CN212137063U - Energy-saving management system for building equipment - Google Patents

Abstract

The utility model discloses a building equipment energy-saving management system, which comprises a box body, wherein a box door is fixedly arranged on the side wall of the box body, a handle which is convenient for a user to open and close the box door is fixedly arranged on the box door, the side wall of the box body is provided with a cooling and dehumidifying mechanism which is used for cooling the interior of the box body to prevent the interior of the box body from being damaged by heating and simultaneously removing moisture in the box body to keep the interior of the box body dry, the utility model is provided with a cooling and dehumidifying mechanism which utilizes the humid air in the box body to ensure that the moisture in the humid air is overflowed under the vacuum state so as to obtain air with low temperature and utilizes low-temperature air to cool the interior of the box body, thereby preventing the interior of the box body from being damaged by the equipment in the box body which is damaged by high temperature and influences normal transmission work, and simultaneously dehumidif, the circuit of the equipment is corroded, so that the equipment in the box is damaged, and the service life of the equipment in the box is prolonged.

Description

Energy-saving management system for building equipment

Technical Field

The utility model relates to a building energy conservation management system technical field specifically is a building equipment energy conservation management system.

Background

Along with the development of economy in China, the problem of high energy consumption of office buildings and large public buildings in state organs is increasingly prominent, the construction area of China is completed every year and is about 20 hundred million mu, wherein the public buildings are about 4 hundred million mu, the proportion of the large public building area with more than 2 ten thousand mu to the building area of cities and towns is less than 4%, but the energy consumption accounts for more than 20% of the construction energy consumption, only 4% of the existing about 430 million mu buildings in China adopt energy efficiency measures, and the heating energy consumption of the unit building area is more than 3 times of that of newly built buildings in developed countries, so that the energy-saving management work of the large public buildings is made, and the energy-saving management method has important significance.

In the energy-saving management system of building equipment, the use of block terminal is very general, the effect of block terminal is installation terminal check out test set, the voltage and current of every equipment of monitoring that these equipment can be accurate, and make statistics of the electric energy of equipment use, carry on the host computer, but, many direct mount of present block terminal are in the distribution well of building, space is little in the distribution well of building, be unfavorable for the block terminal to dispel the heat, terminal check out test set lasts work under high temperature environment, can lead to the interior precision component of terminal check out test set to damage, influence terminal equipment's use, humidity in the distribution well is big simultaneously, water droplet in the humid air can be attached to on terminal check out test set, corrode equipment circuit, influence terminal check out test set's normal operating.

In view of the above problems, an improved energy-saving management system for construction equipment is now devised.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a building equipment energy-saving management system to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

the utility model provides a building equipment energy-saving management system, includes the box, fixed mounting has the chamber door that is used for switch box on the lateral wall of box, fixed mounting has the handle of person's of facilitating the use switch chamber door on the chamber door, be provided with on the box lateral wall and be used for cooling down to the box inside and prevent that the equipment in the box from being heated the damage and detach the interior moisture of box simultaneously and make the box inside keep dry cooling dehumidification mechanism.

As a further aspect of the present invention: the cooling and dehumidifying mechanism comprises a first air duct, the first air duct is fixedly installed at the upper end of the side wall of the box body, a first valve used for controlling the opening and closing of the first air duct is fixedly installed on the first air duct, a compression pipe used for enabling water to overflow and dissipate in vacuum to reduce the temperature is fixedly installed at the vertical fixed installation of one end, far away from the box body, of the first air duct, a second air duct is fixedly installed on the side wall of the compression pipe under the first air duct, and a second valve used for controlling the opening and closing of the second air duct is fixedly installed on the second air duct.

The one end that the compression pipe was kept away from to the second air duct passes box lateral wall fixedly connected with and is used for carrying out radiating cooling tube to the box inside, the cooling tube is the S type and installs on the box lateral wall relative with the chamber door, the one end that the second air duct was kept away from to the cooling tube passes box lateral wall fixed connection on the exhaust system in the building, compression pipe upper end fixedly connected with third air duct, third air duct and compression pipe communicate each other, the one end fixedly connected with that the compression pipe was kept away from to the third air duct makes the inside vacuum pump that becomes of compression pipe to the air that extracts the compression pipe.

As a further aspect of the present invention: one end of the first air duct, which is close to the box body, is fixedly connected with a dust cover used for preventing dust in the box body from entering the first air duct.

As a further aspect of the present invention: the air conditioner is characterized in that fans used for accelerating air flow in the compression pipe are respectively and fixedly mounted on the inner walls, close to the first air guide pipe and the second air guide pipe, of the compression pipe, water absorption sponges used for absorbing water in air are arranged between the fans, connecting rods are fixedly connected to two ends of each water absorption sponge, and the connecting rods are horizontally fixed on the inner walls of the compression pipes.

As a further aspect of the present invention: and a humidity sensor for detecting the humidity of the water absorption sponge is fixedly arranged on the water absorption sponge.

As a further aspect of the present invention: the side wall of the water absorption sponge is wrapped with gauze for preventing the water absorption sponge from drying and falling off.

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

the utility model is provided with a cooling and dehumidifying mechanism, which utilizes the humid air in the box body to lead the moisture in the humid air to overflow and disperse under the vacuum state, thereby obtaining the air with low temperature, and utilizes the low-temperature air to cool the interior of the box body, thereby preventing the equipment in the box body from working under high temperature, leading the equipment in the box body to be damaged and influencing the normal power transmission work;

meanwhile, the interior of the box body is dehumidified, so that water drops in the humid air are prevented from being attached to equipment in the box body, equipment circuits are prevented from being corroded, the equipment in the box body is damaged, and the service life of the equipment in the box body is prolonged.

Drawings

Fig. 1 is a schematic three-dimensional structure diagram of an energy-saving management system for construction equipment.

Fig. 2 is a schematic structural diagram of an energy-saving management system for construction equipment.

Fig. 3 is an enlarged schematic diagram of a construction equipment energy conservation management system at a in fig. 2.

Wherein: the refrigerator comprises a refrigerator body 1, a refrigerator door 2, a handle 3, a first air duct 4, a first valve 5, a compression pipe 6, a second air duct 7, a second valve 8, a radiating pipe 9, a fan 10, a water absorption sponge 11, a connecting rod 12, a humidity sensor 13, a third air duct 14 and a vacuum pump 15.

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.

Please refer to fig. 1-3, in the embodiment of the present invention, an energy-saving management system for construction equipment, includes a box body 1, fixed mounting has a chamber door 2 for opening and closing the box body 1 on the lateral wall of the box body 1, fixed mounting has a handle 3 for opening and closing the chamber door 2 for the convenient user on the chamber door 2, be provided with on the lateral wall of the box body 1 and be used for cooling down to the inside of the box body 1 and prevent the equipment in the box body 1 from being damaged by heat and removing the moisture in the box body 1 simultaneously and make the inside dry cooling and dehumidifying mechanism that keeps of the box.

The cooling and dehumidifying mechanism comprises a first air duct 4, the first air duct 4 is fixedly installed at the upper end of the side wall of the box body 1, the first air duct 4 is communicated with the interior of the box body 1, a first valve 5 for controlling the opening and closing of the first air duct 4 is fixedly installed on the first air duct 4, a compression pipe 6 for enabling water to overflow and absorb heat in vacuum to reduce the temperature is vertically and fixedly installed at one end, away from the box body 1, of the first air duct 4, the first air duct 4 is communicated with the interior of the compression pipe 6, a second air duct 7 is fixedly installed on the side wall of the compression pipe 6 right below the first air duct 4, the second air duct 7 is communicated with the interior of the compression pipe 6, a second valve 8 for controlling the opening and closing of the second air duct 7 is fixedly installed on the second air duct 7, one end, away from the compression pipe 6, of the second air duct 7 penetrates through the side wall of the box body 1 and is fixedly connected with, the radiating pipe 9 is S-shaped and is arranged on the side wall of the box body 1 opposite to the box door 2, and one end, far away from the second air duct 7, of the radiating pipe 9 penetrates through the side wall of the box body 1 and is fixedly connected to an exhaust system in a building.

The inner walls of the compression pipe 6 close to the first air duct 4 and the second air duct 7 are respectively and fixedly provided with a fan 10 for accelerating the flow of air in the compression pipe 6, a water absorption sponge 11 for absorbing moisture in the air is arranged between the fans 10, two ends of the water absorption sponge 11 are fixedly connected with a connecting rod 12, the connecting rod 12 is horizontally fixed on the inner wall of the compression pipe 6, the water absorption sponge 11 is fixedly provided with a humidity sensor 13 for detecting the humidity of the water absorption sponge 11, the upper end of the compression pipe 6 is fixedly connected with a third air duct 14, the third air duct 14 is communicated with the compression pipe 6, one end of the third air duct 14 far away from the compression pipe 6 is fixedly connected with a vacuum pump 15 for extracting the air in the compression pipe 6 to change the inside of the compression pipe 6 into vacuum, and the working principle of the dehumidifying and cooling mechanism is to open the first valve 5 and the second valve 8, and starting the fan 10, the fan 10 sucks the wet air in the box body 1 into the compression pipe 6 through the first air duct 4, then the air in the compression pipe 6 flows onto the exhaust system of the building through the second air duct 7 and the radiating pipe 9, in the air flowing process, the water absorption sponge 11 in the compression pipe 6 can absorb the water in the air, the humidity sensor 13 detects the humidity on the water absorption sponge 11 in real time, when the humidity on the water absorption sponge 11 reaches a set value, the humidity sensor 13 sends a signal to close the first valve 5 and the second valve 8, and the vacuum pump 15 is started, the vacuum pump 15 extracts the air in the compression pipe 6 through the third air duct 14, so that the inside of the compression pipe 6 becomes vacuum, in the vacuumizing process, the air pressure in the compression pipe 6 is reduced, the water evaporation speed on the water absorption sponge 11 is increased, the liquid water is converted into gaseous water, and the vaporization process can absorb a large amount of heat, make the temperature in the compression pipe 6 drop fast, open first valve 5 earlier, make the air in the box 1 enter into the compression pipe 6, balanced atmospheric pressure, then open second valve 8, under the effect of fan 10, blow into the cooling tube 9 to the cold air in the compression pipe 6 in to make the cooling tube 9 cool down box 1, the effect of dehumidification cooling mechanism is to utilize the humid air in the box 1, under the vacuum individual state, make the moisture in the humid air spill and disperse, thereby obtain the air that the temperature is low, and utilize low temperature air to cool down the inside of box 1, prevent that the equipment work in the box 1 is under high temperature, lead to the equipment damage in the box 1, influence normal transmission of electricity work, dehumidify the inside of box 1 simultaneously, prevent that the water droplet in the humid air from attaching to the equipment in the box 1, corrode the equipment circuit, lead to the equipment damage in the box 1, the service life of the equipment in the box body 1 is prolonged.

The utility model discloses a theory of operation is:

when the air-conditioning device is used, the first valve 5 and the second valve 8 are opened, the fan 10 is started, the fan 10 sucks the humid air in the box body 1 into the compression pipe 6 through the first air duct 4, then the air in the compression pipe 6 flows onto an exhaust system of a building through the second air duct 7 and the radiating pipe 9, in the air flowing process, the water-sucking sponge 11 in the compression pipe 6 can absorb the moisture in the air, the humidity sensor 13 detects the humidity on the water-sucking sponge 11 in real time, when the humidity on the water-sucking sponge 11 reaches a set value, the humidity sensor 13 sends out a signal to close the first valve 5 and the second valve 8 and start the vacuum pump 15, the vacuum pump 15 extracts the air in the compression pipe 6 through the third air duct 14 to enable the interior of the compression pipe 6 to become vacuum, in the vacuumizing process, the air pressure of the compression pipe 6 is reduced, and the water evaporation speed on the water-sucking sponge 11 is increased, liquid water turns into gaseous state water, and the process of vaporization can absorb a large amount of heats, makes the temperature in the compression pipe 6 descend fast, opens first valve 5 earlier, makes the air in the box 1 enter into the compression pipe 6 in, balanced atmospheric pressure, then opens second valve 8, under fan 10's effect, blows in the cooling tube 9 to the cold air in the compression pipe 6 in to make cooling tube 9 cool down box 1.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (6)

1. The utility model provides a building equipment energy-saving management system, includes box (1), fixed mounting has chamber door (2) that are used for switch box (1) on the lateral wall of box (1), fixed mounting has handle (3) of person's of facilitating the use switch chamber door (2) on chamber door (2), a serial communication port, be provided with on box (1) lateral wall and be used for cooling down box (1) inside and prevent that the equipment in box (1) is heated the damage and detach the moisture in box (1) simultaneously and make the inside dry cooling dehumidification mechanism that keeps of box (1).

2. The energy-saving management system for the construction equipment according to claim 1, wherein the temperature-reducing and dehumidifying mechanism comprises a first air duct (4), the first air duct (4) is fixedly installed at the upper end of the side wall of the box body (1), a first valve (5) for controlling the first air duct (4) to be opened and closed is fixedly installed on the first air duct (4), a compression pipe (6) for enabling water to overflow and absorb heat in vacuum to reduce the temperature is vertically and fixedly installed at one end, away from the box body (1), of the first air duct (4), a second air duct (7) is fixedly installed on the side wall of the compression pipe (6) right below the first air duct (4), and a second valve (8) for controlling the second air duct (7) to be opened and closed is fixedly installed on the second air duct (7);

the one end that compression pipe (6) were kept away from in second air duct (7) passes box (1) lateral wall fixedly connected with and is used for carrying out radiating cooling tube (9) to box (1) inside, cooling tube (9) are the S type and install on box (1) lateral wall relative with chamber door (2), the one end that second air duct (7) were kept away from in cooling tube (9) passes box (1) lateral wall fixed connection on the exhaust system in the building, compression pipe (6) upper end fixedly connected with third air duct (14), third air duct (14) and compression pipe (6) communicate each other, the one end fixedly connected with that compression pipe (6) were kept away from in third air duct (14) makes the inside vacuum pump (15) that become the vacuum of compression pipe (6) inside air compression pipe (6) that extract.

3. The energy-saving management system for the construction equipment according to claim 2, wherein a dust cover for preventing dust in the box body (1) from entering the first air duct (4) is fixedly connected to one end of the first air duct (4) close to the box body (1).

4. The energy-saving management system for the construction equipment according to claim 2, wherein fans (10) for accelerating the flow of air in the compression pipe (6) are respectively and fixedly installed on the inner walls of the compression pipe (6) close to the first air duct (4) and the second air duct (7), water absorption sponges (11) for absorbing water in the air are arranged between the fans (10), connecting rods (12) are fixedly connected to two ends of each water absorption sponge (11), and the connecting rods (12) are horizontally fixed on the inner walls of the compression pipe (6).

5. The energy-saving management system for the construction equipment as claimed in claim 4, wherein a humidity sensor (13) for detecting the humidity of the water absorption sponge (11) is fixedly arranged on the water absorption sponge (11).

6. The energy-saving management system for the construction equipment as claimed in claim 4, wherein the side wall of the water absorption sponge (11) is wrapped with gauze for preventing the water absorption sponge (11) from drying and falling off.

Images