APPLICATION OF DIGITAL CELLULAR RADIO FOR MOBILE LOCATION ESTIMATION


IIUM Engineering Journal, Vol. 22, No. 2, 2021 Odilov et al. 
https://doi.org/10.31436/iiumej.v22i2.1768 

EFFECT OF MAGNETIC FIELD ON THE PHYSICAL 

AND CHEMICAL PROPERTIES OF FLOWING 

LUBRICATING COOLING LIQUIDS USED  

IN THE MANUFACTURING PROCESS 

ERKIN ODILOV1, UMIDJON MARDONOV2*, KHUSNIDDIN ABDIRAKHMONOV2,

ABDUGANI ESHKULOV1 AND BEHZOD RAKHMATOV3

1
Faculty of Mechanic, 

2
Faculty of Machine Construction,  

Tashkent State Technical University, Tashkent, Uzbekistan 
3
Faculty of Chemical Technology of Inorganic Substances, 

Tashkent Institute of Chemical Technologies, Tashkent, Uzbekistan 

*
Corresponding author: fff8uma@mail.ru 

         (Received: 5th January 2021; Accepted: 5th March 2021; Published on-line: 4th July 2021) 

ABSTRACT:   In this paper, the effect of magnetic field on lubricating cooling liquids, 

which are used in the cutting process in manufacturing, was studied. We chose three 

different lubricating cooling liquids that are commonly used in local manufacturing 

factories to conduct the experiment. Three main properties of these lubricoolants, boiling 

point, kinematic viscosity, and density, were analysed after magnetizing them. The 

magnetization processes were conducted in two conditions of liquids. At the first stage, 

the authors magnetized the liquids in stationary conditions; at the second stage, they 

magnetized the flowing liquids and analysed the difference among all the obtained results. 

This article shows the results of the comparisons and analyses the magnetic field influence 

on different types of fluids. Moreover, the paper investigates the dependence of magnetic 

field strength on the influence of magnetic field on liquids. It was found that the examined 

three parameters of liquids were changed after magnetic field treatment. The finding of 

this research offered a simple approach to improve the lubricating and cooling process in 

machining details in manufacturing.  

ABSTRAK: Dalam makalah ini, pengaruh medan magnet pada cecair pendingin pelincir, 

yang digunakan dalam proses pemotongan dalam pembuatan, telah dikaji. Kami memilih 

tiga cecair penyejuk pelincir berbeza yang biasa digunakan di kilang pembuatan tempatan 

untuk menjalankan eksperimen. Tiga sifat utama pelincir ini seperti takat didih, kelikatan 

kinematik, dan ketumpatan dianalisis setelah memagnetkannya. Proses pembesaran 

dilakukan dalam dua keadaan cecair. Pada peringkat pertama, kami memagnetkan cecair 

dalam keadaan pegun dan membandingkan hasilnya; pada peringkat kedua, kami 

memagnetkan cecair semasa mengalir dan menganalisis perbezaan antara hasil yang 

diperoleh. Artikel menunjukkan hasil perbandingan ini dan menganalisis pengaruh medan 

magnet pada pelbagai jenis cecair. Lebih-lebih lagi, makalah ini meneliti pergantungan 

kekuatan medan magnet terhadap pengaruh medan magnet pada cecair. Didapati bahawa 

tiga parameter cecair yang diperiksa diubah setelah rawatan medan magnet. Penemuan 

penyelidikan ini menawarkan pendekatan mudah untuk meningkatkan proses pelinciran 

dan penyejukan dalam perincian mesin dalam pembuatan. 

KEYWORDS: boiling point; cutting, liquid; magnetic field; manufacture 

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1. INTRODUCTION  

There are many scientific works about the effect of magnetic field on the physical and 

chemical properties of water. When liquids are exposed to magnetic field effects, they 

become magnetized liquids. Nikolskiy et al. analytically and experimentally investigated 

the influence of magnetic and electric fields with tension gradient in the direction of the 

movement of the contacting gas-liquid phases [1]. Rashid at al. presented an investigation 

of water evaporation through a magnetic field of 0.5 T, which was located at different 

locations of tested water height (water-air interface, water mid-height, and bottom) [2]. 

Amiri and Dadkhah investigated whether or not a physical water treatment reduces the 

surface tension of water, as reported in some scientific literature [3]. Tritigin et al. studied 

the influence on the microflora of water-oiled lubricating cooling liquid of a weak 

electromagnetic pulse field [4]. Ageev noted that one of the hypotheses explaining the effect 

of a weak magnetic field on biological objects is that water properties were changed by 

magnetic field [5]. Hassan and Rahmon’s study is a step towards gaining a better 

understanding of the effect of magnetism on water properties and on the biology of culture 

organisms, such as the brine shrimp, Artemia salina. Their study evaluated the effects of 

magnetic field exposure on water properties, which in turn affected the hatchability of A. 

salina [6]. Baresel et al. have taken the concept of water treatment by functionalized 

magnetic particles one step forward by integrating the technology into a complete proof of 

concept, which included the preparation of surface-modified beads, their use as highly 

selective adsorbents for heavy metals ions (zinc, nickel), and their performance in terms of 

magnetic separation [7]. Mardonov et al. studied the effect of magnetic field on the dynamic 

viscosity coefficient of flowing water. They found that the dynamic viscosity coefficient of 

water changed after magnetization. They magnetized flowing water using different 

magnetic field strengths. After magnetization, they measured the coefficient and found that 

dynamic viscosity of water was decreased [8]. 

The effect of magnetic field on liquids is still a controversial issue, and there is a lack 

of research in this field. Almost all of the research about magnetic field effect on liquids 

were conducted on water and the majority of that research was effectively used in the 

agriculture field. The authors of this paper suggest that use of magnetic field treatment in 

the manufacturing process would have a great advantage. 

Although many scientific works about the influence of magnetic field on some 

parameters of water have been reported from many studies, no scientific works analysed the 

effect of magnetic field on lubricating cooling liquids, which are used in cutting processes. 

Kinematic viscosity, boiling point, and density are effectively the most important 

parameters of lubricating cooling liquids used in cutting processes. Analysing the influence 

of magnetic fields on the properties of lubricants would help to increase the efficiency of 

machining and increase the wear resistance of the cutting tool. The purpose of this research 

work is to study the effect of magnetic field on these three properties of lubricating cooling 

liquids such as boiling point (heating from room temperature until the liquids boil), 

kinematic viscosity, and density. The experiment suggests that some parameters of liquids, 

such as boiling point, kinematic viscosity, and density were changed by the magnetic field.  

It is essential to point out that in this research, three different liquids were studied, including 

water, and the results were applicable for other types of liquids. It has been proven, here, 

that magnetic field treatment decreases the boiling point of any liquid with respect to the 

magnetic field strength. In addition, the effect of magnetic field on kinematic viscosity and 

density of liquids were investigated in this study. Moreover, the influence of the magnetic 

field strength on magnetization effect was studied. 

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2.   METHODS AND MATERIALS 

2.1  Magnetization 

The first liquid (liquid-1) was tap water and it was from a local water supply company 

(“Suvsoz”, Uzbekistan), the second and the third liquids (liquid-2 and liquid-3) were taken 

from a local manufacturing factory (Meridian-A). These three liquids were used as 

lubricating cooling liquids in the “Meridian-A” manufacturing factory. The second liquid, 

liquid-2, was a compound of water and K2Cr2O7 powder with 0.2% concentration. More 

accurately, m=50 grams K2Cr2O7 powder was dissolved in m0=25 kg of water. Lubricating 

cooling liquid with that concentration is used in cutting details made from mild steel. Liquid-

3 is also a lubricating cooling fluid and it is mainly used for machining details where the 

material’s hardness is higher (hard alloys) than other details. It is a 5% concentration of 

special cutting fluid marked BM-76M with water. 

The magnetizing equipment UMD-1 was developed for magnetizing liquids, the 

equipment consisted of 8 magnets, and the size of each magnet was 120x80x16 (length, 

width, height) with a minimum strength of 40 Mt. The details of UMD-1 magnetizing 

equipment are given in Fig. 1. 

 

Fig. 1: UMD-1 magnetizing equipment.  

1 – Magnets on the top, 2 – magnets below, 3 – wooden part for separation. 

Four magnets (1) were placed on the other four (2) with a gap between them. They were 

separated by a non-conductor material (3) between them. Three types of magnetic field 

strength (40 mT, 60 mT, 80 mT) were selected to magnetize the liquids and magnetic field 

strength was controlled by changing the distance between magnets. More clearly, changing 

the non-magnetic parts with ones of different height, resulted in various magnetic field 

strengths. A PVC pipe was placed between the magnets, and its diameter was 10 mm. Four 

hundred eighty mm of the polyvinyl chloride (PVC) pipe passed through UMD-1 

magnetizing equipment and this was the length of the magnetic field. When a liquid flowed 

through the PVC pipe, it turned into a magnetized liquid. All of the samples circulated at a 

flowing speed of 0.4 m/s for 30 min in UMD-1 magnetizing equipment. The scheme of the 

magnetizing process is given in Fig. 2. 

 
Fig. 2: 1 – UMD-1 magnetizing equipment, 2 – PVC pipe, 3 – container, 4 – pump, 5 

– liquid, 6 – tap, 7 – flowing direction of the liquid. 

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The magnetic field strength, magnetizing condition, and velocity of liquids were 

considered as three influential factors that affected the changes caused by the magnetic field 

[9,10]. Therefore, all of the experiments were conducted in the same laboratory conditions 

and the specification of the laboratory conditions is given in Table 1. 

Table 1: Example system technical data  

Item Value 

Atmospheric pressure 770 mmHg 

Humidity 80% 

Height above sea level 440 meter 

Flowing speed of liquid 0.4 m/s 

Diameter of the PVC 10 mm 

2.2  Measurement of the Kinematic Viscosity 

A capillary glass viscometer VPJ-4 (Fig. 3) is one of the commonly used devices to 

measure the viscosity coefficient of liquids and it was designed to determine the kinematic 

viscosity of liquids in accordance with GOST 33-66. Its range of measurement is from 0.6 

mm2/s to 10000 mm2/s and it was very easy to measure and is also a popular method for 

measurement in laboratory conditions. Capillary viscometer VPJ-4 (Fig. 3) is a device in 

the form of a U-shaped tube, the elbow (1) is soldered with the capillary (5). Measuring 

viscosity by a viscometer is based on the determination of the time required for a certain 

volume of liquid to flow out through the capillary. 

                                 

                                    (a)                                                              (b) 

Fig. 3: VPJ-4 capillary viscometer.  

1, 2 – bend of the viscometer; 3 – discharge pipe; 4 – upper reservoir of the 

viscometer; 5 – capillary; 6 – lower reservoir of the viscometer; M1 and M2 – labels, 

limiting the measured volume of the lower reservoir viscometer. 

To determine the flow time to the discharge pipe (3), a rubber tube connected to a rubber 

bulb was inserted. Then, holding the bend (2), the viscometer was turned over and the bend 

(1) was immersed in a reservoir with liquid. The liquid was sucked in (with a pear) to the 

M1 mark, without letting air bubbles form in the liquid. At the moment when the liquid 

reached the M2 mark, the device was removed from the vessel and immediately turned over 

to its original position. Excess fluid was removed from the bend (1), the rubber tube was 

removed from the bend (2), and it was put on the bend (1). Then, the viscometer was placed 

in the thermostat so that the expansion (4) was lower than the liquid level in the thermostat. 

It was kept in a thermostat for more than 30 minutes at a given temperature and then the 

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liquid was sucked into the bend to the level of one-third of the expansion (4). The rubber 

tube was disconnected and the time for the meniscus level to drop from the M1 mark to the 

M2 mark was measured with a stopwatch. 

The diameter of the capillary was 3.55 mm. The kinematic viscosity of the liquid was 

determined using the following Eq. (1) [GOST 33-66], 

𝑉 =
𝑔

9.807
∙ 𝑇 ∙ 𝐾 (1) 

where,  

K – Constant of the viscometer (9.224 mm2/s2 according to GOST 33-66) 

V – Kinematic viscosity of liquid [mm2/s] 

T – Liquid flow time in seconds 

g – Acceleration of gravity [m/s2] 

2.3  Measurement of the Density 

Density is one of the main physical quantities that characterizes the properties of a 

substance. When exercising control over technological processes and product quality, 

measuring the density of substances plays an essential role. It is known that to determine 

the density of a solid or liquid, it is sufficient to define the ratio of body weight to its volume. 

On the other hand, the ratio of the densities of a solid and a liquid determines, for example, 

the condition for the floating of a solid in a liquid, and the values of their density are the 

magnitude of the pushing forces from the liquid and the weight of the body inside the liquid. 

This relationship opens the ability to measure density through the interaction of a liquid and 

a solid immersed in that liquid. In our experiment, we used the densimeter with second class 

of accuracy according to GOST 1300-57 and its measurement range was from 1.000 to 1.800 

(Fig. 4). 

                                         

                                 (a)                                                                  (b) 

Fig. 4: 1 – Liquid; 2 – Densimeter; 3 – Density measuring scale of the densimeter; 4 – 

tanker, 5 – Ballast. 

Densimeters and hydrometers are commonly used to measure the density of different 

types liquids. The densimeter is a glass float of constant mass and volume, the expanded 

(lower) part of which is filled with ballast – clean and dry metal shot, filled with a layer of 

resin with a melting point of at least 80 °C. Thanks to the ballast (5), the densimeter is in a 

vertical position during measurements. In the upper thinned part of the float, there is a scale 

graduated in units of density. The use of a densimeter to determine the relative density of a 

liquid is based on Archimedes' law, therefore, the upper divisions of the scale correspond to 

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the lowest density, and the lower divisions correspond to the highest density. The readings 

are counted along the lower meniscus of the fluid. In the manufacturing and canning 

industry, sets of standard general-purpose densimeters of at least 2nd class of accuracy are 

used, calibrated to measure the relative density at a temperature of 20 °C with a 

measurement range from 0.7000 to 1.840 or from 820 to 1840, respectively. 

2.4  Measurement of the Boiling Point 

The TP300 (Fig. 5) digital thermometer (Xi′an Lonn M&E Equipment Co., Ltd., China) 

was used to measure the boiling point of magnetized and non-magnetized liquids under 

different conditions. The boiling point is determined by the nature of the substance and 

depends on external pressure. It is a characteristic of bodies located only in solid-state and 

for high molecular weight compounds. To determine the boiling point of fluids, we took a 

container and filled it with liquid (100 ml), and started to heat. While heating we put a TP300 

digital thermometer into the liquid and marked the boiling point of the liquid. 

 

Fig. 5: TP300 digital thermometer (measurement range is from -50 oC to +300 oC). 

3.   RESULTS AND DISCUSSION 

3.1  Effect of Magnetic Field on the Boiling Point of Lubricating Cooling Liquids 

The digital thermometer recorded the boiling point of the three different liquids. As 

stated above, three different liquids were analysed under the influence of magnetic field 

with three different magnetic field strengths (40 mT, 60 mT, and 80 mT). To compare the 

results, at first, the boiling point of liquids without magnetic field effect was measured under 

laboratory conditions. Second, the magnetic field was affected, with a MFS of 80 mT, to 

liquids in a stationary condition (not flowing) and the results were compared. The boiling 

point results were consistent with reports in the literature that the boiling point of water 

increases after magnetic field treatment [11]. Figure 6 shows the difference between the 

obtained results. 

It is noticeable from Fig. 6 that liquids under the effect of magnetic field in peace (still) 

condition, have lower boiling point than their natural boiling point. Every liquid’s natural 

boiling points differed from each other, but when they were affected by the magnetic field, 

there was difference between boiling points of magnetized liquids in peace condition and 

non-magnetized liquids. Then the effect of the magnetic field with different MFS on flowing 

liquids was analysed. After 30 minutes of magnetic treatment under each magnetic field 

strength in the same laboratory condition, as specified in Table 1, the following results, 

given in Fig. 7, were obtained. 

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Fig. 6: The boiling point of not-magnetized and  

magnetized (in peace condition) liquids. 

 

Fig. 7: The boiling point of not-magnetized and  

magnetized (in the flowing condition) liquids. 

The boiling point is one of the main physical parameters of fluids and its value might 

be changed under the effect of the magnetic field. The boiling point of liquids depends on 

the condition and other parameters of liquids such as atmosphere and properties of fluids. 

As can be seen in Fig. 7, the boiling point of magnetized liquids decreases as magnetic field 

strength increases. The difference between boiling point of not magnetized and magnetized 

fluids (in the flowing condition) under the 80 mT of magnetic field strength were 1.9 oC for 

liquid-1, 3 oC for liquid-2, and 2.2 oC for liquid-3 respectively. In addition, it is interesting 

to note that the higher the magnetic field strength the lower the boiling point of the liquids. 

The lowest boiling point was determined in 80 mT magnetic field strength. It was found 

that, if magnetic field strength was increased the effect of magnetic field on liquids was also 

increased. 

3.2  Effect of Magnetic Field on the Kinematic Viscosity Coefficient of Lubricating 

Cooling Liquids 

Viscosity coefficient is one of the important properties of lubricating cooling liquids 

used in the machining process in manufacturing. Analysing the effect of magnetic field on 

that parameter of liquids will help to increase the efficiency of the manufacturing process. 

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Under laboratory conditions, the VPJ-4 measuring device was used to record the results. 

This device commonly used in Uzbekistan. 

To analyze the effect of the magnetic field on the viscosity coefficient of liquids, the 

three different lubricating cooling liquids in stationary condition were magnetized for 30 

minutes. Eight permanent magnets with 80 mT magnetic field strength were used to make 

the magnetizing condition.  Then, the viscosity coefficient of unmagnetized and magnetized 

(in peace condition) liquids (Fig. 8) were compared. It is clear from the data given in Fig. 8, 

that under the influence of the magnetic field, the kinematic viscosity coefficient of each 

liquid decreased noticeably. The difference between kinematic viscosity coefficient of 

unmagnetized and magnetized liquids were 0.323 mm2/s for liquid-1, 0.057 mm2/s for 

liquid-2, and 0.156 mm2/s for liquid-3. 

 

Fig. 8: The kinematic viscosity coefficient of not magnetized  

and magnetized (in peace condition) liquids. 

Following this experiment, the influence of the magnetic field on flowing liquids was 

assessed. A UMD-1 magnetizing device was used to magnetize the flowing liquids. 

Lubricating cooling liquids passed through the UMD-1 magnetizing device at 0.4 m/s. The 

diameter of the pipe, which was used to pass flowing liquid through the UMD-1, was 10 

mm. After 30 minutes of the magnetizing process, the kinematic viscosity of liquids was 

measured and the results are given in Fig. 9. 

 

Fig. 9: Viscosity coefficient of not magnetized and  

magnetized (in flowing condition) liquids in different magnetic field strengths. 

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Results given in Fig. 9 show that a magnetic field can cause a decrease in the viscosity 

coefficient of flowing liquids. Moreover, the viscosity coefficient of flowing liquids 

depends on the magnetic field strength, because as the strength of the magnetic field 

increases, the kinematic viscosity of liquids decreases. The lowest viscosity coefficient was 

determined under the influence of the highest magnetic field strength (80 mT). Comparisons 

show that the value between the unmagnetized and magnetized liquids, under the highest 

MFS, were 1.246 mm2/s for liquid-1, 0.803 mm2/s for liquid-2, and 0.295 mm2/s for liquid-

3.  

It was also found that the effect of magnetic field on flowing and not flowing liquids 

depends on the properties of the liquids. It is clear from the numbers obtained in Figs. 8 and 

9 that liquid-1 was affected by the magnetic field more than the other two liquids. Liquid-3 

had the least change among the three liquids after magnetization. Because the concentration 

of liquid-3 has more components than other liquids and its crystals are differentiated from 

tap water (liquid-1) more than liquid-2. It is investigated that the greater the percent 

concentration of liquids, the less the magnetization effect on the liquids. 

3.3  Effect of Magnetic Field on the Density of Lubricating Cooling Liquids 

The magnetic field effect on the density of lubricoolants is also important in machining 

details in the manufacturing process. For the purpose of increasing efficiency in machining 

details, the effect of magnetic fields on the density of liquids was given greater attention by 

authors. As above, at first, the difference between the density of unmagnetized and 

magnetized (in peace condition) liquids was compared. There were also differences among 

the obtained results (Fig. 10). Figure 10 shows that after magnetizing liquids, their density 

increased and the differences were 0.002 g/cm3 for liquid-1, 0.001 g/cm3 for liquid-2 and 

0.002 g/cm3 for liquid-3. 

 

Fig. 10: The density of unmagnetized and magnetized (in peace condition) liquids. 

When the flowing liquids were magnetized in different magnetic field strengths, the 

results changed noticeably with respect to the magnetic field strength. The results, which 

were taken in the same laboratory conditions, are given in Fig. 11. 

Despite the fact that the density of the liquids differed from each other in the same 

conditions, the density of each liquid was increased after 30 minutes of the magnetization 

process while they were flowing (Fig. 11). The density of the first sample was 1.000 g/cm3 

before magnetization, but it reached to 1.005 g/cm3 after magnetizing at 40 mT. When the 

MFS increased to 80 mT, the density reached its highest point in the experiment (1.007). 

Liquid-2 and liquid-3 also increased from 1.002 g/cm3 to 1.006 g/cm3 and from 1.009 g/cm3 

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to 1.011 g/cm3 respectively. In fact, the highest density was obtained at 80 mT of magnetic 

field strength. 

 

Fig. 11: The density of unmagnetized and magnetized (in flowing condition) liquids 

in different magnetic field strengths. 

A decrease in the viscosity coefficient after magnetic field treatment was found. When 

magnetic field influences liquids, their crystals are regulated in the magnetic field direction 

by the magnetic field. This regulation of crystals causes a decrease in the viscosity 

coefficient after magnetic field treatment. Moreover, the regulation of crystals causes an 

increase in the density after magnetic field treatment.  Also, it has been explored that, the 

effect of magnetic field on liquids depends on the properties of fluids, or more accurately, 

in the same laboratory condition and same magnetic field strength, magnetic field influence 

was different on various liquids. It is worth noting that the influence of a magnetic field on 

liquid depends on what kind of chemical elements are dissolved in the liquid. Moreover, the 

maximal change in all of the experiments was obtained at 80 mT of magnetic field strength 

while the lowest change was reached at 40 mT of magnetic field strength.  

Obtained results are very influential to manufacturing processes because the changes in 

these parameters of liquids have an impact on the wear resistance of the cutting tool used in 

the machining process. The influence of magnetized lubricating cooling liquids on the wear 

resistance of cutting tools helps to increase the efficiency in the machining process and saves 

energy [8,15,16]. 

However, this issue about magnetic field treatment of liquids remains controversial. 

Complete understanding of the influence of magnetic fields on fluids has a great impact on 

agriculture, industry, and other fields [12-14]. Some scientists are working on the issue of 

magnetic field treatment of water, but there lack of researches on this issue, especially the 

magnetic field effect on different liquids. 

4.   CONCLUSION 

The results obtained in the laboratory experiment showed that there was an increase in 

the density of liquids when they were affected by the magnetic field. In spite of the fact that 

the increase was not always noticeable on the density of fluids, it depended on the magnetic 

field strength. Also, the density of water was more affected by the magnetic field than the 

other two dissolved liquids which means that the density of dissolved liquids is less likely 

to be influenced by the magnetic field. However, the influence of the magnetic field on the 

boiling point of dissolved liquids were about 1.5 times higher than tap water.   In addition, 

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it was found that kinematic viscosity and boiling point of experimented liquids were 

decreased after magnetic field treatment. However, after magnetic field treatment of flowing 

liquid, the kinematic viscosity of liquid-1 decreased by 24% while the kinematic viscosity 

of liquid-2 and liquid-3 decreased by 8% and 19% respectively. The difference between the 

effect of magnetic field on stationary and flowing liquids was also examined and it was 

explored that flowing liquids were influenced more than liquids in stationary conditions. 

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