KR20090094549A - Concrete specimen curing apparatus capable of maturity - Google Patents

Abstract

A temperature tracking concrete specimen curing apparatus capable of displaying accumulated temperature is provided to predict curing finishing time accurately by displaying accumulated temperature, accumulated average temperature and accumulated curing time on a real time basis. A temperature tracking concrete specimen curing apparatus capable of displaying accumulated temperature comprises a curing chamber, a first temperature sensor, a second temperature sensor, a measurement unit, timer, a temperature tracking control unit, a display unit, and an air-conditioning and heating unit. The curing chamber(10) comprises a heater unit(20) and a freezer unit(30) to control the temperature inside a camber. The first temperature sensor(50) and the second temperature sensor(52) are embedded in the curing chamber and a concrete structure respectively. The measurement unit(111) recognizes the temperature value of the concrete structure through the first temperature sensor. The timer(113) counts the time when a system is turned on according to the external control. A temperature tracking control unit(110) consists of a main control unit(115) outputting control signals of the freezer unit and the heater unit. The display unit(120) displays accumulated temperature, accumulated average temperature and accumulated curing time of the concrete structure and the curing chamber. The air-conditioning and heating unit(80) controls the heater unit and the freezer unit of the curing chamber.

Description

Concrete specimen curing apparatus capable of display of integrated temperature {Concrete specimen curing apparatus capable of maturity}

The present invention relates to a temperature tracking specimen curing apparatus, and more particularly, displays an integrated temperature, a cumulative average temperature, and a cumulative curing time during curing of a specimen for evaluation of concrete strength under the same conditions as the actual temperature of a concrete structure. The present invention relates to a temperature tracking specimen curing apparatus capable of accurately predicting the time for disassembly of formwork or clubbing, thereby enabling the display of accumulated temperature to prevent air delay.

After pouring concrete, measuring the strength of concrete in real structures is a very important factor in determining the curing period (such as the period of staying of molds and clubs), the quality of structures, and the performance of subsequent processes.

According to the Concrete Standard Specification by the Ministry of Construction and Transportation (Korean Concrete Society, 1999, hereinafter abbreviated as 'Concrete Standard Specification'), whether the curing of concrete is appropriate, the time to remove the formwork, and the timing of introduction of prestress, In order to check the safety of loading at an early stage, the strength of the site structure should be tested using the specimens cured in the same condition as the concrete in the site (Chapter 2 General Concrete). It is required to use specimens cured in the same state as.

In addition, the time to finish the curing, the formwork, and the stripping off in Korea-China concrete, which are subjected to severe weathering, are to be tested by the strength test of the specimens cured in the same condition as the concrete in the field or at the accumulated temperature of the concrete. It is decided by the estimated strength.

Thus, in evaluating the strength of the structural concrete, although the method of using the specimen cured under the same conditions (temperature and humidity) as the actual structural concrete is prioritized, the convenience of application and the proper test apparatus in the actual construction site are preferred. Instead of testing the specimens, most of them decide the curing time of the structural concrete according to the general standards set out in the concrete standard specification, and some of them are subjected to the field-sealed specimens cured by the concrete. It is a situation to evaluate the strength of the structure concrete.

However, as described above, in the case of the actual structure concrete, various construction conditions (type of concrete, type and importance of the structure, type and section size of the member, load applied to the member, etc.) and curing conditions (temperature, humidity, etc.) of the construction site Since the strength expression characteristics are very different depending on the external environment, etc., it is necessary to apply universal standards uniformly without considering the conditions of each construction site as described above. It causes the delay of construction period.

In addition, the specimen for evaluating the compressive strength of the most important concrete among the evaluation criteria for the various standards prescribed in the concrete standard specification mentioned above is for the standard curing (20 ± 3 ℃) specimens. Curing conditions (seasonal, cross-crossing, regional, construction site and cross-sectional size) are very different, making it difficult to ensure the accuracy of strength evaluation.

On the other hand, in the case of site-sealed curing, only cold-heavy concrete, which is constructed in winter, is targeted, but this is also evaluated to show a curing temperature history that is significantly different from that of actual structural concrete.

For example, when concrete is poured into a pillar member having an outside air temperature of 0 ° C. and a width × length × height of 0.5 × 0.5 × 3.0 m, the resulting structural concrete has a diameter of 10 cm and a height of 20 cm. Compared to the sampling specimen for evaluation, the time to reach the outside air temperature (0 ° C.) is delayed much.

In other words, in the case of the sampling specimen for strength evaluation which is greatly influenced by the outside temperature, the result of the strength is much lower than that of the actual structure concrete. In this case, although the compressive strength of the structural concrete has already been secured, the removal time of the formwork or the ridge is delayed a lot, resulting in an increase in not only the overall construction period but also the total construction cost.

In order to solve this problem, the present applicant has developed and applied for the Republic of Korea Patent Publication No. 10-2005-0018080 (name: temperature tracking specimen curing device that is controlled in accordance with the degree of strength expression of the actual structure concrete).

As shown in FIG. 1, the temperature tracking specimen curing apparatus controlled according to the strength expression level of the actual structure concrete includes a curing chamber 10 including a casing 12 having a predetermined size to provide a space in which the specimen T is placed. ). In order to facilitate the movement of the device at a short distance, as shown in the drawing, it is preferable to install rolling means 14 made of wheels or casters in the curing chamber 10.

The curing chamber 10 is provided with a heater unit 20 and a refrigeration unit 30 for temperature control inside the chamber. The heater unit 20 and the refrigerating unit 30 are selectively operated according to a result of comparing the temperature of the actual concrete structure 2 with the temperature of the curing chamber 10, and thus the temperature of the curing chamber 10. To maintain the same temperature as the actual concrete structure (2).

As for the said refrigeration unit 30, the heat exchange part 32 is provided in the curing chamber 10 inside. The circulation fan 40 is provided inside the curing chamber 10. The temperature distribution inside the curing chamber 10 may be uniformly maintained by driving the circulation fan 40.

In addition, in order to measure the temperature inside the concrete structure 2 and the curing chamber 10, a first temperature sensor 50 is embedded in the concrete structure 2, and another curing method in the curing chamber 10. A second temperature sensor 52 is provided. Thermocouples may be used as the first and second temperature sensors 50 and 52.

On the other hand, as for temperature control of the curing chamber 10, the temperature estimation control unit 60, the display unit 70 and the air conditioning unit 80 is provided. The temperature estimation control unit 60, the temperature value (a) of the concrete structure input from the temperature sensor 50 on the concrete structure 2 side, and the second temperature sensor 52 on the curing chamber 10 side. By comparing the temperature value (b) in the curing chamber 10 input from the curing chamber 10, the heater unit 20 to match the temperature (cure temperature) inside the curing chamber 10 with the temperature of the concrete structure (2) And controls the driving of the refrigeration unit (30).

In addition, the temperature following control unit 60 compares the temperature history with the naked eye by applying the temperature values input from the first and second temperature sensors 50 and 52 to the display unit 70 for display. To be reviewed. The temperature tracking control unit 60 includes a measurement unit 62 and a main control unit 64.

The measurement unit 62 recognizes the temperature value input from the first temperature sensor 50 embedded in the concrete structure 2 and applies it to the main control unit 64, and the display unit 70. To be displayed. The measurement unit 62 recognizes the temperature of the concrete structure 2 at a predetermined period (seconds, minutes, hours, days ...) through the first temperature sensor 50.

In addition, the main control unit 64 compares the temperature value applied from the measurement unit 62 with the temperature value input from the curing chamber 10 side second temperature sensor 52, and accordingly, the heating and cooling operation is performed. A control signal for controlling the unit 80 is output, and in addition, the temperature value input from the curing chamber 10 side second temperature sensor 52 is output to the display unit 70 for display.

The display unit 70 displays a temperature value of the concrete structure 2 and a temperature value of the curing chamber 10 applied from the temperature tracking control unit 60. The display unit 70 includes a first channel 72 and a second channel 74, one of which displays the temperature value (a) of the concrete structure (2), the other is the curing chamber The temperature value (b) of (10) is displayed.

The cooling and heating operation unit 80 receives a control signal applied from the temperature tracking control unit 10 to control driving of the heater unit 20 and the refrigerating unit 30 of the curing chamber 10. The cooling and heating operation unit 80 includes a heater operation unit 82 for controlling the driving of the heater unit 20, and a freezer operation unit 84 for controlling the driving of the refrigerating unit 30.

In the accompanying drawings, the entire process of curing the actual structure concrete and the specimen using the temperature tracking curing device is shown as a flowchart (see FIG. 1 in parallel).

As shown in FIG. 2, first, the temperature following curing apparatus is moved to a site where the actual structure concrete is to be constructed, and then the first temperature sensor 50 is installed at the site where the concrete is to be placed (step 100).

After the step 100, the concrete is poured so that the first temperature sensor 50 is embedded in the concrete structure 2, and at the same time to produce a specimen (T) for the evaluation of concrete strength curing chamber 10 ) Into the inside (step 110). Here, about six specimens (T) for the concrete strength evaluation are produced.

Thereafter, curing for the concrete structure and the specimen for strength evaluation for a predetermined period of time (step 120).

During the curing in step 120, one or two of the specimens T being cured in the curing chamber 10 are taken out, and a compressive strength test is performed on the specimen T for strength evaluation (step 130).

As a result of the compressive strength test of the specimen T for strength evaluation, if the target strength for the concrete structure 2 is satisfied, curing of the concrete structure 2 is terminated and the formwork is removed, and the curing chamber 10 ) The curing of the test specimen T for internal strength is also terminated (step 150).

If the compressive strength test results for the specimen for strength evaluation (T) in the step 130, the target strength for the concrete structure (2) does not reach, for curing and strength evaluation of the concrete structure (2) for the specimen (T) Curing is repeated continuously until the target intensity is met (step 120).

In the accompanying drawings, a process of controlling the internal temperature of the specimen curing apparatus by following the temperature of the actual structure concrete by the temperature following curing apparatus is shown as a flowchart.

The process shown in FIG. 3 includes the step 120 described in FIG. 2, that is, the temperature following control unit 60 curing the concrete structure 2 and the specimen for strength evaluation 2, more specifically, the main control unit 64. ) Shows a specific control process (see FIG. 1 in parallel).

As shown in FIG. 3, in curing the specimen 2 for strength evaluation, first, the temperature value a input from the first temperature sensor 50 on the concrete structure 2 side, and the curing chamber ( The temperature value b inputted from the second temperature sensor 52 on the side 10) is read (step 200).

Specifically, the temperature value a applied from the first temperature sensor 50 embedded in the concrete structure 2 is recognized by the measurement unit 62, and the main control unit 64 is applied from the measurement unit 62. In addition to reading the temperature value (a), the temperature value (b) input from the second temperature sensor 52 on the curing chamber 10 side is read.

Next, after reading the temperature values a and b of the concrete structure 2 and the curing chamber 10 as in step 200, these temperature values a and b are applied to the display unit 70. To be displayed (step 210). Therefore, the construction supervisor can visually compare and examine both side temperature values a and b displayed on the display unit 70.

Specifically, in the temperature values (a, b) applied to the display unit 70, the temperature value (a) for the concrete structure (2) is applied from the measuring unit 62 to the channel 1 (72) The temperature value b for the curing chamber 10 is applied from the main control section 64 and displayed in the channel 2 74.

After the step 210, the temperature value a of the concrete structure 2 read and the temperature value b of the curing chamber 10 are compared (step 220).

In the comparison of the temperature values a and b, it is determined whether the difference (| a-b |) between the two temperature values a and b is within the allowable temperature difference t. The allowable temperature difference t is a value set in advance as an allowable temperature range that the temperature of the curing chamber 10 may have with respect to the temperature of the concrete structure 2.

In the step 220, when the difference between the two temperature values | ab | is within the allowable temperature difference t, a control signal for turning off both the heater unit 20 and the refrigerating unit 30. To stop the driving (step 230). Specifically, a control signal for turning off both the heater unit 20 and the refrigerating unit 30 is output to the air conditioning unit 80.

In step 220, when the difference between the two temperature values (a-b |) is out of the allowable temperature difference t, the two temperature values a and b are compared (step 240).

If the a value of the two temperature values is large, since the temperature inside the curing chamber 10 is lower than the allowable range compared to the curing temperature of the concrete structure 2, the curing unit 10 is driven by driving the heater unit 20. Is raised (step 250). Specifically, the control signal for driving the heater unit 20 is output to the air conditioning unit 80.

When the b value is larger than the two temperature values, since the temperature inside the curing chamber 10 is higher than the allowable range compared to the curing temperature of the concrete structure 2, the refrigeration unit 30 is driven to drive the curing chamber 10. Lower the temperature (step 260). Specifically, the control signal for driving the refrigeration unit 30 is output to the air conditioning unit 80.

Thereafter, while repeating the step 200, the temperature of the curing chamber 30 is controlled to match the temperature of the concrete structure.

However, according to the temperature tracking specimen curing apparatus which is controlled in correspondence with the strength expression level of the conventional actual structure concrete, only the temperature value (a) of the concrete structure and the temperature value (b) of the curing chamber are displayed. In order to detect the integrated temperature, a separate manager must check the temperature value every time, and based on this, calculate the average temperature value and calculate it by substituting it into the formula to detect the integrated temperature. There was a hassle.

The present invention was developed to solve the above-described conventional problems, and an object of the present invention is to integrate the temperature, cumulative average temperature and cumulative curing time by real-time display the integrated temperature to accurately predict the curing completion time It is to provide a temperature tracking specimen curing device capable of display.

Features of the present invention for achieving the above object,

A curing chamber made of a casing having a predetermined size to provide a space in which the specimen is placed, and having a heater unit and a refrigerating unit for controlling internal temperature; A first temperature sensor embedded in the concrete structure to measure the temperature of the actual concrete structure; A second temperature sensor installed in the curing chamber to measure the temperature inside the curing chamber; And a measurement unit for recognizing the temperature value (a) of the concrete structure at regular intervals through a first temperature sensor embedded in the concrete structure, and receiving a temperature value (a) for the structure concrete from the measurement unit. The temperature value (b) from the second temperature sensor on the curing chamber is input and the two temperature values (a, b) are compared, and the control signal for the heater unit and the refrigeration unit is output according to the result of the comparison. A temperature estimation control unit comprising a main controller; And a display unit for receiving and displaying a temperature value (a) of the concrete structure and a temperature value (b) of the curing chamber from the temperature tracking control unit. And a cooling and heating operation unit 80 that receives a control signal applied from the temperature following control unit 10 and controls driving of the heater unit 20 and the refrigerating unit 30 of the curing chamber 10. In the following specimen curing apparatus, the main control unit of the temperature tracking control unit further includes a timer for counting the time when the system is turned on according to the control, the temperature value (b) from the second temperature sensor and the timer. The integrated temperature (M), the cumulative average temperature (θ) and the cumulative curing time (Δt) are detected in real time according to a predetermined integration temperature function using the time counted by.

Here, the main control unit of the temperature following control unit detects the integrated temperature by setting the time point at which the system is turned on as a reference time and the time point when 24 hours have elapsed from the reference time to 1 day.

The display unit may further include: a first channel configured to display a temperature value (a) of the concrete structure output from the main controller of the temperature tracking control unit; A second channel for displaying a temperature value (b) of the curing chamber output from the main controller of the temperature tracking control unit; And a third channel for displaying the integrated temperature M output from the main controller of the temperature tracking control unit, the cumulative average temperature θ, and the cumulative curing time Δt.

Here, the main control unit of the temperature following control unit sequentially displays the integrated temperature M, the cumulative average temperature θ and the cumulative curing time Δt through the third channel of the display unit for a predetermined time period, or The integrated temperature M, the cumulative average temperature θ and the cumulative curing time Δt are displayed at the same time.

  According to the temperature tracking specimen curing apparatus capable of displaying the integrated temperature as described above, the curing completion time can be accurately predicted by displaying the integrated temperature in real time, thereby ensuring the reliability of the quality of the concrete structure.

Therefore, the present invention accurately predicts the curing completion time by the temperature tracking specimen curing device capable of displaying the integrated temperature, and compressive strength test at any age (1 day, 2 days, 3 days ...) through the cured test specimens. By performing the test, the strength of the actual structural concrete can be evaluated more precisely, and subsequent processes can be performed, thereby ensuring the reliability of the quality of the actual structural concrete and accurately determining the dismantling time of the formwork or clubbing. have.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying exemplary drawings.

Figure 4 is a block diagram showing the configuration of the temperature tracking specimen curing apparatus capable of displaying the integrated temperature according to the present invention. In FIG. 4, an arrow indicates a signal flow.

As shown in FIG. 4, the temperature tracking specimen curing apparatus 100 capable of displaying the integrated temperature according to the present invention includes a curing chamber 10, a heater unit 20, a refrigeration unit 30, and a circulation. A fan 40, a first temperature sensor 50, a second temperature sensor 52, a temperature estimation control unit 110, a display unit 120, and an air conditioning unit 80 are provided.

First, the curing chamber 10, the heater unit 20, the refrigeration unit 30, the circulation fan 40, the first temperature sensor 50, the second temperature sensor 52 and air conditioning The operation unit 80 has been given the same reference numeral in the same configuration as in the prior art, and the description thereof will be omitted.

The temperature estimation control unit 110 includes a measurement unit 111, a timer 113, and a main control unit 115.

The measurement unit 111 recognizes the temperature value a input from the first temperature sensor 50 embedded in the concrete structure 2 and applies it to the main control unit 64 to be described below. It is applied to the display unit 120 to be displayed. The measurement unit 111 recognizes the temperature of the concrete structure 2 at a predetermined period (seconds, minutes, hours, days ...) through the first temperature sensor (50).

The timer 113 counts the time when the system is turned on under external control and provides a counting value.

The main control unit 115 is set as shown in Equation 1 below by using the temperature value b input from the second temperature sensor 52 and the time counted by the timer 113, that is, a counting value. The integrated temperature M, the cumulative average temperature θ and the cumulative curing time Δt are detected in real time according to the integration temperature function, and the temperature value input from the second temperature sensor 52 on the curing chamber 10 side. (b) is output to the display unit 120 to be displayed. In addition, the main controller 115 sequentially displays the integration temperature M, the cumulative average temperature θ, and the cumulative curing time Δt through the third channel 125 of the display 120 for a predetermined time. . At this time, the main control unit 115 may simultaneously display the integration temperature (M), the cumulative average temperature (θ) and the cumulative curing time (Δt) through the third channel 125 of the display 120 according to the selection. In this case, it is preferable to set the time point at which the system is turned on as a reference time, and set the time point at which 24 hours have elapsed from the reference time to 1 day to detect the integrated temperature.

Here, M is integration temperature (degreeC.Day), t is time, (theta) is concrete temperature (degreeC) in (DELTA) t time, A is 10 degreeC as an integer, and (DELTA) t represents cumulative curing time.

In addition, the display unit 120 may accumulate the temperature value a of the concrete structure 2 applied from the temperature following control unit 110, the temperature value b of the curing chamber 10, and the integration temperature M, and accumulate. The average temperature θ and the cumulative curing time Δt are displayed. In the present embodiment, the display unit 120 includes a first channel 121, a second channel 123, and a third channel 125, and the first channel 121 is a temperature following control unit 110. The temperature value (a) of the concrete structure (2) output from the main control unit 115 of the) and the second channel 123 is cured output from the main control unit 115 of the temperature following control unit 110 The temperature value b of the chamber 10 is displayed, and the third channel 125 includes an integrated temperature M output from the main controller 115 of the temperature tracking control unit 110 and a cumulative average temperature θ. And the cumulative curing time Δt.

Hereinafter, the operation of the temperature tracking specimen curing apparatus capable of displaying the integrated temperature according to the present invention will be described in detail with reference to FIGS. 4 and 5.

5 is an explanatory diagram for explaining the operation of the temperature tracking specimen curing apparatus capable of displaying the integrated temperature according to the present invention.

Since the process of adjusting the temperature value of the curing chamber 10 is the same as in the prior art, the description thereof will be omitted.

First, when the system 115 is turned on (S10), the timer 113 is operated (S11), and receives a counting value from the timer 113, and at the same time the temperature from the second temperature sensor 52 The value b is provided (S12). At this time, the main control unit 115 stores the temperature value for each time using the counting value (S13), calculates the average of the stored temperature value and stores the average temperature value (S14).

In this state, the main control unit 115 calculates and stores an integrated temperature M by substituting a counting value, that is, a total curing time and an average temperature value in Equation 1 above (S15), and stores the stored integrated temperature M. The display unit 120 displays the third channel 125 through the display unit 120 (S16). In this case, the main controller 115 may calculate the integration temperature M in a time unit that is the minimum unit. However, the main control unit 115 may also calculate the unit temperature in units of days depending on the selection.

At the same time, the main controller 115 displays the accumulated average temperature θ, which is the stored average temperature value, and the cumulative curing time Δt, which is the total curing time, through the third channel 125 of the display 120.

On the other hand, the main control unit 115 checks whether the system is off (S17), and if the system is off, the system is terminated, and if the system is not off, it returns to step 12 (S12) to continue the subsequent operation.

Therefore, as shown above, the integrated temperature is automatically displayed through the curing chamber temperature and curing time, and the cumulative average temperature and the curing time are additionally displayed to accurately predict the curing completion time of the specimen and the concrete structure for measuring the concrete strength. Can be.

1 is a configuration diagram of a temperature tracking specimen curing apparatus that is controlled in accordance with the strength development degree of the conventional concrete structure concrete;

2 is a flow chart for explaining the actual structure concrete and specimen curing process according to the conventional configuration,

3 is a flow chart for explaining a process of controlling the internal temperature of the specimen curing apparatus by following the temperature of the actual structure concrete by the temperature following specimen curing apparatus controlled in response to the degree of strength development of the conventional concrete structure concrete,

4 is a block diagram of a temperature tracking specimen curing apparatus capable of displaying the integrated temperature according to the present invention;

5 is an explanatory diagram for explaining the operation of the temperature following specimen curing apparatus capable of displaying the integrated temperature according to the present invention;

<Explanation of symbols for the main parts of the drawings>

2: real concrete structure 10: curing chamber

20: heater unit 30: refrigeration unit

40: circulation fan 50, 52: first and second temperature detection sensor

60, 110: temperature tracking control unit 62, 111: measurement unit

64, 115: main control part 70, 120: display part

80: air conditioning unit 113: timer

Claims (4)

A curing chamber made of a casing having a predetermined size to provide a space in which the specimen is placed, and having a heater unit and a refrigerating unit for controlling internal temperature; A first temperature sensor embedded in the concrete structure to measure the temperature of the actual concrete structure; A second temperature sensor installed in the curing chamber to measure the temperature inside the curing chamber; And a measurement unit for recognizing the temperature value (a) of the concrete structure at regular intervals through a first temperature sensor embedded in the concrete structure, and receiving a temperature value (a) for the structure concrete from the measurement unit. The main controller receives the temperature value (b) from the curing chamber side second temperature sensor and compares the two temperature values (a, b) and outputs control signals for the heater unit and the refrigeration unit according to the result of the comparison. A negative temperature estimation control unit; And a display unit for receiving and displaying a temperature value (a) of the concrete structure and a temperature value (b) of the curing chamber from the temperature tracking control unit. And a cooling and heating operation unit 80 that receives a control signal applied from the temperature following control unit 10 and controls driving of the heater unit 20 and the refrigerating unit 30 of the curing chamber 10. In the following specimen curing device, The main control part of the temperature following control unit is And further includes a timer that counts the time when the system is on under control thereof. Accumulation temperature (M), cumulative average temperature (θ) and cumulative curing time (Δt) in accordance with a preset integration temperature function using the temperature value (b) from the second temperature sensor and the time counted in the timer. Temperature tracking specimen curing device capable of displaying the integrated temperature, characterized in that the detection in real time. The method of claim 1, The main control part of the temperature following control unit is A temperature following specimen curing apparatus capable of displaying the integrated temperature, wherein the integrated temperature is detected by setting the time when the system is turned on as a reference time and setting the time when 24 hours have elapsed from the reference time to 1 day. The method of claim 1, The display unit, A first channel displaying a temperature value (a) of the concrete structure output from the main controller of the temperature tracking control unit; A second channel for displaying a temperature value (b) of the curing chamber output from the main controller of the temperature tracking control unit; And The integrated temperature (M) output from the main controller of the temperature tracking control unit, and the third channel for displaying the cumulative average temperature (θ) and the cumulative curing time (Δt) temperature which can display the integrated temperature Following specimen curing device. The method of claim 1, The main control part of the temperature following control unit is The integration temperature M, the cumulative average temperature θ and the cumulative curing time Δt are sequentially displayed for a predetermined time through the third channel of the display unit, or the integration temperature M and the cumulative average temperature θ are sequentially displayed. And a cumulative curing time (Δt) at the same time, the temperature tracking specimen curing apparatus capable of displaying the integrated temperature.

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