SU546760A1 - Device for controlling heat consumption in a central heating system of a building - Google Patents

Description

one

The invention relates to the field of automatic control of building building systems.

A device for controlling heat consumption in a central heating system of a building is known, comprising a heat medium flow sensor, heat and heat input temperature sensors, TCiM air temperature sensors of the heated premises of the building, an actuator valve that changes the heat flow rate, a heat flow regulator, and also Parameters of the system, the adder of which is connected to the outdoor temperature sensors and to the actuator of the apparatus for changing the tempo Aturi coolant.

A disadvantage of the known device is that in controlling the heat consumption, factors such as the action of wind, sun and features of the building heating system are not taken into account.

The purpose of the invention is to increase the quality of heat control. The goal is achieved by the fact that the regulator of the ratio of the parameters of the system is completed with a corrector and converter of the degree of correction. The inputs of the corrector are connected to the air temperature sensors of the heated premises of the building, and the output of the corrector is connected to an adder via a converter of the degree of correction. The ratio controller of the parameters of the system is made with a difference meter connected to an adder and sensor for the temperature of the supplied and discharged system, as well as with a multimeter connected to the difference meter and a sensor of the telomelntel.

In addition, the ratio controller of the system parameters has a reference indicator connected to the air temperature sensors of the heated premises of the building and the actuator of the keyboard, which changes the flow rate of the coolant, and the flow sensor

The body is connected to the body and head flow control.

FIG. 1 is a schematic of a device for controlling heat consumption in a central heating system of a building

multiplier; in fig. 2 is a schematic diagram of a device with a teilonosnl flow regulator.

The device contains: it is the controller 1 of the ratio of the parameters of the system including the adder 2 connected to the sensor 3

external air temperature p with the actuator 4 of the valve 5 of the apparatus 6 for changing the temperature of the coolant, which can be used as an elevator, pump or boiler (in the drawing of the YAN version there is an embodiment with a pump). Regulus 3

Torus 1 also includes a corrector 7 with a converter of 8 degrees of correction, connected with c) mamator 2 and sensors 9 and 10 of the air temperature of heated mixing areas. Regulator 1 may contain a difference meter 11 connected to sensors 12 and 13 of the temperature of the inlet and outlet heat carrier, as well as a factor 14 associated with difference meter 11 and sensor 15 of the heat flow meter installed on the return pipe 16. In addition, regulator 1 may include a comparison indicator 17, combined with the executive mechanism 18 of the classroom, which changes the flow rate of the thermal fluid on the return pipe 16, and sensors 9 and 10. The heating devices 19 are arranged in series on the supply pipe de 20.

A variant of the device is possible in which the sensor 15 is connected to the heat carrier flow regulator 21 installed on the pipe 20, and the Equation Indicator 17 is connected to the decoupling valve mechanism 18 installed on the bridge 22 between the supply and return pipes.

The device works as follows. The signals from sensors 3 and 13 are fed to adder 2, which verifies that the actual ratio of the temperature of the coolant and the outside air is given. If there is no correspondence, the adder 2 sends a command to the actuator 4 of the valve 5, which changes the temperature of the heat transfer medium until the specified ratio between the outside air temperature and the heat transfer temperature is restored.

In cases when, due to the influence of additional factors, the temperature of the air in heated rooms deviates from the task, corrector 7 gets into work. Corrector 7 receives signals from sensors 9 and 10, and correlates with the average air temperature sends the correct signal to summattor 2, establishing a new ratio between the temperatures of the heat transfer medium and the outside air. As a result, the regulator does not respond to maintaining an increased (lowering the temperature of the internal air) or a lowered (or increasing the temperature) graph of the heat carrier temperature.

To regulate the supply of teila in buildings, in which there are additional organizational and individual controlled ventilation systems, for example, in residential buildings, regulator 1 turns on converter 8, which changes the value of the corrective signal of corrector 7 depending on the sign of the deviation of the internal air temperature. In this case, the converter 8 sets a lower degree of correction (increase) of the temperature graph at

four

negative deviations of the internal air temperature and a greater degree of correction (decrease) and positive deviations of the internal air temperature. 5 As a result, an increase in the heat output of the heating system above normal is accompanied by a sufficiently noticeable reduction in the internal air temperature as compared with the workplace, while a decrease in the tenodate pressure is 10% within the preset values of the internal air temperature. Due to this, air exchange in the air gap between winds and winds is reduced to the maximum possible; the elimination of the need for an excessive increase in the power of the heat supply systems, which would be required if the desired internal air temperature is maintained and the wind is strong; eliminating the need to air heated rooms 20 under the action of the sun.

In order to eliminate ienravilnaya heat supply when the calculated and actual temperature is recovered from the system to the ratio controller

5, the meter 1 of the difference between the temperatures of the supplied and discharged body and the sensor is inputted, to which in this case the sensors 12 and 13 are connected. In this case, the regulator 1 maintains the specified ratio between the difference

0 temperature of the coolant and the temperature of the outside air, which provides for the immediate realization of the schedule of teil and eliminates the overestimation or underestimation of the teloo output and the mismatch between the calculated and actual properties of the heating system.

Under the conditions when in the heating system the flow of coolant can vary, the device can be made in controller 21,

0 installed on conduit 20 and connected to the sensor 15, which provides a permanent and unambiguous connection between the pa3HOCTbto of the temperatures of the supplied and discharged heat and temperature and the consumption of teila. Same task

5 can be solved by introducing in regulator 1 a multiplier 14 connected to sensor 15. Multiplier 14 changes the value of the signal of the difference between the telescreens, in proportion to the flow of the thermal carrier.

0 If it is necessary to change the ratio of the airflow of heating devices 19 in the rooms of the upper and lower floors of multi-storey buildings, an indicator of gravity 17 is inserted into the device connected to the sensors

5 temnerur 9 and 10 lower and upper floors. With the inequality of the indicated temperatures, taking into account the sign of the deviation, the comparator 17 gives the command to the adaptive mechanism 18 of the claan, which changes the consumption of the tenon carrier. In this case, the temperature of the coolant in the individual devices and the ratio of their ten-output change. This takes place until the difference in air temperatures between the rooms of the upper and lower rooms is resolved.

floors.

Claims (5)

1. A device for controlling heat consumption in a building's central otileyi system, which contains a telenosupply consumption sensor, temperature sensors for the supplied and exhaust heat carrier, air temperature sensors for heated premises in the building, an actuator for changing heat carrier flow rate, a heat flow regulator, and a temperature controller for relative heat flow regulator, a heat flow regulator, a heat flow regulator, and a corresponding heat regulator and a corresponding heat regulator systems, the adder of which is connected with the sensors of the outside air temperature and with the emergency mechanism of the apparatus for changing the temperature, heat The carrier, characterized in that, in order to improve the quality of regulation, the ratio controller of the system parameters is made with a correction agent and a correction degree converter, the offset inputs are connected to air temperature sensors of heated premises in the building, and the offset output is connected to an adder via a correction degree converter. 2. A device of claim 1, characterized in that the controller of the ratio of the parameters of the system is wavelength with a difference detector connected to the adder and temperature sensors of the input and exhaust heat carrier. 3. The device according to nn. 1 and 2, characterized in that the ratio controller of the system parameters is made with a multiplier, which is connected with the difference meter and the flow sensor of the heating medium. 4. Device on PP. 1, 2 and 3, characterized in that the regulator of the correlated parameters of the system is made with a comparison indicator connected to the air temperature sensors of the tipped rooms of the building and the actuator of the valve that changes the flow rate of the coolant. 5. Device but AI. 1, 2 and 4, characterized in that the coolant flow sensor is connected to the coolant flow regulator. I ITxXbrr / jA.V .b% H) |