US3261481A - Magnetic feed and positioning means for automatic assembly mechanism - Google Patents

Description

July 19, 1966 M. J LAVERTY 3,261,481

MAGNETIC FEED AND POSTIONING MEANS FOR AUTOMATIC ASSEMBLY MECHANISM 4 Sheets-Sheet 1 Filed May 6, 1964 T m mm PM M FROM l/OPPER MOVEMENT 1 INSERT/0N LOCATOB MOVEMENT STA/ MIG MOVEMENT STA/(MIG MOVEMENT INDEX/N6 MOVEMENT Fz 'gfj (PRIOR ART) INVENTOR. M412 m1 umerv ATTORNEY July 19, 1966 M. J. LAVERTY 3,

MAGNETIC FEED AND POSTIONING MEANS FOR AUTOMATIC ASSEMBLY MECHANISM Filed May 6. 1964 4 Sheets-Sheet 2 INVENTOR.

' Male/"M1 u. z/n/fzrr ATTORNEYS July 19, 1966 M. J. LAVERTY 3,261,481

MAGNETIC FEED AND POSTIONING MEANS FOR AUTOMATIC ASSEMBLY MECHANISM 4 Sheet 3 Filed M 6' 1964 INSERT/0M MOVEMENT W & m R E mm m E w. W M d, M 7. M W M k July 19, 1966 M. J. LAVERTY 3,261,481 MAGNETIC FEED AND POSTIONING MEANS FOR AUTOMATIC ASSEMBLY MECHANISM 4 Sheets-Sheet 4 Filed May 6. 1964 III I M AIR SOURCE F ROM COMPRESSED ATTORNEY United States Patent 3 261 481 MAGNETIC FEED ANi) PosrrroNiNG MEANS non AUTOMATIC ASSEMBLY MECHANISM Martin J. Laverty, Jericho, Long Island, N.Y., assignor to Murray Manufacturing Corporation, Brooklyn, N.Y.,

a corporation of New York Filed May 6, 1964, Ser. No. 365,377 3 Claims. (Cl. 214-1) This invention relates to magnetic means for feeding and accurately positioning close tolerance parts in automatic assembly mechanisms. Although the invention is applicable to a wide range of automatically assembled devices, it is particularly useful in tube and pole piece assemblies such as described in US. Patent No. 3,037,- 800, which was issued to M. I. Laverty et al. on June 5, 1962, for a Tube and Pole Piece Assembly. Accordingly, the invention will be described in connection with tube and pole piece assemblies. It should he understood, however, that the invention can be used to feed and position any suitably dimensioned part that is made of or contains ferromagnetic material.

The above noted US. patent discloses a tube and pole piece assembly which is used in certain electrical circuit breakers. The tube-pole piece assembly comprises a hydraulically sealed non-magnetic tube. Contained within the tube are a movable magnetic pole piece and a spring for retarding the movement of the pole piece towards an end of the tube, to which there is internally afiixed another magnetic pole piece.

In the circuit breaker, the tube-pole piece assembly is mounted within a coil of wire through which the circuit breaker current flows, so that the pole piece is exposed to a magnetic field that varies in accordance with the magnitude of current flow through the circuit breaker. The stiffness of the spring and the viscosity of hydraulic dampening fluid within the tube-pole piece assembly are chosen so that there i practically no tendency for the pole piece to travel during normal current flow. During overload conditions, however, the magnetic field increases in strength, causing the movable pole piece to travel towards the fixed pole piece with a rate proportional to the overload current. When the two pole pieces reach closest proximity to each other, the reluctance of the magnetic circuit is considerably reduced, thereby causing a corresponding increase in the magnetic flux through the pole pieces. This increase in flux serves to trip a magnetic armature near the tube-pole piece assembly and opens the electrical contacts of the circuit breaker, thereby interrupting the current flow. It will be apparent from the foregoing description that the tube-pole piece assembly acts as a time-delay device which permits a continuous overload condition to exist for a predetermined time before interrupting the circuit. Thus, in the industry, the tube-pole piece assembly is known as a hydraulic-magnetic time delay tube.

It is desirable automatically to assemble the fixed pole piece within the tube, to reduce the cost of the circuit breaker. One particular problem, however, involves the insertion of the relatively small size stationary pole piece within the tube. In a typical example, the tube is a brass cylinder which is 2" long, with an inside diameter of 0.279", and closed at one end. The stationary pole piece, which is a steel disc 0.275" in diameter and 0.062 thick, must be inserted precisely in the open end of the tube, and then be moved 2" to the closed end of the tube, where it is subsequently staked in place by an automatic staking tool. Since there is only 0.004" clearance between the disc and inside of the tube, the feeding and positioning mechanism must be extremely accurate to avoid a blockage of the disc at the open end of the tube or jamming during its 2" of travel from the open to the closed end of the tube.

The required accuracy can be obtained with clamping or collapsible collet-type fixtures, or by the Widely used suction or vacuum mechanisms. These mechanisms, however, are relatively complex and costly, particularly the vacuum type, which requires pumps and involves relatively high maintenance costs. Electromagnet mechanisms are undesirable because they require a power source and present a space problem with parts as small as 0.275" in diameter. A permanent magnet mechanism would be ideally suited for this application, except that conventional permanent magnet feed and positioning means lacks the required accuracy of repetitive positioning for small parts. With very small parts, the flux spread of the conventional permanent magnet tends to move the part out of position due to random variations in the grain structure, dimensions, and inherent magnetic field of the parts. Large parts hold their position on a permanent magnet due to inertia and traction, but small parts are displaced by the above noted random variations, and this displacement would exceed the required tolerance.

Accordingly, one object of this invention is to provide a permanent magnet feed and positioning means which has a high degree of repetitive positioning accuracy with very small parts.

Another object of this invention is to provide a permanent magnet feed and positioning means which minimize position displacements caused by random variations in the grain structure, dimensions, and inherent magnetic field of the parts.

A further object of this invention is to provide magnetic means for feeding and accurately positioning close tolerance parts in automatic assembly mechanisms.

An additional object of this invention is to provide an improved mechanism for automatically inserting the stationary pole piece into a hydraulic-magnetic time delay tube.

Other objects and advantages of the invention will become apparent to those skilled in the art from the following description of several specific embodiments thereof, as illustrated in the attached drawings, in which:

FIG. 1 is a schematic representation of a prior art permanent magnet mechanism for automatically insert ing ferromagnetic discs into short, open-ended tubes;

FIG. 2A is an elevation section of a prior art magnetic stylus showing the lines of force produced thereby;

FIG. 2B is a plan section of the prior art magnetic stylus of FIG. 2A;

FIG. 3A is an elevation section of a magnetic stylus of this invention showing the lines of force generated thereby;

FIG. 3B is a plan section of the magnetic stylus of FIG. 3A;

FIG. 4A is an elevation section of a prior art magnetic stylus holding a small ferromagnetic disc;

FIG. 4B is an elevation section of the magnetic stylus of this invention holding a small ferromagnetic disc;

FIG. 5 is a schematic representation of a novel mechanism for inserting spherical pole pieces into hydraulicmagnetic time delay tubes;

FIG. 6A is an elevation section of the magnetic stylus of FIG. 5 with a spherical pole piece near the edge thereof;

FIG. 6B shows the spherical pole piece of FIG. 6A being attracted into position by the magnetic stylus;

FIG. 6C shows the spherical pole piece of FIG. 6B in its final position on the magnetic stylus;

FIG. 7A shows another magnetic stylus of this invention with a pole piece near the edge thereof;

FIG. 7B shows the pole piece of FIG. 7A being attracted into position by the magnetic stylus;

FIG. 7C shows the pole piece of FIG. 7B in its final position on the magnetic stylus; and

FIG. 8 shows another magnetic stylus of this invention with a central air channel for disengaging the part held thereby with a jet of compressed air.

Referring to FIG. 1, the prior art permanent magnet mechanism for feeding and inserting ferromagnetic discs into short, open-ended tubes contains a movable stylus 10 which is fitted at one end with a high flux density permanent magnet insert 12. Stylus 10 is made of a nonmagnetic material, and is slidably mounted in a guide member 14 for movement into and out of an open ended tube 16 positioned below stylus 10 by a movable support 18, which can be an indexed assembly line or an indexed turntable. The movable support 18 holds a plurality of open ended tubes which may be indexed to position the tubes one at a time under stylus 10, to receive the ferromagnetic disc. In this particular mechanism, the tubes are aligned in exact position under stylus 10 by a funnelshaped locator 20, which is moved down over the tube after it has been indexed into the approximate position by the movable support 18.

A ferromagnetic disc 22 is shown attached to the stylus 10 by means of the magnetic attraction of permanent magnet 12. The discs are fed into position on permanent magnet 12 by an automatic feed mechanism comprising a feed tube 24, which receives a continuous supply of the discs from a feed hopper, and a slide member 26, which is slidable in a guide member 28 and moves the discs one at a time under permanent magnet '12. After a disc has been positioned on stylus 10, slide member 26 retracts to receive another disc, and stylus 10 moves downwardly to insert disc 22 into tube 16 as indicated by the dashed lines in FIG. 1. At the end of the insertion stroke, disc 22 is staked into place in the bottom of tube 16 by staking members 30 and 32, which are operated automatically by means not shown. After the disc 22 has been staked in place, stylus 10 is withdrawn from the tube to its initial position, and locator 20 is also withdrawn from the tube. An empty tube is then indexed into position under stylus 10, and the cycle repeated.

Many different control means are known in the art for automatically sequencing an assembly mechanism in accordance with the foregoing sequence of operation; therefore, the details of the control means are omitted from this patent application for the sake of clarity.

Although the above described prior art mechanism works satisfactorily with large, loose tolerance parts, it lacks the required accuracy of repetitive positioning for small, close tolerance parts. It cannot, therefore, be used to insert 0.275" x 0.062 discs into 0.279" x 2" during the assembly of small, hydraulic-magnetic time delay tubes. The reason for this lack of repetitive positioning lies in the magnet rather than in the feed mechanism.

After the discs are positioned on the stylus, they come under the influence of the magnetic field of magnet 12, as shown in FIGS. 2A, 2B and 4A. Since the discs are quite small, the flux spread of magnet 12 tends to move the discs out of position due to random variations in the grain structure, dimensions, and inherent magnetic field of the part. As shown in FIG. 4A, there is a strong component of magnetic force acting in the transverse direction on disc 22, particularly at the periphery thereof, and the disc is too light to generate enough friction and inertia to resist movement. Therefore, after being accurately positioned on the magnet 12 by the slide mechanism, the disc is displaced by the flux spread of the magnet.

In accordance with the invention, however, this displacement is minimized by providing a novel magnetic insert with a short circuited magnet which minimizes the flux spread. As shown in FIGS. 3A and 3B, this invention utilizes two permanent magnets 34 and 36 which are positioned side by side with the north pole of one magnet adjacent the south pole of the other magnet. Since lines of flux travel by the lowest reluctance path from a north pole to a south pole, this produces a magnetic short cir- (it cuit and holds most of the lines of flux close to the magnet. Furthermore, the magnetic short circuit minimizes the peripheral magnetic field and virtually eliminates the flux spread which caused displacement of the disc in the prior art mechanism. As shown in FIG. 4B, the magnet as used in this invention produces almost no transverse force on the disc 22, and therefore does not cause any displacement due to random variations in the disc. Accordingly, the magnet as used in this invention allows the feed mechanism of FIG. 1 to be used to insert a 0.275 x 0.062 disc into a 0.279" X 2" tube.

The magnet as used in the invention is not limited to inserting discs in tubes. In some hydraulic-magnetic time delay tubes, a spherical stationary pole piece is used, and the invention can handle spherical parts as well as disc shaped parts.

FIG. 5 shows a mechanism for inserting 0.275" diameter spheres into a 0.279 x 2" tube. In this embodiment of the invention, spheres are released from a tube 40 by a feed lever 42, which releases the spheres one at a time and allows them to roll to the edge of magnets 34' and 36. FIGS. 6A, 6B and 6C show how the spheres are attracted into position on the magnets, which have a spherical depression formed in the face thereof mechanically to guide sphere 38 into exact position. The depression in the magnets is, of course, centered on the stylus 10, and preferably has a slightly smaller radius of curvature than the sphere so that the positioning action will be governed by contact between the sphere and the periphery of the depression. This minimizes displacement due to variations in the diameter or curvature of the spheres.

The embodiment of FIG. 5 also differs from the embodiment of FIG. 1 in that the parts are disengaged from the stylus by a larger magnetic field rather than by being staked in place. Movable support member 18' is fitted with a large permanent magnet 44 which is positioned under tube 16. When sphere 38 is inserted in tube 16, the magnetic field of magnet 44, being stronger than the magnetic field of magnets 34 and 36', holds the sphere in the tube when the stylus is withdrawn.

The magnet as used in this invention can also be used with other parts such as magnetic shaped washers, as i1- lustrated in FIGS. 7A, 7B and 7C. In this example, the magnets 34" and 36" are shaped to form a truncated cone which serves mechanically to guide the washer into exact position by engaging the central opening in the washer.

FIG. 8 shows another variation of the invention in which a central air channel 48 is formed in stylus 10 and magnets 34 and 36 to disengage the part by means of a jet of compressed air. In the example shown, a disc 22 is being removed after having been inserted into a tube 16. The air jet disengagement could, of course, also be utilized in the embodiment of FIG. 6 if desired, in place of permanent magnet 44.

From the foregoing description it will be apparent that this invention provides improved magnetic means for feeding and accurately positioning close tolerance parts in automatic assembly mechanisms. And it should be understood that this invention is by no means limited to the specific embodiments disclosed herein, since many modifications can be made in the disclosed structure without departing from the basic teaching of the invention. For example, although permanent magnets are used in the disclosed embodiments, the short-circuiting principle is equally applicable to electro-magnets and can be used to minimize position displacement in electromagnetic devices if desired. Also, many different forms and shapes of magnets could be employed to match particular parts. These and many other modifications of the disclosed structure will be apparent to those skilled in the art, and this invention includes all modifications falling within the scope of the following claims.

What is claimed is:

1. In an apparatus for inserting a magnetic pole piece into a non-magnetic tube, the improvement comprising;

a longitudinal transport member having a free end for insertion into said non-magnetic tube located axially relative to the longitudinal axis of said member, said transport member being movably mounted to travel forward and return to its home position along its longitudinal axis, a pair of magnets adjacent each other at the free end, the south and north poles of a face of one magnet being adjacently opposed to the north and south poles respectively of a face of the other magnet, the opposed faces of said magnets being disposed along the axis of said longitudinal member, means located near the free end of said transport member for delivering a magnetic pole piece to said free end, and means at the free end of said transport member for mechanically centering and guiding said pole piece into its correct position when it it delivered to said free end so that said pole piece can be inserted easily into the non-magnetic tube by said transport member.

2. The apparatus of claim 1 wherein an air channel is provided passing axially through said magnets, whereby compressed air may be applied to said channel to deposit said pole piece when it is inserted into said nonmagnetic piece.

3. The apparatus of claim 1 wherein a third magnet is provided located adjacent the bottom of said nonmagnetic tube, said magnet being stronger than the magnets at the free end of the transport member so that when the pole piece is inserted into the tube, said magnet is able to remove the pole piece from the free end of said transport member.

References Cited by the Examiner UNITED STATES PATENTS 1,903,047 3/ 1933 Impey 29465.5 X 2,329,770 9/ 1943 Knox 29-511 2,840,892 7/ 8 Erdmann. 2,997,918 8/ 1961 Spear 29465.5 3,023,879 3/ 1962 Catferty. 3,037,800 6/1962 Laverty 3 287--20.3 3,091,347 5/ 1963 Sehn.

FOREIGN PATENTS 999,770 10/ 1951 France.

MARVIN A. CHAMPION, Primary Examiner.

Claims (1)

1. IN AN APPARATUS FOR INSERTING A MAGNETIC POLE PIECE INTO A NON-MAGNETIC TUBE, THE IMPROVEMENT COMPRISING; A LONGITUDINAL TRNSPORT MEMBER HAVING A FREE END FOR INSERTION INTO SAID NON-MAGNETIC TUBE LOCATED AXIALLY RELATIVE TO THE LONGITUDINAL AXIS OF SAID MEMBER, SAID TRANSPORT MEMBER BEING MOVABLY MOUNTED TO TRAVEL FORWARD AND RETURN TO ITS HOME POSITION ALONG ITS LONGITUDINAL AXIS, A PAIR OF MAGNETS ADJACENT EACH OTHER AT THE FREE END, THE SOUTH AND NORTH POLES OF A FACE OF ONE MAGNET BEING ADJACENTLY OPPOSED TO THE NORTH AND SOUTH POLES RESPECTIVELY OF A FACE OF THE OTHER MAGNET, THE OPPOSED FACES OF SAID MAGNETS BEING DISPOSED ALONG THE AXIS OF SAID LONGITUDINAL MEMBERS, MEANS LOCATED NEAR THE FREE END OF SAID TRANSPORT MEMBER FOR DELIVERING A MAGNETIC

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