JPS6364642B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The object of the present invention is to perform wide-angle deflection with small airflow resistance.

Conventionally, devices are known that use the Coanda effect to control the flow direction. (For example, JP-A-54-
60661) However, in this case, a part of the blade that controls the deflection of the flow is placed so as to correspond to the most constricted part of the flow path, and the change in airflow resistance due to the rotation of the blade is , it was a big one.

In order to solve the above problems, the flow direction control device of the present invention is provided with a flow path having an inlet section and an outlet section, and one side of the outlet section has a shape that gradually expands toward the outlet. A curved guide wall with a straight section is provided, a protrusion for directing the flow inward is provided on the other side, and a blade is provided that can rotate around an axis, and the upstream end of the blade is approximately arc-shaped. The blade is formed into a curved shape, and the upstream end of the blade is positioned downstream of the upstream end of the guide wall curved portion. With the above-described configuration, the present invention allows the adhesion to the arc-shaped blades and the straight part of the guide wall to work effectively when the flow is deflected. (downstream), and wide-angle deflection with low air flow resistance is achieved.

An embodiment of the present invention will be described below with reference to FIGS. 1 to 3.

In FIGS. 1 and 2, 1 is a flow direction control device. Reference numeral 2 denotes a lower entrance wall, which has a step 3 and is connected to a guide wall 4. 5 is a curved portion of the guide wall 4, and 6 is a straight portion.

Reference numeral 7 denotes an upper wall, which has a curved portion (protrusion) 8 at the downstream end that directs the flow inward.

The left and right directions are divided by side plates 9 and 10,
There is a lower plate 11 on the lower side.

12 is a blade having a curved shape. 13 is its upstream end, which has a substantially arcuate shape that reduces flow resistance. 14 is the downstream end. The blade 12 is locked to the side plates 9, 10 by a shaft 15, and is rotatable around the shaft 15 and can be fixed at any position.

The part surrounded by the lower inlet wall 2 and the upper wall 7 on the upstream side of the step 3 is the inlet part 16, and the part downstream of the step 3 is the outlet part 17.

The vane 12 is arranged such that its upstream end 13 is located downstream of the outlet end 18 of the inlet portion 16, that is, the downstream end of the curved portion 5 of the guide wall 4.

Further, the curved portion 8 is arranged such that its tip portion 19 is located upstream of the downstream end 14 of the blade 12.

Next, the operation will be explained.

FIG. 2 shows the case where the blades 12 are directed downward.
A flow A ₁ flowing in from the inlet portion 16 is divided by the blade 12 into a lower flow B ₁ and an upper flow C ₁ .

If a part of the blade 12 were present inside the inlet portion 16 as in the past, among the divided flows, the lower flow in particular caused an increase in air flow resistance due to the restriction of the lower inlet wall 2. However, in the case of the present invention,
The vanes 12 are arranged downstream of the outlet end 18 of the inlet section 16, and for the lower flow _B1 , the guide wall 4 is formed in a shape that gradually expands the flow path width, so that strong regulation of the flow is achieved. Power doesn't work. In other words, the air flow resistance can be reduced compared to the conventional method.

At this time, when the width of the flow B ₁ increases, the adhesion effect to the guide wall 4 decreases. However, the curved section 6 existing downstream of the guide wall 4 can reduce the tendency of the flow adhering at the curved section 5 to separate, thereby maintaining stable wide-angle deflection.

In addition, since the tip 19 of the curved portion 8 of the flow C ₁ above the blade 12 is located at the upstream end of the downstream end 14 of the blade 12, the adhesion effect to the blade 12 is promoted more than when it is located on the downstream side as in the conventional case. . Furthermore, this effect, together with the fact that the blades 12 are arcuate and easy to adhere to, promotes the downward deflection of the flow _C1 .

The flow B ₁ and the flow C ₁ merge to form a flow D ₁ which is largely deflected downward as a whole.

In addition, regarding such deflection, the airflow resistance at the branching of the flow _A1 cannot be ignored, but in the present invention, the loss due to resistance is reduced by forming the upstream end 13 of the blade 12 into a substantially circular arc shape. ing.

FIG. 3 shows the case where the blades 12 are directed upward.

The flow A ₂ flowing in from the inlet portion 16 is divided by the vane 12 into a lower flow B ₂ and an upper flow C ₂ .

The upper flow C ₂ has a tendency to be deflected downward by the bend 8 . However, since the downstream end 14 of the blade 12 is located on the downstream side, it is restricted in the direction of the blade 12 and moves in the horizontal direction.

On the other hand, the lower flow B ₂ travels straight without adhering to the guide wall 4 due to the presence of the step 3 . Streams B ₂ and C ₂
and merges together and heads in the horizontal direction _D2 as a whole.

Next, a second example will be described.

In FIG. 4, a straight portion 20 is further added to the upper wall 7 of FIG. 3 on the downstream side of the curved portion 8. The other parts are the same as those in FIG. 3 and are therefore given the same numbers.

Next, the operation will be explained.

Among the flow A ₃ flowing in from the inlet portion 16, the upper flow C ₃ of the blade 12 tends to be deflected downward due to the effect of the curved portion 8, but due to the presence of the straight portion 20, it adheres to the straight portion 20 again and becomes horizontal. Head in the direction. At this time, since the length of the straight part 20 is set so that the adhesion effect to the straight part 20 works more effectively than the adhesion effect to the blade 12, the inclination angle θ' of the blade 12 is the inclination angle in FIG. At angles less than θ, horizontal flow is achieved.

The flow B ₃ on the lower side of the blade 12 travels straight without adhering to the guide wall 4 due to the step 3 and becomes a horizontal flow D ₃ that merges with the upper flow. At this time, since the inclination angle θ' of the blade 12 is relatively small, the flow B ₃ easily joins the flow C ₃ .

As a whole, horizontal blowing is achieved at a small inclination angle θ', so horizontal blowing is possible with smaller air flow resistance.

Next, referring to FIG. 5, an example in which the embodiments shown in FIGS. 1, 2, and 3 are added to an air conditioner will be described.

In FIG. 5, 21 is an air conditioner.
22 is a heat exchanger, 23 is a heater, and 24 is a blower. 25 is a stabilizer, 26 is a rear guider, and a ventilation path for the blower 24 is formed by these. 27 is an air outlet section.

The air outlet portion 27 has the same structure as that shown in FIG. 2, and therefore is designated by the same number. Reference numeral 28 denotes left and right deflection vanes attached to the guide wall.

29 is a front grill, and 30 is a main body. 31 is a dew pan.

Next, the operation will be explained.

When the blower 24 rotates, the flow P from the room is heated or cooled by the heat exchanger 22, passes through the blower 24, and flows out from the outlet 27.

When the vanes 12 are directed downwards, the flow adheres to the guide wall 4, has a large downward deflection angle α, and flows away in the direction Q. Also, if the blades 12 are directed upward, the flow will flow in the S direction, and between them the blades 1
The flow direction R can be set according to the inclination of No. 2.

In this configuration, the blower 24 is a cross-flow
When configured with a fan, if the output resistance of the fan is large, the air volume will drop significantly. However, as described in the examples in Figures 2 and 3 above, the present invention has a configuration that allows deflection to be achieved with little airflow resistance, so wide-angle deflection is possible without interfering with air conditioning capacity. becomes. Especially in recent years, when the depth L has been shortened due to the arrangement conditions in living spaces, the air outlet portion 27 is close to the blower 24, which has a large effect on the performance of the blower 24. However, according to the present invention,
This influence can be reduced.

Furthermore, by adding a motor to the shaft 15 of the blade 12 in this configuration, a wide-angle air return swing function can be achieved. Furthermore, by detecting the air outlet temperature and controlling the rotation angle of the blades 12, the air outlet is deflected horizontally when the air outlet temperature is low during heating, and is deflected downward when the air outlet temperature reaches the required temperature. Realization becomes possible.

As shown in the present invention, the blade is arranged downstream from the upstream end of the curved portion of the guide wall, the upstream end of the blade is formed into an arc shape, a straight portion is added to the guide wall, and the downstream end of the curved portion is connected to the downstream end of the blade. By locating it further upstream, it has become possible to obtain a wide angle of deflection with less air flow resistance.

Furthermore, by providing a straight section downstream of the bent section, it was possible to further reduce the air flow resistance during horizontal blowing.

Furthermore, by incorporating this device into an air conditioner, it has become possible to achieve a comfortable air conditioning effect.

[Brief explanation of drawings]

1 is a perspective view of a flow direction control device in an embodiment of the present invention, FIGS. 2 and 3 are sectional views showing the operation of FIG. 1, and FIG. 4 is a sectional view in a second embodiment, FIG. 5 is a sectional view of the first embodiment incorporated into an air conditioner. 1...Flow direction control device, 3...Step, 4...
Guide wall, 5... Curved part, 6... Straight part, 8... Bent part, 12... Vane, 13... Upstream end, 14...
Downstream end, 15... shaft, 16... inlet section, 17...
Outlet part, 18... Inlet part outlet end, 19... Tip part, 20... Straight part, 21... Air conditioner, 2
2... Heat exchanger, 24... Air blower, 27... Air outlet section.

Claims (1)

[Scope of Claims] 1. A flow path having an inlet portion and an outlet portion, and one side of the outlet portion has a curved shape that gradually expands toward the outlet and has a straight portion on the downstream side. A guide side is provided, and the other side is provided with a protrusion that directs the flow inward, and a blade is provided that divides the flow and is rotatable about an axis, the upstream end of the blade is approximately arc-shaped, and the blade The blade is formed into a curved shape, and the upstream end of the blade is located downstream of the upstream end of the guide wall curved portion, and the rotational movement of the blade prevents the flow from adhering to the guide wall. A flow direction control device arranged to be controlled. 2. The tip of the protrusion that directs the flow inward is located upstream of the downstream end of the blade, and
2. The flow direction control device according to claim 1, further comprising a substantially linear wall on the downstream side of which the flow can adhere when the flow is directed in a straight direction.