氣力輸送系統(tǒng)的阻力是物料在管道內(nèi)被氣流輸送時(shí)受到的各種阻礙力總和，直接影響輸送能耗、氣流速度選擇與管道設(shè)計(jì)。這些阻力由多種因素共同作用形成，了解其組成有助于優(yōu)化系統(tǒng)參數(shù)、降低運(yùn)行成本，確保物料穩(wěn)定高效輸送。

　　The resistance of a pneumatic conveying system is the sum of various hindering forces experienced by materials when transported by airflow in a pipeline, which directly affects the energy consumption, airflow velocity selection, and pipeline design of the conveying system. These resistances are formed by the combined action of multiple factors, and understanding their composition can help optimize system parameters, reduce operating costs, and ensure stable and efficient material transportation.

　　物料與管道的摩擦阻力是核心組成，源于物料顆粒對(duì)管道內(nèi)壁的撞擊與摩擦。物料在氣流帶動(dòng)下運(yùn)動(dòng)時(shí)，顆粒會(huì)因氣流速度分布不均向管壁偏移，較大顆粒還會(huì)因重力貼近管壁滑動(dòng)或滾動(dòng)，持續(xù)與管壁作用。這種阻力與物料特性密切相關(guān)：硬度高、棱角鋒利的物料，對(duì)管壁磨損更嚴(yán)重，阻力更大；顆粒粒徑越大、密度越高，阻力隨之增加。管道特性也有影響，內(nèi)壁粗糙的管道比光滑管道阻力大，管道轉(zhuǎn)彎處因顆粒撞擊，阻力會(huì)突然增大，尤其在直角彎頭處更為明顯。

　　The frictional resistance between materials and pipelines is the core component, originating from the impact and friction of material particles on the inner wall of the pipeline. When materials move under the influence of airflow, particles will shift towards the pipe wall due to uneven distribution of airflow velocity. Larger particles will also slide or roll close to the pipe wall due to gravity, continuously interacting with the pipe wall. This resistance is closely related to the characteristics of the material: materials with high hardness and sharp edges have more severe wear on the pipe wall and greater resistance; The larger the particle size and density, the higher the resistance. The characteristics of pipelines also have an impact. Pipelines with rough inner walls have greater resistance than smooth pipelines. At the turning points of pipelines, the resistance will suddenly increase due to particle impact, especially at right angled bends.

　　氣流流動(dòng)產(chǎn)生的阻力包括沿程阻力與局部阻力。沿程阻力是氣流在直管段內(nèi)流動(dòng)時(shí)，因氣體分子內(nèi)摩擦及與管壁摩擦產(chǎn)生的能量損耗，與管道長(zhǎng)度、氣流速度、管道直徑相關(guān)：管道越長(zhǎng)，沿程阻力累積越大；氣流速度越高，阻力隨之上升；管道直徑越小，阻力也越大。局部阻力出現(xiàn)在氣流狀態(tài)突變位置，如管道入口、出口、閥門(mén)、變徑處等，這些位置氣流會(huì)產(chǎn)生渦流、沖擊或流速突變，導(dǎo)致能量損失。系統(tǒng)中的過(guò)濾器、分離器等設(shè)備，也會(huì)因改變氣流狀態(tài)產(chǎn)生局部阻力。

　　The resistance generated by airflow includes along path resistance and local resistance. Along the way resistance refers to the energy loss caused by the friction between gas molecules and the pipe wall when the airflow flows in a straight pipe section. It is related to the length of the pipeline, the velocity of the airflow, and the diameter of the pipeline: the longer the pipeline, the greater the accumulated along the way resistance; The higher the airflow velocity, the higher the resistance; The smaller the diameter of the pipeline, the greater the resistance. Local resistance occurs at locations where there is a sudden change in the airflow state, such as the inlet, outlet, valve, and variable diameter of the pipeline. At these locations, the airflow can generate vortices, impacts, or sudden changes in flow velocity, resulting in energy loss. The filters, separators, and other equipment in the system can also generate local resistance due to changes in the airflow state.

　　物料懸浮與加速所需能量形成的阻力，是有效輸送的必要消耗。氣流需克服物料重力使顆粒懸浮，同時(shí)將靜止物料加速至與氣流相近速度，這兩個(gè)過(guò)程都消耗能量。密度大、粒徑粗的物料，懸浮所需氣流速度更高，阻力更大；輸送初始階段，物料從靜止被加速，加速阻力最明顯，隨著物料速度接近氣流速度，阻力逐漸減小。物料濃度增加時(shí)，懸浮和加速所需能量上升，阻力也隨之增大。

　　The resistance formed by the energy required for material suspension and acceleration is a necessary consumption for effective transportation. The airflow needs to overcome the gravity of the material to suspend the particles, while accelerating the stationary material to a velocity similar to that of the airflow, both of which consume energy. Materials with high density and coarse particle size require higher airflow velocity and greater resistance for suspension; In the initial stage of transportation, the material is accelerated from rest, and the acceleration resistance is most obvious. As the material velocity approaches the airflow velocity, the resistance gradually decreases. When the material concentration increases, the energy required for suspension and acceleration increases, and the resistance also increases accordingly.

　　物料之間的相互作用產(chǎn)生的阻力，在高濃度輸送時(shí)尤為顯著。管道內(nèi)物料濃度較高時(shí)，顆粒距離縮小，會(huì)發(fā)生頻繁碰撞、摩擦甚至團(tuán)聚，形成額外阻力。較小顆?？赡芪叫纬蓤F(tuán)塊，增大阻力；較大顆粒會(huì)推開(kāi)周圍小顆粒，消耗更多能量。這種相互作用還會(huì)導(dǎo)致氣流速度分布紊亂，加劇能量損耗，輸送粘性物料時(shí)，顆粒易粘結(jié)形成絮團(tuán)，使阻力急劇增加，甚至造成管道堵塞。

　　The resistance generated by the interaction between materials is particularly significant during high concentration transportation. When the concentration of materials in the pipeline is high, the distance between particles decreases, resulting in frequent collisions, friction, and even agglomeration, forming additional resistance. Smaller particles may adsorb and form clumps, increasing resistance; Larger particles will push away smaller particles around them, consuming more energy. This interaction can also cause turbulence in the distribution of airflow velocity, exacerbate energy loss, and when transporting viscous materials, particles are prone to bond and form flocs, leading to a sharp increase in resistance and even causing pipeline blockage.

　　系統(tǒng)漏風(fēng)與壓力損失形成的阻力，在實(shí)際運(yùn)行中普遍存在。系統(tǒng)若管道連接處密封不良，會(huì)出現(xiàn)漏風(fēng)：正壓系統(tǒng)漏風(fēng)導(dǎo)致管道內(nèi)壓力下降，需消耗更多能量維持流速，增加阻力；負(fù)壓系統(tǒng)漏風(fēng)使外部空氣進(jìn)入，稀釋物料濃度，增加風(fēng)機(jī)負(fù)荷。此外，系統(tǒng)中的分離器、除塵器等設(shè)備若堵塞或過(guò)濾效率下降，會(huì)導(dǎo)致壓力損失增大，形成額外阻力。

　　The resistance caused by system air leakage and pressure loss is commonly present in actual operation. If the sealing at the pipeline connection of the system is poor, air leakage may occur: air leakage in the positive pressure system leads to a decrease in pressure inside the pipeline, requiring more energy to maintain flow rate and increase resistance; The negative pressure system leaks air, causing external air to enter, diluting material concentration, and increasing fan load. In addition, if the separators, dust collectors and other equipment in the system are blocked or the filtration efficiency decreases, it will lead to an increase in pressure loss and the formation of additional resistance.

　　氣力輸送系統(tǒng)總阻力是多種阻力的疊加，設(shè)計(jì)時(shí)需綜合考慮各部分影響，通過(guò)合理選擇管道材質(zhì)、優(yōu)化布局、匹配氣流速度與物料濃度降低總阻力。運(yùn)行中定期維護(hù)，也能有效控制阻力增長(zhǎng)，確保系統(tǒng)長(zhǎng)期高效運(yùn)行。

　　The total resistance of a pneumatic conveying system is the superposition of multiple resistances. When designing, it is necessary to comprehensively consider the influence of each part, and reduce the total resistance by selecting pipeline materials reasonably, optimizing layout, matching airflow velocity and material concentration. Regular maintenance during operation can effectively control resistance growth and ensure long-term efficient operation of the system.

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