Introduction

Modern requirements for the rational use of raw materials and energy resources for industrial enterprises, including factories producing construction supplies, require innovative development and upgrade of their production facilities. Despite the new types of walling products, the popularity of ceramic bricks remains at a high level, and technological complexes for brick production represent a significant share of the industry.  It is important to develop and implement methods and means of controlling the technological process of ceramic bricks manufacture, as it ensures the required quality of the products -with the lowest possible specific energy consumption in each individual case. The creation of algorithms and control systems with similar properties requires a preliminary analysis of the production cycle processes, the selection and justification of technological parameters, that characterize the quality of bricks and determine the causes of defects. The graphical representation of technological variables dependencies simplifies the analysis of the technological process and helps to identify hidden patterns. In this regard, the visualization of the working area of the space of technological parameters for the processes of brick production is considered an important task.

The manufacture of ceramic bricks, carried out most often by plastic shaping, includes several basic steps, at each of which the mechanical, physical, and chemical properties of the raw materials change in a certain way [1, 2]: preliminary preparation of raw materials, shaping, drying and firing. The peculiarity of this technological chain is in the significant impact of each process on the subsequent stages.

In this paper, we solve the problem of data visualization, that characterize the stage of shaping the ceramic paste in an auger vacuum extruder for the paste wetting, mixing, vacuuming and the extrusion itself. The subsequent analysis of the obtained graphic images will allow to determine the most effective approaches to the management of the considered technological process.

1. Analysis of the Technological Process of Shaping Ceramic Paste in an Auger Vacuum Extruder as an Object of Automation

The shaping of ceramic paste is one of the most important stages of brick production, determining the quality of the finished product [3, 4]. The complexity of managing this process is due to its substantial non-linearity, the non-stationary nature of the mechanical, physical and chemical properties of the raw materials, the inability to measure certain technological parameters, and the fact that defects caused by the extrusion step and the deviation of the products from the required value are detected only after drying and firing [4‑6]. Nevertheless, rather strict requirements are imposed on ceramic bricks related to their strength, deviations of their geometric shape, absence of defects in the internal structure (concentric and s-shaped cracks, laminated bars, etc.) [7].

The auger vacuum extruder is an aggregated unit that consists of a clay mixer, a vacuum chamber and the extruder [8]. After preliminary preparation, clay feedstock is fed into the loading window of the mixer using a belt feeder for further moistening, steam heating and mixing. Next, the ceramic paste enters the vacuum chamber where the air is extracted from it, adsorbed by the surface of clay particles (causing microcracks in the brick). After vacuuming, the ceramic paste is transported by an auger to the pressure head where the paste is pressed through the head outlet of a given shape resulting in a bar of the desired cross section.

It is known [4, 6, 9] that the strength value R of finished products under compression depends significantly on the shear rate  and the moister level w of the ceramic paste in the pressure head, the value of the vacuum pressure P_v in the vacuum chamber of an auger extruder (Fig. 1). Therefore, these parameters make up the vector of controlled coordinates

 ,

where t is time; T is the transpose mark.

Shear rate  is determined by the auger angular velocity ω and the flow behavior index of the ceramic paste ψ [10, 11]; P_v is determined mainly by the vacuum pump flow rate Q_vp and the flow area of the duct, which can vary by ΔF due to dust and pollution in the vacuum chamber [6, 12]; w depends on the moisture value w₀ of the raw material entering the clay mixer and the flow rate of the water added to it while mixing Q_v [11, 13, 14]. During operation, it is possible to regulate ω, Q_vp, Q_v values by varying the frequency of the voltage ω_0a, supplying the auger driving motor, the frequency voltage ω_0vp, feeding the driving motor of the vacuum pump, voltage U_0sv, supplied to the water metering solenoid valve, respectively. In this case, the vector of control actions will be as follows:

,

The disturbance vector will take the form:

.

 

Fig. 1. Influence of the technological parameters of ceramic paste shaping on brick strength R.

 

In order to make the most rational management decisions in the current technological situation, it is necessary to find the optimal position of the operation point in space  of the extrusion technological parameters, the coordinates of which are determined by the elements of the vector . We suggest that the easiest way for such an approach to be implemented is by visualizing the dependencies between the controlled coordinates of the process and further analysis of the obtained graphical representation.

2. Influence of the Technological Parameters of Shaping on the Strength of Ceramic Bricks

Strength class M is one of the brick's main characteristics [7]. Based on the analysis of the requirements described in GOST 530-2012 (Ceramic Brick and Stone. General Technical Conditions) we can suggest that a certain class M is assigned to a brick (provided that the requirements for flexural strength are met) in accordance with the following logical rule:

(1)

In studies [4, 9], the authors present an assessment of the influence of the shear rate  in samples made of non-vacuum ceramic paste (P_v = 0 %) on their strength R′ under compression after drying and firing. Every curve  of the represented family of functional dependencies, corresponding to some fixed moisture value w, has approximately the same shape with a pronounced extremum at . We assume that these curves absolutely coincide in shape and are located at the same level relative to the R′ axis, and as w changes, they shift only along the  axis. The analysis of the dependencies presented in studies [4, 9] makes it possible to describe the shifting extremum with moisture level variations in the technologically justified range by a quadratic function

,

(2)

where k₁, k₂, c₃ are constants.

Based on the data [4, 9] for ceramic samples from Cambrian clay, and taking into account expression (2), we construct a family of curves for five moisture values (Fig. 2).

 

Fig. 2. The dependence of the compressive strength of a brick on the shear rate when shaping a non-vacuum ceramic paste:

1 – w = 15.5 %; 2 – w = 17.1 %; 3 – w = 19.9 %; 4 – w = 22.5 %;

5 – w = 25.5 %.

 

In the case under consideration, k₁ = 0.1457 s^–1, k₂ = 4.4815 s^–1, c₃ = 34.778 s^–1.

Studies of the effect of vaccum processing of the extruded ceramic paste [6] revealed that no increase in strength R was observed at vacuum level of 40÷60 %, at 80÷90 % the strength increased by 70 %. Based on these conclusions, we introduce the concept of hardening coefficient K_h [12], which is described as the ratio of the strength R of a finished brick obtained from a vacuum processed paste (where R depends on the vacuum level) to the strength R' of a brick made of non-vacuum paste

.

(3)

Let us construct the dependence of the hardening coefficient K_h on the vacuum level P_v (Fig. 3), and select the area of acceptable variation in the vacuum level (on the condition of excluding defective products by appearance), which is in the range . Based on [6] -  = 70 %,  = 100 %, optimal value .

 

Fig. 3. Dependence of the hardening coefficient of ceramic bricks on the vacuum pressure in vacuum chamber of an auger extruder.

 

It can be noted that the change in the hardening coefficient K_h can occur between the abcc′d and abb′c'd polylines, and according to the data in [6] it is not possible to identify the pattern that more accurately determines the increase in strength of ceramic bricks during vacuuming of raw materials used for their production. Therefore, for further analysis here, we will use the option that requires a higher vacuum level, that is, the abcc′d polyline, which will increase the likelihood of obtaining the expected hardening effect. The polyline abcc'd is a graph of a non-linear function .

The presented dependences illustrate the influence of the vector elements of controlled coordinates  separately, but do not provide a holistic picture and do not allow to determine the optimal, w, P_v values, ensuring the operation of the unit in the most rational mode for the current technological situation. In this regard, it is advisable to create a generalized space of technological parameters of the ceramic paste extrusion process .

3. Graphic Synthesis of the Space of Technological Parameters of the Ceramic Paste Extrusion Process

A structural diagram is one of the options for representing the space of technological parameters of the ceramic paste extrusion process  . This method makes sense if the space  need to be embedded in the computational model of the brick production process. In this case, to reduce the number of manipulations with data arrays, we advise to use only one family curve in the structural diagram  at some selected base value of moisture w_b, and cast the current value of the shear rate  to an equivalent value  according to the expression

,

(4)

where  is the value of the shear rate correction,

;

(5)

 is the curve  extremum, corresponding to the moisture value w_b.

Thus, the extrusion process can be modelled at any moisture value of the ceramic paste using only one curve of the dependence of the brick strength on the speed of shear deformations.

The combination of expressions (1) ‒ (3) and non-linear functional dependencies of Φ₁ and Φ₂ allows to create a structural representation of the space of technological parameters of the ceramic paste shaping process (Fig. 4). However, this form of display, convenient for use in computational experiments, does not allow for a thorough analysis of this three-dimensional dependence, or to reveal its hidden properties. Therefore, it is obviously necessary to introduce the space  in the form of three-dimensional graphic design in the coordinates of technological variables ‒ , w, P_v. The solution of this problem is accomplished by graphic synthesis with several stages.

 

Fig. 4. Structural representation of the space of technological parameters of the ceramic paste extrusion process.

 

Projecting function graphs  (Fig. 2), where the boundaries of brick strength classes M are also indicated in accordance with expression (1), on  plane allows to get a group of curves , each of which corresponds to a specific value of R′. Further, we use only some of these curves, which will be boundary in terms of the separation of  plane into class areas. We should also take into account that for Cambrian clay the optimum shaping moisture value w_s is about 23.5 % [5], and we will take Δw_acc = ± 1 % [15] as the acceptable range. Minding these limitations, we obtain a set of work areas of an auger extruder (in terms of  and w) (Fig. 5), within which it is possible to ensure the production of a brick of a certain class from a non-vacuum ceramic paste. In fact, the formed image is a cross-section of space  with P_v = 0% - .

 

Fig. 5. The cross-section of the space of technological parameters of the ceramic paste extrusion process in  plane.

 

We should find the sought space  by multiplying the elements of the set  by the hardening coefficient, which lies in range. According to the above data, , . Thus, given the expression (3), we synthesize a three-dimensional space:

 .

Let us present  in the form of a set of surfaces   (Fig. 6), limiting ourselves to the consideration of four values of P_v.i from the allowable range of changes in the vacuum pressure of the vacuum chamber of an auger extruder in the process of shaping ceramic paste for brick production: Ð_v.1 =  = 70 % , Ð_v.2   = 80 % , P_v.3 =  = 90 % , P_v.4 =  = = 100 %. This series of values determine the values of the hardening coefficient K_h.i – K_h.1 = 1.23, K_h.2   = 1.47, K_h.3 = K_h.4 =  = 1.7. Using this kind of visualization clearly shows the areas of constant values of brick strength classes in space  (Fig. 6).

Sections  in  plane (Fig. 7) record working range of the unit, which provide for the production of bricks of a certain class with fixed values of w.

 

 

Fig. 6. Three-dimensional visualization of the space of technological parameters of the ceramic paste extrusion process.

 

Fig. 7. The cross-sections of the space of technological parameters of the ceramic paste extrusion process in  plane.

 

Based on the analysis of the surfaces obtained (Fig. 6, 7), we proposed an automatic control system  structure for an auger vacuum extruder (ACS for AVE) to manufacture the ceramic stones [11]. The structure consists of three separate channels and includes a multi-dimensional object of control, by which we understand the combination of hydrodynamic and electromechanical processes in the preparation of clay raw materials and the shaping of bars and subsequent drying and firing processes. The state of the object is determined by  vector. We use the following as converting elements: in shear rate control channel  – frequency converter to power the extruder drive; in the control channel for the P_v value – frequency converter for the vacuum pump motor; in the moisture control channel w – pulse-width modulators for powering the coils of the solenoid valves supplying water and steam to the extruder mixer.

The synthesized space of technological parameters of the ceramic paste extrusion  is incorporated into the vector of master signals for the ACS for AVE and can be adjusted depending on the data obtained during production. The arrangement and implementation of such an automation system allows to establish the competitive brick production, to ensure an increase in productivity and to reduce the specific energy consumption along with stabilizing the brick strength matching the given class requirements.

Conclusion

The paper describes the technique allowing the visualization of the space of technological parameters of the ceramic paste extrusion process. At first, this stage was considered using the approaches of system analysis, identification of objects of control and automatic control theory, which allowed to isolate the vectors of control and disturbing influences, the vector of controlled variables, elements of which were taken as coordinates of the multidimensional parameter space of the extrusion process.

The authors analyzed the results of few and scattered studies to assess the impact of the main parameters, most characterizing the efficiency of an auger vacuum extruder (shear rate and moisture levels of the ceramic paste in the pressure head and the level of vacuum pressure in the vacuum chamber), on the quality of the finished product, and first of all on its strength. This made it possible to represent the sought space in the form of a three-dimensional graphic design, in which the iso-areas of brick classes are visually displayed in coordinates corresponding to the elements of the vector of controlled variables. It should also be noted that a structural representation of the multidimensional relationship between the shear rate, the moisture of the ceramic paste, the vacuum pressure and the strength class was obtained, which is essential in preparing and conducting computational experiments.

Studying sections of the found space of technological parameters has greatly facilitated the creation of the structure of the automation system for an auger vacuum extruder and the algorithms for its rational work.

The conducted survey reflects the results of one of the stages of research work on the synthesis of the structure and the formation of the software for the digital automatic control system for the production of ceramic bricks.

References

1. Khimicheskaya tekhnologiya keramiki [Chemical technology of ceramics] / edited by I.Ya. Guzman. Moscow, Stroymaterialy, 2003. 496 p. [in Russian].

2. Zolotarskiy A.Z., Sheynman E.Sh. Proizvodstvo keramicheskogo kirpicha [Ceramic brick production]. Moscow, Vysshaya shkola, 1989. 264 p. [in Russian].

3. Tolkachev V.Ya. Tekhnologiya kachestvennoy ekstruzii izdeliy iz glin [Technology of high-quality extrusion of clay products]. Krasnoyarsk, Kompyuternyye tekhnologii, 2009. 220 p. [in Russian].

4. Barabanshchikov Yu.G. Vliyaniye skorosti formovaniya na prochnost stroitelnykh izdeliy [The effect of shaping speed on the strength of building products] // Nauchno-tekhnicheskiye vedomosti SPbGPU, ¹ 6-1, 2006, pp. 170-175. [in Russian].

5. Avgustinik A.I. Keramika [Ceramics]. Leningrad, Stroyizdat (Leningr. otd-niye), 1975. 592 p. [in Russian].

6. Tretiakov I.M., Golubovich S.R. Shnekovyye vakuum-pressy i vakuumnyye ustanovki [Auger vacuum extruders and vacuum systems]. Moscow, Gosudarstvennoye izdatelstvo literatury po stroitelnym materialam, 1953. 92 p. [in Russian].

7. GOST 530-2012 Kirpich i kamen keramicheskiye. Obshchiye tekhnicheskiye usloviya [Ceramic brick and stone. General technical conditions]. Moscow, Standartinform, 2012. 39 p. [in Russian].

8. Handle F. Extrusion in Ceramics. Berlin, Springer, 2007. 468 p.

9. Barabanshchikov Yu.G. Formirovaniye struktury i prochnosti stroitelnykh materialov pri trenii vodosoderzhashchikh syryevykh smesey [Formation of structure and strength of the building materials in friction raw water containing mixtures]. Sankt-Peterburgskiy gosudarstvennyy politekhnicheskiy universitet, Saint-Petersburg, 2006. 292 p. [in Russian].

10. Silenok S.G. Mekhanicheskoe oborudovanie predpriyatiy stroitelnyikh materialov, izdeliy i konstruktsiy [Mechanical equipment of enterprises of building materials, products and structures] / S.G. Silenok, A.A. Borschevskiy, M.N. Gorbovets. Moscow, Mashinostroenie, 1990. 416 p. [in Russian].

11. Galitskov S.Ya., Nazarov M.A., Galitskov K.S. Structure of Intelligent Control System of Auger Vacuum Extruder for Ceramic Bricks' Manufacturing // International Journal of Applied Engineering Research, 2015, Volume 10, Number 20, pp. 40846-40852.

12. Nazarov M.A., Kantseva A.M. Matematicheskoye opisaniye protsessa vakuumirovaniya keramicheskoy massy pri proizvodstve kirpicha kak obyekta upravleniya [Mathematical description of vacuuming ceramic paste process in bricks production as an object of control] // Traditsii i innovatsii v stroitelstve i arkhitekture. Stroitelnyye tekhnologii: sbornik statey / SGASU, Samara, 2016, pp. 455-460. [in Russian].

13. Galitskov S.Ya., Ivanov K.A., Nazarov M.A., Sabanov P.A., Pimenov E.K. Matematicheskoye opisaniye protsessa podgotovki keramicheskoy massy v dvukhvalnom glinosmesitele kak obyekta upravleniya [Mathematical description of ceramic paste preparing process in a two-shaft clay mixer as an object of control] // Nauchnoye obozreniye, 2014, ¹ 6, pp. 84-89. [in Russian].

14. Leisenberg W. Moisture measurement on ceramic raw materials // Zigelindustrie International, 2000, ¹ 8, pp. 25-32.

15. Nichiporenko S.P. Osnovnyye voprosy teorii protsessov obrabotki i formovaniya keramicheskikh mass [The main issues of the theory of processing and shaping ceramic pastes]. Kiyev, Izdatelstvo akademii nauk Ukrainskoy SSR, 1960. 112 p. [in Russian].