RU2248957C2 - Machine for dehydration of sapropel - Google Patents

Abstract

FIELD: machines reducing moisture content of sapropel; dehydration of sapropel of colloidal structure.

SUBSTANCE: proposed machine includes loading unit for delivery of sapropel under pressure, unloading unit and technological apparatus for removal of water from sapropel mass. Moisture removal technological apparatus consists of flexible flat belt closed on drive and tension drums and provided with beads on its edges; mounted rotatably above upper run of said belt are dehydrating drums which are engageable with belt; outer cylindrical surface of these drums is coated with dehydrating layer. All dehydrating drums are kinematically linked with drive drum of belt in such way that linear velocity of belt and circumferential velocities of dehydrating drums are similar. Bodies of bearings of each drum may shift in guides oriented normally to plane of belt and provided with hold-down unit. Each dehydrating drum is mounted together with squeeze roller for rotation and engagement with cylindrical surface of dehydrating drum. Hollow roller is perforated and is fitted on end of lever secured by means of hinge and spring-loaded relative to dehydrating drum guides. Inclined chute located under squeeze roller is used for removal of water; upper run of belt is supported by two rollers in area of location of each dehydrating drum embracing the drum from below; rollers are movable in longitudinal guides. Loading unit is provided with slotted proportioner for delivery of sapropel; it is located between belt beads. Dehydrating layer on each dehydrating drum is made from woven non-stretchable porous material of open capillary structure which is bonded by means of waterproof adhesive. Free ends of each backing embrace plates which are secured to flat sections of outer surface of shell of dehydrating drum. Plates are formed over arc of circle of dehydrating drum. Their edges are rounded off on side of embracing the plates. Proposed machine ensures dehydration of sapropel up to 40-50% of mass of initial pulp.

EFFECT: enhanced efficiency; reduced power requirements.

3 cl, 7 dwg

Description

The invention relates to devices for reducing the moisture content of sapropel and can be used for dehydration of sapropels of a colloidal structure.

A device for sapropel dehydration is known, including a loading device for supplying sapropel under pressure, a discharge device, a technological device for draining water from a sapropel mass, made in the form of a disk filter with adjacent disks (Pat. RF No. 2057526, Cl. C 05 F 11/00 , 1996).

However, the disadvantage of this device is the low efficiency in dehydration of sapropel colloidal structure. Our laboratory studies found that finely dispersed sapropels are practically not filtered, therefore, the known device based on filtration is practically unsuitable for dehydration of the sapropel of a colloidal structure.

The objective of the invention is to increase the efficiency of dehydration of sapropel colloidal structure.

The problem is solved due to the fact that in a machine for dehydration of sapropel, including a loading device for supplying sapropel under pressure, an unloading device, a technological device for draining water from a sapropel mass, according to the invention, the technological device for draining water consists of a closed on the drive and tension drums a flexible flat tape with flanges along its edges, over the upper branch of which dewatering drums are installed with the possibility of rotation and interaction with it; whose surface is covered with a dehydration layer, while all the dewatering drums are kinematically connected with the drive drum of the tape so that the linear speed of the tape and the peripheral speeds of the dewatering drums are the same, the bearing housings of the axis of each drum are placed with the possibility of displacement in guides oriented normally to the plane of the tape , and equipped with a screw-type pressing device, each dewatering drum is installed together with the squeezing roller with the possibility of its rotation interaction and with the cylindrical surface of the dewatering drum, and the roller is hollow, perforated and placed on the end of a pivotally mounted lever, spring-loaded to the guides of the dewatering drum, an inclined groove for draining water is placed under the squeezing roller, and the upper branch of the tape in the area of each dewatering drum is supported on two rollers with a coverage of the dewatering drum from the bottom and with the possibility of displacement of the rollers in the longitudinal guides, while the loading device is equipped with but with a slotted dispenser with the possibility of feeding sapropel through it and placing it across the width of the tape between its shoulders, and the dewatering layer on each dewatering drum is formed from glued inextensible substrates of porous material of an open capillary structure glued with waterproof glue in the dry state, and the free ends each substrate is covered in a vertical plane with tension strips, which are fastened to bolts attached to flat sections of the outer surface of the shell dehydration drum eggs with the possibility of pressing the free ends of the substrate to these areas, while the planks on the outside are formed along an arc of a circle of the dewatering drum, and on the side of the envelope of the planks the substrate is made with rounded edges. The kinematic connection of the dewatering drums with the drive drum can be carried out using a chain transmission system. The kinematic connection of the dewatering drums with the drive drum can be carried out due to the frictional interaction of the dewatering drums directly with the beads of the tape.

The sapropel dehydration machine is shown in FIG. 1 — a side view, in FIG. 2 — a section A-A in FIG. 1, in FIG. 3 — a section B-B in FIG. 1, in FIG. 4 — a loading device; figure 5 - site installation of the dewatering drum; in Fig.6 is a view In Fig.5, Fig.7 is the attachment point on the drum of a layer of material of an open capillary structure.

The sapropel dehydration machine consists of a flexible flat tape 3 closed on a drive 1 and a tension 2 reels, inclined at an acute angle P to the horizon. Above the upper branch of the tape 3, dewatering drums 4 are mounted for rotation and interaction with the tape 3, the outer cylindrical surface of which is covered with a layer 5 of porous material of an open capillary structure having hygroscopic properties. The number of dewatering drums is taken from four to six. All the drums 4 are kinematically connected to the drive drum 1 by means of chain gears 6 so that the linear speed of the belt 3 and the peripheral speeds of the drums 4 are the same taking into account the deformation of the layer 5. Bearing housings 7 of the axis 8 of each drum 4 are biased in the vertical guides 9 and are provided with screw pressing devices 10.

Above the upper branch of the tape 3, in its tail part, a loading device is placed for feeding sapropelic mass to the tape 3, which can be previously mixed with the reagent to break its structural bonds. The loading device consists of a slotted dispenser 11 mounted on the discharge pipe 12 of the screw 13, and the latter is placed under the contact tank 14 for mixing sapropel with the reagent.

The tape 3 is made with shoulders 15 with the possibility of placing between them a layer of sapropel 16.

The drums 4 can be kinematically (due to friction forces) connected to the upper branch of the belt 3 due to their pressing against its shoulders 15. In this case, the chain transmission system 6 between them and the drive drum 1 is absent. Two rollers 17 and 18 are installed under the upper branch of the tape 3 in the probe for placing the dewatering drums 4 so that the tape 3 covers the bottom of the dewatering drum 4 by an angle α with the possibility of changing it from zero to 40-60 °. The lower branch of the tape 3 rests on the roller bearings 19.

Each dewatering drum 4 is installed together with a squeezing roller 20, which is hollow and perforated with holes 21. The roller 20 is placed on the end of the lever 22, which is pivotally (23) mounted on the guides 9 and spring-loaded with an adjustable spring 24. Under each squeezing roller 20 is placed inclined groove 25 for water drainage.

The unloading device is equipped with a scraper 26 installed in the run-off zone of the belt 3 from the drive drum 1 to remove dehydrated sapropel from the belt 3.

To attach a layer 5 of porous material of an open capillary structure to the dewatering drum 4, its shell is made with several (for example, two, three, or four) flat sections 27 on its outer cylindrical surface and is provided with through holes 28. A layer 5 of porous material of an open capillary structure (Fig. .1-3) on the drum 4 is formed in the form of two, three or four segments of porous material 29 (Figs. 5-7), glued with a waterproof adhesive in a dry state onto a substrate 30 of inextensible woven material. In this case, the free ends of the substrate 30 are covered in a vertical plane with the tension of the strap 31 and the latter are pressed against the flat sections 27 of the drum 4 with bolts 32 fixed to the straps 31. The bolts 32 are placed in the holes 28 of the shell of the drum 4 and fixed on the inside of the shell with using nuts 33 with oblique washers 34. The strips 31 on the outside are profiled along the arc of a circle of the dewatering drum 4, and from the side of the envelope of the strips 31, the substrate 30 is made with rounded edges. All dewatering drums 4, as well as drive 1 and tension 2 drums are equipped with flanges 35, 36, 37 with the possibility of interaction of the flanges with the side edges 15 of the tape 3.

When the machine is operating, the upper branch of the belt 3 moves in the direction 38, and the dewatering drums 4 and squeeze rollers 20 rotate in the directions 39 and 40.

41 - the joints of the segments of the porous material 29, forming a continuous layer 5 of material of an open capillary structure on the dewatering drums 4; 42 - longitudinal guides, relative to which the rollers 17 and 18 can be displaced to regulate the value of the angle of girth α tape 3 of the dewatering drums 4.

Machine for dehydration of sapropel operates as follows. Pre-dewatering drums 4 are equipped with a continuous layer 5 of porous material of an open capillary structure. To do this, on a substrate 30 of woven material are glued with a waterproof adhesive in a dry state, segments of the corresponding length from a porous material of an open capillary structure. The free ends of the substrate 30 with a grip are fixed on the slats 31 using bolts 32 that pass through the holes in the substrates 30. Next, the segments of the substrate 30 with the glued material 29 are tightened on flat sections 27 of the surface of the shell of the drum 4 by installing bolts 32 in the holes 28 of the shell and fixing the bolts 32 with nuts 33 with oblique washers 34. After installing on the drum 4 all segments of the substrates 30 with the porous material 29 glued on them, a continuous layer of open porous material is formed on the surface of the drum 4 capillary structure (5). The displacement of the rollers 17 and 18 in the guides 42 sets the required angle of coverage α tape 3 of the dewatering drums 4, which determines the estimated exposure time.

Then, with the help of screw pressing devices 10, the necessary pressure of the dewatering drums 4 is created on the tape 3, which rests in the area of the drums 4 on the rollers 17 and 18. By the corresponding installation of the springs 24 on the levers 22, the necessary force is pressed to press the squeeze rollers 20 to the surface (5) of the drums 4 sufficient to squeeze out water. The required amount of deformation (compression) of the porous material of the open capillary structure and its pressure on the sapropel layer 16 are ensured by appropriate selection of the thickness of the segments 29 of the porous material on the drums 4 and the thickness of the substrates 30.

When the drive drum 1 is turned on, the belt 3 starts to move in the direction 38, and the dewatering drums 4 and the squeeze rollers 20 start to rotate in the directions 39 and 40. In this case, the linear speed of the belt 3 and the peripheral speed of the dewatering drums 4 (by choosing the appropriate gear ratio between them using chain gears 6 or due to the transmission of torque directly from the tape) will be almost the same.

When the screw 13 is turned on, sapropel, which can be pre-mixed in the contact tank 14 with the reagent, is supplied under pressure through the pipe 12 into the slotted dispenser 11.

From the slotted dispenser 11, sapropel with a layer 16 of thickness h and width B is fed to the upper branch of the moving flexible tape 3, located between its shoulders 15. The thickness of the layer of sapropel 16 on the tape 3 can be adjusted both by changing the slotted gap h of the dispenser 11, and due to changes in the speed of movement of the tape 3 with a constant gap h of the dispenser 11.

Moving on with the tape 3 and sequentially interacting with the cylindrical surface of the dewatering drums 4, covered with a layer 5 of material of an open capillary structure, sapropel (16) gives moisture to this layer 5. The sapropel is dehydrated due to the hygroscopic effect, which is manifested during successive compression and restoration cycles the initial structure of the layer (5) of the material of the open capillary structure.

When each dewatering drum 4 is rotated at a constant peripheral speed, its water-rich layer 5 constantly runs onto the squeeze roller 20, so that the moisture accumulated in the layer 5 is squeezed out and enters the inclined groove 25 and then into the drain pipe.

The maximum dehydrated layer of sapropel 16 is discharged from the tape 3 in the area of the drive drum 1 and sent for further processing or storage (not shown). The sapropel layer adhering to the tape 3 is separated by a scraper cleaner 26 from the tape 3 and combined with the general stream of dehydrated sapropel discharged from the tape.

The speed of movement of the belt 3 and the productivity of the machine can be increased by increasing the contact zone of the dewatering drum 4 with the sapropel layer 16 when the tape 3 surrounds the dewatering drum 4 on an arc with a central angle α. Moreover, with an increase in the angle of inclination α, the exposure time increases, which means that the speed of the tape 3 and the throughput of the machine for dehydrating sapropel can be increased.

The efficiency of water drainage from the layer 5 of the dewatering drum 4 is increased by using a perforated (21) squeeze roller 20. In this case, the bulk of the water, as shown by experimental studies, is discharged into the roller 20 through the holes 21. Through these holes, the water is drained into the groove 25. The rest squeezed out of the layer 5 water (the smaller part) is discharged through the outer surface of the roller 20.

The inclined arrangement of the tape 3 to the horizontal at an angle β increases the clearance between the rollers 20 and the tape 3, which facilitates the removal of water squeezed out by the rollers 20 with the help of inclined grooves 25, especially with a sufficiently large width of the tape 3, selected from the condition of ensuring the given machine performance.

The implementation of the tape 3 with shoulders 15, and dewatering drums 4 with flanges 35, drive 1 and tension 2 drums with flanges 36 and 37 solves two problems: provides reliable fixation of the sapropel layer 16 on the tape 3 and eliminates the lateral displacement of the tape 3. Moreover, the centering efficiency the tape 3 is increased due to the fact that the flanges 36 and 37 are oriented upward, and the flanges 35 of the dewatering drums 4 are oriented downward.

The formation of a hygroscopic layer in the form of a combination of segments of an inextensible (or weakly extensible) substrate and fragments of a porous material of an open capillary structure glued onto the substrate, firstly, eliminates the possibility of peeling off the hygroscopic layer from the surface of the dewatering drum when this layer is saturated with moisture, because the increase in the volume of the porous material when it is moistened occurs due to an increase in the layer thickness, which is confirmed by experimental studies; secondly, this technical solution facilitates and accelerates the installation and dismantling of the elements of the dewatering layer, because the porous material does not stick to the surface of the drum, but is removed together with the substrate by unscrewing the nuts of the bolted joints. In addition, the substrate itself (woven material) is also removable, attached to the shell of the drum using the same bolts with nuts.

Distinctive features of the invention can improve the efficiency of dehydration of the sapropel colloidal structure with the removal, as shown by studies performed on the machine model, up to 40-50% moisture by weight of the original pulp with low energy intensity of the dehydration process and with the relatively simple technical implementation of the machine for dehydration of continuous sapropel, with a relatively small complexity of operations associated with the replacement of porous material of an open capillary structure on dewatering drums tires, and with reliable centering of the tape with sapropel under the dewatering drums.

Claims (3)

1. A machine for reducing the moisture content of sapropel, including a loading device for supplying sapropel under pressure, an unloading device, a technological apparatus for draining water from a sapropel mass, characterized in that the technological apparatus for draining water consists of a flexible flat tape closed on the drive and tension drums with flanges along its edges, over the upper branch of which dewatering drums are installed with the possibility of rotation and interaction with it, the outer cylindrical surface of which They are provided with a dewatering layer, while all the dewatering drums are kinematically connected with the drive drum of the tape so that the linear speed of the tape and the peripheral speeds of the dewatering drums are the same, the bearing housings of the axis of each drum are biased in guides oriented normally to the plane of the tape and equipped with a pressure screw type device, each dewatering drum is installed together with the squeezing roller with the possibility of its rotation and interaction with the cylindrical the surface of the dewatering drum, the roller being hollow, perforated and placed on the end of a pivotally mounted lever spring-loaded to the guides of the dewatering drum, an inclined groove for draining water is placed under the squeezing roller, and the upper branch of the tape in the area of each dewatering drum is supported by two rollers with a span dewatering drum from the bottom and with the possibility of displacement of the rollers in the longitudinal guides, while the loading device is equipped with a slotted dispenser with the possibility of and through it the sapropel and its placement across the width of the tape between its shoulders, and the dewatering layer on each dewatering drum is formed from pieces of a porous material of an open capillary structure glued with a waterproof adhesive in a dry state, and the free ends of each substrate span vertically planes with the tension of the strap, which are fastened with bolts to the flat sections of the outer surface of the shell of the dewatering drum with possibly the pressure of the free ends of the substrate to these areas, while the strips on the outside are formed along the arc of a circle of the dewatering drum, and from the side of the envelope of the strips the substrate is made with rounded edges. 2. The machine according to claim 1, characterized in that the kinematic connection of the dewatering drums with the drive drum is carried out using a chain transmission system. 3. The machine according to claim 1, characterized in that the kinematic connection of the dewatering drums with the drive drum is carried out due to the frictional interaction of the dewatering drums directly with the beads of the tape.

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