Test system and method for the mutual solubility of biomass-based blended fuel

Abstract

The present invention relates to a test system and method for a biomass-based blended fuel. The system comprises a feeding device, a mixing tank, a light-sensing device, and a control device; the feeding device comprises at least two fuel bottles; the fuel bottle is connected to the mixing tank by means of an oil pipe; the correspondingly connected oil pipe of each fuel bottle is provided with a flow valve; the light-sensing device comprises a laser disposed above the mixing tank, a light-reflecting mechanism disposed at the bottom in the mixing tank, and a light-sensing mechanism disposed at one side of the light reflecting mechanism; the output end of the light-sensing mechanism is signaled with the input end of the control device; the input end of the laser and the input end of the flow valve is separately signaled with the output end of the control device.

Claims

1. A system for testing the mutual solubility of biomass-based blended fuels, the system comprising: a feeding device; a mixing tank; a light sensing device; a control device; the feeding device includes at least two fuel bottles, and the fuel bottles pass through the tubing connected to the mixing tank, each fuel bottle is provided with a flow valve on a correspondingly connected oil pipe; and the light sensing device includes a laser arranged above the mixing tank, a reflecting mechanism arranged on a bottom surface of the mixing tank, and a photosensitive mechanism on one side of the reflecting mechanism, an output end of the photosensitive mechanism is signally connected to an input end of the control device, and an input end of the laser and an input end of the flow valve are respectively connected to a output end of the control device.

2. The system for testing the mutual solubility of biomass-based blended fuels according to claim 1, wherein: the reflecting mechanism is a horizontally placed reflector; the photosensitive mechanism is a plate with a photosensitive sensor on a surface of the plate an surface of the plate with the photosensitive sensor is set toward the laser; and the laser is set at a certain angle with a vertical line and a laser head of the laser is inclined toward the plate.

3. The system for testing the mutual solubility of biomass-based blending fuels according to claim 1, wherein one end of the oil pipe is connected to the corresponding fuel bottle, and the other end is connected to an end of a three-way pipe, and the three-way pipe is connected to the mixing tank.

4. The system for testing the mutual solubility of biomass-based blended fuels according to claim 1, further comprising: a water bathtub, wherein the mixing tank is located in the water bathtub; a temperature control mechanism and a first temperature detector are provided in the water bathtub; an output terminal of the first temperature detector is connected with the input end of the control device, and an input terminal of the temperature control mechanism is connected with the output end of the control device.

5. The system for testing the mutual solubility of biomass-based blended fuels according to claim 1, wherein the mixing tank is provided with a stirrer and a second temperature detector, an output end of the second temperature detector is connected to the input end of the control device, and an input end of the stirrer is connected to the output end of the control device.

6. The system for testing the mutual solubility of biomass-based blended fuels according to claim 1, further comprising an LED display, and an input end of the LED display is connected to the output end of the control device.

7. The system for testing the mutual solubility of biomass-based blended fuels according to claim 1, wherein the control device is an ECU control system.

8. A method for testing the mutual solubility of biomass-based blended fuels, the method comprising: 1) Controlling a test system under a constant temperature condition, introducing a base liquid and an additive solution into different fuel bottles, turning on a laser, sensing a light spot reflected by a reflection mechanism through a photosensitive sensor of a photosensitive mechanism, and marking position signal as a base point through a control device, and then turning off the laser; 2) Quantitatively injecting the base liquid into a mixing tank through a flow valve, making the base liquid in the mixing tank bury the reflective mechanism, turning on the laser when a liquid level in the mixing tank is calm and without bubbles, sensing the light spot reflected by the reflection mechanism through the photosensitive sensor of the photosensitive mechanism, marking the position signal as A.sub.0 through the control device, and then turning off the laser; 3) Injecting the additive solution into the mixing tank by volume unit through the flow valve, turning on the laser when the liquid level in the mixing tank is calm and there are no bubbles, inducing a reflection of the light spot by the reflection mechanism and sensing the reflected light spot through the photosensitive sensor of the photosensitive mechanism, marking the position signal as A.sub.1 by the control device, and then turning the laser off; 4) Repeat step 3) to inject the same volume unit of the additive solution into the mixing tank, recording the position signal of the corresponding light spot respectively of A.sub.2, A.sub.3, A.sub.4 . . . A.sub.n, wherein a displacement relationship from A.sub.0 to A.sub.n corresponding to the spot position changes regularly with respect to the spot position corresponding to the base point until the displacement relationship between the spot position corresponding to A.sub.n+1 and the spot position corresponding to the base point changes irregularly, which indicates a delamination between the base liquid and the additive solution in the mixing tank leading to a sudden change in refractive index; and calculating a cumulative injection volume of the additive solution before the delamination in the mixing tank occurs to obtain a miscible ratio of the biomass-based blended fuel.

9. A method for testing a mutual solubility of biomass-based blended fuels, the method comprising: 1) Introducing a base fluid and an additive solution into different fuel bottles, turning on a laser, sensing a light spot reflected by a reflection mechanism through a photosensitive sensor of a photosensitive mechanism, and marking a position signal as a base point through a control device, and then turning off the laser; 2) Injecting the base liquid and additive solution into a mixing tank in proportion and quantitatively through a flow valve, making the base liquid in the mixing tank bury the reflective mechanism, turning on the laser when a liquid level in the mixing tank is calm and without bubbles and layering, sensing the light spot reflected by the reflection mechanism through the photosensitive sensor of the photosensitive mechanism, marking the position signal as A.sub.0 through the control device, and then turning off the laser 3) Raising or lowering a temperature of the mixing tank in units of temperature, turning on the laser when the liquid level in the mixing tank is calm and there are no bubbles, marking a position signal as A.sub.1 of a light spot reflected by the photosensitive reflection mechanism by the photosensitive sensor of the photosensitive mechanism through the control device, and then turning off the laser; 4) Repeat step 3) to increase or decrease the temperature of the mixing tank with the same temperature unit gradient, and respectively record the position signal of the corresponding light spot after the temperature adjustment to A.sub.2, A.sub.3, A.sub.4 . . . A.sub.n, wherein A.sub.0 to A.sub.n correspond to a relative displacement of the spot position in a copolyesters A.sub.n+1 with respect to the spot position corresponding to the base point A.sub.n+1, and the displacement relationship of the spot position relative to the spot position corresponding to the base point changes irregularly when a stratification of the base liquid and the additive solution occurs in the mixing tank resulting in a sudden change in refractive index; and Recording a temperature information at the time of the stratification to reconcile a relationship between the mutual solubility of the biomass-based blended fuel and the temperature.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic structural diagram of a system for testing the mutual solubility of biomass base blends and fuels in specific embodiments;

(2) FIG. 2 is a light spot displacement diagram for measuring the miscibility ratio of gamma valerolactone and gasoline by using the mutual solubility test system of biomass-based blended fuel in a specific embodiment;

(3) FIG. 3 is a schematic diagram of the light spot displacement measured by the mutual solubility test system of biomass-based blended fuel in a specific embodiment on the relationship between the mutual solubility of gamma valerolactone and gasoline and the environmental temperature.

DETAILED DESCRIPTION OF THE INVENTION

(4) In order to make the objectives, technical solutions and advantages of the present invention clearer, the following further describes the present invention in detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described here are only used to explain the present invention, but not to limit the present invention.

(5) As shown in FIG. 1, a system for testing the mutual solubility of biomass base blend fuels, the system includes a feeding device, a mixing tank, a light sensing device, a water bathtub, an LED display 5 and a control device:

(6) The feeding device includes two fuel bottles 41, the bottom of each fuel bottle 41 is correspondingly connected with an oil pipe, the oil pipe is connected to the mixing tank 2 through a three-way pipe 43, and each fuel bottle 41 is correspondingly connected with a volume flow valve on the oil pipe 42;

(7) The light sensing device includes a laser 31, a light-reflecting mechanism 32, and a photosensitive mechanism 33. The laser 31 is arranged above the mixing tank 2 and arranged at a certain angle with the vertical line; the light-reflecting mechanism 32 is horizontally arranged on the mixing tank 2; the reflector on the inner bottom surface; the photosensitive mechanism 33 is a plate body with a photosensitive sensor arranged on the plate surface. The plate is arranged on the side of the reflective mechanism 32 and the plate surface with the photosensitive sensor faces the laser 31, and the laser head of the laser 31 faces the board is inclined.

(8) The mixing tank 2 is located in the water bathtub 1, a temperature control mechanism 12 and a first temperature detector 11 are arranged in the water bathtub 1, and a stirrer 21 and a second temperature detector 22 are arranged in the mixing tank 2.

(9) The control device is the ECU control device 6. The light sensor output end of the photosensitive mechanism 33 is signal-connected to the input end of the ECU control device 6, and the input end of the laser 31 and the input end of the volume flow valve 42 are respectively connected to the output of the ECU control device 6 of terminal signal connection. The output terminals of the first temperature detector 11 and the second temperature detector 22 are respectively connected to the input terminal of the ECU control device 6, and the input terminals of the temperature control mechanism 12 and agitator 21 are respectively connected to the output of the ECU control device 6. The input terminal of the LED display 5 is connected to the output terminal of the ECU control device 6.

(10) Taking γ valerolactone as an example, using the above-mentioned biomass-based blending fuel mutual solubility test system to determine the mutual solubility ratio of γ valerolactone and gasoline, the steps are as follows: 1) Introduce 200 volumes of gasoline and 200 volumes of γ valerolactone into the two fuel bottles 41 respectively. Gasoline is the base liquid, and γ valerolactone is the additive solution. Coolant is injected into the water bathtub 1, and the ECU control device 6 controls the temperature. After the mechanism 12 works and the coolant temperature reaches 20° C., the ECU control device 6 controls the laser 31 to turn on. The light beam emitted by the laser 31 is reflected by the reflective mechanism 32 to the plate of the photosensitive mechanism 33. The photosensitive sensor senses the light spot and passes the control device. Mark its position signal as the base point, and then the ECU control device controls the laser to turn off; 2) The ECU control device controls the flow valve to open and injects 100 volumes of base liquid into the mixing tank and makes the base liquid in the mixing tank bury the reflective mechanism, and wait until the second temperature detector detects that the base liquid temperature in the mixing tank reaches 20° C. and in its calm and bubble-free state, the ECU control device controls the laser to turn on. The beam emitted by the laser is refracted by the base liquid and is reflected on the plate of the photosensitive mechanism through the reflective mechanism. The photosensitive sensor senses the light spot reflected by the reflective mechanism and passes through the control device. Mark its position signal as A.sub.0, and then the ECU control device controls the laser to turn off; 3) The ECU control device controls the flow valve to open and injects 1 volume of additive solution into the mixing tank. The ECU control device controls the agitator to stir the liquid in the mixing tank for a certain period of time, and the second temperature detector detects the liquid in the mixing tank. When the temperature reaches 20° C. and it is calm and bubble-free, the ECU control device controls the laser to turn on. The beam emitted by the laser is refracted by the liquid and reflected on the plate of the photosensitive mechanism through the reflective mechanism. The photosensitive sensor senses the light spot reflected by the reflective mechanism. And mark its position signal as A.sub.1 through the control device, and then the ECU control device controls the laser to turn off; 4) Repeat step 3) to inject 1 volume unit of additive solution into the mixing tank, and record the position signals of the corresponding light spots as A.sub.2, A.sub.3, A.sub.4 . . . A.sub.n, A.sub.0 to A.sub.n the displacement relationship between the corresponding spot position and the spot position corresponding to the base point changes regularly, and the displacement relationship between the spot position corresponding to A.sub.n+1 and the spot position corresponding to the base point changes irregularly (as shown in FIG. 2). Time means that the liquid in the mixing tank has stratified, resulting in a sudden change in refractive index, which means that the base liquid and the additive solution are no longer mutually soluble in the current temperature state. The control device calculates the additive solution before the stratification in the mixing tank occurs. The accumulative injection volume is displayed on the LED display: ambient temperature 20° C., gasoline 100 volume units and γ valerolactone 35 volume units.

(11) The test system of the present invention can also be used to determine the relationship between the mutual solubility of the blended fuel and the ambient temperature. The method is as follows: 1) Introduce 200 volumes of gasoline and 200 volumes of γ valerolactone into the two fuel bottles respectively. The gasoline is set as the base fluid and the γ valerolactone is set as the additive solution. Coolant is injected into the water bathtub, and the ECU control device controls the temperature control mechanism. After working and making the coolant temperature reach 0° C., the ECU control device controls the laser to turn on, the beam emitted by the laser is reflected on the plate of the photosensitive mechanism through the reflective mechanism, the photosensitive sensor senses the light spot, and the control device marks its position signal as the base point. Then the ECU control device controls the laser to turn off; 2) The ECU control device controls the flow valve to open and injects the base liquid and additive solution into the mixing tank at a volume ratio of 100:35, and makes the liquid in the mixing tank bury the reflective mechanism, and wait for the second temperature detector to detect the inside of the mixing tank. When the liquid temperature reaches 0° C. and it is calm and bubble-free, the ECU control device controls the laser to turn on. The light beam emitted by the laser is refracted by the mixed liquid and reflected on the plate of the photosensitive mechanism through the reflective mechanism. The photosensitive sensor senses the reflection of the reflective mechanism. Light spot, and mark its position signal as A.sub.0 by the control device, and then the ECU control device controls the laser to turn off; 3) The ECU control device controls the temperature control mechanism to work and increases the coolant temperature by 1° C. After the second temperature detector detects that the temperature of the liquid in the mixing tank reaches the corresponding temperature and is calm and without bubbles, the ECU control device controls the laser to turn on. The light beam emitted by the laser is refracted by the liquid and reflected on the plate of the photosensitive mechanism through the reflective mechanism. The photosensitive sensor senses the light spot reflected by the reflective mechanism and marks its position signal as A.sub.1 through the control device, and then the ECU control device controls the laser shut down; 4) Repeat step 3) to perform a gradient heating of the mixing tank (if the base point is set at a high temperature, a gradient cooling method can also be used), and respectively record the position signals of the corresponding spots after heating as A.sub.2, A.sub.3, A.sub.4, . . . A.sub.n, A.sub.0 to A.sub.n corresponding to the light spot position with respect to a A.sub.0 displacement relationship of the spot positions corresponding to change regularly, to be A.sub.n+1 corresponding to the spot position relative to A.sub.0 corresponding to the spot position. When the displacement relationship changes irregularly (as shown in FIG. 3), it means that the liquid in the mixing tank has a delamination phenomenon leading to a sudden change in refractive index, which means that the base liquid and the additive solution are no longer miscible in the current temperature state, and the mixing tank. The second temperature detector inside detects the d temperature information in the mixing tank and displays the corresponding data through the LED display: temperature 20° C.