JP2000262876A - Heat transfer and mixing accelerating mechanism for fluid and fluid machinery using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat transfer and mixing accelerating mechanism of a fluid capable of accurately controlling the intensity and distribution of generated turblence by a relatively simple means without requiring a secondary device and a fluid machinery using this mechanism. SOLUTION: In a heat transfer and mixing accelerating mechanism of a fluid arranged to a part of a fluid passage 15 and applying turblence to the fluid flowing through the fluid passage 15 to accelerate the heat transfer or mixing of the fluid, a turblence forming means 17 applying turblence to the fluid is equipped with a perforated plate 19 having a large number of holes 18, a barrier member 20 with which the fluid passed through the holes 18 of the perforated plate 19 collides and an outflow port 21 allowing the fluid colliding with the barrier member 20 to flow into the fluid passage 15.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a turbulence generation technique suitable for mixing the same kind or different kinds of fluids to equalize thermal or component elements contained in the fluids. In particular, the present invention relates to a mechanism for promoting heat transfer and mixing of a fluid which is effective in causing continuous turbulence in a fluid flowing in a flow path in a test apparatus or an actual equipment, and a fluid apparatus using the same.

[0002]

2. Description of the Related Art As is well known, fluid such as fuel, air or combustion gas flowing in an engine such as a jet engine or a gas turbine or a combustor thereof, or steam in a steam turbine has high turbulence. I have. Therefore, in order to verify the performance of various fluid devices, it is necessary to control the turbulence condition of the fluid in the fluid device that simulates the turbulence condition of the actual fluid machine. Further, in a gas turbine combustor or the like, it is necessary to mix the combustion gas and the fuel in a short time, and it is necessary to perform rapid mixing by turbulent diffusion. Also, rapid and uniform mixing is required in the premixing process for speeding up flame propagation and reducing NOx in the combustor, and mixing by turbulent diffusion is required. Further, it is important to make the temperature uniform in the semiconductor process, and for rapid temperature stabilization, it is necessary to perform temperature diffusion by promoting heat transfer of turbulent diffusion.

Conventionally, as one means for controlling a turbulence condition in a fluid device simulating the turbulence condition of an actual fluid machine described above, a fluid is circulated inside a capillary formed in a grid shape and small holes are formed in the surface of the capillary. There is known a turbulence generation method using a capillary grid in which a fluid flowing through the capillary is ejected from the small holes (for example, "IGTC-Issued by International Gas Turbine Society").
1987-73), III-217 to 222 ").

FIG. 13 shows an overall configuration of a wind tunnel test apparatus in which turbulence is generated by such a capillary grid, and FIG. 14 shows the capillary grid in an enlarged manner.

[0005] As shown in FIG. 13, the wind tunnel test apparatus includes a wind tunnel main body 1, a rectifying grid 2 installed upstream of the wind tunnel main body 1, a nozzle 3 provided downstream of the wind tunnel main body 1, And a test unit 4. A capillary grid 6 is installed in the fluid passage of the wind tunnel main body 1 as a turbulence generating means, and a blower 5 for supplying a fluid to the capillary grid 6 is connected to the capillary grid 6. As shown in FIG. 14, a large number of holes 7 are formed in the peripheral wall of the thin tube grid 6.

At the time of the test, the fluid a is circulated in the wind tunnel main body 1 and the turbulent fluid b
Lead. The fluid b guided to the capillary grid 6 is ejected from the hole 7 in the peripheral wall toward the downstream side of the wind tunnel main body 1 and generates turbulence while mixing with the fluid a flowing from the upstream side of the wind tunnel main body 1. The turbulence of the fluid is observed in the test section 4.

As another wind tunnel test apparatus, a method of generating turbulence by a rotating triangular wing is also known (for example, see “J. Flid Mech. (1996), v.
ol. 320 pp. 331-368 ").

FIG. 15 shows a wind tunnel test apparatus incorporating a turbulence generating mechanism having a triangular wing and a motor for rotating the wing, and FIG. 16 shows the triangular wing and the motor in an enlarged scale.

As shown in these figures, this wind tunnel test apparatus also has a wind tunnel main body 1, a rectifying grid 2 installed upstream of the wind tunnel main body 1, and a nozzle provided downstream of the wind tunnel main body 1. 3 and a test section 4. Then, in the middle of the fluid passage of the wind tunnel main body 1, as turbulence generating means,
A number of triangular wings 9 rotated by a motor 8 are provided. As shown in FIG. 16, each triangular wing 9 is attached to a rotating shaft 8 a of a plurality of motors 8 arranged in a grid, and rotates around each axis.

At the time of the test, the fluid a is circulated in the wind tunnel main body 1 and the triangular wing 9 is rotated by the driving of the motor 8, and the fluid a flowing from the upstream side of the wind tunnel main body 1 is rotated by the rotation of the triangular wing 9. Stirring produces turbulence. The turbulence of the fluid is observed in the test section 4.

[0011]

However, the conventional mechanism having the turbulence generating means having the capillary grid 7, the triangular wing 9, and the motor 8 as described above has the following problems.

That is, in the case of the capillary grid 7, the generated turbulence intensity is as low as about 5% at the maximum, and the blower 5 for guiding the fluid into the capillary is required, so that the apparatus is expensive. Was.

Further, in the mechanism having the turbulence generating means having the triangular wing 9 and the motor 8, it is possible to increase the intensity of the generated turbulence, but the control for that is complicated, and the motor 8 and its motor 8 requires a power supply, a control device, and the like, and has a problem that the device becomes very expensive.

As described above, in a turbulence generation mechanism that simulates turbulence conditions of an actual fluid machine, a fluid device that promotes heat transfer, and promotes turbulent diffusion, the generated turbulence intensity is low or complicated control is performed. And a secondary device such as a blower, a motor, and a power supply are required.

Conventionally, a fluid machine of an actual machine, for example, an internal combustion engine or an external combustion engine, a fuel mixer or a combustor thereof, a steam engine or an accessory thereof, an air conditioner, or a semiconductor manufacturing apparatus for temperature control or an accessory thereof In equipment and the like, a complicated mechanism is required to control the intensity and distribution of the generated turbulence, and a mechanism that can control the intensity and distribution of the turbulence by relatively simple means is known. Absent.

The present invention has been made in view of such circumstances, and does not require a secondary device, and it is possible to accurately control the intensity and distribution of the generated turbulence by relatively simple means. It is an object of the present invention to provide a heat transfer / mixing promoting mechanism for a fluid and a fluid device using the mechanism.

[0017]

The inventor of the present invention has studied the strength of turbulence in the prior art described above. As a result, the fluctuation component of the velocity given to the fluid by the turbulence generating means is small, and as a result, the continuity of the turbulence Was found to have decreased.

The speed fluctuation component will be described with reference to FIG. FIG. 17 shows the relationship between the fluid velocity (vertical axis) and time (horizontal axis).

The velocity in a normal fluid is the average flow velocity (Um
/ S) and the fluctuation speed (um / s). The average speed is an average value of the speeds in a certain time width, and the fluctuation speed indicates an instantaneous variation speed with respect to the average speed.

The fluctuation speed always exists in the actual fluid flowing through the fluid passage, and 0.5 × density × u ² becomes the energy of the fluctuation speed. The energy at this fluctuating rate produces a turbulence. Further, the fluctuation speed has a larger value when the speed gradient is large.

Taking the prior art described above as an example, in the case of a turbulence generation mechanism using a grid, the turbulence generation due to its own velocity gradient of the jet flow spouted from each jet hole of the grid and the adjacent jet flow And a turbulence generation mechanism utilizing two types of turbulence generation due to the interference of However, the velocity gradient is smoothed by transporting energy as going downstream. In addition, the interference between adjacent jets spreads further downstream.

On the other hand, as a mechanism of turbulence generation, both the energy (=
If all of 0.5 × density × (average velocity U ² + fluctuation velocity u ² ) are converted into the fluctuation velocity, the velocity gradient of the flow after the collision and the velocity gradient by the grid are represented by the velocity gradient and the velocity gradient. This is a very large value compared to the fluctuation speed. Therefore, the turbulence generated by the energy having the fluctuating speed becomes very large, and the turbulence in the downstream direction should be strong.

In another conventional technique having a turbulence generating mechanism using a triangular wing, energy is supplied to the flow by an external energy supply such as a motor, and the energy supplied from the motor is varied by a triangular wing connected to the motor. Since it is converted into energy of speed, it is possible to generate large turbulence. However, it is very expensive to install a motor and a triangular wing. Further, it is considerably difficult to incorporate the device into an actual fluid machine such as a mold combustor (in terms of both cost and structure).

Therefore, the inventor has determined that all of the energy (= 0.5 × density × (average velocity U ² + fluctuation velocity u ² )) of both the average velocity and the fluctuation velocity of the jet flow is obtained only by the static mechanism. The conversion to the fluctuation speed was studied diligently.

[0025] As a result, by causing the main fluid itself to collide violently, the velocity gradient and fluctuation speed of the flow after collision are much larger than the velocity gradient and fluctuation velocity by the grid. Inspired by the value. In this case, it is possible to sufficiently realize the collision by means of only a static mechanism.

The present invention has been made based on the above idea. According to the first aspect of the present invention, a turbulence is applied to a fluid flowing through the fluid passage to disturb the fluid flowing through the fluid passage. In a heat transfer / mixing promoting mechanism for a fluid that promotes heat transfer or mixing, a perforated plate having a plurality of holes and a fluid that has passed through the holes of the perforated plate collide as a turbulence generating unit that disturbs the fluid. A fluid heat transfer / mixing promoting mechanism is provided, comprising: a collision body that collides with the collision body; and an outlet that allows the fluid that collides with the collision body to flow out into the fluid passage.

According to the present invention having such a configuration, the fluid flows through the holes of the perforated plate and collides with the collision body to generate turbulence,
Furthermore, the turbulence flows out of the outlet while being mixed with the adjacent flow while the turbulence is made uniform. That is, as a mechanism for generating turbulence, all of the energy (= 0.5 × density × (average velocity U ² + variation velocity u ² )) of both the average velocity and the fluctuation velocity of the jet flow fluctuates due to the collision with the collision object. The velocity is converted into a velocity, and the velocity gradient and the fluctuation velocity of the flow after the collision have very large values compared to the velocity gradient and the fluctuation velocity by the conventional grid. Therefore, the turbulence generated by the energy having the fluctuating speed becomes extremely large, and the turbulence in the downstream direction also becomes strong.

Moreover, the structure is composed of only static parts, and does not require an extra drive mechanism or control device. Therefore,
By relatively simple means, the intensity and distribution of the generated turbulence can be accurately controlled, and a highly functional and inexpensive heat transfer / mixing promoting mechanism for fluid can be realized.

According to a second aspect of the present invention, in the fluid heat transfer / mixing promoting mechanism according to the first aspect, an upstream wall is provided upstream of the turbulence generating means, and a perforated plate having a plurality of holes is provided. The turbulence generating means is configured to be a peripheral wall, and the collision body is provided inside the region surrounded by the perforated plate so as to face the perforated plate, and the fluid outlet is provided in the region. A heat transfer / mixing promoting mechanism for a fluid, which is provided at a downstream portion and further includes a flow rate adjusting plate for controlling a flow rate of a fluid flowing through a portion other than the outlet. .

According to the present invention, the fluid flows through the holes of the perforated plate, collides with the colliding body to generate turbulence, and further flows out of the outlet while mixing with the adjacent flow to make the turbulence uniform. The same function as described above is obtained.

According to a third aspect of the present invention, in the fluid heat transfer / mixing promoting mechanism according to the second aspect, a flow rate adjusting hole for controlling a flow rate of the fluid is provided in an upstream wall provided on an upstream side of the turbulence generating means. And a mechanism for promoting heat transfer and mixing of the fluid.

According to the present invention, the fluid circulates through the holes of the perforated plate, collides with the impingement body to generate turbulence, and the turbulence is uniformized while mixing with the adjacent flow. While mixing with the inflowing fluid, the turbulence is made uniform and flows out from the outlet.

According to a fourth aspect of the present invention, in the fluid heat transfer / mixing promoting mechanism according to the first aspect, the perforated plate of the turbulence generating means faces the fluid flowing inside the turbulence generating means. While being located upstream of the turbulence generating means, the impinging body faces the perforated plate, and the outlet of the fluid is located in the circumferential direction, and further circulates through portions other than the outlet. Provided is a fluid heat transfer / mixing promoting mechanism including a flow rate adjusting plate for controlling a flow rate of a fluid.

According to the present invention, the fluid flows through the holes of the perforated plate, collides with the colliding body to generate turbulence, and further flows out of the outlet while mixing with the adjacent flow to make the turbulence uniform. After that, the fluid flowing out of the outlet is diffused by being deflected in the vertical direction, whereby the fluid becomes more uniform.

According to a fifth aspect of the present invention, in the fluid heat transfer / mixing promoting mechanism according to the fourth aspect, a flow rate adjusting hole for adjusting a flow rate of the fluid is provided in the collision body of the turbulence generating means. Provide a mechanism for promoting heat transfer and mixing of fluid.

According to the present invention, the fluid flows through the holes of the perforated plate, collides with the collision body to generate turbulence, and flows out of the outlet while mixing with the adjacent flow to make the turbulence uniform. After that, the fluid flowing out of the outlet is diffused by being deflected in the vertical direction, whereby the fluid becomes more uniform.

According to a sixth aspect of the present invention, in the fluid heat transfer / mixing promoting mechanism according to any one of the first to fifth aspects, the turbulence generating means makes the turbulence distribution and turbulence scale of the outflowing fluid uniform. The present invention provides a heat transfer / mixing promoting mechanism for a fluid, characterized in that a grid-like plate is provided between the downstream of the outlet and the downstream end of the turbulence generating means.

According to the present invention, the turbulence distribution and turbulence scale of the fluid flowing out of the heat transfer / mixing promoting mechanism can be uniformly distributed.

According to a seventh aspect of the present invention, in the fluid heat transfer / mixing promoting mechanism according to any one of the first to sixth aspects, the arrangement of the holes in the perforated plate is such that the flow direction of the fluid flowing in the fluid passage is changed. And a fluid heat transfer / mixing promoting mechanism characterized by being arranged orthogonal to the fluid.

According to the present invention, the fluid flows through the holes of the perforated plate, collides with the colliding body to generate turbulence, and further flows out of the outlet while mixing with the adjacent flow to make the turbulence uniform.

According to an eighth aspect of the present invention, in the fluid heat transfer / mixing promoting mechanism according to any one of the first to sixth aspects, the arrangement of the holes in the perforated plate is such that the direction of flow of the fluid flowing through the fluid passage is changed. A fluid heat transfer / mixing promoting mechanism, which is arranged in a staggered arrangement.

According to the present invention, the fluid flows through the holes of the perforated plate, collides with the colliding body to generate turbulence, and flows out of the outlet with uniform turbulence while mixing with the adjacent flow.

According to a ninth aspect of the present invention, there is provided a fluid heat transfer / mixing promoting mechanism characterized by combining a plurality of turbulence generating means according to any one of the first to eighth aspects.

According to the present invention, the turbulences generated by the turbulence generating means interfere with each other to form a uniform turbulence.

According to a tenth aspect of the present invention, there is provided a fluid device in which the heat transfer / mixing promoting mechanism according to any one of the first to ninth aspects is applied in a fluid passage.

In the eleventh aspect, the fluid device according to the tenth aspect is a fluid testing device for testing turbulence of a fluid, a fuel mixer or a combustor of an internal combustion engine / external combustion engine,
A fluid device characterized by being an air conditioner or other equipment for semiconductor manufacturing that performs temperature control.

In the fluid heat transfer / mixing promoting mechanism described above, the number of holes and the hole diameter of the perforated plate, the distance between the perforated plate and the collision body, the grid interval of the grid plate,
By changing the number of grids and the number of grids, the strength of the disorder and the scale of the disorder can be freely changed.

[0048]

Embodiments of the present invention will be described below with reference to the drawings. In the following embodiments, a case will be described in which the mechanism for promoting heat transfer and mixing of a fluid according to the present invention is applied to a wind tunnel test device as a fluid test device.

First Embodiment (FIGS. 1 to 3) FIG . 1 shows the overall configuration of a wind tunnel test apparatus according to a first embodiment of the present invention, and FIG. 2 shows the transmission of fluid provided in the apparatus. The heat and mixing promotion mechanism is shown as a perspective view. FIG.
9 shows the degree of turbulence of the fluid obtained by the present embodiment in comparison with the conventional example.

As shown in FIG. 1, the wind tunnel test apparatus according to the present embodiment includes a blower 10 and a duct 11 serving as a wind tunnel main body through which a fluid (air flow) supplied by the blower 10 flows, and an upstream side of the duct 11. The rectifying grid 12 installed in the nozzle, the nozzle 13 provided in the downstream side of the duct 11, and the test unit 1
4 is provided. Then, the fluid passage 1 in the nozzle 13
In the middle of 5, a heat transfer / mixing promoting mechanism 16 is provided.

As shown in FIG. 2, the heat transfer / mixing promoting mechanism 16 has a plurality of holes 18 as turbulence generating means 17 for turbulently flowing the fluid a flowing through the fluid passage 15 in the nozzle 13. It has a perforated plate 19, a collision body 20 against which the fluid a having passed through the hole 18 of the perforated plate 19 collides, and an outlet 21 through which the fluid a colliding with the collision body 20 flows out into the fluid passage 15. Configuration.

The perforated plate 19 is formed as a peripheral wall surrounding a certain area in the fluid passage 15, and extends, for example, a central area in the fluid passage 15 having a quadrangular cross section by a predetermined length along the flow direction of the fluid a. It is a rectangular cylindrical partition partitioning from the periphery over the whole. In the illustrated example, each surface of the peripheral wall formed by the perforated plate 19 faces the inner surface of the nozzle 13 and is fixed by an appropriate attachment (not shown). The plurality of holes 18 of the perforated plate 19 each have a circular shape and are formed in a staggered arrangement with respect to the flow direction of the fluid a.

The colliding body 20 is in the shape of a quadrangular prism (or in the shape of a rectangular tube whose entire surface is closed), and its four outer peripheral surfaces are placed on the inner peripheral surface of the perforated plate 19 in a region surrounded by the perforated plate 19. And are fixed in the perforated plate 19 by an appropriate attachment (not shown).

At the upstream end of the perforated plate 19, an upstream plate 23 facing the flow direction of the fluid a is provided integrally with the perforated plate 19, and the collision body 20 is arranged by the upstream plate 23. The inner area of the perforated plate 19 is partitioned from the outer area.

At the downstream end of the perforated plate 19 and the collision body 20, a flow adjusting plate 2 facing the flow of the fluid a is provided.
2 are joined. The flow rate adjusting plate 22 is provided for the nozzle 1
3 is a square plate that closes the entire space inside the plate 3 and protrudes to the outer peripheral side of the perforated plate 19, and the flow of the fluid a flowing through the outer peripheral side of the perforated plate 19 is blocked here.

The outlet 21 is formed as a hole provided in the flow regulating plate 22. That is, FIG.
As shown in the figure, the inner peripheral side of the perforated plate 19 and the impact body 2
The outlet 21 is formed as a rectangular frame-shaped hole in a range corresponding to the outer peripheral side of 0.

According to the configuration of the present embodiment described above, the fluid a flowing from the upstream side of the fluid passage 15 partially collides with the upstream plate 23 and the turbulence generation means 17 It enters the inside and collides with the collision body 20 to generate turbulence. In addition, uniform turbulence is generated while mixing with adjacent impinging jets. After the fluid a collides with the collision body 20, the fluid a flows out from the outlet 21 and three-dimensionally turbulent is generated.

In this case, both the average velocity and the fluctuation velocity of the jet flow from the hole 18 of the perforated plate 19 (=
All of 0.5 × density × (average speed U ² + fluctuation speed u ² ) are converted into the fluctuation speed by the collision with the collision body 20. Therefore, the velocity gradient of the flow after the collision and the fluctuation speed itself have very large values, the turbulence generated by the energy having the fluctuation speed becomes very large, and the turbulence in the downstream direction also becomes strong.

FIG. 3 is a characteristic diagram showing a comparison between the degree of turbulence of the fluid a obtained according to the present embodiment and that of the conventional configuration using a grid. In FIG. 3, the vertical axis indicates the degree of disturbance (= (u / U) × 100% (FIG. 1).
7)), and the abscissa indicates the downstream position, and the continuity of the turbulence from the time of turbulence generation to the time of outflow is shown as a characteristic line (X1: conventional example, X2: this embodiment).

The test conditions are as follows.

[0061]

[Outside 1]

As shown in FIG. 3, in the case of the present embodiment (X2), a high degree of turbulence of 10% is obtained, and the turbulence persists to the downstream side. On the other hand, in the case of the conventional example (X1), the obtained degree of turbulence is lower than that of the present embodiment, and the turbulence is greatly reduced on the downstream side. From this, it can be seen that the configuration of the present embodiment can provide much better turbulence generation characteristics than the conventional configuration.

Further, according to the present embodiment, the configuration is made up of only static components, and no extra drive mechanism or control device is required. Therefore, the strength and distribution of the generated turbulence can be accurately determined in accordance with the type and flow rate of the fluid by setting the size and arrangement of the holes 18, the number thereof, and the distance between the perforated plate 19 and the collision body 20. By using relatively simple means, a highly functional and inexpensive fluid heat transfer / mixing promoting mechanism can be realized.

Second Embodiment (FIG. 4) FIG. 4 is a perspective view of a fluid heat transfer / mixing promoting mechanism according to a second embodiment of the present invention.

In this embodiment, the basic components are the same as those in the first embodiment, but the shape of the disturbance generating means 17 is different.

That is, as shown in FIG. 4, in the present embodiment, the perforated plate 19 constituting the turbulence generating means 17 is formed in a cylindrical shape, and the inner area thereof is sealed by the circular upstream plate 23. . The holes 18 of the perforated plate 19 are provided over the entire circumference in a staggered arrangement with respect to the flow direction of the fluid a.

The collision body 20 disposed in the area inside the perforated plate 19 is formed in a cylindrical shape coaxial with the perforated plate 19, and the outer peripheral surface faces the inner peripheral surface of the perforated plate 19. It has a configuration. Further, the outlet 21 is provided along the cylindrical space between the perforated plate 19 and the collision body 20 so that the flow rate adjusting plate 2
2, and is open to the downstream side.

The other components are denoted by the same reference numerals as those in FIG. 2 for the corresponding portions in FIG. 4, and the description is omitted.

Also in the case of the present embodiment configured as described above, the fluid a flowing from the upstream side of the
The peripheral perforated plate 19 collides with the upstream plate 23 partially.
Flows into the internal region through the hole 18 and collides with the collision body 20 to generate turbulence. Furthermore, uniform turbulence is generated while mixing with adjacent impinging jets. Then, the fluid after the collision flows out of the outlet 21 and generates three-dimensionally turbulent.

Therefore, according to the present embodiment, the first
As in the embodiment, excellent turbulence generation characteristics can be obtained, and the intensity and distribution of the generated turbulence can be accurately controlled by relatively simple means without requiring an extra drive mechanism or control device. Thus, a highly functional and inexpensive mechanism for promoting heat transfer and mixing of fluid can be realized.

Third Embodiment (FIG. 5) FIG. 5 is a perspective view showing a fluid heat transfer / mixing promoting mechanism according to a third embodiment of the present invention.

In this embodiment, the basic components are the same as those in the first embodiment, but the arrangement and shape of the perforated plate 19 as the turbulence generating means 17 and the turbulence generating means 1
7 in that a flow rate adjusting function is added to the upstream side of FIG.

That is, as shown in FIG. 4, in the present embodiment, the turbulence generating means 17 is formed as a rectangular parallelepiped in which a perforated plate 19 is arranged on two opposing surfaces, and the hole 18 is provided with a fluid a. Are provided at right angles to the flow direction.

The other two opposing plate members 24 forming a rectangular parallelepiped adjacent to the perforated plate 19 are not provided with holes. The collision body 20 is arranged in a region surrounded by the peripheral wall composed of the plates 19 and 24, and the collision body 20
Is formed, for example, in a plate shape so as to face the perforated plate 19, and the fluid a collides on two flat surfaces thereof. Corresponding to the space where this collision takes place,
The outflow port 21 is formed as a rectangular hole parallel to the flow rate adjustment plate 22, and is open to the downstream side.

In this embodiment, the upstream plate 23 is provided with a flow rate adjusting hole 25. The flow control holes 25 allow the fluid a to pass directly through the region surrounded by the perforated plate 19 and to directly flow out from the outlet 21. Depending on the size and number of the flow control holes 25, the perforated plate 19 is set. The flow rate of the fluid a colliding with the collision body 20 through the hole 18 can be controlled.

The other components are denoted by the same reference numerals as those in FIG. 2 for the corresponding portions in FIG. 5, and description thereof will be omitted.

According to the configuration of the present embodiment, a part of the fluid a flowing through the fluid passage 15 passes through the flow rate adjustment hole 25 provided in the upstream plate 23, and the other fluid is supplied to the surrounding perforated plate. The turbulence generating means 17 enters the turbulence generating means 17 through the hole 18 and collides with the collision body 12 to generate turbulence. Further, it mixes with the adjacent impinging jet and mixes with the fluid flowing from the flow rate adjusting hole 25 provided in the upstream plate 23 to generate uniform turbulence. Then, after the collision, it flows out from the outlet 21 and can generate a two-dimensional target disturbance.

According to the present embodiment as well, excellent turbulence generation characteristics can be obtained, and the strength and distribution of the turbulence generated can be accurately determined by relatively simple means without requiring an extra drive mechanism or control device. By controlling the flow rate of the fluid a by the flow rate adjusting hole 25 of the upstream plate 23, the functionality can be enhanced.

Fourth Embodiment (FIG. 6) FIG. 6 is a perspective view showing a fluid heat transfer / mixing promoting mechanism according to a fourth embodiment of the present invention.

In this embodiment, the basic components are the same as those in the first embodiment, but the shape of the collision body 20 and the flow rate adjusting plate 22 on the downstream side are different.

That is, as shown in FIG. 6, in this embodiment, the upstream plate 23 is sealed. The perforated plate 19 constitutes the peripheral surface of the turbulence generating means 17 and the perforated plate 1
The nine holes 18 are staggered. In addition, the collision body 20
Is provided inside the turbulence generating means 17 and has, for example, a cross-shaped cross section so as to face the perforated plate 19. The colliding body 20 having the cross-shaped cross section allows the turbulence generating means 17
Is divided into four flow paths. Outflow holes 21 are formed in the flow rate adjusting plate 22 provided on the downstream side so as to correspond to the four flow paths inside the turbulence generating means 17, and are opened to the downstream side. Further, the flow rate adjusting plate 22 is provided with a flow rate adjusting hole 26 for passing the fluid a flowing on the outer peripheral side of the perforated plate 19. For the other configurations, the corresponding parts in FIG. 6 are denoted by the same reference numerals as in FIG. 2, and description thereof will be omitted.

Also in this configuration, the fluid a flowing into the fluid passage 15 enters the turbulence generating means 17 through the holes 18 of the surrounding perforated plate 19 while partially colliding with the upstream plate 23, It collides with the collision body 20 to generate turbulence. Furthermore, uniform turbulence is generated while mixing with adjacent impinging jets. In this manner, the fluid a flows out of the outlet 21 after the collision, and can generate a three-dimensionally targeted turbulence. Further, from a flow rate adjusting hole 26 provided in the flow rate adjusting plate 22,
A more uniform turbulence can be formed while mixing with the outflowing fluid. And, by these actions, the same effects as in the above-described embodiments can be obtained.

Fifth Embodiment (FIG. 7) FIG. 7 is a perspective view showing a fluid heat transfer / mixing promoting mechanism according to a fifth embodiment of the present invention.

The present embodiment is substantially the same as the first embodiment in that the turbulence generating means 17 has a rectangular parallelepiped peripheral wall. However, the perforated plate 19, the colliding body 20, the outlet 21 and the like are provided. Are different.

That is, as shown in FIG. 7, a perforated plate 19 provided with a plurality of holes 18 faces the fluid a flowing through the fluid passage 15 and is located at the most upstream side of the turbulence generating means 17. Are located in No holes are formed in the peripheral wall 27 constituting the other four surfaces continuously provided around the perforated plate 19, and a downstream portion of the peripheral wall 27 penetrates the flow rate adjusting plate 22 to adjust the flow rate. It protrudes downstream of the plate 22.

The collision body 20 is provided as an end wall that closes the most downstream end of the peripheral wall 27 protruding downstream of the flow rate adjustment plate 22, and faces the perforated plate 19. That is, the perforated plate 19 and the collision body 20 face each other in a state where they are disposed at the upstream end and the downstream end in the flow direction of the fluid a, and a cavity is formed between them.

The outlet 21 is opened over the entire circumferential direction at a portion of the peripheral wall 27 located immediately before the collision body 20 in the flow direction of the fluid a and at a portion protruding downstream of the flow rate adjusting plate 22. ing.

The area of the fluid passage 15 on the outer peripheral side of the peripheral wall 27 is closed by a flow rate adjusting plate 22 disposed on the downstream side, so that the fluid does not flow out from portions other than the outlet 21. It has become.

According to such a configuration, the inside of the fluid passage 15
The fluid a flowing through the hole collides with the perforated plate 19, and a part of the fluid a flows from the hole 18 into a region in the peripheral wall 27 as the turbulence generating means 17. When the fluid ejected from the hole 19 into the region reaches the collision body 12, the fluid collides with the collision body 12 to generate turbulence. The fluid colliding with the colliding body is reflected in various directions to generate turbulence, flows out of the outlet 21 located in the circumferential direction, and after the effluent, the flow is changed to a vertical direction, and the turbulence is uniformed. While moving downstream.

By these operations, the present embodiment also provides the same effects as the above embodiments.

Sixth Embodiment (FIG. 8) FIG. 8 is a perspective view showing a fluid heat transfer / mixing promoting mechanism according to a sixth embodiment of the present invention.

The structure of the present embodiment is almost the same as that of the fifth embodiment, except that a flow regulating hole is formed in the collision body and the flow regulating plate.

That is, as shown in FIG. 8, also in this embodiment, the perforated plate 1 provided with the plurality of holes 18 is provided.
9 is arranged on the most upstream side of the turbulence generating means 17 in a state directly facing the fluid a flowing through the fluid passage 15. The downstream side portion of the peripheral wall 27 that constitutes the other four surfaces continuously provided around the perforated plate 19 penetrates the flow rate adjusting plate 22,
It protrudes downstream of the flow control plate 22.

The collision body 20 is provided as an end wall that closes the most downstream end of the peripheral wall 27 protruding downstream of the flow control plate 22, and faces the perforated plate 19. That is, the perforated plate 19 and the collision body 20 face each other in a state where they are disposed at the upstream end and the downstream end in the flow direction of the fluid a, and a cavity is formed between them. A plurality of flow rate adjusting holes 28 are provided to pierce the collision body 20 and allow the fluid a to flow to the downstream side.

The outlet 21 is opened over the entire circumferential direction at the portion of the peripheral wall 27 located immediately before the impingement body 20 in the flow direction of the fluid a and at the portion protruding downstream of the flow rate adjusting plate 22. ing.

In the present embodiment, the flow rate adjusting plate 22 is also provided with a plurality of flow rate adjusting holes 29 through which fluid can be passed to adjust the flow rate.

With this configuration, as in the case of the fifth embodiment, the fluid a flowing through the fluid passage 15 collides with the perforated plate 19 and a part of the fluid a Flows into the region inside the peripheral wall 27 as the The fluid ejected from the hole 19 into the region is the impact body 12.
When it reaches, it collides and produces turbulence. The fluid colliding with the colliding body is reflected in various directions to generate turbulence, flows out of the outlet 21 located in the circumferential direction, and after the effluent, the flow is changed to a vertical direction, and the turbulence is uniformed. While moving downstream.

In this case, in this embodiment, since the fluid also flows out from the flow rate adjusting holes 28 provided in the collision body 20 and the flow rate adjusting holes 29 provided in the flow rate adjusting plate 22, the flow rate adjusting holes 28, The fluid flowing out of the outlet 29 mixes with the fluid flowing out of the outlet 21 to generate more uniform turbulence.

With this uniform disturbance, the present embodiment also provides the same effects as those of the above embodiments.

Seventh Embodiment (FIG. 9) FIG. 9 is a perspective view showing a fluid heat transfer / mixing promoting mechanism according to a seventh embodiment of the present invention.

The configuration of the present embodiment is obtained by adding means for generating uniform disturbance to the configuration shown in the first embodiment.

That is, as shown in FIG. 9, a perforated plate 19 having a plurality of holes 18 is formed in the shape of a rectangular tube, and the collision body 20 is formed in a rectangular column shape so that the inner peripheral surface of the perforated plate 19 is Against. At the downstream end of the perforated plate 19 and the collision body 20, a flow regulating plate 2 facing the flow of the fluid a is provided.
2 are joined. The outlet 21 is formed as a rectangular frame-shaped hole provided by drilling the flow control plate 22.

In the present embodiment having the turbulence generating means 17 configured as described above, the collision body 20 is
9 has a short configuration in which a downstream portion in an area surrounded by 9 is cut. Then, a grid 30 is installed on the downstream side of the collision body 20 in the area.

For the other components, the same parts as those in FIG. 9 are denoted by the same reference numerals as those in FIG. 2, and description thereof is omitted.

According to this configuration, the fluid a flowing in the fluid passage partially enters the turbulence generating means 17 through the holes 18 of the surrounding perforated plate 19 while partially colliding with the upstream plate 10, and the colliding body 20 In this case, the turbulence is generated by colliding with the adjacent jets, and the uniform turbulence is generated while being mixed with the adjacent impinging jet.

In addition, in this embodiment, in addition to this, when the fluid flows out of the outlet 21, the fluid passes through the grid 17 in advance. Therefore, even if the fluid generated turbulently by the collision is drifted, Due to the dispersing action at the time of passing through the grid 30, a more uniform and uniform turbulence can be generated.

Eighth Embodiment (FIG. 10) FIG. 10 is a perspective view showing a fluid heat transfer / mixing promoting mechanism according to an eighth embodiment of the present invention.

This embodiment is a modification of the seventh embodiment. As shown in FIG. 10, a plurality of holes 18 of a perforated plate 19 are arranged in a staggered arrangement with respect to the flow direction of the fluid a. . In addition, the collision body 20 has a short configuration in which a downstream portion in a region surrounded by the perforated plate 19 is cut. Then, a grid 30 is installed on the downstream side of the collision body 20 in the area.

Since the other configuration is the same as that of the seventh embodiment, the corresponding portions in FIG. 10 are assigned the same reference numerals as those in FIG. 9 and the description is omitted.

According to the structure of this embodiment, the fluid a flowing in the fluid passage partially enters the turbulence generating means 17 through the holes 18 of the peripheral perforated plate 19 while partially colliding with the upstream plate 10, and the collision object The same effect as in the first embodiment can be obtained by generating turbulence by colliding with the nozzle 20 and generating uniform turbulence while mixing with the adjacent collision jet.

In addition, in the present embodiment, in addition to this, when the fluid flows out of the outlet 21, it passes through the grid 17 in advance. A more uniform and uniform turbulence can be generated by the dispersing action or the like when passing through the grid 30.

Ninth Embodiment (FIG. 11) FIG. 11 is a perspective view showing a fluid heat transfer / mixing promoting mechanism according to a ninth embodiment of the present invention.

In the present embodiment, as shown in FIG.
A plurality (for example, three) of disturbance generating means 17 are provided. Each of the turbulence generating means 17 has the same configuration, the upstream plate 23 is sealed, and the outflow hole 21 is open. The perforated plate 19 is formed in a quadrangular cylindrical shape, and forms a peripheral surface of the turbulence generating means 17. The plurality of holes 18 of the perforated plate 19 are arranged in a staggered manner with respect to the flow direction of the fluid a. The collision body 20 is provided in the shape of a quadratic prism inside the turbulence generating means 17, and is configured to face the perforated plate 19. A single flow rate adjusting plate 22 is provided for all the turbulence generating means 17.

According to such a configuration, the fluid a flowing through the fluid passage 15 is supplied to each upstream plate 2 of the plurality of turbulence generating means 17.
While partially colliding with 3, it enters the inside of the turbulence generating means 17 through the holes 18 of the peripheral perforated plate 19 and collides with the colliding bodies 20 to generate turbulence. In addition, uniform turbulence is generated while mixing with adjacent impinging jets. After the fluid collides, the fluid flows out of each turbulence generating means 17 through the outlet 21 to generate a three-dimensional target turbulence, and the fluids flowing out of the adjacent turbulence generating means 17 interfere with each other. Uniform turbulence can be formed.

As an example of this embodiment, four units having a disturbance generating unit having the same dimensions as the test apparatus shown in the first embodiment are arranged in a parallel arrangement as shown in FIG. .9 mm, 35
When the degree of turbulence on the downstream side of 0 mm was examined, it was found that a large value of 25% was obtained.

Tenth Embodiment (FIG. 12) FIG . 12 shows a heat transfer / fluid transfer of a fluid according to a tenth embodiment of the present invention.
The mixing promoting mechanism is shown as a perspective view.

In the present embodiment, as shown in FIG.
A plurality of (for example, seven) disturbance generating means 17 are provided. Each of the turbulence generating means 17 has the same configuration, the upstream plate 23 is sealed, and the outflow hole 21 is open. The perforated plate 19 is formed in a cylindrical shape and forms a peripheral surface of the turbulence generating means 17. Multiple holes 1 in perforated plate 19
Numerals 8 are arranged in a staggered manner with respect to the flow direction of the fluid a. The collision body 20 is provided in a cylindrical shape inside the turbulence generating means 17, and is configured to face the perforated plate 19. A single flow rate adjusting plate 22 is provided for all the turbulence generating means 17.

With such a configuration, similarly to the ninth embodiment, the fluid a flowing through the fluid passage 15 partially collides with each of the upstream plates 23 of the plurality of turbulence generating means 17 while the surrounding perforated plate The turbulence enters the inside of the turbulence generating means 17 through the holes 18 and collides with the collision body 20 to generate turbulence.
In addition, uniform turbulence is generated while mixing with adjacent impinging jets. After the fluid collides, the fluid flows out of each turbulence generating means 17 through the outlet 21 to generate a three-dimensional target turbulence, and the fluids flowing out of the adjacent turbulence generating means 17 interfere with each other. Uniform turbulence can be formed.

Other Embodiments In each of the above embodiments, a specific configuration has been described to some extent on the basis of the drawings in order to show individual characteristics. However, the present invention is not limited to the configuration shown in each embodiment. Can be implemented as a combined configuration, and the perforated plate shown in one embodiment, the arrangement and shape of the holes, the shape and arrangement of the collision body, etc. It may be replaced or replaced with various ones (for example, the hole shape of the perforated plate may be other than circular).

Furthermore, various modifications are possible. For example, a hole for collision is formed in an upstream plate or a portion described as a peripheral wall having no hole, or a collision body is provided correspondingly, or the shape, arrangement, number, etc. of the outlets are appropriately changed. You can also.

In short, by changing the components in accordance with the conditions such as the type, density, and flow rate of the fluid, it is possible to generate the necessary optimum turbulence.

In the above embodiment, the fluid test apparatus has been described as an example. However, the present invention is applicable to various fluid equipment such as an internal combustion engine or an external combustion engine, a fuel mixer or a combustor thereof, a steam engine or the like. Attached equipment,
The present invention can be embodied as an air conditioner, a semiconductor manufacturing apparatus for performing temperature management, or an accessory thereof. In that case, the performance of the actual equipment can be effectively improved.

[0123]

As described in detail above, according to the fluid heat transfer / mixing promoting mechanism of the present invention, a complicated mechanism for controlling the intensity and distribution of turbulence, a secondary device and the like are required. By using relatively simple means, it is possible to generate a high turbulent component, promote heat transfer and mixing of the fluid, and accurately control the intensity and distribution of the generated turbulence.

Further, according to the fluid device using the fluid heat transfer / mixing promoting mechanism according to the present invention, by applying the mechanism to the fluid passage, heat transfer and mixing of the flowing fluid can be simplified. To effectively improve the economic efficiency and the performance of the equipment.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing one embodiment of a wind tunnel test apparatus using a fluid heat transfer / mixing promotion mechanism according to the present invention.

FIG. 2 is a diagram showing a first example of a fluid heat transfer / mixing promotion mechanism according to the present invention.
The perspective view showing an embodiment.

FIG. 3 is a characteristic diagram showing a comparison between a turbulence degree of a fluid heat transfer / mixing promotion mechanism according to the present invention and a turbulence degree of a conventional example.

FIG. 4 is a second view of the fluid heat transfer / mixing promotion mechanism according to the present invention
The perspective view showing an embodiment.

FIG. 5 is a diagram showing a third example of the heat transfer / mixing promoting mechanism of the fluid according to the present invention.
The perspective view showing an embodiment.

FIG. 6 is a fourth view of the fluid heat transfer / mixing promotion mechanism according to the present invention.
The perspective view showing an embodiment.

FIG. 7 is a diagram showing a fifth example of the fluid heat transfer / mixing promoting mechanism according to the present invention.
The perspective view showing an embodiment.

FIG. 8 is a diagram illustrating a sixth embodiment of the fluid heat transfer / mixing promotion mechanism according to the present invention.
The perspective view showing an embodiment.

FIG. 9 is a diagram illustrating a seventh example of the fluid heat transfer / mixing promotion mechanism according to the present invention.
The perspective view showing an embodiment.

FIG. 10 is a perspective view showing an eighth embodiment of a fluid heat transfer / mixing promoting mechanism according to the present invention.

FIG. 11 is a perspective view showing a ninth embodiment of the fluid heat transfer / mixing promotion mechanism according to the present invention.

FIG. 12 is a perspective view showing a fluid heat transfer / mixing promoting mechanism according to a tenth embodiment of the present invention.

FIG. 13 is a configuration diagram showing an example of a conventional wind tunnel test device.

FIG. 14 is an enlarged view showing a grid of the wind tunnel test device shown in FIG.

FIG. 15 is a configuration diagram showing another example of a conventional wind tunnel test device.

FIG. 16 is a configuration diagram showing a triangular wing of the wind tunnel test device shown in FIG.

FIG. 17 is an explanatory diagram showing the relationship between the average speed and the fluctuation speed of a fluid.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Blower 11 Duct 12 Rectifier grid 13 Nozzle 14 Test part 15 Fluid passage 16 Heat transfer / mixing promotion mechanism 17 Disturbance generation means 18 Hole 19 Perforated plate 20 Collision object 21 Outflow port 22 Flow rate adjustment plate 23 Upstream plate 24 Plate material 25, 26 Flow control hole 27 Peripheral wall 28, 29 Flow control hole 30 Grid a Fluid

Claims (11)

[Claims] 1. A fluid heat transfer / mixing promotion mechanism installed in a part of a fluid passage to impart turbulence to a fluid flowing through the fluid passage to promote heat transfer or mixing of the fluid,
As a turbulence generating means for disturbing the fluid, a perforated plate having a plurality of holes, an impingement body that collides with the fluid passing through the holes of the perforated plate, A heat transfer / mixing promoting mechanism, comprising: 2. The fluid heat transfer / mixing promoting mechanism according to claim 1, wherein an upstream wall is provided on an upstream side of the turbulence generating means, and a perforated plate having a plurality of holes is provided on a peripheral wall of the turbulence generating means. And the collision body is provided inside the region surrounded by the perforated plate so as to face the perforated plate, and the fluid outlet is located downstream of the region. A fluid flow adjusting plate for controlling the flow rate of the fluid flowing through a portion other than the outlet. 3. The fluid heat transfer / mixing promoting mechanism according to claim 2, wherein a flow rate adjusting hole for controlling a flow rate of the fluid is provided on an upstream wall provided on an upstream side of the turbulence generating means. Characteristic heat transfer / mixing promotion mechanism. 4. The mechanism for promoting heat transfer and mixing of a fluid according to claim 1, wherein the perforated plate of the turbulence generating means is upstream of the turbulence generating means so as to face the fluid flowing inside the turbulence generating means. And the collision body faces the perforated plate, and the outlet of the fluid is located in the circumferential direction, and further controls the flow rate of the fluid flowing through portions other than the outlet. A fluid heat transfer / mixing promoting mechanism, comprising a flow rate adjusting plate for performing the heat transfer. 5. The fluid heat transfer / mixing promoting mechanism according to claim 4, wherein a flow rate adjusting hole for adjusting a flow rate of the fluid is provided in the collision body of the turbulence generating means. Mixing promotion mechanism. 6. The fluid heat transfer / mixing promoting mechanism according to claim 1, wherein the turbulence generating means comprises:
In order to uniformly distribute the turbulence distribution and turbulence scale of the outflowing fluid, a grid-like plate is provided between the downstream of the outlet and the downstream end of the turbulence generating means. Heat / mixing promotion mechanism. 7. The heat transfer / mixing promoting mechanism for a fluid according to claim 1, wherein the arrangement of the holes in the perforated plate is orthogonal to the flow direction of the fluid flowing in the fluid passage. A heat transfer / mixing promoting mechanism for a fluid. 8. The fluid heat transfer / mixing promoting mechanism according to claim 1, wherein the holes in the perforated plate are arranged in a staggered arrangement with respect to the flow direction of the fluid flowing in the fluid passage. A heat transfer / mixing promoting mechanism for a fluid. 9. A mechanism for promoting heat transfer and mixing of a fluid, wherein a plurality of the turbulence generating means according to claim 1 are combined. 10. A fluid device, wherein the heat transfer / mixing promoting mechanism according to claim 1 is applied in a fluid passage. 11. The fluid device according to claim 10, wherein the fluid device is a fluid test device for testing a turbulence of a fluid, an internal combustion engine or an external combustion engine, a fuel mixer or a combustor thereof, a steam engine or an auxiliary device thereof, an air conditioner. Or a semiconductor device for performing temperature control or an auxiliary device thereof.