RU2525313C2 - Method of determining degree of damage of silage housing of elevator of precast reinforced concrete - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to food and flour and elevator industry and is used to assess the degree of damage of the joints of the outer silage of the elevator of precast reinforced concrete. According to the inventive method the thermal imaging device with a sensitivity of ±0.1°C and wavelength of 2-12 micron is mounted at a distance of 1-100 m from the surface of the elevator at an angle of 20° with positive outdoor temperature and the temperature difference between the inside and outside of the silage of at least 4°C. Then the thermal imaging recording of the outer surface of the silage housing is carried out. Then the results of thermal imaging recording are processed on the computer and the thermal imaging report is obtained according to which the maximum and minimum temperature on the surface of outer walls of the silage housing of the elevator are determined, and the difference of the said temperatures is calculated. The location and degree of damage of the joints of the outer silage of the elevator is determined according to the said method.

EFFECT: improved accuracy and informativeness of the obtained information about the defects of the joints of the outer silage of the elevator of precast reinforced concrete.

Description

The invention relates to the food and flour-grinding industry and is used to assess the degree of damage to the seams of the external silo of a prefabricated reinforced concrete.

A known method for determining the presence of damage to the watertightness of the outer walls of precast concrete silos using artificial sprinkling, involving surface irrigation of the outer walls of the silo with water with free flowing of water along the wall of the silo and establishing the location of damage through the flow of water from the inside. Sprinkling is carried out by grips with a width of 2 m. The vertical and horizontal joints located in the gripping zone are simultaneously tested. The capture includes one strip of vertical joints with a width of 0.5 m and a strip of horizontal joints with a width of 1.5 m. Tests are performed on 20% of the silos located along the perimeter of the hull (“Temporary production test for permeability of walls of precast concrete silos” TsNIIEPselstroy, TsNIIIPromzernoproekt, NIIMosstroy. - M .: 1977.)

The disadvantages of this method include:

- bulkiness of the structure;

- the need for a large amount of water resources;

- significant manual labor costs for moving the gripper (laboriousness) and the need for high-altitude work, life-threatening;

- the duration of the test (5-7 days);

- subjectivity of leakage assessment;

- insufficiently high accuracy, because it is impossible to quantify the extent of damage.

The technical result of the invention is to increase the accuracy of determining the degree of damage to the elevator, reducing the duration of the test and reducing the complexity.

To achieve the specified technical result, a method for determining the degree of damage to the silo of an elevator made of precast concrete, characterized in that a thermal imaging device is installed with a sensitivity of ± 0.1 ° C and a wavelength of 2-12 μm at a distance of 1-100 m from the outer surface of the silo of the elevator at an angle of no more than 20 ° with a positive temperature of the outside air and a temperature difference between the inside and outside of the silo of at least 4 ° C, thermal imaging of the surface under study is carried out, thermogr an aphic report (thermogram), which establishes the maximum and minimum temperature on the surface of the outer walls of the silo of the elevator and determine the place and degree of damage to the seams of the outer silo of the elevator by the difference in the indicated temperatures.

The essence of the method is as follows.

Prefabricated reinforced concrete silos have a square section of silos, the walls of which are mounted from staggered staggered blocks and flat panels. During the operation of silos, due to the influence of adverse factors, horizontal cracks appear in the joints and the destruction of vertical joints, which reduces the waterproofness of the walls of the silos. Water penetrating the joints worsens the sanitary conditions, causes increased corrosion of the fittings, the destruction of the joints and the blocks themselves at low temperatures, resulting in reduced building service life. Establishing the place of damage to the outer walls of the silo, the degree of damage to it allows us to determine the need for work on sealing defective joints, as well as to predict the amount and time of occurrence of such work in the future.

In order to improve accuracy, reduce the duration of the test and reduce the complexity, the place and degree of damage to the silo of the elevator made of precast concrete is determined by the difference between the maximum and minimum temperatures on the surface of the outer walls of the silo of the elevator, measured by a thermal imaging device, the action of which is based on measuring infrared radiation of objects and converting it to a visible image. The level of infrared radiation depends on the surface temperature of the object and on its emissivity. This allows the camera to calculate and display this temperature through a formula.

To determine the degree of damage to the silo casing of the elevator from precast concrete, a thermal imaging device is installed with a sensitivity of ± 0.1 ° C and a wavelength of 2-12 μm at a distance of 1-100 m from the elevator surface at an angle of no more than 20 °. At the same time, the outdoor temperature should be positive, and the difference between the internal and external temperatures of the walls of the empty silo should be at least 4 ° C, thereby improving the conditions for the detection and identification of sections of building envelopes with reduced insulating properties. If the tilt angle of the thermal imaging device is exceeded more than 20 °, the emissivity changes, and as a result, the error in the measurement of the temperature field increases. With an increase in the distance to the measurement object by more than 100 m, the detail of the inspection worsens and the true temperature values are distorted. When the sensitivity of the thermal imaging device is more than ± 0.1 ° C and the wavelength outside the range of 2-12 μm, the measurement accuracy decreases.

Next, thermal imaging of the outer surface of the silo body is carried out. Thermography of the outer walls of the silo can be limited to a common panoramic picture covering the entire wall, if it is impossible to make frame-by-frame shooting due to the small available distance to this object.

The detection of latent defects is based on the principle of comparing the current control zone with the reference (defect-free) zone and determining its thermal characteristics. The reference area is indicated for technological reasons or is determined during thermal imaging inspection. In this case, a thermal imager (infrared scanner) is used to measure surface temperature.

Then, the results of thermal imaging are processed on a computer and a thermographic report (thermogram) is obtained, which sets the maximum and minimum temperatures on the surface of the outer walls of the silo casing of the elevator and calculates the difference in the indicated temperatures.

It was experimentally established that with hermetic seams, the entire outer surface of the silo wall should be in the temperature range from 1 to 2 ° C and the degree of damage in this case is from 0 to 5%, due to different emissivities of the sealing solution and the concrete surface of the sogs, since the air temperature is inside silo is different from outside temperature. If the joints are not tight, air with a lower temperature inside the joint penetrates the outer surface of the joint and lowers its temperature. Under such conditions, the temperature range increases from 3 ° C and above with a characteristic degree of damage to the joints from 25 to 75%. It was also experimentally established that the temperature range with a difference of 4 ° C indicates a significant (almost complete) depressurization of the joints and the possibility of penetration of atmospheric moisture into the silo, and as a consequence of the need for work to seal defective joints.

Next, determine the place and degree of damage to the seams of the external silo of the elevator according to the following signs:

The difference between the maximum and minimum temperatures on the surface of the outer walls of the silo Quantitative description of the degree of damage to the joints of the outer Qualitative condition of seams (joints) of the external silo of the elevator

elevator, ° С elevator silo,% from 1 to 2 0-5 Good (no damage) from 2 to 3 5-25 satisfactory (the beginning of the depressurization process) from 3 to 4 25-75 deeply developed process of depressurization of joints from 4 and above 75-100 complete depressurization of joints and, as a consequence, the need for work to seal them

The place of damage to the silo casing of the elevator is set according to the thermogram in the area with the external temperature of the surface of the outer walls of the silo below their maximum temperature in the same thermogram by more than 2 ° C.

The invention is illustrated in the following examples.

Example 1. Opposite the wall of the silo casing of the elevator, a thermal imaging device with a sensitivity of ± 0.1 ° C and a wavelength of 2-12 μm at a distance of 50 m from the elevator surface at an angle of 3 ° at an outdoor temperature of 23 ° C and temperature differences inside and outside is installed silo 7 ° C. Thermal imaging is carried out, the results are processed on a computer and a thermographic report is obtained, according to which the maximum and minimum temperatures on the surface of the outer walls of the silo of the elevator are set, which are 21.9 and 20.3 ° C, respectively. From the obtained results, the difference in the indicated temperatures is calculated - 1.6 ° C. Then establish the place and degree of damage to the seams of the external silo of the elevator according to the stated signs. Make a conclusion about the absence of a place of damage, the good condition of the seams of the external silo of the elevator and that the degree of damage does not exceed 5%. This indicates a good tightness of the seams.

Example 2. Opposite the wall of the silo casing of the elevator, a thermal imaging device with a sensitivity of ± 0.1 ° C and a wavelength of 2-12 μm at a distance of 25 m from the surface of the elevator at an angle of 5 ° at an outdoor temperature of 24 ° C and a temperature difference inside and outside silo 8 ° C. Thermal imaging is carried out, the results are processed on a computer and a thermographic report is obtained, according to which the maximum and minimum temperatures on the surface of the outer walls of the silo of the elevator are set, which are 21.8 and 19.1 ° C, respectively. From the obtained results, the difference in the indicated temperatures is calculated - 2.7 ° C. Then establish the place and degree of damage to the seams of the external silo of the elevator according to the stated signs. The place of damage to the silo is set according to the thermogram in the area with its external temperature of 19.1 ° C, which is lower than the maximum by more than 2 ° C. Make a conclusion about the satisfactory condition of the seams of the external silo of the elevator and that the degree of damage does not exceed 25%. Such a temperature field indicates a weakening of the sealing of the seams, but has not reached a critical value.

Example 3. Opposite the wall of the silo casing of the elevator, a thermal imaging device with a sensitivity of ± 0.1 ° C and a wavelength of 2-12 μm at a distance of 25 m from the elevator surface at an angle of 5 ° at an outdoor temperature of 25 ° C and a temperature difference of inside and outside is installed silo 12 ° C. Thermal imaging is carried out, the results are processed on a computer and a thermographic report is obtained, according to which the maximum and minimum temperatures on the surface of the outer walls of the silo casing of the elevator are set at 14.1 and 23.0 ° C, respectively. From the obtained results, the difference in the indicated temperatures is calculated - 8.9 ° C. Then establish the place and degree of damage to the seams of the external silo of the elevator according to the stated signs. The place of damage to the silo is set according to the thermogram in the area with its external temperature of 14.1 ° C, which is lower than the maximum by more than 2 ° C. Make a conclusion about the complete depressurization of the seams of the external silo of the elevator and that the degree of damage is more than 75%.

Thus, the invention improves the accuracy, reduce the duration, reduce the complexity of the method of determining the degree of damage to the outer walls of the silo of the elevator from precast concrete, and also evaluate it quantitatively.

Claims (1)

A method for determining the degree of damage to the silo housing of the precast concrete, characterized in that a thermal imaging device is installed with a sensitivity of ± 0.1 ° C and a wavelength of 2-12 μm at a distance of 1-100 m from the outer surface of the silo housing of the elevator at an angle of not more than 20 ° at a positive outside temperature and the temperature difference inside and outside the silo of at least 4 ° C, a thermal imaging survey of the test surface is carried out, a thermographic report (thermogram) is obtained, according to which vayut maximum and minimum temperature on the surface of external walls of the silo housing the elevator and the temperature difference of said determined location and degree of damage of the outer silo elevator seams.