RU2334731C1 - Machine for dehydration of sapropel - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: machine has a charging device, discharging device, elastic belt closed in vertical plane on driving and tensioning drums, dehydrating drums, the external cylindrical surface of which is covered with dehydrated material made of the material of unclosed capillary structure, pressure mechanism for drums, hollow perforated squeeze rollers, chutes for water export. Upper and lower branches of the elastic belt is made of solid-rolled steel of 1-1.5 mm gage with shoulders stuck on the belt between lateral vertical sides with opportunity to react with them by their side edges, and are supported by their low side on the bars placed lengthwise and fixed on traverses connecting vertical sides. Under the dehydrating drum, the bars are placed under the upper branch of the belt with gaps, and their upper edges from the side of the gaps are slanted down and have curvilineal shape with upper bulge. One of the vertical sides on the part of the driving drum is supplied with a branch pipe to deliver heated air through it and the drain system between upper and lower branches of the elastic belt towards the tensioning drum, and slotted batcher is supplied with heating device.

EFFECT: invention allows increasing efficiency of dehydration at low energy consumption of sapropel processing.

3 cl, 1 dwg

Description

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

A known machine for dehydration of sapropel (prototype), including a loading device for supplying sapropel under pressure, an unloading device, a technological apparatus for draining water from a sapropel mass, consisting of a flexible tape closed on the drive and tension drums with flanges along its edges, above the upper branch of which the dewatering drums are installed with the possibility of rotation and interacting with it with the possibility of rotation with a peripheral speed equal to the linear speed of the flexible tape, the outer cylindrical the surface of the dewatering drums is covered with a dehydrating layer, and the bearings of their axes are displaced in guides oriented normally to the plane of the tape and equipped with pressing devices, each dewatering drum is installed together with a hollow perforated squeezing roller located at the end of the articulated lever, spring-loaded to dewatering drum guides, with the possibility of rotation and interaction with the cylindrical surface of the dewatering drum, An inclined chute for water drainage is placed with the squeezing roller, and the upper branch of the tape in the area of each dewatering drum is supported by two rollers with the coverage of the dewatering drum from below, the loading device is equipped 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 a porous material of an open capillary structure glued onto an inextensible fabric substrate (RU No. 2248957 C2 C05F 7/00 C02F 11/12, 2005).

However, using the known machine for dehydration, it is possible to remove no more than 40-50% of water from the sapropelic mass, therefore, the drying operation of the dehydrated sapropel remains rather laborious and energy-intensive.

The technical result of the invention is to increase the efficiency of dehydration of sapropel with an increase in the rate of water separation during its dehydration.

The technical result is achieved in 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, consisting of a flexible tape closed with a collar in the vertical plane on the drive and tension drums along its shoulders edges above the upper branch of which the dewatering drums are installed with the possibility of rotation and interaction with it with the possibility of rotation with a peripheral speed equal to the line flexible tape, the outer cylindrical surface of the dewatering drums is covered with a dewatering layer, and the bearing housings of the axes of these drums are displaced in guides oriented normally to the plane of the tape and are equipped with screw-type pressing devices, each dewatering drum is installed together with a hollow perforated squeezing roller placed on the end of a pivotally mounted lever, spring-loaded to the dewatering drum guides, with the possibility of rotation In order to interact and interact with the cylindrical surface of the dewatering drum, an inclined chute for water drainage is placed under the squeezing roller, and the upper branch of the tape in the area where each dewatering drum is placed is deflectable with the coverage of the dewatering drum from below, the loading device is equipped with a slotted doser with the possibility of feeding sapropel through it and its placement across the width of the tape between its shoulders, and the dewatering layer on each dewatering drum is formed from glued onto an inextensible the woven substrate of the porous material of an open capillary structure, according to the invention, the upper and lower branches of a flexible tape made of 1-1.5 mm thick rolled steel with collars glued to the tape are placed between the longitudinal vertical walls with the possibility of interaction with them with their lateral edges and are supported by the lower sides on the longitudinally placed bars fixed on the cross-pieces connecting the vertical walls, and under the dewatering drums the bars are placed under the upper branch of the tape are filled with gaps, and their upper edges are beveled downward from the gaps and have a curvilinear shape with a bulge upward, one of the vertical walls on the side of the drive drum is equipped with a pipe with the possibility of supplying heated air through it and its canalization between the upper and lower branches of the flexible tape a tension drum, and the slotted dispenser is equipped with a heating device. The heating device can be made in the form of a thermally insulated jacket, covering the slotted batcher from the outside, the inner cavity between the jacket and the surface of the slotted batcher being connected by a pipe with an internal cavity between the upper and lower branches of the tape, and the pipe itself is placed on the side of the tension drum. The heating device can be made in the form of heating elements placed inside the slit dispenser.

Figure 1 shows a machine for dehydration of sapropel - a longitudinal section; figure 2 is a section aa in figure 1.

The sapropel dewatering machine consists of a loading device made in the form of a slit dispenser 1, which is connected via a pipe 2 to the screw 3 for supplying pressure sapropel to the slotted dispenser 1, a discharge device 4, and a technological apparatus for draining water from a sapropel mass, consisting of closed in a vertical plane on the drive 5 and tension 6 reels of a flexible tape 7 made of 1-1.5 mm thick rolled steel with beads 8 and 9 glued to the tape 7 at its edges. Above the upper branch of the belt 7, the dewatering drums 10 are mounted to rotate and interact with it, so that they can rotate at a peripheral speed equal to the linear speed of the flexible tape 7. The outer cylindrical surface of the dewatering drums 10 is covered with a dehydration layer 11. The dehydration layer 11 on each dehydration drum 10 is formed of an open capillary structure glued onto a porous fabric substrate, and the bearing housings 12 of the axes of these drums 10 are biased in the guides 13, oriented normally to the plane of the flexible tape 7, and equipped with pressure devices 14 screw type. Each dewatering drum 10 is installed in conjunction with a hollow perforated squeezing roller 15 located at the end of the pivotally mounted (16) lever 17, spring-loaded (18) to the guides 13 of the dewatering drum 10, with the possibility of rotation and interaction with the cylindrical surface of the dewatering drum 10. Under the squeezing roller 15 there is an inclined groove 19 for draining water. The upper branch of the flexible tape 7 in the area of each dewatering drum 10 is placed with the possibility of deflection with coverage of the dewatering drum 10 from the bottom. The upper and lower branches of the flexible tape 7 are placed between the longitudinal vertical walls 20 and 21 with the possibility of interacting with them with their lateral edges with shoulders 8 and 9. Both branches of the flexible tape 7 are supported by their lower sides on the longitudinally placed bars 22 and 23, mounted on the cross members 24 and 25 connecting the vertical walls 20 and 21. Moreover, under the dewatering drums 10, the bars 22 under the upper branch of the tape 7 are placed with gaps 26, and their upper edges 27 from the side of the gaps 26 are beveled down and have a curved shape with a bulge u up. One of the vertical walls 20 on the side of the drive drum 5 is equipped with a nozzle 28 with the possibility of supplying heated air through it and its canalization between the upper and lower branches of the flexible tape 7 towards the tension drum 6. The slit dispenser 1 is equipped with a heating device. The heating device can be made in the form of a thermally insulated jacket 29, covering the slotted dispenser 1 from the outside, and the inner cavity between the jacket 29 and the surface of the slotted dispenser 1 is connected by a pipe 30 with an internal cavity 31 between the upper and lower branches of the flexible tape 7, and the pipe 30 itself placed on the side of the tension drum 6. The heating device can be made in the form of heating elements (not shown) placed inside the slotted dispenser 1. 32 — direction of movement of the flexible tape 7, 33 — direction of rotation of the dewatering drums 10, 34 — device for cleaning the flexible tape 7, 35 — a layer of sapropelic mass placed on the flexible tape 7.

Machine for dehydration of sapropel operates as follows. Using the pressing devices 14, the pressure drums are shifted towards the flexible tape 7 to provide the necessary pressure on it and the angle of the drum 10 with the flexible tape 7, the corresponding installation of the springs 18 provides the necessary force to press the pressure rollers 15 to the dewatering drum 10. Through the pipe 28 into space 31 between the upper and lower flexible steel tape 7 from the air heater (not shown) air heated to 50-60 degrees is supplied, which, passing between the vertical walls 20 and 21, heats the flexible tape 7. Simultaneously with the same air exiting from the nozzle 30 continuously heated slotted dispenser 1 by the passage of air under jacket 29. Slit dispenser 1 can be heated and special heating elements (not shown). When the drive drum 5 is turned on, the tape 7 starts moving in the direction 32. Due to the interaction of the shoulders 8 and 9 fixed on the tape 7 with the dewatering drums 10, they also begin to rotate in the direction 33. When the screw 3 is turned on, the sapropelic mass 35 is supplied under pressure through the pipe 2 into the slotted dispenser 1, in which it is constantly heated to a temperature of 50-60 degrees. From the slotted dispenser 1, the sapropelic mass 35 is fed with a layer up to 6 mm thick onto a heated flexible steel tape 7, located evenly between the beads 8 and 9. Moving with the tape 7 and interacting sequentially with the dehydrating layers 11 of the dewatering drums 10, the sapropel gives moisture to this layer . Deep dehydration of the sapropel is provided due to the hygroscopic effect, which is manifested in successive cycles of compression and restoration of the initial structure of the dehydration layer from the material of an open capillary structure.

The intensification of the water separation process occurs due to the violation of structural bonds in the sapropelic mass when it is heated. The constant heating of the flexible steel strip 7 does not allow the sapropelic mass 35 to cool after it is heated in the slit dispenser 1 and change its structure until it interacts with the dewatering drum 10. During the interaction itself, the temperature of the sapropelic mass varies slightly, because the dewatering layer 11 is made of material (type "Express") with high thermal insulation properties.

During the rotation of each dewatering drum 10, the moisture-enriched layer 11 constantly runs onto the squeeze roller 15, so that the moisture accumulated in the layer 11 is squeezed out and enters the inclined groove 19 and then into the drain pipe (not shown). The dehydrated layer of sapropelic mass 35 is discharged from the belt 7 in the area of the drive drum 5 and is sent for further processing, for example, drying.

Distinctive features of the invention can improve the efficiency of dehydration of sapropel colloidal structure with the removal, as shown by laboratory studies, up to 75-85% of moisture by weight of the original pulp at low energy intensity of the processing of sapropel in the production chain extraction - dehydration - drying.

Claims (3)

1. Machine for sapropel dehydration, including a loading device for supplying sapropel under pressure, an unloading device, a technological device for draining water from a sapropel mass, consisting of a flexible tape closed in a vertical plane on the drive and tension drums with flanges along its edges, above the upper branch which are installed with the possibility of rotation and interaction with it dewatering drums with the possibility of rotation with a peripheral speed equal to the linear speed of the flexible tape, the outer cylinder the surface of the dewatering drums is covered with a dehydrating layer, and the bearing housings of the axes of these drums are displaced in guides oriented normally to the plane of the tape and are equipped with screw-type pressing devices, each dewatering drum is installed together with a hollow perforated squeezing roller located at the end of the articulated set lever, spring-loaded to the dewatering drum guides, with the possibility of rotation and interaction with a cylindrical turn with the dehydration drum, an inclined chute for water drainage is placed under the squeezing roller, and the upper branch of the tape in the area of each dewatering drum is placed with the possibility of deflection with coverage of the dewatering drum from below, the loading device is equipped with a slotted dispenser with the possibility of feeding sapropel through it and placing it across the width tape between its shoulders, and the dewatering layer on each dewatering drum is formed from a porous material glued onto an inextensible woven substrate a capillary structure, characterized in that the upper and lower branches of a flexible tape made of 1-1.5 mm thick rolled steel with collars glued to the tape are placed between the longitudinal vertical walls with the possibility of interaction with them with their lateral edges and are supported by their lower sides on longitudinally placed bars fixed on the cross-pieces connecting vertical walls, and under the dewatering drums the bars under the upper branch of the tape are placed with gaps, and their upper edges with a hundred The gaps are sloping down and curved upward, one of the vertical walls on the side of the drive drum is equipped with a nozzle with the possibility of supplying heated air through it between the upper and lower branches of the flexible tape towards the tension drum, and the slotted dispenser is equipped with a heating device . 2. The sapropel dehydration machine according to claim 1, characterized in that the heating device is made in the form of a thermally insulated jacket, covering the slotted dispenser from the outside, the inner cavity between the jacket and the surface of the slotted doser being connected by a pipe to the inner cavity between the upper and lower branches of the tape , and the pipe itself is placed on the side of the tension drum. 3. Machine for dehydration of sapropel according to claim 1, characterized in that the heating device is made in the form of heating elements placed inside the slit dispenser.

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