KR102503207B1 - Management method of storehouses for activated carbon - Google Patents

Abstract

The present invention relates to a management facility, device, and operation method for storing recycled carbon or new activated carbon of waste activated carbon. By establishing a storehouse system capable of storing recycled carbon or new activated carbon for spent activated carbon generated in domestic use and managing the history quality, the history management of activated carbon for each business site is performed. By monitoring the quality status of activated carbon in an activated carbon storage facility, the quantity of activated carbon with the quality substantially the same as that of the received activated carbon can be shipped to a business site that makes a request for storage. Thus, the optimization of quantity management of activated carbon can be realized.

Description

Management method of storehouses for activated carbon

The present invention relates to a management facility, apparatus, and operation method capable of stockpiling and storing recycled carbon or new activated carbon of spent activated carbon.

Wastewater treatment facilities that purify and discharge various wastewater such as domestic sewage and industrial wastewater to a certain level are operated by passing the wastewater through a water treatment tank filled with an adsorbent and adsorbing harmful components contained in the wastewater with an adsorbent to purify the water. As an adsorbent usually filled in a water treatment tank, activated carbon, which is an amorphous material composed of mostly carbon and has a large specific surface area and adsorption capacity and excellent ability to remove harmful substances, is mainly used.

Activated carbon, which is used as an adsorbent in industrial wastewater treatment facilities, is filled with organic substances in the pores formed on the surface of activated carbon at a certain period of time, and the water purification treatment capacity is rapidly reduced, so activated carbon is periodically replaced or recycled. am.

The supply and demand of such activated carbon is a situation where the majority of the quantity is imported from abroad, and in the case of the domestic activated carbon market, which depends on such imported quantity, it is greatly affected by the unpredictable international situation, and if there is a disruption in the global supply chain, The activated carbon industry has a problem that the blow is very large.

Therefore, in order to stably supply the domestic demand for activated carbon, there is a growing need for a method of constructing a stockpiling system for recycled activated carbon or new activated carbon supplied domestically and efficiently managing limited resources.

Korean Patent Registration No. 10-2092541

The present invention has been devised to solve the above-described problems, and an object of the present invention is to build a stockpile warehouse system capable of storing and stockpiling and managing the history quality of recycled charcoal or new activated carbon for spent activated carbon generated in domestic use, By performing the history management of activated carbon for each unit and monitoring the quality status of activated carbon within the activated carbon dispensing facility, the stockpiled quantity of activated carbon having substantially the same quality as the warehoused state is requested. It is to provide an operating plan that enables the optimization of the quantity management of activated carbon by enabling it to be shipped to the business site.

As a means for solving the above problems, in the embodiment of the present invention, as shown in FIGS. 1 to 11, the waste activated carbon is supplied from the spent activated carbon supplier Sn where the spent activated carbon is generated in the storage device, Step 1 of receiving, in the integrated management server (T), information on the recycled activated carbon recycled in the recycling facility (Rn) or the new activated carbon manufactured in the activated carbon manufacturing facility (Rm) being stored in the activated carbon storage warehouse (Rg);

The activated carbon inspection module 100 of the integrated management server (T) analyzes and collects the history information including the type, source, and weight of the warehousing activated carbon and the physical and chemical state including the iodine value and water content of the activated carbon to collect the warehousing information. Step 2 to analyze;

Based on the information analyzed by the activated carbon inspection module 100, the integrated management server T determines the storage method of the received activated carbon, selects the storage location, and then determines the source, type, storage location, and status information of the activated carbon. Step 3 of forming a synthesized stored information code;

Step 4 of transferring the activated carbon received from the activated carbon transfer module 200 through a conveyor in a ton bag accommodation state or a storage container accommodation state to which the storage information code is attached, and placing it on a transfer type pallet disposed in an elevating device;

Step 5 of driving the lifting and lowering device in the storage activated carbon transport module 200 to lift the transfer type pallet and store it in a storage space block built in an activated carbon storage warehouse (Rg); including, activated carbon storage warehouse operation to provide a way.

According to an embodiment of the present invention, a stockpile warehouse system capable of storing and stockpiling recycled activated carbon or new activated carbon for spent activated carbon generated in domestic use and managing history quality is established, and the history management of activated carbon is performed for each business site, and the By enabling the monitoring of the quality status of activated carbon within the discharge facility, the quantity of activated carbon with the quality substantially the same as that of the received condition can be shipped to a business site that has requested stockpiling, so that the quantity of activated carbon management can be optimized.

In particular, the activated carbon stockpiling management system according to the present invention inspects the state information of the storage state (recycled carbon, new charcoal) for the quality of a special storage object called activated carbon, and closely monitors quality changes through re-inspection at the time of shipment. Therefore, it is possible to establish an efficient resource management plan by managing the risk of unpredictable quality change at the storage request site.

In addition, in a situation where concerns about the resource weaponization of activated carbon, which depends on imports, are growing, it is possible to implement stable domestic activated carbon supply and demand management in preparation for unstable supply and demand of activated carbon due to disruptions in the global supply chain due to unpredictable changes in international situations. enable the benefits to be realized.

Specifically, according to an embodiment of the present invention, in order to secure the price and quality of activated carbon through an optimal activated carbon stockpiling and operating system, the storage facility of recycled carbon and the storage facility of recycled carbon are separated, and the recycled carbon is mixed to other water purification plants The advantage of being able to control the quality of reclaimed coal by preventing it from being transported to the place of demand is realized.

In addition, by building a storage facility with a storage space block structure of a multi-layer cell structure, it is possible to store more activated carbon (new carbon, regenerated carbon) in a limited space, and precise logistics management is possible by managing the storage location and storage status information in a database. make it happen

In particular, by introducing a loading method using a conveyor and rail transport facility and a stacker crane suitable for the storage method of the storage space block structure, the storage and stockpiling of activated carbon can be made into a logistics system that can automatically withdraw and withdraw, enabling automated management of shipping and warehousing. can

Furthermore, according to an embodiment of the present invention, an advantage of efficiently managing the quality of activated carbon can be realized through quality inspection at the time of warehousing and shipping of activated carbon.

1 is a block diagram showing the configuration of an activated carbon storage warehouse operation method (hereinafter referred to as the present invention) according to an embodiment of the present invention.
Figure 2 is a flow chart showing the implementation process of the present invention.
3 is a conceptual diagram illustrating a process of storing and storing stored activated carbon in a stockpile warehouse.
4 is a conceptual diagram showing an embodiment of a transfer conveyor applied to the present invention.
5 is a conceptual diagram illustrating an embodiment of a storage container applied to the present invention.
Figure 6 shows the configuration of a functional unit that performs management control in the integrated management server (T) in an embodiment of the present invention.
7 is a conceptual diagram illustrating a process of releasing activated carbon stockpiled and stored in the present invention.
8 is a diagram showing the structure of a stacker crane (SCR) used in the present invention.
9 is a rear cross-sectional view showing the arrangement of the stacker crane and the storage space block of the present invention.
10 is a diagram illustrating the arrangement structure of the activated carbon stockpile of the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content will be thorough and complete and the spirit of the present invention will be sufficiently conveyed to those skilled in the art.

Terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, the terms "include" or "have" are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having meanings consistent with the meanings in the context of the related art, and unless explicitly defined in this application, they should not be interpreted in ideal or excessively formal meanings. don't

1 is a block diagram showing the configuration of an activated carbon stockpile warehouse operation method (hereinafter referred to as the present invention) according to an embodiment of the present invention, and FIG. 2 is a flowchart illustrating the implementation process of the present invention. 3 is a conceptual diagram illustrating a process of storing and storing stored activated carbon in a stockpile warehouse.

1 and 2, the present invention receives waste activated carbon from a waste activated carbon supplier (Sn) where spent activated carbon is generated in a storage device, or recycled activated carbon or activated carbon manufacturing facility recycled from a waste activated carbon recovery facility (Rn). Step 1 of receiving the information that the new activated carbon manufactured in (Rm) is received into the activated carbon stockpile (Rg) to the integrated management server (T), and received from the activated carbon inspection module (100) of the integrated management server (T) 2nd step of analyzing the warehousing information by collecting historical information including the type, source, and weight of the warehousing activated carbon and the physical and chemical state including the iodine value and water content of the activated carbon, and the information analyzed by the activated carbon inspection module 100 3 steps of determining the storage method of the received activated carbon in the integrated management server (T) based on, selecting the storage location, and forming a storage information code that integrates the source, type, storage location, and status information of the activated carbon, 4th step of transporting the activated carbon received from the activated carbon transport module 200 through a conveyor in a ton bag accommodation state or a storage container accommodation state with the storage information code attached, and placing it on a transport type pallet disposed in an elevating and descending device, the storage It may be configured to include a fifth step of driving the lifting and lowering device in the activated carbon transport module 200 to lift the transportable pallet and store it in a storage space block built in the activated carbon storage warehouse Rg.

Specifically, as shown in FIG. 1, the present invention, as shown in FIG. 1, regenerated activated carbon (hereinafter referred to as 'recycled carbon') '), or activated carbon newly manufactured at the activated carbon manufacturing facility (Rm) (hereinafter referred to as 'new carbon') is stored in the activated carbon stockpile (Rg), stored, and stored when necessary. The basic skeleton is to make it available for use after being shipped out. In this case, the activated carbon stockpile (Rg) enables monitoring and control of the equipment system through the integrated management server (T) that manages the operation of the overall equipment system.

In the present invention, the stockpile warehouse for storing re-combustible coal and new coal is classified and described below, but the stockpile warehouse system of the present invention can also receive and store spent activated carbon, and in the case of a storage warehouse for spent activated carbon However, since it can be implemented in the same way as the operation structure of the storage and stockpiling warehouse for recycled coal described later, the method and structure of the storage and storage warehouse for waste coal will be omitted.

Referring to FIGS. 2 and 3 , a method of storing, managing, and releasing the above-described recycled carbon and new carbon in an activated carbon storage warehouse will be described in detail.

First, referring to FIGS. 2 and 3, the present invention is a first-step process, receiving waste activated carbon from a waste activated carbon supplier (Sn) where waste activated carbon is generated in a storage device and regenerating waste activated carbon in a waste activated carbon regeneration facility (Rn). The integrated management server T receives the information that the new activated carbon manufactured in the activated carbon manufacturing facility Rm is stored in the activated carbon storage warehouse Rg.

As shown in FIG. 3, activated carbon (hereinafter referred to as 'received activated carbon') stored in the activated carbon stockpile Rg is transported through a transport truck t1, and is transported through a transport facility such as a crane CR or a forklift truck t2. It is unloaded through, and the unloaded stored activated carbon is mounted on a transport support structure such as a transport pallet (L) to perform transport preparation.

Next, the history information including the type, import source, and weight of the warehousing activated carbon received from the activated carbon inspection module 100 of the integrated management server T and the physical and chemical state including the iodine value and water content of the activated carbon are analyzed and collected The second step of analyzing the warehousing information is performed. (The configuration of the activated carbon inspection module will be described in detail in FIG. 4 to be described later.)

That is, the warehousing activated carbon stored in the warehousing preparation area (M) of the activated carbon stockpiling warehouse (Rg) is stored through the conveyor (c1), and the weight is measured through the weighing machine (m1) at the same time as warehousing, not shown. However, the physical and chemical state is measured through measuring equipment that analyzes information such as moisture content, weight, and iodine value of the activated carbon itself, and the gas component or content information leaked through the gas detector (m2) is also measured. You will be able to do it. This measurement information and detailed information such as history information of warehousing activated carbon (type of activated carbon (new charcoal or recycled charcoal), date of warehousing, source, etc.) are converted into data together with this measurement information and organized as warehousing information, and the integrated management server stores this information as DB to be stored and managed.

Thereafter, as shown in FIG. 3, the stored activated carbon can be transported to a place for storing the stored activated carbon through a transfer vehicle (RGV). In the case of the transport vehicle (RGV), known equipment may be used as equipment for transporting activated carbon stored on a transport pallet along rails.

However, in this case, the input activated carbon may be transported by dividing the transport conveyor according to whether the activated carbon is recycled or new charcoal.

This is a three-step process of the present invention, based on the information analyzed by the activated carbon inspection module 100, the integrated management server T determines the 'storage method of activated carbon' to be received, selects the storage location, This can be done after the process of forming a 'storage information code' that integrates the source, type, storage location, and status information of activated carbon is performed.

In the case of such a 'storage information code', it is coded in the database of the integrated management server (T) so that it can be stored and managed, and it can be matched and managed using an identification code in the form of a barcode or OR code on the surface of a tone bag or container. let it be

In the case of the above-described 'storage method of activated carbon', in the case of storing reactivated carbon with a high water content in the form of storing stored activated carbon, it is stored in a ton bag accommodation form, or in the case of new carbon, since the water content is relatively low, a separate storage container (also In 7), it can be decided to store the activated carbon directly or in a storage container in a state where the activated carbon is contained in a tone bag.

In the present invention, reclaimed coal and new coal are separated and stored in separate places, and in the case of reclaimed coal, since the moisture content is high, there is a lot of moisture leaking out of the ton bag, so the storage is stored in a place where a separate drainage facility is managed. It is desirable to do

Therefore, when the above-described 'activated carbon storage method' is selected as a tone bag storage method for recycled charcoal, the tone bag (non-woven fabric material) containing the recycled charcoal is transported and stored as it is, and in FIG. 3, the recycled charcoal conveyor (C6 ) to the recycled coal storage block (Rg3) and lifted and lowered through the stacker crane (SCR3) so that it can be stored.

In this case, in the case of the recycled coal conveyor (C6), it is driven through a conveyor driving device having the same structure as the conveyors (C2 to C5) that transport the coal, but using a structure in which a moisture absorbing member having a moisture absorbing function is mounted on the surface of the conveyor. it is desirable

That is, in the case of the recycled coal conveyor C6 in FIG. 3, in the process of transporting in the form of a ton bag, there is a problem in that moisture flows out due to a large amount of moisture contained, and at the same time, a problem of generating coal dust occurs, causing contamination of the inside of the facility. There is a risk that problems may occur. Therefore, as shown in FIG. 4, in the case of the recycled coal conveyor C6, the belt conveyor structure 10 rotates through the drive roller 20, and the moisture absorbing member 30 is disposed on the surface of the general conveyor structure to remove moisture generated from the tone bag. It is preferable to apply a conveyor structure that can absorb moisture and dust.

This moisture absorbing member is formed as a plate-shaped member of urethane material, but it can be applied to one implemented in a structure in which a plurality of moisture absorbing holes are formed on the surface. Unlike this, as another embodiment, as an example of the present invention, in the case of a moisture absorbing member , It is molded using a soft elastic material, and a material having elasticity and softness such as nitrile rubber will be suitable. The above nitrile rubber refers to 'acrylonitrile-butadiene rubber (NBR)' As an abbreviation, it refers to a rubber made of a random copolymer of acrylonitrile and butadiene, and is characterized by excellent elasticity and soft elasticity.

As shown in FIG. 4, the moisture absorbing member 30 of the present invention can be manufactured in various shapes such as a flat circular shape, a square or a triangle, and (a) the moisture absorbing member 30 has a myriad of vertical moisture absorbing holes 31 It is more preferable to form a penetrating layer to increase the moisture absorption efficiency.

Furthermore, while implementing the moisture absorbing member 30, as shown in FIG. ), it is possible to increase the moisture absorption efficiency by increasing the mooring time on the surface of the moisture absorbing member without flowing out of the moisture from the tone bag to the outside.

In addition, as shown in (c) and (d) of FIG. 4 , it is also possible to implement the concavo-convex pattern 33 protruding through the surface of the moisture absorbing member in a form applied to the structures (a) and (b) described above. The concave-convex pattern is implemented in a form that protrudes from the surface of the moisture absorbing member, so that a strong friction bearing force is formed at the lower part of the tone bag to prevent the tone bag from flowing on the conveyor.

As described above, as shown in FIGS. 3 and 4 , in the present invention, new coal and recycled coal are distinguished, and a storage location is separately designated so that they can be stored.

That is, when the ton bag storage method is selected for recycled charcoal, the ton bag (non-woven fabric material) containing the recycled charcoal is transported and stored as it is. In FIG. 3, the recycled charcoal storage block passes through the recycled charcoal conveyor C6. It is transferred to (Rg3) and lifted and stored through a stacker crane (SCR3), and in the case of new coal, it can be stored using a storage container 500 as shown in FIG. 5.

Of course, in the case of new charcoal, it does not mean that the tone bag storage method cannot be applied, and it is of course possible to store and reserve in the tone bag storage form. However, in the case of new charcoal, the moisture content is not high, and unlike recycled charcoal, in terms of requiring more precise management in terms of quality control, to increase management efficiency, a tone bag is accommodated in a storage container as shown in FIG. 5, It can be made to be stored in a way that accommodates the new charcoal itself. The most common and preferred example can be applied in the form of accommodating the tone bag itself in a storage container.

The storage container 500 may be implemented as a box-shaped structure having a housing body 520 having an accommodation space therein and a cover unit 510, and a state check sensor unit 530 on the side surface. By arranging, it is possible to check the humidity, temperature, and exhaust gas in the accommodation space in real time, and send them to the external monitoring integrated management server so that management suitable for the environment can be made.

In addition, a mesh-type air permeable network structure is provided on the lower bottom portion 550 to allow internal air to communicate with the outside, and at the same time, a photocatalyst material is applied to the surface of the mesh network so that oxides generated from carbon, It is possible to perform a function of removing an absorbent gas or the like through a photo-oxidation reaction. In addition, since it is a mesh structure, drainage can be made when a small amount of moisture is formed inside. Although not shown, it is more preferable that a light irradiation lamp for radiating ultraviolet light to the surface of the mesh structure may be disposed on the inner surface of the lower part of the body so that a photo-oxidation reaction may be realized.

At the same time, the transport roll 540 is formed so that the bottom part can be separated from the ground, and at the same time, the fork of the stacker crane, which will be described later, enters to facilitate storage and delivery of the storage container itself. That is, in the case of using the storage container of the present invention, it is possible to accommodate without using a pallet loading member that is essential when applying the tone bag method. Of course, it is also possible to employ a method of accommodating and storing the container by placing it on the pallet loading member.

Figure 6 shows the configuration of a functional unit that performs management control in the integrated management server (T) in an embodiment of the present invention.

Referring to FIG. 6, in the present invention, as described above in FIG. 2, the activated carbon inspection module that checks the status of the activated carbon to be inspected or checks the status of the activated carbon when it is shipped later and compares it to the time of warehousing. (100) is provided so that acquired information can be managed by the integrated management server (T).

The activated carbon inspection module 100 includes an activated carbon classification unit 110 that classifies the received activated carbon as new carbon or regenerated carbon, a sensor group that analyzes the physical and chemical characteristics of the activated carbon (moisture content, iodine content analysis, contained substances), and sensed It may include an activated carbon analysis unit 120 that stores and processes information, and an activated carbon positioning unit 130 that sets a storage location (considering storage block and empty space extraction) according to the type of activated carbon.

Furthermore, the activated carbon information storage unit 140 stores information on the storage location of the stored activated carbon and analysis state information at the time of storage, and analyzes the state of the activated carbon at the time of shipment to form state information and contrast information at the time of storage. It may be configured to include a contrast analysis unit 150 to.

In addition, the integrated management server T of the present invention enables control of the activated carbon transfer module 200 for transporting stored activated carbon or shipped activated carbon. That is, it is possible to control the driving of the conveyor for transporting the above-described activated carbon or the lifting and lowering operation of the stacker crane.

In the integrated management server (T), information on the storage location set in the above-described activated carbon positioning unit 130 is calculated, a drive line for moving to the storage location is extracted, and a conveyor of the drive line is operated. Conveyor drive unit 210, crane drive unit 220 that performs a control operation of driving a stacker crane that stores the moved storage activated carbon in a storage position through an elevating and descending operation, and a lane transfer section between conveyors When there exists, It may be configured to include a transfer cart controller 230 that controls the transfer cart (RGV) to perform transfer.

In addition, the integrated management server (T) includes an activated carbon management module 100, a storage activated carbon compartment area unit 310 for monitoring and displaying the remaining space of the storage space for storing activated carbon and the storage space in real time, A compartment area environment sensor unit 320 for displaying monitoring information by sensing the external air environment (humidity, temperature, gas condition) of each compartment area, and a ventilation fan to check the storage space condition and perform exhaustion if necessary. An exhaust control unit 330 that drives the exhaust control unit 330, and a drainage control unit 340 that collects and discharges the leaked water leaking from the storage space so that it can be configured to further include. In general, the management environment of the storage space for stored activated carbon is preferably maintained at a relative humidity of 70% or less, and the temperature is preferably maintained at 50° C. or less. In particular, it is important to control the generation of oxides, unsaturated oils, metal salts, absorbent gases, steam, and heat. Gas components are detected and exhausted or removed by oxidation, and unsaturated oils or metal salts are included in leaked water. Many of them can be removed by drainage treatment, and steam and heat can be removed and controlled through the exhaust system.

7 is a conceptual diagram illustrating a process of releasing activated carbon stockpiled and stored in the present invention.

Referring to the drawings of FIGS. 1, 2 and 7, the stockpiled activated carbon of the present invention goes through the following shipping process.

The process of releasing the stored activated carbon is the 7th step in which the request for the warehoused activated carbon is transmitted to the integrated management server (T) through the terminal of the spent activated carbon supplier (Sn) or the terminal of the activated carbon manufacturing facility (Rm), the integrated management The server T checks the stored information code that matches the stored activated carbon information described in the request signal in step 7, and sends a shipping instruction for the stored activated carbon stored in the storage location of the matching stored activated carbon to the stored activated carbon transport module 200. 8th step of transferring, 9th step of withdrawing the activated carbon stored in the storage space block receiving the shipment instruction by driving the elevating device of the stored activated carbon transport module 200, the activated carbon inspection module 100 for the withdrawn activated carbon Step 10 of analyzing current status information of activated carbon and forming release information in comparison with status information at the time of warehousing. It may include 11 steps of transmitting to the terminal and finally shipping the shipped activated carbon.

Specifically, looking at the warehouse department in detail, first, 7 steps are performed in which a warehouse request for activated carbon is transmitted to the integrated management server (T) through the terminal of the spent activated carbon supplier (Sn) or the terminal of the activated carbon manufacturing facility (Rm). do.

In the case of this 7th step, the client who initially stocked and stocked recycled charcoal or new charcoal requests release of the same product stocked and stocked, and in the stockpile warehouse of the present invention, the source and type of activated carbon , storage location, and storage information code that integrates status information is searched so that matching warehousing activated carbon can be released.

That is, the integrated management server (T) checks the storage information code that matches the stored activated carbon information described in the request signal in step 7, and receives a shipping instruction for the stored activated carbon stored in the matching stored activated carbon storage location. Eight steps of delivery to (200) are performed. As shown in FIG. 7, assuming the case of coal received and stored in the storage container 500 in the stacker crane (SCR1) constituting the transfer module 200, the lifting and lowering operation is performed through the stacker crane (SCR1) at the storage position. Delivery is made through

The process of being shipped out is carried out in 9 steps, in which the lifting and lowering device (stacker crane) of the stored activated carbon transport module 200 is driven to take out the activated carbon stored in the storage space block receiving the warehoused instruction.

The activated carbon withdrawn goes through 10 steps of analyzing current status information of the activated carbon in the activated carbon inspection module 100 and forming release information in comparison with status information at the time of warehousing. This is to ensure reliability by comparing the quality status at the time of warehousing and the time of shipment through the contrast analysis unit 150 described above in FIG.

Thereafter, step 11 is performed in which the release information is transmitted to the terminal of the waste activated carbon supplier (Sn) or the terminal of the activated carbon manufacturing facility (Rm) having a request for release, and the final release of the released activated carbon. Referring to FIG. 7, this process transfers the stored activated carbon accommodated in the storage container unloaded through the stacker crane (SCR1) through the conveyors (C7 to C9), and then through the upper crane (CR) or forklift (T2) Through this, it is loaded into the transportation vehicle T1 and taken out.

8 is a diagram showing the structure of a stacker crane (SCR) used in the present invention.

In the case of a stacker crane, it goes without saying that a known device structure can be applied. In the present invention, as shown in FIG. 8, it has column parts 410 disposed on the left and right sides, and has an upper frame 420 and a lower frame 440, and is seated on the column part 410 to win. A lifting unit 430 performing a lowering operation is provided. In the case of the elevating unit 430, an elevating and descending operation is performed through a driving motor m1, and a carriage capable of moving up and down, left and right, and forward and backward is provided, and activated carbon (ton bag or storage container) seated on the carriage is loaded. It can be stored or shipped to the storage location. Normally, the weight of one ton bag of stored activated carbon is usually between 600 and 700 kg, and it may be equipped with a crane capacity that can lift and lower up to 5000 kg.

9 is a rear cross-sectional view showing the arrangement of the stacker crane and the storage space block of the present invention.

The storage space block in the present invention, collectively referred to as a storage cell, may be implemented as a structure in the form of a steel structure that implements a space capable of accommodating one or a plurality of tone bags or storage containers.

As shown in FIG. 9, the storage space block for storing syntan is divided into a syntan storage space block Rg1 for storing syntan and a reclaimed coal storage space block Rg3, and the space block is a unit cell ( A structure in which a plurality of unit storage spaces such as CE1) is stacked on top can be configured.

As shown, the stacker crane 500 is disposed on the side of the space block implemented in a stacked manner, and the stored activated carbon is applied in a manner of withdrawing or storing a ton bag or storage container.

10 is a diagram illustrating the arrangement structure of the activated carbon stockpile of the present invention.

It is an exemplary view in which a plurality of stacked structures are formed in the form of a storage space block, and the coal storage blocks Rg1 and R2 and the recycled coal storage block Rg3 are separately stored. In this case, in the case of the recycled coal storage block (Rg3), a drain pipe is formed at the bottom so that water can be collected and discharged to the wastewater treatment plant 600, and such a drain pipe can also be configured in the new coal storage block. This is desirable in preparation for occurrence of internal moisture or partial drainage, but it is the reclaimed charcoal storage block that is provided with drainage facilities as an essential component, because the moisture content of reclaimed charcoal is very high.

In addition, in the case of stored activated carbon, absorbent gas, oxidizing matter, and polluted air are generated, and equipment such as dust collectors w1 and w3 for collecting dust by intake may be additionally disposed, and the collected gas by intake A purification facility may be further provided so that components can be removed under combustion through the combustion furnace w2. These purification facilities are illustrative, but not limited thereto.

As described above, the technical spirit of the present invention has been specifically described in the preferred embodiment, but the above preferred embodiment is for explanation and not for limitation. As such, those skilled in the art will understand that various embodiments are possible through the combination of the embodiments of the present invention within the scope of the technical spirit of the present invention.

Management facilities, devices, and operation methods capable of stockpiling and storing regenerated carbon or new activated carbon of waste activated carbon according to the present invention are storage and stockpiling of recycled activated carbon or new activated carbon for domestically generated waste activated carbon and stockpiling capable of history quality control By establishing a warehouse system, the history management of activated carbon is performed for each business site, and the quality status of activated carbon can be monitored in the activated carbon discharge facility, so that the activated carbon in stock has the quality of substantially the same state as the received state. Optimization of the quantity management of activated carbon can be implemented by allowing the quantity to be shipped to one business site upon request for stockpiling.

In particular, in the case of the stockpiling warehouse system according to the present invention, it may be used for stockpiling and storing waste activated carbon. In this case, waste activated carbon can be recycled in connection with a recycling facility, manufactured into granular activated carbon, and re-supplied to a water purification plant. The field of application can be expanded. That is, in the case of waste activated carbon supplied from water purification, etc., it can be stored in the stockpile of the present invention, recycled into recycled activated carbon through a related recycling facility, made into powdered activated carbon, and the powdered activated carbon is granular using a special binder. It can be applied and expanded to a system that manufactures activated carbon and resupplies and supplies it to the water purification plant.

Sn: Spent activated carbon supplier
Rn: Spent activated carbon regeneration facility
Rm: Activated carbon stockpile
100: activated carbon inspection module
200: activated carbon transfer module
300: stored activated carbon management module
T: integrated management server
400: stacker crane (elevating device)
500: storage container

Claims (6)

The spent activated carbon supplied from the spent activated carbon supplier (Sn) where the spent activated carbon is generated in the storage device, the recycled activated carbon regenerated at the spent activated carbon recovery facility (Rn), or the new activated carbon manufactured at the activated carbon manufacturing facility (Rm) is activated carbon. Step 1 of receiving the information stored in the storage warehouse (Rg) in the integrated management server (T);
The activated carbon inspection module 100 of the integrated management server (T) collects and analyzes physical and chemical state information including history information including the type, import source, and weight of the warehousing activated carbon and the iodine value and water content of the activated carbon Step 2 of calculating storage information;
Based on the information analyzed by the activated carbon inspection module 100, the integrated management server T determines the storage method of the received activated carbon, selects the storage location, and then determines the source, type, storage location, and status information of the activated carbon. A comprehensive storage information code is formed, and the recycled charcoal recycled in the spent activated carbon recycling facility (Rn) is determined by the ton bag acceptance method, and the recycled charcoal storage block (B1) among the storage space blocks built in the activated carbon stockpile warehouse (Rg). ) Step 3 of setting a storage location to store in;
The activated carbon received from the activated carbon transfer module 200 is transported through a conveyor in a ton bag accommodation state or a storage container accommodating state with the storage information code attached, and placed on a transfer pallet disposed in an elevating device, but the tone bag accommodation method If it is, a fourth step of transferring to a dedicated conveyor disposed on a moisture absorption plate on the surface of the conveyor and having concave-convex fixing protrusions on the top of the moisture absorption plate;
Step 5 of driving the lifting and lowering device in the storage activated carbon transport module 200 to lift the transfer type pallet and store it in a storage space block built in an activated carbon stockpile warehouse Rg;
In step 3, in the case of determining the 'activated carbon storage method', in the case of storing reactivated carbon with a high water content in the form of storing stored activated carbon, it is determined to store in the form of ton bag accommodation,
When the 'activated carbon storage method' is selected as a ton bag storage method for recycled charcoal, the ton bag made of non-woven fabric that accommodates the recycled charcoal inside is transported and stored as it is, but a belt conveyor structure in the case of a recycled charcoal conveyor (C6) performing the transport A moisture absorbing member 30 is placed on the surface of a general conveyor structure in which (10) rotates through the drive roller 20 to absorb moisture and dust generated from the tone bag,
The moisture absorbing member is formed as a plate-shaped member made of urethane material, and a structure in which a plurality of moisture absorbing holes are formed on the surface is applied, and a moisture blocking barrier 32 is formed around the moisture absorbing member. It is implemented on the surface of the conveyor belt and implemented in a structure in which a concave-convex pattern 33 protrudes through the surface of the moisture absorbing member,
After step 5, the storage environment of the stored activated carbon stored in the stored activated carbon management module 300 is sensed through a sensor to adjust the humidity, temperature, and gas state, but the environment of the storage space for maintaining the storage environment of activated carbon. A number of sensors that sense the state are used, and the storage environment is controlled to maintain a basic environment of 70% or less relative humidity and 50 degrees or less temperature. Step 6 of collecting and discharging runoff water;
Step 7 of transmitting a request for shipment of stored activated carbon to the integrated management server (T) through a terminal of a waste activated carbon supplier (Sn) or a terminal of an activated carbon manufacturing facility (Rm);
The integrated management server (T) checks the stored information code that matches the stored activated carbon information described in the request signal in step 7, and receives a shipping instruction for the stored activated carbon stored in the storage location of the matching stored activated carbon. The stored activated carbon transport module ( 200) in 8 steps;
Step 9 of withdrawing the activated carbon stored in the storage space block receiving the shipment instruction by driving the lifting and lowering device of the stored activated carbon transport module 200;
Step 10 of analyzing current state information of the activated carbon in the activated carbon inspection module 100 for the withdrawn activated carbon and forming shipment information compared with state information at the time of warehousing;
Step 11 of transmitting the release information to a terminal of a waste activated carbon supplier (Sn) or a terminal of an activated carbon manufacturing facility (Rm) having a request for release, and finally releasing the released activated carbon;
including,
Activated carbon storage warehouse operation method. delete delete delete The method of claim 1,
The lifting device,
A stacker crane disposed on the transfer carriage, a lifting unit for raising and lowering the transfer carriage, and a stacker crane having a pallet loaded into the storage space block with a ton bag or storage container seated on the upper portion; applying,
How to operate an activated carbon stockpile. delete

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