US3485254A

US3485254A - Flow control apparatus for fluent magnetic materials

Info

Publication number: US3485254A
Authority: US
Inventors: Hans Ernst
Original assignee: Individual
Current assignee: Individual
Priority date: 1965-09-24
Filing date: 1968-05-07
Publication date: 1969-12-23
Anticipated expiration: 1986-12-23

Description

Dec. 23, 1969 H. ERNST 3,485,254

FLOW CONTROL APPARATUS FOR FLUENT MAGNETIC MATERIALS Original Filed Sept. 24, 1965 2 Sheets-Sheet 1 '9 20 Z2 23 A l I g f /(M l I r 23"- I4 FIGHZ A o 2 lb F'IG.4- 57-- a i i i INVENTOR.

HANS ERNST H. ERNST $485,254

FLOW CONTROL APPARATUS FOR FLUENT MAGNETIC MATERIALS Dec. 23, 1969 2 Sheets-Sheet 2 Original Filed Sept. 24, 1965 FIG.

FIG.6

Has

INVENTOR.

HANS ERNST BY Fae 82 .4

3,485,254 lFLOW CONTROL APPARATUS FOR FLUENT MAGNETIC MATERIALS Hans Ernst, 1021 Eldorado Ave.,

Clearwater, Fla. 33515 Original application Sept. 24, 1965, Ser. No. 489,951, now Patent No. 3,417,771, dated Dec. 24, 1968. Divided and this application May 7, 1968, Ser. No. 727,175 Int. Cl. F16k 9/00, 31/06 11.5. C]. 13781.5 7 Claims ABSTRACT OF THE DISCLOSURE The disclosed apparatus employs the selective introduction of a magnetic field in a channel through which flows a fluid having magnetizable particles dispersed therein in order to control fluid flow. A magnetic control valve disposed in or adjacent the channel includes a permanent or electromagnet for developing a magnetic field through which the fluid flows. The viscosity of the. fluid increases with the strength of the magnetic field to restrict or inhibit fluid flow, as desired.

REFERENCE TO RELATED APPLICATION This is a divisional applicaion of my copending application Ser. No. 489,951 filed Sept. 24, 1965, now US. Patent No. 3,417,771, entitled, Flow Control Apparatus for Fluent Magnetic Materials.

BACKGROUND AND OBJECT OF THE INVENTION This invention relates to control apparatus for governing the flow or volume translation of a fluent material having magnetic properties.

Fluent materials are those capable of flowing, have no shape, and therefore. must be confined in ducts or channels to guide their path of movement during translation from place to place. Such materials may be dry, as metallic dust from tumbling operations, crushed ore and the like; or they may be liquid of any viscosity, containing magnetic particles, such as iron. Thus all these materials have magnetic properties.

In this invention, fluent materials .having magnetic properties are contemplated to include those materials which in their natural state contain a large proportion of magnetizable particles and therefore the materials have magnetic properties; and also those materials which in their natural state have no magnetizable particles but to which magnetizable particles have been added to impart magnetic properties to the material. The term magnetic has conflicting definitions, so as used herein, it is intended to mean capable of being magnetized.

The control of volume translation of this class of materials involves several functions such as starting, stopping, volume control, rate control and selection of path of movement. The motivating force which etfects the translatory movement may vary from gravity feed pressures to high pressures needed to utilize the material as a power medium. Anyone of the functions recited can be eifected by the use of a magnetic control valve which comprises basically a magnet, either electrical or permanent, associated with a channel or passage in a manner that its magnetic field permeates said passage to magnetically intercept the magnetic particles in the approaching material. Thus the particles are interrupted in their course and held.

It should be understood that these particles are relatively small, even minute down to the class of powders and dust. It is contemplated that some may have a magnetic core covered by a non-magnetic coating. By using nitcd States Patent 0 ice ultra fine particles, they may be. adequately suspended in a viscous liquid to make it homogeneous.

One of the objects of this invention is to take advantage of and to utilize the magnetic properties of a fluent material as one of the elements of the combination of means for controlling or modifying its own movement and other characteristics.

Another object of this invention is to eliminate the use. of movable mechanical valving or baffles inside a flow channel, as well as the mechanical linkage thereto when the material being conveyed has magnetic properties by contriving a control system that is external of the channel but influential within the channel.

A further object of this invention is to provide a new and novel control apparatus for the purposes described which is simple in construction, effective in use, and lends itself to remote control.

Other objects and advantages of the present invention should be readily apparent by reference to the following specification, considered in conjunction with the accompanying drawings forming a part thereof, and it is to be understood that any modifications may be made in the exact structural details there shown and described, within the scope of the appended claims, wihout departing from or exceeding the spirit of the invention.

Referring to the drawings in which like reference numerals indicate like or similar parts;

FIGURE 1 is a diagrammatic plan view of a reciprocable magnet for stopping and starting flow of a fluent material having magnetic properties.

FIGURE 2 is an elevational view taken on the line 22 of FIGURE 1.

FIGURE 3 is an end view partly in section taken on the line 33 of FIGURE 2.

FIGURE 4 is a diagrammatic view showing one form of a flow rate control mechanism.

FIGURE 5 is a plan view showing another form of flow rate control mechanism.

FIGURE 6 is an elevational View taken on the line 66 of FIGURE 5.

FIGURE 7 is a diagrammatic view of a flow rate and channel selector control mechanism.

FIGURE 8 is a sectional view through a magnetic control valve.

FIGURE 9 is a section on the line 99 of FIGURE 8.

DETAILED DESCRIPTION OF THE INVENTION A simple basic form of the invention is shown in FIGURES 1, 2 and 3. The reference numeral 10 indicates a closed channel, such as a pipe or conduit, to the top of which is connected a suitable source of supply 11 of a fluent material from which the material flows into the channel 10. At a suitable location along the channel 10 is a control station indicated generally by the reference numeral 12, at which a magnetic control is mounted to control the function of stopping and starting the flow. In this form of the invention, a bifurcaed permanent magnet 13, shown in FIGURE 1, is mounted for reciprocation on suitable supporting means 14, to and from the channel 10. It will be obvious that when the open end of the magnet 13 embraces the channel 10, as shown in FIGURE 1, that a magnetic field 15 will be projected into the channel 10 through which is flowing a fluent material having magnetic properties.

The magnetic field 15 functions to intercept, that is, to magnetize, attract, and hold the moving magnetic particles 16 of the material when the magnet is advanced to the position shown in FIGURE 1. This action clogs the channel, which in the process will stop the flow of nonmagnetic particles as well, until the build-up stops the flow entirely. It will now be seen that the magnetic properties of the material cooperate with the magnet and its magnetic field to form a combination of means to initiate and stop the flow of material.

The magnet 13, having opposing north and

south pole pieces

17 and 18, is reciprocated to and from an active position, preferably by power means rather than by manual means, such as solenoid 19. It has a plunger 20, connected at one end by a pin 21 to the magnet 13. A spring 22 working against a fixed abutment 23 holds the plunger in an advanced position against a stop 23a to stop the flow. By operation of the switch 24, the solenoid is energized, and the magnet 13 is retracted against the stop 23a to start the flow. Thus, when the power is off, the channel is blocked. This is convenient when the system is shutdown.

The effectiveness of this stopping operation will of course depend for one thing on the proportion of magnetic particles to non-magnetic material. Regardless of the proportions, however, if the magnetic particles are intercepted, that is stopped and held, it impedes the flow. It is also recognized of course, that the size of the cross section of the channel and the strength of the magnetic field of magnet 13 also plays an important part in this action.

Therefore it is obvious that there must be a prescribed relationship between the cross sectional space in the channel and the strength of the magnetic field for the field to adequately and effectively magnetize the particles as they enter the field. Thus the magnetized particles form or build up artificial poles on the inside of the channel. Other magnetic material is constantly being added as long as the flow continues, to build up these poles and bridge the channel, which stops the flow completely.

In any case, this results in the formation of a short section 25 of frozen material in the channel 10, as shown in FIGURE 3, within the confines of the magnetic field 15 and held together by magnetic forces. Being confined in length by the extent of the magnetic field, this frozen section must also support the Weight of the free material above it and beyond the reach of the magnetic field when the flow is stopped.

With fuzzy, light, dry material, probably somewhat aerated, the attraction of the magnetic forces and the friction of the side walls of the tube 10 are sufiicient to hold back the material without slippage. With more compact and heavier material, and especially frictionless material, such as oils and the like, these forces may not be sufiicient. To aid in this situation, the interior of the tube may be fitted with a short bushing 26, as shown in FIGURE 3, just below the station 12, which provides a more positive support against slippage.

Strong electro-magnets may be utilized in place of permanent magnets, and controlled by conventional switches, when it is desired to eliminate movable magnets. It may not be convenient to use a vertical channel With gravity feed, in which case the tube may be set at an angle, or even horizontal, and the source of supply pressurized sufiiciently to efiect flow. In some cases, suction may be resorted to.

Another function of the control of volume translation is determining the rate of flow of these materials by use of their own magnetic properties. One form of rate control mechanism is diagrammatically shown in FIGURE 4, comprising two independent magnetic control valves mounted in spaced relation along the tube 10, the first valve comprising a pair of

electromagnets

28 and 29, and the second valve having a pair 30, 31. In operation, the second pair 30, 31 are energized to stop the flow and thereby fill the tube 10 above this point. Then the

first pair

23, 29 are energized to hold back or stop the flow at that point, and the second pair simultaneously de-ener-. gized to release the material trapped between the two pairs so that it flows on as by gravity.

The cycle is repeated by again energizing the magnets 30, 31 and the first pair simultaneously de-energized which again fills the interval of tube 10 between the two pairs of magnets. Thus, by these alternate operations, an intermittent feed is achieved.

An electrical control circuit for governing automatic alternate operation of these valves is shown diagrammatically in FIGURE 4. One end of the windings of the first pair of

magnets

28, 29 is electrically connected in parallel by line 32 to brush 33 of a commutator 34. One end of the windings of the other pair of magnets 30, 31 are connected in parallel by line 35 to brush 36. The remaining ends of all the windings are connected in parallel by line 37 to a power line 38.

Power rotation of the commutator is obtained by providing a conventional power driven reduction gear drive mechanism comprising a motor 39, a worm 40 and a worm gear 41 mounted on shaft 42. The shaft 42 bears the commutator 34 having independent

arcuate sections

43 and 44. The brush 33 is shown riding in contact with the segment 44 which is insulated from the shaft 42. The brush 36 is shown riding in contact with the segment 43. This segment is electrically connected to shaft 42. A line 45 electrically connects shaft 42 to power main 46. In the position of parts shown in FIGURE 4, current flows from the power line 46 to brush 36 and thus energizes magnets 30 and 31, which stops the flow in channel 10 at that point. Since brush 33 is insulated, the

magnets

28, 29 are de-energized. Upon rotation of the commutator 34, the brush 36 eventually engages the insulated segment 44 and the brush 33 engages the power segment 43. This results in the

upper magnets

28 and 29 stopping the flow, and the lower magnets 30, 31 releasing the material trapped between the two pairs of magnets. Thus by continuous rotation of the commutator, the cycle repeats and an intermittent feed is obtained.

Another form of automatic feed mechanism is diagrammatically shown in FIGURES 5 and 6. In FIGURE 5, an electromagnet 57 having

arms

58 and 59 embracing the feed tube 10, is supported on the end of a swinging lever 60, pivoted at 61 on a fixed support 62 at a control station, An eccentric 63 is connected by link 64 t0 the lever 60. By driving the eccentric with a slow speed mechanism, indicated generally by numeral 65 and of the same type as that shown in FIGURE 4, the arm 60 is slowly raised and lowered longitudinally of the tube 10. When the magnet coil 57 is energized, it will stop the How of material in the tube regardless of its position. If this happens in the uppermost position of the lever 60, then when the lever is lowered, the material in the tube will follow the lever down. But when the lever is reversed, the magnet 57 quickly pulls away and releases a certain amount of material in the lower end of the tube due to the departure of the magnetic field. Thus by regulating the rate of rotation of the eccentric and the throw, the rate of feed may be varied.

When it is desired to have a selection between a fast and a slow rate of fiow, the channel 10 as shown in FIGURE 7 may be provided with a narrow by-pass channel 66. The main branch 10a is provided with a magnetic control valve 67 and the by-pass channel 66, of smaller flow capacity, is provided with a magnetic control valve indicated generally by the reference numeral 68. These magnets are connected to a selector switch 69 whereby a selection of rate may be made.

In other words, by blocking the flow in the channel 10a by magnet 67, with the switch 69 in the full line position, the material is forced to flow through the narrow channel section 66, and therefore at a reduced rate. By throwing switch 69 to its dotted line position, the magnet 68 blocks the by-pass 66, and magnet 67 is released to permit normally faster flow through channel section 10a. Thus the same arrangement may be set up for selection of different paths of flow as shown in FIGURE 7. This arrangement is particularly useful when the fluent material having magnetic properties is being pumped through the channel under pressure for use as a power medium. In such a case, the branch channels 70 and '71 are provided with magnetic control valves, indicated generally by

numerals

72 and 73 which may be alternately energized by switch 79 to select the path of flow by blocking flow in the other channel, In this case the

channels

70 and 71 are connected to opposite ends of a cylinder 74, containing a piston 75. Thus selection of channels determines the direction of movement of the piston.

The

channels

70 and 71 are connected together to an exhaust channel 76. When the fiow is coming into channel 70, a magnetic control valve 77 is energized by switch 79 in its dotted line position to block the flow from channel 70 to exhaust; and the magnetic control valve 73 is energized to block the incoming flow to channel 71. The exhaust from cylinder 74 is now free to flow to channel 76.

On the other hand, if the flow in channel 71, is to be utilized, the switch 79 is turned to its full line position to energize magnetic control valve 72 and block flow in channel 70, and also energize magnetic control valve 80 to block exhaust flow from cylinder 74, whereby the piston is actuated in the opposite direction. Turning the switch also released

magnetic control valves

73 and 77, permitting exhaust from channel 70 and one end of cylinder 74, and permitting flow into the other end of cylinder 74.

Positive stops 81 and 82 are provided for engagement by abutments 83 carried by the piston 84 for positively limiting the movement of the piston in either direction. These stops may be replaced by switches or other mechanical means to eflect actuation of switch 79, thereby providing continuous reciprocation of piston 75.

It is to be understood that the cylinder 74 and piston 75 may be replaced by any other form of linear or rotary hydraulic motor, or pressure responsive device.

The magnetic control valves which have been shown diagrammatically in the several views thus far, may be constructed as separate units for insertion in a flow line. FIGURES 8 and 9 show such a magnetic control valve comprising a block housing 85, made of non-magnetic material, having a central chamber 86 and a threaded inlet 87 and an outlet 88 at opposite ends thereof whereby the material may flow through the housing. A magnetizing coil 89 is mounted on top of the housing 85 and supported on an iron core 90. The opposite ends of the core are thus of opposite polarity when the coil is energized.

The chamber is subdivided into sub-chambers 91 by several flat dividers or laminae 92 whereby the incoming flow is caused to divide and flow simultaneously through the sub-chambers 91 and then collected to flow through the outlet 88. The laminae 92 are made of magnetic material, and alternate ones are connected to one pole 93 of the core 90 and the remainder of pole 94.

The path of flow of flux from each pole to the laminae is arranged so as to minimize loss or short circuit. Spacers of magnetic material 102 are placed between the nonmagnetic cover 95 and the ends of the core to support the coil and core above the cover. Spacers 103 at the ends of the core 95 are also of magnetic material. The laminae on the right are stacked on the bolt 96 with spacers 97 of magnetic material between them. The laminae on the left are stacked on the bolt 98 with similar spacers 99 between them. It will be noted that the laminae are short enough that they do not extend to the other bolt. Spacers 100 of non-magnetic material are placed between the laminae to isolate them from each other because of their opposite polarity. Non-magnetic filler pieces 101 are placed between the free ends of the laminae to isolate them from the magnetic spacer blocks. The result is a plurality of narrow slots or sub-chambers 91, the opposite sides of which are of opposite polarity, Since the space between a pair of sides is narrow, a very strong magnetic field can be created and due to the relatively large area in addition, almost instantaneous stopping of flow can be obtained.

It will be noted that the

bolts

96 and 98 are passed through the block 85 and are threaded in the ends of the core whereby the entire assembly is secured together. It will be seen that the flux flows from the ends of the core 90 through the

bolts

96 and 98, the

spacers

102, 103, 97 and 99 to the laminae to create the magnetic field.

There has thus been provided a new and improved apparatus for controlling the flow of fluent magnetic materials within a channel. The fluent material may be selected to have characteristics suited to a particular application. F or instance graphite, oil, molybdenum disulphide, tetrafiuoroethylene, or nylon particles impregnated with magnetic material could be used. The use of impregnated resilient solid materials permits elastic deformation thereof under pressure, thereby aiding in the complete blocking of flow when desired. Furthermore, the fluent medium may be selected to have electrically conductive properties also and this is particularly advantageous to facilitate the pumping action in alternating current energized systems. In this case self induced fields in the fluent medium resulting from the impressed alternating magnetic field are generated.

The apparatus is designed to interact on the magnetic property of the material to effect interception of the flowing magnetic particles in the material and thus stop and hold them. This action progresses to the point that complete stoppage of flow is eifected. It is of course contemplated that de-magnetizers can be used when the material is released to start flow again if found necessary for efficient operation. Such a system has many advantages. There are no moving parts and therefore no mechanical linkages to maintain and keep in repair and the system lends itself to remote control and to miniaturization.

I claim:

1. In an apparatus including a channel for conveying a fluent material having magnetic properties and a magnetic control valve comprising, in combination:

(A) at least one first lamina disposed in the channel;

(B) at least one second lamina disposed in the channel in closely spaced parallel relation to said first lamina,

(1) whereby to define a passageway through which the fluent material conveyed in the channel must pass;

(C) a magnet; and

(D) means associated with said magnet selectively effective to couple magnetic flux from said magnet into said first and second laminae,

(1) whereby to selectively create a magnetic field across said passageway effective to control fluent material flow therethrough.

2. In an apparatus for conveying a fluent material havmg magnetic properties, a magnetic control valve comprising, in combination:

(A) a housing having (1) an inlet,

(2) an outlet; and

(B) a magnetic core mounted on said housing;

(C) a magnetizing coil wound around said core;

(D) at least one first magnetic lamina;

(E) a first magnetic insert coupling one end of said first lamina in magnetic circuit with one end of said core;

(F) at least one second magnetic lamina;

(G) a second magnetic insert coupling one end of said second lamina in magnetic circuit with the other end of said core;

(H) said first and second laminae disposed in said housing in closely spaced relation to define opposing sides of a channel communicating with said inlet and outlet,

(1) whereby upon energization of said magnetizing coil, a magnetic field distributed substantial- 1y uniformly over the entire area of the gap between said laminae arrests the flow of fluent material through said channel from said inlet to said outlet.

3. In an apparatus for conveying a fiuent material having magnetic properties, a magnetic control valve comprising, in combination:

(A) a. housing having (1) an inlet,

(2) an outlet, and

(3) a chamber communicating with said inlet and outlet;

(B) a magnetic core mounted on said housing;

(C) a magnetizing coil wound around said core;

(D) a series of first magnetic dividers in magnetic circuit with one end of said core,

( 1) said first dividers being spaced apart and disposed to span said chamber;

(E) a series of second magnetic dividers in magnetic circuit with the other end of said core,

(1) said second dividers disposed to span said chamber in alternating relation with said first dividers;

(F) said alternating first and second dividers defining a plurality of parallel channels, each communicating with said inlet and outlet,

(1) whereby upon energization of said magnetizing coil, magnetic fields developing between adjacent first and second dividers arrest the flow of the fluent material through said channels from said inlet to said outlet.

4. The magnetic control valve defined in claim 3 where- (1) said first and second dividers are of a flat configuration and are arranged parallel to one another,

(2) whereby said channels are of substantially uniform cross-section throughout their lengths.

5. The magnetic control valve defined in claim 3 wherein said housing is formed of a non-magnetic material, and further includes (G) magnetic inserts (l) interposed between said first dividers and said one end of said core for coupling said first dividers in magnetic circuit with said core, and

(2) interposed between said second dividers and said other end of said core for coupling said second dividers in magnetic circuit with said core.

6. The magnetic control valve defined in claim 5 which further includes (H) non-magnetic spacers (1) interposed between said first dividers and said other end of said core and between second dividers and said one end of said core,

(2) whereby to confine said magnetic circuit to parallel paths across said channels between adjacent first and second dividers.

, 7. The magnetic control valve defined in claim 6 which further includes (H) at least one bolt affixing said core, said first and second dividers, said inserts, and said spacers to said housing.

References Cited UNITED STATES PATENTS 2,820,471 1/1958 Crowell. 3,405,728 10/1968 Dexter 137-251 HAROLD W. WEAKLEY, Primary Examiner US. Cl. XJR. 137251