This invention relates to control of gas flows, and more particularly to a bleed system for releasing pressurized gas from a chamber at a selectively adjustable flow rate. The bleed system is described primarily herein for application in a runaway control for an air motor which shuts off the motor when its speed exceeds a predetermined threshold speed. However, it is understood that the bleed system may be applied in any device where pressurized gas is released at a controlled rate.
It is difficult to accurately control a release of gas from a higher pressure region to a lower pressure region, particularly for an adjustable, low-level release. Due to manufacturing tolerances, conventional bleed valves frequently exhibit inconsistent or varying sizes of flow passages. Adjustments which are intended to produce minor incremental changes in flow rates can result in large step changes. Consequently, the valves are over-sensitive, cannot be accurately calibrated, and are not repeatable in setting a selected rate of flow.
A runaway control of the prior art is disclosed in U.S. Pat. No. 5,349,895, entitled “Air Motor Control,” which is hereby incorporated by reference. That patent discloses an air motor with an expansible chamber having a reciprocable piston driving a pump for pumping materials such as lubricants, sealants, or inks. A problem of pump runaway is at times encountered, due for example to breakage of a discharge line or running out of the material being pumped. The load on the motor is reduced such that the motor speeds up and drives the pump at very high speeds. That can damage the pump and cause expensive and time-consuming spills of material. A runaway control is provided for cutting off operation of the air motor under these circumstances. The control can be adjusted so that it activates to cut off the air motor at a selectable and predetermined threshold speed (e.g., between 5 and 50 cycles per minute) which depends generally on the viscosity of the material being pumped. Adjustment of cut-off speed is effected by a bleed valve for adjusting the rate of flow from a chamber having a pressure which varies in proportion to the speed of the motor. The bleed may be adjusted to vent a maximum quantity of air from the chamber when operating the motor at an increased speed, or adjusted to vent a minimal quantity of air when operating the motor at a nominal speed.
A drawback to runaway controls is that bleed valves are prone to be over-sensitive to adjustments, as described above. It is difficult to accurately calibrate the bleed valve to obtain a desired cut-off speed or to repeat previously obtained settings.
Among the several objects and features of the present invention may be noted the provision of a gas bleed system for releasing gas at a selectively adjustable flow rate; the provision of such a system which may be calibrated to obtain repeatable flow rates; the provision of such a system for use in a runaway control of an air motor for stopping the motor if it should start to run away; and the provision of such a system which is efficient and durable in use and cost-efficient to construct.
In general, the present invention involves an improved air motor of the expansible chamber type comprising an air cylinder, a piston reciprocable therein, a valve mechanism shiftable alternately to effect supply of air to and venting of air from opposite sides of the piston to reciprocate the piston, and a runaway control operable on increase in speed of the air motor above a speed limit to stop the motor. The control includes a pressure-responsive mechanism comprising an air chamber for air under pressure, a movable mechanism movable away from a first position in response to increase in air pressure in the chamber above a predetermined pressure limit to a second position, and movable back to the first position on reduction of pressure in the chamber below the pressure limit. The movable mechanism when in its first position enables operation of the air motor and when in its second position cuts off operation of the motor. An air pump is interconnected with the motor for operation simultaneously with the motor for delivering air under pressure to the chamber at a rate related to the speed of the motor. The improvement comprises a bleed mechanism for bleeding air from the chamber at a controlled rate. The pressure in the chamber is controlled by the rate of delivery of air under pressure to the chamber and the bleed of air from the chamber. On increase in speed of the motor above the speed limit, the pump, operating at increased speed, delivers air under pressure at an increased rate to the chamber over and above the capability of the bleed to bleed off the increase, and on ensuing increase in air pressure in the chamber above the pressure limit, the movable mechanism moves to its second position to cut off the motor. The bleed mechanism comprises a plurality of bleed flow paths of different lengths providing varying resistance to the flow of air. Each bleed flow path has an inlet communicating with the chamber and an outlet. A bleed path selector mechanism is movable between a plurality of different settings corresponding to the plurality of different flow paths. The bleed path selector mechanism communicates in each of the settings with the outlet of one of the bleed flow paths and allows the bleed flow path to vent for bleeding air from the chamber while sealing the outlets of the other bleed flow paths, whereby the speed limit at which motor cuts off can be adjusted by moving the selector mechanism to the desired setting.
In another aspect, a bleed system according to the present invention vents pressurized gas from a chamber to a vent opening at a selectively adjustable flow rate to control change of pressure in the chamber. The bleed system comprises at least two passageways each adapted for venting gas from the chamber and thereby tending to reduce gas pressure in the chamber, each of said at least two passageways having a length. A selector mechanism is adapted for establishing fluid communication between the chamber and vent opening via a selected one of the passageways such that gas is vented from the chamber through the selected passageway to the vent opening. The passageways have different lengths such that selection of one passageway results in flow of gas from the chamber to the vent opening at one flow rate and selection of the other passageway results in flow of gas from the chamber to the vent opening at a different flow rate.
In yet another aspect, a runaway motor control system according to the present invention is for an air motor. The control system comprises a pressure-responsive mechanism operable on increase in speed of the air motor above a speed limit to stop the motor. The mechanism comprises an air chamber for air under pressure, a movable mechanism movable away from a first position in response to increase in air pressure in the chamber above a predetermined pressure limit to a second position, and movable back to the first position on reduction of pressure in the chamber below the pressure limit. The movable mechanism when in its first position enables operation of the air motor and when in its second position cuts off the operation of the motor. An air pump is interconnected with the motor for operation simultaneously with the motor for delivering air under pressure to the chamber at a rate related to the speed of the motor. A bleed mechanism is for bleeding air from the chamber at a controlled rate. The pressure in the chamber is controlled by the rate of delivery of air under pressure to the chamber and the bleed of air from the chamber, whereby on increase in speed of the motor above the speed limit, the pump, operating at increased speed, delivers air under pressure at an increased rate to the chamber over and above the capability of the bleed to bleed off the increase. On ensuing increase in air pressure in the chamber above the pressure limit, the movable mechanism moves to its second position to cut off the motor. The bleed mechanism comprises a plate having a series of channels in a face thereof providing bleed flow paths of varying resistance to the flow of air.
In one more aspect, a bleed system of the invention vents pressurized gas from a chamber to a vent opening at a selectively adjustable flow rate to control change of pressure in the chamber. The bleed system comprises a passageway establishing fluid communication between the chamber and vent opening for venting gas from the chamber and thereby tending to reduce gas pressure in the chamber, the passageway having an inlet, an outlet, and a flow path extending between the inlet and the outlet. An adjustment mechanism is for selectively adjusting a length of the path to change a rate of flow of gas from the chamber to the vent opening.
In yet one more aspect, a bleed system of the invention is for venting pressurized gas from a chamber to a vent opening at a selectively adjustable flow rate to control change of pressure in the chamber. The bleed system comprises a passageway establishing fluid communication between the chamber and vent opening for venting gas from the chamber and thereby tending to reduce gas pressure in the chamber. An adjustment mechanism is for selectively adjusting a size of the passageway to change a rate of flow of gas from the chamber to the vent opening. The adjustment mechanism comprises a conical plug movable within a conically-shaped bore.
Other objects and features of the present invention will be in part apparent and in part pointed out hereinafter.
Corresponding reference characters indicate corresponding parts throughout the views of the drawings.
Referring now to the drawings and in particular to
The air motor 1 of the prior art, and its runaway control system, are now described with reference to
A valve generally designated 17 is mounted on the upper end head 5 for controlling supply of pressure air from a source thereof to and exhaust of air from opposite ends of the cylinder 3. The valve comprises an elongate metal block 19 (e.g. a cast aluminum block) suitably secured on top of the upper end head having a cylindric bore 21 extending from one end thereof to the other and end heads 23 and 25 closing the ends of the bore. A valve member 27, more particularly a valve spool, is axially slidable in the bore between a first position toward the right end of the bore as shown in
The valve spool 27 is movable from its right-hand position of
For operation of the relay valve 47, means indicated generally at 71 is provided for delivery of air under pressure to and exhaust of air from the left end of the relay valve and means indicated generally at 73 is provided for delivery of air under pressure to and exhaust of air from the right end of the relay valve. The means 71, 73 comprise a first pilot valve 75 (
An air pump, generally designated 121 in
The motor chamber 127 is in communication with the bottom of the cylinder 3 via passaging 137 (
Passageway 143 connects the air pump 121 to pressure-responsive system, indicated generally at 161, which is located in a recess 163 in block 79 adjacent the air pump. The pressure-responsive system 161 comprises a first diaphragm 165 located at the right side of the recess and a second diaphragm 167 proximate the first diaphragm 165 and to the left thereof. As shown in
Pressure-responsive system 161 further comprises a pressure-responsive valve 175 (“movable means”) movable within the recess 163 upon an increase in pressure in chamber 169. Valve 175 includes a valve stem 177 which is connected at its right-hand end to the second diaphragm 167 and at its left-hand end to a ball valve member 179, the ball valve member being engagable with a first valve seat 181 located to the left of the ball valve member and a second valve seat 183 located to the right of the ball valve member. The space between valve seats 181, 183 defines a passage chamber 185 which is in communication with passaging 107 such that air traveling through the passaging must enter into and exit from the chamber 185 as the air travels to relay valve 47. The pressure-responsive valve 175 is movable from a first position in which the ball valve member 179 engages the second valve seat 183 (and spaced from the first valve seat 181) such that air flows through passaging 107 to maintain communication between cylinder 3 and pilot valve 101, and in response to increase in air pressure in the chamber 169 above a predetermined limit to a second position in which the ball valve member 179 engages the first valve seat 181 for blocking passaging 107, and therefore blocking flow of air to pilot valve 101. On blocking of passaging 107, the pilot valve 101 is unable to operate, thereby disabling the operation of the relay valve 47 which in turn disables the valve spool 27 for stopping the movement of piston 9 and cutting off the operation of the motor 1. The pressure-responsive valve 175 is movable back to its first position on reduction of pressure in the chamber 169 below the limit.
A spring 187, engageable with a washer 189 positioned adjacent the second diaphragm 167, biases the second diaphragm to maintain the pressure-responsive valve 175 in its stated first position. Upon increase of speed of the motor above a predetermined operating speed (e.g., 50 cycles per minute as set by bleed 171), the air pump 121, operating at increased speed, delivers air under pressure at an increased rate to the chamber 169 over and above the capability of the bleed 171 to bleed off the increase and over and above the resistance of the spring 187 on the second diaphragm 167. On the ensuing increase in air pressure in the chamber above the limit, the second diaphragm moves to the left against the bias of the spring so that the pressure-responsive valve 175 moves to its second position thereby blocking passaging 107 and cutting off the motor. A vent 191 exhausts built-up air pressure to the left of the second diaphragm to the atmosphere.
The previously described arrangement is such that the length of time from when the air motor reciprocates at the predetermined speed limit to when the air motor is cut off depends upon how much over the speed limit the air motor is reciprocating. The greater the speed of the motor, the shorter the length of time for increasing air pressure within chamber 169 over and above the resistance of spring 187 for moving pressure-responsive valve 175 to its second position. And conversely, a speed only marginally above the speed limit delivers pressurized air to chamber 169 at a slower rate, thereby increasing the amount of time needed to move the valve 175 to its second position.
The first and second diaphragms 165, 167 are interconnected at their respective centers by a member 193. The first diaphragm 165 is also biased by the spring 187 (via the force of the spring transmitted through diaphragm 167 and member 193) against the right-hand wall of the recess 163 to block a passageway 195 which is connected to the source of pressure air for supplying pressurized air on diaphragm 165 (which constitutes an auxiliary valve member). The pressurized air assists in moving the pressure-responsive valve 175 to its second position. On the initial movement of the pressure-responsive valve 175 to its second position (as a result of increased pressure in chamber 169), the first diaphragm 165 moves away from the passageway 195 to an open position and pressurized air exerts pressure on the first diaphragm for facilitating the movement of the pressure-responsive valve to its second position. Only by closing the air supply and venting the air trapped in the recess 163 to the right of the first diaphragm may the pressure-responsive valve move back to its first position.
A trip indicator, indicated generally at 201, located on the exterior of the block 79 is in communication with the recess 163 to the right of the first diaphragm 165 by another passageway 197 and is activated upon increased pressure to the right of the first diaphragm as a result of pressurized air being supplied by the air supply. As shown in
During operation of the air motor, piston 9 is movable up and down in cylinder 3 in response to pressurized air delivered by valve 17. Piston 9 drives the plunger of the pump (not shown) connected at the lower end of the piston rod 13 for pumping materials such as sealants. In the event of the discharge line of the pump breaking, or exhaustion of the supply of the material being pumped, the piston 9 will tend to reciprocate in the cylinder 3 at high speed which can cause significant damage to the pump. In response to the increased speed of the piston 9, the air pump 121 of the runaway control operates at an increased speed since the air pump operates as a slave to the air motor. The air pump 121 in turn delivers pressurized air at an increased rate to chamber 169 of the pressure-responsive system 161. The pressure in the chamber 169 is controlled by bleed 171 via which the air entering the chamber from air pump 121 is vented from the chamber at a rate consistent with the predetermined operating speed of the air motor. In response to increase of air pressure in the chamber 169 over and above the capability of the bleed 171 to bleed off the increase, the pressure-responsive valve 175 moves to its second position in which its ball valve member 179 engages the first valve seat 181 for blocking passaging 107. The first diaphragm 165 also moves to a position away from passageway 195 thereby allowing air pressure to be delivered on the first diaphragm for maintaining the blockage of passaging 107.
By blocking passaging 107, the second pilot valve 101 is incapable of allowing the delivery of pressurized air to passaging 105 for moving the relay valve 47 because pressurized air from the lower end of the cylinder entering passaging 107 above the piston when the piston is in its substantially down-stroke position is blocked from entering the second pilot valve 101. Since the relay valve 47 is incapable of moving, the valve spool 27 of the valve means 17 is incapable of moving to its left-hand position. Pressurized air from supply port 29R continues to be supplied to passaging 45 which keeps valve spool 27 in its right-hand position. With the valve spool 27 maintained in its right-hand position, pressurized air from supply port 29R continues to be supplied to the top of the cylinder 3 via passaging 33 above piston 9 thereby holding the piston in its down-stroke position.
By shutting off the air supply (which applies pressure on diaphragm 165) and opening the bleed 171 for venting the built-up air pressure in the chamber 169, the air motor is reset for operation. Upon releasing the built-up air pressure in the chamber 169, the pressure-responsive valve 175 moves back to its first position under the bias of spring 187. Before the air motor is restarted, however, the cause for the air motor runaway must be attended to, e.g., the broken discharge line should be replaced, or the material being pumped should be resupplied.
Reference is made to U.S. Pat. No. 5,349,895 for further detail regarding the runaway motor control.
The bleed system 2 of the present invention is now described with reference to
Each gasket 240 comprises a piece of a suitable rubber or plastic for generally airtight sealing against a face of the plate 220 and closing open sides of all channels 230 on the plate. Other types of sealing arrangements do not depart from the scope of this invention. The gasket has holes 254, 256 corresponding with those on the plate 220 for registering alignment therewith. As shown in
Significantly, the channels 230 in the plate define a plurality of alternate air bleed flow paths or passageways having different lengths and providing different resistances (e.g., friction) to flow of gas through the passageways. Consequently, selection of one passageway results in flow of gas at one flow rate and selection of another passageway results in flow of gas at a different flow rate. It is understood that systems of other forms, including but not limited to channels formed in other objects (which are neither thin nor flat) or channels comprising stand-alone pipes, conduits, or passageways, do not depart from the scope of this invention.
Referring to the embodiment of
The plate 220 of
The channels 230 are formed on the face of the plate 220 with a conventional chemical etching process, as known to those skilled in the art, such as by exposing the plate to an acid to remove material from selected locations. In one embodiment, all channels 230, 274 have a uniform cross-sectional area which remains uniform along an entire length of each channel. Although a variety of cross-sectional sizes or shapes are possible, in a preferred embodiment each channel has a width of about 0.015 inch, a depth of about 0.006 inch, and features a generally rounded shape with a flat bottom as shown in
The selector mechanism 250 (
In one embodiment, the valve members 280 comprise spherical balls and the selector device 282 comprises a knob which is rotatable by a user for moving one valve member to its open position and thereby placing one selected outlet in communication with the inlet. Referring to
The selector mechanism 250 also includes a cover 288, a cover fastener 290, and a washer 292 placed between the bolt 258 and knob 282. Preferably, the washer 292 is a Belleville type washer which augments pressing of the knob against the sealing balls 280. A conventional tactile detent 294 (
In use, the bleed system 2 of the present invention provides a release of gas at a selectively adjustable flow rate. The rate of flow varies generally inversely with the resistance. By rotating the knob 282 of the selector mechanism, the user selects a longer or shorter passageway through which air must pass and a correspondingly larger or smaller resistance to flow. When the first outlet 272a is selected, air has a minimum distance to traverse on the plate. Specifically, air travels only through one connector channel 274, from the inlet 270 to the outlet 272a. When the second outlet 272b is selected, air must travel one down-and-back reach 268b along the plate. Successive outlets provide additional length, with incremental addition of one successive down-and-back reach 268 in series for each outlet. When the final (seventh) outlet 272g is selected, air must traverse all six of the down-and-back reaches 268b-268g on the plate, thereby providing maximum frictional resistance and minimum flow rate. It is understood that other arrangements, such as passageways having distinct inlets or which are not arranged in series, alternative patterns, orientations, channel densities or spacings, or a fewer or greater number of channels, inlets, or outlets, do not depart from the scope of this invention. The reaches may have equal lengths resulting in approximately equal increments in resistance to airflow, or alternatively may vary, as shown by the final (sixth) reach 268g on
The bleed system 2 of the present invention is repeatable because flow paths and cross-sectional areas do not change from one use to the next. There is no variation due to manufacturing tolerances as with conventional bleed valves. Consequently, the bleed system may be accurately calibrated for flow rate or other variable of interest. For use with the air motor 1, settings of the knob 282 may be calibrated corresponding to specific speed limits so that the maximum, predetermined cut-off speed of the air motor can be selected, e.g., 50 or 75 cycles per minute. The bleed system is attached to the air motor as shown in
The bleed system can be used in other applications, e.g., compressors, valve systems, fuel injectors, power generator systems, medical and dental devices, and spraying systems.
A second embodiment of the invention (
A third embodiment of the invention, shown schematically in
An adjustment mechanism comprising a knob 346 is provided for varying a length L of the passageway 338. The knob is firmly connected to piston 334 by a rod 348 such that translation of the knob moves the piston in the bore. A locking mechanism (not shown) is provided to fix the knob 346 and piston 334 at selected positions.
Movement of the piston varies the length L of the passageway 338 between inlet 342 and outlet 344 to vary resistance to flow of gas through the passageway. The location of inlet 342 varies with movement of the piston, while location of outlet 344 is fixed, such that the length of the path is adjustable. Significantly, the length L of the path is continuously adjustable (i.e., is not limited to discrete increment or decrement units) as the piston is moved to any selected position. Consequently the cut-off speed of the air motor 1 may be adjusted with improved resolution.
A fourth embodiment of the invention, shown in
A fifth embodiment of the invention, shown in
In view of the above, it will be seen that the several objects of the invention are achieved and other advantageous results attained.
When introducing elements of the present invention or the preferred embodiment(s) thereof, the articles “a”, “an”, “the” and “said” are intended to mean that there are one or more of the elements. The terms “comprising”, “including” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements.
As various changes could be made in the above constructions without departing from the scope of the invention, it is intended that all matter contained in the above description as shown in the accompanying drawing shall be interpreted as illustrative and not in a limiting sense.