JPH0363429A - air conditioner - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] Industrial Fields of Application The present invention is related to air conditioners that cool or heat indoors, but it is also a conventional technology. 1″L Explanation No. tt@ No. Supplementary Figure (Above) Each is a cutaway cross-sectional view of the main parts of a ceiling-mounted air conditioner (1),
(2) is front grid) L=, (3) is speech bubble,
(4) is a suction port (5) is an air filter, (6) is an indoor heat exchanger (7) that constitutes a well-known refrigeration cycle, and is a water receiver that processes condensed water from the indoor heat exchanger (6). I
[L (8) is a cross-flow fan that sends the air heat-exchanged in the indoor heat exchanger (6) to the outlet (3);
9) is a stabilizer, and (10) is a fan casing. Fig. 9@Fig. (12) is the power supply board that drives the air conditioner (12). Vessel (6
) is an evaporating dish installed below the evaporating dish (1
3a), and has a rising rib (13b) of an arbitrary height around it. Plural evaporating dishes force exchange Problems to be solved by the invention even if they are arranged horizontally and on stairs The above configuration ζ Heat The tilt angle (θ) of the exchanger (6) is 60
If the temperature is less than 20°, the heat exchanger (6) will deteriorate over time.Dust, oil, etc. may accumulate on the heat exchanger (6), causing problems such as condensed water dripping into the room from the heat exchanger (6). □
□ ~ If you try to maintain the inclination angle θ of the heat exchanger (6) at 60° or more, the height (H) of the main unit will increase as shown in Figure 8, making it difficult for this type of air conditioner to be buried in the ceiling. However, there are problems such as not being able to install it in the ceiling, and the first
As shown in Figure 0, if the inclination angle θ of the heat exchanger (6) is set to 60 degrees in order to lower the height (H) of the main body, the water tray that covers the front area of the projection surface of the heat exchanger (6) will be Due to the need to secure the suction opening area, the depth dimension of the main body (W
) increases, ventilation resistance increases, noise levels increase, and there are various problems such as increased material costs and poor installation performance.Also, as shown in Figure 12, multiple evaporators are located below the heat exchanger. Some pans have the pan (13) arranged in a stepped manner, but those with the evaporating pan (13a) placed parallel to the suction port have a large ventilation resistance on the suction side, resulting in increased motor output, higher noise levels, and higher loads. 1. Problems such as overflow from the evaporating dish and condensation on the evaporating dish occur.
The present invention (Friend) In view of the above-mentioned conventional problems, it is possible to reduce the inclination angle (θ) of the heat exchanger to less than 6r, reduce the height and depth of the main body, and prevent condensed water from dripping into the room. The purpose of the present invention is to prevent condensed water from dripping into the room, and to rectify the flow of air from the suction port to the heat exchanger to further reduce noise. In addition, the present invention
The purpose of this invention is to improve the air velocity distribution of the heat exchanger and increase the heat exchanger capacity. An indoor heat exchanger having a mouth and an air outlet and configuring a well-known refrigeration cycle inside the main body. A water tray for treating condensed water is installed on the downstream side of the indoor heat exchanger and on the projection surface of the indoor heat exchanger.
A water receiving gutter having a raised rib of a predetermined height, tilting at an arbitrary angle counterclockwise from the horizontal plane, and extending toward the heat exchanger; When the extending protrusion for draining, the rising rib of the lower water receiving gutter, and the trailing edge of the saucer surface of the upper water receiving gutter overlap, the rear edge of the water receiving gutter at the lowest end overlaps. A plurality of water receiving troughs are arranged in a stepped manner so as to overlap with the water receiving tray, and a second U-shaped guide gutter is provided at both ends of each water receiving gutter and connected to each water receiving gutter and leading to the water receiving tray. In addition, the present invention is such that the water receiving troughs are arranged so that the distance between the water receiving troughs in the second water receiving tray increases as the distance from the cross flow fan increases. The effect of is as follows. The present invention ζ
A saucer that has a rising rib of a predetermined height below the indoor heat exchanger and on the downward projected surface of the indoor heat exchanger, is inclined at an arbitrary angle above the horizontal plane, and extends toward the heat exchanger. A water receiving gutter consisting of a surface, a draining protrusion extending downward at the rear edge of the water receiving gutter, a rising rib of the lower water receiving gutter, and a trailing edge of the saucer surface of the upper water receiving gutter. As the water receptacles overlap, the trailing edge of the water receptacle at the lowest end is arranged in a stepped manner so that they overlap with the water receptacle, and each water receptacle is connected to its own water receptacle at both ends. By providing the second water tray consisting of a U-shaped guide gutter that communicates with the water tray, all of the dripping water from the heat exchanger can be received by the water tray and guided to the water tray by the guide gutter. It is possible to prevent condensed water from dripping into the room or from overflowing from the water receiving gutter.Furthermore, by providing a drainage protrusion extending downward at the rear edge of the water receiving gutter, Hydraulic exchange dripping from the heat exchanger onto the rear edge of the water receiving gutter can be prevented from crawling along the back side of the water receiving gutter and dripping into the room. By tilting at any angle above the horizontal plane, air can be guided smoothly from the suction port to the heat exchanger, and the heat exchanger can be tilted to less than 60" without increasing ventilation resistance on the suction side. The main body can be constructed without increasing the height or depth of the main body.Also, the spacing between the water receiving gutter in the second water receiving tray increases as the distance from the crossflow fan increases.) D Place the water receiving gutter As a result, it has been possible to improve the wind speed distribution, where the wind mainly flows towards the area close to the crossflow fan.
Embodiment Hereinafter, an embodiment of the present invention will be explained with reference to the drawings. 1). In the figure showing the tray part, (2) is the front grill I, (3) is the air outlet (4) is the suction [:L], (5) is the air filter, and (6) is the well-known refrigeration cycle. The indoor heat exchanger (7) is a water receiver IL that processes the condensed water of the indoor heat exchanger. (8) is a cross flow fan, (9) is a stabilizer, and (10) is a fan casing. is a longitudinal cross-sectional view of the main parts of the air conditioner (1), in which (11) is the power supply board (12) that drives the cross flow fan (8), and L (14) is the room Below the inner heat exchanger (6),
Also, it is a water receiving gutter provided on the projection surface of the heat exchanger (6), and (14a) is a rising squirrel (14a) of a predetermined height.
4b) is a saucer ffi (1
4c) is the rear of the saucer surface & (14d) is a draining protrusion extending downward from the rear edge of the water tray (14).
i! The rising rib (14a) and the saucer surface (1
The rear edge (14c) of the water receiving gutter (14) at the lowest end overlaps with the rear edge (14c) of the water receiving gutter (14) at the lowest end.
c) are arranged in a stepwise manner so as to overlap with the water receiving tray (7), and the water receiving trays (7) are connected to each water receiving gutter (14) at both ends of each water receiving gutter (14).
) is provided with a second water tray (16) consisting of a U-shaped guide trough (I5) leading to the drain. Next, the second embodiment of the present invention will be described with reference to FIG. 7. FIG.
17 is a water tray JtiL (17a) is a rising rib of a predetermined height, (17b) is a saucer k extending toward the heat exchanger (6) side (17c) is a rear edge of the saucer surface (
17d) are water draining protrusions extending downward from the rear edge, and water receiving troughs (17)i are arranged in plural pieces on the stairs below the heat exchanger (6) as in the first embodiment. At both ends there are U-shaped guide troughs (18) leading to the water tray (7).
Even if a cross-flow fan (
8) It gets bigger as it gets further away (Ig) 12>
Effects of the invention even if set as 1+ a water receiving gutter having rising ribs, tilting at an arbitrary angle upward from the horizontal plane and extending toward the heat exchanger; and a water draining gutter extending downward from the rear edge of the water receiving gutter. The protrusion, the rising rib of the lower water receiving gutter, and the trailing edge of the saucer surface of the upper water receiving gutter overlap, and the trailing edge of the water receiving gutter at the lowest end overlaps with the water receiving tray in a step-like manner. By arranging a plurality of water receiving troughs and providing a second water receiving tray at both ends of each water receiving gutter, which is a U-shaped guide gutter connected to each water receiving gutter and communicating with the water receiving tray, the heat exchanger All dripping water from the drain can also be collected by the water receiving gutter.The guide gutter can guide the water to the water receiving tray, preventing condensed water from dripping into the room, and preventing condensed water from overflowing from the water receiving gutter. By installing a drainage protrusion extending downward on the rear edge of the water receiving gutter, water drips from the heat exchanger onto the trailing edge of the water receiving gutter.The water drips down the back side of the water receiving gutter and enters the room. In addition, by tilting the receiving plate surface of the water receiving gutter upward toward the heat exchanger at an arbitrary angle, air can be guided smoothly from the suction port to the heat exchanger, and the suction The heat exchanger can be tilted 60 degrees without increasing side ventilation resistance,
The height of the main body can be configured without increasing the depth.Also, the spacing between the water receiving gutter in the second water tray: By arranging the water receiving gutter so that it becomes larger as it gets farther away from the cross flow fan, It has various advantages such as being able to improve the problem of wind speed distribution such as the flow of wind mainly to the area close to the cross-flow fan, and increasing the heat exchanger capacity.

[Brief explanation of drawings]

Figure 1 is a cross section of an air conditioner showing an embodiment of the present invention. Figure 2 is a perspective view of the air conditioner. Figure 3 is a vertical cross section of the air conditioner. Figure 4 is the air conditioner. Figure 5 shows the side of the water tray, and Figure 6 shows the front side of the water tray.
The cross section taken along line A-A in the figure is: Figure 7 is the side cross section of the second water tray in the second embodiment; Figure 8 is the cross section of the air conditioner showing the first conventional example; Figure 9 is Fig. 10 shows the second conventional example; Fig. 11 shows the longitudinal section of the air conditioner;
The figure is a cutaway cross-sectional view of an air conditioner showing the third conventional example.
3. The speech bubble is 4. The intake port is 5.
...Air filter 6...Heat exchanger 6a...
・Hairpin, 6b...Return bend, 7...
・Water receiver IL8...Cross flow fan, 9...
... Stabilizer, 10 ... Fan casing, 1
1... Mokyu 12... Power supply & 14.17
...Water tray maple 14a, 17a...Rising squirrel 14b, 17b...Saucer & 14c
+ l 7 c... Trailing edge 14d, 17d...
Protrusion 15.18...Guidance 16.19...
Second water tank

Claims (2)

[Claims] (1) An indoor heat exchanger that has an inlet and an outlet on the lower surface and configures a well-known refrigeration cycle within the main body, a cross flow that sends the air heat exchanged in the indoor heat exchanger to the outlet. A fan, a driving means for driving the cross-flow fan, and a water tray for treating condensed water of the indoor heat exchanger, and below the indoor heat exchanger,
and a water receiving gutter having a raised rib of a predetermined height on the downward projected surface of the indoor heat exchanger, inclined at an arbitrary angle upward from the horizontal plane, and comprising a saucer surface extending toward the heat exchanger. , the draining protrusion extending downward from the rear edge of the water receiving gutter, the rising rib of the lower water receiving gutter, and the rear edge of the saucer surface of the upper water receiving gutter overlap, and the bottom end A plurality of water receiving gutter is arranged in a stepped manner so that the rear edge of the water receiving gutter overlaps the water receiving gutter, and the water receiving gutter is connected to both ends of each water receiving gutter, and the water receiving gutter is connected to the water receiving gutter at both ends of the water receiving gutter. An air conditioner equipped with a second water tray consisting of a U-shaped guide gutter leading to the (2) The air conditioner according to claim 1, wherein the water receiving gutter is arranged such that the interval between the water receiving trays in the second water receiving tray increases as the distance from the cross flow fan increases.