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Vacuum Components
The various parts and devices that constitute a vacuum system are referred to as vacuum components. These include elements such as vacuum chambers, pumps, gauges, valves, fittings, and filters.
part#
description
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193479
vacuum generator VN-07-H-T3-PQ2-VQ2-RQ2 Standard, high vacuum, width 14 mm, T shape with push-in connector Nominal size, Laval nozzle: 0,7 mm, Grid dimension: 14 mm, Assembly position: Any, Ejector characteristic: (* High vacuum, * Standard), Design struc
Festo
STOCK: 12
Fast shipping526105
vacuum generator VN-07-H-T2-PI2-VI2-RO1 Standard, high vacuum width 10 mm, T shape with female thread and open silencer. Nominal size, Laval nozzle: 0,7 mm, Grid dimension: 10 mm, Design, silencer: open, Assembly position: Any, Ejector characteristic: (*
Festo
STOCK: 4
Fast shipping193572
vacuum generator VN-07-L-T3-PQ2-VQ2-RO1 Standard, high suction rate, width 14 mm, T shape with plug connector and open silencer. Nominal size, Laval nozzle: 0,7 mm, Grid dimension: 14 mm, Design, silencer: open, Assembly position: Any, Ejector characteris
Festo
STOCK: 1
Fast shipping19293
vacuum generator VAD-M5 Nominal size, Laval nozzle: 0,5 mm, Assembly position: Any, Ejector characteristic: High vacuum, Design structure: T-shaped, Operating pressure: 1,5 - 10 bar
Festo
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19294
vacuum generator VAD-3/8 Nominal size, Laval nozzle: 1,5 mm, Assembly position: Any, Ejector characteristic: High vacuum, Design structure: T-shaped, Operating pressure: 1,5 - 10 bar
Festo
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35533
vacuum generator VAD-ME-I-3/8 With integrated solenoid valve for vacuum On/Off and ejector pulse Nominal size, Laval nozzle: 2 mm, Assembly position: Any, Ejector characteristic: High vacuum, Integrated function: (* Ejector pulse valve, electrical, * Elec
Festo
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35553
vacuum generator VAD-MYB-1/8 With integrated solenoid valve Nominal size, Laval nozzle: 0,7 mm, Assembly position: Any, Ejector characteristic: High vacuum, Integrated function: Electrical on-off valve, Design structure: T-shaped
Festo
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171059
vacuum generator VADMI-140-LS-P With air-saving circuit and plug sockets with cable Nominal size, Laval nozzle: 1,4 mm, Grid dimension: 22 mm, Design, silencer: closed, Assembly position: Any, Ejector characteristic: High vacuum
Festo
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162504
vacuum generator VADM-200 With integrated solenoid valve for vacuum On/Off Nominal size, Laval nozzle: 2 mm, Grid dimension: 22 mm, Design, silencer: closed, Assembly position: Any, Ejector characteristic: High vacuum
Festo
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162522
vacuum generator VADM-300-P Nominal size, Laval nozzle: 3 mm, Grid dimension: 22 mm, Design, silencer: closed, Assembly position: Any, Ejector characteristic: High vacuum
Festo
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162518
vacuum generator VADM-140-P Nominal size, Laval nozzle: 1,4 mm, Grid dimension: 22 mm, Design, silencer: closed, Assembly position: Any, Ejector characteristic: High vacuum
Festo
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162506
vacuum generator VADMI-45 With integrated solenoid valve for vacuum On/Off and ejector pulse Nominal size, Laval nozzle: 0,45 mm, Grid dimension: 10 mm, Design, silencer: closed, Assembly position: Any, Ejector characteristic: High vacuum
Festo
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162533
vacuum generator VADMI-200-N With additional vacuum switch, NPN design Nominal size, Laval nozzle: 2 mm, Grid dimension: 22 mm, Design, silencer: closed, Assembly position: Any, Ejector characteristic: High vacuum
Festo
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162530
vacuum generator VADMI-140-P With additional vacuum switch, PNP design Nominal size, Laval nozzle: 1,4 mm, Grid dimension: 22 mm, Design, silencer: closed, Assembly position: Any, Ejector characteristic: High vacuum
Festo
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532720
vacuum generator VN-14-L-T4-PI5-VI5-RO2-A With ejector pulse. Standard, high suction rate, width 18 mm, T shape with female thread and open silencer. Nominal size, Laval nozzle: 1,4 mm, Grid dimension: 18 mm, Design, silencer: open, Assembly position: Any
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193549
vacuum generator VN-07-M-T3-PI4-VI4-RO1 In-line, high vacuum, width 14 mm, with female thread and open silencer. Nominal size, Laval nozzle: 0,7 mm, Grid dimension: 14 mm, Design, silencer: open, Assembly position: Any, Ejector characteristic: (* High vac
Festo
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193601
vacuum generator VN-10-L-T3-PQ2-VA4-RQ2 Standard, high suction rate, width 14 mm, T shape with push-in connector Vacuum connection with male thread. Nominal size, Laval nozzle: 0,95 mm, Grid dimension: 14 mm, Assembly position: Any, Ejector characteristic
Festo
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162505
vacuum generator VADM-300 With integrated solenoid valve for vacuum On/Off Nominal size, Laval nozzle: 3 mm, Grid dimension: 22 mm, Design, silencer: closed, Assembly position: Any, Ejector characteristic: High vacuum
Festo
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532627
vacuum generator VN-07-L-T3-PQ2-VQ2-RO1-M With built-in solenoid valve. Standard, high suction rate, width 14 mm, T shape with plug connector and open silencer. Nominal size, Laval nozzle: 0,7 mm, Grid dimension: 14 mm, Design, silencer: open, Assembly po
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193497
vacuum generator VN-30-H-T6-PQ4-VQ5-RO2 Standard, high vacuum, width 24 mm, T shape with push-in connector and open silencer Nominal size, Laval nozzle: 3 mm, Grid dimension: 24 mm, Design, silencer: open, Assembly position: Any, Ejector characteristic: (
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Vacuum Components
General Guide & Overview
A vacuum system consists of various components that work together to create and maintain a low-density gas environment. These components include vacuum chambers, vacuum pumps, vacuum gauges, and other related components.
Understanding these vacuum components is vital for maximizing the cleaning ability of the vacuum system. By selecting the right components and ensuring their proper functioning, you can optimize the system's performance.
Throughout this article, we will dive into topics such as gas loads, throughput, pumping speed, conductance, and the schematic symbols and diagrams associated with vacuum systems. All the information provided is sourced from reliable industry references, ensuring accuracy and reliability.
Whether you are new to vacuum systems or looking to enhance your knowledge, this guide will provide valuable insights into the components of a vacuum system and how they contribute to its functionality.
Introduction to Vacuum Systems
Vacuum systems play a crucial role in creating low-density gas environments for a wide range of processes. Understanding the basics of vacuum systems is essential for engineers, researchers, and technicians working in various industries.
Sources of Gas Load and Calculation
Gas load refers to the amount of gas present in a vacuum system that needs to be removed. In rough vacuum regimes, the primary sources of gas load are outgassing from surfaces, desorption of adsorbed gasses, and leaking of air through seals. In high vacuum regimes, the gas load is mainly due to residual gas molecules and backstreaming from the vacuum pump. Calculating the gas load is vital for determining the required pumping speed.
Net Pumping Speed and Throughput
Pumping speed refers to the gas flow rate that a vacuum pump can remove from a system. Net pumping speed takes into account the gas load and represents the effective pumping speed. Throughput, on the other hand, represents the volume of gas that can be processed by the vacuum system in a given time. Both pumping speed and throughput influence the efficiency and performance of the vacuum system.
Main Components of Vacuum Systems
Vacuum systems consist of several essential components that work together to create and maintain a vacuum environment. These components include vacuum chambers, vacuum pumps, vacuum gauges, and various other auxiliary equipment. Vacuum chambers provide the required space for carrying out processes under vacuum conditions. Vacuum pumps are responsible for removing gas from the system, while vacuum gauges measure and monitor the pressure levels inside the chamber. These key components ensure the proper functioning of vacuum systems.
Understanding the concepts of conductance and pumping speed is crucial for evaluating and selecting the appropriate vacuum components for a specific application. The following sections will delve deeper into the different types of vacuum components, providing insights into vacuum chamber design considerations, types of vacuum pumps, gauges, and other essential components.
Types of Vacuum Components
This section provides a detailed exploration of the different types of vacuum components that are crucial for the efficient operation of vacuum systems.
Vacuum Chambers
A vacuum chamber is a key component that creates and maintains a low-pressure environment by removing air and other gases. This section delves into the design considerations for vacuum chambers, such as material selection and sealing methods. It also explains the calculation of gas load associated with outgassing, which is essential for determining the required pumping speed.
Vacuum Pumps
Vacuum pumps are used to evacuate air and other gases from the vacuum chamber. This section explores the various types of vacuum pumps available for different vacuum regimes. It covers popular pump technologies such as rotary vane pumps, diaphragm pumps, and turbomolecular pumps, highlighting their advantages and applications.
Vacuum Gauges
Vacuum gauges are essential for measuring and monitoring the pressure in the vacuum chamber. This section discusses the different types of vacuum gauges, including ionization gauges, Pirani gauges, and capacitance manometers. It explains their working principles and the range of pressures they can accurately measure.
Other Vacuum Components
In addition to vacuum chambers, pumps, and gauges, there are several other components that play important roles in vacuum system design. This section explores components such as valves, fittings, and filters. It explains their functions and the considerations for their selection and integration into vacuum systems.
Understanding the different types of vacuum components is essential for building and maintaining efficient vacuum systems. By carefully selecting and utilizing the right vacuum chamber, vacuum pumps, vacuum gauges, and other components, users can ensure optimal performance and reliability in their vacuum applications.
Understanding of vacuum components is essential for the efficient operation of vacuum systems. The selection and proper functioning of these components significantly impact the cleaning ability of the system. By carefully considering factors such as motor input power, water lift, and airflow, users can make informed choices to ensure optimal performance.
When it comes to vacuum systems, achieving the desired level of cleanliness is of utmost importance. Vacuum components, such as vacuum chambers, pumps, and gauges, all contribute to the system's ability to effectively clean the desired area or surface. A well-designed system with properly selected components enhances the cleaning process, resulting in improved outcomes.
For those unfamiliar with vacuum components, seeking guidance from professionals in the field is highly recommended. These experts can provide valuable insights and assistance in selecting and installing the appropriate vacuum components for specific applications. This collaboration ensures that the chosen components are compatible with the system requirements, enabling efficient and effective cleaning.
FAQ
What are vacuum components?
Vacuum components are the different parts and devices that make up a vacuum system. They include vacuum chambers, vacuum pumps, vacuum gauges, valves, fittings, and filters.
What is a vacuum chamber?
A vacuum chamber is an enclosed space or container that is designed to create and maintain a low-pressure, low-density gas environment. It is used for various processes that require a vacuum, such as scientific experiments and industrial applications.
What are vacuum pumps?
Vacuum pumps are devices used to remove gases and create a vacuum within a vacuum chamber. They work by creating a pressure differential, which allows them to extract and pump out the gases present in the chamber.
What are vacuum gauges used for?
Vacuum gauges are instruments used to measure the pressure within a vacuum system. They provide a readout or indication of the level of vacuum present, allowing operators to monitor and control the pressure as required.
What are other components used in vacuum systems?
In addition to vacuum chambers, vacuum pumps, and vacuum gauges, there are other components used in vacuum systems. These include valves, which control the flow of gases within the system, fittings, which connect different components together, and filters, which remove particles and contaminants from the gas.
How do vacuum components affect the cleaning ability of a vacuum system?
Vacuum components play a significant role in the cleaning ability of a vacuum system. Factors such as the motor input power, water lift, and airflow are influenced by the selection and proper functioning of vacuum components. By choosing the right components and ensuring their optimal performance, users can ensure efficient and effective cleaning with their vacuum system.