Bomba de purín de cabeza alta WG
Introdución da bomba
ESPECIFICACIÓNS:
Tamaño: 65-300 mm
Capacidade: 37-1919m3/h
Cabeza: 5-94 m
Manipulación de sólidos: 0-90 mm
Concentración: máx. 70%
Presión máx.: máx. 4,5 mpa
Materiais: aliaxe hipercromada, etc.
AIER® WG High Efficiency Slurry Pump
In order to meet the requirements on the development of the electric power, metallurgy and coal industries, our company has designed and developed WG(P) Series up-to-date general slurry pump with large capacity, high head, multi-stages in series to remove ash & sludge and to deliver liquid-solids mixture, based on the experience of slurry pump design and manufacture for many years, and abstracting the research results of advanced technology from home and abroad.
características
deseño moderno CAD, rendemento súper hidráulico, alta eficiencia e menor taxa de abrasión;
Paso amplo, non obstrución e bo rendemento de NPSH;
Adoptáronse o selo de expulsión combinado co selo de embalaxe e o selo mecánico para garantir a fuga de purín;
O deseño de fiabilidade garante MTBF longo (tempo medio entre eventos);
O rolamento métrico con lubricación con aceite, sistemas de lubricación e refrixeración razoables garanten que o rodamento funcione a baixa temperatura;
Os materiais das pezas húmidas teñen un bo rendemento de antidesgaste e anticorrosión;
A bomba pódese usar para eliminar as cinzas da auga do mar para evitar a corrosión da auga do mar, o sal e a néboa e a corrosión electroquímica;
A bomba pode funcionar en serie con varias etapas dentro da presión permitida.
A bomba ten as vantaxes dunha construción razoable, alta eficiencia, funcionamento fiable e fácil mantemento. Pódese usar amplamente para manipular a mestura contida de sólidos abrasivos e corrosivos nos departamentos de enerxía eléctrica, metalurxia, minas, carbón, materiais de construción e industria química, especialmente para eliminar cinzas e lodos na central eléctrica.
Notación da bomba
100 WG(P):
100: Diámetro de saída (mm)
WG: Bomba de lodos de alta altura
P: Bombas de varias etapas (1-2 etapas sen marca)
A bomba de lodo WG é horizontal, dunha soa etapa, de succión única, en voladizo, dobre carcasa, bomba de lodo centrífuga. A bomba xira no sentido das agullas do reloxo vista desde o extremo da unidade.
As partes húmidas da bomba WG e WGP co mesmo diámetro de saída poden ser intercambiables. As súas dimensións de instalación son as mesmas. Para a parte de accionamento da bomba de purín WG(P), adoptouse o marco dividido horizontal con lubricación de aceite e dous conxuntos de sistemas de refrixeración por auga dentro e fóra. Se é necesario, pódese subministrar auga de refrixeración. A xunta preparada para a auga de refrixeración e a presión da auga de refrixeración pódense ver na táboa 1.
Two kinds of shaft seal – expeller seal combined with packing and mechanical seal.
O selo mecánico subministrado con auga de selado de alta presión recoméndase cando a bomba funciona en serie, e o selo do expulsor combinado coa embalaxe úsase na bomba dunha etapa.
A presión da auga e a cantidade de todo tipo de selado do eixe é a seguinte:
1) Presión de auga de selado
Para a bomba dunha etapa con selado de expulsión combinada con embalaxe, a presión da auga do selado do eixe é de 0,2-0,3 Mpa.
Para o funcionamento en serie de varias etapas co selo de expulsión combinado coa empaquetadura, a presión da auga de selado debe ser: A presión de auga de selado máis baixa de n etapa =
Hi + 0.7Hn Where: n ≥2.
Para o selado mecánico, a presión da auga de selado de cada etapa da bomba é superior a 0.1Mpa que a presión na saída da bomba.
2) Presión de auga de selado (ver táboa 1)
Táboa 1: parámetros da auga de selado
| Tipo de bomba | Marco | Auga de selado (l/s) |
Selado de xuntas de auga | Xunta de auga de refrixeración No cadro |
Presión da auga de refrixeración |
| 65 WG | 320 | 0.5 | 1/4" | 1/2", 3/8" | 0,05 a 0,2 MPa |
| 80 WG | 406 | 0.7 | 1/2" | 3/4", 1/2" | |
| 100 WG | |||||
| 80 WGP | 406A | ||||
| 100 WGP | |||||
| 150 WG | 565 | 1.2 | 1/2" | 3/4", 3/4" | |
| 200 WG | |||||
| 150 WGP | 565A | ||||
| 200 WGP | |||||
| 250 WG | 743 | 1" | |||
| 300 WG | |||||
| 250 WGP | 743A |
Deseño de construción
Material da parte da bomba
| Nome da peza | Material | Especificación | HRC | Aplicación | Código OEM |
| Forros e impulsor | Metal | AB27: 23%-30% ferro branco cromado | ≥56 | Úsase para condicións de maior desgaste con pH entre 5 e 12 | A05 |
| AB15: 14%-18% ferro branco cromado | ≥59 | Usado para condicións de maior desgaste | A07 | ||
| AB29: 27%-29% ferro branco cromado | 43 | Usado para condicións de pH máis baixos, especialmente para FGD. Tamén se pode usar para instalacións de desulfuración e condicións de baixa acidez cun pH non inferior a 4 | A49 | ||
| AB33: 33%-37% ferro branco cromado | Pode transportar purín osixenado cun pH non inferior a 1 como xeso fosforico, ácido nítrico, vitriolo, fosfato, etc. | A33 | |||
| Expulsor e anel de expulsión | Metal | B27: 23%-30% ferro branco cromado | ≥56 | Úsase para condicións de maior desgaste con pH entre 5 e 12 | A05 |
| Ferro gris | G01 | ||||
| Caixa de recheo | Metal | AB27: 23%-30% ferro branco cromado | ≥56 | Úsase para condicións de maior desgaste con pH entre 5 e 12 | A05 |
| Ferro gris | G01 | ||||
| Marco/placa de cuberta, caseta de rodamentos e base | Metal | Ferro gris | G01 | ||
| Ferro dúctil | D21 | ||||
| Eixo | Metal | Aceiro carbono | E05 | ||
| Manga do eixe, anel de lanterna/restrictor, anel de pescozo, parafuso da glándula | Aceiro inoxidable | 4Cr13 | C21 | ||
| 304 SS | C22 | ||||
| 316 SS | C23 | ||||
| Selos e aneis de unión | Goma | Butilo | S21 | ||
| Caucho EPDM | S01 | ||||
| Nitrilo | S10 | ||||
| Hypalon | S31 | ||||
| Neopreno | S44/S42 | ||||
| Viton | S50 |
Curva de rendemento
Dimensións de instalación
The Role of High Head Slurry Pumps in Long-Distance Slurry Transport Systems
A high head slurry pump plays a pivotal role in transporting abrasive and dense slurries over long distances and significant vertical heights. Unlike standard industrial slurry pumps, high head pumps are specifically engineered to provide the increased pressure necessary for long pipeline systems, ensuring the efficient and consistent movement of solids-laden fluids.
In industries such as mining, mineral processing, coal preparation, and dredging, materials often need to be transported through extended pipelines, sometimes spanning hundreds of meters. The combination of high solids content, abrasive particles, and long transport distances makes conventional pumps unsuitable, as they may fail under high head conditions or suffer from excessive wear. A high head slurry pump addresses these challenges by delivering reliable performance while maintaining operational efficiency.
The design of a high head slurry pump emphasizes durability and resistance to wear. Casings and impellers are often made of high-chrome alloys or wear-resistant metals, allowing the pump to handle abrasive slurries with minimal erosion. Many slurry pump manufacturers also offer customizable options, such as modular impellers and liners, enabling easy maintenance and replacement, thereby reducing downtime and maintenance costs.
Additionally, high head slurry pumps are engineered for optimal hydraulic performance. Their impeller and volute designs minimize energy loss, allowing slurries to be transported at higher pressures without overloading the motor or increasing operational costs. This energy-efficient design is particularly important in industrial settings, where large volumes of slurry must be moved continuously over extended distances.
Applications of high head slurry pumps include tailings disposal, long-distance slurry transport from mines to processing plants, and chemical slurry movement in metallurgical operations. Their ability to sustain high pressures and manage abrasive fluids reliably makes them a critical component in industrial processes.
In conclusion, a high head slurry pump is essential for long-distance slurry transport systems, offering high pressure, durability, and efficiency. Selecting a reliable slurry pump manufacturer ensures that your plant receives a customized, high-performance solution tailored to demanding industrial applications.
How High Head Slurry Pumps Improve Efficiency in Mining and Processing Plants
Mining and mineral processing plants require robust equipment capable of handling abrasive slurries with high solids content. A high head slurry pump is integral in these facilities, enhancing efficiency, reducing energy consumption, and minimizing maintenance needs. By delivering high pressure and flow over long distances, these pumps streamline material handling and improve overall plant productivity.
In mining operations, tailings and ore slurries often need to be transported from extraction sites to processing plants or storage areas. A high head slurry pump is specifically designed to handle this workload, maintaining consistent flow rates even with challenging slurry compositions. This ensures that production lines run smoothly without bottlenecks or downtime caused by pump failure.
The efficiency of a high head slurry pump also translates to energy savings. Advanced impeller designs and optimized hydraulic profiles reduce friction losses and pump energy requirements. Many industrial slurry pumps from reputable slurry pump manufacturers are designed with high efficiency in mind, allowing plants to lower operational costs while maintaining the required throughput.
Maintenance is another area where high head slurry pumps provide advantages. These pumps are constructed with wear-resistant materials such as high-chrome alloys or alloy steels, minimizing erosion from abrasive particles. Replaceable liners and impellers allow maintenance teams to perform targeted repairs without dismantling the entire pump system, reducing downtime and labor costs.
Furthermore, these pumps are available in various configurations, including horizontal and vertical designs, enabling flexible installation in confined or challenging spaces. The modular construction also supports scalability, allowing mining and processing plants to adjust pump capacity as operational needs evolve.
In summary, using a high head slurry pump in mining and processing plants improves slurry transport efficiency, reduces energy consumption, and minimizes maintenance costs. Partnering with a reliable slurry pump manufacturer ensures access to high-quality, durable pumps capable of withstanding abrasive industrial conditions while delivering long-term performance.
Material Selection for High Head Slurry Pumps: Metal vs Alloy
Selecting the appropriate material for a high head slurry pump is crucial to maximize performance, wear resistance, and operational lifespan. Industrial applications often involve abrasive and corrosive slurries, which can quickly erode or damage pumps made from unsuitable materials. Choosing between metal and alloy construction depends on the specific process requirements and the slurry’s characteristics.
Traditional metal slurry pumps are typically made of ductile iron or stainless steel, offering robust structural strength and corrosion resistance. These materials are suitable for moderate abrasiveness and provide reliable long-term service. However, in highly abrasive conditions, such as those found in mining or mineral processing, standard metals may wear quickly, leading to reduced efficiency and increased maintenance costs.
Alloy construction, especially high-chrome or nickel-chrome alloys, offers superior wear resistance and hardness, making them ideal for heavy-duty industrial slurry transport. A high head slurry pump made from these materials can handle slurries with high solids concentrations and large particle sizes without rapid erosion. The enhanced durability ensures continuous operation with minimal downtime, which is essential for high-capacity industrial processes.
Many slurry pump manufacturers offer modular designs that allow clients to choose between metal or alloy liners and impellers based on operational needs. This flexibility enables plants to optimize pump longevity and reduce maintenance frequency. Additionally, alloy materials can improve hydraulic performance by maintaining smooth surfaces within the pump, reducing energy losses and improving overall efficiency.
The selection of materials also impacts cost-effectiveness. While alloy pumps may have higher initial investment costs compared to standard metals, their extended service life and reduced maintenance requirements often result in lower total operational costs over time. Industrial facilities that prioritize reliability and efficiency benefit significantly from investing in high-quality alloy high head slurry pumps.
In conclusion, material selection for a high head slurry pump plays a decisive role in durability, efficiency, and cost-effectiveness. Whether using metal or alloy construction, choosing a reliable slurry pump manufacturer ensures that the pump is tailored to handle demanding industrial slurries while providing long-term operational performance.
Categorías de produtos
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Bomba de purín de alta resistencia WA
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Bomba de purín de cabeza alta WG
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Bomba de purín WL de carga lixeira
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Bomba de sumidoiro WY
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Bomba de purín de alta eficiencia WZ
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Bomba de dragado WN
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Bomba de purín de goma WAJ
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Bomba de area de grava WS, WSG
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Bomba de solución WS, WSH
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Bomba de sumidoiro WY
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Bomba TL, TLR FGD
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Bomba de espuma vertical WP
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Bombas de purín sumerxibles ZJQ
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BOMBA SUMERGIBLE QJ
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Bombas cerámicas de purín ACT (ZCT).
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Bombas cerámicas de purín BCT