RU93886U1 - CONTROLLED LIQUID GAS FLOW REGULATOR - Google Patents

Abstract

 1. A controlled regulator of the flow of liquefied gas, comprising a housing with a gas cavity in communication with the inlet and outlet, a gas supply valve with an electromagnetic actuator, an inlet gas valve with an electromagnetic actuator installed in the inlet of the housing, at least one gas outlet valve with an electromagnetic a drive, connected to the outlet of the housing, a pressure sensor, a liquefied gas heater installed in the gas cavity and an electronic control unit, the input of which is electrically it is connected with a gas pressure sensor, and the outputs of the electronic control unit are electrically connected to the electromagnetic actuators of the gas flow valve, gas inlet valve and gas outlet valve, the gas gas valve inlet being in communication with a liquefied gas source, and the output in communication with a gas inlet valve, characterized in that the liquefied gas heater is placed in the housing with the possibility of heating the surfaces of the gas cavity, the electronic control unit is configured to generate an electrical signal and “on-off”, supplied to the electromagnetic drive of the gas flow valve, and pulse-width electrical signals supplied to the electromagnetic drives of the inlet gas valve and the output gas valve, and the pulse width of the pulse-width signal is proportional to the difference of the gas pressure measured by the sensor and the target pressure gas stored in the memory of the electronic control unit, and the distance along the gas in the gas cavity from the inlet in the housing to the pressure sensor

Description

The utility model is intended for converting gas from a liquefied state to a gaseous one and maintaining its flow rate at the level set by the electronic control unit.

Known controlled regulator of the flow of liquefied gas, comprising a housing with a gas cavity in communication with the inlet and outlet openings, a gas supply valve with an electromagnetic actuator, an inlet gas valve with an electromagnetic actuator installed in the inlet of the housing, an outlet gas valve with an electromagnetic actuator installed in the outlet of the housing, a pressure sensor installed in the gas cavity, a liquefied gas heater, and an electronic control unit, the input of which is electrically connected to the sensors gas pressure, and the outputs of the electronic control unit are electrically connected to the electromagnetic actuators of the gas flow valve, gas inlet valve and gas outlet valve, the gas valve inlet being in communication with a liquefied gas source, and the output in communication with a gas inlet valve (see RF patent No. 2162540, published January 27, 2001

A disadvantage of the known controlled controller is that in the prototype the inlet (control) valve is installed after the evaporator and the pressure regulation in the first chamber is made on already vaporized gas. The density of the vaporized gas is several times lower than the density of the liquefied gas; therefore, to control the flow rate, an inlet (control) valve is required with a passage section that is an order of magnitude higher than the required passage section of the valve for regulating liquefied gas. This requires the use of an inlet valve coil with a power several times higher than the capacity of a liquefied gas inlet valve coil.

The technical result, the achievement of which is proposed by the proposed utility model, is to reduce the diameter of the inlet section of the inlet valve, which reduces the weight of the regulator. The placement of a liquefied gas heater in the housing leads to the same technical result. The possibility of heating the surfaces of the gas cavity directly from the liquefied gas heater placed in the housing leads to a more economical use of the heat of the heater, since heat losses are reduced compared to the prototype, where the heater is moved outside the heater body.

In addition, the technical result of the claimed utility model is to reduce the power of the coil of the electromagnetic drive of the inlet valve, which leads to a reduction in the energy consumption necessary for the operation of the controller. Using the pulse width of the pulse-width signal proportional to the difference of the gas pressure measured by the sensor and the target gas pressure stored in the memory of the electronic control unit in the claimed utility model increases the accuracy of gas flow control depending on the pressure of the vaporized gas in the gas cavity. The accuracy of regulation of gas flow depending on the pressure of the vaporized gas is also increased by the placement of the pressure sensor in the zone where the vaporized gas is located, which is achieved by a sign that the distance along the gas in the gas cavity from the inlet in the housing to the pressure sensor is greater distance along the gas from the pressure sensor to the outlet in the housing.

Thus, the technical result aimed at achieving the proposed utility model is to reduce the weight of the regulator, reduce heat loss of the heater, increase the accuracy of regulation of gas flow depending on the pressure in the gas cavity and reduce the energy consumption necessary for the operation of the regulator.

The specified technical result is achieved by the fact that the controlled regulator of the flow of liquefied gas, comprising a housing with a gas cavity in communication with the inlet and outlet, a gas supply valve with an electromagnetic actuator, an inlet gas valve with an electromagnetic actuator installed in the inlet of the housing, at least one gas outlet valve with an electromagnetic actuator, connected to the outlet of the housing, a pressure sensor, a liquefied gas heater installed in the gas cavity, and an electric the control unit, the input of which is electrically connected to the gas pressure sensor, and the outputs of the electronic control unit are electrically connected to the electromagnetic actuators of the gas flow valve, gas inlet valve and gas outlet valve, the gas valve inlet being in communication with the liquefied gas source and the output in communication with gas inlet valve, while the liquefied gas heater is placed in the housing with the possibility of heating the surfaces of the gas cavity, the electronic control unit is made with possibly By generating a key on-off electrical signal supplied to the electromagnetic drive of the gas flow valve and pulse-width electric signals supplied to the electromagnetic drives of the gas input valve and gas outlet valve, the pulse width of the pulse-width signal is proportional to the difference of the gas pressure sensor and a given pressure of the gas stored in the memory of the electronic control unit, and the distance along the gas in the gas cavity from the input o the holes in the housing to the pressure sensor are greater than the distance along the gas from the pressure sensor to the outlet in the housing.

The liquefied gas heater can be made in the form of a channel placed in the housing for supplying liquid coolant from an external heating source or in the form of an electric heating element placed in the housing.

The drawing shows a diagram of the controller.

The controlled regulator of the flow of liquefied gas contains a housing 1 with a gas cavity 3 in communication with the inlet and outlet openings. The regulator includes: a gas supply valve 8 with an electromagnetic actuator, an inlet gas valve 4 with an electromagnetic actuator installed in the inlet of the housing 1, at least one gas outlet valve 6 with an electromagnetic actuator connected to the outlet of the housing 1, a pressure sensor 5 installed in the gas cavity 3, the liquefied gas heater 2, and the electronic control unit 7. The input of the electronic control unit 7 is electrically connected to the gas pressure sensor 3, and the outputs of the electronic control unit 7 are electrically connected to the electromagnetic drives of the gas flow valve 8, gas inlet valve 4 and gas outlet valve 6. The gas flow valve inlet 8 is in communication with a liquefied gas source ( for example, a cylinder of liquefied gas, not shown in the drawing), and the outlet of the gas supply valve 8 is in communication with the inlet gas valve 4, for example through a channel in the housing 1. A feature of the claimed useful mode whether it is that the liquefied gas heater 2 is placed in the housing 1 with the possibility of heating the surfaces of the gas cavity 3. In this case, the electronic control unit 7 is configured to generate pulse-width electrical signals supplied to the electromagnetic drives of the gas flow valve 8, the gas inlet valve 4 and output gas valve 6. The pulse width of the pulse-width signal is proportional to the difference of the gas pressure measured by the sensor 3 and the target gas pressure stored in the electric memory nnogo control unit 7. The distance along the gas in the gas cavity 3 from the inlet in the housing 1 to the pressure sensor 5 is greater than the distance along the gas from the pressure sensor 5 to the outlet in the housing 1, which allows you to place the pressure sensor 5 in the zone of vaporized gas directly in front of the outlet housing 1 for more accurate measurement of gas pressure exiting the regulator.

The liquefied gas heater 2 can be made either in the form of a channel placed in the housing 1 for supplying a liquid coolant from an external heating source as shown in the drawing, or in the form of an electric heating element placed in the housing 1 (not shown).

As components of the design of the controller can be used already known devices produced by industry.

Pressure sensor - type MPXHZ 6400 of the Motorola company (USA);

Consumption gas valve - OMV or VALTEC (Italy);

Gas inlet valve - type ATM70 of the Slavgaz company (Russia);

Outlet gas valve - type АТМ20 of the Slavgaz company (Russia);

Electronic control unit - type "AGAT-VRTec" company "Slavgaz" (Russia).

The operation of the controlled regulator of the flow of liquefied gas is as follows:

When the electrical signal "on / off" from the electronic control unit 7, the electromagnetic actuator opens the gas flow valve 8 and liquefied gas is supplied to the gas inlet valve 4. A hot liquid coolant is supplied to the heater channel 2 from an external heating source and heats the housing 1, including the walls of the gas cavity channel 3. By an electric signal from the electronic control unit 7, the electromagnetic drive opens the gas inlet valve 4 and liquefied gas enters the gas cavity 3, on the walls of which it evaporates and exits the regulator under pressure. The pressure level is measured by the pressure sensor 5 and transmitted to the electronic control unit 7. If the gas pressure exceeds a predetermined value, the electronic unit 7 sends an electric signal to the electromagnetic actuator of the inlet valve 4 and closes it, while the gas pressure in the gas cavity 3 starts to drop to the preset level, after which the electromagnetic actuator opens the gas inlet valve by the signal from the electronic control unit 7 4 and the gas pressure in the gas cavity 3 starts to rise again. The gas inlet valve 4 is controlled by a pulse-width signal, the opening pulse of which is proportional to the difference between the measured gas pressure in the gas cavity 3 by the pressure sensor 5 and a predetermined pressure value stored in the memory of the electronic control unit 7. Evaporated gas is supplied under pressure to the inlet of the outlet gas valve 6, the electromagnetic drive of which is also controlled by a pulse-width electric signal. Thus, the resulting flow rate depends both on the pressure level of the vaporized gas, and on the duty cycle of the signal that controls the opening of the outlet gas valve 6. In addition, the presence of the outlet gas valve 6 allows you to synchronize the time of supply of the vaporized gas with an external signal or any control algorithm implemented by the electronic control unit 7.

Thus, the claimed utility model allows to provide a technical result, which consists in reducing the weight of the regulator, reducing heat loss of the heater, increasing the accuracy of regulation of gas flow depending on the pressure in the gas cavity and reducing the energy consumption necessary for the operation of the regulator.

Claims (3)

1. A controlled regulator of the flow of liquefied gas, comprising a housing with a gas cavity in communication with the inlet and outlet, a gas supply valve with an electromagnetic actuator, an inlet gas valve with an electromagnetic actuator installed in the inlet of the housing, at least one gas outlet valve with an electromagnetic a drive, connected to the outlet of the housing, a pressure sensor, a liquefied gas heater installed in the gas cavity and an electronic control unit, the input of which is electrically it is connected with a gas pressure sensor, and the outputs of the electronic control unit are electrically connected to the electromagnetic actuators of the gas flow valve, gas inlet valve and gas outlet valve, the gas gas valve inlet being in communication with a liquefied gas source, and the output in communication with a gas inlet valve, characterized in that the liquefied gas heater is placed in the housing with the possibility of heating the surfaces of the gas cavity, the electronic control unit is configured to generate an electrical signal and on-off, supplied to the electromagnetic drive of the gas flow valve, and pulse-width electrical signals supplied to the electromagnetic drives of the gas input valve and gas outlet valve, and the pulse width of the pulse-width signal is proportional to the difference of the gas pressure measured by the sensor and the target pressure gas stored in the memory of the electronic control unit, and the distance along the gas in the gas cavity from the inlet in the housing to the pain pressure sensor more than the distance along the gas from the pressure sensor to the outlet in the housing. 2. The controller according to claim 1, characterized in that the liquefied gas heater is made in the form of a channel placed in the housing for supplying a liquid coolant from an external heating source. 3. The regulator according to claim 1, characterized in that the liquefied gas heater is made in the form of an electric heating element located in the housing.