SU1630683A1 - Heat supply system of block hothouses - Google Patents

Abstract

The invention relates to agriculture and can be used in district heating systems for greenhouse plants. The aim of the invention is to increase the efficiency of heat supply process control and increase the coefficient of action of the heat supply source under alternating heat loads. The device contains a heat supply source 1 with a load regulator 2, an integrating-differentiating link 3, direct 4 and return pipelines 5 of heating water, a flow sensor 6, a meteo-factor sensor 7, two filters — a high-frequency 8 and a low-frequency 9, a regulator 10, a throttling valve 11, controller 12, bypass valve 13 and water temperature sensor 14. The change in meteorological factors is converted by sensor 7 into a signal proportional to their amplitude. The low-frequency and high-frequency components, separated by filtrates 8 and 9, are fed to the input of regulators 10 and 12 and change the consumption of heating water that goes into heating. Due to the fact that the temperature front reaches the heat supply source 1 within a certain time, depending on the consumption of heating water in main pipelines, the load controller 2 has the opportunity to switch from one load level of the heat supply source 1 to another in an optimal way. 1 hp f-ly, 1 ill. a & (L and zd ae oo with

Description

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The invention relates to agriculture and can be used in district heating systems for greenhouse combinations.

The purpose of the invention is to increase the efficiency of the heat supply process control and increase the efficiency of the heat supply source under the accumulated heat loads.

The drawing shows a functional diagram of the heat supply system of a block of greenhouses.

The system contains a heat supply source 1 with a load regulator 2, an integro-differentiating link 3, direct 4 pipelines and a return 5 heating water, a flow sensor 6, a meteo-factor sensor 7, two filters: high-frequency 8 and low-frequency 9, regulator 10, a throttling valve 11, a regulator 12, an overflow valve 13 and a water temperature sensor 14.

The system works as follows.

Changes in the meteorological factors are converted by sensor 7 into a signal proportional to their amplitude. The low-frequency component of this signal, highlighted by filter 9, is fed to the input of the regulator 10, which, by moving the valve plug 11, changes the flow

change the temperature of the return water for thermal input block greenhouses. Due to the fact that the new temperature front reaches the heat supply source 1 in a certain time, depending on the consumption of heating water in the main pipelines, at the regulator. loads it is possible to switch from one load level of the heat supply source 1 to another in an optimal way. For this, the sensor 14 measures the temperature of the heating water after the thermal input of the greenhouse block and a signal proportional to it is fed to the input of the integrating differentiation link 3, the parameters of which vary depending on the signal value of the sensor 6, and hence on the consumption of the heating water.

The functional value of the link 3 is in a smooth optimal transfer, followed by the disappearance of the signal, of the heat load of the heat supply source 1 so that the heat supply source is already working at the new appropriate level of load to approach the new temperature front.

Claims (1)

The invention The heat supply system of the heat of heating water going to the surroundings, containing a meteorological heating sensor due to its throttling. These changes in the consumption of heating water are still almost without any inertia causing corresponding changes in the load of the heat supply source 1, but since the rate of these changes is limited to filter 9, deteriorates the efficiency of its work and, therefore, does not reduce the efficiency of the boiler in transient conditions. The high-frequency component of the signal from sensor 7, selected by filter 8, is fed to the input of controller 12, which, moving the plunger 13, changes the flow of heating water going to be heated, by bypassing part of it from direct 4 to the reverse 5 line. Thus, the high-frequency component of the changes in meteorological factors does not cause a change in the consumption of heating water in the main pipelines. This component causes the corresponding 40 45 50 55 A heat supply source with a load regulator, direct and reverse heating water pipelines connected to the heat supply source, with which the thermal input of the greenhouse block with the bypass and throttling valves with the corresponding regulators is connected, with the bypass valve installed between the direct pipelines backflow water, and throttling is installed behind the overflow pipe on the direct water pipeline, characterized in that, in order to increase the efficiency of control of the heat supply process and Sheni efficiency heat supplying source at alternating thermal loads, is provided with systems and vysokochas-frequency low-pass filters, sensor evap ry reverse water flow sensor and integrodifferentsiruyuschim-link, the low-pass filter between the output chen including The sensor meteofakt persons containing a weather sensor a heat supply source with a load regulator, direct and reverse heating water pipelines connected to the heat supply source, with which the thermal input of the greenhouse block with the bypass and throttling valves with the appropriate regulators is connected, the bypass valve is installed between the direct and reverse heat pipelines water, and the throttling one is installed behind the overflow pipe on the direct water pipeline, characterized in that, in order to increase the efficiency of control of the heat supply process and Accelerating efficiency heat supplying source at alternating thermal loads, the system is provided with a low-frequency and high-frequency filters, return water temperature sensor, flow sensor and integrodifferentsiruyuschim-link, the low-pass filter connected between the output of the sensor meteofakto1630683 ditch and the throttle link regulator input, the output of which is associated with the high-frequency valve and the high-frequency input of the source load regulator between the output of the meteofactor and heat supply sensor, and the parametric and the input of the regulator regulator input of the integro-differentiating link pan, and the output of the temperature sensor s is connected to the output of the flow sensor, The return water is connected to an information line installed on the pipeline. to the national input of integrodifferentsiyu-heating water. I