JP2006160039A - Elastic crawler - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an elastic crawler maintaining durability by preventing cutting of a tension body buried in a range of crawler width direction passing through with an idler. <P>SOLUTION: In the coreless elastic crawler 1 driven in a crawler circumferential direction while restricting deviation of a position in a crawler width direction relative to the idler 4 passing between a pair of left and right projections 6, circumferential tensile force of the elastic crawler 1 is ensured by the tension body 9 buried in the range of the crawler width direction passing with the idler 4. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an elastic crawler used in various crawler type traveling devices.

Crawler type traveling devices are currently widely used in agricultural machines such as combine machines and construction work machines such as backhoes, and various elastic crawlers are mounted on these crawler type traveling devices. Among these, as a coreless elastic crawler, a drive sprocket that passes between a pair of left and right projections protruding from the inner peripheral surface of the crawler body is sandwiched between the projections and driven in the crawler circumferential direction by the frictional force. Are known (see, for example, Patent Document 1).
JP-A-6-107251 (FIG. 4)

When the elastic crawler of Patent Document 1 is wound around the drive sprocket and idler, a tensile force is applied in the crawler circumferential direction, but the drive sprocket contacts the inner peripheral surface of the crawler body between the protrusions. Tensile strength concentrates on the buried central tensile body. Since the tensile strength in the circumferential direction of the elastic crawler is ensured by combining the tensile member in the central part with other tensile members distributed to the left and right, excessive tensile strength is applied to the tensile member in the central part. If the strength is insufficient, cutting will occur. As shown in FIG. 5, the problem is that the tensile body 51 is embedded on both the left and right sides of the protruding portion, and the elastic crawler 50 in which the idler 60 passes between the protruding portions 52 is too large in the central tensile member. It can happen in the same way by applying high tensile strength.
Therefore, in view of the problems of the prior art, the present invention is to obtain an elastic crawler that maintains durability by preventing cutting of a tensile body embedded in a crawler width direction range through which an idler or the like passes. Objective.

In order to achieve the above object, the present invention takes the following technical means.
That is, the present invention provides a crawler main body made of an endless belt-like rubber-like elastic body in which a pair of left and right protrusions arranged at regular intervals in the circumferential direction of the crawler project integrally from the inner peripheral surface, and the outer peripheral surface of the crawler main body A lug group formed in a predetermined lug pattern and a tensile body embedded along the circumferential direction of the crawler inside the crawler body, and in the crawler width direction with respect to the idler passing between the protrusions. In a coreless elastic crawler that is driven in the crawler circumferential direction while displacement is restricted, the tensile body embedded in the crawler width direction range through which the idler passes ensures the circumferential tensile strength of the elastic crawler. It is characterized by having such strength.

  According to the elastic crawler of the present invention, the tensile body embedded in the crawler width direction range through which the idler passes has a strength that ensures the tensile strength in the circumferential direction of the elastic crawler. Even if the tensile strength concentrates in the crawler width direction range through which the web passes, the strength of the tensile body does not become insufficient. Thereby, in the case where the elastic crawler is used in the crawler type traveling device in which the idler passes between the pair of left and right protrusions, the tensile body is prevented from being cut, so that the durability of the elastic crawler can be maintained.

Moreover, it is preferable that the tensile body is embedded only in a crawler width direction range through which the idler passes. In this way, the number of steel cords and the like constituting the tensile body can be reduced, so that the cost can be suppressed.
Further, the tensile body includes a main tensile body embedded in a crawler width direction range through which the idler passes and sub-stretch bodies embedded on both the left and right sides of the main tensile body in the crawler width direction. It is good. In this case, since the wider range of the crawler body is reinforced and the rigidity thereof is increased, cutting of the crawler body can be prevented.

  It is preferable that the sub tensile body has a smaller strength than the main tensile body. In this case, the rigidity of the overlapping portion of the circulating sub-strength body is reduced, so that it is possible to prevent the loss of horsepower and the steel cords constituting the main and sub-strength bodies. Further, by extending the protrusion to the end of the crawler body, the thickness of the crawler body may be increased to increase the rigidity of the crawler body.

  As described above, according to the present invention, since the strength of the tensile body embedded in the crawler width direction range through which the idler and the like pass is increased, the cutting is prevented and the durability can be maintained.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows an elastic crawler 1 according to the first embodiment of the present invention, and FIG. 2 shows a crawler type traveling device 2 using the elastic crawler 1. The crawler type traveling device 2 is used for an agricultural machine, a construction work machine, or the like, and is arranged between a driving sprocket 3 and an idler 4 provided before and after the traveling machine body, and between the driving sprocket 3 and the idler 4. It is comprised by the wheel group comprised by the provided several wheel 5, and the elastic crawler 1 wound around these wheels 5. FIG. The drive sprocket 3 that drives the elastic crawler 1 is provided with a pair of rotationally driven disks arranged in the left-right direction, and left and right drive pins spaced apart in the circumferential direction between the disks. (Not shown).

  The elastic crawler 1 is configured as a coreless, and includes a crawler body 7 having a pair of left and right protrusions 6 formed at intervals in the crawler circumferential direction, and a predetermined lug on the outer circumferential surface of the crawler body 7. A lug group 8 formed in a pattern and a tensile body 9 embedded to restrict the extension of the crawler body 7 are provided. The wheel 5 provided in the crawler type traveling device 2 has a pair of left and right circular wheel portions that are coaxially integrated at a constant interval in the crawler width direction of the crawler body 7. The part is a matagi wheel that spans the protrusion 6 in between.

  The crawler body 7 is formed into an endless belt having a substantially constant thickness by an elastic body made of rubber, and the pair of left and right projections 6 are made of an elastic body made of the same material as the crawler body 7, and the inner circumference of the crawler body 7 It protrudes from the center of the surface in the crawler width direction. By engaging the drive pins of the drive sprocket 3 with these protrusions 6, the elastic crawler 1 is driven along the crawler circumferential direction. Further, as shown in FIG. 1, the idler 4 is positioned so as to pass between the protrusions 6 and has a thickness that is substantially the same as the dimension between the protrusions 6, and the position of the elastic crawler 1 in the crawler width direction. The deviation is regulated. The plurality of lugs 8 formed on the outer peripheral surface of the crawler body 7 at a predetermined interval in the circumferential direction are formed in a single letter shape extending in the crawler width direction.

  The tensile body 9 is embedded only in the crawler width direction range through which the idler 4 passes between the protrusions 6 and circulates endlessly along the entire circumference of the crawler in the circumferential direction. Further, since the thickness of the idler 4 is substantially the same as the dimension between the protrusions 6, the crawler width direction range in which the tensile body 9 is embedded is also the crawler width direction range between the inner wall surfaces of the protrusions 6. It corresponds. That is, the tensile body 9 is not embedded over both ends of the crawler body as in the prior art, but is embedded only in the crawler width direction range through which the idler 4 passes. The number of tensile cords 9A (described later) to be performed is significantly smaller than that of the conventional.

  The tensile body 9 is configured by arranging a number of tensile cords 9A made of steel cords or the like extending along the crawler circumferential direction, and surrounding these with unvulcanized rubber. Since one tensile cord 9A is formed in an annular shape by overlapping both ends thereof inside the crawler body 7 (lap joint), the elastic crawler 1 is wound around the drive sprocket 3 and the like. When bent, tensile strength in the crawler circumferential direction acts on the tensile body 9. Further, the tensile body 9 has such a strength that the tensile strength in the crawler circumferential direction is ensured only by the tensile body 9, and therefore the tensile cord 9A has a larger wire diameter than the conventional one. Is used. When the elastic crawler 1 is wound around the drive sprocket 3 and the idler 4, the idler 4 comes into contact with the crawler body 7 between the protrusions as shown in FIG. Although concentrated, the tensile body 9 located here has a sufficient strength to ensure the tensile strength, so that the tensile body 9 can be prevented from being cut.

  Examples of the tensile cord 9A include, for example, a steel cord obtained by combining several steel filaments and several bundles, a nylon cord composed of filaments such as nylon and tetron, a tetron cord, and other aramid fiber cords A glass fiber cord or the like is employed. As the tensile body 9 of the present embodiment, a cord wrap configured by arranging a number of end-tensioned tensile strength cords 9A wound around the crawler circumferential direction in parallel in the crawler width direction. Although the structure of the system is adopted, one tensile cord is wound spirally (one tensile cord is wound several times in the crawler circumferential direction while shifting the position in the crawler width direction) It is also possible to adopt a seamless spiral structure constituted by the above.

  According to the elastic crawler 1 of this embodiment, the tensile body 9 embedded in the crawler width direction range through which the idler 4 passes has such strength that the tensile strength in the circumferential direction of the elastic crawler 1 is ensured. Therefore, even if the tensile strength is concentrated in the crawler width direction range through which the idler 4 passes, the strength of the tensile body 9 does not become insufficient. Therefore, when the elastic crawler 1 is used for the crawler type traveling device 2 in which the idler 4 passes between the pair of left and right protrusions 6 as in the present embodiment, the tensile body is insufficient in strength as in the prior art. The elastic crawler 1 can be maintained in durability since cutting of the tensile body 9 is prevented.

  FIG. 3 shows a second embodiment of the elastic crawler 20 according to the present invention. This embodiment is different from the above embodiment in that in addition to the same central tensile body (hereinafter referred to as main tensile body 9) as in the above embodiment, another tensile body (hereinafter referred to as sub-tension body). 10)). Therefore, the tensile body of this embodiment is composed of a main tensile body 9 and a sub-tension body 10. In addition, the part which is common in the said embodiment attaches | subjects the same code | symbol, and abbreviate | omits the description. The sub-strength body 10 is embedded on both the left and right sides of the main tensile body 9 in the crawler width direction so as to be close to the main tensile body 9, and in a range corresponding to the raceway surface on the inner peripheral surface of the crawler body 7. Crossing. The sub-tension member 10 is composed of a tensile cord 10A (steel cord) made of the same material as the tensile cord 9A (steel cord) of the main tensile member 9, and the wire diameter thereof is the tensile cord 9A of the main tensile member. Is smaller than

  Specifically, the wire diameter ratio of the sub tensile body and the main tensile body is 3: 5. Accordingly, the rigidity of the portion in which the sub-strength body 10 is embedded is smaller than the portion in which the main tensile body 9 is embedded. Thus, since the sub-strength body 10 having a smaller wire diameter is embedded on both the left and right sides of the main tension body 9, the rigidity of the crawler body 7 outside the protrusion 6 is increased. Cutting or the like can be prevented. Further, the rigidity of the overlap portion of the sub-strength body 10 that circulates in the crawler circumferential direction is reduced, so that it is possible to prevent a horsepower loss and the pull out of the tensile strength cords 9A and 10A.

  FIG. 4 shows a third embodiment of the elastic crawler 30 according to the present invention. The main difference between this embodiment and the second embodiment is that a pair of left and right projections 11 are extended to the edge 7a of the crawler body. Therefore, the wheel is a medium wheel type. The protrusion 11 extends from the portion of the crawler body 7 through which the idler 4 passes to the edge 7a, and the end 11a becomes a tapered surface that inclines toward the outer periphery of the crawler as it goes outward in the crawler width direction. ing. Further, the sub-strength bodies 12 embedded in the left and right sides of the main tensile body 9 embedded in the crawler width direction central portion are made of the same steel cord as that of the second embodiment, and the main tensile body 9 It is embedded in a place separated outward in the crawler width direction. The sub-strength body 12 is configured with substantially the same width as the main tensile body 9.

  The elastic crawler 30 configured in this manner can further improve its durability because the rigidity of the crawler body 7 is increased by the sub-strength body 12 and the extended protrusion 11. In addition, the crawler type traveling device to which the elastic crawlers 20 and 30 according to the second and third embodiments are attached contacts the crawler main body 7 at substantially the same crawler width direction position as the idler 4 passing between the protrusions 6 and 11. Such a drive sprocket 3 is preferably provided. This is because if the idler 4 and the drive sprocket 3 are in contact with the crawler main body 7 at the same crawler width direction position, the sub-strength bodies 10 and 12 are less likely to be displaced in the crawler thickness direction with respect to the main tensile body 9.

It is width direction sectional drawing of the elastic crawler which concerns on 1st Embodiment. It is a side view of a crawler type traveling device. It is width direction sectional drawing of the elastic crawler which concerns on 2nd Embodiment. It is width direction sectional drawing of the elastic crawler which concerns on 3rd Embodiment. It is sectional drawing of the width direction of the conventional elastic crawler.

Explanation of symbols

3 Drive sprocket 4 Idler 6, 11 Protrusion 7 Crawler body 9 Tensile body (main tensile body)
10, 12 Sub tensile body

Claims (5)

A crawler body made of an endless belt-like rubber-like elastic body in which a pair of left and right protrusions arranged at regular intervals in the circumferential direction of the crawler project integrally from the inner circumferential surface, and a predetermined lug pattern on the outer circumferential surface of the crawler body The formed lug group and a tensile body embedded in the crawler circumferential direction inside the crawler main body are provided, and positional deviation in the crawler width direction with respect to the idler passing between the protrusions is regulated. In the core-less elastic crawler driven in the crawler circumferential direction,
An elastic crawler, wherein a tensile body embedded in a crawler width direction range through which the idler passes has a strength that ensures a tensile strength in a circumferential direction of the elastic crawler.   The elastic crawler according to claim 1, wherein the tensile body is embedded only in a crawler width direction range through which the idler passes.   2. The tensile body comprises a main tensile body embedded in a crawler width direction range through which the idler passes, and sub-stretch bodies embedded on both left and right sides of the main tensile body in the crawler width direction. Elastic crawler as described in.   The elastic crawler according to claim 3, wherein the sub-tension member has a smaller strength than the main tensile member.   The elastic crawler according to any one of claims 1 to 4, wherein the protrusion extends to an edge of the crawler body.

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