CN214895565U

CN214895565U - Wisdom garden building developments energy consumption monitoring system

Info

Publication number: CN214895565U
Application number: CN202120653487.9U
Authority: CN
Inventors: 周遊
Original assignee: Fujian Zhoudao Decoration Design Engineering Co ltd
Current assignee: Fujian Zhoudao Decoration Design Engineering Co ltd
Priority date: 2021-03-31
Filing date: 2021-03-31
Publication date: 2021-11-26
Anticipated expiration: 2031-03-31

Abstract

The utility model discloses a wisdom garden building developments energy consumption monitoring system, including monitoring server, monitoring power and a plurality of monitor terminal, monitoring terminal includes monitor and communicator, the monitor passes through communicator and monitoring server wireless communication connection, the monitoring power includes solar cell panel, rechargeable battery and a plurality of switch module, solar cell panel and rechargeable battery electric connection, switch module includes a plurality of axis body switches and trigger unit, rechargeable battery passes through axis body switch and monitor or communicator electric connection, trigger unit is used for opening or closes the axis body switch. The utility model discloses a wisdom garden building developments energy consumption monitoring system can select the time of gathering energy consumption instrument data through the mode of controlling the axis body switch, under the prerequisite that satisfies the actual demand, can reduce energy consumption to the generated energy that makes solar cell panel can supply the monitoring key as much as possible, realizes energy saving and emission reduction's effect, more green.

Description

Wisdom garden building developments energy consumption monitoring system

Technical Field

The utility model relates to a wisdom garden technical field, specific wisdom garden building developments energy consumption monitoring system that says so.

Background

With the rapid development and deep application of new technologies such as global internet of things, big data, cloud computing and artificial intelligence, more and more enterprises are gradually emerging, in order to meet the requirements of industrial production and scientific experiments, the smart park is also expanded in a large scale, and the consumed energy is gradually increased. Therefore, how to reduce the consumption of unnecessary energy and improve the utilization rate of energy is an urgent problem to be solved. For this reason, dynamic monitoring of building energy consumption is needed, but most of the monitoring systems in the prior art adopt a continuous monitoring mode, and rather, a lot of unnecessary energy consumption is generated.

SUMMERY OF THE UTILITY MODEL

In order to solve the deficiencies in the prior art, the utility model aims to provide a wisdom garden building developments energy consumption monitoring system can select the time of gathering energy consumption instrument data through the mode of control axis body switch, under the prerequisite that satisfies the actual demand, can reduce energy consumption to the generated energy that makes solar cell panel can supply the monitoring key as much as possible, realizes energy saving and emission reduction's effect, more green.

In order to achieve the above object, the utility model discloses a concrete scheme does:

the utility model provides a wisdom garden building developments energy consumption monitoring system, includes monitoring server, monitoring power and a plurality of monitor terminal, monitoring terminal includes monitor and communicator, the monitor passes through the communicator with monitoring server wireless communication connects, the monitoring power includes solar cell panel, rechargeable battery and a plurality of switch module, solar cell panel with rechargeable battery electric connection, switch module includes a plurality of axis body switches and trigger unit, rechargeable battery passes through the axis body switch with the monitor perhaps communicator electric connection, trigger unit is used for opening or closing the axis body switch.

Preferably, the monitoring power supply comprises a bottom plate, a back plate is vertically and fixedly arranged on the bottom plate, the rechargeable battery is fixedly arranged on the bottom plate, the solar panel is obliquely arranged on the back plate, and the switch assembly is fixedly arranged on the back plate.

Preferably, the switch assembly includes two parallel side plates, one of the side plates is fixedly connected to the back plate, a plurality of parallel partition plates are fixedly connected between the two side plates, the plurality of partition plates partition a plurality of cavities, and the shaft switches are correspondingly disposed in the cavities.

Preferably, the shaft switch includes a lifting lever and a plurality of connection contacts for connecting the rechargeable battery, the monitor, or the communicator.

Preferably, the switch module includes two mounting panels that are parallel to each other, two the equal fixed connection of mounting panel is two between the curb plate, two rotate between the mounting panel and be connected with the pivot, one of them is passed to the one end of pivot be connected with driving motor behind the mounting panel, fixed cover is equipped with a plurality of first trigger pieces and a plurality of second trigger piece in the pivot, first trigger piece is used for triggering periodically the axis body switch, the second trigger piece is used for lasting the trigger the axis body switch.

Preferably, the first trigger piece is disc-shaped, the first trigger piece is coaxially sleeved on the rotating shaft, and a plurality of concave parts are formed in the peripheral side wall of the first trigger piece.

Preferably, the second trigger piece is disc-shaped, and the second trigger piece is coaxially sleeved on the rotating shaft.

The utility model discloses can select the time of gathering energy consumption instrument data through the mode of control axis body switch, under the prerequisite that satisfies the actual demand, can reduce energy consumption to the generated energy that makes solar cell panel can supply the monitoring key as much as possible, realizes energy saving and emission reduction's effect, green more.

Drawings

In order to more clearly illustrate the technical solutions in the present embodiment or the prior art, the drawings needed to be used in the description of the embodiment or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a block diagram of the overall structure of the present invention;

FIG. 2 is a schematic diagram of the overall structure of the monitoring power supply;

fig. 3 is a schematic structural view of a switch assembly.

Reference numerals: the solar cell panel comprises a solar cell panel 1, a rechargeable battery 2, a back panel 3, a bottom panel 4, a switch assembly 5, a mounting panel 6, a rotating shaft 7, a partition plate 8, a side panel 9, a shaft body switch 10, a connecting contact 11, a cavity 12, a lifting rod 13, a first trigger 14, a depression 15, a second trigger 16 and a driving motor 17.

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 to 3, fig. 1 is a block diagram of an overall structure of the present invention, fig. 2 is a schematic diagram of an overall structure of a monitoring power supply, and fig. 3 is a schematic diagram of a switch assembly.

The utility model provides a wisdom garden building developments energy consumption monitoring system, including monitoring server, monitoring power and a plurality of monitor terminal, monitoring terminal includes monitor and communicator, the monitor passes through communicator and monitoring server wireless communication connection, the monitoring power includes solar cell panel 1, rechargeable battery 2 and a plurality of switch module 5, solar cell panel 1 and rechargeable battery 2 electric connection, switch module 5 includes a plurality of axis body switches 10 and trigger unit, rechargeable battery 2 passes through axis body switch 10 and monitor or communicator electric connection, trigger unit is used for opening or closes axis body switch 10.

When the system is used, the monitoring terminal is fixedly arranged at the building energy consumption instrument, and only the communicator can be arranged on the Internet of things instrument with the capability of automatically acquiring data, and then the system can be started. After the system is started, the trigger unit controls the shaft body switch 10 to be turned on or turned off, when the shaft body switch 10 is turned on, a collector or a communicator which is electrically connected with the shaft body switch 10 is started, when the collector is started, data of the collector or the energy consumption instrument are sent to the monitoring server through the corresponding communicator, and when the communicator is started, the communicator completes sending of the data. The monitoring server can record the building dynamic energy consumption condition of the intelligent park according to the received energy consumption instrument data.

The utility model discloses can select the time of gathering energy consumption instrument data through the mode of control axis body switch 10, under the prerequisite that satisfies the actual demand, can reduce energy consumption to make solar cell panel 1's generated energy can supply the monitoring key as much as possible, realize energy saving and emission reduction's effect, more green.

The specific structure of monitoring power does: the monitoring power supply comprises a bottom plate 4, a back plate 3 is vertically and fixedly arranged on the bottom plate 4, a rechargeable battery 2 is fixedly arranged on the bottom plate 4, a solar cell panel 1 is obliquely arranged on the back plate 3, and a switch component 5 is fixedly arranged on the back plate 3. According to the actual mounted position of monitoring power, can adjust solar cell panel 1's inclination in a flexible way to promote solar cell panel 1's generated energy, and then can be for more monitor terminal power supplies simultaneously.

The specific structure of the switch assembly 5 is as follows: the switch component 5 comprises two side plates 9 which are parallel to each other, wherein one side plate 9 is fixedly connected with the back plate 3, a plurality of partition plates 8 which are parallel to each other are fixedly connected between the two side plates 9, a plurality of cavities 12 are separated from the plurality of partition plates 8, and the shaft body switch 10 is correspondingly arranged in the cavities 12.

The specific structure of the shaft switch 10 includes: the shaft switch 10 includes a lifting lever 13 and a plurality of connection contacts 11, and the connection contacts 11 are used for connecting the rechargeable battery 2, the monitor, or the communicator. The connection contacts 11 protrude from the cavity 12 to facilitate connection, and in this embodiment, the spindle switch 10 may be a cherrymx series spindle switch.

The specific structure of the trigger unit is as follows: switch module 5 includes two mounting panels 6 that are parallel to each other, the equal fixed connection of two mounting panels 6 is between two curb plates 9, it is connected with pivot 7 to rotate between two mounting panels 6, be connected with driving motor 17 after one of them mounting panel 6 is passed to the one end of pivot 7, fixed cover is equipped with a plurality of first trigger 14 and a plurality of second trigger 16 in the pivot 7, first trigger 14 is used for periodically triggering axis body switch 10, second trigger 16 is used for lasting trigger axis body switch 10. According to the specific arrangement mode of the shaft switch 10, the first trigger 14 and the shaft switch 10 or the second trigger 16 and the shaft switch 10 can be flexibly selected.

The specific structure of the first trigger 14 is: the first trigger 14 is disc-shaped, the first trigger 14 is coaxially sleeved on the rotating shaft 7, and a plurality of concave parts 15 are formed on the peripheral side wall of the first trigger 14. When the first trigger 14 rotates along with the rotating shaft 7, the lifting rod 13 contacts the recessed portion 15 or the peripheral side wall of the first trigger 14, when the lifting rod 13 contacts the peripheral side wall of the first trigger 14, the lifting rod 13 is pushed, the shaft body switch 10 is triggered, and when the lifting rod 13 contacts the recessed portion 15, the lifting rod 13 is in a home position, and the shaft body switch 10 is in a closed state. The number of the recesses 15 can be flexibly selected according to the trigger frequency of the shaft switch 10.

The specific structure of the second trigger 16 is: the second trigger piece 16 is disc-shaped, and the second trigger piece 16 is coaxially sleeved on the rotating shaft 7. Since the second trigger 16 is disc-shaped, the peripheral sidewall of the second trigger 16 is always in contact with the lifting rod 13, so that the shaft switch 10 is always in an on state.

In a specific embodiment of the utility model, a monitoring system for the dynamic energy consumption of smart park buildings comprises a monitoring server, a monitoring power supply and a plurality of monitoring terminals, wherein each monitoring terminal comprises a monitor and a communicator, the monitors are in wireless communication connection with the monitoring server through the communicators, the monitoring power supply comprises a solar cell panel 1, a rechargeable battery 2 and a plurality of switch components 5, the solar cell panel 1 is electrically connected with the rechargeable battery 2, each switch component 5 comprises a plurality of shaft switches 10 and a trigger unit, the rechargeable battery 2 is electrically connected with the monitors or the communicators through the shaft switches 10, the trigger unit is used for opening or closing the shaft switches 10, the monitoring power supply comprises a bottom plate 4, a back plate 3 is vertically and fixedly arranged on the bottom plate 4, the rechargeable battery 2 is fixedly arranged on the bottom plate 4, the solar cell panel 1 is obliquely arranged on the back plate 3, the switch components 5 are fixedly arranged on the back plate 3, the switch assembly 5 comprises two parallel side plates 9, wherein one side plate 9 is fixedly connected with the back plate 3, a plurality of parallel partition plates 8 are fixedly connected between the two side plates 9, a plurality of cavities 12 are separated by the plurality of partition plates 8, the shaft body switch 10 is correspondingly arranged in the cavities 12, the shaft body switch 10 comprises a lifting rod 13 and a plurality of connecting contacts 11, the connecting contacts 11 are used for connecting the rechargeable battery 2, a monitor or a communicator, the switch assembly 5 comprises two parallel mounting plates 6, the two mounting plates 6 are both fixedly connected between the two side plates 9, a rotating shaft 7 is rotatably connected between the two mounting plates 6, one end of the rotating shaft 7 passes through one of the mounting plates 6 and is connected with a driving motor 17, a plurality of first trigger parts 14 and a plurality of second trigger parts 16 are fixedly sleeved on the rotating shaft 7, the first trigger parts 14 are used for periodically triggering the shaft body switch 10, first trigger 14 is discoid, and first trigger 14 coaxial cover is established in pivot 7, has seted up a plurality of depressed part 15 on the week lateral wall of first trigger 14, and second trigger 16 is used for lasting trigger axis body switch 10, and second trigger 16 is discoid, and second trigger 16 coaxial cover is established in pivot 7.

When the system is used, the monitoring terminal is fixedly arranged at the building energy consumption instrument, and only the communicator can be arranged on the Internet of things instrument with the capability of automatically acquiring data, and then the system can be started. After the system is started, the trigger unit controls the shaft body switch 10 to be turned on or turned off, when the shaft body switch 10 is turned on, a collector or a communicator which is electrically connected with the shaft body switch 10 is started, when the collector is started, data of the collector or the energy consumption instrument are sent to the monitoring server through the corresponding communicator, and when the communicator is started, the communicator completes sending of the data. The monitoring server can record the building dynamic energy consumption condition of the intelligent park according to the received energy consumption instrument data. When the first trigger 14 rotates along with the rotating shaft 7, the lifting rod 13 contacts the recessed portion 15 or the peripheral side wall of the first trigger 14, when the lifting rod 13 contacts the peripheral side wall of the first trigger 14, the lifting rod 13 is pushed, the shaft body switch 10 is triggered, and when the lifting rod 13 contacts the recessed portion 15, the lifting rod 13 is in a home position, and the shaft body switch 10 is in a closed state. The number of the recesses 15 can be flexibly selected according to the trigger frequency of the shaft switch 10. Since the second trigger 16 is disc-shaped, the peripheral sidewall of the second trigger 16 is always in contact with the lifting rod 13, so that the shaft switch 10 is always in an on state.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. The utility model provides a wisdom garden building developments energy consumption monitoring system which characterized in that: including monitoring server, monitoring power and a plurality of monitoring terminal, monitoring terminal includes monitor and communicator, the monitor passes through the communicator with monitoring server wireless communication connects, the monitoring power includes solar cell panel (1), rechargeable battery (2) and a plurality of switch module (5), solar cell panel (1) with rechargeable battery (2) electric connection, switch module (5) include a plurality of axis body switches (10) and trigger unit, rechargeable battery (2) pass through axis body switch (10) with the monitor perhaps communicator electric connection, trigger unit is used for opening or closing axis body switch (10).

2. The intelligent campus building dynamic energy consumption monitoring system of claim 1 wherein: the monitoring power supply comprises a bottom plate (4), a back plate (3) is vertically and fixedly arranged on the bottom plate (4), the rechargeable battery (2) is fixedly arranged on the bottom plate (4), the solar cell panel (1) is obliquely arranged on the back plate (3), and the switch assembly (5) is fixedly arranged on the back plate (3).

3. The intelligent campus building dynamic energy consumption monitoring system of claim 2 wherein: the switch assembly (5) comprises two side plates (9) which are parallel to each other, one side plate (9) is fixedly connected with the back plate (3), a plurality of partition plates (8) which are parallel to each other are fixedly connected between the two side plates (9), a plurality of cavities (12) are separated from the plurality of partition plates (8), and the shaft body switch (10) is correspondingly arranged in the cavities (12).

4. The intelligent campus building dynamic energy consumption monitoring system of claim 3 wherein: the shaft body switch (10) comprises a lifting rod (13) and a plurality of connecting contacts (11), and the connecting contacts (11) are used for connecting the rechargeable battery (2), the monitor or the communicator.

5. The intelligent campus building dynamic energy consumption monitoring system of claim 4 wherein: switch module (5) include two mounting panel (6) that are parallel to each other, two equal fixed connection of mounting panel (6) is two between curb plate (9), two rotate between mounting panel (6) and be connected with pivot (7), one of them is passed to the one end of pivot (7) be connected with driving motor (17) behind mounting panel (6), fixed cover is equipped with a plurality of first trigger parts (14) and a plurality of second trigger parts (16) on pivot (7), first trigger part (14) are used for triggering periodically axis body switch (10), second trigger part (16) are used for lasting the triggering axis body switch (10).

6. The intelligent campus building dynamic energy consumption monitoring system of claim 5 wherein: the first trigger piece (14) is disc-shaped, the first trigger piece (14) is coaxially sleeved on the rotating shaft (7), and a plurality of concave parts (15) are formed in the peripheral side wall of the first trigger piece (14).

7. The intelligent campus building dynamic energy consumption monitoring system of claim 5 wherein: the second trigger piece (16) is disc-shaped, and the second trigger piece (16) is coaxially sleeved on the rotating shaft (7).