DE69029520T2 - Conveyor belt - Google Patents

Description

Field of the invention

The present invention relates to conveyor belts in general, and in particular to a conveyor belt having guards protecting the ends of connecting shafts, each connecting shaft extending through openings in the connecting means. Conveyor belts meeting the definition of the preamble of claim 1 are known from EP-A-0 032 712 and from GB-A-1 066 905. It is the stated object of the present invention to significantly reduce the rotational friction between the connecting shaft and the adjacent portions of the connecting members, and the connecting members are formed from modules shaped such that every other row of connecting members comprises only whole connecting members with no spacing between the modules.

Summary of the invention

According to the present invention there is provided a conveyor belt comprising: a plurality of connecting means, each connecting means having a front end, a rear end, a first side and a second side, a first shaft opening extending through the front end of each connecting means, and a second shaft opening extending through the rear end of each connecting means; and a plurality of connecting shafts, each connecting shaft extending through a first shaft opening in one of the connecting means and through the second connecting opening in another connecting means to interconnect the two connecting means, each connecting shaft having a first end extending a short distance beyond the first side of one of the connecting means, and a second end extending a short distance beyond extending beyond the second side of one of the connecting means; characterized in that: each first shaft opening is further defined as being an elongated hole having a leading end formed at a radius greater than the radius of the connecting shafts, and a shaft oscillating surface is provided in each of the first shaft openings, each connecting shaft being disposed generally adjacent the shaft oscillating surface formed at one of the first shaft openings, and the shaft oscillating surface riding on the connecting shaft during operation of the conveyor belt to significantly reduce rotational friction between the connecting shaft and adjacent portions of the links; and wherein the shaft oscillating surface in each of the first shaft openings extends a sufficient distance such that the connecting shaft rolls on the shaft oscillating surface as the conveyor belt moves along an arcuate path, and wherein a shaft oscillating surface formed at the second shaft opening is further defined to extend a sufficient distance such that the connecting shaft rolls on the shaft oscillating surface as the conveyor belt moves along an arcuate path.

Short description of the drawings

Show it:

Figure 1 is a bottom plan view of a portion of a conveyor belt constructed according to the present invention, the portion of the conveyor belt shown in Figure 1 having only three connecting devices;

Figure 2 is a bottom plan view of a characteristic connecting device;

Figure 3 is a sectional view of a connecting member in one of the connecting devices, taken substantially along lines 3-3 of Figure 2, with the connecting shaft not shown;

Figure 4 is a sectional view of a connecting member in one of the connecting devices, taken substantially along lines 4-4 of Figure 2, and with the connecting shafts shown in cross section;

Figure 5 is a side elevational view of a characteristic connector taken substantially along lines 5-5 of Figure 2;

Figure 6 is a side elevational view of a characteristic connector taken substantially along lines 6-6 of Figure 2;

Figure 7 is a schematic diagram of two connecting devices connected to one another via a connecting shaft (shown by the dashed lines), and an operating position of the connecting shaft is shown exaggerated, in which the illustrated section of the conveyor belt is under tension and tends to pull one connecting device away from the other connecting device;

Figure 8 is a plan view from below similar to Figure 1, but showing a modified conveyor belt, wherein each of the connecting devices consists of modules having a construction according to the invention;

Figure 9 is a top plan view of a modified conveyor belt incorporating the construction of the conveyor belt of Figure 1 but having snails (only one snail is shown in Figure 9);

Figure 10 is a side elevation of the portion of the conveyor belt shown in Figure 9;

Figure 11 is a side elevational view of a side guard having a construction according to the present invention;

Figure 12 is a top plan view of the side protection device of Figure 11 on a conveyor belt constructed as shown in Figure 1;

Figure 13 is a side elevation of a conveyor belt with a plurality of side guards positioned thereon;

Figure 14 is a top plan view of a conveyor belt constructed as shown in Figure 1, showing a connecting shaft without a head;

Figure 15 is a schematic diagram of a prior art elongated conveyor belt extending around two sprockets; and

Figure 16 shows another schematic diagram of an elongated conveyor belt according to the state of the art, which extends around two sprockets.

Description of the preferred embodiments

In Figure 1, the general reference numeral 10 designates a conveyor belt constructed according to the present invention. In Figure 1, only a portion of the conveyor belt 10 is shown, and as shown in Figure 1, the conveyor belt 10 comprises a A plurality of connecting means 12, only three connecting means 12 being shown in Figure 1, and the individual connecting means being designated by the reference numerals 12a, 12b and 12c in Figure 1. It should be noted that in practice a conveyor belt constructed in accordance with the present invention will comprise a larger number of connecting means 12 connected together to form an endless conveyor belt 10 extending generally around sprockets, and the conveyor belt will be used to transport objects as is well known in the art.

Each connector 12 includes a front end 14, a rear end 16, a first side 18 and a second side 20, as can be clearly seen in Figure 2 with respect to a typical connector 12. Each connector 12 further includes a first shaft opening 22 (Figure 2) extending through the front end 14 of each connector 12 and extending generally between the first and second sides 18 and 20 of each connector 12. Each connector 12 further includes a second shaft opening (Figure 2) extending through the rear end 16 of each connector 12 and extending generally between the first and second sides 18 and 20 of each connector 12.

The conveyor belt 10 further comprises a plurality of connecting shafts 26, wherein two connecting shafts 26 are shown in Figure 1, which are designated in Figure 1 with the individual reference numerals 26a and 26b. Each connecting shaft 26 extends through the first shaft opening 22 in one of the connecting devices 12 and through the second shaft opening 24 in another connecting device 12 in order to connect the two Each connecting shaft 26 includes a first end 28 and a second end 30 as shown in Figure 1 with respect to the connecting shaft 26b. The first end 28 of each connecting shaft 26 extends a little beyond the first side 18 of one of the connecting devices 12 and the second end 30 of each connecting device 12 extends a little beyond the second side 20 of one of the connecting devices 12.

The conveyor belt 10 comprises a plurality of first protective devices 32, wherein in Figure 1 three first protective devices 32 are shown, which are designated in Figure 1 with the individual reference numbers 32a, 32b and 32c. Each first protective device 32 is connected to the first side 18 of one of the connecting devices 12. Each first guard 32 extends generally over and generally encloses the first end 28 of one of the connecting shafts 26. The first guards 32 cooperate to enclose and substantially protect the first ends 28 of the connecting shafts 26 and to substantially prevent the first ends 28 of the connecting shafts 26 from engaging objects during operation of the conveyor belt 10 which may otherwise result in damage or destruction of the first ends 28 of the connecting shafts 26.

As shown in Figure 5, each of the first guards 32 has an access opening 34 formed therethrough, and each access opening 34 is generally aligned with one of the second shaft openings 24 in one of the connectors 12. Each first guard 32 is connected to the rear end 16 of one of the connectors 12, and each first guard 32 extends generally a distance from the rear end 16 toward the front end 14 of one of the connecting devices 12. The opposite end of each first protection device 12 is connected to the first side 18 of one of the connecting devices 12, generally between the front end 14 and the rear end 16, thereby forming a shaft gap 36 (Figure 2) between each first protection device 32 and the first side 18 of one of the connecting devices 12.

The first end 28 of each of the connecting shafts 26 extends through the second shaft opening 24 in one of the connecting devices 12 and into the shaft gap 36 formed by one of the first protective devices 32. The access openings 34 and the shaft gaps 36 provided by the first protective devices 32 provide openings for visual inspection of the first end portions 28 of the connecting shafts 26 and the adjacent portions of the second shaft openings 24 and the connecting devices 12.

The conveyor belt 10 comprises a plurality of second protective devices 38, wherein in Figure 1 three second protective devices 38 are shown, which are designated in Figure 1 with the individual reference numbers 38a, 38b and 38c. Each second protective device 38 is connected to the second side 20 of one of the connecting devices 12. Each second guard 38 extends generally over and generally encloses the second end 30 of one of the connecting shafts 26. The second guards 38 cooperate to enclose and substantially protect the second ends 30 of the connecting shafts 26 and substantially prevent the second ends 30 of the connecting shafts 26 from engaging objects during operation of the conveyor belt 10 which may otherwise result in damage or destruction of the second ends 30 of the connecting shafts 26.

As shown in Figure 6, each of the second guards 38 has an access opening 40 formed therethrough, and each access opening 40 is generally aligned with one of the second shaft openings 24 in one of the connectors 12. Each second guard 38 is connected to the rear end 16 of one of the connectors 12, and each second guard 38 extends from the rear end 16 generally a short distance toward the front end 14 of one of the connectors 12. The opposite end of each second guard 38 is connected to the second side 20 of one of the connectors 12, generally between the front end 14 and the rear end 16, thereby forming a shaft gap 42 between each second guard 38 and the second side 20 of one of the connectors 12.

The second end 30 of each connecting shaft 26 extends through one of the second shaft openings 24 in one of the connecting devices 12 and into one of the shaft spaces 42 formed by one of the second protective devices 38. The access openings 40 and the shaft spaces 42 provided by the second protective devices 38 provide openings for visual inspection of the second end portions 30 of the connecting shafts 26 and adjacent portions of the second shaft openings 24 and the connecting devices 12.

To connect the connecting devices 12 to the connecting shafts 26, the front end 14 of each connecting device 12 is disposed near the rear end 16 of another connecting device 12 and positioned such that the first shaft opening 22 in one of the connecting devices 12 is generally in alignment with the second shaft opening 24 in the adjacent connecting device 12. At this position, one of the connecting shafts 26 extends through the first and second shaft openings 22 and 24 of the adjacent connecting devices 12 to a position where the first end 28 of each connecting shaft 26 extends into the shaft gap 36 provided by one of the first protection devices 32, and the second end 30 of each connecting shaft 26 extends partway into the shaft gap 42 provided by one of the second protection devices 38.

At this position of the connecting shaft 26, a device such as a soldering iron can be inserted through the access opening 34 into each of the first guards 32 and guided into engagement with the first ends 28 of the connecting shafts 26 so that the first ends 28 of the connecting shafts 26 are deformed and a shaft head 44 (in Figure 1, a shaft head 44 is designated by a reference numeral) is formed at each first end 28. Each shaft head 44 has a diameter that is larger than the diameter of the first and second shaft openings 22 and 24, thereby preventing each of the connecting shafts 26 from being removed through the first and second shaft openings 22 and 24 due to the engagement between the shaft head 44 and the first side 18 of each of the connecting devices 12.

In the same manner, a device such as a soldering iron can be inserted through the access opening 40 into each of the second guards 38 and guided into engagement with the second ends 30 of the connecting shafts 26 so that the second end 30 of one of the connecting shafts 26 is deformed and to form a shaft head 46 (in Figure 1, a shaft head 46 is designated by a reference numeral) at each second end 30. Each shaft head 46 has a diameter which is larger than the diameter of the first and second shaft openings 22 and 24, thereby preventing any of the connecting shafts 26 from being removed through the first and second openings 22 and 24 due to the engagement between the shaft head 46 and the second side 20 of each of the connecting devices 12.

Each connector 12 includes a plurality of connectors 48 (three connectors 48 are designated by reference numerals in Figure 2). Each connector 48 includes a first side 50, a second side 52, a front end 54, and a rear end 56 (shown in Figure 2 with respect to one of the connectors 48). A connector opening 58 (shown in Figure 2 with respect to one of the connectors 48) is formed through the rear end 56 of each connector 44. Each connector opening 58 extends generally between the first and second sides 50 and 52 of each connector 48. Each connector opening 58 is shaped to receive a portion of the front end 54 of one of the connectors 48 in an adjacent connector 12.

In the assembled position of the connectors 12, the front end 14 of each connector 12 is disposed adjacent the rear end of another connector 12, with the front end 54 of each link 48 in one of the connectors 12 generally inserted into and disposed within one of the link openings 58 in one of the links 48 of the adjacent connector 12. The adjacent connectors 12 extend generally parallel to one another, with the first sides 18 of all of the connectors 12 generally axially aligned, and with the second sides 20 of all of the connectors 12 also axially aligned.

A first front connecting shaft opening 60 is formed through the first side 50 of each link 48 generally near the front end 54 (shown in Figure 2 with respect to one of the links 48 and in Figure 3). A second front connecting shaft opening 62 (shown in Figure 2 with respect to one of the links 48 and in Figure 4) is formed through the second side 52 of each of the links 48 generally near the front end 54. The first and second front connecting shaft openings 60 and 62 are axially aligned, and each of the front connecting shaft openings 60 and 62 is sized and adapted to receive one of the connecting shafts 26. The connecting shaft openings 60 and 62 form the first shaft opening 22.

A recess 63 is formed through a portion of the front end 54 of each link 48, as shown in Figure 1 with respect to one of the links 48 and in Figures 3 and 4. Each recess 63 is generally aligned with the first and second front link shaft openings 60 and 62. Each recess 63 is shaped and adapted to receive a portion of one of the link shafts 26. The link shafts 26 extend through the first and second front link shaft openings 62 and 63 and through the recess 63.

A first rear connecting shaft opening 64 (shown in Figure 1 with respect to one of the connecting links 48 and in Figure 3) is formed through the first side 50 of each of the connecting links 48 generally near the rear end 56. A second rear connecting shaft opening 66 (shown in Figure 1 with respect to one of the connecting links 48 and in Figure 4) is formed through the second side 52 of each of the connecting links 48 generally near the rear end 56. formed near the rear end 56. The first and second rear connecting shaft openings 64 and 66 are axially aligned, and each of the rear connecting shaft openings 64 and 66 is sized and adapted to receive one of the connecting shafts 26. The connecting shaft openings 64 and 66 cooperate to form the second shaft opening 24.

One end of a connecting element 68 (in Figure 2, a connecting element 68 is designated by a reference numeral) is attached to the second side 52 of each link 48, generally proximate the rear end 56. Each connecting element 68 extends generally a short distance from the second side 52 of each link 48, and the opposite end of each connecting element 68 is connected to the first side 50 of an adjacent link 48, generally proximate the rear end 56. The connecting elements 68 cooperate to connect the links 48 together, thereby forming a series of links 48 in each connector 12.

The front ends 54 of all of the links 48 in each link 12 cooperate to form the front end 14 of each link 12. The rear ends 56 of all of the links 48 in each link 12 cooperate to form the rear end 16 of each link 12. The first side 50 of one of the links 48 and each link 12 cooperate to form the first side 18 of each link 12. The second side 52 of one of the links 48 and each link 12 cooperate to form the second side 20 of each link 12.

To form the conveyor belt 10 at the assembled position of the connectors 12, the front end 14 of each connector 12 is positioned generally adjacent to the rear end 16 of one of the connectors 12. The front ends 54 of all of the links 48 in one of the connectors 12 are generally positioned in the connection opening 58 in one of the links 48 in the adjacent connector 12 and positioned so that the first front connection shaft openings 60 and 62 in each of the links 48 in one of the connectors 12 are aligned with the rear connection shaft openings 64 and 66 in the adjacent connector 12. At this position, a connecting shaft 26 is inserted through the aligned front connecting shaft openings 60 and 62 and the aligned rear connecting shaft openings 64 and 66 to interconnect the two adjacent connecting devices 12.

Each of the links 48 further includes a link tension member 70 (in Figure 2, a link tension member 70 is designated by a reference numeral). Each link tension member 70 has an end connected to the first side 50 and an opposite end connected to the second side 52 of one of the links 48. Each link tension member 70 extends generally between the first and second sides 50 and 52 of one of the links 48, with each link tension member cooperating to provide additional structural strength to maintain the first side 50 separated from the second side 52.

As shown in Figures 3 and 4, each of the front connecting shaft openings 60 and 62 specifically includes a elongated opening or slot having an upper end portion formed on a radius 72 (as shown in Figure 3 with respect to opening 60) and having a shaft pendulum surface 74 (shown in Figure 3 with respect to opening 60) in each forward connecting shaft opening 60 and 62.

Specifically, each of the rear connecting shaft openings 64 and 66 includes an elongated opening having a lower end portion formed on a radius 76 (shown in Figure 3 with respect to the opening 64) and further having a feature referred to herein as a shaft engaging surface 78 (shown in Figure 3 with respect to the opening 64) in each rear connecting shaft opening 64 and 66.

The radius 72 is larger than the diameter of the connecting shafts 26. The radius 72 is preferably sized so that the shaft-pendulum surface 74 approaches a flat surface while still maintaining an arcuate or shallow V-shape. The shaft-pendulum surface 74 extends a distance (arc length) long enough to allow the connecting shaft 26 to remain on the shaft-pendulum surface 74 while the conveyor belt 10 is transported along a curved path, such as around a sprocket.

In the assembled position of the connecting devices 12, the connecting shafts 26 extend through the connecting shaft openings 60, 62, 64 and 66. The connecting shaft openings 60 and 62 are sized and shaped so that each connecting shaft 26 runs normally about a central position on each of the shaft oscillating surfaces 74, as shown in Figure 4. As the conveyor belt 10 moves over a curved path, such as a sprocket, the connecting shafts 26 pivot or roll on the shaft oscillating surfaces 74, with the connecting shafts 26 remaining at a substantially stationary position with respect to the shaft engagement surfaces 78. In other words, this means that during movement of the conveyor belt 10 over a curved path there is practically no relative movement between the connecting shafts 26 and the shaft engagement surfaces 78.

The rocking motion of the connecting shafts 26 on the shaft-pendulum surface 74 substantially reduces the rotational friction between the connecting shafts 26 and the portions of the connecting members 48 generally formed by the shaft-pendulum surfaces 74 and 78.

The fact that the connecting shafts 48 tend to rock or oscillate on the shaft oscillating surfaces 74 is particularly significant when the conveyor belt 10 is constructed of plastic or ceramic connecting means 12 and plastic or ceramic connecting shafts 26. When the conveyor belt 10 is in use and under stress tends to separate the connecting means 12 from one another, each connecting shaft 26 is slightly deflected at the locations where the connecting shaft 26 enters and exits the shaft openings 60, 62, 64 and 66, thereby causing the connecting shafts 26 to bend somewhat sinusoidally along the length of the connecting shaft 26, as shown in Figure 7 with respect to one connecting shaft 26 schematically shown in dashed lines and to two connecting means 12b and 12c schematically shown in Figure 7. In this case, the connecting shaft 26 is practically prevented from rotating while the conveyor belt 10 moves around a sprocket (not shown). If the shaft openings 60 and 62 were simply circular and had a diameter that is slightly larger than the diameter of the connecting shaft 26, there would be greatly increased rotational friction between the connecting shaft 26 and adjacent portions of the connecting members 48, which would lead to severe wear of the connecting shafts 26. In the present invention, this wear is significantly reduced because the connecting shafts 26 roll or oscillate on the shaft oscillating surfaces 74.

As shown in Figures 9 and 10, the conveyor belt 10 may further comprise a plurality of augers 80 that cooperate to transport material, with only one auger 80 being shown in Figure 7. Each auger 80 comprises a portion that extends into the connectors 12 and openings (not shown) for receiving the connecting shafts 26. Thus, each connecting shaft 26 further extends through openings (not shown) in the augers 80 to connect the augers 80 to the conveyor belt 10.

Conveyor belts such as conveyor belt 10 must typically be manufactured with different widths extending between the first and second sides 18 and 20 of the connectors 12. If each connector 12 were a single, molded, unitary product, this would mean that a different shape would have to be created for each desired width of conveyor belt 10. Alternatively, each connector 12 may include a section having a predetermined number of links 48 located near a similar section having the same or a different number of links 48, in which case sections 12 having different lengths may be connected together to create different widths. In the latter case, however, the Distances between the different sections reduce the overall strength of the structure of the conveyor belt 10 designed in this way.

In one embodiment and according to the illustration in Figure 8, the conveyor belt 10a is designed with a plurality of interconnected first and second connecting devices 82 and 84. Four connecting devices are shown in Figure 8 and are designated by the reference numerals 84a, 84b, 82a and 82b. The connecting devices 82 and 84 are arranged next to one another and at intervals along the length of the conveyor belt 10a.

Each first connector 82 includes a front end 81, a rear end 83, a first side 85 and a second side 87 as shown in Figure 8 (in Figure 8, only one of the first connectors 82a is designated by reference numerals for the front end 81, the rear end 83, the first side 85 and the second side 87). Each first connector 82 has a first shaft opening formed through a portion of the front end 81 of the connector and a second shaft opening formed through a portion of the rear end 83 of the connector in exactly the manner described above with respect to the first and second shaft openings 22 and 24 of the connectors 12.

The first connecting device 82 includes a first end module 86, a second end module 88, and an intermediate module 90 located between the first and second end modules 86 and 88. The modules 86, 88, and 90 are arranged in end-to-end relation so that the first connecting device 82 is formed.

The first end module 86 has a first end 92 and a second end 94 and includes a plurality of links 95 (in Figure 8, only one of the links 95 is designated by a reference numeral). Each of the links 95 is of exactly the same construction as described above with respect to the connectors 12 for the links 48, and each link 95 in the first end module 82 comprises a "whole link." The second end 94 of the first end module 86 is formed by a half-connector, such as for connecting the member 68 described above with respect to the connectors 12.

The second end module 88 includes a first end 96 and a second end 98. The second end module 88 includes a plurality of links 97 (in Figure 8, only one of the links 97 is designated by a specific reference numeral). The links 97 all have exactly the same construction and function as the links 48 described above with respect to the connectors 12, and each of the links 97 has a first shaft opening (not shown) and a second shaft opening (not shown) formed through the links in exactly the same manner as the first and second shaft openings 22 and 24 of the connectors 12 and described in detail above. All of the links 97 in the second end module 88 are whole links, and the second end 98 of the second end module 88 is formed by half of a connecting element corresponding to the connecting element 68 described in detail above in relation to the connecting devices 12.

The intermediate module 90 has a first end 102 and a second end 104. The intermediate module 90 comprises a plurality of connecting links 103, these connecting links 103 all being designed exactly like the connecting links 48 already described above in the text (in Figure 8 only one of the connecting links 103 is designated with a specific reference number). The first end 102 of the intermediate module 90 is formed by one half of a connecting element that corresponds to the connecting element 68 that has already been described in detail above in the text with respect to the connecting device 12. The second end 104 of the intermediate module 90 is formed by one half of a connecting element that corresponds to the connecting element 68 that has already been described in detail above in the text with respect to the connecting devices 12.

At an assembled position of the first connector 82, the second end 94 of the first end module 86 is spaced apart near the second end 104 of the intermediate module 90, and the first end 102 of the intermediate module 90 is spaced apart near the second end 98 of the second end module 88. In this position, the first end 92 of the first end module 86 forms the first side of the first connector 82, and the first end 96 of the second end module 88 forms the second side 87 of the first connector 82.

Each second connecting device 84 includes a front end 106, a rear end 107, a first side 109 and a second side 111. In Figure 8, only the ends 105 and 107 and the sides 109 and 111 of the second connecting device 84a are designated with specific reference numerals.

Each second connecting device 84 comprises a first end module 106, a second end module 108 and an intermediate module 110.

The first end module 106 has a first end 112 and a second end 114. The first end module 106 includes a plurality of links 113 (in Figure 8, only one of the links 113 is designated by a specific reference numeral). Each link 113 has exactly the same shape and form as the links 48 described above in the text with respect to the connector 12, with the exception that the link 113 forming the second end 114 of the first end module 106 includes a device referred to herein as a half link, and the half link forming the second end 114 of the first end module 106 is designated by the specific reference numeral 115 in Figure 8. The half connecting link 115 comprises half of a whole connecting link 113.

The second end module 108 has a first end 116 and a second end 118. The second end module 108 includes a plurality of connecting links 117 (in Figure 8, only one of the connecting links 117 is designated by a specific reference numeral), and the connecting links 117 are of exactly the same construction as the connecting links 48 described in detail above in relation to the connecting device 12, with the exception that the connecting link forming the second end 118 of the second end module 108 specifically comprises a half connecting link, and the half connecting link forming the second end 118 of the second end module 108 is designated by the specific reference numeral 119 in Figure 8. The half connecting link 119, which forms the second end 118 of the second end module 108, comprises half of a whole connecting link 117.

The intermediate module 110 has a first end 120 and a second end 122. The intermediate module 110 includes a plurality of links 121, each of the links 121 having exactly the same construction as the links 48 described in detail above in the text with respect to the connector 12, with the exception that the link forming the first end 120 comprises a half link and is designated in Figure 8 by the specific reference numeral 123, and the link forming the second end 122 specifically comprises a half link and is designated in Figure 8 by the specific reference numeral 124. The half connecting links 123 and 124, which form the first and second ends 120 and 122 of the intermediate module 110, respectively, comprise approximately half of a whole connecting link 121.

In an assembled position, the first end module 106, the second end module 108, and the intermediate module 110 of each second connector 84 are arranged in an end-to-end relationship to form the second connector 84. In particular, the second end 114 of the first end module 106 is spaced proximate the second end 122 of the intermediate module 110, and the first end 120 of the intermediate module 110 is spaced proximate the second end 118 of the second end module 108. The first end 112 of the first end module 106 cooperates to form the first side 109 of the second connector 84, and the first end 116 of the second end module 108 cooperates to form the second side 111 of the second connector 84.

When the modules 86, 88 and 90 are arranged in this end-to-end relationship to form the first connection device 82, with the modules 106, 108 and 110 in the end-to-end relationship to form the second connection device 84 are arranged, the front end 105 of the second connecting device 84 is located close to the rear end 83 of the first connecting device 82 so that the connecting links 113, 115, 117, 119, 121, 123 and 124 are each located in one of the link openings formed by the connecting links 95, 97 and 103 in the first connecting device 82, and wherein a connecting shaft is arranged through the first shaft opening in the second connecting device 84 and through the second shaft opening in the first connecting device 82 to interconnect the first and second connecting devices 82 and 84 in an assembled position as described above with respect to the connecting devices 12, the connecting shafts 26 and the connecting openings 58.

When the connecting means 82 and 84 are designed in the manner described above, with the modules 86, 88 and 90 in the first connecting means 82 comprising whole links, and with the modules 106, 108 and 110 in the second connecting means 84 comprising whole links with the ends formed from half links, every other row of links interconnected by connecting shafts will have only whole links interconnected to whole links, as shown in Figure 8, thereby providing increased overall structural integrity in the conveyor belt 10 since only every other row of interconnected links will have spaces between the modules forming the connecting means 82 and 84.

In Figure 11, a side protection device 150 designed according to the present invention is shown. The side protection device 150 comprises an upper end 152, a lower end 154, a first side 156, and an opposite second side 158. The sides 156 and 158 each have an outward taper, with the sides 156 and 158 extending upwardly from the lower end 154. The upper end 152 is wider than the lower end 154.

A first notch 160 is formed in the first side 156 generally near the lower end 154. The first notch 160 is shaped to receive a connecting shaft 26, and the first notch 160 extends a distance slightly greater than the diameter of the connecting shaft 26.

A second notch 162 is formed in the second side 158 generally near the lower end 154. The second notch 162 is shaped to receive a connecting shaft 26 and is formed on a radius slightly larger than the radius of the connecting shaft 26.

Figure 12 shows a portion of the three connecting devices 12f, 12g and 12h, each of which has the same construction as the connecting devices 12 described above in the text. The three connecting devices 12f, 12g and 12h are connected to one another by the connecting shafts 26f and 26g.

As shown in Figure 12, a side guard 150 is attached to the connecting shafts 26f and 26g. To attach the side guard 150, the lower end 154 is positioned generally over the connecting shafts 26f and 26g, and the lower end 154 is then moved downwardly toward the connecting shafts 26f and 26g until the connecting shaft 26g snaps into the second notch 162. The side guard 150 is then slightly bent until the shaft 26f is generally disposed within the first notch 160. The side guard 150 is then released, causing the side guard 150 to spring back to its original, unbent shape, thereby positioning the connecting shaft 26f within the first notch 160.

As shown in Figure 13, a plurality of side guards 150 are connected to the conveyor belt 10 (in Figure 13, only one of the side guards 150 is designated with a reference number). The conveyor belt 10 is shown in Figure 13 at various positions to illustrate the positioning of the side guards 150.

If one or more side guards 150 are damaged or folded over during operation, the conveyor belt 10f does not have to be disassembled to install new side guards 150. The side guards 150 are simply snapped into place in the appropriate positions as described above. If one or more side guards 150 are damaged, it is also possible to remove the damaged side guard 150 by simply bending the side guard 150 in the opposite direction as described above and pulling it upwards to disengage the shafts 26f and 26g from the corresponding notches 160 and 162.

Figure 14 shows a pair of connecting devices 12i and 12j which have exactly the same construction as the connecting devices 12 described in detail above in the text, with the following exceptions. The connecting devices 12i and 12j have aligned shaft openings 22i and 24i arranged and shaped as described above to accommodate a connecting shaft 26i.

The connecting devices 12i and 12j each have first and second guards 32i and 38i which are of the same construction as the guards 32 and 38 described above, except that the access openings 34i and 40i are each offset relative to the shaft openings 24i. The offset openings 34i, 40i and 24i are elongated. The openings 34i and 40i each have a lower portion aligned with the upper portion of the openings 24i, and these aligned portions are sized to receive the connecting shaft 26i.

To install the connecting shaft 26i, the connecting device 12j is pushed upward in a general direction 170 to a position where the openings 22i are aligned with the aligned portions of the openings 34i or 40i and 24i. At this position, the connecting shaft 26i is inserted through the openings 34i or 40i and through the openings 22i and 24i. After the connecting shaft 26i is installed, the connecting device 12j moves back to the position shown in Figure 14 relative to the connecting device 12i, and the guard 32i or 38i prevents the connecting shaft 26i from moving out of the opening 34i or 40i because the connecting shaft 26i is not aligned with the opening 34i or 40i. With such a design, no head needs to be formed at the ends of the connecting shafts 26, such as the shaft heads 44 and 46.

When the conveyor belt 10 is tensioned, the connecting devices 12 tend to move away from each other and the connecting shafts 26 are bent in a sinusoidal curve, as already described above in the text with reference to Figure 7.

When the conveyor belt 10, which is constructed of plastic or ceramic connectors 12 and plastic or ceramic connector shafts 26, is tensioned, it stretches and elongates. In one embodiment, an elongation of the conveyor belt 10 of 1/8 inch per foot of the length of the conveyor belt 10 was observed. With a length of conveyor belt 10 of forty feet placed over two spaced apart sprockets, in practice a conveyor belt 10 constructed in accordance with the present invention could be used with an unstretched length of approximately forty feet less forty feet times 1/8 inch divided by 12 inches. The conveyor belt 10 is then stretched around the sprockets to a assembled position. The stretched or tensioned conveyor belt 10 reduces bending of the chain and the belt near the sprockets, which results from thermal expansion and swelling during operation of the conveyor belt 10.

In Figure 15, a prior art conveyor belt 200 (shown in dashed lines) is shown mounted around a pair of sprockets 202 and 204. The conveyor belt 200 is supported between the sprockets 202 and 204 by a pair of supports 206 and 208. As shown, the conveyor belt 200 would expand by thermal expansion or swelling. Near the sprocket 204, the belt generally sags by 210. The occurrence of such sagging of the belt is prevented by a Conveyor belt designed according to the present invention is significantly reduced.

As shown schematically in Figure 16, a prior art conveyor belt 212 is mounted around two sprockets 214 and 216. The conveyor belt 212 is supported by a support 218, with the conveyor belt 212 further supported on the underside by a pair of cylindrical supports 220 and 222. When the conveyor belt 212 expands during use, the chain sags through 224. This type of chain sagging is prevented by a conveyor belt constructed in accordance with the present invention.

The connecting shafts described herein are preferably made of an elastic material, such as plastic or a ceramic material. The connecting devices are also made of plastic or a ceramic material. A conveyor belt constructed in this way elongates without significant deformation, which leads to permanent use in sections or to the destruction of sections of the connecting devices or the connecting shafts.

Claims (3)

1. Conveyor belt (10) comprising: a plurality of connectors (12), each connector (12) having a front end (14), a rear end (16), a first side (18) and a second side (20), a first shaft opening (22) extending through the front end (14) of each connector (12), and a second shaft opening (24) extending through the rear end (16) of each connector (12); and a plurality of connecting shafts (26), each connecting shaft (26) extending through a first shaft opening (22) in one of the connecting devices (12) and through the second connecting opening (24) in another connecting device (12) to interconnect the two connecting devices (12), each connecting shaft (26) having a first end (28) extending a little beyond the first side (18) of one of the connecting devices (12) and a second end (30) extending a little beyond the second side (20) of one of the connecting devices (12); characterized in that: each first shaft opening (22, 60) is further defined as being an elongated hole having a front end formed at a radius (72) greater than the radius of the connecting shafts (26), and wherein a shaft oscillating surface (74) is provided in each of the first shaft openings (22), each connecting shaft (26) being disposed generally adjacent the shaft oscillating surface (74) formed at one of the first shaft openings (22), and wherein the shaft oscillating surface (74) rides on the connecting shaft (26) during operation of the conveyor belt (10) to reduce rotational friction between the connecting shaft (26) and the adjacent parts of the connections (48); and wherein the shaft oscillating surface (74) in each of the first shaft openings (22) extends a sufficient distance so that the connecting shaft (26) rolls on the shaft oscillating surface (74) when the conveyor belt (10) moves over an arcuate path, and wherein a shaft oscillating surface formed on the second shaft opening (24) is further defined to extend a sufficient distance so that the connecting shaft (26) rolls on the shaft oscillating surface (74) when the conveyor belt (10) moves over an arcuate path. 2. Conveyor belt (10) according to claim 1, characterized in that the radius (72) of each wave-pendulum surface (74) is sufficiently large so that each wave-pendulum surface (74) approximates a flat surface formed on a curve. 3. Conveyor belt (10) according to claim 1 or 2, characterized in that the shaft pendulum surface (74) formed in the first shaft opening (22) extends over a distance that is greater than the diameter of the connecting shaft (26).