Copyright © 2023 O. Dykha, M. Hetman, A. Staryi, T. Kalaczynski. This is an open access article distributed under the Creative 
Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the 

original work is properly cited. 
 

 

 

Problems of Tribology, V. 28, No 2/108-2023, 62-69 
 

Problems of Tribology 
Website: http://tribology.khnu.km.ua/index.php/ProbTrib 

E-mail: tribosenator@gmail.com 
 

DOI:  https://doi.org/10.31891/2079-1372-2023-108-2-62-69 

 

 

Review of aspects of processing and use of waste cooking oils as effective 

lubricants 
 

O. Dykha1*, M. Hetman1, A. Staryi1, T. Kalaczynski2 

1Khmelnytskyi national University, Ukraine 
2Politechnika Bydgoska im. Jana i Jędrzeja Śniadeckich, Poland 

*E-mail: tribosenator@gmail.com 
 

Received: 10 May 2023: Revised 10 April 2023: Accept 16 June 2023 
 

 

Abstract 

 

In connection with environmental pollution and the depletion of oil reserves, biologically based lubricants 

have received great interest as a replacement for mineral oil-based lubricants. Biolubricants have a number of 

advantages over mineral lubricants, including high biodegradability, low toxicity, lubricating properties and 

minimal environmental impact. The presented review describes the main characteristics and properties of 

biological lubricants, various vegetable oils, which are used as raw materials for the production of biolubricant 

materials. The physicochemical properties of biological lubricants were analyzed from the point of view of 

improvement. The technological processes used for the chemical modification of vegetable oils, ensuring the 

lubricity and anti-wear properties of the obtained biolubricants are determined. Various additives used to improve 

the properties of biolubricants are also recommended. This review material will provide researchers and 

practitioners with additional information on the practice of using biolubricants. 

 

Keywords: vegetable oils, food industry waste, environmental friendliness, chemical modification, 

physical processing, lubrication, wear resistance 

 

Introduction 

 

Worldwide concern over the massive use of petroleum-based products is affecting the production of 

lubricants in a way that also requires the search for new oil-free technologies. Nowadays, environmental protection 

requirements [1-6] have turned biodegradability into one of the main parameters from the point of view of choosing 

base oils and improvers of lubricating properties of materials. It is known that various vegetable oils are suitable 

as base oils for lubricants. However, the large acreage devoted to industrial oil crops competes with the use of land 

for food production, and this is a major controversial issue. Thus, the production of biolubricants based on edible 

vegetable oils has recently been considered an unsustainable practice. In addition, 

 

Main material 

 

Edible vegetable oils are widely used for frying, which is usually carried out at a temperature of 160 to 

180 ◦C in the presence of air and moisture. At the same time, chemical changes occur as a result of thermo -

oxidative and hydrolytic reactions, isomerization of double bonds, oligomerization and degradation of 

triglycerides. Thus, the chemical composition of the oil after frying is different from the original fresh oil, it 

undergoes undesirable physico-chemical changes (among other things, color, smell, viscosity, acidity, general 

polar compounds). In recent decades, the amount of waste cooking oil (WCO) generated by the food industry, 

restaurants, fast food establishments and homes has been continuously increasing, at a rate of up to 2% per year, 

due to the increase in food products and, above all, the consumption of fast food by the population. 

There is inadequate disposal of WCO through the sewage system, causing both economic problems and 

pollution of rivers and soils. On the one hand, the irrational disposal of used cooking oil in the sewer creates 

problems with the operation and maintenance of municipal sewage treatment plants, which significantly increases 

the costs of their cleaning. 

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Problems of Tribology 63 

 

 On the other hand, one liter of waste vegetable oil poured into the environment can pollute 0.5 million 

liters of water, which will cause serious environmental problems [1-4]. Therefore, proper management of WCO is 

mandatory to reduce its impact on the global environment and improve their availability for reuse in various 

industrial processes such as bio-lubricants, biodiesel, asphalt additives and others. 

 The use of WCO as a feedstock in biodiesel plants is an established practice. However, demand for 

biodiesel is currently declining to reduce harmful emissions, and many biodiesel plants are closing around the 

world. Therefore, other methods of reuse should be explored to reduce the negative environmental impact and 

greenhouse gas emissions of WCO. With this in mind, bio-lubricants can be a way to use waste cooking oil with 

a dual purpose. First, it can prevent non-food land use; secondly, it can prevent their potential impact if disposed 

of in the environment. Therefore, other methods of reuse should be explored to reduce the negative environmental 

impact and greenhouse gas emissions of WCO. With this in mind, bio-lubricants can be a way to use waste cooking 

oil with a dual purpose. First, it can prevent non-food land use; secondly, it can prevent their potential impact if 

disposed of in the environment. Therefore, other methods of reuse should be explored to reduce the negative 

environmental impact and greenhouse gas emissions of WCO. With this in mind, bio-lubricants can be a way to 

use waste cooking oil with a dual purpose. First, it can prevent non-food land use; secondly, it can prevent their 

potential impact if disposed of in the environment. 

In general, most of the research work related to waste cooking oils focuses on the use of their fatty acid 

methyl esters for the production of WCO-derived molecules and elucidating their physicochemical characteristics 

[1-3]. There is insufficient information about the full physicochemical characteristics of the used WCO and the 

relationship between its physicochemical properties and tribological characteristics. 

Therefore, a comparative assessment of waste cooking oil from different food enterprises and an analysis 

of the influence of their physical and chemical properties on tribological behavior is needed. 

This review presents the results of the latest research in the field of using waste cooking oils for the 

production of technical lubricants. 

The work [1] reveals the achievements of modern scientists in the creation of environmentally friendly 

biodegradable lubricants. It is noted that the main problem is the development of a universal biodegradable base 

oil that could replace base mineral oils taking into account the preservation of the environment. The need for 

environmentally friendly products has been discussed for a long time in many forums. ASTM reviews the products 

available today and the tests required to determine performance criteria for biodegradable fluids. Synthetic fluids 

as a base oil have become widely used in a variety of industrial applications. Some of the applications include 

engine oils, transmission oils, hydraulic oils, compressor oils, pump and turbine oils. The choice of different base 

lubricants depends on the type of application, cost and biodegradability requirements. Vegetable oils are widely 

used for two-stroke systems, open gears, chain saws. For automotive lubricants with extended drain intervals, 

hydrotreated mineral oils are increasingly preferred. The development of chemically modified esters based on 

biological resources is a very profitable option for environmentally friendly applications. Development of synthetic 

esters from cost-effective sources for critical applications (automotive and industrial) is one of the best choices. 

Additionally, there is a need to develop hydrocarbon-based mineral oils with improved biodegradability and 

performance. Lubricants should be evaluated on the basis of increased thermal and mechanical stability, 

environmental safety and rapid biodegradability. 

In the review [2], lubricants on a biological basis, various vegetable oils used as raw materials for the 

production of lubricants on a biological basis are considered in detail. The physical and chemical properties of 

biologically based lubricants are described. Features of the processes used for chemical modification of vegetable 

oils, lubricating properties of bio-based lubricants, as well as various additives to improve the properties of bio-

based lubricants are highlighted. Vegetable oils have several advantages over conventional mineral oils, as they 

have a high level of biodegradability and are safe for the environment. The following methods of chemical 

modification of vegetable oils can be used to increase thermo-oxidative stability: transesterification, epoxidation 

or selective hydrogenation. The properties of biobased lubricants can also be improved by introducing additives: 

antioxidants, detergents and dispersants, nanoparticles, corrosion inhibitors, anti-seize additives and anti-wear 

additives. Bio-based lubricants appear to be promising alternatives for replacing petroleum-derived lubricants. 

Regarding the use of vegetable oils as lubricants on a biological basis, additional studies are being conducted to 

understand the lubrication mechanisms of these lubricants and their mixtures. 

In [3], two main types of WCO treatment are discussed in detail: chemical transformations to utilize the 

chemical functional groups present in the waste, and physical treatments such as extraction, filtration and 

distillation procedures. The first part, which concerns chemical synthesis, is mostly related to the production of 

fuel. The second part, related to physical processing, focuses on the production of biolubricants. In addition, during 

the description of the filtration procedures, special attention is paid to the development and application of new 

materials and technologies for the treatment of WCO materials. 

A technology based on a combination of water treatment and filtration on porous materials was made in 

[4], designing a mini-recycling plant aimed at the production of biolubricants from WCO (Fig. 1) [4]. 

The proposed technology can be described as follows: WCO is to be purified from water. The refined 

waste oil is then pushed to the filter module, where it is cleaned by a porous material. The combination of refining 

and filtration makes it possible to obtain purified processed vegetable oil. 



64 Problems of Tribology 

 

Despite the results achieved in the field of filtration, further efforts are needed to improve performance 

and cost-effectiveness. In particular, careful research is needed to reduce the amount of oil absorbed by cellulose 

filters, to reduce the cost of synthesis and regeneration of synthetic materials. 

In work [5], several types of cooking oil waste from various food establishments were investigated: a 

regular restaurant, a fast food restaurant, a fried food establishment, a mixture of used cooking oils of various 

unknown origins, without segregation 

Oil has undergone molecular distillation. Distillation of WCO does not require too much energy, so it can 

be considered economically feasible. Molecular distillation yields two fractions: a lighter fraction enriched in free 

fatty acids, and a heavier fraction containing the most polar compounds and a low fraction of undistilled free fatty 

acids. Both fractions are liquid at room temperature. 

 

 
Fig. 1. WCO recycling process [4]. 

 

Studies of WCOs have shown marked variations in their chemical composition associated with several 

variables involved in the various roasting processes investigated. Deep-fried oils showed a high content of free 

fatty acids and diglycerides due to the hydrolysis of triglycerides [5]. In contrast, lightly roasted WCO showed 

rather low acidity, indicating a lower degree of hydrolysis. Variations in the chemical composition had different 

effects on the studied properties. WCO with the highest content of molecules (oligomers, dimers and polymers) 

showed the highest kinematic viscosity. WCOs with the highest values of total polar compounds and acidity 

showed the lowest viscosity index values, while WCOs with the lowest acidity values showed the highest viscosity 

index values and were less sensitive to temperature. revealed that acidity also affects the fluidity of oils at low 

temperature, so oils with the lowest acidity values have the best fluidity at low temperature. It was found that the 

high acidity and high ratio of unsaturated and saturated fatty acids of the oils gave these WCOs the greatest 

lubricating ability [5]. 

Molecular distillation was shown to yield two fractions, light and heavy, with significantly improved 

tribological properties compared to their parent waste cooking oil. Thus, the low viscosity and high polarity of the 

light fractions enriched with free fatty acids provide improved lubricating characteristics both in extreme and 

mixed modes of friction. 

In the study [6] methylolpropane triester of fatty acid (TFATE) was obtained as a base oil of biolubricant 

material. This product was synthesized by transesterification of fatty acid methyl esters from waste cooking oil. 

The constituent reactions and oxidative stability of TFATE were analyzed. Under the selected conditions, TFATE 

was obtained with a yield of 85.7%. After purification by molecular distillation at 120 0C, the TFATE content in 

the product reached 99.6%. It has been proven that the chemical and physical properties of TFATE meet the 

requirements of ISO VG32. 

A study [7] showed that WCO can be successfully hydrolyzed by Candida rugosa lipase to obtain FFA at 

an enzyme concentration of 1 g L-1 within 30 hours. The resulting FFA can be esterified with a higher alcohol 

(octanol) using Amberlyst 15H to produce an environmentally friendly bio-lubricant. It was found that 

temperature, amount of catalyst, molar ratio of reagents (alcohol : FFA) have a significant effect on the reaction 

rate. Complete recycling can be achieved in minimal time by using a suitable desiccant to remove the water 

produced during the esterification reaction. It can be concluded from the experiment that the most favorable 

conditions for the maximum conversion in the minimum time are the molar ratio octanol : FFA 3 : 1, temperature 

80 ◦C, catalyst 2 g and desiccant (preferably silica gel powder) 50% by weight of FFA. 

Studies have shown that esters based on olive oil have the highest thermal oxidation resistance due to the 

low content of polyunsaturated acids. While NPG esters have higher stability in thermo-oxidative conditions. 

The polyols used during the transesterification process are NPG, TMP and PE. Each of them contains a 

different number of hydroxyl functional groups. In general, the viscosity of ester-based lubricants increases with 

polyol functionality. The number of hydroxyl groups affects the viscosity of esters in the following order: PE > 

TMP > NPG. Similarly, the viscosity of vegetable oil-based TMP esters is higher than that of equivalent esters, 

which may be due to the presence of three acidic groups in the ester structure. 

The introduction of separation into methyl ether lowers the solidification temperature, disrupting the 

alignment and construction of hydrocarbon chains. This allows the oil to solidify at lower temperatures. 

A specialized batch reactor (1.5 L) made of stainless steel was used to carry out esterification reactions 

under appropriate operating conditions (Fig. 2). The reactor was equipped with: a stirrer with an electric drive and 

a digital speed display (rpm); a thermostat that maintained the desired temperature of the liquid in the shirt; inlet 

channel for pouring the sample; sampling outlet equipped with a valve. 



Problems of Tribology 65 

 

 

 
 

Fig. 2. Schematic diagram of the reactor for the esterification reaction: 1- reactor, 2- stirrer, 3- reactor casing, 

4- thermocouple, 5- material output, 6 - material input, 7 - temperature indicator, 8- stirring speed indicator. 

 

The review [8] describes in detail biological lubricants, various vegetable oils used as raw materials for 

the production of biolubricants, physicochemical properties of biological lubricants, processes used for chemical 

modification of vegetable oils. The properties of biolubricants are considered, as well as various additives used to 

improve the properties of biolubricants. Low temperature characteristics are the main limitation when it comes to 

the use of vegetable oils as lubricants. Although vegetable oils have strong intermolecular interactions that provide 

a strong lubricating film, these interactions also result in poor low-temperature properties. 

The life cycle of lubricants obtained from renewable sources is shown in fig. 3 [8]. The main component 

of vegetable oils are triacylglycerols (98%), as well as various fatty acid molecules attached to the single structure 

of glycerol. 

 

 
 

Fig. 3. Life cycle of biolubricants 

 

Although the thermo-oxidative stability of vegetable oils can be a problem, this problem can be overcome 

by chemical modification of vegetable oils through transesterification, epoxidation or selective hydrogenation. 

Sunflower oil is extracted from sunflower seeds and is usually used for cooking, as well as for the 

production of margarine and biodiesel. Sunflower oil is cheaper compared to olive oil. Sunflower varieties differ 

in the content of fatty acids [9-11]. Sunflower oil with a high oleic acid content has many properties that make it 

suitable for use in lubricants, with good oxidation resistance and lubricity. [9-11]. One study showed that high 

oleic sunflower oil (HOSO) can be used to replace mineral oils in textile and leather production without technical 

problems or equipment modification [11]. The correct composition of sunflower oil can be compared with mineral 

oil. 

High oxidation resistance is an important criterion for lubricants, as low oxidation resistance will cause 

the lubricant to oxidize rapidly if left untreated. As a result, the lubricant thickens and polymerizes into a plastic 

consistency. Numerous studies were conducted to study the resistance of vegetable oils to oxidation [12-14]. The 



66 Problems of Tribology 

 

oxidation resistance of vegetable oils is generally lower than that of synthetic esters due to the higher degree of 

unsaturation in vegetable oils. Oxidation is undesirable because it leads to polymerization and degradation of the 

lubricant. 

Attempts to improve the low-temperature properties and oxidation resistance of vegetable oils include 

transesterification of trimethylolpropane and methyl ether from vegetable sources [15–17]. Transesterification is 

a reaction in which a triglyceride molecule reacts with three moles of methanol in the presence of an acidic or 

basic catalyst [18-19], resulting in the formation of glycerol and mixtures of methyl esters of fatty acids. 

The disadvantages of vegetable oils, such as low thermo-oxidative stability and cold flow, can also be 

enhanced by the use of additives. Manufacturers of different vegetable oils may choose different additives to meet 

the requirements of a particular application. For some oils, additives can be up to 5% (by weight). The presence 

of additives contributes to the improvement of the properties of lubricants and lubricants on a biological basis in 

terms of corrosion inhibition, as well as friction and wear characteristics. In general, esters with biodegradable 

additives have superior wear resistance compared to pure oils or blends of vegetable oils. 

Antioxidants are used to slow down or prevent the oxidation process by slowing the oxidative degradation 

of the lubricant, while ensuring that the lubricant meets the technical requirements [20]. 

Nanoparticles are effective additives for lubricants and bio-based lubricants to reduce friction and wear. 

Nanoparticles are considered to be more effective compared to conventional additives for protection against high 

pressure and anti-wear additives due to their environmental properties [21]. The properties of biolubricants depend 

on the properties of the nanoparticles, such as the size, shape and concentration of the nanoparticles. 

Friction in the contact of surfaces from the shear forces required to separate the interacting asperities. 

Friction and wear can be reduced by adding anti-wear and anti-seize additives to the oil. These additives create 

strong protective films on the metal surface, entering into a thermochemical reaction with the metal surface. Anti-

seize and anti-wear additives usually contain chlorine, phosphorus and sulfur [22]. These elements protect the 

surface of the metal with layers of sulfides, chlorine, or phosphides that are easily erased, preventing severe galling 

and wear. 

A fairly in-depth analysis of directions for processing used cooking oils is presented in the review [23]. 

It is noted thatthe use of biomass wastes such as used cooking oil (WCO) does not create competition and is a 

better source of resource recovery as it allows a second life cycle (Fig. 4). 

 

 
 

Fig. 4. Chain of cooking oil waste [23]. 

 

Valorization of WCO was realized by the following processes: transesterification, transesterification, 

hydrolysis, hydrodeoxygenation, hydrocracking and hydrogenation. Among them, transesterification is the main 

process that allows the production of biodiesel and bio-lubricant. Biodiesel can be obtained using heterogeneous 

catalysts having basic centers, acidic centers, a mixture of acidic and basic centers, or enzymes. Among 

heterogeneous catalysts, magnetic catalysts have been developed for easy separation of catalysts after each cycle. 

Homogeneous catalysts and enzymes as catalysts also allow the production of biodiesel. Various alternative 

technologies have been successfully studied, such as electrolysis, ultrasound, microwaves, continuous flow, even 

continuous flow with microwaves. Compared to transesterification, transesterification makes it possible to obtain 

biodiesel and triacetin instead of glycerol. Hydrolysis of WCO generates free fatty acids, glycerol, and water, while 

hydrogenation of WCO yields free fatty acids, free fatty aldehydes, free fatty alcohols, and alkanes via 

hydrodeoxygenation, hydrocracking using a similar petrochemical process. 

In [24], used cooking oil is chemically modified to obtain biolubricants. Three WCO-based fluids were 

synthesized and considered as base lubricants for environmentally friendly lubricants. Typical properties of these 

biolubricants, such as viscosity, viscosity index, solidification temperature, cloud point. Corrosion resistance, 

oxidation resistance and four-ball anti-wear properties were investigated. WCO and its derivatives were tested for 



Problems of Tribology 67 

 

friction and wear reduction using a four-ball friction machine. Experimental results indicate that chemically 

modified WCOs are an economic, sustainable and ecological substitute for mineral oils and will find potential 

practical applications in the field of lubricants. 

In order to reduce environmental pollution as a result of biolubricant synthesis, the study [25] developed 

an ecological and efficient strategy for the preparation of octylated biolubricant from waste cooking oil (WCO). 

First, it was hydrolyzed by lipase to obtain unsaturated fatty acids, and the latter were later concentrated by urea 

complexation. Further, new esters were synthesized by esterification with ethylhexanol using lipase, and new 

esters were additionally epoxidized. After that, the epoxy group was attacked with a reagent, octanoic acid, to 

obtain an octylated biolubricant. Articles [26-27] review recent advances in the synthesis of biolubricants from 

vegetable oils using chemical modification methods, such as esterification/reesterification, 

 

Conclusions 

 

An overview of the basic properties of biologically based lubricants, the role of chemical functionality 

and additives, as well as their relationship with the effectiveness of the lubricant is presented. Vegetable oils have 

several advantages over conventional mineral oils, as they are biodegradable and safe for the environment. 

Although the thermo-oxidative stability of vegetable oils may be insufficient, this problem can be overcome by 

chemical modification of vegetable oils by transesterification, epoxidation or selective hydrogenation. The 

properties of bio-based lubricants can also be improved by adding additives such as antioxidants, detergents and 

dispersants, viscosity modifiers, nanoparticles, corrosion inhibitors, extreme pressure and anti-wear additives. 

 

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Problems of Tribology 69 

 

 

Диха О., Гетьман М., Старий А., Калачинський Т. Огляд аспектів переробки і застосування 

відпрацьованих кулінарних олив як ефективних мастильних матеріалів 

 

У зв'язку із забрудненням навколишнього середовища та виснаженням запасів нафти мастила на 

біологічній основі викликають великий інтерес як заміна мастилам на основі мінеральних масел. 

Біомастила мають низку переваг перед мінеральними мастильними матеріалами, включаючи високу 

здатність до біологічного розкладання, низьку токсичність, змащувальні властивості та мінімальний вплив 

на навколишнє середовище. У представленому огляді описано основні характеристики та властивості 

біологічних мастил, різноманітних рослинних олій, які використовуються як сировина для виробництва 

біомастильних матеріалів. Проаналізовано фізико-хімічні властивості біологічних мастил з точки зору 

поліпшення. Визначено технологічні процеси хімічної модифікації рослинних олій, що забезпечують 

змащувальні та протизносні властивості отриманих біомастильних матеріалів. Також рекомендуються 

різні добавки, що використовуються для поліпшення властивостей біомастильних матеріалів. Цей 

оглядовий матеріал надасть дослідникам і практикам додаткову інформацію про практику використання 

біомастильних матеріалів. 

 

Ключові слова: рослинні олії, відходи харчової промисловості, екологічність, хімічна модифікація, 

фізична обробка, змащення, зносостійкість.