JP2004205276A - Tire uniformity machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To sufficiently prevent a displacement of a shaft core without requiring high working accuracy, and while to shorten the measuring cycle time. <P>SOLUTION: This tire uniformity machine has a pair of upper /lower spindles 4 and 5, in which an upper/lower rims 2 and 3 for holding a bead part of a tire 1 are concentrically installed, a first elevating mechanism 12 for moving the lower spindle 5 as one of the upper/lower spindles 4 and 5 to hold each of the bead parts of the tire 1 with the upper/lower rims 2 and 3 and to connect both the upper/lower spindles 4 and 5 to each other, a centering mechanism 50 for adjusting the shaft core of the lower spindle 5 to the shaft core of the upper spindle 4 with the wedge work by the pushing force of both the spindles 4 and 5 when connecting both the upper/lower spindles 4 and 5 to each other, and a mechanical lock mechanism 30 for engaging both the spindles 4 and 5 so the they face to each other when connecting them and for generating the connecting force resisting the inner pressure of the tire when inspecting the tire. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a tire uniformity machine that inspects tire uniformity by rotating while supplying compressed air to the tire.
[0002]
[Prior art]
In a conventional tire uniformity machine, a male taper portion and a female taper portion are provided inside the upper and lower rims, and both tapered portions are arranged concentrically with respect to the axes of the upper and lower rims. Then, when connecting the upper and lower spindles with the upper and lower rims attached, by fitting and pressing while positioning the male taper portion in the radial direction along the inclined wall surface of the female taper portion, Connect the upper and lower spindles while aligning the axes of the upper and lower rims. Then, after maintaining the upper bead portion and the lower bead portion of the tire in an airtight state with the upper rim and the lower rim with this connection, pressurized air was supplied into the tire, and the tire was rotated together with the upper and lower rims. It is configured to inspect the uniformity (uniformity) of the tire at that time (for example, see Patent Document 1).
[0003]
Conventionally, instead of pressing the male and female tapers in the above configuration to connect the upper and lower spindles, a lock shaft is inserted inside the upper and lower spindles and provided on the upper and lower spindles. There has also been proposed a configuration in which an engagement portion and an engaged portion provided on a lock shaft are engaged to connect the upper and lower spindles via a lock shaft (for example, see Patent Document 2).
[0004]
[Patent Document 1]
JP-A-6-134890 (FIG. 1)
[Patent Document 2]
JP-A-11-223571 (FIG. 1)
[0005]
[Problems to be solved by the invention]
However, in the configuration of the above-mentioned conventional patent document 1, since the positioning is performed by fitting the male taper portion and the female taper portion, there is an advantage that the axis alignment of the upper and lower spindles can be easily performed. In the spindle, the male taper portion and the female taper portion are simply pressed and connected. Therefore, when a reaction force in the axial direction of the spindle due to the tire internal pressure (reaction force becomes several tens tons even with an internal pressure of several kg / cm ² ) is applied at the time of tire inspection, the upper and lower spindles are connected with sufficient resistance. In order to obtain the necessary coupling force, a frame with high rigidity enough to support the reaction force, a large bearing, and a large hydraulic cylinder that generates a large thrust beyond the reaction force are required There is a problem that can not be avoided.
[0006]
On the other hand, in the configuration of Patent Literature 2, instead of connecting the upper and lower spindles by pressing the male taper portion and the female taper portion as in Patent Literature 1, the lock shaft is inserted inside the spindle, and the engagement provided on the spindle is provided. The spindle is fixed to the lock shaft by engaging the part with the engaged part provided on the lock shaft. Therefore, even when the rigidity of the frame is not increased and the size of the hydraulic cylinders and bearings is not increased, when the reaction force due to the tire internal pressure is applied during tire measurement, the spindle and the lock shaft have sufficient resistance to connect the coupling force. Obtainable. However, since the lock shaft is inserted inside the spindle, a gap formed between them is unavoidable, and there is a problem that the misalignment due to the gap adversely affects the measurement accuracy. To solve this problem, it is sufficient to make the gap as small as possible, but it is not possible to make the gap small enough to prevent misalignment due to limitations in processing accuracy and assembly accuracy. Further, in the configuration of Patent Document 2, it is necessary to reduce the speed sufficiently so that the lock shafts do not come into contact with each other before the lock shaft is inserted into the spindle, so that the cycle time becomes longer.
[0007]
Accordingly, the present invention is to provide a tire uniformity machine capable of sufficiently preventing the displacement of the shaft center without requiring a high processing accuracy and shortening the measurement cycle time.
[0008]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, a tire uniformity machine according to the first aspect of the present invention includes a pair of spindles each having a rim holding a bead portion of a tire mounted concentrically, and each bead portion of the tire being mounted on the rim. A spindle moving mechanism for moving at least one of the pair of spindles so as to hold and connect the spindles to each other; and A centering mechanism that matches the axis of the spindle with the axis of the one spindle, and a coupling force that engages with the spindles so as to have an opposing positional relationship when the spindles are coupled to each other, and opposes the tire internal pressure during tire inspection. And a lock mechanism for generating
[0009]
According to the above configuration, since the centering mechanism adjusts the axis of the other spindle while elastically reducing the diameter by the pressing force in the inner circumferential direction of one of the spindles, the coupling force of the lock mechanism is adjusted. In this connection, it is possible to exhibit a centering function of aligning the axes of the spindles while functioning as a cushion when connecting. Thereby, even if the axes of the spindles are slightly displaced due to, for example, a low processing accuracy or assembling accuracy of each part, the spindles can be securely connected without any damage. The axes can be matched. Furthermore, the spindle can be moved at a high speed and connected. This makes it possible to sufficiently prevent the displacement of the shaft center without requiring a high degree of processing accuracy, and to shorten the measurement cycle time.
[0010]
The invention according to claim 2 is the tire uniformity machine according to claim 1, wherein the alignment mechanism is fitted on a sliding-side peripheral surface of the other spindle, and has an outer diameter toward the one spindle. A collet member whose outer peripheral surface is inclined so as to decrease, and the collet member is fitted to the one spindle so that the collet member can be fitted so as to apply the pressing force in the inner peripheral direction to the outer peripheral surface of the collet member. And a formed inner peripheral inclined surface.
[0011]
According to the above configuration, the alignment mechanism can be formed by a general collet chuck method. In addition, when the collet member is fitted to the inner peripheral inclined surface, a large gap is formed in the radial direction, so that even if a large deviation occurs in the axis of the spindles, the collet member is securely attached to the inner peripheral inclined surface. Can be fitted.
[0012]
The invention according to claim 3 is the tire uniformity machine according to claim 2, wherein the alignment mechanism has an urging mechanism that urges the collet member in the one spindle direction.
[0013]
According to the above configuration, even when both spindles in the connected state slightly separate in the axial direction due to the reaction force of the tire or the like, the biasing mechanism moves the collet member in the direction of one of the spindles to maintain the fitted state. Therefore, the pressing force applied to the collet member does not decrease. Thereby, the centering function at the initial stage of the connection can be maintained.
[0014]
The invention according to claim 4 is the tire uniformity machine according to claim 3, wherein the centering mechanism adjusts the diameter of the collet member elastically by a pressing force in the inner circumferential direction of one of the spindles. It is characterized in that it is urged by an urging force larger than a frictional force between the collet member and the sliding side peripheral surface when exerting the function.
[0015]
According to the above configuration, a stable alignment function can be exhibited.
[0016]
The invention according to claim 5, wherein a pair of spindles each having a rim holding a bead portion of the tire mounted concentrically, and a concave connecting portion provided on one spindle while holding each bead portion of the tire on the rim. A spindle moving mechanism for moving at least one of the pair of spindles in the axial direction so as to connect the spindles by inserting a convex connecting portion provided on the other spindle, and A centering mechanism having a wedge-shaped sleeve interposed in the gap formed between the two spindles in a circumferential direction of the spindle so as to generate a wedge action, and a position facing when the spindles are connected to each other. It has an engagement part provided in the concave connection part and the convex connection part so as to be related to each other, and the engagement of the engagement part reduces the tire internal pressure during tire inspection. It is characterized by having a locking mechanism for generating a coupling force against.
[0017]
According to the above configuration, when the alignment mechanism inserts the convex connection portion of the other spindle into the concave connection portion of the one spindle, and connects the spindles by the connection force of the lock mechanism, the two connection portions The axis of the spindles can be adjusted by the wedging action of the wedge-shaped sleeve between them. Therefore, when connecting the spindles, it is possible to exhibit a centering function of aligning the axes of the spindles. Thus, even if the axes of the spindles are slightly displaced due to, for example, a low processing accuracy or assembling accuracy of each part, the spindles are aligned while being guided by the wedge-shaped sleeve. Therefore, the axes of the spindles can be surely aligned without causing damage. Furthermore, the spindle can be moved at a high speed and connected. This makes it possible to sufficiently prevent the displacement of the shaft center without requiring a high degree of processing accuracy, and to shorten the measurement cycle time.
[0018]
The invention of claim 6 is the tire uniformity machine according to claim 5, wherein the wedge-shaped sleeve of the alignment mechanism is a collet member. Thereby, the function of the wedge-shaped sleeve can be easily and largely exerted by a general member.
[0019]
According to a seventh aspect of the present invention, in the tire uniformity machine according to the fifth or sixth aspect, the alignment mechanism has an urging mechanism for urging the wedge-shaped sleeve in a direction in which the wedge action increases. I have. As a result, it is possible to sufficiently prevent the alignment function from deteriorating during tire inspection. Further, the cushion function at the time of connecting the spindle can be enhanced.
[0020]
The invention according to claim 8 is the tire uniformity machine according to any one of claims 5 to 7, wherein the lock mechanism has a portion in which the engaging portion has at least a concave and convex portion and at least one of the portions. By operating one side, the other side is engaged. Thus, the lock mechanism can be realized with a simple structure.
[0021]
A ninth aspect of the present invention is the tire uniformity machine according to any one of the fifth to seventh aspects, wherein the concave connecting portion is arranged in an axial direction with respect to a spindle on which the concave connecting portion is provided. And a cylindrical member whose position is variable. Thereby, the rim width can be adjusted to an arbitrary rim width by moving the cylindrical member forward and backward.
[0022]
The invention according to claim 10 is the tire uniformity machine according to claim 9, wherein the cylindrical member has a jack mechanism having a female screw provided on the cylindrical member and a male screw screwed thereto. It is characterized in that the position is variable. Thus, the tubular member can be moved in the axial direction with a simple configuration.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described below with reference to FIGS.
As shown in FIG. 2, the tire uniformity machine according to the present embodiment has an upper rim 2 that holds an upper bead portion of a tire 1 and a lower rim 3 that holds a lower bead portion of the tire 1. . The upper rim 2 is detachably provided at the tip (lower end) of the upper spindle 4. On the other hand, the lower rim 3 is detachably provided at the tip (upper end) of the lower spindle 5. The two spindles 4 and 5 have the upper rim 2 and the lower rim 3 facing each other, and the axes of the two rims 2 and 3 are aligned on the same straight line.
[0024]
The upper spindle 4 and the lower spindle 5 are provided on a ceiling frame 6 and a base frame 8, respectively. These frames 6.8 are supported by a plurality of vertical frames 7 such that the ceiling frame 6 is horizontally arranged at the upper position and the base frame 8 is horizontally arranged at the lower position. Each vertical frame 7 is erected vertically from the site surface 9. The premises surface 9 has a pit 10 in a central portion of a region surrounded by the vertical frame 7.
[0025]
The pit 10 allows the lower portion of the lower spindle 5 to be accommodated. The lower spindle 5 holds the lower rim 3 detachably, a lower rim holding mechanism 11, a first elevating mechanism 12 that moves the lower rim holding mechanism 11 up and down, and moves the lower rim holding mechanism 11 up and down together with the first elevating mechanism 12. A second lifting mechanism 13. The second lifting mechanism 13 is provided with a horizontal support member 14 that supports the lower rim holding mechanism 11, a nut member 15 provided at the base of the horizontal support member 14, and the nut member 15 screwed together, and provided in the vertical direction. It has a ball screw member 16 and a ball screw drive motor 17 for driving the ball screw member 16 to rotate.
[0026]
The second elevating mechanism 13 configured as described above raises and lowers the nut member 15 by rotating the ball screw member 16 in a desired direction and angle by the ball screw drive motor 17, and the horizontal member connected to the nut member 15. The first lifting mechanism 12 can be positioned at a desired height position via the support member 14. Further, the lower rim holding mechanism 11 can be moved to a tire holding position.
[0027]
The horizontal support member 14 in the second lifting mechanism 13 supports the first lifting mechanism 12 in the vertical direction. The first elevating mechanism 12 is arranged in parallel beside the second elevating mechanism 13. As a result, the first lifting mechanism 12 and the second lifting mechanism 13 are shorter than the case where the maximum distance for raising and lowering the lower rim holding mechanism 11 by the two mechanisms 12 and 13 is realized by the stroke amount of one hydraulic cylinder. , The required depth of the pit 10 is reduced.
[0028]
The first lifting mechanism 12 is composed of a hydraulic cylinder arranged such that the cylinder rod 12a is located on the upper side. The tip (upper end) of the cylinder rod 12a is connected to the lower rim holding mechanism 11. Further, when the first lifting mechanism 12 is raised to the tire mounting / dismounting position by the second lifting mechanism 13, the tires 1 can be mounted and removed by the two rims 2 and 3 by moving the cylinder rod 12a forward and backward.
[0029]
As described above, the lower rim holding mechanism 11 that is raised and lowered by the two lifting mechanisms 12 and 13 has the lower rim support member 20 that holds the lower rim 3 as shown in FIG. Here, FIG. 1 shows a state in which the rims 2 and 3 are widely opened with the rotation axis S interposed therebetween (the right side in the figure) and a state in which the rims 2 and 3 are slightly opened (the left side in the figure). The lower rim support member 20 is formed at a concave portion 20a formed at the center of the upper end surface, a sliding side peripheral surface 20b formed at the outer peripheral wall of the upper end portion, and at a lower end side of the sliding side peripheral surface 20b. And a flange portion 20c. The concave portion 20a and the sliding-side peripheral surface 20b support a mechanical lock mechanism 30 and a centering mechanism 50 described later, respectively. The flange portion 20c is formed to support the lower surface on the inner peripheral side of the lower rim 3. Note that the mechanical lock mechanism 30 and the centering mechanism 50 constitute a convex connecting portion for connecting the upper and lower spindles 4 and 5 to each other.
[0030]
Further, the lower rim support member 20 has a side peripheral surface below the flange portion 20c surrounded by the outer cylinder support 22. The outer cylinder support 22 rotatably supports the lower rim support member 20, and moves the lower rim holding mechanism 11 through the outer cylinder support 22 so as to move up and down the cylinder rod 12 a of the first elevating mechanism 12. Supported by. An air supply hole 22a is formed in the lower part of the outer cylinder support 22 from the outer peripheral surface to the inner peripheral surface. The upper end of the air pipe 26 is connected to the air supply hole 22a. As shown in FIG. 2, the air pipe 26 hangs down from the lower rim holding mechanism 11 along the first elevating mechanism 12 and is supported by the horizontal support member 14 so as to be able to move up and down. Have been. The lower end of the air pipe 26 is connected to an air supply unit via an air hose (not shown).
[0031]
Also. As shown in FIG. 1, inside the lower rim support member 20, a rod insertion hole 20d corresponding to the rotation axis S (the axis of the lower rim 3) is formed, and air is formed along the rod insertion hole 20d. A supply hole 20e is formed. The upper end of the air supply hole 20e is opened at a position above the flange portion 20c of the lower rim support member 20, and the lower end of the air supply hole 20e communicates with the air supply hole 22a of the outer cylinder support 22. Can be supplied into the tire 1 held by the rims 2.3.
[0032]
On the other hand, a rod member 24 is inserted into the rod insertion hole 20d so as to be able to move up and down. The lower end of the rod member 24 is rotatably connected to a cylinder rod 23 a of a rod elevating cylinder 23. The rod elevating cylinder 23 is fixed to the lower surface of the outer cylinder support 22. The rod elevating cylinder 23 moves the rod member 24 vertically relative to the lower rim support member 20.
[0033]
The upper end of the rod member 24 is connected to the mechanical lock mechanism 30. The mechanical lock mechanism 30 includes a conical inclined member 31 having an inclined side peripheral surface, a claw member 32 whose inner peripheral surface is slidably abutted on the side peripheral surface of the inclined member 31, and a radius of the claw member 32. And a claw support 33 that is movably supported in the direction. The claw member 32 has an uneven portion 32a on the outer peripheral surface. The uneven portion 32a of the claw member 32 can mesh with the uneven portion 41a formed on the inner cylindrical member 41 of the upper spindle 4. Accordingly, the mechanical lock mechanism 30 can move the claw member 32 in the radial direction along the side peripheral surface of the inclined member 31 by moving the inclined member 31 up and down. The mechanical lock mechanism 30 fixes the upper spindle 4 and the lower spindle 5 in the vertical direction by engaging the concave and convex portion 32a with the concave and convex portion 41a of the inner cylindrical member 41 of the upper spindle 4 by the advancement of the claw member 32. To be connected to. That is, when the upper and lower spindles 4.5 are connected to each other, the mechanical lock mechanism 30 is engaged so that the two spindles 4.5 are opposed to each other with a predetermined distance (gap) therebetween. A coupling force against the internal pressure is generated.
[0034]
A centering mechanism 50 is provided below the mechanical lock mechanism 30 in the outer peripheral direction. The centering mechanism 50 includes a collet member 51 that is a kind of wedge-shaped sleeve having a wedge-shaped vertical cross section that matches the axis of the lower rim support member 20 with the axis of the inner cylindrical member 41, and biases the collet member 51 upward. And a plurality of biasing mechanisms 52 that perform the operations.
[0035]
As shown in FIG. 6, the above-mentioned collet member 51 has the appearance of a conical sleeve and is inserted into the sliding-side peripheral surface 20b of the lower rim support member 20 so that the axis of the lower rim support member 20 is adjusted. , Ie, the axis of the lower rim 3 (the other spindle). The collet member 51 has an elastic force, and the outer peripheral surface 51a is inclined so that the outer diameter increases from the upper side to the lower side. A plurality of slits 51b are formed at equal intervals in the up-down direction on the outer peripheral surface 51a of the collet member 51. These slits 51b are formed so that the open ends are alternately positioned, and the inner diameter can be easily and significantly reduced by elastically reducing the diameter of the collet member 51 by the pressing force in the inner circumferential direction. ing.
[0036]
As shown in FIG. 7, the collet member 51 is adapted to be fitted into the concave connecting portion of the inner cylinder member 41. When the upper and lower spindles 4 and 5 are connected to each other, the collet member 51 generates a wedge action in a gap formed in the spindle circumferential direction between the two connecting portions. The concave connecting portion of the inner cylindrical member 41 has an inner peripheral inclined surface 41b whose inner diameter increases from the upper side to the lower side on the inner peripheral wall at the lower end. When the collet member 51 of the convex connecting portion is inserted and fitted into the concave connecting portion of the inner cylindrical member 41 while being guided, the inner peripheral inclined surface 41 b is formed on the inner peripheral surface 51 a of the collet member 51. By applying a pressing force in the direction, the diameter of the collet member 51 is reduced. As a result, the centering mechanism 50 allows the collet member 51 to elastically reduce the diameter and tighten the entire circumference of the sliding side peripheral surface 20b while aligning the axis of the lower rim support member 20 with the axis of the inner cylinder member 41. It is designed to exhibit a centering function.
[0037]
The above-mentioned collet member 51 is urged upward by the urging mechanism 52, that is, the direction in which the collet member 51 is strengthened in the wedge action. The urging mechanisms 52 are arranged at equal intervals at the base of the flange portion 20c of the lower rim support member 20. The urging mechanism 52 is formed in a bolt shape, and includes a push-up member 53 that contacts the lower surface of the collet member 51, and a spring member 54 that urges the push-up member 53 upward. The urging force of the spring member 54 is set to be larger than the frictional force between the collet member 51 and the sliding side peripheral surface 20b of the lower rim support member 20 when the centering function is exerted. Thereby, when the lower spindle 5 is lowered while the inner cylinder member 41 and the collet member 51 are performing the alignment function, the collet member 51 is pushed up to keep the positional relationship with the inner cylinder member 41 constant. By maintaining, the deterioration of the alignment function is prevented.
[0038]
The biasing force of the spring member 54 is a value that does not change the positional relationship between the collet member 51 and the inner cylinder member 41 even when a lateral load is applied when the drum 102 of FIG. 2 is pressed against the inflated tire 1. Is set to Thus, even when the tire 1 is inspected, the wedge action is maintained, so that the centering function can be reliably exhibited.
[0039]
The inner cylinder member 41 is housed in an outer cylinder member 42 as shown in FIG. The inner cylinder member 41 and the outer cylinder member 42 form a part of a rim width adjustment mechanism 58 together with a screw shaft member 45 described later. The outer cylinder member 42 is provided with a flange portion 42a on a lower outer peripheral portion so as to have a function as an upper rim holding mechanism.
[0040]
Further, the inner cylinder member 41 has the above-described uneven portion 41a and the inner peripheral inclined surface 41b formed on the inner peripheral surface, and has a horizontal portion 41c formed therein. The horizontal portion 41 c is set so that the uneven portion 32 a of the claw member 32 faces the uneven portion 41 a of the inner cylindrical member 41 when the horizontal portion 41 c contacts the upper surface of the claw support 33. A keyway 41 e is formed on the outer peripheral surface of the inner cylinder member 41 in the up-down direction. A guide key 43 is movably fitted in the key groove 41e. The guide key 43 is fixed to the outer cylinder member 42 so as to prohibit the rotation of the inner cylinder member 41 with respect to the outer cylinder member 42.
[0041]
Further, a female screw portion 41d is formed at the upper end of the inner cylinder member 41. The female screw portion 41d is screwed to a male screw portion 45a formed below the screw shaft member 45. The screw shaft member 45 constitutes a jack mechanism, and is configured to change the position of the inner cylindrical member 41 in the axial direction with respect to the lower spindle 5. Specifically, as shown in FIG. 4, the screw shaft member 45 is disposed so that the axis thereof coincides with the rotation axis S, and the upper portion is rotatably supported by the spindle cylinder member 46. The spindle cylinder member 46 is rotatably supported by the ceiling frame 6, and has a lower end connected to an upper end of the outer cylinder 42.
[0042]
A clutch mechanism 47 is provided at an upper end of the screw shaft member 45. The clutch mechanism 47 can switch between connection and disconnection between the screw shaft member 45 and the spindle cylinder member 46. Specifically, the clutch mechanism 47 connects the screw shaft member 45 and the spindle cylinder member 46 in a fixed state in the ON state, and enables both members 45 and 46 to rotate integrally. On the other hand, the clutch mechanism 47 releases the connection between the screw shaft member 45 and the spindle cylinder member 46 in the OFF state, and enables the members 45 and 46 to rotate independently.
[0043]
Further, a brake disk 48 is provided at the upper end of the screw shaft member 45. The brake disk 48 can be held by a brake device 49. The brake device 49 is fixed to the ceiling frame 6 via a support member (not shown). The brake device 49 is turned on when the rotation of the screw shaft member 45 is prohibited, and clamps the brake disc 48. When the rotation of the screw shaft member 45 is permitted, the brake device 49 is turned off and the brake disk is turned off. 48 is opened.
[0044]
The ceiling frame 6 is provided with a spindle driving device 56. The spindle driving device 56 is connected to the spindle cylinder member 46 via a driving belt 57, and is capable of rotating the spindle cylinder member 46 in any direction and at any speed. The upper spindle 4 having the inner cylinder member 41, the outer cylinder member 42, the screw shaft member 45, and the spindle cylinder member 46 in the axial direction as described above sets the clutch mechanism 47 to the ON state and the brake device 49 to the OFF state. While operating the spindle driving device 56, all the members 41, 42, 45 and 46 in the axial direction can be integrally rotated. The upper spindle 4 operates the spindle driving device 56 while the clutch mechanism 47 is in the OFF state and the brake device 49 is in the ON state, and rotates the inner cylinder member 41 with respect to the fixed screw shaft member 45. The inner cylinder member 41 can be moved forward and backward (moved up and down) with respect to the outer cylinder member 42.
[0045]
The rotation direction, number of rotations, and rotation angle of the screw shaft member 45 and the spindle cylinder member 46 of the upper spindle 4 can be detected by a rotation detection mechanism 60. As shown in FIG. 5, the rotation detection mechanism 60 includes a first pulley 63 connected to the screw shaft member 45 via a first belt 61 and a first pulley 63 connected to the spindle cylinder member 46 via a second belt 62. And two pulleys 64. The first pulley 63 is connected to a first gear 67 in the housing 65 via a first rotation shaft 66 rotatably supported by the housing 65.
[0046]
On the other hand, the second pulley 64 is connected to a second gear 69 inside the housing 65 via a second rotating shaft 68 rotatably supported by the housing 65 and a third pulley outside the housing 65. It is connected to a pulley 70. The third pulley 70 is connected to a fourth pulley 72 via a third belt 71, and the fourth pulley 72 is connected to a first rotation detector 74 composed of an incremental encoder via a third rotation shaft 73. It is connected. Thereby, the first rotation detector 74 transmits the rotation of the spindle cylinder member 46 of FIG. 4 via the second belt 62, the third pulley 70, the fourth pulley 72, and the like, thereby causing the spindle cylinder member 46 to rotate. The number of rotations (rotation angle) can be detected and output as an angle detection signal.
[0047]
Further, a second gear 69 in the housing 65 that rotates together with the first rotation detector 74 is meshed with a first bevel gear 76 via a fourth gear 75. The first bevel gear 76 is rotatably provided on a shaft member 77 rotatably supported by the housing 65. A fixed member 78 is fixed to the shaft member 77, and a second bevel gear 79 is rotatably provided with the fixed member 78 interposed therebetween. The second bevel gear 79 is meshed with the above-described first gear 67 to which the rotation of the screw shaft member 45 in FIG. 4 is transmitted. Further, the first bevel gear 76 and the second bevel gear 79 are meshed with the planetary gear 80. The planet gear 80 is rotatably supported on the side surface of the fixed member 78.
[0048]
Thereby, when the spindle cylinder member 46 of FIG. 4 is rotated in a state where the first gear 67 is fixed by the stop of the screw shaft member 45 of FIG. 4, the second bevel gear 79 meshed with the first gear 67. 4 is also fixed, the planetary gear 80 rotates around the shaft member 77 via the first bevel gear 76 when the second gear 69 rotates by the rotation of the spindle cylinder member 46 in FIG. The member 77 will rotate. When the spindle cylinder member 46 of FIG. 4 is rotated in a state where the first gear 67 is rotated by the rotation of the screw shaft member 45 of FIG. 4, the second bevel gear 79 meshed with the first gear 67 is also rotated. Since the first bevel gear 76 rotates at a fixed position when the second gear 69 rotates due to the rotation of the spindle cylinder member 46 in FIG. 4, the shaft member 77 is stopped because the shaft member 77 rotates in the same direction.
[0049]
At one end of the shaft member 77, a fifth pulley 81 is provided. The fifth pulley 81 is connected via a fourth belt 82 and a fifth pulley 83 to a second rotation detector 84 composed of an absolute encoder. The second rotation detector 84 can detect the origin of the spindle cylinder member 46 only when the screw shaft member 45 in FIG. 4 is stopped and the spindle cylinder member 46 is rotating, and can output the origin as an origin detection signal. It has become.
[0050]
The rotation detecting mechanism 60 configured as described above is connected to a control device (not shown). The control device includes an arithmetic unit, a storage unit, an input / output unit, and the like. Various data areas such as a tire data area, a rim width data area, and a test data area are formed in the storage unit. The tire data area stores data such as the type of the tire 1, the bead width of each type, the rotation speed corresponding to each type, and the like. The rim width data area stores rim width data indicating an interval between the upper rim 2 and the lower rim 3. The test data area stores inspection data obtained by rotating the tire 1.
[0051]
The storage unit also stores a control program for controlling the operation of the tire uniformity machine. This control program calculates the bead width of the tire 1 based on the type data input by operating the input / output unit, and based on the origin detection signal and the angle detection signal so that the rim width corresponds to the bead width. A rim width setting function for moving the inner cylinder member 41 forward and backward with respect to the outer cylinder member 42, and an inspection such as a rotation speed and a rotation speed corresponding to the type data based on an inspection command by operating a start button of the input / output unit or the like. An inspection function for performing an inspection based on an angle detection signal so as to meet specifications, an abnormal operation detection function for confirming the presence or absence of an abnormal operation based on an origin detection signal and an angle detection signal, and a rim 2.3 of a tire 1 that has been inspected. It is provided with various functions such as a carry-in / out function of removing the tire 1 from the rim and carrying the tire 1 before inspection to the rims 2.3.
[0052]
The rotation detection mechanism 60 that outputs the origin signal and the angle detection signal to the control device as described above is provided on the ceiling frame 6 as shown in FIG. An intermediate frame 85 is provided horizontally at a substantially central portion of the vertical frame 7 supporting the ceiling frame 6. A pair of tire mounting tables 86 are provided symmetrically on the intermediate frame 85. The distance between the tire mounting tables 86 and 86 can be expanded or reduced in accordance with the outer diameter of the rims 2.3. The tire 1 can be attached and detached.
[0053]
Further, tire transport mechanisms 87 are provided outside the respective tire mounting tables 86. As shown in FIG. 3, the tire transport mechanism 87 includes gripping members 88 for gripping the tread portion of the tire 1 and rotating devices 89 for rotating the gripping members 88 in the tire 1 direction. Two sets of gripping mechanisms 90 are provided in the transport direction (horizontal direction), and a transport cylinder 91 for moving these gripping mechanisms 90 in the transport direction is provided. A carry-in roller 92 and a carry-out roller 93 are provided before and after in the carrying direction about the arrangement position of the upper spindle 4 and the lower spindle 5, respectively. Then, the above-described tire transport mechanism 87 causes the transport cylinder 91 to advance, thereby gripping the tire 1 on the carry-in roller 92 before inspection by one gripping mechanism 90 and inspecting the tire 1 at the inspection position (between the rims 2 and 3). By gripping the rear tire 1 with the other gripping mechanism 90 and retreating the transport cylinder 91, the tire 1 before inspection can be moved to the inspection position and the tire 1 after inspection can be moved onto the unloading roller 93. It is possible.
[0054]
As shown in FIG. 2, a measuring mechanism 97 is provided between the intermediate frame 85 and the ceiling frame 6 and beside the lower end of the upper spindle 4. The measurement mechanism 97 includes a drum 102 that simulates a road surface for inspection, and a drum that rotatably supports the drum 102 such that a rotation axis of the drum 102 is parallel to a rotation center of the tire 1 (upper / lower rim). A support 99, a load cell (not shown) provided on the axis of the drum 102 and measuring the uniformity (uniformity) of the tire 1 via the drum 102, and a ball jack 100 for pressing the drum 102 against the tire 1 with a predetermined pressing force. And
[0055]
The operation of the tire uniformity machine in the above configuration will be described.
[0056]
(Data input process)
First, by operating, for example, a keyboard of the input / output unit in the control device (not shown), the operator inputs the kind data, quantity data, and the like of the tire 1 to be inspected next. The type data is used for collecting specifications such as a bead width and a tire inner diameter of the tire 1 corresponding to the type data stored in advance. Thereafter, it is determined whether or not the rim width of the upper / lower spindles 4, 5 corresponds to the bead width of the tire 1 to be inspected. If the rim width does not correspond to the bead width, a rim width adjusting step is performed. You. Then, when the setting of the rim width is completed, an inspection process for performing uniformity measurement of the tire 1 is executed.
[0057]
(Rim width adjustment process)
If the bead width of the tire 1 does not correspond to the rim width of the upper / lower spindles 4, 5, this step is executed. First, as shown in FIG. 4, the positional relationship between the outer cylinder member 42 and the inner cylinder member 41 for which the current rim width is set is confirmed. After the amount of movement (elevation) of the inner cylinder member 41 required for installation at the next rim width is determined based on this positional relationship, the rotation direction and rotation of the inner cylinder member 41 corresponding to this movement amount are obtained. A number is required.
[0058]
Next, the clutch mechanism 47 is operated so as to be in the OFF state, the connection between the screw shaft member 45 and the spindle cylinder member 46 is released, the brake device 49 is operated in the ON state, and the brake disk 48 is held. As a result, the rotation of the screw shaft member 45 is prohibited. As a result, only the spindle cylinder member 46 can be rotated.
[0059]
Next, the spindle driving device 56 is operated, and the spindle cylinder member 46 is rotated in a predetermined direction. Thus, the outer cylinder member 42 connected to the spindle cylinder member 46 rotates. Further, since the outer cylinder member 42 and the inner cylinder member 41 are movably connected only through the guide key 43 in the vertical direction, the inner cylinder member 41 rotates together with the outer cylinder member 42. As a result, when the inner cylinder member 41 rotates about the fixed screw shaft member 45, the female screw portion 41d of the inner cylinder member 41 is screwed into the male screw portion 45a of the screw shaft member 45 in the vertical direction. Moving.
[0060]
When the spindle cylinder member 46 is rotated as described above, this rotation is transmitted to the rotation detection mechanism 60 via the second belt 62. As a result, as shown in FIG. 5, the third pulley 70 connected to the second belt 62 via the second pulley 64 is rotated, and the first rotation detector 74 is rotated. Is output to a control device (not shown) as an angle detection signal.
[0061]
Also, the second gear 69 connected to the second belt 62 via the second pulley 64 rotates, and the first bevel gear 76 rotates. At this time, as described above, since the screw shaft member 45 in FIG. 4 is fixed, the first gear 67 and the first gear 67 connected to the screw shaft member 45 via the first belt 61 and the first pulley 63 are connected. The second bevel gear 79 is maintained in a fixed state. Therefore, as a result of the planetary gear 80 rotating around the shaft member 77 via the first bevel gear 76, the shaft member 77 rotates. As a result, the second rotation detector 84 rotates via the fifth pulley 81, and the origin detection signal is output from the second rotation detector 84 to a control device (not shown).
[0062]
The phase of both the angle detection signal and the origin signal output to the control device is obtained, and it is determined whether or not the rim width adjustment is correctly performed based on the change in the phase. In addition, a reference position is set based on the origin signal, and the rotation speed of the spindle cylinder member 46 is obtained based on at least the angle detection signal. Based on the rotation speed, the moving amount (elevation amount) of the inner cylinder member 41 is determined. Is detected. Then, when the movement amount reaches the target, as shown in FIG. 4, the rotation of the spindle cylinder member 46 is stopped by stopping the spindle driving device 56.
[0063]
(Inspection process)
If the rim width corresponds to the tire 1 to be inspected, this step is executed. First, as shown in FIG. 2, the lower rim holding mechanism 11 is set at a predetermined height position by the second lifting mechanism 13 together with the first lifting mechanism 12. Thereafter, the first lifting mechanism 12 is lowered, and the upper surface of the lower rim 3 is positioned below the tire mounting tables 86.
[0064]
Next, as shown in FIG. 3, the tire 1 before inspection placed on the carry-in roller 92 is gripped by the gripping mechanism 90 and transferred to the tire mounting tables 86 located between the upper and lower rims 2.3. Will be posted. Thereafter, as shown in FIG. 4, the lower rim 3 is raised by the first lifting mechanism 12 to hold the lower bead portion of the tire 1. Then, the lower rim 3 is further raised while holding the tire 1, the upper bead portion of the tire 1 is mounted on the upper rim 2, and the upper spindle 4 and the lower spindle 5 having the upper and lower rims 2.3 are provided. Are linked.
[0065]
That is, as shown in FIG. 1, when the lower rim holding mechanism 11 of the lower spindle 5 is raised, the tip end (convex connecting portion) of the lower rim support member 20 is inserted into the concave connecting portion of the inner cylindrical member 41. Then, as shown in FIG. 7, the collet member 51 (wedge-shaped sleeve) fitted on the sliding side peripheral surface 20 b of the lower rim support member 20 is guided along the inner peripheral inclined surface 41 b of the inner cylindrical member 41. As the lower rim support member 20 rises, the entire outer peripheral surface 51 a of the collet member 51 is pressed in the inner peripheral direction by the inner peripheral inclined surface 41 b of the inner cylindrical member 41. As a result, the core is aligned so that the axis of the inner cylinder member 41 matches the axis of the inner cylinder member 41 while the collet member 51 exerts a wedge action.
[0066]
At this time, the collet member 51 is elastically reduced in diameter while being guided by the inner peripheral inclined surface 41b, and is urged upward by the urging mechanism 52 to be positioned at the upper portion. Therefore, even when the lower rim support member 20 is quickly raised and fitted, since the elastic diameter reducing operation of the collet member 51 and the urging mechanism 52 function as a cushion, the collet member 51 is hardly damaged. Has become something. Further, due to the difference between the outer diameter of the upper end portion of the collet member 51 and the inner diameter of the lower end portion of the inner peripheral inclined surface 41b of the inner cylindrical member 41, in the initial stage of fitting the collet member 51 to the inner cylindrical member 41, Large gaps occur. Therefore, the collet member 51 can be securely fitted to the inner cylinder member 41 without having to create each member with high processing accuracy as in the related art, and the position adjustment when raising the lower rim holding mechanism 11 can be performed. The collet member 51 can be securely fitted to the inner cylinder member 41 without being damaged even if the ability is insufficient or the ascending speed is high.
[0067]
When the above-described centering operation is performed by the centering mechanism 50 including the collet member 51 and the urging mechanism 52, a fixing operation in the axial direction is performed by the mechanical lock mechanism 30 inside the inner cylinder member 41. Is done. That is, when the upper end surface of the mechanical lock mechanism 30 comes into contact with the laterally provided portion 41 c, the uneven portion 32 a of the claw member 32 is opposed to the uneven portion 41 a of the inner cylinder member 41. Then, as shown in FIG. 1, the inclination member 31 is raised by the rod elevating cylinder 23 via the rod member 24, and the claw member 32 is pushed out in the outer peripheral direction by the rise of the inclination member 31. The portion 32a is fitted into the uneven portion 41a of the inner cylinder member 41. As a result, the upper spindle 4 and the lower spindle 5 are fixed in the axial direction by the mechanical lock mechanism 30, that is, the upper and lower spindles 4 and 5 have a positional relationship of facing each other at a predetermined distance. .
[0068]
Next, as shown in FIG. 4, the brake device 49 is turned off to release the brake disc 48, and the clutch mechanism 47 is turned on to fix the spindle cylinder member 46 and the screw shaft member 45. Connected to state. Further, as shown in FIG. 1, a predetermined pressure air is supplied to the tire 1, and the tire 1 is brought into an inflation state.
[0069]
When the tire 1 is in the inflation state, the reaction force of the tire 1 acts to separate the upper and lower rims 2.3 (the upper and lower spindles 4.5). Therefore, if there is a play in the axial direction between the upper and lower spindles 4, 5, the lower rim support member 20 of the lower spindle 5 is lowered by the play, and the two spindles 4, 5 are separated from each other. . At this time, since the collet member 51 provided on the lower rim support member 20 is urged upward by the urging mechanism 52, even if the lower rim support member 20 is lowered, the collet member 51 is kept in the inner cylindrical member. 41 remains at the position pressed by the inner peripheral inclined surface 41b. Thereby, the centering function by pressing the collet member 51 with the inner peripheral inclined surface 41b is maintained.
[0070]
Further, as shown in FIG. 1, the upper spindle 4 and the lower spindle 5 are fixed in the axial direction by a mechanical lock mechanism 30. Therefore, even if the reaction force of the tire 1 is very large, the interval between the upper and lower spindles 4, 5 will not be separated by more than the play. In addition, the mechanical lock mechanism 30 is used to fix the upper and lower spindles 4 and 5 in the axial direction, so that the upper and lower spindles 4 and 5 are fixed only by the hydraulic cylinder of the first lifting mechanism 12. Parts and mechanisms such as the first lifting mechanism 12 that raises and presses the lower spindle 5 can be reduced in size.
[0071]
Thereafter, the drum 102 is pressed against the tire 1 with a predetermined pressing force. In this case, the pressing force (lateral load) on the tire 1 by the drum 102 acts so as to push down the collet member 51, but the urging mechanism 52 pushes up the collet member 51 with an urging force greater than the pressing force. Therefore, the alignment function of the collet member 51 is maintained.
[0072]
Next, as shown in FIG. 4, the spindle drive device 56 is operated, and the spindle cylinder member 46 is rotated, whereby the screw shaft member 45, the inner cylinder member 41, and the outer cylinder member 42 are rotated. As a result, the lower spindle 5 including the lower rim support member 20 connected by the centering mechanism 50 and the mechanical lock mechanism 30 rotates. Then, as shown in FIG. 2, the tire 1 is rotated, and the drum 102 is rotated and vibrated to measure the uniformity (uniformity) of the tire.
[0073]
When the spindle cylinder member 46 is rotated as described above, this rotation is transmitted to the rotation detection mechanism 60 via the second belt 62. As a result, as shown in FIG. 5, the third pulley 70 connected to the second belt 62 via the second pulley 64 is rotated, and the first rotation detector 74 is rotated. Is output to a control device (not shown) as an angle detection signal.
[0074]
Also, the second gear 69 connected to the second belt 62 via the second pulley 64 rotates, and the first bevel gear 76 rotates. At this time, as described above, since the screw shaft member 45 in FIG. 4 is rotated together with the spindle cylinder member 46, the first shaft member 45 connected to the screw shaft member 45 via the first belt 61 and the first pulley 63 is used. The gear 67 and the second bevel gear 79 are rotated at the same speed as the first bevel gear 76. Accordingly, the planetary gear 80 rotates at the same position by receiving the rotation of the first bevel gear 76 and the second bevel gear 79, and as a result, the shaft member 77 is stopped. As a result, since the second rotation detector 84 maintains the stopped state, the second rotation detector 84 does not output the origin detection signal.
[0075]
When the angle detection signal is output to the control device, the control device determines the rotational speed and the rotational speed of the tire 1 based on the angle detection signal, and specifies the measured value of the uniformity and the positional relationship between the tire 1. Further, the control device monitors the output state of the origin signal, and when the origin signal is input, notifies the operator that an abnormality has occurred in the clutch mechanism 47 or the like in FIG.
[0076]
When the inspection of the tire 1 is completed as described above, the operation opposite to the above-described operation is performed as shown in FIG. 2, and the tire 1 after the inspection is moved by the lowering of the lower rim 3 to the tire mounting tables 86. And the lower rim 3 is separated from the tire 1. Then, as shown in FIG. 3, the tire 1 before the inspection on the carry-in roller 92 and the tire 1 after the inspection between the upper and lower rims 2 and 3 are gripped by the gripping mechanisms 90 and 90, respectively. 1 is transferred between the upper and lower rims 2 and 3, and the tire 1 after the inspection is transferred onto the carry-out roller 93. Then, the inspection of the next tire 1 is repeated.
[0077]
As described above, the tire uniformity machine according to the present embodiment has a pair of upper and lower spindles in which the upper and lower rims 2.3 holding the bead portion of the tire 1 are coaxially mounted as shown in FIG. The upper and lower rims 2.3 and 4.5 hold one bead of the tire 1 and connect the upper and lower spindles 4.5 with one another. When the upper and lower spindles 4.5 are connected to the spindle moving mechanism (first raising / lowering mechanism 12, second raising / lowering mechanism 13) for moving the spindle 5, the pressing force of the upper / lower spindles 4.5 exerts a wedge action. While the upper and lower spindles 4 and 5 are connected to each other, the alignment mechanism 50 engages with the alignment mechanism 50 that aligns the axis of the lower spindle 5 with the axis of the upper spindle 4 so that they face each other. Force against tire pressure It is a mechanical lock mechanism 30 that occurs configuration having a.
[0078]
Specifically, a pair of upper and lower spindles 4.5 and 5 on which the upper and lower rims 2.3 holding the bead portion of the tire 1 are mounted concentrically, and the upper and lower rims 2.3 and The lower spindle 5 is held so as to hold each bead portion and insert the convex connecting portion provided on the lower spindle 5 into the concave connecting portion provided on one upper spindle 4 to connect the upper and lower spindles 4.5. And a spindle moving mechanism for moving the spindle in the axial direction, and a wedge action is generated in a gap formed between the spindles in the circumferential direction of the spindle when the upper and lower spindles 4 and 5 are connected to each other. When the upper and lower spindles 4 and 5 are connected to each other, the centering mechanism 50 having the collet member 51 (wedge-shaped sleeve) and the inner periphery of the concave connection portion and the outer periphery of the convex connection portion are arranged to face each other. The provided engaging portion (the uneven portion 32a Uneven portion 41a) has, has been configured to have a mechanical lock mechanism 30 for generating a coupling force against the tire internal pressure during the tire test by engagement of the engaging portion.
[0079]
In addition, in this embodiment, as shown in FIG. 2, since the tire uniformity machine which arrange | positions the tire 1 horizontally and inserts it from above and below was demonstrated, the upper / lower spindles 4.5 and the upper / lower spindles 5 were described for convenience of explanation. Although described as the rims 2 and 3, the present invention is not limited to this, and the present invention can be applied to a tire uniformity machine in which the tire 1 is arranged in an arbitrary direction and inspected. Therefore, the upper and lower spindles 4 and 5 and the upper and lower rims 2 and 3 can be arranged in any direction such as a horizontal direction. Further, in the present embodiment, the case where the lower spindle 5 is moved to the upper spindle 4 is described. However, the present invention is not limited to this, and at least one of the upper and lower spindles 4.5 is moved. Anything is fine. Further, the spindle moving mechanism may be constituted by one hydraulic cylinder.
[0080]
According to the above configuration, the centering mechanism 50 adjusts the axes of the lower spindles 4 and 5 while exerting a wedge action by the pressing force acting on the upper and lower spindles 4 and 5. When the lower spindles 4 and 5 are connected by the mechanical lock mechanism 30, a centering function of aligning the axes of the upper and lower spindles 4 and 5 can be exhibited. Thus, even if the upper and lower spindles 4 and 5 are slightly misaligned due to, for example, a low degree of processing accuracy or assembling accuracy of each part, the spindles are wedge-shaped. Since the alignment is performed while being guided by the sleeve, the axes of the upper and lower spindles 4 and 5 can be surely aligned without causing damage. Further, the urging action of the urging mechanism of the centering mechanism 50 or the elastic diameter reducing operation of the centering mechanism (collet) acts as a cushion, so that the upper and lower spindles 4 and 5 are moved at a high speed and connected. It can also be done. This makes it possible to sufficiently prevent the displacement of the shaft center without requiring a high degree of processing accuracy, and to shorten the measurement cycle time.
[0081]
As shown in FIG. 7, the centering mechanism 50 according to the present embodiment is slidably fitted to the sliding-side peripheral surface 20 b of the lower spindle 5 so that the outer diameter decreases toward the upper spindle 4. The collet member 51 is a kind of a wedge-shaped sleeve having an inclined outer peripheral surface 51a, and the collet member 51 is fitted upward so as to apply an inner circumferential pressing force to the outer peripheral surface 51a of the collet member 51. An inner peripheral inclined surface 41b formed on the spindle 4 is provided. The collet member 51 may be provided on the upper spindle 4 and the inner peripheral inclined surface 41b may be provided on the lower spindle 5. In addition, instead of the collet member 51, the centering mechanism 50 may be provided so as to slidably fit a conical sleeve which is a wedge-shaped sleeve having no slit.
[0082]
The centering mechanism 50 is formed by a wedge-shaped sleeve typified by a general collet chuck system. When the collet member 51 is fitted on the inner peripheral inclined surface 41b, a large space is formed between the upper and lower spindles 4 in the radial direction. Since the gap is formed, the spindles 4 and 5 can be connected at a high speed. In addition, since the wedge-shaped sleeve is guided and guided along the inner peripheral inclined surface 41b, the collet member 51 can be reliably inclined even if a large misalignment occurs between the upper and lower spindles 4 and 5. It can be fitted to the surface 41b.
[0083]
The centering mechanism 50 has a biasing mechanism 52 that biases the collet member 51 (wedge-shaped sleeve) in the direction of the upper spindle 4, that is, in the direction in which the wedge action of the collet member 51 is enhanced. Thus, even when the upper and lower spindles 4.5 in the connected state slightly separate in the axial direction due to the reaction force of the tire 1, the urging mechanism 52 moves the collet member 51 (wedge-shaped sleeve) toward the upper spindle 4. In order to maintain the fitted state (wedge action), the pressing force applied to the collet member 51 (wedge-shaped sleeve) is maintained. Thereby, the centering function at the initial stage of the connection can be maintained. Further, the centering mechanism may be provided such that the wedge-shaped sleeve is slidably fitted to the concave connecting portion side. In this case, it is necessary to protrude an inclined surface corresponding to the inclined surface on the inner periphery of the wedge-shaped sleeve on the convex connecting portion side. In this case, also in this case, the wedge-shaped sleeve can be urged in a direction in which the wedge action increases.
[0084]
Further, the locking mechanism 50 has an engaging portion formed by the uneven portion 32a of the claw member 32 and the uneven portion 41a of the inner cylinder member 41, but is not limited thereto. What is necessary is just to have a part which has a part, and to engage with the other side by operating at least one side of the part concerned. For example, the portion having the concave and convex portions on the inner cylinder member side may be operated so as to protrude toward the inner peripheral side so as to engage with the concave and convex portions facing each other. Also, for example, by providing a plurality of claws on the convex connecting portion side, providing a hole through which the claws of the convex connecting portion are inserted on the concave connecting portion side, and rotating at least one of both connecting members by a predetermined angle. Alternatively, a so-called bayonet lock may be used in which a claw portion is also provided in a hole portion of the concave connection portion so as to engage with the claw portion on the convex connection portion side.
[0085]
【The invention's effect】
According to the present invention, since the centering mechanism is configured to adjust the axis of the other spindle while elastically reducing the diameter by the pressing force in the inner circumferential direction of one of the spindles, when the spindles are connected by the lock mechanism. In addition, a centering function of aligning the axes of the spindles can be exhibited while functioning as a cushion. Thus, there is an effect that the displacement of the shaft center can be sufficiently prevented without requiring high processing accuracy, and the cycle time of measurement can be shortened.
[Brief description of the drawings]
FIG. 1 is an explanatory view showing a main part of a tire uniformity machine.
FIG. 2 is an explanatory view showing an overall configuration of the tire uniformity machine as viewed from the front.
FIG. 3 is an explanatory view showing an overall configuration of the tire uniformity machine in a plan view.
FIG. 4 is an explanatory diagram showing a main part of the tire uniformity machine.
FIG. 5 is a schematic configuration diagram of a rotation detection mechanism.
FIG. 6 is a schematic configuration diagram of a mechanical lock mechanism and a centering mechanism.
FIG. 7 is an explanatory diagram of a mechanical lock mechanism and a centering mechanism.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Tire 2 Upper rim 3 Lower rim 4 Upper spindle 5 Lower spindle 11 Lower rim holding mechanism 12 First raising / lowering mechanism 13 Second raising / lowering mechanism 15 Nut member 16 Ball screw member 20 Lower rim support member 20a Depression 20b Sliding side peripheral surface 20c Flange Part 20d Rod insertion hole 20e Air supply hole 22 Outer cylinder support 23 Rod elevating cylinder 24 Rod member 30 Mechanical lock mechanism 31 Inclined member 32 Claw member 32a Irregular portion 33 Claw support 41 Inner cylinder member 41a Irregular portion 41b Inner peripheral inclined surface 41c Lateral portion 41d Female thread portion 41e Key groove 42 Outer cylinder member 42a Flange section 43 Guide key 45 Screw shaft member 46 Spindle cylinder member 47 Clutch mechanism 48 Brake disk 49 Brake device 50 Alignment mechanism 51 Collet member 51a Outer peripheral surface 51b Slit 52 urging mechanism 53 push-up member 54 spring Material 56 spindle drive 57 drives a belt 60 rotation detection mechanism 74 first rotation detector 84 second rotation detector 87 tire conveying mechanism 9 site surface 9 pit 90 gripping mechanism 91 conveyance cylinder 99 while drum substrates

Claims (10)

A pair of spindles with rims holding the bead portion of the tire mounted concentrically,
A spindle moving mechanism that moves at least one of the pair of spindles so that the rim holds each bead portion of the tire and connects the spindles to each other;
When the spindles are connected to each other, a centering mechanism that matches the axis of the other spindle with the axis of the one spindle while exerting a wedge action by the pressing force of both spindles,
A tire uniformity machine, comprising: a lock mechanism that engages with the spindles so as to have an opposing positional relationship when the spindles are coupled to each other, and generates a coupling force that opposes a tire internal pressure during tire inspection. The alignment mechanism,
A collet member which is inserted into the sliding-side peripheral surface of the other spindle and whose outer peripheral surface is inclined so that the outer diameter decreases toward the one spindle;
An inner peripheral inclined surface formed on the one spindle so that the collet member can be fitted so as to apply the pressing force in the inner peripheral direction to the outer peripheral surface of the collet member. The tire uniformity machine according to claim 1. The tire uniformity machine according to claim 2, wherein the centering mechanism has an urging mechanism for urging the collet member in the one spindle direction. The alignment mechanism,
An urging force greater than the frictional force between the collet member and the peripheral surface on the sliding side when the collet member is elastically reduced in diameter by the pressing force in the inner circumferential direction of one of the spindles to exert a centering function. The tire uniformity machine according to claim 3, wherein the tire uniformity is applied. A pair of spindles with rims holding the bead portion of the tire mounted concentrically,
The pair of spindles so that the rim holds each bead portion of the tire and the concave connection portion provided on one spindle is inserted into the convex connection portion provided on the other spindle to connect the spindles to each other. A spindle moving mechanism for moving at least one of the two in the axial direction;
A centering mechanism having a wedge-shaped sleeve interposed in the gap between the spindles so as to generate a wedge action in a gap formed in a circumferential direction between the spindles when the spindles are connected to each other;
When the spindles are connected to each other, there is provided an engaging portion provided on the concave connecting portion and the convex connecting portion so as to be in an opposing positional relationship, and the tire at the time of tire inspection is provided by the engagement of the engaging portion. A tire uniformity machine comprising: a lock mechanism that generates a connecting force against internal pressure. The tire uniformity machine according to claim 5, wherein the wedge-shaped sleeve of the centering mechanism is a collet member. The tire uniformity machine according to claim 5, wherein the centering mechanism has an urging mechanism that urges the wedge-shaped sleeve in a direction in which a wedge action is strengthened. 8. The lock mechanism according to claim 5, wherein the lock mechanism has a portion in which the engaging portion has at least a convex and concave portion, and engages with the other side by operating at least one side of the portion. The tire uniformity machine according to any one of the preceding claims. The said concave connection part is comprised with the cylindrical member whose position is variable in the axial direction with respect to the spindle on the side where the said concave connection part is provided, The one of Claim 5 thru | or 7 characterized by the above-mentioned. The tire uniformity machine according to 1. The tire uniformity according to claim 9, wherein the cylindrical member is configured to be variable in position by a jack mechanism having a female screw provided on the cylindrical member and a male screw screwed thereto. Machine.

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