KR101438684B1 - Dewatering machine - Google Patents

Abstract

The present invention relates to a dehydrator for dewatering various types of filtered wefts containing water and solids, and more particularly, to a dehydrator for dehydrating various kinds of filtered wefts containing water and solids, The discharge port is provided with a pressurizing chamber provided with a discharge port, and a pressure regulating means is provided to communicate with the discharge port, so that the pressurization pressure can be controlled through a simple operation. It is possible to use the dehydrator itself as a pressure feeding pump for feeding the dehydrated water by providing the rotor and preventing the clogging of the outlet and increasing the discharge pressure.

Description

DEWATERING MACHINE

The present invention relates to a dehydrator for dehydrating a dehydrated water such as a raw material containing water, a manufactured product, a foodstuff, a food waste, sludge generated in a wastewater treatment plant, and the like into a dehydrated water having a low water content and a dehydrated filtrate. More particularly, the present invention relates to a screw-type dehydrator for squeezing and dewatering contaminants by a screw rotating in a cylindrical fine screen.

Dehydrators include centrifugal dehydrators, belt presses, and filter presses.

Since the centrifugal dehydrator is compact, it takes less space and has a sealed structure, so there is a small disadvantage that the odor is small but the noise vibration and the power consumption are large due to high rotation.

Belt presses have low dewatering efficiency and many other disadvantages, and filter presses are relatively compact and have excellent dewatering efficiency.

Therefore, recently, a screw-type dehydrator (Screw Filter Press) which is compact, has low power consumption, excellent dewatering efficiency, continuous operation type, and has little noise vibration and odor is attracting attention.

Many improvements have been made to improve the efficiency of the screw dehydrator and to reduce defects. A pressure plate is provided on the discharge side of the dehydrator so as to control the pressing force applied to the dehydrated water by adjusting the discharge amount of dehydrated water.

An example of a pressure plate provided in a screw dehydrator according to Japanese Patent No. 10-0736699 is a discharge passage formed of a discharge port 12 formed in a housing provided between a screw rotating shaft and a cylindrical screen and a hole 61 formed in a discharge cylinder 60 Whereby the dehydrated water is discharged. The discharge passage includes a pressing shaft 54 having a ring-shaped pressing plate 50 formed at the center thereof with a shaft hole 52 and formed with threads for adjusting the pressure by adjusting the length of the pressing shaft 50, A pressure regulating means 56 composed of a rotating means 55 and the like is applied. A plurality of pressure regulating means are provided along the circumference of the platen, the platen is supported by a pressurizing shaft, and the pressurizing shaft is supported by the discharge cylinder.

Such a conventional pressure plate has a configuration in which it is difficult to evenly adjust and maintain the discharge pressure in the entire discharge port because a plurality of pressing shafts supporting the pressure plate are rotated to uniformly press the ring-shaped pressure plate. Since the pressing force must be adjusted by rotating each of the plurality of shafts as described above, the operation is cumbersome and even when the discharge pressure needs to be changed, rapid response is difficult.

Further, since the dehydrated water falls through the discharge port on the lower side formed in the lower portion of the discharge cylinder 60, it is difficult to install the conveyor belt in the lower part of the dehydrator or collect the dehydrated water dropped on the floor by the force.

In addition, since the conventional screw-type dehydrator slips between the scum and the screw, the screw can not be squeezed and propelled, the dewatering efficiency is low, the screen is clogged with water and the water is wasted, The pressure energy discharged from the debris can not be used for transferring, forming, or sedimenting dehydrated water and is wasted.

SUMMARY OF THE INVENTION The present invention has been conceived to overcome the problems of the prior art described above, and it is an object of the present invention to provide an exhaust gas purifying apparatus which is simple in structure, simple in operation, strong in compression force and propulsion force in screw, excellent in dehydration efficiency, And to minimize the clogging of the screen, thereby realizing a dehydrator capable of reducing the amount of waste water generated by backwashing and increasing the utilization rate.

According to an aspect of the present invention, there is provided a dehydrator comprising: a cylindrical screen having a plurality of fine holes; a screw having a rotating shaft and a spiral rotating blade; a driving unit rotating the screw; A discharge port for discharging the dehydrated water to the outside of the screen, a pressurizing chamber for receiving and discharging the discharged dehydrated water, which is communicated with the discharge port, and formed at one side of the pressurizing chamber, And a pressure regulating means provided in communication with the discharge port and regulating the discharge pressure of the water to be filtered, the filtered water introduced into the screen through the discharge port is discharged to the outside of the pressure chamber, The dewatering is performed while being pressed by the rotating screw, Water is discharged into the pressurizing chamber through the discharge port and the dehydrate discharged into the pressurizing chamber is discharged to the outside of the pressurizing chamber through the discharge port and the discharge amount of the dehydrated product is controlled by the pressure adjusting means provided to be in communication with the discharge port The discharge pressure on the discharge port side is raised and the discharge pressure raised on the discharge port side gradually increases the internal pressure of the pressurization chamber and the discharge pressure of the discharge port to finally increase the dewatering pressure inside the screen.

Therefore, when the discharge pressure of the dehydrated water discharged through the discharge port is adjusted by operating the pressure adjusting means, the discharge pressure at the discharge port is controlled in a chain-like manner and the dehydration pressure acting on the filtered water inside the screen is controlled. Moisture content can be easily and reliably controlled.

In the description of the present invention, the dewatering object before being put into the cylindrical screen and the dewatering object being dewatered in the cylindrical screen are defined as the dewatering object, and the dewatering object after being discharged from the outlet is defined as dehydrated object .

In addition, the dehydrator according to the present invention may further include at least one rotating blade installed on a rotating shaft adjacent to the discharge port. Therefore, it is possible to prevent clogging of the discharge port and to discharge the dehydrated water uniformly while rotating the rotary blade.

In addition, the dehydrator according to the present invention may further include at least one impeller installed in a rotary shaft inside the pressurizing chamber. The rotor blade rotates to prevent clogging of the discharge port to uniformly discharge dehydrated water and to push dehydrated water in the pressurization chamber toward the discharge port to increase the discharge pressure. Since the discharge pressure is increased by the rotor blade in this way, the dehydrator itself according to the present invention can perform the function of the feed pump for feeding dehydrated water without using a separate feed pump.

Further, in the dehydrator according to the present invention, when the dehydrated water pressure-feeding pipe is extended to the outlet and the dehydrated water is conveyed through the pressure-feeding pipe, the dehydrated water is continuously discharged from the discharge port, The pressure of the dehydrated water is increased, and finally the dehydration pressure acting on the tap water in the screen is increased, so that the pressure feeding pipe itself can exercise the function of the pressure adjusting means. As described above, the pressure regulating means in the dehydrator according to the present invention may be a dehydrated water discharge tube extended to the discharge port and capable of transferring the dehydrated water, so that the dehydrator also functions as a pump for feeding the dehydrated water .

Further, the dehydrator according to the present invention may further include a scraper installed on a screw rotated by the driving unit, wherein the scraper scrapes the inner surface of the screen while rotating together with the screw, Can be prevented. Accordingly, the use of water for cleaning the screen can be minimized and the utilization rate can be increased.

Further, the dehydrator according to the present invention may further include a propulsion assisting means selected from a groove, a projection, and a raker formed in the screw, and the propulsion assisting means formed on the screw may prevent slipping between the tap water and the screw And the distortion, shear force, and propulsion acting on the scum are increased, and dehydration can proceed smoothly.

Further, the dehydrator according to the present invention may further include at least one extrusion molding machine installed to communicate with the discharge port, and the molding machine may mold the dehydrated water into a predetermined shape or divide the dehydrated water into a small size using the discharge pressure discharged from the discharge port have. Since the pressure required in the extrusion process can be used by the discharge pressure of the discharge port generated by the rotation of the screw, a separate drive part for extrusion can be omitted in the extrusion molding machine itself and only the power necessary for cutting can be taken. And power demand can be reduced.

The dehydrator according to the present invention having the above-described configuration can simplify and simplify the construction and operation of the pressure regulating means for regulating the pressure acting on the weft, enhance the propulsion ability and the compression ability of the screw, It is possible to convey the dehydrated water by using the discharge pressure in the dehydrator and the discharge tube, so that the dehydrator itself can be used as the transferring means to easily transfer the dehydrated water to the required position, and the clogging of the screen can be minimized, It is possible to minimize the generation of wastewater and increase the operating rate, and it is expected that the dehydrated water can be molded into a shape requiring a dehydrated product or can be reduced in size to a small size.

1 is a side cross-sectional view of a dehydrator according to the present invention.
2 is a side sectional view showing a pressurizing chamber and a rotary blade included in a dehydrator according to the present invention.
3 is a side sectional view showing a pressurizing chamber and a rotor blade included in the dehydrator according to the present invention.
4 is a side cross-sectional view showing a press-feeding pipe coupled to a dehydrator according to the present invention.
5 is a conceptual diagram showing a scraper installed on a screw included in a dehydrator according to the present invention.
6 is a conceptual diagram showing a propulsion assistant means formed in a screw included in a dehydrator according to the present invention.
7 is a conceptual diagram showing a molding means included in the dehydrator according to the present invention.

Hereinafter, a dehydrator 1000 according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a side cross-sectional view of a dehydrator according to the present invention.

1, a dehydrator according to the present invention includes a cylindrical screen 100 having a plurality of fine holes formed therein, a screw composed of a rotary shaft 210 and a helical rotary blade 220, A discharge port 110 disposed at the other side of the screen and discharging dehydrated water to the outside of the screen, a discharge port 120 disposed at one side of the screen 100 for discharging the dehydrated water to the outside of the screen, And a discharge port (510) formed in the pressurizing chamber and discharging dehydrated water to the outside of the pressurizing chamber. The discharge port (510) communicates with the discharge port. The pressurizing chamber (500) communicates with the discharge port and receives and pressurizes the dehydrate discharged from the screen. And a pressure regulating means (700 of FIGS. 2 and 3) for regulating a discharge pressure so as to be discharged in a state in which the object to be dried is pressurized to a predetermined pressure, wherein the screen, the rotary shaft, the pressure chamber, (400), and the discharge port is provided with a rotary blade (600) which is rotated by a rotary shaft.

When the driving unit 300 is operated, dehydrated water is introduced into the screen through the inlet by the rotating screw and is dewatered in the screen. The dehydrated water is then propelled in the direction of the outlet, To the pressurizing chamber.

The dehydrated water discharged into the pressurizing chamber is discharged out of the pressurizing chamber through the discharge port and the discharge amount of the dehydrated product is controlled to be a predetermined discharge pressure by the pressure regulating means provided so as to communicate with the discharge port, The pressure inside the pressurizing chamber and the discharge pressure of the discharge port are increased stepwise and finally the dewatering pressure inside the screen can be increased.

That is, by regulating the discharge pressure of the dehydrated water discharged through the discharge port by operating the pressure regulating means, the discharge pressure at the discharge port is controlled in series, and the dehydration pressure acting on the filtered water pressed inside the screen is controlled, The water content of the dehydrated water can be controlled.

The discharge port may be a ring-shaped opening formed on a side surface between the screen and the rotary shaft, or a plurality of holes, so that if the pressure regulating means is provided to directly communicate with the discharge port, the same problem as in the conventional dehydrator is caused.

Therefore, in the present invention, a pressure chamber capable of collecting dehydrated water discharged from the discharge port and press-feeding the discharged dehydrated water to the discharge port is provided, and a pressure adjusting means is provided to communicate with the discharge port, So that the discharge pressure and the dewatering pressure can be adjusted easily and quickly.

2 is a side sectional view showing a pressurizing chamber and a rotary blade included in a dehydrator according to the present invention.

2, the dehydrator 1000 according to the present invention includes a pressurizing chamber 500 installed on the side of the discharge port 120a. Therefore, A plurality of discharge ports 120a formed in a ring-shaped discharge port (120b in FIG. 3) formed between the rotating shafts 210 or in a member between the screen and the rotating shaft and arranged mainly in a circular shape are spaced apart from a discharge port provided at one side of the pressure chamber And the required pressure until reaching the discharge port is also irregular, so that the discharge of dehydrated water may not be performed smoothly at the discharge port and the discharge port spaced apart from the discharge port adjacent to the discharge port.

Accordingly, in the present invention, at least one rotary blade 600 capable of cutting dehydrated water discharged from the discharge port is installed on the rotary shaft adjacent to the discharge port.

The rotary blade rotates together with the rotary shaft to cut dehydrated water discharged from the discharge port formed in the side wall of the pressurizing chamber to prevent the discharge port from clogging and to prevent the discharge port from being tilted to one place.

Further, the rotary blade may be installed on the rotary shaft on the front surface of the inner discharge port of the cylindrical screen.

The outlet in Fig. 2 is shown as a plurality of holes arranged in a circle around the rotation axis so as to communicate with the inside of the screen on the side wall of the pressurizing chamber.

The pressure regulating means 700 provided to communicate with the discharge port is a valve capable of controlling the degree of opening and closing. The gate of the valve is inclined so that the discharge pressure generates a component in the horizontal direction to indicate that the dehydrated product can be discharged smoothly have.

3 is a side sectional view showing a pressurizing chamber and a rotor blade included in the dehydrator according to the present invention.

3, the rotor blade 620 included in the dehydrator 1000 according to the present invention rotates together with the rotating shaft 210 and rotates the discharge water discharged from the discharge port 120b formed on the other side of the pressurizing chamber 500 It is possible to prevent dehydration from sticking to the inner wall of the pressurizing chamber and prevent dehydration of the inside of the pressurizing chamber by dewatering the inside of the pressurizing chamber, The water can be pushed to the discharge port 510 side to increase the discharge pressure.

The rotary blades constituting the screw are spiral, while the rotor blades can be constructed as a centrifugal flow type, such as a rotor blade of a centrifugal pump.

The discharge port is shown as a ring-shaped opening formed between the side wall of the pressurizing chamber and the rotating shaft.

The pressure regulating means 700 provided to communicate with the discharge port is an air cushion capable of pressurizing the discharge port side under a constant pressure by the pressure of the compressed gas filled in the cylinder and is made of an elastic body such as a hydraulic pressure or a spring And may be composed of regulating devices capable of pressurizing with a set pressure.

Thus, the pressure regulating means can be selected from among known pressure regulating means such as valves, an air cushion back pressure regulator, a hydraulic back pressure regulator, etc. without limitation.

4 is a view showing a state in which a feed pipe is installed in a dehydrator according to the present invention.

4, in the dehydrator 1000 according to the present invention, a dehydrated water feed pipe 800 capable of feeding dehydrated water is connected to the outlet port through which the dehydrated water is discharged from the pressurizing chamber, It is possible to extend dehydrated water to a place where dehydrated water such as a loading facility 900 of a vehicle, a product processing process, a drying facility, an incineration facility, an electric penetration dehydrator, etc. is required.

As described above, the dehydrator according to the present invention is capable of simultaneously performing the functions of the screw pump for feeding the solid material through the feed pipe because the dehydrated water is discharged through the discharge pipe at the same time.

Therefore, it is possible to dispense with the installation of a conveying facility such as a separate conveyor, and pressure is applied to the discharge port during the pressure feeding process through the pressure feeding pipe, so that the pressure feeding pipe itself can act as a pressure adjusting means.

However, the dehydrated water can not meet the discharge pressure required at the discharge port by only the required head by the discharge pipe, and in this case, the pressure required to add the underpressure calculated by subtracting the required pressure from the discharge pipe from the required discharge pressure Means can be installed to compensate for insufficient pressure.

For example, in order to achieve proper dewatering, a pressing force of 5 kg / cm 2 is required at the discharge port, whereas when the required pressure for feeding the dehydrated product in the feeding tube is 2.7 kg / cm 2, cm < 2 >, the required pressure can be satisfied.

The pressure regulating means may be selected from among the known apparatuses so as to be in communication with the discharge port and the installation position may be selected without restriction from any one of the discharge port side, the end of the discharge conveyance pipe, .

On the other hand, when an excessive pressure is applied to the discharge port due to the pressure transmission distance to the far or higher position, a rotor blade is installed inside the pressure chamber as shown in FIG. 3 and the dehydrated water is pushed toward the discharge port side The deficient discharge pressure can be compensated for by increasing the discharge pressure. Thus, the dehydrator according to the present invention can perform the function of the transfer pump for feeding the dehydrated water to another place.

Further, it is possible to additionally provide a feed means (not shown) capable of conveying solid matter such as a screw pump, a mono pump, an air pressure pump, etc. to supplement the deficient discharge pressure.

Pneumatic pump can compensate for deficient discharge pressure and can wash the pressure tube with strong compressed air to remove the residual dehydrated water in the pressure tube. Can be prevented.

5 is a view showing a scraper installed on a screw included in a dehydrator according to the present invention.

5, the screw 200, which is included in the dehydrator according to the present invention and is composed of the rotating shaft 210 and the rotating blades 220, scrapes the inner surface of the cylindrical screen 100 while rotating, And a scraper 610 that can scrape off and prevent clogging of the screen. Accordingly, the clogging of the screen 100 by the scum can be minimized, thereby minimizing the amount of washing water used to clean the screen and the downtime caused by washing.

FIG. 6 is a view showing propulsion assist means formed on a screw included in the dehydrator according to the present invention. FIG.

When the discharge pressure is increased by adjusting the pressure regulating means communicated with the discharge port, the pressure acting on the scooped object in the screen increases through the pressurizing chamber and the discharge port, so that the load of the screw 200 is increased and slippage occurs between the screw and the scooped object So that the pressing and pushing of the water can not be performed smoothly.

In the present invention, at least one of the rotary shaft 210 and the rotary vane 220 constituting the screw 200 may be formed with a circular, polygonal, or linear shape such as a semi-circular sphere, a polygonal groove, Various shapes of protrusions such as circular, polygonal, and linear shapes such as a semi-circular protrusion, a polygonal protrusion, and a linear protrusion are formed.

In addition, a plurality of lokers 250 may be disposed on at least one of the rotary shaft and the rotary vane to add driving force for pushing the scum to the discharge port side.

The lacquer may be in the form of a round, polygonal, wedge-shaped rod, or a plate shape of a triangular, polygonal, or semicircular shape. The shape of the lacquer is not limited to the shape of the plate, Can be selected and configured.

As described above, in the present invention, propulsion assisting means of various shapes and sizes such as grooves, projections, and lacquers are formed on the screw, and the friction force between the screw and the tap water and the pressing force, shearing force, and thrust acting on the tap water are increased, .

In addition, the propulsion assisting means constitutes a lacquer on the side of the inlet port having a relatively large driving force requirement, and a groove or a projection is formed in the screw on the side of the outlet port, which requires relatively small driving force and mainly requires a pressing force and a shearing force Various types of propulsion assisting means having different shapes can be formed on the screw of the screw.

FIG. 6 is a view showing a state where the lacquer 250 is formed on the front stage of the screw 200 included in the dehydrator, the linear groove 230 is formed in the middle stage, and the circular protrusion 240 is formed in the rear stage, The propulsion assisting means can appropriately distribute the frictional force and the thrust force depending on the degree of the collision.

As described above, the dehydrator according to the present invention further includes a propulsion assisting unit selected from a groove, a protrusion, and a lacquer formed in the screw, and the propulsion assisting unit prevents slippage between the obstacle and the screw, It can increase distortion, shear force and propulsion.

7 is a view showing the molding means included in the dehydrator according to the present invention.

In Fig. 7, a molding machine using a slit-shaped nozzle 810 for thinly spreading dehydrated water in the molding means included in the dehydrator according to the present invention is shown.

The feed pipe 800 branches so that dehydrated water can be supplied from both sides of the nozzle so that the dehydrated water can be evenly supplied to the narrow and long slit-shaped nozzle. The dehydrated water can be extruded through a slit-shaped nozzle into a thin plate like an electroosmotic dehydrator, a confectionery belt, and the like to facilitate dehydration, drying, molding, and cooking. Therefore, the molding machine of the present embodiment can be applied not only to the electroosmotic dehydrator but also to the confectionary process and the like.

Loop-type piping is preferable as the connection pipe of the slit-type nozzle so that the dehydrated water can be extruded with a uniform pressure because the dehydrated water is formed thinly and widely through the slit-shaped nozzle.

In the dehydrator according to the present invention, a wide variety of molding means (not shown) such as a plurality of tubular nozzles, a pellet molding machine, and the like may be installed at the tube of the dehydrated water pressure feeding tube to form a predetermined shape and size, It is possible to divide the dehydrated water into a small size by the pressing force which is pressure-fed by the dehydrator before being injected into the fermentation tank or the reactor.

The molding means is a pellet molding machine (not shown). The dehydrated water is directly fed to the pellet molding machine and extruded into pellets using the discharge pressure of the dehydrator.

As described above, the molding means is provided at the pipe end of the pressure-feeding pipe or at the discharge port side, and can transfer the dehydrated water to a desired place, and can be formed into a predetermined width, length, size and shape or can be divided into small sizes.

In addition, the molding means is not necessarily formed into a predetermined shape or standard product, but also includes a structure capable of dividing the dehydrated water into a small size suitable for incineration, cooking, and drying.

In the foregoing, the present invention has been described in detail based on the embodiments and the accompanying drawings. However, the scope of the present invention is not limited by the above embodiments and drawings, and the scope of the present invention will be limited only by the content of the following claims.

100: Screen 110:
120, 120a, 120b: Outlet 200: Screw
210: rotating shaft 220: rotating blade
230: linear groove 240: circular protrusion
250: Laker 300: Driving part
400: frame 500: pressure chamber
510: discharge port 600: rotating blade
610: Scraper 620: Rotor blade
700: pressure regulating means 800: pressure feeding tube
810: Nozzle 900: Loading facility
1000: Dehydrator

Claims (7)

A cylindrical screen having a plurality of fine holes formed therein;
A screw composed of a rotary shaft and a helical rotary blade;
A driving unit for rotating the screw;
An input port disposed at one side of the screen for inputting the filtered water into the screen;
A discharge port disposed on the other side of the screen and discharging dehydrated water to the outside of the screen;
A pressurizing chamber communicating with the discharge port to receive and pressurize the discharged dehydrated product;
A discharge port formed in the pressure chamber and discharging dehydrated water to the outside of the pressure chamber;
A pressure regulating means installed to communicate with the discharge port and regulating discharge pressure of the dehydrated product; And
And propulsion assist means rotated together with the rotary shaft to prevent slippage between the screws and to provide frictional force and shear force,
And the dehydrated water introduced into the screen through the inlet port is dewatered while being pressed by a rotating screw in conjunction with the driving part, the dewatered dehydrated water is discharged into the pressurizing chamber through the outlet, The discharge pressure on the discharge port side is raised and the discharge pressure raised on the discharge port side is increased by the discharge pressure of the dehydrated water discharged from the discharge port. And the dehydration pressure of the inside of the screen can be finally increased by raising the internal pressure of the pressurizing chamber and the discharge pressure of the discharge port stepwise. The method according to claim 1,
And at least one rotary blade installed on a rotary shaft adjacent to the discharge port,
Wherein the rotary blade prevents clogging of the discharge port and discharges dehydrated water uniformly while rotating. The method according to claim 1,
Further comprising at least one rotor blade installed on a rotary shaft inside the pressurizing chamber,
Wherein the rotor blade rotates to prevent clogging of the discharge port to uniformly discharge the dehydrated water and to push the dehydrated water in the pressurizing chamber toward the discharge port to increase the discharge pressure. The method according to claim 1,
Wherein the pressure regulating means is a dehydrated water pressure-feeding pipe extending from the discharge port and capable of transporting dehydrated water,
Wherein the dehydrator is capable of performing the function of a feed pump for feeding dehydrated water in parallel. The method according to claim 1,
And a scraper provided on the screw,
Wherein the scraper scrapes the inner surface of the screen while rotating together with the screw to prevent clogging of the screen. The method according to claim 1,
Wherein the propulsion assist means comprises:
A groove, a projection, and a lacquer formed on the screw. The method according to claim 1,
And a shaping means provided at a tube end or a discharge port side of the pressure feeding pipe and capable of forming dehydrated water using a discharge pressure or dividing the dehydrated water into a small size.

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