Temperature measuring method

文档序号:5688 发布日期:2021-09-17 浏览:46次 中文

1. A method of measuring a temperature indicative of a temperature of a cladding having a containment cavity for containing nuclear fuel at a blast opening of the cladding at a first time instant at which the cladding is blasted to form a blast opening, the method comprising:

performing bulging blasting on the cladding in the target state under a preset condition to obtain a reference position of a blasting opening of the cladding, heating the cladding through a heating device, and when the cladding is in the target state, locating a central line of the cladding at a preset position of the heating device;

setting at least two first measuring positions on the cladding which is not subjected to the bulging blasting according to the reference position, wherein the at least two first measuring positions are staggered with the reference position, and each first measuring position is provided with a first temperature measuring element;

performing bulging blasting on the cladding provided with the first temperature measuring element under a preset condition to obtain first data and a to-be-detected position of a blasting opening of the cladding, wherein the first data is the temperature measured by the first temperature measuring element at the first moment, and the cladding provided with the first temperature measuring element is in a target state in the process of performing bulging blasting on the cladding provided with the first temperature measuring element;

acquiring interpolation basic data of the cladding under a preset condition;

and carrying out interpolation processing on the position to be detected according to the first data and the interpolation basic data to obtain the characterization temperature.

2. The temperature measurement method according to claim 1, wherein obtaining the interpolation base data of the cladding under the preset condition comprises:

increasing the temperature of a heating device to a reference blasting temperature under a preset condition, wherein the heating device is configured to heat the cladding, the cladding is in a target state in the heating process, and the time when the temperature of the heating device reaches the reference blasting temperature is a second time;

and acquiring the temperature distribution of the cladding at the second moment as the interpolation basic data.

3. The temperature measurement method of claim 2, wherein the temperature profile comprises an axial temperature profile and a circumferential temperature profile of the cladding; the reference position is positioned between at least two first measuring positions along the axial direction of the cladding, each first measuring position comprises at least two sub-measuring positions, each sub-measuring position is provided with the first temperature measuring element, and the distance between one sub-measuring position and the reference position in the axial direction of the cladding is equal to the distance between the other sub-measuring position and the reference position in the axial direction of the cladding; carrying out interpolation processing on the position to be detected according to the first data and the interpolation basic data to obtain the characterization temperature, wherein the interpolation processing comprises the following steps:

for each first measurement position, performing circumferential interpolation on the position to be measured according to the circumferential temperature distribution, a first temperature and a second temperature to obtain a third temperature, wherein the first temperature is measured by a first temperature measuring element at one sub-measurement position at a first moment, and the second temperature is measured by the first temperature measuring element at the other sub-measurement position at the first moment;

and carrying out axial interpolation on the position to be measured according to at least two third temperatures and the axial temperature distribution to obtain the characterization temperature.

4. The temperature measuring method of claim 3, wherein at least two of the sub-measuring positions are a first sub-measuring position and a second sub-measuring position, wherein the first sub-measuring position and the second sub-measuring position are at an angle of 180 degrees along the circumferential direction of the cladding, the first temperature is measured by the first temperature measuring element at the first sub-measuring position at a first time, and the second temperature is measured by the first temperature measuring element at the second sub-measuring position at the first time; in the process of carrying out bulging blasting on the cladding provided with the first temperature measuring element, a first sub-measuring position is located in a first reference plane, the first reference plane is respectively superposed with a center line of the cladding and a guiding position, the guiding position is a position of a highest temperature position of the cladding in the circumferential temperature distribution relative to the heating device at a second moment, and the first sub-measuring position is located on one side, facing the guiding position, of the center line of the cladding; carrying out circumferential interpolation on the position to be measured according to the circumferential temperature distribution, the first temperature and the second temperature to obtain a third temperature, and the method comprises the following steps:

acquiring a fourth temperature and a fifth temperature in the circumferential temperature distribution, wherein the fourth temperature is the highest temperature in the circumferential temperature distribution, and an included angle between the position of the fifth temperature and the position of the fourth temperature along the circumferential direction of the cladding is 180 degrees;

acquiring a sixth temperature in the circumferential temperature distribution, wherein the sixth temperature is the temperature at the position to be measured in the circumferential temperature distribution;

and carrying out circumferential interpolation on the position to be measured according to the first temperature, the second temperature, the fourth temperature, the fifth temperature and the sixth temperature to obtain the third temperature.

5. The temperature measuring method according to claim 4, wherein the third temperature is calculated by the formula:

in the formula:

t is a third temperature;

a is a fourth temperature;

b is a fifth temperature;

c is a sixth temperature;

d is the first temperature;

and e is the second temperature.

6. The method according to claim 3, wherein the obtaining the characterization temperature by performing an axial interpolation on the to-be-measured location according to at least two third temperatures and the axial temperature distribution comprises:

obtaining a seventh temperature and an eighth temperature according to the axial temperature distribution, wherein the seventh temperature is the temperature at one first measurement position in the axial temperature distribution, the eighth temperature is the temperature at the other first measurement position in the axial temperature distribution, and the seventh temperature is less than the eighth temperature;

acquiring a ninth temperature in the axial temperature distribution, wherein the ninth temperature is the temperature at the position to be measured in the axial temperature distribution;

and carrying out axial interpolation on the position to be measured according to the two third temperatures, the seventh temperature, the eighth temperature and the ninth temperature to obtain the characterization temperature.

7. The temperature measurement method according to claim 6, wherein the calculation formula for the characteristic temperature is:

in the formula:

Tpto characterize the temperature

h is an eighth temperature;

i is a seventh temperature;

j is the ninth temperature;

T1the greater of the two third temperatures;

T2the smaller of the two third temperatures.

8. The temperature measurement method according to claim 3, wherein the obtaining of the interpolation base data of the cladding under the preset condition before the temperature of the heating device is increased to the reference blasting temperature under the preset condition further comprises: the method comprises the steps that a plurality of second measuring positions and a plurality of third measuring positions are arranged on a cladding, the second measuring positions are arranged along the axial direction of the cladding, each second measuring position is provided with a second temperature measuring element, the axial temperature distribution is obtained through the second temperature measuring elements, the third measuring positions are arranged along the circumferential direction of the cladding, each third measuring position is provided with a third temperature measuring element, all the third measuring positions are located in a second reference plane, the second reference plane is perpendicular to the axial direction of the cladding, and the circumferential temperature distribution is obtained through the third temperature measuring elements.

9. The temperature measurement method according to any one of claims 1 to 8, wherein the preset conditions include a preset pressure in the pressure inside the enclosure and a preset temperature rise rate of the heating device.

10. The temperature measurement method according to any one of claims 1 to 8, wherein the time at which the explosion of the cladding forms the explosion vent is a difference between a time at which a pressure in the cladding suddenly drops and a measurement response time of the pressure in the cladding; the measurement method further comprises: and acquiring the measurement response time.

Background

In the safety analysis Of the nuclear reactor core, there is a very considerable hypothetical Accident, namely, the Large Break Loss Of Coolant Accident (LOCA). If a new fuel is to be deployed in a pressurized water reactor, the fuel's performance under the LOCA must be studied to prove its reliability under possible LOCA incidents and to provide experimental data for core safety analysis programs.

The phenomenon of cladding bulging and blasting inevitably occurs in the LOCA process of the pressurized water reactor, and if the cladding is excessively embrittled, the cladding is possibly cracked to block the whole flow channel; in the case of a cladding that is not overly embrittled, extreme coplanar bulging may occur to plug portions of the flow channels.

During the operation of a nuclear power plant reactor, the performance of nuclear fuel is an important factor affecting the safety and economy of the reactor. Therefore, the research on fuel elements is put on a very prominent position internationally, and various performances of the nuclear fuel elements are continuously improved by optimizing the design of the fuel elements, adopting advanced structural materials, improving element manufacturing processes and other methods, so that nuclear power is promoted to develop towards a safer and more economic direction. However, according to the requirements of reactor safety, before a nuclear fuel adopting a novel fuel cladding enters large-scale application, the nuclear fuel should be tested for its bulging blasting performance under the LOCA. In the related art, it is difficult to measure the temperature at the moment when the explosion of the clad occurs at the explosion port of the clad more accurately.

Disclosure of Invention

In view of the above, it is desirable to provide a temperature measuring method to measure the temperature at the moment of explosion of the cladding at the explosion opening of the cladding more accurately.

To achieve the above object, an embodiment of the present application provides a temperature measuring method for measuring a characteristic temperature of a cladding having a receiving cavity for receiving nuclear fuel, the characteristic temperature being a temperature at a first time at a bursting opening of the cladding, the first time being a time at which the bursting of the cladding to form the bursting opening, the temperature measuring method including:

performing bulging blasting on the cladding in the target state under a preset condition to obtain a reference position of a blasting opening of the cladding, heating the cladding through a heating device, and when the cladding is in the target state, locating a central line of the cladding at a preset position of the heating device;

setting at least two first measuring positions on the cladding which is not subjected to the bulging blasting according to the reference position, wherein the at least two first measuring positions are staggered with the reference position, and each first measuring position is provided with a first temperature measuring element;

performing bulging blasting on the cladding provided with the first temperature measuring element under a preset condition to obtain first data and a to-be-detected position of a blasting opening of the cladding, wherein the first data is the temperature measured by the first temperature measuring element at the first moment, and the cladding provided with the first temperature measuring element is in a target state in the process of performing bulging blasting on the cladding provided with the first temperature measuring element;

acquiring interpolation basic data of the cladding under a preset condition;

and carrying out interpolation processing on the position to be detected according to the first data and the interpolation basic data to obtain the characterization temperature.

In one embodiment, obtaining the interpolation basic data of the cladding under the preset condition comprises:

increasing the temperature of a heating device to a reference blasting temperature under a preset condition, wherein the heating device is configured to heat the cladding, the cladding is in a target state in the heating process, and the time when the temperature of the heating device reaches the reference blasting temperature is a second time;

and acquiring the temperature distribution of the cladding at the second moment as the interpolation basic data.

In one embodiment, the temperature profile includes an axial temperature profile and a circumferential temperature profile of the cladding; the reference position is positioned between at least two first measuring positions along the axial direction of the cladding, each first measuring position comprises at least two sub-measuring positions, each sub-measuring position is provided with the first temperature measuring element, and the distance between one sub-measuring position and the reference position in the axial direction of the cladding is equal to the distance between the other sub-measuring position and the reference position in the axial direction of the cladding; carrying out interpolation processing on the position to be detected according to the first data and the interpolation basic data to obtain the characterization temperature, wherein the interpolation processing comprises the following steps:

for each first measurement position, performing circumferential interpolation on the position to be measured according to the circumferential temperature distribution, a first temperature and a second temperature to obtain a third temperature, wherein the first temperature is measured by a first temperature measuring element at one sub-measurement position at a first moment, and the second temperature is measured by the first temperature measuring element at the other sub-measurement position at the first moment;

and carrying out axial interpolation on the position to be measured according to at least two third temperatures and the axial temperature distribution to obtain the characterization temperature.

In one embodiment, one of the at least two sub-measurement positions is a first sub-measurement position, and the other sub-measurement position is a second sub-measurement position, the included angle between the first sub-measurement position and the second sub-measurement position along the circumferential direction of the cladding is 180 degrees, the first temperature is measured by the first temperature measuring element at the first sub-measurement position at a first moment, and the second temperature is measured by the first temperature measuring element at the second sub-measurement position at the first moment; in the process of carrying out bulging blasting on the cladding provided with the first temperature measuring element, a first sub-measuring position is located in a first reference plane, the first reference plane is respectively superposed with a center line of the cladding and a guiding position, the guiding position is a position of a highest temperature position of the cladding in the circumferential temperature distribution relative to the heating device at a second moment, and the first sub-measuring position is located on one side, facing the guiding position, of the center line of the cladding; carrying out circumferential interpolation on the position to be measured according to the circumferential temperature distribution, the first temperature and the second temperature to obtain a third temperature, and the method comprises the following steps:

acquiring a fourth temperature and a fifth temperature in the circumferential temperature distribution, wherein the fourth temperature is the highest temperature in the circumferential temperature distribution, and an included angle between the position of the fifth temperature and the position of the fourth temperature along the circumferential direction of the cladding is 180 degrees;

acquiring a sixth temperature in the circumferential temperature distribution, wherein the sixth temperature is the temperature at the position to be measured in the circumferential temperature distribution;

and carrying out circumferential interpolation on the position to be measured according to the first temperature, the second temperature, the fourth temperature, the fifth temperature and the sixth temperature to obtain the third temperature.

In one embodiment, the calculation formula of the third temperature is:

in the formula:

t is a third temperature;

a is a fourth temperature;

b is a fifth temperature;

c is a sixth temperature;

d is the first temperature;

and e is the second temperature.

In an embodiment, performing an axial interpolation on the position to be measured according to at least two third temperatures and the axial temperature distribution to obtain the characterization temperature includes:

obtaining a seventh temperature and an eighth temperature according to the axial temperature distribution, wherein the seventh temperature is the temperature at one first measurement position in the axial temperature distribution, the eighth temperature is the temperature at the other first measurement position in the axial temperature distribution, and the seventh temperature is less than the eighth temperature;

acquiring a ninth temperature in the axial temperature distribution, wherein the ninth temperature is the temperature at the position to be measured in the axial temperature distribution;

and carrying out axial interpolation on the position to be measured according to the two third temperatures, the seventh temperature, the eighth temperature and the ninth temperature to obtain the characterization temperature.

In one embodiment, the calculation formula of the characteristic temperature is:

in the formula:

Tpto characterize the temperature

h is an eighth temperature;

i is a seventh temperature;

j is the ninth temperature;

T1the greater of the two third temperatures;

T2the smaller of the two third temperatures.

In one embodiment, before increasing the temperature of the heating device to the reference blasting temperature under the preset condition, obtaining the interpolation basic data of the cladding under the preset condition, further comprises: the method comprises the steps that a plurality of second measuring positions and a plurality of third measuring positions are arranged on a cladding, the second measuring positions are arranged along the axial direction of the cladding, each second measuring position is provided with a second temperature measuring element, the axial temperature distribution is obtained through the second temperature measuring elements, the third measuring positions are arranged along the circumferential direction of the cladding, each third measuring position is provided with a third temperature measuring element, all the third measuring positions are located in a second reference plane, the second reference plane is perpendicular to the axial direction of the cladding, and the circumferential temperature distribution is obtained through the third temperature measuring elements.

In one embodiment, the predetermined conditions include a predetermined pressure within the enclosure and a predetermined ramp rate of the heating device.

In one embodiment, the moment when the rupture of the cladding forms the rupture port is the difference between the moment of the sudden drop in pressure in the cladding and the measured response time of the pressure in the cladding; the measurement method further comprises: and acquiring the measurement response time.

According to the temperature measuring method, the reference position of the blast hole of the cladding is obtained under the preset condition, and when the first measuring position is arranged on the cladding, the first measuring position and the reference position are correspondingly staggered, so that the possibility that the corresponding first temperature measuring element is subjected to larger impact at the blast hole is reduced as much as possible, and the first temperature measuring element can accurately measure the temperature at the corresponding first measuring position. The method comprises the steps of obtaining first data and a to-be-detected position of a bursting opening of a cladding after the cladding provided with a first temperature measuring element is blasted, carrying out interpolation processing on the to-be-detected position according to interpolation basic data and the first data obtained by measurement of the first temperature measuring element to obtain a characteristic temperature, directly arranging an element for measuring the temperature at the bursting opening to measure the temperature at the bursting opening, and enabling the first temperature measuring element to be small in impact and accurate in measured temperature data. The characterization temperature is indirectly obtained through the temperature measured by the first temperature measuring element at the position other than the blast hole, so that the temperature of the blast hole of the cladding at the moment that the cladding is blasted is accurately measured.

Drawings

FIG. 1 is a schematic structural view of an enclosure according to an embodiment of the present application showing a plurality of second measuring locations axially distributed on the enclosure, each second measuring location having a second temperature sensing element, the third measuring location and the third temperature sensing element not being shown;

FIG. 2 is an axial temperature profile of an enclosure according to an embodiment of the present application;

FIG. 3 is a cross-sectional view taken at location A-A of FIG. 1 showing a plurality of third measuring locations on the cladding circumferentially distributed, each third measuring location having a third temperature sensing element, the second and second temperature sensing elements not shown;

FIG. 4 is a circumferential temperature profile of the cladding of an embodiment of the present application;

FIG. 5 is a schematic structural view of an enclosure according to an embodiment of the present application showing a first sub-measurement position and a second sub-measurement position on the enclosure, each of the first sub-measurement position and the second sub-measurement position having a first temperature sensing element, showing a pressure measuring element for measuring pressure within the enclosure;

FIG. 6 is a cross-sectional view taken at location B-B of FIG. 5;

FIG. 7 is a graph of the time dependence of the parameters associated with the ballooning blasting process in accordance with an embodiment of the present application;

FIG. 8 is a schematic view of an embodiment of the present application with the enclosure placed in a heating device;

FIG. 9 is a schematic view of the enclosure of FIG. 8 after being rotated through an angle.

Description of reference numerals: an enclosure 100; a blast opening 101; a second measurement position 200; a third measurement position 300; a first measurement position 400; a first sub-measurement position 401; a second sub-measurement position 402; a pressure measuring element 500; a second reference plane 600; a first reference plane 700; a centerline 800; the device 900 is heated.

Detailed Description

It should be noted that, in the present application, technical features in examples and embodiments may be combined with each other without conflict, and the detailed description in the specific embodiment should be understood as an explanation of the gist of the present application and should not be construed as an improper limitation to the present application.

In the description of the embodiments of the present application, the bulging blasting is a process, and the process of bulging blasting includes a process in which the temperature of the clad is raised from the time of heating the clad having a certain internal pressure to the time of bursting the clad. The bursting of the cladding creates a blast opening. The moment when the cladding is blasted to form the blast hole is a time node in the whole bulging blasting process.

Before describing the embodiments of the present application, it is necessary to analyze the reason why it is difficult to accurately measure the temperature of the cladding explosion hole at the time when the cladding is blown out, and to obtain the technical solution of the embodiments of the present application through reasonable analysis.

In the related art, a thermocouple is usually installed at a bursting port of a cladding to directly measure the temperature of the bursting port, the cladding is blasted to form the bursting port in the process of blasting the cladding, when the cladding is blasted, the impact at the bursting port of the cladding is large, the thermocouple at the bursting port is subjected to large impact at the moment when the cladding is blasted, and the thermocouple at the bursting port is difficult to accurately measure the temperature at the bursting port, so that the temperature at the bursting port of the cladding at the moment when the cladding is blasted is difficult to accurately measure.

In view of this, referring to fig. 1, an embodiment of the present application provides a temperature measurement method for measuring a characteristic temperature of an enclosure 100, the enclosure 100 having a containment chamber for containing nuclear fuel, the characteristic temperature being a temperature at a first time at which a blast opening 101 of the enclosure 100 is at, the first time being a time at which a blast of the enclosure 100 occurs, the temperature measurement method comprising:

performing bulging blasting on the cladding 100 in a target state under a preset condition to obtain a reference position of a blasting hole 101 of the cladding 100, heating the cladding 100 by a heating device 900, and when the cladding 100 is in the target state, locating a central line 800 of the cladding 100 at a preset position of the heating device 900;

arranging at least two first measuring positions 400 on the cladding 100 which is not subjected to the bulging blasting according to the reference position, wherein the at least two first measuring positions 400 are staggered with the reference position, and each first measuring position 400 is provided with a first temperature measuring element;

performing bulging blasting on the cladding 100 provided with the first temperature measuring element under a preset condition to obtain first data and a position to be measured of a blasting opening 101 of the cladding 100, wherein the first data is the temperature of the first temperature measuring element at a first moment, and the cladding 100 provided with the first temperature measuring element is in a target state in the process of performing the bulging blasting on the cladding 100 provided with the first temperature measuring element;

acquiring interpolation basic data of the cladding 100 under a preset condition;

and carrying out interpolation processing on the position to be measured according to the first data and the interpolation basic data to obtain the characterization temperature.

Thus, by obtaining the reference position of the explosion opening 101 of the cladding 100 under the preset condition, when the first measurement position 400 is arranged on the cladding 100, the first measurement position 400 is correspondingly staggered with the reference position, so that the possibility that the corresponding first temperature measurement element is subjected to larger impact at the explosion opening 101 is reduced as much as possible, and the first temperature measurement element can more accurately measure the temperature at the corresponding first measurement position 400. After the cladding 100 provided with the first temperature measuring element is blasted, first data and a position to be measured of the blast hole 101 of the cladding 100 are obtained, interpolation processing is carried out on the position to be measured according to the interpolation basic data and the first data obtained by measuring the first temperature measuring element to obtain a characteristic temperature, an element for measuring the temperature is not required to be directly arranged at the blast hole 101 to measure the temperature at the blast hole 101, the first temperature measuring element is less impacted, and the measured temperature data is more accurate. The temperature measured by the first temperature measuring element at a position other than the blast hole 101 indirectly obtains the characterization temperature, thereby more accurately measuring the temperature of the blast hole 101 of the cladding 100 at the moment when the cladding 100 is blasted.

It will be appreciated that the measured characteristic temperature is a temperature obtained by bursting the cladding 100 under predetermined conditions, which may vary accordingly.

In one embodiment, the step of obtaining the interpolation basic data of the cladding 100 under the preset condition and the step of performing the inflation blasting on the cladding 100 in the target state under the preset condition to obtain the reference position of the blast hole 101 of the cladding 100 are not in sequence.

In one embodiment, the enclosure 100 is generally circular tubular in shape.

In one embodiment, the first temperature measuring element is a thermocouple.

In one embodiment, the temperature of the first measurement location 400 on the enclosure 100 may be obtained by a non-contact thermometer.

It will be appreciated that the pressure within the enclosure 100 and the rate of rise of the heating means 900 heating the enclosure 100 will have some effect on the final measured characteristic temperature. In one embodiment, the predetermined conditions include a predetermined pressure within the enclosure 100 and a predetermined ramp rate for the heating device 900. Thus, the related experiments are performed under the conditions that the pressure in the cladding 100 is the preset pressure and the heating rate of the heating device 900 is the preset heating rate, so that the experiment conditions are relatively uniform, and the accuracy of the obtained characterization temperature is relatively high.

In one embodiment, the predetermined pressure is 5MPa and the predetermined heating rate is 2.8 ℃/s.

Note that the unit ℃/s is degrees celsius per second.

In one embodiment, the heating device 900 is a furnace.

In one embodiment, the rate of temperature rise of the furnace may be set.

In one embodiment, the heating furnace is provided with a device for monitoring and displaying the temperature of the heating furnace.

In one embodiment, the pressure within the enclosure 100 is measured by a pressure measuring cell 500.

In one embodiment, the pressure measuring element 500 is a pressure gauge or a pressure sensor.

In one embodiment, the blast-blasting the clad 100 in the target state under the preset condition to obtain the reference position of the blast hole 101 of the clad 100 includes:

performing bulging blasting on the cladding 100 in a target state under a preset condition to form a blast hole 101;

the location of the blast opening 101 on the cladding 100 is taken as the reference location.

In this way, the reference position is obtained by the bulging blasting of the envelope 100 under preset conditions.

It will be appreciated that the reference location is used as a basis for the subsequent placement of the first temperature sensing element. The reference position is not the true position of the blast opening 101 where the subsequent cladding 100 is formed by the bulging blast, but is merely a reference to the position where the blast opening 101 may be formed. When the cladding 100, which has not been subjected to the bulging blasting, is subjected to the bulging blasting process, the position of the blast hole 101 formed in the cladding 100 is near the reference position. After the reference position is obtained by performing the bulging blasting on the clad 100, the clad 100 on which the bulging blasting has been performed cannot be subjected to the subsequent experiment, and the clad 100 needs to be replaced, and the clad 100 on which the bulging blasting has not been performed is used for the subsequent experiment.

In one embodiment, in the step of obtaining the reference position of the explosion vent 101 of the clad 100 under the preset condition, it is possible to provide the clad 100 for performing the expansion explosion with or without an element for measuring the temperature.

In one embodiment, the reference position may be a position of the enclosure 100 along an axial direction of the enclosure. Illustratively, when the cladding is arranged axially in the up-down direction, the reference position is a position 550mm from the bottom of the cladding 100 along the axial direction of the cladding, i.e., the distance between the bottom of the cladding 100 and a plane coinciding with the reference position and perpendicular to the axial direction of the cladding is 550 mm.

In one embodiment, obtaining the interpolation base data of the cladding 100 under the preset condition comprises:

increasing the temperature of the heating device 900 to a reference blasting temperature under a preset condition, wherein the heating device 900 is configured to heat the cladding 100, the cladding 100 is in a target state in the heating process, and the time when the temperature of the heating device 900 reaches the reference blasting temperature is a second time;

the temperature distribution of the cladding 100 at the second time is acquired as interpolation basis data.

Therefore, the temperature distribution of the cladding 100 at the second moment is obtained by simulating the temperature environment of the bulging blasting and the temperature of the cladding 100 at which the blasting occurs, the temperature distribution can truly reflect the temperature change rule of the cladding 100 between two adjacent first temperature measurement elements along the circumferential direction of the cladding, and the temperature distribution is used as interpolation basic data to perform interpolation processing on the position to be measured to obtain accurate characterization temperature.

It should be noted that the heating device 900 is required to heat the cladding 100 during the bulging blasting of the cladding 100, and the center line 800 of the cladding 100 is located at the preset position of the heating device 900 during each heating process, so that the influence of the heating device 900 on the temperature distribution of the cladding 100 is reduced as much as possible.

It should be explained that the reference explosion temperature is a temperature at which explosion may occur during the theoretical expansion explosion of the cladding 100, and the cladding 100 may or may not be exploded after the temperature of the heating device 900 is increased to the reference explosion temperature. It will be appreciated that the reference burst temperature is relatively close to the temperature at which the cladding 100 bursts.

In one embodiment, the reference burst temperature under the predetermined condition is estimated by an empirical formula.

In one embodiment, the reference burst temperature is 800 ℃.

It will be appreciated that the reference burst temperature is not obtained by empirical formulas. In one embodiment, the clad 100 is blast and the temperature of the heating device 900 is recorded at the time the clad 100 is blasted to form the blast opening 101 and is used as the reference blast temperature.

In one embodiment, the reference burst temperature may also be slightly less than the theoretical burst temperature at which the clad 100 bursts.

In one embodiment, the temperature profile of the cladding 100 at the second time includes an axial temperature profile and a circumferential temperature profile.

In one embodiment, referring to fig. 1 and 3, before increasing the temperature of the heating device 900 to the reference blasting temperature under the preset condition, the obtaining of the interpolation base data of the cladding 100 under the preset condition further includes: a plurality of second measuring positions 200 and a plurality of third measuring positions 300 are arranged on the cladding 100, the plurality of second measuring positions 200 are arranged along the axial direction of the cladding, each second measuring position 200 is provided with a second temperature measuring element, the axial temperature distribution is obtained through the second temperature measuring element, the plurality of third measuring positions 300 are arranged along the circumferential direction of the cladding, each third measuring position 300 is provided with a third temperature measuring element, all the third measuring positions 300 are located in a second reference plane 600, the second reference plane 600 is perpendicular to the axial direction of the cladding, and the circumferential temperature distribution is obtained through the third temperature measuring elements. In this manner, the axial and circumferential temperature distributions of the cladding 100 are obtained by arranging the respective temperature sensing elements at different locations. A plurality of second measurement locations 200 are arranged axially along the cladding, each second measurement location 200 having a second temperature sensing element disposed therein to facilitate measurement of the axial temperature distribution of the cladding 100. A plurality of third measurement locations 300 are arranged circumferentially along the cladding, and a third temperature sensing element is provided at each third measurement location 300 to facilitate measurement of the circumferential temperature distribution of the cladding 100. Having both the second measurement location 200 and the third measurement location 300 on the clad 100 allows the axial temperature distribution and the circumferential temperature distribution of the clad 100 to be measured during a single blow-up.

In an embodiment, the distance between any two second measurement positions 200 is a first distance, and any two first distances may be equal or different.

It can be understood that the distance between two adjacent second measurement positions 200 along the axial direction of the cladding is set according to actual conditions, and the smaller the distance between two adjacent second measurement positions 200 along the axial direction of the cladding is, the more second measurement positions 200 can be arranged along the axial direction of the cladding 100 are, the higher the accuracy of the axial temperature distribution of the cladding 100 is, and the more accurate the obtained characteristic temperature is.

The included angle of the two adjacent third measurement positions 300 along the circumferential direction of the cladding is set according to the actual situation, the smaller the included angle of the two adjacent third measurement positions 300 along the circumferential direction of the cladding is, the more the third measurement positions 300 can be arranged along the axial direction of the cladding 100 are, the higher the circumferential temperature distribution precision of the cladding 100 is, and the obtained characterization temperature is more accurate.

In one embodiment, the angle between two adjacent third measurement locations 300 along the circumferential direction of the cladding may be 30 degrees.

In one embodiment, the angle between two adjacent third measurement locations 300 along the circumferential direction of the cladding may be 90 degrees.

In one embodiment, the second temperature measuring element and the third temperature measuring element are both thermocouples.

In one embodiment, the temperature profile of the enclosure 100 may also be obtained by a non-contact temperature measuring instrument such as an infrared measuring instrument.

In one embodiment, the circumferential temperature distribution and the circumferential temperature distribution of the cladding 100 may be acquired separately.

In one embodiment, the interpolation basic data is a temperature distribution of the cladding 100, the temperature distribution of the cladding 100 includes an axial temperature distribution and a circumferential temperature distribution, and the obtaining of the interpolation basic data of the cladding 100 under the preset condition includes: a step of acquiring an axial temperature distribution of the cladding 100 and a step of acquiring a circumferential temperature distribution of the cladding 100.

The step of obtaining an axial temperature profile of the cladding 100 includes:

arranging a plurality of second measuring positions 200 on the cladding 100, wherein the plurality of second measuring positions 200 are arranged along the axial direction of the cladding, and each second measuring position 200 is provided with a second temperature measuring element;

increasing the temperature of the heating device 900 to a reference blasting temperature under a preset condition, wherein the heating device 900 is configured to heat the cladding 100 provided with the second temperature measuring element, in the heating process, the cladding 100 provided with the second temperature measuring element is in a target state, and the time when the temperature of the heating device 900 reaches the reference blasting temperature is a second time;

the temperature of all of the second temperature sensing elements at the second time is taken as the axial temperature profile of the cladding 100.

In this manner, an axial temperature distribution of the cladding 100 is obtained by providing a plurality of second measurement locations 200 on the cladding 100 that are axially aligned.

The step of obtaining a circumferential temperature profile of the cladding 100 includes:

providing a plurality of third measurement locations 300 on the cladding 100, the plurality of third measurement locations 300 being arranged circumferentially along the cladding, each third measurement location 300 being provided with a third temperature measuring element, all third measurement locations 300 being located in a second reference plane 600, the second reference plane 600 being perpendicular to the cladding axial direction;

increasing the temperature of the heating device 900 to a reference blasting temperature under a preset condition, wherein the heating device 900 is configured to heat the cladding 100 provided with the third temperature measuring element, in the heating process, the cladding 100 provided with the third temperature measuring element is in a target state, and the time when the temperature of the heating device 900 reaches the reference blasting temperature is a second time;

the temperature of all third temperature sensing elements at the second time is taken as the circumferential temperature profile of the cladding 100.

In this manner, the circumferential temperature distribution of the cladding 100 is obtained by providing a plurality of third measurement positions 300 arranged circumferentially on the cladding 100.

In one embodiment, the axial temperature profile of the cladding 100 is shown in FIG. 2 and the circumferential temperature profile of the cladding 100 is shown in FIG. 4.

In one embodiment, referring to fig. 5 and 6, the reference position is located between at least two first measuring positions 400 along the axial direction of the cladding, each first measuring position 400 comprises at least two sub-measuring positions, each sub-measuring position is provided with a first temperature measuring element, and the distance between one sub-measuring position and the reference position along the axial direction of the cladding is equal to the distance between the other sub-measuring position and the reference position along the axial direction of the cladding.

In an embodiment, the distances between the sub-measurement positions of one of the at least two first measurement positions 400 and the reference position and the distances between the sub-measurement positions of the other first measurement position 400 and the reference position may be equal or unequal.

In an embodiment, referring to fig. 5 and 6, the temperature distribution of the cladding 100 includes an axial temperature distribution and a circumferential temperature distribution, and the interpolation processing on the position to be measured according to the first data and the interpolation basic data to obtain the characterization temperature includes:

for each first measurement position 400, performing circumferential interpolation on the position to be measured according to circumferential temperature distribution, a first temperature and a second temperature to obtain a third temperature, wherein the first temperature is measured by the first temperature measuring element at one of the sub-measurement positions at the first moment, and the second temperature is measured by the first temperature measuring element at the other sub-measurement position at the first moment;

and carrying out axial interpolation on the position to be measured according to the at least two third temperatures and the axial temperature distribution to obtain the characterization temperature.

Therefore, the interpolation processing of the position to be detected is carried out step by step in a mode of firstly carrying out circumferential interpolation and then carrying out axial interpolation, the interpolation processing of the position to be detected is decomposed into the circumferential interpolation and the axial interpolation, the interpolation processing in a single direction is simpler, the interpolation processing is carried out in different directions, the interpolation processing method is simplified to a certain extent, and the representation temperature can be conveniently obtained through the interpolation processing.

It should be noted that when the enclosure 100 is in the target state, the center line 800 of the enclosure 100 is located at the preset position of the heating device 900, and the highest temperature position in the circumferential temperature distribution of the enclosure 100 is constant in the enclosure circumferential direction with respect to the position of the heating device 900, which is determined by the heating environment of the heating device 900, regardless of the angle to which the enclosure 100 is rotated about the center line 800 of the enclosure 100. Referring to fig. 8 and 9, the relative position of the enclosure 100 and the heating device 900 obtained by rotating the enclosure 100 in fig. 8 by a certain angle around the center line 800 of the enclosure 100 is shown in fig. 9, after the enclosure 100 in fig. 8 is rotated by a certain angle around the center line 800 of the enclosure 100, the position a on the enclosure 100 is moved to the original position b, the original position b on the enclosure 100 is moved to the original position c, and if the highest temperature position in the enclosure circumferential temperature distribution in fig. 8 is present at the position b, the highest temperature position in the enclosure circumferential temperature distribution in fig. 9 is present at the position a. Referring to fig. 8 and 9, with the center line 800 of the clad 100 as a center, the 180-degree direction of the heating device 900 at the left and the 0-degree direction of the heating device 900 at the right, the position b of the clad 100 shown in fig. 8 and the position a of the clad 100 shown in fig. 9 are constant along the circumferential direction of the clad with respect to the position of the heating device 900, and are both located in the 180-degree direction of the heating device 900.

In one embodiment, the location on the clad 100 where the temperature is highest along the circumferential direction of the clad is generally recorded as 180 degrees for ease of recording. Illustratively, in the circumferential temperature distribution of the clad 100, the position of the centerline 800 of the clad 100 is the center of the circle, and the direction in which the centerline 800 of the clad 100 points to the highest temperature position in the circumferential temperature distribution of the clad 100 is defined as the 180-degree direction. Referring to fig. 8, a position b on the clad 100 is a 180-degree position of the clad 100 in the circumferential direction of the clad, and other positions on the clad 100 define an angle in the circumferential direction of the clad with reference to the position b. Referring to fig. 9, a position a on the clad 100 is a 180-degree position of the clad 100 in the circumferential direction of the clad, and the other positions on the clad 100 define an angle in the circumferential direction of the clad with reference to the position a.

In one embodiment, referring to FIG. 4, the circumferential temperature profile of the cladding 100 is shown in FIG. 4, with the highest temperature location in the circumferential temperature profile being the 180 degree location.

In one embodiment, please refer to fig. 5 and 6, wherein one of the sub-measurement positions is a first sub-measurement position 401, the other sub-measurement position is a second sub-measurement position 402, an included angle between the first sub-measurement position 401 and the second sub-measurement position 402 along the circumferential direction of the cladding is 180 degrees, the first temperature is measured by the first temperature measurement element at the first sub-measurement position 401 at the first time, and the second temperature is measured by the first temperature measurement element at the second sub-measurement position 402 at the first time. During the bulging blasting of the cladding 100 provided with the first temperature measuring element, the first sub-measuring position 401 is located in a first reference plane 700, the first reference plane 700 coincides with the centre line 800 of the cladding 100 and a guiding position, respectively, the guiding position being the position of the highest temperature position of the cladding 100 in the circumferential temperature distribution relative to the heating device 900 at the second moment in time, the first sub-measuring position 401 being located on the side of the centre line 800 of the cladding 100 facing the guiding position. Carrying out circumferential interpolation on the device to be tested according to the circumferential temperature distribution, the first temperature and the second temperature to obtain a third temperature, and the method comprises the following steps:

acquiring a fourth temperature and a fifth temperature in the circumferential temperature distribution, wherein the fourth temperature is the highest temperature in the circumferential temperature distribution, and an included angle between the position of the fifth temperature and the position of the fourth temperature along the circumferential direction of the cladding is 180 degrees;

acquiring a sixth temperature in the circumferential temperature distribution, wherein the sixth temperature is the temperature at the position to be measured in the circumferential temperature distribution;

and carrying out circumferential interpolation on the position to be measured according to the first temperature, the second temperature, the fourth temperature, the fifth temperature and the sixth temperature to obtain a third temperature.

Therefore, in the circumferential interpolation processing process, a fourth temperature and a fifth temperature need to be obtained, due to the arrangement mode of the first sub-measurement position 401 and the second sub-measurement position 402, the highest temperature in the circumferential temperature distribution is selected as the fourth temperature, so that temperature data can be read more accurately from the circumferential temperature distribution diagram, the fifth temperature is located at a corresponding 180-degree position and is usually located outside an end point in the temperature distribution diagram, so that data can be read more accurately from the circumferential temperature distribution diagram, and the finally obtained characterization temperature is more accurate.

In an embodiment, when the circumferential temperature of the cladding 100 is obtained by the third temperature measuring element, the position of the cladding 100 with the highest circumferential temperature along the cladding in the second plane is usually a reference position where the third temperature measuring element is arranged, and this position is also the circumferential position where the fourth temperature is located, and the positions where the fourth temperature is located and the fifth temperature is located are both direct measurement positions of the third temperature measuring element, so that the obtained data is more accurate, and therefore, circumferential interpolation is performed according to the fourth temperature and the fifth temperature in the circumferential temperature distribution, and more accurate characterization temperature can be obtained.

In one embodiment, the third temperature is calculated by the following formula:

formula (1) wherein:

t is a third temperature;

a is a fourth temperature;

b is a fifth temperature;

c is a sixth temperature;

d is the first temperature;

and e is the second temperature.

In one embodiment, the third temperature is calculated by the following formula:

the meaning of each parameter in the formula (2) is the same as that in the formula (1).

In one embodiment, when the cladding is axially arranged in the up-down direction, the position to be measured of the explosion opening 101 of the cladding 100 is 560mm away from the bottom of the cladding 100, and the included angle between the position to be measured of the explosion opening 101 of the cladding 100 and the position of the fourth temperature along the circumferential direction of the cladding is 90 degrees. One of the first measurement locations 400 is 500mm from the bottom of the enclosure 100 and the other first measurement location 400 is 600mm from the bottom of the enclosure 100.

In one embodiment, a circumferential interpolation is performed on the first measurement location 400 at 500mm, corresponding to the first measurement location 400 at 500mm, the first temperature is 828.8 ℃, the second temperature is 782.2 ℃, the fourth temperature is 840 ℃, the fifth temperature is 814 ℃, the sixth temperature is 833 ℃, and the third temperature is 816.3 ℃ according to equation (1).

In one embodiment, a circumferential interpolation is performed on the first measurement location 400 at 600mm, corresponding to the first measurement location 400 at 600mm, the first temperature is 839.8 ℃, the second temperature is 816.9 ℃, the fourth temperature is 840 ℃, the fifth temperature is 814 ℃, the sixth temperature is 833 ℃, and the third temperature is 833.6 ℃ according to equation (1).

In an embodiment, performing an axial interpolation on the position to be measured according to the at least two third temperatures and the axial temperature distribution to obtain a characterization temperature includes:

obtaining a seventh temperature and an eighth temperature according to the axial temperature distribution, wherein the seventh temperature is the temperature at one of the first measurement positions 400 in the axial temperature distribution, the eighth temperature is the temperature at the other one of the first measurement positions 400 in the axial temperature distribution, and the seventh temperature is less than the eighth temperature;

acquiring a ninth temperature in the axial temperature distribution, wherein the ninth temperature is the temperature at the position to be measured in the axial temperature distribution;

and carrying out axial interpolation on the position to be measured according to the two third temperatures, the seventh temperature, the eighth temperature and the ninth temperature to obtain a representation temperature.

In this way, the temperature corresponding to the first measurement position 400 and the temperature corresponding to the position to be measured in the axial temperature distribution are used to realize the axial interpolation of the position to be measured, thereby obtaining the characterization temperature.

In one embodiment, the calculation formula of the characteristic temperature is:

in formula (3):

Tpto characterize the temperature

h is an eighth temperature;

i is a seventh temperature;

j is the ninth temperature;

T1the greater of the two third temperatures;

T2the smaller of the two third temperatures.

In one embodiment, the calculation formula of the characteristic temperature is:

the meaning of each parameter in the formula (4) is the same as that in the formula (3).

In one embodiment, the third temperature of first measuring location 400 at 500mm from the bottom of enclosure 100 is 816.3 deg.C, the third temperature of first measuring location 400 at 600mm from the bottom of enclosure 100 is 833.6 deg.C, and the location to be measured is 560mm from the bottom of enclosure 100. The seventh temperature was 818 ℃, the eighth temperature was 825 ℃, the ninth temperature was 823 ℃, of the two third temperatures, T1 was 833.6 ℃, T2 was 816.3 ℃, and the characterization temperature was 828.7 ℃ was obtained according to equation (3).

In an embodiment, in the process of performing the bulging blasting on the cladding 100 provided with the first temperature measuring elements under the preset condition, the characterization temperature can be obtained only by providing four first temperature measuring elements, and the number of the required temperature measuring elements is small.

In an embodiment, the axial interpolation may be performed on the position to be measured according to the axial temperature distribution of the cladding 100 and the corresponding first temperatures at the two first sub-measurement positions 401 along the axial direction of the cladding, the axial interpolation may be performed on the position to be measured according to the axial temperature distribution of the cladding 100 and the corresponding second temperatures at the two second sub-measurement positions 402 along the axial direction of the cladding, and the circumferential interpolation may be performed according to the result of the axial interpolation of the first temperatures, the result of the axial interpolation of the second temperatures, and the circumferential temperature distribution of the cladding 100 to obtain the characterization temperature.

In one embodiment, the time at which the rupture of the enclosure 100 forms the rupture 101 is the difference between the time of the sudden drop in pressure within the enclosure 100 and the measured response time of the pressure within the enclosure 100. The measuring method further comprises the following steps: a measurement response time is obtained. Therefore, the influence of the measurement response time of the reduced pressure on the characterization temperature is accurate.

In one embodiment, obtaining the measurement response time comprises: the pressurizing step and the depressurizing step are alternately performed on the containing cavity of the enclosure 100 to determine the response time of the pressure measurement.

In one embodiment, the pressure measurement response time is 5 seconds.

In one embodiment, the time of the pressure dip in the enclosure 100 is 127 seconds, the first time is the time at which the explosion of the enclosure 100 occurs to form the blast opening 101, and the first time is 127-5 to 122 seconds.

FIG. 7 shows the data relating to a first moment in time during a certain bulging blast of the enclosure 100 provided with a first temperature element. Where the curve Ts is the temperature curve of the heating apparatus 900, i.e., the furnace set temperature as partially illustrated in the figure. Where curve Pr is the pressure curve of the envelope 100, i.e. the pressure illustrated in the legend part. Wherein, the temperature 1, the temperature 2, the temperature 3 and the temperature 4 of the legend part are respectively the temperature curves of the corresponding first temperature measuring element in the whole expansion blasting process.

In one embodiment, the first measuring position 400 may not include the second sub-measuring position 402, and when the first sub-measuring position 401 of one of the first measuring positions 400, the position to be measured, and the first sub-measuring position 401 of the other first measuring position 400 are in a straight line along the axial direction of the enclosure, the temperature at the position to be measured can be directly and axially interpolated by the temperatures of the first temperature measuring elements of the two first sub-measuring positions 401 at the first time to obtain the characterization temperature.

The various embodiments/implementations provided herein may be combined with each other without contradiction.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

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