FLAMED-BASED VACUUM GENERATOR

Abstract

The present disclosure discloses a flamed-based vacuum generator, including a shell and a combustion assembly, where the shell has a cavity, the cavity being a space having at least one opening, and the combustion assembly includes a combustible object and an igniter, the igniter being configured to ignite the combustible object, the combustible object generating a flame in the cavity, and the flame extinguishing in the cavity. In the present disclosure, through in-depth study of the internal mechanism of vacuum generated by flame combustion, it is found that the extinguishing process of a flame is the key to the generation of vacuum, and a larger flame and more sufficient combustion indicate a higher vacuum pressure generated in the cavity after the flame is extinguished.

Claims

1. A flamed-based vacuum generator, comprising a shell and a combustion assembly, wherein the shell has a cavity, the cavity being a space having at least one opening, and the combustion assembly comprises a combustible object and an igniter, the igniter being configured to ignite the combustible object, the combustible object generating a flame in the cavity, and the flame extinguishing in the cavity.

2. The flamed-based vacuum generator according to claim 1, wherein the combustion assembly further comprises a fuel replenishment unit, wherein the fuel replenishment unit is configured to replenish fuel required by the combustible object to the cavity.

3. The flamed-based vacuum generator according to claim 2, wherein the fuel replenished to the cavity by the fuel replenishment unit is a combustible gas, a combustible liquid, or an atomized combustible liquid.

4. The flamed-based vacuum generator according to claim 1, wherein the vacuum generator further comprises a ventilation mechanism, and the ventilation mechanism is configured to deliver air or a combustion-supporting gas to the cavity.

5. The flamed-based vacuum generator according to claim 4, wherein the ventilation mechanism further comprises a blowing device and an intercepting mechanism, the intercepting mechanism is configured to control communication between the cavity and outside atmosphere, so that the blowing device inputs the air or the combustion-supporting gas to the cavity.

6. The flamed-based vacuum generator according to claim 1, wherein the vacuum generator further comprises a high pressure inhibition device, configured to reduce a high pressure formed in the cavity when the flame is generated.

7. The flamed-based vacuum generator according to claim 6, wherein the high pressure inhibition device communicates the cavity and the outside atmosphere only when the pressure in the cavity is greater than a pressure outside the shell.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0021] FIG. 1 is a schematic diagram of a most basic structure and process of the present disclosure;

[0022] FIG. 2 is a change curve of pressure and temperature in a cavity during a whole process of combustion and extinguishment of a flame;

[0023] FIGS. 3A-3B show an experiment FIG. 3A and a result diagram FIG. 3B of a relationship between an amount of a flame and a vacuum pressure in the cavity;

[0024] FIG. 4 is schematic structural diagram of a specific implementation of the present disclosure;

[0025] FIG. 5 is a schematic diagram of the structure shown in FIG. 4;

[0026] FIG. 6 is a change curve of pressure in the cavity during the experiment process in FIG. 5;

[0027] FIG. 7 is schematic structural diagram of another specific implementation of the present disclosure;

[0028] FIG. 8 is a change curve of pressure in a cavity during the experiment process of the structure in FIG. 7;

[0029] FIG. 9 is schematic structural diagram of another specific implementation of the present disclosure;

[0030] FIG. 10 is schematic structural diagram of another specific implementation of the present disclosure; and

[0031] FIG. 11 is schematic structural diagram of another specific implementation of the present disclosure.

DETAILED DESCRIPTION

[0032] The solutions of the present disclosure is further explained and described by combining the embodiments and the accompanying drawings.

Embodiment 1

[0033] In this example, the vacuum generator is formed by a shell, a combustible object, and an igniter. The combustible object is an alcohol-containing block. A cavity is formed in the shell, and the alcohol-containing block is disposed in the cavity. The cavity is provided with an opening. To test the pressure and temperature changes in the cavity, a temperature sensor and a pressure sensor are disposed on a surface of a workpiece.

[0034] As shown in FIG. 1, first, the igniter ignites a solid alcohol-containing block, and the solid alcohol-containing block burns in the cavity to form a flame. Then, an end face at the opening of the shell is placed on the workpiece, and the workpiece covers the opening of the cavity and separates the cavity from the surrounding atmosphere, so that the cavity forms a closed space. The flame consumes oxygen in the cavity, and with the gradual decrease in the oxygen concentration, the flame is extinguished, and a vacuum pressure is formed in the cavity. The opening of the shell connects the vacuum pressure to the surface of the workpiece and plays a role in sucking the workpiece.

[0035] FIG. 2 is a curve of pressure and temperature in the cavity after the open end surface of the opening of the shell is placed on the workpiece. It can be seen that before step 3 in FIG. 1, the cavity is communicated with the surrounding atmosphere, and the pressure in the cavity is equal to the atmospheric pressure. After step 3, the pressure in the cavity decreases with the extinguishment of the flame, and finally a vacuum pressure of 50 kPa is formed. The reasons for the above vacuum pressure in the cavity are analyzed as follows:

[0036] 1) The combustion of the solid alcohol-containing block consumes oxygen

[0037] Oxygen accounts for 20% of the air. In the process of alcohol combustion, assuming that the combustion is completely sufficient, the chemical reaction of alcohol combustion consumes three oxygen molecules and produces two carbon dioxide molecules at the same time. According to this calculation, after the flame is extinguished, the gas in the cavity is reduced by about 7% (=20%/3), and the vacuum pressure obtained through calculation is only 7 kPa. The vacuum pressure is far less than the vacuum pressure measured by experiments. Apparently, the reason is not the main reason for the vacuum in the above-mentioned cavity.

[0038] 2) After the flame is extinguished, the temperature decreases and the gas cools and shrinks

[0039] When the solid alcohol-containing block burns, a large amount of heat is released, which increases the temperature in the cavity. After the flame is extinguished, the combustion stops, the alcohol-containing block no longer releases heat, the heat in the cavity is dissipated through heat exchange with the shell wall, and the temperature in the cavity decreases, so the gas in the cavity cools and shrinks to form a vacuum pressure. However, the data in FIG. 2 shows that the temperature has been rising until the flame is completely extinguished. And, even though the temperature is still rising, the vacuum pressure has been formed in a short time. When the temperature rises to the peak, there is already a vacuum pressure of 30 kPa. Apparently, the vacuum pressure of 30 kPa cannot be explained by temperature drop. Moreover, the temperature drop is a very slow process, and therefore the temperature drop cannot well explain the rapid generation of vacuum pressure either.

[0040] 3) Condensation of flame

[0041] A flame is a gas-like substance. The extinguishment of a flame is essentially a process in which this gas-like substance condenses into a liquid or solid. That is, when the flame is extinguished, the gas-like flame disappears, thus generating vacuum. A larger flame volume indicates a higher vacuum pressure that is generated after the flame is extinguished. FIG. 3A is a schematic diagram of the corresponding experiment. A plurality of alcohol-containing cotton balls are placed on a plane. The plurality of alcohol-containing cotton balls are ignited to generate a plurality of flame clusters. Then, the flame clusters are covered by a shell, and meanwhile the pressure inside the shell is measured by using a pressure sensor, to obtain the experimental results in FIG. 3B. The experimental results show that a larger number of flame clusters indicates a greater vacuum pressure in the shell, that is, a larger flame volume indicates a greater vacuum pressure. Moreover, in the process, the generation of the vacuum pressure is synchronized with the extinguishment of the flame, so the generation speed of vacuum pressure is very quick.

[0042] Generally, people only know the above-mentioned 1) and 2), which leads to a misunderstanding that: after the flame is extinguished, the formation of vacuum is very slow (the temperature drop process takes a long time), and the vacuum pressure is very small. The misunderstanding limits the development and utilization of the phenomenon. In addition, it also leads to another misunderstanding that: the magnitude of vacuum is not correlated with the size of flame. Therefore, in the current cupping technology, a flame is not put inside the cavity, and no design requirements for the size of the flame are put forward. It has been found through research in the present disclosure that the third reason is the core reason of generating vacuum pressure, and when being applied to a vacuum generator, so long as sufficient combustion is ensured and a flame large enough is obtained, high vacuum pressure can be quickly generated. Such the vacuum generator can have the value of industrial applicability.

Embodiment 2

[0043] FIG. 4 shows another specific implementation of the present disclosure. Compared with Embodiment 1, the vacuum generator of this embodiment maintains sufficient combustion and obtains a large flame by replenishing fuel. There are many ways to replenish fuel, but this embodiment will only be explained in one specific way. In this embodiment, the combustible object is an alcohol-impregnated asbestos block disposed in a cavity of a shell. The vacuum generator further includes a fuel replenishment unit, which includes a fuel container disposed outside the shell. The fuel container and the asbestos block are connected through a delivery pipe. An on/off valve is mounted on the delivery pipe. The igniter is disposed outside the shell, and an ignition head of the igniter extends into the shell and is close to the asbestos block.

[0044] When the on/off valve is opened, the liquid fuel (such as alcohol, kerosene, or gasoline) stored in the fuel container flows to the asbestos block through the delivery pipe and soaks the asbestos block, and then the on/off valve is closed to cut off the liquid fuel supply. Then, the igniter ignites the liquid fuel on the asbestos block, to generate a flame. The end surface at the opening of the shell is placed on a workpiece. The workpiece covers the opening of the cavity and separates the cavity from the surrounding atmosphere. The flame is extinguished, and a vacuum pressure is formed inside the cavity. The opening of the shell connects the vacuum pressure to the surface of the workpiece and plays a role in sucking the workpiece. After repeated combustion, the liquid fuel on the asbestos block becomes less, which may lead to the flame becoming smaller. The on/off valve may be opened again to replenish fuel to the asbestos block to ensure that there is enough fuel on the asbestos block, so that it can burn to form a large flame, thereby obtaining a higher vacuum pressure after the flame is extinguished.

Embodiment 3

[0045] In this embodiment, the vacuum generator of FIG. 4 is placed on the workpiece in advance, and the shell and the workpiece form a closed cavity, as shown in FIG. 5. Then, the fuel on the asbestos block is ignited. The fuel burns with the air in the cavity to generate a flame. Subsequently, the air in the cavity ran out and the flame is extinguished. FIG. 6 is a change curve of pressure in the cavity obtained through experiments. When the fuel burns in the closed cavity, generation of the flame may cause the pressure in the cavity to rise rapidly. Such the pressure rise may raise the pressure drop curve when the flame is extinguished, which may lead to the decrease of vacuum pressure in the cavity, and even fail to form a vacuum pressure. Therefore, in industrial applications, inhibition of the pressure rise of the combustible object in closed cavity is helpful to enhance the vacuum pressure. In this embodiment, a high pressure inhibition device is disposed to inhibit and reduce the pressure rise when the flame is generated, thereby achieving the objective of improving the vacuum pressure. The high pressure inhibition device communicates the cavity with the outside atmosphere only when the pressure in the cavity is greater than a pressure outside the shell.

[0046] The high pressure inhibition device in this embodiment is a check valve, and the check valve is communicated with the cavity through a pipe, as shown in FIG. 7. When the fuel burns, the pressure in the cavity rises, and the check valve opens under the action of pressure difference between the two sides (the atmospheric pressure is lower than the pressure in the cavity). The high-pressure gas in the cavity is discharged through the check valve, thereby playing a role in reducing the high pressure in the cavity. When the vacuum pressure begins to form in the cavity, the check valve is closed under the action of pressure difference on both sides (the atmospheric pressure is higher than the pressure in the cavity), thereby playing a role in maintaining the vacuum pressure in the cavity. FIG. 8 shows experimental results of the device of FIG. 7. By comparing the results in FIG. 6 and FIG. 8, it can be seen that the high pressure inhibition device can effectively inhibit and reduce the pressure rise in the cavity and increase the vacuum pressure after the flame is extinguished.

Embodiment 4

[0047] FIG. 9 shows another specific implementation of the present disclosure. This embodiment is a further improvement on the above-mentioned embodiments, and it is possible to conveniently use the vacuum pressure through the opening of the shell.

[0048] The opening of the shell in this embodiment is reduced into a hole. The opening of the shell communicates the vacuum pressure in the cavity through a vacuum tube to vacuum-using equipment, such as a suction cup. The vacuum in the cavity enables the suction cup to suck the workpiece. When the suction cup is detached from the workpiece, external air may flow through the suction cup and vacuum tube into the cavity, so that there is a certain amount of oxygen in the cavity, so that secondary combustion can be carried out.

[0049] After primary combustion is completed, an exhaust gas may be generated in the cavity. The opening of the shell in this embodiment is relatively small, and therefore it is difficult to effectively discharge exhaust gas. If the exhaust gas cannot be discharged, the oxygen content in the cavity may be reduced, resulting in insufficient combustion of fuel, and further affecting the flame volume. Therefore, the vacuum generator of this embodiment is further provided with a ventilation mechanism for discharging combustion exhaust gas and feeding air, as shown in FIG. 10. The ventilation mechanism includes a blowing device and an intercepting mechanism. The intercepting mechanism is configured to control communication between the cavity and outside atmosphere, so that the blowing device inputs the air to the cavity or discharges the exhaust gas from the cavity to the outside atmosphere. Before the next combustion, the intercepting mechanism is opened to communicate the cavity with the outside atmosphere. The blowing device is then started, to feed outside air through the air supply pipe to the cavity. In the process of air supply, the exhaust gas from the last combustion is discharged outward through an open hole or an intercepting mechanism. After the exhaust gas is discharged and the air is filled in the cavity, the intercepting mechanism closes the communication between the cavity and the outside atmosphere, and at the same time, the blowing device stops. After the suction cup is placed on the workpiece, the igniter ignites the fuel on the asbestos block to carry out a new round of workpiece suction action.

[0050] In addition, to increase the burning flame, the ventilation mechanism may further feed a combustion-supporting gas such as pure oxygen to the cavity. Oxygen can make the combustion more sufficient and the flame bigger.

Embodiment 5

[0051] In this embodiment, the combustible object used in the vacuum generator is gaseous or quasi-gaseous, such as methane, or atomized gasoline. As shown in FIG. 11, the fuel replenishment unit includes an on/off valve, a fuel container, and a delivery pipe. When the on/off valve is opened, the combustible gases or oil mist are delivered from the fuel container to the cavity to be mixed with the air in the cavity. After ignition by the igniter, a flame is generated, and a vacuum pressure is formed when the flame is extinguished. The advantages of using the gaseous or quasi-gaseous fuel such as combustible gas or oil mist as the combustible object is that the flame can be formed in the whole cavity, which is helpful to improve the vacuum pressure. Experiments show that compared with the above-mentioned alcohol-containing block and asbestos block soaked with alcohol, using atomized alcohol as fuel can produce a higher vacuum pressure.