NON-INVASIVE DEVICE FOR SIMULTANEOUS TESTING DYNAMIC CHARACTERISTICS AND INJECTION LAW OF GAS NEEDLE VALVE AND METHOD THEREOF

20250052642

18/519040

November 26, 2023

A non-invasive device for simultaneous testing dynamic characteristics and injection law of a gas needle valve and a method therefor are disclosed. The device includes a tested injector, a pressure sensor, a temperature sensor, an eddy current displacement sensor, a constant volume sealed container, and a controller. A nozzle of the tested injector is inserted into a constant volume cavity of the constant volume sealed container; the eddy current displacement sensor is arranged at a lower part of a gas needle valve of the tested injector; the pressure sensor and the temperature sensor are inserted into the constant volume cavity; and the controller is configured to receive displacement data, pressure data, and temperature data, and calculate the injection law of the tested injector based on the pressure data and the temperature data, achieving multi parameters testing of the needle valve lift and injection law in the same time and space.

1. A non-invasive device for simultaneous testing dynamic characteristics and injection law of a gas needle valve, comprising: a tested injector, a pressure sensor, a temperature sensor, an eddy current displacement sensor, a constant volume sealed container, and a controller; a nozzle of the tested injector is inserted into a constant volume cavity of the constant volume sealed container; the eddy current displacement sensor is arranged at a lower part of a gas needle valve of the tested injector; the pressure sensor and the temperature sensor are inserted into the constant volume cavity; and the controller is configured to receive displacement data collected by the eddy current displacement sensor, pressure data collected by the pressure sensor, and temperature data collected by the temperature sensor, and calculate the injection law of the tested injector based on the pressure data and the temperature data.

2. The device according to claim 1, wherein the device further comprises a high-pressure oil source and a high-pressure gas source; the high-pressure oil source is connected to the tested injector to provide fuel to the tested injector; and the high-pressure gas source is connected to the tested injector to provide gas to the tested injector.

3. The device according to claim 1, wherein the device further comprises a back pressure and pressurization valve and a pressure relief valve, and the back pressure and pressurization valve and the pressure relief valve are arranged on the constant volume sealed container.

4. A method for simultaneous testing dynamic characteristics and injection law of a gas needle valve realized by the device of claim 1, wherein the method comprises: obtaining the displacement data collected by the eddy current displacement sensor; the eddy current displacement sensor is arranged at the lower part of the gas needle valve of the tested injector; obtaining the pressure data collected by the pressure sensor; the pressure sensor and the temperature sensor are inserted into the constant volume cavity of the constant volume sealed container; and the nozzle of the tested injector is inserted into the constant volume cavity of the constant volume sealed container; calculating the injection law of the tested injector based on the pressure data and the temperature data.

5. The method according to claim 4, wherein calculating the injection law of the tested injector based on the pressure data and the temperature data specifically comprising: determining temperature changes in the constant volume cavity based on the temperature data; determining a calculation method of a injection volume of the tested injector based on the temperature changes; determining the injection law based on the determined calculation method of the injection volume.

6. The method according to claim 5, wherein an expression of the injection law is: [mathematical expression included] wherein, V is specific volume; M is molar mass; p is pressure inside the cavity; R is an adiabatic coefficient; T0 is temperature inside the cavity.

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edspap.20250052642