Rubber Sheet Member Joining Device and Method

Abstract

Provided are a rubber sheet member joining device and method. At least one opposing surface of a pair of gripping parts is provided with a contact member having a contact surface projecting toward an other opposing surface of the pair of gripping parts; the pair of gripping parts grip ranges in proximity to end surfaces in a state in which end surfaces project from the one opposing surface toward the other opposing surface; the total of end surface projection amounts of the end surfaces from the opposing surfaces is set to be a predetermined length larger than a separation distance between the opposing surfaces when the contact member is sandwiched between the opposing surfaces; and by bringing the contact member into a state of being sandwiched between the opposing surfaces, the movement of the gripping parts in proximity to each other is stopped and the end surfaces are joined together.

Claims

1. A rubber sheet member joining device, comprising: a pair of gripping parts for gripping, respectively, ranges in proximity to end surfaces of rubber sheet members to be joined, the rubber sheet members being unvulcanized; a drive unit that moves at least one of the pair of gripping parts in a direction approaching and separating from each other; and a control unit for controlling operation of the pair of gripping parts and operation of the drive unit, the rubber sheet member joining device being configured such that: at least one opposing surface of the pair of gripping parts comprises a contact member with a contact surface projecting toward an other opposing surface of the pair of gripping parts; when the pair of gripping parts are in close proximity to each other, the contact member is in a state of being sandwiched between the opposing surfaces, and movement of the pair of gripping parts in proximity to each other is stopped; the ranges in proximity to the rubber sheet members are gripped, respectively, in a state in which the end surfaces project from the one opposing surface toward the other opposing surface of the pair of gripping parts, respectively; and a total end surface projection amount of the end surfaces from the opposing surfaces, respectively, is set to be larger by a predetermined length than a separation distance between the opposing surfaces when the contact member is in a state of being sandwiched between the opposing surfaces and movement in proximity to each other is stopped.

2. The rubber sheet member joining device according to claim 1, wherein the contact members are provided, respectively, on the opposing surfaces to be attachable or detachable, and when the pair of gripping parts come in close proximity to each other, the contact members are configured to come into contact with each other to stop movement of the pair of gripping parts in proximity to each other.

3. The rubber sheet member joining device according to claim 1, wherein the contact members are attachable to and detachable from the pair of gripping parts comprising the contact members.

4. The rubber sheet member joining device according to claim 1, wherein the contact surface has a lower kinetic friction coefficient than the opposing surface, and no lubricating oil is used.

5. The rubber sheet member joining device according to claim 1, further comprising an adjustment mechanism for adjusting a contact surface projection amount of the contact surface of the contact member that is gripped by the pair of gripping parts, respectively, from the opposing surface of the pair of gripping parts.

6. The rubber sheet member joining device according to claim 5, further comprising a projection amount sensor configured to detect the contact surface projection amount, wherein a position of the contact member is configured to be adjusted by the adjustment mechanism such that the contact surface projection amount detected by the projection amount sensor is within a preset target range.

7. The rubber sheet member joining device according to claim 5, further comprising a state sensor that determines a state of a joint portion where the end surfaces are joined together, respectively, wherein a projection amount in a thickness direction of the joint portion is calculated based on data determined by the state sensor; and a position of the contact member is configured to be adjusted by the adjustment mechanism so that the projection amount in the thickness direction of the joint portion between the end surfaces to be joined next is within a preset permissible range.

8. A rubber member joining method for joining end surfaces of rubber sheet members by gripping, respectively, ranges in proximity to end surfaces of the rubber sheet members to be joined by a pair of gripping parts, the rubber sheet members being unvulcanized, and by moving at least one of the pair of gripping parts in a direction approaching each other; the rubber member joining method comprising steps of: installing a contact member having a contact surface projecting toward an other opposing surface of the pair of gripping parts on at least one opposing surface of the pair of gripping parts; gripping the ranges in proximity to the rubber sheet members, respectively, in a state in which the end surfaces project from the one opposing surface toward the other opposing surface of the pair of gripping parts, respectively; setting a total end surface projection amount of the end surfaces from the opposing surfaces, respectively, to be larger by a predetermined length than a separation distance between the opposing surfaces when the contact member is in a state of being sandwiched between the opposing surfaces; and stopping movement of the pair of gripping parts in proximity to each other by bringing the pair of gripping parts in close proximity to each other in a state in which the contact member is sandwiched between the opposing surfaces.

9. The rubber sheet member joining device according to claim 2, wherein the contact members are attachable to and detachable from the pair of gripping parts comprising the contact members.

10. The rubber sheet member joining device according to claim 9, wherein the contact surface has a lower kinetic friction coefficient than the opposing surface, and no lubricating oil is used.

11. The rubber sheet member joining device according to claim 10, further comprising an adjustment mechanism for adjusting a contact surface projection amount of the contact surface of the contact member that is gripped by the pair of gripping parts, respectively, from the opposing surface of the pair of gripping parts.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0021] FIG. 1 is an explanatory diagram illustrating, in a longitudinal cross-sectional view, gripping parts of an embodiment of a rubber sheet member joining device according to the present technology.

[0022] FIG. 2 is an explanatory diagram illustrating the gripping parts in FIG. 1 in a plan view.

[0023] FIG. 3 is an explanatory diagram illustrating one gripping part in a front view.

[0024] FIG. 4 is an explanatory diagram illustrating, in a longitudinal cross-sectional view, a state in which the end portions of the rubber sheet members in FIG. 1 are gripped by the respective gripping parts.

[0025] FIG. 5 is a partial enlarged view of FIG. 4.

[0026] FIG. 6 is an explanatory diagram illustrating, in a longitudinal cross-sectional view, a state in which the end surfaces of the rubber sheet members in FIG. 4 are joined together.

[0027] FIG. 7 is an explanatory diagram illustrating, in a longitudinal cross-sectional view, a state in which the grip on one end portion of the rubber sheet member in FIG. 6 by the gripping part is released.

[0028] FIG. 8 is explanatory diagram illustrating, in a longitudinal cross-sectional view, gripping parts of another embodiment of a joining device.

[0029] FIG. 9 is an explanatory diagram illustrating a modified example of an adjustment mechanism in FIG. 8.

[0030] FIG. 10 is an explanatory diagram illustrating, in a vertical cross-sectional view, gripping parts of still another embodiment of a joining device.

DETAILED DESCRIPTION

[0031] Hereinafter, the rubber sheet member joining device and method of the present technology will be described in detail based on the embodiments illustrated in the drawings.

[0032] In an embodiment of a joining device 1 for rubber sheet members of the present technology illustrated in FIGS. 1 and 2, end surfaces 13a, 13b to be joined, of unvulcanized rubber sheet members 12, are brought in contact and joined together. There are cases in which the end surfaces 13a, 13b of the different rubber sheet members 12 are joined together, and there are cases in which one end and the other end of the same rubber sheet members 12 are joined together. The rubber sheet members 12 are members made of only unvulcanized rubber such as tread rubber, side rubber, or the like or are members made of unvulcanized rubber and a reinforcing material (fiber, steel cord, or the like) embedded in the unvulcanized rubber such as carcass material, a belt member, or the like.

[0033] The joining device 1 includes: a pair of gripping parts 3, 4 for gripping a range in proximity to each of the end surfaces 13a, 13b to be joined with the rubber sheet members 12 (in other words, end portions 13 of the rubber sheet members 12); a drive unit 7 that moves at least one of the pair of gripping parts 3, 4 in a direction approaching or separating from each other (hereinafter, also referred to as a front-rear direction X); and a control unit 9 that controls operation of the pair of gripping parts 3, 4 or operation of the drive unit 7. In this embodiment, the one gripping part 3 is moved in a direction approaching or separating from the other gripping part 4 in a stationary state in the front-rear direction X; however, a configuration is also possible in which the other gripping part 4 is moved in a direction approaching or separating from the one gripping part 3 in a stationary state in the front-rear direction X, or in which both gripping parts 3, 4 are moved in a direction approaching or separating from each other.

[0034] The drive unit 7 includes: a sliding portion 8a provided on a side surface of the gripping part 3; a motor 8b that engages with the sliding portion 8a and moves the sliding portion 8a in the front-rear direction X; and a movement guide 8c attached to a frame 2. The movement guide 8c extends in the front-rear direction X. By driving the motor 8b to move the sliding portion 8a while guiding the movement thereof by the movement guide 8c, the gripping part 3 moves in the extending direction (front-rear direction X) of the movement guide 8c. A computer or the like is used as the control unit 9. An actuator such as a fluid cylinder or the like may be used as the drive unit 7.

[0035] In this embodiment, each of the gripping parts 3, 4 has the same structure, so only the one gripping part 3 will be described as a representative. The gripping part 3 includes: a pair of upper and lower gripping pieces 3b, 3c; and an opening/closing drive unit 3d for moving the one gripping piece 3b in a direction approaching or separating from the other gripping piece 3c in a stationary state. In this embodiment, a roller conveyor in which a large number of rotatable rollers are disposed at intervals in the front-rear direction X is used as the other gripping piece 3c. This roller conveyor also functions as an other gripping piece 4c of the other gripping part 4.

[0036] An actuator such as a fluid cylinder or the like may be used as the opening/closing drive unit 3d. By controlling the opening/closing drive unit 3d by the control unit 9, the gripping piece 3b closes when brought in proximity to the gripping piece 3c, and the gripping piece 3b opens when separated from the gripping piece 3c. Configuration is also possible in which the other gripping piece 3c is moved in a direction approaching or separating from the one gripping piece 3b in a stationary state, or in which both gripping pieces 3b, 3c are moved in a direction approaching or separating from each other.

[0037] A contact member 5 is provided on opposing surfaces 3a, 4a of the respective gripping parts 3, 4. Each contact member 5 has a contact surface 5a projecting from one of the opposing surfaces 3a, 4a toward the other of the opposing surfaces 4a, 3a. The contact member 5 may be provided on at least one of the opposing surfaces 3a, 4a of the pair of gripping parts 3, 4.

[0038] In this embodiment, as illustrated in FIG. 3, a plurality of the plate-shaped contact members 5 having the rectangular contact surface 5a are mounted side by side on the gripping piece 3b having the rectangular opposing surface 3a. Each contact member 5 may be attached to or detached from the opposing surface 3a to be mounted by screws or the like. Similarly, the plurality of plate-shaped contact members 5 having the rectangular contact surface 5a are mounted side by side on the gripping pieces 4b having the rectangular opposing surface 4a. Each contact member 5 may be attached to or detached from the opposing surface 4a to be mounted by screws or the like. The shape of the contact surface 5a in a front view is not limited to being a rectangle, and various shapes such as a circle, an ellipse, or the like may be adopted.

[0039] When the pair of gripping parts 3, 4 come close to each other, the contact surfaces 5a of the respective contact members 5 come in contact with each other. Therefore, it is preferable to use a material having excellent impact resistance for the contact members 5 (contact surfaces 5a). As will be described later, since each of the contact members 5 slides in a state in which the contact surfaces 5a are in contact with each other, it is desirable for the contact surfaces 5a to have a small kinetic friction coefficient. For example, the contact surfaces 5a preferably have a lower kinetic friction coefficient than the opposing surfaces 3a, 4a. More specifically, as the contact members 5, a low friction material such as a resin having excellent lubricating properties (fluororesin, nylon resin, polyacetal resin, ultra high molecular weight polyethylene, and the like) or a metal or the like having lubricating properties corresponding to these may be adopted, or a lubricating treatment such as fluororesin surface treatment may be preferably performed on the contact surfaces 5a. In a case where the kinetic friction coefficient is small in this way, it is configured that lubricating oil is not used in order that the adhesiveness (the adhesiveness of the unvulcanized rubber) between the end surfaces 13a, 13b is not reduced. In addition, in order to avoid excessive surface pressure of the contact surfaces 5a that are in contact, the surface area of one contact surface 5a is, for example, 2000 mm.sup.2 or greater.

[0040] Next, an example of a procedure for joining the end surfaces 13a, 13b to each other will be described.

[0041] As illustrated in FIG. 1, each of the rubber sheet members 12 to be joined are disposed on the gripping pieces 3c, 4c. Next, as illustrated in FIG. 4, by bringing the gripping pieces 3b, 4b in close proximity to the opposing gripping pieces 3c, 4c, respectively, and by closing the gripping parts 3, 4, the respective end portions 13, 13 of the rubber sheet members 12 are gripped by the gripping parts 3, 4.

[0042] When gripping the one end portion 13 by the one gripping part 3, the end surface 13a is gripped in a state in which the end surface 13a projects from the opposing surface 3a of the one gripping part 3 toward the opposing surface 4a of the other gripping part 4. Similarly, when gripping the other end portion 13 by the other gripping part 4, the end surface 13b is gripped in a state in which the end surface 13b projects from the opposing surface 4a of the other gripping part 4 toward the opposing surface 3a of the one gripping part 3.

[0043] At this time, as illustrated in FIG. 5, the sum of an end surface projection amount d1 of the end surface 13a from the opposing surface 3a and an end face projection amount d2 of the end surface 13b from the opposing surface 4a (total end surface projection amount d=d1+d2) is set to be larger than a separation distance L between the opposing surfaces 3a, 4a in a state in which the contact members 5 are sandwiched between the opposing surfaces 3a, 4a by a predetermined length B (d=L+B). The total of contact surface projection amounts c1, c2 in the front-rear direction X from the opposing surfaces 3a, 4a of the respective contact surfaces 5a, 5a is the separation distance L (L=c1+c2).

[0044] The predetermined length B serves as a butting margin when the end surfaces 13a, 13b are joined together. The appropriate predetermined length B varies depending on the specifications of the rubber sheet members 12, but is, for example, from 0.6 to 0.9 times a total end surface projection amount d.

[0045] Next, as illustrated in FIG. 6, the drive unit 7 is operated by the control of the control unit 9 to move the one gripping part 3 toward the other gripping part 4. The movement of the gripping part 3 causes the contact surfaces 5a of the respective contact members 5 to collide and come in contact with each other. In other words, by bringing the pair of gripping parts 3, 4 in close proximity to each other in a state in which the contact members 5 are sandwiched between the opposing surfaces 3a, 4a, the movement of the pair of gripping parts 3, 4 toward each other is stopped.

[0046] The sum of the end surface projection amounts d1, d2, from the respective opposing surfaces 3a, 4a, of the respective end surfaces 13a, 13b (total end surface projection amount d) is set to be larger than the above-described separation distance L (L=c1+c2) by the predetermined length B. Therefore, as illustrated in FIG. 6, the end surfaces 13a, 13b are joined together in a state of being abutted against each other.

[0047] Next, as illustrated in FIG. 7, the gripping pieces 3b, 4b are separated from the gripping pieces 3c, 4c to open the gripping parts 3, 4. As a result, the grip on the respective end portions 13, 13 by the gripping parts 3, 4 is released. Either one of the gripping parts 3, 4 may be opened first, and in this case, since the contact members 5 slides in a state in which the contact surfaces 5a are in contact with each other, it is desirable that the contact surfaces 5a have a small kinetic friction coefficient.

[0048] By the series of steps described above, joining of the end surfaces 13a, 13b is completed. The same process is performed by sequentially gripping the ranges in proximity to the end surfaces 13a, 13b to be joined (end portions 13, 13) by the gripping parts 3, 4. According to the present technology, movement of the pair of gripping parts 3, 4 toward each other is stopped by bringing the pair of gripping parts 3, 4 in close proximity to each other in a state in which the contact members 5 are sandwiched between the opposing surfaces 3a, 4a, and therefore the pair of gripping parts 3, 4 (end surfaces 13a, 13b) may be brought close to each other more quickly. Since the contact members 5 are in surface contact via the contact surfaces 5a, they are less likely to be damaged even in the case of colliding at a somewhat high speed.

[0049] Since the one gripping part 3 is controlled by the control unit 9 and moves in proximity to the other gripping part 4, the end surfaces 13a, 13b may be accurately and quickly positioned at predetermined positions. Accordingly, the end surfaces 13a, 13b may be joined with high accuracy and in a shorter time than was done in the related art.

[0050] In this embodiment, since the contact members 5 may be freely attached to or detached from the gripping parts 3, 4, the contact members 5 may be easily replaced in a case of wear due to usage over time. Since the degree of wear of the contact members 5 varies depending on the positions where the contact members 5 are disposed, in this embodiment, it is possible, according to the degree of wear, to replace only the contact member 5 that requires replacement.

[0051] In addition, by selecting contact members 5 having appropriate specifications (dimensions in the front-rear direction X are different) according to the specifications of the rubber sheet members 12 to be joined, the contact surface projection amounts c1, c2 of the contact surfaces 5a of the respective contact members 5 may be changed. Along with this, it becomes easy to set the separation distance L described above to a target value.

[0052] As in the embodiment illustrated in FIG. 8, adjustment mechanisms 6a for adjusting the contact surface projection amounts c1, c2 may be provided. The adjustment mechanisms 6a of this embodiment are shims disposed in recesses formed in the opposing surfaces 3a, 4a. A plurality of the shims 6a having different thicknesses are prepared, and the contact members 5 together with the shims 6a having an appropriate thickness selected from the above are mounted in the recesses of the opposing surfaces 3a, 4a. Thereby, the contact surface projection amounts c1, c2 of the respective contact members 5 may be adjusted.

[0053] Alternatively, as illustrated in FIG. 9, actuators installed on the gripping parts 3, 4 may be used as adjustment mechanisms 6b. By moving each contact member 5 in the front-rear direction X by these actuators 6b, the contact surface projection amounts c1, c2 may be adjusted. The operation of the actuators 6b may be controlled by the control unit 9 or a dedicated control unit.

[0054] In a case in which such an actuator 6b is used, a projection amount sensor 10 for detecting the contact surface projection amounts c1, c2 may be provided. The positions of the contact members 5 in the front-rear direction X are configured to be adjusted by the actuators 6b so that the contact surface projection amounts c1, c2 detected by the projection amount sensor 10 are within a preset target range. Accordingly, even in a case in which the contact members 5 (contact surfaces 5a) are worn, the contact surface projection amounts c1, c2 may be maintained within the target range.

[0055] The embodiment illustrated in FIG. 10 includes a state sensor 11 that determines the state of a joint portion 14 where the end surfaces 13a, 13b are joined. As the state sensor 11, a camera device, a displacement sensor, or the like that acquires image data of the joint portion 14 may be used. The state sensor 11 calculates a projection amount E in a thickness direction from a peripheral portion of the joint portion 14 based on the detected data. In a case where a butting margin B is too large, the projection amount E may exceed the permissible range because the joint portion 14 bulges excessively.

[0056] Therefore, the actuator 6b is controlled by the control unit 9, based on the projection amount E calculated using the detection data of the state sensor 11, and the positions of the contact members 5 in the front-rear direction X are adjusted so that the projection amount E in the thickness direction of the joint portion 14 between the end surfaces 13a, 13b to be joined next is within a preset permissible range. This is advantageous for avoiding a defective joint between the end surfaces 13a, 13b.