Xử lí nhớt thải bằng phương pháp vật lý và hóa học

Mình đang nghiên cứu đề tài tái chế nhớt thải bằng phương pháp vật lý (ly tâm, màng lọc, chưng cất, trích ly) và phương pháp hóa học (dùng hóa chất) Các anh chị có thông tin tài liệu hay kinh nghiệm, chia sẻ với mình nhé!:art (

Hi,

Nhớt thải rất đa dạng. Do vậy, nếu là sinh viên làm nghiên cứu khoa học thực hành, bạn cần chuẩn bị rõ :

• Các điều kiện đầu vào cho việc xử lý nhớt thải: thiết bị hiện có trong điều kiện phòng thí nghiệm hoặc nơi liên kết đào tạo, các kết quả phân tích về nhớt thải, nguồn gốc nhớt thải
• Các điều kiện về đầu ra : chỉ tiêu yêu cầu cho một chủng loại nhớt tái chế.

( nếu bạn thấy hữu ích thì xem tiếp.Bạn cần cân nhắc kỹ trước khi bạn thực hiện tiếp điều này)

[hide]Quy trình xử lý nhớt thải phụ thuộc rất nhiều vào các giá trị phân tích nhớt thải đầu vào. Dựa vào đó, người ta thiết kết ra quy trình tái chế chuyên biệt cho từng nhóm loại nhớt thải. Điều này có nghĩa bạn phải tiến hành các giai đoạn :

1- Phân tích nhớt thải và định rõ xuất xứ của nó. 2- Thiết kế các quy trình xử lý (bước xử lý, thông số vận hành) 3- Lựa chọn quy trình theo điều kiện thiết bị 4- Chạy thử và phân tích nhớt đã xử lý 5- Hiệu chỉnh thông số vận hành của quy trình theo kết quả phân tích nhớt tái chế đầu ra… 6- Trở lại giai đoạn 4 cho đến khi đạt yêu cầu

Hiện nay, các tài liệu tái chế nhớt thài có thể tìm thấy không tập trung trong một cuốn sách hay một bài báo cụ thể nào. Chúng rải rác theo đề tài bàn luận. Có một bài bạn có thể tham khảo qua:

( từ [i][b][COLOR=“green”]http://findarticles.com/p/articles/mi_qa5322/is_200505/ai_n21372067[/b][/i]

Used lubricants: recycle or regenerate?

Many different words are used to describe the recycling of waste materials such as used lubricants. Commonly used terms include:

• Reclamation: Recovery of useful products from wastes.

• Recycling: Reclamation for further use.

• Regeneration (or Reconditioning): Restoring to good condition.

• Remanufacturing: Manufacturing again.

• Rerefining: Refining again.

• Re-use: Using again.

For used lubricants, the three disposal options are rerefining (recycling), regeneration (re-use) or waste energy recovery.

Recycling, which involves the collection of waste materials, their processing into new products and the use of those products, is preferred by the European Commission. However, traditional rerefining processes for used lubricants face problems of byproduct disposal, particularly acid residues or clay sludges. More modern rerefining processes used in Europe and North America are interesting but are not free of problems, catalyst poisoning, for example.

Key issues for rerefiners of used lubricants include:

• The variability of feedstock quality.

• Unknown contaminants and the resulting complexity of the chemical analysis required to determine exact processing conditions.

• The removal of non-recyclable components, such as oil-soluble oxidation products, condensed carbonaceous compounds, wear metals and degraded additives.

• Disposal of solid wastes.

• Rerefined base oil quality and acceptance.

• Economics.

The overall economics of lubricants rerefining depend on several factors, including the availability and cost of used oils as feedstocks, process costs, product yields and the values of products and byproducts. These factors can vary substantially between markets. In some countries, collection costs are subsidized, so the cost of feedstock is very low. In other countries, used oils have an alternative value as fuel, so the cost of feedstock to a rerefiner is much higher.

Thermal energy recovery from used lubricants, recommended by the oil industry, is currently the fate of most used lubricants in North America. However, air emission legislation is tightening, resulting in the imposition of restrictions. In some areas, used oil is subject to hazardous waste incineration standards.

Regenerating (reconditioning) used lubricants returns them to their original specification or performance properties. Regeneration can be done as part of normal lubricant use, for example, when turbine or compressor oil returning to a system supply tank is passed through a combination of depth and adsorbent filter units. These remove solids, wear metals, water and oxidative and thermal degradation products continuously. This practice is relatively common in large industrial turbine and power-generating systems.

Regeneration can also be done at a customer’s site using truck-mounted units. Complete regeneration of the oil in a large electrical substation transformer can be completed in less than eight hours using an on-site truck unit, obviously with the transformer isolated from the electrical supply system.

Regeneration processes can be relatively simple. The used oil is dewatered to remove small amounts of free and dissolved water and then filtered to remove solids. It is then passed through an absorbing filter, usually diatomaceous clay, to remove oil-soluble degradation products and degraded additives. Once all the impurities have been removed, the oil is analyzed for kinematic viscosity, flash point, carbon residue, total acid number, additive content and other relevant properties. Where necessary, the oil is respiked with small amounts of new additives, so its performance is as good as new.

Unfortunately, not all used lubricants can be regenerated easily. Examples include automotive engine oils, severely degraded compressor oils, emulsion type fire-resistant hydraulic fluids and water-mix metalworking fluids. Lubricants that are very difficult or prohibitively expensive to regenerate must usually be burnt, incinerated, treated using rerefining processes or disposed using waste-treatment processes.

David Whitby is chief executive of Pathmaster Marketing Ltd. in Surrey, England. You can contact him at pathmaster@dial.pipex.com [/COLOR]

từ [i][b]http://reliabilityweb.com/index.php/articles/industrial_lubricants_reduce_re-use_recycle[/b][/i]

Summary

While lubricants are a relatively minor cost for many production operations, the cost associated with unscheduled break down of equipment as a result of lubricant failure can be significant. For example, an unexpected outage of a power station due to malfunctioning of a hydraulic control system would be extremely costly.

It is therefore necessary for users to ensure that the condition of the lubricants in the equipment is always within operational specifications.

Like many industrial components, over 80% of lubricants are being disposed of prematurely. Adhering to some simple guidelines can significantly extend the useful life of most lubricants resulting in reduced consumption, extended machine life, and minimized unscheduled shutdown maintenance.

Fundamental Chemistry

The first step to extending the useful life of a lubricant is to understand the fundamental chemistry of its ageing process. This enables the equipment manufacturer to design equipment to minimize ageing and the user to operate his equipment for maximum fluid life.

Measuring the ageing process:

Acid Number

During normal usage, lubricants form decomposition (oxidation) products in small quantities. Total Acid number (TAN) measures the rate of decomposition by indicating the amount of acid present. It is expressed as the number of milligrams of potassium hydroxide (KOH) necessary to neutralize 1 gram of lubricant.

The standard Acid Number specification for most lubricants is less than 1 mg KOH/gm. Chemical breakdown of lubricants, known as hydrolysis, is greatly accelerated when moisture in the lubricants becomes too high or when the lubricant temperature becomes excessive.

In other words, the main points to keep in mind about the lubricant breakdown process are: · Water is needed and will accelerate the process of hydrolysis · Heat accelerates the process, and · The acid produced and/or some introduced contaminants can catalyze further hydrolysis.

Therefore the best way to prevent your lubricant from ageing is to keep the system as dry as possible, avoid unnecessary high temperature conditions and maintain a low acid number through a comprehensive fluid maintenance program.

Heat

The operating temperature of many industrial lubricants can be kept low with good design considerations. Providing sufficient buffer fluid for example, will allow the heat to dissipate. In the case of mobile equipment where there is limited space, the use of an appropriate heat exchanger is recommended.

Most functional fluids such as hydraulic oils are employed to convert electrical energy to mechanical energy. These fluids are not subjected to high heat stress and therefore will age very slowly. Heat can however be absorbed by the lubricant if the fluid has a high air content. The surging pressure experienced by the fluid will compress and expand the air, heating it, resulting in high lubricant temperature.

As a general rule, every 10oC increase in operating temperature over the “nominal” level would reduce the useful life of the lubricant by half.

Contaminants

Contamination in lubricants can either be introduced or self generated. The typical contaminants in lubricants include:

Particulate contaminants:

All new systems will contain some contaminant left during manufacture and assembly. This usually consists of fibrous material from rags, casting sand, pipe-scale, cast iron and other metal particles, jointing material and loose paint.

When a normal system has been run-in for a reasonable period, the majority of solid contaminants will be in the form of small platelets, created by bedding-in and the normal wear process, the bulk of which are between 5 and 15 microns in size. Because of their size and shape, they can take a long time to settle.

The other common form of self-generated contaminant is that local cold welding microscopic surface particles will be torn off when they move in relation to each other releasing wear particles.

Unless extreme care is taken in filling and topping up a system, considerable quantities of contaminant can be added during these processes. Many of these contaminants are likely to be abrasive.

A lubricating system can also be contaminated by ingression through the oil film on seals. Worn seals will increase this possibility. Contamination will be introduced if all reservoir openings are not fitted with air breather filters.

The other mechanisms that cause self-generating contaminants include: adhesive, abrasive, erosion, fatigue, de-lamination, corrosive, electro-corrosive, fretting corrosion, cavitation, electrical discharge and polishing wear. Each of these types of wear categories has its own mechanism and symptoms, however in practice they may occur singularly, combined or in sequence.

Gases

Nearly all lubricants contain some dissolved gases, and at atmospheric pressure hydraulic oil normally contains 8% of its volume as dissolved air, which in this state causes no problem. However, the presence of air bubbles in a system will cause erratic operation, and air bubbles in suction lines can damage some types of pumps.

It should be noted that entrained air in fluids, when compressed to 2000 psi or more, could become very hot locally. This generated heat causes the fluid surrounding the bubble to burn. As the products of combustion are both fluid and solid contaminants, more contamination can be generated reducing the life of the equipment.

Moisture and Chemicals

The detrimental effect that water and chemicals can have in hydraulic systems are, in certain systems, equal to or greater than operating a dirty hydraulic system.

There are two distinct phases of water that can be present in oil - free and dissolved water. Free water can also be present in the form of an emulsion - microscopic droplets of water distributed throughout the fluid.

Water, in excess of the oil’s saturation point, damages a system through accelerated abrasive wear, corrosion and fluid breakdown. Tests conducted at the Fluid Power Research Center at Oklahoma State University indicate that the presence of water significantly increases component sensitivity to abrasive wear from particulate contamination.

Most components exhibit much greater deterioration in performance when both dirt and water are present compared to dirt alone. Excessive water can impact on the system performance and fluid chemistry, adversely resulting in numerous problems such as: · Accelerated corrosion · Reduced bearing life · Thinner load-bearing oil film · Material fatigue · Accelerated oil oxidation · Change in viscosity · Deterioration of oil additives · Bacterial problems

Given the saturation point of water at 65oC is about 200ppm (0.02%), a moisture content exceeding 200 ppm will result in the formation of free water in the system - more free water in cooler regions of the system or when the system is not in operation.

This free water can react with products of lubricant oxidation and additives to form organic acid compounds and “sludge” that will compromise hydraulic performance.

MEASURING CONTAMINATION IN LUBRICANTS There are several tests that either measure or give an indication of the amount of contamination in a lubricant, depending on the type of oil tested and its functional requirements.

Fluid Sampling and Analysis

Long before a lubricant is ready to be analyzed, provisions must be made to obtain the samples from the lubricating system and minimize the chance of additional contamination getting into the system. While many sampling methods are available this is not included in the scope of this article. More information on this topic is available from the author.

Contamination Levels

There have been several attempts to categorize degrees of contamination in fluids, including the ISO Cleanliness Code, SAE 749-1963, and the National Aerospace Contamination Limits NAS1638.

These different cleanliness level indicators can be compared in a Cleanliness Level Correlation Table.

The NAS-1638 classification shows the classification system issued by the National Aerospace Standards Committee. The system classes are numbered from 00 through 12. The particle contamination limits for new fluids and different type of hydraulic systems are also shown in the table below for comparative purposes.

Class No.6 (approx. NAS Class 9) indicates the particulate levels of hydraulic fluid as received from the refinery or oil supplier. An SAE Class No. 3 level or lower is preferred.

Class No.4 (approx. NAS Class 7) indicates the particulate level of hydraulic fluid required for most conventional hydraulic systems that do not include hydraulic pressure regulators or hydraulic servo-control valves.

Class No.2 (approx. NAS Class 5) indicates the particulate level of hydraulic fluid required for hydraulic systems when there are hydraulic pressure regulating valves and hydraulic servo-valves.

Maintenance of System Cleanliness

A new lubricant fill in a machine is kept clean by the action of filters and by the chemical action of the additive package in the lubricant. The types of filters used in most instances remove solid or gelatinous particles to the limits of the filter. These filters do not generally remove the liquid or gaseous contaminants.

Effective contamination control is not just a matter of filters. System planning, location of filters, heat exchanger capacity, etc. are but a few of the items that have been considered in a machine’s design to reduce the generation of particulate contamination.

Contamination Limits

Barring isolated instances, it is generally recognized that by having clean lubricant, equipment will give better performance and more reliability. Changing filter elements at given regular time interval, is not desirable, nor necessary.

If installed, filter elements should be changed whenever the differential pressure across the filter exceeds the suggested maximum differential. The degree of filtration (micron rating) will depend on the type of equipment and /or the manufacturers recommendations.

Contamination Removal

Removing the contaminants present in a lubricant before they become a problem will prevent the fluid from deteriorating to the extent that it is rendered un-usable. This will extend the useful life of the lubricant and reduce its consumption.

The process involves routine testing of the fluid to determine the condition of the fluid and the system, and taking corrective action before the contamination becomes unacceptable.

The contaminants present can be removed from the fluid by various means.

These include: · Filtration · Separation · Centrifugation · Pasteurization · Vacuum dehydration · Ion exchange filtration · Coalescing filtration · Water Absorbing Element filtration · Others

While removing solid contaminants can be done relatively easily and that most lubricating systems have filtration units installed to manage this aspect, very few systems have the capability of removing moisture, chemicals and gases.

Methods of Water Removal

Centrifugation The separation of moisture by means of centrifugation utilizes centrifugal force developed by rotating the oil at high speed. Solid particles and water are thrown outward and are continuously drained. Dry oil leaves the centrifuge from the center of the separation bowl. Whilst a centrifuge is an excellent piece of equipment for removal of bulk free water, it will not remove dissolved or emulsified water and is generally expensive to run with high maintenance and operating costs.

Coalescence

This is a process through which tiny water droplets come together and form one large droplet. This form of water removal from oil uses special cartridges, which combine small dispersed water droplets into larger ones. The large water drops are retained within a separator screen and fall to the bottom of the filter while the dry oil passes through the screen. Coalescers are greatly affected by the properties of the carrier liquid, including interfacial tension and viscosity, but are a simple means of removing a small percentage of free water.

Water Absorbing Elements

Water absorbing filters are usually a non-woven polymeric medium containing an immobilizing water absorbing polymer. This polymer has been modified to retain its integrity as it chemically bonds water. The water retention capacity of these elements is dependent upon the oil viscosity and flow rate. These elements are an effective means of removing and retaining only small quantities of free and emulsified water, which are not considered economical for larger system or those that suffer continual water ingress.

Vacuum Dehydration

Vacuum dehydration purifiers employ the principles of mass transfer to achieve high efficiency removal of water and gases. To achieve an efficient mass transfer the processed fluid must have a large surface area. This is produced by a variety of techniques including spinning discs, distribution rings and spray nozzles.

Free and dissolved water and gases are removed by exposing the contaminated fluid to a low relative humidity atmosphere, which is obtained by maintaining a chamber vacuum. When air is drawn into the vacuum chamber, it expands to about five times it former volume resulting in five times reduction in relative humidity. Water and gas molecules are attracted to the lower vapour pressure produced in the chamber and are exhausted along with the airflow.

Vacuum dehydration will achieve reductions of up to 100 percent of free water and gases and most of the total dissolved water and gases - to approximately 100 parts per million.

Reprocessing Methods

There are several options available to equipment owners to reprocess their lubricants. These include on-site and off-site reprocessing.

On-Site Reprocessing

There are many advantages in processing lubricants on-site. Some on-site oil reprocessing companies are able to provide this service while the equipment is still running. The advantages of this process include:

1. No machine down time There is no need to shut down the machine while the fluid is being reprocessed. There is therefore no loss in production.

2. No mess no fuss There is no need to arrange drums or suitable storage tanks, transfer pumps etc., and to organize the transferring of oil from the system tank into these storage facilities. Often, the transferring of fluid from the system tank to temporary storage facilities can cause spills resulting in massy clean up exercise.

3. Bonus System Flush Since the system will be running throughout the process, newly reprocessed fluid will flush out contaminants trapped in the pipe-works, the valves and other system components. This process can often produce a system that is cleaner than when it was newly installed.

4. Little disruption to operation There will be minimal disruption to customer operation. The only potential interference are hoses that run from and back to the reprocessing vehicle and the presence of the reprocessing vehicle.

Oilclean on-site side-stream reprocessing offers:

· State of the art dehydration facilities that are very effective in removing moisture from oil. · State of the art filtration systems. · Skilled operators backed up by engineers and laboratory support. · Allows your machine to continue operating while the fluid is being brought back to specification. · Flushes the system with cleaned fluid while it is running. · Extend its useful life of lubricants. · Reduce its cost associated with waste disposal. · Reduce its consumption of new oil.

Off-site reprocessing

The oil is removed from site to a recycling facility for reprocessing. This option is becoming less attractive due to the continuous tightening of environmental regulations governing transportation of prescribed waste.

Off-site disposal

The oil is removed from site to be disposed of as prescribed waste. Similar to the above, this option is becoming more costly due to the continuous tightening of environmental regulations governing both transportation and disposal methods.

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Nếu bạn là người sản xuất thì bạn nên cân nhắc về thực hiện đề tài nghiên cứu tiền khả thi theo hướng hợp tác với các nhà chuyên môn.

một vài dòng không biêt giúp gì bạn ko. Loại bỏ các tạp chất nổi này khỏi nước thực chất cũng giống như lắng các chất rắn, chỉ khác là trong trường hợp này tỷ trọng của hạt nhỏ hơn của nước do đó hạt sẽ nổi lên. Trong phương pháp này người ta sử dụng 2 loại bể lắng là bể thu dầu và bể thu mỡ. Kích thước hạt dầu đuọc chọn là 0,008 -0,01 cm. Trong bể nhờ sự khác nhau về trọng lượng riêng của dầu và nước mà dầu , nhớt được nổi lên trên và được gạt ra ngoài bằng hệ xích và thanh gạt. Việc loại dầu khỏi bể cũg tùy thuộc và bề dày của lớp dầu. Trong điều kiện thông thường, hiệu suất đạt được tới 97-98%, tuy nhiên lựơng dầu còn lại vẫn cao, khoảng 100mg/l. Đây là một phương pháp vật lý và không sử dụng hóa chất. đối với cái có tỷ trọng cao hơn thì ta làm ngược lại nhé! cái này trong máy ko nhớ kiếm ở đâu. mình nghĩ tam thời cũng chủ yếu dùng các phương pháp vật lý thôi bạn.

Hi,

Vấn đề tái chế nhớt thải và cặn dầu mỡ bôi trơn tại VN hiện nay đang bị lạm dụng theo hướng mua chất thải từ Đài Loan, các khu CN, các khu chế xuất về để làm lại.

Theo thông tin mới đây, cảnh sát knh tế và môi trường đã theo dõi và bắt quả tang một công ty nhập lậu chất thải độc hại nói trên dưới dnah nghĩa hàng dung môi methanol về để xử lý.

Theo tinh thần tôn trọng pháp luật và bảo vệ môi trường, tôi đóng topic này để tránh bị lạm dụng thông tin vào mục đích tương tự nói trên.

Thân ái,

Teppi