CN217116710U - Ventilation energy-saving intelligent system for base station - Google Patents

Abstract

The utility model discloses a basic station ventilation energy-saving intelligent system, include: a base cabinet; the communication equipment is arranged in the base cabinet; a controller disposed in the base cabinet; the solar device is arranged at the top of the base cabinet; and an air conditioner disposed in the base cabinet; the upper part of the base cabinet is provided with an air exhaust device, the lower part of the base cabinet is provided with an air intake device, and the air exhaust device and the air intake device penetrate through the heat insulation layer of the base cabinet; the utility model discloses an add solar device, energy storage battery and dc-to-ac converter, the daily operation of exhaust device and hot blast blowpipe apparatus is maintained to the electric energy that solar device obtained, and the electric energy of air conditioner is provided by the electric wire netting, and the air conditioner only is less than or is higher than regulation operating temperature and exhaust device and hot blast blowpipe apparatus stop work time at the inside temperature of basic cabinet and just starts, can reduce the air conditioner service load like this to reduce power consumption.

Description

Ventilation energy-saving intelligent system for base station

Technical Field

The utility model belongs to the technical field of basic station ventilation energy-saving, specifically speaking relates to a basic station ventilation energy-saving intelligent system.

Background

Under the environment of energy saving and environmental protection, energy saving and consumption reduction are the current development direction, and are also effective ways for reducing the use cost and energy shortage, and especially in the technical fields of communication, electric power, environmental protection and the like, the energy saving and consumption reduction is the main direction of development and innovation. Various electronic devices in the current mobile base station can normally operate for a long time only under a certain environmental temperature (the base station temperature is 18-28 ℃ specified by the national standard GB50174-93 of the base station environment for a long time). In order to reach the standard environmental temperature of the base station, most of the base stations adopt an unattended operation state, and an air conditioner is started and operated all the year round. The method has the problems of large expenditure of electricity for the air conditioner of the base station and electricity waste of the air conditioner, air conditioner loss caused by long-term continuous operation of the air conditioner, greatly reduced service life of the air conditioner, high failure rate, large overhauling and maintaining pressure and the like, and the operation cost is greatly increased. In addition, when the air conditioning equipment is damaged, if measures are not taken in time, the equipment in the machine room is damaged due to unsmooth heat dissipation and ventilation, and normal communication work is influenced.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims to solve the technical problem that a basic station ventilation energy-saving intelligent system is provided, solve among the prior art problem that the air conditioner use load is big with big power consumption.

In order to solve the technical problem, the utility model discloses a basic station ventilation energy-saving intelligent system, include: a base cabinet; the communication equipment is arranged in the base cabinet; a controller disposed in the base cabinet; the solar device is arranged at the top of the base cabinet; and an air conditioner disposed in the base cabinet; the upper part of the base cabinet is provided with an air exhaust device, the lower part of the base cabinet is provided with an air intake device, and the air exhaust device and the air intake device penetrate through the heat insulation layer of the base cabinet; one end of the air exhaust device is connected with the air guide part through a pipeline, the air guide part is arranged at the top in the base cabinet, and the other end of the air exhaust device is arranged in a protective cover outside the base cabinet; the two ends of the air inlet device are respectively provided with a first filter plate and a second filter plate; the protective cover is provided with a protective net; the solar device is used for photovoltaic power generation and storing in the energy storage battery, and the energy storage battery converts and transmits electric energy to the air exhaust device and the air intake device through the inverter; the communication device, the controller and the air conditioner are powered by a power grid.

Further, the solar device is provided with a solar panel and a solar track following device.

Furthermore, the air guide part is square, a reticular pipeline is arranged in the air guide part, and air guide covers are arranged at the intersected nodes of the pipelines.

Furthermore, the air guide cover is in a horn shape.

Furthermore, the protective cover is fixed on the side wall of the base cabinet, and the opening of the protective cover faces downwards.

Furthermore, one end of the air inlet device is provided with a fixed support, and the second filter plate is inserted on the fixed support.

Compared with the prior art, the application can obtain the following technical effects:

the utility model discloses an add solar device, energy storage battery and dc-to-ac converter, the daily operation of exhaust device and hot blast blowpipe apparatus is maintained to the electric energy that solar device obtained, and the electric energy of air conditioner is provided by the electric wire netting, and the air conditioner only is less than or is higher than regulation operating temperature and exhaust device and hot blast blowpipe apparatus stop work time at the inside temperature of basic cabinet and just starts, can reduce the air conditioner service load like this to reduce power consumption.

Of course, it is not necessary for any one product to achieve all of the above-described technical effects simultaneously.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

FIG. 1 is a schematic view of the interior of a base cabinet according to an embodiment of the present invention;

fig. 2 is a schematic diagram of an operation block diagram of a control system according to an embodiment of the present invention.

Reference symbols of the drawings

The solar energy communication system comprises a base cabinet 1, communication equipment 2, a controller 3, an air conditioner 4, an exhaust device 5, an air inlet device 6, an air guide part 7, a protective cover 8, a first filter plate 9, a second filter plate 10, a protective net 11, an energy storage battery 12, an inverter 13, a solar panel 14, a solar track following device 15, an air guide cover 16, a fixing support 17, an outer wall plate 18, a heat insulation layer 19 and an inner wall plate 20.

Detailed Description

Embodiments of the present application will be described in detail with reference to the drawings and examples, so that how to implement technical means to solve technical problems and achieve technical effects of the present application can be fully understood and implemented.

Referring to fig. 1 and 2, fig. 1 is a schematic view of the interior of a base cabinet according to an embodiment of the present invention; fig. 2 is a schematic diagram of an operation block diagram of a control system according to an embodiment of the present invention. A base station ventilation energy-saving intelligent system comprises: a base cabinet 1; a communication device 2 provided in the base cabinet 1; a controller 3 provided in the base 1; the solar device is arranged at the top of the base cabinet 1; and an air conditioner 4 disposed in the base cabinet 1; the upper part of the base cabinet 1 is provided with an air exhaust device 5, the lower part is provided with an air intake device 6, and the air exhaust device 5 and the air intake device 6 penetrate through a heat insulation layer 19 of the base cabinet 1; one end of the air exhaust device 5 is connected with an air guide part 7 through a pipeline, the air guide part 7 is arranged at the top in the base cabinet 1, and the other end of the air exhaust device 5 is arranged in a protective cover 8 outside the base cabinet 1; the two ends of the air inlet device 6 are respectively provided with a first filter plate 9 and a second filter plate 10; the protective cover 8 is provided with a protective net 11; the photovoltaic power generation of the solar device is stored in an energy storage battery 12, and the energy storage battery 12 converts and transmits electric energy to the air exhaust device 5 and the air intake device 6 through an inverter 13; the communication device 2, the controller 3 and the air conditioner 4 are powered by the grid.

The solar device is provided with a solar panel 14 and a solar track following device 15, the solar panel 14 is fixed on the solar track following device 15, and the solar panel 14 can move along with the sun to improve the utilization rate of sunlight; the air guide part 7 is square, a reticular pipeline is arranged in the air guide part, the air guide cover 16 is arranged at the intersection node of a plurality of pipelines, the air guide cover 16 is horn-shaped, and the plurality of air guide covers 16 which are arranged regularly can quickly absorb heat generated by the communication equipment 2 in the base cabinet 1, so that the cooling efficiency is improved; the protective cover 8 is fixed on the side wall of the base cabinet 1, and the opening of the protective cover faces downwards; one end of the air inlet device 6 is provided with a fixed support 17, and the second filter plate 10 is inserted on the fixed support 17, so that the second filter plate 10 can be conveniently inserted, pulled out and replaced; the cabinet body of the base cabinet 1 is composed of an outer wall plate 18, an insulating layer 19 and an inner wall plate 20.

The operation principle of the control system is as follows: the first temperature and humidity sensor and the second temperature and humidity sensor are connected to the controller 3, the air inlet device 6 and the air exhaust device 5 are connected to the controller 3, and the infrared emitter is connected to the controller 3; the solar panel 14 is connected with the energy storage battery 12, the energy storage battery 12 is connected with the inverter 13, and the inverter 13 is connected with the air intake device 6 and the air exhaust device 5; the temperature range of the working environment of the communication equipment 2 is 18-28 ℃, the temperature in the base cabinet 1 can be increased by the heat generated by the working of the communication equipment 2, the difference between the temperature in the base cabinet 1 and the temperature outside the base cabinet is larger in summer and winter, the air conditioner 4 is mainly used for controlling the temperature, the difference between the temperature inside and outside the base cabinet 1 is smaller in spring and autumn, and the air inlet device 6 and the air exhaust device 5 are mainly used for air exchange; when the second temperature and humidity sensor monitors that the temperature inside the base cabinet 1 approaches 28 ℃ and the air intake device 6 and the exhaust device 5 are ventilated and can not cool, the controller 3 sends an instruction to start the air conditioner 4 by using the infrared transmitter, close the air intake device 6 and the exhaust device 5 and only use the air conditioner 4 to control the temperature inside the base cabinet 1; when the first temperature and humidity sensor monitors that the external temperature is within the range of 8 ℃ -18 ℃, the controller 3 sends an instruction to turn off the air conditioner 4 by using the infrared emitter, and starts the air intake device 6 and the air exhaust device 5, the internal part of the base cabinet 1 is cooled by using the external air, the power of the air intake device 6 and the air exhaust device 5 is automatically adjusted by the controller 3, and the controller 3 adjusts the power of the air intake device 6 and the air exhaust device 5 according to the temperature monitored by the second temperature and humidity sensor, for example: when the temperature monitored by the second temperature and humidity sensor is 17 ℃, the controller 3 reduces the power of the air inlet device 6 and the air exhaust device 5, even stops the air inlet device 6 and the air exhaust device 5, and when the temperature monitored by the second temperature and humidity sensor is 25 ℃, the controller 3 increases the power of the air inlet device 6 and the air exhaust device 5, so that the air exchange is accelerated and the temperature is reduced; when the first temperature and humidity sensor monitors that the external temperature is lower than 8 ℃, the controller 3 turns off the air inlet device 6 and the air exhaust device 5, and starts the air conditioner 4 to control the temperature.

The utility model discloses an add solar device, energy storage battery 12 and dc-to-ac converter 13, the daily operation of 5 and air inlet unit 6 of exhaust device is maintained to the electric energy that solar device obtained, and the electric energy of air conditioner 4 is provided by the electric wire netting, and air conditioner 4 only is less than or is higher than regulation operating temperature and exhaust device 5 and air inlet unit 6 stop work just starts when 1 inside temperature of base cabinet, can reduce 4 service loads of air conditioner like this to reduce power consumption.

While the foregoing description shows and describes several preferred embodiments of the invention, it is to be understood, as noted above, that the invention is not limited to the forms disclosed herein, but is not intended to be exhaustive or to exclude other embodiments and may be used in various other combinations, modifications, and environments and is capable of changes within the scope of the inventive concept as expressed herein, commensurate with the above teachings, or the skill or knowledge of the relevant art. But that modifications and variations may be effected by those skilled in the art without departing from the spirit and scope of the invention, which is to be limited only by the claims appended hereto.

Claims (6)

1. A base station ventilation energy-saving intelligent system comprises: a base cabinet; a communication device disposed in the base cabinet; a controller disposed in the base cabinet; the solar device is arranged at the top of the base cabinet; and an air conditioner disposed in the base cabinet;

the air-exhaust air-intake; one end of the air exhaust device is connected to the air guide part through a pipeline, the air guide part is arranged at the top in the base cabinet, and the other end of the air exhaust device is arranged in the protective cover outside the base cabinet; the two ends of the air inlet device are respectively provided with a first filter plate and a second filter plate; the protective cover is provided with a protective net; the solar device is used for photovoltaic power generation and storing in an energy storage battery, and the energy storage battery converts and transmits electric energy to the air exhaust device and the air intake device through an inverter; the communication device, the controller, and the air conditioner are powered by a power grid.

2. The intelligent base station ventilation and energy saving system of claim 1, wherein the solar device has a solar panel and a solar track following device.

3. The intelligent ventilation and energy-saving system for the base station as claimed in claim 1, wherein the air guide part is square, a mesh-shaped pipeline is arranged in the air guide part, and an air guide hood is arranged at the intersection node of a plurality of pipelines.

4. The intelligent base station ventilation and energy conservation system of claim 3, wherein the scoop is flared.

5. The intelligent base station ventilation and energy saving system as claimed in claim 1, wherein the protective cover is fixed on the side wall of the base cabinet with its opening facing downward.

6. The intelligent ventilation and energy saving system for base stations as claimed in claim 1, wherein the air intake device is provided with a fixing bracket at one end, and the second filter plate is inserted into the fixing bracket.

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