US2797075A

US2797075A - Hump type furnace belt drive

Info

Publication number: US2797075A
Application number: US464042A
Authority: US
Inventors: Wilbur Sinclair Francis
Original assignee: SARGEANT AND WILBUR Inc
Current assignee: SARGEANT AND WILBUR Inc
Priority date: 1954-10-22
Filing date: 1954-10-22
Publication date: 1957-06-25
Anticipated expiration: 1974-06-25

Description

June 5 s. F. WILBUR HUMP TYPE FURNACE BELT DRIVE 2 Sheets-Sheet 1 Filed Oct. 22, 1954 INVENTOR. SINCLAIR FRANCIS WILBUR ATTORN E June 25', 1957 s. F. WILBUR 2,797,075

HUMP TYPE FURNACE BELT DRIVE Filed Oct. 22, 1954 2 Sheets-Sheet 2 CD m IN V EN TOR.

ATTORN EY SINCLAIR FRANCIS WILBUR' United rates Patent 9 HUMP TYPE FURNACE BELT DRIVE Sinclair Francis Wilbur, Seekonk, Mass., assignor to Sargeant and Wilbur, Inc., Pawtucket, R. 5., a corporation of Rhode Island Application October 22, 1954, Serial No. 464,042

8 Claims. (Cl. 263-8) This invention relates to the belt drive of a hump type furnace and more particularly to the controls for keeping the belt taut,

An object of the present invention is to provide a new type of mechanism for driving the continuous conveyor belt of a furnace.

Another object of the present invention is to provide improved means for keeping the continuous conveyor belt taut.

Other objects of the present invention will be pointed out in part and become apparent in part in the following specification and claims.

A hump type furnace is a furnace designed to aid in the control of lighter than .air atmospheres which envelop the work during the process of heat treatment.

A feature of this type furnace is the location of the purging, heating and cooling chambers at a level above. the door openings of the entrance and exit ends of the conveyor belt. Thus providing the minimizing of the infiltration-of oxidizing air and moisture into the purging, heating and cooling chambers, even in the presence of room drafts.

Endless conveyor belts are used to carry the work from the entrance to the purging chamber up the incline to and through the heating chamber and down to the exit of the cooling chamber. The conveyor belts aremade of heat resisting alloy material. The high temperature of the heating chamber reduces the strength of the belt. The maximum stress upon the belt occurs at the exit end of the heating chamber; which is the point furthest from the conventional belt traction point located at the loading point or furnace entrance.

The maximum stress includes the force required to move the work loaded belt up the incline through the purging and heating chambers. The stress from the heat, friction and gravitational pull through heat and purging chambers could be so great that no work could be placed on the conveyor belt with-out exceeding the tensile strength of the belt.

If the force required to move the work loaded belt up the incline and through the purging chamber did not have to be added to the force required to move the belt through the heating chamber, then the weight of the work carried by the belt through the heating chamber would be high. Applicant provides such an arrangement in a pintype drive roller which positively engages the wire mesh of the conventional conveyor belt. The drive roller being located at the junction of the purging and heating chambers, and at the top of the incline.

This arrangement entails other considerations. If the slack in the conveyor belt, due to heating and loading is not adequately compensated for belt failure will occur. Applicant provides for this contingency by automatically controlling the tautness of the continuous conveyor belt.

Referring to the drawing wherein like reference numerals refer to like parts:

- Figure l is a diagrammatic side elevational view partly in section of the new and improved hum type furnace belt drive.

Figure 2 is a side elevational view, partly in section of the new pin type drive roller.

Figure 3 is an end view of Figure 2.

Figure 4 is a fragmentary plan view of the wire mesh conveyor belt.

Referring to Figure 1 wherein an endless conveyor belt 11 of conventional wire mesh construction is shown passing over drive drum 12, sensing roller 13, into and through purging chamber 14, over pin drive roller 15, into and through heating chamber 16, through cooling chamber 19, over takeup drum 17 and back to drive drum 12 which is provided with a pinch pulley 18.

An electric magnetic clutch 22' is provided which has the inherent characteristic of slippage between the face plates of the clutch. The degree of slippage depending upon the voltage input of the clutch. Sensing roller 13 adjusts the resistance of a potentiometer 21. This potentiometer 21 electrically connected to magnetic clutch 22, controls the voltage input to magnetic clutch 22. Sensing roller 13 in contact with belt 11 and actuated by the change in tautness of belt 11, transmits this actuation or motion to potentiometer 21, thereby changing the electrical resistance of potentiometer 21, hence the voltage input to magnetic clutch 22.

Drive drum 12 is driven by means of an electric motor 23 driving a speed reducer 24 which is connected to drive drum 12 by means of a 'belt 25. Motor 23 also drives electric magnetic clutch 22 through the medium of a speed reducer 26. A chain 27 connects electric magnetic clutch 22 with pin drive roller 15.

Take up drum 17 is under the control of an air cylinder 30. A second sensing roller 31 contacting belt 11 on the side of pin driver roller 15 opposite to the position of sensing roller 13, actuates an electric switch 32 electrically connected through wires 33 to solenoid valve 34 which controls regulating valve 36 leading to air cylinder 30. Thus, in the event that conveyor belt 11 builds up ahead of pin drive roller 15, in the direction of belt travel, interferring with the working height of belt 11 in purging chamber 14, sensing roller 31 will cause take up drum 17 to take the slack out of conveyor belt 11 by energizing the circuit leading to solenoid valve 34 which will actuate valve 36, initiating movement of air cylinder 30 and take up drum v17 into the dot and dash position shown in Figure 1. A source of .air supply of 100 p. s. i. is provided to conduit 40 which leads to regulating valve 35 and to solenoid valve 34. Air cylinder 34 is under control of regulating valve 35 which maintains a pressure of 40 p. s. i. on the piston in air cylinder 30. Thus providing a predetermined position for take up drum .17, thereby applying a predetermined stress on belt 11.

When belt 11 carries a work load and expands and contracts as it passes into and out of the heating chamber 16, sensing roller 31 in contact with belt 11, is actuated by the tautness of belt 11. The motion imparted to sensing roller 31 .by the change in tautness engages and disengages electric switch 32 which controls solenoid valve 34 through electric wires 33. Solenoid valve 34 controls the flow of air supply to regulating valve36 which permits air to flow to air cylinder 30, actuating the piston therein and moving take up drum forward toward the dot and dash position shown in Figure 1. When sole- I noid valve 34 shuts off the air supply to regulating valve 36, the piston in air cylinder 30 is under the influence of regulating valve 35. Conveyor belt 11 will have a tendency at times to move take up drum 17 from the dot and dash position to the full position shown in Figure 1. Since regulating valve 36 is rendered inoperative by solenoid valve '34, it behooves regulating valve 35 to prevent an excessive amount of pressure from building up in air cylinder 30. To that end a bleeder vent is provided in regulating valve 35, which allows the air pressure in air cylinder 30 to reduce itself to the predetermined pressure of regulating valve 35. g

It will be noted that regulating valve 35 maintains a constant predetermined low pressure on air cylinder 30 while regulating valve 36 adds air pressure to air cylinder 30 when work loads on the conveyor belt 11 demand tautness on belt 11 through take up drum 17.

In operation, work to be heat treated will be placed upon continuous conveyor belt 11 at entrance point 40. The weight of the work will tend to produce slack in belt 11 thereby reducing the effectiveness of the drive of the belt 11 at drive drum 12 and in some instances permit the slack in belt 11 to build up to a point of piling. Thereby hindering the passage of the work and the belt through purging chamber 14. Sensing roller 13 prevents this undesirable condition when it actuates potentiometer 21 controlling the voltage, hence the torque of electric clutch 22. Motor 2 3.through speed reducer 26 drives one face plate of electric clutch 22. The other face plate drives pin drive drum 15. The amount of slippage between the face plates is regulated by the voltage, controlled by potentiometer 21. Sensing roller 13 when slack in belt 11 dictates, causes .pin drive drum 15 to increase in speed and torque, thereby taking the slack out of belt 11.

Thus it will be observed, that applicant provides two points of drive for continuous conveyor belt 11 instead of the usual one. It will be further noted that the two drives 12 and 15 for belt 11 are ancillary one to the other with drive 15 becoming effective when needed most, namely, when the belt carries a heavy work load.

Another advantage of this ancillary drive 15 is to allow drive 15 to loaf, thereby minimizing wear on the drive 15 and belt 11 when drive drum 12 can alone effectively move belt 11.

Sensing roller 31 functioning as previously described maintains a predetermined tautness in belt 11 in the area of the heating chamber 16.

Referring to Figures 2, 3, and 4 wherein is shown the detail construction of the new pin drive drum 15, consisting of a disk 46, having a multiple number of pin receiving cavities 47. Pins 48 are slidably mounted in pin receiving cavities 47 and are retained therein by means of dowels 50 which engage grooves 51 in the sides of pins 48. Coils springs 52 or any other resilient medium are interposed between the base of pin receiving cavities 47 and the-base of pins 48, thereby urging pins 48,0utwardly from thebase of cavities 47. The construction just enumerated is substantially that of a spring detent except a novel construction of detentsis provided for effecting a new use; namely a belt drive. The pins 48 are spring actuated in order to permit pins 48 to be pushed into the body of disk 46 when a pin 48 strikes the body portion 54 of meshed wire conveyor belt 11 of linked construction instead of contacting a space 55 in the wire mesh of said belt 11. A bore 53 is provided in centerof disk 46 to permit mounting upon a rotating shaft.

This is a. preferred form of the invention. Modifications would include a Reeves drive, a variable .belt and pulley drive or fluid clutch members in place of the magnetic electric clutch and appropriate means between the sensing device and the alternatevariable speed means for regulating their output in accordance with tension or tautness in the belt.

Having shown and described a preferred embodiment of the present invention, by Way of example, but realizing that structural changes could be made and otherexamples. given without departing from either the spirit or scope of. this invention.

7 What I claim is:

1. In apparatus of the class described, the combination of a conveyor belt, a first drum for supporting the front end portion to the belt, a second drum for supporting the;

rear end portion of the belt, means for adjustably mounting said second drum for movement toward or from said first drum, a third drum for supporting the belt intermediate the first drum and second drum, an electric magnetic clutch operatively connected to said third drum, an electric motor operatively connected to drive said first drum and said electric magnetic clutch, a sensing roller in engagement with said belt, a potentiometer electrically connected to said electric magnetic clutch, said sensing roller being operatively connected to said potentiometer to transfer the movement of the tautness and slackness of the belt to said electric magnetic clutch to vary the speed of rotation of said third drum.

2. In apparatus of the class described, the combination of a conveyor belt, a first drive drum for supporting the front end portion of the belt, a second drum for supporting the rear end portion of the belt, means including an air cylinder for adjustably mounting said second drum for movement toward or away from said first drum, a third drum for supporting the belt intermediate the first drum and second drum, and electric magnetic clutch operatively connected to said third drum, and electric motor operatively connected to drive said first drum and said electric magnetic clutch, a first sensing roller engaging said belt and adapted to move therewith in accordance with changes in the tautness of the belt, a potentiometer electrically connected to said electric magnetic clutch, and adapted to be operated by the movement of said first sensing roller to change the torque of said electric magnetic clutch and thereby control the speed of rotation of said third drum, a first regulating valve provided with an. automatic predetermined pressure bleeder connected on one side to said air cylinder, a second regulating valve connected on one side to said air cylinder, a source of air supply to said first and said second regulating valves, a solenoid valve interposed between the source of air supply and said second regulating valve, an electric switch, electrically connected to said solenoid valve and a second sensing roller engaging said belt, adapted to move therewith in accordance with changes in the tautness of the belt, said movement of the sensing roller, engaging and disengaging said electric switch to open and close the source of air supply to said air cylinder through said solenoid valve and said second regulating valve.

3. In a furnace consisting of a work loading table, a heating chamber located above said work loading table, a. purging chamber connecting said work loading table with said heating chamber, a work unloading table, a cooling chamber connecting said heating chamber with said work unloading table, a continuous conveyor belt passing from said work loading table, to and through said purging chamb,er,,heating chamber, cooling chamber to said work unloading table and' back to said work loading table, a first drive drum supporting said conveyor belt at said work loading table, a belt take-up second drum supporting said conveyor belt at said work unloading table, means for adjustably mounting said belt take-up second drum for movement toward and away from said first drive drum, a pin type drive third drum supporting said conveyor belt at the junction of said purging and heating chambers, an electric magnetic clutch, an electric motor driving said first drive drum and said electric magnetic clutch operatively connected to said pin type drive third drum and means for sensing the tautness of said conveyor belt at said first. drive drum and relaying said conveyor belt tautness to said pin type drive third drum through said electric magnetic clutch to thereby automatically effect adjustment in the'tautness of said conveyor belt to maintain a predetermined normal operative tautness in said conveyor belt. 4. A claim as delineated. in claim 3 further characterized in that, a second means for sensing the tautness of said conveyor belt at the juncture of said purging chamher and said heating chamber, a source' of air supply, a first regulating valve connected to said air supply and to said. air. cylinder to maintain a constant predetermined pressure on said air cylinder, a second regulating valve connected to said air supply and to said air cylinder, a solenoid valve interposed between said air supply and said second regulating valve, an electric switch responsive to the second means for sensing the tautness of said conveyor belt, electrically connected to said solenoid valve to allow the source of air supply to pass to said second regulating valve to charge said air cylinder and thereby actuate said belt take-up second drum toward and away from said first drive drum.

5. In a furnace consisting of a work loading table, a heating chamber located above said work loading table, a purging chamber connecting said work loading table with said heating chamber, a work unloading table, a cooling chamber connecting said heating chamber with said work unloading chamber, a continuous conveyor belt passing from said work loading table to and through said purging chamber, to and through said heating chamber, to and through said cooling chamber and to said work unloading table, returning to said work loading table, a first drive drum, means for driving said first drive drum supporting said conveyor belt at said Work loading table, a belt take-up second drum supporting said conveyor belt at said work unloading table, means for adjustably mounting said belt take-up second drum for movement toward and away from said first drive drum, a third drum supporting said conveyor belt at the junction of said purging and heating chambers, means for sensing the tautness of said conveyor belt at the juncture of said purging and heating chambers, adjacent said third drum, a source of air supply, a first regulating valve connected to said air supply and to said air cylinder to maintain a constant predetermined pressure on said air cylinder to maintain an initial tautness on said conveyor belt and an air bleeder orifice in said first regulating valve to relieve air pressure in said air cylinder when the air pressure in the air cylinder exceeds a predetermined pressure, a second regulating valve connected to said air supply and to said air cylinder, a solenoid valve interposed between said air supply and said second regulating valve, an electric switch responsive to the means for sensing the tautness of said conveyor belt, electrically connected to said solenoid valve to allow the source of air supply to pass to said second regulating valve to build up a pressure in said air cylinder beyond the predetermined pressure of said first regulating valve when the tautness of the conveyor belt falls below a predetermined amount due to the heat exchange of the belt when passing through the purging, heating and cooling chambers and due to the work load, said pressure build up in said air cylinder moving said take-up second drum away from said first drum and thereby causing tautness in said conveyor belt.

6. A continuous conveyor belt of wire mesh construction comprising in combination a positive driving element consisting of disk having a multiple number of pin receiving orifices, a multiple number of pins, one for each orifice, slidably mounted therein and retained in sliding position by means of a dowel pin, each pin having a longitudinal groove engaging a dowel pin, a coil spring positioned in each orifice urging said pin outwardly from the base of the orifice, a bore located in the center of said disk to engage means for driving said disk and said continuous conveyor belt as each pin successively engages the wire mesh, said pins retracting into said pin receiving orifices as a pin engages the wire of the Wire mesh.

7. In a furnace consisting of a work loading table, a heating chamber located above said work loading table, a purging chamber lying in an inclined plane connecting said work loading table with said heating chamber, a work unloading table, a cooling chamber lying in an inclined plane connecting said heating chamber and said work unloading table, a continuous conveyor belt having an open mesh construction passing from said work loading table up the inclined plane to and through said purging chamber, to and through said heating chamber, to and through said cooling chamber down said inclined plane to said work unloading table and back to said work loading table, a first drive drum supporting said continuous conveyor belt at said work loading table, and means for driving said belt and said first drive drum, a tightening and belt loosening second drum supporting said continuous conveyor belt at said work unloading table, means for adjustably mounting said second drum for movement to tighten and loosen said continuous conveyor belt, a positive driving third drum supporting said continuous conveyor belt at the junction of said purging chamber and said heating chamber which carries the weight of said continuous conveyor belt at the point where the continuous conveyor belt is subjected to stress from the heat of the entrance of said heating chamber, said positive driving third drum consisting of a disk having a multiple number of pin receiving orifices, a multiple number of pins, one for each orifice and slidably mounted therein and retained in sliding position by means of dowel pins fixed in said disk at the side of each orifice, each pin having a longitudinal groove engaging a dowel pin, a coil spring positioned in each orifice urging the pin outwardly from the base of the orifice, a bore located in the center of said disk engage means for driving said disk and said continuous conveyor belt as each pin in the rotation of said disk engages the open mesh of said continuous conveyor belt, said pins retracting against the tension of said springs when said pins engage the body of said continuous conveyor belt, the means for driving said disk being ancillary to and driven by the means for driving said first drive drum.

8. In apparatus of the class described, the combination of a conveyor belt, a first drum for supporting the front end portion of the belt, a second drum for supporting the rear end portion of the belt, means for adjustably mounting said second drum for movement toward or from said first drum, a third drum for supporting the belt intermediate the first drum and second drum, means operatively connected to drive said first drum and means therefrom for driving said third drum, said last mentioned means having interposed therein a variable speed means and a sensing means in engagement with said belt between the first and third drums, responsive to the variation in tension therein for determining the regulating effect of said variable speed means, thereby to control the speed of said third drum relative to the speed of the first drum to maintain a prescribed tension in said belt.

References Cited in the file of this patent UNITED STATES PATENTS 694,211 Souhami Feb. 25, 1902 2,306,448 Kratz Dec. 29, 1942 2,623,630 Erickson Dec. 30, 1952 2,701,712 Gilbert Feb. 8, 1955