Pumping speed：70L/S、150L/S、300L/S、600L/S、1200L/S Roots vacuum pumps, often referred to as mechanical booster pumps, are ideal for venting gases from sealed containers and cannot be compressed at atmospheric pressure. Roots pumps are often used in conjunction with backing pumps such as rotary vane pumps, liquid ring pumps and oil-sealed rotary piston vacuum pumps. Widely used in metallurgy, chemical industry, electronics, textile and other fields.

Pumping speed：70L/S、150L/S、300L/S、600L/S、1200L/S   Roots vacuum pumps, often referred to as mechanical booster pumps, are ideal for venting gases from sealed containers and cannot be compressed at atmospheric pressure. Roots pumps are often used in conjunction with backing pumps such as rotary vane pumps, liquid ring pumps and oil-sealed rotary piston vacuum pumps. Widely used in metallurgy, chemical industry, electronics, textile and other fields.  

Pumping speed：70L/S、150L/S、300L/S、600L/S、1200L/S Roots vacuum pumps, often referred to as mechanical booster pumps, are ideal for venting gases from sealed containers and cannot be compressed at atmospheric pressure. Roots pumps are often used in conjunction with backing pumps such as rotary vane pumps, liquid ring pumps and oil-sealed rotary piston vacuum pumps. Widely used in metallurgy, chemical industry, electronics, textile and other fields.

Pumping speed：70L/S、150L/S、300L/S、600L/S、1200L/S Roots vacuum pumps, often referred to as mechanical booster pumps, are ideal for venting gases from sealed containers and cannot be compressed at atmospheric pressure. Roots pumps are often used in conjunction with backing pumps such as rotary vane pumps, liquid ring pumps and oil-sealed rotary piston vacuum pumps. Widely used in metallurgy, chemical industry, electronics, textile and other fields.

Pumping speed：70L/S、150L/S、300L/S、600L/S、1200L/S Roots vacuum pumps, often referred to as mechanical booster pumps, are ideal for venting gases from sealed containers and cannot be compressed at atmospheric pressure. Roots pumps are often used in conjunction with backing pumps such as rotary vane pumps, liquid ring pumps and oil-sealed rotary piston vacuum pumps. Widely used in metallurgy, chemical industry, electronics, textile and other fields.

N 952Flow Rate (max.): 36 l/minPressure (max.): 0.1 bar (rel.)Vacuum (max.): 1.5 mbar (abs.)

N 952 Flow Rate (max.): 36 l/min Pressure (max.): 0.1 bar (rel.) Vacuum (max.): 1.5 mbar (abs.)

N 952Flow Rate (max.): 36 l/minPressure (max.): 0.1 bar (rel.)Vacuum (max.): 1.5 mbar (abs.)

The TXW 200–500 series pumps are 100% oil less rotary vane vacuum pumps. They are designed to operate on a continuous basis at any point from atmospheric pressure to a maximum vacuum level of  25"HgV, depending on the model. lubricating graphite composite vanes. Applications include those where regenerative blowers These 100% oil-less, or dry, pumps are ideal for The TXW series pumps are direct drive units and are supplied with TEFC flange mounted electric motors. Each pump is equipped with an integral vacuum relief valve, a 4-micron inlet filter, exhaust silencer, and vibration isolators as standard equipment. applications where oil or water use is objectionable. All Becker TXW series pumps use long-life, self cannot reach a deep enough vacuum, or those where oil-flooded vacuum pumps operate at vacuum levels that emit excessive oil aerosols, often referred to as “smoke”. TXW pumps are ideal for graphic arts, pack aging, vacuum chucking, robotics and material handling, medical/surgical, and air sampling, among others. Also available in tank mounted simplex and duplex, and modular/expandable central vacuum system configurations. Pressure and combination pressure/ vacuum pumps are also available

  Step1: inhale and seal all the air in the volume chamber, and the compression begins; Step 2: continue to compress to the center point of the volume cavity; Step3: compress the air to the center of the volume chamber, and the exhaust will begin soon; Step4: exhaust, end of a compression process

Step1: inhale and seal all the air in the volume chamber, and the compression begins; Step 2: continue to compress to the center point of the volume cavity; Step3: compress the air to the center of the volume chamber, and the exhaust will begin soon; Step4: exhaust, end of a compression process

The system has a wide range of applications. No matter the pumping speed, capacity and vacuum pressure, we can make appropriate choices according to the special requirements of customers. Combined with different applications, we can adjust the appropriate system requirements according to the needs of the process, so as to meet the real space requirements of the whole plant or various mechanical equipment applications. 

The system has a wide range of applications. No matter the pumping speed, capacity and vacuum pressure, we can make appropriate choices according to the special requirements of customers. Combined with different applications, we can adjust the appropriate system requirements according to the needs of the process, so as to meet the real space requirements of the whole plant or various mechanical equipment applications. 

The system has a wide range of applications. No matter the pumping speed, capacity and vacuum pressure, we can make appropriate choices according to the special requirements of customers. Combined with different applications, we can adjust the appropriate system requirements according to the needs of the process, so as to meet the real space requirements of the whole plant or various mechanical equipment applications. 

The system has a wide range of applications. No matter the pumping speed, capacity and vacuum pressure, we can make appropriate choices according to the special requirements of customers. Combined with different applications, we can adjust the appropriate system requirements according to the needs of the process, so as to meet the real space requirements of the whole plant or various mechanical equipment applications. 

The impellers are mounted directly on the motor shaft for noncontact compression entirely without friction.Maximum operational reliability, even at high differential is ensured by the arrangement of the bearings outside the compression chamber. The gas it taken in though the inlet1.As it enters the side channel 2,the rotating impeller 3 imparts velocity to the gas in the direction of rotation.Centrifugal force in the impeller blades accelerates the gas outward and the pressure increase .Every rotation adds kinetic energy. Resulting in the further increase of the pressure along the side channel .The side channel narrow at the rotor,sweeping the gas off the impeller blades and discharging it though the outlet silencer 4 where it exits the side channel blower. 

The impellers are mounted directly on the motor shaft for noncontact compression entirely without friction.Maximum operational reliability, even at high differential is ensured by the arrangement of the bearings outside the compression chamber. The gas it taken in though the inlet1.As it enters the side channel 2,the rotating impeller 3 imparts velocity to the gas in the direction of rotation.Centrifugal force in the impeller blades accelerates the gas outward and the pressure increase .Every rotation adds kinetic energy. Resulting in the further increase of the pressure along the side channel .The side channel narrow at the rotor,sweeping the gas off the impeller blades and discharging it though the outlet silencer 4 where it exits the side channel blower.

The impellers are mounted directly on the motor shaft for noncontact compression entirely without friction.Maximum operational reliability, even at high differential is ensured by the arrangement of the bearings outside the compression chamber. The gas it taken in though the inlet1.As it enters the side channel 2,the rotating impeller 3 imparts velocity to the gas in the direction of rotation.Centrifugal force in the impeller blades accelerates the gas outward and the pressure increase .Every rotation adds kinetic energy. Resulting in the further increase of the pressure along the side channel .The side channel narrow at the rotor,sweeping the gas off the impeller blades and discharging it though the outlet silencer 4 where it exits the side channel blower. 

The impellers are mounted directly on the motor shaft for noncontact compression entirely without friction.Maximum operational reliability, even at high differential is ensured by the arrangement of the bearings outside the compression chamber. The gas it taken in though the inlet1.As it enters the side channel 2,the rotating impeller 3 imparts velocity to the gas in the direction of rotation.Centrifugal force in the impeller blades accelerates the gas outward and the pressure increase .Every rotation adds kinetic energy. Resulting in the further increase of the pressure along the side channel .The side channel narrow at the rotor,sweeping the gas off the impeller blades and discharging it though the outlet silencer 4 where it exits the side channel blower.

The impellers are mounted directly on the motor shaft for noncontact compression entirely without friction.Maximum operational reliability, even at high differential is ensured by the arrangement of the bearings outside the compression chamber. The gas it taken in though the inlet1.As it enters the side channel 2,the rotating impeller 3 imparts velocity to the gas in the direction of rotation.Centrifugal force in the impeller blades accelerates the gas outward and the pressure increase .Every rotation adds kinetic energy. Resulting in the further increase of the pressure along the side channel .The side channel narrow at the rotor,sweeping the gas off the impeller blades and discharging it though the outlet silencer 4 where it exits the side channel blower. 

The impellers are mounted directly on the motor shaft for noncontact compression entirely without friction.Maximum operational reliability, even at high differential is ensured by the arrangement of the bearings outside the compression chamber. The gas it taken in though the inlet1.As it enters the side channel 2,the rotating impeller 3 imparts velocity to the gas in the direction of rotation.Centrifugal force in the impeller blades accelerates the gas outward and the pressure increase .Every rotation adds kinetic energy. Resulting in the further increase of the pressure along the side channel .The side channel narrow at the rotor,sweeping the gas off the impeller blades and discharging it though the outlet silencer 4 where it exits the side channel blower.