CN113506644A - Visual experimental device and method suitable for bundle channel flow boiling heat transfer - Google Patents

Abstract

The invention provides a visual experimental device suitable for bundle channel flowing boiling heat transfer, which comprises: the system comprises an experiment loop part and a data acquisition part, wherein the experiment loop part comprises a visual experiment body and a high-voltage power supply, and the visual experiment body comprises an experiment rod bundle; deionized water in the experiment loop part enters the visual experiment body and is heated by the experiment rod bundle, and deionized water at the outlet of the visual experiment body is cooled by the coolant and then enters the visual experiment body again; an ITO (indium tin oxide) electroplated layer is arranged on the experimental bar bundle and is connected with a high-voltage power supply, and a coolant in a bar bundle channel absorbs heat generated by an ITO film to generate bubbles; the data acquisition part acquires transient bubble characteristics of two-phase flow in the internal area of the rod bundle channel through the visual experiment body. According to the invention, a set of closed experimental loop is designed, the visualization requirement of the rod bundle channel is met, and the flow, the water temperature, the wall temperature and the heating power in the rod bundle channel are obtained through the data acquisition system part while the transient bubble of the rod bundle channel is obtained.

Description

Visual experimental device and method suitable for bundle channel flow boiling heat transfer

Technical Field

The invention relates to the technical field of nuclear power, in particular to a visualization experiment device and method suitable for bundle channel flowing boiling heat transfer.

Background

Nuclear reactors have power densities much greater than conventional active devices and the reactor core is in a high temperature, high pressure environment. In order to increase the heat exchange area of the nuclear fuel, the fuel bundles are usually arranged in a bundle structure of cells. The coolant of a reactor primary loop flows through the rod bundle assembly and takes away heat generated by the reactor core, and the research on the flow heat transfer characteristics in the rod bundle channel has important significance for ensuring the safety of the reactor core.

For pressurized water reactor cores, there is single phase flow in the core under normal operating conditions. When a small break accident occurs in a primary circuit or the main pump stops running, the reactor core is boiled and transfers heat and generates steam bubbles due to insufficient cooling of the reactor core. For a boiling water reactor, under the design working condition, coolant is directly boiled in a reactor core, and reactor core steam directly pushes a steam turbine to do work after passing through a steam-water separator and a dryer. It follows that the phenomenon of flow boiling heat transfer is common during operation of nuclear reactors.

Of the relevant theories regarding boiling heat transfer, the cavity theory proposed by Zuber is generally accepted. The theory of boiling heat transfer holes considers that when the heat flux density of the heat transfer surface, the superheat degree of fluid of a heat boundary layer and other parameters reach a certain range, the nucleation point of the heat transfer wall surface is activated after the heat flux density of the heat transfer wall surface, the superheat degree of fluid of the heat boundary layer and other parameters reach a certain range. The liquid phase near the nucleation point absorbs the heat transferred by the thermal boundary layer and rapidly vaporizes and forms a vapor bubble. After the steam bubble grows to a certain degree, the steam bubble can generate actions of annihilation, slippage, growth and the like according to different heat transfer working condition points. As the vapor bubble continues to absorb heat from the thermal boundary layer, the relevant parameters begin to fall below the critical point for nucleate boiling and the vapor bubble stops growing. Research on boiling heat transfer of a bundle component has been started since the seventies of the last century, but no complete set of heat transfer theoretical system and prediction model exists so far. The observation of the transient behavior of the vapor bubble is of great significance to the study of the flow heat transfer of the rod bundle channel.

Through retrieval, patent document CN110729060B discloses a visual experimental device and method for a flow trace in a rod bundle channel under a motion condition, which comprises a rod bundle element and a rod bundle channel which are positioned in a rod bundle channel shell, wherein a visual window is arranged on the rod bundle channel shell; the bottom of the rod cluster channel shell is connected with a fixed flange plate, and the fixed flange plate is used for fixing the rod cluster element and enabling a working medium to flow into the rod cluster channel; the upper surface of the fixed flange plate is provided with a plurality of needles, a flow passage communicated with all the needles is arranged in the fixed flange plate, and the injection system is used for injecting a tracer into the flow passage. The research content corresponding to the prior art is concentration field measurement under a single-phase flow condition, and the capability of researching the characteristics of the size, the service life and the like of the steam bubble under the condition of two-phase flow is not provided.

Patent document CN104681110B discloses a full-transparent visualization experiment device for a rod bundle channel, which comprises a rod bundle channel body and a pressure-bearing shell arranged outside the rod bundle channel body and used for clamping the rod bundle channel body, wherein the rod bundle channel body is made of a transparent material, and observation grooves are formed in the periphery of the pressure-bearing shell. Although the prior art preliminarily realizes the visualization experiment of the two-phase flow, the two-phase flow characteristics of the inner area of the rod bundle cannot be obtained.

Because the rod cluster component is of a grid cell structure, the structure is more complex compared with a circular tube structure, and a set of visual experiment system is needed to be developed to observe transient bubble images in the rod cluster component. Meanwhile, the system has the capability of collecting key experimental parameters such as fluid flow, temperature, heat flux density and the like in the rod bundle.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a visual experimental device and a visual experimental method suitable for the flow boiling heat transfer of a rod bundle channel, and a set of closed experimental loop is designed; the quartz glass tube with the ITO electroplated layer is used as an experimental rod, so that the visualization requirement of a rod bundle channel is met; when shooting transient bubbles of the rod bundle channel, the flow, the water temperature, the wall temperature and the heating power in the rod bundle channel are obtained through a data acquisition system.

The invention provides a visual experimental device suitable for the flow boiling heat transfer of a rod bundle channel, which comprises: the system comprises an experiment loop part and a data acquisition part, wherein the experiment loop part comprises a visual experiment body and a high-voltage power supply, and the visual experiment body comprises an experiment rod bundle; deionized water in the experiment loop part enters the visual experiment body and is heated by the experiment rod bundle, and deionized water at the outlet of the visual experiment body is cooled by the coolant and then enters the visual experiment body again; an ITO (indium tin oxide) electroplated layer is arranged on the experimental bar bundle and is connected with a high-voltage power supply, and a coolant in a bar bundle channel absorbs heat generated by an ITO film to generate bubbles; the data acquisition part acquires transient bubble characteristics of two-phase flow in the internal area of the rod bundle channel through the visual experiment body.

Preferably, the experiment loop part comprises a deionized water tank, a magnetic gear pump, a filter and an observation section; one end of the deionized water tank is connected with one end of the magnetic gear pump, and the other end of the deionized water tank is connected with one end of the observation section; one end of the filter is connected with the other end of the magnetic gear pump, and the other end of the filter is connected with the visual experiment body.

Preferably, the deionized water tank comprises a visual window, a cooling coil, a heater and an exhaust valve, the exhaust valve is in through connection with the inside and the outside of the deionized water tank, and the visual window is arranged between the cooling coil and the heater.

Preferably, the non-condensable gas in the experimental loop part is exhausted through an exhaust valve at the top of the deionized water tank, and the water temperature in the deionized water tank is jointly regulated by the cooling coil and the heater.

Preferably, the visual experiment body further comprises experiment rod bundle fixing plates and positioning grids, the experiment rod bundle fixing plates are arranged at two ends of the experiment rod bundle, and the positioning grids are arranged on the experiment rod bundle at equal intervals.

Preferably, the visual experiment body further comprises a visual rod bundle experiment section, the experiment rod bundle is a quartz glass tube, the quartz glass tube is arranged in a rectangular shape and is arranged in the visual rod bundle experiment section, and the ITO electroplated layer is arranged on the inner wall surface of the quartz glass tube.

Preferably, the quartz glass tube has an outer diameter of 9.5mm and a wall thickness of 1mm, and the quartz glass tube has a heat resistance temperature exceeding 800 ℃.

Preferably, heat generated by the ITO plating is absorbed by the deionized water in the rod bundle channel through the quartz glass tube, and the transmittance of the ITO plating is over 70%.

Preferably, the system also comprises a thermocouple and a flowmeter, wherein the thermocouple and the flowmeter are arranged on the rod bundle channel, the flow rate of the fluid in the experimental loop part is recorded by the flowmeter, the water temperature and the wall temperature are recorded by the thermocouple, and the heating power is read by an index on the high-voltage power supply.

According to the visualization experiment method suitable for the flow boiling heat transfer of the rod bundle channel, which is provided by the invention, the visualization experiment is carried out by adopting the visualization experiment device suitable for the flow boiling heat transfer of the rod bundle channel, and the visualization experiment method comprises the following steps:

step S1: arranging quartz glass tubes with ITO electroplated layers into a rectangle, placing the quartz glass tubes in a visual rod bundle experiment section, and connecting the ITO electroplated layers on the quartz glass tubes with a high-voltage power supply;

step S2: opening a magnetic gear pump on the experimental loop part, and discharging the non-condensable gas out of the experimental loop part through an exhaust valve;

step S3: adjusting the water temperature in the deionized water tank to a specified temperature through a cooling coil and a heater, and adjusting the fluid flow rate of the experimental loop part through a valve on the experimental loop part;

step S4: starting a high-voltage power supply and adjusting the electric power of the high-voltage power supply, wherein heat generated by the ITO electroplated layer is absorbed by a coolant in the visual experiment body after passing through the quartz glass tube, and bubbles are generated;

step S5: shooting bubble characteristics in the rod bundle channel through the data acquisition part, and simultaneously recording the flow speed of the experimental loop part, the water temperatures of an inlet and an outlet of the rod bundle channel, the wall surface temperature of the rod bundle channel and the heating power of the high-voltage power supply;

step S6: changing the flow rate of the experimental loop part, the inlet temperature and the heating power of the visual rod bundle experimental section, and repeating the steps S1-S5 to obtain transient bubble images and wall temperature parameters under different conditions.

Compared with the prior art, the invention has the following beneficial effects:

1. the invention can obtain the characteristics of the two-phase flow steam bubble in the internal area of the rod bundle by adopting the visual experimental section and the visual experimental rod bundle through the flow boiling heat transfer of the rod bundle channel.

2. According to the invention, the quartz glass tube is used as the experiment rod bundle, the quartz glass has high heat resistance and small thermal expansion coefficient, and can meet various experiment working conditions.

3. According to the invention, the ITO electroplated layer is plated on the inner wall surface of the quartz glass tube, so that the shooting requirement of the bubble image is met, the visualization of the rod bundle channel can be realized, and the transient bubble image in the rod bundle component can be directly shot through the data acquisition part.

4. The invention combines a flowmeter, a thermocouple and the like, so that parameters such as flow, water temperature, wall temperature and the like are collected for thermal analysis while transient bubbles are shot.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic diagram of the overall structure of a visual experimental apparatus suitable for bundle channel flow boiling heat transfer in the present invention;

FIG. 2 is a schematic structural diagram of an experimental section of a visualization bundle in accordance with the present invention;

FIG. 3 is a schematic structural view of a fixing plate of the experimental bar of the present invention;

fig. 4 is a schematic structural view of an electrode fixing plate according to the present invention.

In the figure:

Detailed Description

The present invention will be described in detail with reference to specific examples. The following examples will assist those skilled in the art in further understanding the invention, but are not intended to limit the invention in any way. It should be noted that it would be obvious to those skilled in the art that various changes and modifications can be made without departing from the spirit of the invention. All falling within the scope of the present invention.

As shown in fig. 1, the present invention provides a visual experimental apparatus suitable for bundle channel flow boiling heat transfer, comprising: the system comprises an experiment loop part and a data acquisition part, wherein the experiment loop part comprises a visual experiment body and a high-voltage power supply 12, and the visual experiment body comprises an experiment rod bundle; deionized water in the experiment loop part enters the visual experiment body and is heated by the experiment rod bundle, and deionized water at the outlet of the visual experiment body is cooled by the coolant and then enters the visual experiment body again; an ITO (indium tin oxide) electroplated layer 1502 is arranged on the experimental bar bundle, the ITO electroplated layer 1502 is connected with a high-voltage power supply 12, and a coolant in a passage of the bar bundle absorbs heat generated by an ITO film to generate bubbles; the data acquisition part acquires transient bubble characteristics of two-phase flow in the internal area of the rod bundle channel through the visual experiment body.

The experiment loop part comprises a deionized water tank 1, a magnetic gear pump 6, a valve 7, a flowmeter 8, a filter 9, a first thermocouple 10, an experiment rod bundle fixing plate 11, an observation section 13, a positioning grid 14 and a visual rod bundle experiment section 15; one end of the deionized water tank 1 is connected with one end of the magnetic gear pump 6, and the other end is connected with one end of the observation section 13; one end of the filter 9 is connected with the other end of the magnetic gear pump 6, and the other end is connected with the visual experiment body. Deionized water tank 1 includes visual window 2, cooling coil 3, heater 4 and discharge valve 5, and discharge valve 5 through connection deionized water tank 1's inside and outside, visual window 2 sets up between cooling coil 3 and heater 4. The visualization window 2 is used for observing the state of the fluid in the water tank. The experiment rod cluster fixing plates 11 are arranged at two ends of the experiment rod cluster, and the positioning grids 14 are arranged on the experiment rod cluster at equal intervals.

Before the formal experiment, the non-condensable gas in the experiment loop part is discharged through an exhaust valve 5 at the top of the deionized water tank 1, and the water temperature in the deionized water tank 1 is jointly regulated by a cooling coil 3 and a heater 4. The coolant flow rate and the motor heater electric power in the cooling coil 3 adjust the temperature of the water in the deionized water tank 1 to a specified range. The deionized water is driven by the magnetic gear pump 6, sequentially flows through the flowmeter 8, the filter 9, the visual rod bundle experiment section 15 and the observation section 13, and finally returns to the deionized water tank 1.

The data acquisition part comprises a high-speed camera 16 and a computer 17, the bubble characteristics in the rod bundle channel are shot through the high-speed camera 16, the flow speed of fluid in the experiment loop part is recorded by a flowmeter 8, the water temperature and the wall temperature are recorded through a first thermocouple 10 and a second thermocouple 1503, and the heating power is directly read through readings on a high-voltage power supply 12.

As shown in fig. 2, the visualization rod bundle experimental section 15 further includes a second thermocouple 1503, an electrode 1504, an experimental rod fixing plate 1505 and an electrode fixing plate 1506, the experimental rod bundle is a quartz glass tube 1501, the quartz glass tube has good temperature resistance and low thermal expansion coefficient, and can meet the experimental requirements of flow heat transfer, and the heat resistance temperature of the quartz glass tube 1501 exceeds 800 ℃. The electrode is a cylinder of 100mm length and 9.4mm diameter and is inserted inside quartz glass tube 1501 and fixed by silver brazing.

As shown in fig. 3, the fixing plate 1505 for the test stick includes a flange hole 15051, a positioning hole 15052 for the test stick and a silicone ring 1503, and the fixing plate 1505 for the test stick is made of stainless steel and has a thickness of 30 mm. The flange holes 15051 on the experimental rod fixing plate 1505 are used for fixing the visual rod bundle experimental section 15, and the experimental rod positioning holes 15052 are used for fixing the experimental rod bundle. The electrodes 1504 at both ends of the experimental rod bundle were passed through the round holes of the cell structure on the experimental rod fixing plate 1505. Install a external diameter 9.55mm internal diameter 9.45 mm's silica gel circle 1503 additional between electrode and cell structure round hole, the silica gel circle adopts O type rubber circle, and O type rubber circle can seal the experiment stick cluster completely to keep insulating between electrode 1504 at experiment stick both ends and the experiment stick fixed plate 1505, avoid experiment stick fixed plate 1505 electrified.

As shown in fig. 4, the electrode fixing plate 1506 is made of red copper and has an electrode positioning hole 15061 formed thereon. The electrode 1504 at the end of the test stick is inserted into the electrode positioning hole 15061 after passing through the test stick fixing plate 1505. The electrode 1504 and the electrode fixing plate 1506 are welded together by silver brazing. The electrode fixing plate 1506 is connected to both ends of the high voltage power supply 12 by copper wires.

Preferred embodiments of the present invention will be described further.

Based on the above embodiment, the quartz glass tube 1501 in the present invention is arranged in a rectangular shape and placed in the visual rod bundle experimental section 15, and the ITO plating layer 1502 is provided on the inner wall surface of the quartz glass tube 1501. The ITO plating layer 1502 is conductive and has a transmittance of over 70%, and transient bubble images of the interior of the bundle assembly can be taken through the ITO plating layer 1502 during the experiment.

Based on the above examples, the quartz glass tube 1501 in the present invention has an outer diameter of 9.5mm and a wall thickness of 1mm,

the invention also provides a visual experiment method suitable for the flow boiling heat transfer of the rod bundle channel, and the visual experiment is carried out by adopting the visual experiment device suitable for the flow boiling heat transfer of the rod bundle channel, which comprises the following steps:

step S1: arranging quartz glass tubes 1501 with ITO electroplated layers 1502 into a rectangle, placing the rectangle in a visual rod bundle experiment section 15, and connecting the ITO electroplated layers 1502 on the quartz glass tubes 1501 with a high-voltage power supply 12;

step S2: opening a magnetic gear pump 6 on the experimental loop part, and discharging the non-condensable gas out of the experimental loop part through an exhaust valve 5;

step S3: the temperature of water in the deionized water tank 1 is adjusted to a specified temperature through the cooling coil 3 and the heater 4, and the flow rate of fluid in the experimental loop part is adjusted through a valve 7 on the experimental loop part;

step S4: starting the high-voltage power supply 12 and adjusting the electric power of the high-voltage power supply 12, wherein heat generated by the ITO electroplated layer 1502 is absorbed by a coolant in the visual experiment body after passing through the quartz glass tube 1501, and bubbles are generated;

step S5: shooting bubble characteristics in the rod bundle channel through the data acquisition part, and simultaneously recording the flow speed of the experimental loop part, the water temperatures of an inlet and an outlet of the rod bundle channel, the wall surface temperature of the rod bundle channel and the heating power of the high-voltage power supply 12;

step S6: changing the flow rate of the experimental loop part, the inlet temperature and the heating power of the visual rod bundle experimental section 15, and repeating the steps S1-S5 to obtain transient bubble images and wall temperature parameters under different conditions. The flow rate is adjusted by adjusting the opening and temperature of each valve of the loop, and the electric power of the heater in the water tank and the flow rate and the electric power of the coolant in the cooling coil are adjusted by directly using the high-voltage power supply 12.

Those skilled in the art will appreciate that, in addition to implementing the system and its various devices, modules, units provided by the present invention as pure computer readable program code, the system and its various devices, modules, units provided by the present invention can be fully implemented by logically programming method steps in the form of logic gates, switches, application specific integrated circuits, programmable logic controllers, embedded microcontrollers and the like. Therefore, the system and various devices, modules and units thereof provided by the invention can be regarded as a hardware component, and the devices, modules and units included in the system for realizing various functions can also be regarded as structures in the hardware component; means, modules, units for performing the various functions may also be regarded as structures within both software modules and hardware components for performing the method.

In the description of the present application, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the present application and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present application.

The foregoing description of specific embodiments of the present invention has been presented. It is to be understood that the present invention is not limited to the specific embodiments described above, and that various changes or modifications may be made by one skilled in the art within the scope of the appended claims without departing from the spirit of the invention. The embodiments and features of the embodiments of the present application may be combined with each other arbitrarily without conflict.

Claims (10)

1. A visual experimental apparatus suitable for bundle channel flow boiling heat transfer is characterized by comprising: the experiment loop part comprises a visual experiment body and a high-voltage power supply (12), and the visual experiment body comprises an experiment rod bundle;

deionized water in the experiment loop part enters the visual experiment body and is heated by the experiment rod bundle, and deionized water at the outlet of the visual experiment body is cooled by the coolant and then enters the visual experiment body again;

an ITO (indium tin oxide) electroplated layer (1502) is arranged on the experimental rod bundle, the ITO electroplated layer (1502) is connected with the high-voltage power supply (12), and a coolant in a rod bundle channel absorbs heat generated by an ITO film to generate steam bubbles;

the data acquisition part acquires transient bubble characteristics of two-phase flow in the internal area of the rod bundle channel through the visual experiment body.

2. The visualization experiment device suitable for the bundle channel flow boiling heat transfer according to the claim 1, wherein the experiment loop part comprises a deionized water tank (1), a magnetic gear pump (6), a filter (9) and an observation section (13);

one end of the deionized water tank (1) is connected with one end of the magnetic gear pump (6), and the other end of the deionized water tank is connected with one end of the observation section (13);

one end of the filter (9) is connected with the other end of the magnetic gear pump (6), and the other end of the filter is connected with the visual experiment body.

3. The visual experimental device suitable for bundle channel flow boiling heat transfer of claim 1, wherein the deionized water tank (1) comprises a visual window (2), a cooling coil (3), a heater (4) and an exhaust valve (5), the exhaust valve (5) is connected with the inside and the outside of the deionized water tank (1) in a penetrating manner, and the visual window (2) is arranged between the cooling coil (3) and the heater (4).

4. The visual experiment device suitable for the bundle channel flow boiling heat transfer is characterized in that the non-condensable gas in the experiment loop part is exhausted through an exhaust valve (5) at the top of the deionized water tank (1), and the water temperature in the deionized water tank (1) is jointly regulated by the cooling coil (3) and the heater (4).

5. The visual experiment device for the bundle channel flow boiling heat transfer according to claim 1, wherein the visual experiment body further comprises experiment bundle fixing plates (11) and spacer grids (14), the experiment bundle fixing plates (11) are arranged at two ends of the experiment bundle, and the spacer grids (14) are arranged on the experiment bundle at equal intervals.

6. The visualization experiment device suitable for the bundle channel flow boiling heat transfer as claimed in claim 1, wherein the visualization experiment body further comprises a visualization bundle experiment section (15), the experiment bundle is a quartz glass tube (1501), the quartz glass tube (1501) is arranged in a rectangular shape and placed in the visualization bundle experiment section (15), and the ITO electroplated layer (1502) is arranged on the inner wall surface of the quartz glass tube (1501).

7. A visual experimental device suitable for bundle channel flow boiling heat transfer according to claim 6, characterized in that the quartz glass tube (1501) has an outer diameter of 9.5mm and a wall thickness of 1mm, and the quartz glass tube (1501) has a heat resistance temperature exceeding 800 ℃.

8. The visual experimental facility for the flow boiling heat transfer of the rod bundle channel as claimed in claim 6, wherein the heat generated by the ITO electroplated layer (1502) is absorbed by the deionized water in the rod bundle channel through the quartz glass tube (1501), and the transmittance of the ITO electroplated layer (1502) is more than 70%.

9. The visual experimental device suitable for the bundle channel flow boiling heat transfer as claimed in claim 1, further comprising a thermocouple and a flow meter (8), wherein the thermocouple and the flow meter (8) are arranged on the bundle channel, the flow rate of the fluid in the experimental loop part is recorded by the flow meter (8), the water temperature and the wall temperature are recorded by the thermocouple, and the heating power is read by an index on the high-voltage power supply (12).

10. A visual experiment method suitable for the flow boiling heat transfer of the rod bundle channel, which is characterized in that the visual experiment is carried out by using the visual experiment device suitable for the flow boiling heat transfer of the rod bundle channel, which is disclosed by any one of claims 1 to 9, and comprises the following steps:

step S1: arranging quartz glass tubes (1501) with ITO electroplated layers (1502) into a rectangle, placing the quartz glass tubes into a visual rod bundle experiment section (15), and connecting the ITO electroplated layers (1502) on the quartz glass tubes (1501) with a high-voltage power supply (12);

step S2: opening a magnetic gear pump (6) on the experimental loop part, and discharging the non-condensable gas out of the experimental loop part through an exhaust valve (5);

step S3: the temperature of water in the deionized water tank (1) is adjusted to a specified temperature through the cooling coil (3) and the heater (4), and the flow rate of fluid in the experimental loop part is adjusted through a valve (7) on the experimental loop part;

step S4: starting the high-voltage power supply (12) and adjusting the electric power of the high-voltage power supply (12), wherein heat generated by the ITO electroplated layer (1502) is absorbed by a coolant in the visual experiment body after passing through the quartz glass tube (1501), and bubbles are generated;

step S5: shooting bubble characteristics in the rod bundle channel through the data acquisition part, and simultaneously recording the flow speed of the experimental loop part, the water temperatures of an inlet and an outlet of the rod bundle channel, the wall surface temperature of the rod bundle channel and the heating power of the high-voltage power supply (12);

step S6: changing the flow rate of the experimental loop part, the inlet temperature and the heating power of the visual rod bundle experimental section (15), and repeating the steps S1-S5 to obtain transient bubble images and wall temperature parameters under different conditions.

Images