We supply pressure intensifiers for isostatic presses, autofrettage systems and a variety of other applications. The maximum operating pressure is currently 16,000 bar. The largest stroke volume delivered to date was 30 litres.
Pressure intensifiers can be used to pump liquids and gases. They are suitable for continuous and discontinuous operation. The drive is hydraulic.
We also supply the required hydraulic power unit on request. As standard, our pressure intensifiers are designed for a hydraulic drive pressure of 250 to 350 bar. The high-pressure part can be separated from the hydraulic part by a spacer (lantern) if no traces of the drive fluid may enter the high-pressure fluid and vice versa.
The overall design of the pressure intensifier allows easy installation. In the axial direction, the pressure intensifier is held by four tie rods which absorb the entire axial load.
In addition to the favourable mounting conditions, a higher degree of operational safety is achieved here. Smaller pressure intensifiers can be supplied partially single acting, or with two high pressure heads double acting for continuous conveying.
We supply pressure intensifiers for isostatic presses, autofrettage systems and a variety of other applications. The maximum operating pressure is currently 16,000 bar. The largest stroke volume delivered to date was 30 litres.
Pressure intensifiers can be used to pump liquids and gases. They are suitable for continuous and discontinuous operation. The drive is hydraulic.
We also supply the required hydraulic power unit on request. As standard, our pressure intensifiers are designed for a hydraulic drive pressure of 250 to 350 bar. The high-pressure part can be separated from the hydraulic part by a spacer (lantern) if no traces of the drive fluid may enter the high-pressure fluid and vice versa.
The overall design of the pressure intensifier allows easy installation. In the axial direction, the pressure intensifier is held by four tie rods which absorb the entire axial load.
In addition to the favourable mounting conditions, a higher degree of operational safety is achieved here. Smaller pressure intensifiers can be supplied partially single acting, or with two high pressure heads double acting for continuous conveying.
We supply pressure intensifiers for isostatic presses, autofrettage systems and a variety of other applications. The maximum operating pressure is currently 16,000 bar. The largest stroke volume delivered to date was 30 litres.
Pressure intensifiers can be used to pump liquids and gases. They are suitable for continuous and discontinuous operation. The drive is hydraulic.
We also supply the required hydraulic power unit on request. As standard, our pressure intensifiers are designed for a hydraulic drive pressure of 250 to 350 bar. The high-pressure part can be separated from the hydraulic part by a spacer (lantern) if no traces of the drive fluid may enter the high-pressure fluid and vice versa.
The overall design of the pressure intensifier allows easy installation. In the axial direction, the pressure intensifier is held by four tie rods which absorb the entire axial load.
In addition to the favourable mounting conditions, a higher degree of operational safety is achieved here. Smaller pressure intensifiers can be supplied partially single acting, or with two high pressure heads double acting for continuous conveying.
We supply pressure intensifiers for isostatic presses, autofrettage systems and a variety of other applications. The maximum operating pressure is currently 16,000 bar. The largest stroke volume delivered to date was 30 litres.
Pressure intensifiers can be used to pump liquids and gases. They are suitable for continuous and discontinuous operation. The drive is hydraulic.
We also supply the required hydraulic power unit on request. As standard, our pressure intensifiers are designed for a hydraulic drive pressure of 250 to 350 bar. The high-pressure part can be separated from the hydraulic part by a spacer (lantern) if no traces of the drive fluid may enter the high-pressure fluid and vice versa.
The overall design of the pressure intensifier allows easy installation. In the axial direction, the pressure intensifier is held by four tie rods which absorb the entire axial load.
In addition to the favourable mounting conditions, a higher degree of operational safety is achieved here. Smaller pressure intensifiers can be supplied partially single acting, or with two high pressure heads double acting for continuous conveying.
Pneumatic driven liquid pumps generate high pressures with a minimum size. The pumps work according to the differential piston principle, i.e. normal air pressure, usually up to 7 bar, is guided onto a large piston and moves a small hydraulic piston. The ratio A (area) x P (pressure) of the large piston corresponds to that of the small piston, apart from low friction losses, just like with pressure intensifiers. Air pumps offer the following advantages:
Automatic standstill after reaching the set maximum pressure
Easy integration into existing systems
No energy loss during long pressure holding times
Due to the compressed air drive they are suitable for use in explosion-proof areas
Counteracting leaks in the system
Simple activation by manual or controlled valves
Pneumatic driven liquid pumps generate high pressures with a minimum size. The pumps work according to the differential piston principle, i.e. normal air pressure, usually up to 7 bar, is guided onto a large piston and moves a small hydraulic piston. The ratio A (area) x P (pressure) of the large piston corresponds to that of the small piston, apart from low friction losses, just like with pressure intensifiers. Air pumps offer the following advantages:
Automatic standstill after reaching the set maximum pressure
Easy integration into existing systems
No energy loss during long pressure holding times
Due to the compressed air drive they are suitable for use in explosion-proof areas
Counteracting leaks in the system
Simple activation by manual or controlled valves
Pneumatic driven liquid pumps generate high pressures with a minimum size. The pumps work according to the differential piston principle, i.e. normal air pressure, usually up to 7 bar, is guided onto a large piston and moves a small hydraulic piston. The ratio A (area) x P (pressure) of the large piston corresponds to that of the small piston, apart from low friction losses, just like with pressure intensifiers. Air pumps offer the following advantages:
Automatic standstill after reaching the set maximum pressure
Easy integration into existing systems
No energy loss during long pressure holding times
Due to the compressed air drive they are suitable for use in explosion-proof areas
Counteracting leaks in the system
Simple activation by manual or controlled valves
Pneumatic driven liquid pumps generate high pressures with a minimum size. The pumps work according to the differential piston principle, i.e. normal air pressure, usually up to 7 bar, is guided onto a large piston and moves a small hydraulic piston. The ratio A (area) x P (pressure) of the large piston corresponds to that of the small piston, apart from low friction losses, just like with pressure intensifiers. Air pumps offer the following advantages:
Automatic standstill after reaching the set maximum pressure
Easy integration into existing systems
No energy loss during long pressure holding times
Due to the compressed air drive they are suitable for use in explosion-proof areas
Counteracting leaks in the system
Simple activation by manual or controlled valves
Pneumatic driven liquid pumps generate high pressures with a minimum size. The pumps work according to the differential piston principle, i.e. normal air pressure, usually up to 7 bar, is guided onto a large piston and moves a small hydraulic piston. The ratio A (area) x P (pressure) of the large piston corresponds to that of the small piston, apart from low friction losses, just like with pressure intensifiers. Air pumps offer the following advantages:
Automatic standstill after reaching the set maximum pressure
Easy integration into existing systems
No energy loss during long pressure holding times
Due to the compressed air drive they are suitable for use in explosion-proof areas
Counteracting leaks in the system
Simple activation by manual or controlled valves
Pneumatic driven liquid pumps generate high pressures with a minimum size. The pumps work according to the differential piston principle, i.e. normal air pressure, usually up to 7 bar, is guided onto a large piston and moves a small hydraulic piston. The ratio A (area) x P (pressure) of the large piston corresponds to that of the small piston, apart from low friction losses, just like with pressure intensifiers. Air pumps offer the following advantages:
Automatic standstill after reaching the set maximum pressure
Easy integration into existing systems
No energy loss during long pressure holding times
Due to the compressed air drive they are suitable for use in explosion-proof areas
Counteracting leaks in the system
Simple activation by manual or controlled valves
