Descrição do produto
Industrial Vacuum Hydraulic Compressor Filter Press Centrifugal Pump for Wastewater
Descrição do produto
SYAX filter press feed pump
The SYAX filter press feed pump is a specially designed and developed filter press feed pump product that utilizes advanced fluid theory and combines the feed conditions of various filter press applications.After various trials in coal washing, environmental protection, aluminum plants, smelting and other fields, its performance has reached the leading level in China. Its pressure filtration effect, drying time, anti clogging performance of sewage and dirt, no leakage, and overall stability have all been praised by users. It has played a positive promoting role in improving efficiency for various users.
| Modelo | Flow rate m3/h | Head of delivery m | Speed r/min | Equipped with power kw |
| 50SYAX60-15 | 15-40 | 30-60 | 1480 | 15 |
| 50SYAX65-18.5 | 20-70 | 30-65 | 1480 | 18.5 |
| 50SYAX80-22 | 20-70 | 35-80 | 1480 | 22 |
| 50SYAX100-30 | 20-70 | 50-100 | 1480 | 30 |
| 65SYAX75-30 | 20-70 | 35-75 | 1480 | 30 |
| 65SYAX76-37 | 20-100 | 30-76 | 1480 | 37 |
| 65SYAX80-45 | 35-125 | 35-80 | 1480 | 45 |
| 80SYAX75Q-55 | 50-160 | 35-75 | 1480 | 55 |
| 100SYAX80-75 | 70-260 | 35-80 | 1480 | 75 |
| 100SYAX80-90 | 70-280 | 35-80 | 1480 | 90 |
| 150SYAX80-110 | 100-320 | 35-80 | 1480 | 110 |
SYB filter press feed pump
The SYB filter press feed pump is a new generation filter press pump designed and developed by our company based on the operating conditions of various filter presses. Adopting negative pressure technology and a double stage semi open impeller structure design, the maximum pressure of the pump can reach 1.6Mpa, suitable for feeding high-pressure filter presses. It can transport various materials with weak corrosiveness, hard particles, and poor filtration for a long time, as well as other situations that require high-pressure force to transport materials without blockage or leakage. Widely used in industries such as pharmaceuticals, wastewater treatment, papermaking, and nanomaterials.
| Modelo | Flow rate m3/h | Head of delivery m | Speed r/min | Equipped with power kw |
| 50SYB12.5-80 | 12.5 | 80 | 11 | 2900 |
| 5oSYB12.5-100 | 12.5 | 100 | 15 | 2900 |
| 5oSYB12.5-120 | 12.5 | 120 | 18.5 | 2900 |
| 5OSYB12.5-140 | 12.5 | 140 | 22 | 2900 |
| 50SYB12.5-160 | 12.5 | 160 | 30 | 2900 |
| 65SYB25-80 | 25 | 80 | 15 | 2900 |
| 65SYB25-100 | 25 | 100 | 18.5 | 2900 |
| 65SYB30-65 | 30 | 65 | 18.5 | 2900 |
| 65SYB25-120 | 25 | 120 | 22 | 2900 |
| 65SYB25-140 | 25 | 140 | 30 | 2900 |
| 65SYB25-160 | 25 | 160 | 37 | 2900 |
| 80SYB50-80 | 50 | 80 | 22 | 2900 |
| 80SYB50-100 | 50 | 100 | 30 | 2900 |
| 80SYB50-120 | 50 | 120 | 37 | 2900 |
| 80SYB50-140 | 50 | 140 | 45 | 2900 |
| 80SYB50-160 | 50 | 160 | 55 | 2900 |
SYC filter press feed pump
The SYC type filter press feed pump is a leak free filter press feed pump developed by our company. The unique negative pressure structure design makes the pump have the advantages of simple structure, stable performance, and no leakage during high lift operation. It is an updated product of rubber lined pump, F-type corrosion-resistant pump, H-chemical centrifugal pump, and fluorine alloy pump, suitable for conveying various corrosive liquid slurries with particles and viscosity in the process of filter press at a temperature of -10 ºC -120 ºC, Filler seals and double end mechanical seals are available for users to choose from.
| Modelo | Flow rate m3/h | Head of delivery m | Maximum pressure kg | Motor power kw | Speed r/min |
| 50SYC12.5-50 | 12.5 | 50 | 5 | 5.5/7.5 | 2900 |
| 50sYC12.5-60 | 12.5 | 60 | 6 | 7.5/11 | 2900 |
| 50SYC12.5-80 | 12.5 | 80 | 8 | 11/15 | 2900 |
| 60SYC25-32 | 25 | 32 | 3.2 | 5.5/7.5 | 2900 |
| 65SYC25-40 | 25 | 40 | 4 | 7.5/11 | 2900 |
| 65SYC25-50 | 25 | 50 | 5 | 11/15 | 2900 |
| 65SYC25-60 | 25 | 60 | 6 | 15/18.5 | 2900 |
| 65SYC25-80 | 25 | 80 | 8 | 18.5/22 | 2900 |
| 80SYC50-40 | 50 | 40 | 4 | 11/15 | 2900 |
| 80SYC50-50 | 50 | 50 | 5 | 15/18.5 | 2900 |
| 80SYC50-60 | 50 | 60 | 6 | 18.5/22 | 2900 |
| 80SYC50-80 | 50 | 80 | 8 | 22/30 | 2900 |
| 100SYC100-50 | 100 | 50 | 5 | 22/30 | 2900 |
| 100SYC100-60 | 100 | 60 | 6 | 30/37 | 2900 |
| 100SYC100-80 | 100 | 80 | 8 | 37/45 | 2900 |
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Application Range
1. Sewage treatment: sewage, sewage oil, sludge containing CHINAMFG substances, and various chemicals.
2. Chemical industry: acids, alkalis, salts, various viscous paste emulsions, forming ointments, dyes, pigments, inks, and paints.
3. Energy industry: various fuels (raw oil, crude oil, diesel), coal, water, coal slurry, coal slurry, and nuclear waste.
4. Paper industry: various cellulose and pulp, coatings, black liquor treatment, etc.
5. Ceramic Industry: Porcelain clay, refractory clay, glaze, bentonite, white carbon black.
6. Exploration and mining: various drilling mud, tunnel engineering, multiphase transportation of oil, water, and concrete.
| Serviço pós-venda: | Online Service |
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| Garantia: | 1 ano |
| Max.Head: | >150m |
| Max.Capacity: | 300-400 L/min |
| Driving Type: | Motor |
| Impeller Number: | Single-Stage Pump |
| Personalização: |
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Qual é o impacto da altitude no desempenho da bomba de vácuo?
O desempenho das bombas de vácuo pode ser influenciado pela altitude em que elas são operadas. Aqui está uma explicação detalhada:
Altitude refere-se à elevação ou altura acima do nível do mar. À medida que a altitude aumenta, a pressão atmosférica diminui. Essa diminuição da pressão atmosférica pode ter vários efeitos sobre o desempenho das bombas de vácuo:
1. Redução da capacidade de sucção: As bombas de vácuo dependem do diferencial de pressão entre o lado da sucção e o lado da descarga para criar um vácuo. Em altitudes mais elevadas, onde a pressão atmosférica é menor, o diferencial de pressão disponível para a bomba trabalhar é reduzido. Isso pode resultar em uma diminuição da capacidade de sucção da bomba de vácuo, o que significa que ela pode não ser capaz de atingir o mesmo nível de vácuo que atingiria em altitudes mais baixas.
2. Nível de vácuo final mais baixo: O nível de vácuo máximo, que representa a pressão mais baixa que uma bomba de vácuo pode atingir, também é afetado pela altitude. Como a pressão atmosférica diminui com o aumento da altitude, o nível de vácuo máximo que pode ser atingido por uma bomba de vácuo é limitado. A bomba pode ter dificuldade para atingir o mesmo nível de vácuo que atingiria no nível do mar ou em altitudes mais baixas.
3. Velocidade de bombeamento: A velocidade de bombeamento é uma medida da rapidez com que uma bomba de vácuo pode remover gases de um sistema. Em altitudes mais elevadas, a pressão atmosférica reduzida pode levar a uma diminuição na velocidade de bombeamento. Isso significa que a bomba de vácuo pode levar mais tempo para evacuar uma câmara ou sistema até o nível de vácuo desejado.
4. Aumento do consumo de energia: Para compensar a diminuição do diferencial de pressão e atingir o nível de vácuo desejado, uma bomba de vácuo operando em altitudes mais elevadas pode exigir maior consumo de energia. A bomba precisa trabalhar mais para superar a pressão atmosférica mais baixa e manter a capacidade de sucção necessária. Esse aumento no consumo de energia pode afetar a eficiência energética e os custos operacionais.
5. Variações de eficiência e desempenho: Diferentes tipos de bombas de vácuo podem apresentar diferentes graus de sensibilidade à altitude. As bombas de palhetas rotativas vedadas a óleo, por exemplo, podem apresentar variações de desempenho mais significativas em comparação com as bombas secas ou outras tecnologias de bombas. O projeto e os princípios operacionais da bomba de vácuo podem influenciar sua capacidade de manter o desempenho em altitudes mais elevadas.
É importante observar que os fabricantes de bombas de vácuo normalmente fornecem especificações e curvas de desempenho para suas bombas com base em condições padronizadas, geralmente no nível do mar ou próximo a ele. Ao operar uma bomba de vácuo em altitudes mais elevadas, é aconselhável consultar as diretrizes do fabricante e considerar quaisquer limitações ou ajustes relacionados à altitude que possam ser necessários.
Em resumo, a altitude em que uma bomba de vácuo opera pode ter um impacto em seu desempenho. A pressão atmosférica reduzida em altitudes mais elevadas pode resultar na diminuição da capacidade de sucção, em níveis mais baixos de vácuo final, na redução da velocidade de bombeamento e no possível aumento do consumo de energia. Compreender esses efeitos é fundamental para selecionar e operar bombas de vácuo de forma eficaz em diferentes ambientes de altitude.
Can Vacuum Pumps Be Used for Leak Detection?
Yes, vacuum pumps can be used for leak detection purposes. Here’s a detailed explanation:
Leak detection is a critical task in various industries, including manufacturing, automotive, aerospace, and HVAC. It involves identifying and locating leaks in a system or component that may result in the loss of fluids, gases, or pressure. Vacuum pumps can play a significant role in leak detection processes by creating a low-pressure environment and facilitating the detection of leaks through various methods.
Here are some ways in which vacuum pumps can be used for leak detection:
1. Vacuum Decay Method: The vacuum decay method is a common technique used for leak detection. It involves creating a vacuum in a sealed system or component using a vacuum pump and monitoring the pressure change over time. If there is a leak present, the pressure will gradually increase due to the ingress of air or gas. By measuring the rate of pressure rise, the location and size of the leak can be estimated. Vacuum pumps are used to evacuate the system and establish the initial vacuum required for the test.
2. Bubble Testing: Bubble testing is a simple and visual method for detecting leaks. In this method, the component or system being tested is pressurized with a gas, and then immersed in a liquid, typically soapy water. If there is a leak, the gas escaping from the component will form bubbles in the liquid, indicating the presence and location of the leak. Vacuum pumps can be used to create a pressure differential that forces gas out of the leak, making it easier to detect the bubbles.
3. Helium Leak Detection: Helium leak detection is a highly sensitive method used to locate extremely small leaks. Helium, being a small atom, can easily penetrate small openings and leaks. In this method, the system or component is pressurized with helium gas, and a vacuum pump is used to evacuate the surrounding area. A helium leak detector is then used to sniff or scan the area for the presence of helium, indicating the location of the leak. Vacuum pumps are essential for creating the low-pressure environment required for this method and ensuring accurate detection.
4. Pressure Change Testing: Vacuum pumps can also be used in pressure change testing for leak detection. This method involves pressurizing a system or component and then isolating it from the pressure source. The pressure is monitored over time, and any significant pressure drop indicates the presence of a leak. Vacuum pumps can be used to evacuate the system after pressurization, returning it to atmospheric pressure for comparison or retesting.
5. Mass Spectrometer Leak Detection: Mass spectrometer leak detection is a highly sensitive and precise method used to identify and quantify leaks. It involves introducing a tracer gas, usually helium, into the system or component being tested. A vacuum pump is used to evacuate the surrounding area, and a mass spectrometer is employed to analyze the gas samples for the presence of the tracer gas. This method allows for accurate detection and quantification of leaks down to very low levels. Vacuum pumps are crucial for creating the necessary vacuum conditions and ensuring reliable results.
In summary, vacuum pumps can be effectively used for leak detection purposes. They facilitate various leak detection methods such as vacuum decay, bubble testing, helium leak detection, pressure change testing, and mass spectrometer leak detection. Vacuum pumps create the required low-pressure environment, assist in evacuating the system or component being tested, and enable accurate and reliable leak detection. The choice of vacuum pump depends on the specific requirements of the leak detection method and the sensitivity needed for the application.
How Do You Choose the Right Size Vacuum Pump for a Specific Application?
Choosing the right size vacuum pump for a specific application involves considering several factors to ensure optimal performance and efficiency. Here’s a detailed explanation:
1. Required Vacuum Level: The first consideration is the desired vacuum level for your application. Different applications have varying vacuum level requirements, ranging from low vacuum to high vacuum or even ultra-high vacuum. Determine the specific vacuum level needed, such as microns of mercury (mmHg) or pascals (Pa), and choose a vacuum pump capable of achieving and maintaining that level.
2. Pumping Speed: The pumping speed, also known as the displacement or flow rate, is the volume of gas a vacuum pump can remove from a system per unit of time. It is typically expressed in liters per second (L/s) or cubic feet per minute (CFM). Consider the required pumping speed for your application, which depends on factors such as the volume of the system, the gas load, and the desired evacuation time.
3. Gas Load and Composition: The type and composition of the gas or vapor being pumped play a significant role in selecting the right vacuum pump. Different pumps have varying capabilities and compatibilities with specific gases. Some pumps may be suitable for pumping only non-reactive gases, while others can handle corrosive gases or vapors. Consider the gas load and its potential impact on the pump’s performance and materials of construction.
4. Backing Pump Requirements: In some applications, a vacuum pump may require a backing pump to reach and maintain the desired vacuum level. A backing pump provides a rough vacuum, which is then further processed by the primary vacuum pump. Consider whether your application requires a backing pump and ensure compatibility and proper sizing between the primary pump and the backing pump.
5. System Leakage: Evaluate the potential leakage in your system. If your system has significant leakage, you may need a vacuum pump with a higher pumping speed to compensate for the continuous influx of gas. Additionally, consider the impact of leakage on the required vacuum level and the pump’s ability to maintain it.
6. Power Requirements and Operating Cost: Consider the power requirements of the vacuum pump and ensure that your facility can provide the necessary electrical supply. Additionally, assess the operating cost, including energy consumption and maintenance requirements, to choose a pump that aligns with your budget and operational considerations.
7. Size and Space Constraints: Take into account the physical size of the vacuum pump and whether it can fit within the available space in your facility. Consider factors such as pump dimensions, weight, and the need for any additional accessories or support equipment.
8. Manufacturer’s Recommendations and Expert Advice: Consult the manufacturer’s specifications, guidelines, and recommendations for selecting the right pump for your specific application. Additionally, seek expert advice from vacuum pump specialists or engineers who can provide insights based on their experience and knowledge.
By considering these factors and evaluating the specific requirements of your application, you can select the right size vacuum pump that meets the desired vacuum level, pumping speed, gas compatibility, and other essential criteria. Choosing the appropriate vacuum pump ensures efficient operation, optimal performance, and longevity for your application.
editor by CX 2023-11-19
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