CN213633251U - Thermotechnical temperature heat flow detector for building energy-saving detection - Google Patents

Abstract

The utility model discloses a thermal technology's temperature and heat flow detector that building energy-conservation detected, including instrument rack, heat dissipation mechanism, rotary mechanism and positioning mechanism, the fixed orifices has been seted up to instrument rack inner wall, and the fixed orifices inboard is connected with the dead lever, heat dissipation mechanism connects in instrument rack inboard, rotary mechanism installs on instrument rack outside top, the draw-in groove has been seted up to instrument rack inner wall, positioning mechanism installs in the inboard bottom of instrument rack, the rubber sleeve is installed in the laminating of instrument rack outer wall. This thermotechnical temperature heat flow detector that building energy conservation detected through the positioning mechanism who sets up, and the equipment of being convenient for like this can be more stable carry out the heat flow and gather, and equipment can charge and data transmission through the interface simultaneously, and traditional detector of relative ratio, this design is more convenient, and also more environmental protection and energy saving simultaneously, the simple easy operation of design more accords with people's modernization demand.

Description

Thermotechnical temperature heat flow detector for building energy-saving detection

Technical Field

The utility model relates to a building energy conservation detects relevant technical field, specifically is a thermal technology's temperature heat flow detector that building energy conservation detected.

Background

The building energy-saving detection is characterized by that it uses standard method, proper instrument and equipment and environmental condition, and uses the raw material, equipment, facilities and building, etc. in the energy-saving building to make thermal performance and its related technical operation, and it is an important means for ensuring the construction quality of energy-saving building.

However, the prior thermotechnical temperature heat flow detector for building energy-saving detection has the disadvantages of poor equipment heat dissipation performance and single structure, and the traditional equipment adopts a battery as an energy source, so that the environment is not protected and the energy is saved.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a thermal technology's temperature of building energy-conservation detects thermal technology heat flow detector to solve the thermal technology temperature of building energy-conservation that the present use proposed in the above-mentioned background art detects heat flow detector, equipment heat dispersion is relatively poor, and the structure is comparatively single, and traditional equipment adopts the battery environmental protection and energy saving inadequately as the energy, and simultaneous display device can't adjust the problem that the staff of being convenient for detected.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a thermal technology's temperature and heat flow detector that building energy-conservation detected, includes meter rack, heat dissipation mechanism, rotary mechanism and positioning mechanism, the fixed orifices has been seted up to meter rack inner wall, and the fixed orifices inboard is connected with the dead lever, and the test pen is installed in the dead lever outside simultaneously, heat dissipation mechanism connects in meter rack inboard, rotary mechanism installs on meter rack outside top, the draw-in groove has been seted up to meter rack inner wall, and the draw-in groove inboard is connected with the fixture block, and the fixture block outside is installed and is controlled the board simultaneously, positioning mechanism installs in the inboard bottom of meter rack, the rubber sleeve is installed in.

Preferably, the instrument rack is in threaded connection with the test pen through the fixing rod, and the inner side of the fixing hole and the outer side of the fixing rod are both in threaded arrangement.

Preferably, the instrument rack is connected with the control board in a clamping mode through a clamping block, and the inner side of the clamping groove is in a concave structure.

Preferably, the instrument rack inner wall is tightly attached to the outer wall of the rubber sleeve, and the length of the outer wall of the rubber sleeve is the same as that of the inner wall of the instrument rack.

Preferably, the heat dissipation mechanism comprises a data acquisition board, a heat dissipation fan and an infrared sensor, wherein the heat dissipation fan is installed on the inner side of the data acquisition board, and the infrared sensor is connected to the outer side of the heat dissipation fan.

Preferably, rotary mechanism includes pivot, display instrument and sealing washer, the pivot outer wall is connected with the display instrument, and the sealing washer is installed in the laminating of the display instrument outside.

Preferably, the positioning mechanism comprises a positioning hole, a positioning rod, a heat flow plate and an interface, the positioning rod is connected to the inner side of the positioning hole, the heat flow plate is installed on the outer side of the positioning rod, and the interface is installed on the inner side of the heat flow plate.

Compared with the prior art, the beneficial effects of the utility model are that:

1. according to the thermotechnical temperature heat flow detector for building energy-saving detection, the arranged heat dissipation mechanism is adopted, so that the infrared sensor can dissipate heat and exhaust air through the heat dissipation fan when in working operation, the problems of equipment failure and the like caused by damage of an equipment overheating circuit due to long-time operation of the equipment are avoided, and the function of protecting circuit equipment can be effectively played when the equipment is in operation;

2. according to the thermotechnical temperature heat flow detector for building energy-saving detection, the rotating mechanism is arranged, so that the angle of the display instrument can be adjusted through the rotating shaft in the working operation process, a worker can find a convenient and comfortable angle for detection more conveniently, the display instrument can be closed through the rotating shaft when the equipment does not need to operate, meanwhile, the display instrument is more convenient to replace when a fault problem occurs in the later stage, and the cost is also saved;

3. this thermotechnical temperature heat flow detector that building energy conservation detected through the positioning mechanism who sets up, and the equipment of being convenient for like this can be more stable carry out the heat flow and gather, and equipment can charge and data transmission through the interface simultaneously, and traditional detector of relative ratio, this design is more convenient, and also more environmental protection and energy saving simultaneously, the simple easy operation of design more accords with people's modernization demand.

Drawings

Fig. 1 is a schematic view of the front cross-sectional structure of the present invention;

fig. 2 is a schematic structural view of the rotating mechanism of the present invention;

FIG. 3 is a schematic diagram of the structure of the manipulating board of the present invention;

fig. 4 is a schematic structural diagram of the positioning mechanism of the present invention.

In the figure: 1. an instrument rack; 2. a fixing hole; 3. fixing the rod; 4. a test pen; 5. a heat dissipation mechanism; 501. A data acquisition board; 502. a heat dissipation fan; 503. an infrared sensor; 6. a rotation mechanism; 601. a rotating shaft; 602. a display instrument; 603. a seal ring; 7. a card slot; 8. a clamping block; 9. controlling a version; 10. a positioning mechanism; 1001. positioning holes; 1002. positioning a rod; 1003. a heat flow plate; 1004. an interface; 11. a rubber sleeve.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: the utility model provides a thermal technology's temperature and heat flow detector that building energy-conservation detected, including instrument rack 1, heat dissipation mechanism 5, rotary mechanism 6 and positioning mechanism 10, fixed orifices 2 have been seted up to 1 inner wall of instrument rack, and 2 inboard fixed links 3 that are connected with of fixed orifices, test pen 4 is installed in 3 outsides of fixed link simultaneously, heat dissipation mechanism 5 is connected in 1 inboards of instrument rack, rotary mechanism 6 installs on 1 outside top of instrument rack, draw-in groove 7 has been seted up to 1 inner wall of instrument rack, and the draw-in groove 7 inboard is connected with fixture block 8, control board 9 is installed in 8 outsides of fixture block simultaneously, positioning mechanism 10 installs in 1 inboard bottom of instrument rack, rubber sleeve.

Further, meter rack 1 is through dead lever 3 and 4 threaded connection of test pen, and 2 inboards of fixed orifices are the screw thread form setting with the 3 outsides of dead lever, through dead lever 3 and the test pen 4 that sets up, and the test pen 4 of being convenient for like this carries out the installation of temperature through dead lever 3, and the test pen 4 can be more direct and the accurate heat that carries on detect simultaneously.

Further, instrument rack 1 passes through fixture block 8 and is connected with the block of controlling board 9, and draw-in groove 7 inboard is "concave" shape structure setting, through the control board 9 and the fixture block 8 that set up, is convenient for like this control board 9 through the installation of the more temperature of fixture block 8 for equipment operation is controlled and is had a good operational environment.

Further, 1 inner wall of instrument rack closely laminates with 11 outer walls of rubber sleeve, and 11 outer wall lengths of rubber sleeve are the same with 1 inner wall length of instrument rack, through the rubber sleeve 11 that sets up, and the operation of the protective apparatus body safety and stability of being convenient for like this can effectually prevent the problem of the impaired trouble of equipment that leads to that the external world collides with, great improvement the life of equipment.

Further, heat dissipation mechanism 5 includes data acquisition board 501, heat dissipation fan 502 and infrared sensor 503, and heat dissipation fan 502 is installed to data acquisition board 501 inboard, and the heat dissipation fan 502 outside is connected with infrared sensor 503, through the heat dissipation mechanism 5 that sets up, and the infrared sensor 503 of being convenient for like this can dispel the heat the exhaust through heat dissipation fan 502 when the work operation.

Further, rotary mechanism 6 includes pivot 601, display 602 and sealing washer 603, and pivot 601 outer wall connection has display 602, and the laminating of the display 602 outside installs sealing washer 603, crosses the rotary mechanism 6 that sets up, and the display 602 of being convenient for like this can carry out angle modulation through pivot 601 in the work operation, and the staff of being convenient for more finds a convenient and comfortable angle and detects.

Further, positioning mechanism 10 includes locating hole 1001, locating lever 1002, hot flow board 1003 and interface 1004, and locating hole 1001 inboard is connected with locating lever 1002, and hot flow board 1003 is installed to the locating lever 1002 outside, and interface 1004 is installed to hot flow board 1003 inboard simultaneously, and through the positioning mechanism 10 that sets up, the equipment of being convenient for like this can be more stable carry out the hot flow and gather, and equipment can be through interface 1004 charging and data transmission simultaneously.

The working principle is as follows: for a thermotechnical temperature heat flow detector for building energy-saving detection, firstly, an equipment switch is turned on, then a fixing hole 2 formed in an instrument frame 1 is aligned with a fixing hole 2 formed in a test pen 4, then a fixing rod 3 is inserted into the fixing hole 2 for screwing installation, secondly, a shaft hole formed in the instrument frame 1 is aligned with a shaft hole formed in a display 602, secondly, a rotating shaft 601 is inserted into the shaft hole for rotating and screwing installation, thirdly, a positioning hole 1001 formed in the instrument frame 1 is aligned with a positioning hole 1001 formed in a heat flow plate 1003, thirdly, a positioning rod 1002 is inserted into the positioning hole 1001 for screwing installation, and through a positioning mechanism 10, the equipment can more stably collect heat flow, meanwhile, the equipment can charge and transmit data through an interface 1004, compared with the traditional detector, the design is more convenient and faster, the design is more environment-friendly and energy-saving, finally, the infrared sensor 503 is attached to the data acquisition board 501 connected with the heat dissipation fan 502, the equipment switch is turned off, the installation process of the thermal engineering temperature heat flow detector for building energy-saving detection is completed, the model of the infrared sensor 503 is VC303B, and the model of the display instrument 602 is P5Z.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a thermotechnical temperature heat flow detector that building energy-conservation detected, includes meter rack (1), heat dissipation mechanism (5), rotary mechanism (6) and positioning mechanism (10), its characterized in that: fixed orifices (2) have been seted up to instrument rack (1) inner wall, and fixed orifices (2) inboard is connected with dead lever (3), and test pen (4) are installed in dead lever (3) outside simultaneously, heat dissipation mechanism (5) are connected in instrument rack (1) inboard, rotary mechanism (6) are installed on instrument rack (1) outside top, draw-in groove (7) have been seted up to instrument rack (1) inner wall, and draw-in groove (7) inboard is connected with fixture block (8), and control board (9) are installed in fixture block (8) outside simultaneously, positioning mechanism (10) are installed in instrument rack (1) inboard bottom, rubber sleeve (11) are installed in instrument rack (1) outer wall laminating.

2. The thermal engineering temperature heat flow detector for building energy conservation detection as claimed in claim 1, wherein: the instrument rack (1) is in threaded connection with the test pen (4) through the fixing rod (3), and the inner side of the fixing hole (2) and the outer side of the fixing rod (3) are in threaded arrangement.

3. The thermal engineering temperature heat flow detector for building energy conservation detection as claimed in claim 1, wherein: the instrument rack (1) is connected with the control board (9) in a clamping mode through the clamping block (8), and the inner side of the clamping groove (7) is of a concave structure.

4. The thermal engineering temperature heat flow detector for building energy conservation detection as claimed in claim 1, wherein: the instrument rack is characterized in that the inner wall of the instrument rack (1) is tightly attached to the outer wall of the rubber sleeve (11), and the length of the outer wall of the rubber sleeve (11) is the same as that of the inner wall of the instrument rack (1).

5. The thermal engineering temperature heat flow detector for building energy conservation detection as claimed in claim 1, wherein: the heat dissipation mechanism (5) comprises a data acquisition board (501), a heat dissipation fan (502) and an infrared sensor (503), wherein the heat dissipation fan (502) is installed on the inner side of the data acquisition board (501), and the infrared sensor (503) is connected to the outer side of the heat dissipation fan (502).

6. The thermal engineering temperature heat flow detector for building energy conservation detection as claimed in claim 1, wherein: the rotating mechanism (6) comprises a rotating shaft (601), a display instrument (602) and a sealing ring (603), the outer wall of the rotating shaft (601) is connected with the display instrument (602), and the sealing ring (603) is installed on the outer side of the display instrument (602) in an attaching mode.

7. The thermal engineering temperature heat flow detector for building energy conservation detection as claimed in claim 1, wherein: the positioning mechanism (10) comprises a positioning hole (1001), a positioning rod (1002), a heat flow plate (1003) and an interface (1004), wherein the positioning rod (1002) is connected to the inner side of the positioning hole (1001), the heat flow plate (1003) is installed on the outer side of the positioning rod (1002), and the interface (1004) is installed on the inner side of the heat flow plate (1003).

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