JPS604367B2 - Fluid flow direction control device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides a nozzle section in the flow of a fluid, a control plate in the flow passing through the nozzle, and a rotational movement of the control plate. The purpose of this is to control the adhesion to a gradually expanding guide wall provided on the downstream side of the nozzle, and to continuously deflect the flow passing through the nozzle over a wide angle.

In addition, a bent portion is provided at the downstream end of the control plate, and the bent portion directs the flow, and the presence of the bent portion reduces the size of the flow passing through the area partitioned by the bent portion and the guide wall, thereby reducing the flow. The purpose of this is to increase the adhesion effect of the nozzle and, as a whole, to expand the deflection angle with respect to the bending side of the flow emitted from the nozzle.

In explaining the present invention, the example shown in FIG. 1 will be described as a conventional example in order to make the present invention easier to understand, although it is a prior art that is not publicly known.

In the figure, 1 is a flow direction control device.

2 is an upstream chamber, and 3 and 4 are upstream chamber side walls.

Reference numerals 5 and 6 denote nozzle forming portions that protrude inward from the downstream ends of the upstream chamber side walls 3 and 4, and form a constricted nozzle portion 7 with respect to the upstream chamber 2.

Reference numeral 8 denotes a control plate having a shaft 9', which is rotatably supported.

Reference numerals 9 and 10 indicate guide walls having a substantially arcuate shape on the upstream side.

Next, the operation will be described.

As shown in Figure 1, tilt the control board slightly to the left.

Then, in the flow between the control plate 8 and the nozzle forming part 5, the flow shown by the arrow a passing near the nozzle forming part 5 becomes the flow shown by the arrow a2 directed by the control plate. merges with arrow a. The flow is as follows. This flow adheres to the guide wall and is deflected away. On the other hand, in the flow between the control plate 8 and the nozzle forming section 6, arrow a
The flow near the control plate indicated by 4 is separated at the upstream end of the control slope, but the flow near the nozzle forming portion 6 indicated by arrow a5 is emitted slightly to the left.
Overall, the flow is a6 slightly to the left.

The flow heat is attracted and merges with flow a3, and finally,
The flow is shown by arrow A. The deflection angle to the left is 8,
When attempting to further increase the deflection angle Q of the control plate 8, the leftward deflection effect of the flow a2 becomes stronger.

Furthermore, the blowing medium W formed by the control plate 8 and the nozzle forming part 5 becomes shorter, and the negative pressure between the flow a3 and the guide wall becomes larger relative to the flow a3. This increases the adhesion to the guide wall and increases the deflection effect. However, due to the increase in the inclination Q of the control plate 8, the projected length Wc of the control plate 8 increases in the flow indicated by the arrow Ao, and the resistance to the flow increases.

Furthermore, as the projected length Wc increases, the distance between the streams a3 and a6 increases, making it difficult for the two streams to merge. The present invention provides a fluid flow direction control device that eliminates these drawbacks, and one embodiment thereof will be described below with reference to the drawings from FIG. 2 onwards.

First, the flow operation of the present invention will be explained with reference to FIGS. 2a, b, and c.

In FIG. 2a, 11 is a flow direction control device according to the invention.

12 is an upstream chamber, and 13 and 14 are side walls of the upstream chamber.

Reference numerals 15 and 16 indicate nozzle forming portions that protrude inward from the downstream end of the side wall of the upstream chamber, and form a nozzle portion 17 that is narrowed relative to the upstream chamber 12 .

A control plate 18 has a shaft 19, and this shaft 19 is rotatably supported.

A bent portion 20 is formed at the downstream end of the control plate 18 . Reference numerals 21 and 22 indicate guide walls having a substantially arcuate shape on the upstream side.

FIG. 2a shows the case of left deflection, FIG. 2b shows the case of center blowing, and FIG. 2c shows the case of right deflection.

Next, the operation will be described. FIG. 2a shows a case where the control board 18 is placed slightly to the left.

Tilt angle. ' is the same as Q in FIG. In the flow passing between the control plate 18 and the nozzle forming part 15, the flow passing near the nozzle forming part 15 is directed in substantially the same direction as the flow a in FIG.

On the other hand, the flow along the control plate 18 is directed toward the bending portion 201 at the downstream end, and becomes a flow shown by arrows heading leftward than the flow a2 in FIG.

As the leftward deflection tendency of the flow Q increases, the adhesion effect of the flow to the guide wall 21 as indicated by the arrow b3 becomes stronger. Also, due to the presence of the bent portion 20, the airflow inside W, which is formed by the downstream end portion of the bent portion 20 and the nozzle forming portion 15,
also becomes shorter, and the adhesion effect of the flow Q to the guide wall becomes stronger.

On the other hand, among the flows passing between the control plate 18 and the nozzle forming part 16, the flow b4 passing through the upstream end of the control plate 18
At its upstream end, it separates and goes almost straight ahead, but since the flow b5 near the nozzle forming part 16 goes slightly inward, the flow as a whole is deflected slightly to the left and is attracted by the flow b3. The flow becomes wide.

This causes the final flow to be in the direction of arrow B.

That is, the final deflection angle 8 is determined by the setting angle Q of the same control board.
' increases compared to the deflection angle 8 shown in FIG.

At this time, the projected length Wc of the control board 18 increases only slightly from the projected length Wc in FIG. 1, and the air volume does not decrease significantly. FIG. 2b shows a case where the control plate 18 is tilted slightly to the right. In the flow passing between the control plate 18 and the nozzle forming part 15, the flow passing near the nozzle forming part 15 is indicated by the arrow C pointing slightly inward.
, the flow is as follows.

Further, the flow passing through the upstream end of the control plate 18 travels almost straight, as shown by arrow C2. Therefore, the flow C,,
C2 is a straight flow C3 that does not adhere to the guide wall 21
becomes. In the flow passing between the control plate 18 and the nozzle forming portion 16, the flow C4 along the control plate 18 heads slightly to the right.

On the other hand, the flow C5 near the nozzle forming portion 16 heads slightly to the left, and as a whole becomes a flow C6 that travels almost straight without adhering to the guide wall 22. Flows C3 and C6 merge to form flow C, which travels almost straight.

FIG. 2c shows a case where the control plate 18 is tilted slightly to the right.

Among the flows passing between the control plate 18 and the nozzle forming part 16, the flow d5 passing near the nozzle forming part 16 is directed slightly to the left.

However, since the flow d4 along the control plate 18 has a strong tendency to deflect to the right, the flow as a whole heads downward and the guide wall 22
The flow d6 is attached to the . On the other hand, among the flows that pass between the control plate 18 and the nozzle forming portion 15, the flow that passes through the upstream end of the control plate 18 becomes a flow d2 that travels straight ahead with a separation.

Further, the flow passing near the nozzle forming portion 15 is directed slightly to the right, and this flow d causes the flow d2 to deflect to the right, and becomes a flow d3 which is pulled by the flow d6. Eventually, the flow heads in the direction of D, but at this time, since the bend group 20 is set to an appropriate length, it does not disturb the flow d3 when the flow d3 merges with the other flow.

In other words, it exhibits the same rightward deflection performance as that without the bent portion. FIG. 3 is an example in which the flow direction control device is applied to an air outlet of an air conditioner. In the figure, 23 is the air conditioner main body.

24 is a heat exchanger, 25 is a blower, and 26 is a flow direction control device.

27 is a filter, and 28 is a dew pan.

29 is a rear guider, and 30 is a stabilizer.

31 is a front grill, and 32 is a casing.

A vane 33 is attached to the outlet of the flow direction control device and deflects the blown air flow to the left and right when the air conditioner main body 23 is viewed from the front.

Next, the operation will be described. As the blower 25 rotates, the airflow that is drawn from the room through the heat exchanger 24 is blown out by the flow direction control device 25 .

The deflection operation of the flow direction control device 26 is shown in FIGS. 2a, b, and c.
As shown in FIG. 2, the angle of inclination 6 of the control plate 18 allows deflection in any direction indicated by the arrows B' to 0 to D'.

In particular, when the temperature of the air outlet is detected and the signal is used to drive the control plate to cause flow deflection, wide-angle deflection is possible without increasing the driving torque of the control plate.

In addition, it is effective when the flow velocity distribution of the flow flowing into the flow direction control device is uneven depending on the type of fan in the air conditioner and the flow path of the blower system, and it is desired to improve the deflection performance on one side. be.

Furthermore, when the air conditioner 23 is viewed from the front, it is usually long in the left-right direction, and if the control plate 18 is a flat plate, it is likely to be deflected by gravity.

However, the presence of a bent portion serves as reinforcement and makes it difficult for bending to occur. Note that throughout the present invention, the control plate is shown as having a linear bent shape, but it may have a curved shape as long as the same effect is achieved.

Further, the element shape is not limited to a symmetrical shape as shown in the figure.

As is clear from the description of the embodiments above, according to the fluid flow direction control device of the present invention, one control plate is disposed in the flow passing through the nozzle, and a guide wall with a gradually expanding shape is disposed on the downstream side. , the flow direction can be easily controlled.

In particular, since a bent portion is provided at the downstream end of the control plate,
Wide-angle deflection is possible without increasing the rotation angle of the control plate and without causing a significant increase in airflow resistance.

Therefore, when used to control the flow direction of an air conditioner, the torque required to rotate the control plate can be increased without increasing the torque required to rotate the control plate.
Wide-angle deflection control becomes possible. Further, the bending portion of the control plate increases the strength against deflection compared to the case of a flat plate, making it easier to use.

[Brief explanation of the drawing]

Figure 1 is a horizontal sectional view of a conventional fluid flow direction control device;
Figures 2a, b, and c are horizontal cross-sectional views of a fluid flow direction control device according to an embodiment of the present invention in different operating states, and Figure 3 is a case in which the same fluid flow direction control device is applied to an air conditioner. FIG. DESCRIPTION OF SYMBOLS 11... Flow direction control device, 16, 16... Nozzle forming member, 17... Nozzle part, 18... Control plate, 2
0...Bending portion, 21, 22...Guiding wall, 23...
Air conditioner body, 24... heat exchanger, 25... blower,
26... Flow direction control device, 29... Rear guider
, 30... stabilizer. Figure 1 Figure 2 Figure 3

Claims (1)

[Claims] 1. One nozzle that throttles the flow of fluid, at least one guide wall provided in a gradually expanding shape downstream of this nozzle, and a control plate that rotates about an axis to control the streamline state of the fluid. A fluid flow direction control device comprising: a bending portion at a downstream end of the control plate.