KR101773271B1 - Method for unloading water-containing bulk material - Google Patents

Abstract

We propose an effective treatment method of water and suspended water that unavoidably occurs at the unloading of bulk ash. In the unloading of the functional bulk material such as ore or coal from the cargo ship by using the grab bucket 5 of the bridge type crane or the unloader, in the unloading operation, the suspension water Wm , The polymeric coagulant is added to the suspension water Wm to cause coagulation and agglomeration of the water and the powder particles of the suspension water Wm and then unloaded together with the bulk material.

Description

METHOD FOR UNLOADING WATER-CONTAINING BULK MATERIAL < RTI ID = 0.0 >

The present invention is characterized in that water is generated when a bulk material such as ore or coal containing moisture is intermittently or continuously unloaded from a carrier ship or a barge by a bucket of a legged crane, an unloader or a continuous unloader The present invention relates to an unloading method of a functional bulk material developed to solve an unloading fault occurring.

Most bulk materials such as ores and coal are imported from foreign countries, and most of them are transported by ships. Most of these bulk materials, especially ores and coal, have a high water content in recent years, and the water is separated from the bulk material in the transportation process and becomes in a state of being lodged in the bottom of the dock. As a result, in the middle or late of the unloading process by the unloader or the like, a depression is formed in the bulk material after the grab by the grab bucket for unloading, and a suspension water in the state where the powder particles and the water are turbid is generated There is a problem that the slurry state is not only a problem but also an unloading obstacle. This problem also occurs in the unloading process by the bucket of the continuous unloader comprising the bucket conveyor or the like.

Also, when heavy rain or the like occurs during unloading from the ship, regardless of whether or not unloading is continued, the bulk material becomes high water and the rainwater remains in the bottom of the dock, .

This is also the case in a country having a wet season, and unless a roof for covering a bridge type crane or an unloader is included including a ship, the bulk material during unloading becomes high water content, and eventually becomes a slurry state with continued unloading , There was a problem that unloading obstacle was reached.

To solve such a problem, there has been proposed a method as disclosed in Patent Documents 1 and 2, that is, when water is generated, the water is once pumped through a drainage device (aspirator), and then unloading is resumed Have been proposed.

Patent Document 1: JP-A-60-204526 Patent Document 2: Japanese Utility Model Notification Bulletin 50-13339

However, the float-up / drainage method proposed in Patent Documents 1 and 2 is a method in which a ship is moved to a place having a drainage (flooding) facility every time, or the drainage (flooding) And the water is pumped up from each porthole. Therefore, in addition to an increase in facility cost, there is a problem that drainage takes time.

In particular, the water is often repelled after the grabbing of the bulk material by the grab bucket during unloading, or at the depression caused by the excavation of the bulk material by the bucket of the continuous unloader, There is a problem that the unloading operation is repeatedly interrupted and resumed, and the operation efficiency is greatly reduced. Particularly, in recent years, ore or coal has been poor, for example, high water content has become the majority, and this problem is becoming more and more present.

In the prior art proposed in Patent Documents 1 and 2, only the water is supposed to be poured. However, after the gravity of the bulk material by the grab bucket or after the excavation of the bulk material by the bucket, (Slurry) into which powder particles having small particle diameters separated from the powder particles have flowed in. In this case, it is difficult to float in the conventional water pump, and this has been a definite obstacle to the unloading operation.

It is therefore an object of the present invention to propose an effective treatment method of water and suspending water which inevitably occurs at the unloading of the functional bulk material.

As an effective solution to overcome the above-described problems of the prior art and also as an effective solution in achieving the above object, the present invention relates to a method for efficiently and efficiently extracting a functional bulk material such as ore or coal from a cargo ship to a grab bucket of a bridge- In the case of unloading intermittently or continuously using a bucket of a continuous unloader, when suspending water in a state in which powder particles are suspended in water is generated during unloading operation, the polymer flocculant and / Characterized in that at least one of the water adsorbent is added to cause adsorption of at least water of the suspension water to coagulate, flocculate and / or suspend water in the water and the powder particles, and then unloads the water together with the bulk material We propose a unloading method of ashes.

In the unloading method according to the present invention,

[1] At least water can be adsorbed to the water adsorbent by adding only a polymer flocculant to the suspension water to cause coagulation / agglomeration of the water and the powder particles, or by adding only the water adsorbent to the suspension water .

In the method of the present invention,

[2] As the moisture adsorbent, a polymeric absorbent is used,

[3] The moisture adsorbent may be added in an amount of more than 0.5 to 3.3 mass% of the suspended water amount,

[4] It is preferable that the moisture adsorbent is added in an amount of 1.0 to 2.0 mass% of the suspended water amount.

Also,

[5] The polymer flocculant may be added in an amount of 0.4 to 1.0 mass%

[6] adding a polymer flocculant to the position where the suspension water is generated, and mixing and stirring the bulk material at another site to generate coagulated particles and aggregated particles to unload,

[7] A process for producing a suspension, comprising adding a water adsorbent to a site where the suspension water is generated, mixing the bulk materials at different sites,

[8] A method for producing a suspension, comprising: adding a polymer flocculant and a water adsorbent to a generation site of the suspension water to produce coagulated particles and aggregated particles by a polymer flocculant; At least adsorbing the water to the moisture adsorbent and then unloading,

[9] A method for producing a suspension, comprising adding a water adsorbing agent to a position where the suspension water is generated, reducing at least water in the suspension water, adding a polymer flocculant to generate coagulated particles and aggregated particles,

[10] It is considered that it is possible to provide a more preferable solution by setting the spectral ratio, which indicates the weight ratio of the bulk material to the weight of the suspension water containing the polymer flocculant and / or the water adsorbent, to 7 or more.

According to the method of the present invention having the above-described structure, even when the suspension water is generated in the loading port of the cargo ship during the unloading, at least one of the polymer flocculant and the water adsorbent is added, (Water, polymer flocculant, moisture adsorbent, and powder particles) together with other bulk materials are unloaded after causing the flocculation and / or adsorption (absorption / repair) of at least water on the water adsorbent, It is not necessary to carry out the scouring operation only for the suspended water.

Therefore, the unloading operation can be continuously performed without causing the unloading operation to be interrupted as in the prior art, so that the unloading operation efficiency can be remarkably improved.

In the case where only the polymer flocculant is used, adverse effects such as difficulty in mixing the starting materials due to adhesion can be avoided since the polymer flocculant and the powder particles of the ore react with each other to be smoothly transported. In addition, since the amount of use is at least good, there is an advantage such as a low cost.

On the other hand, since the polymer flocculant has a limited water content, it is required to increase or decrease the amount of the drug depending on the kind of the bulk material, There is a disadvantage to be.

On the other hand, when only the water adsorbent is used, there is an advantage that there is no upper limit to the amount of water absorption since water can be adsorbed as much by increasing the amount of the drug.

However, in addition to the high cost due to high unit cost and high usage, the polymer adsorbent, for example, splashes on the conveyor belt or makes voids or water segregation between the powder particles, and thus adversely affects the next step and the conveying line There is a disadvantage.

However, when the polymer flocculant and the water adsorbent are used in combination, the upper limit of the water content of the bulk material can be increased by adsorbing moisture in a range that can not be filled with the polymer flocculant into the water adsorbent, and the cost can be lowered compared with the case of using only the water adsorbent And there is an advantage that the influence on the next process and the conveying line can be reduced as compared with the use of only the moisture adsorbent.

1 is an explanatory diagram showing a state in which a bulk material in a cargo ship is unloaded using a grab bucket of an unloader.
2 is an explanatory view showing a state in which a bulk material in a cargo ship is unloaded using a bucket of a continuous unloader.
Fig. 3 is a conceptual diagram for explaining the action when the polymer flocculant or the water adsorbent is added to the suspension water.
4 is a conceptual diagram for explaining the action when both the polymer flocculant and the water adsorbent are added to the suspension water.
Figure 5 is a schematic diagram of the experimental vessel.
6 is an explanatory diagram of an unloading method using a grab bucket of an unloader according to the method of the present invention.
Fig. 7 is a view showing a name of a portion to be inserted into a dock of a continuous unloader. Fig.
8 is an explanatory diagram of an unloading method using a bucket of a continuous unloader according to the method of the present invention.
9 is an explanatory diagram of a preferred unloading method using a bucket of a continuous unloader according to the method of the present invention.
Figure 10 is an illustration of another preferred method of the present invention utilizing a grab bucket of an unloader.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described based on the points shown in the drawings.

1 or the like, ore or coal (hereinafter also referred to as " pomegranate ") referred to as a bulk material 2 contained in a cargo ship 1 of a cargo ship, When unloading is carried out using a bucket, generally, a water tank 3 consisting of water is generated in the lower part of the pumice deposits. When the unloading operation of the bulk material 2 proceeds and reaches the middle layer to the lower layer portion, a depression 4 is formed in a part of the bulk re-accumulation layer after being grabbed by the grab bucket. In the depression 4, It is known that the powdery particles separated from the ores of the shape are dispersed and the suspended water Wm in a suspended state is accumulated.

When the suspension water Wm is generated in the bulk re-accumulation layer in the hold, the unloading progresses and gradually becomes slurry, making it difficult to unload the unloader in the grab bucket 5 or the like. In addition, even if the slurry can be held by the grapple bucket 5 once, the slurry flows out from the hopper or the belt conveyor portion not shown in the unloader, and the operation of the unloader can not be continued. Particularly, this condition often occurs at the bottom of the hold 1, and it is often necessary to stop the unloading operation and to raise the water. This problem is also applicable to the unloading by the bucket of the continuous unloader that has been used recently instead of the unloading by the grab bucket.

As shown in Figs. 2 and 7, in the continuous unloader, the vertical support beam portion is inserted into the loading window 1, and unloading is carried out by continuous excavation by a plurality of buckets 5. Fig. The bucket 5 is connected via a chain so that the insertion length, scraping length and the like to the hold 1 can be adjusted by adjusting the length between the sprockets by means of a hydraulic cylinder mechanism. So that the depth adjustment can be performed. Further, the bucket 5 is rotated counterclockwise in the drawing while the excavation amount is adjusted at the drive link portion by driving by a separate driving device, and the surface of the raw material is excavated by the bucket 5, Unloading can be performed. The excavated bulk material is unloaded from the bucket elevator outside the ship.

In the lower part of the bulk sedimentation layer, it is separated from the bulk material in the transportation process, and the sediment is accumulated in the bottom of the dock (3), or the seawater is solidified by rainwater (3). When the unloading operation by the continuous unloader proceeds and reaches the middle layer to the lower layer portion, a depression 4 is formed in a part of the bulk redeposited layer after the excavation by the bucket, The suspended water Wm is generated. As the unloading progresses, the slurry gradually becomes slurry, making unloading difficult even by the bucket 5 of the continuous unloader.

That is, once slurried, even if it can be excavated by the bucket 5 like the grap bucket, it flows out from the hopper or the belt conveyor in the continuous type unloader, and the continuous unloader can not continue its operation do.

Therefore, in the present invention, when the suspension water Wm is generated, a predetermined amount of at least one of a polymer flocculant and a moisture adsorbent such as a polymer absorbent is added to the suspension water Wm in the depression 4, and, for example, (Water and powder particles) are collapsed to coagulate and aggregate to form a solid, and suspended water Wm is adsorbed (absorbed and repaired) in the water adsorbent, and unloaded together with the bulk material Thereby improving the efficiency of the unloading operation.

That is, according to the method of the present invention, it is possible to unload the coagulated / agglomerated particulate matter and / or the moisture adsorbent adsorbing the suspension water Wm together with the bulk material 2 such as a pomegranate.

Figs. 3 (a) to 3 (c) show the state in which the polymer flocculant A is added to the suspension water Wm containing the powder particles P. Fig. By this addition, as shown in Fig. 3 (b), the suspension water Wm condenses in such a manner that a part of the powder particle P is collapsed on the polymer expanded in the form of a branch of the molecular chain of the polymer flocculant A, Some of these small condensed particles 6 are formed. 3 (c), the agglomerated particles 7 having a large particle diameter are agglomerated (gathered) together with the lapse of time (progress of unloading) .

At this stage, the suspension water Wm becomes a solid state, and can easily be grabbed and scratched by the grab bucket 5 or the like, so that the suspension water Wm itself is also unloaded together with the bulk material.

3 (d) and 3 (e) show a state in which the water adsorbing agent B is added to the suspension water Wm containing the powder particles P. FIG. 3 (e), the water of the suspension water Wm is confined within the crosslinked structure of the water adsorbent B together with the powder particles P and is granulated into a swollen form.

That is, since the suspension water Wm is absorbed in the water adsorbent B and becomes a solid state (swollen state), it can be easily grabbed by the grab bucket 5, As shown in FIG. Likewise, the suspension water Wm can be excavated together with the bulk material 2 by the bucket of the continuous unloader.

In another embodiment of the present invention, at least one of the polymer flocculant and the water adsorbent is added to the suspension water Wm, and the pebble-like bulk material 2 in the vicinity of the depression 4 or the other part is placed in the grab bucket 5) and, if possible, stirring (grabbing by the grapple bucket and repeating the dropping operation) is preferable in order to promote the solidification described above and to improve the efficiency of the unloading operation.

In the continuous unloader, at least one of the polymer flocculant and the water adsorbent is added to the suspension water Wm, and the pebble-like bulk material 2 in the vicinity of the depressed portion 4 generated by the bucket excavation, (Operation of repeating switching of the scratching direction by the bucket) is preferably performed in order to facilitate the solidification described above and to improve the efficiency of the unloading operation.

As the water-soluble polymer flocculant used in the present invention, by adding the agent to the suspension water, an adsorption activity is caused in the powder by the electrostatic force and the hydrogen bonding of the polymer, and the crosslinking action between the particles is caused, And forming condensation particles can be used. For example, polyacrylamide-based (co-polymerized with acrylamide and sodium acrylate), polyvinylamidine-based, and amphoteric polymer-based flocculant, which are organic coagulants in powder, granule form or liquid form, It is preferable because it exhibits cohesive action. Of course, it may be mixed with an inorganic coagulant.

In addition, an acrylic acid cation polymer, an acrylamide cation polymer, a methacrylic acid polymer, a methacrylic acid amino ester cation polymer, and an amidine polymer may be used.

As the moisture adsorbent, for example, a superabsorbent polymer (SAP) can be used, a water absorption rate is fast, a high absorbability and a high water retention are provided, A polymer absorbent such as a polyacrylate (sodium, potassium) resin and the like, which does not substantially release moisture even when some force is applied thereto, is preferable. This polymeric absorbent has physical properties that do not exhibit stickiness even when moisture is adsorbed in the molecular structure after moisture absorption. In this sense, it is more preferable to use inorganic silica gel, activated alumina, zeolite, and the like. As this moisture adsorbent, a powdery or granular one is used.

In order to increase the contact area with the water and to increase the water absorption rate, it is preferable to use a powdery or granular material as the moisture adsorbent, Shall be less than 10 mm. More preferably 1 mm or more and 5 mm or less.

That is, when the particle diameter is less than 0.5 mm, scattering during use can not be effectively prevented. On the other hand, when the particle diameter is 10 mm or more, the surface area of contact with the water becomes relatively small and the water absorption rate tends to decrease. It takes too much time, and sufficient effect can not be obtained in a short time. Therefore, it is more preferably 1 mm or more and 5 mm or less.

However, when both the polymer flocculant in the suspension water Wm and the polymer absorbent in the form of the water adsorbent are added, as shown in Figs. 4 (a) to 4 (c) (f), the same effect can be finally obtained without distinction of adding the polymer flocculant first and adding the polymer absorbent late.

4 (a) to 4 (c), a polymeric coagulant and a polymeric absorbent for coping with water that can not be coped with only by the coagulant are added at the same time and stirred, whereby the collapse by the polymeric polymer of the powdery particles and the water- At the same time, surplus water is adsorbed by a polymer absorbent such as a water molecule. Finally, as shown in Fig. 4 (c), the aggregated particles and the swollen polymer absorbent become massive.

4 (d) to 4 (f), KURISAT C-333L (KURITA KOGYO Inc.) as an example of the polymer flocculant was firstly contained in the suspension water Wm, (Registered trademark) was added and stirred to cause condensation of powder particles and water molecules. Thereafter, Kurisat C-500L (registered trademark of Kurita Kogyo Co., Ltd.) as an example of a polymeric absorbent was added and stirred.

As a result, as shown in Fig. 4 (f), an agglomerate similar to that shown in Fig. 4 (c) in which the agglomerated particles and the swollen polymer absorbent were integrated into a mass was obtained.

Next, experiments performed to confirm the operation and effect of the present invention will be described.

This experiment was carried out using the iron vessel C shown in Fig.

As a function bulk ore, Brazilian Karajas iron ore, which is rich in water, is charged into the iron vessel C in a conical shape, deposited and added with water, and then grabbed precisely the center portion of the conical deposit, A water-soluble polyacrylamide-based polymer coagulant was added at the stage where a depression was made and the mixture was stirred (equivalent to suspension water).

In this experiment, even if only the polyacrylamide-based polymer coagulant was added to Karajas iron ore, the action of the powder particles and the water molecules to repel the polymeric polymer occurred, but it was still small and it was found that any treatment is necessary. Thus, stirring was carried out by shuffling the above-mentioned water retaining portion formed in the central depression portion by a shovel. Also, this shuffling operation simulates a repetitive operation of grabbing and opening by the grab bucket in the actual equipment.

The results of this experiment are shown in Table 1. As can be seen from the results of this experiment, simple addition of a polymer flocculant without agitation is less effective. On the other hand, when accompanied by stirring (30 to 80 seconds), the spectral ratio indicating the weight ratio of the bulk material to the weight of the suspension water is set to 7 or more. At this time, a better effect was obtained by adding a polymer flocculant in an amount corresponding to 0.4 to 1.0 mass% to the suspension water.

It was also found that when the polymer flocculant was added to the suspension water and then Karajas iron ore, which is another bulk material, was added thereto and mixed therein, the effect of addition was further improved.

In Table 1, when the ratio expressed by the weight ratio, that is, the ratio of the weight of the bulk material contained in the suspension water is 7 or more, the solidification and aggregation of the powder particles progress sufficiently and the aggregated particles can be reliably obtained. Further, the aggregated particles are aggregated bodies having a strength enough to be collected by, for example, a grappling bucket or the like.

Other experiments performed to confirm the operation and effect of the present invention will be described.

This experiment was conducted by using the iron vessel C shown in Fig. 5, using the Brazilian Karajas iron ore, which is rich in water as the function bulk ore, charging the iron vessel C into a conical shape and depositing it to add water, And then a concave portion of the conical sedimentary layer is grasped and a shovel is used to make a depression therein to generate a slurry (equivalent to a suspended water), and granular (beads) polyacrylic salt sodium The resin was added.

The results of this experiment are shown in Table 2. According to this, it has been found that the addition of the polymer absorbent merely causes the polymer absorbent after the addition and absorption to become lumpy (massive), resulting in a disadvantage in handling. Here, the polymer absorbent refers to a medicament which swells by putting water several hundreds times or more of its own weight.

For example, a polymer absorbent (absorbent polymer) has a property of swelling about 400 times in pure water. However, as in the present invention, it has been confirmed that about 200 times in the case of suspension water in which the powder particles and the water are suspended are practical limits. Further, when the swelling rate of the added polymeric absorbent is small, the swollen product is easily fried and is expected to be scattered out of the conveyor during transportation by a belt conveyor or the like, so that the swelling rate is preferably 30 times or more as the swelling rate.

The amount of the water absorbent (absorbent polymer) to be added to the suspension water Wm is set at an addition amount of more than 0.5 mass% with respect to the suspension water in order to reduce the addition amount of the water absorbent (absorbent polymer) to about 200 times in terms of the swelling rate. When the swelling rate is 30 times or more, the added amount of the moisture adsorbent is set to 3.3 mass% or less.

As shown in Table 2, when the swelling rate is 100 times or less, the added amount of the water adsorbent is 1.0 percent by mass or more, and when the swelling rate is 50 times or less, the added amount of the water adsorbent is preferably 2.0 percent by mass or less.

As described above, in this experiment, only the addition of the sodium polyacrylate resin granules to the Karajas iron ore is lumpy (massive), but the adsorption action of the suspended water containing the powder particles is weak, It is necessary to add the above. Thus, in this experiment, a stirring operation was carried out by shaking the above-mentioned water-retaining portion formed in the central depressed portion 4 by shoveling. This shuffling operation simulates the stirring operation by repeating the grabbing by the grab bucket in the actual equipment, the repeated operation of the opening drop, or the switching of the raking direction by the bucket of the continuous unloader.

≪ Example 1 >

For example, Karajas iron ore, which is an iron ore that is separated from water and bulk material in the import process and is in a state where the water in the bottom of the dock is in a state of high water at the time of arrival in Korea.

When unloading iron ore in the state shown in FIG. 6 (a), when the Karajas iron ore having a moisture value of 7.9 mass% to 24.7 mass% is unloaded from the carrier, the acrylamide polymer coagulant is added to the suspension water , And an amount such that the concentration of the chemical solution corresponding to 0.6 mass% was added. The amount of the polymer flocculant with respect to the amount of the suspension water Wm is generated after the suspension water Wm is grabbed into the grab bucket. Therefore, the amount of the polymer flocculant to be added is determined by estimating from the grab bucket capacity. Likewise, the determination of the spectral ratio: 7 or more showing the weight ratio of the bulk material to the weight of the suspension water containing the polymer flocculant and / or the water adsorbent was also estimated from the grab bucket capacity.

Next, after the polymer flocculant is added to the suspended water Wm generated in the depression formed in the ore deposit in the pail, the bulk material (Karajas iron ore) around the suspended water Wm is added to the suspension water Wm at about 10 The amount of fold was added and the mixture was stirred for 30 to 80 seconds using a grab bucket. That is, unloading operation was carried out after repeating the operations of grabbing and opening the bulk material (polymer flocculant) in the grab bucket 5.

As a result, by adding a polymer flocculant to the suspension water Wm and mixing it, the action of the polymer particles and the water particles of the suspension water Wm being caused to bow by the polymer polymer is promoted, and the particles coagulated by the polymer become large lumps (aggregated particles) Making it possible to unload.

In particular, although a large amount of water remained at the bottom of the boat in the past, the amount of water remaining was reduced by the above treatment. From the above results, since the Karajas iron ore itself has a large amount of water in transportation of the conventional Karajas iron ore, water is often generated at the time of unloading to the land, so that the removal (drainage) work of the suspension water Wm is intermittently performed When the above-described unloading method according to the present invention is employed, when the efficiency when no water is generated is taken as 100%, the unloading operation for performing the drainage work can only achieve an efficiency of 65% , And an efficiency of about 92% was achieved.

≪ Example 2 >

When the Karajas iron ore, which is an example of the bulk material 2 in the state shown in FIG. 6 (a), is unloaded from the cargo hold 1, the polymer flocculant of Example 1 is replaced with a polyacrylate An amount corresponding to 1.0 to 2.0 mass% of the resin granule with respect to the suspension water amount was added.

The amount of the polymer absorbent relative to the amount of the suspension water is estimated from the capacity of the grab bucket 5 because the suspension water Wm is generated in the depression 4 after the suspension water Wm is grabbed by the grab bucket and the amount of the polymer absorbent to be added is determined . Likewise, the determination of the numerical value 7 or more indicating the ratio of the weight of the bulk material to the suspended water amount as the weight ratio was also estimated from the grab bucket capacity.

Next, the polymeric absorbent is added to the suspended water Wm generated at the portion of the depression 4 formed in the ore deposit in the pail, and the bulk material 2 (Karajas iron ore) around the suspended water Wm is added to the suspended water Wm , And mixed using a grab bucket (5). That is, after the operations of the grab bucket 5 for holding the bulk material and releasing the opening were repeated, the unloading operation was repeated.

As a result, by adding a polymeric absorbent to the suspension water Wm and mixing it, the action of adsorbing the powder and water molecules in the suspension water Wm to the polymer adsorbent is promoted, and unloading is facilitated.

In addition, the repetition of the grabbing and opening drop may result in aggregation of the polymeric absorbents, resulting in a large lump, easily clogged with the hopper, and even if the polymeric absorbent can be dispersed, the swollen body is easily fried, The spectral ratio indicating the weight ratio of the bulk material to the weight of the suspension water containing the polymer flocculant and / or the water adsorbent is set to 7 or more. Thus, the swollen material absorbing the suspended water Wm in the bulk material (Polymer absorbent) was also dispersed.

As a result, a large amount of water remained on the bottom of the boat in the past, but the amount of water remaining after the above treatment was also reduced.

From the above results, it can be seen from the above results that since the Karajas iron ore itself has a large amount of water in the transportation of Karajas iron ore, water is largely discharged at the time of unloading into the land, and conventionally the removal of the suspension water Wm (drainage) When the above unloading method suitable for the invention is employed, when the efficiency in the case where no water is generated is taken as 100%, the unloading in the conventional drainage method can achieve only 65% Efficiency can be achieved.

≪ Example 3 >

At the time of storm, the unloading by the continuous unloader is continued, and the iron ore which is excessively watered will be described below as an example.

7, unloading by the bucket of the continuous unloader is continued as shown in FIG. 7, and unloading work proceeds. In the stage where the unloading reaches the lower part of the latter half of unloading, When the iron ore in the state shown in Fig. 8 (a), which was started to be unloaded from the carrier, was added in an amount corresponding to 1.0 to 2.0 mass% with respect to the suspension water amount of the polyacrylate resin granules as the polymer absorbent.

Since the amount of the polymer absorbent relative to the amount of the suspension water Wm is generated in the depression after the suspension water Wm is excavated by the bucket, it is estimated from the excavation amount based on the bucket capacity and the excavation depth, and the amount of the polymer absorbent to be added And the like. Likewise, a numerical value expressed as a weight ratio described later was also estimated from the excavation amount based on the bucket capacity and excavation depth.

Next, a polymeric absorbent is added to the suspension water Wm generated in the depression portion formed in the bulk re-accumulation layer in the reservoir 1, and then the bulk material around the suspension water is scraped with a bucket and put into the suspension water, I mixed it using a bucket.

That is, after the stirring of the bulk material and the polymer absorbent was repeated by the stirring operation by the operation of repeating the switching of the raking direction with the bucket of the continuous unloader, the unloading operation was continued. As a result, by adding a polymeric absorbent to the suspension water Wm and mixing, the adsorption action of the powder particles and the water molecules in the suspension water by the polymer absorbent was promoted, and unloading was facilitated.

In addition, by merely repeating the switching of the scraping and collecting direction of the bucket, the polymer absorbent aggregates collectively to form a large aggregate, which is liable to be clogged with the hopper, and even if the polymer absorbent can be dispersed, There is a possibility of falling from the belt conveyor. Therefore, by setting the spectral ratio, which indicates the weight ratio of the bulk material to the weight of the suspension water containing the polymer flocculant and / or the water adsorbent, to 7 or more, the suspended water Wm The swollen material (polymeric absorbent) absorbed could be further dispersed.

During the unloading, when water was observed, a large amount of water remained at the bottom of the boat in the past, but the amount of water remaining after the above treatment was also reduced. From the above results, conventionally prepared for unloading in heavy rain. However, when the above unloading method according to the present invention is employed at the time of unloading onto the land, it is possible to achieve an efficiency of about 85% even at unloading at long periods of time when the efficiency at normal time is taken as 100% there was.

<Example 4>

At the time of storm, the unloading by the continuous unloader is continued, and the excess coal is described below as an example.

7, unloading by the bucket of the continuous unloader is continued as shown in FIG. 7, and unloading work proceeds. In the stage where the unloading reaches the lower part of the latter half of unloading, When the coal in the state shown in Fig. 9 (a) which has started to be unloaded from the carrier is unloaded from the carrier similarly to the unloading of the iron ores of Examples 1, 2 and 3, the polyacrylate resin granules as the polymer absorbent , And an amount corresponding to 1.0 to 2.0 mass% was added.

Since the amount of the polymeric absorbent relative to the amount of the suspension water Wm is generated in the depression after the suspended water is excavated by the bucket, it is estimated from the excavation amount based on the bucket capacity and the excavation depth, and the amount of the polymeric absorbent to be added is determined . Likewise, the numerical value expressed as the weight ratio was also estimated from the excavation amount based on the bucket capacity and the excavation depth.

Next, the polymeric absorbent is added to the suspended water Wm generated in the portion of the depression formed in the bulk sediment layer in the pail, the coal around the suspended water is scraped into the suspended water using a bucket, and the puddled water is mixed using a bucket . That is, after repeating the stirring of the coal and the polymer absorbent by the stirring operation by the operation of repeating the switching of the raking direction in the bucket of the continuous unloader, the unloading operation was continued.

As a result, it was confirmed that the action of adsorbing the powder particles and the water molecules in the suspension water by the polymer absorbent was promoted by adding a polymeric absorbent to the suspension water Wm and mixing, thereby facilitating unloading.

Also, in the case of coal, as in the case of iron ore, only agitation of repeating the direction of scraping and gathering may cause aggregation of the polymeric absorbent agents to form a large agglomerate, which is likely to be clogged with the hopper and which can disperse the polymeric absorbent agent, , It is possible to reduce the amount of suspension in the bulk material by setting the spectral ratio to 7 or more, which indicates the weight ratio of the bulk material to the weight of the suspension water containing the polymer flocculant and / or the water adsorbent, The swollen material (polymer absorbent) which absorbed the water was further dispersed.

In the course of unloading, when water was observed, a large amount of water remained on the bottom of the boat in the past.

From the above results, when the unloading method suitable for the present invention is employed in unloading on the land which was prepared for unloading in the heavy rain in the past, when the efficiency at normal time is taken as 100% It was possible to achieve an efficiency of about 95% even in the unloading operation.

Since the use of the polymeric absorbent in Examples 2 to 4 is inadequate, it is unloaded onto the ground by a belt conveyor through a grap bucket or a bucket and then piled up in the raw material yard. As such, iron ore is used as raw material for sintering, It could be used as a raw material.

&Lt; Example 5 >

The unloading of Karajas iron ore, which is separated from water and bulk materials in the import process, is an iron ore that is in a state where the water in the bottom of the dock is at the bottom of the dock upon arrival in Korea.

When unloading iron ore in the state shown in FIG. 6 (a), when the Karajas iron ore having a moisture value of 7.9 mass% to 24.7 mass% is unloaded from the carrier, the acrylamide polymer coagulant is added to the suspension water , And an amount such that the concentration of the chemical solution corresponding to 0.6 mass% was added. Since the amount of the polymer coagulant relative to the amount of the suspension water Wm is generated in the depression after the suspension water Wm is scratched (excavated) with the bucket of the continuous unloader, the amount of the polymer flocculant is reduced from the excavation amount based on the grab bucket capacity and the excavation depth And estimating the suspended water Wm occurring in the depressed portion to determine the amount of the polymer flocculant to be added. Likewise, a numerical value of 7, which is a non-reciprocal value with respect to the weight of the suspension water Wm including the polymer coagulant, of the bulk material weight expressed by the weight ratio, is determined from the excavation amount based on the bucket capacity and the excavation depth, The water Wm was estimated and executed.

Next, after the polymer flocculant is added to the suspended water Wm generated in the depression formed in the ore deposit in the pail, the bulk material (Karajas iron ore) around the suspended water Wm is added to the suspended water Wm, About 10 times the weight of the bulk material, buckets were used to scrape the bulk material and mixed for 30 to 80 seconds.

That is, after the agitation of the bulk material and the polymer flocculant was repeated by the operation of repeating the switching of the raking direction in the bucket of the continuous unloader, the unloading operation was continued.

As a result, by adding the polymer flocculant to the suspension water Wm and mixing, the action of the polymer particles and the powder particles in the suspension water Wm being caused by the polymer polymer is promoted so as to be the same as when using the grappling bucket, (Agglomerated particles), thereby enabling unloading.

Particularly, although a large amount of water remained in the bottom of the boat in the past, almost no residual water was found by the above treatment. From the above results, in the conventional transportation of Karajas iron ore, the Karajas iron ore itself has a large amount of water, and when water is unloaded into the land, a large amount of water is generated, so that the removal (drainage) work of the suspension water Wm is intermittently carried out When the above unloading method according to the present invention is employed, when the efficiency when water is not generated is taken as 100%, it is only about 65% An efficiency of 93% was achieved.

&Lt; Example 6 >

At the time of storm, the unloading by the continuous unloader is continued and the unloading of iron ores in excess of water will be described below as an example.

7, unloading by the bucket of the continuous unloader is continued as shown in FIG. 7, and unloading work proceeds. In the stage where the unloading reaches the lower part of the latter half of unloading, When the iron ore in the state shown in FIG. 8 (a) started to be unloaded from the carrier, an amount of the acrylamide-based polymer coagulant was added to the suspension water to the concentration of the chemical solution corresponding to 0.6 mass%.

Since the amount of the polymer flocculant with respect to the amount of the suspension water Wm is generated in the depression after the suspension water Wm is excavated by the bucket, the depression amount is determined from the excavation amount based on the bucket capacity and the excavation depth, The amount of suspension water Wm was estimated and the amount of the polymer flocculant to be added was determined.

Likewise. The spectral ratio indicating the weight ratio of the bulk material to the weight of the suspension water containing the polymer flocculant and / or the water adsorbent, and the excavation amount based on the bucket capacity and the excavation depth, as a weight ratio described later.

Next, the polymer flocculant is added to the suspension water Wm generated in the depression portion formed in the bulk re-accumulation layer in the reservoir 1, and then the bulk material around the suspension water is scraped with a bucket and put into the suspension water, I mixed it using a bucket.

That is, after the agitation of the bulk material and the polymer flocculant was repeated by the operation of repeating the switching of the raking direction in the bucket of the continuous unloader, the unloading operation was continued.

As a result, by adding the polymer flocculant to the suspension water Wm and mixing it, the action of the polymer particles and the water particles in the suspension water Wm is promoted by the polymer polymer, and the particles condensed by the polymer become larger lumps Made and unloaded.

During the unloading, when water was observed, a large amount of water remained on the bottom of the boat in the past, but the remaining water was slightly observed by the above treatment.

From the above results, conventionally prepared for unloading in heavy rain. However, when the above unloading method suitable for the present invention is employed at the time of unloading to the land, when efficiency at normal time is taken as 100%, about 87% efficiency can be achieved even in unloading at long time I could.

&Lt; Example 7 >

Hereinafter, iron ore which has been unloaded by a continuous unloader at the time of storm and whose moisture content is excessively high (in a weight ratio of less than 7) can not be modified by a polymer flocculant alone.

The unloading by the bucket of the continuous unloader as shown in FIG. 9 is continued during the heavy rain, the unloading operation proceeds, and at the stage of reaching the lower layer portion of the latter half of the unloading, , The amount of the acrylamide-based polymer flocculant was adjusted to the concentration of the chemical solution corresponding to 0.6 mass% with respect to the suspension water amount, Thereafter, a polyacrylate resin granule as a polymer absorbent was added in an amount of 1.0 to 2.0 mass% with respect to the suspended water amount to be less than 7 as a spectral ratio.

The addition amount of the polymer absorbent and the polymer flocculant to the amount of the suspension water Wm is estimated from the excavation amount based on the bucket capacity and the excavation depth since the suspension water Wm is generated in the depression after excavating with the bucket, And the amount of the water-soluble polymer is determined.

Next, the polymer flocculant and the polymer absorbent are added to the suspended water Wm generated in the depressed portion formed in the bulk re-deposited layer in the reservoir 1, and then the bulk material around the suspended water is scraped off with a bucket, I poured in and mixed using a bucket.

That is, after repeating stirring of the bulk material, the polymer flocculant, and the polymer absorbent by the operation of repeating the switching of the raking direction in the bucket of the continuous unloader, the unloading operation was continued.

As a result, by adding a polymeric absorbent to the suspension water Wm and mixing it, the water that could not be modified by the polymer flocculant group was adsorbed by the polymer absorbent, and the modifying action of the polymer particles and water molecules in the remaining suspended water was promoted And unloading becomes easy.

In addition, the order of addition of the polymeric absorbent and the polymer flocculant was reversed or the same effect was obtained at the same time.

During the unloading, when water was observed, a large amount of water remained on the bottom of the boat in the past, but the remaining water was hardly seen by the above treatment.

From the above results, conventionally prepared for unloading in heavy rain. However, when the unloading method according to the present invention is employed at the time of unloading to the land, it is possible to achieve an efficiency of about 90% even at unloading at long periods of time when the efficiency at normal time is taken as 100% there was.

&Lt; Example 8 >

Hereinafter, iron ore which has been unloaded by gravity type unloader at the time of storm, and which is excessively watery in a state in which the polymer flocculant can not be reformed (spectral ratio is less than 7) will be described as an example.

Unloading by gravity type unloader as shown in Fig. 10 was continued during the heavy rain, and unloading work progressed. In the stage where the unloading reached the lower part of the latter half of the unloading, water was observed by high- When the iron ore in the state shown in Fig. 10 (a) is unloaded from the carrier, an amount of the acrylamide-based polymer flocculant is added in an amount such that the concentration of the solution corresponds to 0.6 mass% with respect to the suspended water amount, , And a polyacrylate resin granule as a polymer absorbent was added in an amount of 1.0 to 2.0 mass% with respect to the suspension water amount which was less than 7 in the spectral ratio.

The addition amount of the polymer absorbent and the polymer flocculant to the amount of the suspension water Wm is estimated from the excavation amount based on the bucket capacity and the excavation depth, And the amount of the drug was determined.

Next, a polymeric absorbent and a polymer flocculant are added to the suspended water Wm generated in the depression formed in the ore deposit in the pail, and bulk material (Karajas iron ore) around the suspended water Wm is added to the suspended water Wm I used the grab bucket for 30 to 80 seconds. That is, unloading operation was performed after repeating the operations of grab and bulk drop of the bulk material (polymer flocculant) with the grab bucket.

As a result, by adding a polymeric absorbent to the suspension water Wm and mixing it, the water that could not be modified by the polymer flocculant group was adsorbed by the polymer absorbent, and the modifying action of the polymer particles and water molecules in the remaining suspended water was promoted And unloading becomes easy.

In addition, the order of addition of the polymeric absorbent and the polymer flocculant was reversed or the same effect was obtained at the same time.

During the unloading, when water was observed, a large amount of water remained on the bottom of the boat in the past, but the remaining water was hardly seen by the above treatment.

From the above results, conventionally prepared for unloading in heavy rain. However, when the above unloading method suitable for the present invention is employed at the time of unloading to the land, the efficiency of about 93% can be achieved even when the unloading is carried out for a long time when the normal efficiency is 100% there was.

[Industrial Availability]

The above-described unloading technique of the bulk material of the present invention can be applied to the unloading operation of the bulk material such as gravel, sand, grain, etc., in addition to the above-described functional ore or coal.

One; Dock 2; Bulk material
3; Bottom 4; Depression
5; Bucket A; Moisture adsorbent
C; Iron vessel P; Powder
Wm; Suspension water

Claims (25)

When unloading a functional bulk material such as ore or coal from a cargo ship by using a legged crane or a grab bucket of an unloader or a bucket of a continuous unloader, When suspension water is generated, by adding a polymer flocculant to the suspension water, coagulation and coagulation of water and powder particles with respect to the suspension water, and addition of a water adsorbent are added to the suspension water, The unloading is carried out together with the bulk material. &Lt; RTI ID = 0.0 &gt; 31. &lt; / RTI &gt; The method according to claim 1,
Adding only the polymer flocculant to the suspension water to cause condensation and aggregation of the water and the powder particles, and then performing unloading together with the bulk material. The method according to claim 1,
Wherein water is adsorbed to the water adsorbent by adding only the water adsorbent to the suspension water, and then the water is unloaded together with the bulk material. The method according to claim 1 or 3,
A method for unloading a functional bulk material, wherein a polymeric absorbent is used as the moisture adsorbent. The method according to claim 1 or 3,
Wherein the water adsorbent is added in an amount of more than 0.5 to 3.3 mass% of the suspended water amount. 5. The method of claim 4,
Wherein the water adsorbent is added in an amount of more than 0.5 to 3.3 mass% of the suspended water amount. The method according to claim 1 or 3,
Wherein the water adsorbent is added in an amount of 1.0 to 2.0 mass% of the suspended water amount. 5. The method of claim 4,
Wherein the water adsorbent is added in an amount of 1.0 to 2.0 mass% of the suspended water amount. 6. The method of claim 5,
Wherein the water adsorbent is added in an amount of 1.0 to 2.0 mass% of the suspended water amount. 3. The method according to claim 1 or 2,
Wherein the polymer flocculant is added in an amount of 0.4 to 1.0 mass% of the suspension water. 3. The method according to claim 1 or 2,
Wherein the polymer flocculant is added to the position where the suspension water is generated, and the bulk material of the other site is mixed and stirred to produce the coagulated particles and the aggregated particles, followed by unloading. 11. The method of claim 10,
Wherein the polymer flocculant is added to the position where the suspension water is generated, and the bulk material of the other site is mixed and stirred to produce the coagulated particles and the aggregated particles, followed by unloading. The method according to claim 1 or 3,
Wherein a moisture adsorbent is added to a position where the suspension water is generated and at the same time, the bulk material in another portion is mixed and stirred and then unloaded. 5. The method of claim 4,
Wherein a moisture adsorbent is added to a position where the suspension water is generated and at the same time, the bulk material in another portion is mixed and stirred and then unloaded. 6. The method of claim 5,
Wherein a moisture adsorbent is added to a position where the suspension water is generated and at the same time, the bulk material in another portion is mixed and stirred and then unloaded. 8. The method of claim 7,
Wherein a moisture adsorbent is added to a position where the suspension water is generated and at the same time, the bulk material in another portion is mixed and stirred and then unloaded. The method according to claim 1,
Adding a polymer flocculant and a water adsorbent to the suspension water generating site to produce coagulated particles and aggregated particles by adding a polymer flocculant and allowing the water in the suspended water portion free from the generation of coagulated particles and aggregated particles to be adsorbed on the water adsorbent And then unloading the mixed bulk material together with the bulk material. The method according to claim 1,
Characterized in that a water adsorbent is added to the position where the suspension water is generated to reduce the water content in the suspension water and then the coagulated particles and the aggregated particles are produced by adding the polymer flocculant and unloaded together with the bulk material A method of unloading bulk material. The method according to any one of claims 1 to 3 and 17 to 18,
Wherein the ratio of the weight of the bulk material to the weight of the suspension water containing at least one of the polymer flocculant and the water absorbent is 7 or more. 5. The method of claim 4,
Wherein the ratio of the weight of the bulk material to the weight of the suspension water containing at least one of the polymer flocculant and the water absorbent is 7 or more. 6. The method of claim 5,
Wherein the ratio of the weight of the bulk material to the weight of the suspension water containing at least one of the polymer flocculant and the water absorbent is 7 or more. 8. The method of claim 7,
Wherein the ratio of the weight of the bulk material to the weight of the suspension water containing at least one of the polymer flocculant and the water absorbent is 7 or more. 11. The method of claim 10,
Wherein the ratio of the weight of the bulk material to the weight of the suspension water containing at least one of the polymer flocculant and the water absorbent is 7 or more. 12. The method of claim 11,
Wherein the ratio of the weight of the bulk material to the weight of the suspension water containing at least one of the polymer flocculant and the water absorbent is 7 or more. 14. The method of claim 13,
Wherein the ratio of the weight of the bulk material to the weight of the suspension water containing at least one of the polymer flocculant and the water absorbent is 7 or more.

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