KR20120138787A - All-weather energy-saving method and device for refrigerator and all-weather energy-saving refrigerator - Google Patents

Abstract

The present invention relates to a kind of a multi-energy power refrigerator and a method for controlling the power, and the main problem to be solved by the present invention is to perform integrated switching control through electric energy such as various low pressure energy, and then, after rectifying city electricity, It is intended to realize the compatibility of various kinds of energy of the refrigerator by boosting it with a slightly higher DC electric current and connecting it to various inverters and compressors which are commonly used at present. The present invention includes an MCU, a city electric power module, a low voltage energy power module, a battery power module, and an electric appliance control circuit. The three power modules and the electric appliance control circuit are all connected to the MCU, and the three power modules are parallel to each other. After the connection, it is connected to the integrated switching module, the integrated switching module is connected to the electric appliance control circuit, the integrated switching module is connected to the MCU, which is a kind of multi-energy power refrigerator in which the MCU intensively controls three power modules and the electric appliance. to provide. The multi-energy power supply control system of the present invention can realize compatibility with various types of energy of the refrigerator, greatly reduce the cost, and improve the safety and currency of the product.

Description

Multi-energy power refrigerator and its control method {ALL-WEATHER ENERGY-SAVING METHOD AND DEVICE FOR REFRIGERATOR AND ALL-WEATHER ENERGY-SAVING REFRIGERATOR}

The present invention relates to a kind of multi-energy power refrigerator and a power control method thereof.

In recent years, with the development of low pressure energy and increasing demand for low pressure refrigerators, the research and development and mass production of such refrigerator products have already been adopted on the agenda. The low pressure frequency variable compressor and its drive controller currently used are expensive, inferior in safety, and incompatible with each other.

The main problem to be solved by the present invention is to control the electrical energy, such as various low-pressure energy, and then integrated into the DC electricity slightly higher than the direct current after rectifying the city electricity, to various inverters and compressors that are commonly used now By connecting to finally to implement the compatibility for various energy of the refrigerator.

In order to solve the above problems, the present invention includes an MCU, an urban electric power module, a low voltage energy power module, a battery power module, an electric appliance control circuit, and all three power modules and an electric appliance control circuit are connected to the MCU. The three power modules are connected in parallel to each other and then to the integrated switching module. The integrated switching module is connected to the electric appliance control circuit. The integrated switching module is connected to the MCU so that the MCU intensively controls the three power modules and the electric appliance. To provide a kind of multi-energy power refrigerator.

The integrated switching device includes a switching switch which is connected to the MCU and automatically switches the switch by performing a voltage sampling comparison on three power modules.

The energy switching device is provided with two control modes, an automatic control mode and a manual switching mode, respectively.

The electric control circuit is installed as a DC power supply control circuit.

A boost module is installed between the battery power module and the integrated switching module.

The low voltage power module is preferably installed as a solar energy module power source.

The solar energy module is connected to the city electric power module and the battery power module, respectively.

The control method of the multi-energy power refrigerator of the present invention includes the following steps:

1) power on the refrigerator to start operation;

2) the MCU samples the low voltage energy power module, the battery power module, and the city electric power module, respectively, and enters step 3 if the voltage of the low voltage energy power module is greater than the set value; If less than the set value, step 6 is entered;

3) the MCU detects whether it is necessary to power the low voltage load and, if necessary, energizes the circuit of the low voltage load; If no, go to step 4;

4) transfer the low-energy energy electric energy to the storage battery through the battery control circuit, and then step up through the boosting module and enters step 5;

5) transfer electrical energy to the appliance control circuit via the integrated switching module and return to step 1;

6) The MCU controls the switching of the low-voltage energy power supply module, energizes the city electric power supply module, and then enters step 5.

The present invention can supply power to a refrigerator using various low pressure energy such as photovoltaic cells. In addition, in a condition where there is no energy storage device such as a storage battery, a low voltage energy power supply method may be used alone, or a combined power supply method in which a storage battery is added to low pressure energy may be used. The present invention uses a variety of low-voltage energy, such as photovoltaic cells, and boosts it to a direct current 320V to supply to the inverter, and if the power supply of such energy is insufficient, supplement the energy of the battery, and if the energy of the battery is also insufficient city electricity And power supply by mixing the battery, and supplying power to the city electricity when the battery is completely discharged so that the refrigerator can be operated in the cooling control state all the time.

The present invention controls the charging and discharging of the battery and collects low power, so that various low voltage energy can supply power to the electric appliance through the battery. If the maximum output voltage of low-voltage energy is selected below the maximum voltage that the battery will allow for constant connections, the overcharge problem can be essentially prevented. When the cell needs to be charged at a high current, energizing the relay can reduce the energy loss caused by the pressure drop on the diode. Since the low-voltage energy output close to the maximum voltage of the battery is directly connected to the battery through a diode, even if the controller fails, the battery can be charged, thereby effectively preventing the battery from being damaged due to severe power shortage. When the electric current of the battery is insufficient and constant current charging is required, the charging current can be expanded by increasing the voltage in the boost circuit. In order to prevent line damage due to high current transmission, the current is transferred after the power is boosted. If there is no low voltage energy output for a long time and the battery is automatically discharged and affects the battery life, the MCU will control the output voltage to the maximum of the city's power output below the maximum voltage that allows the battery to be connected all the time. This prevents the battery from being damaged by severe power shortages. If not enough power is supplied to the battery, the booster circuit will stop to prevent damage to the battery due to over discharge. Controlling charging and discharging of the battery and collecting low power is as shown in FIG. 2, and FIG. 2 includes a charge and discharge control process of the battery. The process of initializing the charge control of the battery is illustrated in FIG. 3, which includes detecting and processing a voltage value of the low pressure energy and a battery voltage value. The flow chart of the continuous charge control process is as shown in FIG. 4. In accordance with the voltage and current conditions of the battery, constant current charging is performed on the battery in a forward and backward order, and the constant current charging is floating charged.

The low pressure energy of the present invention is directly connected to the electric appliance through a step-up or step-down process to supply power to the load. The low pressure energy is subjected to a high pressure step-up process or a step-down process, and can directly supply electric power to an electric appliance in a condition where there is no energy storage device such as a storage battery. When selecting the capacity and power size of the low pressure energy, the output function of the energy must be greater than the rated power of the electric appliance. In the control method, real-time detection of the output power size of the energy is performed, and when the low pressure energy is the maximum power point. Intelligent operation of the voltage and current conditions, so that the low-voltage energy can be operated at the maximum output power state, and when the output power of the energy is less than the rated power of the electric appliance, the multi-energy inverter board sends a preliminary alarm signal to the user. Appropriate processing is performed on the input low voltage energy, while the city electric power is connected, so that the electric appliance is in a normal operation state for a long time.

The present invention was designed to control all the control circuits of all the common components of the refrigerator by a DC power supply, and to supply low-pressure energy directly to various electric appliances, including a DC-AC conversion module. In order to further enhance the application and dissemination of multi-energy refrigerators and to improve various performance indicators of refrigerators, the control circuits of all electric appliance components such as defrost heaters, lamps, and solenoid valves are designed with DC power, and also different processes According to the requirements, energy control such as local linear control is performed on the rotational speed, power, brightness, and the like. At the same time, a DC-AC conversion module is provided in the multi-energy inverter board, and the high-voltage direct current electricity after boosting the low voltage energy is inverted to 220V AC electricity and supplied to an electric appliance such as a rated compressor, a lamp, a solenoid valve, and the like. In this case, the multi-energy inverter plate has very large compatibility and currency with respect to various other AC direct current electric appliances.

The city electricity and the high-voltage booster circuit switching circuit of the present invention can realize manual switching and automatic switching of the two circuits after sampling and comparing the DC voltage after rectifying the city electricity and the voltage after boosting the low voltage power supply. In the manual switching mode, the user selects the power supply method, and in the automatic switching mode, when the electrical energy of the low voltage energy is satisfied and the energy is sufficient to be provided to the next load, it is automatically switched to the high voltage boost circuit, and the low voltage energy If the electrical energy is insufficient, that is, after outputting the electrical energy after rectifying the city electricity to supply power. Here, the concrete implementation process is to supply the voltage after boosting using low voltage energy to an inverter when the voltage value boosted by high voltage is larger than the voltage value after rectifying city electricity.

The multi-energy power supply control system of the present invention can realize compatibility with various types of energy of the refrigerator, greatly reduce the cost, and improve the safety and currency of the product.

1 is a control flowchart of a multi-energy power supply control system.
2 is a structural block diagram of a refrigerator.

As shown in Figure 2, the present inventors multi-energy power refrigerator, MCU, city electric power module (1), low-voltage energy power module (2), battery power module (3), electric appliance control circuit (4), integrated switching It includes a module (5), three power modules are connected in parallel to each other and then connected to the electrical appliance control circuit (4) through an integrated switching module (5), MCU each of the three power supply module, electrical appliance control circuit (4) ) And integrated switching module (5), the MCU intensively controls the three power modules and electrical appliances. The low voltage energy power module 2 is connected to the city electric power module 1 and the battery power module 6, respectively, the low voltage energy power module 2 is a low-voltage energy, such as photovoltaic cells, for example, solar energy module Can be installed and used. The electric appliance control circuit 4 is provided as a DC power supply control circuit, and includes a control loop necessary for adjustment of frequency, rotational speed, power, voltage, and current, and all of them can perform linear control through PWM. A boosting module is installed between the battery power supply module 3 and the integrated switching module 5, and the integrated switching module 5 is provided with a changeover switch, and the changeover switch is connected to the MCU. The integrated switching module 5 can be installed in two control modes, namely, automatic control mode and manual switching mode through the changeover switch. The integrated switching module 5 converts the DC voltage and the low-voltage power supply to the high voltage after rectifying the city electricity. After switching and sampling the voltage after boosting, two circuits are manually switched and automatic switching is realized.In the manual switching mode, the user selects a power supply method, and in the automatic switching mode, low voltage energy is satisfied and electric energy is satisfied. When is enough to provide to the next load, it is automatically switched to the high-voltage boost circuit, and if the low-energy energy lacks, the electric energy after rectifying the city electricity is supplied to supply power. The refrigerator adopting such a structure can realize compatibility with various energy to lower the cost and improve the safety and currency of the product.

1 is a control flowchart of a multi-energy power control system. When the refrigerator is turned on and the refrigerator starts operation, the voltage sampler performs sampling on the low voltage energy power module, the battery power module, and the city electric power module, respectively. When the voltage of the low voltage energy power module is higher than the set value, the MCU detects the power to be supplied to the low voltage load, energizes the circuit with the low voltage load, and detects that the MCU does not need to supply power to the low voltage load. The low voltage energy is transferred to the storage battery through the circuit, and the low voltage electric energy is boosted through the boosting module, and then the electric energy is transferred to the electric appliance control circuit through the integrated switching module to supply power to the low pressure load, and to supply power. After this is finished, the refrigerator returns to the initial operating state. If the voltage of the low voltage energy power supply module is lower than the set value, the MCU controls the interruption of the low voltage energy power supply module, connects the city electric power supply module, and transfers the electric energy to the electric appliance control circuit through the integrated switching module. After the power supply is terminated, the refrigerator returns to its initial operating state. By supplying power to the refrigerator in this way, compatibility with various energy can be realized.

.

Claims (8)

In a kind of multi-energy power refrigerator having a MCU, a city electric power module, a low voltage energy power module, a battery power module, and an electric appliance control circuit, all three power modules and an electric appliance control circuit are connected to the MCU.
The three power modules are connected in parallel to each other and then to the integrated switching module, the integrated switching module is connected to the electric appliance control circuit, and the integrated switching module is connected to the MCU so that the MCU intensively controls the three power modules and the electric appliance. A kind of multi-energy power refrigerator, characterized in that. The method of claim 1,
Integrated switching device is provided with a changeover switch, characterized in that the switch is connected to the MCU multi-energy power refrigerator. The method of claim 1,
Multi-energy power refrigerator, characterized in that the energy switching device is provided with two control modes divided into automatic control mode and manual switching mode respectively. The method of claim 1,
The electric appliance control circuit is a multi-energy power refrigerator, characterized in that installed as a DC electric power control circuit. The method of claim 1,
Multi-energy power refrigerator characterized in that the boosting module is installed between the battery power module and the integrated switching module. The method of claim 1,
Low-voltage power module is a multi-energy power refrigerator, characterized in that installed as a solar energy module. The method of claim 1,
Solar energy module is a multi-energy power refrigerator, characterized in that connected to the city electric power module and the battery power module, respectively. In the control method of the multi-energy power refrigerator of claim 1,
Power on the refrigerator to start operation;
The MCU samples each of the low voltage energy power module, the battery power module, and the city electric power module, and enters step 3 if the voltage of the low voltage energy power module is greater than the set value; If less than the set value, step 6 is entered;
The MCU detects whether it is necessary to power the low voltage load and, if necessary, energizes the circuit of the low voltage load; If no, go to step 4;
After transferring the low-energy energy electric energy to the storage battery through the battery control circuit, and step-up through the boosting module and enters step 5;
Transfer the electrical energy to the appliance control circuit via the integrated switching module and return to step 1;
The MCU controls the switching of the low-voltage energy power module to energize the city electric power module, and then enters step 5; Control method of a multi-energy power refrigerator comprising a step.

Images