Copyright © 2022 O. Salenko, M. Khorolska, V. Lopata, A. Solovuch, V. Kulyzhskyi. 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. 27, No 2/104-2022, 94-103 
 

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

E-mail: tribosenator@gmail.com 
 

DOI:  https://doi.org/10.31891/2079-1372-2022-104-2-94-103 

 

 

Using a functional approach in solving problems improve performance 

waterjet equipment 

 
O. Salenko1, M. Khorolska1, V. Lopata 2*, A. Solovuch3, V. Kulyzhskyi4 

 
1Kremenchug Mуkhailo Ostrohradskyi National University, Ukraine 

2E.O. Paton Electric Welding Institute of the National Academy of Sciences of Ukraine, Ukraine 
3Central Ukrainian National Technical University, Ukraine 

4G.S. Pisarenko Institute for Problems of Strength National Academy of Sciences of Ukraine, Ukraine 

*E-mail: beryuza@ukr.net 

 

Received: 25 April 2022: Revised: 22 May 2022: Accept: 15 June 2022 
 

 

Abstract 

 

The paper shows the influence of parameters of the calibration tube jet-abrasive devices on the quality of 

the process of waterjet cutting critical parts. The results of modeling the formation of two-phase flow and its 

movement in the calibration tube. Determined that the effects wear ductal fluid of the tube varying intensity and 

character. In this regard there is the need for functional-oriented approach to the choice of means to ensure the 

desired geometric parameters of the tube. It is concluded that the decrease in the intensity of ductal Shot material 

of the tube and thus maintain its geometric parameters is possible by the use of suitable protective coatings , 

thickness and physical and mechanical characteristics are selected on the basis of Value attributes according to 

the intensity and type of abrasive loading surface. 

 

Key words: waterjet cutting, calibration tube, protective layers, functional-oriented approach. 

 

Introduction 

 

The appearance and widespread using in industry of new structural materials, especially composites, and 

new high-tech products, makes the need for new methods of treatment. One of these methods is hydroabrasive 

cutting. The use of hydroabrasive cutting justifies itself especially where use of traditional methods does not give 

a satisfactory quality. Additional costs for works or reducing of the production rate go into oblivion. An 

additional advantage of this method is its cleanliness and environmental friendliness. Modern systems of 

hydroabrasive cutting provide continuous optimization of production and quality in manufacturing. The need for 

high processing results requires sustainability and compactness of jet-abrasive stream. 

 

 
 

Fig. 1. Calibration tubes, collet mixing chamber and sapphire nozzle inserts by firm SynergicInc., (Provider – 

ELFIHmbH, Austria) 

http://creativecommons.org/licenses/by/3.0/
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https://doi.org/10.31891/2079-1372-2022-104-2-94-103


Problems of Tribology 95 

 

Using of hydroabrasive processing enables significantly improve the quality of machined surface and 

cutting performance, which requires the development of promising new layout tools for combined treatment. 

Among the trends of hydroabrasive treatment the improving of the accuracy and efficiency of processing 

equipment is allocated. Effectiveness can be enhanced by increasing fluid pressure (600 MPa) and the number of 

concurrent working heads [1, 2]. However, increasing of working pressure leads to intensification of systems of 

wear of hydrocutting equipment, including calibration tubes (Fig. 1), which in turn reflected in the cost of 

processing. 

 

Objective  

 

Calibration tube is one of the most important elements of hydrocutting system, which affects the 

technological and economic characteristics of the cutting. Industrial observations suggest that most functional 

failures in the implementation of hydroabrasive cutting occurs due to sudden changes in geometry of jet-forming 

elements (nozzle and calibration tube). The tube is exposed to constant wear, resulting in internal diameter 

increases, which determines the wear tube. Usually firmness of tube presents 10...15 hours, and its cost arrives at 

20...50 $ [2]. 

In this regard, an urgent task is improving the stability of calibration tube using the functional-oriented 

approach. To determine the peculiarities of wear of calibration tube, the impact of movement abrasive grains and 

species destruction are analyzed. 

 

The research 

 

It is known that in the motion of two-phase flow "liquid – solid particles" through the calibration tube 

there is chaotic action on the walls of the tube of some abrasive particles at different angles of attack and with 

different power of hit. Abrasive destruction of surface of the tube depends on the nature of action of the abrasive 

grains on its surface. Depending on the direction of action of the abrasive jet to the surface there are the 

following schemes of action: the destruction with a shock jet , when the angle of attack α = 90 (Fig. 2 a), with 

sliding jet, when α = 0 (Fig. 2 b), with oblique jet, when 0 <α <90 (Fig. 2 c) [3, 4]. 

 

 
Fig. 2. Scheme of action of the abrasive jet to the surface 

 

If on the flat surface of the material affects the flow of hard abrasive particles that fly at the speed vu at an 

angle α to the surface, each share with a punch, elastically deforms the work surface and slip on it with friction. 

Assumed that the normal component of velocity v0  makes only elastic deformation of the material, and tangent 

v0 is partially or completely extinguished and does the work of cutting, engaging in frictional contact with the 

surface. With the reduced turns out that the largest processing performance theoretically should be at an angle of 

attack α = 45, which is confirmed by many authors [5]. The intensity of wear in the abrasive flow is defined as 

the result of multiple impacts of solid particles on the surface wear at different angles of attack. Initial period of 

destruction of the metal is characterized by the introduction of abrasive particles in the surface layer at some 

depth, the second - of continuous movement of particles of the material along surface layer at some distance at 

which the displacement of microvolumes of the metal in layer occurs in the direction of introduction of particles 

and their separation from the array. 

In implementing of the abrasive particle in the surface layer of metal in a free kick there is deformation 

near the contact zone, resulting in this layer there is a complex inhomogeneous stress-strain field with a variable 

limit. Stresses and strains arising from the introduction of abrasive particles in the metal depend on complex 

factors that characterize the parameters of the flow of particles and resistance of the metal to elastic-plastic 

deformations. Elastic and plastic deformations will develop in the contact zone, which will assist to metal 

collapse under the particle in the radial direction and subsequent tangential changes in the direction of motion of 

the relative particles to the surface. Depth introduction of the particle and its tangential displacement associated 

with the mechanical properties of the abrasive and of material of wearing surface, particles size, and deformation 

of the metal. 

At small angles of attack due to the predominance of tangential velocity impact, the main process of 

destruction of the surface layer is the tangential displacement microvolumes of metal in the direction of 



96 Problems of Tribology 

 

implementation, i.e. microcutting. At the angles of the attack close to 90º, mechanism of destruction of the 

surface layer of metal in a stream of abrasive particles takes a polydeformational striking character due to the 

predominance of the normal velocity.  Destruction of structural materials under the action of abrasive particles 

contained in the flow of fluid is very complex and may be semifluid, brittle, polydeformational or acquires 

fatigue character and is complicated with phenomenon of cavitation. 

Thus, the parameters of the internal profile of tube should ensure the following conditions of flow: 

1) the minimum thickness of the boundary layer flow inside the tube, turbulent layer of output free jet, 

which reduces the thickness and the interaction of jet with the environment; 

2) reducing of the possibility of separation of boundary layer of jet, helping to reduce excitation of central 

flow; 

3) reducing of the possibility of cavitation, which provides an exception of formations of low pressures 

inside the tube to avoid formation of bubbles and destruction of tube. 

The physical and mechanical properties of the material, which facing the particle, also have impact on the 

efficiency of processing. The theoretical dependence given in [5] help to assess of the impact angle of attack on 

the intensity of wear only qualitatively. Therefore, to analyze the phenomena that occur in calibration tube 

during the formation of liquid abrasive flow the software package flow vision was used. When modeling the 

problem of detection of conditionality of diagrams load on the cross-section of calibration tube with 

microhermetic parameters of jet erosion was treated, establish the role and activity of wave processes occurring 

in streams and exert force on the inner diameter of the calibration tube. 

The core package is a unit of the numerical solution of equations of fluid motion in the orthogonal 

coordinate system (Navier-Stokes equation (1)) that for certain initial and boundary conditions defined by the 

user, provides a diagram of distribution of velocities and dynamic pressures at the point of contact with the jet or 

other surface: 

 
























































































































































































































.
111

;
2111

;
2111

2

2

2

2

22

2

222

2

2

2

22

2

222

2

2

2

22

2

2

r

v

rz

vv

rr

v
v

z

ρ

ρr
f

z

v
v

v

r

v

r

v
v

t

v

r

vv

rr

v

rz

vv

rr

v
v

ρ

ρr
f

r

vv

z

v
v

v

r

v

r

v
v

t

v

r

vv

rr

v

rz

vv

rr

v
v

r

ρ

ρ
f

r

v

z

v
v

v

r

v

r

v
v

t

v

zzzz
z

z
z

z
z

z

r
zr

rrrrr
r

r
z

rr
r

r
























                                                       (1) 

where fr, fφ, fz – voltages of mass forces along the respective axes; r, φ, z; v – kinematic viscosity; 

z

vv

z

vv

z

vv

r

v zzrrr



























 
;;;;;;  – components of the strain rates of elementary volume of fluid (the same 

name derived describes the strain rate compression or stretching of line elements of the selected volume, and 

dissimilar – the rate of change of the angles between them); ρ – mass density of fluid; vr, vφ, vz – speeds of the 

elementary volume of the respective coordinates. 

 

Found stresses values of mass forces along the respective axes provided continuity 

 
0













 

z

v
r

v

r

rv zr  determines mass force acting on the volume of liquid, which is considered:  

 

 
W

dWfF ,                                                                                      (2) 

where W – elementary volume.  

 

Initial conditions are determined by geometrical profile nozzle orifice, by the pressure of liquid pb and its 

properties. Boundary conditions determine the leakage of jet to the surface, which is an internal cylindrical 

surface of the calibration tube. Mass transfer was determined by (3) based on the Stokes equation, which 

determines the strength of resistance in a stream of particles: 

 



Problems of Tribology 97 

 

s
c

d

w
F

2

18 
 ,                                                                                       (3) 

where μ – rate of fluid flow through the nozzle; ds – diameter of tube. 

Three-dimensional model of free jet was created to determine the parameters of the system and using the 

software package flow vision was determined the pressure and velocity in the jet. For the model studies was 

considered the problem of leakage of jet fluid that flows out of the hole diameter of 1 mm. In order to determine 

pressure and velocity of fluid in the jet the problem with free surface was created and solved. 

Were given the following physical parameters: 

- the initial parameters; 

- basic values - temperature 273 K, pressure 101 000 Pa; 

- parameters of the model - the density of liquid 1000kh/m3; 

- liquid 0 - clear water; 

- adaptation of the grid up to level 2. 

Boundary conditions for the elements (walls, entrance, exit) and the degree of adaptation for each of them 

are given. Speed jet at the inlet is 300 m/s. Initial mesh with 25652 cells where 21168 of them solidified it in the 

area of the exit from nozzle and at the surface of leakage is given. The general model parameters and time course 

of the calculation in the range from 0 to 5 • 10-5 are given, the calculation is standard. The calculation results 

derived in the form of diagrams (Fig. 3, a, b) fill – pressure in the range of 3,5•105 Pa to 7,579•107 Pa; rate – 

isolines, from 0 to 300 m/s [6]. 

Researches showed that most loaded from the point of view of abrasive wear are places of entrance of liquid-

abrasive mixture and on an exit from a tube (Fig. 3). In these areas transversal pressure caused by wave 

processes maximally influences on the mobile particles of abrasive. 

 

 
 

Fig. 3. The results of modeling of liquid-abrasive mixture with the walls of the calibration tube 

 

 
 

Fig. 4. The photomicrography of the worn edges of the tube 

 

Submitted photomicrography of the edge of nozzle shows that the destruction takes place on that part of 

that perceived maximum hydrodynamic load (Fig. 4) caused with a back wave in time of leakage jet on an 

obstacle – the work surface. Thus, the picture of the damage of tube corresponds to parameters of simulated 

pressure diagram in the longitudinal and end sections nozzle channel. Obtained in Fig. 5 oscillogram shows a 

periodic increase pressure on the edge of the nozzle with amplitude from 0 Pa to 250 МPa and frequency 2 • 10-

6 s, which indicates the presence of wave processes in the body of the jet. 

Durability σw of materials calibration tubes with hydroabrasive wear is a complex and ambiguous 

function of the conditions of interaction of material with abrasive particles and the environment [3]: 

 

);;;;;;;(
'

 vKKdПTf фmw  ,                                                            (4) 



98 Problems of Tribology 

 

where Т — duration of wear; П — concentration of abrasive particles in a liquid;  

d — size of particles; Кт — coefficient of hardness equal to the ratio of hardness of material to hardness of 

abrasive particles; Кф' — coefficient that describes the shape of the particles; v — velocity of abrasive particles 

in the moment of impact with the details surface; α — angle of velocity vector of particle to wearing surface 

(angle of attack); χ — coefficient characterizing the decrease of mechanical properties of material resulting 

softening physical-chemical action environment. 

 

 
 

Fig. 5. Graph of velocity and pressure under leakage of jet on the walls of the calibration tube 

 

Total volume of material seized in the interaction with the walls of hydroabrasive stream calibration tube will 

be: 

 

a
nn

i

barn
www 







15

)186(

3

)3(
2

21 ,                                                (5) 

 

hole depth п and its length а as a function of process parameters: 
 

n

abpa

aba

na
a

nn

an
n

mz

RTk

Rk

zmv

HBzk

Rmv

22

;
2

22

2











,                                                        (6) 

where m – mass of abrasive particles; vn, va – normal and tangential component of particle impact velocity with 

the treated surface; Ra, HB, b – parameters of roughness, hardness and strength of surface; zn – granularity of 
abrasive particles; Tp – constant, taking into account the inertia of the process microcutting; kn, ka – constant 

coefficients.   

Since the calibration tube takes hydrodynamic and mechanical loading from fast moving abrasive 

particles inserted in the flow of fluid from the nozzle cut, the reason for its withdrawal from the calibration 

aperture Dk growth over the limit and split of individual elements, thus changing the geometry formed by 

grooves cut (Fig. 6). This damage is caused with wearing phenomena. It is logical increase firmness of the 

calibration tubes by causing protective coatings. The use of special wear-resistant coatings can significantly 

improve the time of stability of materials in aggressive environments, improve the stability of the process due to 

less intensive changes in the dynamics of initial geometrical parameters of the channel [7]. However, currently 

there are no clear guidelines regarding the type of coatings that can be used in this practice and rational 

technologies application of such coatings on the inner surface of the channel. 

 

 
Fig. 6. The dependence of change of the calibration opening on run-in time  



Problems of Tribology 99 

 

 

To address the question of whether the use of certain surface coatings on hydroabrasive resistance the 

samples with size 40x10x5 mm from titanium alloy VK8 were tested, which is instrumental material of elements 

of hydroabrasive processing, as no cover, so with a vacuum-plasma coating TiN, with the nitrided layer and the 

combined coverage of the nitrided layer and TiN (Fig. 7). Modes of coating are given in Table 1. 

 

 
Fig. 7. Microelectronic researches of alloy VK8: а – without coating; b – with coating TiN; c – with the nitrided 

surface layer 

Table 1  

Modes of coating 

Parameters Vacuum-plasma spraying TiN Ionic-plasma thermocyclic nitriding 

Working pressure Р 2,2•10-3 mmHg 100 Pа 

Arc current Iд, А 100 10 

Temperature Т, ºС 520 550 

Voltage U, V 500 600 

Time, min 40 360 

 

To microelectronic studies of these, coating were deposited considering functional-oriented approach to 

flat plates, which were established for research under certain angles to leakage jet (Fig. 8). 

Functionally-oriented approach involves the production of calibration tube by special technology, which 

is based on strict topologically oriented implementation of the required set of algorithms of technological 

performance of processing in required micro and macro zones and parts of the product that meet the functional 

requirements of their operation in each of its zone. 

 

 
 

Fig. 8. Installation of a test piece on desktop of hydrocutting machine LSK-5-400 

 

For a comparative analysis all experimental studies were made at the same processing parameters, which 

were adopted: leakage pressure – 280 MPa, volumetric concentration of abrasive in suspension – 0,6 kg/min, 

processing time – 10,5 minutes. Investigation of angle of attack for wear of samples were carried out using a 

garnet sand from grit 30 mesh as an abrasive in suspension. The distance between the initial section of ejecting 

adjutage of ink-jet apparatus and the sample was 80 mm. In Fig. 9 there are comparative diagrams of coating 

TiN and combined coating  wearing, presented as the depth of damage layer, measured relative to the plane 



100 Problems of Tribology 

 

undamaged surface. Angle of leakage of samples is 15 0 (/12). Found that the dynamics of damage protective 

coatings is fundamentally different: coating TiN weared more rapidly and in 3 minutes damage reached its 

maximum. After that damage rate declined, and on the samples were observed area almost its complete removal. 

Further active destruction of substrate material began (Fig. 10). The of combined coating was more resistant to 

liquid cavitation abrasive wear (almost 3 times). This wear was evenly without forming complete detachment 

areas.  In the following diagrams the dependence of the degree of damage is presented (like a deep hole that is 

formed on the surface (h) for a fluid time). Dependence of change of depth hole formed in function of the angle 

jet of leakage α is given. Impact angle of leakage boost on the speed of removal of coating was determined by 

measuring the penetration of the jet in the specimen at a time equal to 1 min. Measurements performed in the 

range of angles from 30 (/60) to 300 (a further increase in angle leads to complete destruction of coating and 

base and a groove about 3-4 mm). The adequacy of the obtained models – 0,95. 

According to the obtained data it is easy to conclude that most works better coverage at the tangent jet of 

leakage. The operation time in 1 min is not exponential, because this time is necessary to establish to ensure 

comparability of measurements of the dynamics of wear at the big corners of leakage (Fig. 11). The difference 

between the mechanisms of interaction between the abrasive particles to the surface of the tube along the canal 

and attempts to reach approximately the same low rate of erosion due to the development of modern functional 

approach discussed in the works O. Mykhaylova ([8, 9], etc.). Suggests the presence on the surface clearly 

deterministic function of makro zones, which require different properties and different ways of providing 

functions. These may be the appropriate coverage that satisfactorily be taken one or the other type of abrasive 

loading. However, the difficulty lies precisely in the fact that the diameter of the tube is not the same and rather 

small – from 4,2 mm at the inlet of the tube to 0,95–1,20 mm at its cut. 

However, the use of coatings provides for a change in the design of the handset and change the material 

from which it is made. We suggest to use a calibration tube of fundamentally new design. Wear-resistant gauge 

tube to form a liquid abrasive jet cutting was made of two symmetrical parts, connected together by mechanical 

means, including covered clip, planted with the intention to form a longitudinal axial channel for passage of the 

working fluid from the abrasive surface and the longitudinal axial channel for the precedence of damage from 

exposure waterjet stream inflicted with durable fragmented layer, which is based on the functional-oriented 

approach is the adhesion of the film material, which the wear intensity for excellent action waterjet stream is the 

same, the length of the application layer (a fragment) is responsible length of the high intensity of the action of 

abrasive particles.  
Plot of Fitted Model

h1 = 0,00601282 + 0,022641*t

0 1 2 3 4 5

t

0

0,03

0,06

0,09

0,12

0,15

h
1

 
a 

Plot of Fitted Model

h2 = (0,1194 + 0,0983334*t)^2

0 1 2 3 4 5

t

0

0,1

0,2

0,3

0,4

0,5

h
2

 
b 

Fig. 9. The comparative diagrams wear of coating TіN (а) and combined coating nitrided + TiN (b) 



Problems of Tribology 101 

 
 

 
 Fig. 10. Samples after testing 

 

Plot of Fitted Model

h_1 = exp(-3,91971 + 0,155241*alpha)

0 5 10 15 20 25 30

alpha

0

0,4

0,8

1,2

1,6

2

h
_
1

 
a 

 

Plot of Fitted Model

h_2 = exp(-2,93538 + 0,144434*alpha)

0 5 10 15 20 25 30

alpha

0

1

2

3

4

5

h
_
2

 
b 

Fig. 11. Dependence of wear coating ТiN (a) and combined coating on the corner of accumulating (b) 

 

According to functional-based approach product manufacturing, it should be implemented a number of 

features that can be provided by individual carriers of cheaper material or work that is the least costly. Therefore, 

in our opinion , the use of fragmented layer is more efficient than the production of the entire tube with a wear 

resistant, but also more expensive in material. 

To verify the presented ideas and get real wear profiles 10 gauge tubing coated with patchy layers (Fig. 

12) were produced and tested after a fixed lifetime (T = 10,0 hours). Tubes material was regenerated solid alloy 

of VK with burning created by electrocontact TiN coating thickness of 1,5 mm (factionalism 30/50 μm) at the 

point where the movement of abrasive grains was ordered (in zone 1), PVD-coated in Zone 2 (where channel 

sees mostly rolling effect of the abrasive particles rolling and PVD- coating of nitriding (N + TiN) at the end of 



102 Problems of Tribology 

 

the tube, where there is influence reflected from the surface treatment of the particles; nitride layer thickness – 

200 μm, coating TiN – 10 μm. The results shows that the coating securely protects channel tube, embryos failed 

to precede the occurrence of intense destruction on the surface of the channel, while apparent space docking in 

different layers along the length of the channel, and the thickness of the PVD-coating of nitriding (N + TiN) 200 

μm proved practically remove. However, the development of damage to the channel took place almost without 

disturbing the original diametric portion and quite evenly. Studies performed using laser jet set LSC-400-5. 

Thus, we can state that, along with other means of reducing the wear lodged in [8,9], and improve the stability of 

geometric parameters of channel function approach is effective and efficient.  

 

 
а 

 
b 

Fig. 12. Coated tubes (a) and wear profile of the channel after 10 hours of work (b): 0 – without layers; 1–9 – 

coated functional layers 

 

At the same time, the need for further analysis of options for implementation layers, and in the future – 

attempts to create an inverted gauge tubes, layers that build the channel (made of a material that can then be 

easily removed) to the outer surface . In this case, the obvious advantage is the formation of a surface of the 

channel,  where carbides or nitride compounds can be oriented so that the surface was formed by low hydraulic 

resistance. For these studies appropriate involvement of Rapid Prototyping. Further work is currently being 

regenerated with replacement hard metal cheaper material , such as alloyed steel. However, in our opinion, 

identified patterns and approaches can be used in any critical inkjet devices.  

 

Conclusions 

 

A model of two-phase flow of high-speed waterjet cutting stream in ductal calibration of the tube allowed 

to prove the existence of certain areas in which great damage processes manifested channel based on what is 

proposed to use a functional approach and created a new design tube which implies the existence of fragmented 

functional layers on the surface of the channel. Experimental tests of the proposed type gauge tubes that have 

proven given consideration. Of all the parameters – Dk, σDk, γDk, λDk (Fig. 6), the application of functional 

coatings can reduce γDk, thereby increasing the lifetime of the tube to the predicted onset of failure as 

D

ik DDT



   



Problems of Tribology 103 

 

Guaranteed stability of the proposed calibration tube type stability than conventional tubes at an average 

of 1.5...1.8 times and averages above 17,5 hours, while the dispersion is 10–12 %. Retrieved functional 

dependencies wear gauge tube coated on the criteria of sustainability hydroabrasive complement general 

methodological information base and certainly contribute to the development of the principle of control 

properties of the surface layer. 

 

References 

 

1. Prospects of development of waterjet and water abrasive processing. Looking downstream. Amer. 

Mach. 2001. 145, №3, P. 80-82, 84, 86, 88, 90.  

2. Salenko O.F., Fomovska O.V. (2008)”Prospects for market equipment for sheet handling”, Visnyk 

KDPU, 2008. №6(48). P. 45-50. 

3. Tsygankovskij A.B. Determining of the degree of influence of the angle of attack jet on productivity 

and quality of waterjet processing submerged jets, Visnyk SNU named by V. Dal. 2009. №6, P. 220-228. 

4. Provolotskij A.E. Jet-abrasive treatment of details, Tehnica, Kyiv: 1989. 189 p. 

5. Kleis I.R. Fundamentals of the choice of materials for operation in the gas abrasion wear. Friction and 

wear, 1980. №2, P. 263 - 271. 

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Саленко О. Ф.,  Хорольська М. С., Лопата В.Н., Соловых А.Е., Кулижський В.М. 

Використання функціонального підходу при вирішенні задач  підвищення працездатності 

гідрообразивного обладнання 

 

У роботі показаний вплив параметрів калібрувальної трубки струминно-абразивних пристроїв на 

якість процесу гідроабразивного різання відповідальних деталей. Приведені результати моделювання 

формування двофазного потоку та його руху в калібрувальній трубці. Визначено, що плинні явища 

зношування протокової частини трубки мають різну інтенсивність і характер. У зв'язку з цим постає 

необхідність застосування функціонально-орієнтованого підхіду до вибору засобів забезпечення 

потрібних геометричних параметрів трубки. Зроблено висновок, що зменшення інтенсивності зйому 

матеріалу з протокової частини трубки та, відповідно, підтримання її геометричних параметрів можливе 

шляхом використання відповідних захисних покрить, товщина та фізико-механічні характеристики яких 

обираються на основі функціонально-вартісних ознак відповідно до інтенсивності та виду абразивного 

навантаження поверхні. 

 

Ключові слова: гідроабразивне різання, калібрувальна трубка, зношування, захисні шари, 

функціонально-орієнтований підхід