The pneumatic tire characterized by comprising the tread and the crosslinked rubber composition, of the present invention, wherein the tread and the crosslinked rubber composition comprise two or more kinds of rubber components and a filler and have a volume of the low density region of 35% or more, a volume of the void portion of 7.5 or less and a filler distribution D represented by the following formula (I) of 2.0 or less are excellent in abrasion resistance.

D=(A.sub.1/B.sub.1)/(A.sub.0/B.sub.0)(I)

In the formula (I), A.sub.1 represents a volume fraction of a rubber component A in a filler gel, B.sub.1 represents a volume fraction of a rubber component B in a filler gel, A.sub.0 represents a volume fraction of a compounded rubber component A, B.sub.0 represents a volume fraction of a compounded rubber component B.

The present invention provides deterioration analysis method which allows a detailed analysis of deterioration, especially deterioration of surface conditions, of a polymer material. The present invention relates to a deterioration analysis method, including irradiating a polymer material with high intensity X-rays, and measuring X-ray absorption while varying the energy of the X-rays, to analyze deterioration of the polymer.

The present invention provides deterioration analysis method which allows a detailed analysis of deterioration, especially deterioration of surface conditions, of a polymer material. The present invention relates to a deterioration analysis method, including irradiating a polymer material with high intensity X-rays, and measuring X-ray absorption while varying the energy of the X-rays, to analyze deterioration of the polymer.

A performance evaluation method for elastic material including rubber or elastomer, the method includes a step of applying a strain to a test piece made of the elastic material to form at least one void inside the test piece, a step of obtaining projected images of the test piece by irradiating the test piece with X-rays at a plurality of times after the at least one void is formed, and a step of obtaining a volume change of the at least one void between the plurality of times based on the projected images, as one of indexes of performance.

Provided is a highly accurate method for evaluating the abrasion resistance of rubber compositions. The present disclosure relates to a method for evaluating abrasion resistance of a rubber composition by X-ray scattering measurement or neutron scattering measurement, the method including performing X-ray scattering measurement or neutron scattering measurement in a region q expressed by the following Formula 1 to obtain a scattering intensity curve I.sub.(q), fitting the following Formula 2 to the scattering intensity curve I.sub.(q) to obtain a mass fractal dimension D, and evaluating the abrasion resistance of the rubber composition based on the mass fractal dimension D,

[00001]$\begin{array}{cc}q=\frac{4\sin \left(/2\right)}{}& \left(\mathrm{Formula}1\right)\end{array}$$\left(e:\mathrm{scattering}\mathrm{angle},:\mathrm{wavelength}\mathrm{of}x-\mathrm{rays}\mathrm{or}\mathrm{neutrons}\right)$$\begin{array}{cc}{I}_{\left(q\right)}{q}^{-D}& \left(\mathrm{Formula}2\right)\end{array}$$\left(D:\mathrm{mass}\mathrm{fractal}\mathrm{dimension}\right).$

A device for testing a tyre (2) for representing tomographical images of sections of a casing of the tyre includes a source (11) of ionizing radiation arranged outside the tyre (2) and a detector (12) for receiving the radiation. The detector (12) is situated opposite the source (11) with respect to at least one section of the casing. The axis (X-X) of the tyre runs parallel to a sectional plane (P) passing through the focus (F) of the source (11) and the detector (12). The tyre and the source-detector assembly are moved with rotational motion relative to one another about an axis of rotation (Z-Z) perpendicular to the sectional plane (P), according to a predetermined angular excursion range. The detector (12) is disposed in a central internal zone (20) of the tyre (2) during the testing cycle.

The present invention provides deterioration analysis method which allows a detailed analysis of deterioration, especially deterioration of surface conditions, of a polymer material. The present invention relates to a deterioration analysis method, including irradiating a polymer material with high intensity X-rays, and measuring X-ray absorption while varying the energy of the X-rays, to analyze deterioration of the polymer.

The present invention provides deterioration analysis method which allows a detailed analysis of deterioration, especially deterioration of surface conditions, of a polymer material. The present invention relates to a deterioration analysis method, including irradiating a polymer material with high intensity X-rays, and measuring X-ray absorption while varying the energy of the X-rays, to analyze deterioration of the polymer.

A device and method for the radioscopic examination of a continuous strip-shaped material of rubber which runs continuously in particular. During the movement, the strip-shaped material is x-rayed by a radioscopic measurer and the entire cross-sectional surface is detected so that foreign bodies or defects present in the material are detected according to their position and orientation. An elimination device removes the previously identified foreign body during the feed movement of the material in that a tool, configured as a punching tool, of the elimination device is moved synchronously with the material.

Among other things, a tire inspection system (100) and method are provided. A radiation source (116) and a detector array (118) are configured to rotate about an axis of rotation. During a first examination of a tire (104), the tire (104) has a first orientation relative to the axis of rotation, and during a second examination, the tire (104) has a second orientation relative to the axis of rotation. For example, between the first examination and the second examination, the tire (104) is at least one of shifted with respect to the axis of rotation or rotated about a tire rotation axis (e.g., perpendicular to the axis of rotation) to change the orientation of the tire relative to the axis of rotation. Such rotation and translation of the tire (104) are carried out by using a conveyer belt (114) and a robotic arm (602). In this manner, imagery of the tire (104) may be developed, which can be inspected to identify irregularities, etc. in the tire (104), for example.