SK289078B6 - Sensor of the size and acting location of the external force - Google Patents

Abstract

Sensor of the size and acting location of the external force consists of two or more optical media (2), of the pistons (3) transmitting an external force simultaneously on optical media (2) and from the housing (4) in which the optical media (2) are embedded, wherein the piston (3) is connected to the housing (4) by a thin layer of flexible material (10) and the optical media (2) are positioned so that the distance of their axes from the axis of the piston (3) depends on the coordinate measured along the axis of the sensor. Sensor of the size and acting location of the external force can be used, for example, for weighing cars in motion and makes it possible to determine the place of passage, the speed as well as the distribution of the load.

Description

The field of technology

The invention relates to a sensor of the size and location of the force. The field of technology to which the invention relates is measurement technology and sensor technology.

Current state of the art

Force sensors are devices that work on different physical principles. These devices make it possible to determine the magnitude of the applied force by using, for example, piezoelectric sensors, while the electrical voltage created on the opposite walls of the sensor when the force is applied is directly proportional to this force. It is also possible to use optical environments whose transmission parameters depend on the magnitude of the applied force. The effect of the acting external force on the absorption coefficient (microbending losses), the change in the polarization of optical radiation, the change in the wavelength of the reflected optical radiation after passing through the Bragg grating and on the optical length of the environment (various types of optical interferometers) is most often used.

Sensors based on the use of these physical principles are currently developed and fairly widely used in various applications, including their use for determining the weight of cars. Usually, only one parameter is determined with the help of sensors, namely the magnitude of the applied external force (SK 134-2018 U1 Device for measuring dynamic force using an optical fiber). If it is also necessary to determine the place of action of the external force, then another sensor is used to detect the place of action (CN101666660 (A) Vehicle load action position recognizing method based on fiber bragg grating sensing technology). When using a system consisting of several independent force sensors (KR100383818 (B1) Weight measurement system using fiber optic grating sensor), it is possible to determine, in addition to the size, the location of the applied force. In this case, the accuracy of determining the action of the force depends on the distance of the discrete elements used. And at the same time, the greater the number of elements for the purpose of determining the more precise location of the external force, the more complicated the construction and evaluation. A similar method of determining the size of the force and at the same time the location of the force, as presented, is described in PP 42-2019 Optical sensor of the size and location of the external force, with the difference that in the presented patent, the dimensions of the optical environment (in the example embodiment, a rod) depend on coordinate measured along the length of the optical medium.

The essence of the invention

The mentioned shortcomings are eliminated by the sensor of the size and location of the external force. The presented sensor of the size and location of the external force is not bound to a specific physical principle, so it can be implemented using sensors using the influence of the external force on various transmission parameters of the optical environment.

The sensor of the size and location of the external force, which is realized by using two or more optical environments through which optical rays (waves) pass, are located in the area in which the size and location of the force is to be determined, and the transmission parameters of these environments depend on the size of the external forces acting on optical environments. These optical environments are arranged in such a way that the external force acts simultaneously on the optical environments used, but the degree to which the external force is divided into components acting on the individual environments depends on the location in which it acts. Due to the dependence of the ratio by which the external force is divided into forces acting on individual environments, the optical state at the exit from these environments is also different from the place of action of the external force. Since the optical state is characterized by amplitude, phase and polarization, and all these characteristics can be detected by a suitable detector, the dependence of any of these parameters on the magnitude of the acting force can be used to determine the degree of external force action on individual optical environments, and with the known dependence of the ratio, in in which the force is divided into individual environments, detection of the optical state at their output makes it possible to determine the size and location of the external force acting.

Optical environments through which the used optical rays (waves) propagate can be realized as waveguides (optical fibers), light guides or objects with dimensions that are considerably larger than the wavelength of the used light (rods).

The property of optical sensors to simultaneously determine the magnitude of the force and the place of its action is manifested as an advantage, for example, in determining the weight of cars as they move. In addition, when the sensor is placed at a suitable angle against the direction of movement of the vehicle, a single sensor makes it possible to determine not only the weight, but also the speed of the passing car, as well as the distribution of the weight of the load.

Overview of images on drawings

The diagram of the assembly for determining the size and location of the external force using the influence of the deformation of the optical media 2 realized by means of optical fibers 2a and 2b for the orientation of the plane of polarization of light is shown in fig. 1. The scheme of the assembly for determining the size and location of the external force, using the influence of the deformation of the optical media 2 realized with the help of optical fibers 2a and 2b for the orientation of the plane of polarization of light, which uses its division by means of a split piston 3 to determine the location of the external force, is shown in Fig. 2. The scheme of the sensor for determining the size and location of the external force using the influence of the deformation of the optical media 2 realized by means of optical fibers 2a and 2b on the phase of light is shown in fig. 3.

Examples of implementation of the invention

Example 1

The scheme of the assembly for determining the size and location of the external force using the influence of the deformation of the optical media 2 realized in this example by the optical fibers 2a and 2b for the orientation of the plane of polarization of light is shown in fig. 1. In the presented sensor of the size and location of the external force, the optical radiation from the sources of polarized monochromatic light 1 is coupled into two optical fibers 2a and 2b, the transmission parameters of which are the same and do not depend on the longitudinal coordinate of the fiber and are placed under the piston 3 obliquely so that are parallel to each other and the distance of their axes from the axis of the piston 3 depends linearly on the distance measured along the axis of the piston 3. The piston 3 is connected to the housing 4 by a thin layer of flexible material 10. As a result, the forces with which the piston 3 acts on the optical fibers 2a and 2b they depend not only on the magnitude of the external force, but also on the place in which the external force acts. The sum of these forces is equal to the external applied force, so for optical fibers 2a and 2b, in which the dependence of the change of the transmission parameters on the magnitude of the applied force is linear, the sum of the changes of the detected optical parameter is proportional to the magnitude of the external force. But the difference of these forces depends on the location in which the external force acts on the sensor, so the changes in the optical state detected at the output of the optical fibers 2a and 2b also depend on the location in which the external force acts. After passing through the optical fibers 2a and 2b, the light rays are connected to two detectors of the polarization plane 5, consisting of light intensity detectors and polarization filters. The electrical signal from the detectors 5 is fed by coaxial cables 6 to the electronic evaluation unit 7, in which the magnitude and location of the external force is determined based on the knowledge of the distance between the axes of the optical fibers 2a and 2b and the dependence of the change in the orientation of the polarization plane on the magnitude of the applied force.

Example 2

The scheme of the assembly for determining the size and location of the external force, using the influence of the deformation of the optical media 2 realized with the help of optical fibers 2a and 2b for the orientation of the plane of polarization of light, which uses its division by means of a split piston 3 to determine the area of application of the external force, is shown in Fig. 2. In the presented sensor of the magnitude and location of the external force, the optical radiation from the sources of polarized monochromatic light 1 is coupled into two optical fibers 2a and 2b, the transmission parameters of which do not depend on the coordinate, are the same and are stored under the split piston 3 consisting of parts 3a and 3b . The widths of these pistons 3a and 3b depend on the coordinate measured along the optical fibers 2. Their widths are chosen so that their sum is the same at all distances and their difference increases linearly. In this case, the fiber 2a is placed under the piston 3a and the fiber 2b is placed under the piston 3b. Due to the different widths of the pistons 3a and 3b, the forces with which the pistons 3a and 3b act on the fibers 2a and 2b are not the same and depend on the location in which the external force acts. The sum of these forces is equal to the external applied force, so for fibers 2a and 2b, in which the changes in the transmission parameters on the magnitude of the applied force do not depend on the location, the sum of the changes in the detected optical parameter is proportional to the external force. But their difference is dependent on the place of action of the external force, so that the changes in the optical state detected at the output of fibers 2a and 2b are also dependent on the place where the external force acts.

After passing through the optical fibers 2a and 2b, the light rays are connected to two detectors of the polarization plane 5, consisting of light intensity detectors and polarization filters. The electric signal from the detectors 5 is fed by coaxial cables 6 to the electronic evaluation unit 7, in which, based on the knowledge of the dependence of the width of the pistons 3a and 3b on the coordinate and the dependence of the change in the orientation of the polarization plane on the magnitude of the applied force, the magnitude and location of the external force is determined.

Example 3

The scheme of the sensor for determining the size and location of the external force using the influence of the deformation of the optical media 2 realized by means of optical fibers 2a and 2b on the phase of light is shown in fig. 3. In such a sensor of the size and location of the external force, optical radiation from highly coherent light sources 1 is coupled into two optical fiber circulators 9, to which optical fibers 2a and 2b are connected, whose end faces are plated in order to increase the reflection coefficient. The transmission parameters of these fibers 2a and 2b are the same in all places. The fibers 2a and 2b are placed under the piston 3 obliquely so that they are parallel to each other, and the distance of their axes from the axis of the piston 3 depends linearly on the distance measured along the axis of the piston 3. As a result, the force exerted by the piston on the fibers 2a and 2b also depends from the point where the external force acts. The sum of these forces is equal to the external force, so for fibers where the dependence of the change in transmission parameters on the magnitude of the force is linear, the sum of changes in the detected optical parameter is proportional to the magnitude of the external force, and their difference is dependent on the coordinate measured along fibers 2a and 2b. so even changes in the optical state detected at the output of the optical fiber circulators 9 are dependent on the place where the external force acts. The light intensity at the output of optical fiber circulators 9 is detected by detectors 5.

The light intensity at the output of the optical fiber circulators 9 is the interference intensity of the waves reflected at the front of the optical fibers 2a and 2b, through which the light enters the fibers 2a and 2b, and at their end, so it provides information about the change in their length caused by an external force. The electrical signal from the detectors 5 is fed via coaxial cables 6 to the electronic evaluation unit 7, in which, based on the knowledge of the dependence of the distance of the axes of the optical fibers 2a and 2b from the axis of the piston 3 and the dependence of the phase change on the magnitude of the applied force, the magnitude and location of the external force is determined.

The intensity of the interference signal is a monotonic function of the phase difference only in the range π, which corresponds to a change in the length of the optical fiber 2 by half the wavelength of the light used. This results in both the high sensitivity of the system and its small range. But with the use of a fast enough detection system, with a monotonically increasing and monotonically decreasing force, it is possible to determine its magnitude from the time course of the signal obtained during the application of the external force. Its determination is possible because from the number of periods of the recorded signals it is possible to determine how many times the phase of the signal has changed by the value of 2π, and thus to determine the phase change and thus the magnitude of the force on a large scale and with great accuracy. In this way, the system enables the combination of high sensitivity and a large area in which the magnitude of the force and the place of its action can be determined.

Industrial applicability

A sensor consisting of several optical environments with different parameters depending on the location of the force can be used to determine the magnitude and location of the force, which can be used in measurement and sensor technology, for example, for weighing moving vehicles, as well as for checking the uniform distribution of the weight of the load vehicles.

List of relationship tags

- sources of linearly polarized monochromatic light

- optical environments

2a - optical fiber

2b - optical fiber

- pistons

3a - piston

3b - piston

- case

- polarization plane detectors

- coaxial cables

- electronic evaluation unit

- optical fiber circulators

- a thin layer of flexible material

Claims (2)

1. A sensor of the magnitude and location of the external force, consisting of two or more optical environments (2), a piston (3) transmitting the external force simultaneously to the optical environments (2), a housing (4), 5 in which the optical environments (2) ) stored, while the piston (3) is connected to the sleeve (4) by a thin layer of flexible material (10), characterized by the fact that the optical environments (2) are located in such a way that the distance of their axes from the axis of the piston (3) depends on coordinates measured along the axis of the sensor. 2. Sensor of the size and location of the external force, consisting of two or more optical environments (2), a split piston (3) transmitting the external force to the optical environments (2), a housing 10 (4) in which the optical environments (2) ) stored, while the piston (3) is connected to the sleeve (4) by a thin layer of flexible material (10), characterized by the fact that the optical environments (2) are placed under the divided piston (3), divided into at least two parts (3a, 3b), the width of which depends on the coordinate measured along the axis of the sensor.