RU2387930C1 - Air conditioner of ceiling type (versions) and its internal unit (versions) - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: air conditioner and its unit are intended for creating comfortable conditions in various rooms. Air conditioner includes brackets intended for its hanging and internal unit including a housing made in the form of a box, which has an upper plate, side plates and open area made in lower part of this housing, front panel installed with possibility of being removed in open area of the housing, heat exchanger of internal unit owing to which the above housing is divided from inside into the main space and additional space, and air injector attached to upper plate of the housing on that side of the plate which faces the main space includes the following: heat-insulating material of the main space, which is located on upper plate so that its surface faces the main space of the housing; and heat-insulating material of additional space, which is arranged on side plates so that its surface faces the additional space of the housing; at that, heat-insulating material of the main space is equipped with open area which allows attaching the air injector to upper plate.

EFFECT: decreasing overall dimensions.

14 cl, 24 dwg

Description

The present invention relates to a ceiling type air conditioner.

The indoor unit of the ceiling type air conditioner has a case in the form of a box, on the lower side of which an open area is made. Inside the case is divided into the main space and additional space as a result of the placement of the heat exchanger of the indoor unit. The main space is limited by the upper plate of the body and the heat exchanger of the indoor unit, and the internal air, which has not yet been conditioned, is taken from the room into the main space. The additional space is limited by the side plates of the body, the upper plate of the body and the heat exchanger of the indoor unit, and the conditioned air is supplied from the main space to the additional space. To prevent condensation due to the presence of air-conditioned air, heat-insulating material is placed on the side plates and the upper plate of the body, which is designed to heat the additional space and whose surface faces the additional and main spaces in such a way as to cover the entire surface of the side plates and the upper plate ( for example, see JP-A-2004-84999).

At the same time, there is a slight risk that, except in the additional space, condensation will occur in the main space, such condensation can occur if the air humidity in the space under the roof arch is high. Therefore, there is an option when the heat-insulating material is installed outside the housing on its outer surface.

If the insulating material is installed outside the housing on its outer surface, then the height of the indoor unit increases.

In addition, at the indoor unit of a ceiling-type air conditioner, the air injection port has an elongated shape and extends along each side of the front panel, and a damper is provided inside the said port to regulate the direction of the discharge of heat-exchanged air. This flap extends in the longitudinal direction of the air discharge port and is fixed in such a way as to allow it to rotate relative to the swing shafts created at both ends in the longitudinal direction. A regulating element is provided in the central part of the shutter for adjusting the swing range of this shutter. This control element is brought into contact with the control element located on the side of the main body at the time of the start of operation, as a result of which the starting point for the swing range of the damper is set (for example, see document JP-A-2007-93041).

However, the shutter has an elongated shape and, in addition, it is a part of a cast polymer, therefore, it may bend (deform) as a result of exposure to the heat of the injected air or the like. When the damper is bent, the position of the damper control element changes, as well as the contact position between the damper control element and the control element on the main body side. Therefore, there is a risk that the starting point of the swing range of this damper will shift.

Further, a ceiling-type air conditioner is known, in the housing of which an air blower and a heat exchanger are located, and the front panel of which is located on the lower side of the housing (for example, see document JP-A-2001-235174). This type of air conditioner has a temporary mount area designed to temporarily mount the front panel to the chassis for safety. The front panel is temporarily attached to the temporary mounting area, and then this panel is fixedly mounted on the housing with screws.

In this case, for example, brackets for installation are located on the lower side of the drain pan, and the temporary fastening areas are made in these brackets. As a result, there are problems associated with the complexity of the design, an increase in the number of parts and an increase in the cost of production.

A ceiling-type air conditioner is also known, the main body of which is suspended from the ceiling by means of suspension bolts, the front panel is attached to the lower surface of the main body of the air conditioner, and the corner panels that can be freely removed are located at the four corners of the body of this front panel.

In this type of air conditioner, for example, if a worker works with suspension bolts to adjust the height of the main body of the indoor unit or the like, this worker removes the corner panel from the body of the front panel to release the open area made in the panel body and pokes his hand or tool through this open area or performs similar actions to gain access and work with the suspension bolt. It is necessary that the corner panel is easily removed from the body of the front panel during operation, as described above, for reasons of speed of operation.

Based on this, an air conditioner is proposed in which the corner panel is provided with a permanent magnet, the front panel is provided with a metal plate brought into contact with this permanent magnet, and the ease of removing the corner panel from the front panel is enhanced by using the attractive force arising between the permanent magnet and the metal plate (for example, see Japanese patent No. 3284755).

However, for the conditioner discussed above, due to the need to use a permanent magnet and a metal plate, the production cost increases, and in addition, it is also necessary to provide a special mechanism for attaching a permanent magnet and a metal plate to the corner panel and front panel, as a result of which the design of the device is complicated.

Thus, it is an object of the present invention to provide an indoor unit of a ceiling type air conditioner in which thermal insulation can be provided without increasing the height of this indoor unit.

Another objective of the present invention is to provide an indoor unit of a ceiling type air conditioner in which the variation in the swing range of the damper can be reduced even if the damper is bent.

In addition, it is another object of the present invention to provide a ceiling type air conditioner that provides a simple temporary mounting scheme for the front panel, as a result of which the number of parts can be reduced, and thus the production cost can be reduced.

In addition, the next objective of the present invention is to provide a ceiling type air conditioner, the cost of which can be reduced and the design can be simplified while maintaining the ease of removing the corner panel from the front panel.

According to the first aspect of the present invention, in order to perform the above tasks, the ceiling-mounted air conditioner indoor unit including a box-shaped body having an upper plate, side plates and an open area formed in the lower part of this body, a removable faceplate in the open area of the housing, the heat exchanger of the indoor unit, due to which the said housing inside is divided into the main space and the additional space, and an air blower attached to The upper case plate, on the side of this plate that faces the main space, additionally contains: a heat-insulating material of the main space placed on the upper plate so that its surface faces the main space of the body, and a heat-insulating material of the additional space placed on the side plates so that its surface faces the additional space of the housing, and the heat-insulating material of the main space is provided with an open region Strongly which allows blower attached to the top plate.

According to this embodiment, the heat-insulating material of the main space can be placed on the upper plate on the side that faces the main space of the housing (i.e., on the inner surface of the upper plate), so as not to obstruct the attachment area of the air blower.

With the above implementation, the heat-insulating material of the main space and the heat-insulating material of the additional space can be made as a whole. With this embodiment, the heat-insulating material is made in its entirety, therefore, the number of parts can be reduced. In addition, the number of installation steps can also be reduced.

Further, in the above-described embodiment, the inner surface of the heat-insulating material of the main space, which faces toward the air blower, can be made flat. With this arrangement, nothing interferes with the air flow directed by the air blower, and air can flow in a straight path.

In the above-described embodiment, a cutout can be made on the inner surface of the heat-insulating material of the main space, in which the wires pass, this surface can be equipped with a wire clamp designed to fix the wires in the cut-out and attach the heat-insulating material of the main space to the upper plate of the housing. According to this embodiment, the wires can be securely fixed, and, in addition, heat-insulating material can be firmly attached to the upper plate.

According to a first aspect of the present invention, the heat-insulating material of the main space is placed on the upper plate on the side that faces the main space of the body, and an open area is made in the heat-insulating material of the main space for attaching the air blower to the upper plate. As a result, the heat-insulating material of the main space can be attached to the upper plate, while not occupying the installation area of the air blower. Accordingly, there is no need to shift the installation area of the heater by an amount corresponding to the thickness of the heat-insulating material of the main space. Therefore, it is not necessary to increase the height of the housing. As a result, compared with the situation when the heat-insulating material is placed on the outside of the upper plate, heat insulation can be performed without increasing the overall height of the indoor unit.

In addition, the heat-insulating material of the main space and the heat-insulating material of the additional space are made as a whole, therefore, in comparison with the situation when they are fixed separately, the fixing time can be reduced, and the fixing work can also be facilitated. In addition, the number of parts can be reduced, and as a result, the number of manufacturing steps can be reduced.

Further, the inner surface of the heat-insulating material of the main space, which faces the side of the air blower, is made flat, so there is no turbulence even in the case when the air flow supplied from the air blower hits this inner surface. In addition to this, the air flow supplied from the air blower can flow along a straight path, as a result of which wind noise (noise during air flow) can be reduced and, as a result, noise isolation can be ensured.

Further, a cutout is made on the inner surface of the heat-insulating material of the main space, in which the wires of the air blower pass, and there is a wire clamp designed to fix the wires in the cut-out and attach the heat-insulating material of the main space to the upper plate of the housing, which allows reliable fastening of the air blower wires. In addition, the heat-insulating material can be firmly attached to the upper plate, and as a result, an unnecessary gap between the heat-insulating material and the upper plate does not occur.

According to a second embodiment of the present invention, an indoor unit of a ceiling type air conditioner including a box-shaped body having an upper plate, side plates and an open area formed in the lower part of the body, a front panel mounted to be removable in the open area of the body, the heat exchanger of the indoor unit, due to which the said housing inside is divided into the main space and the additional space, and an air blower attached to the upper plate of the housing, the side of this plate, which faces the main space, further comprises: an air injection port, made of an elongated shape and extending along the side of the front panel; a damper that extends in the longitudinal direction of the air discharge port and has swing shafts at both ends; and a seat having a mounting hole in which each of the swing shafts is swingably mounted, and a stepper motor designed to drive the swing shaft of the damper, each of the swing shafts of the damper having a protrusion that projects from the outer peripheral surface of the swing shaft, and the wall of the mounting hole made in the seat is provided with at least one cutout engagement, which is in contact with said protrusion to regulate the swing range of the shutter.

According to the embodiment described above, the swing range of the shutter can be adjusted depending on the position of the mounting hole.

In the described embodiment, the wall of the mounting hole of the seat can be provided with two cutouts engagement, which are mutually symmetrical arrangement. With this embodiment, there is no need to provide several types of seats corresponding to the position of the cutout gearing.

In addition, the mounting hole may have a cylindrical shape. With this embodiment, it is easy to make a mounting hole and a cutout meshing.

According to a second aspect of the present invention, the swing shaft of the damper is provided with a protrusion that projects from the outer peripheral surface of this shaft, and the wall of the mounting hole is provided with an engagement cutout for adjusting the swing range of the damper by contact with said protrusion. As a result, the swing range of the shutter can be adjusted using the mounting hole area adjacent to the mounting area of the stepper motor. Therefore, even when the damper is bent due to the influence of the heat of the injected air or the like, this heat does not affect the protrusion, which prevents mutual displacement of the protrusion and the cutout of the engagement. As a result, when air conditioned, heat exchanged air can be supplied to a desired zone.

In addition, the engagement cutouts are made in the wall of the mounting hole in a symmetrical manner. Therefore, even when the orientation of the flap changes when it is installed on the seat, it is possible to make the protrusion abut the engagement cutout. As a result, there is no need to provide for several types of seats, and the details can be unified by using one seat.

Further, by using a mounting hole of a cylindrical shape, it is easy to manufacture this mounting hole and engagement cutouts, as a result of which the production cost can be reduced.

According to a third aspect of the present invention, there is provided a ceiling-type air conditioner including a box-shaped body having an upper plate, side plates and an open area formed in the lower part of the body, a front panel mounted to be removable in an open area of the body, an internal heat exchanger unit, due to which the said housing inside is divided into the main space and the additional space, an air blower attached to the upper plate of the housing on the other side of this plates, which is facing the main space, and brackets for hanging, which are made on the side plates of the body and through which they insert suspension bolts, lowering from the beams of the ceiling, to hang the body to the ceiling, characterized in that each of the brackets for hanging contains the first part, passing in the housing, the second part passing through the hole made in the housing, the outside of the housing, essentially parallel to the upper plate, and the third part, which is hooked to the lower end of the side plate casing, to create support for the lower end of the side plate of the casing, and which is equipped with an area of temporary fastening intended for temporary fastening of the front panel to the casing.

According to a third aspect of the present invention, the third part included in the suspension bracket is provided with a temporary fastening area for temporarily fastening the front panel, as a result, the temporary fastening scheme of the front panel is simplified and there is no need for a separate part for temporary fastening. Therefore, you can reduce the number of parts and, as a result, reduce the cost of production.

In the embodiment described above, the third part may be provided with a final fixation area intended for final fixation of the temporarily fixed panel on the housing. According to this embodiment, in the said third part of the suspension bracket, a final fixation area and a temporary fixation area are provided, therefore, it is possible to simplify the fixing circuit of the front panel. In addition, both the final fixation area and the temporary attachment area are made in the third part of the suspension bracket. Therefore, after temporary fastening of the front panel, you can directly perform the final fixation of this panel to the body, for example, without changing the position of the stepladder on which the worker stands, as a result of which the installation technology can be improved.

In addition, the temporary fastening area can be created by bending upward the end portion of the third part. According to such an embodiment, the temporary fastening area can be created in a simple manner and the temporary fastening scheme of the front panel can be simplified.

In the above-described embodiment, the front panel may be provided with open areas at its four corners, which correspond to suspension brackets, moreover, these open areas of the front panel are closed by corner panels, and each of a pair of open areas located opposite each other diagonally from the number of open areas of the front panels may be provided with a hook-like element, which is hooked to the area of temporary fastening. According to this embodiment, when removing the corner panel, it is possible to easily access the hook-shaped element, as a result of which it is possible to easily hook the hook-shaped element to the temporary fastening area / to remove the hook-shaped element from this temporary fastening area. In addition, a hook-like element is provided for each of the diagonally open open areas of the front panel, therefore, in the case of a mini-cassette type indoor unit having small dimensions in the horizontal plane, the worker can easily install / remove the front panel alone.

According to a third aspect of the present invention, the third part included in the suspension bracket is provided with a temporary fastening area for temporarily fastening the front panel, thereby simplifying the temporary fastening scheme of the front panel, and thus there is no need for a separate part for the temporary fastenings. Accordingly, it is possible to reduce the number of parts, as well as reduce the cost of production.

According to a fourth aspect of the present invention, there is provided a ceiling-type air conditioner including a box-shaped body having an upper plate, side plates and an open area formed in the lower part of the body, a front panel mounted to be removable in an open area of the body, an internal heat exchanger unit, due to which the said housing inside is divided into the main space and the additional space, the air blower attached to the upper plate of the housing on the other side is th plate, which faces the main space, and an angular panel mounted to be removable in each of the four angular regions of the body of the front panel, characterized in that the angular panel is equipped with an engaging tab made to engage in the meshing hole created in each of the four angular regions of the body of the front panel, and a mounting leg, which is created in one corner region of the corner panel so that it extends to the landing part made on the inner corner wall of the body of the front panel Nelly, and secured in the seat of the corner panel during installation on the body front panel.

In the above-described embodiment, the fixing leg can be made of elastic material and provided with a protrusion made with the possibility of engagement in the engagement hole created on the inner corner wall.

In the above-described embodiment, at the end portion of the fixing leg, a platform can be created that extends above the landing portion when the corner panel is mounted on the body of the front panel.

According to a fourth aspect of the present invention, the angular panel is moved with force in the direction of overlap to that place of the front panel body where this angular panel is to be fixed, the engaging foot on the angular panel is inserted into the meshing hole created in the front panel body and the protrusion of the fixing leg is angled the panels are located in the meshing hole in the inner corner wall of the front panel body, which makes it easy to fix the corner panel to the front panel body. In addition, with elastic deformation of the mounting leg to weaken the engagement between the protrusion and the engagement hole, the corner panel can be easily removed from the body of the front panel. As a result, installation / removal can be facilitated without the use of any special element, such as a permanent magnet, plate or the like, it is possible to reduce the cost and simplify the design of the device.

The invention is illustrated in the drawings, where:

Figure 1 is a schematic view of an indoor unit of a ceiling type air conditioner according to the present invention, viewed from an angle from the bottom;

Figure 2 is a side sectional view of the indoor unit shown in Figure 1;

Figure 3 is a plan view illustrating the location of the insulating material and the fan motor when they are installed in the housing;

Figure 4 is a General view corresponding to Figure 3, when viewed at an angle from above;

Figure 5 is a sectional side view corresponding to Figure 3;

6 is a General view illustrating a heat-insulating material as a whole, when viewed from an angle from above;

7 is a General view illustrating a fan motor assembly;

Fig. 8 is a side view of a rubber shock absorber attached to a base of a fan motor;

Fig.9 is a General view on an enlarged scale of the air discharge port created in the front panel, as well as the damper in the ceiling type air conditioner;

FIG. 10 is a schematic enlarged view of the support portion of the shutter shown in FIG. 9;

11 is a plan view illustrating the location of a stepper motor when mounted on a seat;

Fig - a General view of the seat for the stepper motor;

Fig - a General view of the shutter as one part;

Fig - a General view of the housing with brackets mounted on it for hanging;

Fig. 15 is a diagram of a mounting operation of brackets for hanging on the housing;

Fig. 16 is a perspective view illustrating a front panel with which a corner panel has been removed;

Fig is a diagram of the operation of mounting the front panel;

Fig. 18 is a layout diagram of a ceiling type air conditioner in a false ceiling with a cellular structure, as viewed from the side of the air conditioner;

Fig - a General view of the air conditioner from its lower side;

Figure 20 is a longitudinal sectional view of an air conditioner;

Fig is a view of one of the angular regions of the body of the front panel, when viewed from the side of the room;

Fig is a General view of the corner panel from the reverse side;

23 is a diagram illustrating the moment before attaching the corner panel to the body of the front panel; and

24 is a diagram illustrating the moment after attaching the corner panel to the body of the front panel.

Next, with reference to the accompanying drawings, preferred embodiments of the present invention will be described.

First option

Below, with reference to the accompanying drawings, a first embodiment of the present invention will be described. Figure 1 presents a General view of the indoor unit 10 of the air conditioner ceiling type, when viewed from the bottom surface, and Figure 2 is a view in longitudinal section of the main body 20 of the indoor unit. In this embodiment, as an example of the indoor unit 10, an indoor unit of cassette type with four-way air supply and a mini-cassette type with horizontal dimensions of 600 mm × 600 mm will be described. However, the present invention is not limited to the type indicated above and can be applied to an indoor unit with two air supply directions or with four air supply directions having the usual dimensions in the horizontal plane.

As shown in FIG. 1, the indoor unit 10 of the air conditioner has a main body 20 that is mounted in a mounting hole made in the cell of the suspended ceiling, from the side of the room, and a faceplate 100 attached to the main body 20 of the indoor unit from the bottom side.

The main body 20 of the indoor unit has a housing 21 that forms the external shape (dimensions in the horizontal plane) of this main body. The housing is made in the form of a box and contains a lower open area 21a, which is a fully open area on the lower side, as well as an upper plate 21b and side plates 21c. The upper plate 21b and the side plates 21c are manufactured by sheet metal processing. The lower open area 21a is covered by a faceplate 100, which is described above.

As shown in FIG. 1, in four corner regions on the outer surfaces of the side plates 21c of the housing 21, suspension brackets 28 are provided for suspending the main body 20 of the indoor unit. Suspension brackets 28 are mounted on suspension bolts 129 that are lowered from the ceiling, whereby the main body 20 of the indoor unit is suspended from the ceiling. In addition, the main body 20 of the indoor unit can be attached to the retaining rails forming a cellular structure of the surface of the suspended ceiling.

The front panel 100 has an air intake port 110 for collecting internal air into the central part of the front panel, four air injection ports 120 that are elongated in shape are located along the sides of the front panel 100 around the air intake port 110 and pump heat-exchanged air, and corner panels 102, forming the four corner regions of the faceplate 100. Each of the air injection ports 120 is provided with a shutter 122 for adjusting the direction of the air discharge. The corner panels 102 are designed to be removably mounted on the underside of the front panel 100, and of a size such that the installer can reach the mounting area of the brackets 28 for hanging on the bolts 129 for hanging when the corner panel 102 is removed .

A heat-insulating material 22 made of polystyrene foam (described in more detail below) is installed on the entire inner surface of the upper plate 21b and side plates 21c of the housing 21, and the main body 20 of the indoor unit has such a thermal insulation scheme that provides insignificant heat transfer between the internal space of the housing and the external environment outside this case.

A heat exchanger 24 of an indoor unit is installed in the housing 21, the frame of which in plan has a substantially rectangular shape. The upper end part of the heat exchanger 24 of the indoor unit is fixed so that there is no gap between this end part and the heat-insulating material 22, as shown in FIG. The lower end part of the heat exchanger 24 of the indoor unit is fixed in such a way that there is no gap between this end part and the drain pan 25, designed to receive the drained water generated during the heat exchange process.

Accordingly, the heat exchanger 24 of the indoor unit partitions the internal space into the main space S1 (the central region of the housing 21, when viewed in the horizontal plane) and the additional space S2 (the peripheral region from the side plates of the housing 21, when viewed in the horizontal plane).

The main space S1 is limited by the upper plate 21b of the housing 21 and the heat exchanger 24 of the indoor unit, and an air blower 23 is located in this space. The air blower 23 comprises a fan motor 23a attached to the upper plate 21b of the housing 21 by suitable means, and a fan 23b mounted on a rotary shaft of the fan motor . Accordingly, when the shaft of the fan 23b is rotated, air is sucked in in the direction of the rotary shaft (in the direction T1 in FIG. 2) through the air intake port 110 and is pumped into the peripheral region (towards the heat exchanger 24 of the indoor unit, in the direction T2 in FIG. 2).

In addition, a bell-shaped bell 26 is arranged between the air intake port 110 on the front panel 100 and the air blower 23 so that it tapers like a cone to the air blower 23. An electric unit 27 is located on the side of the bell-shaped bell 26 from the side of its outer peripheral surface. In the block 27 electricians placed electrical control circuits designed to control electrical devices, such as an air blower 23, etc.

The additional space S2 is limited by the side plates 21c and the upper plate 21b of the housing 21, as well as the heat exchanger 24 of the indoor unit, and the air supplied from the main space S1 is heat exchanged by the heat exchanger 24 of the indoor unit and then sent to this additional space S2.

Figure 3 is a bottom view illustrating the location of the heat-insulating material 22, the fan motor 23a, which is part of the air blower 23, and the drain pump assembly 29, designed to pump out the drained water located in the drain pan 25, when mounted in the housing 21. On Figure 4 presents a General view obtained from Figure 3, when viewed at an angle from above, and Figure 5 presents a side view in section, corresponding to Figure 3. Figure 6 presents a General view illustrating the insulating material as a whole, when viewed at an angle from above. Figure 3-6, the main body 20 of the indoor unit is shown in an inverted state (the lower open area 21a is located above), in this position the main body 20 of the indoor unit is manufactured.

As shown in FIGS. 2 and 6, the heat-insulating material 22 consists of a main heat-insulating material 22a, the surface of which faces the main space S1, and an additional heat-insulating material 22b, installed so that its surface faces the additional space S2. The main heat-insulating material 22a and the additional heat-insulating material 22b are made as a whole of polystyrene foam. The main heat-insulating material 22a is used to prevent heat transfer between the air above the upper plate 21b under the roof of the room and the internal air drawn into the main space. In addition, additional heat-insulating material 22b is used to prevent heat transfer between the air under the roof of the room and the air subjected to heat exchange by means of the heat exchanger 24 of the indoor unit.

A groove 31 is created on the inner surface Q of the main heat-insulating material 22a, which is designed so that it extends from the outside of the fan motor 23a, as shown in FIGS. 3-6. The heat exchanger 24 of the indoor unit is made so that its upper end part matches the shape of the bottom surface of the groove 31 and that this upper end part of the heat exchanger 24 of the indoor unit and the groove 31 are brought into mutual contact without a gap between them.

As shown in FIG. 6, a recessed area R is formed on the inner surface Q of the main heat-insulating material 22a, on which the fan motor 23a is fixed. This recessed area R is lower relative to the remaining part of the inner surface Q at a distance corresponding to one vertical level difference, and is designed so that the fan motor 23a is at the same height as in a conventional air conditioner. As shown in Fig.6, three holes 32 are created in accordance with the provisions of the mounting areas 40 of the motor 23a of the fan. The holes 32 are designed so that they pass through from the inner surface Q to the surface of the back side.

As shown in FIG. 7, the fan motor 23a located on the recessed area R has three mounting areas 40, in each of which a rubber shock absorber 41 is fixed. In more detail, the rubber shock absorber 41 is substantially cylindrical in shape, and the central (in the direction of height) part of this shock absorber created a narrowed part 42, as shown in Fig. This tapered portion 42 is secured in a recess 43 created in the mounting region 40, so as to clamp the mounting region 40 in thickness, as shown in FIG. 7. In addition, the rubber shock absorber 41 is designed so that the upper part 42a and the lower part 42b have a different diameter up to the narrowed part 42.

The diameter of the lower part 42b is set so that it is substantially equal to the diameter of the hole 32 in the main heat-insulating material 22a, as a result of which the lower part 42b enters the hole 32 without a gap. When assembling the fan motor 23a and the upper plate 21b by means of bolts 44, the fan motor 23a is fixedly mounted on the upper plate 21b. The rubber shock absorber 41 absorbs the vibration of the fan motor 23 a caused by the rotation of the engine.

As shown in FIG. 6, a cut-out 51 is created on the inner surface Q of the main heat-insulating material 22a, in which wires 50 extending from the fan motor 23a are placed. The wires 50 are connected to the electrics unit 27 and supply power to the fan motor 23a. The wire retainer 52 is fixed relative to the cutout 51 so as to close this cutout. As shown in FIG. 3, the wire clip 52 is attached to the upper plate 21b by screws 53 or the like. A wire retainer 52 is fixed to the upper plate 21b, as a result of which it presses the main heat-insulating material 22a against the upper plate 21b without a gap between them.

The inner surface Q of the main heat-insulating material 22a is formed by a flat surface without level differences. When fixing the wire retainer 52, the surface of this retainer 52 and the inner surface Q are essentially in the same plane.

That is, the inner surface Q is positioned so that it faces the air blower 23, and the air supplied from this air blower 23 hits the inner surface Q. As a result, the air does not hit a level difference or a different level zone and therefore there is no turbulent air flow. In addition, air strikes the inner surface Q, and a flat surface allows air to move along an absolutely straight path.

In a ceiling-type air conditioner indoor unit 10 corresponding to this embodiment of the present invention, on the upper plate 21b, on its side that faces the main space S1 of the housing 21, the main heat-insulating material 22a is placed, and this prevents heat transfer between the air under the roof of the room, and internal air drawn into the main space S1. Accordingly, condensation in the housing 21 can be prevented.

An opening 32 was created in the main heat-insulating material 22a for attaching the air blower 23 to the upper plate 21b, as a result of which the main heat-insulating material 22a can be mounted on the upper plate without interfering with the fixing of the rubber shock absorber 41 in the mounting region 40 of the air blower 23. Therefore, it is not necessary to shift the mounting the position of the air blower 23 in the height direction by an amount determined by the presence of the main heat-insulating material 22a, therefore, it is not necessary to increase the height of Pusa 21. Thus, as compared with a situation where a heat insulating material disposed on the outer side of the upper plate 21b, insulation can be ensured without increasing the height of the main body 20 of the indoor unit.

The main heat-insulating material 22a and the additional heat-insulating material 22b are made integrally, and compared with the situation when the separately made main heat-insulating material 22a and the additional heat-insulating material 22b are fixed separately, installation time can be reduced. In addition to this, installation can be facilitated. In addition, the number of parts can be reduced, and as a result, the number of manufacturing steps can be reduced.

Further, the inner surface Q of the main heat-insulating material 22a, which faces the side of the air blower 23, is flat in shape, therefore, the air supplied by the air-blower 23 hits the inner surface Q of the main heat-insulating material 22a and there is no turbulent air flow. Moreover, it is possible to straighten the trajectory of the air supplied by the air blower 23, as a result of which it is possible to reduce the noise created by it and provide sound insulation.

A cut-out 51 is made on the inner surface of the main heat-insulating material 22a, along which the wires 50 of the blower 23 pass, and the wires 50 are fixed in this cut-out 51. In addition, a wire retainer 52 is provided for attaching the main heat-insulating material 22a to the upper plate 21b of the housing 21 , due to this wire 50 of the blower 23 can be reliably fixed. In addition, the main heat-insulating material 22a can be firmly attached to the upper plate 21b, and therefore there is no unnecessary gap between the main heat-insulating material 22a and the upper plate 21b.

The present invention is not limited to the embodiment described above, and various types of modifications and alterations can be made based on the general technical idea of the present invention.

As for the heat-insulating material 22, in the indoor unit 10 corresponding to this embodiment of the present invention, the main heat-insulating material 22a and the additional heat-insulating material 22b are made as a whole. However, they can be made individually. That is, the heat-insulating material can be obtained by appropriately choosing either combining or separation, taking into account the size of the metal mold for the manufacture of the heat-insulating material, the cost of this form, etc., while the size of the heat-insulating material 22 varies in accordance with the size of the indoor unit 10 (for example, mini-cassette type, the dimensions of which are reduced to 600 mm × 600 mm).

Second option

FIG. 9 is an enlarged perspective view of the air injection port 120 and the shutter 122 located in the front panel 100, and FIG. 10 is an enlarged view of the support portion of this shutter. FIG. 11 is a plan view illustrating, when the corner panel 102 is removed, the location of the footprint for the stepper motor when it is mounted on the front panel 100. FIG. 12 is a general view of the footprint 30 for the stepper motor, and FIG. 13 is a general view. view of shutter 122 as one part.

The damper 122 extends essentially along the entire length of the air injection port 120 in its longitudinal direction, as shown in FIG. 1 and FIG. 9. Of the four corner regions of the faceplate 100 in one such corner region, which is shown in the upper left part of the drawing in FIG. 5, two seats 30 are created that serve as a support for one of the ends of the shutter 122 in its longitudinal direction (i.e., in the other three angular areas seating is not provided). As shown in FIG. 10, the seat 30 supports one of the ends of the shutter 122.

As shown in FIG. 12, the seat 30 is configured in such a way that it is substantially L-shaped in cross section and has a horizontal portion 31a and a vertical wall 31b, and a cylindrical support element 32 is formed on the outer surface of the vertical wall 31b, going outward. A mounting hole 33 is provided in the horizontal portion 31a for securing the seat 30 to the main body of the faceplate 100. As shown in FIG. 10, the outer surface of the vertical wall 31b forms the inner surface of one of the ends of the air discharge port 120 located in the longitudinal direction.

In addition, a stepper motor 34 is fixed in the L-shaped interior of the seat 30. The stepper motor 34 is connected to the electric unit 27 by wires (not shown), and the rotation angle of this motor is controlled by a controller located in the electric unit 27.

The cylindrical support element 32 consists of a continuous hole wall 32a and a hollow portion 32b surrounded by this hole wall 32a. At least one engagement cutout is created in the hole wall 32a. In this embodiment, two engagement cutouts 35a, 35b are created in the hole wall 32a, which are mutually symmetrical when viewed from the front seat 30 (in the direction A shown in FIG. 12). As shown in FIG. 12, the engagement cutouts 35a, 35b are configured to extend from the edge of the hole wall 32a to the vertical wall 31b.

As shown in FIG. 12, a drive shaft 34a of the stepper motor 34 is elongated in the center of the hollow portion 32b of the cylindrical support member 32, elongated in the same direction as the cylindrical support member.

The damper 12 is made using polymer casting as one part and contains a plate 40 that defines the direction of the air flow, which is elongated in the longitudinal direction and whose width increases towards its central part, as well as two swing shafts 41 extending outward from the end parts of the plate 40, specifying the direction of the air flow in its longitudinal direction, as shown in Fig.11. The swing shaft 41 is designed so that it has a substantially cylindrical shape, and flat sections 41a that are mutually parallel are created in the upper and lower parts of the swing shaft 41. On the upper flat portion 41a, a protrusion 42 is created in the form of a rectangular parallelepiped that protrudes outward from the outer surface of the swing shaft 41. In the end parts of the swing shafts 41, substantially elliptical meshing holes 43 are created, the centers of which coincide with the axes of the respective swing shafts 41. The diameter of the arcuate portion 41b is set so that it is equal to or slightly less than the diameter of the hollow portion 32b of the cylindrical support member 32.

When the swing shaft 41 is installed inside the hollow portion 32b of the cylindrical support member 32 shown in FIG. 12, the drive shaft 34a of the stepper motor 34 enters the engagement hole 43. The arcuate portion 41b of the swing shaft 41 can rotate freely while in sliding contact with the inner surface of the bore wall 32a. At the same time, the protrusion 42 of the swing shaft 41 enters the engagement cutout 35a or 35b and when the shutter 122 is rotated, the protrusion 42 comes into contact with the engagement cutout 35a or 35b, thereby adjusting the swing range of the shutter 122.

Next, with reference to FIG. 11, installation of the seat 30 will be described.

If we consider the case for one seat 30 of two seats 30, the drive shaft 34a of the stepper motor 34 (see Fig. 12) is installed so that it faces the bottom of the drawing in Fig. 11 and this stepper motor 34 rotates the shutter 122 (indicated by reference numeral 122L in FIG. 11) mounted along the left side of the faceplate 100.

In the drawing plane of FIG. 11, in the lower corner region (not shown) of the front panel 100, a connecting device (not shown) is provided for connecting the lower rocking shaft 41 of the shutter 122L and the rocking shaft 41 of the shutter 122 mounted in a direction along the lower side of the front panel . The connecting device can directly transmit the rotational moment of the stepper motor 34 to the shutter 122 extending along the lower side of the front panel 100 and, in addition, the two shutters 122 are connected to each other so as to rotate in phase.

If we consider the case for another seat 30 of two seats, the drive shaft 34a of the stepper motor 34 (see Fig. 12) is installed so that it faces the right side of the drawing in Fig. 11, and the stepper motor 34 rotates the shutter 122 (by 11 indicated by the reference number 122U) mounted along the upper side of the front panel 100.

In the drawing plane of FIG. 11, in the upper right corner region (not shown) of the front panel 100, a connecting device (not shown) is provided for connecting the swing shaft 41 on the right side of the damper 122U and the swing shaft 41 of the damper 122 mounted in the direction along the right side of the front panel. As in the case of the connecting device discussed above, this connecting device can directly transmit the rotational moment of the stepper motor 34 to the shutter 122 extending along the right side of the faceplate 100, and further, the two shutters 122 are connected to each other so as to rotate in phase .

When the swing shaft 41 is installed in the cylindrical support member 32 of the seat 30, the protrusion 42 of the swing shaft 41 of the above damper 122L enters the engagement cutout 35a located on the left side when viewed in the direction of arrow A in FIG. 12. When the swing shaft 41 is installed in the cylindrical support member 32 of the seat 30, the protrusion 42 of the swing shaft 41 of the above damper 122U enters the engagement cutout 35a located on the right side when viewed in the direction of arrow A in FIG. 12. That is, the cutouts 35a and 35b are designed so that they are mutually symmetrical, as a result of which two seats 30 can be used simultaneously.

The mounting hole 33 of the seat 30 is positioned so that it faces toward the room when the corner panel 102 (see FIG. 1) is removed, as shown in FIG. 11. Accordingly, when removing the corner panel, you can replace the seat 30.

Next, operation of the indoor unit corresponding to this embodiment of the present invention will be described.

When the indoor unit 10 starts to operate, four shutters 122 located in the air injection port 120 are driven by stepper motors 34 mounted on two seats 30, which leads to the start of swinging of the shutters 122. At the same time, the protrusion 42 located on the swing shaft 41 the shutter 122, abuts against the side of the cutout 35a or 35b, which determines the starting point of the swing range of the shutter 122. After that, the stepper motor 34 is rotated by a predetermined angle in response to a signal from the control circuit, and the swing range of the shutter is determined and based on the signal outputted from the control circuit.

In the indoor unit 10 of the ceiling type air conditioner according to the present invention, the swing shaft 41 of the damper is provided with a protrusion 42 protruding outward from the outer surface of the swing shaft 41, and the hole wall 32a is provided with engagement cutouts 35a, 35b that engage the protrusion 42 to adjust the initial points of the swing range of the shutter 122. As a result, by means of a cylindrical support element 32 located next to the mounting area of the stepper motor 34, it is possible to adjust the start point of the swing range beyond trays 122. Thus, even when the plate 40 defining the direction of the air flow, which is made on the shutter 122, due to the heat of the injected air or the like, this curvature of the plate 40 does not affect the protrusion 42, and therefore, the mutual displacement of the protrusion 42 and engagement cutouts 35a, 35b. As a result, during the air-conditioning operation, heat-exchanged air can be supplied to a predetermined area.

Since the engagement cutouts 35a and 35b are formed symmetrically in the bore wall 32a, the protrusion 42 may be configured to abut the cutout 35a, 35b even if the installation direction of the shutter 122 in the seat 30 is reversed. As a result, there is no need to provide several types of seats 30, and the details can be unified by using one seat 30.

In addition, the hole in which the swing shaft 41 is mounted is defined by the cylindrical support member 32, whereby it is easy to create the hollow portion 32b and the engagement cutouts 35a, 35b, and the cost can also be reduced.

When the corner panel 102 is removed, the mounting hole 33 of the seat 30 is positioned so that it faces toward the room. Thus, when removing the corner panel 102, it is easy to replace the seat 30, whereby maintenance can be facilitated.

The present invention is not limited to the embodiment described above, and various types of modifications and alterations can be made based on the general technical idea of the present invention.

In the above-described embodiment, a cylindrical support element 32 is created in the seat 30 and the swing shaft 41 is installed in this cylindrical support element 32. However, another scheme can be used. For example, the hole corresponds to the arcuate portion 41b of the swing shaft 41, and a cutout can be made for this hole to adjust the range of movement of the protrusion 42.

Third option

On Fig presents a General view of the housing 21 with mounted brackets for hanging on it, and Fig.15 presents a diagram of the operation of installing the brackets for hanging on the housing.

As described above, the suspension brackets 28 are attached from the four corners of the housing 21, respectively, and the suspension bolts 129 pass through the suspension brackets 28, which allows the housing 21 to be suspended from the ceiling by means of these suspension bolts 129. As shown in FIG. 15, each of the suspension brackets 28 comprises a first part 31 extending in the housing 21, a second part 32, and a third part 33. The second part 32 extends substantially parallel to the upper plate 21b outside the housing 21 when the first part 31 is inserted through an opening (not shown) created in the housing 21 in the direction of arrow P and then rotated in the direction of arrow R until the first portion 31 opposite the surface 31a adjoins the inner surface of the side plate 21c of the housing 21, and also includes a cutout 32a (Fig. 14), black With which the bolt 129 passes for suspension. The third part 33 is mounted close to the lower end 21d of the side plate 21c of the housing 21 for use as a support to this lower end 21d when the first part 31 is inserted through an opening (not shown) created in the housing 21 in the direction of the arrow P and then rotated in the direction of arrow R until the first part 31 opposite the surface 31a adjoins the inner surface of the side plate 21c of the housing 21.

More specifically, the suspension brackets 28 are substantially U-shaped in which the second part 32 and the third part 33 extend parallel to each other from the upper and lower ends of the first part 31. The first part 31, the second part 32 and the third part 33 are made as a single part from one sheet blank, for example, using pressure processing. Thus, the brackets 28 for hanging can be easily manufactured and the cost of production can be reduced.

As shown in FIG. 15, the suspension bracket 28 is attached to the side plate 21c of the housing 21 by a screw 35 in the position where the opposite surface 31a of the first part 31 is adjacent to the inner surface of this side plate 21c of the housing 21. In this case, the second part 32 It adjoins the upper edge of the hole (not shown) created in the housing 21, and the third part 33 hooks the lower end 21d of the side plate 21c of the housing 21 as a hook. Accordingly, the suspension bracket 28 is designed to it is possible to support the weight of the housing 21. Therefore, the screw 35 serves solely to connect the suspension bracket 28 and the side plate 21c, and this screw 35 does not perceive the weight of the housing 21. Thus, even if the screw 35 is loosened, the suspension bracket 28 supports the housing 21 by the second part 32 and the third part 33, and this prevents the release of the bracket 28 for hanging from the connection with the housing 21.

The suspension bracket 28 is used to suspend the main body 20 of the indoor unit from the floor beam through the suspension bolt 129, and if the height of the main body 20 of the indoor unit is changed, the suspension bolt 129 is adjusted. In the positions (at four corners) corresponding to the suspension brackets 28, the corner panels 102 are located. Thus, when the corner panel 102 is removed, the suspension brackets 28 are opened, and as a result, the suspension bolts 129 can be easily accessed. Accordingly, there is an advantage in that it is easy to access the brackets 28 for hanging from the outside by simply removing the corner panels 102.

In this embodiment of the present invention, the suspension bracket 28 has a temporary attachment area 34 for temporarily attaching the faceplate 100 (FIG. 1) to the third part 33, as shown in FIG. The temporary fastening region 34 is a hook created by bending the end portion of the third part 33 in an upward direction, and is created as a unit with the first part 31 and the second part 32 when manufactured using pressure treatment.

In addition, the suspension bracket 28 has a threaded hole 33a created in the third part 33, as shown in FIG. Threaded holes 33a are used when the faceplate 100 is attached to the housing by screws and they serve as areas for final fixation.

As described above, if there is a temporary fastening region 34 in the third part 33 of the bracket 28 for hanging to this temporary fastening region 34, it is easy to access when the corner panel 102 is removed, and this allows the front panel 100 to be temporarily attached to the temporary fastening region 34. In addition, there is no need to create a temporary mounting area separately from the suspension bracket, as a result of which the number of parts can be reduced and, as a result, the production cost can be reduced. Moreover, a threaded hole 33a is created in the third part 33 of the suspension bracket 28. Accordingly, after temporary mounting of the front panel, the worker can finally attach the front panel to the housing 21 without changing the position of the stepladder on which it stands, which allows to improve the installation technology.

On Fig presents a General view showing the angular region of the front panel 100, which is removed from the corner panel. On Fig shows the image for the state when the indoor unit 10 is suspended, inverted.

As shown in FIG. 16, the corner region of the faceplate 100 has a recessed portion 41 located lower than the surface of the faceplate 100 and an open region 42 created between the recessed portion 41 and the edge 100A of the faceplate 100. The recessed portion 41 and open area 42 is closed by the corner panel 102 (FIG. 1). The open area 42 is created in a position corresponding to the hanging bracket 28 mounted on the housing 21, and through this open area 42, the hanging bracket 28 can be accessed.

In this embodiment, the recessed portion 41 has a seat 43 obtained by continuing to extend part of this recessed portion 41 in the direction of the open area 42, and a through hole 44 is created in this seat for attaching the faceplate 100 to the housing 21.

A hook element 151 is placed on the edge of the seat 43, which is hooked onto the temporary attachment area 34. The hook element 151 is made by bending a metal plate, for example a leaf spring or the like, and has a base 52 attached to the seat 43, an elastic portion 53, which is a continuation of the base 52 and extends upward (downward in FIG. 16), and a hook 54, which is hooked onto the temporary fastening region 34 created by bending the end portion of the elastic portion 53 inward. The hook 54 is designed so that the angle between it and the elastic portion 53 at their intersection is approximately 45 °. The base 52 extends from the end of the seat 43 to the lower surface region of this seat 43 (the upper surface in FIG. 16) and is attached to the seat 43 by a screw 45. As described above, in this embodiment, the hook element 151 is located on the edge of the open area 42, therefore, it does not close this area 42 and does not interfere with operation.

In addition, the hook element 151 is placed on the edge of each of a pair of diagonally open areas 42 of the open areas of the faceplate 100 (not shown). Accordingly, in the case of a mini-cassette indoor unit 10 having small dimensions in the horizontal plane, the worker can install and remove the front panel alone, working with one hand with each of the hook-shaped elements 151 placed in opposite open diagonal open areas of the front panel 100.

Next, with reference to FIG. 17, an operation of mounting the front panel 100 on the housing will be described.

First, the hands are placed in diagonally open open regions 42 and the upper edge (i.e., hook 54) of the hook-like element 151 located in the open region 42 is rejected outwardly (in FIG. 17 in the direction of the arrow X) with a finger. In the state, the front panel 100 is lifted up and the hook 54 of the hook element 151 is hooked onto the temporary fastening region 34 on the suspension bracket 28. With this design, the hook-shaped element 151 is made of a leaf spring, and therefore, the elastic part 53 returns to its original state when the hook 54 is released by the finger, as a result of which the temporary fastening region 34 on the hanging bracket 28 and the hook 54 of the hook-shaped element 151 are engaged with each other, and the front panel 100 is temporarily attached to the housing 21.

Then, the screw 60 is inserted into the through hole 44 (Fig. 16) created in each seat 43 of the faceplate 100, and this screw 60 is fixed in the threaded hole 33a created in the third part 33 of each of the brackets 28 for hanging. Thus, the front panel can be easily attached to the housing 21. In addition, when the front panel is removed, it is possible to perform the opposite operation of the installation.

As described above, according to this embodiment of the present invention, in the ceiling type air conditioner, which has a housing 21 for receiving an air blower 23 and an indoor unit heat exchanger 24 therein, a faceplate 100 located on the lower side of the housing 21, and brackets 28 for hanging placed on the side plates 21c of the casing, and in which the casing 21 is suspended from the floor beam, and the casing is supported by the bolts for hanging from the said beam and inserted into the brackets 28 for suspension, each of the brackets 28 for hanging contains a first part 31 extending in the housing 21, a second part 32, which extends outwardly through the hole created in the housing 21, so that it is essentially parallel to the upper plate 21b, and a third part 33, which is hooked to the lower end 21d of the side plate 21c of the housing 21 to support the lower end 21d of the side plate. The third part 33 is provided with a temporary fastening area 34 for temporarily fastening the front panel 100. Thus, by using a part of the hanging bracket 28, the front panel 100 can be temporarily attached to this hanging bracket 28 and the temporary fastening of the front panel 100 can be simplified. Moreover, there is no need to create a temporary mount area 34 separately. Accordingly, it is possible to reduce the number of parts and, as a result, the production cost can be reduced.

According to this embodiment of the present invention, the third part 33 has a threaded hole 33a, with which the final fixation is performed on the case 21 of the front panel 100 in a state of temporary fastening, and therefore, temporary fastening and final fixation of the front panel 100 to the body 21 can be performed, using the third part 33 of the brackets 28 for hanging, and it is possible to simplify the installation of the front panel 100. In addition, the threaded hole 33a and the temporary fastening region 34 are located in the third parts 33 of the bracket 28 for hanging. Therefore, after temporarily attaching the front panel 100, it can be finally fixed to the housing 21 without changing the position of the stepladder on which the worker stands, and thus, the installation technology can be improved.

Moreover, according to this embodiment of the present invention, the temporary fastening region 34 is created by bending the end portion of the third part 33, so that the temporary fastening region 34 can be easily created and the temporary fastening scheme of the front panel 100 can be simplified.

Further, according to this embodiment of the present invention, the front panel 100 has open areas 42 that are closed by corner panels 102 that are located at the four corners of the front panel 100 in accordance with the position of the suspension brackets 28; a pair of open areas 42 of the four open areas 42, which are located diagonally opposite each other on the front panel 100, correspond to hook elements 151 that engage with the temporary fastening areas 34, and thus, when removing the corner panels 102, it is easy access the hook elements 151. Accordingly, the hook elements 151 and the temporary holding region 34 can be easily engaged / disengaged. In addition, the location of the hook-shaped elements corresponds to the position of the open areas 42, which are opposite each other diagonally. Therefore, in the case of the indoor unit 10 of the so-called mini-cassette type, which has small dimensions in the horizontal plane, the worker can easily install / remove the front panel alone, with one hand working with each of the hook elements 151, which are opposite each other diagonally on the front panel.

The present invention is not limited to the embodiment described above, and various types of modifications and alterations can be made based on the general technical idea of the present invention. In the above-described embodiment of the present invention, the temporary fastening region 34 is integrally formed with the third part by bending the end portion of the third part, however, the present invention is not limited in this way. For example, the temporary fastening area can be created separately from the third part and attached to the third part due to such connection methods as welding, screwing or the like.

Fourth option

On Fig presents the layout of the air conditioner 102 of the ceiling type corresponding to the fourth embodiment of the present invention, in the suspended ceiling 101 with a cellular structure, when you look at the air conditioner from the bottom side.

This honeycomb suspended ceiling has a plurality of retaining rails 103 that are suspended from the ceiling using a plurality of suspension members (not shown). These retaining rails 103 are installed to obtain a cellular structure, in each cell bounded by the retaining rails 103, an open area 104 arises between the retaining rails. In this embodiment of the present invention, each of the open areas between the retaining rails has a size of 600 mm x 600 mm. In the respective open areas 104, between the retaining rails there is a ceiling panel 105 corresponding to the size of the open area and forming the surface of the suspended ceiling, a lighting unit 106 for lighting the room, an air conditioner 102 for air conditioning the room, etc.

On Fig presents a General view of the air conditioner 102 from its lower side, and Fig.20 shows a view of the air conditioner 102 in longitudinal section.

An air conditioner 102 according to this embodiment of the present invention is a cassette type air conditioner with four-way air supply, the dimensions of which in the horizontal plane correspond to the open area 104 between the holding rails, and this air conditioner has a main body 111 suspended from the ceiling by means of suspension bolts and a faceplate 112 attached to the lower surface of the main body 111 of the air conditioner, as shown in FIGS. 19 and 20.

As shown in Figs. 19 and 20, the main body 111 of the air conditioner has a body 113 that forms the external shape (dimensions in a horizontal plane) of this air conditioner 102. The body is made essentially in the form of a duct having an open area on the lower surface and contains an upper plate 113A and side plates 113B. As shown in FIG. 19, suspension brackets 114 are located in four corner regions on the outer surfaces of the side plates 113B, and these suspension brackets 114 are mounted on suspension bolts 110 that are lowered from the ceiling, as a result of which the housing 113 is suspended by suspension bolts 110 and use the aforementioned overlap as support for this body.

As shown in FIG. 20, on the entire inner surface of the upper plate 113A and the side plates 113 B of the housing 113, as in the case of the first embodiment, a heat-insulating material 115 made of polystyrene foam is placed. A fan 116 is connected to the upper plate 113A of the housing 113 for pumping air, and an internal heat exchanger 117 is placed on the outer periphery of the fan 116 for pumping air. The air that is sucked through the air intake port 121 (described later) on the front panel 112 by the blower 116 air is supplied to the indoor heat exchanger 117, and in addition, the air subjected to heat exchange in the indoor heat exchanger 17 is pumped from the air injection port 122 (described later) on the front panel and 112. Below the indoor heat exchanger 117 there is a drain pan 118 made of polystyrene foam, designed to receive droplets of water condensate falling from this heat exchanger 117.

The front panel 112 has a front panel body 120 that is substantially rectangular in plan view, as shown in FIG. 19, and the front panel body 120 has an air intake port 121 created substantially in the center of this body 120, port 122 air injection, created on each of the four sides of the body 120 of the front panel so as to extend along each of the mentioned sides of the body 120. The air intake grille 123 is freely removable installed in the air intake port 121, also a filter is installed in the air intake port 121 p 124 to remove dust contained in the air flowing through the air intake port 121 to the housing 113. The air conditioner 102 draws in the indoor air through the air intake port 121 to the housing 113, exposes this air to heat and then pumps it through the discharge port 122 air to the room.

In addition, at the four corners of the faceplate body 120 below the suspension brackets 114 shown in FIG. 19, side openings 125 of the faceplate are created (see FIGS. 21 and 23), and angular mountings are freely removable on the faceplate body 120 panels 130 so as to cover the side openings 125 of the front panel. As in the case of the first to third embodiments of the present invention, when the air conditioner 102 is installed or its height is adjusted, the worker or another person removes the corner panel 130 to open the side hole 125 of the faceplate, pokes a hand or tool into the side hole 125 of the faceplate for gain access to the suspension bolt 110 and operates with this suspension bolt 110 to position the air conditioning unit 102 or perform similar actions. Therefore, it is required that the corner panel 130 can be easily mounted / removed during operation to easily and quickly carry out this work, and to practice the ease of installation / removal of the corner panels, the face panel body 120 and the corner panels 130 according to this embodiment of the present invention structurally executed in the manner described below.

On Fig presents a view of one corner region 120A of the four corner regions of the body 120 of the front panel, when viewed from the side of the room, and this drawing shows the state when the corner panel 130 and the grille 123 of the air intake are removed. On Fig presents a General view of the corner panel 130 from the side of its reverse surface. In this case, the reverse surface of the corner panel 130 is the surface of this panel facing the space under the arch of the room when the corner panel is mounted on the body 120 of the front panel. 23 and 24 are diagrams illustrating a method of mounting the corner panel 130 on the main body 120 of the front panel / removing the corner panel 130 from the main body 120 of the front panel. On Fig presents the moment before installing the corner panel 130 on the body 120 of the front panel, and on Fig presents the moment after installing the corner panel 130 on the body 120 of the front panel. In the description below, the four corner regions of the faceplate 112 are of substantially the same design, and therefore, they will be further discussed with the example of one corner region 120A. Similarly, the four corner panels 130, located at the four corners of the front panel body 120, have essentially the same design, so they will be further discussed with the example of one corner panel 130.

First, the corner region 120A of the front panel body 120 will be described in which the corner panel 130 is fixed.

As shown in FIG. 24, the front panel body 120 has a frame 180 configured as a frame surrounding the air injection ports 122, and this frame 180 has four frame elements 181. The two frame elements 181A and 181B shown in FIG. 21 create a straight line the angle between each other in the area of the corner region 120A of the front panel body 120, and the corner region 120A is a continuation of the side opening 125 of the front panel toward the arch of the room. On the side of the side opening 125 of the front panel, which faces the room, an open mounting area 131 (hereinafter referred to as the open area) is formed, which includes the corner panel 130. The open area 131 is made essentially rectangular in accordance with the shape of the corner panel 130, as a result of which the corner panel 130 enters this open area 131. On the inner end surface of the outer corner portion 132 of the open area 131, an external engagement hole 133 is formed, which is a recess facing from the center (the direction from the center is indicated by the arrow in Fig. 21, and this direction will be referred to hereinafter as the "outward direction"), out of a total of four angular parts of the open area 131. The outer engagement hole 133 is the engagement hole into which the outer foot enters 152 engagement (FIG. 22) of the corner panel 130, which will be described later.

On the inner end surface of the open region 131 in two lateral corner portions 134 adjacent to the outer corner portion 132, out of the total number of four corner portions of the open region 131, lateral engagement holes 135 are created, as shown in FIGS. 21 and 23. The lateral engagement holes 135 represent there are engagement holes, into which the engagement side tabs 154 (FIG. 22) of the corner panel 130, which will be described later, are included.

In addition, in the inner corner portion 136 located toward the center, an inner corner wall 140 is created from the total number of four corner portions of the open area 131.

As shown in FIGS. 21 and 23, the inner corner wall 140 is an element that connects the surfaces 182, 183 (FIGS. 23 and 24) of the inner walls of the two frame elements 181A and 181B, and this wall 140 comprises a bounding plate 186 and a seating portion 142.

The bounding plate 186 is a plate-shaped element by which the open area 131 and the air intake port 121 are separated from each other, and this plate extends in the direction of the room and, at the same time, tilted outward with respect to the body 120 of the front panel. In the bounding plate 186, a lateral engagement hole 141 is created on the surface of the inner corner wall by removing part of the material of this bounding plate 186, as shown in FIG. This lateral meshing hole 141 on the surface of the inner corner wall is a meshing hole that includes a protrusion 159 created in the mounting leg 156 of the corner panel 130, which is described later. In this case, the bounding plate 186 is tilted outward, since the protrusion 159 (FIG. 22) of the fixing leg 156 of the corner panel 130 is moved toward the side engagement hole 141 on the surface of the inner corner wall when the corner panel 130 is mounted in the open area 131, but this will be described in more detail below.

A base portion 142 is formed at the base of the inner corner wall 140 from the side of the air intake port 121. The seat portion 142 is a seat that adjoins the platform 158 (FIG. 22) of the mounting leg 156 made on the corner panel 130, which is described later, and this pad 158 is attached to the landing portion 142. The landing portion 142 has a landing protrusion 145 extending toward the air intake port 121 (toward the center). The landing protrusion 145 is provided with a threaded hole 144 into which a fixing screw 143 is screwed, for fixing the corner panel 130 to the front panel body 120.

This landing protrusion 145 is designed so that it protrudes toward the air intake port 121. Accordingly, when the air intake grill 123 is installed in the air intake port 121, the landing protrusion 145 and the fixing screw 143 screwed into the threaded hole 144 on this landing protrusion 145 are not visible from the room, thereby improving the appearance of the air conditioner.

As shown in FIG. 22, the corner panel 130 is configured to have a rectangular shape corresponding to the shape of the open area 131, and the outer peripheral wall 150 extending toward the overlapping side is designed so that it extends along two outer sides from a common the number of four sides of the corner panel 130. In the outer peripheral wall 150 of the corner panel, an external engaging foot 152 is formed that projects outward and is located in the outer corner portion of the four corner parts of the corner panel 130. The outer l the mesh gear 152 enters the external mesh hole 133 (FIG. 21) created in the open area 131.

In addition, in the outer peripheral wall 150 of the corner panel in the two lateral corner portions 153 adjacent to the outer corner portion 132, engagement side tabs 154 are formed that should fit into the engagement side holes 135 (Figs. 21 and 23) created in the open area 131. Further, in the inner corner portion 155, located on the side closer to the center, from the total number of four corner portions of the corner panel, a fixing leg 156 is arranged.

The fixing leg 156 is made of elastic material and has an upright portion 157 extending toward the overlap and a pad 158 that is configured to deviate from the end portion of the upright portion 157 toward the center, as shown in FIG. 22.

The upright portion 157 is provided with a protrusion 159 extending outward, as shown in FIG. This protrusion 159 enters the lateral engagement hole 141 on the surface of the inner corner wall 140 described above, and an inclined portion 160 is created on the outer surface of this protrusion 159, which is inclined toward the center. This inclined portion 160 guides the protrusion 159 into the lateral engagement hole 141 on the surface of the inner corner wall 140 when the corner panel 130 is installed in the open area 131.

In addition, the pad 158 is brought into contact with the landing portion 142 described above and secured to this portion 142, and a through hole 161 is formed on this pad 158, oriented in the direction from the ceiling to the room. This through hole 161 is a hole through which the fixing screw 143 passes. When the corner panel 130 and the front panel body 120 are connected to each other, as shown in FIGS. 23 and 24, a special fixing screw 143 is installed in the through hole 161 by screwing it into the threaded hole 144, which allows you to attach the corner panel 130 to the body 120 of the front panel through a threaded connection.

At site 158, the length L1 (see FIG. 22) of the portion extending inwardly (toward the center) from the edge of the through hole 161 exceeds the length L2 (FIG. 21) of the portion extending inwardly (toward the center) from the edge of the threaded hole 144 in the landing portion 142, and when installing the corner panel 130 in the open area 131, the end portion of the pad 158 extends inward (toward the center) further than the landing portion 142, and a worker or other person can take on this elongated portion. Accordingly, when removing the corner panel 130 from the open area 131, the worker or other person grabs this area 158 and, with the help of this area 158, moves the corner panel 130, as a result of which the corner panel 130 is released from the open area 131.

The installation of the corner panel 130 on the body 120 of the front panel is as follows.

Namely, the corner panel 130 is temporarily attached in the open area 131 of the front panel body 120 without using a fixing screw 143 when the air intake grill 123 is removed from the front panel body 120, and then the corner panel 130 is finally fixed to the front panel body 120 by means of a fixing screws 143. Thereafter, an air intake grill 123 is attached to the front panel body 120.

More specifically, as shown in FIG. 23, the outer engagement foot 152 on the corner panel 130 is hooked into the outer engagement hole 133 in the open region 131, and the inner corner portion 136 of the corner panel 130 is moved with force toward the overlap side when the outer tab 152 meshing has entered the outer meshing hole 133.

When the corner panel 130 is moved with force toward the overlap, the engagement side tabs 154 on the corner panel 130 enter inside the open area 131 and then snap into the engagement side holes 135 elastically. At the same time, the upright portion 157 of the mounting leg 156 on the corner panel 130 and the protrusion 159 are guided by tilting the inner corner wall 140 and move along this wall 140 from the side of the air intake port 121. In this case, the inclined portion 160 of the protrusion 159 directs this protrusion 159 in such a way that the protrusion 159 slides toward the overlap while being in contact with the inner corner wall 140. At the same time, the upright portion 157 is elastically deformed in accordance with the inclination of the inclined portion 160 protrusion 159. Upon subsequent pressing of the corner panel 130, the inclined portion 160 guides the protrusion 159, and this protrusion enters the lateral engagement hole 141 on the surface of the inner corner wall 140, resulting in the protrusion 159 Hugo is fixed in this hole 141, and the temporarily fixing operation ends.

After temporary fastening, the fixing screw 143 is installed through the through hole 161 created in the platform 158 of the mounting leg 156, and screwed into the threaded hole 144 created in the seating protrusion 145 of the landing portion 142, thereby performing a final fixation. After final fixation, the air intake grill 123 is mounted on the air intake port 121. At the same time, the landing protrusion 145 is made so that it protrudes toward the air intake port 121, as described above, therefore, the fixing screw 143 is not visible after the air intake grille 123 is installed, as shown in FIGS. 18 and 19 .

As described above, according to this embodiment of the present invention, the temporary attachment of the corner panel 130 can be accomplished by easily and easily engaging the outer engagement tab 152 created on the corner panel 130, like a hook in the outer engagement hole 133 created in the front panel body 120, and subsequent movement with the effort of the corner panel towards the overlap. Thus, the work can be done easily and quickly. In addition, during the temporary fastening period, the corner panel 130 is installed in the open area 131 by means of the external engaging foot 152, the lateral engaging legs 154 and the protrusion 159 of the mounting leg 156, which are created in the four corner parts of the corner panel 130, so that the state of the temporary mounting of the corner panels. Therefore, it is possible to prevent the corner panel 130 from falling after the temporary fastening operation, and thereby increase safety.

Next, the operation of removing the corner panel 130 from the body 120 of the front panel will be described.

When removing the corner panel 130, as shown in FIG. 24, the air intake grill 123 is first removed from the front panel body 120, the fixing screw 143 screwed into the seating portion 142 is opened, and then this fixing screw 143 is unscrewed. Moreover, even when the fixing screw 143 is removed (in a temporary fixing state), the corner panel 130 does not fall, as described above, and therefore, a worker or another person can perform the work of loosening the fixing screw 143 using both hands. As a result, you can increase efficiency and speed, as well as increase safety.

After unscrewing the fixing screw 143, they take hold of the platform 158 of the mounting leg 156, the platform 158 is moved toward the center (in the direction indicated by the arrow Y1 in FIG. 24) to deform the upright portion 157 of the mounting leg 156 in an elastic fashion, the protrusion 159 of the upright portion 157 is pulled from the side engagement holes 141 on the surface of the inner corner wall 140 to disengage the protrusion 159 with said hole 141, and then the pad 158 is forced downward toward the room, resulting in the inner corner portion 136 Glowe panel 130 is moved to the side of the room. Simultaneously with the movement of the corner panel 130 towards the room, the meshing tabs 154 on the corner panel 130 disengage in the lateral meshing holes 135 in the open area 131, and also the outer meshing tab 152 on the cornering gears out of meshing in the outer meshing hole 133 in the open region 131. panels 130. Thus, all four corner parts of the corner panel 130 are disengaged, and the corner panel 130 is removed from the body 120 of the front panel.

As described above, according to this embodiment of the present invention, the corner panel 130 can be removed from the body 120 of the front panel simply by holding onto the pad 158 of the mounting leg 156 on the corner panel 130 and elastically deforming the pad 158 to move the corner panel 130 toward the room, and work can be done quickly and easily. Furthermore, during the removal operation, even when the fixing screw 143 is removed, the corner panel 130 is prevented from falling and, as a result, safety can be improved.

In addition, according to this embodiment of the present invention, the corner panel 130 is removed from the body 120 of the front panel, moving the corner panel 130 in the direction of the room by a pulling movement. In this case, for example, in the case of applying the removal scheme of the corner panel 130 by shifting the corner panel 130 outward, taking into account the adjacent arrangement of the air conditioner 102 and the lighting unit 106, as shown in FIG. 18, the lighting unit 106 is located in the area where the corner panel 130, and therefore, this block 106 prevents the angular panel 130 from shifting, making removal difficult. However, in this embodiment of the present invention, the corner panel 130 is removed by moving it toward the room, and therefore, for example, even when the air conditioner 102 and the lighting unit 106 are adjacent, as shown in FIG. 18, such a situation does not occur that the unit 106 lighting prevents the removal of the corner panel 130, and there is no difficulty in removing this panel.

As described above, according to this embodiment of the present invention, when the corner panel 130 is attached to the front panel body 120, this can be easily and quickly done by engaging the external engaging tab 152 of the corner panel 130 in the external engaging hole 133 in the front panel body 120 and then moving it with the effort of the corner panel 130 in the direction of overlap. Moreover, when the corner panel 130 is removed from the body 120 of the front panel, this can be quickly done by holding the pad 158 of the mounting leg 156 of the corner panel 130, shifting the pad 158 toward the center to elastically deform the upright portion 157 of the mounting leg 156 by pulling the protrusion 159 of the upright portion 157 from the lateral meshing hole 141 on the surface of the inner corner wall to disengage them, and then moving the corner panel 130 toward the room via the pad 158. As described above, according to This embodiment of the present invention, it is possible to reduce the cost and simplify the design of the device without using any special elements such as a permanent magnet, plate, etc., while maintaining ease of installation / removal of the corner panel 130.

In addition, according to this embodiment of the present invention, at the end portion of the mounting leg 156, a platform 158 is created that extends over the landing portion 142, which makes it easy and reliable to hold onto this platform 158, as a result of which the work can be performed easily and efficiently.

Any modifications and changes may be made to the described embodiment of the present invention without departing from the spirit and scope of this invention. For example, the air conditioner 102 is installed in a suspended ceiling with a cellular structure, however, the present invention can be applied to a built-in air conditioner when the air conditioner is mounted in an opening made in the ceiling. An air conditioner 102 according to this embodiment of the present invention is a cassette type air conditioner with four-way air supply and horizontal dimensions of 600 mm × 600 mm, however, the present invention is not limited to this type of air conditioner. For example, the present invention can be applied to an air conditioner with dimensions in the horizontal plane of 640 mm × 640 mm, or for an air conditioner with two-way air supply.

Claims (18)

1. The indoor unit is a ceiling-type air conditioner, comprising a box-shaped body having an upper plate, side plates and an open area made in the lower part of the body, a front panel mounted to be removable in the open area of the body, an indoor unit heat exchanger, due to which the casing inside is divided into the main space and the additional space, and the air blower attached to the upper plate of the casing on the side of this plate that faces the main space, supplement no containing:
thermal insulation material of the main space, placed on the upper plate so that its surface faces the main space of the body; and
heat-insulating material of the additional space placed on the side plates in such a way that its surface faces the additional space of the body, and the heat-insulating material of the main space is provided with an open area that allows the air blower to be attached to the upper plate. 2. The indoor unit of the ceiling type air conditioner according to claim 1, in which the heat-insulating material of the main space and the heat-insulating material of the additional space are made as a whole. 3. The indoor unit of the ceiling type air conditioner according to claim 1, in which the inner surface of the heat-insulating material of the main space, which faces the air blower, is made flat. 4. The indoor unit of the ceiling-type air conditioner according to claim 1, wherein a cut-out is made on the inner surface of the heat-insulating material of the main space, and said inner surface is provided with a wire clip for fixing wires in the cut-out and attaching the heat-insulating material of the main space to top plate of the housing. 5. An indoor unit of a ceiling-type air conditioner, comprising a box-shaped body having an upper plate, side plates and an open area made in the lower part of the body, a front panel mounted to be removable in the open area of the body, an indoor unit heat exchanger, due to which said casing inside is divided into the main space and the additional space, and an air blower attached to the upper plate of the casing on the side of this plate that faces the main space optionally containing:
an air injection port made of an elongated shape and extending along the side of the front panel;
a damper that extends in the longitudinal direction of the air discharge port and has swing shafts at both ends; and
a seat having a mounting hole in which each of the swing shafts is mounted with a swing, and a stepper motor designed to actuate the swing shaft of the damper, each of the swing shafts of the damper having a protrusion protruding from the outer peripheral surface of the swing shaft, and a wall the mounting hole made in the seat is provided with at least one cutout engagement, which is in contact with said protrusion to regulate the swing range of the valve. 6. The indoor unit of the ceiling type air conditioner according to claim 5, wherein the wall of the mounting hole of the seat is provided with two engagement cutouts that are mutually symmetrical. 7. The indoor unit of the ceiling type air conditioner according to claim 5, wherein the mounting hole is cylindrical. 8. A ceiling-type air conditioner comprising a box-shaped case having an upper plate, side plates and an open area made in the lower part of this case, a front panel mounted to be removable in an open area of the case, an indoor unit heat exchanger, due to which the case is inside divided into the main space and the additional space, an air blower attached to the upper plate of the housing on the side of this plate that faces the main space, and brackets for hanging which are made on the side plates of the housing and through which the suspension bolts are lowered from the floor beams to suspend the housing to the ceiling, in which each of the suspension brackets comprises a first part passing in the housing, a second part passing through an opening made in the housing outwardly of the housing substantially parallel to the upper plate, and a third portion that is hooked to the lower end of the side plate of the housing to support the said lower end of the side plate of the housing and which The second one is provided with a temporary fastening area intended for temporary fastening of the front panel to the housing. 9. The ceiling type air conditioner of claim 8, wherein said third part is provided with a final fixation area for final fixation of the temporarily fixed panel on the housing. 10. The ceiling type air conditioner of claim 8, wherein the temporary mount area is created by bending upwardly the end portion of the third part. 11. The ceiling-mounted air conditioner of claim 8, wherein the front panel is provided with open areas at its four corners, which correspond to hanging brackets, these open areas of the front panel being covered by corner panels, and each of a pair of open areas located opposite each other diagonals from the number of open areas of the front panel, equipped with a hook-shaped element, which is hooked to the area of temporary fastening. 12. A ceiling type air conditioner comprising a box-shaped case having an upper plate, side plates and an open area made in the lower part of this case, a front panel mounted to be removable in the open area of the case, an indoor unit heat exchanger, due to which the case is inside divided into the main space and the additional space, an air blower attached to the upper plate of the housing on the side of this plate, which faces the main space, and the corner panel is installed with the possibility of removing in each of the four angular regions of the body of the front panel, in which the angular panel is equipped with a meshing foot made with the possibility of engagement in the meshing hole created in each of the four angular regions of the body of the front panel, and a fixing leg, which is created in one corner the area of the corner panel so that it extends to the landing part made on the inner corner wall of the front panel body and is fixed in this landing part when installing the corner panel on the front panel body . 13. The ceiling type air conditioner according to claim 12, wherein the mounting leg is made of elastic material and provided with a protrusion configured to engage in a meshing hole created on the inner corner wall. 14. The ceiling-mounted air conditioner according to claim 12, wherein a platform extends over the landing portion at the end portion of the mounting leg when the corner panel is mounted on the body of the front panel.
Priority on points: July 25, 2007 according to claims 1-4; July 25, 2007 according to claims 5-7; August 6, 2007 according to claims 8-11; 08/06/2007 according to claims 12-14.

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