JPS6219602B2 - - Google Patents

Description

Detailed Description of the Invention The present invention is capable of wide-angle deflection without separating the flow, and also separates the flow into two directions and sends it out. The purpose is to increase the angle formed by the flow in two directions without causing significant flow resistance.

Another object of the present invention is to perform wide-angle deflection without causing significant flow resistance even when the flow is sent in one direction without separation in the same device.

Conventionally, no flow direction control device has been known that has a function of separating the flow into two directions and increasing the angle formed by the flow, and a function of performing wide-angle deflection without separating the flow.

The present invention achieves this function,
A flow path having an inlet portion and an outlet portion, the flow path being connected to a pair of opposing side plates and a lower side wall of the inlet having a step protruding in a direction to enlarge the flow path, and disposed at the outlet portion. A curved guide wall with a gradually expanding shape or a curved guide wall including a part of a straight line toward the outlet, connected to the upper wall of the inlet having a step protruding in the direction of enlarging the flow path, and disposed at the outlet. The guide wall is formed of a substantially linear wall, and is rotatable about an axis disposed perpendicular to the side plates, dividing the inflow flow between the side plates into two on the side of both guide walls. When a blade is provided and the downstream end of the blade is near the straight wall,
a state in which the flow is directed in a horizontal direction, and a state in which when the downstream end is near the curved guide wall, the flow adheres to the curved guide wall and the flow is directed downward; Furthermore, the end located above is located downstream of the step of the upper wall of the entrance section, so that the end located above is closer to the straight wall, and the end located lower is closer to the curved guide wall. This is a flow direction control method that allows the flow divided on the straight wall side to be separated from the blade, and the inflow flow to be attached to the curved guide wall and the straight wall and to be divided. When the inflow flow is directed in a straight direction, one of the flows divided by the vanes adheres to the straight wall, and the other joins with it, achieving a straight flow. In addition, when the inflow flow is deflected to the greatest extent, one of the flows divided by the vanes adheres to the curved guide wall, and the other joins with the protrusion that directs the flow inward, resulting in a wide-angle deflection flow. is achieved. Further, when the inflow flow is divided, one of the flows divided by the vanes adheres to the straight wall and the other adheres to the curved guide wall, thereby achieving wide-angle separation.

An embodiment of the present invention will be described below with reference to the drawings.

In FIGS. 1 and 2, 1 is a flow direction control device.

Reference numeral 2 denotes a lower side wall of the entrance, which has a step 3 and is connected to a curved guide wall 4.

5 is an upper wall of the entrance part, which has a step 6;
It is attached to a substantially straight wall 7.

The flow path 8 is divided by a line l, l' connecting the step 3 and the step 6 into an inlet section 9 on the upstream side and an outlet section 10 on the downstream side.

11 is a blade having a curved shape. 12 is its upstream end, and 13 is its downstream end.

The upstream end 12 is located downstream of the step 6. Further, the linear wall 7 has a position and a length such that an upper flow can adhere to the blade 11 when the blade 11 is in the state shown in FIG.

The blade 11 is fixed to the side plates 15 and 16 by a shaft 14, and is rotatable around the shaft 14 and can be fixed at any position.

Next, the operation will be described.

FIG. 2 shows the case where the blades 11 are directed upward. That is, this is the case where the downstream end 13 of the blade 11 is located near the straight wall 7.

Out of the flow _A1 flowing in from the inlet part 9, the blade 11
The upper flow C ₁ is directed horizontally by the vanes 11 and is attached to the straight wall 7 and directed horizontally. On the other hand, the lower flow B ₁ of the blade 11 heads horizontally without adhering to the guide wall 4 due to the presence of the step 3, merges with the flow C ₁ , and heads horizontally as a whole.

FIG. 3 shows the case where the blade 11 is directed downward by θ ₁ from the horizontal. That is, the downstream end 13 of the blade 11
is located near the guide wall 4.

Lower flow of flow _A2 flowing in from inlet part 9
B ₂ is directed towards the guide wall 4 by the curved vanes 11 . This flow adheres to the guide wall 4 and is largely deflected downward due to the Coanda effect.

On the other hand, the upper flow C ₂ of the blade 11 tends to adhere to the linear wall 7 after being separated at the step 6 . However, since the adhesion effect on the curved blade 11 caused by the flow C ₂ and the attraction effect by the flow B ₂ are larger than the negative pressure effect that causes the winding flow E in the vicinity of the straight wall 7, the flow C ₂ is deflected downward without adhering to the straight wall 7 and merges with flow B ₂ to form flow D ₂ which is largely deflected downward.

At this time, the confluence of flow C ₂ and flow B ₂ is at blade 1
occurs at position "X" downstream from 1.

When the inclination angle θ ₁ of the blade 11 is gradually increased, the flow C ₂ gradually separates from the blade 11 and the confluence point “X” also moves downstream, and at a certain angle, the flow C 2 is separated from the blade 11 and the straight wall 7 The negative pressure at is greater and the flow C ₂ leaves the vane 11 and adheres to the straight wall 7 .

FIG. 4 shows the state at that time.
That is, the upstream end 12 of the blade 11 is located downstream of the step 6, and the upstream end 12 is brought closer to the straight wall 7, and the downstream end 13 is brought closer to the guide wall 4, thereby creating a straight wall. This is a case where the flow divided into 7 sides separates from the blade 11. Feather 11
The inclination angle θ ₂ is larger than θ ₁ in FIG.

The flow A ₃ that flows in from the inlet 9 is divided into a flow B ₃ that adheres to the guide wall 4 and is largely deflected downward due to the Coanda effect, and a flow C ₃ that adheres to the linear wall 7 and heads in the horizontal direction. .

Next, a second example will be shown.

In FIG. 5, 5' is an upper wall that is sloped to direct the flow inward. The rest of the structure is the same as that shown in FIG. 2, and therefore is designated by the same reference numerals.

In this case, since the upper flow C ₄ of the blade 11 is directed downward by the upper wall 5', a large angle can be taken until the rotation of the blade 11 causes the flow to be split in two directions. That is, the inclination angle of the blade 11 shown in FIG. 5 has the same value (θ ₂ ) as the inclination angle shown in FIG. , no flow diversion occurs. Therefore, when compared with Figure 3,
The deflection angle that can be achieved before a ₂ > a ₁ and the flow splits can be increased.

An example in which the flow direction control device of the present invention is attached to an air conditioner will be described.

In FIG. 6, 17 is an air conditioner. 1
8 is a heat exchanger, 19 is a heater, and 20 is a blower. 21 is a stabilizer, 22 is a rear guider, and a ventilation path for the blower 20 is formed by these.

23 is an air outlet section.

The air outlet portion 23 is indicated by the same number because the shape of the guide wall 4 is the same as that in FIG. 5 except that it has a curved portion 24 on the upstream side and a straight portion 25 on the downstream side. be. lower wall 2
is constructed integrally with the rear guider 22,
The upper wall 5' is constructed integrally with the stabilizer 21. 26 is attached to the guide wall 4,
These are left and right deflection vanes.

27 is the grill, and 28 is the main body. 29 is a dew pan.

In FIG. 7, 30 is a motor capable of forward and reverse rotation, and 31 is its drive shaft. Drive shaft 31
is connected to the shaft 14 of the blade 11 by a connecting member 32.

33 is a flow temperature sensing element. 34 is an electric circuit section for rotating the blade 11 to a predetermined position in response to an input signal. Further, 35 is a dial for setting the blade 11 to an arbitrary position, and 36 is a dial for inputting an input signal to the electric circuit section 34.
It is a switch for switching.

Next, the operation will be explained.

When the blower 20 rotates, the flow P from the room is heated or cooled by the heat exchanger 18, passes through the blower 20, and flows out from the blowing portion 23.

When the position of the blade 11 is as shown in FIG. 6, the flow Q blown out from the blower 23 is divided into two, the lower flow adheres to the guide wall 4 and becomes the flow R which is largely deflected downward, and the other flow The upper flow becomes a horizontal flow S attached to the straight wall 7.

If the blade 11 is rotated clockwise,
The blowout flow corresponds to that shown in FIG. 5, and is a flow deflected downward. Further, when the blade 11 is rotated clockwise, the flow becomes horizontal as shown in FIG.

In FIG. 6, the guide wall 4 has a shape in which a straight part 25 is added to a curved part 24. This increases the adhesion effect during downward deflection and basically does not interfere with the flow direction control in FIGS. 2, 3, and 4.

In FIG. 6, a temperature detection element 33 is installed to detect the air temperature of the flow Q.

Now, as shown in Fig. 7, the switches 36 are both a ₁ ,
Suppose that it is connected to the _b1 contact side and the temperature sensing element 33 is in operation. When the air conditioner 17 is in heat pump operation, if the temperature of the blowout flow Q is low and does not reach a predetermined value, the temperature detection element 33 detects the temperature, and the electric circuit section 34 causes the motor 30 to The blades 11 are set in the state shown in FIG. 2, and the flow is directed horizontally and does not directly hit the human body. Next, when the blowing temperature reaches a predetermined temperature, the angle of the blade 11 is set so that the flow is directed downward.

The electric circuit section 34 is configured to change the angle setting at this time depending on the setting of the air volume blown out from the air conditioner 30. That is, when the amount of air is small, the angle of the blades 11 is set so that all the flow is directed downward as shown in Figure 3, and when the amount is large, the flow is divided into two as shown in Figure 4. One goes downward and the other goes horizontally.

As shown above, since the present invention utilizes the Coanda effect to control the flow deflection, the airflow can be deflected over a wide angle without creating a large airflow resistance.
It becomes possible. Regarding the flow state during wide-angle deflection,
It became possible to deflect all flows, or to keep some flows horizontal while directing others downwards.

In addition, by arranging the upstream end of the blade to be located downstream of the step, the upstream end is closer to the straight wall, and the downstream end is closer to the guide wall, so that the flow divided into the straight wall side can be controlled by the blade. It is possible to achieve wide-angle separation of the flow by realizing separation from the flow. In particular, when the upper wall has an inclination, a large deflection angle can be taken until the flow reaches the split state.

When this flow direction control device is attached to the outlet of an air conditioner, the following effects are produced especially during heat pump operation.

When the air volume is large, the air flow can be deflected downward to a degree that does not create a draft, and the entire air can be heated without causing discomfort.

[Brief explanation of the drawing]

FIG. 1 is a perspective view showing a flow direction control device in an embodiment of the present invention, FIGS. 2, 3, and 4 are sectional views showing the operation in the embodiment of FIG. 1, and FIG. FIG. 6 is a sectional view showing a flow direction control device according to the present invention incorporated into an air conditioner, and FIG. 7 is an explanatory view of the main part of FIG. 6. 1... Flow direction control device, 2... Inlet lower side wall, 3... Step, 4... Guide wall, 5, 5'... Inlet upper side wall, 6... Step, 7... Straight wall, 8
...Flow path, 9...Inlet section, 10...Outlet section, 11
...Blade, 12...Upstream end, 14...Shaft, 17...
... Air conditioner, 18 ... Heat exchanger, 20 ... Air blower, 23 ... Air outlet section, 24 ... Curved section, 2
5... Straight line section.

Claims (1)

[Scope of Claims] 1. A flow path having an inlet portion and an outlet portion, the flow path having a pair of opposing side plates and a lower side wall of the inlet having a step protruding in a direction to enlarge the flow path. a continuous curved guide wall that gradually expands toward the outlet and a partially straight curved guide wall disposed in the outlet section; and an upper wall of the inlet section that has a step that protrudes in the direction of enlarging the flow path. The inflow flow is formed by a substantially linear wall connected to the guide wall and arranged at the outlet part, and flows between the side plates around an axis arranged perpendicular to the side plates to two on both guide walls. a state in which a rotatable blade is provided in a divided state, and when the downstream end of the blade is in the vicinity of the straight wall, the flow is directed in a horizontal direction;
Further, when the end located downstream is near the curved guide wall, the flow adheres to the curved guide wall and the flow is directed downward, and the end located above is located near the entrance. The upper end of the section is located downstream of the step on the side wall, and the upper end is closer to the straight wall, and the lower end is closer to the curved guide wall, so that it is divided into the straight wall side. A flow direction control method in which the flow is separated from the blade, and the inflow flow adheres to the curved guide wall and the straight wall and is divided into flows. 2. The flow direction control method according to claim 1, wherein the upper wall is inclined inward of the flow.