CN117250418A - Low-carbon park comprehensive energy and electric energy monitoring system and cabinet body - Google Patents

Abstract

The invention discloses a comprehensive energy and electric energy monitoring system for a low-carbon park and a cabinet body, wherein the system comprises a feedback sensor, the feedback sensor is connected with a load acquisition unit and used for acquiring and processing first information data in real time, and the data is transmitted to a device control host arranged at the core position of the low-carbon park through a station control layer switch. According to the comprehensive energy electric energy monitoring system and the cabinet body for the low-carbon park, the system realizes real-time monitoring, optimization and continuous improvement of energy sources through continuous data acquisition, processing and analysis, control strategy formulation, control instruction transmission and execution and feedback data acquisition and reprocessing and analysis, forms closed loop circulation and achieves the aim of the low-carbon park; and the ventilation direction can be changed, so that various heat dissipation effects are achieved.

Description

Low-carbon park comprehensive energy and electric energy monitoring system and cabinet body

Technical Field

The invention relates to the technical field of electric energy monitoring systems and system heat dissipation, in particular to a comprehensive energy electric energy monitoring system for a low-carbon park and a cabinet body.

Background

Under the drive of development, energy conservation and emission reduction work of various industries is carried out successively, along with the promotion of low-carbon environmental protection measures, energy management and control trend is more and more digital and intelligent, a comprehensive energy system is widely applied as an important carrier for improving energy utilization efficiency and promoting energy conservation and emission reduction, a low-carbon park needs to use clean energy such as electric energy generated by photoelectricity and wind power, however, the electric energy generated by photoelectricity and wind power is greatly influenced by environmental factors, and therefore, the production electricity consumption requirements of various enterprises in the park can not be met under certain conditions, and in order to automatically distribute traditional electric energy such as photoelectricity, wind power and thermal power, a comprehensive energy electric energy monitoring system of the low-carbon park is provided.

Meanwhile, the electric energy monitoring system is required to run all the time, once the operation is stopped, distribution and optimal utilization cannot be carried out, therefore, under the continuous working condition, a large amount of heat is generated, if the heat is not timely processed, the efficiency is low and the heat is easy to block due to the fact that the temperature is too high, very serious consequences are easily caused once the heat is stopped, the existing heat dissipation is achieved through air cooling and induced draft, and once the heat is rained, rain beads are introduced to cause wetting to a host computer of an internal system, so that the safety hazard is caused.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description summary and in the title of the application, to avoid obscuring the purpose of this section, the description summary and the title of the invention, which should not be used to limit the scope of the invention.

The invention is provided in view of the problems of the existing low-carbon park comprehensive energy and electric energy monitoring system.

Therefore, the invention aims to provide a comprehensive energy and electric energy monitoring system for a low-carbon park, which aims to: the electric energy can be optimally utilized and reasonably distributed.

In order to solve the technical problems, the invention provides the following technical scheme: the system comprises a feedback sensor, wherein the feedback sensor is connected with a load acquisition unit and used for acquiring and processing first information data in real time and transmitting the data to a device control host arranged at the core position of a low-carbon park through a station-controlled layer switch; the device control host receives, processes and analyzes the real-time data of the load acquisition unit and the line protection device, prepares an energy management and control strategy, and transmits a control instruction to the load acquisition unit and the line protection device to monitor and optimally control the energy of the low-carbon park; the line protection device is used for monitoring the state of the electric energy transmission line and carrying out protection and feedback data acquisition according to the instruction of the device control host; the device control host computer monitors through the energy sensor the heat energy that produces in the cabinet body to through the use condition and the energy load of energy sensor real-time supervision low carbon garden energy.

As a preferable scheme of the comprehensive energy and electric energy monitoring system for the low-carbon park, the invention comprises the following steps: the device control host is configured at the core position of the low-carbon park, and the energy management and control strategy is prepared for optimizing the utilization of energy through data processing and analysis of the first information transmitted by the load acquisition unit.

As a preferable scheme of the comprehensive energy and electric energy monitoring system for the low-carbon park, the invention comprises the following steps: the device control host transmits formulated control instructions to the corresponding load acquisition units and the line protection devices through communication between the device control host and the load acquisition units and the station control layer switch, so that energy control and load adjustment are realized; the load acquisition unit and the line protection device continuously acquire real-time data after executing energy management and load control, form a circulating feedback mechanism and provide basis for the device control host to adjust energy management and control strategies.

The comprehensive energy and electric energy monitoring system for the low-carbon park has the beneficial effects that: the system realizes the real-time monitoring, optimization and continuous improvement of energy sources through continuous data acquisition, processing and analysis, control strategy formulation, control instruction transmission and execution and feedback data acquisition and reprocessing and analysis, forms a closed loop and realizes the aim of a low-carbon park.

The present invention has been made in view of the above problems with the existing cabinets.

Accordingly, the present invention is directed to a cabinet, which aims at: the wind direction can be automatically switched according to the rainfall, and raindrops are prevented from entering.

In order to solve the technical problems, the invention provides the following technical scheme: the device comprises a protection mechanism, a switching mechanism and a heat dissipation mechanism, wherein the protection mechanism comprises a protection cabinet wrapping a host machine body, a water storage tank arranged on the outer side of the protection cabinet, a rain storage tank connected to one end of the water storage tank, a bearing plate arranged in the protection cabinet and used for bearing the host machine body, and supporting legs fixed at one end of the protection cabinet; the switching mechanism is matched with the water storage tank and the rain storage tank for use and comprises a blocking part, a closing part and a ventilation pipe, wherein the blocking part is arranged in the rain storage tank and extends to the protective cabinet, the closing part is arranged on the water storage tank and matched with the blocking part, and the ventilation pipe is arranged on the protective cabinet and the water storage tank; the heat dissipation mechanism is arranged on the dustproof part outside the protective cabinet, the first air blowing part is arranged at one end of the blocking part and extends into the dustproof part, and the second air blowing part is arranged on the dustproof part and matched with the first air blowing part.

As a preferable scheme of the cabinet body, the invention comprises the following steps: the outer side of the protective cabinet is provided with an air vent plate and is matched with the blocking part; the separation part comprises a floating plate arranged in the rain storage pool, a separation plate arranged on the outer surface of the floating plate and penetrating through the ventilation plate and the protective cabinet, and a through hole formed in the separation plate.

As a preferable scheme of the cabinet body, the invention comprises the following steps: the closing component comprises a storage block arranged in the rain storage pool, a retaining plate arranged in the rain storage pool and positioned above the floating plate, a baffle plate fixed at one end of the retaining plate and penetrating through the ventilation pipe, and a ventilation hole formed in the outer surface of the baffle plate.

As a preferable scheme of the cabinet body, the invention comprises the following steps: the dustproof part comprises a dustproof box arranged on the outer surface of the protective cabinet, a first filter plate and a second filter plate which are respectively fixed on the inner surface of the dustproof box, and a driving assembly and a connecting gear which are arranged on the second filter plate; the driving assembly comprises a motor fixed at the second filter plate and a transmission gear arranged at the output end of the motor and matched with the first blowing component.

As a preferable scheme of the cabinet body, the invention comprises the following steps: the first blowing component comprises a connecting plate, a rotating wheel, teeth, a driven gear shaft and a first fan blade, wherein the connecting plate is arranged at one end of the baffle plate and supported by the baffle plate and extends to the dust box, the rotating wheel is arranged on a connecting piece at the tail end of the connecting plate, the teeth are arranged at the inner side of the rotating wheel and matched with the connecting gear, the driven gear shaft is meshed with the connecting gear and installed on the second filter plate through a bearing, and the first fan blade is arranged on the outer surface of the driven gear shaft.

As a preferable scheme of the cabinet body, the invention comprises the following steps: the first fan blades are located between the first filter plate and the second filter plate, holes of the ventilation plate are identical to the holes of the through holes, the through holes are driven by the baffle plate to move and then are staggered with each other, and the holes of the ventilation plate are not ventilated any more.

As a preferable scheme of the cabinet body, the invention comprises the following steps: the second blowing component comprises a connecting shaft limited on the bearing plate, second fan blades arranged on the connecting shaft and a planetary gear fixed at one end of the connecting shaft; the planetary gear is positioned at the other position of the rotating wheel, and when the horizontal plane of one end of the rotating wheel, which is close to the planetary gear, is coincident, teeth of the rotating wheel can be meshed with the planetary gear.

The cabinet body has the beneficial effects that: if install when the electric energy monitoring devices of open environment meetting raining condition, can be through the self-closing ventilation hole, switch ventilation position, then discharge to the working chamber inside dispel the heat, prevent water droplet such as rainwater from entering into the working chamber inside, dispel the heat to the electronic component of working chamber inside, when the electric energy monitoring devices of installing at open environment meetting under the condition of not raining, can discharge the inside air of working chamber to the external world, then inhale the inside air of working chamber with external environment to the working chamber inside, dispel the heat to the electronic component of working chamber inside.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

fig. 1 is a schematic flow diagram of the system for monitoring comprehensive energy and electric energy in a low-carbon park.

Fig. 2 is a schematic diagram of the overall structure of the integrated energy and power monitoring system and the cabinet of the low-carbon park.

Fig. 3 is a schematic diagram of a front sectional structure of the ventilation plate and baffle plate connection of the low-carbon park comprehensive energy and electric energy monitoring system and the cabinet body.

Fig. 4 is a schematic diagram of a connection structure between a driving assembly and a sun gear of the low-carbon park comprehensive energy and electric energy monitoring system and a cabinet body.

Fig. 5 is a schematic diagram of an overall side sectional structure of the integrated energy and power monitoring system and the cabinet of the low-carbon park.

Fig. 6 is a schematic structural diagram of a first fan blade working state of the low-carbon park comprehensive energy and electric energy monitoring system and the cabinet.

Fig. 7 is a schematic diagram of a working front sectional structure of a first fan blade of the low-carbon park comprehensive energy and electric energy monitoring system and a cabinet of the invention.

Fig. 8 is a schematic diagram of the meshing structure of teeth and connecting gears of the integrated energy and electric energy monitoring system and the cabinet body in the low-carbon park.

Fig. 9 is a schematic diagram of a working structure of a second fan blade of the low-carbon park comprehensive energy and electric energy monitoring system and the cabinet of the invention.

Detailed Description

In order that the above-recited objects, features and advantages of the present invention will become more readily apparent, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present invention is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

In describing the embodiments of the present invention in detail, the cross-sectional view of the device structure is not partially enlarged to a general scale, and the schematic drawings are only examples, which should not limit the scope of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in actual fabrication.

Example 1

Referring to fig. 1, in a first embodiment of the present invention, a system for monitoring comprehensive energy and electric energy of a low-carbon park is provided, where a feedback sensor of the system is connected to a load acquisition unit for acquiring and processing first information data in real time, and the feedback sensor transmits the data to a device control host configured at a core position of the low-carbon park through a site control layer switch.

In the low-carbon park, feedback sensors are installed at each key position, and the feedback sensors comprise temperature sensors, electric energy meters, current sensors and the like and are used for monitoring information such as the service condition of energy, energy load, electric energy loss and the like in real time.

The load acquisition units are distributed at all energy load points of the low-carbon park and are connected with the feedback sensor. The load acquisition unit acquires and processes first information data such as temperature, electric energy use amount, current data and the like in the feedback sensor in real time.

The load acquisition unit is connected with the station control layer switch through the Ethernet, and the acquired data are transmitted to the device control host through the communication channel.

The device control host receives, processes and analyzes the real-time data of the load acquisition unit and the line protection device, prepares an energy management and control strategy, and transmits a control instruction to the load acquisition unit and the line protection device to monitor and optimally control the energy of the low-carbon park; the line protection device is used for monitoring the state of the electric energy transmission line and carrying out protection and feedback data acquisition according to the instruction of the device control host; the heat energy generated by the device control host in the cabinet body is monitored through the energy sensor, and the use condition and the energy load of the energy of the low-carbon park are monitored in real time through the energy sensor.

The device control host is configured in a control center of the core position of the low-carbon park, receives real-time data from the load acquisition unit, performs data processing and analysis, and performs statistics and comparison analysis on information such as energy use conditions, load distribution, electric energy loss and the like.

Based on the result of data analysis, the device control host establishes reasonable energy management and control strategies, wherein the control strategies cover the aspects of energy distribution optimization, load adjustment, electric energy loss optimization and the like so as to realize the efficient utilization of the energy of the low-carbon park.

In the use process, the device control host is configured at the core position of the low-carbon park, and the energy management and the optimal utilization of the control strategy to the energy are prepared by carrying out data processing and analysis on the first information transmitted by the load acquisition unit, and the device control host transmits the formulated control instruction to the corresponding load acquisition unit and the line protection device through communication between the device control host and the station control layer switch, so that the energy control and the load regulation are realized; the load acquisition unit and the line protection device continuously acquire real-time data after executing energy management and load control, form a circulating feedback mechanism, and provide basis for adjusting energy management and control strategies for a device control host.

The device control host transmits the formulated control instruction to the corresponding load acquisition unit and the line protection device through the station control layer switch, and the load acquisition unit executes energy regulation and load control according to the received control instruction to implement an energy management strategy.

The line protection device is used for protecting and measuring the power transmission line according to the instruction sent by the host, monitoring the state of the line and collecting feedback data.

After the energy management and the load control are executed, the load acquisition unit and the line protection device continue to acquire real-time data, and the acquired data are transmitted back to the device control host computer through communication with the station control layer switch to form a circulating feedback mechanism.

The device control host computer carries out data processing and analysis again, compares the actual execution condition with the expected control effect, and adjusts the energy management and control strategy according to the analysis result of the feedback data to form a closed loop.

Example 2

Referring to fig. 2 to 6, for a second embodiment of the present invention, which is different from the first embodiment, there is provided a cabinet including a protection mechanism 100, a switching mechanism 200, and a heat dissipation mechanism 300.

Compared with embodiment 1, further, the protection mechanism 100 comprises a protection cabinet 101 wrapping the main body G, a water storage tank 102 arranged outside the protection cabinet 101, a rain storage tank 103 connected to one end of the water storage tank 102, a bearing plate 104 arranged inside the protection cabinet 101 and used for bearing the main body G, and supporting legs 105 fixed at one end of the protection cabinet 101.

The host body G is wrapped by the protection cabinet 101, so that the host body G can be effectively protected, rainwater is prevented from directly falling onto the protection cabinet 101 through the water storage tank 102 and the rainwater storage tank 103, the bearing plate 104 is arranged, the bearing plate 104 can bear the weight of the host body G, the bearing plate 104 is provided with a plurality of notches, the host body G can be effectively ventilated, and the bottom of the host body G can be also cooled.

In use, the switching mechanism 200 is used in cooperation with the water storage tank 102 and the rain storage tank 103, and comprises a blocking component 201 arranged in the rain storage tank 103 and extending to the protection cabinet 101, a closing component 202 arranged on the water storage tank 102 and matched with the blocking component 201, and a ventilation pipe 203 arranged on the protection cabinet 101 and the water storage tank 102.

Through the cooperation, the retaining of water storage tank 102 can let ventilation pipe 203 submerge in water, effectually carries out the heat transfer, and simultaneously the rain pond 103 also can hold the rain gradually, when the rainwater of rain pond 103 reaches a certain amount, the separation part 201 then can rise and carry out the separation to the ventilation group of guard cabinet 101 to the separation part 201 can drive closing part 202 and remove, lets closing part 202 open ventilation pipe 203, also dispels the heat when utilizing ventilation pipe 203 to dispel the heat.

Further, the heat dissipation mechanism 300 includes a dust-proof member 301 disposed outside the protection cabinet 101, a first air-blowing member 302 disposed at one end of the blocking member 201 and extending into the dust-proof member 301, and a second air-blowing member 303 disposed on the dust-proof member 301 and cooperating with the first air-blowing member 302.

When using, dustproof part 301 can effectively protect inside, and when using naturally, prevents that the dust from directly blowing into inside, and when normally raining not using, first blast part 302 start can be through the outside induced draft entering into inside dispel the heat to host computer body G, blow the wind to the outside again.

When raining, the first air blowing component 302 is closed, the second air blowing component 303 is started, and the second air blowing component 303 can suck air from the bottom, so that the phenomenon that rainwater is sucked due to air suction from the outer side is prevented, and the host body G can be effectively cooled.

In addition, during daily use, the first air blowing component 302 blows air flow to the ground at the dustproof component 301 to keep the place clean, and during raining, dust cannot be sucked up by the wind force due to the reason that dust particles are adhered to the air during raining, so that the second air blowing component 303 cannot suck the dust into the main machine body G during air suction, and the use efficiency is high and the dust is not easy to enter.

The rest of the structure is the same as that of embodiment 1.

Example 3

Referring to fig. 2 to 6, a third embodiment of the present invention is different from the second embodiment in that: and (5) rainproof process.

Preferably, the outside of the protective cabinet 101 is provided with a ventilation plate 101a and is matched with the blocking member 201; the blocking member 201 includes a floating plate 201a disposed in the rain reservoir 103, a blocking plate 201b disposed on an outer surface of the floating plate 201a and passing through the ventilation plate 101a and the protection cabinet 101, and a through hole 201c opened in the blocking plate 201 b.

When raining, rainwater can fill the rainwater storage tank 103 and the water storage tank 102, at this moment, after more rainwater, the floating plate 201a can be floated by the buoyancy of the rainwater, and the baffle plate 201b is driven to move, so that the through holes 201c of the baffle plate 201b are not overlapped with the holes of the ventilation plate 101a any more, and water inflow can be prevented in the continuous raining stage.

The floating plate 201a can be made of a material with higher buoyancy, such as a composite foam material with the density of 0.2-0.7 g/cm and the water absorption rate of not more than 3%, and the size of the floating plate 201a is selected according to actual conditions, so that the equipment can normally operate.

Further, as compared with embodiment 2, the closing member 202 includes a storage block 202a provided in the rain reservoir 103, a retaining plate 202b provided in the rain reservoir 103 and located above the floating plate 201a, a baffle 202c fixed to one end of the retaining plate 202b and penetrating through the ventilation pipe 203, and a ventilation hole 202c provided at an outer surface of the baffle 202c.

Meanwhile, when the floating plate 201a floats, the retaining plate 202b can be pushed upwards, the retaining plate 202b can drive the baffle 202c upwards, the vent hole 202c can coincide with the hole on the baffle 202c, and heat exchange, ventilation and heat dissipation are convenient.

The rest of the structure is the same as that of embodiment 2.

Example 4

Referring to fig. 2 to 8, a fourth embodiment of the present invention is different from the third embodiment in that: and the heat dissipation process is not performed in rainy days.

Further, as compared with embodiment 3, the dust-proof member 301 includes a dust-proof case 301a provided on the outer surface of the protective cabinet 101, a first filter plate 301b and a second filter plate 301c respectively fixed to the inner surface of the dust-proof case 301a, and a driving assembly 301d and a connection gear 301e provided on the second filter plate 301 c; the driving assembly 301d includes a motor 301d-1 fixed to the second filter plate 301c and a transmission gear 301d-2 provided at an output end of the motor 301d-1 to be engaged with the first blowing unit 302.

When the host is not raining normally, the motor 301d-1 is started and drives the transmission gear 301d-2 to rotate, and the first air blowing component 302 is effectively matched with the first air blowing component 302, so that the first air blowing component 302 can suck air through the ventilation plate 101a to dissipate heat of the host body G, and hot air is discharged through the first filter plate 301b and the second filter plate 301 c.

The first blowing part 302 includes a connection plate 302a provided at one end of the barrier 201b to be supported and extended to the dust box 301a, a rotation wheel 302b provided on a connection member at the end of the connection plate 302a, teeth 302b-1 provided inside the rotation wheel 302b and engaged with the connection gear 301e, a sun gear 302c fixed to the outer surface of the rotation wheel 302b and engaged with the transmission gear 301d-2, a driven gear shaft 302e engaged with the connection gear 301e and mounted on the second filter plate 301c through a bearing, and a first fan blade 302f provided at the outer surface of the driven gear shaft 302 e.

In the rotation process of the transmission gear 301d-2, the transmission gear 301d-2 will engage with the connection gear 301e, so that the connection gear 301e drives the rotating wheel 302b, the rotating wheel 302b can drive the teeth 302b-1 to rotate and engage with the connection gear 301e, and the connection gear 301e is continuously engaged with the driven gear shaft 302e, so that the driven gear shaft 302e can drive the first fan blade 302f to rotate.

The first fan blades 302f are located between the first filter plate 301b and the second filter plate 301c, the holes of the ventilation plate 101a are the same as the holes of the through holes 201c, the through holes 201c are staggered after being driven by the baffle plate 201b to move, and the holes of the ventilation plate 101a are not ventilated any more.

When the first fan blade 302f rotates, the holes of the ventilation plate 101a overlap with the through holes 201c, so that the first air blowing component 302 can suck air through the ventilation plate 101a to dissipate heat of the main body G, and the hot air is discharged through the first filter plate 301b and the second filter plate 301 c.

The rest of the structure is the same as that of embodiment 3.

Example 5

Referring to fig. 2 to 9, a fifth embodiment of the present invention is different from the fourth embodiment in that: and (3) a heat dissipation process in raining.

Further, compared to embodiment 4, the second blowing member 303 includes a connection shaft 303a which is limited to the carrier plate 104, a second fan blade 303b which is provided to the connection shaft 303a, and a planetary gear 303c which is fixed to one end of the connection shaft 303 a.

During the rain, the floating plate 201a floats, and the blocking plate 201b drives the connecting plate 302a to move, so that the connecting plate 302a can drive the rotating wheel 302b to move upwards, and the sun gear 302c on the rotating wheel 302b also moves upwards at this time, but the sun gear 302c keeps engaged with the rotating transmission gear 301d-2, so that the sun gear 302c also continuously rotates.

In use, the planet gear 303c is positioned in another orientation of the rotator wheel 302b such that the tooth 302b-1 of the rotator wheel 302b is able to engage the planet gear 303c when the rotator wheel 302b coincides with a horizontal plane near one end of the planet gear 303c.

The rotating sun gear 302c also drives the teeth 302b-1 to rotate when moving upwards, the teeth 302b-1 can be clamped into the planetary gears 303c, the planetary gears 303c can receive meshing force to drive the connecting shaft 303a to rotate, the connecting shaft 303a can drive the connecting shaft 303a to rotate, and the connecting shaft 303a can drive the second fan blades 303b to rotate.

The planetary gear 303c and the teeth 302b-1 can be meshed by adopting an oblique gear, so that the teeth 302b-1 can be effectively ensured to be clamped into the planetary gear 303c when rotating, friction is reduced, and tooth loss is prevented.

The direction in which the second fan blade 303b and the first fan blade 302f rotate is different, the wind blown by the second fan blade 303b is blown to the host body G from the lower net, heat is radiated, the wind absorbing heat enters the ventilation pipe 203, the ventilation pipe 203 exchanges heat and cools down through the rainwater in the water storage tank 102 after being heated, finally the cooled water is attached to the host body G through the ventilation pipe 203, so that the host body G is radiated again, and finally the wind is discharged from the outer side, thereby improving the overall efficiency.

The rest of the structure is the same as that of embodiment 4.

It is important to note that the construction and arrangement of the present application as shown in a variety of different exemplary embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter described in this application. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the position of elements may be reversed or otherwise varied, and the nature or number of discrete elements or positions may be altered or varied. Accordingly, all such modifications are intended to be included within the scope of present invention. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the exemplary embodiments without departing from the scope of the present inventions. Therefore, the invention is not limited to the specific embodiments, but extends to various modifications that nevertheless fall within the scope of the appended claims.

Furthermore, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not be described (i.e., those not associated with the best mode presently contemplated for carrying out the invention, or those not associated with practicing the invention).

It should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present invention may be modified or substituted without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered in the scope of the claims of the present invention.

Claims (10)

1. A low carbon garden comprehensive energy electric energy monitoring system which is characterized in that: the system comprises a feedback sensor, wherein the feedback sensor is connected with a load acquisition unit and used for acquiring and processing first information data in real time and transmitting the data to a device control host arranged at the core position of a low-carbon park through a station-controlled layer switch;

the device control host receives, processes and analyzes the real-time data of the load acquisition unit and the line protection device, prepares an energy management and control strategy, and transmits a control instruction to the load acquisition unit and the line protection device to monitor and optimally control the energy of the low-carbon park;

the line protection device is used for monitoring the state of the electric energy transmission line and carrying out protection and feedback data acquisition according to the instruction of the device control host;

the device control host computer monitors through the energy sensor the heat energy that produces in the cabinet body to through the use condition and the energy load of energy sensor real-time supervision low carbon garden energy.

2. The low-carbon park comprehensive energy and electric energy monitoring system according to claim 1, wherein: the device control host is configured at the core position of the low-carbon park, and the energy management and control strategy is prepared for optimizing the utilization of energy through data processing and analysis of the first information transmitted by the load acquisition unit.

3. The low-carbon park comprehensive energy and electric energy monitoring system according to claim 1 or 2, wherein: the device control host transmits formulated control instructions to the corresponding load acquisition units and the line protection devices through communication between the device control host and the load acquisition units and the station control layer switch, so that energy control and load adjustment are realized;

the load acquisition unit and the line protection device continuously acquire real-time data after executing energy management and load control, form a circulating feedback mechanism and provide basis for the device control host to adjust energy management and control strategies.

4. The utility model provides a cabinet body which characterized in that: comprising the system of any one of claims 1-3, further comprising,

the protection mechanism (100) comprises a protection cabinet (101) wrapping a host machine body (G), a water storage tank (102) arranged on the outer side of the protection cabinet (101), a rain storage tank (103) connected to one end of the water storage tank (102), a bearing plate (104) arranged inside the protection cabinet (101) and used for bearing the host machine body (G), and supporting legs (105) fixed to one end of the protection cabinet (101);

the switching mechanism (200) is matched with the water storage tank (102) and the rain storage tank (103) for use, and comprises a blocking component (201) arranged in the rain storage tank (103) and extending to the protective cabinet (101), a closing component (202) arranged on the water storage tank (102) and matched with the blocking component (201), and a ventilation pipe (203) arranged on the protective cabinet (101) and the water storage tank (102);

the device comprises a heat dissipation mechanism (300), a dustproof part (301) arranged on the outer side of the protective cabinet (101), a first blowing part (302) arranged at one end of the blocking part (201) and extending into the dustproof part (301), and a second blowing part (303) arranged on the dustproof part (301) and matched with the first blowing part (302).

5. The cabinet according to claim 4, wherein: the outside of the protective cabinet (101) is provided with a ventilation plate (101 a) and is matched with the blocking component (201);

the blocking component (201) comprises a floating plate (201 a) arranged in the rain storage pool (103), a blocking plate (201 b) arranged on the outer surface of the floating plate (201 a) and penetrating through the ventilation plate (101 a) and the protective cabinet (101), and a through hole (201 c) formed in the blocking plate (201 b).

6. The cabinet according to claim 5, wherein: the closing component (202) comprises a storage block (202 a) arranged in the rain storage pool (103), a retaining plate (202 b) arranged in the rain storage pool (103) and positioned above the floating plate (201 a), a baffle plate (202 c) fixed at one end of the retaining plate (202 b) and penetrating through the ventilation pipe (203), and a ventilation hole (202 c) formed in the outer surface of the baffle plate (202 c).

7. The cabinet according to claim 6, wherein: the dustproof part (301) comprises a dustproof box (301 a) arranged on the outer surface of the protective cabinet (101), a first filter plate (301 b) and a second filter plate (301 c) respectively fixed on the inner surface of the dustproof box (301 a), and a driving assembly (301 d) and a connecting gear (301 e) arranged on the second filter plate (301 c);

the driving assembly (301 d) comprises a motor (301 d-1) fixed on the second filter plate (301 c) and a transmission gear (301 d-2) arranged at the output end of the motor (301 d-1) and matched with the first blowing component (302).

8. The cabinet according to claim 7, wherein: the first blowing component (302) comprises a connecting plate (302 a) arranged at one end of the baffle plate (201 b) and supported by and extending to the dust-proof box (301 a), a rotating wheel (302 b) arranged on a connecting piece at the tail end of the connecting plate (302 a), teeth (302 b-1) arranged on the inner side of the rotating wheel (302 b) and matched with the connecting gear (301 e), a sun gear (302 c) fixed on the outer surface of the rotating wheel (302 b) and matched with the transmission gear (301 d-2), a driven gear shaft (302 e) meshed with the connecting gear (301 e) and installed on the second filter plate (301 c) through a bearing, and a first fan blade (302 f) arranged on the outer surface of the driven gear shaft (302 e).

9. The cabinet according to claim 8, wherein: the first fan blades (302 f) are located between the first filter plate (301 b) and the second filter plate (301 c), holes of the ventilation plate (101 a) are identical to the holes of the through holes (201 c), the through holes (201 c) are driven by the baffle plate (201 b) to move and then are staggered with each other, and the holes of the ventilation plate (101 a) are not ventilated any more.

10. A cabinet according to claim 8 or 9, wherein: the second blowing component (303) comprises a connecting shaft (303 a) limited on the bearing plate (104), second fan blades (303 b) arranged on the connecting shaft (303 a), and a planetary gear (303 c) fixed at one end of the connecting shaft (303 a);

the planetary gear (303 c) is located at another position of the rotary wheel (302 b), and when the horizontal plane of one end of the rotary wheel (302 b) close to the planetary gear (303 c) is coincident, the tooth (302 b-1) of the rotary wheel (302 b) can be meshed with the planetary gear (303 c).