RU2792171C2 - Combined power plant of modular type of mobile and stationary design, including renewable energy sources - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to the field of electrical engineering, in particular to autonomous power supply systems of objects remote from the central power supply. The result is achieved by the fact that the installation contains three autonomous power modules (No. 1, No. 2 and No. 3), the first and second of which are formed on the basis of a separate block container of Arctic design and each of the three modules is placed on a car trailer with outrigger jacks. Autonomous energy module No. 1 is a module for generating, converting and storing energy. Autonomous power module No. 2 includes a photovoltaic generating system, micro hydropower plants in modular and mobile design and a switching module for connection to electric energy storage devices located in autonomous power module No. 1. Autonomous energy module No. 3 includes three wind power plants of vertical or horizontal type or a combination thereof.

EFFECT: creation of a combined power plant based on renewable energy sources with the provision of modularity, mobility and the possibility of stationary use.

1 cl, 6 dwg

Description

The invention relates to renewable energy sources and can be used to generate electricity.

A patent of the Russian Federation for a utility model No. 124742, IPC F03G 6/06 "Autonomous post for charging electric vehicles" is known. The utility model relates to renewable energy sources and can be used for power generation and electric charging of hybrid and electric vehicles, as well as vehicles with engines with flywheel energy storage devices. Alternatively, an autonomous charging station for electric vehicles can be used as an autonomous power plant for the needs of various industrial and domestic consumers in urban and rural areas. Autonomous charging post for electric vehicles contains: tandem photovoltaic solar modules, which are placed on the roof of the charging post and on its sides at an angle of 45° to the roof plane; one or more rotary wind turbines with a vertical axis of rotation; multi-pole low-speed magnetoelectric generator with a flywheel rotor; battery storage; workplaces for charging batteries of electric and hybrid vehicles by contact and non-contact methods; an elevator for transporting batteries from storage to work stations for charging batteries of electric and hybrid vehicles; a robot transporter for delivering batteries to workplaces for charging batteries of electric and hybrid vehicles; devices for wireless charging of electric vehicles; solar spotlights for additional lighting of tandem photovoltaic solar modules in order to increase their efficiency; solstice tracking systems; automated workplace for the operator of an autonomous electric vehicle charging station. The required technical result is achieved as a result of the joint use of the energy of the Sun, wind and Earth in order to provide an autonomous post for charging electric vehicles with electricity for targeted needs and additionally hot water supply, regardless of traditional energy sources. The disadvantage of this technical solution is the lack of an alternative energy source (diesel generator set), bulkiness, complexity of transportation and installation, as well as lack of mobility.

Closest to the claimed invention is the RF utility model patent No. 162099, IPC F03G 6/00 "Hybrid Autonomous Container Power Plant". A hybrid autonomous container power plant belongs to renewable energy sources and can be used to generate electricity for the needs of various industrial and domestic consumers. Hybrid autonomous containerized power plant is made with the possibility of compact assembly and transportation in a container and contains: solar panels, each of which has its own controller; wind turbines, each of which has its own controller; diesel generator set with diesel generator set control cabinet and fuel tank; rechargeable batteries; control system controller; control switchboard. The controllers have an output to the batteries, which are connected to the inverter, connected in turn to the control switchboard and the control system controller, which is also connected to the diesel generator set through the diesel generator set control cabinet, while the control system controller is connected to external network and with the output network of the load, and all devices of the power plant are placed in a container with thermal insulation, which is equipped with windows for input of the external network and the output network of the load, as well as windows for ventilation, and the controller of the control system is connected to the output network of the load through the control switchboard . The essence of the utility model lies in the efficient sharing of energy generated by solar panels, wind turbines and a diesel generator set in order to provide consumers with electricity for their intended needs.

The disadvantages of this technical solution are:

1. Lack of an alternative source of electricity generation using micro hydroelectric power plants.

2. A diesel generator set supplies the electricity generated by it from fossil fuel exclusively directly to the power grid, and not to the electrical energy storage (batteries), which leads to the cost of electrical energy to maintain the load network, even without the necessary payload functioning in it.

3. Batteries (electrical energy storage) do not have an internal heating system, which allows to reduce energy costs directed to the own needs of the power plant.

4. Low efficiency of wind energy use, since the wind power plant is located at a fixed height, which does not allow the simultaneous collection of surface creeping wind flows and above-ground wind flows.

The technical objective of the invention is the creation of a combined power plant based on renewable energy sources with modularity, mobility and the possibility of stationary use.

The technical result is achieved due to the fact that the combined mobile and stationary modular type power plant, including renewable energy sources, contains three autonomous power modules (No. 1, No. 2 and No. 3), the first and second of which are formed on the basis of a separate block container of Arctic design, and each of the three modules is placed on a trailer. When using a combined power plant with autonomous power modules without car chassis, it can be included (as a power supply module, in one configuration or another) into various quickly deployed mobile complexes for stationary use, made on the basis of standard or special containers.

The external view of autonomous power modules in the transport and working positions is shown in Fig. 1 and FIG. 2.

Autonomous power module No. 1 is housed in an arctic-design block-container mounted on a car trailer with outrigger jacks that ensure module alignment in the horizontal plane and protection against tipping over when exposed to large wind loads, and is a module for generating, converting and storing energy, which includes a photovoltaic generating system, a diesel generating set, an electrical energy storage device, an automatic fire extinguishing system, a ventilation and air conditioning system, a hardware and software energy management and diagnostics module, an inverter unit, a switching module, converters - chargers from photovoltaic generating systems, wind turbines , micro hydroelectric power plants, a diesel generating set, a power bus and a remote power supply designed to provide the consumer with direct current with voltages of 12 V and 24 V at a distance from the autonomous power tic module No. 1 up to 50 meters. Moreover, the diesel generator works (produces and transmits electricity) exclusively to the storage of electrical energy. This fundamental solution makes it possible to avoid losses of electricity generated by a diesel generator, which, if it were otherwise connected (directly to the “load” circuit), would to a certain extent be spent on maintaining the load network when it does not have the necessary amount of payload. The main connecting electric power element of the autonomous energy module No. 1 is a power bus (bus 48 V), to which electric energy storage devices and converters are connected - chargers from photovoltaic generating systems, wind turbines, microhydroelectric power plants, diesel electric unit. Through the circuits of the switching module, the incoming energy is supplied to converters - chargers from photovoltaic generating systems, wind power plants, microhydroelectric power plants, diesel power generators, and after its conversion, it is sent to electric energy storage devices via the power bus, which allows charging electric energy storage devices and supplying energy to consumers at the same time. In the absence of input energy (solar, wind and water), the transmission of electricity to consumers is carried out from the storage of electrical energy, and after its discharge (the critical level of the discharge is determined by the parameter specified in the software of the hardware-software module), power is supplied from the diesel generator (turning into the generation mode). electricity) through the storage of electric energy, functioning in this case in the "buffer mode". To ensure the receipt of generating capacities from autonomous power modules No. 2 and No. 3, as well as for the transmission of electricity to consumers, a switching module is used.

The photovoltaic generating system, which is part of the autonomous power module No. 1, can be transported both inside and outside the container, is mounted on the container body in the working position, incorporates a monitoring photoelectric sensor to evaluate its efficiency and consists of laminated solar panels with a small weight and fixed on the upper and lower sides of the frame, by means of a perforated metal tape built into the solar panels, in turn, the upper and lower sides of the frame are attached to each other using side racks, inside of which there are springs that ensure reliable fastening of the solar panels between the top and the lower sides of the frame, as well as self-cleaning of the surface of the solar panels from snow and ice, due to small bends and microvibrations caused by the wind acting on the surface of the solar panels and the tension (compression) of the springs installed in the side racks of the frame.

The block of inverters ensures the issuance of single-phase and (or) three-phase AC voltage, parallel operation with the network of single-phase and (or) three-phase AC voltage, charging of the electric energy storage device from the network of single-phase and (or) three-phase AC voltage.

The hardware-software energy management and diagnostics module, which is part of the autonomous energy module No. 1, is a complex of hardware and software tools designed for energy management and diagnostics of a combined power plant. The hardware-software module for energy management and diagnostics includes a central computer, a means of visual display of information, an electronic compass, Wi-Fi, 3G, a GPRS modem, a satellite communication terminal, a signal receiver of GLONASS, NAVSTAR, GPS systems and, through digital interfaces (RS-485 bus), connected to the electric energy storage, diesel generating set, automatic fire extinguishing system, ventilation and air conditioning system, converters - chargers from photovoltaic generating systems, wind power plants, micro hydroelectric power plants, diesel generating set, monitoring photoelectric sensors, digital anemometer, inverters and provides control and display of the charge and discharge modes of the electric energy storage, measurement and display of the power coming from the primary energy sources and the power given to the load, automatic start and stop of the generating set according to the programmed algorithm, control of the parameters of the electrical unit, control and maintenance of the set temperature inside the container, forecasting the amount of energy generated by primary energy sources, depending on the time of day, season, coordinates of the location of the combined power plant, weather forecast, as well as remote control, diagnosis and management of work combined power plant through special software installed on a smartphone, tablet or computer.

Each object interacting with the hardware-software energy control and diagnostics module is equipped with a controller that provides the energy-control and diagnostics hardware-software module with information about the state and operation parameters of the object. Controllers also make objects self-sufficient, allowing them to work offline.

The remote access module provides information on the state and operation of the combined power plant to a remote user (system), allows you to remotely enter the electricity consumption plan and weather forecast, as well as display diagnostic information and data on the operation parameters of the facility.

The appearance of the autonomous power module No. 1 in the working position is shown in Fig.3.

Autonomous power module No. 2 is placed in an arctic-type container mounted on a car trailer with outrigger jacks that ensure module alignment in a horizontal plane and protection against tipping over when exposed to large wind loads, and includes a photovoltaic generating system, microhydroelectric power plants in a modular - mobile version and switching module. At the same time, the photovoltaic generating system of the autonomous power module No. 2 is completely identical to the photovoltaic generating system of the autonomous power module No. 1.

The external view of the autonomous power module No. 2 in the working position is shown in Fig. 4.

Autonomous energy module No. 3 is placed on a car trailer with outrigger jacks that provide alignment of the modules in a horizontal plane and protection against tipping over when exposed to large wind loads, and includes three wind turbines of a vertical or horizontal type, or a combination of them (one central wind turbine and two extreme wind turbines), ballast load, anemometer and switching module.

For the most complete use of wind flows, the module uses two types of wind power plants - two extreme installations with rotors with a diameter of 800 mm and one central installation with a rotor with a diameter of 1,600 mm. The two outer installations have a smaller sweeping area of the rotor blades in comparison with the central installation, but they are more sensitive to wind flows. Rotors with a diameter of 800 mm have a high rotation speed. In the working position, the two extreme wind turbines are raised to a height of four meters from the ground level by manual block-type lifting devices, made according to the principle of building a chain hoist, with reliable fixation of the turbines in the upper position. This type of lifting device design allows, with the minimum dimensions of the lifting device, to quickly and reliably bring the extreme wind turbines from the transport position to the working position and vice versa, by the efforts of two people by rotating the handle of the worm gear, without taking the generated electrical energy. This design feature allows the rotating turbine rotor to be separated from the level of snowdrifts and provides greater efficiency of energy conversion of radial wind flows and protects against the impact of the shielding of the bottom of the trailer. The central wind turbine has a larger sweeping area, but is less dynamic. In the working position, it is lifted two meters from the ground level by a frame-type manual lifting mechanism using a screw lever lifting mechanism, ensuring reliable fixation in the upper position. The main purpose of the central wind power plant is to collect low-lying creeping wind currents that are typical for the northern and Arctic coasts.

The switching module is used to connect the wind turbines of the autonomous energy module No. 3 with the electric energy storage devices located in the autonomous energy module No. 1, as well as to transfer information to the hardware-software module for energy management and diagnostics about wind speed and direction.

The wind power plants, which are part of the autonomous power module No. 3, incorporate a digital anemometer to measure the direction and speed of the wind.

The external view of the autonomous power module No. 3 with vertical wind turbines in the working position is shown in Fig. 5.

In general, the design of the combined power plant is built according to the modular principle, which makes it possible to use it in various combinations of the combination of module No. 1 with modules No. 2 and No. 3 or use only module No. 1, which in this configuration will be a combined power plant.

The system of communications between the devices of a combined power plant of a modular type, mobile and stationary, including renewable energy sources, is shown in Fig. 6.

The assembly of a combined power plant of a modular type, mobile and stationary, including renewable energy sources, is as follows. After the installation arrives at the place of operation, the equipment of the autonomous power modules No. 1, No. 2 and No. 3 included in the product is installed. Installation is carried out by two workers. The following works are carried out at the installation site:

1. Photovoltaic generating systems are being installed. To install stand-alone power modules #1 and #2, containers with trailers are installed in such a way that the working sides of the photovoltaic generating systems are oriented to the south. After that, the containers are aligned with outriggers, the structures of photovoltaic generating systems are mounted, and the modules are grounded. Mounting of the supporting structures of photovoltaic generating systems is carried out on a flat surface on the ground next to the container and is carried out section by section. Each section contains 4 cells located one below the other. For the installation of each section, 2 load-bearing beams are used, equipped with appropriate fasteners. Inside each beam there is a cable for power output (positive wire in one, negative wire in the other). For electrical switching of beam sections, they are equipped with mating connectors fixed in the beam body. In this way, on-site cabling work is eliminated, ensuring a quick and reliable assembly of the entire structure. Installation is carried out from the upper cell in series. After installing three cells, the beams with fixed cells are lifted onto the container and fixed on the container. To facilitate lifting, the installation of the last cell is already carried out on fixed beams. The load-bearing beams are fixed to the container by fixing the beams with stops, one end of which is securely fixed through the ear to the container, and the other end to the section beam. The stops consist of two parts, which allows you to change their length to choose the angle of inclination of photovoltaic generating systems. The electrical contact of photovoltaic generating systems with the storage of electrical energy is carried out by means of a switching module located in the container wall and a power cable. The dismantling of photovoltaic generating systems is carried out in the reverse order.

2. The transfer of microhydro power plants from the composition of the autonomous energy module No. 2 from the transport position to the working state is carried out by block assembly.

3. The transfer of wind turbines from the autonomous energy module No. 3 from the transport position to the working state is carried out using lifting mechanisms.

4. After the installation of autonomous power modules No. 2 and No. 3, they are connected by appropriate cables through the switching module to the autonomous power module No. 1. After that, devices and equipment of consumers are connected to the output connectors 220 V and 380 V of the switching module.

5. The combined power plant is turned on, the operation of the equipment is checked and its operation is started.

After the installation is completed, the installation does not require additional management and maintenance. Energy accumulation is controlled by a hardware-software module. After the end of operation, the equipment is dismantled and transferred to the transport position.

A combined power plant of a modular type, mobile and stationary, including renewable energy sources, operates as follows:

1. Electricity generated by the photovoltaic generating system of the autonomous energy module No. 1 through the switching module, the converter-charger and the power bus is fed to the electric energy storage device.

2. Electricity generated by the photovoltaic generating system and microhydroelectric power plants of the autonomous energy module No. 2 through the switching module, the converter - the charger and the power bus is fed to the electric energy storage.

3. The electricity generated by the wind turbines of the autonomous energy module No. 3 through the switching module, the converter-charger and the power bus is fed to the electric energy storage device.

4. If it is possible to connect to an external network, then the current is transmitted through the switching module, the inverter unit and the power bus to the electric energy storage device.

5. When the generation of energy from the photovoltaic generating system, wind turbines and micro hydroelectric power plants stops, as well as the inability to connect to the external network, the diesel electric unit automatically (at the signal of the hardware-software module) turns on and starts generating energy and transmitting it through the converter - charger and power bus to the storage of electrical energy.

6. The electric energy storage unit accumulates the energy transferred from photovoltaic generating systems, wind power plants, micro hydro power plants, diesel generating set or external network.

7. From the electric energy storage device, direct current is transmitted through the power bus to the inverter unit, where it is converted into alternating current, and then alternating current is fed through the switching module to the load output network.

Maintenance of a combined power plant of a modular type, mobile and stationary, including renewable energy sources, is as follows. All equipment is controlled by a hardware-software module, which, through digital interfaces (RS-485 bus), is connected to an electrical energy storage device, a diesel generating set, an automatic fire extinguishing system, a ventilation and air conditioning system, converters - chargers from photovoltaic generating systems, wind power plants, micro hydroelectric power plants, diesel generating set, monitoring photoelectric sensors, a digital anemometer, an inverter unit and provides control and display of charge and discharge modes of the electric energy storage device, measurement and display of the power coming from primary energy sources and power delivered to the load, automatic start and stop of the diesel generating set according to the programmed algorithm, control of diesel generator parameters, control and maintenance of the set temperature inside the container, forecasting the amount of energy generated by primary and sources of energy, depending on the time of day, season, coordinates of the location of the combined power plant, weather forecast, as well as remote monitoring, diagnosis and management of the operation of the combined power plant using special software installed on a smartphone, tablet or computer, while the unit The inverters ensure the output of single-phase and (or) three-phase AC voltage, parallel operation with the network of single-phase and (or) three-phase AC voltage, charge of the electric energy storage device from the network of single-phase and (or) three-phase AC voltage.

Based on the foregoing, the maintenance of a combined mobile and stationary modular power plant, including renewable energy sources, in the operating mode consists only in maintaining the required fuel level.

The proposed design has the following advantages compared to the prototype:

1. To ensure mobility, autonomous power modules No. 1, No. 2 and No. 3 are placed on a high-traffic car trailer (chassis), equipped with mechanical outrigger jacks, which ensure the alignment of the modules in a horizontal plane and protection against overturning when exposed to large wind loads.

2. Autonomous power modules No. 1 and No. 2 include containers of arctic design for placement and transportation of components in them, while the photovoltaic generating system, which is part of autonomous power modules No. 1 and No. 2, can be transported both inside and outside of the containers, in the working position it is mounted on the body of the containers, it incorporates a monitoring photoelectric sensor to evaluate its efficiency and consists of laminated solar panels, which are lightweight and fixed on the upper and lower sides of the frame by means of a perforated metal tape built into the solar panels , in turn, the upper and lower sides of the frame are attached to each other with the help of side racks, inside of which springs are installed, ensuring reliable fastening of the solar panels between the upper and lower sides of the frame, as well as self-cleaning of the surface of the solar panels from snow and ice, due to slight bending microvibrations caused by wind impact on the surface of solar panels and stretching (compression) of springs installed in the side racks of the frame.

3. The diesel generating set, which is part of the autonomous power module No. 1, generates and transmits electricity exclusively to the electric energy storage device, which allows to avoid losses of electricity generated by the diesel generator, which, if it is connected otherwise (directly to the "load" circuit), to a certain extent would be spent on maintaining the load network when it lacks the necessary amount of payload.

4. Wind power plants, which are part of the autonomous power generation module No. 3, include a digital anemometer for measuring wind direction and speed, lifting devices that provide lifting of wind turbines to different heights in order to use the energy of surface and aboveground winds, as well as transportation wind turbines in a folded position, while the wind turbines are transported inside the container disassembled, assembled outside the container in a horizontal position, and then, using winches installed on the container, they rise to a vertical position and are fixed on the end walls of the container.

All of the above indicates the fulfillment of the set technical task and the industrial applicability of the claimed installation.

Claims (1)

Combined mobile and stationary modular type power plant, including renewable energy sources, containing: an autonomous energy module No. 1 for generating, converting and storing energy, including a photovoltaic generating system, an electrical energy storage device, a diesel generating set, an automatic fire extinguishing system, a ventilation system and air conditioning, a hardware and software module for energy management and diagnostics, an inverter unit, a power bus, a remote power supply unit, a switching module, converters - chargers from photovoltaic generating systems, wind power plants, microhydroelectric power plants, a diesel electric unit; autonomous power generation module No. 2, which includes a photovoltaic generating system, microhydro power plants in a modular mobile design and a switching module; autonomous power generation module No. 3, which includes three vertical or horizontal wind turbines or a combination of them, a ballast load, an anemometer and a switching module, characterized in that, to ensure mobility, autonomous power modules No. 1, No. 2 and No. 3 are placed on off-road vehicle trailer equipped with mechanical outrigger jacks that provide leveling of the modules in a horizontal plane and protection against tipping over under the influence of large wind loads, and autonomous power modules No. 1 and No. 2 incorporate Arctic-type containers for placing and transporting composite parts, while the photovoltaic generating system, which is part of the autonomous power modules No. 1 and No. 2, can be transported both inside and outside the containers, is mounted on the container body in the working position, incorporates a monitoring photoelectric yes sensor for evaluating its efficiency and consists of laminated solar panels, having a low weight and fixed on the upper and lower sides of the frame by means of a perforated metal tape built into the solar panels, in turn, the upper and lower sides of the frame are attached to each other using side racks , inside which springs are installed, ensuring reliable fastening of the solar panels between the upper and lower sides of the frame, as well as self-cleaning of the surface of the solar panels from snow and ice, due to slight bending microvibrations caused by the effect of wind on the surface of the solar panels and stretching of the springs installed in the side racks of the frame , and the diesel power unit, which is part of the autonomous energy module No. 1, generates and transmits electricity exclusively to the electric energy storage device, in turn, the wind power plants that are part of the autonomous energy module No. 3 for generating energy, having they include a digital anemometer to measure the direction and speed of the wind, lifting devices that ensure the lifting of wind turbines to different heights in order to use the energy of surface and aboveground winds, as well as the transportation of wind turbines in a folded position, while the wind turbines are transported inside the container in disassembled form , are assembled outside the container in a horizontal position, and then, with the help of winches installed on the container, they rise to a vertical position and are fixed on the end walls of the container; electronic compass, Wi-Fi, 3G, GPRS modem, satellite communication terminal, signal receiver of GLONASS, NAVSTAR, GPS systems and, through digital interfaces, is connected to the electric energy storage unit, diesel generating set, automatic fire extinguishing system ion, ventilation and air conditioning system, converters - chargers from photovoltaic generating systems, wind power plants, microhydroelectric power plants, diesel generating set, monitoring photoelectric sensors, digital anemometer, inverter unit and provides control and display of charge and discharge modes of the electric energy storage, measurement and display of power from primary sources of energy and power delivered to the load, automatic start and stop of the diesel generating set according to a programmed algorithm, control of the parameters of the diesel generating set, control and maintenance of the set temperature inside the container, forecasting the amount of energy generated by primary energy sources, depending on the time of day , season, coordinates of the location of the combined power plant, weather forecast, as well as remote control, diagnosis and management of the operation of the power plant using special software installed on a smartphone, tablet or computer, while the inverter unit provides the output of single-phase and / or three-phase AC voltage, parallel operation with the network of single-phase and / or three-phase AC voltage, charging the electric energy storage device from the network single-phase and/or three-phase AC voltage.

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