阅读说明：本技术 用于具有双凸缘一体式极片的电磁致动器的系统和方法 (System and method for an electromagnetic actuator with a dual-flange integral pole piece ) 是由 B·海德曼 M·佩尔曼 于 2020-10-09 设计创作，主要内容包括：本公开提供了一种用于具有一体式极片的电磁致动器的系统和方法,所述一体式极片布置在所述电磁致动器内且联接至壳体。电磁致动器可以包括：壳体；一体式极片；接收在一体式极片内的电枢；以及端盖。一体式极片构造成提供对电磁致动器内的气隙的减小。(The present disclosure provides a system and method for an electromagnetic actuator having an integrated pole piece disposed within the electromagnetic actuator and coupled to a housing. The electromagnetic actuator may include: a housing; an integrated pole piece; an armature received within the integral pole piece; and an end cap. The integrated pole piece is configured to provide a reduction of an air gap within the electromagnetic actuator.)

1. An integrated pole piece for an electromagnetic actuator, the integrated pole piece comprising:

a first end defining a substantially open top side;

a second end opposite the first end;

a first flange disposed adjacent to and extending radially outward from the first end;

a second flange extending radially outward from the second end; and

an armature recess extending at least partially through the integral pole piece from the generally open top side to the second end, the armature recess configured to slidably receive an armature.

2. The integrated pole piece of claim 1 wherein the armature recess of the integrated pole piece defines a base configured to provide an end stop for the armature.

3. The integral pole piece of claim 1, further comprising:

a first sidewall extending between the first and second flanges of the integral pole piece, the first sidewall defining a choke portion.

4. The integrated pole piece of claim 1 further comprising a second sidewall projecting axially above the first flange to receive an end cap.

5. The integrated pole piece of claim 1, wherein one of the first flange or the second flange defines a stepped profile.

6. The integrated pole piece of claim 5, wherein the stepped profile is configured to provide an end stop for a housing that is pressed against the stepped profile.

7. The integrated pole piece of claim 6, wherein the stepped profile is further configured to provide a press fit with an inner surface of the housing.

8. The integral pole piece of claim 1, further comprising:

a protrusion extending axially away from the second end of the integral pole piece, the protrusion configured to secure the valve body to the integral pole piece when the protrusion is crimped around the valve body.

9. An electromagnetic actuator comprising:

a housing;

an integral pole piece disposed within the housing, the integral pole piece comprising:

a first end defining a substantially open top side;

a second end opposite the first end; and

a first flange at the first end and a second flange at the second end, the first and second flanges extending radially outward from the integral pole piece; and

an armature recess extending from the top side of the primary opening toward the second end; and

an armature slidably received within the armature recess, the armature selectively movable between a first end position and a second end position,

wherein a base of the armature recess defines the first end position for the armature.

10. The electromagnetic actuator of claim 9, further comprising an end cap coupled to the first end of the integral pole piece.

11. The electromagnetic actuator of claim 10, wherein the end cap defines a seal against the top side of the primary opening of the integral pole piece.

12. The electromagnetic actuator of claim 10, wherein the end cap defines the second end position for the armature.

13. The electromagnetic actuator of claim 10, wherein the end cap is press fit to an outer surface of the top side of the primary opening of the integral pole piece.

14. The electromagnetic actuator of claim 9, further comprising:

a bobbin positioned around the armature and disposed between the first and second flanges of the integral pole piece.

15. The electromagnetic actuator of claim 14, wherein the bobbin is insert molded to the integral pole piece.

16. The electromagnetic actuator of claim 9, wherein the second flange defines a stepped profile that provides a mounting surface for the housing to be pressed against.

17. The electromagnetic actuator of claim 9, wherein the first flange and the second flange extend radially outward to interface with an inner surface of the housing.

18. The electromagnetic actuator of claim 9, wherein one of the first flange or the second flange defines a press fit between the housing and the integral pole piece.

19. A method of manufacturing an electromagnetic actuator, the method comprising:

manufacturing an integral pole piece comprising a sidewall, a first flange, and a second flange axially spaced from the first flange, the first and second flanges extending radially outward from the sidewall;

insert molding a bobbin between the first flange and the second flange, the bobbin defining a bobbin configured to receive a coil winding; and

pressing a housing onto the integral pole piece such that a press fit is formed between the housing and at least one of the first flange or the second flange.

20. The method of claim 19, further comprising pressing an end cap onto the integral pole piece such that a press fit is formed between the end cap and the integral pole piece.

Background

In general, an electromagnetic actuator may include an armature and a pole piece within a housing.

Disclosure of Invention

The present disclosure relates generally to systems and methods for electromagnetic actuators having dual-flange integral pole pieces. The double-flanged, integral pole piece may provide a reduction in air gaps and a reduction in the number of flux-carrying components disposed within the electromagnetic actuator.

In some aspects, the present disclosure provides an integrated pole piece for an electromagnetic actuator. The unitary pole piece may include a first end defining a top side of the primary opening and a second end opposite the first end. The first flange may be disposed adjacent to and extend radially outward from the first end. The second flange may extend radially outward from the second end. The integral pole piece may further include an armature recess extending at least partially through the integral pole piece from the substantially open top side toward the second end. The armature recess may be configured to slidably receive the armature.

In some aspects, the present disclosure provides an electromagnetic actuator. The electromagnetic actuator may include a housing and an integral pole piece disposed within the housing. This integral type pole piece can include: a first end defining a substantially open top side; a second end opposite the first end; and a first flange at the first end and a second flange at the second end. The first and second flanges may extend radially outward from the integral pole piece. The integral pole piece may further include an armature recess extending from the substantially open top side toward the second end. The electromagnetic actuator may further include an armature slidably received within the armature recess. The armature is selectively movable between a first end position and a second end position. The base of the armature recess may define a first end position for the armature.

In some aspects, the present disclosure provides a method of manufacturing an electromagnetic actuator. The method may include providing an integral pole piece including a sidewall, a first flange, and a second flange axially spaced from the first flange. The first flange and the second flange may extend radially outward from the sidewall. The method may further include insert molding a bobbin between the first flange and the second flange. The bobbin may define a bobbin configured to receive the coil winding. The method may further include pressing the housing onto the integral pole piece such that a press fit is formed between the housing and at least one of the first flange or the second flange.

The foregoing and other aspects and advantages of the present disclosure will become apparent from the following description. In the description, reference is made to the accompanying drawings which form a part hereof, and in which there is shown by way of illustration preferred constructions of the disclosure. Such constructions do not necessarily embody the full scope of the disclosure, but are therefore intended to be referenced to the claims and used herein to interpret the scope of the disclosure.

Drawings

The present disclosure will be better understood and features, aspects and advantages other than those set forth above will become apparent when consideration is given to the following detailed description thereof. This detailed description refers to the following figures.

Fig. 1 is a top, left, front isometric view of an electromagnetic actuator according to aspects of the present disclosure.

Fig. 2 is a top right rear isometric view of the electromagnetic actuator of fig. 1.

Fig. 3 is a top view of the electromagnetic actuator of fig. 1.

FIG. 4 is a cross-sectional view of the electromagnetic actuator of FIG. 3, taken along line 4-4.

FIG. 5 is a cross-sectional view of the electromagnetic actuator of FIG. 3, taken along line 5-5.

Fig. 6 is an exemplary magnetic flux density contour plot for the electromagnetic actuator of fig. 1.

Detailed Description

Before any aspects of the disclosure are explained in detail, it is to be understood that the disclosure is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The disclosure is capable of other configurations and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of "including," "comprising," or "having" and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms "mounted," "connected," "supported," and "coupled" and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, "connected" and "coupled" are not restricted to physical or mechanical connections or couplings.

The following discussion is presented to enable a person skilled in the art to make and use aspects of the present disclosure. Various modifications to the described configurations will be readily apparent to those skilled in the art, and the generic principles herein may be applied to other configurations and applications without departing from aspects of the disclosure. Thus, the aspects of the present disclosure are not intended to be limited to the embodiments shown, but are to be accorded the widest scope consistent with the principles and features disclosed herein. The following detailed description should be read with reference to the drawings, in which like elements in different drawings have like reference numerals. The drawings, which are not necessarily to scale, depict selected configurations and are not intended to limit the scope of embodiments of the disclosure. Those skilled in the art will recognize that the non-limiting examples provided herein have many useful alternatives and fall within the scope of the present disclosure.

As used herein, the term "axial" and variations thereof refer to a direction extending generally along an axis of symmetry, a central axis, or a direction of elongation of a particular component or system. For example, an axially extending feature of a component may be a feature that extends generally in a direction parallel to the axis of symmetry or elongate direction of the component. Similarly, the term "radial" and variations thereof as used herein refers to a direction that is substantially perpendicular to the corresponding axial direction. For example, the radially extending structure of the component may extend generally at least partially in a direction perpendicular to the longitudinal or central axis of the component. As used herein, the term "circumferential" and variations thereof refer to a direction extending around the circumference or perimeter of an object, around an axis of symmetry, around a central axis, or the elongate direction of a particular component or system.

Fig. 1-3 illustrate an electromagnetic actuator 10 according to aspects of the present disclosure. The electromagnetic actuator 10 may include a housing 12, an end cap 14, a connector 16, and an integral pole piece 18. The housing 12 may define a generally cylindrical shape and may be made of a magnetic material (e.g., magnetic steel, iron, nickel, etc.). In other non-limiting examples, the housing 12 may define other shapes as desired. In the non-limiting example shown, the housing 12 may be formed via rolling a metal plate or sheet to form a cylindrical housing. In the non-limiting example shown, the housing 12 may define a uniform thickness. Thus, when rolled, the housing 12 may have a seam (not shown) that extends axially from a first side 20 (e.g., a top side from the perspective of fig. 1-2) of the housing 12 to a second side 22 (e.g., a bottom side from the perspective of fig. 1-2) opposite the first side 20. In other non-limiting examples, the housing 12 may be seamless and formed from extruded or rolled tube that can be welded later. In the non-limiting example shown, the housing 12 of the electromagnetic actuator 10 may define a purely cylindrical shape. In some non-limiting examples, the housing 12 may be deep drawn to provide an end cap (i.e., the housing may be manufactured to include an integral end cap).

The end cap 14 may substantially cover a top side 15 of the electromagnetic actuator 10 (e.g., the electromagnetic actuator 10 from the perspective of fig. 1-3). As described herein, the end cap 14 may seal or otherwise prevent a fluid leakage path from the top of the electromagnetic actuator 10. The end cap 14 may also wrap around the top side of the electromagnetic actuator 10 and at least partially cover the outer surface 23 of the housing 12. In the non-limiting example shown, the end cap 14 may extend from the first side 20 toward the second side 22 of the housing 12, thereby defining a sidewall 24 of the end cap 14. The sidewall 24 may extend circumferentially around at least a portion of the outer surface 23 of the housing 12. For example, the side wall 24 may at least partially cover a front side 25 of the housing 12 (e.g., from the perspective of fig. 1). In the non-limiting example shown, the end cap 14 may also provide a substantially open back side 27 of the housing 12 (e.g., from the perspective of fig. 2) such that approximately half of the outer surface 23 of the housing 12 is not covered by the end cap 14. The side wall 24 of the end cap 14 may be positioned to cover a seam (not shown) on the housing 12. For example, the side walls 24 may prevent contaminants from entering the seams of the housing 12.

In the non-limiting example shown, the contact cover 26 may be formed in the end cap 14. The contact cover 26 may be positioned adjacent the second side 22 of the housing 12 and extend radially outward from the sidewall 24 when the end cap 14 is mounted to the housing 12. The contact cover 26 may include one or more openings or cutouts 28 formed therein. In the non-limiting example shown, the contact cover 26 includes a pair of cutouts 28, one cutout 28 for each electrical contact 30 extending from the connector 16. In some non-limiting examples, the contact cover 26 can include more or less than two cutouts to correspond with any number of electrical contacts 30 formed in the connector 16. In the non-limiting example shown, the contact cover 26 can at least partially cover the electrical contacts 30. The cutouts 28 may provide separation between the electrical contacts 30. The electrical contacts 30 may be made of a conductive material (e.g., aluminum, copper, etc.). In operation, the electrical contacts 30 can provide electrical communication between a controller (not shown) and a wire coil 80 disposed within the housing 12.

In the non-limiting example shown, the end cap 14 may also include one or more mounting flanges 32 extending radially outward from the outer surface 23 of the housing 12. The mounting flange 32 may be attached to the end cap 14 via one or more angled brackets 33. The mounting flange 32 may include fastener holes 34 extending axially through the mounting flange 32, each of the fastener holes 34 configured to receive a respective bolt or fastener to secure the end cap 14 and the electromagnetic actuator 10 to a mounting structure (e.g., manifold, valve body, etc.). In the non-limiting example shown, the mounting flanges 32 may be disposed on circumferentially opposite sides of the end cap 14 (e.g., the mounting flanges 32 may be circumferentially separated by increments of approximately 180 °).

With particular reference to fig. 1 and 3, the sidewall 24 may be attached to at least one mounting flange 32 and extend circumferentially around at least a portion of the outer surface 23 of the housing 12 toward the other mounting flange 32. In the non-limiting example shown, circumferentially extending arm 35 may extend circumferentially from sidewall 24 to one of mounting flanges 32. In this manner, the circumferentially extending arm 35 may attach the sidewall 24 to one of the mounting flanges 32. With particular reference to fig. 2 and 3, the positioning of the mounting flanges 32 may define a circumferential space therebetween. In the non-limiting example shown, the circumferential space between the two mounting flanges 32 may be devoid of material. For example, the end cap 14 may expose a portion of the outer surface 23 of the housing 12 that is substantially the same as the circumferential space between the two mounting flanges 32.

In other non-limiting examples, the end cap 14 may include more or less than two mounting flanges 32 arranged circumferentially at any increment around the exterior of the housing 12. In the non-limiting example shown, the end cap 14 may include the side wall 24, the contact cover 26, the mounting flange 32, the angled bracket 33, and the circumferentially extending arm 35 as a single, integral component.

The end cap 14 may comprise a thermoplastic material. The end cap 14 may be manufactured separately from the housing 12 or the integral pole piece 18 for coupling therewith during assembly. The end cap 14 may be manufactured in an injection molding process and the end cap (including the side wall 24, the contact cap 26, the flange 32, and the arm 35) may be formed as a unitary component.

Turning now to fig. 4 and 5, the integral pole piece 18 may be made from a single piece of magnetic material (e.g., magnetic steel, iron, nickel, etc.). The integral pole piece 18 can include a first end 36, a second end 38 opposite the first end 36, and a body 40. The first end 36 may be disposed adjacent the end cap 14 when assembled. The body 40 of the unitary pole piece 18 may define a generally cylindrical shape and may extend axially from the first end 36 to the second end 38.

The integral pole piece 18 may include an armature recess 42. The first end 36 of the integral pole piece 18 may define a generally open end. For example, the armature recess 42 may extend at least partially through the body 40 of the integrated pole piece 18 from the first end 36 toward the second end 38. The armature recess 42 can define an internal cavity extending from an opening 47 at the first end 36 of the integrated pole piece 18 toward the second end 38. The armature recess 42 may also define a first sidewall 48 and a base 50. The first sidewall 48 of the integral pole piece 18 may extend axially between the first ends 36 toward the second end 38, terminating at a base 50 where the profile of the integral pole piece 18 is significantly thicker within the body 40 toward the second end 38. The base 50 of the armature recess 42 extends radially inward from the first sidewall 48. The base 50 of the armature recess 42 also includes a pole piece aperture 52 extending from the base 50 of the armature recess 42 to the second end 38 of the integral pole piece 18. The pole piece aperture 52 may be centrally located in the integrated pole piece 18 and provide fluid communication (e.g., of the process fluid) with the armature recess 42.

In the non-limiting example shown, the armature recess 42 may receive the armature 43. The armature 43 can slide between two or more positions within the armature recess 42. The armature 43 may be made of a magnetic material (e.g., magnetic steel, iron, nickel, etc.). The armature 43 may include a central bore extending axially through the armature 43, which may provide fluid communication between opposite ends thereof. In the illustrated, non-limiting example, the housing 12, the end cap 14, the integral pole piece 18, and the armature 43 may define a common central axis 45.

The first side wall 48 of the integral pole piece 18 may define a choke portion 54. The choke portion 54 may be defined as a radial recess or radial reduction in thickness of the first sidewall 48. The choke portion 54 is sized to ensure that magnetic saturation is created in the choke portion 54 during operation of the electromagnetic actuator 10. The illustrated first sidewall 48 includes a first tapered surface 56 and a second tapered surface 58 with a choke portion 54 disposed between the first and second tapered surfaces 56, 58. The first and second tapered surfaces 56, 58 may each taper toward the choke portion 54 forming a generally V-shaped or U-shaped radial recess in the first sidewall 48.

Still referring to fig. 4 and 5, the integral pole piece 18 may be a double-flange integral pole piece and include a first flange 44 and a second flange 46. The first flange 44 may extend radially outward from a distal end of the first sidewall 48 to interface with an inner surface of the housing 12. The first flange 44 may be disposed adjacent the first end 36 of the integral pole piece 18. A second flange 46 may extend radially outward from a distal end of the body 40 proximate the second end 38 of the integral pole piece 18 to interface with an inner surface of the housing 12. In the non-limiting example shown, the first flange 44 is disposed axially below the first end 36 of the integral pole piece 18. The first flange 44 or the second flange 46 may define a rectangular profile. In the non-limiting example shown, the first flange 44 defines a substantially rectangular cross-sectional profile. The first flange 44 may include a first bobbin surface 60 extending substantially perpendicularly from the first sidewall 48. In some non-limiting examples, the first flange 44 or the second flange 46 may define a stepped profile. In the non-limiting example shown, the stepped profile defined by the second flange 46 includes a first flange portion 62 defining a first diameter and a second flange portion 64 defining a second diameter. The second flange portion 64 may define a larger diameter than the first flange portion 62. The first flange portion 62 may include a second bobbin surface 66 extending substantially perpendicularly from the main body 40 of the unitary pole piece 18. The second flange portion 64 may include a housing surface 68 extending substantially perpendicularly from the first flange portion 62. When assembled, the housing 12 may engage the housing surface 68 such that the housing surface 68 provides an end stop for the housing 12 when the housing 12 is pressed onto the integral pole piece 18. The first flange 44 and the second flange 46 may be sized to provide a clearance fit or a press fit with the housing 12. In the non-limiting example shown, the first flange 44 may define a clearance fit with the housing and the second flange 46 may define a press fit with the housing.

Second flange 46 may include a mounting surface 70, the mounting surface 70 configured to engage a structure to which electromagnetic actuator 10 may be coupled in an application. The mounting surface 70 may extend substantially perpendicularly from the second end 38 of the integral pole piece 18 toward the second flange portion 64. That is, the mounting surface 70 may extend radially outward from the distal end of the integral pole piece 18.

In the non-limiting example shown, the integral pole piece 18 may include an outer surface 72. The outer surface 72 may be defined by a second sidewall 71 that extends axially above the first flange 44 (e.g., from the perspective of fig. 4-5) to the first end 36 of the integral pole piece 18. For example, the first flange 44 may not be at the extreme end of the integral pole piece 18. That is, the first flange 44 may be spaced an axial distance from the first end 36 of the integral pole piece 18 such that the second sidewall 71 projects above the first flange 44 to form an outer surface 72 into which the end cap 14 may be engaged. When assembled, the end cap 14 may engage the outer surface 72 when the end cap 14 is pressed onto the integral pole piece 18. The central portion of the end cap 14 may define a generally "cup-shaped" profile. That is, a central portion of the end cap 14 may define a cylindrical cup shape having a closed end 74 (e.g., an upper end from the perspective of fig. 4-5) and an open end 76 opposite the closed end 74 (e.g., a lower end from the perspective of fig. 4-5). End cap 14 may include a pole piece recess 78 extending from open end 76 toward closed end 74.

The end cap 14 may provide a seal for the opening 47 of the integral pole piece 18. In the non-limiting example shown, the first end 36 of the integral pole piece 18 may define a press fit with the end cap 14 when the end cap 14 is mounted thereon. For example, the inner surface of the pole piece recess 78 in the end cap 14 may engage the outer surface 72 of the integral pole piece 18 to provide a seal therebetween to prevent fluid from flowing out of the armature recess 42 (or otherwise preventing a fluid leakage path from the armature recess 42). In some non-limiting examples, the inner surface of the pole piece recess 78 may include an O-ring groove that receives an O-ring to provide a seal between the integrated pole piece 18 and the end cap 14. In other non-limiting examples, the outer surface 72 of the integrated pole piece may include an O-ring groove that receives an O-ring to provide a seal between the integrated pole piece 18 and the end cap 14.

The end cap 14 and armature recess 42 may completely enclose or seal the armature 43 therein. That is, the armature recess 42 may be sealed behind the armature 43 and in front of the armature 43 by a continuous surface defined by the integral pole piece 18. Specifically, the end cap 14, the first sidewall 48, the second sidewall 71, and the mounting surface 70 define a series of surfaces or sealing interfaces. In use, the electromagnetic actuator 10 may be mounted to a structure such that a seal is formed between the mounting surface 70 and the structure. Thus, when installed, the surfaces and sealing interfaces defined along the mounting surface 70, the first side wall 48, the second side wall 71, and the end cap 14 may completely seal the armature recess 42 and the armature 43 slidably disposed therein.

With continued reference to fig. 4 and 5, the electromagnetic actuator 10 may include a coil 80 disposed within the housing 12. The coil 80 may be wound around a bobbin 82, the bobbin 82 being sized to position the coil 80 within the housing 12 such that, when assembled, the coil 80 extends at least partially around the armature 43. The coil 80 may be made of, for example, a copper coil configured to generate a magnetic field, and thereby apply a force to the armature 43 in response to an electrical current applied to the coil 80. The magnitude of the magnetic field generated by the coil 80 and the magnitude of the force may be determined by the magnitude of the current applied to the coil 80. As described above, the electromagnetic actuator 10 may be in electrical communication with a control device (not shown) through the electrical contacts 30. In some embodiments, a control device (not shown) may be configured to selectively apply an electrical current to the wire coil 80 at a desired magnitude.

Because the armature 43 may be slidably received within the armature recess 42 defined by the integral pole piece 18, the armature 43 may be selectively axially movable within the armature recess 42 between one or more positions in response to a force generated by the magnetic field of the wire coil 80. When the armature 43 is in the first end position, the end cap 14 may define a first end stop for the armature 43; the integrated pole piece 18 may define a second end stop for the armature 43 when the armature 43 is in the second end position. For example, the interior of the central "cup-shaped" portion of the end cap 14 may define a first end stop for the armature 43. The base 50 of the armature recess 42 in the integrated pole piece 18 can provide a second end stop for the armature 43 therein. Thus, the armature 43 may move axially within the armature recess 42 between a first end stop provided by the end cap 14 and a second end stop provided by the integral pole piece 18.

The bobbin 82 may be made of a non-magnetic material (e.g., plastic). In the non-limiting example shown, the bobbin may be formed using an insert molding process. For example, the integrated pole piece 18 and electrical contacts 30 may be placed into a mold. The non-magnetic material may then be injected into the mold, specifically, between the radial recesses formed in the area between the first bobbin surface 60 formed by the first flange 44 and the second bobbin surface 66 formed by the second flange 46, thereby forming the bobbin 82. The bobbin 82 may define a bobbin, and the coil 80 may be wound around the bobbin 82 within the bobbin.

Referring now to fig. 5, the housing 12 may include an opening 84 at the second side 22 of the housing. The opening 84 provided in the housing may be rectangular or "D-shaped" to provide a passage for the electrical contact 30 to extend radially outward from the bobbin 82. The opening 84 may be defined by a gap formed between the housing surface 68 of the second flange 46 and an upper portion (e.g., from the perspective of fig. 5) of the opening 84 in the housing 12. The electrical contacts 30 pass through and under the contact cover 26 that projects radially outward from the side wall 24 of the end cap 14.

In operation, the electromagnetic actuator 10 may be used, for example, as a variable force solenoid valve, and/or the electromagnetic actuator 10 may be integrated into a control valve arrangement. In either case, the electromagnetic actuator 10 may be coupled to the application structure 102. In some non-limiting examples, the application structure 102 may be a valve body 102.

One non-limiting application in which the electromagnetic actuator 10 may be integrated into the control valve 100 will be described with reference to fig. 4-5. As shown in fig. 4 and 5, the electromagnetic actuator 10 may be integrated into the control valve 100. The control valve 100 may include a valve body 102. The valve body 102 may be coupled to the integral pole piece 18. The second end 38 of the integral pole piece 18 may include a body protrusion 104 that extends away from the otherwise flush mounting surface 70. It should be appreciated that the body protrusion 104 generally defines a flat profile. In the example shown in fig. 4 and 5, the body protrusion 104 defines a generally curved profile after undergoing the crimping process. When assembled, the valve body 102 may be positioned within the valve body protrusion 104 against the mounting surface 70 at the second end 38 of the integral pole piece 18. Valve body protrusion 104 may then be crimped to secure or otherwise couple to valve body 102. The design of the electromagnetic actuator 10 enables the valve body 102 to engage only the second end 38 of the integrated pole piece 18, thereby simplifying assembly of the control valve 100.

During installation, the valve body 102 may be inserted into, for example, a bore 106 defined by a mounting structure 108. In one embodiment, the mounting structure 108 may be in the form of a mounting structure 108. The valve body 102 may be inserted into the bore 106 until the mounting surface 70 of the second flange 46 engages the mounting structure 108. That is, the mounting surface 70 of the second flange 46 may act as a stop for the control valve 100 and define the depth of insertion of the valve body 102 into the bore 106. With the valve body 102 inserted into the bore 106, in some embodiments, fasteners (e.g., bolts) may be installed to secure the control valve 100 to the mounting structure 108. Fasteners (not shown) may be inserted through the fastener holes 34 of the mounting flange 32 to engage the end cap 14 to apply a mounting force that pushes the end cap axially downward, thereby pushing the electromagnetic actuator 10 axially downward onto the mounting structure 108. In the illustrated embodiment, the mounting force may force the mounting surface 70 into engagement with the mounting structure 108, thereby providing a seal therebetween.

In conventional systems, the electromagnetic actuator may include a pole piece and a c-pole that are axially separated such that a gap exists between the two. The use of pole pieces and c-poles as separate components may result in misalignment between these components during manufacture or operation, and may also complicate the assembly process. Any misalignment between the pole piece and the c-pole may cause the armature to side load and wear, or tip over, resulting in increased hysteresis. As described above, the present disclosure provides an electromagnetic actuator 10 having an integral pole piece 18. The use of an integral pole piece 18 eliminates any potential misalignment between the pole piece and the c-pole as they are manufactured from a single component. Accordingly, the systems and methods for electromagnetic actuators with integral pole pieces described herein may eliminate or reduce armature wear or tipping and increased hysteresis due to pole piece/c-pole misalignment.

In addition, the integral pole piece reduces the number of components. For example, in conventional systems, the electromagnetic actuator may include an end plate, or otherwise a valve body or application structure, that is axially separated from the pole piece such that a potential air gap exists between the valve body or application structure. Conventionally, an end plate provides one of two end stops for the armature. As described above, the present disclosure provides an electromagnetic actuator 10 having an integral pole piece 18. The integral pole piece 18 provides an end stop for the armature 43 by providing an internal cavity defined by the armature recess 42, wherein the base 50 of the armature recess 42 provides one of the end stops for the armature 43. Thus, the systems and methods for an electromagnetic actuator with an integral pole piece described herein may eliminate the air gap present in conventional electromagnetic actuators and reduce the overall flux carrying components. That is, the electromagnetic actuator of the present disclosure includes three flux-carrying components: a housing 12, an integral pole piece 18, and an armature 43.

As shown in fig. 6, the systems and methods described herein for an electromagnetic actuator including an integral pole piece with a simplified housing provide an electromagnetic actuator with improved magnetic efficiency compared to conventional actuators. For example, the electromagnetic actuator 10 described herein may reduce the number of air gaps. That is, when the electromagnetic actuator 10 is assembled, the housing 12 is pressed onto the integral pole piece 18, with the second flange 46 of the integral pole piece 18 forming a press fit with the housing 12, and the first flange 44 providing a clearance fit with the housing 12, both of which may be designed such that little or no air gap exists therebetween. Thus, the non-limiting example shown includes only two non-working air gaps. Those skilled in the art understand that air gaps result in magnetic inefficiencies. Thus, air gaps minimized in number or gap thickness reduce these inefficiencies.

The method of assembly of the electromagnetic actuator 10 and the configuration of the dual-flange integral pole piece 18 may provide an improved magnetic flux path between the housing 12 and the integral pole piece 18. For example, increasing the flux area of the air gap reduces magnetic efficiency. The double-flanged unitary pole piece 18 having the first flange 44 and the second flange 46 extending radially outward therefrom places the air gap at a location defining a larger radius/diameter than conventional pole pieces. The location of the air gap at the larger radius increases the magnetic flux area of the air gap, thereby reducing the magnetic inefficiency of the electromagnetic actuator 10.

The method of manufacturing the electromagnetic actuator 10 described herein may also improve the magnetic performance of the electromagnetic actuator 10. For example, insert molding the bobbin 82 around the integral pole piece 18 may reduce the wall thickness of the bobbin 82. The wall thickness of the bobbin 82 may be reduced because the integral pole piece 18 and the first and second flanges 44, 46 may provide structure for the integrity of the bobbin, allowing for a larger bobbin. In the case of larger bobbins, the coil 80 may contain more turns in the winding, thereby improving magnetic performance. In addition, the axial height of the first and second flanges 44, 46 may be increased due to the reduced wall thickness of the bobbin 82. The larger flange further increases the flux area of the air gap, thereby reducing the magnetic inefficiency of the electromagnetic actuator 10. Since the bobbin 82 is formed around the pole piece, the bobbin 82, which is insert molded onto the unitary pole piece 18, reduces the total number of tolerance factors (i.e., tolerance stack-ups) as opposed to being pressed or mounted as part of a larger assembly.

The electromagnetic actuator 10 described herein may also provide an improved heat dissipation coefficient. For example, the press fit between the housing 12 and the integral pole piece 18 may minimize thermal resistance by allowing heat exchange therebetween (e.g., via metal-to-metal contact). The integral pole piece may also reduce the thermal resistance between the pole piece and the manifold by providing a large contact area between the pole piece and the manifold (i.e., the mounting surface 70) and a reduced number of individual components (i.e., the pole piece is monolithic and heat can more easily flow from one end of the electromagnetic actuator to the other). This improved heat dissipation factor may allow the coil windings to have higher resistance or to operate at higher currents for longer periods of time without overheating, thereby maximizing coil performance.

In this specification, embodiments have been described in a manner that enables a clear and concise description to be written, but it is intended and will be understood that various combinations and subcombinations of the embodiments may be made without departing from the disclosure. For example, it will be understood that all of the preferred features described herein are applicable to all aspects of the invention described herein.

Thus, while the present disclosure has been described in connection with particular embodiments and examples, the present disclosure is not necessarily so limited, and various other embodiments, examples, uses, modifications and alterations to the embodiments, examples and uses are intended to be included in the appended claims. The entire disclosure of each patent and publication cited herein is incorporated by reference as if each patent or publication were individually incorporated by reference.

Various features and advantages of the disclosure are set forth in the following claims.