DE112016000398T5 - Cylindrical coil with reinforced stroke - Google Patents

Abstract

A coil assembly includes a pole piece. The pole piece includes an interior chamber and interior grooves in the interior chamber, with the interior grooves spaced at intervals to access a transmission. The coil assembly includes an electromagnetic signal source surrounding the pole piece and a fitting adapted to move in the inner chamber when an electromagnetic signal is emitted from the electromagnetic signal source.

Description

Technical area

The present application relates to solenoid assemblies. More specifically, in the application, a mechanism for amplifying the stroke of a solenoid is provided.

background

In solenoid assemblies, an electromagnetic signal is applied to an armature for the armature to move up or down. The path traveled by the anchor is the hub. If a long stroke is to be achieved, a longer solenoid assembly must be used, thereby relinquishing some of the force of the armature movement, or providing greater electromagnetic force. This leads to an increase in the cost and size of the solenoid assembly.

SUMMARY

 With the devices disclosed in the present patent, the aforementioned disadvantages are overcome and the prior art is improved by a cylindrical coil assembly comprising a sliding arm whose stroke is longer than the stroke of the armature.

A solenoid assembly includes a pole piece. The pole piece includes an inner space and inner grooves in the inner space, wherein the inner grooves are spaced so that they engage with a gear in each other. The solenoid assembly includes an electromagnetic signal source that encloses the pole piece and an armature that is configured to move within the interior space when an electromagnetic signal is transmitted from the electromagnetic signal source.

A valve assembly includes a flow path through a housing, wherein at least one valve is configured to selectively open or close the flow path, and a solenoid assembly. The solenoid assembly includes a pole piece. The pole piece includes an inner space and inner grooves in the inner space. The inner grooves are spaced so that they mesh with each other with a gear. The solenoid assembly further includes an electromagnetic signal source that encloses the pole piece and an armature that is configured to move within the interior space when an electromagnetic signal is transmitted from the electromagnetic signal source.

A solenoid assembly includes a pole piece. The pole piece comprises an inner space and an inner surface on the inner space. The inner surface touches a roller. The solenoid assembly further includes an electromagnetic signal source that encloses the pole piece and an armature that is configured to move within the interior space when an electromagnetic signal is transmitted from the electromagnetic signal source.

A valve assembly includes a flow path through a housing, wherein at least one valve is configured to selectively open or close the flow path, and a solenoid assembly. The solenoid assembly includes a pole piece. The pole piece comprises an inner space and an inner surface on the inner space. The inner surface touches a roller. The solenoid assembly further includes an electromagnetic signal source that encloses the pole piece and an armature that is configured to move within the interior space when an electromagnetic signal is transmitted from the electromagnetic signal source.

Additional objects and advantages will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the disclosure. The objects and advantages are also achieved and attained by means of the elements and combinations particularly pointed out in the appended claims.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and not limiting of the claimed invention.

BRIEF DESCRIPTION OF THE DRAWINGS

1 is a cross-sectional view of a pole piece assembly with an armature and a slide arm.

2A is a view of a solenoid assembly in a panel.

2 B is an exploded view of a solenoid assembly.

3 is a cross-sectional view of an electromagnetic signal source around a pole piece, wherein the pole piece has an interior space for the movement of an armature in the interior.

4 FIG. 12 is a cross-sectional view of a fuel valve assembly including a solenoid assembly. FIG.

5 FIG. 12 is a cross-sectional view of a pole piece assembly using balls instead of gears. FIG.

6A is a cross-sectional view of the arrangement of a rotating element.

6B - 6C are cross-sectional views of rotating elements.

DETAILED DESCRIPTION

 Reference will now be made in detail to the examples illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings for the same or similar parts. Directional indications such as "left" and "right" are intended to facilitate reference in the figures.

1 shows a cross-sectional view of a pole piece assembly 100 with an anchor 102 and a sliding arm 103 , The anchor 102 is located in an interior 141 of the pole piece 101 , The anchor 102 can move along the axis A to the back wall 146 of the interior 141 moving to or from her.

On the anchor 102 can at least one gear 120 to sit. The gear 120 has teeth 122 the inside grooves 110 in the interior 141 intervention. A second gear 121 can also be on the anchor 102 to sit. The second gear 121 can also teeth 122 have in a second row of inner grooves 111 in the interior 141 intervention.

The gears 120 . 121 so sit on the anchor 102 that they are on the anchor 102 do not move along the axis A. The gears 120 . 121 However, they can rotate, causing the anchor 102 is possible on the back wall 146 to move her to or from her. The gears 120 . 121 can include a bearing around a shaft or a cylinder pin 123 rotates.

The anchor 102 can form a unit or a first part 144 include that with a second part 145 connected is. The first part 144 may be a cylindrical pin, a pin or a shaft, the one or the perfect fit in the second part 145 was snapped or pressed. A tail 150 of the first part 144 can be in a hollow area 142 of the pole piece 101 extend. The first part 144 can fit in a single pass 151 be inserted, the hollow area 142 with the interior 141 combines. By this arrangement, the anchor can 102 axially in the pole piece 101 move while reducing movements or vibrations in directions away from the axis A. This arrangement helps keep the pole piece 101 along the axis A with the anchor 102 and the sliding arm 103 remains aligned.

The sliding arm 103 is located in a hollow area 140 in the anchor 102 , The sliding arm 103 can move along the axis A to the back wall 143 of the hollow area 140 moving to or from her. The sliding arm 103 has grooves 130 on that are spaced apart with their teeth 122 of the anchor 102 sitting gear 120 mesh. The sliding arm can have several rows of grooves 130 . 131 which are designed to work with both gears 120 . 121 interlock.

Moves the sliding arm 103 itself, the gears turn 120 . 121 , Likewise, the gears rotate 120 . 121 if the anchor 102 moves. Moves the anchor 102 for example from the back wall 146 away, the gear rotates 122 in a clockwise direction and the gear 121 counterclockwise. By this rotational movement of the sliding arm of the rear wall 143 of the anchor 102 pushed away. The sliding arm thus moves at a higher speed along the axis A than the armature 102 , For example, the slide arm moves along the axis A at a speed R _s relative to the armature 102 while the anchor 102 also along the axis A at a speed R _a relative to the pole piece 101 moves, which does not move along the axis A, then the sliding arm moves 103 along the axis A at a speed R _s + R _a relative to the stationary pole piece 101 ,

The spacing of the gear teeth 122 , the spacing of the inner grooves 110 . 111 and the spacing of the grooves 130 . 131 can be adjusted to the axial movement or the stroke of the armature 102 and the sliding arm 101 set.

The depth of the hollow area 142 and the interior 141 Can be chosen so that the requirements of the solenoid coil assembly 100 be fulfilled. For example, these areas can be designed deeper to allow the anchor 102 has more room to move along the axis A over a longer distance. Likewise, the hollow area 140 be designed deeper, so that the sliding arm 103 along the axis A can move over a longer path. This axial movement can be called a stroke. This is the length of the stroke of the sliding arm 103 longer than the stroke of the anchor 102 , In addition, a lower magnetic force is necessary to the sliding arm 103 and the anchor 102 to move.

2A is a view of a composite solenoid assembly 200 , 2A includes an upper flux guide 201 , a disguise 202 , an electrical input port 209 , a lower flux guide 208 and a pole piece 207 , An exploded view of the solenoid assembly 200 is in 2 B shown. The solenoid assembly closes an upper flux guide 201 , a disguise 202 , a paint wire 203 , a connection 204 , a bobbin 205 , a diode 206 , a pole piece 207 and a lower flux guide 208 one.

3 is a cross-sectional view of a solenoid assembly 300 , The solenoid assembly 300 closes a pole piece 301 , of enameled wire 313 is enclosed. An anchor 302 is in the pole piece 301 and a sliding arm 303 is located in the anchor 302 , The pole piece 301 , the anchor 302 and the sliding arm 303 are aligned along the axis A.

3 shows a solenoid assembly 300 in which the sliding arm 303 is in a raised position. The original position of the top 348 of the sliding arm is marked as P2. The sliding arm 303 is completely raised in this position, which indicates its upper limit along the axis A. The position P6 indicates the position of the top 348 of the sliding arm 303 in an extended position. The sliding arm 303 enters the extended position after the sliding arm 303 from the back wall 342 of the anchor 302 moved away. D2 is the distance between P2 and P6 or in other words: D2 is equal to the path that the slide arm 303 from its original position P2 to an extended position P6. D2 can be considered the path of the stroke of the slide arm 303 be referred to in the extended position.

D2 is greater than D. D is the path that the anchor 302 from the original position P1 of the top 347 of the anchor 302 to an extended position P5 of the top 347 of the anchor 302 has covered. This is in the extended position of the stroke of the sliding arm 303 longer than the stroke of the anchor 302 ,

D2

= Weg des Hubs des Gleitarms in der ausgefahrenen Position

D

= Weg des Hubs des Ankers in der ausgefahrenen Position

N

= ein Faktor, der gleich einer Zahl größer als 1 ist

The relationship between the stroke of the sliding arm 303 and stroke of the anchor 302 in the extended position can be calculated with the equation (1), where D2 = D * N Eq. (1)

D2

= Stroke of the stroke of the slide arm in the extended position

D

= Distance of the stroke of the armature in the extended position

N

= a factor equal to a number greater than 1

The magnitude of N may depend on many factors, including the shape and size of the anchored rollers and gears. 6A shows a gear 620 with a first page 696 with a distance r ₁ from the center C of the gear 620 to the first rolling circle surface 693 and a second page 697 with a distance r ₂ from the center C of the gear 620 to the second Wälzkreisfläche 694 , Since r _{1 is} greater than r ₂ , the rotational speed of the gear is 620 at the first pitch circle surface 693 greater than the rotational speed at the second Wälzkreisfläche 694 , Grasping the teeth 622a , as in 6A shown in the grooves 630 on the sliding arm 603 and the teeth 622b in the grooves 610 on the pole piece 601 a, moves the sliding arm 603 faster than the anchor 602 , This means that the sliding arm 603 a longer stroke than the anchor 602 Has. Both the speed and the stroke of the sliding arm 603 can be changed by changing the sizes and shapes of the rotating gear 620 , Polschuhs 601 , Anchor 602 and sliding arm 603 be changed.

If the rollers or gears have a uniform size and shape, N is equal to 2. 5 shows such an arrangement. The sliding arm 503 therefore moves twice as fast as the anchor 502 , And the sliding arm 503 may have a stroke that is twice as long as the stroke of the anchor 502 ,

Both rollers and gears are rotating elements that can be used to enhance the stroke of a slide arm. 6B shows an example of a gear 620 with first teeth 622a on a first page 696 and second teeth 622b on a second page 697 , The rotating element need not be a roller or gear. For example, as in 6C shown a rotating element 620C increase the stroke of a sliding arm. Instead of teeth, the rotating element 620C a textured surface with, for example, waves 624a and waves 624b on. It is not necessary that the rotating element 620C has a textured surface. Frictional forces may be sufficient if the sides 696 . 697 are smooth.

The rotating element 620C may contact the outer surface of the slide arm in a similar manner as the rotating gear 620 the sliding arm 603 in 6A touched, only that the rotating element 620C has no teeth that engage in the grooves of the slide arm. The rotating element 620C can also contact the outer surface of the pole piece as the rotating gear 620 the pole piece 601 in 6A touched, only that the rotating element 620C has no teeth that engage in the grooves of the pole piece.

The rotating elements 620C has a first page 696 with a distance d ₁ from the center of the rotating element 620C and a second page 697 with a distance d ₂ from the center C of the rotating element 620C , Since d _{1 is} greater than d ₂ , the rotating element amplifies 620C the stroke of the sliding arm. To obtain the desired gain, d ₁ and d _{2 can be} adjusted.

The extended hub serves many applications. An example application is the operation of fuel valves where a spool helps to control the fluid pressure. 4 shows a valve assembly 400 with a coil assembly 460 in the extended position after fitting 302 a path D from its home position P1 and the slide arm 403 has traveled a distance D2 from its starting position P2. 3 shows the sliding arm 303 and the fitting 302 in a raised position, after both the sliding arm 303 as well as the fitting 302 from the extended position to the back wall 341 the inner chamber 341 have moved away.

D4 is the path between the starting position P1 of the fitting 302 and the raised position P3 of the fitting 302 , D3 is the path between the starting position P2 of the sliding arm 303 and the raised position P4 of the slide arm 303 , In 3 D3 is shorter than D4. That means the way between the top edge 348 of the sliding arm 303 and its home position P2 is shorter than the path between the top edge 347 of the fitting 302 and its initial position P1. Although the sliding arm 303 when it is in the extended position, a longer stroke than the fitting 302 has, can the sliding arm 303 Move closer to its starting position P2 zoom than the fitting 302 can move to its original position P1 when it is in the raised position. This is possible because of the sliding arm 303 faster than the fitting 302 emotional. The gears 120 . 121 allow the sliding arm 303 to move faster. When the sliding arm 303 moved downwards to the extended position, press the gears 120 . 121 the sliding arm 303 down and away from the fitting 302 so that the sliding arm 303 moves faster down than the fitting 302 , When the sliding arm 303 moved upwards to the raised position, pull the gears 120 . 121 the sliding arm 303 up to the fitting 302 down, so that the sliding arm 303 moves faster upwards than the fitting 302 ,

4 shows a cross-sectional view of the valve assembly 400 with a coil assembly 460 , The valve assembly 400 has a first flow path 471 in the case 490 the valve assembly 400 , with a second flow path 472 can be connected. Together, the first flow path 471 and the second flow path 472 form a single flow path when connected. Liquid can from the first flow path 471 to the second flow path 472 or from the second flow path 472 to the first flow path 471 flow. A check valve 480 or another valve can either be with the first flow path 471 or the second flow path 472 get connected. This in 4 shown check valve 480 can be used to control the fluid pressure, for example, open when the pressure in flow path 471 reaches a certain threshold, so that liquid from the first flow path 471 to the second flow path 472 can flow.

Valve 404 may allow or prevent a liquid between the first flow path 471 and the second finally 472 can flow. Valve 404 can be one from an outer valve 405 be surrounded poppet valve. When in the raised position, valve allows 404 Liquid either from flow path 471 to flow path 472 to flow or by flow path 472 to flow path 471 , The flow can also take place when the outer valve 405 closed, provided that valve 404 is in the raised position. 4 shows an arrangement in which both valve 404 as well as the outer valve 405 are closed. In the second flow path 472 Pressure can build up to a value at which the outer valve 405 is lifted so that liquid from the second flow path 472 to the first flow path 471 can flow. Around the outer valve 405 To raise, the pressure in flow path must be 472 by spring 406 overcome applied force, which is the outer valve 405 in the closed position. The sliding arm 403 can with valve 404 be connected. Therefore, valve moves 404 along the axis A, while the sliding arm 403 moved along axis A. As 4 shows is valve 404 closed when the sliding arm 403 in the extended position. When the sliding arm 403 is in the raised position is valve 404 opened so that liquid from the first flow path 471 to the second flow path 472 can flow.

Valve 404 is raised when an electrical signal or an electric current through the magnet wire 413 flows. The magnet wire 413 is an electromagnetic signal source. The electrical power may be from a power source, such as a power generator, a battery, a generator, or other electrical power source 493 to provide. The electricity can be through a control system 492 be controlled, for example via a computer or microcomputer. When electric current passes through the magnet wire 413 flows, the magnet wire sends 413 an electromagnetic signal and a magnetic field are generated. This creates a magnetic force that can attract metallic or other ferromagnetic materials.

The fitting 402 may include metallic or ferromagnetic material. For example, the first section 445 Made of metal. The electromagnetic signal generated by the current conducted through the magnet wire pulls the first section 445 of the fitting 402 at. The magnetic force of the electromagnetic signal may be the first section 445 up to the back wall 449 the hollow section 442 of the pole piece 401 pull out. The magnetic force can also be the first section 445 down from the back wall 449 Press away, for example, if the first section 445 consists of a permanent magnet. If the first section 445 or any section of the fitting 402 is made of a metallic or ferromagnetic material, the sliding arm may consist of a non-metallic or non-ferromagnetic material. Therefore, the magnetic force does not necessarily have the sliding arm 403 influence. The sliding arm 403 and the second section 444 The fitting may be made of plastic or other lightweight moldable material.

The strength of the magnetic force depends on the amount of current passing through the magnet wire 413 flows. The magnetic force also depends on the number of turns of the wire. The force can be over the connection 491 into the coil assembly 460 enter. connection 491 can be connected to an electrical power source 493 and a control system 492 be connected, for example, a microcomputer or other control system 492 , The control system 492 can be programmed to send out a set amount of electricity at a set time to open and close the valve 404 to control.

A spring can valve 404 in the closed position hold up valve 404 is lifted by the coil assembly. Also, gravity and fluid pressure can valve 404 keep in the closed position. Therefore, the magnetic force must be strong enough to overcome the force exerted by any holding force.

5 shows a cross-sectional view of a pole piece assembly 500 , the rollers 520 instead of gears. The pole piece assembly 500 in 5 can be the stroke of the sliding arm 503 extend. Like the gears 120 . 121 in 1 Can the rollers 520 turn and so the sliding arm 503 Press downwards when the fogging occurs 502 moved downwards. Likewise, rollers can 520 turn and the sliding arm 503 Press upwards when the fogging occurs 502 moved upwards. The outer surface 540 the rollers 520 adheres to the outer surface 530 of the sliding arm 503 , This adhesion is maintained by frictional forces, thus preventing the rollers from spinning 520 on the sliding arm 503 , The outer surface 540 the rollers 520 adheres to the surface 550 the inner chamber 541 ,

The rollers 520 , the sliding arm 503 and the pole piece 501 can be made of any non-slip material to increase the friction forces at the point where the rollers 520 the sliding arm 503 touch and on the rollers 520 the inner chamber 541 of the pole piece 501 touch. The rollers 520 , the sliding arm 503 and the pole piece 501 can also be coated with a non-slip material to increase the frictional forces. The rollers 520 can be balls, cylinders or other shapes. Rotating components, for example the in 6C shown rotating component may be made of non-slip material or coated with non-slip material. Surface structures such as bumps, knurls or burrs may be added to the surfaces of the rollers, gears, rotating members, sliding arm and pole piece to increase frictional forces and prevent spinning. These parts may comprise the same non-slip material or different non-slip materials.

Those skilled in the art will recognize other implementations by considering the specifications disclosed herein and the examples. The specifications and embodiments are to be considered as examples only, with the true scope of the invention being indicated by the following claims.

Claims (64)

 Coil assembly comprising: Pole piece comprising: Inner chamber; and Inner grooves in the inner chamber, wherein the inner grooves are mounted at intervals to engage in a transmission; the pole piece surrounding electromagnetic signal source; and A fitting designed to move in the inner chamber when an electromagnetic signal is emitted from the electromagnetic signal source. The spool assembly of claim 1, wherein the fitting comprises a hollow portion including a back wall, and wherein the spool assembly further comprises a sliding arm located in the hollow portion, the sliding arm comprising spaced grooves to enter Gear to grasp, the sliding arm is designed so that it moves in response to movements of the fitting when the electromagnetic signal is emitted. The spool assembly of claim 2, wherein the sliding arm moves toward the rear wall. The spool assembly of claim 2, wherein the sliding arm moves away from the rear wall. The coil assembly of claim 1 or claim 2, further comprising a gear located on the fitting. The spool assembly of claim 5, wherein the gear comprises a plurality of teeth and the teeth engage at least a portion of the inner grooves and a portion of the outer grooves. The coil assembly of claim 2, wherein: the internal grooves include: a first set of internal grooves and a second set of internal grooves opposite the first set of internal grooves, the outer grooves include: a first set of outer grooves and a second set of outer grooves opposite the first set of outer grooves and the fitting includes: a first toothed gearing between the first set of internal grooves and the first set of external grooves and a second toothed gear between the second set of internal grooves and the second set of external grooves. The coil assembly of claim 7, wherein when the electromagnetic signal source emits an electromagnetic signal, the fitting in the inner chamber moves, the first gear and the second gear rotate, the fitting moves relative to the inner grooves, and the sliding arm moves relative to the fitting emotional. The spool assembly of claim 8, wherein, as the fitting moves, the fitting travels a path D within the pole piece and the slide arm travels at least one path N · D, where N is greater than one. The coil assembly of claim 9, wherein N is greater than or equal to 2. The coil assembly of claim 2 or claim 7, wherein the fitting comprises a first portion and a second portion attached to the first portion, the second portion receiving the sliding arm. The coil assembly of claim 11, wherein the first portion comprises a metallic material. The coil assembly of claim 11, wherein the first portion comprises a ferromagnetic material. The coil assembly of claim 2 or claim 7, wherein the fitting comprises a metallic material and the slide arm comprises a non-metallic material. Valve assembly comprising: a flow path through a housing; at least one valve configured to selectively open and close the flow path; Coil assembly comprising: Pole piece comprising: Inner chamber; and Inner grooves in the inner chamber, wherein the inner grooves are mounted at intervals to engage in a transmission; the pole piece surrounding electromagnetic signal source; and A fitting designed to move in the inner chamber when an electromagnetic signal is emitted from the electromagnetic signal source. The valve assembly of claim 15, wherein the fitting comprises a hollow portion including a rear wall, and wherein the coil assembly further comprises a sliding arm located in the hollow portion, the sliding arm includes spaced grooves for engaging a gear, the sliding arm thus configured is that it moves in response to movements of the fitting when the electromagnetic signal is emitted. The valve assembly of claim 16, wherein the slide arm moves toward the rear wall. The valve assembly of claim 16, wherein the sliding arm moves away from the rear wall. The valve assembly of claim 15 or claim 16, further comprising a gear located on the fitting. The valve assembly of claim 19, wherein the gear comprises a plurality of teeth and the teeth engage at least a portion of the inner grooves and a portion of the outer grooves. The valve assembly of claim 16, wherein: the internal grooves comprise: a first set of internal grooves and a second set of internal grooves opposite the first set of internal grooves comprising outer grooves: a first set of outer grooves and a second set of outer grooves opposite the first set of outer grooves and the fitting comprises: a first toothed gear between the first set of inner grooves and the first set of outer grooves and a second toothed gear between the second set of internal grooves and the second set of external grooves. The valve assembly of claim 21, wherein when the electromagnetic signal source emits an electromagnetic signal, the fitting in the inner chamber moves, the first and second toothed gears rotate, the fitting moves relative to the inner grooves, and the slide arm moves relative to the fitting emotional. The valve assembly of claim 22, wherein, as the fitting moves, the fitting travels a path D within the pole piece and the slide arm travels at least one path N · D, where N is greater than one. The valve assembly of claim 23, wherein N is greater than or equal to 2. The valve assembly of claim 16 or claim 21, wherein the fitting includes a first portion and a second portion attached to the first portion, the second portion receiving the slide arm. The valve assembly of claim 25, wherein the first portion comprises a metallic material. The valve assembly of claim 25, wherein the first portion comprises a ferromagnetic material. The valve assembly of claim 16 or claim 21, wherein the fitting comprises a metallic material and the slide arm comprises a non-metallic material. The valve assembly of claim 16, wherein the electromagnetic signal source controls the fitting to move the sliding arm from a raised position, the sliding arm moving toward the rear wall to raise at least one valve to an extended position, the sliding arm extending from the rear wall moved away to close at least one valve.  The valve assembly of claim 16, wherein the electromagnetic signal source controls the fitting to move the sliding arm from an extended position, the sliding arm moving away from the rear wall to raise at least one valve to a raised position, the sliding arm being to the rear wall moved to close at least one valve. The valve assembly of claims 16, 29 or 30, wherein at least one valve comprises a poppet valve connected to the slide arm. The valve assembly of claim 31, further comprising an outer valve around the poppet valve. Coil assembly comprising: Pole piece comprising: Inner chamber; and Inner surface on the inner chamber, wherein the inner surface touches the rotating member; the pole piece surrounding electromagnetic signal source; and A fitting designed to move in the inner chamber when an electromagnetic signal is emitted from the electromagnetic signal source. The coil assembly of claim 33, wherein the fitting comprises a hollow portion including a back wall, and wherein the coil assembly further comprises a slide arm located in the hollow portion, the slide arm comprises a surface contacting the rotating member, the slide arm is adapted to moves in response to movements of the fitting when the electromagnetic signal is emitted. The coil assembly of claim 34, wherein the slide arm moves toward the rear wall. The spool assembly of claim 34, wherein the sliding arm moves away from the rear wall. The coil assembly of claim 34, wherein the rotating member is on or in fitting.  The coil assembly of claim 37, wherein the rotating member is a roller. The coil assembly of claim 35, wherein the fitting comprises a plurality of the rotating components. The coil assembly of claim 39, wherein when the electromagnetic signal source emits an electromagnetic signal, the fitting moves in the inner chamber, the plurality of rotating components rotate, the fitting moves relative to the pole piece, and the slide arm moves relative to the fitting. The spool assembly of claim 35, wherein, as the fitting moves, the fitting travels a path D within the pole piece and the slide arm travels at least one path N · D, where N is greater than one. The coil assembly of claim 41, wherein N is greater than or equal to 2. The coil assembly of claim 35 or claim 39, wherein the fitting includes a first portion and a second portion attached to the first portion, the second portion receiving the slide arm. The coil assembly of claim 43, wherein the first portion comprises a metallic material. The coil assembly of claim 43, wherein the first portion comprises a ferromagnetic material. The coil assembly of claim 35 or claim 39, wherein the fitting comprises a metallic material and the slide arm comprises a non-metallic material. Valve assembly comprising: a flow path through a housing; at least one valve configured to selectively open and close the flow path; Coil assembly comprising: Pole piece comprising: Inner chamber; and Inner surface in the inner chamber, wherein the inner surface touches the rotating member; the pole piece surrounding electromagnetic signal source; and A fitting designed to move in the inner chamber when an electromagnetic signal is emitted from the electromagnetic signal source. The valve assembly of claim 47, wherein the fitting comprises a hollow portion including a rear wall, and wherein the coil assembly further comprises a slide arm located in the hollow portion, the slide arm comprises a surface contacting the rotating member, the slide arm is adapted to moves in response to movements of the fitting when the electromagnetic signal is emitted. The valve assembly of claim 48, wherein the slide arm moves toward the rear wall. The valve assembly of claim 48, wherein the slide arm moves away from the rear wall. The valve assembly of claim 48, wherein the rotating member is on or in fitting. The valve assembly of claim 51, wherein the rotating member is a roller. The valve assembly of claim 48, wherein the fitting comprises a plurality of the rotating components. The valve assembly of claim 53, wherein when the electromagnetic signal source emits an electromagnetic signal, the fitting moves in the inner chamber, the plurality of rotating components rotate, the fitting moves relative to the pole piece, and the slide arm moves relative to the fitting. The valve assembly of claim 54, wherein, as the fitting moves, the fitting travels a path D within the pole piece and the slide arm travels at least one path N · D, where N is greater than one. The valve assembly of claim 55, wherein N is greater than or equal to 2.  The valve assembly of claim 49 or claim 53, wherein the fitting includes a first portion and a second portion attached to the first portion, the second portion receiving the slide arm. The valve assembly of claim 57, wherein the first portion comprises a metallic material. The valve assembly of claim 57, wherein the first portion comprises a ferromagnetic material. The valve assembly of claim 49 or claim 53, wherein the fitting comprises a metallic material and the slide arm comprises a non-metallic material. The valve assembly of claim 49, wherein the electromagnetic signal source controls the fitting to move the sliding arm from a raised position, the sliding arm moving toward the rear wall to raise at least one valve to an extended position, the sliding arm extending from the rear wall moved away to close at least one valve. The valve assembly of claim 49, wherein the electromagnetic signal source controls the fitting to move the sliding arm from an extended position, wherein the sliding arm moves away from the rear wall to at least one valve Raise a raised position, wherein the sliding arm moves to the rear wall to close at least one valve. The valve assembly of claims 49, 61 or 62, wherein at least one valve comprises a poppet valve connected to the slide arm. The valve assembly of claim 63, further comprising an outer valve around the poppet valve.

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