JPS6357642B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The object of the present invention is to obtain deflection over a wide angular width without causing a large drop in flow rate over a short overall length in the flow direction.

Another object of the present invention is to detect a target temperature and automatically perform flow deflection in a deflection device that achieves the deflection operation.

Another object of the present invention is to enable selection between automatic flow deflection operation and manual flow deflection operation in the deflection device.

Conventionally, some air conditioning flow deflection devices from the ceiling detect the temperature of the air outlet using a bimetal and drive a plate placed near the outlet of the air outlet to automatically deflect the flow. However, since this device attempts to deflect the flow only by deforming the flow near the nozzle exit, the deflection angle cannot be wide enough.

Furthermore, a device in which automatic flow deflection and manual flow deflection can be selected has not been put into practical use.

The present invention provides a flow deflection device that eliminates the above-mentioned conventional drawbacks, and embodiments thereof will be described below with reference to the drawings.

First, the structure of the embodiment shown in FIGS. 1 to 4 will be explained.

In FIG. 1, 1 is a flow deflector.
Reference numerals 2 and 3 denote walls, which limit the sides of the upstream section 4. Nozzle forming members 5 and 6 project inward from the walls 2 and 3, respectively, and form a sharp constriction. The upstream portions of the nozzle forming members 5 and 6 are approximately arcuate. The nozzle part 7 formed by the protruding ends of the nozzle forming members 5 and 6 is
The structure is such that the flow from the upstream section 4 is rapidly restricted. The width of the nozzle portion is expressed by the distance _Ws between the protruding ends of the nozzle forming members 5 and 6.

In the description of the flow deflection section 1, for convenience, the shape thereof will be explained as being symmetrical with respect to the center line of the nozzle section 7. However, this is not a necessary structural requirement.

Reference numeral 8 denotes a blade, which is fixed to the shaft 9 and can be rotated around the shaft 9 by the rotation of the shaft 9.
It is configured. The shaft 9 is located on the central axis of the nozzle section 7.

10 and 11 are guide walls, the upstream part of which is
It is approximately arc-shaped, and the downstream portion is formed in a straight line.

In FIG. 3, 15 is a flow deflection device;
It is composed of a flow deflection section 1 and a blade driving device 16.

The flow deflection section 1 has its left and right end surfaces connected to walls 17 and 18.
is restricted.

The shaft 9' is rotatably supported through the wall 18, and the shaft 9 is rotatably supported through the wall 17. A locking member 9'' passes through the shaft 9' and restricts rightward movement of the shaft 9'.

A cam 19 is fixed to the right end of the shaft 9.
The cam 19 has an inclined surface 20.
0 is limited in length by stop surfaces 20', 20''.

Reference numeral 21 denotes a bellows that serves as a driving source, and a temperature sensing tube 22 and a connecting tube 23 that serve as temperature detection means.
A temperature-sensitive expansion liquid or gas is sealed inside the tubes. Reference numeral 24 denotes a pressing body that protrudes from the left end of the bellows 21 and comes into contact with the inclined surface of the cam 19. The thermosensitive tube 22 is placed at a suitable location to be subjected to flow deflection.

In FIG. 4, details of the blade drive device shown in FIG. 3 are shown. A torsion coil spring 25 is arranged between the cam 19 and the wall 17, and one end is connected to the wall 17.
The other end is fixed to the cam 19, and the cam 19
is biased to the right, and the inclined surface 20 is pressed against the bellows 2.
It is pressed against the pressing body 24 of No. 1 with a required pressure. Also, due to the twisting force, the cam 19
However, when a counterclockwise rotation (as seen from the right side in FIG. 4) occurs, a restoring force is constantly generated. In addition, bellows 21
The right end of is fixed to a relatively fixed surface 26 with respect to the wall 17.

Next, the structure of another embodiment shown in FIGS. 5 and 6 will be explained.

In FIG. 5, 27 is a lever fixed to the shaft 9, 28 is a lever holding plate having grooves 29, 30, 31 forming a "U" shape as a whole;
The lever 27 and the lever holding plate 28 constitute a switching means that can rotate the blade 8 to any position regardless of the temperature or the like. The lever 27 has a “U” groove 2
9, 30, and 31 are movably provided. The lever holding plate 28 is fixed to the wall 17.

FIG. 7 shows the structure of an air conditioner using the flow deflection device shown in FIGS. 1 to 4, and this will be explained.

In FIG. 7, 40 is a wall-mounted heat pump indoor unit. 41 is a heat exchanger, 42
3 is an air blower, and 32 is an air conditioning flow outlet.

33 is the rear guider of the blower 42; 34 is the rear guider of the blower 42;
It's a stabilizer.

35 is a condensation pan of the heat exchanger 41, 36 is a filter, 37 is a main body casing, and 38 is a front grill. 39 is a suction part of the front grill.

In the air-conditioning flow blowing section 32, reference numeral 43 denotes a blade that deflects the flow in the left-right direction when the indoor unit 40 is viewed from the front.

Next, the operation in each embodiment will be explained.

In FIG. 1, when the blade 8 is aligned with the central axis of the flow deflection part 1, the flow A passing between the blade 8 and the nozzle forming part 6 and the flow between the blade 8 and the nozzle forming part 5 are The flow B passing between the two is symmetrical with respect to the central axis. Therefore, at this time, the flow velocities of the flow passing near the nozzle forming parts 5 and 6 are a ₁ and a ₂ because of the contracted flow, but because of the left-right symmetry, they are canceled out and the flow as a whole moves in the straight direction. Flow becomes C.

In FIG. 2, consider a case where the blade 8 is rotated slightly more counterclockwise than in FIG. 1. Feather 8
In the flow between and the nozzle forming part 6, the flow velocity b ₁ near the nozzle forming part 6 is directed slightly to the left due to contracted flow, but the regulating force of the flow velocity b ₂ along the blade 8 is large. Therefore, the flow D as a whole moves to the right, causing a Coanda effect between the guide wall 10 and the guide wall 10.
Flows along 0.

On the other hand, in the flow between the blade 8 and the nozzle forming part 5, the flow velocity b ₃ on the blade 8 side is almost in the straight direction, but the flow velocity b ₄ on the nozzle forming part 5 side is due to contraction flow. Head to the right. As a result, the flow as a whole has a tendency to deflect to the right. Furthermore, since a mutual attraction effect occurs between the flow E and the flow D, the flow E finally becomes in a state along the flow D, and the combined flow of the flow D and the flow E becomes F.

As described above, since the flow deflection synergistically utilizes the deflection by the blades 8 and the deflection by the Coanda effect, a large deflection angle can be obtained by a slight movement of the blades 8.

The movement of the blades at this time is small, so the drop in flow rate is also small.

Also, in terms of experimental values, the total length L is the nozzle width _Ws ,
In the case of 3 times or more, the value of the deflection angle θ on one side is about 60°.

From FIG. 1 to FIG. 2, the deflection of the flow relative to the rotational movement of the vanes 8 is continuous.

Further, in this embodiment, the nozzle forming portions 5, 6
Although the step Se is provided between the upper end flow of the guide walls 10 and 11, the above-mentioned operation will occur even if it is not provided.

Various types of detection means 12 are conceivable for detecting temperature. Examples include temperature-sensitive liquids, temperature-sensitive gases, temperature-sensitive solids, thermistors, and positors.

Further, as a driving source, a bimetal itself can also serve as a sensor, and other sources include a bellows, a solenoid, a motor, and the like.

FIG. 4 shows an embodiment in which automatic deflection in the flow direction is performed by detecting temperature.

In FIG. 4, since the vanes 8 face upward, the flow flowing into the flow deflection section 1 is directed toward the guide wall 10.
It is attached to and deflected upward.

Now, when the temperature at the location where the flow is deflected rises, the temperature of the temperature-sensitive cylinder 22 rises, and the temperature-sensitive liquid or gas enclosed therein expands. This causes the bellows 21 to expand.

In FIG. 5, since the surface 26 is fixed, the pressing body 24 is displaced to the left. Since the contact surfaces of the pressing body 24 and the inclined surface 20 are formed to be mutually smooth, the cam 19 rotates clockwise when viewed from the right side in FIG. Then, the abutment surface slides down the inclined surface 20 by a height approximately corresponding to the displacement of the bellows 21, and the shaft 9 slides down by a rotation angle corresponding to this height.
That is, the blade 8 is rotated.

Next, when the temperature at the location where the flow is deflected decreases, the temperature of the temperature-sensitive cylinder 22 decreases, and the temperature-sensitive liquid or gas enclosed therein contracts. This causes the bellows 21 to contract and shift to the right. At this time, the right biasing force of the torsion coil spring 25,
The restoring force works effectively, causing the cam 19 to rotate in a counterclockwise direction when viewed from the right side in FIG. 5, and the shaft 9, that is, the blade 8, to rotate in the same direction.

In Figure 4, when the above operation occurs,
Corresponding to the rotation of the blade 8, the flow direction causes a continuous deflection operation from top to bottom and from bottom to top.

Considering the case where this embodiment is used as a deflection device for an air conditioning blowout and the flow direction is deflected according to the blowout temperature, the blowout temperature range does not change much, so the deflection of the bellows 21 is as follows. Very little. However, the flow deflection section 1 used in the present invention is applicable because the deflection angle can be sufficiently controlled with a slight deviation of the blades 8.

Note that the inclined surface 20 of the cam 19 has a stop surface 20',
20'', the rotation of the blade 8 is restricted even if the temperature is above a predetermined value or below a predetermined value.
This is designed to prevent the flow rate from decreasing more than necessary.

Fig. 6 shows another embodiment of the flow deflection device according to the present invention, and the schematic configuration is the same as Fig. 4, but since the blade drive device is different, an enlarged side view of only that part is shown. This is what is shown.

When the lever 27 is located in the groove 29,
The operation of the vanes 8 is exactly the same as described in the embodiment of FIGS. 4 and 5 above.

At this time, the shaft 9' is restricted from moving to the right by the locking member 9'', as shown in FIG. In addition, since the groove 29 is formed to have a width wider than the width of the lever 27,
When the blade 8 rotates during automatic deflection, the lever 2
7 move in the groove 29 at the same time, but this does not impede the rotational movement. At this time, the lever 27 has a function as a kind of display device indicating the blowing direction.

Next, when performing manual operation, lever 27
is moved downward, then translated to the left along the groove 31, and then moved upward within the groove 30,
Fix it in the desired position.

That is, as the lever 27 moves downward in the groove 29, the pressing body 24 and the inclined surface 20 are separated. Furthermore, due to the leftward parallel movement between the grooves 31, the bellows 2
The cam 19 is moved to the left to a position where the pressing body 24 and the cam 19 do not come into contact even if the cam 1 is expanded to the maximum extent.
At any position within the groove 30, the lever 27 is urged rightward by the torsion coil spring 25 and is locked at the right end of the groove 30. When the lever 27 is locked in the lower position within the groove 30, the torsion coil spring 25 has a restoring force tending to deflect the lever 27 upwards. However, at this time, lever 2
7 is biased to the right by the torsion coil spring 25, because the torsion coil spring 25 is more compressed than in the case of FIG. It is designed to generate powerful force. Therefore, lever 2
7, that is, the blades 8 can be set at any position.

Also, if you want to return to automatic operation, move the lever 27 into the groove 3.
0, and when it is released at the groove 31, due to the rightward biasing force and restoring force of the torsion coil spring 25,
The cam 20 has an inclined surface 20 that presses against the pressing body 2 at that time.
It automatically returns to position 4 and the abutting state, and thereafter performs the automatic deflection operation shown above.

As described above, since the deflection operation is possible with a small deflection of the bellows 21, the length of the groove 31 required for attaching and detaching the bellows 21 and the cam 19, that is, the moving distance of the lever 27, can be shortened. In addition, when the lever is operated manually, a large deflection can be achieved within a small range of lever movement.

Note that when the lever 27 is present in the groove 31, the position of the blade 8 is set to a position where it is not used.

FIG. 8 shows an example in which the flow deflection device 15 of the present invention is applied to an air conditioning flow outlet 32 of an indoor unit 40 in a wall-mounted heat pump. Since the automatic deflection operation and the manual deflection operation are the same as described above, only the part corresponding to the flow deflection section 1 is shown in FIG. be.

When the heat pump is in operation, the flow G sucked from the room flows through the suction section 39 and the filter 3.
6. Pass through the heat exchanger 41 and by the blower 42,
The air is discharged into the room again through the air conditioning flow outlet 32.

The temperature sensing cylinder 22 is arranged at a position where it can detect the temperature of the air conditioning flow after passing through the blower.

When operating a heat pump, at the start of operation,
During thermo-off and day ice,
Unwarmed wind sometimes blew out, causing discomfort. Therefore, the stopping surface of the cam 19 is determined so that the blades 8 face upward until the temperature sensing tube 22 corresponding to the air conditioning outlet reaches a temperature that does not cause discomfort. Then, during operation of the heat pump, in the temperature range that causes discomfort, all of the air conditioning flow adheres to the guide wall 10 and flows in the substantially horizontal direction H, so that it does not directly hit the human body. When the temperature further rises, the blade 8 rotates counterclockwise in response to the temperature detected by the thermosensor tube 22, as explained in the previous embodiment, and the flow continues from I to J. to change. That is, as the temperature of the air outlet increases, the flow is deflected downward to prevent the tendency of warm air to move upward, thereby improving the temperature distribution throughout the room and creating comfortable air conditioning conditions.

In addition, when the blade drive device shown in Fig. 6 is used, it has a cold draft prevention function during preload heating,
Manual deflection operation is possible during cooling.

Furthermore, when this deflection device is used, the difference in air volume during heating and cooling is small.

Note that during cooling, the pressing body 24
The length of the stop surface 20' of the cam 19 must be taken into account in order to prevent it from completely disengaging from the cam 19.

Further, in this embodiment, the temperature sensing tube 22 is placed at the blow-off part, but it can also be placed upstream of the heat exchanger, in the living area, outdoors, etc. depending on the purpose.

As is clear from the description of the embodiments above, the flow deflection device of the present invention synergistically utilizes the flow deflection by the blades and the deflection due to the Coanda effect that occurs further downstream. In contrast, with a short overall length, it is possible to deflect the flow over a wide range of angles without causing a large drop in flow rate.

In addition, since the overall deflection is achieved by a small deflection of the blade angle, a large automatic deflection of the flow becomes possible with a simple mechanism by a small displacement of the drive means based on temperature detection. .

Furthermore, by making the coupling means removable, it is possible to select automatic or manual flow deflection operation.

Furthermore, when used in an air conditioner, cold drafts are prevented during the operation of the heat pump, when the thermostat is turned off at the start of operation, and during day ice, thereby providing a comfortable air conditioning effect.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view of the flow deflection section of a flow deflection device according to an embodiment of the present invention showing straight flow, FIG. 2 is a cross-sectional view of the same flow deflection device in a deflected flow state, and FIG. A perspective view of the device, FIG. 4 is an enlarged side view of the blade drive device in the same device, FIG. 5 is an enlarged side view of the blade drive device in the embodiment of the present invention, and FIG. 6 is taken along C-C′ in FIG. 7 is a cross-sectional view of the flow deflection device of the present invention incorporated into an air conditioner. 1... Flow deflection section, 5, 6... Nozzle forming section,
7...Nozzle part, 8...Blade, 9...Shaft, 10,
11... Guide wall, 15... Flow deflection device, 16...
... Vane drive device, 19 ... Cam, 21 ... Bellows (drive source), 22 ... Temperature-sensitive tube (detection means), 24
... Pressing part, 25 ... Torsion coil spring, 27 ...
... lever, 29, 30, 31 ... groove, 32 ... air conditioning flow outlet, 40 ... wall-mounted heat pump indoor unit, 41 ... heat exchanger, 42 ... blower.

Claims (1)

[Claims] 1. A blade rotatable around an axis, a nozzle portion having a sharp aperture, a guide wall formed in a gradually enlarged shape on the downstream side of the nozzle portion in order to attach a flow by rotation of the blade, and an object. temperature detection means for automatically deflecting the flow direction in accordance with the temperature; a drive source for the blades that operates in response to a signal from the detection means; A flow deflection device comprising switching means that can be rotated into position.