This invention relates to a pneumatically operated hoist and particularly to such a hoist with a braking mechanism for quickly stopping the movement of the cable of such hoist in the event of a sudden change in the load held by the hoist or the loss of the air used to operate the hoist. This hoist includes a braking mechanism that compensates for sudden acceleration of loads carried by the hoist or the sudden changes in such loads.

Pneumatic balancing hoists are well established as a standard in the materials handling industry. These pneumatic balancing hoists or air balancers, have been used to move work pieces about a factory or industrial site. A problem may occur, however, when the hook connected to the cable of the hoist suddenly has a change in the load. As a result of a change in load, for example, when the load is suddenly dropped, the force of the load pulling down on the cable and hook are suddenly no longer present to balance the air pressure contained in the air balancer. In short, a braking means for preventing the cable being pulled up abruptly or with a start has long been desired in the industry. The braking mechanism of the present invention avoids the problem not solved in the prior art that is posed by the longitudinal or axial movement of the drum used in such hoists by eliminating the axial movement from the braking surfaces such that only radial forces are involved in the braking mechanism.

A number of different variations in the design of such pneumatically operated hoists exist; such as can be seen U.S. Patent Nos. 2,710,107, and related designs in U.S. Patents 3,324,148 and 3,384,350, which feature a housing with an air chamber for causing rotation of a cable drum as a nut about a stationary ball screw, with a cable rotating on the cable drum and connected to a load. Air is supplied to the chamber by way of an inlet from a source of pressurized air with various means for controlling the supply of air as shown in

SUBSTlTUTt SHEET (RULE 26)

U.S. Patent 3,325,148. Each of these earlier patents is incorporated for all purposes into this application. Another design of pneumatically operated hoists can be seen in U.S. Patent 3,286,989 and 3,421,737, which are incorporated herein and employ an air chamber for causing rotation of a cable inside a cylindrical bore of the housing through the use of rollers inside the drum. Again, the cable drum rotates and moves longitudinally as the cable unwinds or winds with the movement of a load.

Prior art approaches to a braking mechanism for a balancing hoist have not resolved this problem. One approach has been to control the movement of the cable by controlling the air pressure counter-balancing the load. Also, to prevent the rapid movement of the cable and load in the event of a loss of pressure in the air pressure chamber, various control mechanisms have been designed to address the sudden loss of air pressure. The designs that address the control of the air pressure, however, have the drawback of being too slow in response as it takes too long to adjust the air pressure to avoid the fast movement of the cable and hook when a load has been dropped. Another approach has been to employ a braking device on the outside of the cable drum through the use of centrifugal force once the speed of the rotation of the cable drum reaches a certain speed. This design can be seen in U.S. Patent 2,710,107 and 3,286,989. Each of these patents discloses some braking means on the outside of the cable drum that is rotating and moving longitudinally. The problem with each of these designs is that the braking mechanism are unreliable because they must necessarily brake while moving longitudinally. As a result of this longitudinal movement, it has been found that the braking mechanism is inherently unreliable. One braking mechanism in the prior art did attempt to avoid the longitudinal movement. In U.S. Patent 3,276,747, a safety device for rotatable members is disclosed that employs a plurality of pivotable dogs mounted for rotation with the cable drum. This approach, however, has been

unworkable primarily because of the locking of the braking mechanism, but also because of the difficulty of installing such a design in a pneumatically operated hoist employing a housing and rotating cable drum such as disclosed and claimed herein.

One object of the invention is to provide a means for braking the rotation of the cable drum in the event that the speed of the drum exceeds a predetermined, safe maximum speed. Another object of the invention is to provide a means for braking the rotation of the cable drum to prevent the drum from accelerating at an excessive rate.

Another object of this invention is to provide a material handling safety device having the advantages outlined herein.

Another object is to provide a material handling system such as an overhead rail system incorporating this braking mechanism for a balancing hoist.

Thus, the principle object of this invention is to provide a new and improved design for a braking mechanism in balancing hoists which substantially eliminates or minimizes the disadvantages of the prior braking mechanisms of earlier balancing hoists. Another object of this invention is to provide such a braking mechanism that is simple, involves few additional parts, and can be easily manufactured as well as easily adapted to existing balancing hoists that do not incorporate the invention.

This new braking mechanism resolves the problems of the longitudinal movement of the cable drum by locating a braking means on a separate rotational means that is connected to the cable drum such that only the rotational forces of the cable drum are translated to such rotational means. This is done by connecting the cable drum and rotational means by way of one or more rods or other driving means that are inserted into one or more openings in the cable drum and a plate mounted on the cable drum. As the cable drum rotates on a fixed stationary screw, for example, the drum moves longitudinally down the rod or rods

while rotating means. The rotating means is also equipped with a braking mechanism that is actuated once the actual speed of the rotational means or the centrifugal force associated with such rotation reach certain values. The braking mechanism, such as brake shoe, can then be applied against a braking surface on the interior of the housing. One principle advantage of such a design is that the braking surface on the interior of the housing is at a predetermined location on the inside of the housing, rather than at a number of different possible locations over the length of the longitudinal movement of the cable drum, which is necessarily the case when the braking mechanism must be functional at all longitudinal locations of the cable drum. The economy and ease of manufacture because of this feature of the invention is another object of this invention.

Various braking designs that depend on the centrifugal or inertial forces associated with the rotation of the rotating means can be easily substituted for the preferred embodiments disclosed herein. Similarly, this design can be employed with different types of balancing hoists besides the one disclosed in the preferred embodiment disclosed herein. For example, in the balancing hoists that employ a cable drum moving longitudinally within a cylindrical bore inside the housing, this design of braking mechanism can easily be adapted and employed as is readily apparent.

Numerous other objects and advantages of the invention will be apparent from the following detailed description of a preferred embodiment thereof, reference being made to the accompanying drawings.

FIG. 1 is an overall perspective of a balancing hoist according to the invention shown supporting a load;

FIG. 2 is a sectional view of the preferred embodiment of the balancing hoist;

FIG. 3 is the same sectional view of the hoist, the view disclosing the operative elements thereof in positions different from those shown in FIG. 2.

FIG. 4 is a side view of the preferred embodiment from the end of the housing wherein the rotating means and the braking mechanism are located;

FIG. 5 is the same side view shown in FIG. 4, disclosing the operative elements of thereof in positions different from those shown in FIG. 4.

FIG. 6 is a side view of a second preferred embodiment from the end of the housing wherein the rotating means and the braking mechanism are located.

Referring to the drawings, and more particularly, to FIG. 1, a pneumatically operated hoist 1 embodying the invention is supported from an overhead rail 32 by hoist trolley 2. Extending from the hoist downward is a lifting cable 3 that passes through a cable guide 33 and can be fitted with various types of hooking mechanisms for attaching a load for movement. The movement of loads with such a pneumatically-operated hoist is well known in the art. It should be noted that the balancing hoist could also be supported by a stationary mounting as well.

Referring to FIGS. 2 and 3, the hoist includes a housing 40 having end walls 4 and 5. A ball screw 6 extends longitudinally throughout the housing and is connected at each of the housing at each end centrally to the end walls 4 and 5. A ball screw assembly 7 is mounted on the ball screw 6 and moves longitudinally in the housing 8 when turned relative to the ball screw. Ball screw assemblies of this nature are known in the art and will not be discussed in detail. A cable drum is mounted on the ball screw assemble and moves on the ball screw both rotatably and longitudinally relative to the ball screw 6. The cable drum 8 has a shallow helical groove 9 that receives the cable 10 when the load is raised and the cable is wound on the drum. One end of the cable is suitably affixed to the drum at one end

of the helical groove. As the cable drum moves rotatably and longitudinally, the cable is wound or unwound about the drum for raising and lowering loads. Whether the cable is wound or unwound will obviously depend on the direction of the movement of the load being up or down. The cable 3 passes through cable guide 33 to the various types of hooking mechanisms for attaching a load for movement. A thrust bearing is located adjacent to the drum 8 and bears against a hub portion 11 of the cable drum. The thrust bearing 12 is mounted on an extension 13 of the drum is arranged to bear against a piston 14. The piston 14 has a peripheral seal 15 which engages and slides on the inner surface of the housing 8 such as to tightly seal the gas in the chamber. In this fashion, the second end wall 4, the right hand portion of the housing 8, and the piston 14 form a chamber to receive gas for operating the hoist. The piston 14 has an inner diameter lip seal 17 that is in slidable but sealing contact with the sleeve 18 over the right end of the ball screw 6.

When gas is supplied to the chamber, air usually being used, and is under sufficient pressure, the piston 14 is moved toward the left and, through the thrust bearing 12, forces the cable drum 9 and the ball screw assembly 7 in the same longitudinal direction. During this movement, the ball screw assembly is caused to rotate the drum in a manner to raise and lower the cable and the load. The air supplied to the chamber can be controlled in various ways that are well known in the art and various means will not be discussed in detail.

Referring now to FIGS 2 and 3, to effect the rotational movement of a rotating means displaced away and apart from the cable drum, two drive rods 20 are slidably connected to the cable drum by two openings 21 that are located longitudinally. One or more drive rods and longitudinal openings can be employed. In the preferred embodiment disclosed herein, two such openings that are of sufficient length and diameter to ensure a

stable and reliable rotation of the drive rods as the cable drum rotates with the movement of the cable and, in turn, a load. Referring now to FIGS. 4 and 5, these drive rods 20 are in turn fixably mounted to the rotating means or flywheel 22. The flywheel 22 is bored for the installation of bearings 23 on a hub 24, which allow for a smooth and controlled rotation of the flywheel. At least one brake shoe is mounted onto the flywheel 22 by use of pin 25, about which the brake shoe can pivot. In FIGS. 4 and 5, one brake shoe 26 is restrained radially by a biasing means such as spring 27, which spring is connected to the brake shoe 26. (The shape of the brake shoe 26 and the location of the spring 27 can be readily varied so long as the brake shoe properly contacts the braking surface 28.) The spring is similariy attached to the flywheel 22 by spring anchor 29, spring tension adjusting screw 31, which is rotatably fixed to spring anchor 29 and mounted to the flywheel 22. The tension of the spring 27 can also be adjusted by changing the hole to hole distance for the two ends of the spring 27. The surface of the brake shoe 30 are located adjacent to the interior wall of the end cover that is mounted onto the housing 8. The end cover has been suitably bored and machined at the location of the flywheel to form a braking surface 28 around the entire inner surface of the end cover 5. By locating the braking surface in the end cover 5 rather than in the housing 10, it is readily apparent that one can undertake a method to retrofit and modify existing balancing hoists to incorporate the claimed invention.

Referring now to FIG. 6, another preferred embodiment would employ two brake shoes 26 restrained radically by biasing means such as springs 27, the tension of which can be adjusted as previously disclosed herein. The most advantageous approach for this second preferred embodiment would be to install or connect the second brake shoe to the flywheel directly opposite the first brake shoe, such that the second brake shoe would contact the

braking surface 28 directly across from the braking surface contacted by the first brake shoe. The use of two brake shoes could be employed for an especially large balancing hoist.

When the cable drum rotates at an acceptable speed or acceleration, the brake shoe 26 is restrained in a radially inward position by the spring 27. This allows the cable drum to freely turn during routine operation of the hoist. When the rotation of the cable drum 8 exceeds a predetermined speed or rate of acceleration, however, the centrifugal force of the brake shoe 26 will force the brake shoe radially outward against the spring 27, such that the brake shoe will engage the braking surface 28 as shown in FIG. 5. Upon engagement between the brake shoe and the braking surface, the brake shoe will become wedged against the braking surface as the brake shoe will pivot into a braking position, the brake shoe functioning as a self-energizing brake. At this point, the cable drum will stop rotating and the cable will similarly stop its uncontrolled movement. Similarly, when the mass of the brake shoe resisting acceleration of the cable drum 8 under excessive acceleration of the cable drum 8 above the desired maximum acceleration rate, the brake shoe will pivot about the pin 25 out of a generally radial plane of movement until the brake shoe 26 engages the braking surface 28 as shown in FIG. 5. Again, once the brake shoe engages the braking surface, the brake shoe will become wedged against the braking surface by the force of the acceleration and the braking mechanism will similarly bring the cable drum quickly to a halt. The speed at which the brake shoe will become engaged to halt the drum will depend on the strength of the spring 27. Similarly, the tension of the spring 27 will determine the minimum acceleration rate that will cause the brake shoes to engage the braking surface and stop the drum. Once the drum has stopped rotating, however, the braking mechanism will promptly and easily disengage, thereby allowing the routine operation of the hoist.

As noted above, another object of this invention was to develop a braking mechanism that could be easily adapted to existing pneumatically operated balancing hoists. Thus, it is possible to modify existing hoists to incorporate this safety device by removing the existing end cover, and replace the cable drum and end cover and incorporate one or more driving rods, flywheel and the braking mechanism described herein.

Additionally, this invention could be employed with other designs of pneumatically operated hoists that do not involve the use of a stationary ball screw 6 but rather the use of cable drum rotating and moving longitudinally within a longitudinal bore inside the housing. These designs are disclosed in U.S. Patent Nos. 3,2286,989 and 3,421,737 and can easily be adapted so as to incorporate the present invention. Specifically, this could be easily done by inserting one or more drive rods into a identical number of holes in the cable drum of such alternative designs and utilizing the drive rods to turn the flywheel mounted on a shaft, with the shaft located at the opposite end of the housing from the air chamber. Thus, the flywheel would rotate around the shaft. The braking mechanism would similarly function in this design and in the event of excessive speed or acceleration of the cable drum, one or more brake shoes will contact the braking surface on the inside of the housing, thereby abruptly halting the cable drum. The adaption of the invention to this alternative design is readily apparent to one skilled in the art.

Another preferred embodiment of this invention involves the use of this invention in various materials handling systems that incorporate well known materials handling elements of rail and trolleys. For example, as shown in FIG. 1, the balancing hoist can be moved through or about a facility by the movement of a trolley 2 on some means for supporting the balancing hoist such as an overhead rail 32. In FIG. 1, the overhead rail 31 is an I-beam rail, which is well known in the art. Similar means for movement of a trolley

are well known in the art of materials handling. These material handling systems allow the movement of work pieces and equipment around the work space for use in an industrial process. Generally, there are two types of rail systems: (1) single rail or monorail systems; and (2) dual rail systems. FIG. 1 shows the means of moving the balancing hoist through the use of a single trolley on one beam or support. Single rail systems, or monorail systems, would similarly function like the overhead support shown in FIG. 1. Single rail systems involve the use of one rail to move the various work pieces by rolling the wheels of the trolley and in turn the balancing hoist along the rail. A dual rail system allows for the use of a carriage or bridge, which can be connected to the balancing hoist. The carriage and bridge move on the rails by use of trolleys mounted on the carriage. It should be noted that facilities can also easily employ the use of precision rail overhead conveyance systems with rails having shapes other than the I-beam rail shown in FIG. 1. These various rail systems are well known in the art and commercially available from Zimmerman International Corp. located in Madison Heights, Michigan. Thus, material handling systems can incorporate the balancing hoists disclosed herein. A "facility" shall refer to any industrial, manufacturing, fabricating, warehousing, processing, or repairing facility in any field of application in which it is necessary to transport, manipulate, or move work pieces or finished products. In short, a facility is any location at which it is necessary to employ materials handling equipment to transport, manipulate, or move work pieces such as an automotive plant, a product warehouse, or equipment manufacturing plant.

Although several embodiments of the invention are illustrated and described in detail, it will be understood that the invention is not limited merely to the embodiments described herein, but contemplates other embodiments and variations that utilize the concepts and teachings of this invention.