# Introduction

he author of the paper was dealing a long time with testing of different kinds of water salts solutions using spherical silver probe 20 mm in diameter. The silver probe was used to evaluate critical heat flux densities of water at different temperatures [1]. However, it was impossible to evaluate critical heat flux densities of water salt solution (electrolytes) using standard silver probe 20 mm in diameter because developed film boiling during quenching was completely absent. Nobody could explain such strange behavior of silver probe during its quenching in cold electrolytes. The matter is that thermal conductivity of silver at 100 o C is equal to 392 W/mK while thermal conductivity of steel is equal to 17.5 W/mK. It means that silver probe, according to law of Fourier, can generate during quenching 22 times larger heat flux density as compared with the steel. In this case developed film boiling must be presented. It was not present at all during testing of silver probe in cold electrolytes. Later scientists switched from silver standard probes to Inconel 600 probe 12.5 mm in diameter [2 -5] and started to use Liscic probe 50 mm in diameter [6,7] for testing liquid media. A huge amount of experiments were carried out with water salt solutions using standard cylindrical probe 12.5 mm and Liscic probe 50 mm in diameter. Typical temperature cooling curves versus time for cylindrical probe 50 mm in diameter are illustrated in Fig. 1  [8]. As seen from Fig. 1, surface temperature of probe drops quickly almost to boiling point of a liquid that coincides very well with the accurate experiments of French [9]. After that surface temperature of probe maintains relatively a long time at the level of saturation temperature of a liquid until nucleate boiling is finished. Such behavior of surface temperature is called self -regulated thermal process [10,11]. There is an equation for its duration evaluation. According to authors [12], the heat transfer coefficient (HTC) decreases with decreasing core temperature of the probe during nucleate boiling process. These two main characteristics of the transient nucleate boiling process were taken into account when considering quenching silver probes in water salt solutions of the same concentration. Transient nucleate boiling analysis, observed during cooling steel probes and silver probes of different sizes, allows understanding the nature of forced heat transfer exchange during quenching silver probes in different kinds of electrolytes. However, the problem concerning unusual behavior of silver probe during its quenching in electrolytes is not easy to solve. Currently, the Inconel 600 probe is used to get core cooling curves and core cooling rates during quenching of the probe. It has only one thermocouple located at its center. Authors [13] criticized the Inconel 600 probe and recommended using Liscic probe 50 mm in diameter with accurately instrumented through probe section three thermocouples. To solve the mentioned problem on unusual behavior of silver spherical probe during quenching in electrolytes, the author of the paper analyzes accurate experimental data obtained during testing electrolytes by silver spherical probe 20 mm, steel cylindrical probe 12 mm, and cylindrical probe 50 mm in diameter. Based on analyzing experimental data, one can came to conclusion that unusual behavior of silver probe during quenching in cold electrolytes is explained by periodical changing of film boiling by shock boiling that replace each other with the high frequency. Also, in the paper the contemporary theory on nucleate boiling process is considered to formulate ones again the boundary condition used for temperature field calculation during quenching when transient nucleate boiling takes place.


# II.


# Heat Transfer Coefficients Evaluation

The standard probe for evaluating the cooling capacity of quenchants is discussed in [2]. Test methods based on ASTM Standards D6200-01, D6482-99, and D6649-00 for determining the cooling characteristics of quenchants are widely used in practice [2,3]. The chemical composition of Inconel 600 is: 72 % nickel; 14-17 % chromium; 6-10 % iron; 0.15 % carbon; 0.5 % copper; and 0.5 % silicon. The diameter of the probe is 12.5 mm and its length is 60 mm. Probe details and its general assembly is provided in Ref.. [2].

Fig. 2 illustrates the spherical silver probe used for study unstable film boiling process [14]. The 20-mmdiameter spherical silver probe was prepared by casting the probe from the molten silver with a type K chromelalumel thermocouple inserted through a 1.5-mm stainless steel sheath, with the thermocouple tip precisely located at the geometric center before casting. After casting, the silver surface was properly ground. The spherical shape of the probe was selected to ensure a uniform heat transfer.

To evaluate heat transfer coefficients and the heat flux density via solving inverse problem, the Liscic probe may be used [6,7]. This is the most accurate commercially available probe, obtaining the most accurate experimental data. Some experimental results are provided in [13].

The Liscic probe is an excellent tool for investigation of the self-regulated thermal process reported in Ref. [6,7].


# Fig. 2:

The spherical silver probe used for testing of quenchants [14].

It was accepted by heat treating community that during quenching of silver probe in liquid media core temperature of the spherical probe always is equal to its surface temperature because thermal conductivity of silver is 400 W/mK and effective heat transfer coefficient (HTC) is not too high that all together always provides Bi < 0.2. However, the condition Bi < 0.2 is not satisfied if consider real heat transfer coefficients (HTCs) instead of effective HTCs [12]. During quenching of silver probe essential temperature difference appears between core and surface temperatures. If so, the problem appears during solving inverse problem in evaluating correct values of HTCs. Probably, CFD modeling could help here.

Currently, such computations are performed using CFD (computational fluid dynamics) methods mostly for plain convection, but unfortunately, it cannot be applied effectively yet to boiling processes, which are the main modes of heat transfer during quenching. That is why the regular thermal condition theory of Kondrat'ev was used for approximate evaluation of HTCs during boiling [14]. Also, accurate experimental data of author [15] were used which are shown in Fig. 3. Based on these data and thermal properties of silver and AISI 304 steel (see Table 1 -Tasble 3), HTCs were evaluated which are provided in Table 4.


# Fig. 3:

Cooling rate curves at the center of spherical probe 20 mm diameter obtained during testing different quenchants [15]: 1, 2, 3 are water solutions of NaCl with concentration 5%, 15%, 20% at a temperature 20 ? ?; 4 is 20% water solution NaCl at a temperature 60 ? ?; 5 is 50% water solution of HNO 3 at a temperature (96 o C); 6, 7 is water at temperatures 20 ? ? and 98 ? ?; 8 is industrial oil at a temperature 50 ? ?. Note ? is the mean value for the range between 100 o C and the stated temperature. Note a is the mean value for the range between 100 o C and the stated temperature.

According to regular thermal conditions theory, cooling rate is directly proportional to Kondrat'ev number Kn (see Eq. ( 1)) [14]:
( ) Kn vK a T T s = ?(1)
Knowing Kondrat'ev number Kn, the generalized Biot number Bi V was found using Eq. ( 2).


# (

) 
Kn Bi Bi Bi V V V = + + 2 0 5( A ) Bi K S V V = ? ? (3)
the heat transfer coefficient was evaluated using Eq. ( 4)
? ? = Bi V KS V (4)
Results of calculations are provided in Table 4.

Table 4: Heat transfer coefficients taking place during quenching of silver and steel probes in water salt solutions

As seen from Table 4, HTCs related to steel probes 12 and 50 mm in diameters are in good agreement with the existing theory of transient nucleate boiling processes taking place during quenching in electrolytes. Namely, the HTCs during nucleate boiling process follow the temperature gradients which were established during quenching of steel probes 12 mm and 50 mm (see Fig. 4). As known [16,17], ? nb q ? 0 7

. . Since for smaller steel probe temperature gradient is larger (see Fig. 4), heat flux density released by it is larger too. It means that average HTC during nucleate boiling is larger for smaller probe. For steel probe 12 mm in diameter at a core temperature 600 o C, HTC is equal to 12180 W/m 2 K while for steel probe 50 mm in diameter HTC is equal to 3550 W/ 2 K. When core temperature in steel probe decreases, HTC decreases too (see Table 4). In contrast to obtained data, with decreasing core temperature of silver probe, the HTC increases almost three times. That can be true for developed film boiling process when it passes to transition boiling where HTC is significantly larger. However, HTCs are so large that they cannot belong to film boiling process. Such huge HTCs can be generated only by develo ped nucleate boiling process. In fact, it is something different that is not known yet to investigators.  


# Material


# III. Contemporary Theory Of Nucleate Boiling Processes

As known, during quenching of metals they are heated and then immersed into a cold liquid, usually open quench tanks. At the time of immersion, boundary liquid boiling layer is formed. The boundary liquid layer is heated to the saturation temperature, and at the same time the part's surface is intensively cooled. Then the liquid at the boundary layer starts to boil and a certain heat flux density is reached that depends on the shape and sizes of the part and thermal conductivity of a material.

Depending on the initial heat flux density, film boiling can take place or can be absent.

It is important to find out the effect of vapor bubble behavior. As known, vapor bubble growth rate is determined as [16]:
f d W 0 = ? ? (5)
Experiments have not revealed the effect of heat flux density, which was changed by 4 or 5 times, on average value of W ? ? [16]. The average vapor bubble growth rate W ? ? is essentially affected by pressure It is of great practical interest to know the effect of aqueous salt solution concentrations on inner characteristics of nucleate boiling process.

Results of experiments, dealing with boiling solutions of NaCl and Na 2 CO 3 at normal pressure, are presented in Table 5.

Table 5: Effect of concentration on boiling inner characteristics [16 ] As one can see from As follows from Table 6, inner characteristics of boiling process do not depend on sort of material. It means that for silver and steel inner characteristics of boiling process are similar.

Overheating in the boundary layer is higher when greater is heat flux density. When liquid overheating ?T T T w s = ?

increases, the number of nucleating centers also increases. Number n of nucleating centers increases by direct proportion to the cube of temperature difference:
3 ~T n ? (6)
At the same time, it is well-known that heat flux density at nucleate boiling in average is also proportional to the cube of temperature difference As known,
? ? ? ? ? ? K m W 2 ?
is considered during boiling as
T q ? = ? [16, 17].
The above mentioned HTC is used at the computation of temperature fields during steel quenching.

Tolubinsky proposed the generalized equation for calculation of the heat transfer coefficient at nucleate boiling process which has the following form [16]:
75 ) ( ' = ? ? ? ? ? ? ? ? g 2 . 0 7 . 0 * ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? v a w r q ? (9)
Where )
( ' ? ? ? ? ? ? ? ? = g Nu is Nusselt number; the ratio ) ( ' ? ? ? ? ? ? g is proportional to bubble release diameter.
From Eq. ( 9) follows that
7 . 0 7 . 0 * 2 . 0 5 . 0 ' 1 ) ( 75 q w r v a g ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? = ? ? ? ? ? ? (10) or 7 . 0 cq = ? (10a) Where 7 . 0 * 2 . 0 5 . 0 ' ' 1 ) ( 75 ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? ? = w r v a g c ? ? ? ? ?
A well known handbook [17] provides equation (11) to be used for heat exchange design of technological processes:
Nu K K Z q = ? ? ? 0 082 0 33 0 7 0 45 . Pr . . .(11)
Here
Nu = ? ? ? ' ; ( ) [ ] ? ? ? ? = ? / ' ' ' . g 0 5
;

( )
K c T T R r Z p w s cr = ? ? ? ? ? ? ' ' ' 2 ; K q r a l q x = ? ? ? 2 '' ' ; l c T r x p s = ? ?? ? ' "
From Eq. ( 11), one can get the same result
7 . 0 cq = ? (11a)
This fact is used for analyzing our calculated data. Thus, different authors came to conclusion that heat transfer during nucleate boiling depends on heat flux density value and is proportional to q 0 7 . . IV. New Heat Exchange Phenomenon Taking Place during Quenching of Silver Probes


# Global

According to statistical physics, free electrons in metal in heated area are under pressure P which is calculated as [18]:
P nkT = (12)
Here n is a number of electrons in one sm 3 of metal; k is the Boltzmann constant which is equal to k =1.3806488 (13) x10 -23 [K -1 ] [18]. During immersion of heated to high temperature metallic probe into electrolyte, a double electrical layer is formed on the boundary liquid -metal which looks like it is shown in Fig. 5  [19 -21]. It happens due to movement of electrons from heated area to cold area. Maximum electrical forcers take place when electrolyte is at an optimal concentration. Fig. 5: A double electrical layer formed during immersion of heated probe into cold electrolyte [21].

A huge electrical force appears between surface of metal and electrolyte during quenching in electrolytes of optimal concentration. When quenching probe in cold electrolyte, cooling process can proceed by two ways as it is shown in Fig. 6  [20,21].

During immersion of the heated probe into cold liquid, there are no bubbles on the metallic surface at all. At this time, cold liquid is heated to the boiling point of a liquid, and the surface temperature of the probe drops rapidly close to the saturation temperature T s . During this extremely short period of time, heat transfer looks like a convection process. Any form and size of probe can be considered during this extremely short time as a semi -infinity plate which is intensively cooled. Cooling curves for different shapes and sizes are almost the same if film boiling is completely absent. Experiments of French support such behavior of cooling curves. When the liquid is overheated, shock boiling starts, and thousands of small bubbles appear, becoming larger with time. Simultaneously, a temperature gradient is established at the surface of the probe. From this moment of time, two different processes may be developed. The full film boiling is established when the initial heat flux density q in is larger than the first critical heat flux density q cr1 , i.e q in > q cr1. Nucleate boiling process occurs immediately after shock boiling when q in < q cr1 [22 -23]. Fig. 6: Two possible boiling processes that may occur during quenching, depending on critical heat flux densities [22].

During steel quenching in cold electrolytes of optimal concentration film boiling is absent because initial heat flux density is below its critical value q cr1 [22]. However, during quenching of silver probes in electrolytes, initial heat flux density is so huge that it is always larger than the critical value q cr1 . It is true because thermal conductivity of silver is almost 20 times larger as compared with steel. At room temperature thermal conductivity of silver is 400 W/mK while for stainless steel it is only 14 W/mK. During quenching of silver probes in electrolytes electrical forces try to resist film boiling process establishment. Due to their presence, the high heat transfer coefficients (HTCs) can be generated by such a way.

When film boiling appears, electrical forces move charged liquid layer to metal surface. The shock boiling starts immediately that creates the new film boiling layer which is a reason for periodical process. And such the periodical cooling process looks like: film boiling ? shock boiling. ? film boiling ? shock boiling ? film boiling ? shock boiling Oscillating with the high frequency, shock boiling process generates the high HTCs. This is a new physical process which can be very useful for practice because such physical process can be governed by external electrical forces to increase essentially HTCs. Especially, it is very important for direct quenching after forging of steel to receive super strengthened materials of high ductility and high wear resistance.

There are three vital ways of affecting and governing boiling processes during quenching to improve radically technological processes aiming service life increase of steel parts and environment improvement. They are:

? Adjusting pressure to delay or accelerate martensitic transformation

? Creating surface insulating layers to drop initial heat flux density below its critical value to prevent completely any film boiling process during quenching of steel parts

? Governing boiling process by external electrical forces to increase HTCs V.


# Discussion

From consideration the existing theory of nucleate boiling processes follows that heat transfer coefficient during nucleate boiling is calculated as shown by Eq. (10 a) and Eq. (11a). Both equations can be rewritten as 

Substituting obtained result (13) into third kind of a boundary condition, we obtain:
( ) ? ? ? ? T r T T s r R + ? ? ? ? ? ? ? = = 10 3 10 3 0 / /(14)
Based on the obtained boundary condition ( 14), an analytical solution was received [12] for quenching steel parts in liquid media that resulted in a well known characteristic of transient nucleate boiling process which is written now as:
? nb F k D a = ? 2 (15)
This final result was many times verified by accurate experiments which coincided very well with the calculated data. It means that above considered theory of boiling processes is suitable for steel parts quenching since it was many timers supported by experiments.

However, the theory cannot support the discussed above the unusual phenomenon on oscillating and periodical changes of shock and film boiling processes. In this specific case, the boundary condition should include the effect of electrical forces which were not considered yet by physicians. Further investigating the unusual heat exchange process, one can expect essential benefits for heat treating industry and other new technologies development.  


# VI
1![Fig. 1: Temperature curves versus time during quenching 50 mm in diameter cylindrical stainless probe in 14 % water solution of NaCl at 23 o C received by experiment [8]](image-2.png "Fig. 1 :")
![Unusual Phenomenon of Forced Heat Exchange taking Place during Quenching Silver Probe in Cold Electrolyte](image-3.png "")
4![Fig. 4: Temperature fields during quenching of cylindrical probes 20 mm (a) and 40 mm (b) in water salt solution of elevated concentration. To find out what happens during quenching of silver probe in cold electrolytes and guess what in reality the unusual forced heat transfer exchange is, let's consider one more time the achievements of nucleate boiling processes theory.](image-4.png "Fig. 4 :")
![stable with respect to change of heat flux density. The most stable of them is average vapor bubble growth rate.](image-5.png "")
![Heat transfer coefficient ? nb Heat transfer coefficient during NB aThermal diffusivity of solid material a '](image-6.png "?")
1T. ºC100200300400500600700800900?,mK W17.51819.6212324.826.327.829.3?,mK W17.517.7518.5519.2520.2521.1521.9022.6523.4
2Temperature. 0 ?0100200400600800900Copper?,mK W393.1384.9380365353.5340.8333Silver,?,mK W410.5392372362374.5--
3T. ºC100200300400500600700800900am s ?10 6 2 , /4.554.634.704.955.345.655.836.196.55am s ?10 6 2 , /4.554.594.6254.754.955.105.195.375.55
5, for high-concentration solutions of NaCl and Na 2 CO 3 , their vaporbubble growth rates are the same and are equal to W ? ?of water. It means that concentration affects HTC duringnucleate boiling process via Prandtl number Pr. It wasshown that for different materials the vapor bubble growth rates are almost the same (see Table6).
6Materiald mm o ,f, / 1sW", mm/sd mm o ,Average value f s , / 1W", mm/sPermanite2.561153Brass2.3671572.562155Copper2.856157
NomenclatureBiBiot number
			© 2020 Global Journals
		
		
			

				


* 
	
		Experimental etermination of the First and Second Critical Heat Flux Densities and Quench Process Characterization
		
			NIKobasko
		
		
			AAMoskalenko
		
		
			GETotten
		
		
			GMWebster
		
	
	
		Journal of Materials Engineering and Performance
		
			6
			1
			
			1997
		
	




* 
	
		Handbook of Quenchants and Quenching Technology
		
			GETotten
		
		
			CEBates
		
		
			Clinton
		
		
			MA
		
		
			1993
			ASM International
			
			Materials Park, OH
		
	




* 
	
		Standard Test Method for Determination of Cooling Characteristics of Quench Oils by Cooling Curve Analysis, Annual Book of ASTM Standards
	
	
		ASTM Standard
				West Conshohocken, PA
		
			ASTM International
			2001
			
		
	




* 
	
		Standard Test Method for Determination of Cooling Characteristics of Aqueous Polymer Quenchants with Agitation (Tensi Method), Annual Book of ASTM Standards
	
	
		ASTM Standard
				West Conshohocken, PA
		
			ASTM International
			2000
			
		
	




* 
	
		Standard Test Method for Determination of Cooling Characteristics of Quenchants by Cooling Curve Analysis with Agitation (Drayton Unit), Annual Book of ASTM Standards
		D6549-00
	
	
		ASTM Standard
				West Conshohocken, PA
		
			ASTM International
			2000
		
	




* 
	
		
			BLiscic
		
		
			HMTensi
		
		
			WLuty
		
		10.1007/978-3-662-01596-4
		Theory and Technology of Quenching
				Berlin
		
			Springer
			1992
			484
		
	




* 
	
		Measurement and Recording of Quenching Intensity in Workshop Conditions Based on Temperature Gradients
		
			BLiscic
		
		doi: 10.1520/ mpc20160007
	
	
		Materials Performance and Characterization
		
			5
			1
			
			2016
		
	




* 
	
		New direction in liquid quenching media development, ??????????? ?? ???????????????
		
			NIKobasko
		
		
			AAMoskalenko
		
		
			PNLogvinenko
		
		
			VVDobryvechir
		
		
			2019
			3
			
		
	




* 
	
		The Quenching of Steels
		
			HJFrench
		
		
			1930
			American Society for Steel Treating
			Cleveland, Ohio, USA
		
	




* 
	
		Steel Quenching in Liquid Media under Pressure
		
			NIKobasko
		
	
	
		Naukova Dumka
		
			1980
		
	




* 
	
		Self -Regulated Thermal Processes During Quenching of Steels in Liquid Media
		
			NIKobasko
		
	
	
		International Journal of Microstructure and Materials Properties
		
			1
			1
			
			2005
		
	




* 
	
		Mechanism of film elimination when intensively quenching steel parts in water polymer solutions of low concentration
		
			NIKobasko
		
	
	
		Global Journal of Science Frontier Research -A: Physics and Space Science
		
			20
			7
			
			2020
		
	




* 
	
		Liscic/Petrofer probe to investigate real industrial hardening processes and some fundamentals during quenching of steel parts in liquid media
		
			Kobasko NLiscic
		
		
			B
		
		10.21303/2461-4262.2017.00495
	
	
		EUREKA: Physics and Engineering
		
			6
			
			2017
		
	




* 
	
		
		
			GMKondrat'ev
		
		
			TeplovyeIzmereniya
		
	
	
		Thermal Measurements
		
			1957
			Mashgiz
		
	




* 
	
		
		
			LVPetrash
		
		
			Quenchants
		
		
			Mashgiz
		
		
			Moscow -Leningrad
		
		
			1959
			112
		
	




* 
	
		Heat Exchanger Design Handbook I. Heat Exchanger Theory
		
			VITolubinsky
		
		D. Brian Spalding, J. Taborek
		
			1980. 1983
			Hemisphere Publishing Corporation
			561
			
			Kyiv; New York, USA
		
	
	Heat Transfer at Boiling, Naukova Dumka




* 
	
		Course of Statistical Physics
		
			BFNozdrev
		
		
			AASenkevich
		
	
	
		Vysshaya Shkola
		
			1969
		
	




* 
	
		Kinetic Theory of Liquids
		
			.IFrenkel Ya
		
	
	
		Nauka
		
			1975
		
	




* 
	
		Boiling of fluid on a metal surface
		
			VIFedorov
		
		
			GVKovalenko
		
		
			DMKostanchuk
		
		10.1007/bf00860120
	
	
		Journal of Engineering Physics
		
			32
			1
			
			1977
		
	




* 
	
		Effect of free electrons in steel on its quenching process in water and water salt solutions
		
			NIKobasko
		
		10.21303/2461-4262.2018.00529
	
	
		EUREKA: Physics and Engineering
		
			1
			
			2018
		
	




* 
	
		Intensive Quenching Systems: Engineering and Design
		
			NIKobasko
		
		
			MAAronov
		
		
			JAPowell
		
		
			GETotten
		
		
			2010
			ASTM International
			234
			USA
		
	




* 
	
		Transient nucleate boiling process as a basis for designing of high efficiency innovative technologies
		
			NIKobasko
		
	
	
		International Journal of Physics and Applications
		
			2
			1
			
			2020