KR960008352B1 - Water recycling system for washing machine - Google Patents

Abstract

The device recycles the water which is used for cleansing the sludge in a dehydrator. The device includes a sludge feeder(10), a water recycling part(300) and a dehydrating part(20) for dehydrating the sludge by pressurizing belts(22,23) and removes the sludge by a scraper(24) and an injection nozzle(25). A guide tank(310) is installed at the lower part of the dehydrating part(20). A pump(320) and a filter(330) are connected to the guide tank(310) for supplying recycled water again to the nozzle(25).

Description

Washing water regeneration system of dehydrator

1 is a block diagram showing a general dewatering system.

FIG. 2 is an enlarged side view showing the reclaimed water portion, which is a main part of FIG.

FIG. 3 is a partially cutaway cross-sectional view of the front view of a partially cutaway portion of FIG. 2.

Figure 4 is a block diagram showing a washing water regeneration system of the present invention dehydrator.

FIG. 5 is a plan view showing a water regeneration unit that is a main part of FIG.

FIG. 6 is a sectional view of the reclaimed water portion, which is a main portion of FIG.

FIG. 7 is an enlarged cross-sectional view showing an enlarged portion of FIG. 5.

8 is an enlarged cross-sectional view showing an enlarged portion of FIG.

* Explanation of symbols for main parts of the drawings

10: sludge supply unit 11: agitator

12: stirrer motor 13: gravity dewatering tank

20: belt pressurized dehydration part 21: drive motor

22,23: upper and lower pressure supply valve 24: scraper

25: spray nozzle 300: water for regeneration

310: guide tank 320: compression pump

330: filter 340: play means

350: connection means

The present invention relates to a dewatering system for dewatering sludge having a high moisture content by a pressurized belt, and more particularly, to a washing water regeneration system for a dehydrator for regenerating water for washing the dehydrated sludge without remaining in the compressed surface of the pressurized belt. It is about.

In general, a dewatering system using a pressurized belt for dewatering sludge having a high moisture content is a sludge supply unit for constantly supplying a high water content sludge solution stirred in the stirrer 11 as shown in FIGS. 1 to 3. 10 and the sludge solution supplied from the sludge supply unit 10 is dewatered by transferring the upper and lower parts rotated while being pressed by the driving motor 21 to the pressure surfaces formed between the pressure belts 22 and 23. And a belt pressurized dewatering unit 20 which is removed by the scraper 24 and the spray nozzle 25, and a regeneration water unit 30 which regenerates the washing water sprayed from the spray nozzle 25.

The sludge supply unit 10 stirred the sludge having a high moisture content by driving the stirrer motor 12 installed in the stirrer 11, the gravity dewatering tank 13 is installed in the lower portion of the stirrer 11, the stirrer ( Sludge solution 11 agitated and discharged in 11) was supplied to the gravity dewatering tank 13 to be gradually dehydrated by gravity and transferred in the direction of the belt pressurized dehydration unit 20.

The belt pressurized dewatering part 20 is a pressure formed between the contact surface of the upper and lower pressure belts 22 and 23, in which the gravity dewatering tank 13 of the sludge supply part 10 is rotated by the drive motor 21. Located at the starting point of the surface, the scraper 24 and the injection nozzle 25 were installed after the end of the pressing surface.

The belt pressurized dewatering unit 20 is a drive motor when the gravity dewatered sludge solution in the gravity dewatering tank 13 is located at the starting point of the pressurized surface formed between the upper and lower contact belts 22 and 23. The upper and lower parts rotated by 21 are pressurized on the pressurized surfaces of the pressure belts 22 and 23, and the dewatered sludge residues are removed from the stripper 24 provided after the end of the pressurized surface. The upper and lower parts of the scraper 24 were attached to the upper and lower pressure belt surfaces without being removed from the scraper 24, and the sludge residue was washed by the water sprayed strongly by the spray nozzle 25.

However, since the belt pressurized dewatering part requires a large amount of the washing water sprayed at a strong pressure from the spray nozzle, the belt pressing dewatering part needs a regeneration water part for regenerating and utilizing the washing water.

Conventional water for regeneration 30, which implements the above needs, as shown in Figures 1 to 3, the guide tank 31 is provided in the lower portion of the belt pressure dehydration unit (20). The free end of the guide pipe 32 fastened to the lower part of the guide tank 31 is positioned inside the strainer net 34 of the strainer 33, and the strainer net 34 of the strainer 33 is separate. The filter motor (M) was mounted and connected, and the water storage tank 35 was installed at the lower portion of the filter 33 so that the filtered regeneration water was stored while passing through the strainer network 34. The water storage tank ( In the conduit 35, a pressurized pipe 37 to which the compression pump 36 was fastened was connected so that the filtered regeneration water was fed to the injection nozzle 25.

In the regeneration water unit 30, the washing water sprayed from the injection nozzle 25 of the belt pressurized dewatering unit 20 washes the sludge residues, falls naturally and flows into the guide tank 31. 31) the washing water introduced into the strainer network 34 of the filter 33 through the guide pipe 32 connected to the lower portion, and the washing water containing the sludge residue introduced into the strainer network 34. The filter was filtered while flowing outward from the inside of the strainer network 34 rotated by the filter motor (M), and the regenerated water filtered while passing through the strainer network 34 is a water storage tank 35 mounted at the bottom thereof. It was stored in the water to form a constant surface, the regeneration water which formed the constant surface was pumped to the injection nozzle 25 through the pressure feed pipe 37 to the driving force of the compression pump 36 was recycled.

However, such a conventional dewatering system, first, because the capacity of the water storage tank separately installed to store the regeneration water passed through the filter should be such that the water can be circulated at least once, Larger, increased space installation cost, and second, because the sludge waste water was introduced through the strainer network opening of the filter installed to rotate around the horizontal axis to filter the sludge contained in the washing water Sludge residues larger than the size of the strainer mesh among the residues are not filtered and gradually accumulate inside the strainer mesh, which causes the strainer to block the strainer mesh and the unfiltered washing water overflows through the opening of the strainer mesh. 유입 Flow into inside of tank In addition, since the washing water stored without being filtered in the water storage tank is directly supplied to the injection nozzle by the compression pump, the nozzle hole is clogged and the washing efficiency is lowered. Also, it is difficult to clean the nozzle hole of the injection nozzle. Third, because the overall regeneration water was installed in the lower part of the belt pressurized dehydration part to store the washing water due to the natural fall, the entire structure of the frame was raised to the upper part, and there was a problem that the stability was lowered.

An object of the present invention is to solve the conventional problems as described above, firstly, since the compression pump is directly connected between the guide tank and the filter, a large capacity water storage tank, which was previously required, is not required, thereby reducing the space installation cost. Second, the filter is installed on the side wall surface of the stirrer so that the strainer network of the filter is rotated about the vertical axis by the stirrer motor, and the washing water containing the sludge residue is filtered from the outside of the strainer network to the inside. In order to improve the spraying efficiency by supplying the filtered regeneration water to the injection nozzle, and thirdly, since the filter for regenerating the washing water is installed on the side wall of the stirrer, the overall structure of the frame is lowered to improve the stability. To provide a water regeneration system.

Hereinafter, described in detail by the accompanying drawings the technical configuration of the present invention.

The washing water regeneration system of the dehydrator of the present invention, as shown in Figure 4, the sludge supply unit 10 for constantly supplying a high water content of the sludge stirred in the stirrer 11, and is supplied from the sludge supply unit 10 The sludge solution that is rotated while being pressurized by the driving force of the driving motor 21 is transferred to a pressing surface formed between the upper and lower pressure belts 22 and 23 to be dehydrated and removed by the scraper 24 and the spray nozzle 25. The belt pressing dewatering unit 20 and the regeneration water unit 30 for regenerating the washing water sprayed from the spray nozzle 25 are not much different from the conventional one. However, the present invention has the features of the technical configuration of the regeneration water unit 300 as described above as follows.

That is, the guide tank 310 is installed in the lower portion of the belt pressurized dehydration unit 20 so that the washing water sprayed from the spray nozzle 25 is naturally dropped and collected after washing the sludge residue. In order to connect the compression pump 320 and the filter 330 in turn to the water to be recycled back to the injection nozzle (25).

The washing water regeneration system of the dehydrator of the present invention as described above, so that the configuration and operation relationship of the sludge supply unit 10 and the belt pressurized dehydration unit 20 is the same as the conventional one to be omitted, and reference numeral 12 shown in the drawing is agitator Motor, and 13 is a gravity dehydration tank.

Meanwhile, as shown in FIG. 5 and FIG. 6, the filter 330 of the regeneration water unit 300 includes a fastening hole 332 formed in the dividing wall 331 that bisects the inside of the filter 330. The inflow pipe 333 to which washing water is pumped is connected to the inflow chamber A formed at one side of the separating wall 331, and the regeneration water is formed at the outflow chamber B formed at the other side of the separating wall 331. The outflow pipe 334 is fastened, and a strainer network 335 with one side of the center open in the inflow chamber A is rotatably fastened to the fastening hole 332 of the separating wall 331. Brush 336 is to be installed on the outer peripheral surface of (335).

In this regeneration water unit 300, the washing water guided by the guide tank 310 by the compression force of the extrusion pump 320 is pumped into the inlet chamber (A) of the filter 330 through the inlet pipe 333 In addition, the washing water pumped into the inflow chamber (A) of the filter (330) is filtered by passing inward from the outside of the strainer network (335) which is fastened to one side of the separating wall (331) and rotated. The water passes through an open portion on one side of the center portion of the strainer network 335 and is pumped into an outflow chamber B formed on the other side of the separating wall 331. The recycled water transported into the outflow chamber B is an outflow pipe ( 334 is pushed back into the spray nozzle 25 and reused.

As the washing water regeneration operation continues as described above, sludge residues contained in the washing water accumulate in the mesh of the strainer network 335 as time passes, but the mesh is removed by the brushy 336 installed on the outer circumferential surface of the strainer network. This wash prevents the regeneration efficiency from lowering.

In addition, as shown in FIG. 7 and FIG. 8, the regeneration water unit 300 is provided with the filter 330 in the stirrer 11 as a clearance means 340 that can be detached from the gap, and the filter 330 ) Strainer network 335 is preferably connected to the stirrer motor 12 of the stirrer 11 by the connecting means 350 to be rotated.

That is, the clearance means 340, the fixing stand 341 is installed on the side wall surface of the stirrer 11, the transfer table 342 is formed detachably on the fixing table 341 is the side wall surface of the filter 330 A clearance bolt 343 for fastening the clearance length is fastened between the sidewall surface on which the holder 341 and the carrier 342 are spaced apart, and the holder 341 and the carrier 342 slide. The fixing bolt 345 is fastened to the transfer groove 344 formed to penetrate through the vertical connecting surface.

The connecting means 350, the rocket 351 is fastened to the rotation shaft of the stirrer motor 12 and the strainer network 335, respectively, the chain 352 is connected to the sprocket 351 is agitator motor ( The driving force of 12) is transmitted to the strainer network 335 without loss.

The clearance means 340 and the connecting means 350, the filter 330 can be easily separated from or separated from the body of the stirrer 11 for cleaning the interior of the filter 330 or parts replacement.

As described above, the washing water regeneration system of the dehydrator of the present invention, first, by directly connecting the compression pump between the guide tank and the filter, there is no need for a large capacity water storage tank conventionally required to reduce the space installation cost Secondly, as the strainer network of the filter is rotated by the driving force of the stirrer motor by installing the filter in the stirrer, the filter motor which is conventionally used separately is not required, and the manufacturing cost is reduced. As the washing water containing the sludge residues is filtered inward from the inside, the filtered regeneration water is stably supplied to the injection nozzle to improve the washing efficiency of the pressurized belt surface. By installing on the side wall of the frame, the overall structure of the frame It will be useful to improve stability.

Claims (5)

The sludge supply unit 10 for constantly supplying the sludge solution stirred in the stirrer 11 and the sludge solution supplied from the sludge supply unit are transferred to the pressurized surfaces of the upper and lower pressure belts 22 and 23 to be dehydrated and scraper ( 24, a belt pressurized dewatering unit 20 removed by the spray nozzle 25, and a regeneration water unit 300 which regenerates the washing water sprayed from the spray nozzle 25, wherein the regeneration water unit 300 is equipped with a guide tank 310 in the lower portion of the belt pressurized dehydration unit 20, the washing water regenerated by connecting the compression pump 320 and the filter 330 to the guide tank in turn to the injection nozzle Washing water regeneration system of the dehydrator characterized in that it is to be pumped. The filter 330 of claim 1, wherein a fastening hole 332 is formed in the dividing wall 331 for dividing the inside of the filter 330, and an inflow chamber A formed at one side of the dividing wall 331. An inflow pipe 333 through which washing water is pumped is connected to the inflow pipe, and an outflow pipe 334 through which the regeneration water flows is fastened to the outflow chamber B formed at the other side of the separating wall 331, and the inflow chamber A At the center, one side of the center strainer net 335 is rotatably fastened to the coupling hole 332 of the separating wall 331, the outer peripheral surface of the strainer net 335 is characterized in that the brush 336 is installed Washing water regeneration system of dehydrator. According to claim 2, wherein the filter 330 is installed in the stirrer 11 by the clearance means 340 to adjust the clearance distance, the strainer network 34 of the filter 330 to the connecting means 350 Washing water regeneration system of the dehydrator, characterized in that to be rotated by connecting to the stirrer motor (12) of the stirrer (11). According to claim 3, The clearance means 340 is attached to the side wall surface of the filter 330, the transfer table 342 is detachably fastened to the fixing table 341 is coupled to the side wall surface of the stirrer 11, A clearance bolt 343 capable of adjusting the clearance length is fastened between the sidewall surfaces at which the holder 341 and the carrier 342 are spaced apart from each other, and the upper and lower joint surfaces on which the holder 341 and the carrier 342 slide. Washing water regeneration system of the dehydrator, characterized in that the fixing bolt 345 is fastened to the conveying groove 344 formed in the. The sprocket 351 is fastened to the rotation shafts of the stirrer motor 12 and the strainer network 335, and the chain 352 is connected to the sprockets 351. Washing water regeneration system of the dehydrator characterized in that the driving force of the stirrer motor 12 is transmitted to the strainer network (335).