CN213676268U - Super giant tire crown with monitoring sensor and tire - Google Patents

Abstract

The utility model provides a special giant tire child hat and tire with monitoring sensor, monitoring sensor installs in the inside of child hat and is located between base rubber and the belted layer, and monitoring sensor includes temperature detection module at least, monitoring sensor still includes microprocessing unit MCU, wireless communication module, battery, peripheral circuit. According to the invention, the monitoring sensor arranged in the tire crown of the extra-large tire can monitor the temperature of the tire tread and the belt layer in real time and transmit data to a receiving device such as a vehicle-mounted data terminal or a handheld device through wireless communication. The position of the possible empty fault inside can be found in time, an effective means is provided for maintenance personnel to quickly determine a solution, and the condition that the tire is scrapped due to the expansion of the fault can be prevented. Maintenance measures are taken at the initial stage of failure occurrence, so that the service life of the tire is prolonged, the running safety of the vehicle is improved, and the heavy property loss is avoided.

Description

Super giant tire crown with monitoring sensor and tire

Technical Field

The utility model relates to a special giant tire child hat and tire with monitoring sensor, in particular to special giant tire child hat and tire with monitoring sensor that can monitor defects such as tire sky and come to nothing.

Background

The super-huge tire refers to the division of tire size in the tire appearance quality standard of the chemical industry standard of the people's republic of China HG/T2177-2011, and a pneumatic tire with a rim nominal diameter of 33 inches or more and a nominal section width of 24 inches or more is a super-huge tire. The tires meeting the requirements of the specification are mainly used for large mining vehicles and engineering vehicles on non-paved roads, and are collectively called as extra-large tires hereinafter. For example, a super giant tire with the tire specification of 59/80R63 has the diameter of about 4000mm, the weight of 5.5 tons per tire, high price and the average service life of about 4000 to 5000 hours.

The ultra-large tire is applied to a mine operation vehicle, a mine road surface is generally paved by on-site broken stones, and a large amount of sharp and sharp stones scattered on the road surface are easy to cause the tire to be cut and punctured and damaged. And the road surface is uneven, the gradient is large, the number of curves is large, the dynamic load deformation and the impact of the tire cause the heat productivity of the tire to be large, the strength to be reduced, and the damage of faults is aggravated. In the case of engineering tires, the failure of the run-out is the main cause of tire scrap. The term "void" refers to a separation phenomenon occurring between inner rubber layers of a tire or between a rubber layer and a steel wire. The large-area void fault causes the damage of the tire structure, can not be repaired, and has the danger of serious safety accidents such as tire burst and the like.

The voids in use are mostly due to damage. Because the size and the thickness of the extra-large tire are larger, the tire can not be leaked immediately due to some puncture injuries, and a driver can not find the tire in time. After silt enters the tire wound, along with rolling and rolling of the tire, the internal wound is gradually enlarged due to continuous friction between gravels and between the gravels and rubber, and the tire is gradually loosened and scrapped, wherein the tire cannot be repaired. If the belt steel wire is exposed and damaged due to deep puncture damage, the steel wire can be corroded and separated from the rubber quickly under the action of air and moisture. Along with the running of the tire, the friction of the separation surface generates heat, so that the performance of the rubber is reduced, the separation phenomenon is further aggravated, and the tire is gradually emptied and scrapped, which cannot be repaired.

Some tires can have undetectable gaps inside the tire tread due to the problems during manufacturing, and the gaps can be increased along with the natural temperature rise in the running process of the tires and the rolling extrusion effect of the tires, so that the friction between the rubbers is caused, and finally the tires are scrapped due to large-range internal void.

In the prior art, the tire can be repaired in the early stage of the void, but no mature void monitoring method exists at present. According to the experience of practical application, because the volume of the common car tire and the truck tire is small, the uniformity of the sizing material during production is good, the condition of manufacturing and emptying is generally avoided, the thickness of the material is low, when puncture faults occur, air leakage is easily caused directly, a user can easily detect the air leakage, and therefore, the monitoring means of the emptying faults is not needed. The prior art is therefore still relatively less investigated for void checking. At present, the method for judging the engineering tire is to use a method of knocking the tire on site, judge the engineering tire by observing and monitoring sound, and is influenced by environmental noise and experience of operators, so that the accuracy is low, and the ultra-large tire has a wide and thick tread and hardly feels sound change when being knocked. There is also a method of removing the tire by a dedicated inspection apparatus, but it is very inconvenient and the inspection apparatus is too expensive to be equipped by general users. Because of the high value of extra giant tires, early scrapping is a significant economic loss. Therefore, a method is needed to find out the fault condition in the early stage of the void and repair the fault condition in time with lower cost, so that the great economic loss caused by tire scrap is avoided.

SUMMERY OF THE UTILITY MODEL

In order to solve the unable early discovery special giant project tire sky trouble of prior art and can not accurate definite fault location, can not in time judge the severity of damage such as prick, the tire can not in time obtain overhauing for the sky scope enlarges and leads to the condemned problem of tire, the utility model provides a special giant tire with monitoring sensor.

The technical scheme of the utility model as follows:

the tyre crown of the extra-large tyre with the monitoring sensor is characterized in that the monitoring sensor is arranged in the tyre crown and positioned between a base rubber and a belted layer, the monitoring sensor at least comprises a temperature detection module, and the monitoring sensor further comprises a microprocessing unit (MCU), a wireless communication module, a battery and a peripheral circuit.

Preferably, the arrangement mode of the monitoring sensors is that the monitoring sensors correspond to tread pattern blocks of the tire, and 1 group of sensors are arranged in the circumferential direction of the tire crown according to the interval of each group of pattern blocks arranged along the circumference or each group or multiple groups of pattern blocks at intervals; the number of arrays of each group of sensors along the axial direction of the tire is at least 1, and the position of the array is near the center of a tire crown or/and near shoulders on two sides of the tire crown.

Further preferably, a group of sensors is arranged at intervals of one pattern along the circumferential direction of the tire, each group of sensors is composed of 3 monitoring sensors along the axial direction of the tire and is respectively positioned at the central position of the circumferential direction of the tire crown and the positions of the two sides of the tire crown close to the tire shoulders.

The preferable tread cap surface is provided with a blind hole, the bottom of the blind hole is positioned between the base rubber and the belt layer, the monitoring sensor is arranged at the bottom of the blind hole, and the upper part of the blind hole is filled with a filling rubber rod or rubber raw rubber.

The micro processing unit MCU and the peripheral circuit can at least complete tasks such as operation, control, storage, analog-to-digital conversion, data processing, power management and the like. The battery provides power for each module in the sensor body. Each component included in the sensor body may be one chip or one component, or may be a plurality of chips or components, where the chips or components integrate part of or all of the modules of the sensor body. The acquired data can be sent to a receiving device in a wireless communication mode, and the receiving device can be a vehicle-mounted data terminal.

Preferred other monitoring modules may include an attitude detection module that detects tire rotation, the attitude detection module having an acceleration sensor and/or a gyroscope. The sensor can judge the rolling of the tyre, distinguish the temperature parameters in different states and execute corresponding operations according to a set program.

Preferably, the other detection module further comprises a wear detection module for detecting the wear amount of the tire pattern. The abrasion detection module is arranged in the pattern block, is synchronously worn with the tire pattern, and transmits the acquired data to a vehicle-mounted data terminal or a handheld device,

preferably, each monitoring sensor has a unique code for identification, so that the monitoring sensor uniquely identifies one sensor in the vehicle-mounted data terminal and the data management system.

Preferably said crown is the crown of a new tyre, a retreaded tyre or a tyre already in use.

A tyre employing the aforesaid crown, said tyre being a new tyre, a retreaded tyre or a tyre already in use.

The beneficial effects are that:

the utility model discloses a special giant tire has realized monitoring child hat inside temperature through tire monitoring sensor, and then can judge special giant tire early sky trouble of coming to nothing. The utility model discloses an install at the inside monitoring sensor of special giant tire child hat (hereinafter referred to as the sensor), can real-time supervision tread and belted layer temperature and send data to receiving arrangement such as on-vehicle data terminal or hand-held device through radio communication. By adopting the mode of crown side installation, no influence is caused on a tire belt layer and a main steel wire during installation, the damage of the steel wire formed when the tire body penetrates through the installation is avoided, and the damage to the stress structure of the tire body is avoided.

1. When a tire has a manufacturing void fault, or deep layer damage caused by damage of a tire crown and a belt layer, or an internal void fault caused by damage, a local abnormal temperature rise condition is formed on a fault point and nearby materials under the action of friction and extrusion of the materials. Therefore, when the tire has a run-out failure, the large amount of heat energy generated by the friction of local materials is accompanied, and abnormal changes are generated due to the temperature rise of the local materials. The method adopts the measure that a plurality of wireless temperature sensors are arranged in the tire crown in an array mode along the circumferential direction and the axial direction, so that the temperature of each monitoring point of the tire can be obtained in real time during the running of a vehicle, and the fault state can be relatively accurately reflected. Through analyzing and comparing temperature data of all detection points, the position of the possible inside out-of-service fault can be found in time, an effective means is provided for maintenance personnel to quickly determine the solution, and the scrapping of tires caused by fault expansion can be prevented. Maintenance measures are taken at the initial stage of failure occurrence, so that the service life of the tire is prolonged, the running safety of the vehicle is improved, and the heavy property loss is avoided.

2. The running state of the tire can be judged by utilizing the acceleration and/or the gyroscope element, the working strategy of the sensor is formulated, the energy consumption of the sensor can be reduced, the service life of a battery is prolonged, and the actual state of the interior of the tire reflected by the measured result can be accurately judged according to the running state of the tire.

3. Through the wireless communication function of the sensor, the data can be transmitted to the receiving device in real time for display, and the data can be transmitted to a remote data management system through the receiving device, so that all the data can be stored and analyzed, and an optimized scheme is further provided for selection and use of tires.

4. In order to ensure the driving safety, the abrasion condition of the tire needs to be periodically checked manually in the using process of the tire in the prior art, and the using states of the tire and the vehicle are judged accordingly. Through increase wearing and tearing detection module in the child hat monitoring sensor, can detect the wearing and tearing volume of tire according to the tactics of setting for, can discover abnormal wear condition such as local wear, excessive wear and eccentric wear simultaneously, reduce personnel's working strength and improved work efficiency. The wear monitoring of the tires can also provide data for judging the running states of the vehicles and the tires, inform users of timely troubleshooting the faults of the vehicles and road conditions, and provide certain guarantee for safe driving.

Drawings

FIG. 1: a schematic crown section of example 1;

FIG. 2: embodiment 1 schematic diagram of arrangement mode and pattern corresponding relation of monitoring sensors;

FIG. 3: the system structure block diagram of the sensor of embodiment 1;

FIG. 4: example 1 a schematic diagram of a sensor structure;

FIG. 5: the schematic crown section of example 2;

FIG. 6: example 2 a schematic diagram of a sensor structure;

FIG. 7: FIG. 1 is an enlarged view taken at point I;

FIG. 8: fig. 6 is an enlarged view at ii.

The various reference numbers in the figures are listed below:

the device comprises a shell, a battery, a 3-ultrahigh frequency communication antenna, a 4-microprocessing unit MCU, a 5-low frequency communication antenna, a 6-temperature detection module, a 7-sensor, an 8-loss rubber body, a 10-blind hole, 11-base glue, 12-belted layer and 13-filling rubber rod.

Detailed Description

For a better understanding of the present invention, the following further explanation of the present invention is made in conjunction with the embodiments.

Example 1

The tire crown of the giant tire with the tire monitoring sensor can monitor the temperature of the tire tread and the belt layer of the tire in real time. The sensor of the present embodiment is mounted by processing a blind hole 10 having a depth between a base rubber 11 and a belt 12 in a crown of a tire, mounting the sensor 7 of the present embodiment to the bottom of the hole, filling a filling rubber rod 13 with a rubber adhesive compound in the blind hole 10, and removing air in the blind hole 10, wherein the filling rubber rod 13 can be replaced with a rubber raw rubber compound, and vulcanizing the rubber raw rubber compound to integrate the rubber with the tire, as shown in fig. 1 and 7.

The installation rule of the sensors in this embodiment is as shown in fig. 2, a group of sensors 7 is arranged at intervals along the circumferential direction of the tire, each group is composed of 3 monitoring sensors 7 along the axial direction of the tire, and the monitoring sensors are respectively located at the central position of the circumferential direction of the tire crown and at positions on two sides of the tire crown close to the tire shoulder, for example, as shown in fig. 2, the three groups framed by the dotted line on the top are a group 1, the three groups framed by the dotted line on the bottom are another group 2, and the groups not framed in the middle are spaced groups.

The main functional structure block diagram of the sensor 7 is shown in fig. 3, the specific structure is shown in fig. 4, the sensor comprises a micro-processing unit MCU4, a temperature detection module 6, an ultrahigh frequency communication antenna 3, a low frequency communication antenna 5, a battery 2 and a shell 1, wherein the low frequency wireless communication module and the ultrahigh frequency wireless communication module are connected with the micro-processing unit MCU4 through circuits; the acceleration sensor is integrated in the temperature detection module 6. All parts of the sensor are arranged in a shell 1, and the temperature detection module 6 is tightly attached to the inner wall of the bottom of the shell 1, so that the temperature detection module can directly measure the temperature of rubber contacted with the shell 1, and the accuracy of temperature measurement is improved.

The microprocessing unit MCU4 and peripheral circuits can at least complete tasks such as operation, control, storage, analog-to-digital conversion, data processing, power management and the like, and transmit acquired data to the vehicle-mounted data terminal through the ultrahigh frequency communication antenna 3.

During actual use, the temperature of each monitoring point can be obtained in real time under the condition of no stopping, and the real fault state can be reflected. Through analyzing and comparing temperature data of all detection points, the position of the possible inside disengaging fault can be found in time, and the detection device is convenient to overhaul in time.

Example 2:

on the basis of the tread of the extra-large tire in the embodiment 1, a wear detection module is added to the monitoring sensor 7 to form a monitoring sensor 9 with temperature detection and wear amount detection at the same time, as shown in fig. 5, 6 and 8. A wear detection module with a worn rubber body 8 added to the monitoring sensor 7 shown in fig. 4 has a size matching the blind hole while employing a housing capable of being integrally connected to the worn rubber body 8. The sensor becomes a tire monitoring sensor with temperature and abrasion amount detection functions by adding the abrasion detection module, and the functions of the monitoring sensor are further expanded. The monitoring sensor 9 can detect the wear amount of the tire according to a set strategy, and can find abnormal wear conditions such as local wear, excessive wear, partial wear and the like. The data is provided for judging the running states of the vehicle and the tires, the user can be informed of timely troubleshooting of the vehicle and road conditions through the monitoring of the abrasion loss of the tires, and the safe driving is guaranteed.

Claims (9)

1. The tyre crown of the extra-large tyre with the monitoring sensor is characterized in that the monitoring sensor is arranged in the tyre crown and positioned between a base rubber and a belted layer, and at least comprises a temperature detection module, and the monitoring sensor further comprises a microprocessing unit (MCU), a wireless communication module, a battery and a peripheral circuit.

2. An extra giant tire crown with monitoring sensors as claimed in claim 1, wherein the monitoring sensors are arranged in a manner corresponding to the tread blocks of the tire, and 1 group of sensors are arranged in the circumferential direction of the crown at the interval of each group of blocks arranged along the circumference or each group of blocks spaced by 1 or more groups; the number of arrays of each group of sensors along the axial direction of the tire is at least 1, and the position of the array is near the center of the tire crown and/or near the shoulders of the two sides of the tire crown.

3. An extra-giant tire crown with monitoring sensors as claimed in claim 2, characterized in that a group of sensors is arranged at intervals along the circumferential direction of the tire, each group is composed of 3 monitoring sensors along the axial direction of the tire, and the monitoring sensors are respectively located at the central position of the circumferential direction of the crown and at the positions close to the shoulders on the two sides of the crown.

4. An extra-large tire crown with a monitoring sensor according to claim 1, characterized in that the crown surface has a blind hole, the bottom of which is located between the base rubber and the belt, the monitoring sensor is mounted at the bottom of the hole, and the upper part is filled with a filling rubber rod or a rubber raw rubber.

5. An extra giant tire crown with a monitoring sensor according to claim 1, characterized in that the monitoring sensor further comprises a wear detection module for detecting the amount of wear of the tire pattern, the wear detection module being arranged within the pattern block and wearing synchronously with the tire pattern.

6. An extra giant tire crown with a monitoring sensor according to claim 1, characterized in that the monitoring sensor further comprises an attitude detection module for detecting the rotation of the tire, the attitude detection module having an acceleration sensor and/or a gyroscope.

7. An extra giant tire tread with monitoring sensors as claimed in claim 1, wherein each monitoring sensor has a unique code for identification, such that it uniquely identifies a sensor in an on-board data terminal and data management system.

8. An extra giant tire tread with a monitoring sensor according to any one of claims 1 to 7, characterised in that the tread is the tread of a new tire, a retreaded tire or a tire already in use.

9. A tire employing the tread cap of an extra large tire with a monitoring sensor of any one of claims 1 to 8, said tire being a new tire, a retreaded tire or a tire already in use.

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