JPS649540B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a flow direction control device for controlling the flow direction.

BACKGROUND ART Conventionally, as this type of flow direction control device, there is, for example, one disclosed in Japanese Patent Application Laid-Open No. 51-127557. This is shown in FIG.

The plural adjustment plates 101 each have one end connected to the shaft 1.
It is rotatably fixed at 02. 103
is a temperature sensing element made of bimetal, the center part 104 is fixed, and the winding end part 105 is connected to the adjusting plate 10.
This winding end portion 105 and each adjustment plate 101 are connected by a shaft 106.
As a result, when the bimetal 103 is placed at a flow outlet (not shown), the adjustment plate 101 is bent by the temperature of the blown air, and the direction of the blown flow changes.

Problems to be Solved by the Invention However, in the configuration described above, the flow changes direction while being unified, and especially when the air volume is large during heating, the person receiving this wind is affected by the air flow. This caused discomfort due to the sensation of cold draft.

SUMMARY OF THE INVENTION In view of the above-mentioned problems, an object of the present invention is to provide a flow direction control device that reduces the amount of air received by a person in accordance with the air temperature and air amount.

Means for Solving the Problems The present invention is intended to solve the above problems, and includes a blade for controlling the flow direction based on the wind temperature and air volume, a detection means for detecting the wind temperature, and a detection means for the detection means. and a drive section that drives the blades according to the temperature and air volume.

Effects According to the present invention, with the above configuration, the drive source drives the blades according to the wind temperature and air volume, and the flow can be automatically divided.

Example An embodiment of the present invention will be described below.

In FIGS. 1 and 2, 1 is a flow direction control device. 2 is a lower entrance wall, having a step 3,
It is attached to the guide wall (curved guide wall) 4.

Reference numeral 5 denotes an upper wall, which has a curved portion (a protrusion that directs the flow inward) 6 and a substantially straight wall (straight wall) 7 on the downstream side thereof.

It is partitioned in the left and right direction by side plates 8 and 9, and a lower plate 10 is provided on the lower side.

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

The tip 14 of the curved portion 6 is located upstream of the downstream end 13 of the blade 11, and the wall 7 is set to such a length that adhesion can occur if the flow is directed horizontally.

The blade 11 is fixed to the side plates 8 and 9 by a shaft 15, and is rotatable around the shaft 15 and can be fixed at any position.

Furthermore, the shape of the upper curved surface 18 of the blade 11 has a curvature that does not increase the airflow resistance in the state shown in FIG. 2, and also prevents the upper side of the blade 11 from separating in the state shown in FIG. It has a certain degree of curvature. The shaft 15 of the blade 11 is set at a position that allows the rotation described above.

On the upstream side of the step 3, the portion surrounded by the lower inlet wall 2 and the upper wall 5 is the inlet portion 16, and the portion downstream of the step 3 is the outlet portion 17.

19 is a lower curved surface of the blade 11.

Next, the operation of the present invention will be explained.

FIG. 2 shows a case where the blade 11 is tilted significantly upward (angle of inclination θ ₁ from the horizontal).

The flow A ₁ flowing in from the inlet portion 16 flows through the blade 11
It is divided into two parts by the upper curved surface 18.

One flow B ₁ is directed downward on a curved surface extending from the axis 15 of the blade 11 to the upstream end 12 . This flow B ₁ adheres to the guide wall 4 and is largely deflected downward.

On the other hand, the flow directed upward on the curved surface extending from the axis 15 of the blade 1 to the downstream end 13 is greatly influenced by the fact that the tip 14 of the curved portion 6 is located upstream of the downstream end 13 of the blade 1. Without being affected, it heads slightly upward, attaches to the wall 7, and becomes a flow C ₁ that heads in a nearly horizontal direction.

FIG. 3 shows the case where the inclination angle of the blade 11 is made small (θ ₂ <θ ₁ ).

At this time, the flow above the blade 11 adheres to the wall 7, as in FIG. 2, and becomes a horizontal flow _C2 . On the other hand,
The flow on the lower side becomes a separated flow at step 3. This flow B ₂ separates at the upstream end 12 of the blade 11, becomes a substantially horizontal flow, and finally becomes a horizontal flow D ₂ that merges with flow C ₂ .

FIG. 4 shows a case where the blade 11 is directed downward (incline angle θ ₃ ).

Among the flow A ₃ flowing in from the inlet portion 16, the flow B ₃ on the lower side of the blade 11 is the lower curved surface 1 of the blade 11.
9, the flow adheres to the guide wall 4 and is largely deflected downward. On the other hand, the upper flow C ₃ of the blade 11 is directed downward by the effect of the curved portion 6 and becomes a flow C ₃ that adheres to the lower curved surface 18 of the blade 11 and is deflected downward. Flows B ₃ and C ₃ merge to form a flow D ₃ that is largely deflected downward.

FIG. 5 shows an enlarged cross section of the blade 11. The radius r of the upper curved surface 18 is smaller than the radius R of the lower curved surface.

As a result, in the state shown in FIG. 2, the air flow resistance is reduced and the flow is separated.

In addition, the radius R of the lower curved surface 19 allows the lower flow B ₃ to change direction smoothly in FIG. 4, and the lower flow B ₂ and the upper flow C ₂ in FIG.
In order to promote the merging with the blades and achieve a stable flow, the upstream end 12 of the blade 11 is set so that the separated flow easily forms a negative pressure in the vicinity of the blade 11.

In FIG. 6, 20 is an air conditioner.
21 is a heat exchanger, 22 is a heater, and 23 is a blower. 24 is a stabilizer, and 25 is a rear guider, which form a ventilation path for the blower 23. 26 is an air outlet section.

The air outlet portion 26 is designated by the same number because the shape of the guide wall 4 is the same as that in FIG. 2 except that it has a curved portion 27 on the upstream side and a straight portion 28 on the downstream side. Reference numeral 29 denotes left and right deflection vanes attached to the guide wall 4.

30 is a front grill, and 31 is a main body. 32 is a dew pan.

In FIG. 7, 33 is a motor capable of forward and reverse rotation, and 34 is its drive shaft. Drive shaft 34
is connected to the shaft 15 of the blade 11 by a connecting member 35.

36 is a flow temperature sensing element. 37 is an electric circuit section for rotating the blade 11 to a predetermined position in response to an input signal. Further, 38 is a dial for setting the blade 11 to an arbitrary position, and 39 is a switch for switching the input signal to the electric circuit section 37.

Next, the operation will be explained.

When the blower 23 rotates, the flow P from inside the room
is heated or cooled by the heat exchanger, passes through the blower 23, and flows out from the blow-off section 26.

When the position of the blade 11 is as shown in FIG. 6, the flow blown out from the blower 23 is divided into two, and the lower flow becomes a flow R that adheres to the guide wall 4 and is largely deflected downward. On the other hand, the upper flow becomes a horizontal flow S adhering to the straight portion 7 on the downstream side of the curved portion 6 .

When the blade 11 is rotated counterclockwise, the blowout flow corresponds to that shown in FIGS. 3 and 4.

In FIG. 6, the guide wall 4 has a shape in which a straight part 28 is added to a curved part 27. This increases the adhesion effect during downward deflection and basically does not interfere with the control of the flow direction in FIGS. 2, 3, and 4.

In FIG. 6, a temperature detection element 36 is installed to detect the air temperature of the flow Q.

Assume now that the switches 39 are both connected to the a ₁ and b ₁ contacts as shown in FIG. 7, and the temperature sensing element 36 is in operation. When the air conditioner 20 is in a state of heat pump operation and the temperature of the outlet flow Q is low and does not reach a predetermined value, the temperature detection element 36 detects the temperature and the electric circuit section 37 drives the motor 33. The blades 11 are set in a state as shown in FIG. 3, and the flow is directed horizontally and does not directly hit the human body.

The air volume blown out from the air conditioner 20 is set by a commonly used air volume setting means, for example, by controlling the rotational speed of the blower 23.

The electric circuit section 37 is configured so that when the current blowing temperature is a predetermined temperature and the set air volume is small, the angle of the blade 11 is as shown in FIG. At this time, the blades 11 are directed downward, and a flow condition similar to that described above in the state of FIG. 4 occurs, and all the flow is directed downward.

Next, when the blowing temperature is a predetermined temperature and the set air volume is large, the electric circuit section 37 is configured so that the angle of the blade 11 is as shown in FIG. 2. At this time, the blade 11 tilts greatly upward and the second blade 11 is tilted upward.
A flow condition occurs as explained in the figure, and a two-way branching condition is achieved in the plane perpendicular to the axis 15 of the blade 11, with one flow being largely downward and the other flowing substantially horizontally. Ru.

The reason for setting such a flow state when the air volume is large is as follows. That is, when the heating load is large, the air volume must be increased in order to heat a given space. However, if the outlet width does not change, the wind speed will increase as the air volume increases, and the draft effect due to this increased wind speed will work to lower the sensible temperature.
At this time, the minimum required amount of air is blown downward, taking into account the wind speed and temperature distribution, and the rest is blown out horizontally, thereby maintaining the overall heating capacity and improving the perceived effect. be.

As described above, in this embodiment, since the adhesion effect is used to control the deflection of the flow, it is possible to deflect the flow over a wide angle without causing a large air flow resistance. Regarding the flow state during wide-angle deflection, it is now possible to deflect all the flows, or to maintain some flows horizontally while directing other flows downward.

When this flow direction control device is attached to the outlet of an air conditioner, the flow is deflected downward to a degree that does not create a draft, especially during heat pump operation, and the remaining flow cannot be blown out horizontally. The effect is such that general heating can be achieved without producing a pleasurable sensation.

Effects of the Invention As is clear from the above, according to the present invention, since the air temperature and air volume are detected and the flow is automatically divided, the downward flow can be made into a part of the overall flow. , it is possible to avoid a situation where the entire flow hits the body depending on the temperature.

[Brief explanation of the drawing]

FIG. 1 is a perspective view showing a flow direction control device according to an embodiment of the present invention, FIGS. 2, 3, and 4 are sectional views showing the flow deflection operation, FIG. 5 is an enlarged sectional view of the blade portion, and FIG. The figure is a cross-sectional view of the flow direction control device according to the present invention incorporated into an air conditioner, FIG. 7 is a perspective view of a main part of the blade drive system in FIG. 6, and FIG. 8 is a perspective view of a conventional example. 1...Flow direction control device, 3...Step, 4...
Guide wall, 6... Curved part, 7... Straight part, 11... Blade, 12... Upstream end, 13... Downstream end, 14...
Tip part, 15...shaft, 16...inlet part, 17...
Outlet section, 18... Upper curved surface, 19... Lower curved surface, 20... Air conditioner, 21... Heat exchanger, 23... Air blower, 26... Air outlet section, 27...
...Curve section, 28...Straight section.

Claims (1)

[Claims] 1. A blade including a flow path having an inlet portion and an outlet portion and rotatable around a shaft disposed within the flow path, and a control means and a drive means for the blade;
A means for detecting the temperature of the air passing through the flow path and a means for setting the air volume are provided, and the control means and the driving means drive the blade to raise or lower the flow when both the air temperature and the air volume exceed a predetermined value. A flow direction control device that sets a two-way flow split state in a direction.