阅读说明：本技术 一种反射隔热涂料保温胶泥复合保温系统保温效果的测试装置及方法 (Device and method for testing heat preservation effect of reflective heat insulation coating heat preservation daub composite heat preservation system ) 是由 卢凌寰 朱惠英 阚家兵 谢鸿卫 蒋字平 谢小利 谢江美 杨阳 于 2020-04-20 设计创作，主要内容包括：本发明公开了一种反射隔热涂料保温胶泥复合保温系统保温效果的测试装置及方法,其特征是：包括以下步骤：步骤一：将混凝土浇筑成混凝土板；步骤二：将混凝土板的一侧涂抹保温胶泥后涂抹反射隔热涂料,并在混凝土板的下侧钻螺孔；步骤三：将步骤二中涂抹了保温胶泥和反射隔热涂料之后的混凝土板放入靠近热源的两个限位板之间,每个所述限位板上分别设置有一组一一对应且均匀排布的圆孔；步骤四：将膨胀螺栓穿过圆孔和对应的螺孔后使用螺母固定。本发明涉及反射隔热涂料保温胶泥复合保温系统保温效果的测试设备领域,具体地讲,涉及一种反射隔热涂料保温胶泥复合保温系统保温效果的测试装置及方法。本装置能对不同位置进温度测量。(The invention discloses a device and a method for testing the heat preservation effect of a reflective heat insulation coating heat preservation daub composite heat preservation system, which are characterized in that: the method comprises the following steps: the method comprises the following steps: pouring concrete into a concrete slab; step two: coating heat preservation daub on one side of a concrete slab, coating a reflective heat insulation coating, and drilling a screw hole on the lower side of the concrete slab; step three: placing the concrete slab coated with the heat preservation daub and the reflective heat insulation coating in the second step between two limiting plates close to a heat source, wherein each limiting plate is provided with a group of round holes which correspond to each other one by one and are uniformly distributed; step four: and the expansion bolt penetrates through the round hole and the corresponding screw hole and then is fixed by using a nut. The invention relates to the field of testing equipment for the heat preservation effect of a reflective heat insulation coating heat preservation daub composite heat preservation system, in particular to a device and a method for testing the heat preservation effect of the reflective heat insulation coating heat preservation daub composite heat preservation system. The device can measure the temperature of different positions.)

1. A test method for the heat preservation effect of a reflective heat insulation coating heat preservation daub composite heat preservation system is characterized by comprising the following steps: the method comprises the following steps:

the method comprises the following steps: pouring concrete into a concrete slab;

step two: coating heat preservation daub on one side of a concrete slab, coating a reflective heat insulation coating, and drilling a screw hole on the lower side of the concrete slab;

step three: placing the concrete slab coated with the heat-preservation daub and the reflective heat-insulation coating in the step two between two limiting plates (4) close to a heat source (6), wherein each limiting plate (4) is provided with a group of round holes (5) which correspond to each other one by one and are uniformly distributed;

step four: the expansion bolt penetrates through the round hole (5) and the corresponding screw hole and then is fixed by a nut;

step five: a circular plate (12) is rotated, the circular plate (12) rotates to drive an arc-shaped sliding groove (13) to rotate, the arc-shaped sliding groove (13) drives a cylindrical sliding block (11) to move, the cylindrical sliding block (11) drives a circular shaft (10) to slide in a sliding groove (8), and the cylindrical sliding block (11) drives a temperature sensor (9) to move to adjust the position of the temperature sensor (9);

step six: the temperature sensor (9) measures the temperature and transmits the temperature information to the controller, and the controller controls the display to display the temperature.

2. The device for testing the heat preservation effect of the reflective thermal insulation coating heat preservation daub composite heat preservation system, which is obtained by the method for testing the heat preservation effect of the reflective thermal insulation coating heat preservation daub composite heat preservation system according to claim 1, is characterized in that: a set of limiting plate (4) fixed connection U-shaped support (2)'s diaphragm upside, every be provided with a set of evenly arranged on limiting plate (4) round hole (5) respectively, a riser upper end fixed connection of U-shaped support (2) heat source (6).

3. The device for testing the heat preservation effect of the reflective heat insulation coating heat preservation daub composite heat preservation system as claimed in claim 2, is characterized in that: another riser upper end fixed connection fixed plate (1) of U-shaped support (2), fixed plate (1) is circular, be provided with spout (8) that a set of circumference was evenly arranged on fixed plate (1), every imbed respectively in spout (8) circle axle (10), every the outer end of circle axle (10) is fixed connection temperature sensor (9) respectively, every the other end of circle axle (10) is fixed connection respectively cylinder slider (11), every the both ends of cylinder slider (11) are passed respectively the both sides of spout (8).

4. The device for testing the heat preservation effect of the reflective thermal insulation coating heat preservation daub composite heat preservation system as claimed in claim 3, is characterized in that: one end of each cylindrical sliding block (11) is embedded into each arc-shaped sliding groove (13), all the arc-shaped sliding grooves (13) are formed in the circular plate (12), and the central shaft of the circular plate (12) is hinged to the center of the fixing plate (1).

Technical Field

The invention relates to the field of testing equipment for the heat preservation effect of a reflective heat insulation coating heat preservation daub composite heat preservation system, in particular to a device and a method for testing the heat preservation effect of the reflective heat insulation coating heat preservation daub composite heat preservation system.

Background

The external thermal insulation system of the external thermal insulation coating of the heat preservation daub-reflection thermal insulation coating is an external thermal insulation structural system of the external thermal insulation coating taking the novel heat preservation daub as a thermal insulation layer and the reflection thermal insulation coating as a thermal insulation decorative layer, has a simple structure, has few interfaces among different structural layers, and can effectively solve the quality problems of cracking, water seepage, falling off and the like of the building external thermal insulation layer. The system is different from a common heat-preservation mortar type external wall external heat-preservation system in that the system integrates heat insulation, heat preservation, water resistance, crack resistance and decoration, overcomes the defects of the traditional building heat-preservation mortar, can effectively solve the problems of peeling, water seepage, cracking, complex construction and the like of the traditional heat-preservation mortar product of the external wall in application, is a good substitute product of the heat-preservation mortar due to good durability, has the same service life with a building, and needs to design a testing device for the heat-preservation effect of a reflective heat-preservation coating heat-preservation mortar composite heat-preservation system in order to test the heat-preservation performance of heat-preservation mortar and reflective heat-preservation coating.

Disclosure of Invention

The invention aims to provide a device and a method for testing the heat preservation effect of a reflective heat insulation coating heat preservation daub composite heat preservation system, which are convenient for prolonging the service life of an external wall heat preservation system.

The invention adopts the following technical scheme to realize the purpose of the invention:

a test method for the heat preservation effect of a reflective heat insulation coating heat preservation daub composite heat preservation system is characterized by comprising the following steps: the method comprises the following steps:

the method comprises the following steps: pouring concrete into a concrete slab;

step two: coating heat preservation daub on one side of a concrete slab, coating a reflective heat insulation coating, and drilling a screw hole on the lower side of the concrete slab;

step three: placing the concrete slab coated with the heat preservation daub and the reflective heat insulation coating in the second step between two limiting plates close to a heat source, wherein each limiting plate is provided with a group of round holes which correspond to each other one by one and are uniformly distributed;

step four: the expansion bolt penetrates through the round hole and the corresponding screw hole and then is fixed by a nut;

step five: rotating a circular plate, wherein the circular plate rotates to drive an arc-shaped sliding groove to rotate, the arc-shaped sliding groove drives a cylindrical sliding block to move, the cylindrical sliding block drives a circular shaft to slide in the sliding groove, and the cylindrical sliding block drives a temperature sensor to move to adjust the position of the temperature sensor;

step six: the temperature sensor measures the temperature and transmits the temperature information to the controller, and the controller controls the display to display the temperature.

As the technical scheme, the limiting plates are fixedly connected with the upper side of the transverse plate of the U-shaped support, a group of round holes are uniformly distributed in each limiting plate, and the upper end of one vertical plate of the U-shaped support is fixedly connected with the heat source.

As a further limitation of the technical scheme, the fixed plate is fixedly connected to the upper end of another vertical plate of the U-shaped support and is circular, a set of sliding grooves are formed in the fixed plate, a set of circumference is uniformly distributed, each sliding groove is embedded into the circular shaft, each outer end of the circular shaft is fixedly connected with a temperature sensor, and each other end of the circular shaft is fixedly connected with the cylindrical sliding block and penetrates through two sides of the sliding grooves.

As a further limitation of the technical scheme, one end of each cylindrical sliding block is embedded into each arc-shaped sliding groove, all the arc-shaped sliding grooves are formed in the circular plate, and the central shaft of the circular plate is hinged to the center of the fixing plate.

Compared with the prior art, the invention has the advantages and positive effects that: the invention provides a device and a method for testing the heat preservation effect of a reflective heat insulation coating heat preservation daub composite heat preservation system. The method has the following beneficial effects:

(1) temperature measurements can be made;

(2) the temperature of the concrete slab at different positions away from a heat source can be tested by arranging a plurality of limiting plates;

(3) the temperature sensor can change positions and can measure the temperature of different positions.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a partial perspective view of the present invention.

Fig. 3 is a schematic perspective view of the present invention.

Fig. 4 is a three-dimensional structure diagram of the present invention.

In the figure: 1. the device comprises a fixed plate, 2, a U-shaped support, 4, a limiting plate, 5, a round hole, 6, a heat source, 7, a sliding rail, 8, a sliding groove, 9, a temperature sensor, 10, a round shaft, 11, a cylindrical sliding block, 12, a round plate, 13 and an arc-shaped sliding groove.

Detailed Description

An embodiment of the present invention will be described in detail below with reference to the accompanying drawings, but it should be understood that the scope of the present invention is not limited to the embodiment.

As shown in fig. 1 to 4, the present invention includes the following steps:

the method comprises the following steps: pouring concrete into a concrete slab;

step two: coating heat preservation daub on one side of a concrete slab, coating a reflective heat insulation coating, and drilling a screw hole on the lower side of the concrete slab;

step three: placing the concrete slab coated with the heat preservation daub and the reflective heat insulation coating in the second step between two limiting plates 4 close to a heat source 6, wherein each limiting plate 4 is provided with a group of round holes 5 which correspond to each other one by one and are uniformly distributed;

step four: the expansion bolt passes through the round hole 5 and the corresponding screw hole and then is fixed by a nut;

step five: rotating a circular plate 12, wherein the circular plate 12 rotates to drive an arc-shaped sliding chute 13 to rotate, the arc-shaped sliding chute 13 drives a cylindrical sliding block 11 to move, the cylindrical sliding block 11 drives a circular shaft 10 to slide in a sliding chute 8, and the cylindrical sliding block 11 drives a temperature sensor 9 to move to adjust the position of the temperature sensor 9;

step six: the temperature sensor 9 measures the temperature and transmits the temperature information to the controller, and the controller controls the display to display the temperature.

The limiting plates 4 are fixedly connected to the upper side of a transverse plate of the U-shaped support 2, a group of round holes 5 are uniformly distributed in each limiting plate 4, and the upper end of one vertical plate of the U-shaped support 2 is fixedly connected with the heat source 6.

Another riser upper end fixed connection fixed plate 1 of U-shaped support 2, fixed plate 1 is circular, be provided with the spout 8 that a set of circumference was evenly arranged on fixed plate 1, every imbed respectively in the spout 8 circle axle 10, every the outer end of circle axle 10 is fixed connection temperature sensor 9 respectively, every the other end of circle axle 10 is fixed connection respectively cylinder slider 11, every the both ends of cylinder slider 11 are passed respectively the both sides of spout 8, be provided with slide rail 7 on another riser of U-shaped support 2, slide rail 7 intercommunication corresponds spout 8, temperature sensor 9 passes slide rail 7.

One end of each cylindrical sliding block 11 is embedded into each arc-shaped sliding groove 13, all the arc-shaped sliding grooves 13 are formed in the circular plate 12, and the central shaft of the circular plate 12 is hinged to the center of the fixing plate 1.

The temperature sensor 9 is an existing product, the temperature sensor 9 is electrically connected with a controller (not shown in the figure), the controller is electrically connected with a display (not shown in the figure), and the controller is communicated with the temperature sensor 9 and the display through wireless transmission signals.

Can select different adjacent limiting plate 4 when the test, put into concrete slab between limiting plate 4, conveniently measure the temperature measurement of distance difference between concrete slab and the heat source.

The working process of the invention is as follows: when the concrete thermal insulation device is used, concrete is poured into a concrete slab, one side of the concrete slab is coated with heat preservation cement, then a reflective thermal insulation coating is coated, screw holes are drilled in the lower side of the concrete slab, the concrete slab coated with the heat preservation cement and the reflective thermal insulation coating in the step two is placed between two limiting plates 4 close to a heat source 6, a group of round holes 5 which are corresponding one to one and evenly distributed are respectively arranged on each limiting plate 4, expansion bolts penetrate through the round holes 5 and the corresponding screw holes and are fixed through nuts, a circular plate 12 is rotated, the circular plate 12 rotates to drive an arc-shaped sliding groove 13 to rotate, the arc-shaped sliding groove 13 drives a cylindrical sliding block 11 to move, the cylindrical sliding block 11 drives a round shaft 10 to slide in a sliding groove 8, the cylindrical sliding block 11 drives a temperature sensor 9 to move, the position of the temperature sensor 9 is adjusted, the temperature sensor 9 carries out temperature measurement and transmits temperature information to a controller, the controller controls the display to display the temperature.

The above disclosure is only one specific embodiment of the present invention, but the present invention is not limited thereto, and any variations that can be made by those skilled in the art are intended to fall within the scope of the present invention.