RU32895U1 - REMOTE CONTROL SYSTEM FOR HOUSEHOLD BOILER AUTOMATION - Google Patents

Description

REMOTE CONTROL SYSTEM FOR HOUSEHOLD BOILER AUTOMATION

The proposal relates to heating equipment used in gas supply systems for residential and industrial agricultural facilities, namely, energy-saving equipment used in the automation of direct-acting heating boilers of the type SABK-8-110, LGU Kontur-3, RSU2-M1 and Temp, built on non-kinematic elements of pneumatic automation.

Known gas universal regulator RGU2-M1 (see technical description and operating instructions for Ca 2.574.023 TO), designed to control the presence of traction, flame, gas pressure drop, integrity of impulse lines, regulation of water temperature or steam pressure.

The automation unit RGU2-M1 consists of flame, traction and temperature sensors connected by impulse lines.

It is also known Automatic gas burner device of the LGU Kontur-3 type (see operation manual, passport 2.199.00.000 RE, TU 21-469-012-93, Kirov). Its automation is also designed to control the presence of traction, flame, pressure drop and the integrity of impulse lines, allows you to maintain the temperature of the coolant set by the temperature controller, automatically turning the main burner on and off.

It contains a water temperature controller (RTV), a shutoff valve, flame and traction sensors with impulse tubes, a gas duct, and an adjusting washer.

M. cl. G 05 V 13/00 G 05 D 23/00

An automation system for household boilers of the SABK8-110 type is also known (see Passport SABK-00.00.000 PS, Ulyanovsk, 1998, PO Box 3382.), including a water temperature controller with a pulse tube, valves with flame sensors and traction with impulse tubes, main valve-cutter, gas duct, impulse discharge tube and igniter.

The above automation system in technical essence is closer to the proposed one and can be adopted as a prototype.

A common drawback of the above analogues and prototype is the lack of a remote control system for the operation of the heating boiler, which creates inconvenience in maintenance and does not allow to operate it economically, hence the unnecessarily high fuel consumption.

The objective of this utility model is to create a remote control system for the automation of domestic boilers, providing control and operation of the heating boiler remotely to eliminate the disadvantages of the prototype.

The problem is solved by the described remote control system for the automation of domestic boilers, including an auxiliary valve shutoff, a water temperature regulator with an impulse tube, a valve with flame and traction sensors with impulse tubes, the main valve - a cutter, gas duct, an impulse discharge tube and an ignitor.

It is clear that the pulse tube of the water temperature controller is equipped with an electromagnetic valve electrically connected to a control unit that provides remote control for the operation of the heating boiler by opening or closing the electromagnetic valve.

The figure shows a diagram of a remote control system for the automation of domestic boilers, where the symbol

An electromagnetic valve is shown connected to a pulse tube of a water temperature controller (RTV).

The remote control system for the automation of domestic boilers includes interconnected impulse tubes: RTV 1 with an impulse tube 2, a flame sensor 3 with an impulse tube 4, a draft sensor 5 with an impulse tube 6, an auxiliary shut-off valve 7, which together represent the control unit, the main valve cutter 8, gas duct 9, discharge pulse tube 10, ignitor 11 with pulse tube 12. The pulse tube 2 of the PTB 1 is equipped with an electromagnetic valve 13, electrically connected to the additional control unit 14, set pressed at a distance (the distance is not limited) providing remote control over the operation of the boiler by opening or closing the electromagnetic valve.

Her work is as follows. ,

When opening the KpaHaV, the descent to the boiler (faucet and boiler in FIG.

shown) gas from the network enters the auxiliary shut-off valve 7 and the main shut-off valve 8 in which both shut-off valves remain fully closed and the electromagnetic valve 13 is open. When the PTV indicator 1 is set to the Start position, the auxiliary shutoff valve 7 automatically opens. Gas enters the ignition 11 of the boiler, where it is ignited. In this case, the main valve 8 remains closed, since in the Start position PTV 1 is closed.

The flame sensor 3 and the draft sensor 5 contain. ball seal nozzles / X position determined by sensitive

element - a bimetallic plate. When the boiler does not work, the nozzle of the draft sensor 5 is closed and the nozzle of the flame sensor 3 is open.

After warming up with the flame of the zalpik And the bimetallic plastype of the flame detector 3, the latter, deforming, presses the sensor ball to the saddle, as a result of which it closes, and the auxiliary valve-cutter 7 opens completely.

When the PTV valve 1 is opened by setting the pointer to the t ° C position, gas from it enters the lower cavity of the main shut-off valve 8, opens it completely, gas passing through it enters the burner 16 of the boiler, where it ignites from the ignition flame 11. When heating the water the boiler above the set temperature (50-90 ° С) RTV 1 is closed and gas supply through the impulse pipe 2 to the lower cavity of the main valve-cutter 8 is stopped and the pressure in it is released and it is closed, at which the gas supply to the burner is stopped, while the ignitor 11 continues to burn constantly.

For operation of the remote control system of the boiler, the RTV temperature sensor is set to 90 ° C, which is a necessary condition for protecting the boiler from overheating. When this control signal comes from the control unit 14:

a) closing — the electromagnetic valve closes, the gas supply to the main shut-off valve 8 from the impulse tube 2 ceases, as a result of which the gas supply to the burner also stops, but the ignitor 11 continues to burn;

b) at the opening - the electromagnetic valve 13 opens, the gas through the impulse tube 2 enters the main shut-off valve 8, which, in turn, allows gas to reach the burner and the latter ignites from the burning igniter.

Remote control of gas combustion in the boiler furnace allows you to operate it in the optimal mode, reduce gas consumption, and stably maintain the desired temperature in the room and technological processes.

In the event of an emergency, the sensors 1, 3, and 5 of the flame, propulsion, and temperature, respectively, of the accident occur, the shutoff valves 7 and 8 are closed, while the gas stops flowing to the igniter and burner.

The technical and economic advantage of the proposal is as follows:

Its use in comparison with the known ones provides a reduction in gas consumption and ease of maintenance, since remote control of gas combustion is carried out automatically. In addition, the scope of its use is expanding. It can also be used in hot water, water heating and other devices where remote automatic control and control of gas combustion in the boiler furnace is required.

,FROM(

Director :( H.F. Mutygullin

Claims (1)

Remote control system for automation of domestic boilers, including an auxiliary valve shutoff, a water temperature regulator with an impulse tube, valves with flame and draft sensors with impulse tubes, a main shutoff valve, a gas duct, an impulse discharge tube and an igniter, characterized in that the regulator impulse tube water temperature is equipped with an electromagnetic valve electrically connected to the control unit, providing remote control over the operation of the boiler by opening or closing the solenoid valve.