Device for determining wheel fastening state using server

What is claimed is: 1. A server-using device for determining a wheel fastening state, comprising: a sensor unit detachably installed in a wheel fastening part at which a wheel assembly is fastened to an axle of a vehicle, the sensor unit being configured to detect a state quantity depending on a fastening state of the wheel fastening part; an information terminal connected to the sensor unit; and a server connected to the information terminal, wherein the information terminal includes a measurement instruction module configured to read vehicle state data regarding the vehicle from a control and communication system of the vehicle and send an instruction for measurement to the sensor unit at timing for which the vehicle state data is taken into consideration, and a communication interface for receiving measurement data from the sensor unit and transmitting the measurement data to the server, and the server includes a first information processing module configured to determine an abnormality of the fastening state of the wheel fastening part by comparing the measurement data with accumulated data that is measured for a determined item of the vehicle state data under the same condition and stored in the past. 2. The server-using device as claimed in claim 1 , further comprising communication devices for wirelessly performing communication between the sensor unit and the information terminal and communication between the information terminal and the server, wherein the first information processing module stores the measurement data and determines the abnormality, and the information terminal includes a display module configured to display a determination result transmitted from the server, on a screen of a display device. 3. The server-using device as claimed in claim 1 , wherein the information terminal includes a second information processing module configured to determine an abnormality of the fastening state of the wheel fastening part based on the measurement data by using the vehicle state data. 4. The server-using device as claimed in claim 1 , wherein the server includes a comparison and notification module configured to: when an abnormality occurs in the vehicle, compare measurement data from which the abnormality is determined, with measurement data of another vehicle; and, if a situation with a similar tendency or a similar level is found between both measurement data as a result of the comparison, notify a vehicle management department or a driver of the vehicle of vehicle information of the other vehicle to call attention. 5. The server-using device as claimed in claim 1 , wherein the sensor unit includes: a ring spacer provided over an entire periphery of the wheel assembly and interposed between respective head portions of a plurality of hub bolts and a plurality of wheel nuts associated with the respective hub bolts so as to receive tightening force by the plurality of hub bolts and the plurality of wheel nuts, the spacer having a plurality of bolt holes that are formed at a plurality of circumferential phase parts, respectively, the plurality of hub bolts being inserted through the plurality of bolt holes, respectively, to mount a wheel of the wheel assembly to a hub, the ring spacer being deformable due to the tightening force; and at least one strain sensor provided between at least two bolt holes of the plurality of bolt holes, the at least one strain sensor being configured to measure strain of the deformed spacer. 6. The server-using device as claimed in claim 5 , wherein the strain sensor, a communication device, and a power source are provided on the spacer and at a circumferential phase part between the at least two bolt holes, the communication device being configured to communicate a detection signal of the strain sensor, the power source being configured to supply power to the strain sensor and the communication device. 7. The server-using device as claimed in claim 5 , wherein the circumferential phase part between the bolt holes is formed with a thin portion. 8. The server-using device as claimed in claim 7 , wherein the spacer includes a thinnest portion at a portion of the circumferential phase part formed with the thin portion between the at least two bolt holes, and the at least one strain sensor measures strain of the thinnest portion, the thinnest portion serving as a strain concentration portion. 9. The server-using device as claimed in claim 5 , wherein the sensor unit further includes: a temperature sensor; and at least any one of an acceleration sensor, a gyro sensor, and a rotation sensor. 10. The server-using device as claimed in claim 5 , wherein the at least one strain sensor includes: a diaphragm mounted on the spacer, the diaphragm being deflectable in response to deformation of the spacer; and a sensor element mounted on the diaphragm, the sensor element being configured to measure deflection of the diaphragm. 11. A server-using device for determining a wheel fastening state comprising: a sensor unit detachably installed in a wheel fastening part at which a wheel assembly is fastened to an axle of a vehicle, the sensor unit being configured to detect a state quantity depending on a fastening state of the wheel fastening part; an information processing terminal connected to the sensor unit so as to allow transmission and reception of a signal, the information processing terminal including a first processor; and a server connected to the information terminal so as to allow transmission and reception of a signal, the server including a second processor, wherein the first processor is programmed to read vehicle state data regarding the vehicle from a control and communication system of the vehicle and send an instruction for measurement to the sensor unit at timing for which the vehicle state data is taken into consideration, and to receive measurement data from the sensor unit and transmit the measurement data to the server, and the second processor is programmed to determine an abnormality of the fastening state of the wheel fastening part by comparing the measurement data with accumulated data that is measured for a determined item of the vehicle state data under the same condition and stored in the past.