ES2662069T3 - Outdoor unit of air conditioner - Google Patents

Abstract

An outdoor air conditioner unit comprising: a body housing (40) having a blower compartment (S1) through which an air flow passes from one side of the front surface to the outside; a fan (39) that is placed in the blower compartment and that serves to generate a flow of air that flows to the side of the front surface of the body housing; a plate-shaped humidification rotor (63) that includes an adsorption zone that performs moisture adsorption in the outside air and a desorption zone that, as a result of being heated, performs the desorption of adsorbed moisture in the area adsorption; and an air flow path to allow air flow to flow from flow down the fan to the adsorption zone, characterized in that the plate-shaped humidification rotor (63) is installed along a plane perpendicular to a forward and backward direction.

Description

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gear 65a disposed on the periphery of the humidifying rotor 63.

The adsorbent agent, such as zeolite, which forms the humidification rotor 63 has the property that it adsorbs moisture from the air at a normal temperature, for example, and performs moisture desorption as a result of being heated at a high temperature by the heater 71 or similar, and reach a temperature higher than the normal temperature. That is, the region of the humidification rotor 63 exposed to the air at a normal temperature is the adsorption zone 61 that performs the moisture adsorption of the outside air, and the region in which the humidification rotor 63 is heated using the heater 71 it is the desorption zone 62 that performs the desorption of the adsorbed moisture.

In addition, the humidification rotor 63 is positioned such that its axis of rotation extends in the forward and backward direction. That is, the main surface of the humidifying rotor 63 is arranged along a plane (for example, the front panel 46) perpendicular to the forward and backward direction in which the outdoor fan 39 generates the air flow . It should be noted that "the main surface of the humidification rotor is disposed along a perpendicular plane" is a concept that includes everything from a case in which the main surface of the humidification rotor is not inclined at all with respect to the plane perpendicular, up to a case in which the main surface of the humidification rotor is inclined approximately ± 15 ° with respect to the plane perpendicular to the forward and backward direction. The main surface of the humidification rotor 63 described in this case is an example of a case in which it is not inclined at all with respect to the perpendicular plane. Generally, arranging the main surface of the humidifying rotor along a plane perpendicular to the forward and backward direction in which the outdoor fan generates the air flow results in a vertical placement in which the width direction (thickness direction) of the humidification rotor extends back and forth so that the humidification rotor does not occupy space in the forward and backward direction.

As shown in Figure 4, the humidifying rotor 63 is placed in the open part 43a of the dividing panel 43 such that the adsorption zone 61 is located in the blower compartment S1 of the outdoor conditioner unit. air 30 and that the desorption zone 62 is located in the machine compartment S2 of the outdoor air conditioner unit 30. As shown in Figure 5, as seen in a plan view, the area of adsorption 61 is located between the outdoor heat exchanger 33 and the front panel 46 in the blower compartment S1, and the humidification unit 60 is positioned together with the outdoor fan 39. Furthermore, as shown in Figure 3, as seen in a front view, the humidification unit 60 is positioned adjacent to the outdoor fan 39 diagonally above and to the right of the outdoor fan 39. The adsorption zone 61 of the humidification unit 60 is oriented towards a section in which the front panel 46 of the body housing 40 is not, so that the adsorption zone 61 is exposed to the outside of the body housing 40. Since the humidification unit 60 is placed in this way, negative pressure is created within the body housing 40 with respect to the outside of the body housing 40, so that the humidifying air can be supplied from outside the body housing 40 to the adsorption zone 61 In addition, by using a blocking surface 81 (see Figure 2) disposed on the grid 80, an air flow can be pushed into the adsorption zone 61 from outside the body housing 40 using the air flow that it is blown outwards from the body housing 40 by the outdoor fan 39.

(2-2-5-2) Heater 71

The heater 71 is disposed opposite to the section of the humidifying rotor 63 which functions as the desorption zone 62. The heater 71 has a structure in which an electric heating cable (not shown in the drawings) is disposed within a container tubular 71a shown in Figure 7, and the outside air absorbed from the inlet 72 (see Figure 1) and supplied to the humidifying rotor 63 is heated by the electric heating cable. In the humidification rotor 63, when the heated air passes through the openings in the honeycomb structure of the humidification rotor 63, moisture desorption is performed from the humidification rotor 63 so that the air sucked into the turbo fan 75 is humidified .

As shown in Figure 7, the heater 71 is attached to a heater support element 74. The heater support element 74 has a semicircular base part 74a and an outer wall part 74b that is arranged straight with respect to to the peripheral edge part of the base part 74a, and the side (the side of the humidifying rotor 63) of the heater support member 74 is open. Additionally, the heater 71 is attached to the base part 74a such that it is covered by the heater support element 74. The heater support element 74 configures part of the desorption path. It should be noted that the heater cover 71 and the heater support element 74 are made of rolled metal. In addition, the heater 71 is installed in the machine compartment S2 of the outdoor air conditioner unit 30 and is placed on the opposite side of the electrical component box 50, the humidification rotor 63 being sandwiched between them.

(2-2-5-3) Turboventilator 75

The turbo fan 75 generates an air flow that is directed from the outdoor unit of air conditioner 30

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up to the indoor unit of air conditioner 20. In addition, the turbo fan 75 is placed opposite the heater 71, the humidification rotor 63 being sandwiched between them and, as shown in Figure 3 and Figure 5, is installed in the machine compartment S2.

The turbo fan 75 has a fan motor 75a, an impeller 75b that is driven by the fan motor 75a and a fan housing 75c housing the impeller 75b. The rotation axis of the impeller 75b of the turbo fan 75 is positioned to extend in the forward and backward direction, and the turbo fan 75 has a vertical placement that does not take up space in the forward and backward direction. In addition, a suction portion 76 of the turbo fan 75 opens backwards. In addition, a discharge part 77 of the turbo fan 75 opens downwards. Additionally, a humidification duct 78 is connected to the discharge part 77, and the supply air duct 18 joins the humidifying duct 78. For this reason, the air absorbed from the suction part 76 of the turbo fan 75 is guided through the humidification duct 78 to the supply air duct 18, it travels through the supply air duct 18 and is blown outwardly from the outlet 24 of the indoor air conditioner unit 20.

(2-2-6) Grid 80

Figure 9 is a perspective view in which the grid is viewed from its rear surface side. The grid 80 has the locking surface 81, a lattice-shaped part 82, in which transverse pieces are placed together vertically and horizontally and in which numerous openings are formed, and a joint frame 83 for attachment to the panel front 46. In addition, an air direction guide 84, to guide the air flow to the adsorption zone 61 of the humidification unit 60, is formed on the rear surface of the locking surface 81. The air direction guide Air 84 is configured by an upper rib 84a and a lower rib 84b.

As shown in Figure 2, in a state in which the grid 80 joins the body housing 40, the left end of the locking surface 81 reaches as far as part of the outlet 44. In other words , part of the right side of the outlet 44 opposes the blocking surface 81. For that reason, part of the air flow blown out from the outlet 44 is blocked by the blocking surface 81. Most of the air flow blocked by the blocking surface 81 is guided to the adsorption zone 61 by the air direction guide

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The upper rib 84a extends diagonally up and to the right from a position diagonally with respect to the right and upper side of the outlet 44, and the lower rib 84b first extends to the right from a position diagonally with respect to the side right and bottom of exit 44, and then gradually change the direction up. The joining frame 83 of the grid 80 is essentially the same height as the upper rib 84a and the lower rib 84b, and when the grid 80 is joined, the joining frame 83 arranged around the grid 80 and the upper rib 84a and the lower rib 84b comes into contact with the front panel 46. For this reason, the outlet 44 and the air inlet 61a of the adsorption path are interconnected by a space surrounded by the front panel 46, the air direction guide 84 and the blocking surface 81. The space surrounded by the air direction guide 84 extends along the direction of rotation of the outdoor fan 39 (one direction counterclockwise, as is watch from the front). For this reason, air is pushed in the direction of arrow A1 in Figure 3.

(3) Air flow during humidification operation

Next, the air flow during the humidification operation will be described. It should be noted that, in the air conditioning system 10, the humidification operation is performed in combination with the heating operation. For this reason, during humidification operation, the compressor 31 and the outdoor fan 39 are driven. In addition, during the humidification operation, the humidification rotor 63 is rotated at a predetermined rotation speed by the energy from the rotor drive motor 64, the heater 71 is on and the turbo fan 75 is running. It should be noted that, since the humidification rotor 63 rotates, the moisture adsorbed by the adsorption of the humidification rotor 63, which functions as the adsorption zone 61, is carried out as the humidification rotor 63 rotates, so that the desorption of the moisture that had been adsorbed by the desorption of the humidification rotor 63, which functions as the desorption zone 62, is performed, thus, the air around the desorption zone 62 is humidified. In addition, the humidification rotor 63 of the present embodiment rotates counterclockwise, as seen from the front, and the section that functioned as the adsorption zone 61 functions as the desorption zone 62 when rotates and reaches the position opposite the heater support element 74.

During the humidification operation, the outdoor fan 39 is driven, which generates an air flow in which outside air is absorbed through the outdoor heat exchanger 33 from the rear surface side of the outdoor heat exchanger 33 and blow outward to the front surface side of the air conditioner outdoor unit 30. Part of the flow of air blown out from the outlet 44 flows into the space configured by the front panel 46, the guide of air direction 84 and the blocking surface 81, and is guided to the adsorption zone 61. The air that reaches the adsorption zone 61 passes from the front

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Claims (1)

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