KR20150131335A - A system for management of electric energy produced by photovoltaic cells - Google Patents

Abstract

There is provided a management system for electric energy generated by a solar cell including an energy consumption control unit 2, a control unit 8 and a heating unit 9 interconnected with each other, and the heating unit 9 is provided with a temperature measurement unit The essence of the present invention is that the energy consumption control unit 2 includes a DC control unit 21 and an AC control unit 22, and at least one heating element 92, And is connected, in part, primarily to the AC power supply 10 via a direct and / or secondary AC voltage source 12 and is connected in part via a primary DC voltage source 6 and / The control unit 8 is connected to the photovoltaic unit 1 which emits a DC voltage through a series connection of a DC / DC converter 4 and a current and voltage input measuring unit 3, Is connected to the photovoltaic unit 1 through the secondary DC voltage source 7 separated by a galvanic method As well, it is that connected to the AC power supply 10 through the primary AC voltage source 11 is separated by a galvanically.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a system for managing electric energy generated by a solar cell,

The present invention is embodied in the area for efficiently utilizing renewable energy resources when solar radiation is converted into electricity or thermal energy with the aid of a photovoltaic device, To an arrangement of a management system of electrical energy generated by a solar cell, including electronic components interconnected to each other to enable storage.

The entire range of systems using energy generated by solar cells is known. For example, documents US4873480A, FR2485827A1, and US4649334A disclose an apparatus for controlling electrical energy with the aid of interconnected electronic components and for controlling the electrical output of the solar panel to a device designed for energy storage in an electric distribution system or Different systems that can be transferred to the device are described. Also, if fully used, an autonomous energy system is known that stores only the energy obtained from the solar panel, and ultimately the surplus energy, in an accumulator or other energy storage. One of the most commonly used solutions for the control of electrical energy is to install the inverter in the system. The inverter converts the DC current to an AC current and enables the resulting connection of the system to the electrical system, which ultimately consumes energy in the apparatus, similar to when it is connected to the distribution system. In order to increase efficiency, inverters are known which utilize monitoring of the point of maximum power MPPT (maximum power point tracking). If all the generated energy is consumed and no load is supplied to the external distribution system, or if the obtained load is supplied to the electric system and combined with the self-consumption, the system equipped with such an inverter can be operated in the operation mode Lt; / RTI > The disadvantage of such a system is the fact that energy conversion results in losses to the inverter.

From the document CZ20110582 A3, a method for efficiently transferring a photovoltaic generator load to a resistive load and a device for carrying out such a method are known, the output load of the photovoltaic generator is stored in a capacitor, To the resistive load. The switching of the DC / DC converter is performed by pulse width modulation (PWM) controlled by an algorithm dependent on the height of the AC voltage on the output of the photovoltaic generator, while the instantaneous value of the load is determined continuously do. A disadvantage of this solution is the system arrangement in which the capacitors are basically permanently connected to the source and then the DC / DC converter is connected to the resistive load with the aid of PWM regulation. This creates a rectangular path of voltage and current given by the frequency PWM with respect to the load and a value of the voltage for each capacitor of the load, which is very disadvantageous from an interference point of view. The PWM setting is derived from the input voltage and resistive load of the panel. If the resistance value is changed, the algorithm used is very inaccurate. Moreover, the energy processed in this manner can not be substantially used except for the thermal deformation of the resistive load. Finally, high-voltage stresses on the capacitors negatively affecting the lifecycle are provided. A further disadvantage of such a system is that there is no arbitrary regulating circuit to make more use of the energy obtained in this way.

Water is a very suitable medium for storing the generated energy. In the home, for example, in order to prepare a service hot water, an electric heater based on the principle of a water storage container and a heating unit for warming the water are used. In the documents CZ25157 U1, CZ22505 U1, CZ22504 U1, US7429719 B1, and FR2604322 A1, an apparatus for using electric energy generated from solar panels for water heating is described. A disadvantage of this solution is that the maximum power point (MPPT) is not monitored, which causes the resistance of the device not to be adjusted to the resistance of the source, and that the energy system can not efficiently use the obtained load . Although the document US5293447 describes a system for monitoring the maximum load being done by switching the resistive load of two values, such a device is implemented in so-called autonomy mode when only the energy obtained from the solar panel is used Do not allow.

It is an object of the present invention to introduce a new system for the management of electric energy generated by a solar cell which can efficiently use the electric energy obtained in the DC mode especially when the energy loss is not caused by the DC to AC conversion will be. These systems are tuned to monitor the point of full load MPPT, and these systems are equipped with devices designed to use excess energy, and where necessary, electronic components used for the conversion of DC-AC are employed. The system is also controllable from a superior control system and can operate in an autonomous energy mode.

The set goals are achieved by the present invention, which is a system for managing electrical energy generated by a solar cell comprising an energy consumption control unit, a control unit and a heating unit interconnected to a considerable extent, And at least one heating element which is deformed for heating of the liquid is employed and the essence of the present invention is that the energy consumption control unit comprises a DC control unit and an AC control unit and is partly directly and / Is connected to the AC power supply and emits a direct current, in part through a primary DC voltage source and / or a series connection of an output measuring unit of current and voltage, a DC / DC converter and an input measuring unit of current and voltage While the control unit is connected to the solar unit via a secondary DC voltage source separated by a galvanic method, As well as to be connected, through the primary AC voltage source it is separated by the fact that the galvanically connected to the AC power supply.

This is advantageous when the DC control unit of the energy consumption control unit operating in the DC voltage mode is composed of a DC thermal fuse and a DC relay, while the DC relay is connected to the DC temperature controller, The measuring unit is connected to the DC / DC converter, and the DC relay is connected to the heating unit.

Likewise, this is advantageous when the AC control unit of the energy consumption control unit operating in the mode of AC voltage is configured as an AC thermal fuse and an AC relay, while the AC relay is connected to the AC temperature controller, And the AC relay is interconnected with the heating unit.

In the optimal case, the DC thermal fuse and the AC thermal fuse of the energy consumption control unit are interconnected to each other via a control safety segment, while the control safety segment includes a temperature measurement unit, a fuse, a DC power relay and an AC The power relay is connected.

In an advantageous design, the DC / DC converter comprises a primary switch and a secondary switch which are connected in part to a primary DC voltage source, partly connected to the control unit and partially interconnected to one another, A parallel circuit is formed with an integrated inductive element in which the capacitor and the load are connected in parallel.

It is also characterized in that in the energy consumption control unit, a charging relay and a charging controller are partly formed and a charging unit connected to at least one energy accumulator is mounted, while the energy accumulator is transformed to supply energy to the grid Which is advantageous when interconnected with an inverter.

In the optimum case, the additional module is connected to a control unit which is configured as a UPS relay at the same time as the energy consumption control unit, and the input measuring element of the current and the UPS control unit are connected in parallel to the UPS relay, , The UPS relay is interconnected with the inverter, and the inverter is realized as a UPS type with dual conversion in favorable design.

Finally, this means that a communication module for providing communication with a detector and / or a superior system of smart remote control for the detection of off-peak electricity in the control unit is employed, The unit is advantageous when a memory medium for recording the working order of the system is mounted.

Systems for the management of electrical energy generated by solar cells are specifically designed for efficient use of the electrical energy obtained when energy is used in direct current mode and can be monitored with a DC / DC converter to monitor the point MPPT of maximum load. The present invention is more efficient than the prior art. The system is also designed to use excess energy when energy is classified as an accumulator and / or used for liquid heating, and at the same time is also used to convert a direct current obtained from a solar panel to an alternating current.

Specific examples of the present invention are schematically illustrated in the accompanying drawings.
Figure 1 is a block diagram of a configuration for water heating of the system.
2 is a block diagram of the overall configuration of the system.
3 is a diagram of a DC / DC converter.
4 is a block diagram of a thermal fuse.
The drawings illustrating the present invention and consequently the examples of specific designs do not limit the expansion of the protection referred to in the definition in any case, but clarify the nature of the invention.

The system for the management of the electrical energy produced by the solar cell comprises a solar unit 1 connected in parallel with the energy consumption control unit 2 in the basic autonomy set according to figure 1, The optical unit 1 is partly made through a series connection of the current and voltage input measuring unit 3, the DC / DC converter 4 and the current and voltage output measuring unit 5, Is performed through the voltage source (6). The DC / DC converter 4 is designed in such a way that the maximum load is always permanent, and further connected to the DC primary voltage source 6 and the control unit 8. The control unit 8 is then connected to the solar light unit 1 via the DC secondary voltage source 7 which is connected to the energy consumption control unit 2 and also separated by a galvanic method of DC voltage. The energy consumption control unit 2 includes two heat control units 21 and 22 connected to the heating unit 9. [ The heating unit 9 is connected to the control unit 8 at the same time while the temperature measuring unit 91 and the heating element 92 designed for heating the liquid are formed. A DC thermal fuse 211, a DC relay 212 and a DC temperature controller 213 are formed in the DC control unit 21 of the energy consumption control unit 2 operating in the DC voltage mode, while the DC control unit 21 21 are connected to the DC / DC converter 4 through the output measuring unit 5. [ The AC control unit 22 of the energy consumption control unit 2 is composed of an AC thermal fuse 221, an AC relay 222 and an AC temperature controller 223 and is connected to the power supply 10 of the AC voltage. The AC power supply 10 is then connected to the control unit 8 via an AC primary voltage source 11 separated in part by a galvanic method of AC voltage and is connected in part via an AC secondary voltage source 12 The total energy consumption control unit 2 is connected.

2, a charge relay 231 and a charge controller 232 are formed in a system operating in an autonomy and also in an island energy mode, and a built-in charging unit 231 connected to the energy accumulator 13, The accumulator 13 is connected to the inverter 15 which provides the alternating current supply part, while the energy consumption control unit 2 with the power supply 23 is mounted. An additional module 14 consisting of a UPS relay 141 connected in parallel with the lead current measuring element 142 and the UPS control unit 143 is connected to the energy consumption control unit 2 while the additional module 14 ) Is also connected to the current inverter (15). The control unit 8 then employs a smart remote control detector 17 for the detection of the partly off-peak current and is connected in part to a selected interface such as USB, Ethernet, RS232, RS485, WiFi, A communication module 18 is employed to provide communication with the upper system with the help of a memory medium 18 for partially recording the working order of the system, for example the amount of energy generated, current, voltage or temperature, (19) is employed.

As shown in Figure 3, the DC / DC converter 4 includes an interconnected primary switch 41 and a secondary switch 42, which are formed of transistor-type N MOSFETs operating in two states, either on or off do. A parallel circuit with the built-in inductive element 43, in which the capacitor 44 and the load 45 are connected in parallel, is formed around the secondary switch 42.

4 illustrates the design of the thermal protection portion in which the mutually integrated DC thermal fuse 211 and the AC thermal fuse 212 of the energy consumption control unit 2 are formed. The thermal fuses 211 and 212 include a control protection segment 100 that is operated from a DC primary voltage source 6 and / or an AC secondary voltage source 12, while the control protection segment 100 includes a temperature measurement unit 101 ), A fuse 102, a DC power relay 103 and an AC power relay 104 are connected.

The DC generated in the solar unit 1 proceeds partly to the current and voltage input measuring unit 3 and then to the DC / DC converter 4 and partly through the DC secondary voltage source 7 Unit 8 and partially connected to the energy consumption control unit 2 and also to the DC / DC converter 4 via the DC primary voltage source 6. [ The function of the synchronic DC / DC converter 4 is that the two serial-connected switches 41, 42 are turned on when the current does not advance to the secondary switch 42 when the input voltage is the ON position of the primary switch 41, 42, but is moved to the capacitor 44 and the load 45 through the parallel circuit via the inductive element 43. [ Inductive element 43 acts like a device, and a linear increase in current and a voltage growth occur on capacitor 44. The secondary switch 42 is turned on at the same time when the primary switch 41 is off and the current flows from the inductive element 43 to the capacitor 44 and the load 45, The inductive element 43 begins to act as a source, and the voltage polarity is switched accordingly. This process is repeated periodically at f frequency. To find the maximum efficiency point of the MPP, the voltage on the load 45 can be changed from 0 to U _FV by changing the on / off period of the particular switch 41,42. The actual value of the current and voltage is calculated from the solar unit 1 and the output taken from the solar unit 1 is calculated at each moment while the output voltage is calculated from the maximum output generated by the solar unit 1 The time of the ON state of the switches 41 and 42 is changed so as to correspond to the requirements of Fig. The output current from the DC / DC converter 4 is transmitted to the DC control unit 21 of the energy consumption control unit 2 via the output measurement unit 5 of the current and voltage. The energy processed by this method proceeds to the energy consumption control unit 2, while the control unit 8 decides on the use of additional energy. The main unit of energy supplied from either the solar unit 1 or the AC power supply unit 10 is the heating unit 9 while the DC control unit 21 and the AC control unit 22 are connected to the A DC secondary voltage source 7 and also an AC primary voltage source 11 and also an energy consuming circuit for separating DC and AC when the DC relay 212 and the AC relay 222 that ensure the strength of the voltage are mounted. The galvanic separation is performed in the control unit 2. [ The temperature controllers 213 and 223 of the control units 21 and 22 are turned on when the temperature of the heating unit 9 is lower than the value set by the user and the AC relay is switched on and the heating element 92 ). ≪ / RTI > When the DC relay 212 is switched on, energy is transferred from the solar unit 1 to the connected heating element 92. In this way, the user uses energy from the AC power supply unit 10 to heat the water when the energy from the sun is not sufficient or when a low tariff of electrical energy is measured by the detector of the smart remote control . When the temperature of the heating unit 9 reaches the required value, the heating from the AC power supply unit 10 is terminated, and the energy obtained from the solar light unit 1 is used for another purpose. The energy obtained from either the solar light unit 1 or the AC power supply unit 10 may be connected to the charging unit 23 and / or directed to the additional module 14 in the energy consumption control unit. In the charging unit 23 the energy is transferred to the charging relay 231 controlled by the charging controller 232 while the accumulator 13 is in the middle for the supply of energy to the inverter 15 and further to the grid 16. [ The charging relay 231 charges the accumulator 13 connected in the form of various types of batteries. In the additional module 14, the energy is transferred through the current measuring input device 142 and the UPS relay 141 and then to the inverter 15, while the UPS relay 141 is connected to the UPS control unit 143, . The additional module 14 makes it possible to charge the accumulator 13 using the DC / DC converter 4 and to take advantage of the possibility of using the solar unit 1 in the MPP with it. The next function of the additional module 14 is to monitor the current passing through one phase of the inverter 15 and the switching in the event of exceeding the set load for switching, . In this case, the inverter 15 is realized by a UPS type having a double conversion. Therefore, when the power supply of all the components of the system is doubled, the system enables back-up of one phase by the help of UPS and control of energy flow. All control of the system is performed by the control unit 8 which transmits and evaluates information from the DC / DC converter 4, the energy consumption control unit 2, the additional module 14 and the detector 17 of the smart remote control All.

The present invention is based on the finding that while the energy obtained from the solar cell can be efficiently used and at the same time lower energy can be used from the distribution network while the energy supplied to the system can be used for heating water or charging the accumulator, It is designed to integrate into a solar system to achieve use.

1 Photovoltaic unit
2 Energy consumption control unit
21 DC control unit
211 DC thermal fuse
212 DC relay
213 DC temperature controller
22 AC control unit
221 AC thermal fuse
222 AC Relay
223 AC temperature controller
23 Charging unit
231 Charge relay
232 charge controller
3 Input current and voltage measurement unit
4 DC / DC converter
41 Primary switch
42 Secondary switch
43 inductive element
44 Capacitors
45 load
5 Current and voltage output measurement unit
6 Primary DC voltage source
7 Secondary DC voltage source
8 control unit
9 Heating unit
91 Temperature measuring unit
92 heating element
10 AC power supply
11 Primary AC voltage source
12 Secondary AC voltage source
13 Accumulator
14 Additional modules
141 UPS relay
142 Input of current measurement element
143 UPS control unit
15 Inverter
16 grid
17 Smart remote control detector
18 communication module
19 Memory media
100 Control Safety Segment
101 Temperature measuring unit
102 fuse
103 DC power relay
104 AC power relay

Claims (11)

A control system for electric energy generated by a solar cell including an energy consumption control unit (2), a control unit (8) and a heating unit (9) interconnected with each other, wherein the heating unit (9) 91) and at least one heating element (92) which is deformed for liquid heating,
The energy consumption control unit 2 includes a DC control unit 21 and an AC control unit 22 and is connected to the AC power supply 10 partly directly and / or via a secondary AC voltage source 12 , Through a series connection of the primary DC voltage source 6 and / or the current and voltage output measuring unit 5, the DC / DC converter 4 and the current and voltage input measuring unit 3, in part, The control unit 8 is connected not only to the photovoltaic unit 1 via the secondary DC voltage source 7 separated by the galvanic method, , And is connected to the AC power supply (10) through a primary AC voltage source (11) separated by a galvanic method. The method according to claim 1,
The DC control unit 21 of the energy consumption control unit 2 operating in the DC voltage mode is constituted by the DC temperature fuse 211 and the DC relay 212 connected to the DC temperature controller 213, A thermal fuse (211) is connected to the DC / DC converter (4) via the output measuring unit (5), and the DC relay (212) is interconnected with the heating unit (9). The method according to claim 1,
The AC control unit 22 of the energy consumption control unit 2 operating in the AC voltage mode is composed of an AC relay 222 connected to the AC temperature fuse 221 and the AC temperature controller 223, Wherein the thermal fuse (221) is connected to the AC power supply (10), and the AC relay (222) is interconnected with the heating unit (9). 4. The method according to any one of claims 1 to 3,
The DC thermal fuse 211 and the AC thermal fuse 212 of the energy consumption control unit 2 are interconnected to each other via the control safety segment 100 while the control safety segment 100 is provided with a temperature measurement Unit 101, the fuse 102, the DC power relay 103 and the AC power relay 104 are connected. 5. The method according to any one of claims 1 to 4,
The DC / DC converter 4 is connected in part to the primary DC voltage source 6 and is connected in part to the control unit 8 and comprises a primary switch 41 and a secondary switch And a parallel circuit having an integrated inductive element 43 in which a capacitor 44 and a load 45 are connected in parallel is formed around the secondary switch 42. [ . 6. The method according to any one of claims 1 to 5,
The energy consumption control unit 2 is provided with a charging relay 231 and a charging controller 232. The electric energy management system 22 is equipped with a charging unit 23 connected to at least one energy accumulator 13, . The method according to claim 6,
Wherein the energy accumulator (13) is interconnected with an inverter (15) that is transformed to supply energy to the grid (16). 8. The method according to any one of claims 1 to 7,
An additional module 14 consisting of a UPS relay 141 is connected to the control unit 8 at the same time as the energy consumption control unit 2 and the UPS relay 141 is connected to a current input measuring device 142 and / The input measuring element 142 is connected to the AC power supply 10 while the UPS relay unit 141 is connected to the inverter 15 in parallel, Management system. 9. The method of claim 8,
The inverter (15) is implemented as a UPS type with dual conversion. 10. The method according to any one of claims 1 to 9,
Wherein the control unit (8) is equipped with a smart remote control detector (17) for detection of off-peak current and / or a communication module (18) for providing communication with an upper system. 11. The method according to any one of claims 1 to 10,
Wherein the control unit (8) is equipped with a memory medium (19) for recording a working order of the system.

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