Powder coating gun with manually operated controls on gun

Control method and apparatus for a manual spray gun may include a second manually actuated trigger disposed on the spray gun handle, with the second trigger being operational to select or change one or more coating operation parameters.

TECHNICAL FIELD OF THE DISCLOSURE

The disclosure relates to the art of applying material onto surfaces, such as for example, spraying or coating a surface with a coating material. More particularly, the disclosure and inventions relate to arrangements and methods for controlling a material application device such as, for example, a spray gun.

BACKGROUND

Powder coating material such as powder paint is commonly applied to an object by spraying the powder coating material. Typically, a spray gun or material application device is used, and spray guns may be manually held and operated or automatic spray guns may be used that are controlled electronically. For manual spray guns, a trigger type device is commonly disposed on the handle so that an operator can finger actuate the trigger to start and stop a coating operation. It is known to provide a separate trigger or switch on the spray gun handle to initiate a purge operation.

Spray technologies include for example electrostatic, non-electrostatic and tribo-electric. The powder flow path through a spray gun must be purged whenever the powder coating material, such as its color or other characteristic, is changed, in order to prevent unwanted contamination. In addition, various parameters are commonly changed for different parts being coated or when different coating materials are used. Such changeovers result in lost production time.

SUMMARY OF THE DISCLOSURE

The present disclosure presents a number of inventive aspects for both apparatus and methods relating to controlling a coating material application device. In accordance with one inventive aspect of the disclosure, a selection or auxiliary device is provided that allows an operator to select one or more coating operation parameters either before, during, between or after coating operations, or in one embodiment, during operation of the material application device including optionally during a coating material operation. In one embodiment, the device may be realized in the form of a manually actuated device that may be used to make adjustments or selections or changes to one or more coating operation parameters. In an exemplary embodiment, the manually actuated device may be in the form of a finger actuated trigger disposed on a handgrip of a manually operated spray gun. Examples of coating operation parameters may include but not limited to flow rate of the coating material, flow rate of the air that produces a flow of coating material, and preset coating operation recipes. The manually actuated device may be in addition to a second manually actuated device disposed on the handgrip such as for example a second trigger that may be used, as one example, to control the on/off operation of the material application device. Functionality associated with actuation of the auxiliary device may be programmable for specific control features desired in particular applications and uses.

In accordance with another inventive aspect of the disclosure, a first controller function may be provided that is associated with a material application device, such as a controller disposed in or on or with a material application device. A second controller function may also be provided that is external or remote from the material application device, such as for example a system controller function that controls operation of various components including but not limited to one or more pumps, feed centers, vibrators, overspray recovery systems, spray booth related controls and so on. The first controller and second controller may communicate with each other, for example over a network, so that a selection or auxiliary device functions to control the one or more coating operation parameters. For example, a trigger may be used to adjust flow rate of the coating material from a spray gun. In another embodiment, the second controller may be used to program or update the software for the first controller. The second controller may optionally be used to change or program the functionality that is associated with actuation of the selection or auxiliary device.

The disclosure also contemplates methods embodied in the use of such apparatus. The disclosure further presents inventive methods including a method for controlling a coating material application system that includes a material application device that is manually held and operated during a coating operation, the method in one embodiment including the steps of manually holding a handgrip of the material application device with one hand, and using the same hand while gripping the material application device to select at least one coating operation parameter.

Further inventive aspects, advantages and benefits will become apparent to those skilled in the art after considering the following description in conjunction with the accompanying drawings.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

The inventions described herein are explained and illustrated in the context of a powder coating material application device, such as, for example, an electrostatic powder spray gun. However, the exemplary embodiments are not intended to be a limitation on the application or use of the various inventive aspects presented in this disclosure. For example, the inventions may be used with non-electrostatic material application devices and with tribo-charging guns that do not utilize an electrode, or combinations thereof. The inventions also are not limited to any particular type or use of coating material. Additionally, the terms ‘spray’ and ‘spray pattern’ are intended to be understood in their broadest meaning to include not only those processes commonly referred to as ‘spray’ or ‘spraying’ but additionally any application technique involving the directing of a generally dry particulate coating material across a space towards a target. The spray pattern may be but need not be atomized. When used, atomization may be based on pressure, air, or both or other atomization techniques and combinations thereof. Still further, the terms ‘spray’ and ‘spray patterns’ are not to be limited to any particular time duration that the material is directed towards the target. In other words, very short bursts of material or narrow jets of material are still to be construed as falling within the understanding herein of the word ‘spray’ and ‘spray pattern’. While the inventions are also described and illustrated herein with reference to an exemplary spray gun configuration, shape and arrangement, nothing herein should be construed as limiting the inventions o such embodiments. Many different configurations and designs may be used, far too many to identify or describe herein.

As used herein, a purge operation refers to stopping flow of coating material from a material supply to a material application device, and applying pressurized purge air through part or all of the coating material flow path to remove as much of the coating material from the flow path as can be achieved for a given purging system design. As used herein, a coating operation refers to a set of events and/or various steps and operations that occur in order for a coating material to be applied to one or more objects. Thus the term coating operation is generally inclusive of one or more, and typically many, operations, functions, settings and conditions that determine the application of material to an object. For example, but not by way of limitation, a coating operation may include supply pump operation, spray booth and overspray recovery operations, conveyor system control, electrostatic control functions, material flow rates, atomization and flow air control, coating material characteristics and so on. For any particular coating operation then, there may be as few as one, but typically many parameters that are controlled or set, or in many cases are adjusted when coating operations are changed. These coating operation parameters may include but are not limited to, for example, voltage and current for electrostatic operations, coating material flow rates, air flow rates, purge timing and flow, as well as many other operations, functions, settings and conditions related to a coating operation. Therefore, the term coating operation parameter should be broadly construed as referring to any information, control, function, input, output, operation, setting, condition or feature related to a coating operation that affects or influences a coating operation. The various parameters or subsets thereof, associated with a specific coating operation are generally referred to herein as recipes or coating operation recipes, and such recipes are typically, though need not be, predetermined and stored in memory for access by a main control system which controls the various system components to execute a coating operation in accordance with a selected recipe. Usually recipes are fixed as far as a line operator is concerned, but some systems may be designed to permit recipe changes and other variations by any personnel with proper authority to make such changes. Thus as used herein, recipe is not intended to be limited to a set of parameters that cannot be changed, but may include recipes in which one or more parameters, instructions, controls and functions may be changed. The term recipe thus also includes recipes that are predetermined or preset, as well as recipes that are put together on a more real time basis before a coating operation, or modified prior to a coating operation.

With reference toFIG. 1, a manually operated material application device10may include a nozzle portion12, a barrel portion14and a handgrip portion16. In the examples herein, the device10may be, for example, any suitable material application device or spray gun. The terms spray gun and material application device are used herein interchangeably, however, it is to be understood that a material application device may be realized in many forms other than just a spray gun and is not limited to that terminology. Typically, the nozzle portion12, barrel portion14and handgrip portion16are each multi-piece assemblies, and also separable from each other. However, the present disclosure and the inventions herein are not limited to any particular design, shape or configuration of the material application device10or its constituent parts, including the design, shape or configuration of the handgrip portion16, and may include machined parts, molded parts, combinations thereof, integrated portions and so on. In some descriptions herein, general reference may be made to a material application device body or device body, by which is meant any part or combination of parts that form portions or all of the structure of the application device, such as for example, the handgrip portion16, the barrel portion14and the nozzle portion12. The various inventions and inventive aspects of the disclosure may be realized in far too numerous ways and configurations of the handgrip portion16, as well as the barrel portion14and nozzle portion12to identify and disclose herein.

The handgrip portion16may be realized, for example, in the form of a handle18that is manually held or gripped during operation of the spray gun10. For electrostatic devices10, the handle18may include a portion that contacts the operator's hand and is grounded. For purposes of this description, the term handgrip is generally used to refer to any structure or assembly or member that is manually held or gripped by an operator during operation of the application device10to support and control the device10, with a handle, grip or other structure being exemplary embodiments of such a handgrip.

As illustrated inFIG. 1, a coating material supply20may be used as a source of coating material to the spray gun10. A feed or supply hose22is commonly used to connect the spray gun10with the supply20. A hose connector24may be provided to securely attach the supply hose22to the spray gun. In the case of an electrostatic spray gun as shown inFIG. 1, an electrical control cable or connection26may be provided between a control system28and an electrical input30of the spray gun. The control system28may also receive one or more signals from the spray gun10, such as for example a trigger actuation signal that indicates that the operator has activated a first manually actuated device32. In the exemplary embodiment, the first manually actuated device may be realized, for example, in the form of a main trigger or switch32to initiate a coating operation. The main trigger32may be designed so that an operator is able to actuate the trigger32using a finger of the same hand that the operator is using to hold the spray gun10via the handgrip portion16. By ‘main’ trigger is simply meant that the primary function associated with the first trigger32, but not necessarily the only function, is to control on/off operation of the spray gun for a coating operation. When the main trigger32is activated, an electrical signal or condition (such as closed contacts) is sent to or detected by the control system28to begin flow of coating material to the spray gun10, and other signals may be generated to activate electrical power for the spray gun (in the case of electrostatic operation for example). In the exemplary embodiment, the electrical signal or condition that is associated with actuation of the main trigger32is coupled to and detected initially by a display controller110(seeFIG. 4herein), which will be explained in greater detail herein below. The display controller110communicates with the control system28over a network, so that the control system28detects actuation of the main trigger32via the display controller and network. Alternatively, the main trigger32actuation may be coupled to the control system28other than through the network, for example, by a wired or wireless connection directly between the main trigger32and the control system28.

All electrical signals or conditions between the spray gun10and the control system28or other system components may be transmitted along electrical lines through the electrical cable26. Alternatively, signals may be transmitted using wireless techniques including RF, IR optical and so on. In the embodiments herein that include the use of a network to link the material application device10with the control system28, the network wiring (single wire or multi-wire) may also pass through the electrical cable26.

The control system28may be any suitable arrangement as is well known in the art for controlling input power and operation of the spray gun electrical requirements, as well as controlling operation of the coating material supply20, a purge supply34and other system related features such as a spray booth, parts conveyor and so on (not shown). The material supply20forms no part of the present inventions except as used in combination with the apparatus and methods as set forth herein. The coating material supply20typically includes a pump or pumps under the control of the control system28so that the control system28starts the pump in response to the operator actuating the trigger32. This causes coating material to flow through the handgrip portion18, the barrel portion14and out through the nozzle portion12to form a desired spray pattern S, typically in the form of a cloud like pattern for powder coating material, for example.

A purge supply34under the control of the control system28may be used to provide pressurized purge air or other gas through a purge hose36to the spray gun10. The purge hose36may be connectable to a suitable hose connector input38disposed on the handgrip16, and in this example a base40of the handle18. The purge air inlet to the handgrip16may thus be separate from the coating material input at the hose connector24, so that purge air initially enters a coating material flow path (not shown inFIG. 1) by first passing through a purge air flow path within the handgrip16. The present inventions however are not limited to any particular purging arrangement or coating material flow path arrangement. For example, purge air may alternatively be introduced into the coating material flow path near or at the supply20, or even up closer to the barrel portion or the nozzle portion12, to name a few examples. The present inventions are also not limited to a coating material flow path that begins at the base of the handle40. In many gun designs, the material flow path first enters the gun up at the barrel portion, for example.

FIG. 2illustrates the application device10in longitudinal cross-section. As shown, the handle18may be ergonomically contoured to ease strain on the operator's hand during prolonged operation or shifts. The coating material hose connector24has a first end42adapted to receive one end of the supply hose22(not shown) and an opposite end44that telescopically slides into a first end46of an inlet tube48.

The inlet tube48extends up through the handle18and mates, such as for example with a telescopic connection, with one end of an elbow adapter50. The elbow adapter50has another end that mates with, such as for example with a telescopic connection, a first end of an outlet tube52. The outlet tube52extends along the barrel portion14to the nozzle portion12so that coating material exits through the distal end of the outlet tube, and into and through the nozzle portion12to form the spray pattern S. The details of the nozzle portion12are not needed for understanding and practicing the inventions of this disclosure. In alternative designs, for example, the outlet tube52may itself form or provide an outlet orifice through which coating material exits the nozzle. In the exemplary embodiments herein, the nozzle portion12may include an electrode assembly54that is charged by an internal power supply section56in the rearward portion of the barrel14. The supply56typically is realized in the form of a high voltage multiplier and related circuits as is well known. Many different types of electrode assemblies may be used, including electrode tips that are positioned outside the nozzle portion12, as well as many different types of power supply designs, configurations and locations, including external power supplies and hybrid designs with portions of the power supply external the spray gun10and other portions internal the spray gun10. An electrode air wash inlet58may be provided that is connectable to a source of pressurized air, with an air passageway (not shown) that extends up through the handle18, along the barrel portion14and into the nozzle portion12so as to provide a flow of air across the nozzle tip to help prevent the accumulation of coating material on the nozzle tip.

The inlet tube48, the elbow50and the outlet tube52thus combine to form or define a coating material flow path—in the exemplary embodiment being formed by the interior volume of the inlet tube48, the elbow50and outlet tube52(and as represented by the arrows associated with the numeral60)—that extends from the handle18, along the barrel portion14to the nozzle portion12.

In accordance with an inventive aspect of the present disclosure, a second manually actuated device70may be provided. This second manually actuated device70may be realized, for example, in the form of a second or auxiliary trigger or switch. Preferably, although not necessarily, the auxiliary trigger70may be finger actuated, and in particular with a finger of the operator's hand that is also holding the spray gun handle18. Separate fingers may be but need not be used to actuate the first and second triggers32,70.

With reference toFIGS. 3,9A and9B, the main trigger32and the auxiliary trigger70may be operably coupled to actuate membrane switches or other suitable switch designs. The main trigger32in this example includes main trigger body72having a pair of flexible arms74extending there from. A distal end76of each flexible arm74engages one side of a membrane switch assembly78, near a membrane switch80that is associated with the main trigger32, such as at locations76aand76bon opposite sides of the membrane switch80. The distal ends76may alternatively engage any other conveniently available surface that will provide adequate support so that the legs74may be compressed inward when the main trigger body72is pulled toward the handle18to actuate the main trigger32.

In this example, the membrane switch assembly78includes three membrane switches80,96and98. The lower switch80may be used to detect actuation of the main trigger32, which the upper two switches96and98may be used to detect actuation of the auxiliary trigger70(as will be further explained herein below). The various membrane switches may be disposed on a board78a, although the membrane switches may be installed in the spray gun in any other convenient manner as desired.

The main trigger body72may further include an inwardly facing hollow boss73that receives and retains a softer actuating post75. The actuating post75is sized so that when it is fully inserted inside the boss73, and end portion75aextends slightly out beyond the end of the boss73. The end portion75aengages the associated membrane switch80to actuate the switch80when the main trigger body72is pulled by the operator. The main trigger body72may be attached to the handle18by any convenient means, such as pivot posts77aon the handle18(only one shown inFIG. 9A) and cooperating holes77bon the main trigger body72. The posts77amay also be used to support the auxiliary trigger70on the handle18. The main trigger body72may further include a window79through which the auxiliary trigger70may extend after assembly. In this manner, an operator may easily access both triggers32and70with one finger if so desired.

When the trigger32is pulled inward (leftward as viewed inFIGS. 3 and 9A, the distal end75aof the actuating post75presses against a flexible contact portion80aof the membrane switch80, which makes electrical contact with a stationary contact portion82(FIG. 3). This electrical contact or connection provides an indication to the control system28to start a coating operation. When the trigger32is released by the operator, the spring like bias of the flexible arms74pushes the trigger body72back to its deactivated position shown inFIG. 3, withdrawing the post75far enough away from the switch80so that the flexible contact portion80asnaps back or moves away from and out of contact with the stationary contact portion82, thereby signaling to the control system28to stop a coating operation. When the main trigger32is released, the post75may but need not remain in actual contact with the flexible contact80a.

The use of the post75has a number of advantages. Preferably, the post may be made of a softer material, such as rubber for example, so that the operator receives a softer tactile feedback for more comfort. By simply changing the relative hardness or softness of the post, the feel can be changed. The use of a soft post75such as rubber material also allows the post75to compress so as to reduce damage on the switch80due to over travel or excessive force applied to the trigger32. The use of the two flexible arms74provides redundancy. Should one of the arms become damaged or break, the other arm will still allow the trigger32to function, and in particular will assure that the switch80is opened when the trigger32is released.

The auxiliary trigger70in this embodiment may be a dual switching device in which the auxiliary trigger70has a neutral or deactivated position illustrated inFIG. 3, a first actuated position and a second actuated position. However, the present inventions are not limited in any manner to a particular trigger configuration nor to a single auxiliary trigger. The auxiliary trigger may have more than two actuated positions, or there could be more than one such auxiliary trigger. As an example, the manually actuated device70may be a slide switch with multiple positions or a rotary switch with multiple positions, or a joystick with multiple positions, and so on. In any case, the auxiliary trigger/switch70design will be determined by the total functionality that is to be carried out by operator use of such devices.

The auxiliary trigger70may include a finger engageable lever84that extends from a central hub86. The hub86may include a spring or other device (not shown) that normally urges the trigger70to the neutral position, meaning that a force needs to be applied to the trigger70in order to actuate a related switch. Extending from the hub86are first and second actuation arms88and90that may engage but need not engage respective flexible contacts92and94of respective upper and lower membrane switches96and98when the trigger70is in the neutral position. Thus, when the auxiliary trigger70is pivoted upward as viewed inFIG. 3, the first actuation arm88presses against its associated flexible contact92to close the upper membrane switch96. Similarly, when the trigger70is pivoted downward as viewed inFIG. 3, the second actuation arm90presses against its associated flexible contact94to close the lower membrane switch98. It should be noted that an operator may easily actuate the auxiliary trigger70while the main trigger32is either also actuated or when it is not actuated. The membrane switches96,98when actuated indicate to the control system that a desired action or function is to occur. As with the main trigger switch80, the corresponding electrical signals or conditions for the auxiliary trigger switches96,98are communicated to the control system28via the display controller110and the network112(FIG. 1). Alternatively, these signals may be communicated in a wireless manner or through wires along the electrical cable26.

For example, the control system28may include instructions such as in software or otherwise, that the up/down actuation of the auxiliary trigger70relates to a command to increment or decrement a coating operation parameter. Alternatively, the auxiliary trigger actuation may be used to scroll through a list of available choices for changing or selecting one or more coating operation parameters. Many other alternative functions and controls may be associated with actuation of the auxiliary trigger70, far too many to list herein. Moreover, the functionality of the auxiliary trigger70may change for different operating modes of the spray gun10or the system. For example, during a coating operation, actuation of the auxiliary trigger70may increase or decrease material flow rate, but during a purge operation the trigger may be used for shutdown or standby modes. Additional features and functions will be described in greater detail herein below.

With reference toFIGS. 2 and 4, in accordance with another inventive aspect of the present disclosure, a visual information device, such as a display100, is provided for presenting information to an operator concerning one or more operating parameters or other information about the spray gun10, one or more of the system components such as the purge supply34, the material supply system20and so on. Preferably, the display100is disposed on or with a portion of the spray gun. In the exemplary embodiment, the display100may be installed at the back end of the barrel portion14, so as to be easily visible to an operator while the operator is using the spray gun.

The display100may be conveniently attached or recessed within the gun body, in this example just aft of the power supply section56. A protective viewing collar102may be used so that the display is protected from adverse impact and contamination, and also perhaps in some situations more easily viewed. A protective lens or cover104may further be provided, and the lens104may include appropriate legends and markings for facilitating use of the display100as needed. The display100may further include a visual indicator device106, such as a pair of seven segment LEDs for example, and one or more circuit boards108that may contain a display controller110and related and additional circuitry. The display controller110performs over all control functions for the display100, and may also include a network interface so that the display controller110may communicate over a network112(seeFIG. 1) with a main controller114associated with the control system28. A suitable network may be a single wire network such as for example a LIN network (the single wire passing through the electrical cable26for example), but any network including multi-wire and wireless may alternatively be used as needed. In the exemplary embodiment, the display100may also include one or more manually actuated inputs116, such as, for example, pushbutton membrane switches. The manual inputs116, however, may alternatively be disposed elsewhere on the application device.

With reference toFIGS. 5 and 6, the display100manually actuated inputs116may include first and second pushbutton membrane switches118and120, for example, although any switch or selector device may be used as needed. Also, the visual indicator device106may include first and second seven segment LED displays122and124. Although the displays122and124in this example are numeric, other displays including alphanumeric, LCD and others may be used that are suitable to convey information desired to be displayed to an operator. Additional visual indicators may be used as desired. For example, first and second lamps, such as LED's,126and128may be used for illuminating associated icons130and132(FIG. 6).

As an example, one of the manually actuated inputs116may be used as a Mode selection switch118. The other manually actuated input may be used as a Purge Start switch120. When the Purge Start switch120is actuated, an indication is sent to the control system28over the network112and the control system28initiates a purge operation. When the Purge Start switch120is not activated, the system may be in a standby condition or a coating operation condition, or other condition as desired. Purge operations may be initiated in other ways besides use of the second input120. For example, the control system28may be programmed to recognize that when the auxiliary trigger70is actuated, a purge operation begins. This allows an operator with one hand to control a coating operation and a purge operation. In such a case, the second input120may be programmed to perform another function, such as a system shutdown, a reset or any other desired action or operation.

The display100in some systems may have its own functionality for presenting information to an operator about any number or type of system related data and parameters. For example, the display controller110may be programmed to simply display material flow rate during a coating operation based on data received from control system28over the network112. Material flow rate may be expressed, for example, in grams per minute, or as a percentage of maximum flow rate, to give two examples. Material flow rate may also be extrapolated from air flow values, such as flow air rate.

However, it is further contemplated that the display100may be used to greatly enhance the flexibility and functionality of the auxiliary trigger70. Since the auxiliary trigger70may be a multiple input device, it may be used to control what information is displayed and to make selections from a listing of options. As an example, the Mode Select button118may be used to select different display modes for the display100. In one embodiment, pressing the Mode switch118places the device in a flow rate mode which causes the second icon132lamp128to be illuminated. Pressing the Mode switch118again extinguishes the second icon132lamp and illuminates the lamp126for the first icon130, which places the device in a Folder display mode. Each successive actuation of the Mode button toggles the display between Folder Mode and Flow Rate Mode.

In the Folder display mode, the operator may next use the auxiliary trigger70to scroll up and down or forward and backward through a list of coating operation preset recipes. Each actuation of the auxiliary trigger70presents a new preset number to the operator via the visual indicator device106. In the example ofFIG. 6, the display is in the Folder Mode, and preset02is being displayed. If the operator leaves the display at preset02, then the control system28will initiate the desired operating parameters for that preset recipe. The operator does not need to necessarily know what all parameters and conditions will be adjusted for that particular recipe, only that this is the recipe either called for or that is working best for the particular coating operation. Optionally, only preset numbers that actually have information associated with them need be displayed to the operator.

In the Flow Rate Mode, the associated icon132is illuminated so the operator knows which mode is being used. In this example, the visual indicator device106now may display flow rate for the coating material through the spray gun10This information for example may be sent from the control system28over the network112to the display controller110. When in the Flow Rate Mode, the operator may actuate the auxiliary trigger70up and down as desired to increase or decrease the flow rate parameter. Since this functionality is independent of the main trigger32, the operator can initiate these selections even while actually performing a coating operation or just prior to or after a coating operation, as the case may be.

The display100greatly enhances this functionality of the auxiliary trigger70because it allows the operator to visually observe the information related to the selected mode of operation, and in also to view options, make selections and view confirmation of the selections, without having to divert attention or field of view away from the spray gun10or the object being coated. This allows one or more operating parameters to be changed or selected without interrupting a particular coating operation, or at least without having to look away from the spray gun or coating area in order to implement such changes, selections and to confirm the selection made. For example, in the Flow Rate Mode, the operator can simply actuate the auxiliary trigger70up or down as needed to adjust or select flow rate during a coating operation to improve the product finish. Or the operator may switch preset recipes as a new object to be coated enters the coating area, or if the current preset is not adequately coating the object. Alternatively, the system may be programmed to allow selections, such as flow rates or preset recipe select or purge initiation for example, when the main trigger32is not actuated. Still further, the functions and controls that are associated with actuation of the auxiliary trigger70may be a function of whether the main trigger32is actuated or not, and further a function of what mode is selected via the manual inputs116. For example, if the main trigger32is actuated, the auxiliary trigger will not be able to initiate a purge operation.

Thus, the combined functionality of the auxiliary trigger70and the display100allows an operator to control a coating operation including selection of one or more operating parameters using one hand if so desired, even the same hand that is being used to support or grip the spray gun, all without having to look away from the spray gun or the coating area to verify selections made.

There is no necessary limitation on the functions and parameter selections that may be programmed for the display100or the auxiliary trigger70. Any functionality and parameter selections may be made available as needed for a particular system. Also, the use of additional auxiliary triggers or multi-position manual actuation devices can further increase the flexibility of the overall concepts described herein. As another example, although successive actuation of the auxiliary trigger70may be used to step through options or incremental changes for one or more coating operation parameters, flow rate for example, if the trigger is held down then the values may increment in greater steps or faster, for example.

The control system28may also include a main or system display140(FIG. 1) that may be used, for example, during system setup, calibration and so on. This display140, however, may or may not be located close to the operator working area, or may not be visible to the operator during a coating operation. The gun mounted display100may present some or all of the same information presented back at the system display140.

To name just a few examples of alternative functionality, by appropriate settings and programming if the control system28and the gun controller110, the auxiliary trigger70may be used to: adjust charging voltage up and down; adjust current limits up and down; adjust the presets of all the guns in a system, including automatic guns, using a manual gun as a master; and to initiate purge operations or color change operations. Color change operations may include operations and functions such as, for example, supply changeover, various purging operations, spray booth cleaning operations, overspray recovery operations, gun blow off and so on.

These are but a few of the many programmable or selectable functions that may be assigned to the auxiliary trigger70. Additional options are available for the manual inputs116that are on the display100. For example, these manually actuated inputs may have functionality assigned to them or programmed such as preset recipe select; initiate purge operation; a disable button, automatic gun triggers, and multiple flow control modes. For flow control, two available and exemplary options are to use one of the manually actuated inputs116to present a choice of a traditional flow control mode or a total flow control adjustment mode. In the traditional flow control mode, the auxiliary trigger70may be used to adjust flow air or atomizing air settings independently of each other. For example, in one input116mode the auxiliary trigger70may be used to adjust flow air, and in another selected input116mode the auxiliary trigger70may be used to adjust atomizing air. In the total flow control mode, an operator may select a total air flow setting via an input function to the main controller114(or alternatively for example total air flow may be selected as part of a preset recipe selection). The total air flow parameter may for example be used to select the velocity of the coating material from the nozzle portion12. The operator may then use the auxiliary switch70to select the percentage or ratio of the total air flow that is to be flow air and atomizing air to achieve desired coating material velocity, flow rate and/or film deposition. Adjusting the ratio, for example, will not change the velocity parameter but will change the amount of powder in the coating material cloud that is produced from the spray gun10. The control system28then sets the appropriate atomizing air value and flow air value based on the two selected input values of total air flow and selected ratio.

It should be noted that reference herein to parameters and values should not be construed in a limiting sense. Parameters and values selected may be actual data points based on empirical or predicted analysis, but also may be numbers, values or other data or information that represent coating operation parameters as to performance, effects and results, rather than representing actual data points. For example, a preset recipe number can be thought of as a parameter or value that is selectable by the operator, but actually just represents or encodes one or more settings, values and so on for a coating operation. As another example, flow rate information presented to the operator on the display100may be actual flow rate values as measured, or may instead be identified as a scale, such as from 0% to 100% of total flow. Thus, the present disclosure should not be construed as requiring any particular format or code or representation of the coating operation parameter choices and selections or other information presented to the operator via the display100and selected via the manually actuated inputs116and auxiliary trigger70.

Note that as the manual inputs116are selected for different functionality, the icons130and132may also be changed as appropriate to identify the functionality to the operator. For example, simple overlays may be used to change the icon figures that are illuminated by the lamps126and128.

Still further, in the exemplary embodiment or others, the system main controller114communicates with the spray gun mounted display controller110via the network112or other suitable communication link. In such cases, the main controller114may be programmed to recognize revision levels or other software and database information that the display controller110is using, and may perform various programming functions, such as for example, upload updates to the display controller110as needed, or update or upload different programs that may be needed for particular applications and configurations.

With reference toFIG. 7, an exemplary embodiment of a display controller110and related circuits is illustrated. The display controller110may be any suitable controller, such as a DSP circuit, for example, or other microcontroller, microprocessor, discrete circuits and so on. Preferably the display controller110is programmable via software as is well known generally in the art of programmable circuits, with appropriate memory and other peripheral support circuits. The display controller110may be disposed on one of the circuit boards108(FIG. 4) and includes appropriate connections to the LED and display driver circuits142. The display and driver circuit142may also receive as inputs the connections to the manually actuated inputs118and120. The display controller110may receive the inputs from the main trigger switch78(FIG. 3) as well as the auxiliary trigger switches96and98. The display controller110also provides communication with the control system28main controller114via wiring bundle144(the network114interface may be provided, for example, within the display controller110software and circuitry, and the main controller114may also have built in the necessary network interface functionality to communicate with the display controller110).

With reference toFIG. 8, in one embodiment of the control system28, the main controller114may be any suitable device such as for example, a DSP type controller, microcontroller, microprocessor, discrete circuits and so on, and known or later developed software, hardware and firmware programming may be used to implement the various functions and controls of the control system28. The main controller114may interface with a Gun Driver circuit146and DC supply148that provides a drive signal to the spray guns associated with the control system28. In this embodiment, the DC supply148is used to power a PWM drive signal for the spray guns. The main controller also interfaces with the network112for communication with the display controller110. The main controller114also interfaces via a serial peripheral interface circuit150awith a display driver circuit150for the system display140(FIG. 1). The spray gun display100may receive some or all or different display information as is presented on the main system display140. For example, flow rates may be displayed on both, as well as selected preset numbers. How much common information is presented at the same time on both displays is a matter of design choice. Additional information that may be displayed on the spray gun display may include various warnings, alarms and so on.

The main controller114may also interface with a network152such as a CAN network for example, for systems that use multiple guns and other equipment interconnected by a communication network, as is known. Other interfaces may include an external input such as a keypad or input knob156to allow the operator to provide inputs to the controller114. For example, it may be desired to adjust the recipe presets, or one or more individual parameters and controls assigned to a particular preset or presets. Since the external input156may produce voltage and current transients, a transient voltage suppression circuit158may be used as needed. Configurable (as in programmable or selectable) auxiliary external inputs160may include, for example, conveyor control, automatic gun trigger controls, fire detection signals and so on. Since these inputs may include field wiring noise and transient spike issues, it may be desirable to use signal conditioning circuits162such as opto-isolators for example to protect the main controller114from such effects. The main controller114may also interface with a vibratory box feeder via a relay circuit164to turn the vibrator on and off as needed. Still further, configuration switches such as DIP switches166may be used for external configuration selection of the control system28, as well as an optional external programming interface168. Many other or alternative interfaces and control and configuration options may be used as needed for a particular system, especially more complex systems that involves manual and automatic guns, advanced spray booth, powder recovery and gun mover designs, and so on.

The inventions have been described with reference to the exemplary embodiments. Modifications and alterations will readily occur to others upon a reading and understanding of this specification and drawings. It is intended to include all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.