JPH1078257A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve diffusion of heat to the side of a blowoff air stream and hence further improve uniform temperature distribution in a room and make comfortable not only the direction of wind but also a wide region in the room in an air conditioner wherein a vertical louvre rotating left and right is provided at a blowoff outlet, and the vertical louvre is rotated to the left-to- right and vice versa with a swinging mechanism. SOLUTION: When a vertical louvre 7 is swinged in an outside region of a predetermined angle θ1 from a center line CL of rotation, a rotation speed ωof the vertical louvre 7 is increased (or a velocity v of a blowoff air steam) and is set to one within a spiral generation region while when the vertical lever 7 is swinged inside the predetermined angle θ1 from the center line CL of the rotation a rotation speed of the vertical louvre 7 is decreased (or the velocity v of the blowoff air stream is increased) and is set to one within no- swirling region.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improvement in an air flow from an air conditioner for obtaining a good temperature distribution in an air-conditioned space.

[0002]

2. Description of the Related Art FIG. 5 is a side sectional view of an indoor unit 1 of a conventional general separate air conditioner, in which a heat exchanger 5 and a blower 6 are provided in a casing 4 having an outlet 2 and an inlet 3.
Is housed, and the room air sucked from the front suction port 3 by the operation of the blower 6 is cooled in the machine during cooling, heated during heating and blown out from the lower outlet 2 into the room. The outlet 2 is provided with a vertical louver 7 and a horizontal louver 8. The vertical louver 7 is rotated left and right by a vertical louver stepping motor 11 via a transmission mechanism 9 and a connecting rod 10 as shown in FIG. Also,
The horizontal louver 8 is vertically swung by a horizontal louver stepping motor 12 as shown in FIG. The direction of the blown air flow is changed left and right by the rotational swing of the vertical louver 7, and is changed up and down by the rotational swing of the horizontal louver 8.

[0003] As described in Japanese Patent Application Laid-Open No. 5-332606 (see FIG. 4 of the same publication), the characteristics of the air flow blown out from the oscillating louver include the wind velocity v of the blown air flow. When the rotation speed ω of the louver is changed, if the rotation speed ω of the louver is larger than the wind speed v of the blown air flow, a vortex is generated in the rear in the rotation direction, and the rotation speed of the louver is When the wind speed is small, the vortex does not occur, and the rotation speed ω of the louver and the wind speed v
It is known that, in relation to, the boundary line becomes a linear function. And Japanese Patent Laid-Open No. 5-332.
Japanese Patent Publication No. 606 proposes a control of a horizontal louver. That is, when the horizontal louver is swung downward from above, the rotation speed of the horizontal louver is set to a speed within the vortex non-generation region with respect to the wind speed of the blown air flow, so that the air conditioner does not need air conditioning. To prevent the blown air flow from diffusing into the space above, and when the horizontal louver swings from below to above, the rotation speed of the horizontal louver is set to the speed within the vortex generation region with respect to the wind speed of the blown air flow. , The diffusion of the blown air flow in a space below an air conditioner requiring air conditioning is increased, and a method of increasing the temperature uniformity in the space has been proposed.

However, there is no proposal or reference in the above-mentioned publications and others regarding the control of the vertical louver 7 which rotates and swings right and left. In consideration of the characteristics of the air flow blown out from the vertical louver 7 that rotates and swings right and left, the following can be considered. That is, as shown in FIG. 6, when the vertical louver 7 connected by the connecting plate 11 is rotated left and right by the stepping motor 11 as shown in FIG. When the rotation speed is higher than the predetermined rotation speed, a large vortex _Vf is generated behind the rotation direction R _r (dotted arrow in FIG. 6) of the vertical louver 7 due to the blown air flow. When the vortex _Vf is generated, the diffusion of the blown air flow to the side is increased, and the diffusion of the temperature is improved. However, the reachability of the flow in the blowout direction _RA is reduced, and the indoor space of the air conditioner is reduced. Comfort in front of the unit tends to be impaired. On the other hand, when the rotation speed ω of the vertical louver 7 is lower than the predetermined rotation speed, the above-described vortex _Vf is not generated, and the reach of the blown air in the blowing direction _RA is as described above (the rotation of the vertical louver 7). (When the speed ω is higher than the predetermined rotation speed), but the diffusion of the temperature in the rotation direction of the vertical louver 7, that is, the side of the blown air flow is small, and the comfort on the side of the air conditioner is impaired. Tend to be.

Therefore, in the above-mentioned conventional air conditioner, the blown air flow is blown out by changing the blow direction to the left and right by the left and right rotation swing of the vertical louver 7, and within a predetermined angle range in front of the indoor unit 1 of the air conditioner. , Since cool air is supplied during cooling and warm air is supplied during heating, compared to a device that does not swing the vertical louver 7, cool air or warm air is supplied to a wide space, and indoor comfort is improved. it is a rotation speed of the vertical louver 7 omega is constant, since it generates a vortex V _f of the rear side in the rotation direction R _r of the outlet air flow is not taken into consideration, the side of the indoor unit 1 of an air conditioner In the space where the cold air or the hot air is blown directly,
It is probable that problems such as too cold during cooling and too hot during heating occurred.

[0006]

As described above, in the above-described conventional air conditioner, the vortex generation condition is not taken into account for the rotational swing of the vertical louver 7 that swings left and right. The vortex _Vf is not generated, the heat diffusion to the side of the blown air flow is poor, the uniformity of the temperature distribution in the room is poor, or only the direction of the wind is too hot (at the time of heating) or too cold (heating). There was a problem that the comfort was insufficient such as during cooling. An object of the present invention is to improve the diffusion of heat to the side of the blown air flow, improve the uniformity of the temperature distribution in the room, and make the wide area of the room comfortable not only in the direction of the wind. I have.

[0007]

In order to achieve the above object, according to the first aspect of the present invention, an air outlet is provided with a vertical louver that rotates left and right, and the vertical louver is rotated from the right by a rotation swinging mechanism. Left, in an air conditioner that rotates and swings from left to right, the rotation speed in the rotation swing of the vertical louver is variable, and the vertical louver is in a region outside a predetermined angle from the center line of the rotation swing. When swinging, the rotation speed in the rotation swing of the vertical louver is set to a speed in the vortex generation region with respect to the wind speed of the blown air flow, and the vertical louver is set at a predetermined angle from the center line of the rotation swing. When swinging in the region, the rotation speed of the vertical louver in swinging rotation is set to a speed in the vortex-free region with respect to the wind speed of the blown air flow.

According to the second aspect of the present invention, the air outlet has a vertical louver which rotates left and right, and the vertical louver is rotated from right to left and from left to right by a rotation rocking mechanism. In the air conditioner, the wind speed of the airflow blown out from the vertical louver is variable, and when the vertical louver swings in a region outside a predetermined angle from the center line of the rotation swing, the rotation speed of the vertical louver is adjusted to the rotation speed of the vertical louver. On the other hand, when the wind speed of the blown air flow is set to the speed in the vortex generation region, and when the vertical louver swings in a region inside a predetermined angle from the center line of the rotation swing, the rotation speed of the vertical louver is In this case, the wind speed of the blown air flow is set to the speed of the vortex-free area.

In the above description, the rotation swing mechanism of the vertical louver includes a drive source such as a stepping motor, a transmission mechanism for transmitting the rotational force of the drive source to the vertical louver, a connecting rod for interlocking the vertical louver, and the like. The concept of The control of the rotation speed of the vertical louver is usually performed by controlling the rotation of a rotation drive source of the vertical louver, for example, the rotation speed of a stepping motor for the vertical louver. Others such as those performed by devising the transmission mechanism are also included. In addition, the control of the wind speed of the blown air flow is usually performed by controlling the rotation speed of a fan motor, but may include other types in which the blowout air flow is controlled by a flow control mechanism such as a damper at a fan outlet. .

Therefore, in the air conditioner according to the first aspect, when the vertical louver swings in an area within a predetermined angle from the center line of the rotational swing, the vertical louver prevents the vortex from being generated by the blown air flow. When the vertical louver oscillates in a region outside a predetermined angle from the center line of the rotational oscillation, the vortex is generated by the blown air flow. The rotation speed of the vertical louver is controlled so as to generate the heat, and the heat diffusion to the side of the blown air flow is improved.

Further, in the air conditioner according to the second aspect, when the vertical louver swings in a region within a predetermined angle from the center line of the rotation swing, the blown air is prevented from generating a vortex by the blown air flow. When the vertical louver oscillates in a region outside a predetermined angle from the center line of the rotational oscillation, the vortex is generated by the blown air flow. The wind speed of the blown air flow is controlled so that the air flow is generated, and the heat diffusion to the side of the blown air flow is improved.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION

(First Embodiment) A first embodiment of the present invention is shown in FIGS.
This will be described with reference to FIG. In the first embodiment, the structural form of the air conditioner is the same as that shown in FIGS. 5 and 6, and the description of the entire air conditioner will be omitted.
In the following description and reference drawings, the same parts as those in FIGS. 5 and 6 are denoted or described with the same reference numerals.

FIG. 1 shows a vertical louver 7 of the air outlet 2. The vertical louver 7 is configured to swing left and right by a stepping motor 11 via a transmission mechanism 9 and a connecting rod 10. . C _L is the center line of the rotational swing of the vertical louver 7, θ is the rotation angle of the vertical louver 7, θ ₁ is a predetermined angle for changing the rotation speed ω of the vertical louver 7, and θ ₂ is the vertical louver. 7 indicates the maximum rotation angle that can be rotated, and _RA indicates the direction of the blown air flow.

FIG. 2 shows a vortex generating region A and a vortex non-generating region B in the relationship between the rotation speed ω of the rotary louver and the wind speed v of the blown air flow at the outlet 2. In the figure, the case of the wind speed v ₂ of the blowing air flow, vortex the louver rotational speed omega ₂ is not generated, high-speed omega ₁ in the vortex than omega ₂ is generated. Further, if the rotational speed omega ₁ of the louver, the vortex in the wind velocity v ₁ of the outlet air flow is not generated, v slow in the v ₂ vortices than ₁ is generated. In this embodiment, the rotation speed of the vertical louver 7 is controlled with respect to the rotation angle of the vertical louver 7 by controlling the rotation speed of the vertical louver stepping motor 11 as shown in relation to time t in FIG. I do. That is, blowing speed of the blowing airflow from the air outlet 2 (wind speed) is a v _1, in this case, the vertical louvers 7, rocking in a predetermined angle theta ₁ of the outer area from the center line C _L of the rotary oscillating when moving (if the absolute value of the rotation angle theta of the vertical louver 7 is greater than theta ₁ in FIG. 1), the rotational speed of the vertical louver 7 omega increased to louver rotational speed ± in the vortex generation area a in FIG. 2 and omega _1, when vertical louver 7 is swung in the inner region than a predetermined angle theta ₁ (if the absolute value of the rotation angle theta of the vertical louver 7 theta ₁ is less than 1), the rotational speed of the vertical louver 7 omega
Is reduced to a louver rotation speed ± ω _{2 in} the vortex non-generation region B of FIG.

As a result, in the present embodiment, the position of the vertical louver 7, that is, the rotation angle θ is −θ ₂ ≦ θ ≦ −θ ₁ , θ
₁ in the case of ≦ θ ≦ θ ₂ is the vortex is generated in the direction of rotation behind the vertical louver 7 to outlet airflow, the side surface of the outlet air stream, i.e.,
The diffusion of heat in the direction of rotation of the vertical louver 7 is promoted,
The position of the vertical louver 7, that is, the rotation angle θ is −θ ₁ ≦ θ ≦ θ ₁
In the case of (1), no vortex is generated rearward in the rotation direction of the vertical louver 7 with respect to the blown air flow, and the reach in the blowout direction _RA is ensured.

Accordingly, in the room where the air conditioner according to the first embodiment is used and where air conditioning is required, the reach of the blown air flow toward the front of the air conditioner is improved. In addition, the comfortable temperature range is wide on the sides of the air conditioner,
A good temperature distribution can be formed for temperature uniformity over a wide range in a room. Further, in the above, in order to simultaneously satisfy the reach of the blown air flow and the uniformity of the temperature distribution, the predetermined angle θ ₁ for switching the rotation speed ω of the vertical louver 7 is required.
It is most effective to set the absolute value of the angle in the range of 15 ° to 30 °. However, depending on the case where one of them is to be prioritized, or the installation position, etc., the predetermined angle θ ₁ can be made variable and adjusted accordingly. You may do so.

(Second Embodiment) Next, a second embodiment of the present invention will be described with reference to FIGS. In the second embodiment, in the indoor unit of the air conditioner, a variable rotation speed motor for driving a blower (corresponding to the blower 2 in FIG. 6) is controlled, and the blown air is adjusted with respect to the rotation speed ω of the vertical louver 7. The flow wind speed v is controlled as shown in FIG.
FIG. 4 shows the rotation angle θ of the vertical louver 7 with respect to the transition of time.
The change of the rotation speed ω and the wind speed v of the blown air flow is illustrated. In the present embodiment, the rotation speed ω of the vertical louver 7 is ± ω ₁
A case, when the vertical louver 7 is swung in the outer region than the predetermined angle theta ₁ from the center line C _L of the rotary swinging ₍₁ absolute value of the rotation angle theta of the vertical louver 7 theta 1
Larger case), to reduce the wind velocity v of the outlet air flow and velocity upsilon ₂ in the vortex generation area A in FIG. 2, the vertical louver 7 in the inner region than a predetermined angle theta ₁ from the center line C _L of the rotary oscillating when swinging (when the absolute value of the rotation angle theta of the vertical louver 7 theta ₁ is less than 1), the speed upsilon ₁ that by increasing the wind velocity v of the outlet air flow in the vortex non-occurrence region B in FIG. 2 And

As a result, in the present embodiment, the position of the vertical louver 7, that is, the rotation angle θ is −θ ₂ ≦ θ ≦ −θ ₁ , θ ₁
≦ the case of theta ≦ theta ₂ is vortex is generated in the direction of rotation behind the vertical louver 7 to outlet airflow, the side surface of the outlet air stream, i.e.,
The diffusion of heat in the direction of rotation of the vertical louver 7 is promoted,
When the position θ of the vertical louver 7 is −θ ₁ ≦ θ ≦ θ _1, no vortex is generated rearward in the rotation direction of the vertical louver 7 with respect to the blown air flow, and the reachability in the blowing direction _RA is secured. You.

Therefore, in a room that requires air conditioning using the air conditioner of the second embodiment, the reach of the blown air flow to the front of the air conditioner is good, and the air conditioner is improved. The comfortable temperature range is widened to the side of the machine. Therefore, it is possible to form a favorable temperature distribution with respect to temperature uniformity over a wide range in a room.

[0020]

As described above, according to the present invention, the temperature distribution becomes uniform over a wide area in the room, and the comfort is improved.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram around a vertical louver of an air conditioner.

FIG. 2 is a diagram showing a vortex generating region and a vortex non-generating region in a relationship between a rotation speed of a rotary louver and a wind speed of a blown air flow.

FIG. 3 is a diagram illustrating a relationship between a rotation angle and a rotation speed of the vertical louver according to the first embodiment.

FIG. 4 is a diagram showing a relationship among a wind speed of a blown air flow, a rotation angle of a vertical louver, and a rotation speed of a vertical louver according to the second embodiment.

FIG. 5 is a side sectional view showing an indoor unit of a conventional air conditioner.

FIG. 6 is an explanatory diagram of a state of an airflow blown out by a vertical louver of the air conditioner.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Indoor unit, 2 ... Outlet, 7 ... Vertical louver, 9 ... Transmission mechanism, 10 ... Connecting rod, 11 ... Stepping motor for vertical louvers, _RA ... Blow-out direction, _Rf ... Rotation direction of vertical louvers, V
_f ... vortex, theta ... rotation angle of the vertical louvers, theta ₁ ... predetermined angle for changing the rotational speed of the vertical louvers, theta ₂ ... the maximum rotational angle of the longitudinal louvers, the center line of the rotation oscillation of C _L ... vertical louvers, omega ... rotation speed of vertical louver, v ... wind speed of blown air flow.

Claims (2)

[Claims] 1. An air conditioner comprising: a vertical louver rotating left and right at an air outlet; and rotating and rotating the vertical louver from right to left and from left to right by a rotary rocking mechanism. When the rotation speed of the vertical louver swings in a region outside a predetermined angle from the center line of the rotation oscillation, the rotation speed in the rotation oscillation of the louver is made variable, and the rotation speed in the rotation oscillation of the vertical louver is set to When the vertical louver oscillates in a region within a predetermined angle from the center line of the rotational oscillation, the rotational speed in the rotational oscillation of the vertical louver is set to the blowing air. An air conditioner characterized in that the speed of the vortex-free area is set with respect to the flow wind speed. 2. An air conditioner, comprising: a vertical louver rotating left and right at an air outlet; and rotating and rotating the vertical louver from right to left and from left to right by a rotation rocking mechanism. The wind speed of the airflow blown out from the louver is variable,
When the vertical louver swings in a region outside a predetermined angle from the center line of the rotation swing, the wind speed of the blown air flow is set to the speed in the vortex generation region with respect to the rotation speed of the vertical louver, When the vertical louver swings in a region inside a predetermined angle from the center line of the rotation swing, the wind speed of the blown air flow is set to the speed of the vortex-free region with respect to the rotation speed of the vertical louver. An air conditioner characterized by the following.