US559073A - Can soldering machine - Google Patents

Can soldering machine Download PDF

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US559073A
US559073A US559073DA US559073A US 559073 A US559073 A US 559073A US 559073D A US559073D A US 559073DA US 559073 A US559073 A US 559073A
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cans
chains
bath
solder
soldering
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    • AHUMAN NECESSITIES
    • A41WEARING APPAREL
    • A41HAPPLIANCES OR METHODS FOR MAKING CLOTHES, e.g. FOR DRESS-MAKING OR FOR TAILORING, NOT OTHERWISE PROVIDED FOR
    • A41H33/00Machines or appliances for folding the edges of collars, cuffs or the like while manufacturing
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L24/00Arrangements for connecting or disconnecting semiconductor or solid-state bodies; Methods or apparatus related thereto
    • H01L24/01Means for bonding being attached to, or being formed on, the surface to be connected, e.g. chip-to-package, die-attach, "first-level" interconnects; Manufacturing methods related thereto
    • H01L24/10Bump connectors ; Manufacturing methods related thereto
    • H01L24/11Manufacturing methods

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  • PatentedApr; 28, 1896[ o e e a g e e e a c witnesseses M. PHOTD-UMD.WASHINGI'ON. D C
  • My invention relates to the manufacture of metallic cans by machine processes, and to the soldering of the ends of such cans, both of round and angular section and of various dimensions.
  • My improvements consist especially in a method of controlling the movement of the cans while being soldered within a convenient limit of traversing movementand space, so as to more effectually expose them to the melted solder, and in various devices to accomplish a more effectual and rapid performance of the processes, as will be set forth in connection with the drawings herewithand the claims at the end of this specification.
  • Figure 1 is an end elevation, partially in section, of one of my improved can-soldering machines arranged for cylindrical cans.
  • Fig. 2 is another partial end View in another plane of the same machine, showing the acid or cleaning bath.
  • Fig. 3 is a partial front View of the same machine, showing various details thereof in the opposite plane to Figs. 1 and 2.
  • Fig. A is a detail of Fig. 1, showing the main bearing of the top spindle of the machine partially in section.
  • Fig. 5 is a view in flat vertical projection of various parts of the machine, including the feeding or impelling chains to move cylindrical cans.
  • Fig. 6 is a similar view of the impelling devices for cans of angular section.
  • Fig. 7 is a front elevation of the main frame of my improved cansoldering machine in flat projection, with the 3 impelling-chains in place.
  • soldering packing-cans by machine processes the custom is to roll the cans on a fixed bed or way, so the corners to be soldered will pass through or be immersed in a bath of melted solder, the bath being not only long enough to permit one rolling revolution of the can, buttwo or more revolutions, so as to insure perfect soldering of the joints.
  • the cans to be soldered are given a rotary movement and also a progressive or forward movement by means I of two chains, one on the top and the other on the bottom of the cans.
  • the chains move in opposite directions at different rates of speed, so that the cans in addition to revolving are moved slowly along in the direction of the fastest moving chain.
  • the cans may be exposed to the melted solder for one or several revolutions, the length of the solder-bath being no longer than required for the largest rectangular cans, and with other elements of the machine can be made much shorter than hitherto required.
  • a A A are pedestals forming a main supportingframe.
  • B B are the impelling-chains to move or roll the cans when of cylindrical form, and C C sprocket-wheels by which the chains 13"13 are supported and driven.
  • the outer of the chains 13 and the top chain B are so arranged as to be adjusted laterally outward by means of the loose collars F, which can be transposed from one side to the other of the outer wheels 0 and the upper fwheels O to intermediate points or to the extreme positions for the longest cans.
  • a guide-bar X is provided for the bottom :part of the chain B to keep it in a straight Iline, and this bar X is also adjusted laterally ;with the wheels 0 and chain B by means of the sliding brackets m m, held by the screws 47., as seen in Figs. 1 and 3.
  • the varying diameter of the cans D D is accommodated by raising the top wheels 0 .andthe chain B by means of the sliding sadfdles H I1 mounted on the standards U, and
  • Driving power for the chain B is applied on the pulley K on the shaft L, and from there transmitted by a driving-chain M from the wheel N on shaft L to the wheel N on the shaft L (seen on the right in Fig. 3,) so the rate of revolution between the wheels N N and the relative speed of the top and bottom chains 3 B is as the diameter of the wheels N and N
  • a set of wheels of different diameters is provided, and relative speed of the chains B and B can be varied as the size or diameter of the cans D may demand.
  • Q is an acid-trough through which the rims orjoints to be soldered first pass, so as to clean the surfaces and remove oil or grease.
  • R is a solder-bath heated to the melting-point by a furnace or any suitable means, preferably by gas or gasolene burners, the bath being kept full orto one level, so the joints of the can D will be immersed uniformly, as seen at S, Fig. 1.
  • the solder-bath R and acid-bath Q are made onlylong enoughto accommodate the largest cans of rectangular section, as will be explained in a future place.
  • the cans D are fed to the machine by a gravity-chute T, as shown in Fig. 3, and are discharged inany convenient manner after soldering.
  • the wheel N on the shaft L is then selected from a series of different diameters andin such relation to the wheel N 2 that the chains B B will move at different velocities in opposite directions, as indicated in Fig. 7, and as the relative sizes of the wheels N N may determine.
  • the cans D being fed in from the chute T, are embraced between the chains B B and set in revolution by friction of the two chains, but as the top one B is moving ata more rapid rate than the one B the cans are rolled slowly forward and at the same time turned about on their own axes, so the corner or seam to be soldered will revolve in the solder-bath R cans of large diameter can be soldered in a short bath and the scams or joints exposed to the melted solder as long or for as many revolutions as is required to secure perfect work, thus saving dimensions, details, and heat, and shortening the machine as a whole and rendering the operations more compact; also permitting immersion of the joint or seam in the solder-bath as long as may be necessary or desirable.
  • a guide-bar V adjustable by means of the screws W and extending the length of the solder-bath to keep the cans D in alinement and adjusted while passing through the melted solder.
  • the top chain B is provided with jaws b, that are loosely pivoted on the rivets or crosspins in the chain, so arranged that when hanging free on the lower or operating side of the chain they will take the position and engage the cans D as shown at c, Fig. 6.
  • pawls cl In the rack 13 is mounted a series of hinged pawls (1 61 These pawls are pivoted near the middle, but so proportioned in section that when free they swing into the position shown at d, and when covered by the cans D will lie fiat or parallel to the rack-bar B, as shown at 02
  • pawls cl (1 can be adjusted to various distances between them bymeans of a series of holes in the rack B as shown in the drawings, and as the length of the sides orthe size of the cans D may require.
  • the operation is as follows: The cans D? are fed into-the machine by hand, so that each of the jaws b will engage a can. The can then slides along on the rack-bar B until it comes in contact with one of the pawls d, and is rolled over, as shown at a, Fig. 6, and dips into the acid-bath Q and the solder-bath R.
  • the dotted line 6 in Fig. 6 indicates the upper position of the chain B as the cans D are rolled or turned. It will thus be seen how the space between the jaws 6 result in giving pauses in the time of movement of the cans.
  • a solder-bath in which the end seams of the cans are immersed, and in combination therewith two impelling-chains, one on the top and one on the bottom side of the can, moving in opposite directions, to roll and at the same time retard the forward movement of the cans, substantially as described.
  • a solder-bath in which the seams or joints to be soldered are immersed; impelling-chains on the top and bottom sides of the cans, moving at a different speed in an opposite direction, the lower or bed chains in two sections, one capable of adjustment laterally, so cylindrical cans of various lengths can be supported and rolled when the seams are being soldered, in the manner substantially as described.
  • impellingchains for the top and bottom of the cans moving in opposite directions and at different rates of speed to revolve and at the same time retard the forward movement of the cans, the top chain with its supporting-wheels and connected parts adjustable vertically or normally to the lower or bed chains, so cans of various diameters can be accommodated between the chains and rolled in contact with the melted solder throughout distances shorter than their perimeter, in the manner substantially as and for the purposes specifled.

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  • Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Textile Engineering (AREA)
  • Computer Hardware Design (AREA)
  • Microelectronics & Electronic Packaging (AREA)
  • Power Engineering (AREA)
  • Electric Connection Of Electric Components To Printed Circuits (AREA)

Description

(No Model.) a sheetssheet 1.
r J. B. OLOT. (JAN SOLDERING MACHINE.
Patented Apr.-28, 1896.
AN'DREW BERNMM. PHUTG'UTHQWASHINGTON, RC
3 SheetsSheet 2.
J. B. GLOT. CAN SOLDERING MAOHINB.
(No Model.)
Patented Apr. 28, 1896.
Witnesses.-
ANDREW B.GRAMAM. FNOTO-LITHQWASHINGTON. [7.0v
(N6 Mbdel.) 3 Sheets-Sheet a.
J. B. OLOT.
CAN SOLDERING MACHINE;
PatentedApr; 28, 1896[ o e e a g e e e a c Witnesses M. PHOTD-UMD.WASHINGI'ON. D C
UNITED ST TES 'ATENT OFFICE.
JOHN B. OLOT, OF. FRANCISCO, CALIFORNIA.
CAN-SOLDERING MACHINE.
SPECIFICATION forming part of Letters Patent No. 559,073, dated April 28, 1896.
Application filed May 1'7, 18M. Elerial No. 511,510. (No model) To all whom it may concern.-
Beit known that 1, JOHN B. CLoT, a citizen of the United States, residing in the city and county of San Francisco, State of California, have invented certain new and useful Improvements in Machines for Soldering the Ends of Metal Packing-Cans, of which the following is a specification.
My invention relates to the manufacture of metallic cans by machine processes, and to the soldering of the ends of such cans, both of round and angular section and of various dimensions.
My improvements consist especially in a method of controlling the movement of the cans while being soldered within a convenient limit of traversing movementand space, so as to more effectually expose them to the melted solder, and in various devices to accomplish a more effectual and rapid performance of the processes, as will be set forth in connection with the drawings herewithand the claims at the end of this specification.
Figure 1 is an end elevation, partially in section, of one of my improved can-soldering machines arranged for cylindrical cans. Fig. 2 is another partial end View in another plane of the same machine, showing the acid or cleaning bath. Fig. 3 is a partial front View of the same machine, showing various details thereof in the opposite plane to Figs. 1 and 2. Fig. A is a detail of Fig. 1, showing the main bearing of the top spindle of the machine partially in section. Fig. 5 is a view in flat vertical projection of various parts of the machine, including the feeding or impelling chains to move cylindrical cans. Fig. 6 is a similar view of the impelling devices for cans of angular section. Fig. 7 is a front elevation of the main frame of my improved cansoldering machine in flat projection, with the 3 impelling-chains in place.
Similar letters of reference are employed to denote like parts throughout.
In the operation of soldering packing-cans by machine processes the custom is to roll the cans on a fixed bed or way, so the corners to be soldered will pass through or be immersed in a bath of melted solder, the bath being not only long enough to permit one rolling revolution of the can, buttwo or more revolutions, so as to insure perfect soldering of the joints.
In the present invention the cans to be soldered are given a rotary movement and also a progressive or forward movement by means I of two chains, one on the top and the other on the bottom of the cans. When the latter are laid in a substantially horizontal position, the chains move in opposite directions at different rates of speed, so that the cans in addition to revolving are moved slowly along in the direction of the fastest moving chain. In this manner the cans may be exposed to the melted solder for one or several revolutions, the length of the solder-bath being no longer than required for the largest rectangular cans, and with other elements of the machine can be made much shorter than hitherto required.
Referring to the drawings, A A A are pedestals forming a main supportingframe. B B are the impelling-chains to move or roll the cans when of cylindrical form, and C C sprocket-wheels by which the chains 13"13 are supported and driven.
When the cans D are of small diameter, only the top chain B is driven, the cans rolling on the lower chains B or on a fixed bed and making several revolutions while travjersing the length of the solder-bath; but for larger cans the chains 13 B are moved differ ?entially, as will now be explained.
n The outer of the chains 13 and the top chain B are so arranged as to be adjusted laterally outward by means of the loose collars F, which can be transposed from one side to the other of the outer wheels 0 and the upper fwheels O to intermediate points or to the extreme positions for the longest cans.
A guide-bar X is provided for the bottom :part of the chain B to keep it in a straight Iline, and this bar X is also adjusted laterally ;with the wheels 0 and chain B by means of the sliding brackets m m, held by the screws 47., as seen in Figs. 1 and 3.
The varying diameter of the cans D D is accommodated by raising the top wheels 0 .andthe chain B by means of the sliding sadfdles H I1 mounted on the standards U, and
raised and lowered by means of the screws I and hand-wheels J.
Driving power for the chain B is applied on the pulley K on the shaft L, and from there transmitted by a driving-chain M from the wheel N on shaft L to the wheel N on the shaft L (seen on the right in Fig. 3,) so the rate of revolution between the wheels N N and the relative speed of the top and bottom chains 3 B is as the diameter of the wheels N and N A set of wheels of different diameters is provided, and relative speed of the chains B and B can be varied as the size or diameter of the cans D may demand.
As the wheel N is raised and loweredwith the saddle II, provision must be made to maintain a constant tension of this drivingband and also to accommodate the chain M, this latter being done by means of an idle intermediate pulley 0, running on a stud and arranged to bemoved up and down and be clamped at any point on the bracket U as shown in Figs. 1 and 3.
Q is an acid-trough through which the rims orjoints to be soldered first pass, so as to clean the surfaces and remove oil or grease. R is a solder-bath heated to the melting-point by a furnace or any suitable means, preferably by gas or gasolene burners, the bath being kept full orto one level, so the joints of the can D will be immersed uniformly, as seen at S, Fig. 1. The solder-bath R and acid-bath Q are made onlylong enoughto accommodate the largest cans of rectangular section, as will be explained in a future place.
The cans D are fed to the machine by a gravity-chute T, as shown in Fig. 3, and are discharged inany convenient manner after soldering.
Referring next to the manner of soldering cylindrical cans, the bottom chains B are=separated laterally to suit the length of the cans by means of the shifting-collars F, and the top chain B is set by means of the handwheels J, so as to rest upon the top of the cans D. The wheel N on the shaft L is then selected from a series of different diameters andin such relation to the wheel N 2 that the chains B B will move at different velocities in opposite directions, as indicated in Fig. 7, and as the relative sizes of the wheels N N may determine.
The cans D, being fed in from the chute T, are embraced between the chains B B and set in revolution by friction of the two chains, but as the top one B is moving ata more rapid rate than the one B the cans are rolled slowly forward and at the same time turned about on their own axes, so the corner or seam to be soldered will revolve in the solder-bath R cans of large diameter can be soldered in a short bath and the scams or joints exposed to the melted solder as long or for as many revolutions as is required to secure perfect work, thus saving dimensions, details, and heat, and shortening the machine as a whole and rendering the operations more compact; also permitting immersion of the joint or seam in the solder-bath as long as may be necessary or desirable.
Behind or at the inner ends of the cans D is placed a guide-bar V, adjustable by means of the screws W and extending the length of the solder-bath to keep the cans D in alinement and adjusted while passing through the melted solder.
The platen or support Y is depressed at Z, Fig. 7, so the cans D and the inner one of the chains B will sink slightly at this point and permit the corner or seam of the cans to dip into the solder-bath R, as shown at S, Fig. 1. This completes the operation of soldering the ends in cylindrical cans.
For cans of square or rectangular section the chains B are removed and a fixed rack B substituted, as shown in Fig. 6, which will next be referred to, the parts being shown enlarged, so as to admit of plainer explanation.
The top chain B is provided with jaws b, that are loosely pivoted on the rivets or crosspins in the chain, so arranged that when hanging free on the lower or operating side of the chain they will take the position and engage the cans D as shown at c, Fig. 6.
In the rack 13 is mounted a series of hinged pawls (1 61 These pawls are pivoted near the middle, but so proportioned in section that when free they swing into the position shown at d, and when covered by the cans D will lie fiat or parallel to the rack-bar B, as shown at 02 These pawls cl (1 can be adjusted to various distances between them bymeans of a series of holes in the rack B as shown in the drawings, and as the length of the sides orthe size of the cans D may require.
The operation is as follows: The cans D? are fed into-the machine by hand, so that each of the jaws b will engage a can. The can then slides along on the rack-bar B until it comes in contact with one of the pawls d, and is rolled over, as shown at a, Fig. 6, and dips into the acid-bath Q and the solder-bath R.
. Each time the can D is thus turned the jaw 17 is released, and the can pauses for a time in the solder-bath until the next succeeding jaw b-engages the next can. In this manner the period in which thecan is still and exposedto the solder is dependent upon the spaces between the jaws b on the chain B In this manner there is a pause, exposing the seam to be soldered for a brief period to the melted solder in the bath R until the next succeeding j aw 1) moves along, and the can is again turned one-fourth of a revolution and another seam or joint is immersed in the melted solder.
The pawls d d -are adjustable by'means of series of holes in the rack B, as shown in Fig. 6, and can be so spaced that cans of any dimensions can be thus soldered.
The dotted line 6 in Fig. 6 indicates the upper position of the chain B as the cans D are rolled or turned. It will thus be seen how the space between the jaws 6 result in giving pauses in the time of movement of the cans.
Having thus described the nature and objects of my invention, what I claim as new, and desire to secure by Letters Patent, is-
1. Ina can-soldering machine, a solder-bath in which the end seams of the cans are immersed, and in combination therewith two impelling-chains, one on the top and one on the bottom side of the can, moving in opposite directions, to roll and at the same time retard the forward movement of the cans, substantially as described.
2. In a can-soldering machine, a solder-bath in which the seams or joints to be soldered are immersed; impelling-chains on the top and bottom sides of the cans, moving at a different speed in an opposite direction, the lower or bed chains in two sections, one capable of adjustment laterally, so cylindrical cans of various lengths can be supported and rolled when the seams are being soldered, in the manner substantially as described.
3. In a can-soldering machine, the combination of the feeding-chains for the cans, two bottom or supporting chains for cylindrical cans, the sprocket-wheels supporting these chains, and a series of transferable collars 011 the shafts or studs of these wheels whereby the Wheels and chains may be adjusted laterally to suit cans of various lengths, substantially as described.
4. In a can-soldering machine, impellingchains for the top and bottom of the cans, moving in opposite directions and at different rates of speed to revolve and at the same time retard the forward movement of the cans, the top chain with its supporting-wheels and connected parts adjustable vertically or normally to the lower or bed chains, so cans of various diameters can be accommodated between the chains and rolled in contact with the melted solder throughout distances shorter than their perimeter, in the manner substantially as and for the purposes specifled.
5. In a can-soldering machine, the combination of solder-baths, impelling-chains to roll cylindrical cans and immerse their seams or end joints in the solderbaths, in the manner described, gearing adapted to vary the relative speed of the top and bottom impelling-chains, thus retarding the forward movement of the cans, and allowing of the reduction in length of the solder-baths, substantially as described.
In testimony whereof I have hereunto affixed my signature in the presence of two witnesses.
JOHN B. CLOT.
Witnesses:
ALFRED A. ENQUIST, WI soN D. BENT, J r.
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