Utilization rate of finished sand made by river pebble, river pebble sand making machine
The river pebble is hard in texture, with less stone powder content in the production process, stable material, good performance, strong compression resistance, wear resistance and corrosion resistance. It is easy to obtain high-quality machine-made sand by using river pebble as raw material to make sand. Because the stone itself contains a certain amount of soil impurities, and a small amount of stone powder will be produced during the sand making process, one ton of river pebble cannot produce one ton of sand, so how much sand can be produced? Which sand making machine is good for sand?
With the continuous development of the construction industry, due to the depletion of natural sand resources caused by excessive sand mining, rising raw material prices, and river environment, the construction sand market, especially natural sand, is seriously in short supply. Therefore, the market urgently needs to develop a machine-made sand equipment that can replace the natural sand to relieve the pressure of the construction industry, during this period, the river pebble sand making machine will definitely receive a lot of attention.
The 5X new sand making machine produced by SMMVIK is a special equipment for mechanical construction sand. It can not only produce high-quality sand and gravel bones for expressways, high-speed railways, high-rise buildings, municipal engineering, hydropower dam construction, port terminals, concrete mixing stations, etc. It has a wide range of applications in the fields of metal ore crushing, quartz sand production, and steel slag treatment. At present, it has become the preferred sand making equipment for domestic sand and gravel production enterprises, and is widely used in river pebble sand production, tailings sand production, construction waste sand production and other fields.
The outstanding performance of the new SMMVIK sand making machine is: after the optimized design of the deep cavity rotor, the material throughput can be increased by about 30%; after the partial wear of the peripheral guard plate, it can be used up and down, which can improve the utilization rate of materials and increase the service life by about 48%. The above; the combined hammer head design, only needs to replace the worn hammer head part, which can reduce the use cost by more than 30%. In addition, the auxiliary hammer head is added to effectively prevent the vertical plate from being damaged after the main hammer head is worn; the core wear-resistant material adopts highly wear-resistant and high-temperature resistant materials used in important industries in the United States.