JP2512428Y2 - Air conditioner with deodorizing function - Google Patents

Description

[Detailed description of the device]

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner having an ozone type deodorizing function.

[0002]

2. Description of the Related Art In a conventional air conditioner having an ozone deodorizing function, a catalyst for detoxifying ozone is disposed downstream of an ozone generator disposed in a flow path. The catalyst in this case is configured as a honeycomb structure filter, and is arranged so as to cover the entire cross section of the flow path so that all of the generated ozone passes through this filter.

By the way, if the entire surface of the flow passage is covered with a filter having a honeycomb structure, the flow passage resistance increases and the blown air volume decreases. Therefore, in order to secure the required blown air volume, the filter is made thin to suppress the flow path resistance. But,
On the other hand, if the filter is made thin, its ability as an ozone decomposition catalyst is reduced. For this reason, conventionally, the ozone concentration must be kept low by that amount.

[0004]

As described above, the conventional apparatus cannot raise the ozone concentration so much that the deodorizing effect is substantially low.

An object of the present invention is to provide an air conditioner with a deodorizing function which can increase the ozone concentration and can substantially improve the deodorizing effect.

[0006]

In order to solve the above problems, the present invention is provided with an evaporator and a small duct separated from the evaporator in the direction of the air flow path. It has a cylindrical shape and its axial center is arranged along the flow path, and this small duct divides the flow path into two independent flow paths, a flow path inside the small duct and a flow path outside the small duct. In the small duct, an ozone generator is arranged on the upstream side, and a filter composed of an ozone decomposition catalyst is arranged on the downstream side, and it is necessary to cover the entire flow passage cross section in the small duct with this filter. It has a feature.

[0007]

As shown in FIG. 3, the deodorizing effect depends on the ozone concentration. When the ozone concentration is 1 ppm or more, the deodorizing effect hardly increases. In the conventional air conditioner with a deodorizing function, since the ozone concentration cannot be increased, the residual odor rate is very high and the deodorizing effect is not substantial.

In the device of the present invention, no deodorizing effect is exerted on the air passing through the flow passage outside the small duct, but ozone is deodorized by the air flowing through the flow passage inside the small duct. Exert. In this case, since the flow path outside the small duct is open, the required blown air volume is at least ensured by this flow path. Therefore, with respect to the flow path in the small duct, the specifications can be determined focusing on the deodorizing point without paying much attention to the blown air volume. That is, for the flow path in the small duct, the concentration of ozone can be increased to such an extent that the deodorizing effect can be effectively exhibited, and at the same time, the thickness of the filter can be set accordingly. This makes it possible to exert a reliable deodorizing action on at least the air passing through the flow path in the small duct by the action of high concentration ozone. Therefore, although the air flowing outside the duct is not deodorized, the deodorized air is surely increased, so that the overall deodorizing effect is enhanced. Further, since the small duct is provided away from the evaporator in the air flow direction, the evaporator can be arranged so as to cover the entire cross section of the duct, and the air flowing through the duct is efficiently cooled by the evaporator. Further, the small duct has a tubular shape, and its axial center is along the air flow path. Therefore, the air flowing in the small duct receives almost no flow resistance due to the small duct body, and the pressure loss is small. As a result, a large amount of air passing through the small duct can be secured, and deodorization efficiency can be increased.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows an embodiment in which the present invention is applied to a vehicle air conditioner. Reference numeral 1 is a duct in which a flow path 2 through which conditioned air flows is formed. A fan 3 is arranged on the upstream side of the flow path 2, and an evaporator 4, an air mix door 5, a heater 6 and an adjusting door 7 are arranged on the downstream side of the fan 3 in that order.

A flow path 2 between the fan 3 and the evaporator 4.
Inside, a cylindrical small duct 8 is arranged just at the center of the flow path 2. This small duct 8 is arranged with its axis parallel to the axis of the flow passage 2, whereby the flow passage 2 between the evaporator 4 and the fan 3 is arranged inside the small duct 8 and outside. It is divided into two channels 2B. These flow paths 2A and 2B are independent of each other with the wall surface of the small duct 8 as a boundary.

The inlet side (upstream side) of the small duct 8
Are arranged at positions where the wind from the fan 3 just enters. Inside the small duct 3, an ozone generator 9 is arranged in the vicinity of the most upstream portion, and a filter 10 for ozone decomposition is arranged downstream thereof. The filter 10 is formed by forming an ozone decomposing catalyst in a honeycomb structure as in the conventional case, and is provided in the downstream opening of the small duct 8 so as to cover the entire surface thereof.

Next, the operation of this air conditioner will be described. In this air conditioner, the wind from the fan 3 has two flow paths, that is, the flow path 2A inside the small duct 8 and the flow path 2 outside.
It splits into B and flows to the evaporator 4. The air flowing through the flow passage 2B outside the small duct 8 directly flows into the evaporator 4, while the air flowing through the flow passage 2A inside the small duct 8 is
Passing through the ozone atmosphere created by the ozone generator 9,
After passing through the filter 10, it flows into the evaporator 4.

Therefore, the flow path 2A inside the small duct 8
The air flowing through the filter is deodorized in the ozone atmosphere and the filter 1
At 0, ozone is detoxified and reaches the evaporator 4. In this case, the channel 2A inside the small duct 8 has a large channel loss because of the filter 10, but the channel 2B outside is small.
Since the filter 10 is not provided, the channel loss is small. Therefore, since the resistances of all the flow paths are not large, a necessary and sufficient amount of air finally blown into the vehicle through the evaporator 4 and the like is secured.

Further, since a necessary and sufficient air volume can be secured by the flow passage 2B outside the small duct 8, the flow passage 2A inside the small duct 8 does not care about the blown air volume, The specifications can be determined by focusing on the deodorizing point. That is, in this flow path 2A, the concentration of ozone can be increased to the extent that the deodorizing effect can be effectively exhibited (about 1 ppm or more), and at the same time, the thickness of the filter 10 can be set accordingly. This makes it possible to exert a reliable deodorizing action on at least the air passing through the flow passage 2A by the action of ozone having a high concentration. Therefore, although the air flowing through the outer flow path 2B is not deodorized, the deodorized air is surely increased, so that the overall deodorizing effect is enhanced. Further, since the small duct 8 is provided upstream of the evaporator 4, the evaporator 4 can be arranged so as to cover the entire cross section of the duct 1, and the air flowing through the duct 1 is efficiently cooled by the evaporator 4. Further, the small duct 8 has a cylindrical shape and its axial center is arranged along the air flow path. Therefore, the air flowing through the small duct 8 receives almost no flow resistance due to the main body of the small duct 8 and the pressure loss is small. As a result, a large amount of air passing through the small duct 8 can be secured, and the deodorizing efficiency in this small duct can be increased.

Next, another embodiment of the present invention will be described with reference to FIG. FIG. 2 shows an embodiment in which the present invention is applied to a residential air conditioner. Reference numeral 1 is a duct that also serves as a main body, in which a flow path 2 through which conditioned air flows is formed. An evaporator 4 is arranged in the upstream part of the flow path 2, and a fan 3 is arranged in the downstream side of the flow path 2, so that the air taken in from the air intake 21 is discharged from the air outlet 22 via the evaporator 4. There is.

In the flow path 2 between the fan 3 and the air outlet 22, a tubular small duct 8 is arranged just at the center of the flow path 2. This small duct 8 is arranged with its axis parallel to the axis of the flow path 2, whereby the flow path 2 is divided into the flow path 2A inside the small duct 8 and the flow path 2 outside.
It is divided into two, B. Further, the inlet side (upstream side) of the small duct 8 is arranged at a position where the wind from the fan 3 just enters. Inside the small duct 3, an ozone generator 9 and a filter 10 for ozone decomposition are arranged as in the above embodiment. Then, according to this air conditioner, the same operational effects as those of the above-described embodiment are exhibited.

Next, the effectiveness of the present invention will be considered with reference to FIG. FIG. 4 shows the relationship between the flow channel area and the air flow rate when the ozone concentration is changed, with the flow channel area on the horizontal axis and the air flow rate on the vertical axis. When the ozone concentration is zero, no ozone decomposing catalyst is provided, so the relationship between the flow passage area and the air volume is as indicated by the straight line P1. In addition, ozone concentration is 1pp
When m is set, the thickness of the ozone decomposing catalyst must be correspondingly increased, so that the flow path resistance increases, so that the air flow rate considerably decreases even with the same flow path area, and the straight line P
It becomes like 2.

Now, a flow channel with a flow channel area of 100 cm ² is
It is assumed that the present invention is applied to two channels having the same area. Then, the area of each flow path becomes 50 cm ² . And
Since no ozone decomposing catalyst is provided in one of the flow paths, the air volume is W _A along the straight line P1. Also, the other channel is 1
Because disposing the catalyst which can decompose ppm of ozone, the air volume becomes W _B along the straight line P2. Therefore, the total amount of air blown from both flow paths is W _A + W _B. To secure this air volume, if the flow area is 100 cm ² ,
In the conventional device, the ozone concentration must be 0.1 ppm. As described above, in the conventional device, the predetermined air volume could not be secured without lowering the ozone concentration, but according to the present invention, the predetermined air volume can be secured even when the ozone concentration is 1 ppm. By increasing the ozone concentration, the overall deodorizing effect is eventually enhanced.

[0019]

As described above, according to the air conditioner of the present invention, it is possible to secure the required blow-out air volume in the flow passage on one side, so that the flow-out air volume is specially considered in the flow passage on the other side. Without doing so, the ozone concentration can be increased, and at the same time, the filter can be thickened to ensure deodorization. Therefore, although the air flowing through the flow path on the one side is not deodorized, the deodorized air is surely increased, so that the overall deodorizing effect is enhanced. Further, since the ozone concentration can be increased, the sterilizing effect of ozone can be expected sufficiently. Further, since the small duct is provided upstream or downstream of the evaporator, the evaporator can be arranged so as to cover the entire cross section of the duct, and the air flowing through the duct is efficiently cooled by the evaporator. Further, the small duct has a tubular shape, and its axis is along the air flow path. Therefore, the air flowing in the small duct receives almost no flow resistance due to the small duct body, and the pressure loss is small. As a result, a large amount of air passing through the small duct can be secured, and deodorization efficiency can be increased.

[Brief description of drawings]

FIG. 1 is a sectional view showing a schematic configuration of an embodiment of the present invention.

FIG. 2 is a cross-sectional view showing a schematic configuration of another embodiment of the present invention.

FIG. 3 is an explanatory diagram for demonstrating the effectiveness of the present invention.

FIG. 4 is another explanatory diagram for demonstrating the effectiveness of the present invention.

[Explanation of symbols]

 1 ...... Duct 2, 2A, 2B ...... Flow path 3 ...... Fan 4 ...... Evaporator 8 ...... Small duct 9 ...... Ozone generator 10 ...... Filter

Claims (1)

(57) [Scope of utility model registration request] 1. An evaporator and an evaporator in a duct.
A small duct that is separated from the
This small duct has a cylindrical shape and its axial center is as described above.
It is arranged along the flow path, and this small duct allows the above-mentioned flow.
There are two independent paths, one inside the small duct and one outside the small duct.
It is divided into two channels, and in the above small duct, it is upstream.
A ozone generator is installed and ozone is decomposed on the downstream side.
A filter consisting of a catalyst is installed, and this filter
An air conditioner with a deodorizing function, which is characterized by covering the entire cross section of the flow path inside the container .