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- Solar photovoltaic power station system based on composite heat source thermal power technology
- Investigation of the Effect of Solar Ventilation on the Cabin Temperature of Vehicles Parked under the Sun
- Recent advances in performance enhancement techniques and the perspective of solar energy for automobile air-conditioning system-a critical review
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25+ million members 160+ million publication pages 2.3+ billion citations Join for free Public Full-text 1 Publisher Preview 1 Content uploaded by Tingsheng Zhang Author content Content may be subject to copyright. This article has been accepted for publication and undergone full peer review but has not been through the copyediting, typesetting, pagination and proofreading process, which may lead to differences between this version and the Version of Record. Please cite this article as doi: 10.1002/ente.202000028. This article is protected by copyright. All rights reserved A high-efficiency, portable, solar-powered cooling system based on a foldable-flower mechanism and wireless power transfer technology for vehicle cabins Tingsheng Zhang, Yan Feng, Xiaoping Wu, Yajia Pan, Zutao Zhang*, Yanping Yuan School of Mechanical Engineering, Southwest Jiaotong University, Chengdu 610031, P. R. China *E-mail: zzt@swjtu.edu.cn Keywords: Vehicle cabin cooling system; Solar foldable flower; Portable mechanism; Wireless power transfer; Photovoltaic Abstract In summer, the high temperature inside vehicles is a problem, because cooling a vehicle parked under the scorching sun is both time and energy consuming. This paper proposes a portable solar-powered cooling system (SPCS) based on a foldable-flower mechanism and wireless power transfer (WPT) technology. The proposed system consists of three main parts: a solar foldable-flower module (SFFM), an energy transfer module, and a temperature control module. The solar foldable-flower module is a novel foldable mechanism that achieves high space utilization through a rotating process and a folding process, like a flower opening its petals. The solar foldable-flower module, equipped with photovoltaic (PV) cells, collects solar energy and converts it into electricity. The energy transfer module stores electricity from the solar foldable-flower module in a supercapacitor via a WPT unit. The temperature control module achieves automatic temperature regulation using a cooling device. Experimental results show that output power can reach up to 7.571 W with a load resistor of 5 Ω, while the efficiency of the WPT can reach up to 73.6% with a load resistor of 15 Ω. Moreover, thermal simulation results illustrate that the proposed system can achieve an average temperature reduction of 27.45 ℃, making it feasible and effective to cool a hot vehicle cabin. 1. Introduction With the continuous consumption of fossil fuels such as oil, coal, and natural gas, the energy crisis has become increasingly serious in the 21st century. The development of renewable energy is growing increasingly topical in current research.[1] Renewable energy research involves various fields[2], such as wind energy[3,4], tidal energy, nuclear energy, mechanical energy[5-7], acoustic energy[8], and solar energy[9,10]. Among the renewable energy types mentioned above, solar energy is particularly topical.[11] Most of the energy required by humans originates from the sun.[12] The atmosphere of the earth only receives about one 2,200 millionth of the sun’s total radiant energy. Solar energy is, in a sense, an infinite source.[13] Particularly, in the 21st century, fossil energy is increasingly being depleted, and the full development and application of solar energy have the dual significance of sustainable development and environmental protection[14]. As a renewable and clean energy source, solar energy is used as the power supply for many studies on air-conditioning systems, and can be classified into two categories, based on their working principles and applications: photovoltaic systems and photothermal systems.[15] With the continuous development of the photovoltaic industry and technology, photovoltaic air- conditioning technology has been gradually improved. Xu et al.[16] presented a solar photovoltaic-based static ice refrigeration air-conditioning system, and investigated its energy transmission and conversion characteristics. They also proposed an ice storage air-conditioning system powered by a distributed photovoltaic system, which shows a prospect of broad application in the tropical region without energy supply from power grids.[17] Eicker et al.[18] concluded that both photovoltaic and photothermal cooling systems can reduce power consumption by 21-70%, by analyzing solar cooling systems for office buildings in different climates. Regarding adsorption and absorption cooling technologies powered by photovoltaic and photothermal collectors, Buonomano et al.[19] designed a dynamic simulation model Accepted Article This article is protected by copyright. All rights reserved with MatLab programming, simulating a solar polygeneration system that simultaneously produces space heating and cooling, as well as electricity. Zheng et al.20] compared the different characteristics of phase change material and microencapsulated phase change material in a solar-powered cooling cycle system. According to the experimental results, microencapsulated phase change material, as a cooling medium, has obvious advantages in cooling cycles driven by solar energy. Huang et al.[21] designed an air-conditioning system, using an inverter, directly powered by an independent solar PV system. By testing six solar air conditioners, it was concluded that solar PV modules must be at least three times the load power in order to achieve low power loss risk in air-conditioning systems. Liu et al.[22] presented a quasi-grid-connected PV DC air-conditioning system. Compared with conventional air conditioners, their designed system can save at least 67% and 77% of grid power, respectively, during the day and night in summer. In terms of comprehensive energy efficiency ratio, solar air conditioners have a ratio 4.6 times higher than that of conventional air conditioners. Some researchers have studied solar PV air-conditioning systems for vehicles. Pang et al.[23] proposed an air-conditioning system powered by PV panels for vehicle cabins. The research indicated that the minimum cooling capacity can reach 1500 W, which can reduce the cabin temperature to 25 °C—similar to a traditional automobile air conditioner. Pan et al.[24] designed a portable solar PV cooling system for vehicles, which for the first time applied wireless power transfer to the cooling system. The second category to power air-conditioning systems is photothermal conversion, which is also the direction that many scholars are studying.[25] Reda et al.[26] proposed a method to select the best parameters for small scale solar-assisted silica-water adsorption cooling systems in arid regions. Solar collectors have an optimum absorption radiation angle of 5°. To solve the problem of cooling domestic water in many dry areas during the summer, Tijani et al.[27] designed a solar multi-stage thermoelectric cooling system. Allouche et al.[28] used TRNSYS to evaluate the performance of a solar driven injector cooling system. A parametric investigation was conducted in a 140-m2 room in Tunisia and some conclusions were drawn. Small thermal storage tanks were recommended, and solar collectors should be based on further research to find the appropriate parameters for solar cooling applications. Using phase change material for latent heat storage in the ejector solar cooling system is also a highly recommended method. Tashtoush et al.[29] designed solar collector subsystem components and used TRNSYS-EES software to achieve performance evaluation of a solar injector cooling system using R134a as a refrigerant, and to perform dynamic hourly simulation of the mixing components of a 7 kW solar ejector cooling system under constant pressure. Bellos and Tzivanidis[30] presented a jet absorption chiller system with a solar parabolic trough collector. Compared with traditional absorption systems, the ejector-absorption system has better performance from numerous aspects. Wang et al.[31] designed, optimized, and analyzed a combined heating, cooling, and electricity system integrated with a photovoltaic and photothermal collector for thermodynamic performance. The experiment results demonstrated that photothermal collectors have better integration performance. Solar photothermal air-conditioning systems for vehicles have also been studied by some researchers. Mei et al.[32] studied a solar-assisted thermoelectric cooling technique in a car air conditioner, and built a mathematical model to analyze the power consumption and performance of thermoelectric materials. Wu et al.[33] developed a novel solar absorption cooling system for office buildings to reduce cooling costs. The unit cost of cooling of the optimized system is $0.24 per kWh of cooling effect, by collecting solar energy on the façade of the building. Qi et al.[34] presented a novel solar cooling system for vehicles based on phase change materials. This system achieves vehicle cooling via heat exchange between the cabin ambient air and the phase change materials. Despite the success of many solar air conditioners, the portability and method of power transfer remain challenging problems in the application of solar air conditioners to vehicles. This paper proposes a new portable solar-powered cooling system, with a supercapacitor which is used to store power[35], for vehicles. Recently, increasing numbers of scholars have focused on research on WPT technology, such as wireless powered communication[36], charging electric vehicles[37] and electronic skin[38]. The proposed system uses WPT technology to avoid modification of the vehicle and to facilitate carrying and installing. The remaining content of the article is as follows. Section 2 introduces the design of the solar-power cooling system proposed in this paper, including a solar foldable-flower module, an energy transfer module, a temperature control unit, and a cooling system. The system is modeled and analyzed in Section 3. Section 4 describes the experimental details and results of both the experiments and simulation. Section 5 discusses the results of the study. Finally, conclusions of this paper are given in Section 6. Accepted Article This article is protected by copyright. All rights reserved 2. System design Figure 1. Flowchart of the proposed solar-power cooling system. (a) Structure and working principle of the solar foldable-flower module. (b) Energy transfer module of the solar-power cooling system. (c) Temperature control module. (d) Workflow of the solar-power cooling system. Figure 2. Schematic diagram of the solar-power cooling system. (a) Lateral view of the solar-power cooling system. (b) Top view of the solar-power cooling system. The proposed solar-power cooling system for vehicles was designed as shown in Figure 1, and comprises a solar foldable-flower module, an energy transfer module, and a temperature control module. First, when the car is parked under the scorching sun, the solar foldable-flower module is placed on the roof of the vehicle. The solar foldable-flower module installed with PV cells uses a Accepted Article This article is protected by copyright. All rights reserved foldable mechanism structure to improve portability. In other words, when the solar foldable-flower module is about to work, the folding mechanism is deployed to obtain a larger illumination area; when the solar foldable-flower module is not working, the mechanism is folded and placed in the vehicle cabin to improve space utilization, so as to not affect driving. The second part is the energy transfer module. During the process of energy transfer, PV cells convert solar energy into electricity, which is stored in the supercapacitor via the WPT unit. The last part is the temperature control module. The temperature sensor measures the real-time cabin temperature. When the measured temperature reaches the preset temperature, the single chip microcomputer controls the stepper motor to unfold the solar foldable- flower module. The cooling system is then started to maintain a suitable temperature inside the vehicle. Before driving, the solar foldable-flower module must be folded and placed in the car. Figure 2 illustrates the schematic diagram of the solar-power cooling system. 2.1. Solar foldable-flower module Figure 3. Structural design of the solar foldable-flower module. (a) Unfolded view of the solar foldable-flower module. (b) Symmetric folding process of the solar foldable-flower module. (c) Rotating folding process of the solar foldable-flower module. (d) Folded view of the solar foldable-flower module. (e) Overall view of the folded solar foldable-flower module installed on vehicle. The structural design of the solar collector proposed in this paper originates from a flower opening its petals, as shown in Figure 3. The device mainly comprises: six petals, bevel gear sets, hinges, stepper Accepted Article This article is protected by copyright. All rights reserved motors, base frames, wire, and fixed pulleys. Each petal comprises sector plates with a diameter of 300 mm and a central angle of 60°, equipped with PV cells. Every three petals are assembled with hinge connections as a solar collector unit. Each unit uses custom hinges to put the axes of the hinge in the same plane. As shown in Figure 3(e), each solar collector unit uses a bevel gear set, and one large bevel gear drives two small bevel gears simultaneously to drive the petals to rotate and fold. Thus, the device uses a stepper motor to drive a large bevel gear and in turn drive two small bevel gears, which are fixed to the axes of the hinges, to achieve rotation and folding of the petals. In Figure 3(b), (d), and (e) each solar collection unit is symmetrically folded by wire, a fixed pulley, and a stepper motor. Therefore, positive and negative movement of the stepper motor can achieve the unfolding and folding of the solar foldable-flower module. The overall size of the folded device is 200 350 450 mm in Figure 3(d). The weight of the solar foldable-flower module is about 4.5 kg. Figure 4 shows the installation view of the solar foldable-flower module when the car is parked under the sun. Figure 4(c)-(f) shows the four states of the solar foldable-flower module during the aforementioned folding or unfolding process. First, the solar foldable flower is taken from the car cabin and placed on the roof of the car, as in Figure 4(a)-(c). Two stepper motors drive the wire, causing the two solar collector units to rotate 30° to the outside, as in Figure 4(d). The other two stepper motors drive the two bevel gear sets, causing each solar collector unit to rotate and unfold, as in Figure 4(e). The first two stepper motors continue to work, making the two solar collectors continue to rotate 60° to the outside. Finally, the unfolding of the solar foldable-flower module is complete, as in Figure 4(f). Figure 4. Installation view of the solar foldable-flower module. (a) The solar foldable-flower module is placed on the roof from inside vehicle. (b) The solar foldable-flower module is installed on vehicle. (c) The folded solar foldable-flower module on vehicle. (d) Symmetric folding process of the solar foldable-flower module on vehicle. (e) Rotating folding process of the solar foldable-flower module on vehicle. (f) The unfolded solar foldable-flower module on vehicle. 2.2. Energy transfer module Figure 5 describes the energy transfer process of the solar-power cooling system. Solar PV panels serve to convert solar energy into electricity. It is innovative that the solar-power cooling system delivers electricity through WPT technology, which has the advantages of (1) satisfactory energy transfer efficiency and (2) not requiring modification of the car. The DC/DC converter adjusts a suitable output voltage. Specifically, its input voltage is from 8 V to 22 V and output voltage is 5 V. The controller controls the charging and discharging of the supercapacitor. Finally, the temperature control module consumes the transmitted energy to maintain the temperature at a suitable level. Accepted Article This article is protected by copyright. All rights reserved Figure 5. Energy transfer process. Figure 6. Field installation of the proposed prototype. (a)Prototype installation of the unfolded solar foldable- flower module on vehicle. (b) Cooling system inside the vehicle. (d) Prototype installation of the folded solar foldable-flower module on vehicle. Figure 6 (a) and (b) demonstrate the field installation of the proposed prototype, including a solar foldable-flower module, a WPT unit, a cooling device, and a supercapacitor, while Figure 6(c) is the outer appearance of a vehicle equipped with the proposed system. PV cells—converting solar energy into the required electrical energy—are installed on the solar foldable-flower module. Each petal consists of three polycrystalline silicon PV cells S1, S2, and S3, with sizes of 53 30 mm, 68 37 mm, and 110 80 mm, respectively. The generated electricity is supplied with a voltage of 5 V, and currents of 30 mA, 60 mA, and 200 mA, respectively. As shown in Figure 7, all solar PV cells are connected in series and in parallel to provide electricity totaling 20 V and 21 W. To avoid modification of the vehicle body, and to reduce the layout of the wire, WPT technology is used to deliver electricity from the roof of the vehicle to the temperature control module. The input voltage and input current of the WPT are 20 V and 1.05 A respectively, while the output voltage and output current are 12 V and 1 A respectively. The inner and outer diameters of the induction coil are 21 mm and 43 mm, respectively. The efficiency of the WPT unit through magnetic coupling resonance is about 50–75%, and the maximum transmission distance is 20 mm. The voltage and capacity of the supercapacitor are 16 V and 20 F respectively, which is produced by Taiwan CDA. Accepted Article This article is protected by copyright. All rights reserved Figure 7. Series and parallel connection of PV cells. 2.3. Temperature control module When a car is parked under the blazing sun, the solar foldable-flower module is set on the vehicle and starts working. In detail, the petals are unfolded, after which the collected solar energy is converted into electricity. The electricity is stored in the supercapacitor via WPT technology. The temperature control module detects and adjusts the cabin temperature in real time. Specifically, when a car is exposed to sunlight for a long time, the temperature inside the vehicle cabin gradually rises. Once the temperature sensor detects that the temperature exceeds 30°C (the preset value), the vehicle cooling device is activated. During this process, the supercapacitor supplies power to the car's cooling device until the cabin temperature drops to the preset value. Additionally, the entire system described above can be controlled via Bluetooth. When the user needs to drive his or her car, the above system can be remotely controlled using a mobile phone to adjust the temperature to a comfortable level before entering the car. The cooling system proposed in this paper, which is a small fan rated at 5 V and 500mA, is shown in Figure 8(a). Figure 8(b) demonstrates the cooling process. Figure 8. View of the cooling system. (a) Cooling device inside vehicle. (b) Cooling process inside vehicle. 3. Modeling and analysis 3.1. Solar foldable flower Accepted Article This article is protected by copyright. All rights reserved Figure 9. Analysis of a solar collector unit. (a) Lateral view of the unfolded solar collector unit sketch. (b) Lateral view of the folded solar collector unit sketch. (c) Meshing lateral view of the bevel gear set. (d) Meshing axonometric view of the bevel gear set. Figure 9 illustrates the work principle of a solar collector unit. Figure 9 (a) and Figure 9 (b) show a schematic view of an unfolded and folded solar collector unit, respectively. As shown in Figure 9 (c), the indexing circle diameter (Rd) of the large bevel gear is 78mm, while the indexing circle (rd) of the small one is 26 mm. In Figure 9 (d), vR is the rotation speed of the large bevel gear that is equal to that of the stepper motor, while vr is that of the small bevel gear rotation—that is, the rotation speed of the petal. The gear ratio (i) between them can be expressed as (1) Figure 10. Analysis of the symmetrical folding mechanism. (a) Lateral view sketch of the unfolded symmetrical mechanism. (b) Lateral view sketch of the folded symmetrical mechanism. Figure 10 (a) and (b) respectively show the unfolded state and the folded state of the symmetrical folding mechanism, where a, b, c, and l are distances among different connection points; ω1 is the revolving speed of stepper motor; d is the diameter of the reel; L is the distance between the fixed pulley and the connection point on the solar collector unit; and v is the speed of the wire. The relationships between them are: (2) (3) (4) α can be obtained by the Cosine Theorem: Accepted Article This article is protected by copyright. All rights reserved (5) Taking the derivative of α, ω2 indicates the revolving velocity of the solar collector unit. (6) Figure 11 states the trends of L and ω2 over time, where L changes linearly and ω2 gradually decreases until it is stabilized. The symmetrical folding process takes approximately 4 seconds. Figure 11. Simulation of the symmetrical folding mechanism. 3.2. Solar radiation 3.2.1 Geographical parameters To calculate the amount of solar radiation somewhere on the surface of the Earth, the first step is to determine basic geographic parameters, including the declination, solar altitude angle, solar azimuth angle, and local solar time. Declination (δ), ranging from -23.5 º to +23.5º, can be estimated by the Cooper formula: (7) where δ is the angular position of the sun at solar noon with respect to the plane of the equator on the th day of a year. According to Duffie and Beckman[39], some parameters are estimated using the following formula: (8) (9) (10) (11) where E is the time correction factor; T refers to the local solar time (h); ω represents the hour angle (°); t is the local standard time (h) (which in this paper represents Beijing); Lst is the standard meridian for the local time zone (which is 105° East in this paper); and Lloc is the longitude of the location (which located in Chengdu (104.07 ° East)). The solar altitude angle (αs) and solar azimuth angle (γs) are given by: (12) (13) Accepted Article Citations (9) References (58) ... When the cooling is not required, the stepper motors rotate in reverse to fully fold it, then stow it in the vehicle for the next use. In 2020, Zhang et al. [32] also designed a portable vehicle solar-powered cooling system based on a foldable-flower mechanism, as shown in Fig. 8. The designed mechanism folds better and is more portable than the mechanism proposed previously [31]. ... ... Portable system design is implemented by using folding mechanisms, including foldable PV supports and foldable PV self-powered applications. Linkage mechanism [31], screw slider mechanism [31e33], and gear set mechanism [32] are commonly used for foldable structure design. In addition to the folding effect, weight is a factor that cannot be ignored for portable PV system design. ... ... Additionally, PV power generation is also used in other transport-related applications. Portable self-powered solar cooling systems were developed to cool vehicle cabins [31,32]. PV-powered charging stations were presented to power electric vehicles [124,125]. ... Solar energy harvesting technologies for PV self-powered applications: A comprehensive review Article Full-text available Feb 2022 RENEW ENERG Daning Hao Lingfei Qi Alaeldin Mohamed Tairab Jinyue Yan View Show abstract ... The air thermophysical parameters are calculated by correlation. According to the properties of binary mixture gas, the correlation equation establishes a calculation equation that expresses the thermophysical properties of moist air by air temperature, pressure and relative humidity [11,12]. These calculation equations are not only of high accuracy but also convenient to use in engineering calculation, experiment and simulation research [13]. ... Solar photovoltaic power station system based on composite heat source thermal power technology Article Full-text available Jan 2023 THERM SCI Xiaomin Fang Xiaolu Li View Show abstract ... Vehicles are important to the transportation sector within our society; however, the consumption of fossil fuels has many disadvantages, including smog emissions and global warming, that require the automotive industry to provide new energy sources and conduct research focused on electric vehicles to overcome these disadvantages [3]. Researchers have developed many ways to harvest energy from the environment, such as vibration energy [4,5] and different categories of energy-harvesting systems, including mechanical, thermoelectric, piezoelectric, wind energy, and solar energy [6][7][8][9][10][11][12][13], which can help to reduce emissions [14][15][16]. Many countries are focused on solar energy, because solar energy is a clean and renewable type of energy that can be used to provide electricity and heat [17]. ... Investigation of the Effect of Solar Ventilation on the Cabin Temperature of Vehicles Parked under the Sun Article Full-text available Dec 2021 Hani Al-Rawashdeh Ahmad Hasan Hazem A. Al-Shakhanbeh Hegazy Rezk View Show abstract Recent advances in performance enhancement techniques and the perspective of solar energy for automobile air-conditioning system-a critical review Article Jun 2022 SOL ENERGY Hemantchandra Patel Kalpeshkumar Vasantbhai Modi View Show abstract A Highly Efficient Multifunctional Wind Barrier Based on PVDF for Power Generation in the Qinghai–Tibet Railway Article Full-text available Mar 2022 Hao Wu Hao Cao Changyuan Jia Zutao Zhang View Show abstract A Multidirectional Pendulum Kinetic Energy Harvester Based on Homopolar Repulsion for Low-Power Sensors in New Energy Driverless Buses Article May 2021 Tingsheng Zhang Minfeng Tang Hai Li Zutao Zhang View Show abstract A hybrid, self-adapting drag-lift conversion wind energy harvesting system for railway turnout monitoring on the Tibetan Plateau Article Aug 2021 Hao Wang Minyi Yi Xiaohui Zeng Zutao Zhang View Show abstract A High‐Efficiency, Portable Solar Energy‐Harvesting System Based on a Foldable‐Wings Mechanism for Self‐Powered Applications in Railways Article Full-text available Apr 2021 Daning Hao Tingsheng Zhang Liang Guo Yanping Yuan View Show abstract Continuous power regulation in wireless power transfer system with a new magnetic field superposition transmitter Article Mar 2021 COMPUT ELECTR ENG Jin Xu Qiyu Tian View Show abstract Recommendations Discover more about: Wireless Power Transfer Article A portable renewable solar energy-powered cooling system based on wireless power transfer for a vehi... June 2017 · Applied Energy Lingfei Qi Hongye Pan Xingtian Zhang [...] Chunbai Wang As the greenhouse effect becomes increasingly serious, cooling a vehicle cabin parked under the blazing sun without running the engine or using an electric vehicle’s power has received considerable attention. In this paper, we develop a novel portable, renewable, solar energy-powered cooling system with wireless power transfer (WPT) and supercapacitors to cool the vehicle cabin. The proposed ... [Show full abstract] Read more Article Full-text available A High‐Efficiency, Portable Solar Energy‐Harvesting System Based on a Foldable‐Wings Mechanism for S... April 2021 · Energy Technology Daning Hao Tingsheng Zhang Liang Guo [...] Yanping Yuan With the rapid development of railways, sensors, signal lights and other rail‐side applications are being used to increase the safety of trains. The source of electricity for rail‐side applications remains a problem during railway construction and in remote areas where there is no electricity grid. In this study, a portable solar energy harvesting system (SEHS) is developed and used to supply ... [Show full abstract] View full-text Article Solar Photovoltaic based Air Cooling System for Vehicles June 2018 · Renewable Energy Wei Pang Hongwen Yu Yongzhe Zhang Hui Yan The conventional automotive air conditioning system was driven by internal combustion engine or power battery, which increased the oil consumption and vehicle carbon emission. In this study, a direct current (DC) air conditioning system powered by solar photovoltaic module (PV) has been designed to solve the problem of temperature increasing inside the vehicle when stops in the broiling summer. ... [Show full abstract] Read more Article Air-cooling system based on phase change materials for a vehicle cabin October 2020 · Materials Today: Proceedings Sangeetha Krishnamoorthi L. Prabhu Glen Kuriakose [...] J. Harikrishnan This paper provides a way to control the temperature of interior compartment of an automobile which is kept stationary and facing the solar energy received from the sun. Phase change materials PCM were mainly used inside the cabin to remove heat and to provide an air cooling system. When the vehicle is at outdoors and kept under the sun these materials were used to take care that the cabin ... [Show full abstract] Read more Начало формы Конец формы or Discover by subject area Recruit researchers Join for free Login Download 0.62 Mb. Do'stlaringiz bilan baham: 
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