CN218382498U - Building energy-saving effect detection device - Google Patents

Abstract

The utility model relates to the field of buildings, in particular to a building energy-saving effect detection device, which comprises a temperature measurement mechanism, a clamping mechanism and an optical measurement mechanism, wherein the clamping mechanism is installed in the temperature measurement mechanism, the optical measurement mechanism is arranged at the lower side of the clamping mechanism, the temperature measurement mechanism comprises a detection box, a first temperature detector, a second temperature detector and a display screen, the front end of the inner wall of the detection box is connected with the first temperature detector, the second temperature detector is installed at the lower side of the first temperature detector, and the display screen is embedded on the front surface of the detection box; the beneficial effects are that: set up the temperature and survey the mechanism, make the temperature of first temperature detection meter detection material upside, the temperature of second temperature detection meter detection material downside, first temperature detection meter and second temperature detection meter pass through electric connection will detect data and pass through signal of telecommunication and transmit for the display screen, and the display screen shows the detection data of two temperature detection meters, and the detection personnel of being convenient for detect the thermal-insulated effect that the material was detected through the temperature difference of first temperature detection meter and second temperature detection meter.

Description

Building energy conservation effect detection device

Technical Field

The utility model relates to a building field especially relates to a building energy conservation effect detection device.

Background

With the rapid development of national economy and the rapid expansion of the building industry, a large amount of energy is consumed in the construction process of a newly-built building, and a large amount of energy is continuously consumed in the longer using process of the newly-built building, so that new technologies and new materials are used in the building construction process at present, the building is warm in winter and cool in summer, and the energy consumption of the building in the using process is reduced as much as possible. And the energy-saving effect of the building needs to be measured by using a building energy-saving detection device.

Patent number (CN 215727698U) discloses a building energy saving effect detection device, which comprises a test bench; a placing box is arranged on the left side of the upper end of the inspection platform, a solar simulation generator is arranged in the placing box, and two groups of track grooves are symmetrically arranged on the right side of the upper end of the inspection platform; meanwhile, two groups of fixing frames are symmetrically arranged, the lower end of each fixing frame is fixedly connected with the inspection bench, test glass is clamped between the two groups of fixing frames, and two groups of fixing mechanisms are symmetrically arranged on the upper and lower parts of the surface of the fixing frame on the outer side; the sliding block slides through the T type piece of lower extreme and clamps the rail inslot portion, and sliding block upper end rear side is equipped with the connecting rod, and the fan is installed on the connecting rod top, makes the device pass through solar panel and fan electric connection for the slew velocity of fan can show solar panel's work efficiency, thereby can reachs experimental glass's light resistance performance, still through the setting of display, can show the slew velocity of fan on the feasible display, can let the experimenter obtain accurate test data. However, the new material for building construction at present reduces the material light resistance performance, and also ensures the heat insulation effect as much as possible, so that the building itself is warm in winter and cool in summer, and the energy consumption of the building in the use process is reduced as much as possible.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is just to provide a building energy saving effect detection device for solving above-mentioned problem.

The utility model discloses a following technical scheme realizes above-mentioned purpose:

a building energy-saving effect detection device comprises a temperature measurement mechanism, a clamping mechanism and an optical measurement mechanism, wherein the clamping mechanism is installed in the temperature measurement mechanism, the optical measurement mechanism is arranged on the lower side of the clamping mechanism, the temperature measurement mechanism comprises a detection box, a first temperature detector, a second temperature detector and a display screen, the first temperature detector is connected to the front end of the inner wall of the detection box, the second temperature detector is installed on the lower side of the first temperature detector, and the display screen is embedded in the front surface of the detection box; wherein the first temperature detector and the second temperature detector are electrically connected with the display screen.

Preferably, the optical measurement mechanism comprises a solar simulation generator, a driving motor, a screw, a sliding rail, a bottom plate, a fixing seat, a servo motor, a rotating rod, a rotating seat, a solar panel, a fan and a filter screen, the solar simulation generator is installed at the upper end of the inner wall of the detection box, the driving motor is fixed at the lower end of the inner wall of the detection box, the screw is connected to the upper end of the driving motor, the sliding rail is arranged at the rear side of the screw, the bottom plate is connected to the outer ring of the screw and the sliding rail, the fixing seat is fixed on the upper surface of the bottom plate, the rotating rod is connected to the upper end of the fixing seat in a rotating mode, the servo motor is connected to the rear end of the rotating rod, the rotating seat is fixed on the upper side of the rotating rod, the solar panel is connected to the upper end of the rotating seat, the fan is installed at the lower end of one side of the detection box, and the filter screens are arranged on two sides of the fan.

Preferably, the screw rod with driving motor passes through the coupling joint, the bottom plate with the screw rod passes through threaded connection, the slide rail with bottom plate sliding connection, the fan with display screen electric connection.

Preferably, the rotating rod is connected with the servo motor through a coupler, and the fan is electrically connected with the solar panel.

Preferably, the clamping mechanism comprises a fixed base, a connecting rod, a spring and a clamping seat, the fixed base is fixed on two sides of the inner wall of the detection box, the connecting rod is arranged at the upper end of the fixed base, the spring is sleeved on the outer ring of the connecting rod, and the clamping seat is connected to the upper side of the connecting rod.

Preferably, the clamping seat is connected with the connecting rod in a sliding mode, and a groove is formed in the upper surface of the clamping seat.

Has the advantages that: through setting up the temperature measurement mechanism, make the temperature of first temperature detector detection material upside, the temperature of second temperature detector detection material downside, first temperature detector and second temperature detector pass through electric connection and will detect data through signal of telecommunication transmission for the display screen, the display screen shows the detection data of two temperature detectors, the detection personnel of being convenient for detect the thermal-insulated effect of material through the temperature difference of first temperature detector and second temperature detector.

Drawings

Fig. 1 is a schematic structural view of a building energy saving effect detection device according to the present invention;

fig. 2 is a right sectional view of the building energy saving effect detection device of the present invention;

fig. 3 is a front cross-sectional view of the building energy saving effect detection device of the present invention;

fig. 4 is an enlarged view at I of fig. 3.

Description of the reference numerals:

1. a temperature measuring mechanism; 2. a clamping mechanism; 3. a light measurement mechanism; 101. a detection box; 102. a first temperature detector; 103. a second temperature detector; 104. a display screen; 201. a fixed base; 202. a connecting rod; 203. a spring; 204. installing a clamping seat; 301. a solar simulation generator; 302. a drive motor; 303. a screw; 304. a slide rail; 305. a base plate; 306. a fixed seat; 307. a servo motor; 308. a rotating rod; 309. a rotating seat; 310. a solar panel; 311. a fan; 312. and (5) filtering the screen.

Detailed Description

The present invention will be further explained with reference to the accompanying drawings:

as shown in fig. 1 to 4, the building energy saving effect detection device comprises a temperature measurement mechanism 1, a clamping mechanism 2 and a light measurement mechanism 3, wherein the clamping mechanism 2 is installed in the temperature measurement mechanism 1, and the light measurement mechanism 3 is arranged on the lower side of the clamping mechanism 2;

in this embodiment: the temperature measuring mechanism 1 comprises a detecting box 101, a first temperature detector 102, a second temperature detector 103 and a display screen 104, wherein the first temperature detector 102 is connected to the front end of the inner wall of the detecting box 101, the second temperature detector 103 is installed on the lower side of the first temperature detector 102, and the display screen 104 is embedded in the front surface of the detecting box 101; the first temperature detector 102 and the second temperature detector 103 are electrically connected with the display screen 104; through setting up temperature measurement mechanism 1, make the temperature of first temperature detect meter 102 detection material upside, the temperature of second temperature detect meter 103 detection material downside, first temperature detect meter 102 and second temperature detect meter 103 pass through electric signal transmission for display screen 104 with the data of detection through electric connection, display screen 104 shows the data of detection of two temperature detect meters, the thermal-insulated effect that the measurement personnel of being convenient for detected the material through the temperature difference of first temperature detect meter 102 and second temperature detect meter 103.

In this embodiment: the clamping mechanism 2 comprises a fixed base 201, a connecting rod 202, a spring 203 and a clamping seat 204, the fixed base 201 is fixed on two sides of the inner wall of the detection box 101, the connecting rod 202 is arranged at the upper end of the fixed base 201, the spring 203 is sleeved on the outer ring of the connecting rod 202, the clamping seat 204 is connected to the upper side of the connecting rod 202, the clamping seat 204 is connected with the connecting rod 202 in a sliding mode, and a groove is formed in the upper surface of the clamping seat 204; through setting up clamping mechanism 2, when the device carries out energy-conserving effect detection, the measurement personnel at first use energy-conserving material to extrude two clamping bases 204, and the clamping base 204 atress slides to both sides along connecting rod 202, and clamping base 204 exerts the force to spring 203 simultaneously, and spring 203 contracts, makes two clamping bases 204 part, and the recess distance equals with energy-conserving material length to guarantee that clamping base 204 can press from both sides the material of equidimension not.

In this embodiment: the optical measurement mechanism 3 comprises a solar simulation generator 301, a driving motor 302, a screw 303, a sliding rail 304, a bottom plate 305, a fixed seat 306, a servo motor 307, a rotating rod 308, a rotating seat 309, a solar panel 310, a fan 311 and a filter screen 312, wherein the solar simulation generator 301 is installed at the upper end of the inner wall of the detection box 101, the driving motor 302 is fixed at the lower end of the inner wall of the detection box 101, the screw 303 is connected to the upper end of the driving motor 302, the sliding rail 304 is arranged at the rear side of the screw 303, the outer rings of the screw 303 and the sliding rail 304 are connected with the bottom plate 305, the fixed seat 306 is fixed on the upper surface of the bottom plate 305, the rotating rod 308 is connected to the servo motor 307, the rotating seat 309 is fixed on the upper side of the rotating rod 308, the solar panel 310 is connected to the upper end of the rotating seat 309, the fan 311 is installed at the lower end of one side of the detection box 101, the filter screen 312 is arranged on two sides of the fan 311, the screw 303 and the driving motor 302 are connected through a coupler, the bottom plate 305 and the screw 303 are connected through threads, the sliding rail 304 and the sliding rail 305 are connected with the bottom plate 305 in a sliding way, the display screen 104, the rotating rod 308 is connected with the servo motor 307 through a coupler 310, and the solar panel 310; through setting up the optical measurement mechanism 3, make the outdoor sun irradiation of sun simulation generator 301 simulation, driving motor 302 drives screw 303 through the shaft coupling and rotates, bottom plate 305 drives fixing base 306 and solar panel 310 through screw thread effect and goes up and down, thereby adjust the distance of solar panel 310 and material, solar panel 310 makes it rotate to get electricity for fan 311 through electric transmission with electric power through the photoelectric reaction, fan 311 passes through electric signal transmission with fan 311 rotational speed for display screen 104 through electric connection, it observes fan 311 rotational speed size through display screen 104 to be convenient for detection personnel, thereby judge the photoresistance performance of the different distances of material, simultaneously when needs are adjusted solar panel 310 and are received illumination angle, start servo motor 307, make servo motor 307 drive bull stick 308 through the shaft coupling and rotate, bull stick 308 drives solar panel 310 through rotor 309 and rotates, thereby adjust solar panel 310's illumination angle.

In the structure, when the device is required to detect the energy-saving effect, a detector firstly uses the energy-saving material to extrude two clamping seats 204, the clamping seats 204 are stressed to slide towards two sides along the connecting rod 202, meanwhile, the clamping seats 204 apply force to the spring 203, the spring 203 contracts to separate the two clamping seats 204, the distance between the grooves is equal to the length of the energy-saving material so as to ensure that the clamping seats 204 can clamp the material, then the solar simulation generator 301 is started, the solar simulation generator 301 irradiates the material to simulate outdoor solar irradiation, the first temperature detector 102 detects the temperature on the upper side of the material, the second temperature detector 103 detects the temperature on the lower side of the material, the first temperature detector 102 and the second temperature detector 103 transmit the detection data to the display screen 104 through electric signals through electric connection, the display screen 104 displays the detection data of the two temperature detectors, so that a detection person can conveniently detect the heat insulation effect of the material through the temperature difference between the first temperature detector 102 and the second temperature detector 103, the driving motor 302 is started at the same time, the driving motor 302 drives the screw 303 to rotate through the coupler, the bottom plate 305 drives the fixing seat 306 and the solar panel 310 to lift through the screw action, so that the distance between the solar panel 310 and the material is adjusted, the solar panel 310 electrically transmits electric power to the fan 311 through the photoelectric action to enable the fan 311 to electrically rotate, the fan 311 electrically transmits the rotating speed of the fan 311 to the display screen 104 through an electric signal, so that the detection person can conveniently observe the rotating speed of the fan 311 through the display screen 104, and accordingly, the light resistance performance of the material at different distances is judged; when the solar panel 310 needs to be adjusted to receive the illumination angle, the servo motor 307 is started, the servo motor 307 drives the rotating rod 308 to rotate through the coupler, and the rotating rod 308 drives the solar panel 310 to rotate through the rotating seat 309, so that the illumination angle of the solar panel 310 is adjusted.

The foregoing illustrates and describes the general principles, features and advantages of the present invention. It should be understood by those skilled in the art that the present invention is not limited to the above embodiments, and the above embodiments and descriptions are only illustrative of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the present invention, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a building energy saving effect detection device which characterized in that: the device comprises a temperature measuring mechanism (1), a clamping mechanism (2) and an optical measuring mechanism (3), wherein the clamping mechanism (2) is installed in the temperature measuring mechanism (1), the optical measuring mechanism (3) is arranged on the lower side of the clamping mechanism (2), the temperature measuring mechanism (1) comprises a detection box (101), a first temperature detector (102), a second temperature detector (103) and a display screen (104), the first temperature detector (102) is connected to the front end of the inner wall of the detection box (101), the second temperature detector (103) is installed on the lower side of the first temperature detector (102), and the display screen (104) is embedded in the front surface of the detection box (101); wherein the first temperature detector (102) and the second temperature detector (103) are electrically connected with the display screen (104).

2. The building energy saving effect detection device according to claim 1, characterized in that: the optical measurement mechanism (3) comprises a solar simulation generator (301), a driving motor (302), a screw (303), a sliding rail (304), a bottom plate (305), a fixed seat (306), a servo motor (307), a rotating rod (308), a rotating seat (309), a solar panel (310), a fan (311) and a filter screen (312), the upper end of the inner wall of the detection box (101) is provided with the solar simulation generator (301), the lower end of the inner wall of the detection box (101) is fixed with the driving motor (302), the upper end of the driving motor (302) is connected with the screw (303), the sliding rail (304) is arranged at the rear side of the screw rod (303), the outer rings of the screw rod (303) and the sliding rail (304) are connected with the bottom plate (305), the upper surface of the bottom plate (305) is fixed with the fixed seat (306), the upper end of the fixed seat (306) is rotationally connected with the rotating rod (308), the rear end of the rotating rod (308) is connected with the servo motor (307), the upper side of the rotating rod (308) is fixed with the rotating seat (309), the upper end of the rotating seat (309) is connected with the solar panel (310), the lower end of one side of the detection box (101) is provided with the fan (311), the filter screens (312) are arranged on two sides of the fan (311).

3. The building energy saving effect detection device according to claim 2, characterized in that: the screw rod (303) with driving motor (302) passes through the coupling joint, bottom plate (305) with screw rod (303) passes through threaded connection, slide rail (304) with bottom plate (305) sliding connection, fan (311) with display screen (104) electric connection.

4. The building energy saving effect detection device according to claim 2, characterized in that: the rotating rod (308) is connected with the servo motor (307) through a coupler, and the fan (311) is electrically connected with the solar panel (310).

5. The building energy saving effect detection device according to claim 1, characterized in that: clamping machine constructs (2) including unable adjustment base (201), connecting rod (202), spring (203) and clamping seat (204), detection case (101) inner wall both sides are fixed with unable adjustment base (201), unable adjustment base (201) upper end is provided with connecting rod (202), connecting rod (202) outer lane cover has spring (203), connecting rod (202) upside is connected with clamping seat (204).

6. The building energy saving effect detection device according to claim 5, characterized in that: the clamping seat (204) is connected with the connecting rod (202) in a sliding mode, and a groove is formed in the upper surface of the clamping seat (204).

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