FI58888C - KONTINUERLIG SKIVPRESS FOER AVLAEGSNANDE AV VATTEN UR MATERIAL - Google Patents

Description

Ι «ΐβ *» · 1 rftl rt1 | ANNOUNCEMENT C O O Q Q

JBTa lbj (11) utlAggningsskimft OOOÖÖ φ | ΓΡνβ C (45) Patent granted on 11 05 1931

Patent seddelat ^ (51) Kv.ik.3 / int.a.3 B 30 B 9/20 FINLAND —FINLAND (21) P »t * nulh« k.mu.-P «« nttn.eknlni 2135/71 ( 22) H * k * ml «ftlvt - Aniöknlngtdkg 28.07-71 ^ ^ (23) Alkupilvt — GIM | h« tsdftf 28.07-71 (41) Interpreters | ulkU * ksl - Blivlt offxnllg 30.01.72

Patents registered. MNM «pn | iW | -w« ipka-.

Patant- och regiataratyralMn 'AntWun utiagd och uti ^ krtftM puumrad 30.01.81 (32) (33) (31) Pyyrfttty utuoikaui — B «jlrd prloritet 29- 07 - 70

Japan-Japan (JP) 65700/70 (71) (72) Ryutaro Yoritomi, 5-17 ~ 12 Koishikawa, Bunkyo-ku, Tokyo, Japan-Japan (JP) (71 *) Leitzinger 0y (5M Continuous disc press for dewatering material -

The present invention relates to a continuous water pressing device, and in particular to an improved so-called V-type press with a pair of filter plates arranged facing each other in front of an outer annular housing mounted on a frame freely rotatably, the inner ends of the shafts being pivotally connected to each other by a center pin supported in the center of the outer annular housing by a support member fixedly connected to the outer annular housing by a rigid arm, first connecting levers engaging the outer ends of the support shafts the ends are located in a plane comprising intersecting support shafts, with the free ends of the first connecting levers being freely adjustably attached to the connecting part on the outer side of the outer annular housing. Each press plate has an oblique, truncated cone-shaped front side and is arranged so that the truncated cone-shaped front sides face each other, the central part of each plate being in contact with a circular central support piece arranged between the plates. The radial perimeters of the plates are located near the inner surface of the housing. An annular channel with V-shaped cross-sections is thus formed between the plates.

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In previously known presses, the axes supporting the plates extended outwards with their longitudinal directions obliquely at a predetermined angle to each other, so that the V-shaped channel had a certain maximum width at a point and a minimum width at a point opposite to the first point in the diameter direction.

As the press plates rotate about the support shafts and as the fed material is introduced into the widest part of the V-shaped channel, the fed material rotates together with the plates while remaining in place between them, and the material is consequently compressed. The liquid in the fed material separates or compresses as the V-shaped channel decreases. With the support shafts in a certain oblique position, it was not possible to change the compression ratio (the ratio between the maximum and minimum channel width).

Previously known presses were not able to efficiently handle varying types of materials that differed in the amount of water they contained and their sliding properties. However, the present invention comprises a continuous pressing device, the pressing ratio of which has to be adjusted in the same way as in the device known from Finnish publication No. 56644.

In this continuous press, the inner ends of the two support shafts are pivotally connected to each other at the center of the circular plate by a pin, and the outer ends of the shafts are fitted in guide grooves formed on each side of the main base. The shafts can be fastened to selected positions in the guide grooves, making it possible to adjust the ratio of the maximum and minimum widths of the V-shaped channel. The compression ratio of the device can thus be pre-adjusted to the desired value depending on the amount of liquid contained in the fed material. When the material is compressed, the counter-forces that affect the filter plates increase as the clearance between the plates becomes smaller (decreases) and the maximum counter-forces are generated at the smallest clearance. After the material has passed through the smallest clearance, the counterforce forces rapidly decrease to a value close to zero. The total counterforce resultant therefore acts on the filter plates at a point somewhat below the smallest clearance, in a plane perpendicular to the pin connecting the shafts. Under certain operating conditions, the resultant is capable of bending the arm, 3,588,88, which supports a circular central support piece, and as a result this results in abrasion between the circumference of the filter plates and the inner surface of the housing. As the compressive force increases, the radial circumferences of the filter plates can be pressed so firmly against the housing that the plates stop rotating.

It is an object of the present invention to provide an adjustable, continuous V-press which does not cause abrasion during use, but is preferably distributed, and which provides efficient control of the outer ends of the support shafts while keeping the size of the device small.

This object is achieved by a press according to the invention on the basis of the features of the invention set out in the appended claim 1.

Other objects and advantages of the invention will become apparent from the following description with reference to the accompanying drawings, in which Figure 1 shows a section taken along line 1-1 of Figure 2, Figure 2 shows a side view of a press according to the invention, Figure 3 shows a press according to Figure 2 in partial section, Fig. 4 is an end view of the press of Fig. 2, Fig. 5 is a partially sectioned view of the press of Fig. 4, and Fig. 6 is a top horizontal projection of the press of Fig. 2.

In practice, the shafts supporting the rotating filter plates are arranged in a downwardly oblique position to facilitate filling and emptying of the raw material in the press. Since the raw material is removed at a point where the V-shaped channel has expanded somewhat after the raw material has been subjected to maximum compression, and since the position near the horizontal plane is a more favorable emptying position, the minimum clearance (minimum clearance) in the V-shaped filter plates is adjusted. in the channel to a point slightly below the horizontal plane. The longitudinal axes of the support shafts are thus directed obliquely downwards. However, to simplify the explanation, this is done by using figures in which the longitudinal axes of the support shafts are arranged horizontally. The directions described below are relative and are used only to simplify the explanation. Thus, the maximum and minimum opening of the V-shaped channel is horizontal, but the discharge of the raw material takes place somewhat above the horizontal plane. If such an arrangement were to be applied in practice, a special type of emptying device would be required. In other words, the support shafts shown in Figure 5 are in fact somewhat inclined downwards. The annular housing 1 supports the base and has an inner surface defining a circular cavity having a certain width and symmetrical with respect to the median plane of the housing. Figure 1 defines the inner surface of the housing by means of corresponding arcs. The circular plate 2 is concentric, fixedly fitted into the cavity by means of an inwardly directed arm 3 (Fig. 3) which inserts from the inner surface of the housing. The outer surface of the circular plate 2 defines a truncated sphere which is wedge-shaped symmetrically with respect to the median plane and which is concentrically arranged with respect to the housing, so that the width of the opposite edges differs in the diameter direction of the plate. The rectangular channel 4 extends through the plate 2 and the planes of the open ends of the channel are oblique compared to the plane perpendicular to the axis of the housing. The inner ends of the support shafts 5 and 6 are pivotally connected to the channel 4; the shaft 5 has a fork-shaped end which receives the end of the shaft 6 and the two ends are pivotally connected to each other by a pin 7. The pin is located in the center of the channel 4 and extends substantially vertically over the channel, the ends of the pin being fixed to a circular bore 2.

The filter plates 8 and 9 rotate concentrically on their shafts 5 and 6. Each plate has a frustoconical front side, and the tubular shafts 10 and 11 are formed integrally with the rear part of the respective plate. A plurality of axially oriented sleeves 20 extend through the filter plates 8 and 9 and terminate at their front sides. Shaft bearings 12 and 13 and shaft bearings or thrust bearings 14 and 15 support shafts 5 and 6. The frustoconical fronts of the plates 8 and 9 have recesses 16 and 17 where the fronts are truncated, and the intended tips of the fronts indeed cut in the vicinity of the pin 7. The inner circumferences of the recesses 16 and 17 form parts of spherical surfaces which, on both sides of the clearance, abut the outer surface of the circular plate 2. In other words, when the plates rotate on the shafts 5 and 6, the recesses 16 and 17 rotate around the outer, curved circumference of the circular plate 2. The radial edge surfaces of the filter plates run in the vicinity of the inner circumference of the housing 1. The sprockets 18 and 19 are attached to the outside of the housing 1 each on their own tubular shafts 10 and 11.

The rotation of the sprockets 18 and 19 with their chains 21 causes the filter plates 8 and 9 to rotate. The chain 21 passes over the sprockets 23 and 24 on the drive shaft 22, which shaft is arranged transversely between the legs of the base. The inlet opening 25 (Figs. 2 and 3) is arranged through the housing 1 above the point corresponding to the maximum width of the V-shaped channel. The discharge opening 26 with its scraping plates (not shown) is arranged above the point where the V-shaped channel is at its narrowest.

A pair of L-shaped, horizontal and interconnected levers 27 and 28 (Figs. 1, 4 and 6) are each in fixed contact at their other ends with the outer ends of the shafts 5 and 6. The support shafts are thus structurally formed in one piece with the horizontal and interconnected levers. The horizontal levers 27 and 28 are located in a plane comprising shafts 5 and 6 (i.e. in a plane perpendicular to the central pin 7). Each of the horizontal arms extends partially around the annular housing 1, and the free ends of the levers form connecting portions 29 and 30 which are bent at a right angle to the outside of the housing 1. The openings 31 and 32 are arranged through these connecting parts and the horizontal connecting rod 33 extends through the openings. The rod 33 is provided with flanges 34 and 35, and the part of the rod located between the flanges fits into a U-shaped notch 37 in the supporting part 36 (Figs. 2 and 3) projecting from the housing 1. The flanges prevent the connecting rod from moving in its axial direction. The adjusting nuts 38 and 39 are threaded into the rod 33 and are in contact with the connecting portions 29 and 30 while maintaining the horizontal levers 27 and 28 in their position on the rod 33.

If the forces acting on the outer ends of the shafts 5 and 6 were only in a plane perpendicular to the longitudinal axis of the center pin 7, it would not be necessary to provide special components at the outer ends of the shafts, but in practice acting on the outer ends of the shafts 6 58888 perpendicular to the longitudinal axis 7 of the center pin. It is therefore necessary to prevent the outer ends of the shafts from moving upwards. In the known devices, openings were provided for the ends of the shafts, but in this case the shafts had to be bent outwards by the support arm 3, which sometimes caused the clamp to become caught or cut.

In the present case, however, the vertical and interconnected levers 40 and 41 are, for example, welded directly to the horizontal levers 27 and 28 at the points where the shafts 5 and 6 are supported. However, the vertical levers may be formed integrally with the corresponding horizontal levers to form a pair of brackets. The vertical, interconnected levers 40 and 41 are located in planes comprising support shafts 5 and 6 and a longitudinal axis of the central pin 7. The branching part and the projecting part at the free ends of the vertical levers 40 and 41 can then intersect each other on the longitudinal axis of the central pin 7 (see Fig. 5). Another pin 42 coaxial with the central pin connects the pivoting intersecting portions, and the other end of the pin 42 is attached to the housing 1.

In use, the ratio between the maximum opening of the V-shaped channel and its minimum opening is initially adjusted according to the raw material. To achieve this adjustment, the adjusting nuts 38 and 39 are rotated in a rod 33 extending through the free ends 29 and 30 of the horizontal levers 27 and 28. Since the connecting rod 36 is centered on the support member 36 by means of flanges 34, the width of the V-shaped channel between the plates is adjusted and determined by tightening the nuts 38 and 39.

During the compression step, the material is subjected to a maximum compression effect at the point where the width of the V-shaped channel is at a minimum. The material is detached from the press as the width of the channel gradually decreases. Counter forces have their maximum when the width is at a minimum, and they quickly approach zero after the material has passed from the narrowest point of the channel. The resultant force of all the strong counter-forces acting on the filter plates must therefore act a small distance below the point of the V-shaped channel with the smallest width. The resultant is gravity which tends to push the shafts 5 and 6 in the outward direction and a pair of forces which tends to turn the support shafts 5 and 6 upwards from a horizontal plane.

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It can be assumed that the force pair can be divided into a large force pair tending to rotate the shaft ends in a plane perpendicular to the longitudinal axis of the center pin 7 and a relatively small force pair tending to rotate the support shafts in a direction perpendicular to this plane. The result of this is forces which tend to push the support shafts 5 and 6 outwards, resisting each other at the central pin 7, and thus act against each other. A small pair of forces tending to rotate the axes perpendicular to the longitudinal axis of the center pin 7 can be further divided into forces acting through the horizontal levers 27 and 28 and pressing the adjusting nuts 38 and 39 on the connecting rod 33 and forces opposing each other at the center pin 7. The latter forces oppose each other and thus do not tend to move the center pin 7. A pair of forces tending to rotate the support shafts 5 and 6 can also be divided into forces capable of pushing the outer pin 42 and forces capable of pulling the center pin 7 through the vertical levers 40 and 41. The former forces oppose each other and thus no force seeks to move the center pin 7.

In summary, the large counterforce forces acting on the filter plates, when the raw material is compressed, become forces that pull the connecting rod 33 through the adjusting nuts 38 and 39, forces that push the outer pin 42, and forces that pull or press the center pin 7. The forces act on either the horizontal levers. 27 and 28 or through the vertical levers 40 and 41.

All forces at the center pin 7 oppose each other. Thus, no large forces as a result of the counter-forces act on the support arm 3 which secures the center pin 7. Thus, only the pushing forces act on the center pin 7 and the outer pin 42, and traction acts on the connecting rod 33. As a result, no outward bending of the support arm 3 occurs. the radial edges of the data plates 8 and 9 between the plates and the housing remain at the normal value. Thus, the compression can take place evenly and continuously.

In addition, the support arm of the center pin, the annular housing and other components do not require special strength. Since there are no bends in the annular housing, etc. in the support arm during compression, there is no leakage of raw material and no scraping contact between the outer, annular housing and the filter plates.

Although the free ends of the vertical and interconnected levers * + 0 and UI in the embodiment shown in the drawings are connected above the housing 1, the two vertical levers may be downwardly directed and connected to each other below or at the bottom of the housing. Such an arrangement gives added strength to the structure and is particularly useful in large machines or in the case of handling materials that are difficult to compress. On the other hand, connecting the free ends of the vertical levers below the housing causes disadvantages when using a fixed housing. In such cases, the free ends of the vertical levers may be pivotally secured by means of two pins, one for each lever, on the lower opposite side of the housing at a position as close as possible to the extended longitudinal axis of the central pin 7.

Claims (8)

9 58888 A continuous press with a pair of filter plates (8, 9) arranged facing each other inside the outer annular housing (1) fixed to the frame, a pair of shafts (5, 6) supporting the filter plates in a freely rotatable manner, the inner ends of the shafts being pivotable connected to each other by a central pin (7) supported in the center of the outer annular housing by a support piece (2) fixedly connected to the outer annular housing by a rigid arm (3), first connecting levers (27, 28) engaging the support shafts ( 5, 6) for guiding them, the free ends of the connecting levers (27, 28) being located in a plane comprising intersecting support shafts, the free ends of the first connecting levers (27, 28) being freely adjustably fixed to the connecting part (36) by an outer annular housing (1). ) on the outside, characterized in that the clamp comprises second connecting levers (40, 41) which are fixedly connected to the first in the vicinity of the outer ends of the support shafts and the free ends of the second connecting levers (40, 41) are located in planes comprising the respective longitudinal axis of the support shaft (5 or 6) and the central pin (7), in addition to the free ends of the other connecting levers (40, 41) the ends are connected to each other by an external pin (42) on the longitudinal axis of the central pin (7) for pivoting about it. Press according to Claim 1, characterized in that the second connecting levers (40, 41) are located in planes comprising a respective support shaft (5 or 6) and a longitudinal axis of the central pin (7). Press according to Claim 1, characterized in that the position planes of the second connecting levers (40, 41) comprising the respective support axis (5 or 6) and the longitudinal axis of the central pin (7) are substantially perpendicular to the positioning plane of the first connecting levers (27, 28). , comprising intersecting support shafts (5, 6). Press according to one of the preceding claims, characterized in that the outer ends of the support shafts (5, 6) are supported and guided exclusively by the interconnected outer ends of the first (27, 28) and second connecting levers (41, 40), the first levers (28, 27 ) the means (33, 38, 39) for adjusting the distance between the ends are arranged to adjust the angle between the other levers (41, 40) and thus also the mutual angle of the support shafts (5, 6) between the outer pin (42) and the central pin ( 7) around the longitudinal axis. Press according to one of the preceding claims, characterized in that the ends of the first (27, 28) and second levers (40, 41) which support the shafts (5, 6) are formed integrally with one another. Press according to one of the preceding claims, characterized in that the longitudinal axis of the central pin (7) is substantially vertical. Press according to one of the preceding claims, characterized in that the second connecting levers (40, 41) are connected to one another above the housing (1). • i Press according to one of the preceding claims, characterized in that an external pin (42) which pivotally connects the ends of the second levers (40, 41) is fastened to the outer surface of the housing (1). 11 58888