1. Introduction
Gas–liquid two-phase flow has a high heat transfer capacity and is widely used in the aerospace field. It often appears in various heat pipes in spacecraft thermal control systems [
1] and in the internal flow channels of various liquid nitrogen heat sinks, heat exchangers, and carburetors in space environment simulation equipment. With the development of new technologies, modern high-performance spacecraft use electronic chips with high integration, high power, and high heat flux, and need cooling technologies with a low weight, small volume, high heat transfer density, and high heat transfer efficiency [
2,
3,
4]. With the development of new spacecraft, components with high heat flux have appeared in space environment simulation equipment, which requires corresponding high-efficiency thermal protection devices. These increasing demands put forward higher requirements on the heat dissipation capacity of traditional thermal control and thermal protection means. Therefore, one of the effective ways to improve the heat transfer performance is to study flow channels with new structures.
The Tesla valve was invented by the famous inventor Nikola Tesla [
5]. Its forward pressure drop and reverse pressure drop are significantly different, so it can perform the function of a one-way valve by its internal structure. It plays a very important role in the field of microfluidic control and drive, so it is often called the “immovable micro-valve” in literature [
6,
7].
The internal flow of the Tesla valve is shown in
Figure 1. In the forward flow, the fluid mainly flows through the main pipe, which is manifested as a high velocity in the main pipe and low velocity in the arc branch pipe. In the reverse flow, most of the fluid flows through the arc branch pipe, while a small part flows through the main pipe, and the impact at the interchange leads to greater resistance. This is because the arc branch pipe structure guides the fluid to the T-shaped connection, where it interferes with the main pipe fluid, thereby obstructing the reverse flow [
6].
In order to explore its internal mechanism and further improve its performance, many scholars have studied the optimization and improvement of its structural parameters. Ronald Louis Bardell [
8] conducted theoretical and numerical studies on the internal mechanism of the Tesla valve, and proposed a key feature for characterizing the efficiency of the Tesla valve: diodicity, which means the ratio of the reverse pressure drop to the forward pressure drop. Bendib et al. [
9] designed a new Tesla valve and conducted a numerical simulation using a turbulence model to study the influence of its structural parameters on the one-way flow efficiency. Turowski et al. [
10] studied the transient characteristics inside the Tesla valve through the transient numerical simulation method and gave its equivalent circuit model. They called it a microfluidic diode based on the directional nature of the flow of the Tesla valve, which had similarities to diodes in the field of microelectronics. Thompson et al. [
11] conducted a numerical study on a multistage Tesla valve and found the influence of parameters such as the number of stages and spacing on the rectification effect of the Tesla valve.
Xu et al. [
12] redesigned the Tesla valve by means of topology optimization and obtained a high-efficiency Tesla valve with the inlet and outlet in the same direction. As shown in
Figure 2, its shape is different from the traditional Tesla valve, but its internal mechanism is still basically the same as that of the Tesla valve.
F. K. Forster et al. [
13,
14] applied the Tesla valve to a valveless piezoelectric pump, as shown in
Figure 3, and achieved good results. Wang Hao et al. [
15] proposed a design scheme for a valveless piezoelectric pump based on inertial momentum action, and also adopted the Tesla valve as a valve without moving parts. Ivano Izzo et al. [
16] used serial conical asymmetric resistance pipes, as shown in
Figure 4, in their valveless piezoelectric pump, whose internal mechanism is still similar to that of the Tesla valve, but its structure is quite different, and there is no difference between the main pipe and the arc branch pipe.
The one-way passage ability of the Tesla valve has also received strong attention in the field of gas–liquid two-phase flow. Thompson et al. [
17] integrated the Tesla valve into the adiabatic section of a pulsating heat pipe to improve the overall thermal performance, as shown in
Figure 5. They found that, compared with flat oscillating heat pipes without a Tesla valve, the use of a Tesla valve promoted circulation in the desired direction and that this boost increased with increasing heat input.
De Vries et al. [
18] designed a new type of Tesla valve and integrated it into the adiabatic section of the pulsating heat pipe to promote circulation, as shown in
Figure 6. The study found that the velocity and thermal performance were improved after increasing the valve.
After an extensive literature search, it was found that the studies on gas–liquid two-phase flow in Tesla valves were mainly concentrated in the field of pulsating heat pipes, all were experimental studies, and no numerical calculation studies on gas–liquid two-phase flow in Tesla valves were found.
In this paper, the gas–liquid two-phase flow in the Tesla valve is numerically calculated using the VOF model, and the flow pattern distribution and resistance change rule in the Tesla valve under zero-gravity conditions are explored. It provides a technical basis for further improving the heat transfer capacity of two-phase systems.
2. Mathematical Models and Simulation Methods
2.1. Geometric Model and Mesh Generation
The calculation model, shown in
Figure 7, is established according to the classic configuration that has been widely used today, namely the T45A Tesla valve structure mentioned in Ronald Louis Bardell’s study [
8].
The geometric model used for numerical calculation in this paper is shown in
Figure 8. The geometric model is a two-stage series Tesla valve, and the structure of the Tesla valve is the classic T45A-type configuration. The angle of the arc side intersection is 90°, the angle of the linear side is 45°, and the flow channel section is a square with a side length of 2 mm. Due to the complex structure of the model, the calculation area is discretized by a tetrahedral unstructured mesh.
2.2. Mathematical Model
Since the gas phase and liquid phase are continuous phases, the Euler–Euler simulation method (two-fluid model) is adopted. The core of the method is to treat the mixture of different phases as interleaved continuous dielectric materials. Interface capture adopts the volume fraction model (VOF model). In the calculation process of this model, only a set of momentum equations are used by each phase flow fluid at the same time, and the volume fraction of each phase fluid in each control unit is obtained. Then, the velocity, temperature and pressure distribution of each phase flow fluid are obtained from the volume fraction.
The VOF method is an interface capturing technique that is well suited for simulating immiscible fluids with clearly defined interfaces, and is widely used in the scenario of flow pattern analysis, such as those observed in slug flow. In this flow regime, the gas and liquid phases are distinctly separated, and the VOF method can accurately track the evolution of the interface between them. However, it is important to note that the VOF method may not be the most appropriate choice for simulating dispersed bubbly flow, where the phases are interpenetrating and the interfaces are not clearly defined.
Despite this limitation, we chose to use the VOF method for all the flow patterns in our study, including the dispersed bubbly flow, due to its ability to handle high gas volume fractions and its computational efficiency. While the VOF method may not capture the detailed dynamics of the interpenetrating phases in the bubbly flow regime, it can still provide valuable insights into the overall flow behavior and pressure drop characteristics.
2.3. Boundary Conditions
The boundary conditions are as follows: the inlet is set as the velocity-inlet, the outlet is the pressure-outlet, the pressure is normal pressure, and the wall boundary adopts adiabatic and non-slip boundary conditions.
The two phases are set as follows: the internal liquid phase is pure water and the gas phase is water vapor. The evaporation and condensation process of the phase interface is considered in the calculation, and both the gas–liquid phases at the inlet are 100 °C. The thermo-physical properties of the liquid and gas phases used in our simulations are summarized in
Table 1.
The gas content of the inlet (gas volume fraction) is set to 0.5. This parameter does not adopt the method of directly setting the gas content of the inlet two-phase flow, but separates the gas phase and liquid phase into two areas on the inlet section, and the gas liquid enters respectively at the same velocity. The area ratio of different areas is the gas–liquid ratio of the inlet. In this study, the area of the gas inlet is the same as that of the liquid inlet.
Considering the influence of the surface tension of the gas–liquid interface and referring to the actual flow pattern, the inlet area is set as a shape, as shown in
Figure 9, with the central circular area being the gas phase and the surrounding area being the liquid phase.
In our numerical simulations, the gas phase is positioned in the center of the channel at the inlet boundary. This phase distribution pattern is adopted to mimic the common scenario in two-phase flow systems, where the gas phase is injected into the liquid phase through a central nozzle or orifice. Such an arrangement promotes the formation of a symmetric flow pattern and is often encountered in practical applications, such as in gas–liquid mixers or bubble columns. Furthermore, the central positioning of the gas phase at the inlet helps to minimize the influence of the wall on the initial phase distribution, allowing for a more unbiased investigation of the flow patterns that develop downstream. This setup also facilitates the comparison of our results with experimental studies and other numerical simulations that employ similar inlet conditions.
5. Conclusions
In this paper, the gas–liquid two-phase flow in the flow passage of two Tesla valves under zero-gravity conditions with a rectangular section was numerically calculated. By using the VOF model and the inlet two-phase separation method, the forward and reverse flow patterns and pressure drop changes in the Tesla valves under different inlet velocities were analyzed. The main conclusions are as follows:
The flow pattern in the Tesla valve is related to the inlet velocity. At the low inlet velocity (0.1–0.2 m/s), the flow pattern is slug flow. The bubbles are distributed evenly at different positions in the Tesla valve, and affected by surface tension, the bubble resistance is large, resulting in a small difference between the velocity of the main pipe and the arc branch pipe.
When the inlet velocity is 0.4 m/s, the main flow pattern in the Tesla valve is annular flow and the gas–liquid phase separation flows through different flow channels, which is related to the pressure gradient generated by centrifugal force.
At a higher inlet velocity (0.6–0.8 m/s), bubbly flow and slug flow coexist. Due to the dominant role of inertia force, its flow characteristics are closer to single-phase flow, which generates different velocities at different locations, resulting in different flow patterns.
Within the study range, the difference in the forward and reverse pressure drops of two-phase flow was smaller than that of single-phase flow. The two-phase diodicity remained around 1.0, and decreased first and then increased with the change in inlet velocity, reaching minimum values of 0.78 at 0.2 m/s and 1.44 at 0.8 m/s.
Based on the simulated cases presented in this study, the use of Tesla valves in two-phase gas–liquid flow applications shows promise under certain flow regimes and operating conditions. Our simulations demonstrate that the unique geometry of the Tesla valve, with its alternating main and branch channels, can enhance mixing and separation between the gas and liquid phases and promote the breakup and coalescence of gas bubbles. In slug, annular, and bubble flows, the geometry of the Tesla valve appears to effectively regulate the flow pattern distribution, facilitate gas discharge, and improve the overall system performance. However, it is important to note that the effectiveness of Tesla valves in two-phase gas–liquid flows may be dependent on factors such as the specific valve geometry, flow rates, and fluid properties. Our study focused on a single Tesla valve geometry, and further investigations considering different valve designs and operating conditions are necessary to fully assess the feasibility and optimal application range of Tesla valves in these systems. Despite the limitations of our study, the results suggest that Tesla valves have the potential to offer advantages in certain two-phase gas–liquid flow applications. The improved mixing and dispersion characteristics observed in our simulations indicate that Tesla valves merit further exploration and consideration as a viable flow control and enhancement device in these systems.