KR900700778A - Method and apparatus for coating the inner cavity - Google Patents

Abstract

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Description

Method and apparatus for coating the inner cavity

Since this is an open matter, no full text was included.

1 is a partial cross-sectional view of a device used in a method of coating a target with a fluid.

2 is a diagram of a coating apparatus.

3 is a partial cross-sectional view of another preferred embodiment apparatus for use in a method of coating a target with a fluid.

Claims (55)

The object to be coated is placed in a predetermined position and a hollow probe having at least one hole is moved from below the object to be coated to a position for coating the object, while simultaneously pumping material from the reservoir into the probe and removing the probe. Distributing the fluid using centrifugal force from the rotational movement of the probe through at least one hole in the probe by rotating it at a predetermined speed and advancing it to a predetermined length. How to selectively coat. The coating method of claim 1 further comprising moving the coated object through a drying chamber. The coating method according to claim 1, wherein the probe is continuously rotated during the coating process. The method of claim 1, wherein the probe disperses the material while moving to a predetermined position in one direction through the object, pumps a predetermined amount of coating material through the probe, and recovers the probe from the coated object after the coating process is stopped. Coating method. The coating method of claim 1, wherein the probe disperses the material during movement in the first direction through the object and also during the recovery movement in the opposite direction from the object. The coating method according to claim 1, wherein the computer simultaneously adjusts the rotational speed of the probe with respect to the change in the coating material and the pump that sends the material to the probe. The method of claim 1, wherein the probe is rotated at 10,000 to 15,000 per minute. Precise coating of the threaded portion of the nut by simultaneously rotating the hollow probe with at least one aperture at a predetermined speed, pumping material from the reservoir into the hollow probe, and moving the probe a predetermined distance through the hole of the nut. A method for selectively coating a nut using a centrifugal force for dispersing the coating fluid constituted. The coating method according to claim 8, wherein the computer controls the rotational speed, the pumping speed of the fluid transferred to the probe, and the moving distance of the probe. The method of claim 8, wherein the probe disperses fluid while traveling a predetermined distance through the bite, and when the fluid reaches a predetermined position, the fluid is pumped from the probe to the support chamber to improve control of the coating pattern applied to the nut. Coating method which is continuously rotated and removed from the hole of the nut. A nut having threads coated with a fluid according to the method of claim 8. Nut having a thread coated with Teflon according to the method of claim 8. A support means for supporting an object, a probe for distributing fluid in the object, a rotary drive means for rotating the probe, a supply container for the fluid, a pump means for transferring fluid from the supply container to the extended hollow probe, the probe A control means for coating the object in a predetermined manner using centrifugal force to disperse the fluid by adjusting the plunger means, the rotary driving means, the pump means and the plunger means for moving the inner hollow body of the object. Apparatus for applying fluid to internal cavities. The coating apparatus according to claim 13, wherein the coating unit has drying means for drying the coating object after the probe is removed from the object. 15. The coating apparatus according to claim 14, wherein the drying means is a vacuum means for introducing heated blown air into a closed chamber at one position and discharging air to the second position. The coating apparatus according to claim 13, wherein the positioning means places the object in a predetermined position before coating the object with the fluid. 17. A coating apparatus according to claim 16, wherein the object is fed toward a positioning means on the support trajectory and the object is loaded onto the support trajectory from a rotating bowl feeder. The coating apparatus according to claim 13, wherein the apparatus has exhaust means for connecting and cleaning the fluid with a discharge vessel. The coating apparatus according to claim 13, wherein the pump transfer means is provided with a reversible pump to stop the fluid from flowing from the probe when the probe reaches a predetermined position and to recover the coating material from the probe. A mechanism for moving the nut in a single line prior to coating the nut, computer means for controlling the fluid dispensed to the nut, a positioning device for positioning the nut in a predetermined position, a probe with at least one outlet means, fluid supply chamber, fluid A pump for transferring fluid from the void chamber to the probe, a motor for rotating the probe, plunger means for moving the probe through the nut, valve means for controlling the transfer of the fluid on the nut; the pump, motor, plunger means and valve And a computer means which controls the means to allow the use of almost all of the fluid coating the nut, thereby coating an object such as a nut with fluid utilizing centrifugal force without wasting material. 21. A coating system according to claim 20, wherein recirculation means operates to continuously stir the fluid by continuously moving the fluid through the valve means to eliminate stagnation. 22. The coating system of claim 21, wherein the coating system has a discharge means for cleaning the device by removing material to be removed from the device. 21. The coating system of claim 20, wherein the rotary ball feeder means is positioned in a single line prior to coating the nut using vibration. 24. A coating system according to claim 23, wherein a feeder having a vibrating feeding means delivers a nut or the like into the rotating ball means. 21. The coating system of claim 20, wherein the drying means comprises air discharging means and exhausting means for drying the nut and the like after coating. The coating system of claim 25 wherein said drying means is covered and temperature controlled. 21. A coating system according to claim 20, wherein said probe is removable for replacement with a probe for another fluid. 21. The method according to claim 20, wherein the probe is easily interchangeable and has a pulley integrally formed as part of the probe so that the speed of another probe can be controlled by exchange of the probe, thereby changing the user's error using a variable speed control means. Coating system that can reduce the removal. The object is continuously moved to the fluid application position and the hole probe applicator having at least one hole is moved from the position under the object to the coating to take advantage of gravity, the applicator is continuously rotated, and the applicator is in the coating position. The applicator when pumping fluid from at least one reservoir when it reaches and continuing to move the applicator upwards through the object by a predetermined distance and simultaneously reversing the pump to draw fluid from the hole of the applicator A method of selectively coating an object to be coated with a fluid having an internal cavity in such a way as to stop its upward movement and remove the applicator from the object. 30. The method of claim 29, wherein the applicator coats the object while withdrawing the applicator from the object. Positioning means for positioning the object to be coated at a predetermined position, probe means having a cavity and at least one hole, rotation driving means for rotating the probe means, fluid supply container, fluid probe from the fluid supply container The pump means for pumping the pump to the cavity hole of the probe, the moving means for moving the probe means from the first position in the internal cavity of the object, the rotary driving means, the pump means, the adjusting means to adjust the hole of the probe means Apparatus for coating the selected internal cavity of the object with a fluid having control means for coating the object in a predetermined manner using centrifugal force to disperse the fluid through. 32. A coating apparatus according to claim 31, wherein the probe means is substantially cylindrical and the hole at the tip of the probe means is smaller in diameter than the outer diameter of the shaft portion of the probe. 33. A coating apparatus according to claim 32, wherein said control means comprises a digital computer for adjusting said rotating means, pump means, and moving means to provide a uniform coating thickness. 34. A coating apparatus according to claim 33, wherein said digital computer comprises means for controlling a coating operation to selectively coat only a part of the internal cavity of said object. 32. A coating apparatus according to claim 31, wherein said digital computer comprises means for controlling a coating operation to selectively coat only a part of the internal cavity of said object. 35. The apparatus of claim 34, wherein said moving means provides substantial vertical movement of said probe means, said rotary drive means rotating said probe means continuously and thereby connecting with said aperture of said probe means for dispersal. And the centrifugal dispersion of the fluid is controlled by the pump means for introducing the fluid to a level in the cavity, wherein the centrifugal dispersion of the fluid is stopped by the pump means by stopping the pumping of the fluid going to the cavity hole of the probe means. 32. The probe according to claim 31, wherein said moving means provides a substantially vertical movement of said probe means, said rotary drive means rotating said probe means continuously and thereby connecting with said aperture of said probe means for dispersing. The centrifugal dispersion of the fluid is controlled by the pump means for introducing the fluid to a level in the cavity of the coating apparatus, wherein the centrifugal dispersion of the fluid is stopped by the pump means by stopping the pumping of the fluid going to the cavity hole of the probe means. . 37. A coating apparatus according to claim 36, wherein said probe means is substantially cylindrical and has a smooth outer surface and is driven by said rotational drive means to enable displacement removal from the housing. A position noise device for positioning the fastener, etc., a probe having a cavity and at least one hole; a drive motor for rotating the probe; a fluid pump chamber; a metering pump for transferring fluid from the fluid supply chamber to the cavity of the probe; Step motor for moving the probe vertically upward through the internal cavity of the fastener from the original position below the lower surface of the fastener to adjust the drive motor, the metering pump and the step motor to the centrifugal dispersion of the fluid through the hole of the probe And applying the fluid to the internal holes of the fastener or the like, which is configured as a digital computer for controlling the coating of the internal cavities. 40. The method of claim 39, wherein the drive motor continuously rotates the probe, and centrifugal dispersion of the fluid is by means of a metering pump that introduces the fluid to a certain level in the cavity of the probe that is connected to the hole of the probe for dispersion through the probe. And the centrifugal dispersion of the fluid is terminated by stopping the metering pump which pumps the fluid into the cavity of the probe. 41. The applicator of claim 40 wherein said digital computer control has means for adjusting its operation to selectively coat only a portion of the length of the internal cavity of said fastener. 42. The applicator of claim 41 wherein the probe has a substantially cylindrical cross section and the aperture of the probe has a tip diameter that is less than an outside diameter of the axial portion of the probe. 43. The applicator of claim 42 wherein the probe has a substantially smooth outer surface and the probe is movable and returnable within the housing assembly and the housing assembly and the probe are rotated together by a drive motor. The applicator of claim 43 wherein the fluid is conveyed by a metering pump to a position below the hole of the probe through a hollow tube located in the cavity of the probe. 45. The applicator of claim 44 wherein said hollow tube is held stationary while said probe continuously rotates around said probe causing a periphery dispersion of fluid pumped through the hollow tube by means of a metering pump. . 46. A coated object having a cleaning chamber in which discharge cleaning means for periodically cleaning said fluid from said device and a closed chamber into which heated air is introduced to shorten the time required for drying said fluid after the coating operation is completed are provided. Applicator further comprises a drying means for drying the. 40. A coated object having a cleaning chamber in which the exhaust cleaning means for periodically cleaning the fluid from the device is provided and a heated blowing air is introduced to shorten the time required for drying the fluid after the coating operation is completed. Applicator further comprises a drying means for drying the. 47. An applicator as in claim 46, wherein said internal cavity is an internal threaded portion. 40. An applicator as in claim 39, wherein said internal cavity is an internal threaded portion. The object to be coated is placed at a predetermined position, the probe having a hollow cavity and at least one hole is moved from the first position to the second position at which the coating operation is started at a predetermined speed, and the probe is moved at a predetermined rotational speed. Rotate the furnace along the longitudinal axis of the probe, and continue the movement of the probe from the second position at which the coating starts to the third predetermined position at the same time as the coating finishes and centrifugally disperse the fluid on the inner surface of the object through the hole. Pumping fluid from the fluid chamber into the hollow hollow of the probe, stopping pumping the fluid, withdrawing the probe from the position of the third well to the first predetermined position, and removing the object from the predetermined position Method for selectively coating the inner surface of the object, characterized in that consisting of. The object to be coated is placed in a predetermined position, the probe is rotated about the longitudinal axis of the probe at a predetermined rotational speed, and the probe having a hollow cavity and at least one hole is opened from the position below the object. Vertically moving the probe at a predetermined speed in the first predetermined position in the interior cavity, momentarily stopping the vertical movement of the probe at the first predetermined position, and coating from the first predetermined position where the coating operation is started. Continue the vertical upward movement of the probe at a second predetermined coating movement speed to a second predetermined position at which the work ends simultaneously, and decelerate the probe from the fluid reservoir to centrifugally disperse the fluid in the interior cavity of the object through the hole of the probe. Pump the fluid into the hollow cavity, stop pumping the fluid, withdraw the probe from the second predetermined position to a position below the object, and A method of selectively coating an inner surface of an object in a manner consisting of removing steps from the tooth. 52. The inner surface of an object according to claim 51, wherein the presentation pin is initially placed at a predetermined position of the object to be coated, and the positioning spring supports the object between the positioning spring and the side support to fix the object at the predetermined position. To coat with fluid. 53. The method of claim 52, wherein the centrifugal coating of the interior cavity of the object is continued while withdrawing the probe from the second predetermined location to the first predetermined location and wherein the centrifugal coating of the inner surface of the object causes the downward movement of the probe to A method of selectively coating an inner surface of an object in a stationary manner when reaching a first predetermined position in. 54. The method of claim 53, wherein the inner surface has an internal thread and the object is a fastener. 53. The method of claim 51, wherein the inner surface has an internal thread and the object is a fastener. ※ Note: The disclosure is based on the initial application.