CAJ | 학술논문

为提高池塘养殖的机械增氧效率，应用Solidworks软件设计了移动式太阳能能增氧机，该设备由太阳能动力组件、水面行走机构、增氧装置和运动控制系统等组成。移动式太阳能增氧机可在水面自主行走，产生波浪和实现上下水层交换。性能测试表明，移动式太阳能增氧机的光照启动强度为17000 lx，空载噪声为75.3 dB，水面行走机构的行走速度在0.027～0.041 m/s之间波动，无线遥控距离为44.2 m，在增氧装置位置的最大浪高为0.44 m。随着光照强度的增强，增氧装置增氧效率和扰动水体能力增强，最大机械增氧能力为1.24 kg/h，动力效率2.59 kg/(kW·h)；最大扰动水体1254.4 m3/h，扰水动力效率2613.3 m3/(kW·h)。移动式太阳能增氧机利用太阳能作为能源，在池塘水体中运行面积大、运行时间长，强化了池塘自身的自净能力，具有生态调控的功能，有利于池塘物质循环和水质改善。
위제고지당양식적궤계증양효솔，응용Solidworks연건설계료이동식태양능능증양궤，해설비유태양능동력조건、수면행주궤구、증양장치화운동공제계통등조성。이동식태양능증양궤가재수면자주행주，산생파랑화실현상하수층교환。성능측시표명，이동식태양능증양궤적광조계동강도위17000 lx，공재조성위75.3 dB，수면행주궤구적행주속도재0.027～0.041 m/s지간파동，무선요공거리위44.2 m，재증양장치위치적최대랑고위0.44 m。수착광조강도적증강，증양장치증양효솔화우동수체능력증강，최대궤계증양능력위1.24 kg/h，동력효솔2.59 kg/(kW·h)；최대우동수체1254.4 m3/h，우수동력효솔2613.3 m3/(kW·h)。이동식태양능증양궤이용태양능작위능원，재지당수체중운행면적대、운행시간장，강화료지당자신적자정능력，구유생태조공적공능，유리우지당물질순배화수질개선。
Dissolved oxygen (DO) is the most important factor in pond aquaculture. In order to reduce “oxygen debt” of water in the bottom and prevent fish from hypoxia in the next morning, aerators usually need to run which can stir the water in pond. However, this method consumes a lot of electrical energy and is of low efficiency. A movable solar aerator was designed by the software of Solidworks to solve these problems. It mainly consisted of solar power mechanism, water walking mechanism, aerator and working control system, which could move upon the water, generate waves and exchange amount of water from bottom to surface, etc. The solar power mechanism provided energy for the entire machine, while the water walking mechanism drives the whole machine to move on the water surface. The aerator orbits of the equipment could affect a large area of the pond. In order to verify the reliability of the system, the reliability of walking performance was tested under both idling and load situation by the experiment in which the walking test platform was separately proceeded on the ground and in the pond. First, to deploy the reliability test on the ground, the steel cable was fixed with the stainless steel stem with the diameter of 6 mm, and the locked position was located outside the stop block, so as to ensure there was sufficient gap between stainless steel stem and steel cable. Based on that, it would ensure the synchronous motion of steel cable and stainless steel stem while no interference issue between them. Additionally, to perform the reliability test in the pond, the 2 ends of the steel cable were fixed through the wooden stake. When the moving distance was separately set as 2, 3 and 4 m, after setting the parameters in the control system, the running time and the odometer of single track could be recorded separately. The test duration was 1 day, running 5 h per day with 3 replications, and the illumination intensity of movable solar aerator start-up was 1 7000 lx. In order to test the stirring water capacity of the movable aerator, the aerator was mounted in the center of the round pond with depth of 1.8 m and diameter of 9 m, to get the relevant parameters, such as rotation speed, wave height located at 0, 3 and 6 m away from the device center, wave velocity and wave length. Results of a series of tests on the mechanical properties revealed that the minimum illumination intensity of movable solar aerator start-up was 1 7000 lx; the idle running noise was 75.3 dB; the moving speed upon the water was between 0.027 and 0.041 m/s; the remote-controlled distance was 44.2 m; the maximum wave height was 0.44 m in the aerator position. When the illumination intensity got stronger, the value of oxygen transfer efficiency and the capacity of stirring water were getting higher. The maximum mechanical aeration capacity was 1.24 kg/h, with dynamic efficiency of 2.59 kg/(kW·h); the maximum stirring water capacity was 1254.4 m3/h, with stirring dynamic efficiency of 2613.3 m3/(kW·h). The movable solar aerator utilized solar power, which had the advantages of large operational area and long running time, which was about from 5 to 6 h per day. According to the test result of the water walking mechanism, it performed well with high stability and reliability, which overcame the traditional problems of limited operation area and large energy consumption. It could effectively accelerate to exchange water of the upper and lower layer by machinery disturbing in the whole pond, which could be up to 60%-80% of the pond area. Thus, this process corresponds to the concept of environmental friendly, energy saving, high efficiency and low-carbon emission.