SU750221A1 - Apparatus for automatic control of heat supply - Google Patents

Description

one

The invention relates to heating technology and is intended for automatic control of a district heating system.

A system is known for automatically controlling the heating capacity of gas heating boilers, taking into account changes in the outside air temperature, heat capacity of the firing stations and wind l.

This device measures the outside air temperature, the exterior wall temperature of the building, solar radiation, and wind speed, converts them into electrical signals, sums it up, and the resulting signal is used to control the heat supply to the building.

However, this device is not efficient enough, especially in modern buildings, since the measured signals are summed up without taking into account the physical relationship between building heat loss and climatic parameters, tuning, the relative values of the signals by channel is made empirically.

Closest to the proposed invention is a device for automatic control of heat supply, comprising an outside wall temperature sensor, outside air temperature, indoor air temperature, wind speed, a summing amplifier, a multiplication unit, a scale amplifier, an adder, a switch, an indicator and scale resistors, moreover, the outdoor temperature sensor

10 walls connected to the first input of the adder, the temperature sensor of the internal air through the first large-scale resistor connected to the input of the summing amplifier, with the second and third

15 scale resistors, the output of the summing amplifier is connected to the second scale resistor and to one input of the multiplication unit, the output of which is connected to the second input of the adder, the fourth scale resistor is connected to the switch and through the fifth scale resistor to the input of the scale amplifier, the output of which is connected to the switch , with another input of the multiplication unit and through sequentially connected sixth and seventh scale resistors - with the input of a scale amplifier, and the indicator through the eighth scale

Claims (2)

30 resistor connected to a switch 2. A disadvantage of this device is the poor quality of regulation in the case of large length of heating mains due to the lack of accounting for the predicted values of the outdoor temperature and wind speed, as well as the lack of accounting for the calculated wind speed. The purpose of the invention is to increase the efficiency of heat consumption and control accuracy. This is achieved in that a device for automatic control of heat supply, comprising sensors for the exterior wall temperature, outdoor air temperature, indoor air temperature, wind speed, summing amplifier, multiplier, scale amplifier, summator, switch, indicator, and scale resistors, the temperature sensor of the outer wall is connected to the first input of the adder, the temperature sensor of the internal air through the first large-scale resistor is connected to the input of the summing amplifier, with the second the third scale resistors, the output of the summing amplifier is connected to the second scale peer and the store and to one input of the multiplication unit, the output of which is connected to the second input of the adder, the fourth scale resistor is connected to the switch and to the input of the scale force of the bodies, the output which is connected to the switch, to the other input of the multiplication unit and through the sixth and seventh masigig resistors connected in series to the input of the scale amplifier, and the indicator through the eighth scale the sensor is connected to a switch, simulators of the predicted outdoor temperature and wind speed, a two-position switch and a calculated wind speed sensor are inserted, the sensor of the calculated wind speed is connected to the input of a large-scale amplifier, simulators of the predicted wind speed and outdoor temperature are connected to the on-off switch to which they are connected respectively, the third input of the adder, the wind speed sensor and the fourth large-scale resistor. . The drawing is a structural diagram of the proposed device. The device for automatic control of heat supply contains sensors 1–4, respectively, of the exterior wall temperature, those of the internal and external air, wind speed, summing amplifier 5, multiplication unit 6, scale amplifier 7, adder 3, switch 9, indicator 10, sensor 11 of the estimated wind speed, simulator 12 of the predicted outdoor temperature, simulator 13 of the predicted wind speed, the Duplex switch 14, as well as large-scale resistors 15.16 n 1 of summing amplifier 5, large-scale resistors 18 -21 scale amplifier 7, scale resistor 22 of the indicator 10. Sensor 11 of the estimated wind speed is connected to the input of the scale amplifier 7 by its output, the output of the predicted outdoor temperature simulator 12 through the dip switch 14 is connected to the input of the summing amplifier 5 and to the second input of the adder 8, and the output of the simulator 13 of the predicted wind speed through a two-position switch 14 is connected to the input of the scale amplifier 7. Moreover, in one position, the two-position switch 14 to the input is summing the amplifier 5 and the output of the sensor 2 are connected to the second input of the adder 8, the outside air temperature, and the output of the wind speed sensor 4 to the input of the scale amplifier 7, and in the second position of the two-position switch 14 to the input of the summing amplifier 5 and the output of the second adder 8 simulator 12 predicted outdoor temperature, and to the input of the large-scale amplifier 7 is connected to the output of the simulator 13 predicted wind speed. The device simulates the physical process of heat transfer of a building under the operation of external meteorological parameters according to the following law) () (. And-h), the reduced temperature; - outdoor temperature; t (in is the temperature in the exterior wall model of the building, t is the air temperature in the room, W is the wind speed; v / is the calculated wind speed, f is the coefficient characterizing the ratio of heat loss through heat-intensive fences to the total heat loss for a given building; factor characterizing the rapid heat output losses due to the influence of wind on the thermal mode of the room. Signals from sensors 1 and 2 are fed to two inputs of adder 8, the gain factors of which are chosen proportional to H-hO-H-, respectively. Simultaneously, the signals from sensors 2 and 3 are fed to the input of amplifier 5, the output of which forms a voltage proportional to the difference (tg-t) using scale resistors 15, 16 and 17. This voltage is applied to one and the inputs of the multiplication unit 6. The second input of this device is supplied from sensor 4 and from sensor 11 through scale amplifier 7, and the scale factor of this amplifier is set proportional to the value of dp using scale rheistors 18-21. Thus, at the output of multiplication unit 6, a signal is formed that is proportional to the value (b-h). The switch 9 and the indicator 10 allow the amplifier zero to be monitored zero and podstryuyku its implementation. Similarly, the control circuits for the zeros of amplifier 5 and adder 8 are constructed for each of the inputs. During the monitoring period, the input of the amplifier under test is connected with the switch 9 to the housing and simultaneously the indicator 10 is connected to the output of the amplifier under test, sequentially with which the scale resistor 22 is turned on. This is how the device operates at the position of the two-position switch 14 corresponding to the depicted and corresponding Operation mode . In the second position, the switch 14 in the Forecast mode connects to the amplifier 5 and the adder B with the output of the simulator 12 of the predicted outdoor temperature, and the output of the simulator 13 of the predicted wind speed is connected to the input of the amplifier 7. In this case, the device simulates the physical process of heat transfer from the building at the predicted values of the outdoor temperature and wind speed. Chrprognn kprogiO-) m rKrogn .npor "-4) g where t j is the predicted reduced temperature; t. - Predicted tempeN. PrGPP outdoor outdoor predictable wind speed. Sensor 11 and simulators 12 and 13 are electrical models of the corresponding parameters and are structurally designed in the form of a dispatcher console that controls the heating mode. On the remote there are two modes of operation: Work and Forecast. In Operation mode, the device determines the current value of the reduced temperature in the Prediction mode — the predicted value of the reference temperature that is used by the controller for optimal heat management. Due to the large extent of the heating mains, during the passage of the coolant from the heat source to the consumers, the meteorological conditions change. The heat losses of the building at this moment no longer correspond to the heat gains. Taking into account the predicted value of the reduced outdoor air temperature during the adjustment period made it possible to create a correspondence between heat losses and heat gains, to improve the use of fuel, to improve the occupancy level of the workers. Improving the method of regulating the mode of heat supply and the desire to save fuel determines the need to take into account not only the actual, but also the estimated wind speed. The calculated wind rate is equal to the average wind speed for the three coldest months. When calculating the heat loss of a building, heat transfer coefficients for fences are selected according to the Building Norms and Rules depending on the calculated wind speed. From the analysis of climatic data, it follows that the repetition of wind speeds, estimated, over a large territory of the USSR during the heating season is from 40 to 65%. Therefore, taking into account the calculated wind speed makes it possible to save fuel during the period of speed, less than the calculated one. Formula of the Invention A device for automatic control of heat supply, comprising sensors for the outer wall temperature, outdoor air temperature, indoor air temperature, wind speed, summing amplifier, multiplication unit, large-scale amplifier, adder, switch, indicator and large-scale E resistors, with the outer wall temperature sensor connected to the first input of the adder, temp sensor The internal air is connected through the first scale resistor to the input of a summing amplifier, with the second and third scalers, the output of the summing amplifier is connected to the second scale resistor and to one input of the multiplication unit, the output of which is connected to the second input of the adder, the fourth scale resistor is connected to to the switch and via the fifth scale resistor to the input of the scale amplifier, the output of which is connected to the switch, to another input of the multiplication unit and connected in series through s sixth and seventh.