JPS61105450A - Testing device for temperature rise in heat insulated concrete and mortar - Google Patents

Abstract

PURPOSE:To reproduce the actual mixing, properties, etc., of concrete at an actual building site by controlling the temperature of a heating medium so that the surface temperature of a test vessel follows up a temperature rise of heat of hydration. CONSTITUTION:A storage container 10 and a carriage 12, a heating medium jacket 14, a sample and the test vessel 16, etc., are provided. Then when a test of heat insulation temperature is taken by using a heat insulation tempera ture rise testing device 9, a lever 25 is drawn to suspend the container 10 on the carriage 12 with a lift hook 24, and the lever 25 is fixed to hold the con tainer 10 suspended. Then, a lock device 21 fitted to the front part 10b of the container 10 is released and the container is separated in the right and left directions with a handle 20. Then, the test vessel 16 which contains the sample is installed in the jacket 14 and the container 10 is closed and locked again. The lever 25 is fallen down to lower the container 10 on the carriage 12, and a test is taken again. Therefore, the temperature in the test vessel 16 is raised without any time difference and an ideal test of heat insulation temperature is taken.

Description

Detailed Description of the Invention [Field of Industrial Application] The present invention relates to an adiabatic temperature rise test device for concrete and mortar, and in particular, to a device for testing concrete or mortar as a sample stored in a test chamber. Control the heat transfer rate so that the surface temperature of the medium jacket follows, keep the sample in the test chamber in an adiabatic state, and measure the adiabatic temperature rise of the sample? Regarding tl.

[Conventional technology]

Conventionally, an adiabatic temperature rise test device for concrete and mortar has been widely used to check the placement status of concrete or mortar at a construction site. That is, the adiabatic temperature test is performed by forming concrete or the like in a test device using a mixture similar to the actual mixture at a construction site.

In general, such an adiabatic temperature rise testing device for concrete or the like is equipped with a fixed heat medium tank using water or air as a heat medium. In other words, in the case of an air tank, the test tank is covered with a buffering material such as cork, styrofoam, or styrene, and in the case of an aquarium, the sample in the test tank is covered with a buffering material such as cork. The purpose is to control the temperature of the heat medium in the tank to follow the temperature rise due to the hydration reaction of cement, artificially create an adiabatic state, and measure the amount of adiabatic temperature rise in the concrete sample. A-ru. As shown in Fig. 5, the concrete insulation temperature rise test device 1 using air as a heating medium is used as an example. A cylindrical buffer container 2 made of cork is installed in a stainless steel calorimeter box l serving as a container, and a test Il! Concrete 3 as a sealed sample is stored in I8. A heater 4 is disposed on the side and below the buffer container 2, and its operation is controlled by a temperature controller 5. Also,
A concrete thermometer 8a is inserted into the concrete 3 stored in the test tank 8, and an in-tank thermometer 8b is installed inside the calorimeter box l, and the concrete thermometer 8a records the temperature. Connected to a total of 7.

Therefore, when water in the mortar or concrete reacts with cement in the test tank 8 and heat of hydration reaction is generated, the temperature inside the calorimeter box 1 is approximately the same as the temperature inside the test tank 8. The heater 4 operates and heats until .

That is, the heater 4 operates in a manner that follows changes in the temperature rise of the sample in the test chamber 8, and the sample is insulated while the temperature in the test chamber 8 and the temperature inside the calorimeter box 1 are kept approximately the same. This measures the amount of temperature rise.

By the way, in such conventional concrete and mortar adiabatic temperature rise test equipment, when the test chamber 8 is large-sized, an air chamber (calorimeter box) is used.
Since the test tank 8 must also be large, a test tank 8 with a diameter and height of about 40 cm is generally used.

[The shortcomings of conventional technology]

However, depending on the adiabatic temperature rise test device formed with such a small sealing size, it is possible to obtain a uniform sample from concrete whose maximum size is about 150 mm to 200 mm, which is the coarse aggregate used in dams, etc. Although this method uses concrete of a size smaller than the specified size, it has the disadvantage that it is not possible to reproduce the actual mix of concrete or the properties of concrete at a construction site. Further, in the conventional adiabatic temperature rise test apparatus, the test chamber 8 is covered with a buffer material 2a such as cork to prevent heat from flowing out from the sample 3 housed inside. However, since the buffer material 2a serves as a heat insulating material, even when heated by the heater, there is a time lag between the temperature rise in the test chamber 8 and the temperature rise in the chamber. This also has the disadvantage that heat flows out from the sample in the test chamber 8 during this slight time lag.Furthermore, in conventional adiabatic temperature rise test equipment, the calorimeter Since the box 1 is not movable, it takes time to set up the test chamber 8, and the initial temperature rise of the sample cannot be measured accurately. Stirring is necessary to make it uniform, but if the stirring is too strong, heat will be generated due to friction between the heating medium particles and between the fan and the heating medium, and the heat will be generated in the test chamber 8 through the buffer material 2a. On the other hand, heat is conducted to the sample and an adiabatic state cannot be formed.

If the stirrer is too small, use the calorimeter box 1.
There was a drawback that the difference in the temperature distribution within the chamber became large, making it impossible to form a similar adiabatic state.

Therefore, one object of the present invention is to be able to sufficiently reproduce the actual mix of concrete and the properties of concrete at a construction site, to effectively form an adiabatic state, and to accurately measure the initial temperature rise of a sample.

In order to achieve this object, the first invention provides:

A sample made of concrete or mortar is stored in a test tank located inside the containment vessel, and the heating medium temperature is controlled so that the surface temperature of the test tank follows the temperature rise of the heat of hydration generated by the hydration reaction. In the adiabatic temperature rise test device, which maintains the sample in the test tank in an adiabatic state and measures the adiabatic temperature change of the sample, the test tank is heated by a heat insulating material and a heat medium jacket provided inside the heat insulating material. formed,
The test tank is provided in close contact with the heat medium jacket, and the containment vessel has an upper plate and a side plate that can be split into two, and is detachably installed on a trolley.

Further, in the second invention, the containment vessel is formed of a heat insulating material and a heat medium jacket provided inside the heat insulating material, and the test tank is provided in close contact with the heat medium jacket, and
The containment vessel is formed so that the top plate and side plate can be split into two, and is detachably installed on one truck, and a lifting device is provided to lift the heat insulating material and heat transfer jacket and separate them onto the one truck.

[Embodiments of the invention]

Hereinafter, the present invention will be described in detail based on embodiments shown in the accompanying drawings.

As shown in FIGS. 1(A) to 1(D), the concrete and mortar adiabatic temperature rise test apparatus 8 according to the present embodiment includes a containment vessel 10 and a control section 11.
0 is installed on a movable trolley 12. The containment vessel 10 is formed into a substantially rectangular parallelepiped, and consists of a heat insulating material 13 and a heat medium jacket 14 provided inside the heat insulating material 13. The test tank 1B according to this embodiment, in which the test tank 18 containing the concrete 15 as a sample is arranged, has a cylindrical shape and a diameter of 800 m5, as shown in FIG. 1(B). The height is 800m. Further, the containment vessel 10 consisting of the heat insulating material 13 and the heat medium jacket 14 is formed so that the top surface portion 10d and the side surface portion lee can be split into two in the width direction except for the bottom surface portion 10e. That is, hinge parts 17 and 18 are attached to the rear surface 10a of the containment vessel 10 at two places, and the hinge rods 8 are inserted through these hinge parts 17 and 18. Two handles 20 and a locking device 21 are attached to the front part 10b of 10. Therefore, the storage capacity! ! 10 is the hinge rod! 9
It can be rotated left and right around the center and divided into two. In addition, the concrete and mortar adiabatic temperature rise test device 8 according to this embodiment uses water as a heating medium,
As shown in FIG. 1(C), from the control unit 11 to the containment vessel 1
A water supply pipe 22 and a drain pipe 23 extend below 0, and are attached to a heat medium jacket 14 provided in the containment vessel 10 via connecting portions 22a and 23a, respectively. The reference numeral 24 is a lift hook for lifting the storage container 11G, and the reference numeral 25 is a lever used to lift the storage container StO. On the other hand, the control section 11
2B is for controlling the temperature inside the containment vessel 10 and recording the temperature rise of the sample 15, and 2B is a temperature recorder;
Reference numeral 27 is a temperature regulator.

When performing an adiabatic temperature test using the adiabatic temperature test test equipment W8 configured as described above, the lever 25 is pulled and the lever 25 is pulled to suspend the containment vessel 10 onto the trolley 12 using the lift 7tuk 17. The container 10 is fixed and maintained in a lifted state.

Next, the locking device 21 attached to the front face 10b of the containment vessel 1O is released, and the containment vessel 10 is
Divide into two horizontally. Then, the test tank I6 containing the sample is placed inside the heat medium jacket 14, and the containment vessel 1G is closed and locked again. After that, the lever 25 is lowered and the containment vessel 10 is lowered onto the trolley 12 to perform the test.Also, when testing samples of different sizes, the first
As shown in FIG.
The following is an example of an experiment carried out using the concrete and mortar adiabatic temperature rise test apparatus according to the present invention.

Mortar with the composition shown in Figure 2 and concrete with the composition shown in Figure 3!・About 1 adiabatic temperature 1f using the device according to the present invention! The L + rise results are compared with the adiabatic temperature change results using the conventional device shown in Figure 5 and the change in the center temperature of the concrete during concrete pouring when a 2 cubic concrete block is covered with 20 cm thick Styrofoam. In addition, the fourth
From Fig. 4, it is clear that the adiabatic temperature - (1 increase) result obtained by this device accurately reproduces the change in the center temperature of the concrete block, which can be considered to be almost adiabatic. The adiabatic temperature rise result obtained by this device was lower than the temperature at the center of the concrete block, making it difficult to call it an accurate adiabatic temperature rise test.

〔Effect of the invention〕

The present invention has the above-mentioned configuration, and the test chamber is installed in a heat medium jacket provided inside the heat insulating material, and the heat medium jacket ensures that the surface temperature is always the same as the sample center temperature. The temperature inside the test chamber can be increased without any time lag, and heat will not flow out from the sample inside the test chamber.
In the present invention, since the heating medium circulates at high speed, the surface of the heating medium jacket has a uniform temperature, and unlike conventional methods, the temperature distribution inside the containment vessel does not become uneven, making it an ideal adiabatic temperature rise test. It can be performed. On the other hand, in the present invention, since the containment vessel is installed on a trolley and is movable,
Ij the test tank! If the initial temperature of the sample is measured in advance, the temperature inside the containment vessel can be set to the initial temperature of the sample. Furthermore, since the test tank is provided with a heating medium jacket and is not in direct contact with the heating medium, it is less susceptible to the effects of stirring heat and can maintain a well-insulated state. Furthermore, the containment vessel according to the second invention is removably installed on the trolley, and can be replaced with a containment vessel that can accommodate a larger test tank, making it possible to conduct tests using samples of various sizes. Therefore, it is possible to faithfully view the actual mix of concrete, properties of concrete, etc. at the construction site. This effect is achieved.

[Brief explanation of drawings]

FIG. 1(A) is a side view of a concrete and mortar adiabatic temperature J:'yl test apparatus z1 according to the present invention. Figure 1 (B) is a front view of the same, Figure 1 (G) is a cutaway of the same part.
: Top view, Figure i1 (D) is a side view showing the containment vessel to be replaced, Figure 2 is a table showing the mix of mortar used in the experiment,
Figure 3 is a table showing the mix of concrete used in the experiment, Figure 4 is a graph showing a comparison of the results of various types of adiabatic temperature rise tests and the temperature change at the center of a large block, and Figure B5 is a graph showing the comparison of the temperature change at the center of a large block. It is an explanatory view showing an adiabatic temperature rise test device. 8...Concrete and mortar insulation temperature rise test device 10...Containment vessel 10d...E plate foe...Side plate 12...Dolly 13...Insulating material 14...Heat medium jacket 15... ...Sample 1B...Test tank 24...Lift hook (hanging device) Patent applicant: Sumitomo Cement Co., Ltd. Figure 1 (A) Ic)

Claims (3)

[Claims] (1) A sample made of concrete or mortar is stored in a test tank located inside the containment vessel, and a heating medium is used so that the surface temperature of the test tank follows the temperature rise of the heat of hydration generated by the hydration reaction. In the concrete and mortar adiabatic temperature rise test device, which maintains the sample in the test chamber in an adiabatic state by controlling the temperature and measures the adiabatic temperature change of the sample, the containment vessel includes a heat insulating material and an inner wall of the heat insulating material. The test tank is provided in close contact with the heat medium jacket, and the containment vessel has a top plate and a side plate that can be split into two, and can be attached to and taken off from the trolley. An adiabatic temperature rise testing device for concrete and mortar, which is characterized by being freely installed. (2) The adiabatic temperature rise testing device for concrete and mortar according to claim 1, wherein the storage container is formed to be able to accommodate other test tanks of different sizes. (3) A sample made of concrete or mortar is stored in a test tank placed inside the containment vessel, and a heating medium is used so that the surface temperature of the test tank follows the temperature rise of the heat of hydration generated by the hydration reaction. In the concrete and mortar adiabatic temperature rise testing device, which maintains the sample in the test tank in an adiabatic state by controlling the temperature and measures the adiabatic temperature change of the sample, the containment vessel includes a heat insulator and a heat insulator inside the heat insulator. The test tank is provided in close contact with the heat medium jacket, and the containment vessel has a top plate and a side plate that can be split into two, and can be attached to and taken off from the trolley. A concrete and mortar adiabatic temperature rise testing device, characterized in that it is provided with a lifting device which is freely installed and which separates the heat insulating material and heat medium jacket from a lifting truck.