opening 41. Further For example, the inlet opening 41 should be located near the upstream edge area 21A, suitably it is located between 10-150 mm, more preferably a maximum of 100 mm from the edge area 21A.

The device according to Figs. 1 and 2 operates as follows. When the machine is started up for operation, the inner surface of the belt is provided with an oil film to lubricate between the belt 6 and the pressing surface 21 of the shoe element 2, but also to cool the shoe press unit.

Oil is usually supplied at different positions, for example through the distribution chamber 7, which lubricates in the central zone of said pressing surface 21, (see Fig. 1) and usually at least elsewhere directly on the inner surface of the belt. Otherwise, the shoe press unit is operated in a manner known per se, whereby the shoe element 2, by means of the pressing unit 3, 5, exerts a pressure against the counter-roller 10 in order for an intermediate fi web to be subjected to the desired treatment, for example dewatering. In this case, the excess oil which accompanies the belt 6 to the upstream end of the shoe element will be forced out of the converging zone which is formed between the inner surface 6A of the belt and the upstream edge region 21A of the shoe element. The excess oil 0 thus gains kinetic energy and will spray backwards, towards the direction of movement of the belt, into the inlet opening 41 to be collected inside the container 43 A, 43B, 44, 45, 46. Thanks to a smaller overpressure inside the shoe press unit (when closed shoe press unit is used ), the oil collected in the container will be forced out through the first part of the evacuation channel 48A further through the rubber bellows 48C and then via the connecting pipe 48B into the outlet pipe 49, to finally end up in a collecting vessel (not shown). In some applications, the outlet pipe 49 is connected to a negative pressure to ensure adequate oil evacuation. Usually an attempt is made to operate a closed shoe press unit with an internal overpressure of less than 50 mbar.

A certain amount of oil will not be ejected, but will instead follow the surface in the edge area 21A of the shoe element down towards the end wall 23 of the shoe element. In the embodiment shown according to Fig. 1, gravity is assisted in obtaining this extra oil supply to the container. It should be pointed out, however, that this is not a necessity, since a certain negative pressure can be created in the control area adjacent to the inlet opening 41, so that this can take place without the influence of gravity in the event of excess oil. Thus, there is no limitation on the present invention that the evacuation arrangement is provided with the evacuation tube 48A in the vertical line. 10 15 120 25 30 35: oo o o oo s.f .. ==. == .. = s -; Fig. 3 shows in perspective, the above-mentioned containers 43A, 43B, 44, 45, 46 in the form of a unit with hinge plate 42 and evacuation tube 48A. It is also shown that the articulation plate 42 is provided with a number of holes 47 for arranging fastening screws 50. Thanks to the evacuation arrangement being sectioned and arranged at the shoe element 2, the inlet opening 41 will always be optimally positioned in relation to the oil spray regardless of the deflection of the beam 1. According to the preferred embodiment The container should preferably not be less than 500 mm in length and not exceed 1500 mm in length, so that optimal evacuation can be obtained. 60 mm.

The diameter should preferably not be less than 10 mm and preferably not exceed 50 mm.

According to an alternative embodiment of the invention, the evacuation tube 48A, which is fixed to the container, may be of sufficient length to be able to penetrate into the outlet tube 49 through its opening 49A. In this case, a seal, for example one or two O-rings, is suitably arranged directly in the opening 49A at the outlet pipe 49, these seals cooperating directly with the outer surface of the evacuation pipe 48A. Due to the fact that the outlet pipe 49 can be made with a large diameter, suitably between 100-200 mm, the end of the evacuation pipe 48A can move freely inside the outlet pipe 49, since the maximum stroke for a shoe element 2 normally never exceeds 50 mm, usually between 20-35 mm .

The invention is not limited by what is shown above but can be varied within the scope of the appended claims. Thus, it is understood, for example, that the evacuation arrangement can be made of materials other than thin-walled sheet metal, for example some polymeric material. It is also understood that the parts included in the evacuation arrangement do not necessarily have to be made of one and the same material, but can be made of a number of different details / materials, which can be arranged / connected to each other on a plurality of obvious alternatives for the person skilled in the art. Furthermore, it is understood that it is only for exemplary purposes that the evacuation arrangement is arranged at a distribution chamber.

Of course, the evacuation arrangement can for instance be arranged directly at the shoe element 2, for instance along one side side 23. It is further understood that the container can consist of a device whose designs differ greatly from the above, for example with an oval cross-section, according to space possibilities in the shoe press. is intended for use. It will also be appreciated that devices other than a rubber bellows 48B may be provided to arrange the visible sealing connection between two sub-tubes of the evacuation arrangement, for example a reinforced visible and dense polymeric material other than rubber, a liquid tight fabric material.

Claims (20)

10 15 20 25 30 35 aâši PATENTKRAV A method for oil evacuation from a shoe press unit, which shoe press unit comprises a beam (1), a shoe element (2) movably arranged by means of a pressing unit (3, 5) at said beam (1) with a pressing surface (21), an oil evacuation arrangement ( 4) with at least one inlet opening (41) which is moved with shoe elements (2), a number of evacuation channels (48) and an outlet pipe (49) and a flexible belt (6) cooperating with said shoe element (2), wherein during operation oil is supplied for lubricating between said pressing surface (21) and said belt (6), an excess kinetic energy oil is squeezed out at an upstream rim region (21A) of said pressing surface (21), and an excess oil is evacuated from said shoe press unit with said oil evacuation arrangement. , characterized in that said inlet opening (41) is arranged in a container (43A, 4.318, 44, 45, 46) fixedly connected to the shoe element (2) in such a way that a large part of said excess oil is injected directly into said inlet. opening (41), that said outlet pipe (49) is fixedly connected to said beam (1) and that at least a first part of said evacuation channel (48) is movably arranged relative to said outlet pipe (49). Method according to claim 1, characterized in that said evacuation channel (48) comprises a first, preferably substantially rigid, tubular part (48A) which is fixedly connected to said inlet opening (41). Method according to claim 2, characterized in that said tubular part (48A) is movably arranged inside a through hole (1A) in the beam (1) and has a sufficient length to project on the other side of said through hole (1A). . A method according to claim 3, characterized in that the end of said movable tubular part (48A) is sealingly movably arranged relative to said outlet pipe (49). 5. A method according to claim 4, characterized in that a flexible means (48C), preferably a rubber bellows, is used to provide said seal. Method according to claim 5, characterized in that said visible means (48C) is connected with one end of said movable tubular channel (48A) and with its other end to a second tubular channel (48B) which is fixedly arranged at said outlet pipe (49). 10 15 20 25 30 35 7. A method according to claim 1, characterized in that said shoe press unit consists of a closed shoe press which is arranged with an internal overpressure, said overpressure being between 10-500 mbar, preferably less than 200 mbar and more preferably less than 50 mbar. Method according to claim 7, characterized in that said outlet pipe (49) is connected to a negative pressure acting from the shoe press in order to be able to more easily evacuate said excess oil. Device at shoe press unit, which shoe press unit comprises a beam (1), a shoe element (2) movably arranged by means of a pressing unit (3, 5) at said beam (1) with a pressing surface (21) comprising an upstream edge area (21A), an oil evacuation arrangement (4) with an inlet opening (41), said inlet opening (41) being fixedly arranged in relation to said shoe element (2), a number of evacuation channels (48) and an outlet pipe (49) and one with said shoe element ( 2) cooperating fl visible belt (6), characterized in that said inlet opening (41) is arranged in a container (43A, 43B, 44, 45, 46) connected to the shoe element (2) in such a way that a large part of said excess oil is injected directly into said inlet opening (41), that said outlet pipe (49) is fixedly connected to said beam (1) and that at least a part (48A) of an evacuation channel (48) is movably arranged relative to said outlet pipe ( 49). Device according to claim 9, characterized in that said inlet opening (41) is arranged at a container (43A, 43B, 44, 45, 46) at which said movable part (48A) of said evacuation channel (48) in a sealing manner is fixedly connected, which container preferably comprises enclosing wall elements and a bottom (44). Device according to claim 9, characterized in that said part (48A) of said evacuation channel (48A) cooperates with a sealing means (48C), which creates a substantially tight connection between said inlet opening (41) and said outlet pipe (49). . Device according to claim 11, characterized in that said sealing means consists of an exemplary tubular device (48C), preferably a rubber bellows, which with its one end sealingly connects around said movable part of the evacuation channel (48A) and with its other end to a device (48B) fixedly connected to said outlet pipe (49). 10 15 20 25 30 515 923 ' Device according to claim 12, characterized in that said device (48B) consists of a tubular socket, preferably a metal pipe, which is sealingly connected to said outlet pipe (49). Device according to claim 11, characterized in that said movable part (48A) of the evacuation channel (48) at its end with its outer surface directly cooperates with a sealing means, preferably containing at least one O-ring, arranged at the inlet opening of the evacuation channel ( 49A). Device according to claim 11, characterized in that said sealing means comprise two tubular, telescopically arranged sub-elements (48A, 48B) which cooperate in a sealing manner. Device according to claim 10, characterized in that the area between a lower (41A) limiting surface of the inlet opening (41) and the shoe element (2) is arranged with shielding means (42), which means preferably extends substantially rectilinearly. Device according to claim 9, characterized in that the shortest distance (S) between the upper limiting surface (41B) of said inlet opening (41) and the inner surface (6A) of the belt is between 0-10 mm, preferably less than 5 mm . Device according to claim 10, characterized in that the longitudinal extent of said container is between 500 -1500 mm. Device according to claim 10, characterized in that said first evacuation channel (48A) has a diameter between 30-100 mm, preferably 50-70 mm. Device according to claim 18, characterized in that at least two such containers (43A, 43B, 44, 45, 46) are arranged next to each other inside said shoe press unit.