JP2645320B2 - Concrete strength management device - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a concrete strength management device for predicting and managing the strength of concrete that records a special temperature such as a high or low temperature.

"Conventional technology" In general, relatively large concrete structures called mass concrete tend to have higher concrete temperatures after casting than ordinary concrete structures, especially in concrete. Is remarkable. Therefore, in such mass concrete, it is expected that the strength development at the time of the early age of the material will be significantly increased, and concrete such as cracks will occur due to the temperature difference between the surroundings or the temperature difference between the inside and the surface of the mass concrete. Since a phenomenon that adversely affects the strength may occur, it has been necessary for the builder to appropriately predict and manage the state of the concrete strength.

In addition, naturally, even in a concrete structure constructed under conditions different from general construction conditions, such as in the heat or cold, the manifestation of strength differs from that of a general concrete structure. Need to be properly predicted and managed.

Therefore, the present applicant arranges a concrete specimen in a water tank and measures the temperature of the concrete under execution or the temperature of the simulated mass concrete in an insulated state so that the measured temperature is the same as the temperature in the water tank. By heating / cooling the inside of the water tank, the concrete specimen is given the same temperature history as the concrete under execution or the simulated mass concrete, and thus the concrete mass can be easily and accurately controlled using the specimen. A method and apparatus for managing specimens was proposed (Japanese Patent Application No. 58-165824).

[Problems to be Solved by the Invention] By the way, in recent years, there is a demand to grasp not only the influence of temperature but also the influence of humidity on concrete. However, in the above proposed example, although the temperature of the concrete specimen placed in the water can be changed by changing the temperature of the water in the water tank, the humidity is always 100% in the water. It was impossible to give a humidity change to the concrete specimen, and there was room for further improvement in this respect.

The present invention has been made in consideration of the above circumstances, and has as its object to provide a concrete strength management device capable of grasping the influence of humidity.

"Means for Solving the Problems" The present invention solves the above problems by employing the following means.

That is, the invention according to the first aspect is characterized in that a constant temperature bath in which a concrete specimen enters, a heating / cooling device provided in the constant temperature bath to heat and cool the air therein, and air in the constant temperature bath Humidifier that adjusts the humidity of the temperature, and a temperature detector that detects the historical temperature of the concrete that was actually constructed, based on the detection signal of this temperature detector, based on the detected temperature of the air in the constant temperature bath to the detected temperature And a temperature controller for controlling the heating / cooling device to adjust the temperature.

The invention according to a second aspect of the present invention provides a thermostat in which a concrete specimen enters, a heating / cooling device provided in the thermostat to heat and cool the air inside the thermostat, and an air in the thermostat. Humidifier for adjusting the humidity of the humidifier, an insulated tank in which simulated concrete is cast inside with four surfaces insulated, a temperature detector for detecting the hysteresis temperature of the simulated concrete in the insulated tank, and this temperature detector And a temperature controller for controlling the heating / cooling device so that the temperature of the air in the constant temperature bath is adjusted to the detected temperature based on the detection signal.

The invention according to a third aspect of the present invention provides a thermostat in which a concrete specimen enters, a heating / cooling device provided in the thermostat and heating / cooling the air inside the thermostat, and the thermostat. A wetter for adjusting the humidity of the air in the tank, a temperature / humidity storage means for storing the actual temperature / humidity of the concrete actually implemented, and a history temperature / humidity of the actual concrete stored in the temperature / humidity storage means Based on the data,
It is characterized by comprising a temperature / humidity controller for controlling the heating / cooling device and the wetting device so as to match the temperature / humidity of the air in the constant temperature bath with the temperature / humidity data of the air in the constant temperature bath. I have.

Further, the present invention according to a fourth aspect provides a constant temperature bath in which a concrete specimen enters, a heating / cooling device provided in the constant temperature bath to heat and cool the air therein, A moisturizer for adjusting the humidity of the air, an insulating tank in which four surfaces are insulated and a simulated concrete is cast inside, a temperature and humidity detector for detecting the history temperature and humidity of the simulated concrete in the insulating tank; Based on the detected temperature and humidity of the temperature and humidity detector, comprising a temperature and humidity controller that controls the heating / cooling device and the wetting device so as to adjust the temperature and humidity of the air in the constant temperature chamber to the detected temperature and humidity. It is characterized by becoming.

According to a fifth aspect of the present invention, there is provided a thermostat in which a specimen of concrete enters, a heater / cooler provided in the thermostat to heat and cool the air therein, and an air in the thermostat. A humidity controller for adjusting the humidity of the concrete, temperature and humidity prediction means for predicting the history temperature and humidity of the concrete, and based on the predicted temperature and humidity data obtained by the prediction means, the predicted temperature and humidity data are added to the air in the constant temperature chamber. And a temperature / humidity controller for controlling the heating / cooling device and the wetting device so as to adjust the temperature and the humidity.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 and 2 are views showing a concrete strength management device according to an embodiment of the present invention.

In these figures, reference numeral 1 denotes a thermostat having a heat insulating structure, in which a concrete specimen S is stored. In the thermostat 1, storage shelves are provided in multiple stages, and it is possible to store a large number of specimens S. Reference numerals 2 and 3 heat and heat the air in the thermostat 1, respectively.
It is for cooling. A heater 4 is disposed inside the heater 2, a pipe 5 is disposed in the cooler 3, and a refrigerator 6 is connected to the pipe 5. Above the heater 2 and the cooler 3, a spray nozzle 7 for adjusting the humidity of the air in the thermostat 1 is provided.
The spray nozzle 7 is connected to a water tank 9 via a pipe 8. In addition, pumps and valves indicated by reference numerals 10 and 11 are connected to the pipe 8. The spray nozzle 7, the pipe 8, the water tank 9, the pump 10, and the valve 11 constitute a wetter 12.

Above the spray nozzle 7, that is, at the upper end on the rear side inside the thermostat 1, a fan 13 for keeping the temperature and humidity of the air in the thermostat 1 uniform is provided. This fan 13
Is a fan motor 14 provided on the outer upper surface of the thermostat 1.
Is connected to

The heater 2, the cooler 3, the nozzle 7, and the fan 13 are provided in a duct 1 a in the thermostat 1. When the fan 13 is turned, a constant airflow flows in the duct 1 a and other thermostats 1. it can. For this purpose, the heating / cooling devices 2 and 3
The inside of the cooled thermostat 1 can be uniformly stirred. A water receiver 1b is provided on the lower surface in the thermostat 1, and the cooler 3 is provided.
And excess water from the nozzle 7 can be received.

The heater 4 and the refrigerator 6 are controlled by a temperature controller 16 provided in a control box 15. A thermocouple (for example, a CC thermocouple) 17 is connected to the temperature controller 16 as a temperature detector. The thermocouple 17 is actually construction is mounted in position P ₂ of the place P ₁ or simulated concrete actual construction concrete is, to detect the history temperature of the concrete at the attachment point, the temperature and the temperature detection signal Send to controller 16.

Further, a personal computer 19 is connected as temperature predicting means for predicting the temperature by heat conduction analysis or the like based on the history temperature of the concrete.
In the humidity estimating means, data which records a temporal change of humidity in a certain area is input in advance to the personal computer 19, and the humidity is controlled by sequentially outputting the data.

Then, the temperature controller 16 controls the heater 4 and the refrigerator 6 so that the temperature in the thermostat 1 is adjusted to the history temperature. Therefore, the temperature controller 16 includes a constant temperature bath 1
Thermocouple 18 (for example, C-C) for detecting and feeding back the internal temperature and the internal temperature of the concrete specimen S
Is connected. The status of the temperature control by the temperature controller 16 is indicated by a temperature indicator 20 provided in the control box 15.
Displayed by

Next, a specific circuit configuration of the temperature controller 16 and its surroundings will be described with reference to FIG.

In the figure, reference numeral 40 is a commercially available temperature indicating controller,
The controller 40 is supplied with power from R and S of the three-phase alternating current R, S and T via a fuse f, an alternative contact SS1 and a transformer T. Relays RY1, RY2, RY3, RY4 and pilot lamp PL1 are also connected in parallel to power supply lines R, S.

Reference numeral 42 denotes a program controller as a temperature / humidity storage means. As in the case of the temperature indicating controller 40, among the three-phase alternating currents R, S, and T via a normally open contact RY2 which is excited and driven by a relay RY2. Power is supplied from R and S. The program controller 42 has similar conditions to the concrete to be implemented, and also stores the historical temperature data of the previously applied concrete, and a zero compensation circuit 41 is connected in parallel.

In front of the relay RY1, a push button type normally open contact PBS2 and an alternative contact SS2 are provided in parallel. The contact SS2 is set to control the inside of the thermostat 1 to a constant temperature when it is in a conductive state, and to control the inside of the thermostat ₁ to follow the right place P1 of the concrete to be implemented when it is in an open state. Similarly, in the preceding stage of the relay RY2, an alternative contact SS3 is provided, and when the contact SS3 is in a conductive state, the temperature control is performed by the temperature instruction controller 40, and when the contact is open, the temperature control is performed by the program controller 42. Set as follows. On the other hand, a push button type normally open contact PBS3 is provided in front of the relay RY3. This push button type normally open contact PBS3
Is set so that the absolute value of the temperature of the concrete specimen S is displayed by the temperature indicating controller 40 when the conductive state is established. In addition, an alternative contact SS4 is provided in front of the relay RY4.

Relays RRY and RY5 are also connected in parallel to power lines R and S. In front of the relay RY5, a push-button type normally open contact PBS1, a normally open contact RY5 excited by the relay RY5, and a normally closed contact RRY with a timer are connected in parallel. OR, R.OR and normally closed contacts OH1, OH2, DP
S is connected in series. Fuse F.OR, P.OR, R.OR
Is operated when the fan 13, the pump 10 and the refrigerator 6 are overloaded, and the normally closed contact DPS is activated when the pressure condition of the refrigerator 6 becomes abnormal. The pilot lamp PL2 is connected to the relay RY5 via a normally closed contact RY5 which is driven by excitation by the relay RY5.
Via a normally open contact and a normally closed contact RY1
The power supply lines R and S are connected in parallel. The pilot lamps PL5 and PL6 are connected to the pilot lamps PL7 and PL6 via a normally-open contact and a normally-closed contact RY2 which are excited and driven by a relay RY2.
8 is a normally open contact and a normally closed contact RY driven by the relay RY3.
3 are connected in parallel to the power supply lines R and S.

Further, SV, F, P, R, H, and F are connected to the power supply lines R and S through a normally open contact RY5 that is excited and driven by a relay RY5.
L is connected in parallel.

The relay F is provided with a knife switch SW1 at the preceding stage. In front of the relay P, a knife switch SW2, a normally closed contact RY4 excited and driven by the relay RY4, and a floatless switch FL are connected in series. Pilot lamp PL
Reference numeral 9 is connected in parallel to the relay P, and a floatless switch FL is provided at the preceding stage. Further, a knife switch SW3 and a contact LPS are connected in series at a stage preceding the relay R. On the other hand, in front of the relay SV, a knife switch 4, a normally open contact TC.ALM, a normally closed contact TS50 ° C., and a contact LPS are connected in series. PL13 is a pilot lamp connected to the relay SV. Further, a knife switch SW5 is connected in series before the relay H.

The controller 40 includes a thermocouple as shown in FIG.
17 and 18 are connected in parallel. Of these thermocouples 17 and 18, the thermocouple 17 is inserted into the concrete for practical use or the simulated mass concrete as described above, while the thermocouple 18 is inserted into the thermostat 1. A normally open contact RY1 excited by a relay RY1 and a normally closed contact excited by a relay RY3 between the positive terminal of the thermocouple 17 and the positive terminal 40a of the controller 40.
RY3 is interposed, and a normally-closed contact RY2 that is excited and driven by a relay RY2 is connected in parallel to the normally-open contact RY1. Similarly, a normally closed contact RY1 that is excited and driven by the relay RY1 is interposed between the negative terminal of the thermocouple 17 and the negative terminal 40b of the controller 40. The positive side of the thermocouple 18 is connected to the positive terminal 40a of the controller 40.
The negative side of the thermocouple 18 is connected to the negative side 40b of the controller 40, and a normally open contact RY3 which is driven by excitation by the relay RY3 is interposed between them.

Further, a compensating circuit 41 is connected in parallel to the controller 40. As shown in FIG. 3B, a relay is provided between the positive input terminal 41a of the compensating circuit 41 and the positive terminal of the controller 40. RY1, RY
Normally closed contacts RY1 and RY2, each of which is excited and driven by 2, are interposed. Similarly, between the negative input terminal 41b of the compensation circuit 41 and the negative terminal of the controller 40, a normally open contact RY1 excited by the relay RY1 and a normally closed contact RY2 excited by the relays RY2 and RY3. , RY3 is interposed. Further, the positive output terminal 41c of the compensation circuit 41 is connected to a thermocouple via a normally closed contact RY1 which is driven by excitation by the relay RY1.
17 is connected to the positive electrode side, and similarly, the negative output terminal 41d of the compensation circuit 41 is connected to the normally closed contact RY driven by the relay RY3.
It is connected to the positive side of the thermocouple 18 via 3. Further, the negative side of the thermocouple 17 and the negative side of the thermocouple 18 are connected via normally closed contacts RY1, RY2, RY3 which are respectively driven by excitation by relays RY1, RY2, RY3.

Further, a program controller 42 is connected to the negative terminal 40b of the controller 40.
The normally open contacts RY2 and RY2 driven by the motor 2 are interposed.

The pump 10 is supplied with three-phase alternating currents R, S, and T via an electromagnetic switch P and a circuit breaker P that are closed by excitation of the relay P. Similarly, the refrigerator 6 is also supplied with the three-phase alternating currents R, S, and T via the electromagnetic switch R and the circuit breaker R that are closed by the excitation drive of the relay R. Further, the heater 4 is also supplied with three-phase alternating currents R, S, and T via electromagnetic switches H, H that are closed by excitation of the relay H. The relays SV1 and SV2 respectively drive the main solenoid valve and the bypass circuit of the refrigeration in excitation.

Next, simulated concrete used with the circuit,
The four-sided heat insulation tank and its peripheral devices will be described.

Simulated concrete C ₂ is shown in FIG. 4 to FIG. 5, are Da設the four sides thermal insulation vessel 30.

That is, assuming a state in which the bar-shaped concrete in the minimum member thickness direction is taken out from the concrete member C to be worked, and by completely insulating the four surrounding surfaces except both end surfaces in the longitudinal direction, the concrete in the working concrete is obtained. Simulates heat generation, heat conduction, heat conduction behavior, etc. due to hydration in the minimum member thickness direction of the member C, and thus predicts one-dimensional temperature progress and temperature distribution state in the minimum member thickness direction of the concrete member C under construction. Is trying to obtain.
Therefore, the steel plate form 31 of the heat insulating tank 30 is formed into a shape in which both longitudinal end surfaces of the rod-shaped member are opened, and a glass cotton heat insulating plate 32 and a heat A control heater 33 combined with a conductive plate and an FRP (fiber reinforced plastics) plate 34 are provided. Then, the glass cotton heat insulating plate 32 gives an amount of heat corresponding to the heat between the heat insulating tank 30 and the outside by the control heater 34, thereby maintaining the inside of the heat insulating tank 30 in a completely insulated state. is there.

Such Da設is the inside simulated concrete C _2, or near the surface of the structure of the thermal insulation vessel 30, a plurality of thermocouples 35 and 35 along its longitudinal direction, ... are installed, and, These are connected to a self-recording temperature recorder 37 and a temperature controller 38 in a control panel 36 adjacent to the heat insulating tank 30. The temperature controller 38 appropriately controls the heater 33 based on the detection signals of the thermocouples 35, 35,.... Then, the reference point temperature of the simulated concrete C ₂ is thermogram thermometer
The temperature is input to the above-described temperature controller 16 via 37 as a history temperature. The reference point temperature, the thermocouple 35, the temperature of the interior and surface like a predetermined site within the simulated concrete C ₂ detected by ......, actual construction concrete C to be measured
The temperature may be set at an appropriate temperature in accordance with the type of the material.

Next, a concrete strength management method using the concrete strength management device having the above configuration will be described.

At the time of design and construction planning, first, as shown in FIGS. 4 and 5, a simulated concrete C ₂ is poured into the heat insulating tank 30, and the temperature of the simulated concrete C _{2 at} the appropriate place P ₂ is measured by the thermocouple 35. , 35... This hysteresis temperature is input to the temperature controller 16 as a detection signal.

At the same time, the concrete specimen S was placed in the constant temperature bath 1
And the contact SS in the temperature controller 16
1 is turned on, and the knife switches SW1 to SW5 are turned on, and the refrigerator 6, the pump 10, the refrigerant main solenoid valve, the bypass circuit, and the heater 4 are turned on. Then, the temperature of the temperature controller 40 is simulant concrete C ₂ and a thermostat 1 was measured with a thermocouple 17 and 18, wherein the difference between them so as to make zero the refrigerator 6, and controls the heater 4 or the like . Thus, the concrete specimen S, substantially the same temperature conditions as the history of a simulated concrete C ₂ temperature is given. Then, at a predetermined material age, the concrete specimen S is appropriately taken out of the constant temperature bath 1 and a strength test is performed, whereby the strength development state and the progress of the concrete concrete C can be predicted.

Further, the time of actual installation, the history temperature from place P ₁ of the actual construction concrete C is measured, the history temperature, compares the time above the design, and the simulated concrete C ₂ historical temperature data collected during construction planning, In a real-time state, the temperature of the constant-temperature bath 1 is controlled in accordance with the history temperature of the concrete C. Therefore, concrete specimen S
Almost the same temperature condition as that of the working concrete C is given, whereby the strength development state and the progress of the working concrete C can be managed by the concrete specimen S.

Accordingly, the strength management method and apparatus of the concrete described above, when design, during construction planning, real construction concrete C in accordance with the history temperature of the simulated concrete C ₂ that imitates the constant temperature bath 1 concrete specimen S is accommodated The temperature of the concrete and the concrete
Since in accordance with the history temperature controls the temperature of the thermostatic chamber 1, the actual construction concrete S or temperature conditions simulated concrete C ₂ imitating it directly and accurately can be provided to the concrete specimen S. Therefore, unlike the conventional method for predicting the strength of concrete, it is possible to directly and easily perform the strength prediction and management of the concrete C to be implemented without performing estimation and estimation, and the accuracy is extremely high. Can predict and manage.

In particular, in this concrete strength management device,
Instead of the conventional water tank, the internal humidity controllable thermostat is used, and since the moisturizer is provided in this thermostat, the ambient humidity surrounding the specimen can be changed. In addition, it is possible to control the strength of concrete not only for temperature changes but also for humidity changes. Therefore, according to the concrete strength management device of the present invention, it is possible to perform the strength management that can sufficiently cope with various changes in the weather conditions surrounding the concrete C.

Further, in this embodiment, after the temperature in the thermostat 1 is heated and cooled by the heaters / coolers 2 and 3, the fan 7 circulates through the thermostat 1 to make the temperature uniform. The temperature can be finely adjusted.

It is needless to say that the detailed structure of the concrete strength management of the present invention is not limited to the above embodiment, and various modifications are possible.

[Effects of the Invention] As described in detail above, according to the present invention, a constant temperature bath into which a concrete specimen enters, and a heating / cooling device provided in the constant temperature bath to heat and cool the air inside the constant temperature bath ,
A humidifier for adjusting the humidity of the air in the constant-temperature bath, and a temperature detector for detecting the hysteresis temperature of the actually-constructed concrete or simulated concrete poured into an insulated bath having four surfaces insulated. And a temperature controller for heating / cooling the inside of the constant temperature bath based on a detection signal of the temperature detector so as to adjust the temperature of the air in the constant temperature bath to the detected temperature. , Wetting control in the thermostat is possible by the wetting device,
Since various changes in humidity in the thermostat are possible, it is also possible to control the strength of concrete against humidity. Therefore, according to the present invention, it is possible to realize a concrete strength management device that can cope with a change in humidity.

A constant temperature bath into which the concrete specimen enters, a heating / cooling device provided in the constant temperature bath to heat and cool the air therein, and a wetter for adjusting the humidity of the air in the constant temperature bath,
Based on the temperature and humidity storage means for storing the history temperature and humidity of the actually implemented concrete, and based on the history temperature and humidity data of the actual concrete stored in the temperature and humidity storage means, the temperature and humidity data are stored in the history temperature and humidity data. Since the concrete strength management device includes a temperature / humidity controller for controlling the heating / cooling device and the wetting device so as to adjust the temperature / humidity of the air in the tank, the stored history temperature / humidity data is stored. It is possible to repeatedly perform concrete strength management based on the same temperature and humidity data.

Further, the constant temperature bath, an insulating bath in which the simulated concrete is cast inside the four surfaces are insulated, and a temperature and humidity detector for detecting the history temperature and humidity of the simulated concrete in the insulating bath,
Based on the detected temperature and humidity of the temperature and humidity detector, a temperature and humidity controller that controls a heating / cooling device and a wetting device so as to adjust the temperature and humidity of the air in the thermostat to the detected temperature and humidity. Since the concrete strength control device is used in combination with the concrete strength control device, it is possible to perform a more realistic strength control.

Further, based on the temperature / humidity prediction means for predicting the history temperature and humidity of the concrete, and the temperature and humidity data obtained by the prediction means, the temperature / humidity data is added to the predicted temperature / humidity data. Since it is a concrete strength management device equipped with a temperature / humidity controller that controls a heating / cooling device and a wetting device in a thermostat so as to adjust the humidity, it is not necessary to measure the actual hysteresis temperature. Can be controlled.

BRIEF DESCRIPTION OF THE DRAWINGS FIGS. 1 to 5 are views showing a concrete strength management device according to an embodiment of the present invention, and FIG. 1 (a).
Is a schematic configuration diagram showing an enlarged view of the inside of the circle in FIG.
FIG. 1 (b) is a schematic configuration diagram showing the whole, FIG. 2 is a side sectional view showing a thermostat and its accessories, FIG. 3 is a circuit diagram showing a circuit configuration of a temperature controller, and FIG. FIG. 5 is a schematic configuration diagram showing the heat insulating tank and its peripheral devices, and FIG. 5 is a longitudinal sectional view of the heat insulating tank. S ...... concrete specimen, C ...... actual construction concrete, C ₂ ...... simulated concrete, 1 ...... thermostat 2 ...... heater, 3 ...... cooler, 12 ...... wetting device, 16 ...... temperature control Vessel 19 personal computer 30 heat insulation tank 42 computer

 ──────────────────────────────────────────────────続 き Continuation of front page (72) Inventor Keiji Aoyagi 2-16-1 Kyobashi, Chuo-ku, Tokyo Shimizu Construction Co., Ltd. (56) References JP-A-60-57252 (JP, A)

Claims (5)

(57) [Claims] 1. A constant-temperature bath in which a concrete specimen enters, a heating / cooling device provided in the constant-temperature bath for heating and cooling the air therein, and a wetting device for adjusting the humidity of the air in the constant-temperature bath. And a temperature detector for detecting the hysteresis temperature of the actually implemented concrete, and the heating based on the detection signal of the temperature detector, so that the temperature of the air in the constant temperature chamber is adjusted to the detected temperature. A concrete strength management device including a temperature controller for controlling a cooler. 2. A constant temperature bath in which a concrete specimen enters, a heating / cooling device provided in the constant temperature bath for heating / cooling the air therein, and a wetter for adjusting the humidity of the air in the constant temperature bath. And a heat insulation tank in which the simulated concrete is cast inside with four surfaces insulated, a temperature detector for detecting the hysteresis temperature of the simulated concrete in the heat insulation tank, and a detection signal of the temperature detector, A concrete strength management device, comprising: a temperature controller for controlling the heating / cooling device so that the temperature of the air in the constant temperature bath is adjusted to the detected temperature. 3. A constant temperature bath in which a concrete specimen enters, a heating / cooling device provided in the constant temperature bath for heating and cooling the air therein, and a wetting device for adjusting the humidity of the air in the constant temperature bath. Based on the temperature and humidity storage means for storing the history temperature and humidity of the actually implemented concrete, and based on the history temperature and humidity data of the actual concrete stored in the temperature and humidity storage means, A concrete strength management device comprising a temperature / humidity controller for controlling the heating / cooling device and the wetting device so as to adjust the temperature and humidity of the air in the constant temperature bath. 4. A constant temperature bath in which a concrete specimen enters, a heating / cooling device provided in the constant temperature bath for heating and cooling the air therein, and a wetting device for adjusting the humidity of the air in the constant temperature bath. And a heat insulation tank in which the simulated concrete is cast inside with four surfaces insulated, a temperature and humidity detector for detecting the history temperature and humidity of the simulated concrete in the heat insulation tank, and a detection humidity of the temperature and humidity detector. A concrete strength management device comprising a temperature / humidity controller for controlling the heating / cooling device and the wetting device so that the temperature / humidity of the air in the thermostat is adjusted to the detected temperature / humidity. 5. A constant temperature bath in which a concrete specimen enters, a heating / cooling device provided in the constant temperature bath for heating and cooling the air therein, and a wetting device for adjusting the humidity of the air in the constant temperature bath. Temperature and humidity predicting means for predicting the history temperature and humidity of concrete, and the heating is performed based on the predicted temperature and humidity data obtained by the predicting means so as to match the temperature and humidity in the constant temperature chamber with the predicted temperature and humidity data. A concrete strength management device comprising a temperature and humidity controller for controlling a cooler and a wetter.