Electric peaking combined heat and power (CHP) waste heat recovery device and operating method thereof

Abstract

The invention relates to an electric peaking combined heat and power (CHP) waste heat recovery device and an operating method thereof. The device comprises an inner power plant portion and a heat exchange station portion, wherein the inner power plant portion comprises a heat exchanger, a waste heat recovery electric heat pump, an energy-storing electric heat pump, high/low temperature water storing tanks, a heating network heater, a valve and a circulating water pump; the heat exchange station portion mainly comprises high/low temperature water storing tanks, an electric heat pump, a heat exchanger, a valve and a circulating water pump; as for the operating method of the device, the device can operate in periods of an electrical load trough, an electrical load flat peak and an electrical load peak respectively through combination of different valve switches, the high temperature water storing tank is used for balancing the difference between system heat supply amount and heating load, the low temperature water storing tank is used for stabilizing steam exhaust waste heat recovery amount, thereby, the problem that the electricity generation peaking capacity is limited due to mutual coupling of electricity generation and heat supply in traditional operating modes of 'heat determines electricity' is solved, a CHP unit can participate in power grid load regulation, the power grid regulating capacity can be improved so as to deal with the condition of constantly increasing of electrical load trough-to-peak difference, and the absorptive capacity of a power grid for wind power generation can be improved so as to reduce phenomena of 'fan suspending'.

Description

technical field [0001] The invention relates to a heat exchange device and its operation method, in particular to a power peak-shaving cogeneration waste heat recovery device and its operation method which utilize heat storage technology combined with heat and power cogeneration and power plant waste heat recovery, and belong to energy power technology field. Background technique [0002] The northern regions of my country belong to wind energy-rich regions. Wind power generation is developing rapidly in these regions. The installed capacity of wind power is increasing year by year, and the proportion of installed capacity of wind power to the total installed capacity is also increasing year by year. However, wind power generation has the characteristics of anti-load, that is, the output of wind power is larger during the low load of the power grid at night, and the output of wind power is smaller during the peak power consumption of the grid during the day. At the same tim...

AI Technical Summary

Problems solved by technology

At the same time, the peak-to-valley difference of electric load is also expanding year by year, which makes it difficult for the power grid to regulate peak load.

[0003] At present, urban heating in northern my country still relies heavily on coal-fired boilers, resulting in high energy consumption and high pollution for heating.

Combined heat and power generation is an efficient heat supply method. However, my country's thermal power plants operate in the way of "heating power". In order to ensure heat supply, many thermal power plants have greatly limited their power output adjustment range. During the trough period, its power generation cannot be suppressed, thus seizing the space for wind power generation to be connected to the grid, so t

Images