The embodiments described below relate to, solenoids, and more particularly, to a solenoid with an over-molded component.
Fluid control valves are used in a wide variety of applications to control the flow of a fluid. The fluid being controlled may comprise a gas, a liquid, or a combination thereof. In some situations, the fluid may also include suspended particulates. While fluid control valves vary widely in the specific configuration used to open and close a fluid communication path through the valve, one specific type of valve actuation is performed using a solenoid. In solenoid-actuated valves, an electric current is applied to an electromagnetic coil, with the coil typically positioned around a magnetic core. The coil generally comprises a wire that is wrapped around a plastic bobbin numerous times resulting in a plurality of so-called turns. The energized solenoid generates a magnetic field. The strength of the magnetic flux of the field is proportional to the number of turns as well as the electrical current provided to the wire.
As is well-known in the art, the magnetic flux produced by the energized coil is shaped and directed by the magnetic core and a magnetic pole piece. In some solenoid valves, the pole piece can additionally act as a physical guide for the movable armature. Because the magnetic core and the pole piece direct the magnetic flux, proper positioning of the components results in the most efficient application of the magnetic flux to the movable armature. Ideally, the magnetic core and the pole piece would be positioned in a perfectly coaxial/concentric alignment. As used herein, coaxial and concentric are used interchangeably and are intended to mean that the components being referred to share a common axis or centerline. While “perfect” concentricity may not be practical due to manufacturing tolerances, those skilled in the art can readily appreciate that the more concentric the magnetic core and pole piece are positioned, the more efficiently the magnetic flux can be applied to the movable armature. Additionally, in situations where the pole piece acts as a guide tube for the movable armature, improving concentricity can improve the direction of movement of the movable armature with respect to the magnetic core.
The solenoid's efficiency can be further improved by reducing the air-gap that is made between the movable armature and the pole piece. In situations where the pole piece acts as a guide tube for the movable armature, the air-gap can be decreased by improving the concentricity between the pole piece and the magnetic core. One reason is that as the concentricity between the pole piece and the magnetic core improves, the allowable tolerance between the movable armature and the portion of the magnetic core that receives a portion of the movable armature can decrease, i.e., a larger gap is not necessary to account for a variation away from coaxial alignment.
In some solenoids, a portion of the movable armature is received in a depression formed in the magnetic core. The solenoid's efficiency can be further improved by reducing the air-gap that is made between the movable armature and the walls of the depression. Additionally, the solenoid's efficiency can be further improved by altering the external walls of the depression to adjust the magnetic force versus displacement curves experienced when the solenoid is actuated.
In addition, there is generally a desire to reduce the number of components required to manufacture the valve. One potential reduction of parts is in the seals required to prevent fluid controlled by the valve from reaching the electromagnetic coil.
As a result of the above-mentioned efficiency issues, there have been numerous prior art attempts at increasing the concentricity, decreasing the air-gap, and reducing the number of seals required.
Although the prior art solenoid valve 10 eliminates the need for an O-ring to create a fluid-tight seal between the pole piece 4 and the bobbin 2, the prior art solenoid valve 10 is subject to a loss of concentricity between the magnetic core 3 and the pole piece 4, and thus, a movable armature (not shown). This is shown by the longitudinal axis X-X of the magnetic core 3 being offset from the longitudinal axis Y-Y of the pole piece 4. One reason for the unintended offset is that the core 3 and the pole piece 4 are forced into the bobbin 2. Even small variances between the longitudinal axis X-X and the longitudinal axis Y-Y can reduce the magnetic flux aligned to act on the movable armature. The unaligned magnetic flux lowers the efficiency of the valve due to a lower amount of the magnetic flux acting on the movable armature in the direction of the armature's movement. Further, with a portion of the magnetic flux potentially pulling the movable armature at an angle with respect to the armature's movement, frictional forces may increase as the movable armature moves within the pole piece 4.
Furthermore, because concentricity between the magnetic core 3 and the pole piece 4 is compromised, a larger area must be formed in the magnetic core 3 to accommodate the movable armature or a smaller armature needs to be used in order to avoid the movable armature hitting the magnetic core 3. Either case results in a larger air-gap than desired.
Although the weld joint 27 can improve upon the concentricity between the magnetic core 24 and the pole piece 25, the welding operation can be expensive and time-consuming. Further, in order to provide a suitably small air-gap between the movable armature 26 and the pole piece 25, the weld joint may be required to be ground down to provide a smooth surface, further increasing the time and cost of the assembly.
Therefore, there exists a need in the art for an improved solenoid with an improved concentricity, air-gap, and strength. The solenoid may be incorporated into a valve, an electromagnet, etc. The embodiments described below provide these and other improvements and an advance in the art is achieved. The embodiments described below provide a solenoid with an over-molded component used to hold the magnetic core and the pole piece in place. In some embodiments, the over-molded component comprises a bobbin. The over-molded component is capable of increased manufacturing tolerances that minimize the air-gap between the movable armature and the pole piece, for example.
A solenoid is provided according to an embodiment. According to an embodiment, the solenoid comprises a magnetic core. The solenoid further comprises a pole piece positioned substantially coaxially with the magnetic core. According to an embodiment, the solenoid further comprises an over-molded component over-molded around at least a portion of the magnetic core and at least a portion of the pole piece.
A method is provided according to an embodiment. The method comprises aligning a magnetic core substantially coaxially with a pole piece. According to an embodiment, the method further comprises over-molding a component around at least a portion of the magnetic core and at least a portion of the pole piece.
According to an aspect, a solenoid comprises:
Preferably, the solenoid further comprises one or more grooves formed in one or both of the magnetic core and the pole piece for receiving a portion of the over-molded component.
Preferably, the solenoid further comprises a spacing ring located at an interface between the magnetic core and the pole piece.
Preferably, the over-molded component is over-molded around the spacing ring.
Preferably, the solenoid further comprises a movable armature movable within the pole piece between a first position and at least a second position.
Preferably, the movable armature extends into at least a portion of the magnetic core in the second position.
Preferably, the solenoid further comprises one or more grooves formed in the movable armature for communicating a fluid between a first end and a second end of the movable armature.
Preferably, the solenoid further comprises a spacer extending from the magnetic core.
Preferably, the over-molded component comprises a bobbin.
Preferably, the solenoid further comprises a bobbin located around at least a portion of the over-molded component.
According to another aspect, a method comprises:
Preferably, the step of aligning comprises inserting a centering pin through at least a portion of the magnetic core and at least a portion of the pole piece.
Preferably, the method further comprises a step of removing the centering pin after the step of over-molding.
Preferably, the method further comprises a step of positioning a spacing ring at an interface between the magnetic core and the pole piece prior to over-molding the component.
Preferably, the over-molded component comprises a bobbin.
Preferably, the method further comprises a step of positioning a bobbin around at least a portion of the over-molded component.
Preferably, the method further comprises a step of wrapping a wire around the bobbin a plurality of times.
Preferably, the method further comprises positioning the magnetic core, pole piece, over-molded bobbin, and wire within a valve housing of a valve.
Preferably, the method further comprises a step of inserting a movable armature into a least a portion of the pole piece to selectively open a fluid communication path between a first fluid port and a second fluid port of the valve.
According to an embodiment, an electrical current can be supplied to the wire 302 in order to actuate the valve 300. Once the magnetic flux acting on the movable armature 306 exceeds the biasing force of the biasing member 307 along with or without any fluid force, the movable armature 306 will be actuated.
Once the movable armature 306 is moved away from the valve seat 308, fluid can flow between the first and second fluid ports 309, 310. In some embodiments, the movable armature 306 may include one or more grooves 311 that extend approximately parallel to a longitudinal axis of the movable armature 306. The one or more grooves 311 can provide a fluid path to the end of the movable armature 306 opposite the valve seat 308 in order to provide a pressure balanced armature. Consequently, fluid pressure can act on both ends of the movable armature 306 to at least partially balance the fluid forces acting on the movable armature 306. In order to allow fluid to freely reach the end of the movable armature 306, a spacer 312 can be provided. The spacer 312 can be coupled to the magnetic core 304, for example. In other embodiments, the spacer 312 may comprise a portion of the magnetic core 304. According to yet another embodiment, the spacer 312 may be coupled to the movable armature 306. According to an embodiment, the spacer 312 may be formed from a non-magnetic material in order to avoid magnetic sticking of the movable armature 306 after electrical energy is removed from the coil.
As mentioned above, the magnetic force applied on the movable armature 306 will be maximized when the magnetic field is properly aligned with respect to the longitudinal axis of the movable armature 306, and thus, the movement of the movable armature 306.
According to an embodiment, the pole piece 305 acts as a guide for the movable armature 306 with the movable armature 306 sliding within the pole piece 305. Consequently, in order to properly align the magnetic force acting on the movable armature 306, concentricity between the magnetic core 304 and the pole piece 305 should be maximized. As explained above, while certain manufacturing tolerances may not permit perfectly concentric alignment of the magnetic core 304 and the pole piece 305, the magnetic force acting on the movable armature 306 can be improved as perfect concentric alignment is approached. As shown, the magnetic core 304 and the pole piece 305 are shaped generally as tubes. Therefore, in order to maintain concentricity between the two components, the radial centers of the two components should be properly aligned along the same longitudinal axis, in this case, the longitudinal axis, X-X of the valve 300. As shown, the valve 300 improves upon the valve 10 in that the magnetic core 304 and the pole piece 305 are coaxially aligned along the longitudinal axis X-X of the valve 300. When the magnetic core 304 and the pole piece 305 are coaxially aligned, the magnetic force acting on the movable armature 306 can be maximized for a given electrical current and number of coil turns.
As an example, with the magnetic core 304 and the pole piece 305 being coaxially aligned, the air gap between the movable armature 306 and the pole piece 305 can be minimized. For example, an air gap d1 is shown between the pole piece 305 and the movable armature 306. In one tested embodiment, an air gap of approximately 0.025 mm has been achieved. However, this should in no way limit the scope of the present embodiment. In addition to the reduced air gap d1 between the pole piece 305 and the movable armature 306, with coaxially aligned components, a reduced air gap d2 can be achieved between the movable armature 306 and a depression 313 in the magnetic core 304. In some embodiments, the air gap d2 may be approximately the same as the air gap d1 or may be different. A relatively small and consistent air gap is achievable between the movable armature 306 and the depression 313 in the magnetic core 304 due to the coaxial alignment of the pole piece 305, which guides the movable armature 306, and the magnetic core 304. This is in contrast to a prior art solenoid 60, which is shown in
According to an embodiment, concentricity is improved compared to the prior art by over-molding a component 303 around the magnetic core 304 and the pole piece 305. In some of the embodiments, described below, the over-molded component comprises a bobbin 303. However, in other embodiments, the over-molded component 303 can comprise a sleeve with a separate bobbin 703 positioned around at least a portion of the over-molded component 303 (See
Although the centering pin 400 is shown as extending through only a portion of the magnetic core 304, in other embodiments, the centering pin 400 can extend entirely through the magnetic core 304. The magnetic core 304 may therefore, include a small aperture extending through at least a portion of the length of the magnetic core 304 to accommodate a portion of the centering pin 400. In preferred embodiments, the entire diameter of the centering pin 400 shown in the figures would not extend through the magnetic core 304 because the magnetic core 304 would consequently require a large open space. This open space would lower the effectiveness of the magnetic core 304. Rather, a portion of the centering pin 400 having a smaller diameter could be provided.
With the magnetic core 304 and pole piece 305 properly aligned by the centering pin 400, the three components can be inserted into an appropriate mold (not shown) and the coil bobbin 303 can be over-molded around at least a portion of the three components. The over-molding operation can be conducted by injection molding, for example. The specific details relating to the molding process are omitted for brevity of the description. Over-molding is a well-known technique used in a variety of industries. Therefore, those skilled in the art will readily recognize a suitable molding process and molding machine.
As those skilled in the art will readily recognize, in order to accommodate the over-molding process, the magnetic core 304 and the pole piece 305 will need to have a higher melting temperature than the plastic used to form the bobbin 303. This is typically not a problem as the metals used to form the magnetic core 304 and the pole piece 305 generally have a higher melting temperature than the plastic bobbin 303. Therefore, the injected plastic will generally not melt the magnetic core 304 or the pole piece 305 during the over-molding process.
Over-molding the bobbin 303 around the magnetic core 304 and the pole piece 305 provides a number of advantages. Over-molding results in molecular adhesion between the substrate materials (the magnetic core 304 and the pole piece 305) and the over-molded material (the bobbin 303). Therefore, once the bobbin 303 cools and solidifies, the magnetic core 304 and pole piece 305 are maintained in their proper coaxial positions by the bobbin 303. Additionally, the molecular adhesion results in a substantially fluid-tight seal between the magnetic core and the bobbin 303 as well as between the pole piece 305 and the bobbin 303. Advantageously, O-ring seals can be eliminated between these components.
According to an embodiment, once the over-molded bobbin 303 cools, the centering pin 400 can be removed as shown in
As can be appreciated, the over-molded bobbin 303 can improve the concentricity between the magnetic core 304 and the pole piece 305 because the bobbin 303 is molded while the magnetic core 304 and the pole piece 305 are substantially coaxially aligned with the centering pin 400. According to one embodiment, the centering pin 400 is capable of aligning the magnetic core 304 and the pole piece 305 to within 1/100 mm of the desired position. This type of precision is currently unavailable in the prior art at a low cost. Further, the over-molded bobbin 303 can reduce the required air-gap between the movable armature 306 and the pole piece 305. This is because, the pole piece 305 is not physically deformed as in the prior art where the pole piece is physically forced into the bobbin. Therefore, less space is required to accommodate a potentially offset alignment. The increased alignment also allows for a reduced air-gap between the movable armature 306 and the magnetic core 304, as mentioned above. The reduced air-gap can improve control over the magnetic force provided to the movable armature 306 throughout a displacement range of the movable armature 306 as the movable armature 306 is partially received in the depression 313. The force provided to the movable armature 306 can be further adjusted by changing the shape of the wall 420 of the depression 313. For example, while the wall 420 is shown tapering towards the end, other configurations can provide different responses. Therefore, the particular configuration shown should not limit the scope of the description and claims.
As an alternative, the over-molded component 303 may be over-molded, and once removed from the mold, the bobbin 703 can be pressed over at least a portion of the over-molded component 303. The bobbin 703 can then be held in place via friction fit, adhesives, mechanical fasteners, etc. In either situation, the over-molded component 303 can maintain concentricity between the magnetic core 304 and the pole piece 305 as in the previously shown embodiments.
The embodiments described above provide an improved solenoid. The solenoid may be incorporated into a valve or some other electromagnet that acts on a work piece. The solenoid in the embodiments described above improves the solenoid's efficiency by more accurately aligning and maintaining the magnetic core and the pole piece along a common axis. The improved accuracy is attributable to the over-molded component that holds the components in place while also providing a substantially fluid-tight seal. Therefore, the embodiments described above also eliminates one or more seals that are seen in the prior art.
The detailed descriptions of the above embodiments are not exhaustive descriptions of all embodiments contemplated by the inventors to be within the scope of the present description. Indeed, persons skilled in the art will recognize that certain elements of the above-described embodiments may variously be combined or eliminated to create further embodiments, and such further embodiments fall within the scope and teachings of the present description. It will also be apparent to those of ordinary skill in the art that the above-described embodiments may be combined in whole or in part to create additional embodiments within the scope and teachings of the present description.
Thus, although specific embodiments are described herein for illustrative purposes, various equivalent modifications are possible within the scope of the present description, as those skilled in the relevant art will recognize. The teachings provided herein can be applied to other valves, and not just to the embodiments described above and shown in the accompanying figures. Accordingly, the scope of the embodiments described above should be determined from the following claims.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2012/004459 | 10/25/2012 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/064226 | 5/10/2013 | WO | A |
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