JP2652300B2 - Dehydration equipment for hydrated materials - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for dehydrating a hydrated material, in which water squeezed by a squeezing roll is absorbed by a water-absorbing belt.

[0002]

2. Description of the Related Art One or two sheets of felt (nonwoven fabric) or sponge utilizing capillary water absorption force are provided on the outer side of an upper and lower filter cloth belt which is mounted on a plurality of rolls and can run at least partially facing each other. There are a dehydrator in which the belt is mounted as a water-absorbent belt and a dehydrator in which the filter cloth belt itself is replaced with a water-absorbing felt or sponge-like belt.

More specifically, Japanese Patent Publication No. 56-15293 proposes a dewatering apparatus in which two sponge-like belts are attached to the outside of upper and lower filter cloth belts as a water-absorbing belt. The main dewatering section of the dewatering device is driven independently while facing each other, but runs in synchronization with each other, as viewed from the sandwiched dewatering object, an endless filter cloth belt, a sponge-shaped water absorbing belt and It consists of a perforated plate-shaped slat conveyor, sandwiches a material to be dehydrated between filter cloth belts, and pressurizes and dewaters the perforated plate-shaped slat conveyor while transporting the material. Here, the water dewatered under pressure is not held by the sponge-shaped belt but flows out to the tray.

As can be seen from the above-mentioned Japanese Patent Publication No. 56-15293, a conventional dewatering device uses a felt or sponge-like belt as a water-absorbing belt, but these belts use the water-absorbing power by capillary action. Because it is a belt, once it absorbs water, it has the disadvantage of releasing water again when pressure is applied and returning water to the hydrated material.Therefore, it is necessary to absorb the water while squeezing out the water by applying pressure. It is impossible in principle to use a water-absorbing belt, and the dewatering effect is not sufficiently exhibited even when a water-absorbing belt is used.

Japanese Patent Application Laid-Open No. 63-140281 discloses a method in which a water-absorbing polymer compound is attached to the surface of a pair of conveyer belts which rotate around each other, and the water-absorbing polymer compound is brought into contact with a water-absorbing substance. This shows a method of draining water. The draining action disclosed here is water removal by direct contact with a dehydration target based on the chemical action of a water-absorbing resin (polymer compound), and the action of physical force does not contribute to water removal. . Therefore, even if the method disclosed in the above publication is applied to the present application, a sufficient dewatering effect is not exhibited. In particular, when applied to the step of dehydrating organic sludge, it is expected that the sludge will adhere to the surface of the water-absorbing polymer compound of the water-absorbing belt. Due to the strength of the molecular compound, there is a problem that the polymer compound is not practical because it is scraped off by the scraper.

[0006]

SUMMARY OF THE INVENTION An object of the present invention is to provide a novel dehydrating apparatus which can eliminate all the above-mentioned disadvantages of the conventional dehydrating apparatus.

[0007]

SUMMARY OF THE INVENTION The above problems are solved by the dehydrating apparatus of the present invention. That is, the present invention
A water-absorbing belt having one or more sets of water-absorbing substances on the outside of an upper and lower filter cloth belt which is mounted on a plurality of rolls including at least one squeezing roll and is capable of running at least partially facing each other. in the dehydration processing apparatus sludge equipped with pairs by a plurality of rolls having said mill roll
Squeezing section formed between the upper and lower filter cloth belts
The volume of the squeezing section gradually decreases in the traveling direction.
Using a water-absorbent resin which is formed so as to be small and does not easily separate water by pressure as the water-absorbing substance, passes the water-absorbing belt together with the upper and lower filter cloth belts through the pressing roll, A sludge dewatering apparatus characterized in that the water squeezed out at (1) is absorbed by the water absorbing belt.

[0008] The dewatering treatment apparatus of the present invention is particularly characterized in that at least one of a plurality of roll groups is a pressing roll having a function of squeezing out moisture in a hydrated material. In addition, there is a water absorbing belt in a portion where the water in the hydrated material is squeezed by the squeezing roll.

The water-absorbing belt having a water-absorbing resin used in the dehydrating apparatus of the present invention is a belt manufactured by the following method. (1) A belt in which the surface of a running belt is coated with a water-absorbent resin that does not easily separate from water by pressure, or a belt in which a water-absorbent resin is molded into various shapes and embedded in the running belt. (2) A belt filled with a water-absorbent resin that does not easily release water under pressure. (3) A water-absorbent resin that does not easily release water under pressure is processed into a fibrous form and woven. A woven belt, a non-woven belt or a belt planted on a base cloth It is essential that at least one water-absorbing belt be present in the dewatering treatment apparatus of the present invention, but two or more belts may be present. May be a water-absorbing belt manufactured by a different method among the above (1) to (3).

The above-mentioned meaning that water is not easily separated by pressurization means that, for example, the pressure applied to the water-absorbing resin in the water-absorbing belt by a pair of opposing pressing rolls is about 50 kg / cm ^2. This means that water does not separate from the water-absorbing resin.

According to the dewatering apparatus of the present invention, water once absorbed by pressurization is not easily separated as in the case of using a conventional water-absorbent belt made of sponge or felt. It is now possible to absorb water in a wet state, so even if a water-absorbent belt is mounted on a plurality of squeezing rolls, the water retained in the water-absorbent belt is discharged and the water is again absorbed into the water-containing material. There is no fear of returning, and even with a single squeeze roll, a water-absorbing belt can be mounted on the side where pressure is applied, making it possible to dramatically increase the dewatering rate compared to the past. Was.

Since the hydrated material and the water-absorbent belt are in indirect contact with each other, the hydrated material adheres to the filter cloth belt, and even if the hydrated substance is removed by using a scraper, the scraper comes into contact with the filter cloth belt. Therefore, the water-absorbing resin can be treated without being damaged. The water-absorbent resin mounted on the water-absorbent belt has a water-absorbing capacity of 10 to 1000 times its own weight, but eventually becomes saturated, so replace the belt each time or use a water-absorbent resin regenerating device. The belt may be provided in the middle of the flexible belt and recycled.

Examples of the water-absorbing resin include methyl cellulose, polyvinyl methyl ether, polyethylene oxide, poly-N-dialkylacrylamide, sodium polyacrylate, saponified vinyl acetate-acrylate copolymer, and vinyl acetate-maleic acid. Saponified methyl copolymer, isobutylene-maleic anhydride copolymer, polyacrylonitrile hydrolyzate, starch-acrylonitrile graft copolymer saponified product, starch-acrylic acid graft copolymer, polysaccharide-acrylic acid graft copolymer There are polymers and crosslinked products thereof, and these can be used alone or in combination. Of course, when the above water-absorbent resin is applied to the surface of a filter cloth or the like, it may be dissolved in water or the like, and the resulting solution may be applied and dried to form a water-absorbent resin layer.
After the coating process, the resin layer may be subjected to a crosslinking treatment.

One kind of the water absorbing belt of the present invention is manufactured by coating the surface of the running belt with the above water absorbing resin. The traveling belt serving as a base material is formed of a material such as rubber, woven cloth, or a non-water-absorbing resin, and is premised on good adhesion to the water-absorbing resin. Also, when coating the running belt with the water-absorbent resin, if the adhesion affinity between the running belt and the water-absorbent resin is poor or the deformation of the water-absorbent resin layer is large, if the water-absorbent resin is directly coated, the resin will peel off and fall off Since there is a possibility that the adhesion surface may be subjected to interface treatment to improve the adhesion between the traveling belt and the water-absorbent resin, or first apply a resin with small deformation,
By coating the outside with a highly deformable resin, a highly durable water-absorbing belt can be manufactured.

Another type of the water-absorbent belt of the present invention is manufactured by embedding a water-absorbent resin formed into various shapes into a running belt. In this case, a notch for embedding the resin in a belt made of rubber or a non-water-absorbing resin may be provided, the resin may be bonded with an adhesive, or the water-absorbing resin molded into a chemical fiber is attached in a bead shape. An object may be embedded in the belt. In addition, it is better to increase the cross-linking density of the resin and reduce the amount of deformation due to water absorption in the bonded portion of the resin. The shape may be a bead, a polygon, or any other shape, and the shape is not particularly limited.

As another type of the water-absorbing belt of the present invention, when a water-absorbent belt is manufactured by filling a water-absorbent resin into a bag processed into a bag shape, the water-absorbent resin to be filled in the bag is used. As the shape, any of powder, bead, and fiber shapes or a mixture of those shapes is used. The bag-like belt may be of any type as long as it has an opening that does not allow the resin filled therein to flow to the outside, and a material such as a woven fabric or a wire mesh is used. Simply filling the water-absorbent resin into the bag-shaped belt may cause the distribution of the resin to be biased. Therefore, process the bags so that they are divided into small pieces, or connect the divided bags to form a single water-absorbent belt. Is manufactured, the unevenness of the resin is eliminated, and a uniform water absorbing ability can be expected.

In the case of spinning a resin and woven into a water-absorbent belt, which is another type of the water-absorbent belt of the present invention, the yarn spun from the water-absorbent resin has low strength. Fibers such as conventional polyester are used for warp yarns receiving tension as a woven fabric, and yarns spun from a water-absorbent resin are used for weft yarns. A simple plain weave is preferred as the woven fabric method, but a knit woven fabric may be used when the expansion and contraction of the weft spun from the water-absorbent resin due to absorption and dehydration is large.

In order to increase the strength of the water-absorbent resin fiber,
When spinning, a chemical fiber may be used as a core wire, and a yarn obtained by crosslinking and molding a water-absorbing resin so as to cover the core wire may be used. Further, in the case of a belt of another type of the present invention in which the water-absorbent belt is manufactured from a nonwoven fabric, a so-called felt may be formed by entanglement of short fiber-like water-absorbent resin fibers on both surfaces of a base fabric of chemical fibers. Alternatively, a short fiber water-absorbent resin fiber may be needle-punched on one surface of the base fabric of the chemical fiber, and the back surface may be resin-coated to prevent unthreading. Furthermore, on one side of the base fabric of the chemical fiber, a short fibrous water-absorbent resin fiber is planted,
Electro welding may be used.

Next, among the water-absorbent belts having the above-mentioned various water-absorbent resins, transition from hydrophobic to hydrophilic or vice versa depending on the temperature of methylcellulose, polyvinyl methyl ether, polyethylene oxide, poly-N-dialkylacrylamide and the like. When a water-absorbent belt is manufactured using a water-absorbent resin having the following characteristics, the water-absorbent resin has a water-absorbing capacity of at most about 10 to 200 times its own weight.
In this case, it is necessary to provide a regenerating device in the middle of the circuit to regenerate the resin. For example, there is a regenerating method using heat. It depends on the type of resin,
Generally, a resin containing water is heated to 35 to 70 ° C. to shrink the resin and release water taken in.
In that case, a resin that can be regenerated at a temperature close to room temperature is more thermally efficient.

On the other hand, among the water-absorbent belts having the water-absorbent resin, saponified crosslinked starch-acrylonitrile graft copolymer, crosslinked starch-acrylic acid graft copolymer, crosslinked polysaccharide-acrylic acid graft copolymer When a water-absorbing belt containing a super-absorbent polymer such as a coalesced or cross-linked acrylic acid copolymer is produced, the water-absorbing capacity of these water-absorbent resins is as large as 100 to 1000 times their own weight, so that the regeneration treatment is not performed. It is more advantageous to dispose after reaching the water absorption. When the water-absorbing belt is installed in the latter half of the compression zone of the dehydrating device, the absolute amount of water to be dehydrated is small, so that the life of the resin is extended, which is economically advantageous.

[0021]

The present invention is a dewatering treatment apparatus equipped with a water-absorbing belt having a water-absorbing resin which does not separate under pressure of 50 kgf / cm ² or less. The water-absorbing resin can easily absorb water once absorbed. Since there is no water separation, even if the water absorbing belt is mounted on a plurality of squeezing rolls, there is no concern that the water held in the water absorbing belt is discharged and wets the hydrated material again, and the pressure was applied. Since water can be absorbed in this state, a water-absorbing belt can be mounted on the side to which pressure is applied, and it is expected that the dewatering rate will be dramatically increased as compared with the conventional case.

[0022]

1 and 2 show an embodiment to which the present invention is applied.
In FIG. 1, water absorbing belts 4 and 5 coated with a water absorbing resin are mounted on the latter half of the compression section of the opposed roll type dehydrator. In the middle of the water-absorbent belt, there are provided absorbent resin regenerating devices 6 and 7, where the water-absorbent belt is repeatedly used by regenerating the water-absorbent resin.

The hydrate to be dehydrated is supplied to the supply box 1
After being adjusted to an appropriate thickness there, it is transferred to a pressing section having an opposing roll including the pressing roll 10.
Since the compressing section is designed so that the volume gradually decreases, the pressure is gradually applied to the hydrated material to be dehydrated. The latter half of the squeezing unit is a high-pressure dewatering unit, where the hydrated material is dehydrated by applying a higher pressure, but the squeezed water is immediately absorbed by the water-absorbent resin because the water-absorbing belt is attached, and the hydrated water is re-hydrated. No water is absorbed by objects. The dehydrated hydrated material is scraped and collected by the scrapers 8 and 9.

FIG. 2 shows a belt press type dehydrator with a water absorbing belt 4 mounted thereon. The absorbent resin regenerating device 6 is also provided in the middle of the water absorbing belt 4. In the horizontal roll, a pressure based on the tension of the filter cloth belt is generated on the roll surface, and the hydrous substance is dehydrated by the pressure. The water absorbing belt is
Although it is attached to only one side of the latter half of the squeezing roll 10, it can be attached to both sides, and it is more effective if it is attached to a plurality of squeezing rolls.

(Embodiment 1) FIG. 3 shows an embodiment of the present invention. The hydrate to be supplied to the hydrate supply box 11 may be either sludge prepared by adding a coagulant in advance and dehydrated sludge dehydrated by a usual dehydrator or centrifuge. The case of dewatered sludge obtained by dewatering excess sludge with a normal belt press dehydrator will be described. The moisture content of the used dewatered sludge was 85%. Put the dewatered sludge on the upper and lower filter cloth 1
10 mm thick between 2 and 13 and the opposite roll 1
It depressed and dewatered at 8 and 19. Water absorption around the fabric in the water-absorbing resin fibers of the opposing roll 18, 19 belts 14, 15
There Yes and hung, and to be able to absorb water squeezed with the opposing roll 18, 19 water absorbent belt 14, 15.
Reference numerals 6 and 7 denote regenerating devices for the water-absorbing resin.

[0026] FIG. 4 is a conventional felt made absorbent belt in the case of using absorbent belts woven with absorption water resin fiber dewatering performance when squeezed repeatedly dewatered sludge using the apparatus of FIG. 3 This is a comparison with the case of using. The water content of the sludge in the case of using a felt absorbent belt 8
Whereas saturated at 0% in the case of using the water-absorbing belt which is woven with a water-absorbent resin fibers of the present invention 85% for each moisture content of the sludge is repeatedly dehydration, 80%, 75%, 72 .
The dehydration proceeds to 5%, 71%,... And the water content decreases.

[0027]

In the dewatering device, a water-absorbing belt containing an absorbent resin is attached to the outside of the filter cloth belt, and a squeezing roll is provided in a roll group. Since it becomes possible to absorb the water squeezed out in a hung state, it is possible to expect a drastic improvement in the dehydration rate as compared with the conventional case, and it is possible to reduce the volume of hydrated substances.

[Brief description of the drawings]

FIG. 1 is a schematic view showing an example of a dehydration processing apparatus in which a water-absorbing belt is attached in the latter half of a facing roll type dehydrator.

FIG. 2 is a schematic view showing one example of a dehydration processing apparatus in which a water-absorbing belt is attached to a belt press type dehydrator.

Figure 3 is a schematic view showing an example of a dehydration treatment apparatus fitted with a water-absorbing belt which is woven with absorption water resin fibers on the counter-roller type dehydrator.

FIG. 4 is a graph comparing the performance when dewatered sludge is dewatered using the apparatus of FIG. 3 with the performance of a conventional apparatus.

[Explanation of symbols]

1,11 reproduction of the feeding box 2,3,12,13 filter cloth belt 4,5,14,15 absorbent belt 6,7 absorption water soluble resin system 8,9 16,17 scraper 10,18,19 squeeze roll

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Mutsuo Nakajima 1-6-27 Konan, Minato-ku, Tokyo Inside Ebara Infirco Co., Ltd. (72) Inventor Satoshi Miyashita 1-2-27 Konan, Minato-ku, Tokyo (56) References JP-A-63-146745 (JP, A) JP-A-63-140281 (JP, A) JP-A-56-105899 (JP, A) Jpn. (JP, U) Japanese Utility Model Showa 61-143791 (JP, U) JP-B 56-15293 (JP, B2)

Claims (1)

(57) [Claims] 1. One or one or more sets of water-absorbing substances, which are mounted on a plurality of rolls including at least one squeezing roll and which are at least partly opposed to each other and are capable of running in opposition to upper and lower filter cloth belts. In a sludge dewatering treatment apparatus equipped with a water-absorbing belt having a plurality of compression rolls,
Formed between the upper and lower filter cloth belts
Having a volume in the direction of travel.
By using a water-absorbing resin which is formed so as to be sequentially smaller, and does not easily separate water by pressure as the water-absorbing substance, the water-absorbing belt is passed through the pressing roll together with the upper and lower filter cloth belts, A sludge dewatering apparatus, wherein the water squeezed by a squeezing roll is absorbed by the water absorbing belt.