Descrição do produto
Specification:
| Modelo | Stage | Frequência | Power | Voltage | Current | Airflow | Vaccum | Compress | Noise | Weight | |
| 4HB3AC | Hz | KW | V | A | m3/h | mbar | mbar | dB(A) | Kg | ||
| 4HB420H26 | Double | 50 | 1.6 | 200-240Δ/345-415Y | 7.5Δ/4.3Y | 87 | -480 | 450 | 61 | 33 | |
| 60 | 2.05 | 220-275Δ/380-480Y | 7.6Δ/4.4Y | 105 | -430 | 410 | 66 | ||||
The list for all 4HB series:
| Modelo | Stage | Frequência | Power | Voltage | Current | Airflow | Vaccum | Compress | Noise | Weight | |
| 4HB 1AC | Hz | KW | V | A | m3/h | mbar | mbar | dB(A) | Kg | ||
| 4HB210A75 | Single | 50 | 0.55 | 200-240v | 3.1 | 47 | -230 | 290 | 57 | 18 | |
| 60 | 0.63 | 200-240v | 7.1 | 57 | -270 | 320 | 62 | ||||
| 4HB220A75 | Double | 50 | 1.5 | 200-240v | 9.7 | 47 | -370 | 600 | 58 | 30 | |
| 60 | 1.75 | 200-240v | 10.3 | 60 | -420 | 660 | 62 | ||||
| 4HB310A75 | Single | 50 | 0.94 | 200-240v | 7.6 | 66 | -250 | 350 | 57 | 18 | |
| 60 | 1.1 | 200-240v | 9 | 80 | -280 | 390 | 62 | ||||
| 4HB320A75 | Double | 50 | 1.5 | 200-240v | 9.7 | 65 | -400 | 550 | 59 | 32 | |
| 60 | 1.75 | 200-240v | 10.3 | 76 | -390 | 540 | 53 | ||||
| 4HB410A41 | Single | 50 | 1.1 | 200-240v | 10.1 | 87 | -300 | 380 | 55 | 23 | |
| 60 | 1.3 | 200-240v | 10.3 | 105 | -350 | 390 | 62 | ||||
| 4HB420A31 | Double | 50 | 1.5 | 200-240v | 9.7 | 87 | -460 | 430 | 61 | 34 | |
| 60 | 1.75 | 200-240v | 10.3 | 105 | -430 | 410 | 66 | ||||
| Modelo | Stage | Frequência | Power | Voltage | Current | Airflow | Vaccum | Compress | Noise | Weight | |
| 4HB3AC | Hz | KW | V | A | m3/h | mbar | mbar | dB(A) | Kg | ||
| 4HB420H26 | Double | 50 | 1.6 | 200-240Δ/345-415Y | 7.5Δ/4.3Y | 87 | -480 | 450 | 61 | 33 | |
| 60 | 2.05 | 220-275Δ/380-480Y | 7.6Δ/4.4Y | 105 | -430 | 410 | 66 | ||||
| 4HB420H56 | Double | 50 | 3.3 | 200-240Δ/345-415Y | 13Δ/7.5Y | 87 | -500 | 750 | 61 | 39 | |
| 60 | 3.8 | 220-275Δ/380-480Y | 13.8Δ8Y | 105 | -510 | 850 | 66 | ||||
| 4HB520H26 | Double | 50 | 2.2 | 200-240Δ/345-415Y | 11.4Δ/6.6Y | 120 | -470 | 460 | 64 | 40 | |
| 60 | 2.55 | 220-275Δ/380-480Y | 11.2Δ/6.5Y | 145 | -500 | 450 | 70 | ||||
| 4HB520H77 | Double | 50 | 4.3 | 345-415Δ | 9.5Δ | 120 | -500 | 820 | 65 | 51 | |
| 60 | 4.8 | 380-480Δ | 10Δ | 145 | -530 | 810 | 71 | ||||
| 4HB620H36 | Double | 50 | 3.3 | 200-240Δ/345-415Y | 13Δ/7.5Y | 165 | -460 | 500 | 67 | 48 | |
| 60 | 3.8 | 220-275Δ/380-480Y | 14.2Δ/8.2Y | 195 | -480 | 420 | 71 | ||||
| 4HB620H57 | Double | 50 | 5.7 | 345-415Δ | 12Δ | 165 | -460 | 740 | 68 | 65 | |
| 60 | 6.3 | 380-480Δ | 11.5Δ | 195 | -480 | 840 | 72 | ||||
| 4HB650H67 | Triple | 50 | 7.5 | 345-415Δ | 16Δ | 170 | -730 | 1040 | 72 | 86 | |
| 60 | 8.6 | 380-480Δ | 16Δ | 200 | -700 | 1040 | 76 | ||||
The advantages of CHINAMFG blowers:
1. 100% oil free, Insulation class is F, Protection class is IP55.
2. Dual frequency 50HZ and 60HZ are available
3. Made of die cast aluminum ADC12.
4. Dual usage: compressor and vacuum (suction and blow).
5. Virtually maintenance free, with sealed long life bearings.
6. Smart design and low noise
7. ATEX explosion proof motor is available for all the blowers.
8. IE2 and IE3 motor are available for some blowers.
9. Good quality and competitive prices.
10. Quick delivery date.
Application of CHINAMFG blowers/pumps:
Our blowers are widely used in the following applications.
1. CHINAMFG (fish and prawn pong aeration)
2. Waste water treatment, sewage treatment system.
3. Pneumatic conveying systems.
4. Pharmaceutical machinery
5. Garment machinery
6. Wood working machinery
7. Plastic machinery
8. Printing machinery
9. Textile machinery
10. Packaging machinery
11. Garment machinery
12. Paper processing.
13. Industrial cleaning machinery
14. Air knives
15. Dental suction equipment / dental vacuum pump
Our workshop:
Our Exhibition:
Our certification: (CE, ISO & CCC)
The instruction for CHINAMFG blowers:
The team of CHINAMFG has focused on this kind of blower for more than 15 years. We only produce side channel blowers, it’s also called ring blower, regenerative blower, air blower, vacuum pump etc.. We also supply belt drive blowers and all the parts for this kind of blower. The range of the power for our blowers is from 0.12kw to 30kw.
Each production procedure is operated in our own workshop, tooling making, die casting, stamping, high precision machining, assembling and automatic spraying, so we could control the quality, cost and delivery date better.
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| Serviço pós-venda: | Yes |
|---|---|
| Garantia: | One Year |
| Óleo ou não: | Oil Free |
| Estrutura: | Centrifugal |
| Método do exaustor: | Bomba de vácuo de aprisionamento |
| Grau de vácuo: | Vacuum |
| Samples: |
US$ 367/Piece
1 Piece(Min.Order) | |
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| Personalização: |
Disponível
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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.
How Do Vacuum Pumps Impact the Quality of 3D Printing?
Vacuum pumps play a significant role in improving the quality and performance of 3D printing processes. Here’s a detailed explanation:
3D printing, also known as additive manufacturing, is a process of creating three-dimensional objects by depositing successive layers of material. Vacuum pumps are utilized in various aspects of 3D printing to enhance the overall quality, accuracy, and reliability of printed parts. Here are some key ways in which vacuum pumps impact 3D printing:
1. Material Handling and Filtration: Vacuum pumps are used in 3D printing systems to handle and control the flow of materials. They create the necessary suction force to transport powdered materials, such as polymers or metal powders, from storage containers to the printing chamber. Vacuum systems also assist in filtering and removing unwanted particles or impurities from the material, ensuring the purity and consistency of the feedstock. This helps to prevent clogging or contamination issues during the printing process.
2. Build Plate Adhesion: Proper adhesion of the printed object to the build plate is crucial for achieving dimensional accuracy and preventing warping or detachment during the printing process. Vacuum pumps are employed to create a vacuum environment or suction force that securely holds the build plate and ensures firm adhesion between the first layer of the printed object and the build surface. This promotes stability and minimizes the risk of layer shifting or deformation during the printing process.
3. Material Drying: Many 3D printing materials, such as filament or powdered polymers, can absorb moisture from the surrounding environment. Moisture-contaminated materials can lead to poor print quality, reduced mechanical properties, or defects in the printed parts. Vacuum pumps with integrated drying capabilities can be employed to create a low-pressure environment, effectively removing moisture from the materials before they are used in the printing process. This ensures the dryness and quality of the materials, resulting in improved print outcomes.
4. Resin Handling in Stereolithography (SLA): In SLA 3D printing, a liquid resin is selectively cured using light sources to create the desired object. Vacuum pumps are utilized to facilitate the resin handling process. They can be employed to degas or remove air bubbles from the liquid resin, ensuring a smooth and bubble-free flow during material dispensing. This helps to prevent defects and imperfections caused by trapped air or bubbles in the final printed part.
5. Enclosure Pressure Control: Some 3D printing processes, such as selective laser sintering (SLS) or binder jetting, require the printing chamber to be maintained at a specific pressure or controlled atmosphere. Vacuum pumps are used to create a controlled low-pressure or vacuum environment within the printing chamber, enabling precise pressure regulation and maintaining the desired conditions for optimal printing results. This control over the printing environment helps to prevent oxidation, improve material flow, and enhance the quality and consistency of printed parts.
6. Post-Processing and Cleaning: Vacuum pumps can also aid in post-processing steps and cleaning of 3D printed parts. For instance, in processes like support material removal or surface finishing, vacuum systems can assist in the removal of residual support structures or excess powder from printed objects. They can also be employed in vacuum-based cleaning methods, such as vapor smoothing, to achieve smoother surface finishes and enhance the aesthetics of the printed parts.
7. System Maintenance and Filtration: Vacuum pumps used in 3D printing systems require regular maintenance and proper filtration to ensure their efficient and reliable operation. Effective filtration systems within the vacuum pumps help to remove any contaminants or particles generated during printing, preventing their circulation and potential deposition on the printed parts. This helps to maintain the cleanliness of the printing environment and minimize the risk of defects or impurities in the final printed objects.
In summary, vacuum pumps have a significant impact on the quality of 3D printing. They contribute to material handling and filtration, build plate adhesion, material drying, resin handling in SLA, enclosure pressure control, post-processing and cleaning, as well as system maintenance and filtration. By utilizing vacuum pumps in these critical areas, 3D printing processes can achieve improved accuracy, dimensional stability, material quality, and overall print quality.
Are There Different Types of Vacuum Pumps Available?
Yes, there are various types of vacuum pumps available, each designed to suit specific applications and operating principles. Here’s a detailed explanation:
Vacuum pumps are classified based on their operating principles, mechanisms, and the type of vacuum they can generate. Some common types of vacuum pumps include:
1. Rotary Vane Vacuum Pumps:
– Description: Rotary vane pumps are positive displacement pumps that use rotating vanes to create a vacuum. The vanes slide in and out of slots in the pump rotor, trapping and compressing gas to create suction and generate a vacuum.
– Applications: Rotary vane vacuum pumps are widely used in applications requiring moderate vacuum levels, such as laboratory vacuum systems, packaging, refrigeration, and air conditioning.
2. Diaphragm Vacuum Pumps:
– Description: Diaphragm pumps use a flexible diaphragm that moves up and down to create a vacuum. The diaphragm separates the vacuum chamber from the driving mechanism, preventing contamination and oil-free operation.
– Applications: Diaphragm vacuum pumps are commonly used in laboratories, medical equipment, analysis instruments, and applications where oil-free or chemical-resistant vacuum is required.
3. Scroll Vacuum Pumps:
– Description: Scroll pumps have two spiral-shaped scrolls—one fixed and one orbiting—which create a series of moving crescent-shaped gas pockets. As the scrolls move, gas is continuously trapped and compressed, resulting in a vacuum.
– Applications: Scroll vacuum pumps are suitable for applications requiring a clean and dry vacuum, such as analytical instruments, vacuum drying, and vacuum coating.
4. Piston Vacuum Pumps:
– Description: Piston pumps use reciprocating pistons to create a vacuum by compressing gas and then releasing it through valves. They can achieve high vacuum levels but may require lubrication.
– Applications: Piston vacuum pumps are used in applications requiring high vacuum levels, such as vacuum furnaces, freeze drying, and semiconductor manufacturing.
5. Turbo Molecular Vacuum Pumps:
– Description: Turbo pumps use high-speed rotating blades or impellers to create a molecular flow, continuously pumping gas molecules out of the system. They typically require a backing pump to operate.
– Applications: Turbo molecular pumps are used in high vacuum applications, such as semiconductor fabrication, research laboratories, and mass spectrometry.
6. Diffusion Vacuum Pumps:
– Description: Diffusion pumps rely on the diffusion of gas molecules and their subsequent removal by a high-speed jet of vapor. They operate at high vacuum levels and require a backing pump.
– Applications: Diffusion pumps are commonly used in applications requiring high vacuum levels, such as vacuum metallurgy, space simulation chambers, and particle accelerators.
7. Cryogenic Vacuum Pumps:
– Description: Cryogenic pumps use extremely low temperatures to condense and capture gas molecules, creating a vacuum. They rely on cryogenic fluids, such as liquid nitrogen or helium, for operation.
– Applications: Cryogenic vacuum pumps are used in ultra-high vacuum applications, such as particle physics research, material science, and fusion reactors.
These are just a few examples of the different types of vacuum pumps available. Each type has its advantages, limitations, and suitability for specific applications. The choice of vacuum pump depends on factors like required vacuum level, gas compatibility, reliability, cost, and the specific needs of the application.
editor by CX 2024-01-30
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