RU95115513A - AUTOMATED SYSTEM FOR PERIODIC REMOVAL OF METAL IONS FROM THE CHEMICAL BATH, AUTOMATED SYSTEM OF STABILIZATION OF CHEMICAL BATH, METHOD OF REMOVAL OF METAL IONS AND THE SYSTEM OF AUTOMATIC SEDIMENT DEPOSITION - Google Patents

Claims (63)

1. An automated system for periodically removing metal ions and contaminants from a chemical bath, including a first tank containing a chemical bath; an ion exchange column (IEX) comprising ion exchange material for removing contaminants or metal ions from the chemical bath; characterized in that it comprises: first circulation means responsive to the first control signals for draining the chemical bath from the first tank, passing it through the ion exchange column and returning the processed chemical bath from the ion exchange column back to the first tank; first conductivity measuring means installed in the chemical bath in the first tank for transmitting a first conductivity signal indicating the conductivity of the chemical bath; second conductivity measuring means immersed in a chemical bath returned from processing in the ion-exchange column to the first tank to form a second conductivity signal indicating the conductivity of the treated chemical bath, and a controller programmed to the first operating mode to generate the first control signals, and during the resultant circulation of the chemical bath to detect the difference between the first and second conductivity signals, decreasing to a predetermined minimum value, to complete the first control buttons to turn off the first circulation means.  2. The system according to p. 1, characterized in that it further includes a second tank containing deionized water (D. 1. water); second circulation means, responsive to the second control signals, for pumping a predetermined amount of deionized water into the ion exchange column to displace the residual chemical bath and return the displaced chemical bath to the first tank, and a controller programmed for the second operating mode, which follows the first mode, for the formation of the second control signals in a given period of time.  3. The system according to claim 2, characterized in that it further includes an opening for discharging waste products from the processing system; third circulating means, responsive to third control signals, for pumping deionized water from the second tank through the ion exchange column in one direction to flush the latter and discharging deionized water from it through the waste hole, and a controller programmed for the third mode of operation that follows after the second mode, for the formation of third control signals in a given period of time.  4. The system according to p. 3, characterized in that it further includes a third tank containing a chemical regenerating agent; the fourth circulation means, responsive to the fourth control signals, for pumping the chemical regenerating agent from the third tank through the ion exchange column and for discharging the chemical regenerating agent from it through the wastewater opening, so metal ions are removed from the ion exchange column to regenerate them, and the controller, programmed in the fourth mode of operation, which follows after the third mode, for the formation of the fourth control signals in a given period of time.  5. The system according to claim 4, characterized in that it further includes a third conductivity means installed in the waste hole, for generating a third conductivity signal indicating the conductivity of liquids discharged through the waste hole, and a controller programmed in the fifth mode after the fourth mode, to generate third control signals to start the second wash cycle of the ion exchange column and detect a third conductivity signal decreasing to a predetermined value, to complete the third x control signals.  6. The system according to claim 4, characterized in that it further includes a controller programmed in the fifth mode of operation, after the fourth mode, for generating third control signals for at least a predetermined period of time necessary for washing the ion exchange column with deionized water in one direction to remove residual chemical regenerating agent from it.  7. The system according to claim 6, characterized in that it further includes a fifth means of circulation that responds to fifth control signals for pumping deionized water from the second tank through the ion exchange column in the opposite direction to ensure removal of essentially all foreign particles from it; a controller programmed in the sixth mode of operation after the fifth mode of operation, for generating fifth control signals for a given period, time.  8. The system according to claim 1, characterized in that the chemical bath consists of a latex-based coating composition for use in an automatic coating deposition method.  9. The system of claim 1, wherein the first circulation means further includes first filtering means installed between the first tank and the inlet of the ion exchange column to remove particles from the chemical bath, to reduce essentially clogging of the ion exchange column.  10. The system of claim 9, wherein the first circulation means further includes second filtering means between the outlet of the ion exchange column and the first tank for removing ion exchange material and other solid particles from the treated chemical bath before it returns to the first tank .  11. The system according to p. 3, characterized in that it further includes a third tank containing a fresh regenerating agent; a fourth tank containing a used chemical regenerating agent; the fourth circulation means, responsive to the fourth control signals, for pumping a predetermined amount of once used chemical regenerating agent from the fourth tank through the ion exchange column and for discharging the regenerating agent through the outlet, so that the ion exchange material is regenerated at least partially; a fifth circulation means responsive to the fifth control signals for pumping fresh regenerating agent from the third tank through and out of the ion exchange column to discharge the used chemical regenerating agent from the waste outlet; sixth circulation means, responsive to sixth control signals, for pumping deionized water from the second tank into the ion exchange column in one direction to displace the used regenerating agent from it into the fourth tank; a controller programmed in the fourth operating mode for generating fourth control signals in a predetermined period of time; a controller programmed in the fifth mode of operation for generating fifth control signals during a period of time necessary to complete the regeneration of the ion exchange material; a controller programmed in the sixth mode of operation to generate sixth control signals for a period of time necessary to fill or pass a predetermined amount of the used regenerating agent into the fourth tank, and a controller programmed in the seventh mode of operation to generate third control signals for a predetermined period time for flushing the ion exchange column in one direction with a given amount of deionized water.  12. The system according to claim 11, characterized in that it further includes a seventh circulation means responsive to the seventh control signals for pumping deionized water from the second tank through the ion exchange column in the opposite direction to ensure removal of substantially all particles and for discharging from it deionized water through the wastewater hole, and a controller programmed in the eighth mode of operation, for the formation of the seventh control signals for the period of time required to pass enough the amount of deionized water through the ion exchange column in the opposite direction to remove essentially residual regenerating agent from it.  13. The system according to p. 12, characterized in that it further includes first means for detecting the level in the fourth tank for generating signals indicating the level of the used regenerating chemical agent in the fourth tank, and a controller additionally programmed for the fourth operating mode to respond to signals from the first level detecting means, both for completing the fourth control signals when the level of the chemical regenerating agent used is reduced to a predetermined decreasing level, so for the beginning of the fifth mode of operation.  14. The system according to p. 13, characterized in that it further includes a second level detection means in the third tank for generating signals indicating the level of fresh chemical regenerating agent in the third tank, and a controller further programmed for the fifth mode of operation to complete or exclude generating fifth control signals in response to level signals from a second level detecting means indicating that the level of fresh regenerating chemical agent in the third tank has decreased to a predetermined min mal level.  15. The system according to p. 14, characterized in that it further includes first pumping means responsive to the first pump control signal for supplying a fresh chemical regenerating agent from its supply source to the third tank, and a controller additionally programmed to supply the first signal controlling the pump to the first pumping means in response to level signals from the second level detecting means indicating the level of fresh regenerating chemical agent in the third tank, decreasing to a predetermined minimum level detection, and to complete the first control signal in response to the level signals from the second level detection means indicating the level of fresh regenerant in the third tank increasing to a predetermined maximum level.  16. The system according to p. 10, characterized in that it further includes first pressure detection means connected through the inlet and outlet of the first filtering means for generating a first clogging signal if the pressure through the first filter exceeds a predetermined value, and a controller, further programmed in response to the first clogging signal, allowing you to complete the first mode of operation, and then preventing the further operation of the system until the first filter is replaced.  17. The system according to p. 16, characterized in that it further includes a second means for determining pressure connected to the outlet of the second filter means for generating a second clogging signal if the pressure at the output of the second filter means decreases to a predetermined minimum value and the controller, additionally programmable to respond to the second clogging signal, allowing you to complete the first mode of operation and after that interfering with the further operation of the system until the first filter is replaced tr  18. The system according to p. 2, characterized in that it further includes a means for determining the level installed in the second tank, for generating signals of the levels of deionized water indicating the specified minimum and maximum levels, respectively; an automatic valve means connected between the pressure source of deionized water and the second tank, responsive to the valve operating signal to turn it on so that the deionized water can pass into the second tank, and a controller, additionally programmed to respond to the minimum level of deionized water, to generate a signal operation of the valve and then to respond to the signal of the maximum level of the valve to complete the signal of operation of the valve.  19. The system according to claim 1, characterized in that the ion-exchange material consists of an iminodiacetate ion-exchange resin.  20. The system according to p. 5, characterized in that it further includes a fifth circulation means that responds to fifth control signals for pumping a predetermined amount of a chemical bath from the first tank into the ion exchange column to displace residual deionized water from it and discharge the latter from the hole for wastewater, and a controller programmed in a sixth mode of operation following the fifth mode to generate fifth control signals for a predetermined period of time, in preparation for the first mode of operation.  21. The system according to claim 7, characterized in that it further includes a sixth circulation means responsive to sixth control signals for pumping a predetermined amount of a chemical bath from the first tank into the ion exchange column, for displacing residual deionized water from it and discharging the latter from sewage openings, and a controller programmed in the seventh operation mode following the sixth mode to generate sixth control signals for a predetermined period of time in preparation for the first operation mode.  22. The system according to p. 12, characterized in that it further includes an eighth circulation means responsive to eighth control signals for pumping a predetermined amount of a chemical bath from the first tank into the ion exchange column, for displacing residual deionized water from it and discharging the latter from openings for waste, and a controller programmed in the ninth mode of operation after the eighth mode of operation, for the formation of eighth control signals in preparation for the first mode of operation.  23. An automated stabilization system for a chemical bath, including at least periodically removing metal ions and contaminants from the chemical bath, characterized in that it comprises a first tank containing deionized water (DI water); a second tank with a chemical regenerating agent; a third tank containing a chemical bath; an ion exchange column (IEX) filled with an ion exchange resin to remove metal ion contaminants from a chemical bath passing through it; an opening for discharging waste products from the system for processing them; a first pump driven by a first pump control signal; a second pump driven by a second pump control signal; a first valve connected in series with the first pump and the ion exchange column between the third tank and the waste hole; a second valve connected in series with the first pump and the ion exchange column from the third tank and return to the third tank; a third valve connected in series with the second pump and the ion exchange column between the first tank and the third tank; a fourth valve connected in series with the second pump and the wastewater opening to form a path for the deionized water to flow through the ion exchange column in one direction; a fifth valve connected in series with the second pump and the ion-exchange column between the second tank and the wastewater opening, and a controller programmed to provide a sequence of automatic process control for subsequent operating modes, including a first mode for removing residual deionized water from the ion-exchange column and the release of remote deionized water from the wastewater outlet, and the programming of the first mode includes a means of forming and transmitting sneeze signals for opening the first valve; means for generating and transmitting the first pump control signal to the first pump for pumping a predetermined amount of the chemical bath into the ion exchange column to displace excess deionized water from it and discharging excess deionized water from the wastewater opening, and a second mode for supplying the chemical bath through the ion exchange column to remove ions metal from a chemical bath, moreover, the programming of the second mode includes means for generating and transmitting working signals to the second valve to open it and means for generating and transmitting the first pump control signal to the first pump for pumping a predetermined amount of the chemical bath through the ion exchange column for processing and from there back to the third tank.  24. The system according to p. 23, characterized in that it further includes programming the controller in a third mode for removing the residual chemical bath from the ion-exchange column and returning the residual chemical bath to the third tank, the third mode programming including means for generating and transferring workers signals to the third valve to open it; means for generating and transmitting a second control signal to the second pump for pumping a predetermined amount of deionized water into the ion exchange column to displace the residual chemical bath, causing the latter to return to the third tank.  25. The system according to p. 24, characterized in that it further includes programming the controller in the fourth mode for the first washing of the ion exchange column with deionized water and discharging the deionized water from the wastewater opening, the fourth mode programming including means for generating and transferring workers signals to the fourth valve to open it; means for generating and transmitting the second pump control signal to the second pump for pumping the first predetermined amount of deionized water through the ion exchange column in one direction and from it to the waste water outlet.  26. The system according to p. 25, characterized in that it further includes programming the controller in the fifth mode for flushing the ion exchange column with a chemical regenerating agent for resin regeneration in the ion exchange column, and programming the fifth mode includes means for generating and transmitting operating signals to the fifth valve to open it; means for generating and transmitting a second control signal to the second pump for pumping a predetermined amount of a chemical regenerating agent through the ion exchange column and from it into the wastewater opening.  27. The system according to p. 26, characterized in that it includes programming the controller in the sixth mode for the second washing of the ion exchange column with deionized water after the fifth mode of operation, and the programming of the sixth mode includes means for generating and transmitting working signals to the fourth valve for opening; means for generating and transmitting a second pump control signal to the second pump for pumping a second predetermined amount of deionized water in one direction and from it into the wastewater opening.  28. The system according to p. 27, characterized in that it further includes a sixth valve, connected in series with the second pump and the ion exchange column, between the first tank and the wastewater opening to form a path for the deionized water flow through the ion exchange column in the opposite direction along relative to the first direction to ensure the removal of essentially all foreign particles from the ion exchange column.  29. The system according to p. 27, characterized in that it further includes a first filter connected between the third tank and the ion exchange column in series-connected circuits for liquids, also containing the first and second valves, respectively, for filtering a chemical bath before it enters the ion exchange column.  30. The system according to p. 29, characterized in that it further comprises: a second filter connected between the third tank and the ion exchange column in a series-connected liquid circuit, also including the first valve means, for filtering a chemical bath after treatment through an ion exchange column and before she returns to the third tank.  31. The system according to p. 30, characterized in that it further comprises: first and second means for determining pressure, connected to the first and second filter, respectively, for generating the corresponding pressure signals indicating the operating state of the first and second filters, respectively; a controller responding to pressure signals from the first and second pressure sensing means to generate a first clogging signal if the pressure drop through the first filter exceeds a predetermined value, and a second clogging signal if the pressure at the outlet of the second filter decreases below a predetermined value; signaling means responsive to the first and second blocking signals, for generating separate alarms indicating clogging of the first and second filters, and a controller that also responds to pressure signals to complete any of the first and second operating modes that may be in development, and to exclude further operation of the system until the first and second filters act.  32. The system according to p. 30, characterized in that it further includes first detection means connected via a first filter to generate a first pressure signal if the pressure drop through the first pressure means increases above a predetermined value; a controller that responds to the first pressure signal to generate the first alarm and complete the first or second mode of operation, if any, and to exclude additional modes of operation until the differential pressure problem is eliminated, and the first signaling device that responds at the first alarm, to generate an alarm indicating a problem with pressure, to inform the operator to take the necessary measures to eliminate the problem.  33. The system according to p. 32, characterized in that it further includes a second means of determining pressure connected to the outlet of the second filter to generate a second pressure signal if the pressure at the outlet decreases below a predetermined value; a controller that responds to the second pressure signal to generate a second alarm, end the first or second mode of operation, if any, and to exclude additional modes of operation until the corresponding pressure is restored, and a second signaling device that responds to the second alarm to generate an alarm indicating an undesirable decrease in output pressure.  34. The system according to p. 27, characterized in that it further includes first means of travel connected to the first pump for generating the first stroke signals indicating the stroke of the first pump, and a controller programmed to count the first stroke signals to determine the amount of chemical bath pumped by the first pump for a period of time.  35. The system according to p. 34, characterized in that it further includes a second means of travel connected to the second pump for generating second stroke signals indicating each stroke of the second pump, and a controller programmed to count the second stroke signals to determine the number liquid pumped by the second pump during the pumping of deionized water or a chemical regenerating agent for a period of time.  36. The system according to p. 27, characterized in that it further includes a signal device connected to the first to fifth valves for detecting malfunctions in their operation and generating an alarm signaling such malfunctions in at least one of the first to fifth valves .  37. The system of claim 36, wherein the signaling device further comprises means for generating separate alarms indicating each faulty valve included in the first to fifth valves, respectively.  38. The system according to p. 36, characterized in that the controller further includes means that respond to an alarm to stop the system until the fault is resolved.  39. A method for removing metal ions and contaminants from a coating composition bath used in an automatic deposition system, including a first tank for deionized water (DI), a second tank for containing a regenerating chemical agent, a third tank for the used regenerating agent, and a fourth tank for the composition coating, and an ion-exchange column (IEX) containing ion-exchange material, characterized in that it includes the following steps: determine when the concentration of metal ions in the coating composition increases to a predetermined wow level; circulating the coating composition from the fourth tank through the ion exchange column and back to the fourth tank after treatment; determine when there will be enough of the treated coating composition to remove metal ions to reduce the concentration of metal ions to an acceptable level in the coating composition in the fourth tank, and complete the circulation of the coating composition through the ion exchange column.  40. The method according to p. 39, characterized in that the stage of determining the concentration of metal ions is carried out by taking indications of manual titration of the coating composition.  41. The method according to p. 39, wherein the step of determining when a sufficient amount of the coating composition is processed includes the steps of: measuring the conductivity of the coating composition remaining in the fourth tank; measuring the conductivity of the coating composition returned to the fourth tank from the ion exchange column; calculating the difference between the conductivity of the coating composition in the fourth tank and the conductivity of the coating composition returned to the fourth tank, and setting the difference level to start the completion step.  42. The method according to p. 39, characterized in that the coating composition is passed through the first filter before it enters the ion exchange column to remove coagulated parts of the coating composition and other particulate material.  43. The method according to p. 42, characterized in that the coating composition is passed through the second filter after it leaves the ion exchange column, but before returning to the fourth tank, to remove particles of the ion exchange material and other particles.  44. The method according to p. 43, characterized in that they detect clogging of the first filter, generate an alarm when the first filter is clogged, and exclude another operation after processing is completed until the first filter is replaced.  45. The method according to p. 43, characterized in that it is determined when the second filter is clogged; generate an alarm when the second filter becomes clogged, and subsequent operations are warned after completion of the coating composition processing until the second filter is replaced.  46. The method according to p. 43, characterized in that establish the moment when one or both of the first and second filters clogged form an alarm signal, separately indicating the clogging of the first and second filters, respectively, and carry out a warning of another operation after completion of processing the coating composition as long as the first and second filters are free from clogging.  47. The method according to p. 39, characterized in that it further includes, after processing the coating composition, the following steps: a sufficient amount of deionized water is circulated to the ion exchange column to displace the residual coating composition from it and parts of the displaced coating composition are passed into the fourth tank.  48. The method according to p. 47, characterized in that exclude any additional fluid flow from the ion exchange column to the fourth tank; circulating deionized water in one direction through an ion-exchange column; directing the flow of deionized water from the ion exchange column to discharge it through the wastewater opening, and completing the circulation of deionized water through the ion exchange column after the latter has been washed and substantially free of coating composition.  49. The method according to p. 48, characterized in that the circulation of the chemical regenerating agent from the second tank through the ion exchange column and out of the outlet; determining when a predetermined amount of the chemical regenerating agent passes through the ion exchange column to regenerate the ion exchange material, and the flow of the regenerating chemical agent through the ion exchange column is completed.  50. The method according to p. 49, characterized in that the deionized water is circulated from the first tank through the ion exchange column in one direction and out of the outlet; circulating deionized water from the first tank through the ion exchange column in the opposite direction to ensure that substantially all foreign particles are removed from it and the outlet; detect when a predetermined amount of deionized water passes through the ion exchange column to flush it, and complete the circulation of deionized water through the ion exchange column.  51. The method according to p. 48, characterized in that the once used chemical regenerating agent is circulated from the third tank through the ion exchange column and out of the outlet; detect when a predetermined amount of once used chemical regenerating agent passes through an ion-exchange column; complete the circulation of the used chemical regenerating agent; circulating the chemical regenerating agent from the second tank through the ion exchange column and out of the wastewater opening; detect when a predetermined amount of a fresh regenerating chemical agent needed in addition to the previous stream of used regenerating chemical agent passes through an ion exchange column to regenerate a substantially ion exchange material in an ion exchange column; deionized water is circulated from the first tank to the ion-exchange column to displace the used regenerating chemical agent to be discharged into the third tank, and the used regenerating chemical agent from the ion-exchange column is completed to flow into the third tank, either when its level in it reaches a predetermined level or release of a predetermined the amount of regenerating chemical agent used therein.  52. The method according to p. 51, characterized in that the bi-directional circulation of deionized water from the first tank through the ion exchange column and out of the outlet; detect when a predetermined amount of deionized water passes through the ion exchange column to wash it essentially from a regenerating chemical agent and particulate foreign material, and deionized water is circulated through the ion exchange column.  53. The method according to p. 50, characterized in that it includes the steps of: preparing for the stage of starting the circulation of the coating composition through the ion exchange column, circulating a predetermined amount of the coating composition from the fourth tank into the ion exchange column to displace residual deionized water from it, and discharging remote deionized water through the outlet.  54. An automatic coating deposition system, automated to at least periodically remove metal ions and contaminants from a coating composition bath, characterized in that it includes a first tank containing a coating composition; an ion-exchange column (IEX) containing ion-exchange material to remove contaminants - metal ions from the coating composition passed through it; a second tank containing deionized water (D. 1. water) for washing the ion exchange column; a hole for discharging waste products from the treatment system; first circulating means responsive to the first control signals for sucking the first predetermined amount of the coating composition from the first tank and passing the coating composition into the ion exchange column to displace the residual washing deionized water from it and circulating the latter to discharge it from the wastewater opening; second circulation means responsive to the second control signals for drawing an additional coating composition from  the first tank, circulating it through the ion-exchange column and returning almost the remaining part of the coating composition from the ion-exchange column back to the first tank, and a controller programmed in the first mode of operation to generate the first control signals for a given period of time and in the second mode of operation to form the second signals control for at least a predetermined period of time to reduce the concentration of metal ions in the bath coating composition to a predetermined concentration.  55. The system according to p. 54, characterized in that it further includes first conductivity measuring means installed in the coating composition bath in the first tank, for generating a first conductivity signal indicating the conductivity of the coating composition bath; second conductivity measuring means, immersed in the coating composition, returned from processing in the ion-exchange column to the first tank, to generate a second conductivity signal indicating the conductivity of the treated coating composition, and a controller, additionally programmed in it in the second operating mode, to determine the difference between the first and second conductivity signals, decreasing to a predetermined minimum value, to complete the second control signals to turn off the second circulation means.  56. The system according to p. 55, characterized in that it further includes a third means of circulation that responds to third control signals for pumping a predetermined amount of deionized water into the ion exchange column to displace the residual coating composition and return the removed coating composition to the first tank, and a controller programmed in the third mode of operation after the second mode to generate third control signals for a given period of time.  57. The system according to p. 56, characterized in that it further includes a fourth circulation means that responds to the fourth control signals for pumping deionized water from the second tank through the ion exchange column in one direction to flush the latter and discharge deionized water from it through the outlet a wastewater opening, and a controller programmed in the fourth mode of operation after the third mode to generate fourth control signals over a predetermined period of time.  58. The system according to p. 57, characterized in that it further includes a third tank containing a chemical regenerating agent; the fifth circulation means, responsive to the fifth control signals, for pumping the chemical regenerating agent from the third tank through the ion exchange column and discharging the chemical regenerating agent from it from the wastewater opening, thus metal ions are removed from the ion exchange column for regeneration, and a programmable controller in the fifth mode of operation after the fourth mode, for generating fifth control signals for a predetermined period of time.  59. The system according to p. 58, characterized in that it further includes a third conductivity means installed inside the wastewater opening, for generating a third conductivity signal indicating the conductivity of liquids discharged through the wastewater opening, and a controller programmed in the sixth operating mode, which follows after the fifth mode, to generate the fourth control signals for starting the second washing cycle of the ion exchange column and detecting the third conductivity signal, which decreases to the rear nnogo values to complete the fourth control signals.  60. The system according to p. 58, characterized in that it further includes a controller programmed in the sixth mode of operation, which follows after the fourth mode, for generating the fourth control signals for at least a predetermined period of time necessary for washing the ion-exchange column deionized water to remove residual chemical regenerating agent from it.  61. The system of claim 60, further comprising: a sixth circulation means responsive to sixth control signals for pumping deionized water from the second tank through the ion exchange column in the opposite direction to flush the latter to remove substantially foreign matter from it particles and the release of deionized water through the wastewater hole, and a third conductivity means installed inside the wastewater hole to form a third conduction signal indicating the wire the possession of liquids discharged through the wastewater opening; a controller programmed in the seventh mode of operation following the sixth mode to generate fourth control signals for a predetermined period of time to start the second washing cycle of the ion exchange column, followed by the formation of sixth control signals to continue the second washing cycle, simultaneously with the detection of the third conductivity signal, decreasing to a predetermined value to complete the sixth control signals.  62. The system of claim 58, further comprising a sixth circulation means responsive to sixth control signals for pumping deionized water from the second tank through the ion exchange column in the opposite direction to flush the latter to remove substantially foreign material in the form particles and the release of deionized water from the sewage outlet; and a controller programmed in the sixth mode of operation after the fifth mode to generate fourth control signals in a predetermined period of time, and after completing the fourth control signals for generating sixth control signals in a predetermined period of time to complete the flushing of the chemical regenerating agent from the ion exchange column.  63. The system of claim 54, wherein the coating composition consists of a latex-based coating composition.