SU1730209A1 - Plant for electrophoretic coating - Google Patents

Abstract

The invention relates to the field of hardening a pressing tool by deposition of wear-resistant coatings and can be used in the manufacture of measuring tools and gauges, as well as in the manufacture and repair of various parts operating under conditions of increased friction. The purpose of the invention is to improve the quality of coatings and reduce the consumption of the liquid component by reducing evaporation. An installation for electrophoretic coatings comprises a deposition bath 1 The invention relates to the strengthening of a pressing tool by deposition of wear-resistant coatings containing chromium carbide, and can be used in the manufacture of measuring tools and gauges, as well as in the manufacture and repair of various parts that work in conditions of increased friction. The aim of the invention is to improve the quality of the coating and the reduction of electrodes with electrodes 2, a mixing device 3 placed directly under the bath of deposition 1, a feeding device in the form of bipartite diaphragm pneumatic chambers 4 connected to a mixing device using a piping system 5, and with a pneumatic network with using the piping system 6 through the distributors 7 and 8, the throttle 9 and the check valve 10. The precipitation bath 1 is connected to the mixing device 3 by a flexible pipe 11, which has an outlet pipe centrifugal spinner 12. Deposition bath 1 has lower 13 and upper 14 suspension level sensors electrically connected to distributors 7 and 8 Pneumatic mocameras 4 have flexible diaphragms 15 with weights 16. Thanks to this installation design, uniform coating is ensured without tapering and layering depending on the size of solid particles, and the evaporation of the liquid phase of the suspension due to the complete sealing of the mixing device is also excluded. 1 hp F-ly, 1 silt SP with a liquid component due to a decrease in evaporation. The invention is illustrated in the drawing. An installation for electrophoretic coatings comprises a deposition bath 1 with electrodes 2, a mixing device 3 placed directly beneath the bath of deposition 1, a feeding device in the form of double-cavity diaphragm pneumatic cells 4 connected to the mixing device using a system VI C I th

Description

pipelines 5, and with the pneumatic network - by means of pipelines 6 through valves 7 and 8, throttle 9 and non-return valve 10. The precipitation bath 1 is connected to the mixing device 3 by a flexible pipe 11 having a centrifugal spinner 12 in the outlet pipe 12. The sedimentation bath 1 has a lower 13 and the upper 14 suspension level sensors, electrically connected to the distributors 7 and 8. The pneumatic chambers 4 have flexible diaphragms 15 with weights 16.

The installation works as follows.

The air from the pneumatic circuit enters through pneumatic distributors 7 and 8 through pipelines 5 into the lower cavities of the pneumatic chambers4. Under the pressure of air in the lower cavities of the diaphragm 15 of the pneumatic chambers 4, they will start to bend towards the upper cavities, the mixture of air and alcohol vapors is forced out of them through pipelines b into the space above the suspension in the mixing device 3. Under the influence of the vapor-air mixture, the suspension rises through a flexible pipe 11 deposition bath 1 to level sensor 13 for at least 10 s. Upon reaching this level, the sensor 13 will command to turn on the DC deposition, turn off the distributor 7. At the same time, the check valve 10 is closed and the air from the pneumatic network through the regulated choke 9 continues to flow into the lower cavity of the lower pneumatic chamber 4 and, as described, the suspension continues enter the precipitation bath, but at a slower rate — 0.5 l / s. At the same time, the suspension, the exit from the nozzle of the flexible pipe 11 and the rotational drive 12, which rotates freely on the axis, begins to rise by a slowly rotating flow.

The choke 9 is adjusted so that the slurry, having reached the sensor 14, will close its contacts, and the coating thickness will be ensured by the deposition time.

Sensor 14 will give a command to end the precipitation, shut off the air supply from the pneumatic network, turn on the distributors 7

and 8 to the air outlet to the atmosphere from the lower cavities of the pneumatic chambers 4.

At the same time, the suspension from the precipitation bath 1 is returned to the mixing device under the action of the vacuum effect created by the diaphragms 15 of the pneumatic chambers 4 under the action of the loads 16, also by additional support of the suspension by gravity flow.

Due to the use of a two-cavity diaphragm pneumatic chambers, throttles, turntables and level sensors in the installation of the feeding device, the uniformity of the coating is ensured without tapering and layering depending on the size of the solid particles, and the evaporation of the liquid phase of the suspension is eliminated due to the complete sealing of the mixing device. The evaporation from the precipitation bath is reduced by 85% due to the return of the suspension to the mixing device during the change of electrodes.

Claims (2)

1. An installation for electrophoretic coatings comprising a precipitation bath, a mixing device, a suspension supply device for the bath and a piping system, characterized in that, in order to improve the quality of the coating and reduce the consumption of the liquid component by reducing evaporation, the suspension supply device is made sealed double-cavity diaphragm pneumatic chambers, the lower cavities of which are connected by means of valves, the throttles and the check valve to the pneumatic network, and the upper cavities are connected to A mixing device, wherein the mixing device is sealed and connected by a flexible pipe to the precipitation bath, the precipitation bath being placed above the pipeline. 2. The installation according to claim 1, characterized in that it is provided with a centrifugal spinner placed at the top of the flexible pipe.