Uneven Wall Thickness Research Articles

Research on the Optimization of TP2 Copper Tube Drawing Process Parameters Based on Particle Swarm Algorithm and Radial Basis Neural Network

After rolling, TP2 copper tubes exhibit defects such as sawtooth marks, cracks, and uneven wall thickness after joint drawing, which severely affects the quality of the finished copper tubes. To study the effect of drawing process parameters on wall thickness uniformity, an ultrasonic detection platform for measuring the wall thickness of rolled copper tubes was constructed to verify the accuracy of the experimental equipment. Using the detected data, a finite element model of drawn copper tubes was established, and numerical simulation studies were conducted to analyze the influence of parameters such as outer die taper angle, drawing speed, and friction coefficient on drawing force, maximum temperature, average wall thickness, and wall thickness uniformity. To address the problem of the large number of finite element model meshes and low solution efficiency, the wall thickness uniformity was predicted using a radial basis function (RBF) neural network, and parameter optimization was performed using the particle swarm optimization (PSO) algorithm. The research results show that the RBF neural network can accurately predict wall thickness uniformity, and using the PSO optimization algorithm, the best parameter combination can reduce the wall thickness uniformity after drawing in finite element simulation.

Optimization of Core Shift for Injection Mould based on ANFIS-FWA

Background: In most of the deep-cavity shell plastic products injection moulds, such as test tubes, syringes, and other medical devices, the slender core structure is essential. The uneven pressure of the polymer melt acting on the core during the filling process easily causes core deformation, resulting in core shift, the wall thickness inequality of the parts, and a series of problems, which then affect the final shape and mechanical properties of the plastic parts. The type of deep cavity component is prone to core shift defects during injection molding, resulting in uneven wall thickness of the syringe sleeve and inability to achieve perfect fit with the syringe core rod. Reducing the core shift of the component is the key issue of this article. Background: In most of the deep-cavity shell plastic products injection moulds, such as test tubes, syringes, and other medical devices, the slender core structure is essential. The uneven pressure of the polymer melt acting on the core during the filling process easily causes core deformation, resulting in core shift, the wall thickness inequality of the parts, and a series of problems, which then affect the final shape and mechanical properties of the plastic parts. The type of deep cavity component is prone to core shift defects during injection molding, resulting in uneven wall thickness of the syringe sleeve and inability to achieve perfect fit with the syringe core rod. Reducing the core shift of the component is the key issue of this article. Objective: This study aims to combine injection moulding CAE with neural networks and optimization algorithms to reduce core shift, improve molding quality and dimensional accuracy, extend mold life, establish a regression model for predicting core shift, shorten product development time, and improve production efficiency. Methods: Propose an injection moulding process parameter optimization method based on Adaptive Neural Network Fuzzy Inference System (ANFIS) and Rireworks Algorithm (FWA). Taking a certain medical syringe as the research object, the Taguchi experiment was designed with mold temperature, melt temperature, injection time, injection pressure, packing pressure, and packing time as optimization variables. A simulation was conducted using Moldflow software, and the signal-tonoise ratio was used to analyze the significance and trend of the influence of process parameters on the plastic core shift. A predictive regression model is constructed based on ANFIS to express the nonlinear function relationship between process parameters and core shift. FWA is used to conduct global optimization based on the ANFIS model to determine the optimal combination of injection molding process parameters. Results: Through simulation verification, the errors between the FIS prediction model and the ANFIS prediction model were compared with the actual simulation values. The ANFIS prediction model had the highest accuracy, and the core shift of plastic parts based on the ANFIS-FWA combination optimization method decreased by 27.6% compared to before optimization. It was effective in improving the molding quality of plastic parts. result: Through simulation verification, the errors between the FIS prediction model and the ANFIS prediction model were compared with the actual simulation values. The ANFIS prediction model had the highest accuracy, and the core shift of plastic parts based on the ANFIS-FWA combination optimization method decreased by 27.6% compared to before optimization. It was effective to improve the molding quality of plastic parts. Conclusion: The core shift prediction model established based on ANFIS can accurately predict the core shift of the product, greatly reducing the lengthy simulation time of the computer and shortening the product development cycle. The ANFIS-FWA coupling method can find the best combination of process parameters among multiple injection molding process parameters, achieve the improvement of core shift defects, and provide new ideas for optimizing the core shift of the same type of product.

Effects of uneven wall thickness of steel pipes on magnetic permeability perturbation testing for internal defects

ABSTRACT Magnetic Permeability Perturbation testing (MPPT) has the advantage of high sensitivity for deeply buried defects in steel pipes. However, in complex working conditions, variations in the partial wall thickness of the pipe can affect the defect detection results. The paper discusses the influence mechanism of uneven wall thickness on the MPPT of internal defects on steel pipes and analyzes the magnetic field distribution caused by uneven wall thickness which influences on the magnetic permeability perturbation (MPP) of internal defects. The MPP is enhanced at the thinning wall and weakened at the thickening wall. The effect of uneven wall thickness on MPPT signals is confirmed through simulation and experiment. The signal of defects in thinning wall is enhanced, while the signal of defects in thickening wall is weakened. The greater the wall thickness variation, the degree of signal distortion is more significant. Experimental results show that uneven wall thickness has an effect on the detection of the defects with different depths. Finally, a method using deep saturation magnetisation is proposed to mitigate the inconsistent signals caused by uneven wall thickness. The findings will contribute to quantitative evaluation of defects in MPPT.

A novel semi-flexible coaxial nozzle based on fluid dynamics effects and its self-centering performance study

Coaxial nozzles are widely used to produce fibers with core–shell structures. However, conventional coaxial nozzles cannot adjust the coaxiality of the inner and outer needles in real-time during the fiber production process, resulting in uneven fiber wall thickness and poor quality. Therefore, we proposed an innovative semi-flexible coaxial nozzle with a dynamic self-centering function. This new design addresses the challenge of ensuring the coaxiality of the inner and outer needles of the coaxial nozzle. First, based on the principles of fluid dynamics and fluid–structure interaction, a self-centering model for a coaxial nozzle is established. Second, the influence of external fluid velocity and inner needle elastic modulus on the centering time and coaxiality error is analyzed by finite element simulation. Finally, the self-centering performance of the coaxial nozzle is verified by observing the coaxial extrusion process online and measuring the wall thickness of the formed hollow fiber. The results showed that the coaxiality error increased with the increase of Young’s modulus E and decreased with the increase of flow velocity. The centering time required for the inner needle to achieve force balance decreases with the increase of Young's modulus (E\\documentclass[12pt]{minimal} \\usepackage{amsmath} \\usepackage{wasysym} \\usepackage{amsfonts} \\usepackage{amssymb} \\usepackage{amsbsy} \\usepackage{mathrsfs} \\usepackage{upgreek} \\setlength{\\oddsidemargin}{-69pt} \\begin{document}$$E$$\\end{document}) and fluid velocity (vf\\documentclass[12pt]{minimal} \\usepackage{amsmath} \\usepackage{wasysym} \\usepackage{amsfonts} \\usepackage{amssymb} \\usepackage{amsbsy} \\usepackage{mathrsfs} \\usepackage{upgreek} \\setlength{\\oddsidemargin}{-69pt} \\begin{document}$${v}_{f}$$\\end{document}). The nozzle exhibits significant self-centering performance, dynamically reducing the initial coaxiality error from 380 to 60 μm within 26 s. Additionally, it can mitigate the coaxiality error caused by manufacturing and assembly precision, effectively controlling them within 8 μm. Our research provides valuable references and solutions for addressing issues such as uneven fiber wall thickness caused by coaxiality errors.

Novel path planning algorithm for laser powder bed fusion to improve the scan quality of triply periodic minimal surface structures

Traditional path planning methods, such as contour and raster methods, suffer from problems like uneven filling, overfilling, and underfilling in the sliced layers, resulting in poor continuity of the lattice melt pool, internal porosity defects, and severe powder adhesion at the contour edges, while research on path planning for three-periodic minimal surfaces lattices is relatively limited. In this study, a scanning path planning method based on lattice equations control is proposed, which differs from traditional contour paths and raster paths. The new paths are controlled by the isosurface parameters of the lattice equation and optimized using the traveling salesman problem, resulting in more uniform scanning paths. The new paths avoid the underfilling issue present in raster path and the sawtooth-shaped borders of raster path. Additionally, they circumvent the nonuniform scanning path problem caused by uneven wall thickness in contour path. Through visualizing the paths and conducting printing experiments on the lattice, it is found that the new path is more uniform compared to contour paths, effectively addressing the issue of overfilling. Compared to raster paths, the new path has smoother boundaries and reduces internal porosity and powder adhesion within the lattice. This research has important value in reducing internal porosity and external powder adhesion issues in three-period minimal surface (TPMS) lattice printing processes, further enhancing the manufacturing quality of TPMS lattices.

Analysis and optimization of stamping and forming process of bearing outer ring

To address the common issues of wrinkling, tearing, and uneven wall thickness in the actual sheet metal stamping process of the outer ring of needle roller bearings, this study analyzes critical technical indicators such as forming limits, thickness distribution, and principal strains in the forming process in detail. Three-dimensional models of the concave and convex dies were constructed. The effects of different process parameters, including stamping speed, edge pressure, sheet metal thickness, and friction coefficient, on the quality of the forming parts were investigated by varying these parameters. Subsequently, the orthogonal experimental method was used to determine an optimal experimental group from multiple sets of experiments. It was found that under the process parameters of a stamping speed of 3000 mm/s, edge pressure of 2000 N, sheet metal thickness of 0.9 mm, and friction coefficient of 0.125, the forming quality of the outer ring of the bearing is ideal.

Pathological features of vascular wall in Dieulafoy's disease

AimsAlthough there are many clinical reports on Dieulafoy's disease, there are few studies on the pathological structure of vascular wall in Dieulafoy's disease. MethodsIn this study, the main structural changes of the intima and media of the vascular wall were observed by special staining and immunohistochemical methods in the subjects of Dieulafoy's disease of stomach and intestine. ResultsThere were many vessels of different sizes in the submucosa, with uneven wall thickness of the vessels. Compared with the normal control group, the content of blue collagen fibers between the vascular smooth muscle cells in the lesion group was increased, the elastic fibers were thickened, and the internal elastic plate was arranged stiff or even interrupted. ConclusionsThe increase of collagen and elastic fibers between the smooth muscle cells of the medium membrane and the destruction of the structure of the inner elastic plate may be the structural basis of vascular lesions leading to Dieulafoy's disease.

Allowance Extraction Considering of Inner and Outer Contour and Experimental Research on Belt Grinding of Hollow Blade

Aero-engine fan blades often use a cavity structure to improve the thrust-to-weight ratio of the aircraft. However, the use of the cavity structure brings a series of difficulties to the manufacturing and processing of the blades. Due to the limitation of blade manufacturing technology, it is difficult for the internal cavity structure to achieve the designed contour shape, so the blade has uneven wall thickness and poor consistency, which affects the fatigue performance and airflow dynamic performance of the blade. In order to reduce the influence of uneven wall thickness, this paper proposes a grinding allowance extraction method considering the double dimension constraints (DDC) of the inner and outer contours of the hollow blade. Constrain the two dimensions of the inner and outer contours of the hollow blade. On the premise of satisfying the outer contour constraints, the machining model of the blade is modified according to the distribution of the inwall contour to obtain a more reasonable distribution of the grinding allowance. On the premise of satisfying the contour constraints, according to the distribution of the inwall contour, the machining model of the blade is modified to obtain a more reasonable distribution of the grinding allowance. Through the grinding experiment of the hollow blade, the surface roughness is below Ra0.4 μm, and the contour accuracy is between − 0.05~0.14 mm, which meets the processing requirements. Compared with the allowance extraction method that only considers the contour, the problem of poor wall thickness consistency can be effectively improved. It can be used to extract the allowance of aero-engine blades with hollow features, which lays a foundation for the study of hollow blade grinding methods with high service performance.

The analysis of the jump ring on the surface of a thin wall copper tube by drawing with a floating plug

The defect of the jump ring on the surface of the thin wall copper tube by drawing with a floating plug was analyzed, experiment was based on a direct reading spectrometer, metallographic microscope, SEM, and 3D surface topography instrument. Research shows that: when the plug position was over the extreme for-most position, the copper tube was extruded between the drawing die and mandrel, forming a localized necking state; when the plug position was over the extreme rear-most position, the copper tube was drawing in the empty sinking state. The plug does not play a finishing affection, which causes local projections of surface materials. The jump ring macro showed a ring bamboo section scar with bright and dark, micro performance for the uneven wall thickness.

Search procedure for optimal design and technological solutions to ensure dimensional and geometric accuracy of castings

The object of research in the work is the technology of manufacturing shaped castings in disposable sand molds. The existing problem is that the imperfection of design and technological solutions at the stage of developing the technology of a single sand mold casting leads to deviations in the dimensions and geometry of the castings after their manufacture from the requirements of technological documentation. This can lead to an irreparable shortage of casting. To develop measures to eliminate or minimize the event, which consists in the formation of a shortage of castings in terms of dimensional and geometric accuracy, a procedure for searching for optimal design and technological solutions is proposed. A hypothesis has been put forward that a significant factor that leads to deviations in the dimensional and geometric accuracy of castings from the requirements of technological documentation is the imperfection of the gating system design. It is demonstrated on specific castings how this factor can influence the formation of uneven wall thickness. The proposed procedure, which includes 10 consecutive steps, allows to build a plan for a complete factorial experiment and obtain a regression equation for it, linking the parameters of the gating system with indicators of dimensional and geometric accuracy. The presence of such equations provides the possibility of further experimental optimization and determination of design and technological solutions for the development or improvement of casting systems that minimize the deviations of the dimensional and geometric accuracy of castings from the requirements of technological documentation. This also minimizes the likelihood of an event consisting in the formation of an irreparable shortage of castings. The presented study will be useful for machine-building enterprises that have foundries in their structure, where shaped castings are made in disposable sand molds.

A Method for Measuring the Inclination of Forgings Based on an Improved Optimization Algorithm for Fitting Ellipses

During a piercing or punching process, the center axis of a forging stock is required to be parallel to the direction of movement of the upsetting rod or piercing needle because any small tilt of the stock will cause uneven upsetting or uneven punching wall thickness. In order to detect the inclination of a stock during forging, a method for measuring the inclination of forgings based on an improved optimization algorithm for fitting ellipses is proposed in the work. Specifically, a laser rangefinder is used to measure the distances to the surface of the workpiece, which are converted into Section profile coordinates through coordinate transformation. Next, the randomly divided area and random sampling are presented for screening data points, making it possible to effectively eliminate the influence of abnormal values in the measurement points. Then, taking the point-to-ellipse orthogonal distance as the geometric model, we propose an improved particle swarm optimization (PSO) algorithm to solve the target ellipse parameters. Subsequently, we compare the fitting effect with four other contemporary advanced methods to verify the superiority of the algorithm in ellipse fitting. Finally, the three-dimensional linear equation of the center axis of the forging stock is obtained according to the center point of the long axis of the ellipse in the vertical direction, and the inclination angle of the forging stock is calculated according to the linear equation. The experimental measurement reveals that the error that occurred using the method is less than 0.05°.

Prediction of Casing Collapse Strength Based on Bayesian Neural Network

With the application of complex fracturing and other complex technologies, external extrusion has become the main cause of casing damage, which makes non-API high-extrusion-resistant casing continuously used in unconventional oil and gas resources exploitation. Due to the strong sensitivity of string ovality, uneven wall thickness, residual stress, and other factors to high anti-collapse casing, the API formula has a big error in predicting the anti-collapse strength of high anti-collapse casing. Therefore, Bayesian regularization artificial neural network (BRANN) is used to predict the external collapse strength of high anti-collapse casing. By collecting full-scale physical data, including initial defect data, geometric size, mechanical parameters, etc., after data preprocessing, the casing collapse strength data set is established for model training and blind measurement. Under the classical three-layer neural network, the Bayesian regularization algorithm is used for training. Through empirical formula and trial and error method, it is determined that when the number of hidden neurons is 12, the model is the best prediction model for high collapse resistance casing. The prediction results of the blind test data imported by the model show that the coincidence rate of BRANN casing collapse strength prediction can reach 96.67%. Through error analysis with API formula prediction results and KT formula prediction results improved by least square fitting, the BRANN-based casing collapse strength prediction has higher accuracy and stability. Compared with the traditional prediction method, this model can be used to predict casing strength under more complicated working conditions, and it has a certain guiding significance.

Regional temperature control in ceramic injection moulding: An approach based on cooling rate optimisation

The injection moulding of ceramic components with uneven wall thickness presents challenges due to differential cooling rates developing in the injected parts, which cause premature solidification of the feedstock at thin features and lead to detrimental defects, worsening in components from green to sintered states. To cope with this, suitable mould thermal control approaches have to be selected and validated, as current control methods are based on the achievement of a uniform cavity surface temperature, which is not tailored to such complex geometries. In this work, a novel thermal control system is proposed, based on regional mould temperatures, implemented with the use of Peltier modules, which locally and independently heat and cool different cavity features according to their thickness. The regional temperature profiles are optimised over time with the use of a coupled Finite Element - Particle Swarm Optimisation (FE-PSO), to achieve uniform cooling rates throughout the moulded components. The performance of this approach is compared to both constant ambient mould temperature and Rapid Heat Cycle Moulding (RHCM) techniques, which instead aim at achieving uniform temperatures throughout the mould cavity surface. Results show that the novel proposed method, based on regional temperature control and uniform cooling rates, promotes the simultaneous solidification of features with a 10-times difference in surface-to-volume ratio. Due to this, in terms of components quality, the novel method brings the advantages of higher dimensional control and reduction of differential shrinkage compared to the other analysed approaches, thus increasing the capability to use injection moulding to manufacture ceramic components characterised by non-uniform wall thickness.

Computational modelling for the spiral flow in umbilical arteries with different systole/diastole flow velocity ratios

The systole/diastole (S/D) flow velocity ratios in umbilical arteries (UAs) have been used to assess the health status of the feto-placental circulation, yet its connection to the morphology of UAs, specifically its coiling pattern remains unclear. Spiral flow induces unbalanced wall shear stress (WSS) distribution in UAs, and may contribute to the uneven arterial wall thickness, and the chirality. In this paper, we use a 3D computational fluid dynamics (CFD) technique to quantify the wall shear stress (WSS) in UA models of two configurations, i.e. at 0.17 and 0.50 spirals per centimeter, to represent normo- and hyper-coiling, respectively. For CFD simulations we use two different S/D ratios (3.02 and 5.70) revealed from the ultrasonography waveforms of a normal and an intrauterine growth restriction (IUGR) case. We found that more coils in the UA model enhanced WSS throughout a cardiac cycle (up to 24%) with the same inflow condition. In addition, time-averaged WSS are generally increased and more uneven in the hyper-coiling model. We suggest that the large WSS difference between the peak systole and end diastole (62% higher in the IURG case than the normal case) may induce uneven stenosis distribution at UAs, and contribute to UA chirality.

Loading of rocket joins with account for features of constructions of adjacent compartments

The method of calculation of efforts on the fasteners of the junction of missile compartments, which have structural features (uneven wall thickness in a circular or longitudinal direction, the presence of openings) under the action of axial forces and bending moments. The technique takes into account the conditions of rocket fastening in the container or vehicle and allows to determine the basic cases and maximum loads on the fasteners for further calculation of the joints for strength. Cite as: V. M. Kharchenko, D. V. Klymenko, “Loading of rocket joins with account for features of constructions of adjacent compartments,” Prykl. Probl. Mekh. Mat. , Issue 17, 98–104 (2019) (in Ukrainian), https://doi.org/10.15407/apmm2019.17.98-104

Impact of the pressure between the casting and water-cooled mode on the interfacial heat transfer coefficient under LPDC

Low pressure die casting (LDPC) is the main method for aluminum alloy castings. In order to obtain no porous castings, a top-down progressive solidification is required. Owing to the complicated casting shape and the uneven wall thickness, it is difficult to achieve the above requirement, which limits the application of the method. The water-cooled mode, with controllable cooling capacity, can solve this problem, and great importance has been attached to the heat exchange between water-cooled mode and castings. In the present paper, the inverse solution method is adopted to study the influence of the casting mold/casting interface pressure and circulating water flow rate on the interface heat transfer coefficient (IHTC). The results show that the increasing interface pressure and the circulating water flow rate can lead to the highest IHTC of 781.6∼1002.4 W/(m2 ·K) and 1002.4∼1657.6 W/(m2 ·K) respectively. The calculation result of IHTC provides a basis for the design of low pressure casting with water-cooled mode.

Pleomorphic xanthoastrocytomas of adults: MRI features, molecular markers, and clinical outcomes

Fifty adult patients with pathologically-confirmed pleomorphic xanthoastrocytomas (PXAs) were retrospectively analyzed. Adult PXAs appeared as a single lesion in 47 patients and multiple lesions in 3 patients. Temporal lobe was the most common location (17/50). Twenty-two cases were superficial with obvious meningeal contact and 9 were closely adjacent to lateral ventricles. Three imaging patterns were differentiated, including a predominantly solid mass with or without cystic changes (n = 33), a predominantly cystic mass with an obvious mural nodule (n = 14), and a predominantly cystic mass with an uneven wall thickness (n = 3). The mean tumoral apparent diffusion coefficient (ADC) was 0.83 ± 0.17 × 10−3 mm2/s, and the mean ADC ratio was 1.02 ± 0.22. The V-raf murine sarcoma viral oncogenes homolog B1 (BRAF)V600E mutation was found in 12 of 29 patients. In 36 patients with isocitrate dehydrogenases 1 and 2 (IDH1/2) data, only one had IDH1 mutation and no patient had IDH2 mutation. Anaplastic features were common (24/50) and significantly associated with high rates of recurrence or progression (P < 0.001). In conclusion, this study expands our knowledge on the MRI features, molecular markers, and clinical outcomes of adult PXAs, to some extent different from pediatric PXAs.

Altered secretion patterns and cell wall organization caused by loss of PodB function in the filamentous fungus Aspergillus nidulans

Filamentous fungi are widely used in the production of a variety of industrially relevant enzymes and proteins as they have the unique ability to secrete tremendous amounts of proteins. However, the secretory pathways in filamentous fungi are not completely understood. Here, we investigated the role of a mutation in the POlarity Defective (podB) gene on growth, protein secretion, and cell wall organization in Aspergillus nidulans using a temperature sensitive (Ts) mutant. At restrictive temperature, the mutation resulted in lack of biomass accumulation, but led to a significant increase in specific protein productivity. Proteomic analysis of the secretome showed that the relative abundance of 584 (out of 747 identified) proteins was altered due to the mutation. Of these, 517 were secreted at higher levels. Other phenotypic differences observed in the mutant include up-regulation of unfolded protein response (UPR), deformation of Golgi apparatus and uneven cell wall thickness. Furthermore, proteomic analysis of cell wall components in the mutant revealed the presence of intracellular proteins in higher abundance accompanied by lower levels of most cell wall proteins. Taken together, results from this study suggest the importance of PodB as a target when engineering fungal strains for enhanced secretion of valuable biomolecules.

The value of left ventricular angiography in the diagnosis of apical hypertrophic cardiomyopathy

Objective To assess the diagnostic value of left ventricular angiography in patients with apical hypertrophic cardiomyopathy. Methods A total of 32 consecutively recruited patients aged from 61 to 78 with suspected apical hypertrophic cardiomyopathy from inconclusive apex imaging on conventional echocardiography from June 2016 to December 2017 underwent left ventricular opacification.A diagnosis of apical hypertrophic cardiomyopathy was made when the thickness of hypertrophied area of the apex was >1.5 cm, the ratio of the hypertrophied area to the non-hypertrophied area was >1.3, and no hypertrophy was found elsewhere. Results Twenty-four out of 32 patients (75.0%) were diagnosed with apical hypertrophic cardiomyopathy, all of whom had pure apical hypertrophy.The other 8 patients were excluded, with normal thickness in the apex.Patients with apical hypertrophic cardiomyopathy had apical wall thicknesses ranging from 15 mm to 21 mm, reduced myocardial motion amplitude in the apex and uneven echo at certain areas of the ventricular wall.All cases showed clear images of the apex with left ventricular opacification, and the apex of the heart lost its normal morphology and showed a pointed end, with ventricular cavity obliteration or uneven wall thickness in the apex. Conclusions Left heart ventricular angiography can be complimentary to conventional echocardiography in the diagnosis of apical hypertrophic cardiomyopathy by providing a clearer endocardial contour and more accurate estimates of apical wall thickness and therefore enhancing the diagnostic value of ultrasound for apical hypertrophic cardiomyopathy. Key words: Cardiomyopathy, hypertrophic; Echocardiography; Angiocardiography

Thoracic manifestation of Wegener's granulomatosis: Computed tomography findings and analysis of misdiagnosis.

The aim of the present study was to investigate the computed tomography (CT) manifestations of Wegener granulomatosis (WG) in the chest and potential reasons for misdiagnosis. Conventional CT scans and clinical data of 45 patients with WG were retrospectively analyzed. Patients typically presented with multiple system involvement, primarily in the upper and lower respiratory tract. The incidence of thoracic involvement was 75.56% (34/45). Radiographic features were varied between cases in the present study, with the most common features being numerous cavitary nodules and masses in the lungs. Cavitations were usually irregular, with uneven wall thickness, partial centrality, fuzzy inner edges and piecemeal necrosis. These results indicate that WG typically has multiple system involvement, with the chest being most prominent. Multiple variable-sized cavitary nodules with irregular edges and piecemeal necrosis were the most notable features revealed using CT scanning; however, in order to give a definitive diagnosis, biopsies should be performed.