CN207936734U - A kind of comprehensive distributed energy resource system of providing multiple forms of energy to complement each other for bakery - Google Patents

Abstract

A multi-energy complementary integrated distributed energy system for a baking room, including: photovoltaic power generation, a gas turbine, a first generator, a solar collector, a waste heat boiler, a steam turbine, a second generator, a waste heat dehumidifier, and a vacuum tube Air collectors, electric heaters, refrigeration equipment, heating equipment, ovens, feedback control systems, motors, batteries, inverters and energy management systems. The utility model can make full use of solar energy, natural gas and other energy sources to provide heat for the factory to bake and generate electricity at the same time to meet the factory's electricity demand and cold and heat demand. Avoid the hidden dangers of food safety caused by harmful substances produced by traditional coal-fired heating, and achieve the goals of safety, efficiency, energy saving and emission reduction.

Description

A multi-energy complementary integrated distributed energy system for baking rooms

technical field

The utility model belongs to the field of energy, in particular to a multi-energy complementary comprehensive distributed energy system for a baking room.

Background technique

Traditional baking rooms mostly use fossil energy such as coal or electric heating for baking, which has low efficiency and high energy consumption, and harmful substances will affect food safety when coal is burned. How to design a safe and efficient heating system is the focus of this patent. Combine the currently commonly used solar energy and natural gas energy to comprehensively provide multiple energy needs such as cold, heat, and electricity. This combination not only guarantees food safety and improves energy efficiency, but also conforms to the country's current concept of energy conservation, emission reduction and sustainable development.

Utility model content

The utility model aims at the deficiencies in the prior art, and provides a multi-energy complementary integrated distributed energy system for a baking room.

In order to achieve the above object, the utility model adopts the following technical solutions:

A multi-energy complementary integrated distributed energy system for a baking room, characterized in that it includes: photovoltaic power generation, a gas turbine, a first generator, a solar collector, a waste heat boiler, a steam turbine, a second generator, a waste heat Dehumidifiers, vacuum tube air collectors, electric heaters, refrigeration equipment, heating equipment, baking rooms, feedback control systems, motors, batteries, inverters and energy management systems;

The photovoltaic power generation utilizes the photovoltaic effect of solar panels to convert light energy into electrical energy;

The gas turbine is connected to the first generator, and the gas turbine burns natural gas to drive the first generator to generate electricity;

The waste heat boiler is respectively connected with the gas turbine, solar collector, steam turbine, and waste heat dehumidifier, the flue gas generated by the gas turbine flows into the waste heat boiler, the solar collector provides heat for the waste heat boiler, and generates high-temperature flue gas to drive the steam turbine to work, and the steam The turbine drives the second generator to generate electricity, and the unused flue gas in the waste heat boiler enters the waste heat dehumidifier;

The waste heat dehumidifier is connected with the vacuum tube air heat collector, and the waste heat dehumidifier dehumidifies the flue gas from the waste heat boiler, generates dehumidified air and flows into the vacuum tube air heat collector;

The vacuum tube air heat collector is respectively connected with the electric heater, baking room, refrigeration equipment, and heating equipment. The vacuum tube air heat collector heats the dehumidified air from the waste heat dehumidifier, and the heated dehumidified air enters the electric heater, oven Grills, refrigeration equipment and heating equipment;

The refrigeration equipment is connected to the cold terminal, and the dehumidified air from the vacuum tube air collector is used to generate cold air for cooling the cold terminal;

The heating equipment is connected to the heat-using terminal, and the dehumidified air from the vacuum tube air collector is used to generate domestic hot water for cooling the heat-consuming terminal;

The electric heater is connected to the baking room, and the electric heater electrically heats the dehumidified air from the vacuum tube air collector, and the heated dehumidified air enters the baking room;

The baking room is connected to the feedback control system, the feedback control system is connected to the vacuum tube air heat collector, the feedback control system collects the temperature in the baking room, and sends instructions to the vacuum tube air heat collector after processing;

The motor is connected to the baking room, and the fan blades of the motor drive group are turned over after power-on, so that the temperature in the baking room is uniform;

The inverters are respectively connected to the battery, photovoltaic power generation, the first generator, the second generator, the motor, the electric heater, and the waste heat dehumidifier. The battery is used to store electricity, and the inverter transmits the electricity to the motor, electric heating device, waste heat dehumidifier;

The energy management system is respectively connected with the photovoltaic power generation, the gas turbine, and the solar heat collector, and the energy management system switches between solar energy and natural gas.

In order to optimize the above technical solutions, the specific measures taken also include:

The baking room is wall-closed by heat-insulating materials, and pipes with openings are evenly arranged on the heat-insulating ground, and dehumidified hot air enters the baking room through the holes.

When the temperature in the baking room reaches the setting, the hot air heated in the vacuum tube air collector directly enters the baking room; when the temperature in the baking room is lower than the setting, the air in the vacuum tube air collector will It will enter the electric heater for heating treatment, and the hot air heated by the electric heater will enter the baking room; when the temperature in the baking room is higher than the set value, the hot air in the vacuum tube air collector will enter the refrigeration equipment and heat supply Equipment for cooling with cold terminal and heating with hot terminal.

The beneficial effects of the utility model are: maximize the use of solar power generation, solar heat collection, and natural gas distributed power stations to realize the combined supply of cold, heat and electricity, which meets the heat consumption of the baking room and the heat, cold and electricity needs of the factory; Solar energy is the mainstay and natural gas is the supplement. Compared with traditional coal-fired heating, carbon emissions are reduced, which is of positive significance for energy development and utilization, protection of the ecological environment and promotion of sustainable development.

Description of drawings

Fig. 1 is the overall schematic diagram of the utility model.

Detailed ways

Below in conjunction with accompanying drawing, describe the utility model in detail.

The multi-energy complementary integrated distributed energy system for the baking room as shown in Figure 1 includes: photovoltaic power generation, gas turbine, first generator, solar collector, waste heat boiler, steam turbine, second generator, waste heat Dehumidifiers, vacuum tube air collectors, electric heaters, refrigeration equipment, heating equipment, ovens, feedback control systems, motors, batteries, inverters and energy management systems.

Photovoltaic power generation utilizes the photovoltaic effect of solar panels to convert light energy into electrical energy to supply power for electrical equipment in the system.

The gas turbine is connected with the first generator, and the natural gas is burned to drive the first generator to supply power for the electrical equipment in the equipment.

The waste heat boiler is connected with the gas turbine, solar collector, steam turbine, and waste heat dehumidifier. The gas turbine and solar collector provide heat for the waste heat boiler, generate high-temperature flue gas to drive the steam turbine to work, and use the second generator as electricity for the system. The equipment is powered, and the unused flue gas of the waste heat boiler enters the waste heat dehumidifier.

The waste heat dehumidifier is connected with the vacuum tube air collector, and the waste heat dehumidifier dehumidifies the air from the waste heat boiler, and the dehumidified air from the waste heat dehumidifier enters the vacuum tube air collector.

The vacuum tube air collector is connected with the baking room, electric heater, refrigeration equipment, and heating equipment. The vacuum tube air collector is used to heat the dehumidified air from the waste heat dehumidifier. The heated dehumidified air can enter the baking room, electric heating Appliances, refrigeration equipment and heating equipment.

The electric heater is connected with the baking room, and the electric heater is used to electrically heat the dehumidified air coming out of the vacuum tube air collector, and the heated dehumidified air enters the baking room.

Refrigeration equipment and heating equipment are respectively connected to the cold terminal and the heat terminal, and the dehumidified air from the vacuum tube air collector is used to generate cold air and domestic hot water to provide cooling for the cold terminal and heat supply for the heat terminal.

The motor is connected to the baking room, and after power on, the fan blades of the drive group are turned over to achieve the purpose of uniform temperature in the baking room.

The baking room is connected with the feedback control system. The wall of the baking room is closed by heat-insulating material, and the pipes with uniform openings are evenly arranged on the heat-insulating floor. The dehumidified hot air enters the baking room through small holes.

The inverter is connected with the storage battery, photovoltaic power generation, the first generator, the second generator, and various electrical equipment, and the storage battery can store excess electricity generated by solar energy. When encountering continuous rainy days or nights, solar power generation cannot work, and the system will use the stored electricity in the battery to reduce the use of natural gas.

The energy management system is connected with photovoltaic power generation, gas turbines, solar thermal collectors. Solar energy provides guarantee for the normal operation of the entire system during the day. When encountering rainy weather or at night, the solar energy at this time can no longer meet the energy needs of the entire system. In order to ensure the normal operation of the system, the energy management system will switch the energy source and use natural gas to generate heat to maintain the normal operation of the system.

The feedback control system is connected to the evacuated tube air collector. In order to maintain a stable temperature in the baking room, the feedback control system collects the temperature in the baking room. When the temperature in the baking room reaches the requirement, the hot air heated in the vacuum tube air collector will directly enter the baking room. When the temperature in the baking room is insufficient, the air in the vacuum tube air collector will enter the electric heater for heating treatment, and the hot air heated by the electric heater will enter the baking room. When the temperature in the baking room is too high, the hot air in the vacuum tube air collector enters the refrigeration equipment and the heating equipment to supply cooling for the cold terminal and heat supply for the hot terminal.

The above are only preferred implementations of the utility model, and the scope of protection of the utility model is not limited to the above-mentioned embodiments, and all technical solutions under the thinking of the utility model all belong to the scope of protection of the utility model. It should be pointed out that for those of ordinary skill in the art, some improvements and modifications without departing from the principle of the utility model should be regarded as the protection scope of the utility model.

Claims (3)

1. A multi-energy complementary integrated distributed energy system for a baking room, characterized in that it includes: photovoltaic power generation, a gas turbine, a first generator, a solar collector, a waste heat boiler, a steam turbine, and a second generator , waste heat dehumidifier, vacuum tube air collector, electric heater, refrigeration equipment, heating equipment, baking room, feedback control system, motor, battery, inverter and energy management system; The photovoltaic power generation utilizes the photovoltaic effect of solar panels to convert light energy into electrical energy; The gas turbine is connected to the first generator, and the gas turbine burns natural gas to drive the first generator to generate electricity; The waste heat boiler is respectively connected with the gas turbine, solar collector, steam turbine, and waste heat dehumidifier, the flue gas generated by the gas turbine flows into the waste heat boiler, the solar collector provides heat for the waste heat boiler, and generates high-temperature flue gas to drive the steam turbine to work, and the steam The turbine drives the second generator to generate electricity, and the unused flue gas in the waste heat boiler enters the waste heat dehumidifier; The waste heat dehumidifier is connected with the vacuum tube air heat collector, and the waste heat dehumidifier dehumidifies the flue gas from the waste heat boiler, generates dehumidified air and flows into the vacuum tube air heat collector; The vacuum tube air heat collector is respectively connected with the electric heater, baking room, refrigeration equipment, and heating equipment. The vacuum tube air heat collector heats the dehumidified air from the waste heat dehumidifier, and the heated dehumidified air enters the electric heater, oven Grills, refrigeration equipment and heating equipment; The refrigeration equipment is connected to the cold terminal, and the dehumidified air from the vacuum tube air collector is used to generate cold air for cooling the cold terminal; The heating equipment is connected to the heat-using terminal, and the dehumidified air from the vacuum tube air collector is used to generate domestic hot water for cooling the heat-consuming terminal; The electric heater is connected to the baking room, and the electric heater electrically heats the dehumidified air from the vacuum tube air collector, and the heated dehumidified air enters the baking room; The baking room is connected to the feedback control system, the feedback control system is connected to the vacuum tube air heat collector, the feedback control system collects the temperature in the baking room, and sends instructions to the vacuum tube air heat collector after processing; The motor is connected to the baking room, and the fan blades of the motor drive group are turned over after power-on, so that the temperature in the baking room is uniform; The inverters are respectively connected to the battery, photovoltaic power generation, the first generator, the second generator, the motor, the electric heater, and the waste heat dehumidifier. The battery is used to store electricity, and the inverter transmits the electricity to the motor, electric heating device, waste heat dehumidifier; The energy management system is respectively connected with the photovoltaic power generation, the gas turbine, and the solar heat collector, and the energy management system switches between solar energy and natural gas. 2. A multi-energy complementary integrated distributed energy system for a baking room as claimed in claim 1, characterized in that: the baking room is sealed by walls with heat insulating materials, and the heat insulating ground is evenly arranged There are pipes with openings, and the dehumidified hot air enters the baking room through the holes. 3. A multi-energy complementary integrated distributed energy system for a baking room as claimed in claim 1, characterized in that: when the temperature in the baking room reaches the set value, the heating in the vacuum tube air collector The hot air directly enters the baking room; when the temperature in the baking room is lower than the setting, the air in the vacuum tube air collector will enter the electric heater for heating treatment, and the hot air heated by the electric heater will enter the baking room. room; when the temperature in the baking room is higher than the setting, the hot air in the vacuum tube air collector enters the refrigeration equipment and heating equipment to provide cooling for the cold terminal and heat for the hot terminal.