RU2263584C2 - Method of transportation and replacement of large-size pneumatic tires - Google Patents

Abstract

FIELD: transport engineering.

SUBSTANCE: invention can be used for very large vehicles with diameters of tires exceeding 3.05 m, such as quarry dump trucks using tires with detachable tread. Tread band is transported separately from tire carcass in state compressed from two opposite sides. Replacement of tread on tire is carried out at follows: first pressure in tire carcass is partially reduced, at least part of first tread band is removed from side of front part of tire carcass, then tire carcass is rolled forward with application of side force to tread band in direction of removal, until tire carcass has rolled out of first band and lied on carrying surface, then the rest parts of first tread band are removed from tire carcass in side direction. Second tread band is fitted on as follows: firstly part of second tread band is shifted to front part of tire carcass, then tire carcass is rolled forward at application of side force to second tread band.

EFFECT: facilitated transportation and replacement of large pneumatic tires.

6 cl, 8 dwg

Description

DESCRIPTION

The invention relates to methods for transporting, storing and replacing very large pneumatic tires, usually intended for use on very large vehicles, such as mining trucks, and more particularly, to methods possible using a pneumatic tire design with a removable tread band.

The tread band pneumatic tires that are the subject of the present invention are very large tires (with an outer diameter greater than 304.8 cm), typically intended for use on very large vehicles, usually off-road vehicles such as earth moving machines and mining trucks heavy payloads (e.g. 300 short tons or more). These very large tires and vehicles are generally used in long-term field development or construction, such as quarries, mines, foundries, construction of large tunnels / roads, dams / dams, etc. Very large vehicles are usually too large for normal transport to the work site and, therefore, they are often transported in parts to the work site, where the parts are assembled / welded together for use. As modern construction vehicles are becoming increasingly large, their tires are expanding to the size with which the transportation of tires becomes difficult. For example, the construction of an existing 360-ton (326,530 kg) truck requires pneumatic tires with a diameter of 3.91 m, which is considered the maximum tire size acceptable for transportation by conventional rail or road means in the United States. Another consideration is the weight of the tire, since very large tires can weigh between 3628 kg and 6803 kg or more when unmounted. Industry may even require large - 400-ton (362,812 kg) or 450-ton (408,163 kg) - trucks with correspondingly large tires with a diameter of 4.07 m or more. Depending on local restrictions for vehicles (such as tunnel / bridge dimensions and weight restrictions for roads), even the slightly smaller of the "very large tires" can cause significant problems and may require unusual vehicles such as a helicopter.

Another problem facing using very large pneumatic tires is the replacement of very large tires on very large vehicles. Very large vehicles are commonly used in facilities such as quarries where tires are subjected to high stresses and loads, usually in harsh environmental conditions, where tires are exposed to conditions that contribute to puncture and wear. Under these conditions, tires are damaged relatively frequently and must be replaced on the job site. Even for wheels with a removable rim, replacing very large wheels is a difficult and time-consuming process, requiring 5-6 hours to replace one tire.

Another problem is storing very large tires on the job site. As tires become larger, more and more space is required to store them. In addition, if the working conditions are especially difficult or the delivery and replacement of tires immediately "on demand" is not feasible, increased numbers of spare tires should be stored, which further increases the required storage space. In addition, some work sites require different tire designs for different working conditions. For example, for viscous conditions, such as rainy weather conditions, wide treads with deep lugs may be required, while gravel or dry weather conditions require tires with normal treads and a different form of lugs. Given the complexity of existing tire replacement methods, replacing tires to obtain optimal tread patterns is not always feasible.

Finally, even if the drive wheels and control wheels of very large vehicles have the same overall dimensions, the tread patterns of the two types of wheels must be different for the most effective operation. It also increases the number of spare tires that must be stored on the job site.

The technical task of the present invention is to provide a method of transporting very large tires, allowing more use of conventional means of transport, and it is desirable to reduce the need for storage space at the work site, as well as improve the efficiency of the method of replacing very large tires.

Although there are known embodiments of tires with interchangeable treads for automobiles / motorbikes and ordinary trucks, until now there have been no known designs of tires with a tread band that would meet the unique requirements for very large pneumatic tires for very large vehicles. US patent No. 09/424089 under the title "Tire with an improved removable tread band" issued by Rayman, and owned by the author of the present invention, which is a partial continuation thereof, describes a tire with an improved removable tread band for use on large earthmoving machines. This tire with a tread band (the so-called "tire with a track band") "consists of a removable tread band mounted on the outer annular surface of the inflated tire carcass. The unique design of the track band keeps the tread from expanding while improving the reliable installation of the tread on the carcass and providing improved puncture protection.In addition, the improved track tape will support a flatter tread profile, which in turn will increase the reliability nce and durability of the tread. "

A known embodiment of improved treads or track tapes for very large tires is described in US Pat. No. 4,351,380, in which some known track tape tires comprise a plurality of “shoes” engaged with the ground spaced around the periphery of the support structure. Large loads on the shoes lead to high stresses, which sometimes leads to premature tire damage. Patent No. 4351380 discloses a method for producing an improved track tape that comprises a plurality of shoes spaced around the periphery of the load-bearing structure and attached to a reinforcing belt structure located on the side of the shoe that is opposite to its side in contact with the ground.

Most of the tires of the prior art relates to tires with removable tread bracelets (see, for example, US patent No. 3897814, US patent No. 3224482, US patent No. 3087526 and UK patent G.B. 2073109). However, these patents disclose the use of different solutions related to tires used mainly on road vehicles, such as cars and trucks. Examples of these solutions include: changing the spacing of the cord to reduce wear on the outer edge of the tread band to "increase the service life and lower production costs"; improved lateral bending to "increase ride comfort and improve traction"; and combining separate retaining rings to "improve traction and drive quietly." Accordingly, according to the prior art, the number, configuration, arrangement and spacing of retaining rings, reinforcing strips, inextensible cords and mating grooves in the tire carcass and tread band changed, but these changes are neither adequate to address the special requirements for off-road vehicle tires, nor to very large tires in general.

There are still unresolved issues regarding the assembly of a pneumatic tire and tread band, regarding the transportation, storage, inventory and replacement of very large tires on very large vehicles.

The stated technical problem is solved by creating an improved method for transporting, storing and replacing very large pneumatic tires, which are used on very large vehicles, such as mining vehicles. Very large tires of a conventional design sometimes have a height of over 4 m and weigh approximately 3628 kg to 6803 kg, and the proposed designs of very large trucks require even larger tires. The size and weight of very large known tires create significant problems in the transportation, storage and replacement of tires.

According to the invention, very large tires are tires with a removable tread band, and the tread band is transported separately from the tire carcass. The removable tread band for transport is held in a compressed state, whereby it has a significantly reduced diameter for ease of transport.

According to one aspect of the invention, a spacer element is used for the compressed tread band, giving the tread band an oval shape with straight sides.

According to another aspect of the invention, the carcass of the tire for transportation is also held in a compressed state.

According to the invention, tires with a removable tread band are used to simplify and accelerate the process of replacing tires of relatively very large tires on very large vehicles, thereby saving time and money, as well as creating the possibility of changing the tread types of very large tires to suit different working conditions . A tire replacement method according to the invention includes the following steps: (a) partially depressurizing the tire carcass remaining on the vehicle to loosen the tread band; (b) laterally removing the tread band from the tire; (c) laterally installing a replacement tread band on the tire carcass and properly positioning it; and (d) inflating the carcass to the desired pressure to hold the replacement tread band in place on the tire carcass.

According to an aspect of the invention, operations (b) and (c) may be performed by exiting the tread band and entering the replacement tread band, respectively.

According to an aspect of the invention, steps (b) and (c) can be performed directly if a very large vehicle is first mounted so that the tire to be replaced is hung above the ground using, for example, a pneumatic jack, and then a very large vehicle is lowered after completion operations (d).

According to an aspect of the invention, operation (c) includes correctly positioning the tread band on the chassis, for example, by properly positioning the interlocking guides and grooves so that the tread band is positioned on the tire carcass as necessary for normal operation of the assembled tire.

According to an aspect of the invention, the tread band may be replaced by a band having the same configuration or a band having a different configuration to suit different operating conditions, such as different conditions of the bearing surface or different applications of very large vehicles.

According to the invention, tires with a removable tread band are used to reduce the physical size and storage cost of spare very large tires at a work site where very large vehicles are used. A small number of universal tire carcasses are used to replace damaged carcasses, and a greater number of tread bracelets are stored to replace tread carcasses, which are about four times more susceptible to damage or wear than carcasses.

According to an aspect of the invention, tread bracelets of various configurations are stored on a work site, thereby enabling them to be used on very large vehicles to suit different working conditions.

According to an aspect of the invention, at least a portion of the tread band is stored in a compressed state, thereby further reducing storage space requirements.

Other objects, features and advantages of the invention are explained in the following description below, in which reference is made in detail to preferred embodiments of the invention, examples of which are shown in the accompanying drawings. The figures are intended to be illustrative and not limiting. Although the invention has been generally described in the context of these preferred embodiments, it should be understood that it is not intended to limit the nature and scope of the invention to these specific embodiments.

Some elements in selected drawings may not be shown to scale for clarity. Cross sectional views, when presented here, may be in the form of “slices” or “nearsighted” species in which some background lines that would otherwise be visible in true sections are excluded for clarity.

Elements in the figures, as a rule, are numbered as follows. The most significant numbers (hundreds) of the reference number correspond to the figure number. Elements of figure 1 are numbered from 100-199. The elements of figure 2 are numbered within 200-299. Similar elements in the drawings may be denoted by the same reference numbers. For example, element 199 in the figure may be similar and possibly identical to element 299 in another figure. In some cases, similar (including identical) elements may be denoted by like numbers in the same drawing. For example, each of the plurality of elements 199 may be individually indicated as 199a, 199b, 199c, etc. Such a relationship, if it occurs, between similar elements in one or different figures will become clear in the course of the description, including, if applicable, the claims and the abstract.

The design, operation and advantages of a preferred embodiment of the present invention will be better understood when considering the following description given in conjunction with the accompanying drawings, in which:

figure 1 depicts a cross-sectional view showing half of the tire with a removable tread band according to the invention;

figa depicts a side view of the tread band prepared for transportation in accordance with the invention;

2B is a side view of an alternative embodiment of preparing a tread band for transportation in accordance with the invention;

figa depicts a side view of the tire carcass, if necessary, prepared for transportation in accordance with the invention;

figv depicts a cross-sectional view of the tire carcass, if necessary prepared for transportation in accordance with the invention;

4 is a side view of a storage area for very large tires in accordance with the invention;

5A is a sectional view showing a method for replacing a very large tire in accordance with the invention;

5B is a side view of an alternative embodiment of a method for replacing a very large tire in accordance with the invention.

In the description of the invention, the following terms are understood:

“Bead” means a portion of a tire comprising an annular tensioned element wrapped in layer cords and provided with or without other reinforcing elements, such as wing tapes, ridges, leg rails and chafers, for mounting on a wheel rim.

“Reinforcing structure of a bracelet or tread layer” means at least two layers of parallel cords, woven or not woven, laid under the tread, not attached to the board and having left and right corners of winding cords ranging from 17 degrees to 33 degrees relative to the equatorial plane of the tire .

"Tire with an inclined layer" means a tire having a carcass with reinforcing cords in a carcass ply extending diagonally across the tire from the bead core to the bead core at an angle of about 25-50 degrees relative to the equatorial plane of the tire. Cords run at opposite angles in alternating layers.

“Ring” means lines or directions running along the perimeter of the surface of the ring tread perpendicular to the axial direction.

"Cord" means one of the reinforcing cores that make up the layers in the tire.

"Equatorial plane (EP)" means a plane perpendicular to the axis of rotation of the tire and passing through the center of its tread.

“Tread imprint” means a contact patch or contact area of a tire tread with a flat surface under the influence of load and pressure.

“Lateral” and “lateral” means lines or directions parallel to the axis of rotation of the tire (also “axial direction”).

"Normal inflation pressure" refers to the inflation pressure of a particular structure under a specific load specified by the relevant metrological service standards for the operating conditions for the tire.

"Normal load" refers to the specific load at the inflation pressure of a particular design, as designated by the relevant metrological service standards for the operating conditions for the tire.

“Layer” means a continuous layer of rubber coated parallel cords.

"Radial" and "in the radial direction" mean directions extending radially to and from the axis of rotation of the tire.

"Tire with a radial layer" means a pneumatic tire radially or circumferentially tightened, in which the cords of the layer, which extend from side to side, are laid at cord angles of 65 to 90 degrees relative to the equatorial plane of the tire.

"Cords at an angle of zero degrees" means at least one layer of parallel cords (usually made of metal wire) laid under the tread, not attached to the board, spiraling along the circumference along the tread and having cord angles ranging from 0 degrees to 5 degrees relative to equatorial plane of the tire.

The method according to this invention relates to a variant of a very large tire with a tread band (such as tires with a diameter of 3.05 m used on very large vehicles such as mining trucks). The method does not depend on the specific design of the removable tread band and the corresponding frame. Although the construction of a particular very large tire is described below to illustrate an embodiment of the method of the invention, the method should not be limited to this particular tire design.

Figure 1 shows a cross section of a portion of a very large pneumatic tire 10 with a tread band, which in the particular embodiment shown is a mining truck tire of size 70 / 68R63. A tire of size 70 / 68R63 has a maximum outer diameter (OD) in the inflated condition of 411.45 cm, a maximum width in the inflated state in the axial direction of 177.8 cm, and a nominal bead diameter of 160.02 cm. Tread band 12 has a thickness (t) of approximately 25.4 cm and a width of approximately 165.1 cm. The assembled tire 10 weighs 7256 kg, of which approximately 3628 kg relates to a removable tread band 12. The carcass 14 of the tire is usually inflated and sometimes a mixture of air and nitrogen to d phenomenon of around 686 kPa. A very large pneumatic tire 10 with a tread band includes a tread band 12 that comes into contact with the ground and extends around the circumference and is mounted on a radially reinforced and bead carcass 14 of the tire. The tire bead carcass 14 typically includes sidewalls 16 of the tire extending radially inward from the outer annular surface 20 of the carcass 14 of the tire and ends at a pair of bead cores 22. Each sidewall 16 has an upper part 16a located in the shoulder region of the tire carcass 14 and radially outside the maximum sectional width of the tire carcass 14, and a lower part 16b located near the bead cores 22 and radially inside of the maximum sectional width of the carcass 14.

Most of the details of the tire carcass 14 are not related to the method of the present invention and will not be described, except that the carcass 14 usually comprises at least one rubberized laminate layer 34 of the tire cord fabric. The frame 14 is mounted on the mounting rim 42 of the wheel, it is pneumatically sealed in the area of the bead 22, resting against the flange 35 and holding it in place, and the flange can usually be removed from the rim 42 on the wheels used for very large tires 10.

An additional feature is generally included in the tire structure 10 with a removable tread band to facilitate holding the removable tread band 12 in place on the chassis 14. This additional feature, shown in FIG. 1, contains a set of one or more grooves 78 and one or more protrusions 76 formed on the outer annular surface 20 of the frame 14.

A tire tread band 12 which is engaged with the ground and circumferentially circumferential is mounted on the tire carcass 14. At least the tire tread band 12 comprises a tread portion 80 and at least one tape 82, 84, 86 and / or 88 (82- 88) or a set of cords 90 located at an angle of 0 degrees, which extend around the circumference of the tire tread and are intended to limit the expansion of the tread band 12 radially outward. The location and configuration of the cords 90 and / or tapes 82-86 are the subject of other patents and are not essential for the method corresponding to this invention.

An additional feature of the embodiment of the tread band 12 shown in FIG. 1 comprises one or more annular protrusions 72 and one or more annular grooves 74 located on the lower side or inner annular surface 70 of the tread band 12, which engage with the corresponding grooves 78 and protrusions 76 on the tire carcass 14 to prevent the tread band 12 from moving laterally or axially with respect to the carcass 14.

Until the recent advent of the significantly larger "very large" pneumatic tires, there was a very slight need for options for these tires with a removable tread band. The present invention has identified a new category of problems related to very large tires and provides methods for transporting, storing and replacing very large tires according to which tire designs with a removable tread band are used to solve transportation, storage and replacement problems that are unique to this category of tires.

When the pneumatic tires become so large that they cannot be transported by conventional means, the transportation method according to the present invention proposes the use of tires with a removable tread band (e.g. 10) and the transportation of the tread band 12 separately from the tire carcass 14. Regardless of how they are prepared for transportation, the very separation of the tread band 12 from the frame 14 can significantly reduce the weight and size of the transported items. With respect to the example shown in FIG. 1, the total tire diameter decreases from a total outer diameter of the tire of about 4.11 m to about 3.61 m, i.e., the outer diameter of the tire carcass 14. Similarly, the weight of the entire tire of 7256 kg is divided into approximately 3268 kg of the weight of the carcass 14 and approximately 3268 kg.

The separated tread band 12 in preparation for transportation can be compressed to produce different smaller sizes. A preferred embodiment 200 is shown in FIG. 2A, where the tread band is compressed in a diametrical direction and held in a compressed state by one or more couplers 210 (210a, 210b, 210c, 210d, 210e) made of steel or other suitable mounting material, such as plastic , fabric, rope or chain. To prevent flattening of the tread band 12 and potential damage to the band due to excessive bending of the ends 212a and 212b, a spacer element 220 is placed inside the tread band 12. The ties 210 hold the tread band 12 in a compressed state on diametrically opposite sides of the spacer element 220, and the spacer element 220 has a design such that the compressed configuration of the tread band 12 is preferably an elongated oval with straight sides with a height ratio (H) to a length (L) of at least 40%. This minimum height-to-length ratio is intended to prevent damage to the wristband due to excessive bending of the ends 212a and 212b of the tread band 12. The spacer element 220 is made using known techniques and materials suitable for holding the weight and forces arising from transporting the tread band 12. For example , wooden or metal structures or preformed plastic structures could be used to provide a spacer about an element that does not have any sharp edges that could damage the surface of the tread band 12. The dimensions of the spacer element are such that it will support the tread band 12 for about 40% -70% of its length L in a compressed state, at least 50% the width W of the tread band and will also provide the above minimum height to length ratio.

For ease of handling, the compressed tread band 12 is preferably attracted to a lower pallet 230 having dimensions suitable to support at least the entire width W and at least the length Lf of the flat side of the compressed tread band 12. The pallet 230 is made using known techniques and of suitable known materials for the manufacture of the pallet and has a structure capable of withstanding the expected weights and forces arising during transportation.

An upper deck 232, similar to a lower pallet 230, can optionally be positioned above a compressed tread band 12 and held in place by couplers 210. Through the use of a pallet 230 and a deck 232 with ties 210 covering the bottom pallet 230 from below and the upper deck 232, tread band 12 protected against damage due to contact with screeds 210.

FIG. 2B shows an alternative embodiment 250 of a tread band 12 of a very large tire prepared for transport in a compressed state. This alternative embodiment 250 retains the same configuration and overall dimensions of the compressed tread band as in the preferred embodiment 200, but the tread band 12 is laid on its side. Although the spacer element 270 is also used here inside the tread band 12 to maintain the same minimum height to length ratio of the tread band 12, the spacer element 270 may have less strength since it no longer holds the weight of about half of the tread band 12 (or even more if compressed tread bracelets should be stacked). The lower pallet 280 has a width Wp that is greater than the height H or approximately equal to the height of the compressed tread band 12, and a length Lp that is at least equal to the length Lf of the flat side, but preferably equal to the length L of the compressed tread band 12. One or more ties 260 (260a, 260b, 260c) surround the tread band 12 and the lower tray 280 to hold the tread band 12 in a compressed state around the spacer element 270. An upper deck 282, similar to the lower pallet 280, may optionally be located above the compressed tread band gathering of 12 and held in place by tie rods 260. Through the use of the pallet 280 and the deck 282 with couplers 260, covering the bottom of the bottom tray 280 and top of upper deck 282, a tread band 12 is protected from damage by contact with ties 260.

3A and 3B show a possible method 300 for transporting a carcass 14 of a very large tire. This method is not necessary since the overall outer diameter of the OD tire is substantially reduced by using the design 10 with the removable tread band of a very large tire according to this invention. In addition, the degree of diametrical compression possible for tire 10 or tire carcass 14 is severely limited by the stiffness of the carcass sidewalls 16 and beads 22. However, if the very large tire 10 is so large that even a reduced diameter of the carcass 14 of the tire causes transportation problems, the carcass diameter 14 of the tire can be reduced to some extent by compressing it with ties 310 (310a, 310b), which are superimposed over the diameter of the tire carcass. Like the tie wraps 210, 260 of the tread band, the ties 310 may be made of any suitable material such as steel, plastic, canvas, rope or chains. If the selected material for the screeds is found to be excessively abrasive or has sharp edges, suitable gaskets should be placed between the screeds 310 and the tire carcass 14.

As best shown in the cross-section in FIG. 3B, between the tie rods 310 and the tire carcass 14, auxiliary end caps 315 may be located. The end caps 315 may be plywood or other rectangular elements made of wood, plastic or metal having suitable stiffness, which have a length Lc approximately equal to the length of the flattened portion of the compressed tire carcass 14, and a width Wc that is equal to the width of the convex sidewalls 316 (316a, 316b, 316c, 316d) or slightly larger. Since the bead cores 22 are much more rigidly circular in shape than the rest of the tire carcass 14, when the tie bars 310 compress the tire carcass 14, the sidewalls tend to wrinkle, and it is preferable to allow them to bend laterally outward with respect to the equatorial plane of the tire. Outward inflation is the natural direction of movement of the sidewall of the tire, and as such causes minimal strain on the carcass 14. The end caps 315 hold the ties 310 laterally outside the sidewalls 316, thereby allowing the sidewalls 316 to inflate in the most natural way for them under the action of diametric compression forces attached by couplers 310. Dimensions (Lc x Wc) of end caps 315 are determined empirically because they depend on the individual tire carcass 14 and its response to the amount of compression force applied removed by screeds 310, when screeds 310 compress the frame 14 to the diameter Dc required for transport.

The transportation methods described above were illustrated by options 200, 250, 300, which include ties 210, 260, 310 for holding the tread bracelets 12 and tire carriages 14 in a compressed state. Having obtained the transportation method described herein, one skilled in the art can provide alternative means for holding the tread band 12 and the tire carcasses 14 in a compressed state, such as using a tightening box structure around some or all of the parts of one or more tread bands 12 or a tightening box around some or all parts of one or more carcasses of 14 tires.

The method according to the present invention includes the use of tires 10 with a removable tread band for very large vehicles requiring very large tires on the job site. It is estimated that a newly developed carcass of 14 very large tires will last an average longer than four newly developed removable tread bracelets of 12 very large tires in typical difficult working conditions on work sites typical of very large tires (e.g. quarries). This implies that four times less frames 14 are required to be stored on the job site compared to tread bracelets 12. Since tread bracelets 12 occupy significantly less storage space than frames 14, the use of a very large tire design with a removable tread bracelet provides significant storage advantages . These advantages provide savings in storage and transportation, since tread bands 12 are less expensive to purchase, and their transportation is cheaper compared to frames 14 and conventional very large tires.

The ratio of space / cost savings of the tread bands 12 and the carcasses 14 (or conventional tires) is further improved if the work platform requires different types of treads for different driving conditions. While this was not feasible for ordinary tires, the use of removable tread bracelets 10 allows you to store additional tread bracelets 12 of different types on the job site for one number of frames 14 in stock and, thus, turn the frames 14 into universal frames that can be used to form a set very large tires 10 for different purposes.

4 shows a method 400 for storing very large tires 10 with a removable tread band in a typical storage area at a work site. A relatively small number of tire carcasses 414 and a relatively large number of tread bands 412 (412a, 412b, 412c, 412d, 412e) are stored. A portion of the tread band 412a is stored as it was transported. Other tread bands 412b ... 412e are stacked in a slightly compressed state. The tread bracelets 412 have different tread patterns. For example, tread bracelets 412b, 412c of normal width are shaped as lugs to work on gravel or in dry weather and mud. The 412e tread band has a wider tread with deep grousers for conditions with viscous soil, such as in rainy weather. The wider tread band 412e is designed to be mounted on the same frame 414 to which other tread bands 412 are mounted. The tread band 412d has a tread pattern suitable for steered wheels rather than drive wheels.

The use of very large tires 10 with a removable tread band for very large vehicles on the job site according to the method of the invention makes the tire replacement process much more cost-effective. When using conventional very large tires, the very large tire on the wheel should be removed from a very large vehicle, then the first tire should be removed from the wheel and replaced with a second tire, and then the second tire on the wheel should be mounted on a very large vehicle. This method of replacing tires usually takes 5-6 hours to replace one tire.

FIG. 5A shows an embodiment 500 of an improved tire replacement method according to the present invention, according to which tires 10 with a removable tread band are used and which require approximately 1 hour to replace the tread band. Saving time (and money) using this method 500 provides that only the tread band needs to be replaced, as will usually be the case in this case, especially for the newly developed very large tires 10 with the tread band, which include design features of the tread band 12 that protect the carcass from punctures and cuts, and signs of the structure of the frame 14, which increase the durability of the frame in extreme conditions of load and bending. If the carcass is damaged or worn out, then the usual labor-intensive method of replacing the tire to replace the carcass 14 will be required. For the newly developed very large tires 10 with a replaceable tread band, it is assumed that at least 3 out of 4 cases of tire change will only require a tread band change 12.

In an embodiment 500 of a method for replacing a very large tire according to the present invention, a tire 510 having a first tread band 512a to be replaced should be positioned so that the first tread band 512a is brought out of contact with a bearing surface such as ground 537. In this As an example, the necessary part of a very large vehicle 525 is lifted on a jack 539 (for example, a pneumatic jack). Then, in the carcass 514 holding the first tread band 512a to be replaced, the pressure is at least partially reduced until the first tread band 512a is freely positioned on the tire carcass 514. Then, the first tread band 512a is removed laterally from the tire carcass 514 using any suitable non-damaging tools and hardware (e.g., crowbar, hooks, chains, ropes). As shown in FIG. 5A, one or more chains 533 (533a, 533b) are attached to the first tread band 512a and apply lateral force, for example, by hand or with a forklift (not shown). In a preferred method, one could first pull one part of the first tread band 512a (for example, a part closer to the ground 537) and then pull or remove the remaining parts of the first tread band 512a.

The replacement second tread band 512b can now be moved laterally onto the tire carcass 514. This is preferably done using a crane or a forklift (not shown) to raise the top of the second tread band 512b to the level of the top surface of the chassis 514 in close proximity to the chassis 514. Using suitable tools, including, for example, forklift attachments (not shown) ), the upper part of the second tread band 512b is moved laterally (for example, pushed) onto the upper surface of the frame 514. When the upper part of the second tread band 512b is moved laterally, the rest of the second tread band 512b can be pushed so as to follow the lateral movement of the upper part of the second tread band 512b until the entire tread band 512b is correctly circumferentially mounted around the outer annular surface 20 of the tire carcass 514. Such a proper arrangement includes laterally aligning the outer edges of the second tread band 512b with respect to the laterally outer edges of the upper parts 16a of the side walls 16 of the chassis 514; and also includes aligning and engaging any grooves 74, 78 and any corresponding protrusions 72, 76 (if used) on the reciprocal mesh annular surfaces 70, 20 of the second tread band 512b and the tire carcass 514.

Finally, the tire carcass 514 is preferably inflated to the required pressure or is inflated at least enough to ensure that the inner annular surface 70 of the second tread band 514b exactly matches the outer annular surface 20 of the carcass 514. The replacement of a very large tire is completed, and a very large vehicle can be brought into operation by lowering to the ground 537, for example, by lowering and removing the pneumatic jack 539.

FIG. 5B shows an alternative 550 of an improved tire replacement method according to the present invention, in which tires 10 with a removable tread band are also used and fewer devices are required than in the first embodiment 500. As in the first embodiment 500, in the alternative embodiment 550 significant time and cost savings are possible in most cases when only the tread band 12 needs to be replaced.

An alternative method eliminates the need to lift a very large vehicle 525. The first step in the tire replacement method now is to partially lower the pressure in the tire carcass 514 until the first tread band 512a is freely positioned on the carcass 514. The following step of laterally removing the first tread band 512a from the tire carcass 514 using suitable tools is modified to include laterally removing at least the front part 512a1 of the first tread band 512a (for example, retracting the chain 533a1) and then essentially "rolling out" the carcass 514 of the first tread band 512a. The “rolling out” process comprises rolling the chassis 514 in the forward direction 561 (moving a very large vehicle 525 in the forward direction 563) while applying lateral force (for example, one or more chains 533a1) to at least the front portion 512a1 of the first tread band 512a in the direction 565, thus causing the first tread band 512a to roll in a spiral fashion from the tire carcass 514. The rolling process is completed when the first tread band 512a is spirally rolled so that the tire carcass 514 overlaps the bearing surface 537 (e.g., ground) without any part of the first tread band 512a between the carcass 514 and the bearing surface 537. At this moment, the movement 563 of the very large vehicle 525 may stop, and then the remaining parts (if any) of the first tread band 512a may be removed laterally from the frame 514.

The following lateral movement of the second (replacement) tread band 512b onto the tire carcass 514 using suitable tools is modified to include “rolling” the second tread band 512b into the second tread band, that is, reversing the previous removal process according to alternative method 550. Using suitable means, such as a forklift with pushing devices (not shown), the second tread band 512b is lifted and pushed onto the top of the tire carcass 514 so that the second otektorny bracelet 512b overlaps at least part of the upper portion 514a2 and the tire carcass 514 is at least partially retained by it; and the second tread band 512b is also pushed and / or rotated so that at least a portion of the second tread band 512b covers a portion of the front portion 514a1 of the tire carcass 514. Now, the tire carcass 514 can "roll" into the second tread band 512b by rolling the carcass 514 of the tire 561 in the forward direction (moving the very large vehicle 525 in the 563 direction forward) while applying lateral force to at least the front portion 512a1 of the second tread band 512b in an overlapping direction 566, thereby causing the second tread band 512b to spirally roll onto the rolling tire carcass 514. The rolling process is completed when the second tread band 512b is spirally rolled so that the tire carcass 514 is located on the second tread band 512b, which is located between the carcass 514 and the bearing surface 537 (e.g., ground), without entering any part of the carcass 514 in contact with the bearing surface 537, and the second tread band 512b is close to the correct position on the tire carcass 514 in the lower part 514a3 of the carcass 514. Due to the spiral movement of the second tread band 512b, the circular plane of the second tread band 512b may remain at a slight angle to the circular plane of the tire carcass 514 and thus, when the tire carcass 514 continues to roll, the corresponding parts of the second tread band 512b should now be pushed or pulled into laterally so as to rotate it to align two circular planes at least where the second tread band 512b comes into contact with the ground. Steering the steering wheel of a very large vehicle 525 can help to cause the tire carcass 514 to rotate into a second tread band 512b. At this point, the movement in direction 563 of the very large vehicle 525 can be stopped, and then the remaining parts (if any) of the second tread band 512b can be moved to the tire carcass 514 and aligned so that the tread band 512b is correctly set to carcass 514 tires. Subsequent inflation of the tire carcass 514 to the proper pressure completes an alternative 550 of the very large tire replacement method of the invention.

Due to the relative simplicity of the new methods of storing and replacing the tread band 12 for very large tires 10, this invention makes it possible to replace the tread band 12 for using different types of treads (for example, the tread band 412b, 412c, 412d, 412e) to suit different working conditions, such as different conditions of the bearing surface 537 (for example, caused by changes in the environment: wet / dry, summer / winter, dirt / snow / dry), or such as different applications for very large vehicles 525 (e.g. Emer, usage on gravel, dirt, sand, rough terrain or paved road, driving at a high speed driving with low speed).

Although the invention has been illustrated and described in detail in the drawings and in the previous description, they should be considered as illustrative and not limiting in nature, and it should be understood that only preferred options have been shown and described, and all changes and modifications that are consistent with the essence of the invention, must be protected. Undoubtedly, a specialist in the field of technology, to which the present invention most closely relates, will be presented with many other modifications according to the above "subject", and these options are considered as falling within the scope of the invention described here.

Claims (6)

1. A method of transporting very large pneumatic tires having diameters (OD) of more than 3.05 m, in which a very large tire comprises an inflated tire carcass and a removable tread band surrounding the tire carcass and corresponding to the tire carcass when the tire carcass is inflated, characterized in that the following operations are carried out: transporting the tread band separately from the tire carcass and holding the two diametrically opposite sides of the tread band while transporting in a compressed state, thereby reducing the distance e (n) between the two diametrically opposite sides of the tread band. 2. The method according to claim 1, characterized in that the following operations are carried out: a spacer element is placed inside the tread band and the tread band is pulled together so that two diametrically opposite sides of the tread band are held on the spacer element, configuring the tread band in the form of an elongated oval with straight parties in a compressed state. 3. The method according to claim 1, characterized in that the two diametrically opposite sides of the tire carcass are held in a compressed state during transportation, thereby reducing the distance (Dc) between the two diametrically opposite sides of the tire carcass. 4. A method for replacing very large pneumatic tires having diameters greater than 3.05 m, in which a very large tire contains an inflated tire carcass, and a removable first tread band surrounding the tire carcass and having an inner annular surface that exactly matches the outer annular surface of the tire carcass when the tire carcass is inflated, characterized in that the following operations are carried out: (a) at least partially lowering the pressure in the carcass of the tire mounted on a very large vehicle, so that your tread band remains in a weakened state on the tire carcass; (b) laterally moving the first tread band from the tire carcass by pulling the tread band from the carcass laterally; (c) laterally moving the second tread band onto the tire carcass; (a) the second tread band is correctly positioned with its inner annular surface around the outer annular surface of the tire carcass and (e) inflating the tire carcass to obtain an exact match between the inner annular surface of the second tread band and the outer annular surface of the tire carcass. 5. The method according to claim 4, characterized in that in operation (b) the following operations are carried out: first, at least part of the first tread band is removed laterally from at least the front of the tire carcass, then the tire carcass is rolled forward when applied lateral force to the first tread band in the direction of removal until the tire carcass rolls out of the first tread band and rests on the bearing surface in the absence of any part of the first tread band between the carcass and the carrier along surface, and then laterally remove the remaining parts of the first tread band from the tire carcass, and in operation (c) perform the following operations: first, at least part of the second tread band is moved to at least the front of the carcass, then the tire carcass is rolled forward when applying lateral force to the second tread band in the direction of application at least until the carcass rolls into the second tread band and lies on the bearing surface when ii second tread band between the tire carcass and the supporting surface, and is then moved laterally rest of the tread band to the tire carcass. 6. The method according to claim 4, characterized in that before operation (a) a very large vehicle is positioned so that the first tread band is removed from contact with the bearing surface, and the replaced tire no longer carries a load, and after operation (d) it is very the large vehicle is positioned so that the second tread band is brought into contact with the bearing surface, and the replaced tire carries a normal proportion of the load.

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