In the fields of mineral processing and scientific research experiments, shaking tables are key equipment, and the accuracy of their selection directly affects production efficiency and experimental results. As a professional manufacturer of shaking tables, Jiangxi Mingxin has launched a series of products covering mineral processing, laboratory and other scenarios. Faced with a wide range of types, mastering a scientific selection method is crucial. You can easily find the most suitable shaking table equipment by following the three-step principle of "clarifying the purpose, matching the sample, and considering the performance".
The first step is to clarify the purpose of use, which is the basis for equipment selection. Different scenarios have completely different functional requirements for shaking tables. Only by first determining the purpose can we narrow down the selection range. If it is used for mineral separation, the double-layer shaking table for mineral processing produced by Jiangxi Mingxin is an excellent choice. With its compact design, it greatly saves the floor space and at the same time has a large processing capacity. It can directly separate the final concentrate and tailings in a single operation, eliminating the trouble of multiple processing. It is especially suitable for the purification of rare metals and precious metals such as tungsten, tin, and gold, and can also efficiently process common minerals such as iron, manganese ore, and coal, providing strong support for mineral processing enterprises to improve production efficiency. In the case of laboratory scenarios, selection needs to be subdivided according to specific experimental types: when conducting chemical experiments such as Coomassie blue staining and electrophoresis gel fixation, the gentle oscillation of the decolorizing shaking table can ensure the uniform reaction of reagents; when carrying out biological experiments such as cell culture and bacterial culture, the stable operation of the orbital shaking table can simulate a suitable growth environment. If there are strict requirements for temperature, the accurate temperature control function of the constant temperature incubation shaking table is indispensable, which ensures that the experimental conditions remain stable at all times.
The second step is to consider the characteristics of the sample, which is the key to equipment selection. The core function of the shaking table is to separate or culture the sample, and the inherent properties of the sample directly determine the adaptability of the equipment. For shaking tables used in mineral processing, the particle size and density of the ore are the core considerations. When the feed particle size is larger than 0.2mm, the large-gap screen surface of the coarse sand shaking table can avoid ore blockage and ensure the smooth transportation of materials; when the particle size is between 0.2-0.074mm, the fine separation structure of the fine sand shaking table can achieve more accurate separation; if the particle size is less than 0.074mm, the special bed surface design of the slime shaking table can effectively handle the fine slime and prevent material loss. At the same time, the greater the difference in ore density, the more significant the separation effect of the shaking table using the density difference. During the selection process, it is necessary to judge whether the equipment can exert the best separation efficiency based on the ore characteristics. For laboratory shaking tables, the size and weight of the sample are the key points. When using large-capacity culture flasks for experiments, a shaking table with a large amplitude should be selected to ensure the full mixing of the liquid in the flask; when processing micro-samples, a shaking table with a small amplitude can prevent the sample from splashing and ensure the experimental accuracy. In addition, it is also necessary to confirm whether the load capacity of the shaking table meets the requirements to prevent equipment failure caused by overloading and affecting the experimental process.
The third step is to pay attention to the equipment parameters and performance, which is the guarantee for equipment selection. High-quality parameters and stable performance are the prerequisites for the long-term and efficient operation of the shaking table, so it is necessary to carefully compare the equipment details. The power system of the mineral processing shaking table is particularly critical. The transmission structure composed of the motor, eccentric wheel and connecting rod at the head of the table must be able to provide continuous and stable reciprocating power to ensure the uniform and consistent separation process; the flexibility of the slope adjustment device is also indispensable. By flexibly adjusting the bed slope, it can adapt to the separation needs of different ores and improve the separation quality. At the same time, the energy consumption and durability of the equipment also need to be considered. The low-energy consumption design can reduce the operating cost of the enterprise, and the machine body made of high-strength materials can extend the service life of the equipment and reduce maintenance investment. The parameter requirements for laboratory shaking tables are more detailed. The adjustable range of the oscillation frequency needs to match the experimental requirements to ensure that oscillation effects of different intensities can be achieved; the temperature control range and accuracy directly affect the success or failure of biological experiments, so equipment with small temperature control errors should be selected; the amplitude and timing range need to be flexibly adjusted according to the experimental process to make the experimental operation more convenient and efficient.
