CN219416274U - Building energy-saving data acquisition device - Google Patents

Abstract

The utility model discloses a building energy-saving data acquisition device, which belongs to the technical field of building data acquisition, and comprises a roof beam plate and a data acquisition mechanism arranged under the roof beam plate. An edge inner groove is formed on one side of the bottom wall of the roof beam plate. A first servo motor is fixedly installed on the inner wall of the edge inner groove. The first servo motor is arranged horizontally. A central inner groove is opened at the center of the bottom wall of the roof beam plate. , the data acquisition mechanism includes a temperature and humidity sensor installed at the bottom of the sliding seat. The building energy-saving data acquisition device drives the temperature and humidity sensor to move within a large indoor range of the building by driving the first servo motor, and can detect the temperature and humidity at different positions in the building, making the detection result more accurate and reliable.

Description

A building energy saving data acquisition device

technical field

The utility model belongs to the technical field of building data acquisition, in particular to a building energy-saving data acquisition device.

Background technique

Building energy conservation refers to reducing energy consumption and energy demand as much as possible under the condition of meeting the same needs or achieving the same purpose in the process of building material production, building construction and structure construction and use. Therefore, it is necessary to detect and collect various indicators in the building. There are many indicators in the existing indoor environment of buildings that need to be detected and collected, such as temperature and humidity.

In the process of realizing the utility model, the inventors found that there are at least the following problems in this technology: most of the existing devices for detecting and collecting temperature and humidity indicators for building energy saving can only fix the corresponding sensors of temperature and humidity in one position, and cannot move them, resulting in inaccurate results of temperature and humidity detection.

For this reason, we propose a building energy-saving data acquisition device to solve the above problems.

Utility model content

The main purpose of the utility model is to provide a building energy-saving data acquisition device, which can detect the temperature and humidity of different positions in the building, so that the detection results are more accurate and reliable, and can effectively solve the problems in the background technology.

In order to achieve the above object, the utility model adopts the following technical solutions:

A building energy-saving data acquisition device, comprising a roof beam plate and a data acquisition mechanism arranged under the roof beam plate, one side of the bottom wall of the roof beam plate is formed with an edge inner groove, the inner wall of the edge inner groove is fixedly installed with a first servo motor, the first servo motor is installed horizontally, the center of the bottom wall of the roof beam plate is opened with a central inner groove, the output shaft of the first servo motor is coaxially connected to a screw, and the upper thread of the screw rod is sleeved with a slide seat, and the slide seat is attached to the inner wall of the center inner groove, and the data acquisition mechanism includes a Temperature and humidity sensor.

As a preferred embodiment, the screw rod is horizontally arranged in the central inner groove, and the screw rod is rotatably connected with the top beam plate; so that the first servo motor can drive the screw rod to run stably.

As a preferred embodiment, extension rods are symmetrically welded on both sides of the bottom wall of the sliding seat, and a storage board is connected under the two extension rods, and a second servo motor is fixedly installed on the top of the storage board; the second servo motor is vertically arranged, and the second servo motor and the first servo motor need power supply from an external power facility.

As a preferred embodiment, the opening of the inner cavity of the storage board is opened on the bottom wall thereof, the output shaft of the second servo motor is coaxially connected to an inner support shaft, and a turntable is coaxially connected to the bottom of the inner support shaft; so that the second servo motor can drive the inner support shaft and the turntable to rotate.

As a preferred embodiment, the bottom wall of the turntable is welded with a support plate, and a camera is installed on the side wall of the support plate; the camera can detect the picture status of abnormal temperature or humidity in the building room, and realize picture monitoring, so as to detect and deal with it in time when a fire or other emergency occurs.

As a preferred embodiment, a battery is installed on one side of the top wall of the storage board, and the battery is respectively coupled and connected to the second servo motor and the camera; thereby supplying power to the second servo motor and the camera.

In summary, technical effects and advantages of the present utility model:

The building energy-saving data acquisition device drives the first servo motor to move the temperature and humidity sensor within a large indoor range of the building, and can detect the temperature and humidity at different positions in the building room, making the detection results more accurate and reliable. Once the temperature or humidity reaches the index of discomfort, it transmits an electrical signal to the controller, and outside personnel can also check the index of temperature or humidity in real time, so as to facilitate timely adjustment of the temperature or humidity;

The building energy-saving data acquisition device drives the turntable to run by driving the second servo motor, cooperates with the operation of the camera to take pictures of the areas where the temperature and humidity data indicators are abnormal, and transmits the data to the monitoring room, so that the personnel in the monitoring room can know the corresponding situation in time, and can deal with it in time when an emergency such as a fire occurs.

Description of drawings

Fig. 1 is the structural representation of one side of the utility model;

Fig. 2 is the structural representation of the other side of the utility model;

Fig. 3 is a sectional view of the storage board of the present invention.

In the figure: 1. Top beam plate; 2. Edge inner groove; 3. First servo motor; 4. Center inner groove; 5. Screw; 6. Slide seat; 7. Temperature and humidity sensor; 8. Extension rod; 9. Storage board; 10. Second servo motor;

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below in conjunction with the accompanying drawings in the embodiments of the present invention. Apparently, the described embodiments are only some of the embodiments of the present invention, not all of them.

Referring to Figures 1-3, a building energy-saving data acquisition device includes a roof beam 1 and a data acquisition mechanism arranged below the roof beam 1;

One side of the bottom wall of the roof beam 1 is formed with an edge inner groove 2, and the inner wall of the edge inner groove 2 is fixedly installed with a first servo motor 3. The first servo motor 3 is arranged horizontally. A center inner groove 4 is provided at the center of the bottom wall of the roof beam 1. The output shaft of the first servo motor 3 passes through the roof beam 1 and is coaxially connected with a screw 5. The threaded sleeve is provided with a sliding seat 6, and the sliding seat 6 is attached to the inner wall of the central inner groove 4, so that the screw rod 5 can drive the sliding seat 6 to translate in the central inner groove 4 when the screw rod 5 is running. The temperature and humidity data are transmitted to the outside world, and can be viewed in real time by personnel through display devices to achieve real-time data collection;

Both sides of the bottom wall of the sliding seat 6 are symmetrically welded with extension rods 8, and are connected with a storage board 9 below the two extension rods 8. A second servo motor 10 is fixedly installed on the top of the storage board 9. The second servo motor 10 is vertically arranged, and the second servo motor 10 and the first servo motor 3 need external power supply. , and a turntable 12 is coaxially connected to the bottom of the inner support shaft 11, so that the second servo motor 10 can drive the inner support shaft 11 and the turntable 12 to run. The bottom wall of the turntable 12 is welded with a support plate 13, and a camera 14 is installed on the side wall of the support plate 13. The camera 14 can detect the picture situation of abnormal temperature or humidity in the building room, and realize picture monitoring. It is respectively coupled and connected with the second servo motor 10 and the camera 14 so as to supply power to the second servo motor 10 and the camera 14 .

Working principle: both ends of the roof beam 1 are provided with protruding ear plates, and the ear plates are provided with openings. The openings can be threaded holes or other holes. By using bolts and other parts to pass through the openings at both ends of the roof beam 1 and penetrate into the ceiling and other building rooms, the roof beam 1 and the structure on it can be fixed; when used, the temperature and humidity sensor 7 detects the temperature and humidity in the building room in real time. For example, the temperature and humidity in the computer room and other rooms can be detected. The sensor 7 will transmit an electrical signal to the controller coupled with it, and then the controller will transmit the electrical signal to the display device, so that the relevant operation and maintenance personnel can view the data in real time and make changes in time; at the same time, the personnel in the monitoring room can run the camera 14 to check the abnormal position of temperature and humidity. When using the temperature and humidity sensor 7, the first servo motor 3 can be driven regularly to drive the screw rod 5 to run, so that the sliding seat 6 drives the temperature and humidity sensor 7 to translate within a certain range, thereby expanding the detection range and making the detection result more reliable.

The above is only a preferred specific embodiment of the utility model, but the scope of protection of the utility model is not limited thereto. Any person familiar with the technical field within the technical scope disclosed in the utility model, according to the technical scheme of the utility model and its utility model design to make equivalent replacements or changes, should be covered within the scope of protection of the utility model.

Claims (6)

1. A building energy-saving data acquisition device, comprising a roof beam (1) and a data acquisition mechanism arranged below the roof beam (1), characterized in that an edge inner groove (2) is formed on one side of the bottom wall of the roof beam (1), the inner wall of the edge inner groove (2) is fixedly installed with a first servo motor (3), the center of the bottom wall of the roof beam (1) is provided with a center inner groove (4), and the output shaft of the first servo motor (3) is coaxially connected with a screw (5), and the screw (5) ) The upper threaded sleeve is provided with a lower seat (6), and the lower seat (6) is attached to the inner wall of the center inner groove (4), and the data acquisition mechanism includes a temperature and humidity sensor (7) installed at the bottom of the lower seat (6). 2. A building energy-saving data acquisition device according to claim 1, characterized in that the screw (5) is horizontally arranged in the central inner groove (4), and the screw (5) is rotatably connected to the roof beam (1). 3. A kind of building energy-saving data acquisition device according to claim 1, characterized in that, extension rods (8) are welded symmetrically on both sides of the bottom wall of the sliding seat (6), and a storage board (9) is connected below the two extension rods (8), and a second servo motor (10) is fixedly installed on the top of the storage board (9). 4. A building energy-saving data acquisition device according to claim 3, characterized in that, the opening of the inner cavity of the storage board (9) is opened on the bottom wall thereof, the output shaft of the second servo motor (10) is coaxially connected with an inner support shaft (11), and the lower part of the inner support shaft (11) is coaxially connected with a turntable (12). 5. A building energy-saving data acquisition device according to claim 4, characterized in that a support plate (13) is welded to the bottom wall of the turntable (12), and a camera (14) is installed on a side wall of the support plate (13). 6. A kind of building energy-saving data acquisition device according to claim 5, characterized in that, a battery (15) is installed on one side of the top wall of the storage board (9), and the battery (15) is coupled with the second servo motor (10) and the camera (14) respectively.