HIGH SPEED FLUID DISPENSER HAVING ELECTROMECHANICAL VALVE
TECHNICAL FIELD
This invention relates to a fluid dispenser or applicator, particularly one incorporating an electromechanically actuated valving mechanism capable of operating at high frequencies.
BACKGROUND ART
In the dispensing of various types of viscous fluids, such as liquid adhesives, sealants, caulks, and other less viscous materials and in the application of such materials in manufacturing production lines, it is necessary to start and to stop the flow ofthe fluid periodically. The interruption ofthe flow is usually accomplished by means of an electrically operated valve, such as a solenoid valve, provided in the dispensing head. Such valves operate by means of a plunger driven open by an electromagnetic field and closed by a spring biasing means. An example of a dispenser incoφorating such a valving mechanism is shown in United States Patent No. 5,375,738. In the past, various types of valves have been used. Generally, these valves have relied upon a plunger movable within a core having an electromagnetic coil. The operating cycle of such valves has been relatively slow which has limited the techniques by which the material could be applied by the dispenser. An electromagnetic valve which should be able to operate at somewhat higher frequencies is disclosed in United States Patent No. 3,921,670 which relates to an electrically operated valve for use in pneumatic control circuits. This valve has a
magnetically responsive armature that opens and closes a port. It is believed that while this valve is capable of operating at higher frequencies, it can only operate at about 10 Hz, that is, the valve can only open and close about 10 times per second. A dispenser with a valve which could operate at much higher frequencies would permit fluid material to be dispensed more precisely and in accurate patterns. It would also allow the fluid material to be dispensed more rapidly, resulting in more efficient manufacturing operation which could operate at higher speeds. However, the actuation of such a valve at sufficiently high frequencies has not been previously possible.
l o SUMMARY OF THE INVENTION
The present invention provides a novel design for a fluid dispenser for dispensing various types of fluids having a valve which is capable of operating at much higher frequencies than the dispensers ofthe prior art. The dispenser of this invention can operate at frequencies of up to 1,500 Hz, that is, it can open and close
15 around 1,500 times per second. This allows the flow of viscous fluids dispensed by the dispenser to be started and stopped at high speeds, allowing precise application ofthe fluids and even permitting fluids to be dispensed in a printed pattern. It also allows the volume output of the dispenser to be reduced by pulsing the dispenser, and it allows the volume output to be regulated by modulating the pulse duration at
20 a fixed frequency.
In accordance with the present invention, a high frequency dispenser is achieved by providing a dispenser with a valve having a stiff diaphragm spring, which spring is stiffer than the springs used in prior art high speed dispensers. In addition, the valve is actuated by an armature which has a relatively large pole face
25 area overlying the end faces ofthe inner and outer cores ofthe core assembly. So
that movement of the armature is minimally interfered with by the fluid material surrounding the armature, openings are provided through the armature for the flow of the fluid material. The openings provide a fast escape route for fluid material which would otherwise be trapped on the other side ofthe armature as the armature moves between the open and closed positions.
Thus, the present invention provides a dispenser with a valve which operates at higher frequencies through the provision of an armature operated by a very stiff spring and provided with holes for the escape of fluid material around the armature. The large spring force requires that a strong magnetic force be present to move the armature in opposition to the stiff spring. The strong magnetic force is achieved in part by providing an armature which presents a relatively large pole face area overlying the end face ofthe cores, as compared to the relatively small pole face area of United States Patent No. 3,921,670, for example.
Moreover, the armature and cores are arranged with a small stroke, so that the air gaps in the flux loop between the armature and the cores are small. By maintaining small air gaps, the reluctance ofthe magnetic circuit produced by these air gaps is minimized, so that the amount of force produced by the coil is increased. The result is a stronger magnetic force which can oppose a stiff spring to produce very high frequency operation. The dispenser of the present invention is capable of operating with a wide variety of fluids, including viscous fluids, such as liquid adhesives, sealants, caulks, and less viscous fluids having a viscosity approaching that of water. The dispenser is also capable of dispensing fluids which must be maintained at high temperatures, such as hot melt adhesives which must be maintained at temperatures in excess of 400°F.
Unlike many dispensers ofthe prior art, the valve mechanism in the dispenser ofthe present invention includes cores and a coil which are "wet," that is, the flow of fluid material being dispensed flows through the cores, and the cores and the coil
-Λ-
are not sealed from this flow. This allows the cores and the coil, as well as the armature, to be located closer to the flow of fluid, so that a relatively short stroke of the armature can be used to open and close the valve. By operating with a short stroke, the valve can be opened and closed much more quickly than valves in dispensers of the prior art.
Also, unlike many dispensers ofthe prior art, the electromagnetic coil used in the valve of this dispenser has fewer turns. This allows the coil resistance to be much less than that in corresponding coils of prior art valving dispensers, so that this dispenser can operate on a low voltage circuit rather than a standard voltage circuit. This allows the use of less expensive and more reliable electronics in the control circuit operating the dispenser, and results in energy savings.
These and other advantages are provided by the present invention of a dispenser assembly having a magnetically operated valve for dispensing a fluid, which comprises a body having an inner chamber and having a passageway to introduce the fluid into the chamber. An inner core within the chamber has an inner passageway through which the fluid flows. An outer core is around the inner core. A valve member is positioned within the chamber and movable between an open position in which fluid flows out ofthe chamber and a closed position in which fluid flow from the chamber is blocked. An armature within the chamber is connected to move the valve member to the closed position. The armature has a plurality of openings extending therethrough to permit at least some ofthe fluid on one side of the armature to move through the armature to the other side ofthe armature as the armature moves within the chamber. A diaphragm spring is mounted within the chamber and engages the armature to bias the valve member to the closed position. A magnetic coil is between the inner core and the outer core within the chamber and capable of energization to move the armature and allow the valve member to move to the open position.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a top plan view ofthe applicator ofthe present invention.
FIG. 2 is a side sectional view taken along line 2 — 2 of FIG. 1.
FIG. 3 is a detailed view of a portion of FIG. 2 to a larger scale showing the valving mechanism in the closed position.
FIG. 4 is an end sectional view taken along line 4 — 4 of FIG. 1.
FIG. 5 is a top sectional view taken along line 5 — 5 of FIG. 4 showing the groove network on the armature.
FIG. 6 is another top sectional view taken along line 6 — 6 of FIG. 4 showing the holes in the diaphragm spring.
MODE FOR CARRYING OUT THE INVENTION
Referring more particularly to the drawings and initially to FIG. 2, there is shown an applicator 10 according to the present invention. The applicator 10 includes a retainer assembly comprising a first retainer 11 and a second retainer 12 together forming a clamp having an opening for insertion of a rod 13 upon which the applicator 10 may be mounted. The retainers 11 and 12 are clamped together around the rod 13 by a hex screw 14. An applicator body 16 is attached to the retainers 11 and 12 by a hex screw 15.
The applicator 10 depicted in this embodiment can be used for dispensing heated materials such as hot melt adhesive materials, so the applicator may include a heater cartridge 21 within the body 16. A thermal insulator 23 is provided between the body 16 and the retainer 12 to insulate the mounting rod thermally from the
heated block. A temperature sensor 22 is also provided in the body 16 for sensing the level of heat provided by the heater cartridge 21 so that the heater can be regulated. The power supply for the heater cartridge 21 and the connections for the temperature sensor 22 enter the body 16 through a cord set 24 extending from the body and connected to wire connectors 25 contained within a chamber in the body. The chamber in the body 16 containing the wire connectors 25 is enclosed by a removable electrical cover 26 which is attached to the body by a screw 27. Heat from the heater cartridge 21 is thermally transferred through the body 16 into an electromagnetic valve assembly 30 which is housed within the body. The heat is then transferred from the valve assembly 30 into the material being dispensed by the valve.
For unheated materials a smaller body (corresponding to the body 16) can be used to reduce the size ofthe applicator. Alternatively, smaller sized applicators can be used with heaters located upstream along the fluid path from the applicator, with the heaters not being formed as part of, or directly connected to, the applicator.
The valve assembly 30 includes a magnetic core comprising an inner core 31 and an outer core 32 is mounted in the body 16. The generally cylindrical inner core
31 is mounted within a corresponding cylindrical bore in the body 16 and is secured to the body by a set screw 33. An O-ring 34 is provided between the inner core 31 and the body 16 to provide a sealing engagement. A fitting 35 is formed on the top of the inner core 31 for connection to a supply hose for the fluid being dispensed. The fitting 35 is connected to a central axial passageway 36 which extends through the inner core 31. A coil 37 is wound around the inner core 31 with annular spacers 38 and 39 on each end ofthe coil. The outer core 32 surrounds the inner core 31 and the coil 37. An O-ring 40 is provided between the upper end ofthe outer core 32, and another larger O-ring 41 is provided between the lower ends ofthe outer core
32 and the inner core 31. A pair of leads 42 extends from the one end ofthe coil 37
and form a part ofthe cord set 24. The bottom ofthe cores 31 and 32 have end faces 43 and 44, respectively, which lie in the same horizontal plane as shown in FIG. 2. For applications in which the fluid is not heated, the O-ring 41 can be eliminated. The O-ring 41 is needed in heated applications because the heat can crack the potting compound ofthe coil 37, and without the O-ring 41 fluid can leak past the coil and out ofthe applicator since the potting material ofthe coil also acts as a fluid seal. In non-heated applications, therefore, with the O-ring 41 eliminated, along with the spacers 38 and 39, the coil 37 is more truly "wetted" by the fluid material. The term "wetted" as applied to the coil herein is used to mean a coil which is not enclosed in a sealed or isolated chamber to prevent it from coming into contact with the liquid. United States Patent No. 5,375,738, for example, shows a non- wetted coil. Non-wetted coils are more remotely located from the armature which makes them less efficient. United States Patent No. 3,921,670 shows a coil located relatively close to the armature but the valve in that patent is for controlling air flow, not liquid flow. By using a wetted coil in the present invention, the coil can be positioned close to the armature which improves the efficiency of the magnetic circuit, and reduces power requirements while permitting a strong magnetic force to be applied to the armature. A nozzle retainer 47 is attached to the lower end of the body 16 by four screws 48. An O-ring 50 is provided between the body 16 and the retainer 47 to provide a sealed engagement between them. The connection ofthe retainer 47 to the body 16 forms an inner conical chamber 49 within the body below the cores 31 and 32. A dispensing channel 51 extends from the bottom of the chamber 49, and a nozzle holder 52 is inserted into the channel. A suitable nozzle 53 is inserted into the nozzle holder 52. Within the chamber 49 is a spherical valve member 54 which is capable of engaging an annular valve seat 55 mounted in the retainer 47 at the
bottom ofthe chamber 49 to seal off the dispensing channel 51. The valve member 54 and the valve seat 55 may be made of a hard durable material such as carbide. The hard material permits the valve to undergo multiple cycles with a minimal amount of wear to the valve member 54 and the valve seat 55. The valve member 54 is connected to a two-piece armature which comprises an inner armature 60 which is press-fit into the center of an outer armature 61. A diaphragm spring 73 is sandwiched between the inner armature 60 and the outer armature 61, as shown in FIG. 3. The spring 73 may be keyed against rotation relative to the body 16 such as by forming a tab (not shown) on the outside periphery of the spring which projects into a slot (not shown) formed in the body 16. The spring 73 can also include a second tab (not shown) on its inside diameter to project into a slot (not shown) formed in the inner armature 60. This keying ofthe spring 73 prevents the spherical valve member 54 from rotating with respect to the valve seat 55 so that the valve member 54 wears evenly with respect to the seat 55. The inner armature 60 has a central axial passageway 62 which communicates with radial passageways 63 to allow material to enter the conical nozzle chamber 49. An annular spacer ring 64 is located between the outer armature 61 and the inside wall ofthe body 16. The size ofthe spacer ring 64 in the axial direction controls the stroke ofthe armature 60, 61. As shown in FIGS. 3 and 5, the outer armature 61 has a plurality of holes 65 extending through the outer armature in a direction parallel to the axis ofthe armature. A network of grooves 66 and 67 is provided on the top of the inner armature 60 and the outer armature 61, as shown particularly in FIG. 5. The grooves may include a circular groove 66 and at least two radially extending grooves 67 which connect the circular groove with some ofthe holes 65. The radial grooves 67 help to channel fluid between the armature 60, 61 and the core 31, 32 toward the holes 65 in the outer armature 61 so that the fluid can be pushed out from between the armature 60, 61 and the core 31, 32 when the armature is pulled toward
the core. The upper surface ofthe outer armature 61 also has three raised lands 68 extending along the edges ofthe armature. The lands 68 space the armature 60, 61 away slightly from the end surface ofthe core 31, 32 to prevent the armature from sticking to the core due to the presence of the fluid material between the armature and the core.
The diaphragm spring 73 is used to bias the armature 60, 61 toward the dispensing end and thus bias the valve member 54 closed. The spring 73 is donut- shaped, and the inside diameter portion of the spring 73 is captured between the inner armature 60 and the outer armature 61, while the outer edge of the spring is captured between the spacer ring 64 and the retainer 47 as shown in FIG. 3. Referring to FIG. 6, the diaphragm spring 73 also has a plurality of holes 74, which align with the holes 65 in the outer armature 61. The previously described tab (not shown) which can be formed on the inside diameter of the spring 73 to lock the spring against rotation with the inner armature 60 can also be used to maintain alignment between the holes ofthe spring and the holes ofthe inner armature.
In operation, the valve is normally closed by action ofthe spring 73 urging the armature 60, 61 in a downward direction as shown in FIG. 3, so that the valve member 54 firmly engages the valve seat 55. When the coil 37 is energized, a magnetic field is established around the coil and a flux loop is created as shown in FIG. 4. The flux loop extends from the outer core 32 through the outer part ofthe outer armature 61, through the inner part of the outer armature 61 and the inner armature 60, through the inner core 31 and back to the outer core 32. The armature 60, 61 has pole faces 75 and 76 formed on the upper surface ofthe inner armature
60 and the outer armature 61, respectively, as shown in FIG. 3, and these pole faces substantially cover the end faces 43 and 44 ofthe core 31, 32. The windings ofthe coil 37 along with the relatively large pole face area presented by the armature 60,
61 opposite the end face area 43, 44 ofthe core combine to produce a relatively large
electromagnetic force to pull the armature toward the core 31, 32 and allow the valve member 54 to move away from the valve seat 55 and open the valve. The fluid material that is temporarily captured between the armature 60, 61 and the core 31, 32 is channeled by means ofthe groove network 66 and 67 into the holes 65 in the outer armature 61, so that it flows into the chamber 49 as the armature 60, 61 moves upwardly. When the coil 37 is again de-energized, the diaphragm spring 73 pushes the armature 60, 61 in the opposite direction to close the valve. As the valve closes, the space between the armature 60, 61 and the core 31, 32 is quickly filled by the fluid which flows from the chamber 49 back through the holes 65 to the space between the armature 60, 61 and the core 31, 32.
As shown in FIG. 3, the stroke s through which the armature 60, 61 must move to open and close the valve is very small. The force created by the magnetic field produced by the coil 37 is a function ofthe number of turns ofthe coil and the current flowing through the coil. The air gap in the flux loop between the core 31, 32 and the armature 60, 61 increases the reluctance ofthe magnetic circuit and thus reduces the amount of force produced by the coil. By minimizing the stroke s ofthe armature 60, 61, the air gap created around the armature is minimized, and the opening force produced by the coil 37 is maximized.
The three lands 68 on the upper surface ofthe outer armature 61 maintain the outer armature in a stable fixed distance from the core 31, 32 as the armature is held against the core by the magnetic force. The lands 68 space the armature 60, 61 away slightly from the end surface of the cor 31, 32 tc prevent the fluid material from causing the armature to stick to the c It is s> ^sted that three lands 68 be provided, since two lands would result in an unstable positional relationship and four lands could also become unstable ifthe lands wear excessively and unevenly high.
The use of a diaphragm spring 73 is also a significant feature of this invention. The diaphragm spring 73 permits rapid actuation ofthe valve by quickly
moving the armature 60, 61 to the closed position when the coil is de-energized. The valve closing force produced by the spring 73 and the opening force produced by the coil 37 and the armature 60, 61 are balanced to produce high speed operation ofthe valve. Preferably, the valve is designed to cycle through an opening and closing operation at rates of up to 1,500 times per second. In addition to balancing the opening and closing forces, the high speed operation is accomplished by providing a relatively small stroke s ofthe armature along with a large spring force and a large electromagnetic force.
In the present invention, the diaphragm spring 73 has a spring rate of at least 500 lb/in and preferably 1,000-1,500 lb/in. This compares to spring rates of 10-20 lb/in common in coil type springs used in prior art electromagnetic dispensers. In addition, the use of a diaphragm spring permits this high spring rate to be achieved with a very small mass compared to the mass of a coil spring, for example, having the same spring rate. This arrangement permits the armature 60, 61 to be spring biased to the closed position by a very strong spring force produced by a very small spring sandwiched between the armature elements 60 and 61. This feature, together with the close space ofthe armature to the coil, the short stroke ofthe coil, and the highly efficient and powerful magnetic circuit of this electromagnetic valve, permits the dispenser ofthe present invention to dispense dots of material at 1,500 Hz (i.e., 1,500 dots per second), well in excess of the operating frequency of prior art dispensers. Since the dispenser is capable of operating at high frequency, it is possible to use the open time of the valve to regulate the volume output of the dispenser. The valve can be pulsed to open at a desired frequency for a selected open time to produce a desired effective flow rate from the dispenser. This flow rate can then be changed by changing the valve frequency and/or open time ofthe valve.
Unlike the valving arrangements in many ofthe dispensers ofthe prior art, the valve assembly in the dispenser of this invention includes a core and coil which are
"wet," that is the core 31, 32 and the coil 37 are within the material flow path and are immersed in the fluid material. This allows the armature 60, 61 to be closer to the core 31, 32 since the armature is also in the flow path. However, since the armature 60, 61 must move through the fluid material, the presence ofthe holes 65, as well as the channeling grooves 66 and 67, is important to allow the material to flow freely from one side ofthe armature 60, 61 to the other as the valve is opened and closed to permit rapid actuation of the valve.
The coil 37 has relatively few turns, for example, 150-250 turns, in contrast to prior art dispensers which may have electromagnetic coils with 1 ,000 turns or more. By reducing the number of turns on the coil, the electrical resistance of the coil is reduced. A coil for a dispenser in accordance with this invention may have a resistance of around 1-3 ohms, for example. By reducing coil resistance, the valve can operate using a low voltage control circuit of, for example, 48 volts, rather than a control circuit operating with a standard voltage of 150 volts. This allows the use of low voltage electronics which are less expensive and more reliable, and can result in energy savings.
Other variations and modifications ofthe specific embodiments herein shown and described will be apparent to those skilled in the art, all within the intended spirit and scope ofthe invention. While the invention has been shown and described with respect to particular embodiments thereof, these are for the puφose of illustration rather than limitation. Accordingly, the patent is not to be limited in scope and effect to the specific embodiments herein shown and described nor in any other way that is inconsistent with the extent to which the progress in the art has been advanced by the invention.