UA112007U - DEVICES FOR ADJUSTING THE TEMPERATURE OF THE HEATING SYSTEM - Google Patents

Abstract

The device for controlling the temperature of the heating system comprises a coolant temperature sensor, indoor temperature sensor, outdoor ambient temperature sensor, the outputs of which are connected to the microcontroller module of the temperature sensors data processing, proportional-integral-differential controller and actuator. The device further comprises a unit of calculation, unit of set-up, unit of control.

Description

The useful model belongs to the field of heat supply and regulation, namely the regulation of the heating temperature of residential and industrial buildings, and can be used by enterprises and utilities, in which temperature regulation takes place according to the heating schedule.

A well-known device for regulating the temperature of the heat carrier of the heating system (see author St.

USSR Mo 1409990, IPC 2050 23/19 dated November 24, 1986, publ. 15.07.1988), containing a coolant temperature sensor, an ambient temperature sensor, the outputs of which are connected to the temperature sensor data processing module, and an executive element.

The known device consists of an ambient temperature sensor, a heat carrier temperature sensor, a temperature sensor data processing module that determines changes in the temperature of the heat carrier, a subtractor, adder, regulator, an executive element, a heater, a heater power consumption sensor, and a unit that determines changes in heater power.

The disadvantages of the known device are insufficient accuracy of measurements, which is due to the properties of the ambient temperature sensor and overheating during transient modes of operation, which significantly increases electricity consumption and limits the field of application.

A well-known device for regulating the temperature of the heating system: (see useful model

Ukraine Mo 18454, IPC 2050 23/19, z. Mo 200604447; published 15.11.2006), containing a coolant temperature sensor, a room temperature sensor, an ambient temperature sensor, the outputs of which are connected to a microcontroller module for processing temperature sensor data, and an executive element.

The known device consists of an ambient temperature sensor, a coolant temperature sensor, a microcontroller module for processing data of temperature sensors, an executive element, a first heater, a heater power consumption sensor, and a second heater.

The known device works as follows. The signal from the microcontroller data processing module of temperature sensors is fed to the heater, the environmental sensor measures the temperature of the second heater, in the microcontroller data processing module of temperature sensors, the value obtained from the environmental sensor is compared with the set one. If the error value corresponds to the permissible one, the device starts working.

З The ambient temperature sensor and the coolant temperature sensor measure the current value of the ambient and coolant temperature, their signals are fed to the microcontroller data processing module of the temperature sensors, the signal of the actual coolant temperature is subtracted from the ambient temperature signal. If the temperature of the heat carrier differs from the specified temperature, a task signal is generated in the microcontroller data processing module of the temperature sensors, which is proportional to the increase in the power of the heater, which is necessary to heat the heat carrier at the required speed. At the same time, in the microcontroller module for data processing of temperature sensors, the signal from the environmental sensor is transformed into a task signal proportional to the power of the heater, which is necessary to compensate for energy losses in the heating system. The task signals are summed up and, according to the given control parameters, a control signal is formed at the output of the microcontroller module for processing data of temperature sensors. Through the executive element, the power of the heater changes until the value of the sensor of the consumed power of the heater becomes equal to the set value.

The disadvantages of the known device are the need for an additional heater to control the accuracy of measurements of the ambient temperature sensor, which leads to electricity consumption and an increase in the inertia of the system; there is periodic overheating during transient operating modes, which leads to additional electricity consumption.

The device for regulating the temperature of the heating system is the closest in terms of technical essence and the result achieved to the claimed device (see patent of Ukraine for a utility model Mo 96003, IPC 2050 23/19, application Mo 201408964, dated 08.08.2014 , publ. 12.01.2015), containing a coolant temperature sensor, an indoor temperature sensor, an outdoor ambient temperature sensor, the outputs of which are connected to a microcontroller module for processing temperature sensor data, a proportional-integral-differential regulator and an executive element.

A well-known device for regulating the temperature of the heating system consists of a room temperature sensor, an ambient temperature sensor, a microcontroller module for processing data of temperature sensors, a coolant temperature sensor, an executive element, a heater, a heater power consumption sensor, a precision temperature sensor and a proportional-integral-differential ( SUB) because of the regulator. The precision temperature sensor is placed next to the ambient temperature sensor, the input and output of which are connected to the microcontroller module for processing data of the temperature sensors. The input of the PID regulator is connected to the microcontroller data processing module of the temperature sensors, and the output is connected to the executive element. The precision temperature sensor checks the accuracy of the ambient temperature sensor, the PID regulator reduces periodic overheating during transient operating modes.

The device works like this. Signals from room and ambient temperature sensors, as well as a precision temperature sensor, are simultaneously sent to the temperature sensor data processing microcontroller module. The values of the temperature sensors are compared with each other, if the deviation value corresponds to the permissible one, the device disables the precision temperature sensor and starts working. At the same time, the current value of the temperature of the environment and the coolant is measured, their signals are fed to the microcontroller data processing module of the temperature sensors, the signal of the actual temperature of the coolant is subtracted from the value of the ambient temperature signal. If the temperature of the coolant differs from the set one, then in the microcontroller module for processing the data of the temperature sensors, a task signal is formed, proportional to the increase in the power of the heater, at the same time, in the microcontroller module for processing the data of the temperature sensors, the signal from the sensor is transformed into a task signal proportional to the power of the heater, which is necessary to compensate for energy losses in heating system. The task signals are summed up, and a control signal is formed at the output of the microcontroller data processing module of the temperature sensors, which is fed to the input of the PID regulator, where, according to the regulation parameters, a signal is formed that is fed to the executive element. Through the executive element, the power of the heater changes until the measured value from the power consumption sensor becomes equal to the set value.

The disadvantages of the known device are the need to adjust the temperature of the coolant by the heater, which leads to energy consumption costs for its heating and an increase in the inertia of the device; at the same time, periodic overheating occurs during transient operating modes, and this, in turn, leads to additional electricity consumption. In addition, the known device has insufficient temperature setting accuracy.

The proposed useful model is based on the task of improving the device

From temperature regulation of the heating system, in which, by introducing new elements and new connections between elements, the efficiency of the device is ensured by reducing the costs of the coolant and energy consumption for its heating, expanding the functional capabilities of the device, optimizing its structure, reducing overheating during transient modes of operation and increasing the accuracy of indoor temperature setting.

The problem is solved by the fact that in a known heating system temperature control device, which contains a coolant temperature sensor, an indoor temperature sensor, an outdoor ambient temperature sensor, the outputs of which are connected to a microcontroller module for processing temperature sensor data, a proportional-integral-differential regulator and executive element, according to the utility model, the device additionally includes a calculation unit, a preset setting unit, a control unit, while the output of the microcontroller data processing module of the temperature sensors is connected to the first input of the calculation unit, the preset setting unit is connected to the control unit , the output of which is connected to the second input of the calculation unit, the third input of which is connected to the first output of the proportional-integral-differential regulator, the output of the calculation unit is connected to the first input of the proportional-integral-differential regulator, the second output of which is connected with the input of the automatic adjustment unit operation of the proportional-integral-differential regulator, the output of which is connected to the second input of the proportional-integral-differential regulator, the second output of which is connected to the executive element.

What is also new is that digital temperature sensors are used as indoor temperature sensor and outdoor ambient temperature sensor.

The cause-and-effect relationship between the set of declared signs and the technical result is as follows.

New elements of the device for regulating the temperature of the heating system and new connections between the elements, namely, that the device additionally contains: a calculation unit, a preset setting unit, a control unit, while the output of the microcontroller module for processing data of temperature sensors is connected to the first input of the unit calculation, 60 the preset setting unit is connected to the control unit,

the output of which is connected to the second input of the calculation unit, the third input of which is connected to the first output of the proportional-integral-differential regulator, the output of the calculation unit is connected to the first input of the proportional-integral-differential regulator, the second output of which is connected to by the input of the block of automatic adjustment of the proportional-integral-differential regulator, the output of which is connected to the second input of the proportional-integral-differential regulator, which is connected to the executive element through the second output, together with the known features of the useful model, provide an increase in the efficiency of the device due to a decrease consumption of coolant and energy consumption for its heating, expansion of the functional capabilities of the device, optimization of its structure, reduction of overheating during transient modes of operation and improvement of the accuracy of temperature setting in rooms.

The presence of new blocks and new connections in the device allows to implement the calculation-logic mechanism of its action.

The claimed device for regulating the temperature of the heat carrier of the heating system provides automated control of the heating system with the functions of monitoring engineering parameters for administrative and residential buildings. During the operation of the device, the supply of coolant in the building heating system is controlled depending on the temperature of the outside air and inside the building. At the same time, the device automatically adapts when the parameters of the supplied heat carrier change. At the same time, during the heating season, going beyond the set temperature in the room is excluded, even with sharp fluctuations in the air temperature in the yard during the day.

The operating modes of the device are aimed at maintaining a comfortable indoor temperature, for which digital temperature sensors are used as an indoor temperature sensor and an outdoor ambient temperature sensor.

The device allows you to provide flexible schedules of heating temperature regimes (day/night, weekends and holidays, arbitrary period) and automatically adapts when the characteristics of the coolant supplied to the heating system from the heater, central heating network, etc. change.

The drawing shows the functional scheme of the device for regulating the temperature of the heating system.

The device for regulating the temperature of the heating system includes sensor 1 of the coolant temperature, sensor 2 of the indoor temperature, sensor Z of the ambient temperature outside, the outputs of which are connected to the microcontroller module 4 for processing the data of the temperature sensors, a proportional-integral-differential regulator 5 and an executive element 6. The device for regulating the temperature of the heating system additionally contains a calculation block 7, a preset setting block 8, and a control block 9. At the same time, the output of the microcontroller module 4 for data processing of temperature sensors is connected to the first input of the calculation unit 7. Unit 8 of the specified setting is connected to the control unit 9, the output of which is connected to the second input of the calculation unit 7, the third input of which is connected to the first output of the proportional-integral-differential regulator 5. The output of the calculation unit 7 is connected to the first by the input of the proportional-integral-differential regulator 5, the second output of which is connected to the input of the block 10 of automatic adjustment of the proportional-integral-differential regulator, the output of which is connected to the second input of the proportional-integral-differential regulator 5, which is connected by the second output with executive element 6.

The claimed device for regulating the temperature of the heating system works as follows.

When the device is turned on for the first time or during its reconfiguration, or during emergency modes, the unit 10 of the automatic adjustment of the proportional-integral-differential regulator selects the adjustment coefficients of the proportional-integral-differential regulator 5. In the unit 8 of the specified setting, the necessary parameters of the temperature in the room are entered in the daily or/ and weekly mode, which are sent to the calculation unit 7 through the control unit. From sensor 1 of the coolant temperature, sensor 2 of the indoor temperature, sensor of the outdoor ambient temperature, the outputs of which are connected to the microcontroller module 4 of temperature sensor data processing, data on the values of the corresponding temperatures are sent to the temperature sensor data processing microcontroller module 4, where sampling of specific sensor data is carried out, which is taken into account in the calculation of temperatures. From the microcontroller module 4 of temperature sensor data processing, these data are also sent to the calculation unit 7. From the first output of the calculation block 7, the signal is fed to the proportional-integral-differential regulator 5, which has feedback to the calculation block 7. According to the adjustment coefficients of the proportional-integral-differential regulator 5, the operation of the executive element b is controlled, which changes the amount of coolant in the heating system, and the temperature in the room changes accordingly. The claimed device is universal for various types of buildings.

In addition, transmission and storage of indicators from meters (heat, electricity, gas, water) can be organized.

The industrial suitability of the useful model is confirmed by the fact that the proposed device can be manufactured, in accordance with the given description and block diagram, on the basis of known components and technological equipment. So, the microcontroller module for data processing of temperature sensors can be made on the basis of JSC tedaZ2, as an executive element, a valve from the VeiYito company, a calculation unit, a preset setting unit, a control unit, a proportional-integral-differential regulator with a proportional-integral automatic setting unit can be used as an executive element. of a differential regulator can be implemented, for example, by a programmable logic controller PLC 154 "Aries".

The economic effect of the introduction of the device is up to UAH 500,000. for the heating season on an area of 1000 sq.m.

Claims (2)

USEFUL MODEL FORMULA 1. A device for regulating the temperature of the heating system, which contains a coolant temperature sensor, an indoor temperature sensor, an outdoor ambient temperature sensor, the outputs of which are connected to a microcontroller module for processing data of temperature sensors, a proportional-integral-differential regulator and an executive element, which is characterized by the fact that the device additionally contains a calculation unit, a set setting unit, a control unit, while the output of the microcontroller module for processing data of temperature sensors is connected to the first input of the calculation unit, the set setting unit is connected to a control unit, the output of which is connected connected to the second input of the calculation unit, the third input of which is connected to the first output of the proportional-integral-differential regulator, the output of the calculation unit is connected to the first input of the proportional-integral-differential regulator, the second output of which is connected to the input of the automatic adjustment unit proportional-integral-differential of the regulator, the output of which is connected to the second input of the proportional-integral-differential regulator, the second output of which is connected to the executive element. 2. The device for regulating the temperature of the heating system according to claim 1, which is characterized by the fact that digital temperature sensors are used as the indoor temperature sensor and the outdoor ambient temperature sensor. In Mitkuvatuv your myh I ish I R r mpukeMky MaIYH DYN and i Kran Ka diMNMh; MKK about EYANYA. R pchllkdh DARK! ! PE sHE STILL tr i ne U 1 uk, and shi shi t WE! SHE! Ii Mizherei MV you N: her around ss aa! Go and Blohyaemuviinya M pashe and 11 NE and rii her nn OK suhzhyazhzhzhzhzhzhzhzhzhzhi yuyu! V i popomnniiiinin ini povvvvvvai i nni iii roi lezh nm riuNe TEO vivonochaisluvieu 1000100 zhnrememosni i ESHU: rn Y 1 H 3 i 1 U udlllyadladallalkhllalhhah aka KO ohhooifutttiukzhyuyuyuyuyu! and and: N Z : and ; : N i i I I i sh Dazhchikh i zoissvrya NE i clan | ! N DN! and rub EBlyak 10 cumin Z i horuk b fahu naut t Mente rezay ke provided teanke PEDCHEtyuUtove i : GDR en x : Y N yi opo u y : y