Startseite Optimization of nano coating to reduce the thermal deformation of ball screws
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Optimization of nano coating to reduce the thermal deformation of ball screws

  • Xiangsheng Gao EMAIL logo , Kuan Zhang , Min Wang , Tao Zan , Peng Gao und Chaozong Liu
Veröffentlicht/Copyright: 11. Januar 2022
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Nanotechnology Reviews
Aus der Zeitschrift Nanotechnology Reviews Band 11 Heft 1

Abstract

To reduce the thermal deformation of ball screws, the process of nano coating preparation for coating on ball screws to reduce temperature rise and thereby thermal deformation was discussed in this article. Simultaneously, the cooling mechanism was presented. The thermal channels and the relatively even distribution of graphene in the nano coating were observed in scanning electron microscopic images. In terms of the preparation of nano coating, optimization design was carried out to obtain the optimized material ratio and nozzle flow through orthogonal experiment. The influence of design parameters of nano coating on reducing thermal deformation was also discussed. The experimental results show that the maximum temperature rise, thermal deformation, and time to reach thermal balance decreased by 12.5, 69.1, and 46.3%, respectively. The effectiveness of nano coating in reducing thermal deformation was validated experimentally.

Graphical abstract

Keywords: ball screw; nano coating; thermal deformation; graphene

1 Introduction

Ball screws play an important role in accuracy stability of machine tools based on their high efficiency and good stiffness. However, their accuracy is affected by temperature rise caused by the heat sources of machine tools. Previous studies show that errors caused by thermal factors of machine tools account for 40–70% of the total errors [1]. Thus, the thermal error of machine tools can be reduced by presenting a ball screw with improved thermal performance. And studying on thermal performance of ball screws has attached much attention to improve the positioning accuracy of machine tools.

Thermal error compensation is an effective measure to deal with the decrease in ball screw positioning accuracy. Thermal error modeling is the key factor in the thermal error compensation. In terms of thermal error modeling, there are usually two methods, finite element method (FEM) and data-driven method. Liu et al. [2] investigated the dynamic behavior of adjustable preload double-nut ball screw using finite element simulation and experiments. Li et al. [3] used FEM to simulate temperature fields of ball screw feed drive system. FEM is widely used for simulation and analysis. Xie et al. [4] studied the mechanical properties of the composite sandwich matting through finite element analysis and experiments. FEM is an effective method in thermal error modeling, but it is difficult to be implemented in online thermal error compensation due to the low modeling efficiency. Li et al. [5] established a real-time prediction model of axial thermal error. Li et al. [6] presented a real-time prediction method of thermal errors of screw system based on an adaptive moving thermal network model. Chen et al. [7] proposed a thermal error method of the screw-nut feed system considering the heat transfer distance. Gao et al. [8] established the prediction model of thermal errors using PSO-LSTM neural network. Yang et al. [9] utilized the improved Elman network to carry out the thermal error modeling. Li et al. [10] established a finite difference heat transfer model to obtain the temperature field of the screw. Zapłata and Pajor [11] presented a compensation method of thermal errors using partial differential equation model. Li et al. [12] established an adaptive online analytical compensation model to compensate the positioning error of ball screw feed drive systems. Liu et al. [13] proposed a data-driven thermal error compensation model for high-speed and precision five-axis machine tools. The accurate models have a positive effect on reducing thermal errors.

Thermal error suppression is another measure for improvement of ball screw positioning accuracy. Ju et al. [14] proposed a method to suppress the thermal error by using an oil cooling system. Additionally, Shi et al. [15] investigated the effect of cooling system parameters and cooling medium flow rate on temperature distribution of screw shaft of feed drive system. Besides, many materials with unique properties were also used in thermal error reduction and accuracy improvement. Voigt et al. [16] designed a latent heat storage unit based on phase change materials (PCMs) to reduce temperature fluctuation. In our previous work ref. [17], a novel ball screw based on inner-embedded carbon fiber reinforced plastic (CFRP) was designed to reduce thermal deformation, and the effectiveness was validated under actual working condition [18]. In order to improve the thermal conduction between the screw and CFRP, a thermal conductor was mounted between them [19]. Although our previous method for improving ball screws is effective, the design is difficult to be implemented in engineering practice due to the high cost of high-modules carbon fiber and the difficulties in manufacturing. As for the improved ball screw manufacturing, 3D printing is not suitable for it. On one hand, due to the residual stress caused by 3D printing, the size will not be stable leading to inaccurate positioning. On the other hand, the raceway of ball screws by 3D printing cannot be guaranteed to be smooth to ensure the perfect ball-raceway contact. And the thermal management of coating is an effective way to reduce temperature, which has a potential application on ball screws due to the low cost and easy manufacturing. Japar et al. [20] reviewed the designs of microchannel heat sink with channel designs that could result in a high heat transfer rate. Bhat et al. [21] reported that the thermal diffusivity of coating was improved by using the carbon nanotubes. Zheng et al. [22] introduced the development of transparent nanomaterial-based solar cool coatings to reduce solar heat gain into the buildings. Chen et al. [23] exploited an efficient passive cooling coating with good cooling effect. Cheng et al. [24] proposed a single-layer radiative cooling coating, and the best cooling performance was obtained. Niazi et al. [25] developed a technique of microbial bio-coating surface modification for thermal-fluid applications. Sivanathan et al. [26] summarized that the heat transport rate can be improved by PCMs encapsulation. Zhang et al. [27] concluded that the thermochromic coatings can reduce the annual energy consumption. Yi et al. [28] designed the heat-reflective coatings to reduce the asphalt pavement temperature, and the cooling effect was tested. Wang et al. [29] investigated the effect of five types of coatings using a new data optimization method. Chen et al. [30] proposed a three-layer cool coating for asphalt pavements. Tarawneh et al. [31] enhanced the heat conduction of epoxy resin by incorporating the polyaniline and graphene nanoplatelets. Chen et al. [32] investigated the enhancement mechanism of graphene oxide doping on the heat transfer characteristics of the composite anti-/deicing components. Chen et al. [33] considered the effects of polymer materials, coating thicknesses, and surface microstructures on the cooling performance of coatings. Du et al. [34] reviewed that the thermal conductivity of cement can be enhanced by incorporating graphene. Cheng et al. [35] studied the influence of factors on spectral radiative characteristics of the radiative-cooling coating, which can greatly affect the cooling effect. Kolas et al. [36] carried out the measurement related to cooling function of eight different color coatings prepared, and the temperature reduction to 11.5°C was obtained. Zhang and Fan [37] designed a composite coating used to reduce the temperature at the surface of heat source. Kang et al. [38] prepared the coatings with high solar reflectance and strong infrared emittance to realize the daytime radiative cooling. Chen et al. [39] reported an all-inorganic phosphoric acid-based geopolymer coating with robust radiative cooling performance. Guo et al. [40] designed a ball screw with graphene coating to further reduce temperature rise and thermal deformation. The effectiveness of the coating was validated, but the experiments were carried out based on the ball screw model rather than the real ball screw. In addition, the parameters optimization of the coating was not considered. Thus, a method to optimize the material ratio and processing of coating is necessary to reduce thermal deformation of ball screws.

In terms of thermal deformation reduction of the ball screw, nano coatings were considered as an effective technical approach. In this study, a parameters optimization method of nano coating was conducted. The effect of material ratio and spraying process on nano coating thermal performance was discussed. Herein orthogonal experiment was carried out on self-design ball screw bench to obtain the coating with optimal material ratio and spraying process, which had better performance in reducing the temperature rise and thermal deformation. A schematic representation of the study is shown in graphical abstract.

2 Methodology

In this study, a positioning accuracy improvement method was proposed by reducing the temperature rise of ball screws. The nano coating was optimized to enhance the thermal dissipation and applied to reduce the thermal deformation of ball screws.

2.1 Nano coating preparation

The nano coating was developed by modified acrylic silicone resin, graphene, and nano silver powder. The properties of all the materials are shown in Table 1. Considering the excellent thermal conductivity of graphene [41] and the nano silver powder, both of them were selected as the variable to prepare the nano coating. Modified acrylic silicone resin was considered as the matrix. As the active ingredients of nano coating, graphene and nano silver powder were dissolved in the silicone resin. Preparation process is shown in Figure 1. Physical dispersion and chemical modification are the main ways to improve the dispersion of nanomaterials. Ultrasonic dispersion has been regarded as a feasible method to improve the dispersion of graphene oxide [42]. Consequently, ultrasonic dispersion and high-speed stirring were selected to dissolve the graphene and nano silver powder in the silicone resin.

Table 1

Parameters of experimental materials

Materials Description
Graphene GDF, 11–15 nm, Jingdun, Shanghai, China
Nano silver powder 300 nm, Yinke, Xingtai, China
Modified acrylic silicone resin RB-237, Xiyanuo, Wuxi, China
Figure 1 Preparation process of nano coating.
Figure 1

Preparation process of nano coating.

The weighed graphene was added into the beaker after pouring the silicone resin. The mixture was oscillated for 20 min, and the oscillation frequency was set to 40 kHz. After the two were fully mixed uniformly, the nano silver powder was added. The silicone resin, graphene, and nano silver powder were mixed by stirring, and the rotational speed of stirring was maintained at 1,000 rpm for 2 min. An electric spray gun was prepared to spray the graphene nano coating on the surface of the ball screw. During the spraying process, the distance between the nozzle and surface of the ball screw was maintained, and the nozzle pressure was set in advance. After the coating was coated on the whole surface of the ball screw, it was dried for 24 h at ambient temperature. Experiments can be carried out when the coating solidifies and adheres to the surface of the ball screw. During the experiment, the coating on the raceway was destroyed and the rest remained to enhance the heat dissipation. The properties of the instruments are shown in Table 2.

Table 2

Parameters of experimental instruments

Instruments Product description
High-speed stirrer SN-OES-60SH, Lichen, Shanghai, China
High-frequency oscillator DR-MS30, Derui, Shenzhen, China
Electronic scale CX-12000, Yesheng, Shenzhen, China
Electric spray gun Pulijie, Hubei, China

2.2 Thermal characteristics of graphene-coated ball screws

Due to the excellent thermal property of graphene and silver powder, the heat dissipation can be enhanced thereby reducing the temperature rise. Therefore, the thermal performance of the ball screw was improved. The cooling mechanism is shown in Figure 2, where Q N is the heat generation rate of the nut, Q C is the convective heat transfer, and Q R is the radiative heat transfer. The nano coating was beneficial in temperature reduction of the ball screw by enhancing radiation heat dissipation, and thermal deformation can be effectively reduced. The coated ball screw has the advantage of adaptability to thermal deformation without complicated control and calculation.

Figure 2 Cooling mechanism. (a) Uncoated ball screw and (b) coated ball screw.
Figure 2

Cooling mechanism. (a) Uncoated ball screw and (b) coated ball screw.

SEM observation was employed to obtain the state representation and graphene distribution of the nano coating. The samples with good interface conditions after cutting and polishing were selected to prepare for the SEM images shown in Figure 3. From the SEM images, it is indicted that graphene presented a relatively even distribution. The advantages of graphene and nano silver powder with high thermal conduction were adopted to realize the high efficiency transmission of heat flow. Due to the thermal channels formed by graphene depicted in Figure 3(b), the heat generated during operation can be transferred to the environment more effectively resulting in the reduction in temperature and thermal deformation of the ball screw.

Figure 3 SEM images of the nano coating. (a) State representation and (b) thermal channel formed by grapheme.
Figure 3

SEM images of the nano coating. (a) State representation and (b) thermal channel formed by grapheme.

2.3 Experimental procedure

To validate the effectiveness of this method and obtain the optimal material ratio and spraying process, the orthogonal experiment was designed and carried out on our self-design test bench (Table 3), which allowed for collecting both the data of temperature and thermal deformation continuously and synchronously. The experimental setup is illustrated in Figure 4. The prepared ball screw with nano coating was driven at a speed of 1,000 rpm. Simultaneously, the temperature of the fixed bearing, supported bearing, ambient, and nut were collected using temperature sensors. Thermal deformation of the ball screw in axial direction was measured using the eddy current displacement sensor. The properties of the instruments are shown in Table 4.

Table 3

Parameters of ball screws in test bench

Parameters Value
Nominal diameter (d 0) 16.8 mm
Lead (l) 10 mm
Material GCr15
Figure 4 Experimental setup. (a) High speed and precision ball screw test bench, (b) temperature sensor mounted on nut, and (c) temperature sensor mounted on bearing, (d) temperature and thermal deformation test, and (e) data acquisition system.
Figure 4

Experimental setup. (a) High speed and precision ball screw test bench, (b) temperature sensor mounted on nut, and (c) temperature sensor mounted on bearing, (d) temperature and thermal deformation test, and (e) data acquisition system.

Table 4

Experimental instrument properties

Type Product description Accuracy
Temperature sensors KYW-TC, Kunlunyuanyang, Beijing, China ±0.05°C
Temperature inspection instrument Kunlunyuanyang, Beijing, China ±0.05% F.S
Eddy current displacement sensor ML33-01-00-03, Milang, Shenzhen, China 0.05 μm
Displacement inspection instrument XSAE-CHVB1M2V0, Milang, Shenzhen, China ±0.05% F.S

Experiments on the ball screw with different coatings were carried out at the same working condition, and the ambient temperature was selected as the initial temperature. Based on the data acquisition system of LABVIEW, both the real-time temperature and thermal deformation were collected on a computer by the data acquisition card and serial port. Between each experiment, one day was needed to dry the coatings and cool the ball screw.

2.4 Orthogonal design

To study the influence of material ratio and nozzle flow of nano coating on the ball screw temperature rise and thermal deformation, orthogonal experiment was designed. In this article, the nozzle flow p z, the quality of graphene m s, and nano silver powder c g were selected as the key design parameters of the nano coating. Thus, the orthogonal table L 9(34) with three factors and three levels was employed to generate the samples, as shown in Table 5. The quality of silicone resin and nano silver powder was regarded as the total mass of nano coating, and graphene was considered as an additional additive.

Table 5

Parameters design of material preparation and spraying process

No. c g (%) m s (g) p z (mL/min)
P1 20 0.1 1,500
P2 20 0.2 1,125
P3 20 0.3 1,200
P4 15 0.1 1,200
P5 15 0.2 1,500
P6 15 0.3 1,125
P7 10 0.1 1,125
P8 10 0.2 1,200
P9 10 0.3 1,500

According to the orthogonal design, nine experiments were carried out on the ball screw with different nano coatings. Additionally, the experiment on the ball screw without nano coating was also conducted in the same working condition as a comparison.

2.5 Characterization of coating thickness

The performance of nano graphene coating can be influenced by spraying process. Thus, the relationship between coating thickness and nozzle flow was considered to study the effect of spraying process on the heat transfer and heat dissipation performance of the nano coating. According to the orthogonal table in Section 2.4, three types of nozzle flow including 1,500, 1,200, and 1,125 mL/min were set to characterize the thickness of coating. Three stainless steel surfaces (100 mm × 100 mm) were prepared and sprayed using the three types of nozzle flow. During the spraying process, the same spraying condition was used in thickness characterization. The samples with nano coating were dried in the ambient environment, as shown in Figure 5.

Figure 5 Coated samples.
Figure 5

Coated samples.

To obtain the accurate thickness of each sample, the thickness of eight points were measured by micrometer (SH2005A5946, Weidu, Leqing, China). The average of eight measurement points was regarded as the thickness of this sample. The measurement points are illustrated in Figure 6.

Figure 6 Position of measuring points.
Figure 6

Position of measuring points.

3 Results and discussion

3.1 Experimental results

The results of the samples thickness under different nozzle flows are shown in Tables 6 and 7 according to the method proposed in Section 2.5. The result indicated that the increase in the samples thickness is correlated with the increase in the nozzle flow. In this article, the coating thickness of the samples can be approximated as the one on the ball screw.

Table 6

Thickness measurement results of samples

Nozzle flow (mL/min) Thickness of measuring points (μm)
A1 A2 A3 A4 A5 A6 A7 A8 Mean
Uncoated 1,500 928 926 927 930 936 936 931 927 930
1,200 932 937 933 928 928 928 927 932 931
1,125 932 932 926 927 933 927 936 935 931
Coated 1,500 1,109 1,080 1,111 1,118 1,115 1,062 1,095 1,108 1,100
1,200 1,071 1,050 1,104 1,089 1,072 1,088 1,125 1,114 1,089
1,125 1,060 1,066 1,065 1,110 1,093 1,077 1,095 1,088 1,082
Table 7

Thickness of coatings

Nozzle flow (mL/min) Average thickness (μm)
1,500 169.63
1,200 158.50
1,125 150.75

In Section 2.4, orthogonal experiment was designed to obtain the material ratio and spraying process of nano coating with optimal thermal performance. After collecting the temperature and thermal deformation, the comparative experimental results of nine types of graphene-coated ball screws (P1–P9) and standard one (O1) are drawn in Figure 7. The obvious oscillation occurred when the axial thermal deformation was collected, that is because the ball screw test bench is affected by vibration during operation. To obtain the thermal deformation clearly, the low pass filtering was adopted.

Figure 7 Experimental results of temperature and thermal deformation: (a) O1, (b) P1, (c) P2, (d) P3, (e) P4, (f) P5, (g) P6, (h) P7, (i) P8, and (j) P9.
Figure 7 Experimental results of temperature and thermal deformation: (a) O1, (b) P1, (c) P2, (d) P3, (e) P4, (f) P5, (g) P6, (h) P7, (i) P8, and (j) P9.
Figure 7 Experimental results of temperature and thermal deformation: (a) O1, (b) P1, (c) P2, (d) P3, (e) P4, (f) P5, (g) P6, (h) P7, (i) P8, and (j) P9.
Figure 7

Experimental results of temperature and thermal deformation: (a) O1, (b) P1, (c) P2, (d) P3, (e) P4, (f) P5, (g) P6, (h) P7, (i) P8, and (j) P9.

From the results of the orthogonal experiment, it was concluded that nano coating had a positive effect on reducing the temperature rise and thermal deformation of the ball screw. Moreover, different thermal properties were developed by nano coating with different material ratios and spraying processes. The maximum temperature rise (T m), maximum thermal deformation (Δu), and thermal balance time (t d) were selected as the criteria for evaluating the thermal performance. The results of each experiment are summarized in Table 8.

Table 8

Experimental results of thermal performances

No. T m (°C) Δu (μm) t d (min)
O1 30.95 70.3 48.3
P1 29.69 59 37.5
P2 29.42 49.4 42.0
P3 29.31 37.1 35.1
P4 28.41 32.9 47.6
P5 27.99 33.9 37.8
P6 28.46 41.2 45.8
P7 28.13 32.5 36.1
P8 27.09 21.7 26.0
P9 31.93 38 45.7

The thermal deformation of the ball screw with different nano coatings and the standard one are summarized in Figure 8. The minimal thermal deformation was found in the ball screw which was coated with P8 nano coating (Table 9). Therefore, it can be concluded that the P8 nano coating has the most excellent thermal performance. The maximum temperature rise, thermal deformation, and time to reach thermal balance of the ball screw with P8 coating decreased by 12.5, 69.1, and 46.3%, respectively.

Figure 8 Comparative results of thermal deformation.
Figure 8

Comparative results of thermal deformation.

Table 9

Optimized design parameters of nano coating

Parameters m s (g) c g (%) p z (mL/min)
Value 0.2 10 1,200

3.2 Range analysis

In order to evaluate the influence of design parameters of nano coating on reducing the thermal deformation, the range analysis on thermal performance was conducted. The range value can indicate the sensitivity of the factors to the experimental results. A larger range value suggests that it has a greater impact on the experimental results. The results of the range analysis are shown in Figure 9 and Table 10.

Figure 9 Influence of material ratio and spraying process on thermal deformation.
Figure 9

Influence of material ratio and spraying process on thermal deformation.

Table 10

Range analysis on thermal deformation

Level c g (%) m s (g) p z (mL/min)
1st 48.5 41.5 43.6
2nd 36.0 35.0 30.6
3rd 30.7 38.8 41.0
Range 17.8 6.5 13.0

Based on the analysis results, it was concluded that the thermal performance of the nano coating was influenced by the combination of three factors, and the proportion of nano silver powder had main effect on improvement of thermal performance. Thus, better thermal performance of nano coating can be ensured to improve positioning accuracy of the ball screw by using optimized material ratio and spraying process.

4 Conclusion

In this study, an optimization method of nano coating was conducted to improve its thermal performance. The nano coating used is composed of modified acrylic silicone resin, graphene, and nano silver powder. Due to the high thermal conductivity of graphene, the thermal channels can be formed by graphene which can diffuse the heat into the surrounding environment. Thus, material ratio (graphene and nano silver powder) and nozzle flow were considered as the factors which can influence the thermal performance of nano coating on the ball screw. The optimized nano coating formed by optimal material ratio and spraying flow was obtained by orthogonal experiment. The experimental data showed that the maximum temperature rise, thermal deformation and time to reach thermal balance of the ball screw with optimized coating decreased by 12.5, 69.1, and 46.3%, respectively, which proved that the optimized nano coating has promising thermal performance. In the future, the spraying process will be investigated to ensure that the coating is evenly coated on the ball screw surface aiming to further improve the thermal performance of the coating.

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Acknowledgements

The authors would like to thank Mr Dzonu Ambrose Hanson for his kind proofreading.

  1. Funding information: This study was supported by the National Natural Science Foundation of China (Grant Numbers: 51875008, 51505012, and 51575014), Royal Society via an International Exchange Programme (Grant Number: IEC\NSFC\191253), and the International Research Cooperation Seed Fund of Beijing University of Technology (Grant Number: 2021A10).

  2. Author contributions: Xiangsheng Gao conceived the experiment, and wrote the manuscript as well. Kuan Zhang conducted the experiment. Tao Zan, Peng Gao, and Chaozong Liu conducted the data analysis and the English editing. Min Wang supervised this work and revised the manuscript. All authors have accepted responsibility for the entire content of this manuscript and approved its submission.

  3. Conflict of interest: The authors state no conflict of interest.

  4. Data availability statement: All data generated or analyzed during this study are included in this published article.

References

[1] Bryan J. International status of thermal error research. CIRP Ann Manuf Technol. 1990;39:645–56.10.1016/S0007-8506(07)63001-7Suche in Google Scholar

[2] Liu D, Lin P, Lin J, Wang C, Shiau T. Effect of environmental temperature on dynamic behavior of an adjustable preload double-nut ball screw. Int J Adv Manuf Technol. 2019;101(9–12):2761–70.10.1007/s00170-018-2966-xSuche in Google Scholar

[3] Li Y, Su D, Cai X, Wu W, Zhang J, Zhao W. Temperature simulation and thermal equilibrium analysis of the ball screw feed drive system under various working conditions. Proc Inst Mech Eng C-J Eng Mech Eng Sci. 2020;234(24):4844–56.10.1177/0954406220929051Suche in Google Scholar

[4] Xie H, Fang H, Cai W, Wan L, Huo R, Hui D. Development of an innovative composite sandwich matting with GFRP facesheets and wood core. Rev Adv Mater Sci. 2021;60(1):80–91.10.1515/rams-2021-0016Suche in Google Scholar

[5] Li Z, Zhao C, Lu Z. Thermal error modeling method for ball screw feed system of CNC machine tools in x-axis. Int J Adv Manuf Technol. 2020;106(11–12):5383–92.10.1007/s00170-020-05047-wSuche in Google Scholar

[6] Li T, Zhao C, Zhang Y. Prediction method of thermal errors of the screw system in lathes based on moving thermal network. Precis Eng. 2019;59:166–73.10.1016/j.precisioneng.2019.07.001Suche in Google Scholar

[7] Chen Y, Chen J, Xu G. Screw thermal characteristic analysis and error prediction considering the two-dimensional heat transfer structure. Int J Adv Manuf Technol. 2021;115(7–8):2433–48.10.1007/s00170-021-07087-2Suche in Google Scholar

[8] Gao X, Guo Y, Hanson D, Liu Z, Wang M, Zan T. Thermal error prediction of ball screws based on PSO-LSTM. Int J Adv Manuf Technol. 2021;116(5–6):1721–35.10.1007/s00170-021-07560-ySuche in Google Scholar

[9] Yang H, Xing R, Du F. Thermal error modelling for a high-precision feed system in varying conditions based on an improved Elman network. Int J Adv Manuf Technol. 2020;106(1–5):279–88.10.1007/s00170-019-04605-1Suche in Google Scholar

[10] Li T, Liu K. Dynamic model on thermally induced characteristics of ball screw systems. Int J Adv Manuf Technol. 2019;103(9–12):3703–15.10.1007/s00170-019-03760-9Suche in Google Scholar

[11] Zapłata J, Pajor M. Piecewise compensation of thermal errors of a ball screw driven CNC axis. Precis Eng-J Int Soc Precis Eng Nanotechnol. 2019;60:160–6.10.1016/j.precisioneng.2019.07.011Suche in Google Scholar

[12] Li T, Zhao C, Zhang Y. Adaptive on-line compensation model on positioning error of ball screw feed drive systems used in computerized numerical controlled machine tools. Proc Inst Mech Eng B J Eng Manuf. 2019;233(3):914–26.10.1177/0954405417752512Suche in Google Scholar

[13] Liu J, Ma C, Wang S. Data-driven thermally-induced error compensation method of high-speed and precision five-axis machine tools. Mech Syst Signal Process. 2020;138:106538.10.1016/j.ymssp.2019.106538Suche in Google Scholar

[14] Ju X, Lu J, Jin H. Study on heat transfer characteristics and thermal error suppression method of cylindrical giant magnetostrictive actuator for ball screw preload. Proc Inst Mech Eng B-J Eng Manuf. 2021;235(5):782–94.10.1177/0954405420972960Suche in Google Scholar

[15] Shi H, He B, Yue Y, Min C, Mei X. Cooling effect and temperature regulation of oil cooling system for ball screw feed drive system of precision machine tool. Appl Therm Eng. 2019;161:114150.10.1016/j.applthermaleng.2019.114150Suche in Google Scholar

[16] Voigt I, Navarro de Sosa I, Wermke B, Bucht A, Drossel W. Increased thermal inertia of ball screws by using phase change materials. Appl Therm Eng. 2019;155:297–304.10.1016/j.applthermaleng.2019.03.079Suche in Google Scholar

[17] Gao X, Qin Z, Guo Y, Wang M, Zan T. Adaptive method to reduce thermal deformation of ball screws based on carbon fiber reinforced plastics. Materials. 2019;12(19):3113.10.3390/ma12193113Suche in Google Scholar PubMed PubMed Central

[18] Gao X, Guo Y, Wang M, Zan T. Further study on thermal deformation reduction for CFRP-based improved ball screws. Adv Compos Lett. 2020;29:2633366X20917981.10.1177/2633366X20917981Suche in Google Scholar

[19] Gao X, Zhang K, Wang M, Zan T, Luo J. Thermally stimulated artificial muscles: Bio – inspired approach to reduce thermal deformation of ball screws based on inner – embedded CFRP. Rev Adv Mater Sci. 2021;60(1):541–52.10.1515/rams-2021-0047Suche in Google Scholar

[20] Japar W, Sidik N, Saidur R, Asako Y, Yusof S. A review of passive methods in microchannel heat sink application through advanced geometric structure and nano fluids: current advancements and challenges. Nanotechnol Rev. 2020;9(1):1192–216.10.1515/ntrev-2020-0094Suche in Google Scholar

[21] Bhat A, Budholiya S, Raj S, Sultan M, Hui D, Shah A, et al. Review on nanocomposites based on aerospace applications. Nanotechnol Rev. 2021;10(1):237–53.10.1515/ntrev-2021-0018Suche in Google Scholar

[22] Zheng L, Xiong T, Shah K. Transparent nanomaterial-based solar cool coatings: synthesis, morphologies and applications. Sol Energy. 2019;193:837–58.10.1016/j.solener.2019.10.029Suche in Google Scholar

[23] Chen M, Li W, Tao S, Fang Z, Lu C, Xu Z. A pragmatic and high-performance radiative cooling coating with near-ideal selective emissive spectrum for passive cooling. Coatings. 2020;10(2):144.10.3390/coatings10020144Suche in Google Scholar

[24] Cheng Z, Shuai Y, Gong D, Wang F, Liang H, Li G. Optical properties and cooling performance analyses of single-layer radiative cooling coating with mixture of TiO2 particles and SiO2 particles. Sci China-Technol Sci. 2021;64(5):1017–29.10.1007/s11431-020-1586-9Suche in Google Scholar

[25] Niazi S, Sadaghiani A, Gharib G, Kaya V, Celik S, Kutlu O, et al. Bio-coated surfaces with micro-roughness and micro-porosity: next generation coatings for enhanced energy efficiency. Energy. 2021;222:119959.10.1016/j.energy.2021.119959Suche in Google Scholar

[26] Sivanathan A, Dou Q, Wang Y, Li Y, Corker J, Zhou Y, et al. Phase change materials for building construction: an overview of nano-/micro-encapsulation. Nanotechnol Rev. 2020;9(2):896–921.10.1515/ntrev-2020-0067Suche in Google Scholar

[27] Zhang Y, Zhu Y, Yang J, Zhai X. Energy saving performance of thermochromic coatings with different colors for buildings. Energy Build. 2020;215:109920.10.1016/j.enbuild.2020.109920Suche in Google Scholar

[28] Yi Y, Jiang Y, Li Q, Deng C, Ji X, Xue J. Development of super road heat-reflective coating and its field application. Coatings. 2019;9(12):802.10.3390/coatings9120802Suche in Google Scholar

[29] Wang C, Sun X, Guo T, Gao Z, Wang X. Investigations on cooling effects of prepared pavement coatings using the Grubbs method and linear regression analysis. Road Mater Pavement Des. 2019;20(1):171–86.10.1080/14680629.2017.1380072Suche in Google Scholar

[30] Chen Y, Hu K, Cao S. Thermal performance of novel multilayer cool for asphalt pavements. Materials. 2019;12(12):1903.10.3390/ma12121903Suche in Google Scholar PubMed PubMed Central

[31] Tarawneh M, Saraireh S, Chen R, Ahmad S, Al-Tarawni M, Yu L, et al. Mechanical reinforcement with enhanced electrical and heat conduction of epoxy resin by polyaniline and graphene nanoplatelets. Nanotechnol Rev. 2020;9(1):1550–61.10.1515/ntrev-2020-0118Suche in Google Scholar

[32] Chen L, Shen Y, Yi H, Liu Z, Song Q. Mathematical modeling of heat transfer in GO-doped reinforce polymer for anti-/deicing of wind turbines. Int Commun Heat Mass Transf. 2021;123:105235.10.1016/j.icheatmasstransfer.2021.105235Suche in Google Scholar

[33] Chen M, Pang D, Chen X, Yan H. Enhancing infrared emission behavior of polymer coatings for radiative cooling applications. J Phys D-Appl Phys. 2021;54(29):295501.10.1088/1361-6463/abfb19Suche in Google Scholar

[34] Du M, Jing H, Gao Y, Su H, Fang H. Carbon nanomaterials enhanced cement-based composites: advances and challenges. Nanotechnol Rev. 2020;9(1):115–35.10.1515/ntrev-2020-0011Suche in Google Scholar

[35] Cheng Z, Wang F, Wang H, Liang H, Ma L. Effect of embedded polydisperse glass microspheres on radiative cooling of a coating. Int J Therm Sci. 2019;140:358–67.10.1016/j.ijthermalsci.2019.03.014Suche in Google Scholar

[36] Kolas T, Royset A, Grandcolas M, ten Cate M, Lacau A. Cool coatings with high near infrared transmittance for coil coated aluminium. Sol Energy Mater Sol Cell. 2019;196:94–104.10.1016/j.solmat.2019.03.021Suche in Google Scholar

[37] Zhang H, Fan D. Improving heat dissipation and temperature uniformity in radiative cooling coating. Energy Technol. 2020;8(5):1901362.10.1002/ente.201901362Suche in Google Scholar

[38] Kang H, Qiao Y, Li Y, Qin W, Wu X. Keep cool: polyhedral ZnO@ZIF-8 polymer coatings for daytime radiative cooling. Ind Eng Chem Res. 2020;59(34):15226–32.10.1021/acs.iecr.0c01178Suche in Google Scholar

[39] Chen G, Wang Y, Qiu J, Cao J, Zou Y, Wang S, et al. Robust inorganic daytime radiative cooling coating based on a phosphate geopolymer. ACS Appl Mater Interfaces. 2020;12(49):54963–71.10.1021/acsami.0c15799Suche in Google Scholar PubMed

[40] Guo Y, Gao X, Wang M, Zan T. Bio-inspired graphene-coated ball screws: novel approach to reduce the thermal deformation of ball screws. Proc Inst Mech Eng C J Mech Eng Sci. 2021;235(5):789–99.10.1177/0954406220939997Suche in Google Scholar

[41] Behdinan K, Moradi-dastjerdi R, Safaei B, Qin Z, Chu F, Hui D. Graphene and CNT impact on heat transfer response of nanocomposite cylinders. Nanotechnol Rev. 2020;9(1):41–52.10.1515/ntrev-2020-0004Suche in Google Scholar

[42] Liu C, Huang X, Wu Y, Deng X, Zheng Z, Xu Z, et al. Advance on the dispersion treatment of graphene oxide and the graphene oxide modified cement-based materials. Nanotechnol Rev. 2021;10(1):34–49.10.1515/ntrev-2021-0003Suche in Google Scholar
Received: 2021-11-01
Revised: 2021-12-20
Accepted: 2022-12-27
Published Online: 2022-01-11

© 2022 Xiangsheng Gao et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

Artikel in diesem Heft

  1. Research Articles
  2. Theoretical and experimental investigation of MWCNT dispersion effect on the elastic modulus of flexible PDMS/MWCNT nanocomposites
  3. Mechanical, morphological, and fracture-deformation behavior of MWCNTs-reinforced (Al–Cu–Mg–T351) alloy cast nanocomposites fabricated by optimized mechanical milling and powder metallurgy techniques
  4. Flammability and physical stability of sugar palm crystalline nanocellulose reinforced thermoplastic sugar palm starch/poly(lactic acid) blend bionanocomposites
  5. Glutathione-loaded non-ionic surfactant niosomes: A new approach to improve oral bioavailability and hepatoprotective efficacy of glutathione
  6. Relationship between mechano-bactericidal activity and nanoblades density on chemically strengthened glass
  7. In situ regulation of microstructure and microwave-absorbing properties of FeSiAl through HNO3 oxidation
  8. Research on a mechanical model of magnetorheological fluid different diameter particles
  9. Nanomechanical and dynamic mechanical properties of rubber–wood–plastic composites
  10. Investigative properties of CeO2 doped with niobium: A combined characterization and DFT studies
  11. Miniaturized peptidomimetics and nano-vesiculation in endothelin types through probable nano-disk formation and structure property relationships of endothelins’ fragments
  12. N/S co-doped CoSe/C nanocubes as anode materials for Li-ion batteries
  13. Synergistic effects of halloysite nanotubes with metal and phosphorus additives on the optimal design of eco-friendly sandwich panels with maximum flame resistance and minimum weight
  14. Octreotide-conjugated silver nanoparticles for active targeting of somatostatin receptors and their application in a nebulized rat model
  15. Controllable morphology of Bi2S3 nanostructures formed via hydrothermal vulcanization of Bi2O3 thin-film layer and their photoelectrocatalytic performances
  16. Development of (−)-epigallocatechin-3-gallate-loaded folate receptor-targeted nanoparticles for prostate cancer treatment
  17. Enhancement of the mechanical properties of HDPE mineral nanocomposites by filler particles modulation of the matrix plastic/elastic behavior
  18. Effect of plasticizers on the properties of sugar palm nanocellulose/cinnamon essential oil reinforced starch bionanocomposite films
  19. Optimization of nano coating to reduce the thermal deformation of ball screws
  20. Preparation of efficient piezoelectric PVDF–HFP/Ni composite films by high electric field poling
  21. MHD dissipative Casson nanofluid liquid film flow due to an unsteady stretching sheet with radiation influence and slip velocity phenomenon
  22. Effects of nano-SiO2 modification on rubberised mortar and concrete with recycled coarse aggregates
  23. Mechanical and microscopic properties of fiber-reinforced coal gangue-based geopolymer concrete
  24. Effect of morphology and size on the thermodynamic stability of cerium oxide nanoparticles: Experiment and molecular dynamics calculation
  25. Mechanical performance of a CFRP composite reinforced via gelatin-CNTs: A study on fiber interfacial enhancement and matrix enhancement
  26. A practical review over surface modification, nanopatterns, emerging materials, drug delivery systems, and their biophysiochemical properties for dental implants: Recent progresses and advances
  27. HTR: An ultra-high speed algorithm for cage recognition of clathrate hydrates
  28. Effects of microalloying elements added by in situ synthesis on the microstructure of WCu composites
  29. A highly sensitive nanobiosensor based on aptamer-conjugated graphene-decorated rhodium nanoparticles for detection of HER2-positive circulating tumor cells
  30. Progressive collapse performance of shear strengthened RC frames by nano CFRP
  31. Core–shell heterostructured composites of carbon nanotubes and imine-linked hyperbranched polymers as metal-free Li-ion anodes
  32. A Galerkin strategy for tri-hybridized mixture in ethylene glycol comprising variable diffusion and thermal conductivity using non-Fourier’s theory
  33. Simple models for tensile modulus of shape memory polymer nanocomposites at ambient temperature
  34. Preparation and morphological studies of tin sulfide nanoparticles and use as efficient photocatalysts for the degradation of rhodamine B and phenol
  35. Polyethyleneimine-impregnated activated carbon nanofiber composited graphene-derived rice husk char for efficient post-combustion CO2 capture
  36. Electrospun nanofibers of Co3O4 nanocrystals encapsulated in cyclized-polyacrylonitrile for lithium storage
  37. Pitting corrosion induced on high-strength high carbon steel wire in high alkaline deaerated chloride electrolyte
  38. Formulation of polymeric nanoparticles loaded sorafenib; evaluation of cytotoxicity, molecular evaluation, and gene expression studies in lung and breast cancer cell lines
  39. Engineered nanocomposites in asphalt binders
  40. Influence of loading voltage, domain ratio, and additional load on the actuation of dielectric elastomer
  41. Thermally induced hex-graphene transitions in 2D carbon crystals
  42. The surface modification effect on the interfacial properties of glass fiber-reinforced epoxy: A molecular dynamics study
  43. Molecular dynamics study of deformation mechanism of interfacial microzone of Cu/Al2Cu/Al composites under tension
  44. Nanocolloid simulators of luminescent solar concentrator photovoltaic windows
  45. Compressive strength and anti-chloride ion penetration assessment of geopolymer mortar merging PVA fiber and nano-SiO2 using RBF–BP composite neural network
  46. Effect of 3-mercapto-1-propane sulfonate sulfonic acid and polyvinylpyrrolidone on the growth of cobalt pillar by electrodeposition
  47. Dynamics of convective slippery constraints on hybrid radiative Sutterby nanofluid flow by Galerkin finite element simulation
  48. Preparation of vanadium by the magnesiothermic self-propagating reduction and process control
  49. Microstructure-dependent photoelectrocatalytic activity of heterogeneous ZnO–ZnS nanosheets
  50. Cytotoxic and pro-inflammatory effects of molybdenum and tungsten disulphide on human bronchial cells
  51. Improving recycled aggregate concrete by compression casting and nano-silica
  52. Chemically reactive Maxwell nanoliquid flow by a stretching surface in the frames of Newtonian heating, nonlinear convection and radiative flux: Nanopolymer flow processing simulation
  53. Nonlinear dynamic and crack behaviors of carbon nanotubes-reinforced composites with various geometries
  54. Biosynthesis of copper oxide nanoparticles and its therapeutic efficacy against colon cancer
  55. Synthesis and characterization of smart stimuli-responsive herbal drug-encapsulated nanoniosome particles for efficient treatment of breast cancer
  56. Homotopic simulation for heat transport phenomenon of the Burgers nanofluids flow over a stretching cylinder with thermal convective and zero mass flux conditions
  57. Incorporation of copper and strontium ions in TiO2 nanotubes via dopamine to enhance hemocompatibility and cytocompatibility
  58. Mechanical, thermal, and barrier properties of starch films incorporated with chitosan nanoparticles
  59. Mechanical properties and microstructure of nano-strengthened recycled aggregate concrete
  60. Glucose-responsive nanogels efficiently maintain the stability and activity of therapeutic enzymes
  61. Tunning matrix rheology and mechanical performance of ultra-high performance concrete using cellulose nanofibers
  62. Flexible MXene/copper/cellulose nanofiber heat spreader films with enhanced thermal conductivity
  63. Promoted charge separation and specific surface area via interlacing of N-doped titanium dioxide nanotubes on carbon nitride nanosheets for photocatalytic degradation of Rhodamine B
  64. Elucidating the role of silicon dioxide and titanium dioxide nanoparticles in mitigating the disease of the eggplant caused by Phomopsis vexans, Ralstonia solanacearum, and root-knot nematode Meloidogyne incognita
  65. An implication of magnetic dipole in Carreau Yasuda liquid influenced by engine oil using ternary hybrid nanomaterial
  66. Robust synthesis of a composite phase of copper vanadium oxide with enhanced performance for durable aqueous Zn-ion batteries
  67. Tunning self-assembled phases of bovine serum albumin via hydrothermal process to synthesize novel functional hydrogel for skin protection against UVB
  68. A comparative experimental study on damping properties of epoxy nanocomposite beams reinforced with carbon nanotubes and graphene nanoplatelets
  69. Lightweight and hydrophobic Ni/GO/PVA composite aerogels for ultrahigh performance electromagnetic interference shielding
  70. Research on the auxetic behavior and mechanical properties of periodically rotating graphene nanostructures
  71. Repairing performances of novel cement mortar modified with graphene oxide and polyacrylate polymer
  72. Closed-loop recycling and fabrication of hydrophilic CNT films with high performance
  73. Design of thin-film configuration of SnO2–Ag2O composites for NO2 gas-sensing applications
  74. Study on stress distribution of SiC/Al composites based on microstructure models with microns and nanoparticles
  75. PVDF green nanofibers as potential carriers for improving self-healing and mechanical properties of carbon fiber/epoxy prepregs
  76. Osteogenesis capability of three-dimensionally printed poly(lactic acid)-halloysite nanotube scaffolds containing strontium ranelate
  77. Silver nanoparticles induce mitochondria-dependent apoptosis and late non-canonical autophagy in HT-29 colon cancer cells
  78. Preparation and bonding mechanisms of polymer/metal hybrid composite by nano molding technology
  79. Damage self-sensing and strain monitoring of glass-reinforced epoxy composite impregnated with graphene nanoplatelet and multiwalled carbon nanotubes
  80. Thermal analysis characterisation of solar-powered ship using Oldroyd hybrid nanofluids in parabolic trough solar collector: An optimal thermal application
  81. Pyrene-functionalized halloysite nanotubes for simultaneously detecting and separating Hg(ii) in aqueous media: A comprehensive comparison on interparticle and intraparticle excimers
  82. Fabrication of self-assembly CNT flexible film and its piezoresistive sensing behaviors
  83. Thermal valuation and entropy inspection of second-grade nanoscale fluid flow over a stretching surface by applying Koo–Kleinstreuer–Li relation
  84. Mechanical properties and microstructure of nano-SiO2 and basalt-fiber-reinforced recycled aggregate concrete
  85. Characterization and tribology performance of polyaniline-coated nanodiamond lubricant additives
  86. Combined impact of Marangoni convection and thermophoretic particle deposition on chemically reactive transport of nanofluid flow over a stretching surface
  87. Spark plasma extrusion of binder free hydroxyapatite powder
  88. An investigation on thermo-mechanical performance of graphene-oxide-reinforced shape memory polymer
  89. Effect of nanoadditives on the novel leather fiber/recycled poly(ethylene-vinyl-acetate) polymer composites for multifunctional applications: Fabrication, characterizations, and multiobjective optimization using central composite design
  90. Design selection for a hemispherical dimple core sandwich panel using hybrid multi-criteria decision-making methods
  91. Improving tensile strength and impact toughness of plasticized poly(lactic acid) biocomposites by incorporating nanofibrillated cellulose
  92. Green synthesis of spinel copper ferrite (CuFe2O4) nanoparticles and their toxicity
  93. The effect of TaC and NbC hybrid and mono-nanoparticles on AA2024 nanocomposites: Microstructure, strengthening, and artificial aging
  94. Excited-state geometry relaxation of pyrene-modified cellulose nanocrystals under UV-light excitation for detecting Fe3+
  95. Effect of CNTs and MEA on the creep of face-slab concrete at an early age
  96. Effect of deformation conditions on compression phase transformation of AZ31
  97. Application of MXene as a new generation of highly conductive coating materials for electromembrane-surrounded solid-phase microextraction
  98. A comparative study of the elasto-plastic properties for ceramic nanocomposites filled by graphene or graphene oxide nanoplates
  99. Encapsulation strategies for improving the biological behavior of CdS@ZIF-8 nanocomposites
  100. Biosynthesis of ZnO NPs from pumpkin seeds’ extract and elucidation of its anticancer potential against breast cancer
  101. Preliminary trials of the gold nanoparticles conjugated chrysin: An assessment of anti-oxidant, anti-microbial, and in vitro cytotoxic activities of a nanoformulated flavonoid
  102. Effect of micron-scale pores increased by nano-SiO2 sol modification on the strength of cement mortar
  103. Fractional simulations for thermal flow of hybrid nanofluid with aluminum oxide and titanium oxide nanoparticles with water and blood base fluids
  104. The effect of graphene nano-powder on the viscosity of water: An experimental study and artificial neural network modeling
  105. Development of a novel heat- and shear-resistant nano-silica gelling agent
  106. Characterization, biocompatibility and in vivo of nominal MnO2-containing wollastonite glass-ceramic
  107. Entropy production simulation of second-grade magnetic nanomaterials flowing across an expanding surface with viscidness dissipative flux
  108. Enhancement in structural, morphological, and optical properties of copper oxide for optoelectronic device applications
  109. Aptamer-functionalized chitosan-coated gold nanoparticle complex as a suitable targeted drug carrier for improved breast cancer treatment
  110. Performance and overall evaluation of nano-alumina-modified asphalt mixture
  111. Analysis of pure nanofluid (GO/engine oil) and hybrid nanofluid (GO–Fe3O4/engine oil): Novel thermal and magnetic features
  112. Synthesis of Ag@AgCl modified anatase/rutile/brookite mixed phase TiO2 and their photocatalytic property
  113. Mechanisms and influential variables on the abrasion resistance hydraulic concrete
  114. Synergistic reinforcement mechanism of basalt fiber/cellulose nanocrystals/polypropylene composites
  115. Achieving excellent oxidation resistance and mechanical properties of TiB2–B4C/carbon aerogel composites by quick-gelation and mechanical mixing
  116. Microwave-assisted sol–gel template-free synthesis and characterization of silica nanoparticles obtained from South African coal fly ash
  117. Pulsed laser-assisted synthesis of nano nickel(ii) oxide-anchored graphitic carbon nitride: Characterizations and their potential antibacterial/anti-biofilm applications
  118. Effects of nano-ZrSi2 on thermal stability of phenolic resin and thermal reusability of quartz–phenolic composites
  119. Benzaldehyde derivatives on tin electroplating as corrosion resistance for fabricating copper circuit
  120. Mechanical and heat transfer properties of 4D-printed shape memory graphene oxide/epoxy acrylate composites
  121. Coupling the vanadium-induced amorphous/crystalline NiFe2O4 with phosphide heterojunction toward active oxygen evolution reaction catalysts
  122. Graphene-oxide-reinforced cement composites mechanical and microstructural characteristics at elevated temperatures
  123. Gray correlation analysis of factors influencing compressive strength and durability of nano-SiO2 and PVA fiber reinforced geopolymer mortar
  124. Preparation of layered gradient Cu–Cr–Ti alloy with excellent mechanical properties, thermal stability, and electrical conductivity
  125. Recovery of Cr from chrome-containing leather wastes to develop aluminum-based composite material along with Al2O3 ceramic particles: An ingenious approach
  126. Mechanisms of the improved stiffness of flexible polymers under impact loading
  127. Anticancer potential of gold nanoparticles (AuNPs) using a battery of in vitro tests
  128. Review Articles
  129. Proposed approaches for coronaviruses elimination from wastewater: Membrane techniques and nanotechnology solutions
  130. Application of Pickering emulsion in oil drilling and production
  131. The contribution of microfluidics to the fight against tuberculosis
  132. Graphene-based biosensors for disease theranostics: Development, applications, and recent advancements
  133. Synthesis and encapsulation of iron oxide nanorods for application in magnetic hyperthermia and photothermal therapy
  134. Contemporary nano-architectured drugs and leads for ανβ3 integrin-based chemotherapy: Rationale and retrospect
  135. State-of-the-art review of fabrication, application, and mechanical properties of functionally graded porous nanocomposite materials
  136. Insights on magnetic spinel ferrites for targeted drug delivery and hyperthermia applications
  137. A review on heterogeneous oxidation of acetaminophen based on micro and nanoparticles catalyzed by different activators
  138. Early diagnosis of lung cancer using magnetic nanoparticles-integrated systems
  139. Advances in ZnO: Manipulation of defects for enhancing their technological potentials
  140. Efficacious nanomedicine track toward combating COVID-19
  141. A review of the design, processes, and properties of Mg-based composites
  142. Green synthesis of nanoparticles for varied applications: Green renewable resources and energy-efficient synthetic routes
  143. Two-dimensional nanomaterial-based polymer composites: Fundamentals and applications
  144. Recent progress and challenges in plasmonic nanomaterials
  145. Apoptotic cell-derived micro/nanosized extracellular vesicles in tissue regeneration
  146. Electronic noses based on metal oxide nanowires: A review
  147. Framework materials for supercapacitors
  148. An overview on the reproductive toxicity of graphene derivatives: Highlighting the importance
  149. Antibacterial nanomaterials: Upcoming hope to overcome antibiotic resistance crisis
  150. Research progress of carbon materials in the field of three-dimensional printing polymer nanocomposites
  151. A review of atomic layer deposition modelling and simulation methodologies: Density functional theory and molecular dynamics
  152. Recent advances in the preparation of PVDF-based piezoelectric materials
  153. Recent developments in tensile properties of friction welding of carbon fiber-reinforced composite: A review
  154. Comprehensive review of the properties of fly ash-based geopolymer with additive of nano-SiO2
  155. Perspectives in biopolymer/graphene-based composite application: Advances, challenges, and recommendations
  156. Graphene-based nanocomposite using new modeling molecular dynamic simulations for proposed neutralizing mechanism and real-time sensing of COVID-19
  157. Nanotechnology application on bamboo materials: A review
  158. Recent developments and future perspectives of biorenewable nanocomposites for advanced applications
  159. Nanostructured lipid carrier system: A compendium of their formulation development approaches, optimization strategies by quality by design, and recent applications in drug delivery
  160. 3D printing customized design of human bone tissue implant and its application
  161. Design, preparation, and functionalization of nanobiomaterials for enhanced efficacy in current and future biomedical applications
  162. A brief review of nanoparticles-doped PEDOT:PSS nanocomposite for OLED and OPV
  163. Nanotechnology interventions as a putative tool for the treatment of dental afflictions
  164. Recent advancements in metal–organic frameworks integrating quantum dots (QDs@MOF) and their potential applications
  165. A focused review of short electrospun nanofiber preparation techniques for composite reinforcement
  166. Microstructural characteristics and nano-modification of interfacial transition zone in concrete: A review
  167. Latest developments in the upconversion nanotechnology for the rapid detection of food safety: A review
  168. Strategic applications of nano-fertilizers for sustainable agriculture: Benefits and bottlenecks
  169. Molecular dynamics application of cocrystal energetic materials: A review
  170. Synthesis and application of nanometer hydroxyapatite in biomedicine
  171. Cutting-edge development in waste-recycled nanomaterials for energy storage and conversion applications
  172. Biological applications of ternary quantum dots: A review
  173. Nanotherapeutics for hydrogen sulfide-involved treatment: An emerging approach for cancer therapy
  174. Application of antibacterial nanoparticles in orthodontic materials
  175. Effect of natural-based biological hydrogels combined with growth factors on skin wound healing
  176. Nanozymes – A route to overcome microbial resistance: A viewpoint
  177. Recent developments and applications of smart nanoparticles in biomedicine
  178. Contemporary review on carbon nanotube (CNT) composites and their impact on multifarious applications
  179. Interfacial interactions and reinforcing mechanisms of cellulose and chitin nanomaterials and starch derivatives for cement and concrete strength and durability enhancement: A review
  180. Diamond-like carbon films for tribological modification of rubber
  181. Layered double hydroxides (LDHs) modified cement-based materials: A systematic review
  182. Recent research progress and advanced applications of silica/polymer nanocomposites
  183. Modeling of supramolecular biopolymers: Leading the in silico revolution of tissue engineering and nanomedicine
  184. Recent advances in perovskites-based optoelectronics
  185. Biogenic synthesis of palladium nanoparticles: New production methods and applications
  186. A comprehensive review of nanofluids with fractional derivatives: Modeling and application
  187. Electrospinning of marine polysaccharides: Processing and chemical aspects, challenges, and future prospects
  188. Electrohydrodynamic printing for demanding devices: A review of processing and applications
  189. Rapid Communications
  190. Structural material with designed thermal twist for a simple actuation
  191. Recent advances in photothermal materials for solar-driven crude oil adsorption
https://doi.org/10.1515/ntrev-2022-0029
Schlagwörter für diesen Artikel
ball screw; nano coating; thermal deformation; graphene
Creative Commons
BY 4.0

Artikel in diesem Heft

  1. Research Articles
  2. Theoretical and experimental investigation of MWCNT dispersion effect on the elastic modulus of flexible PDMS/MWCNT nanocomposites
  3. Mechanical, morphological, and fracture-deformation behavior of MWCNTs-reinforced (Al–Cu–Mg–T351) alloy cast nanocomposites fabricated by optimized mechanical milling and powder metallurgy techniques
  4. Flammability and physical stability of sugar palm crystalline nanocellulose reinforced thermoplastic sugar palm starch/poly(lactic acid) blend bionanocomposites
  5. Glutathione-loaded non-ionic surfactant niosomes: A new approach to improve oral bioavailability and hepatoprotective efficacy of glutathione
  6. Relationship between mechano-bactericidal activity and nanoblades density on chemically strengthened glass
  7. In situ regulation of microstructure and microwave-absorbing properties of FeSiAl through HNO3 oxidation
  8. Research on a mechanical model of magnetorheological fluid different diameter particles
  9. Nanomechanical and dynamic mechanical properties of rubber–wood–plastic composites
  10. Investigative properties of CeO2 doped with niobium: A combined characterization and DFT studies
  11. Miniaturized peptidomimetics and nano-vesiculation in endothelin types through probable nano-disk formation and structure property relationships of endothelins’ fragments
  12. N/S co-doped CoSe/C nanocubes as anode materials for Li-ion batteries
  13. Synergistic effects of halloysite nanotubes with metal and phosphorus additives on the optimal design of eco-friendly sandwich panels with maximum flame resistance and minimum weight
  14. Octreotide-conjugated silver nanoparticles for active targeting of somatostatin receptors and their application in a nebulized rat model
  15. Controllable morphology of Bi2S3 nanostructures formed via hydrothermal vulcanization of Bi2O3 thin-film layer and their photoelectrocatalytic performances
  16. Development of (−)-epigallocatechin-3-gallate-loaded folate receptor-targeted nanoparticles for prostate cancer treatment
  17. Enhancement of the mechanical properties of HDPE mineral nanocomposites by filler particles modulation of the matrix plastic/elastic behavior
  18. Effect of plasticizers on the properties of sugar palm nanocellulose/cinnamon essential oil reinforced starch bionanocomposite films
  19. Optimization of nano coating to reduce the thermal deformation of ball screws
  20. Preparation of efficient piezoelectric PVDF–HFP/Ni composite films by high electric field poling
  21. MHD dissipative Casson nanofluid liquid film flow due to an unsteady stretching sheet with radiation influence and slip velocity phenomenon
  22. Effects of nano-SiO2 modification on rubberised mortar and concrete with recycled coarse aggregates
  23. Mechanical and microscopic properties of fiber-reinforced coal gangue-based geopolymer concrete
  24. Effect of morphology and size on the thermodynamic stability of cerium oxide nanoparticles: Experiment and molecular dynamics calculation
  25. Mechanical performance of a CFRP composite reinforced via gelatin-CNTs: A study on fiber interfacial enhancement and matrix enhancement
  26. A practical review over surface modification, nanopatterns, emerging materials, drug delivery systems, and their biophysiochemical properties for dental implants: Recent progresses and advances
  27. HTR: An ultra-high speed algorithm for cage recognition of clathrate hydrates
  28. Effects of microalloying elements added by in situ synthesis on the microstructure of WCu composites
  29. A highly sensitive nanobiosensor based on aptamer-conjugated graphene-decorated rhodium nanoparticles for detection of HER2-positive circulating tumor cells
  30. Progressive collapse performance of shear strengthened RC frames by nano CFRP
  31. Core–shell heterostructured composites of carbon nanotubes and imine-linked hyperbranched polymers as metal-free Li-ion anodes
  32. A Galerkin strategy for tri-hybridized mixture in ethylene glycol comprising variable diffusion and thermal conductivity using non-Fourier’s theory
  33. Simple models for tensile modulus of shape memory polymer nanocomposites at ambient temperature
  34. Preparation and morphological studies of tin sulfide nanoparticles and use as efficient photocatalysts for the degradation of rhodamine B and phenol
  35. Polyethyleneimine-impregnated activated carbon nanofiber composited graphene-derived rice husk char for efficient post-combustion CO2 capture
  36. Electrospun nanofibers of Co3O4 nanocrystals encapsulated in cyclized-polyacrylonitrile for lithium storage
  37. Pitting corrosion induced on high-strength high carbon steel wire in high alkaline deaerated chloride electrolyte
  38. Formulation of polymeric nanoparticles loaded sorafenib; evaluation of cytotoxicity, molecular evaluation, and gene expression studies in lung and breast cancer cell lines
  39. Engineered nanocomposites in asphalt binders
  40. Influence of loading voltage, domain ratio, and additional load on the actuation of dielectric elastomer
  41. Thermally induced hex-graphene transitions in 2D carbon crystals
  42. The surface modification effect on the interfacial properties of glass fiber-reinforced epoxy: A molecular dynamics study
  43. Molecular dynamics study of deformation mechanism of interfacial microzone of Cu/Al2Cu/Al composites under tension
  44. Nanocolloid simulators of luminescent solar concentrator photovoltaic windows
  45. Compressive strength and anti-chloride ion penetration assessment of geopolymer mortar merging PVA fiber and nano-SiO2 using RBF–BP composite neural network
  46. Effect of 3-mercapto-1-propane sulfonate sulfonic acid and polyvinylpyrrolidone on the growth of cobalt pillar by electrodeposition
  47. Dynamics of convective slippery constraints on hybrid radiative Sutterby nanofluid flow by Galerkin finite element simulation
  48. Preparation of vanadium by the magnesiothermic self-propagating reduction and process control
  49. Microstructure-dependent photoelectrocatalytic activity of heterogeneous ZnO–ZnS nanosheets
  50. Cytotoxic and pro-inflammatory effects of molybdenum and tungsten disulphide on human bronchial cells
  51. Improving recycled aggregate concrete by compression casting and nano-silica
  52. Chemically reactive Maxwell nanoliquid flow by a stretching surface in the frames of Newtonian heating, nonlinear convection and radiative flux: Nanopolymer flow processing simulation
  53. Nonlinear dynamic and crack behaviors of carbon nanotubes-reinforced composites with various geometries
  54. Biosynthesis of copper oxide nanoparticles and its therapeutic efficacy against colon cancer
  55. Synthesis and characterization of smart stimuli-responsive herbal drug-encapsulated nanoniosome particles for efficient treatment of breast cancer
  56. Homotopic simulation for heat transport phenomenon of the Burgers nanofluids flow over a stretching cylinder with thermal convective and zero mass flux conditions
  57. Incorporation of copper and strontium ions in TiO2 nanotubes via dopamine to enhance hemocompatibility and cytocompatibility
  58. Mechanical, thermal, and barrier properties of starch films incorporated with chitosan nanoparticles
  59. Mechanical properties and microstructure of nano-strengthened recycled aggregate concrete
  60. Glucose-responsive nanogels efficiently maintain the stability and activity of therapeutic enzymes
  61. Tunning matrix rheology and mechanical performance of ultra-high performance concrete using cellulose nanofibers
  62. Flexible MXene/copper/cellulose nanofiber heat spreader films with enhanced thermal conductivity
  63. Promoted charge separation and specific surface area via interlacing of N-doped titanium dioxide nanotubes on carbon nitride nanosheets for photocatalytic degradation of Rhodamine B
  64. Elucidating the role of silicon dioxide and titanium dioxide nanoparticles in mitigating the disease of the eggplant caused by Phomopsis vexans, Ralstonia solanacearum, and root-knot nematode Meloidogyne incognita
  65. An implication of magnetic dipole in Carreau Yasuda liquid influenced by engine oil using ternary hybrid nanomaterial
  66. Robust synthesis of a composite phase of copper vanadium oxide with enhanced performance for durable aqueous Zn-ion batteries
  67. Tunning self-assembled phases of bovine serum albumin via hydrothermal process to synthesize novel functional hydrogel for skin protection against UVB
  68. A comparative experimental study on damping properties of epoxy nanocomposite beams reinforced with carbon nanotubes and graphene nanoplatelets
  69. Lightweight and hydrophobic Ni/GO/PVA composite aerogels for ultrahigh performance electromagnetic interference shielding
  70. Research on the auxetic behavior and mechanical properties of periodically rotating graphene nanostructures
  71. Repairing performances of novel cement mortar modified with graphene oxide and polyacrylate polymer
  72. Closed-loop recycling and fabrication of hydrophilic CNT films with high performance
  73. Design of thin-film configuration of SnO2–Ag2O composites for NO2 gas-sensing applications
  74. Study on stress distribution of SiC/Al composites based on microstructure models with microns and nanoparticles
  75. PVDF green nanofibers as potential carriers for improving self-healing and mechanical properties of carbon fiber/epoxy prepregs
  76. Osteogenesis capability of three-dimensionally printed poly(lactic acid)-halloysite nanotube scaffolds containing strontium ranelate
  77. Silver nanoparticles induce mitochondria-dependent apoptosis and late non-canonical autophagy in HT-29 colon cancer cells
  78. Preparation and bonding mechanisms of polymer/metal hybrid composite by nano molding technology
  79. Damage self-sensing and strain monitoring of glass-reinforced epoxy composite impregnated with graphene nanoplatelet and multiwalled carbon nanotubes
  80. Thermal analysis characterisation of solar-powered ship using Oldroyd hybrid nanofluids in parabolic trough solar collector: An optimal thermal application
  81. Pyrene-functionalized halloysite nanotubes for simultaneously detecting and separating Hg(ii) in aqueous media: A comprehensive comparison on interparticle and intraparticle excimers
  82. Fabrication of self-assembly CNT flexible film and its piezoresistive sensing behaviors
  83. Thermal valuation and entropy inspection of second-grade nanoscale fluid flow over a stretching surface by applying Koo–Kleinstreuer–Li relation
  84. Mechanical properties and microstructure of nano-SiO2 and basalt-fiber-reinforced recycled aggregate concrete
  85. Characterization and tribology performance of polyaniline-coated nanodiamond lubricant additives
  86. Combined impact of Marangoni convection and thermophoretic particle deposition on chemically reactive transport of nanofluid flow over a stretching surface
  87. Spark plasma extrusion of binder free hydroxyapatite powder
  88. An investigation on thermo-mechanical performance of graphene-oxide-reinforced shape memory polymer
  89. Effect of nanoadditives on the novel leather fiber/recycled poly(ethylene-vinyl-acetate) polymer composites for multifunctional applications: Fabrication, characterizations, and multiobjective optimization using central composite design
  90. Design selection for a hemispherical dimple core sandwich panel using hybrid multi-criteria decision-making methods
  91. Improving tensile strength and impact toughness of plasticized poly(lactic acid) biocomposites by incorporating nanofibrillated cellulose
  92. Green synthesis of spinel copper ferrite (CuFe2O4) nanoparticles and their toxicity
  93. The effect of TaC and NbC hybrid and mono-nanoparticles on AA2024 nanocomposites: Microstructure, strengthening, and artificial aging
  94. Excited-state geometry relaxation of pyrene-modified cellulose nanocrystals under UV-light excitation for detecting Fe3+
  95. Effect of CNTs and MEA on the creep of face-slab concrete at an early age
  96. Effect of deformation conditions on compression phase transformation of AZ31
  97. Application of MXene as a new generation of highly conductive coating materials for electromembrane-surrounded solid-phase microextraction
  98. A comparative study of the elasto-plastic properties for ceramic nanocomposites filled by graphene or graphene oxide nanoplates
  99. Encapsulation strategies for improving the biological behavior of CdS@ZIF-8 nanocomposites
  100. Biosynthesis of ZnO NPs from pumpkin seeds’ extract and elucidation of its anticancer potential against breast cancer
  101. Preliminary trials of the gold nanoparticles conjugated chrysin: An assessment of anti-oxidant, anti-microbial, and in vitro cytotoxic activities of a nanoformulated flavonoid
  102. Effect of micron-scale pores increased by nano-SiO2 sol modification on the strength of cement mortar
  103. Fractional simulations for thermal flow of hybrid nanofluid with aluminum oxide and titanium oxide nanoparticles with water and blood base fluids
  104. The effect of graphene nano-powder on the viscosity of water: An experimental study and artificial neural network modeling
  105. Development of a novel heat- and shear-resistant nano-silica gelling agent
  106. Characterization, biocompatibility and in vivo of nominal MnO2-containing wollastonite glass-ceramic
  107. Entropy production simulation of second-grade magnetic nanomaterials flowing across an expanding surface with viscidness dissipative flux
  108. Enhancement in structural, morphological, and optical properties of copper oxide for optoelectronic device applications
  109. Aptamer-functionalized chitosan-coated gold nanoparticle complex as a suitable targeted drug carrier for improved breast cancer treatment
  110. Performance and overall evaluation of nano-alumina-modified asphalt mixture
  111. Analysis of pure nanofluid (GO/engine oil) and hybrid nanofluid (GO–Fe3O4/engine oil): Novel thermal and magnetic features
  112. Synthesis of Ag@AgCl modified anatase/rutile/brookite mixed phase TiO2 and their photocatalytic property
  113. Mechanisms and influential variables on the abrasion resistance hydraulic concrete
  114. Synergistic reinforcement mechanism of basalt fiber/cellulose nanocrystals/polypropylene composites
  115. Achieving excellent oxidation resistance and mechanical properties of TiB2–B4C/carbon aerogel composites by quick-gelation and mechanical mixing
  116. Microwave-assisted sol–gel template-free synthesis and characterization of silica nanoparticles obtained from South African coal fly ash
  117. Pulsed laser-assisted synthesis of nano nickel(ii) oxide-anchored graphitic carbon nitride: Characterizations and their potential antibacterial/anti-biofilm applications
  118. Effects of nano-ZrSi2 on thermal stability of phenolic resin and thermal reusability of quartz–phenolic composites
  119. Benzaldehyde derivatives on tin electroplating as corrosion resistance for fabricating copper circuit
  120. Mechanical and heat transfer properties of 4D-printed shape memory graphene oxide/epoxy acrylate composites
  121. Coupling the vanadium-induced amorphous/crystalline NiFe2O4 with phosphide heterojunction toward active oxygen evolution reaction catalysts
  122. Graphene-oxide-reinforced cement composites mechanical and microstructural characteristics at elevated temperatures
  123. Gray correlation analysis of factors influencing compressive strength and durability of nano-SiO2 and PVA fiber reinforced geopolymer mortar
  124. Preparation of layered gradient Cu–Cr–Ti alloy with excellent mechanical properties, thermal stability, and electrical conductivity
  125. Recovery of Cr from chrome-containing leather wastes to develop aluminum-based composite material along with Al2O3 ceramic particles: An ingenious approach
  126. Mechanisms of the improved stiffness of flexible polymers under impact loading
  127. Anticancer potential of gold nanoparticles (AuNPs) using a battery of in vitro tests
  128. Review Articles
  129. Proposed approaches for coronaviruses elimination from wastewater: Membrane techniques and nanotechnology solutions
  130. Application of Pickering emulsion in oil drilling and production
  131. The contribution of microfluidics to the fight against tuberculosis
  132. Graphene-based biosensors for disease theranostics: Development, applications, and recent advancements
  133. Synthesis and encapsulation of iron oxide nanorods for application in magnetic hyperthermia and photothermal therapy
  134. Contemporary nano-architectured drugs and leads for ανβ3 integrin-based chemotherapy: Rationale and retrospect
  135. State-of-the-art review of fabrication, application, and mechanical properties of functionally graded porous nanocomposite materials
  136. Insights on magnetic spinel ferrites for targeted drug delivery and hyperthermia applications
  137. A review on heterogeneous oxidation of acetaminophen based on micro and nanoparticles catalyzed by different activators
  138. Early diagnosis of lung cancer using magnetic nanoparticles-integrated systems
  139. Advances in ZnO: Manipulation of defects for enhancing their technological potentials
  140. Efficacious nanomedicine track toward combating COVID-19
  141. A review of the design, processes, and properties of Mg-based composites
  142. Green synthesis of nanoparticles for varied applications: Green renewable resources and energy-efficient synthetic routes
  143. Two-dimensional nanomaterial-based polymer composites: Fundamentals and applications
  144. Recent progress and challenges in plasmonic nanomaterials
  145. Apoptotic cell-derived micro/nanosized extracellular vesicles in tissue regeneration
  146. Electronic noses based on metal oxide nanowires: A review
  147. Framework materials for supercapacitors
  148. An overview on the reproductive toxicity of graphene derivatives: Highlighting the importance
  149. Antibacterial nanomaterials: Upcoming hope to overcome antibiotic resistance crisis
  150. Research progress of carbon materials in the field of three-dimensional printing polymer nanocomposites
  151. A review of atomic layer deposition modelling and simulation methodologies: Density functional theory and molecular dynamics
  152. Recent advances in the preparation of PVDF-based piezoelectric materials
  153. Recent developments in tensile properties of friction welding of carbon fiber-reinforced composite: A review
  154. Comprehensive review of the properties of fly ash-based geopolymer with additive of nano-SiO2
  155. Perspectives in biopolymer/graphene-based composite application: Advances, challenges, and recommendations
  156. Graphene-based nanocomposite using new modeling molecular dynamic simulations for proposed neutralizing mechanism and real-time sensing of COVID-19
  157. Nanotechnology application on bamboo materials: A review
  158. Recent developments and future perspectives of biorenewable nanocomposites for advanced applications
  159. Nanostructured lipid carrier system: A compendium of their formulation development approaches, optimization strategies by quality by design, and recent applications in drug delivery
  160. 3D printing customized design of human bone tissue implant and its application
  161. Design, preparation, and functionalization of nanobiomaterials for enhanced efficacy in current and future biomedical applications
  162. A brief review of nanoparticles-doped PEDOT:PSS nanocomposite for OLED and OPV
  163. Nanotechnology interventions as a putative tool for the treatment of dental afflictions
  164. Recent advancements in metal–organic frameworks integrating quantum dots (QDs@MOF) and their potential applications
  165. A focused review of short electrospun nanofiber preparation techniques for composite reinforcement
  166. Microstructural characteristics and nano-modification of interfacial transition zone in concrete: A review
  167. Latest developments in the upconversion nanotechnology for the rapid detection of food safety: A review
  168. Strategic applications of nano-fertilizers for sustainable agriculture: Benefits and bottlenecks
  169. Molecular dynamics application of cocrystal energetic materials: A review
  170. Synthesis and application of nanometer hydroxyapatite in biomedicine
  171. Cutting-edge development in waste-recycled nanomaterials for energy storage and conversion applications
  172. Biological applications of ternary quantum dots: A review
  173. Nanotherapeutics for hydrogen sulfide-involved treatment: An emerging approach for cancer therapy
  174. Application of antibacterial nanoparticles in orthodontic materials
  175. Effect of natural-based biological hydrogels combined with growth factors on skin wound healing
  176. Nanozymes – A route to overcome microbial resistance: A viewpoint
  177. Recent developments and applications of smart nanoparticles in biomedicine
  178. Contemporary review on carbon nanotube (CNT) composites and their impact on multifarious applications
  179. Interfacial interactions and reinforcing mechanisms of cellulose and chitin nanomaterials and starch derivatives for cement and concrete strength and durability enhancement: A review
  180. Diamond-like carbon films for tribological modification of rubber
  181. Layered double hydroxides (LDHs) modified cement-based materials: A systematic review
  182. Recent research progress and advanced applications of silica/polymer nanocomposites
  183. Modeling of supramolecular biopolymers: Leading the in silico revolution of tissue engineering and nanomedicine
  184. Recent advances in perovskites-based optoelectronics
  185. Biogenic synthesis of palladium nanoparticles: New production methods and applications
  186. A comprehensive review of nanofluids with fractional derivatives: Modeling and application
  187. Electrospinning of marine polysaccharides: Processing and chemical aspects, challenges, and future prospects
  188. Electrohydrodynamic printing for demanding devices: A review of processing and applications
  189. Rapid Communications
  190. Structural material with designed thermal twist for a simple actuation
  191. Recent advances in photothermal materials for solar-driven crude oil adsorption
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Heruntergeladen am 2.12.2025 von https://www.degruyterbrill.com/document/doi/10.1515/ntrev-2022-0029/html
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