KR200365673Y1 - Sludge spindry device - Google Patents

Abstract

The present invention relates to a sludge dewatering device, and in particular, by forming a separate additional device in the sludge dewatering device for dewatering the water of the sludge contained in the waste water to increase the dewatering efficiency, as well as by dispersing the force applied to the pressed area during use It prevents damage to peripheral parts and always allows sludge to be dewatered through a certain gap.

Description

Sludge spindry device

The present invention relates to a sludge dewatering device, and in particular, by forming a separate additional device in the sludge dewatering device for dewatering the water of the sludge contained in the waste water to increase the dewatering efficiency, as well as by dispersing the force applied to the pressed area during use The present invention relates to a sludge dewatering device which prevents damage to peripheral parts and allows the sludge to be dewatered through a constant gap at all times.

In general, a large amount of sludge is contained in wastewater generated in a factory, and this sludge is dewatered by a sludge dehydrator and disposed of.

The sludge dewatering device is a flocculation tank that aggregates sludge contained in the wastewater by using a storage tank in which wastewater generated in a factory and sludge contained in the wastewater are temporarily stored, and a coagulant placed on the storage tank and introduced into the storage tank. And, when the sludge is agglomerated by the coagulation tank, the conveying belt for transporting the sludge to the place to be dewatered, and the main drive sprocket and the blood pressure formed at both ends to be discharged to the outlet when the sludge is introduced into the inlet by the conveying belt An upper drive unit and a lower drive unit which are rotated by a drive sprocket, and are respectively provided with a predetermined space on the bottom and the bottom of the main body, and a pressing plate which is connected to the surface of the drive chain and rotates integrally with the drive chain to compress the sludge, Guide rollers located on the outer circumferential surfaces of the upper and lower driving units, respectively In the course of rotation, and rotation while maintaining a constant trajectory along consists of the moisture generated in the sludge by absorbing the filtration bleb.

The sludge dewatering device can be used to dewater the sludge using the sludge dewatering device configured as described above. However, the sludge is compressed and dewatered between the main driving sprockets of the upper and lower driving parts. Therefore, in the conventional dewatering device, when compressing the sludge, a lot of force is generated on the main drive sprocket side, so that other peripheral parts such as the connection part of the drive chain or the bearing are separated or damaged, thereby shortening the product life.

In addition, each cylinder is provided in the upper drive section and the lower drive section. Since the cylinder is always in a state of being pressurized by the main drive sprocket side, there is a gap between the upper drive section and the lower drive section where the sludge is compressed and dewatered. It was not always constant. As a result, a load due to overpressure is generated, which shortens the life of the product.

In addition, the filter cloth for absorbing and filtering the water of the sludge while rotating by the guide roller is configured only to absorb water, so that it is not torn or restoring for long periods of use, so that the upper and lower driving parts are not horizontal. There is a problem that can not easily drain the water generated during dehydration.

Accordingly, an object of the present invention is to conceive in view of the above-described conventional problems, and to form an auxiliary drive sprocket around the main drive sprocket which is substantially depressurized and dehydrated of the sludge, and the force is dispersed by the auxiliary drive sprocket. It is to provide a sludge dewatering device to allow the compression dehydration to proceed.

Another object of the present invention is to form a separate screw device that can move the main drive sprocket up and down a certain section of the upper drive, and when using this, the gap between the upper drive and the lower drive is always made constant by the screw device, It is to provide a sludge dewatering device through which the sludge passing through the gap is squeezed out so that the device does not overdo it.

It is still another object of the present invention to provide a sludge dewatering device that forms a layer between nonwoven fabrics of the filter cloth so that it can be continuously performed by self-resilience without being damaged even in long-term use.

Still another object of the present invention is to provide a sludge dewatering device that allows the upper drive unit and the lower drive unit to have a predetermined inclination angle so that the water of the sludge can be drained smoothly.

1 is a general configuration of the sludge dewatering apparatus according to the present invention,

Figure 2 is an enlarged view of the main portion of the sludge dewatering apparatus according to the present invention,

Figure 3 is a perspective view of the pressing plate according to the present invention.

(Explanation of symbols for the main parts of the drawing)

10,10a; Auxiliary drive sprockets 11,11a; Auxiliary Chain

20; Reduction gear 21; screw

22; Casing 30; Non-woven

31; Layer 40; Home

100; Main body 110; Storage tank

120; Flocculation tank 130; Conveying belt

200; Upper drive section 210,310; Main drive sprocket

220,320; Drive chain 230,330; Blood Drive Sprocket

300; Lower drive unit 400; Press plate

500,500a, 600; Filter cloth 510,610; Guide Roller

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an overall configuration diagram of a sludge dewatering device according to the present invention, Figure 2 is an enlarged view of the main portion of the sludge dewatering device according to the present invention, Figure 3 is a perspective view of the pressing plate according to the present invention.

The sludge dewatering device of the present invention is also contained in the wastewater using a storage tank 110 in which wastewater generated in a factory and sludge contained in the wastewater are temporarily stored, and a coagulant placed in the upper portion of the storage tank 110 and introduced into the wastewater. Agglomeration tank 120 to agglomerate the sludge, a transfer belt 130 for transporting the sludge to a place to be dewatered when the sludge is agglomerated by the agglomeration tank 120, and the sludge is inlet by the transfer belt 130 The main drive sprockets 210 and 310 and the driven sprockets 230 and 330 formed at both ends are rotated by the drive chains 220 and 320 so as to be discharged to the discharge port 150 when they are injected into the 140. The upper drive unit 200 and the lower drive unit 300, which are provided with a predetermined space on the upper and lower ends of the main body 100, respectively, are connected to the surfaces of the drive chains 220 and 320 and rotate integrally with the drive chain. Press plate to press the sludge 400 and 410, respectively, which are positioned on the outer circumferential surfaces of the upper driving unit 200 and the lower driving unit 300, are rotated while maintaining a constant track along the guide rollers 510 and 610. It is made of filter cloth 500, 500a, 600 for absorbing and filtering water, and basically operates as in the prior art.

However, the present invention is to form a separate additional device in the sludge dewatering device for dewatering the water of the sludge contained in the waste water so that the sludge can be dewatered more effectively, as shown in Figure 1 to Figure 3 upper drive unit 200 ) Are located near the main drive sprockets 210 and 310 sides of the lower drive unit 300, respectively, and are connected to the main drive sprockets 210 and 310 by the auxiliary chains 11 and 11a, and rotate. Auxiliary drive sprockets 10 and 10a are formed which distribute the forces generated in the main drive sprocket.

The filter fabric 500, 500a, 600 positioned on the outer circumferential surface of the upper driving unit 200 and the lower driving unit 300 has a layer 31 stacked between the nonwoven fabrics 30, and the layer 31 is It has its own resilience and has a tough performance.

The main drive sprocket 210 of the upper drive unit 200 is coupled to the reduction gear 20 driven by the drive motor 23, the reduction gear 20 and the screw 21 to rotate when the reduction gear is driven and The upper drive unit 200 by the casing 22 for vertically moving the main drive sprocket 210 of the upper drive unit 200 while moving up and down by the screw 21 which is screwed with the screw 21 and rotates. And a gap between the lower driver 300 and the lower driver 300.

In addition, the upper and lower driving parts 200 and 300 have an inclination angle of 10 to 20 ° when viewed from the front so that the water is easily drained when the sludge is dehydrated in the process of discharging the sludge through the inlet. It is preferable to have an inclination angle of 10 degrees.

The pressing plate 400 is used to be attached to the surface of the drive chains 400 and 410 of the upper and lower driving units 200 and 300, respectively, and a plurality of dripping grooves 40 are formed at regular intervals on the front and rear surfaces. The water drain groove 40 has a configuration inclined so that water generated in the sludge can be drained downward.

In order to use the present invention configured as described above, the gap formed between the upper and lower driving parts 200 and 300 must be adjusted before using the first sludge dewatering device. Referring to this operation, when the power is applied to the drive motor 23, the reduction gear 20 is driven, the screw 21 is rotated by the reduction gear 20 is driven.

Then, the casing 22 screwed with the screw 21 moves up and down, and the main drive sprocket 210 of the upper drive part 200 is connected to the lower end of the casing 22 which moves up and down, so that the upper and lower sides of the screw 21 are connected. The main drive sprocket 210 is raised or lowered according to the moving direction. In this case, a gap between the upper driving unit 200 and the lower driving unit 300 may be formed to be suitable for dewatering the sludge.

Then, the sludge introduced into the inlet 140 through the conveying belt 130 is dewatered by the upper driving unit 200 and the lower driving unit 300 in the process of being transferred to the outlet 150, and the filter cloth 500 according to the present invention. The moisture generated in the sludge is absorbed and filtered by the nonwoven fabric 30 of the 500a and 600, and the rarer 31 is restored to the state before pressing again.

On the other hand, the pressing plate 400, 410 is the water generated while pressing the sludge is guided to the water drain groove 40 is drained to the outside and at the same time because the upper drive unit 200 and the lower drive unit 300 has a constant inclination angle Easy draining process.

The sludge is the most pressing force between the main drive sprocket 210, 310 of the upper, lower drive unit 200, 300 before being discharged to the discharge port 150, wherein the main drive sprocket and the auxiliary chain (11) The force is distributed because the auxiliary drive sprockets 10 and 10a, which are connected to the 11a) and rotate together with the main drive sprockets 210 and 310, are driven.

As described above, according to the present invention, the auxiliary drive sprocket is formed around the main drive sprocket which is substantially depressurized by the sludge, and the force is dispersed because the auxiliary drive sprocket presses and dewateres the sludge together with the main drive sprocket. This prevents damage to peripheral components and thus extends the service life.

In addition, since the gap between the upper drive part and the lower drive part is always kept constant by a separate screw device that can move the main drive sprocket up and down a certain period, the sludge passing through the gap is dehydrated like a squeezing device. There is no going on.

In addition, since a layer is formed between the nonwoven fabrics of the filter cloth, it is not damaged even when used for a long time, and it is restored by self-resilience even after absorbing and absorbing moisture while compressing the sludge. You can do it.

In addition, since the upper drive unit and the lower drive unit dehydrates the sludge that is always maintained while maintaining a constant inclination angle, there is an effect such that water generated during sludge dewatering can be easily drained.

In the above described the present invention with reference to a specific preferred embodiment, the present invention is not limited to the above embodiments and various changes and modifications made by those skilled in the art without departing from the spirit of the present invention Make sure you can.

Claims (5)

Coagulation tank for aggregating the sludge contained in the waste water using the storage tank 110, the sludge contained in the waste water generated in the factory and the waste water temporarily stored, and the coagulant is placed in the upper end of the storage tank (110) ( 120 and the transfer belt 130 for transporting the sludge to the place to be dehydrated when the sludge is agglomerated by the coagulation tank 120, and discharged when the sludge is introduced into the inlet 140 by the transport belt 130 The main drive sprockets 210 and 310 and the driven sprockets 230 and 330 formed at both ends so as to be discharged and moved to the 150 are rotated by the drive chains 220 and 320 and the upper and lower bodies 100 and 150. Compression plate for pressing the sludge while being connected to the upper drive unit 200 and the lower drive unit 300 and the drive chains 220 and 320 respectively, which are respectively provided with a space therebetween and rotated integrally with the drive chain ( 400 and 410 and the upper driving unit 2 00) and filter cloths 500 and 500a respectively positioned on the outer circumferential surfaces of the lower driving unit 300 and absorbing and filtering the moisture generated in the sludge while rotating and rotating while maintaining a constant trajectory along the guide rollers 510 and 610. In the sludge dewatering device consisting of 600, Located near the main drive sprockets 210 and 310 sides of the upper drive unit 200 and the lower drive unit 300, respectively, and connected to the main drive sprockets by the auxiliary chains 11 and 11a, Sludge dewatering device characterized in that the auxiliary drive sprocket (10) (10a) is formed to distribute the force generated in the drive sprocket. The filter fabric 500, 500a, 600 positioned on the outer circumferential surface of the upper driving unit 200 and the lower driving unit 300 has a layer 31 formed between the nonwoven fabrics 30. Sludge dewatering device. According to claim 1, wherein the main drive sprocket 210 of the upper drive unit 200 is engaged with the reduction gear 20 driven by the drive motor 23, the reduction gear 20 is rotated when the reduction gear is driven The upper drive unit 200 by the casing 22 for vertically moving the main drive sprocket 210 of the upper drive unit 200 while moving up and down by the screw 21 and the screw coupled to the screw and rotates. Sludge dewatering device, characterized in that the gap between the main drive sprocket 210 of the adjustment. The sludge dewatering device of claim 1, wherein the upper and lower driving parts (200) (300) have an inclination angle of 10 to 20 ° when viewed from the front. According to claim 1, the pressing plate 400, 410 used to be attached to the surface of the drive chains 220, 320 of the upper, lower drive unit 200, 300, a plurality of water at regular intervals on the front and rear surfaces. Sludge dewatering device, characterized in that the drain groove 40 is formed, the water drain groove 40 is inclined downward.