Patent Grant
8440047
The present invention relates to belts and in particular to belts for conveying items or for transmitting power. More specifically, the present invention relates to belts formed of a first material encasing an elongated element designed to reduce the stretching of the belt.
Continuous belts are commonly used for conveying various elements. One common type of belt is a continuous belt that is extruded. Frequently, such belts are extruded from flexible materials, such as thermoplastic materials. One shortcoming of such belts is that the belts have a tendency to stretch during use. As the belt stretches, it tends to slip, thereby reducing the driving force of the conveyor. Further, the weight of the item to be conveyed is related to the tension in the belt. Specifically, as the weight increases, the tension in the belt needs to be increased to minimize slippage between the belt and the drive elements. The increased tension in the belt increases the tendency of the belt to stretch, which in turn increases the likelihood of the belt slipping.
Over the years a number of attempts have been made to overcome the problem of belt stretch. The primary solution has been to embed an item in the belt that has a relatively high tensile strength and resistance to stretching. For instance, polyester fibers are commonly formed in conveyor belts. The polyester fibers are less likely to stretch, and therefore the resulting belt has less likelihood of stretching than the belt without the fibers.
Although the fibers in the belt improve the stretch-resistance of the belt, the tendency of the belt to stretch has still remained a problem. Since the belt is typically formed from a length of material, the fibers are not continuous loops. In other words, along the length of the belt, the fibers are continuous. However, at the point where the ends of the belt are connected to one another, the fibers may be next to one another, but they are not continuous. Therefore, the weak point in a belt seems to be the point at which the ends are connected. For this reason, the focus of many attempts to reduce the problem of belt stretch have focused on manipulating the fibers at the point of connection, resulting in the development of complicated techniques for connecting the ends of the belts. Although many of these techniques have improved the problem of belt stretching, there still exists a need for providing a belt having a reduced tendency to stretch. In particular there is a need for a belt that resists stretch and is economical to produce.
In light of the foregoing, the present invention provides a belt that is economical to produce that is stretch-resistant. In particular the present invention provides a method for producing such a belt.
According to one aspect, the present invention provides a method for producing a stretch-resistant conveyor belt. According to the method, an elongated stretch reduction element is provided. The stretch reduction element is exposed to a reactive fluid in an oxidizing atmosphere. Jacket material is formed into a belt jacket around the stretch reduction material to form a length of material. The ends of the belt are then connected to form a continuous loop.
According to another aspect of the invention, a stretch resistant belt is provided. The belt comprises an outer jacket formed of a flexible material. The belt further includes a stretch resistant element formed of one or more fibers that have been exposed to a reactive fluid in an oxidizing atmosphere. The fibers are combined with the jacket to form a length of belt material. The ends of the belt are connected to form a continuous loop.
The foregoing summary and the following detailed description of the preferred embodiments of the present invention will be best understood when read in conjunction with the appended drawings, in which:
Referring now to the figures, wherein like elements are numbered alike throughout, a belt is designated 10. The belt is a continuous loop having an outer jacket 15 and a stretch reduction element 20. The stretch reduction element is embedded within the jacket 15.
The belt 10 may be utilized in a variety of applications, including power transmission and material handling. Referring to
The belt may be configured in a variety of shapes and profiles. In the present instance, the belt has a generally circular cross-section. Additionally, in the present instance the belt is substantially solid.
The jacket 15 may be formed from a variety of materials depending on the application for the belt 10. For instance, the jacket may be formed from one or more thermoplastic materials, such as urethane. Exemplary thermoplastic materials are polyurethane, such as Texin and Elastollan, or polyether block amide, such as Pebax, or polyester elastomer, such as Hytrel.
The jacket 15 may be formed of a homogeneous material, as it is illustrated in
As shown in
The stretch reduction element 20 may be formed from one or more materials depending on the application for the belt. Several exemplary materials are polyester, nylon, aromatic polyester, and aromatic polyamide. Further, the stretch reduction element 20 can be configured in various forms, such as a plurality of strands or woven fibers. In the present instance, the stretch reduction element is formed of material in the form of fibers or fabric that has been subjected to a reactive fluid in an oxidizing atmosphere to alter the surface of the material. The details of exemplary materials are provided further below in the description of the method for producing the belt.
The stretch reduction element 20 may be oriented relative to the jacket in a variety of configurations. In one configuration, the stretch reduction element is embedded within the jacket so that the jacket surrounds the stretch reduction element. Additionally, the stretch reduction element is oriented such that it extends substantially the entire length of the belt. Further, in the present instance, the stretch reduction element is substantially parallel with the central axis of the jacket, along substantially the entire length of the belt.
The ends of the belt 10 are connected to form a continuous loop, as illustrated in
Method of Production
The method of producing the belt includes several steps. The first step includes providing the materials for the jacket and the stretch reduction element. The second step includes interconnecting the jacket and the stretch reduction element to produce a length of belt; and the third step includes the step of connecting the ends of the length of belt to provide a continuous loop. Each of the steps will be described in greater detail below.
As discussed previously, in the present instance, the belt is a two part belt, having a homogeneous jacket 15 wrapped around a stretch reducing element 20. The jacket material is selected to provide the desired characteristics for the outer surface of the belt and the desired wear characteristics of the belt. Because the application may vary widely, a number of jacket materials are acceptable candidates for the belt. Since it is desirable to provide the ability to weld segments of the belt together, it is desirable to select a jacket that allows two separate segments to be heated and melted together. Accordingly, the jacket material may be selected from among the group of thermoplastic materials and rubber materials. For instance, in the present instance, the jacket material is selected from among a group of thermoplastics including Texin, Elastollan, Pebax and Hytrel. However, it may be desirable to produce the belt from an alternate material that may be joined chemically, such as by solvent or otherwise. Accordingly, the jacket material is not limited to being a thermoplastic.
The jacket material is selected to meet various performance characteristics of the application for the belt. Accordingly, the jacket material may be selected to achieve various characteristics, such as abrasion resistance, coefficient of friction or deformability. Ordinarily, the characteristics of the jacket are selected without significant regard for the characteristics of tensile strength and resistance to stretch For instance, the jacket material may be selected such that the modulus of elasticity (Young's modulus) for the material is less than 1 GPa at room temperature and may be less than 400 MPa. Further, according to one application, the modulus of elasticity is less than 300 MPa at room temperature.
Since the stretch resistant element 20 is normally embedded within the jacket, characteristics such as coefficient of friction and deformability are less significant when selecting a material to be used for the stretch reduction element. Instead, properties such as axial strength and resistance to elongation are primary characteristics of the material selected for the stretch resistant element 20. Specifically, in the present instance, the material used for the stretch reduction element is selected based on the ability of the material to substantially impede elongation under load. Accordingly, the material for the stretch reducing element is selected such that the modulus of elasticity (Young's modulus) is greater than 1 GPa, and may be greater than 10 GPa. Further according to one application, the material is selected such that the modulus of elasticity is greater than 40 GPa. Although the stretch reduction element may be formed from a variety of materials, exemplary materials include polyester, nylon, aromatic polyester, and aromatic polyamide. Additionally, the stretch reduction element may be configured in any of a variety of forms, such as fibers or strands, or it may be a woven material, such as a fabric.
In the following discussion, the material for the stretch reduction element will be referred to as fibers. However, as discussed above, the process is not limited to using fiber.
As described above, the fibers 20 are formed from material having a relatively high modulus of elasticity. In this way, when the fibers are incorporated into the belt, the fibers reduce the tendency of the belt to stretch under load. Additionally, it has been found that the overall tendency of the belt to stretch is reduced if the fibers 20 are processed before being incorporated into the belt.
The fibers 20 are processed by exposing the fibers to an atmosphere of two reactive fluids to modify the surface of the fibers. Specifically, the fibers are exposed to an oxidizing environment in the presence of a second reactive fluid. In the present instance, the second reactive fluid is elemental fluorine. For instance, the fibers may be exposed to a bath of a mixture of fluorine gas and oxygen. The process may occur in a closed environment such as a reactor or other enclosure.
The fibers are exposed to the fluorine and oxygen mixture for a sufficient amount of time to modify the surface of the fibers, but preferably not long enough to modify the internal material of the fibers. In other words, although the entire length of the fiber is modified by the process, the fibers are exposed to the fluorine and oxygen mixture for a length of time sufficient to simply modify the surface layer of the fibers. At least a majority of the fiber material is not modified by the fluorine and oxygen mixture, and in the present instance, the modified surface amount to a substantially small amount of the overall volume of the fiber, such as less than 1%.
After the fibers are modified, the belt is formed. The belt may be formed using a variety of techniques. In the present instance, the jacket material is extruded with the fibers embedded within the jacket. Specifically, the jacket material is co-extruded with the fibers so that the jacket surrounds the fibers.
The extrusion process creates a length of belt material that is used to form a belt. The length of belt has a first end and a second end. The fibers extend through the length of the belt so that the first ends of the fibers are adjacent the first end of the length of belt, and the second ends of the fibers are adjacent the second end of the length of belt.
The length of belt material is formed into a continuous belt by connecting the first end of the belt material to the second end of the belt material. In this way, a loop is formed in which the fibers are continuous along substantially the entire length of the belt, with the first ends of the fibers being disposed adjacent the second ends of the fibers.
The ends of the belt may be connected in a variety of ways. In the present instance, the ends of the belt are welded together. Any of a variety of welds can be used, such as a scarf weld or a butt weld. Further, a more intricate weld joint may be used, such as one in which a portion of the jacket is stripped from each end so that a surface of the fibers are exposed on each end. The ends are then overlapped so that the ends of the fibers overlap, and the belt is then welded by heating the jacket material at the joint. The ends of the jacket material are then squeezed together under pressure to encourage ends of the jacket to flow together to form a weld joint. Alternatively, rather than using a weld, a mechanical fastener may be used to connect the ends of the belt.
Although any of a variety of connections can be utilized, in the present instance, the ends of the belt are butt welded by using sufficient heat applied to the ends of the jacket, and then applying sufficient pressure to the ends to force the ends to flow together to form a weld joint. Any excess jacket material is then trimmed away so that the profile of the belt at the weld is similar to the profile of the belt along substantially the remainder of the belt.
Samples of belts made according to the foregoing process were tested to evaluate the effect of modifying the stretch reduction element. In the test, the jacket material is formed of polyurethane and the stretch reduction element is formed of polyester fibers. The fibers were exposed to fluorine gas in an oxidizing atmosphere. After the fibers were treated, the fibers were co-extruded with the polyurethane jacket to produce a length of belt material of about 65″ having the fibers embedded within the jacket. The belt material was joined together using a butt weld to form a continuous belt.
The belt was then mounted onto a pair of 6″ diameter pulleys. An end load of 200 lbs was applied to the set up. The belt was run at approximately 1000 rpm, which is approximately 1674 ft/min. A torque of approximately 54 in-lbs was applied to the set-up. The resulting theoretical tension ration for the test was 1.2
During the test, the belt was run continuously for a 24 hour period under the test conditions described above. During the test the percentage of belt stretch was measured at different intervals.
The test was repeated on two control belts that incorporated untreated fibers. In other words, the fibers in the control belts were polyester fibers that had not been treated by exposure to fluorine gas in an oxidizing atmosphere. The remaining characteristics of the control belts were similar to the belts described above. Specifically, the control belts were made from the same type of polyurethane jacket. The belts had a 20 mm circular profile, and the reinforcing fibers were polyester.
The results of the test for two similarly prepared test belts and two similarly prepared control belts are illustrated in
It will be recognized by those skilled in the art that changes or modifications may be made to the above-described embodiments without departing from the broad inventive concepts of the invention. It should therefore be understood that this invention is not limited to the particular embodiments described herein, but is intended to include all changes and modifications that are within the scope and spirit of the invention as set forth in the claims.
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