SU887944A2 - Outside air temperature sensor for device operating to heating shedule - Google Patents

Description

The invention relates to techniques for heat supply and is intended for use in systems for automatically controlling the heat supply for heating buildings, regulators of heating boiler rooms and other systems operating on a heating schedule.

Known external air temperature sensors for the device operating according to the heating schedule, you are a ¹ complements a copper resistance thermometer protected enclosure [1].

A disadvantage of the known sensors is the need to manufacture its resistance thermometer with an individual ohmic resistance value for each heating schedule.

By main auto No. 394675 known outdoor temperature sensor for a device operating on a heating schedule [2].

The disadvantage of the sensor is that during the transition of the regulator during the heating season to work on a schedule with a new angle, it is necessary to manually reconfigure the device located in the control panel each time.

The aim of the invention is to provide seasonal automatic correction of the angle of inclination of the heating schedule.

This goal is achieved by the fact that a temperature sensor, an electromagnetic relay, and two variable resistors are introduced into the sensor, one of which is connected in parallel with the coolant temperature sensor through the normally open contacts of the electromagnetic relay, and the other is connected in series with the coolant temperature sensor and shunted by normally closed contacts of the same relay, in this case, an electromagnetic relay powered by a current source is connected in series with a temperature sensor placed in a protective casing.

The drawing shows a circuit diagram of the sensor.

Does the outdoor temperature sensor for a heating appliance consist of a temperature sensor? outdoor air 1, temperature sensor 2, electromagnetic relay 3 having normally open 4 and normally closed 5 contacts, variable resistors b and 7, Temperature sensor * of coolant 8 is connected in series with outdoor temperature sensor 1, placed in a protective casing and containing a basic thermometer resistance Rq and included. in addition to it, additional resistance thermometers, the mutual ratio of the resistance values of which is determined by a series of binary codes. The electromagnetic relay 3 is connected to the current source through the contacts of the temperature sensor 2. The variable resistor 6 is connected in parallel to the sensor 8 through the normally open contacts 4 of the electromagnetic relay 3, the other variable resistor 7 is connected in series with the sensor 8 and shunted by the normally closed contacts 5 _{30 of} relay 3.

Setting the calculated angle of inclination of the heating schedule given selection ratio where i SC - tangent angle calculated heat curve ¹

R ^ is the resistance of the outdoor temperature sensor ⁴⁰ at 0 ° C;

Κιχ - resistance of the temperature sensor of the coolant at about C.

Setting the corrected angle is carried out by means of high ^{April 5} expressions ^ * 4- WR6 ..... 'gde (Uo1gg tangent adjusted 5®' inclination heating schedule;

- resistance of the resistor 6.

Using resistor 7, ensure * 1I8a. maintains the constancy of the total .55th resistance of the measuring chain of sequentially connected sensors 1 and 8 during the transition to work according to the adjusted heating schedule. The resistance of this resistor is calculated by the formula

J7 = J5 where R-j is the resistance 'of the sensor at the coolant temperature at the break point of the heating schedule.

The operation of the device, functioning according to the heating schedule, 'is as follows.

If the temperature of the coolant corresponds to the value set by the heating schedule, the sum of the resistances by the sensor 1 and 8 is constant and, if they are included in the measuring bridge, the bridge will be balanced.

The transition from the calculated to the corrected heating schedule occurs at an outdoor temperature determined by the break point of the heating schedule.

The electrical contacts of the thermometer 2, located inside the protective housing of the sensor 1, are configured to short circuit at the temperature of the outside air where is the temperature of the outside air;

'N.VI ^- temperature at the break point of the heating schedule.

In case of NEGATI, the contacts are closed, as a result of which power is supplied to relay 3. In turn, relay 3, with its contacts 4 and 5, connects variable resistors 6 and 7 to the electric circuit of the measuring arm of the bridge. In this case, resistor 6 reduces the sensitivity of the meter. bridge to a change in the resistance of the sensor 8, and using resistor 7, compensation is provided for the decrease in the resistance of the measuring arm of the bridge caused by the connection of resistor 6. As a result, when the device switches from the calculated heating schedule to the adjusted total resistance of the measuring arm of the bridge does not change and the device remains balanced .

With any deviations of the temperature of the coolant from the set according to the heating schedule, the total resistance of the measuring arm of the bridge changes5. The bridge is unbalanced and voltage appears on its diagonal. Then the amplified signal acts on the actuator, which moves the regulatory body. As a result, the temperature of the coolant changes until the total resistance of the measuring arm of the bridge assumes the previous value, i.e., the temperature of the coolant is set in accordance with the heating schedule.

Using this sensor can improve the efficiency of devices operating according to the heating schedule.

Claims (3)

with a thermal sensor placed in a protective casing. The drawing shows the circuit diagram of the sensor. The outdoor air temperature sensor for an appliance operating on a heating schedule consists of a sensor for outdoor air temperature 1, sensor temperature 2, electromagnetic relay 3, having normally open 4 and normally closed 5 contacts, variable resistors b and 7, Temperature sensor for heat carrier 8 connected in series with the outdoor temperature sensor 1, housed in a protective casing and containing a basic resistance thermometer RQ and connected in series with it additional resistance thermometers, mnoe ratio of the resistances of which are defined adjacent binary code. Electromagnetic relay 3 is connected to the current source through the contacts of the sensor 2. Variable resistor 6 is connected in parallel with sensor 8 through normally open contacts 4 of electromagnetic relay 3, another variable resistor 7 is connected in series with sensor 8 and is bridged by normally closed contacts 5 of relay 3. The design angle for the heating curve is determined by adjusting the ratio,, H1. the tangent of the calculated angle tde td clone heating graph fil resistance of the outdoor temperature sensor at 0 ° C; resistance of the temperature sensor of the coolant at O The adjustment of the angle of inclination is made using the expression. “.J.MM1M, hh - nj where Loobg tangent of the corrected angle of inclination of the heating curve; Rj, is the resistance of the resistor 6. With the help of the resistor 7 it is ensured that the constant of the total resistance of the measuring chain of the successively connected sensors 1 and 8 is maintained during the transition to work on the corrected heating schedule. The resistance of this resistor is calculated using the formula R7sR5 where RJ is the resistance of the sensor at the temperature of the heat carrier at the break point of the heating curve. The operation of the device operating on the heating schedule is carried out as follows. If the temperature of the coolant matches the value given by the heating schedule, the sum of the resistances of sensor 1 and 8 is constant and, if they are included in the measuring bridge, the bridge will be balanced. The transition from the calculated to the adjusted heating schedule occurs at the outside air temperature determined by the break point of the heating schedule. The electrical contacts of the thermometer 2, located inside the protective housing of the sensor 1, are configured to short-circuit at the outside air temperature c..n, vi. S where t) g is the outdoor temperature; .vi temperature at the breakpoint of the heating curve. At t, 1, these contacts are closed, as a result of which the power is supplied to the relay 3. In turn, the relay 3 with its contacts 4 and 5 connects variable resistors 6 and 7 to the electrical circuit of the measuring arm of the bridge. At the same time, the resistor 6 reduces the sensitivity of the measuring-. The bridge resistor 8 compensates for a decrease in the resistance of the measuring arm of the bridge caused by connecting a resistor 6. As a result, when the device switches from the calculated heating graph to the corrected sum, the resistance of the bridge measuring arm does not change and the device remains balanced. In case of any deviations of the temperature of the coolant from the temperature determined by the heating curve, the total resistance of the measuring arm of the bridge changes. The bridge is rebalanced and a voltage appears on its diagonal. The amplified signal then acts on the actuator, which moves the regulating organ. As a result, a change in the temperature of the heat transfer medium occurs until the total resistance of the measuring arm of the bridge takes the same value, i.e. the heat transfer temperature is set in accordance with the heating schedule. The use of this sensor makes it possible to increase the efficiency of work of devices operating according to the heating schedule. DETAILED DESCRIPTION OF THE INVENTION An outdoor temperature sensor for an instrument operating according to a heating schedule according to author. 9,346 characterized in that, in order to provide automatic To the power source of the seasonal tilt angle correction of the heating graph, a thermal sensor, an electromagnetic relay and two variable resistors are inserted into it, one of which is connected in parallel with the coolant temperature sensor through normally open contacts of the electromagnetic relay, and the other is connected in series with the coolant temperature sensor and shuitrovaya normally closed contacts the same relay, while the electromagnetic relay, powered by the current source, is connected in series with the thermal sensor, in a protective casing. Sources of information taken into account during the examination 1. Proud KK. and Grislis V.Ya. Automation of subscriber inputs. Sat Automation of heating boilers, vol. 6, L., Nedra, 1971, p. 113-120. 2. USSR author's certificate number 394675, cl. G O K 7/16, 1971 (prototype). one