The hydro-blasting anti-withdrawal device support is used for mounting an anti-withdrawal device (AWD) utilized when cleaning heat exchanger tubes in a shell-and-tube heat exchanger where the tube sheet is recessed within the shell. The support includes a shell flange attachment plate, an AWD attachment plate, and a pipe spacing the two plates apart. Each plate is substantially rectangular and has a pipe attachment tab extending therefrom, the pipe attachment tabs extending in opposite directions. In use, the shell flange attachment plate is secured to the shell flange, the anti-withdrawal device is secured to the AWD attachment plate, and the pipe is dimensioned to support the AWD in close proximity to the heat exchanger tube sheet.

The hydro-blasting anti-withdrawal device support is used for mounting an anti-withdrawal device (AWD) utilized when cleaning heat exchanger tubes in a shell-and-tube heat exchanger where the tube sheet is recessed within the shell. The support includes a shell flange attachment plate, an AWD attachment plate, and a pipe spacing the two plates apart. Each plate is substantially rectangular and has a pipe attachment tab extending therefrom, the pipe attachment tabs extending in opposite directions. In use, the shell flange attachment plate is secured to the shell flange, the anti-withdrawal device is secured to the AWD attachment plate, and the pipe is dimensioned to support the AWD in close proximity to the heat exchanger tube sheet.

There is described a novel cleaning device for a condenser of a chiller system comprising: a condenser provided with a cooling grid, said cooling grid comprising one or more fins; a dust extraction system configured to remove dust from the surface of the one or more fins of the grid and/or the condenser.

There is described a novel cleaning device for a condenser of a chiller system comprising: a condenser provided with a cooling grid, said cooling grid comprising one or more fins; a dust extraction system configured to remove dust from the surface of the one or more fins of the grid and/or the condenser.

A robot is disclosed for cleaning the exterior of tubes of a heat exchanger. The robot comprises a lance for directing a jet of fluid into spaces between the tubes, a carriage for transporting the lance in a direction of travel parallel to axes of the tubes of the heat exchanger, and traction assemblies for engaging the tubes to enable the carriage to be advanced along the tubes, wherein the traction assemblies are each moveable relative to the carriage in a direction transverse to that of travel in order to change the track width of the robot.

A heat exchanger cleaning system is disclosed which is capable of determining the position of a lance within a tube bundle of a heat exchanger core. The system comprises a lance for directing a jet of fluid into spaces between the tubes of the bundle, an arm mounted alongside the lance and movable relative thereto, an abutment mounted to an end of the arm to sense an outer surface of the heat exchanger core, and a transducer for measuring the position of the lance relative to the arm to determine the extent of travel of the tip of the lance beyond the front face of the tube bundle.

An automatic washing apparatus for a heat exchanger is proposed. The automatic washing apparatus is configured to recognize positions of tube holes through a camera, and to automatically wash the tube holes. The automatic washing apparatus is also configured to be able to automatically wash an external bundle and internal tubes of a heat exchanger in accordance with set operation patterns of an external washing module and an internal washing module, and to be able to reuse washing water used for washing a heat exchanger as washing water by reprocessing the washing water.

An automatic washing apparatus for a heat exchanger is proposed. The automatic washing apparatus is configured to recognize positions of tube holes through a camera, and to automatically wash the tube holes. The automatic washing apparatus is also configured to be able to automatically wash an external bundle and internal tubes of a heat exchanger in accordance with set operation patterns of an external washing module and an internal washing module, and to be able to reuse washing water used for washing a heat exchanger as washing water by reprocessing the washing water.

A flexible lance drive device has at least one drive motor in a first portion of a housing and a drive axle projecting across a second portion of the housing carrying a cylindrical spline drive roller. A plurality of cylindrical guide rollers on fixed axles span across the second portion of the housing aligned parallel to the spline drive roller. An endless belt wrapped around the at least one spline drive roller and guide rollers has a generally smooth outer surface and a transverse splined inner surface having splines shaped complementary to splines on the spline drive roller. A bias member supports a plurality of follower rollers each aligned vertically above one of the at least one spline drive roller and guide rollers operable to press each follower roller toward one of rollers to frictionally grip a flexible lance hose when sandwiched between the follower rollers and the endless belt.

A heat exchanger cleaning device is provided. The cleaning device includes a drive motor configured to rotate a gearbox, a slip clutch and a support beam about a first axis. The support beam carries a thread rod, a second motor, and one or more carriage assemblies. The carriage assemblies move linearly as the second motor rotates the threaded rod. The carriage assemblies include a support tube for receiving an ultra-high pressure tube therethrough. The carriage assemblies adjust relative to the heat exchanger such that the UHP tube may be inserted through the support tube into a hole of the heat exchanger. Therein the UHP tube may be advanced to clean sediment from the heat exchanger tube.