FITTING DEVICE FOR TIRE ASSEMBLY AND FITTING METHOD FOR TIRE ASSEMBLY

Abstract

A tire fitting device includes: an arm for moving toward a tire; a striking roller for applying a striking force in the vicinity of a bead part, the striking roller being attached to the arm; a receiving roller for receiving the tire to which the striking force is applied; and an elastic member for elastically supporting the receiving roller.

Claims

1. A fitting device for a tire assembly, which applies a striking force in vicinity of a pair of bead portions of a tire assembled onto a wheel, so as to increase adhesion between the wheel and the tire, comprising: an arm configured to move toward the tire; a striking roller attached to the arm and configured to apply a striking force in vicinity of the bead portions; a receiving roller configured to receive the tire to which the striking force is applied; and an elastic member configured to elastically support the receiving roller; wherein, within vicinity of the pair of bead portions, the striking force is applied, by the striking roller, in vicinity of one of the bead portions, and a reaction force is applied, by the receiving roller, in vicinity of another of the bead portions.

2. A fitting device for a tire assembly, which applies a striking force in vicinity of a pair of bead portions of a tire assembled onto a wheel, so as to increase adhesion between the wheel and the tire, comprising: an arm configured to move toward the tire; a striking roller attached to the arm and configured to apply a striking force in vicinity of the bead portions; a receiving roller configured to receive the tire to which the striking force is applied; and an elastic member configured to elastically support the receiving roller; wherein, within vicinity of the pair of bead portions, the striking force is applied, by the striking roller, in vicinity of one of the bead portions, whereby the receiving roller that receives the tire vibrates up and down.

3. The fitting device for a tire assembly according to claim 1, wherein the elastic member is a compressible fluid pressure cylinder.

4. The fitting device for a tire assembly according to claim 1, wherein the elastic member comprises a damper in which a non-compressible fluid is sealed, and a spring configured to press the receiving roller back to the vicinity of the other bead portion.

5. A fitting method for a tire assembly, in which a striking force is applied in vicinity of a pair of bead portions of a tire assembled onto a wheel, so as to increase adhesion between the wheel and the tire, comprising the steps of: placing the tire on a receiving roller that is elastically supported by an elastic member, applying a striking force in vicinity of one of the bead portions, by a striking roller that is provided on an arm configured to move toward the tire placed on the receiving roller; and applying a reaction force by the receiving roller in vicinity of another of the bead portions, the reaction force having a magnitude corresponding to a combination of the wheel and the tire, and a magnitude of the striking force by the striking roller.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0039] FIG. 1 is a side view of a fitting device according to the present invention;

[0040] FIG. 2 is an enlarged view of main parts shown in FIG. 1;

[0041] FIG. 3 is a cross-sectional view of an elastic member;

[0042] FIG. 4 is an explanatory diagram of operations;

[0043] FIG. 5 is a cross-sectional view of another elastic member; and

[0044] FIG. 6 is a diagram showing operations of the other elastic member.

DESCRIPTION OF EMBODIMENTS

[0045] An embodiment of the present invention will be described below with reference to the accompanying drawings.

Embodiment

[0046] As shown in FIG. 1, a fitting device 10 is equipped with a pedestal 11, a rail 12 laid horizontally on an upper surface of the pedestal 11, a slider 13 which is mounted on the rail 12 for horizontal movement thereon, a moving cylinder 14 that moves the slider 13, two support posts 15, 15 erected on the slider 14, a lifting plate 16 that moves up and down while being guided by the support posts 15, 15, a jack mechanism 17 for raising and lowering the lifting plate 16, a cam rotating mechanism 18 attached to the lifting plate 16, a cam 19 that is rotated by the cam rotating mechanism 18, a V-shaped arm 21 which is swingably mounted on the lifting plate 16 by a pin 16a, a connecting rod 22 that connects a proximal portion of the arm 21 with the cam 19, a striking roller 23 disposed on a distal end of the arm 21, a receiving roller 24 disposed face-to-face with the striking roller 23, a bracket 25 that rotatably supports the receiving roller 24, an elastic member 40 that elastically supports the bracket 25, another pedestal 26, a post 27 that extends upwardly from the pedestal 26, and an assembly support member 28 supported in a horizontally rotatable manner on the post 27 and which supports a tire assembly 30.

[0047] By the moving cylinder 14, the striking roller 23 and the like can be moved horizontally to a standby position. While on standby, a space above the tire assembly 30 can be opened, and the tire assembly 30 can be removed upwardly and introduced from the above.

[0048] As shown in FIG. 2, the tire assembly 30 includes a wheel 31 and a tire 32 which has been mounted on the wheel 31 in a previous step. However, in the preceding step, adhesion of the tire 32 to the wheel 31 is low, and gaps are present between a rim part 33 of the wheel 31 and bead portions 34, 35 of the tire 32. Air exists within such gaps. By operation of the fitting device 10, the air is expelled, and the gaps become close to non-existent.

[0049] The tire assembly 30 is placed on the assembly support member 28. The receiving roller 24 and the elastic member 40 are disposed below the tire 32, and the striking roller 23 and the arm 21 are disposed above the tire 32.

[0050] As shown in FIG. 3, the elastic member 40, for example, is a strut damper including a damper 42 in which a non-compressible fluid (for example, oil) 41 is enclosed and sealed, and a spring 44 for pressing a piston rod 43 back to its original position.

[0051] The damper 42 is made up from a cylinder 45, a piston 46 accommodated in the interior of the cylinder 45 movably in an axial direction, and the piston rod 43 that extends from the piston 46. The interior of the damper 42 is partitioned into an upper chamber 47 and a lower chamber 48 by the piston 46.

[0052] Preferably, the upper chamber 47 and the lower chamber 48 are connected by external flow passages 51, 52. Further, a first check valve 53 and a first throttle valve 54 are provided in the external flow passage 51. Further, a second check valve 55 and a second throttle valve 56 are provided in the external flow passage 52. The first and second throttle valves 54, 56 are needle valves referred to as speed control valves.

[0053] When an impact force F1 is applied to the distal end of the piston rod 43, the spring 44 contracts and the piston 46 descends. When the piston 46 descends, the fluid 41 inside the lower chamber 48 moves into the upper chamber 47 through the external flow passage 51. At this time, the speed of descent becomes faster when the first throttle valve 54 opens, and becomes slower when the first throttle valve 54 narrows and throttles the fluid 41.

[0054] When the impact force F1 decreases, the spring 44 extends and the piston 46 rises. When the piston 46 rises, the fluid 41 inside the upper chamber 47 moves into the lower chamber 48 through the external flow passage 52. At this time, the ascension speed becomes faster when the second throttle valve 56 opens, and becomes slower when the second throttle valve 56 narrows and throttles the fluid 41.

[0055] As shown in FIG. 4, the receiving roller 24 is inclined at an angle of θ with respect to the horizontal direction. The angle of inclination thereof is set from 20° to 30°.

[0056] When the striking roller 23 strikes in the vicinity of the one bead portion 34, the one bead portion 34 vibrates and is fitted suitably onto the rim part 33. At the same time, the receiving roller 24 generates a reaction force R1. Vibrations from the one bead portion 34 are transmitted through the tire 32 and cause the other bead portion 35 to vibrate. When the other bead portion 35 is vibrated, the receiving roller 34 vibrates as well. Thus, the receiving roller 24 imparts a vibratory reaction force to the other bead portion 35.

[0057] Incidentally, in the case of FIG. 2, if the receiving roller 24 were directly supported on the pedestal 26 without the elastic member 40 being interposed therebetween, it would be possible for a large reaction force to be generated instantaneously. However, since the receiving roller 24 does not vibrate up and down, only a horizontal component of the reaction force would be generated. If the other bead portion 35 were to become locally caught on or hooked over the rim part 33, further fitting of the tire could not proceed.

[0058] Concerning this point, according to the present invention, because of the interposition of the elastic member 40, the receiving roller 24 also moves upwardly while vibrating up and down. Upon doing so, a horizontal component also is accompanied with the components of vibration, the other bead portion 35 does not become hooked on the rim part 33, and fitting thereof proceeds. More specifically, by the receiving roller 24 vibrating up and down, local catching or hooking of the other bead portion 35 onto the rim part 33 can be prevented. Thus, due to such vibrations, the bead portion 35 can be fitted more smoothly onto the rim part 33.

[0059] In the case that the size or hardness of the tire 32 changes, the degree at which the first throttle valve 54 and the second throttle valve 56 shown in FIG. 3 are opened is adjusted.

[0060] Next a modification of the elastic member 40 will be described.

[0061] As shown in FIG. 5, the elastic member 40 is a compressible fluid pressure cylinder 60 referred to as an air damper. The compressible fluid pressure cylinder 60 is made up from a cylinder 61, a piston 62 accommodated movably in the interior of the cylinder 61, and a piston rod 63 that extends from the piston 62. In the present example, outside air (air) is introduced into an upper chamber 64 of the cylinder 61 via an air vent 65, and a compressible fluid 67, which serves as a working medium, is enclosed and sealed in a lower chamber 66 of the cylinder 61. The compressible fluid 67 is a gas such as nitrogen gas. Preferably, a fluid supply passage 68 is connected to the lower chamber 66, and a pressure adjusting valve 69 and a pressure gauge 71 are provided in the fluid supply passage 68.

[0062] As shown in FIG. 6, upon receiving the impact force F1, the compressible fluid 67 in the lower chamber 66 is compressed, and the piston 62 and the piston rod 63 are lowered. When the pressure in the lower chamber 66 rises and the reaction force increases to F1, movement of the piston 62 is stopped.

[0063] If the force F1 decreases, the compressible fluid 67 attempts to return to its original pressure, whereupon the piston 62 and the piston rod 63 are raised. More specifically, the compressible fluid 67 fulfills the roll of a damper and a spring.

[0064] In FIG. 5, the initial pressure of the lower chamber 66 can be adjusted by the pressure adjusting valve 69. When the pressure increases, the spring constant can be increased, and when the pressure decreases, the spring constant can also be decreased. Thus, changes in tire sizes can be handled.

[0065] Moreover, the elastic member 40 may be a coil spring, a disc spring, or a leaf spring.

INDUSTRIAL APPLICABILITY

[0066] The present invention can be suitably applied to a fitting technique for a tire assembly that is assembled onto a vehicle.

DESCRIPTION OF REFERENCE CHARACTERS

[0067] 10 . . . fitting device for tire assembly [0068] 21 . . . arm [0069] 23 . . . striking roller [0070] 24 . . . receiving roller [0071] 30 . . . tire assembly [0072] 31 . . . wheel [0073] 32 . . . tire [0074] 33 . . . rim part [0075] 34 . . . one bead portion [0076] 35 . . . other bead portion [0077] 40 . . . elastic member [0078] 41 . . . non-compressible fluid [0079] 42 . . . damper [0080] 44 . . . spring [0081] 60 . . . compressible fluid pressure cylinder [0082] 67 . . . compressible fluid [0083] F1 . . . striking force [0084] R1 . . . reaction force [0085] Rh . . . horizontal component of reaction force