The present invention generally relates to applicators for dispensing liquid materials and more particularly, to an applicator for applying conformal coatings to substrates, such as electrical components.
Conformal coating is the process of applying a dielectric material onto a substrate. Typically, the substrate is an electrical product, such as a printed circuit (“PC”) board or a device mounted thereon. Conformal coating, also called film coating protects the electrical components on the PC board from moisture, fungus, dust, corrosion, abrasion and other environmental stresses. Common conformal coating materials include silicone, acrylic, polyurethane, epoxy, synthetic resins and various polymers. When applied to PC boards, an insulative resin film of uniform thickness is formed as a solvent evaporates or, as a solvent free material is cured. Current applications require the conformal coating to be applied onto selected areas of the PC board and over some or all of the components thereon in order to preserve electrical and/or heat conduction properties. Applicators are conventionally pneumatically or electrically actuated, for example. In the case of pneumatically actuated applicators, an actuation valve, such as a solenoid valve, is used to supply positively pressurized actuation air to a piston chamber in the applicator in order to move a valve stem in the applicator to an open position. While the valve of the applicator is open, the film of coating material will be dispensed onto the substrate.
Automated systems may have one or several conformal coating applicators mounted on a robotic system. Machine speeds have gradually become faster and, therefore, faster actuation valves are used to cycle the applicator on and off as the robotic system moves the applicator relative to the PC board to selectively apply conformal coating to components on the board. The valve stem of the actuator reciprocates between a closed position in which a first end is engaged against valve seat, and an open position in which a second end is engaged against a hard stop element. Typically, the stop element is part of a stroke adjuster that allows the valve stem travel distance, or stroke, between the open and closed positions to be changed according to the application needs. With faster actuation valves, it has become more common to experience a “rebounding” effect as the valve stem impacts against the stop element at the end of the opening stroke. That is, the top end or second end of the valve stem will impact against the hard stop element, such as a stroke adjustment screw, and rebound or move slightly in the opposite direction one or more times before coming to a complete stop against the stop element. This rebounding movement will cause disruptions in the flow pattern at the leading end of the pattern (e.g., film) being applied to the substrate. For example, this phenomenon can cause the leading end of the film coating strip to have an undesirable “hammer head” or slightly wider shape than the remaining portions of the film strip.
It would therefore be desirable to provide a conformal coating applicator and method that prevent or at least reduce disruptions in the liquid flow upon opening the valve associated with the applicator.
The present invention generally provides an applicator for dispensing a liquid conformal coating material onto a substrate. The applicator includes a body assembly with a liquid flow passage having a liquid inlet adapted to receive the coating material, and a liquid outlet. The body assembly includes a valve seat positioned between the liquid flow passage and the liquid outlet. A valve stem is mounted in the body assembly for reciprocating movement between an open position and a closed position. The valve stem includes a first end and a second end. The first end of the valve stem engages the valve seat in the closed position to stop flow of the liquid coating material through the outlet. The first end disengages from the valve seat in the open position to allow flow of the liquid coating material through the outlet. The body assembly further includes a valve actuating mechanism operative to move the valve stem from the open position to the closed position and further operates to move the valve stem from the closed position to the open position. A resilient dampening element is operatively coupled between the body assembly and the valve stem. The resilient dampening element provides a biasing force against the valve stem as the valve stem moves from the closed position to the open position. This eliminates, or at least reduces rebounding movement of the valve stem toward the closed position and results in a cleaner or sharper leading edge of the applied coating pattern.
Various other features and aspects may also be incorporated into the applicator. For example, in the preferred embodiment the resilient dampening element more specifically comprises a resilient, elastomeric material. The valve stem comprises an assembly including a piston. The piston is positioned in a piston chamber and the piston chamber is configured to receive pressurized air at least on one side of the piston for moving the piston and the valve stem to the open position. The valve actuating mechanism further comprises a spring return mechanism coupled to the valve stem and operative to move the valve stem from the open position to the closed position when the air pressure in the piston chamber is vented. The resilient dampening element is generally located between the valve stem and the hard stop element. A valve stroke adjuster includes a stroke adjustment element, such as a screw, that may be moved to adjust the distance that the valve stem travels between the open and closed positions. The resilient dampening element is located between the valve stem and the stroke adjustment element. In this embodiment, the stroke adjusting element is the hard stop. In one embodiment, the dampening element is in contact with the valve stem in the open and closed positions as well as during movement of the valve stem between the open and closed positions. As an alternative, there may also be a gap between the valve stem and dampening element when the valve stem is in the closed position.
The invention further provides a method of dispensing a liquid conformal coating. The method generally comprises supplying pressurized liquid conformal coating material to a liquid flow passage of an applicator. A valve stem is moved along a stroke length defined between a closed position in which the first end of the valve stem is engaged with a valve seat to prevent the flow of the liquid conformal coating material from the liquid flow passage to an outlet of the applicator, and an open position which the first end of the valve stem is disengaged from the valve seat to allow the liquid conformal coating material to flow from the liquid flow passage to an outlet of the applicator. A resilient, elastomeric element is compressed as the valve stem moves to the open position to provide a biasing force against the valve stem and eliminate, or at least reduce rebounding movement of the valve stem toward the closed position.
A preferred method further comprises compressing the resilient, elastomeric element between the stroke length adjustment element and the valve stem. The method further comprises moving the valve stem to the closed position with a spring return mechanism. The resilient, elastomeric element preferably contacts the valve stem in the open and closed positions as well as during movement of the valve stem along the stroke length between the open and closed positions. The method further comprises using a stroke length adjuster with an adjustment element contacting the resilient, elastomeric element and moving the stroke length adjustment element to vary the stroke length of the valve stem according to application needs.
Various additional features and aspects will become more readily apparent to those of ordinary skill in the art upon review of the following detailed description of an illustrative embodiment, taken in conjunction with the accompanying drawings.
Referring generally to
Referring more specifically to
The nozzle assembly 32 includes a valve seat 62 with a passage 62a communicating between the liquid flow passage 40 and the outlet 44 of the nozzle element 46. This passage 62a is selectively opened and closed by disengagement and engagement of the valve seat 62 with the first end 70a of a valve stem 70. The valve stem 70, in this embodiment, comprises an assembly including a needle 72 mounted for reciprocating movement within the liquid flow passage 40. The valve stem 70 also includes other components, as will be discussed below, and may take on other forms including assemblies or integrally formed stems. The first end 70a of the valve stem 70 is engaged with the valve seat 62 to close the passage 40 as shown in
The assembly that comprises valve stem 70 further includes a piston 110 as well as a receiving element 112 for a compression coil spring 120 associated with the spring return mechanism 80 and stroke adjustment mechanism 30. The piston 110 includes a piston element 122 having a surrounding wiper 124 that engages the internal walls 126 of the piston chamber 100. Piston element 122 is frictionally secured to an intermediate mounting element 132 in part by an O-ring 132a. Mounting element 132 is rigidly coupled to the needle 72 by way of a threaded connection 130 such that the piston element 122 moves with the needle 72 during reciprocating movement along the stroke length of the valve stem 70. The spring receiving element 112 is rigidly coupled for movement with the needle 72 by way of internal threads 142 engaging with the external threads 144 at the upper end of the needle 72. The compression coil spring 120 of the spring return mechanism 80 is positioned between the receiving element 112 and a spring preload element 160 that receives a threaded adjustment screw 162. The screw 162 serves as an adjustment stop element to limit upward movement of the valve stem 70, i.e., to set the “open” position of the valve stem 70. The preload element 160 is threadably received within an upper cap portion 164 of the body assembly 12 via a threaded connection 166. Upper cap portion 164 is attached to main body 14 by bolts (not shown) or other means. Using a tool (not shown) placed in a slot 167, the preload element 160 may be rotated into upper cap portion 164 and will compress the spring 120 with the necessary preload. When the preload element 160 is positioned as desired, an internally threaded retainer 168 is tightened down against the cap portion 164 to maintain the position of the preload element 160. Rotation of the screw 162 will adjust the stroke length of the valve stem 70 or, in other words, the distance that the valve stem 70 travels in moving between the closed position shown in
A resilient dampening element 180, which may take the form of a disc-shaped elastomeric element or other suitable dampening element, is positioned between a portion of the body assembly 12 and the second end 70b of the valve stem 70. The body assembly 12 includes all structure of the applicator 10 except for the valve stem 70 and the resilient dampening element 180. The valve stem 70 includes all the elements that move with the valve stem 70 as it moves between its open and closed positions. In this embodiment, the resilient dampening element 180 is specifically located between the lower end surface 162a of the screw 162 of body assembly 12 and the spring receiving element 112 of the valve stem 70. The elastomeric element may be formed, for example, of natural or synthetic rubber materials, such as nitrile rubber, fluoroelastomers, or polyurethane, and may have a Durometer hardness in the range of 30-90. The preferred material is polyurethane. When the screw 162 is rotated, it moves along the long axis of the valve stem 70 to provide an adjustable stop position for the upper end 70b of the valve stem 70 which, in this case, is defined as the upper end of the spring receiving element 112 that forms part of the valve stem 70. Thus, if the screw 162 is backed off or rotated counterclockwise, when viewed from above in
In operation pressurized liquid conformal coating material is supplied from a suitable supply 190 through fitting 16 and into passage 40 with the valve stem in a closed position as shown in
While the present invention has been illustrated by a description of various preferred embodiments and while these embodiments have been described in some detail, it is not the intention of the Applicants to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications will readily appear to those skilled in the art. The various features of the invention may be used alone or in any combination depending on the needs and preferences of the user. This has been a description of the present invention, along with the preferred methods of practicing the present invention as currently known. However, the invention itself should only be defined by the appended claims.