RU2560346C1 - Household air conditioner - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: casing (11) has suction openings (21) of the upper surface and (22) of the lower surface. Fan (15) of the inner installation generates an air flow which is sucked from each of the suction openings (21, 22). The chamber heat exchanger (13) has a shape which is the shape of an inverted V with the heat exchanging parts (13a, 13b) of the front side and (13c) the rear side, and a part (50) for resistance to suction blocks the air flow which is sucked from the suction opening (21) of the upper surface. In particular, the fan (15) of the inner installation generates the air flow which is sucked from each of the suction openings (21, 22) and extends into the heat exchanging part (13c) of the rear side. A part (50) for resistance to suction is located in the suction opening (21) of the upper surface, which faces the heat exchanging part (13c) of the rear side. At that the part (50) for resistance to suction is formed by a part of the casing (11).

EFFECT: eliminating an event when the suction opening of the lower surface is not functioning, which occurs depending on various circumstances, due to ambient conditions.

6 cl, 8 dwg

Description

FIELD OF THE INVENTION

The present invention relates to an air conditioner and, in particular, relates to a wall type air conditioner.

BACKGROUND OF THE INVENTION

There is a separate type of air conditioner, which is formed using an outdoor unit that is installed outside, and an indoor unit that is installed indoors. In particular, with regard to the indoor unit, there is a wall type unit that is fixed to the inner surface of the wall or the like.

Indoor units of a wall type are known, as shown, for example, in PTL 1 (Publication No. 2001-311530 of Japanese Unexamined Patent Application). The indoor unit in accordance with PTL 1 has a suction hole in the upper surface and has a suction hole in the lower surface and a ventilation hole in the lower surface. Thanks to the indoor unit, air is discharged into the room through the ventilation hole after the intake of room air from both suction openings and heat exchange with the heat exchanger.

A brief description of the present invention

Technical problem

However, the external conditions of the locations in which the indoor units are installed differ depending on each location. Because of this, in the indoor unit, in which there are suction openings not only on the upper surface, but also on the lower surface, as shown in PTL 1, there are cases in which a phenomenon occurs when air is mainly absorbed from the suction opening of the upper surface , and air is almost not absorbed from the suction hole of the bottom surface, depending on the external conditions in which the indoor unit is installed. In particular, the wall-mounted indoor unit is installed indoors in a position that is relatively close to the ceiling, and the gap between the upper surface of the indoor unit and the ceiling is often narrow. As a result, there is a change in the performance of the indoor unit compared to the case when the performance is evaluated in a position in which the gap between the upper surface of the indoor unit and the ceiling is large.

Therefore, the aim of the present invention is to eliminate the phenomenon when the suction hole of the lower surface does not function, which occurs depending on various circumstances due to the difference in external conditions.

Solution

An air conditioner in accordance with a first aspect of the present invention is a wall type air conditioner and comprises a casing, a fan, a heat exchanger and a suction resistance portion. The casing has a suction hole in the upper surface and a suction hole in the lower surface. The suction hole of the upper surface is formed from the front side to the rear side of the upper surface. A suction hole of the lower surface is formed on the lower surface. The fan is located inside the casing and generates a stream of air that is sucked from the suction hole of the upper surface and the suction hole of the lower surface. The heat exchanger is formed inside the casing by connecting the heat exchange parts of the front side and the heat exchange part of the rear side in a shape similar to an inverted V in the form of a side surface. The heat exchange parts of the front side cover the front side of the fan, and the heat exchange part of the rear side covers the back side of the fan. The suction resistance portion blocks the flow of air that is sucked from the suction port of the upper surface. In addition, in the suction resistance portion, the suction resistance in the suction port portion of the upper surface that faces the heat exchange portion of the rear side is greater than the suction resistance in the suction port portion of the upper surface that faces the heat transfer portions of the front side. In this case, the fan generates a stream of air that is sucked from the suction hole of the upper surface and the suction hole of the lower surface and passes into the heat exchange part of the rear side. The suction resistance portion is located in the suction hole of the upper surface, which faces the heat exchange portion of the rear side.

Thanks to the air conditioner, the amount of room air that is sucked in from the suction opening of the upper surface is reduced due to the suction resistance portion. As a result, the degree of increase in room air that is sucked in from the suction opening of the upper surface is reduced to some extent due to the part for suction resistance even when the air conditioner is installed in such external conditions that there is an increase in room air that is drawn in from the suction hole of the upper surface. Accordingly, it is possible to reduce the degree of change in the relationship between the amount of room air that is sucked from the suction port of the upper surface and the amount of room air that is sucked from the suction port of the lower surface, and it is possible to eliminate the phenomenon when the suction port of the bottom surface does not function, which occurs depending from different circumstances due to differences in external conditions.

An air conditioner in accordance with a second aspect of the present invention is an air conditioner in accordance with a first aspect of the present invention, wherein a suction resistance portion is located on a rear side portion of a suction opening of an upper surface that faces a heat exchange portion of a rear side.

Due to this, the amount of room air that is sucked from the rear side of the suction hole of the upper surface is reduced. As a result, it is possible to further reduce the degree of change in the relationship between the amount of room air that is sucked from the suction port of the upper surface and the amount of room air that is sucked from the suction port of the bottom surface.

An air conditioner in accordance with a third aspect of the present invention is an air conditioner in accordance with a first aspect or a second aspect of the present invention, in which a suction resistance portion is formed by a portion of the casing.

Therefore, it is possible to form a part for suction resistance in a simple way, and the costs can be limited compared to the case when the part for suction resistance is formed by another element.

An air conditioner in accordance with a fourth aspect of the present invention is an air conditioner in accordance with a first aspect or a second aspect of the present invention, in which a suction resistance portion is formed by another element in a casing and mounted in a suction port of an upper surface.

Therefore, it is possible to form a part for suction resistance in a simple manner.

An air conditioner in accordance with a fifth aspect of the present invention is an air conditioner in accordance with any of the first aspect to a fourth aspect of the present invention, wherein the suction resistance portion is configured to extend along the entire length of the suction opening of the upper surface in the longitudinal direction.

Due to this, it is possible that the part for suction resistance overlaps along the entire length of the suction hole of the upper surface in the longitudinal direction.

An air conditioner in accordance with a sixth aspect of the present invention is an air conditioner in accordance with any of the first aspect to the fifth aspect of the present invention, wherein the suction resistance portion covers about 30% or more of a portion of the rear side of the suction opening of the upper surface.

Because of this, it is possible to reduce the degree of change in the relationship between the amount of room air that is sucked from the suction port of the upper surface and the amount of room air that is sucked from the suction port of the lower surface, and that the suction port of the bottom surface functions reliably.

An air conditioner in accordance with a seventh aspect of the present invention is an air conditioner in accordance with a sixth aspect of the present invention, wherein the suction resistance portion covers about 50% or more of a portion of a rear side of a suction opening of the upper surface.

Because of this, it is possible to further reduce the degree of change in the relationship between the amount of room air that is sucked from the suction port of the upper surface and the amount of room air that is sucked from the suction port of the bottom surface.

An air conditioner in accordance with an eighth aspect of the present invention is an air conditioner in accordance with any of the first aspect to the seventh aspect of the present invention, wherein the air velocity that is sucked from the suction port of the lower surface is about 0.5 m / s or more.

Here, the suction resistance portion blocks room air that is sucked from at least a portion of the suction port of the upper surface that faces the heat exchange portion of the rear side to such an extent that the speed of the air that is sucked from the suction port of the bottom surface is approximately 0 5 m / s or more. Because of this, it is possible to reliably reduce the degree of change in the relationship between the amount of room air that is sucked in from the suction port of the upper surface and the amount of room air that is sucked in from the suction port of the bottom surface, which depends on the external conditions in which the air conditioner is installed.

Favorable Results of the Invention

Thanks to the air conditioner according to the first aspect of the present invention, it is possible to reduce the degree of change in the relationship between the amount of room air that is sucked from the suction port of the upper surface and the amount of room air that is sucked from the suction port of the lower surface, and the phenomenon where the suction port of the bottom surface can be eliminated does not function, which arises depending on different circumstances due to differences in external conditions.

Thanks to the air conditioner in accordance with the second aspect of the present invention, it is possible to further reduce the degree of change in the relationship between the amount of room air that is sucked from the suction port of the upper surface and the amount of room air that is sucked from the suction port of the bottom surface.

Thanks to the air conditioner in accordance with the third aspect of the present invention, it is possible to form a suction resistance portion in a simple manner, and the costs can be limited compared to the case when the suction resistance portion is formed by another element.

Thanks to the air conditioner in accordance with the fourth aspect of the present invention, it is possible to form a part for suction resistance in a simple manner.

Thanks to the air conditioner in accordance with the fifth aspect of the present invention, it is possible for the suction resistance portion to overlap along the entire length of the suction opening of the upper surface in the longitudinal direction.

Thanks to the air conditioner in accordance with the sixth aspect of the present invention, it is possible to reduce the degree of change in the relationship between the amount of room air that is sucked in from the suction port of the upper surface and the amount of room air that is sucked from the suction port of the lower surface, and that the suction port of the bottom surface functions reliably.

Thanks to the air conditioner in accordance with the seventh aspect of the present invention, it is possible to further reduce the degree of change in the ratio between the amount of room air that is sucked from the suction port of the upper surface and the amount of room air that is sucked from the suction port of the bottom surface.

Thanks to the air conditioner in accordance with the eighth aspect of the present invention, it is possible to reliably reduce the degree of change in the relationship between the amount of room air that is sucked from the suction port of the upper surface and the amount of room air that is sucked from the suction port of the bottom surface, which depends on the environmental conditions in which it is installed air conditioning.

Brief Description of the Drawings

FIG. 1 is a schematic view of the appearance of an air conditioner in accordance with an embodiment;

FIG. 2 is a sectional view of an air conditioner according to an embodiment taken along line II-II of FIG. one;

FIG. 3 is a general view of the inside of the casing on which the support member is fixed in the casing according to an embodiment, and a schematic view in which the casing, the lower frame and the internal fan are removed from the air conditioner;

FIG. 4 is a general view of a cleaning device;

FIG. 5 is a schematic view in which the vicinity of the cleaning device of FIG. 2 increased;

FIG. 6 is a schematic view in which the filter is removed from the support member in FIG. 3;

FIG. 7 is an enlarged schematic view of a neighborhood of a plate of the upper surface in accordance with FIG. 2 and a schematic view in which the support element and the filter are removed from FIG. 2;

FIG. 8 is a schematic view of a neighborhood of the upper surface of an air conditioner, in which an air conditioner according to an embodiment is shown from above.

Description of Embodiments

An air conditioner in accordance with the present invention will be described in detail below with reference to the drawings. Here, the following embodiment is a detailed example of the present embodiment and does not limit the technical scope of the present invention.

(1) Configuration

FIG. 1 is a schematic view of the appearance of an air conditioner 100 in accordance with an embodiment of the present invention. The air conditioner 100 is mounted on an inner surface of a wall or the like, and is connected to an outdoor unit (which is not shown in the drawing) that is mounted on the outside through a refrigerant pipe (which is not shown in the drawing). It is possible that the air conditioner 100 also carries out a cleaning process, during which the filter 25 and the brush 33 (FIG. 2) are automatically cleaned in addition to the cooling process of the interior and the heating process of the interior.

The air conditioner 100 mainly comprises a casing 11, a chamber heat exchanger 13, an indoor fan 15, a lower frame 17, a filter 25, a cleaning device 30, a support member 40, and a suction resistance portion, as shown in FIG. 1-5.

Herein, in the following description, references are used appropriately that indicate directions, such as “up”, “down”, “left”, “right”, “front surface” and “rear surface”, but the links indicate each of the directions in the position wherein the air conditioner 100 is mounted on an inner surface of a wall or the like in the position of FIG. one.

(1-1) Casing

The casing 11 has a box shape that is long and narrow in the horizontal direction (direction W in FIG. 1), as shown in FIG. 1. In detail, the casing 11 forms three-dimensional space with the upper surface plate 11a, the front surface plate 11b, and the rear surface plate 11c, as shown in FIG. 1 and 2, and a chamber heat exchanger 13, an indoor fan 15, a lower frame 17, a cleaning device 30, a support member 40 and a suction resistance portion 50 are located in this three-dimensional space. The upper surface plate 11a mainly forms the upper surface of the casing 11, and the front surface plate 11b mainly forms the front surface of the casing 11. Here, the upper end of the front surface plate 11b is supported for free rotation by a portion of the upper surface plate 11a and can interact with the hinge system. The back surface plate 11c mainly forms the rear surface of the casing 11. The air conditioner 100 is mounted on the inner surface of the wall using the back surface plate 11c mounted on the mounting plate (which is not shown in the drawing), which is mounted on the inner surface of the wall using a screw mount or like that.

In addition, a suction hole 21 of the upper surface is formed in the plate 11a of the upper surface of the casing 11 from the front side to the rear side of the upper surface plate 11a. From the suction hole 21 of the upper surface, indoor air in the vicinity of the suction hole 21 of the upper surface is captured into the inner part of the casing 11 by driving the indoor fan 15 and is sent to the front-side heat exchange parts 13a and 13b (which will be described later) and the heat exchange part 13c the back side (which will be described later) of the chamber heat exchanger 13. Here, arrow A, which is a dashed line in FIG. 2, denotes a flow of room air that is directed to the indoor fan 15 through the suction port 21 of the upper surface and the front-side heat exchange portion 13b as an example.

In addition, the lower surface of the casing 11 is mainly formed by the lower part 17a (which will be described below) of the lower frame 17, and a suction hole 22 of the lower surface and a ventilation hole 23 are formed on the lower surface of the casing 11. The suction hole 22 of the lower surface is located closer to the side of the wall than the ventilation hole 23, and is connected to the inner part of the casing 11 using the suction channel 16 of the stream. From the intake hole 22 of the lower surface, indoor air in the vicinity of the intake hole 22 of the lower surface is captured into the interior of the casing 11 by driving the indoor fan 15 and is sent to the rear side heat exchange section 13c (which will be described later) of the chamber heat exchanger 13 through the intake channel 16 threads. Arrow B, which is a dashed line in FIG. 2, denotes a flow of room air that is directed from the suction port 22 of the lower surface to the rear side heat exchange section 13c as an example. The ventilation hole 23 is located closer to the side of the front surface of the air conditioner 100 than the suction hole 22 of the lower surface, and is connected to the inner part of the casing 11 through the ventilation duct 18 of the stream. From the ventilation hole 23, room air is discharged into the room through the flow ventilation channel 18 after being sucked from each of the suction holes 21 and 22 and subjected to heat exchange with the chamber heat exchanger 13. Arrow C, which is a dashed line in FIG. 2, indicates the flow of room air, which is directed from the ventilation duct 18 to the room through the ventilation hole 23.

The suction flow channel 16 is formed from the lower surface suction hole 22 along the flow channel forming part 17b (which will be described below) of the lower frame 17. The flow ventilation channel 18 is formed from the ventilation hole 23 along the flow channel forming part 17b, the lower frame 17. That is, the suction flow channel 16 and the flow ventilation channel 18 are arranged so as to be adjacent to each other to accommodate between them the flow channel forming portion 17 b of the lower frame 17.

Here, the horizontal casement 23a is fixed in the vicinity of the ventilation hole 23 for free rotation relative to the casing 11. The horizontal casement 23a can be driven by an electric motor for the casement (which is not shown in the drawing) and opens and closes the ventilation hole 23 in accordance with the operating condition of the air conditioner 100. In addition in addition, the horizontal flap 23a performs the function of changing the direction of the release of room air to direct the room air that is discharged from the ventilation opening Stia 23 in a direction which is specified by the user.

(1-2) Chamber heat exchanger

The chamber heat exchanger 13 is formed by a plurality of fins and a plurality of heat transfer tubes. The chamber heat exchanger 13 is mounted on a portion of the lower frame 17 in the inner part of the casing 11. The chamber heat exchanger 13 carries out heat exchange between the refrigerant and the air that passes through the chamber heat exchanger 13 by operating as an evaporator or condenser in accordance with the operating condition of the air conditioner 100.

In particular, the chamber heat exchanger 13 in accordance with the present embodiment has a shape that is essentially an inverted V shape in the form of a side surface on which both ends are bent downward, as shown in FIG. 2, and the indoor fan 15 is located under the chamber heat exchanger 13. In the present embodiment, outside the chamber heat exchanger 13, which has this shape, the heat exchange parts that cover the front side of the indoor fan 15 are called “front side heat exchange parts 13a and 13b,” and a heat exchange part that covers the rear side of the indoor fan 15 is called a “rear side heat exchange part 13c” for convenience in the following description. That is, the chamber heat exchanger 13 in accordance with the present embodiment has a shape that is essentially an inverted V shape, where the front side heat exchange parts 13a and 13b and the rear side heat exchange part 13c are connected in the uppermost portion 13d.

Here in FIG. 2 shows a case by way of example in which the front-side heat exchanging portions 13a and 13b have a shape that is re-bent on the front side of the indoor fan 15. That is, the front-side heat exchange parts 13a and 13b are divided into a section that is located downward in the up and down directions (i.e., the front side heat-exchange section 13a) and a section that is located upward in the up and down directions (i.e., the heat-exchange part 13b front side). However, it is sufficient if the front-side heat exchange parts 13a and 13b are arranged to close the front side of the indoor fan 15 and do not require a configuration that is divided up and down, as shown in FIG. 2.

(1-3) Indoor fan

An indoor fan 15 is located in the interior of the casing 11 and is an automatically controlled fan with a substantially cylindrical shape that is long and narrow in the W direction shown in FIG. 1. By driving the indoor fan 15 generates a flow of room air (see arrows A, B and C, which are dashed lines in Fig. 2), which is supplied from the ventilation hole 23 into the room through the chamber heat exchanger 13 after passing into the chamber a heat exchanger 13 (in detail, front side heat exchange parts 13a and 13b and a rear side heat exchange part 13c) as a result of suction from each of the suction opening 21 of the upper surface and the suction opening 22 of the lower surface.

The drive shaft of the indoor fan 15 is connected to the output shaft of the indoor fan motor (which is not shown in the drawing). The indoor fan 15 can be driven by transmitting the output power of the indoor fan fan motor to the drive shaft of the indoor fan 15 via the output shaft when the indoor fan motor is driven.

(1-4) Lower frame

The lower frame 17 is made using the lower part 17a and part 17b forming the flow channel.

The lower part 17a is an element that forms at least a portion of the lower surface of the casing 11 and from the lower frame 17 is open to the outside of the air conditioner 100. As a result, the user can visually see the lower part 17a in the form of the lower surface of the air conditioner 100.

The flow channel forming part 17b is an element that is located inside the casing 11 and extends from the lower frame 17. The flow channel forming part 17b has a shape that extends upward from the end of the lower part 17a and is bent in the shape of the indoor fan 15.

(1-5) Filter

The filter 25 is mainly located between the plate 11a of the upper surface of the casing 11 and the chamber heat exchanger 13, that is, on the upstream side relative to the chamber heat exchanger 13 in the direction of the flow of room air, and is mounted with the possibility of removal inside the casing 11. The filter 25 closes the front side of the heat exchange parts 13a and 13b of the front side and the rear side heat exchange portion 13c. In addition, the filter 25 has a shape in which the rear end end portion 25b in the forward and backward direction of the filter 25 is located under the uppermost portion 13d of the chamber heat exchanger 13. In more detail, the filter 25 in accordance with the present embodiment essentially has a so-called an inverted U-shape in which a substantially central portion extends along the plate 11a of the upper surface of the casing 11, and the front side end portion 25a and the rear side end portion 25b in the forward and backward direction are closed from above by the cam molecular exchanger 13 by dangling below the uppermost portion 13d of the chamber 13 of the heat exchanger.

Here, in the present embodiment, the rear side end portion 25b of the filter 25 reaches a position in which substantially covers the rear side heat exchanger portion 13c, and the front side end portion 25a of the filter 25 reaches a position in which it completely covers the front side heat exchanger portion 13b and partially covers the portion of the upper portion of the heat exchange portion 13a of the front side. Due to this, the portion of the filter 25, which is facing the heat exchange portion 13c of the rear side, can remove contaminants from room air, which is mainly absorbed from the suction hole 22 of the lower surface. A portion of the filter 25, which faces the heat exchange portions 13a and 13b of the front side, can remove contaminants from room air, which is mainly absorbed from the suction port 21 of the upper surface. That is, the filter 25 can prevent surface contamination of the chamber heat exchanger 13 due to contaminants in room air.

Thus, the filter 25, for example, is a mesh that has a filament or twill weave using a thread made of polymer, formed in an annular shape (i.e., in the form of an endless belt) and passes through a support frame (which is not shown in the drawing) . Two of the filters 25 that extend along the support frame are in a line on the right side and the left side in a front view of the air conditioner 100, as shown in FIG. 3. It is impossible for the filter 25 to maintain a constant shape, since reinforcing edges or ribs, as can be seen on conventional filters, are not formed on the filter 25. As a result, the filter 25 is held in an annular shape by passing through the support frame.

(1-6) Cleaning device

The cleaning device 30 is located inside the casing 11 in the vicinity of the filter 25 or, in more detail, in the vicinity of the bending portion at the bottom of the filter 25, as shown in FIG. 5. The cleaning device 30 is not only intended for cleaning the filter 25, but also performs cleaning of the brush 33 (which will be described later), which directly cleans the filter 25, and has a frame 31, part 32 for actuating the filter, brush 33, part 34 for actuating the brushes, part 35 for cleaning the brush, part 37 for receiving contaminants and the pressure roller 38, as shown in FIG. 2-6.

The frame 31 of the cleaning device has a long and narrow shape in the longitudinal direction (direction W in FIG. 1) of the air conditioner 100, as shown in FIG. 4, and the brush 33 is removably fixed inside the frame 31 of the cleaning device. In addition, the open portion 31a is formed on the upper surface of the frame 31 of the cleaning device, as shown in FIG. 5, and in addition, the frame of the cleaning device 31 is located under the bending portion at the bottom of the filter 25. As a result, the portion of the brush 33 is open to the area above the frame 31 of the cleaning device through the open portion 31a of the frame 31 of the cleaning device and comes into direct contact with the filter through the open portion 31a.

The filter driving portion 32 causes the filter 25 to rotate and is made by means of a roller 32a, a roller motor (which is not shown in the drawing), and the like. A fabric base, which has a so-called pile weave, is glued to the peripheral surface of the roller 32a. The fabric base on the peripheral surface of the roller 32a extends into the filter screen 25 so that slipping is difficult between the roller 23a and the filter 25. The output shaft of the roller motor is connected to the rotating shaft of the roller 32a. The roller 32a rotates and the filter rotates due to the actuation of the roller motor.

The brush 33 has a long and narrow longitudinal shape of the air conditioner 100 in the same manner as the frame 31 of the cleaning device, as shown in FIG. 4, and has a shape in which a cross section that is perpendicular to the longitudinal direction is essentially a circle. The brush 33 removes contaminants from the filter 25 by bringing it into direct contact with the filter 25. The brush 33 is made using rod material 33a and a plurality of wires 33b that are located on the peripheral surface of the rod material 33a, and wires 33b have a length such that wires 33b enter in contact with the filter 25. In addition, the brush 33 is made to rotate relative to the frame 31 of the cleaning device.

The brush actuation portion 34 is designed to rotate the brush 33 and is made, for example, by means of a stepper motor. That is, the output shaft of the brush driving portion 34, which is an electric motor, is connected to the rotating shaft of the brush 33, and the brush 33 is rotated by driving a stepper motor. For example, the movement of the filter stops when the brush 33 rotates, and vice versa, the brush is in a state in which the rotation stops when the filter 25 is moved. That is, the part 32 for actuating the filter and the part 34 for actuating the brushes can alternately move the filter 25 or brush 33.

The brush cleaning portion 35 is secured to the frame 31 of the cleaning device as shown in FIG. 4. As shown in FIG. 5, the brush cleaning portion 35 is located in the direction of the rotating shaft of the brush 33, protrudes from the rear surface of the cleaning device frame 31 to the brush 33, and is inclined in a direction that is opposite to the rotation direction of the brush 33 (i.e., the direction of the arrow in the portion of the brush 33 in FIG. 5 ) Because of this, it is possible for the brush cleaning portion 35 to remove contaminants from the wires 33 b of the brush 33 when the brush 33 rotates in the direction of the arrow in FIG. 5.

Part 37 for receiving contaminants is located under the brush 33 and part 35 for cleaning the brush in the fixing position on the frame 31 of the cleaning device, as shown in FIG. 2 and 5. The contaminants that are brushed off the brush 33 by the brush cleaning part 35 are held in the part 37 for receiving the contaminants. In addition, since the particulate reception part 37 is removably mounted on the cleaning device frame 31, the user can easily remove the contaminants that are held in the particulate reception part 37 by removing the particulate reception part 37 from the cleaning apparatus frame 31 and casing 11.

The pinch roller 38 is a cylindrical rod-shaped element and is rotatably supported by the frame 31 of the cleaning device. Here, the pinch roller 38 is positioned to be in contact with the brush 33 in the vicinity of the brush cleaning portion 35, as shown in FIG. 5. As a result, the pinch roller 38 rotates in a direction opposite to the direction of rotation of the brush 33 in accordance with the rotation of the brush 33 when the brush rotates in the direction of the arrow in FIG. 5. Since the contaminants that are held in the part 37 for receiving the contaminants are pressed by the pressure roller 38, a relatively large amount of the contaminants can pass into the part 37 for receiving the contaminants. In addition, contaminants with a relatively high viscosity are reliably guided to the part 37 for receiving contaminants due to the rotation of the pressure roller 38.

(1-7) Support element

The support member 40 is located above the front side heat exchange portions 13a and 13b and the rear side heat exchange portion 13c, as shown in FIG. 2, and supports part 32 for actuating the filter and part 34 for actuating brushes, which are portions of the cleaning device 30, as shown in FIG. 3 and 6. Then, when the filter 25 is installed in the air conditioner 100, the filter 25 is inserted inside the air conditioner 100 from the front surface of the casing 11 along the support member 40, and the support element 40 guides the filter 25 towards the rear surface of the casing 11 and supports the filter 25. In addition , the support member 40 has a shape in which the rear side end portion 40b, which is the end portion on the lower side of the support member and the end portion on the rear side of the support member 40 in the forward and backward direction, is located below the highest portion 13d the chamber heat exchanger 13 and on the rear side of the highest portion 13d of the chamber heat exchanger 13.

In more detail, an essentially central portion of the support member 40 extends along the plate 11a of the upper surface of the casing 11, and the support member 40 has a shape in which the front side end portion 40a and the rear side end portion 40b in the forward and reverse direction cover the chamber heat exchanger 13 from above by hanging below the highest portion 13d of the chamber heat exchanger 13. That is, when looking only at the front side end portion 40a and the rear side end portion 40b, the support member 40 essentially has a so-called transition returned U-shape.

In addition, as shown in FIG. 3 and 6, the support member 40 has a left side portion 42 and a right side portion 43 that are arranged to insert the partition 41, where, essentially, the center of the support member 40 moves left and right towards the front and back, and as shown in FIG. 3, the filter 25, which extends along the support frame, is mounted on the upper surfaces of the left side portion 42 and the right side portion 43. When installed in the housing 11, the filter 25 is first inserted from the front surface of the housing 11 into the housing 11 in the position of FIG. 6 and slides along the upper surfaces of the left side portion 42 and the right side portion 43 of the support member 40 until the end portion 25b of the rear side of the filter 25 reaches the vicinity of the end portion 40b of the rear side of the support member 40. Because of this, the filter 25 is mounted on the upper surface of the support element 40, as shown in FIG. 3. As a result, a sliding mechanism for sliding the filter 25 is provided on the respective left and right end parts 42a, 42b, 43a and 43b of the left side portion 42 and the right side portion 43, and the end surfaces of the filter 25 that extends along the support frame are facing each other to a friend on the respective left and right end portions 42a, 42b, 43a and 43b of the left side portion 42 and the right side portion 43 in a front surface view of the support member 40, as shown in FIG. 6. In detail, the sliding mechanism is formed by a groove, a plurality of protrusions, and the like. That is, the sliding mechanism on the respective left and right end parts 42a, 42b, 43a and 43b of the left side portion 42 and the right side portion 43 is arranged to move the filter 25 on the support member 40, and this is an effective configuration not only during installation of the filter in the casing 11, but even in cases where the filter 25 moves during cleaning of the filter 35.

(1-8) Part for suction resistance

The suction resistance portion 50 blocks the flow of air that is sucked from the suction hole 21 of the upper surface, and is located in the vicinity of the suction hole 21 of the upper surface, which faces the rear side heat exchange portion 13c, as shown in FIG. 2, 7 and 8. Here, FIG. 7 is an enlarged cross-sectional view of the interior of the casing 11 in the vicinity of the upper surface plate 11a in FIG. 2, and the support member 40 and the filter 25 are removed from FIG. 2. FIG. 8 is a schematic view of a neighborhood of a top surface plate 11a when the air conditioner 100 is viewed from above.

In more detail, the suction resistance portion 50 in accordance with the present embodiment is made of an element other than the upper surface plate 11a, the front surface plate 11b, and the rear surface plate 11c that form the casing 11, and is mounted on the rear side portion 21a of the suction port 21 an upper surface that faces the rear side heat exchange section 13c. That is, the suction resistance portion 50 is another element that is located on the rear side and above the indoor fan 15 in the suction hole 21 of the upper surface. In addition, in other words, the suction resistance portion 50 is another element that is located above the rear side heat exchange portion 13c and on the rear side of the uppermost portion 13d of the chamber heat exchanger 13 in the forward and backward direction of the air conditioner 100, but is not located in the center of the suction port 21 the upper surface, and is located on the side of the back surface plate 11c. Here, the portion 21a of the rear side of the suction port 21 of the upper surface is a portion from the uppermost portion 13d of the chamber heat exchanger 13 to the plate 11c of the rear surface of the casing 11. Accordingly, as shown in FIG. 8, the rear side heat exchange portion 13c is located inside the casing 11 that faces the rear side portion 21a, and the front side heat exchange parts 13a and 13b are located inside the casing 11 that faces the front side portion 21b that extends from the uppermost chamber heat exchanger portion 13d 13 to the plate 11b of the front surface of the casing 11.

Here, the materials of the suction resistance portion 50 may be the same as the material for the casing 11 and consist, for example, of polymer. Alternatively, the suction resistance portion 50 may consist of metal or the like.

In addition, the suction resistance portion 50 is configured to cover the entire length in the longitudinal direction (i.e., in the direction W in FIG. 1) of the suction hole 21 of the upper surface in the left and right directions, and has a long and narrow shape, which is essentially is rectangular in the left and right directions in a view of the upper surface of the air conditioner 100, as shown in FIG. 8.

Here in FIG. 2, 7, and 8, in accordance with the present embodiment, a case is shown where the suction resistance portion 50 comes into contact with a plate 11c of the rear surface of the casing 11, so that there are no gaps, and extends to the front surface side of the casing 11 (i.e., the side of the plate 11b of the front surface of the casing 11) as an example. In addition, in FIG. 8 depicts a case where, by way of example, the suction resistance portion 50 comes into contact with the left side end portion 11d and the right side end portion 11e of the casing 11.

Thus, the amount of room air that is sucked from the rear side portion 21a of the upper surface of the suction hole 21 is reduced due to the suction resistance portion 50 blocking the rear side portion of the suction hole 21 of the upper surface, and room air that is sucked from the upper surface the casing 11 into the inner part of the casing 11, is sucked through the portion of the suction hole 21 of the upper surface, which is mainly not blocked (in detail, the front side portion 21b and part of the portion 21a of the rear side that is not locked). As a result, the degree of increase in room air that is sucked in from the suction hole 21 of the upper surface is reduced to some extent by the suction resistance portion 50 even when the air conditioner 100 according to the present embodiment is set in such environmental conditions that occurs an increase in room air that is sucked from the suction port 21 of the upper surface in the case where it is assumed that the suction resistance portion 50 is not provided.

Here, “environmental conditions” are conditions that are expressed in that the type of environment is the location in which the air conditioner 100 is installed. As environmental conditions, examples include, for example, that the distance between the ceiling of the room and the top the surface of the air conditioner 100 is relatively small at the installation site of the air conditioner and the like.

Here, it will be described to what extent the suction resistance portion 50 blocks the rear side portion 21a of the suction opening 21 of the upper surface. The suction resistance portion 50 in accordance with the present embodiment blocks the suction hole 21 of the upper surface to the extent that the speed of the air that is sucked from the suction hole 22 of the lower surface is about 0.5 m / s or more, regardless of the actual environmental conditions environments in which the air conditioner 100 is installed. In detail, in the case where the area of the rear surface portion 21a of the upper surface of the suction hole 21 is 100%, the resistance part 50 syvaniyu covers about 30% or more portion of the back side 21a. Furthermore, it is preferable that the suction resistance portion 50 overlap approximately 50% or more of the rear side portion 21a. In FIG. 2, 7, and 8, in accordance with the present embodiment, a case is shown where, as an example, the suction resistance portion 50 blocks approximately 60% of the rear side portion 21a.

Because of this, it is possible that the ratio between the amount of room air that is sucked from the suction hole 21 of the upper surface and the amount of room air that is sucked from the suction hole 22 of the lower surface is reliably reduced by the dependence and changes due to environmental conditions, which the air conditioner 100 is installed. Accordingly, it is possible to reduce the degree of change in the ratio between the amount of room air that is sucked from the suction port 21 on top and the amount of room air that is sucked in from the suction hole 22 of the lower surface, and it is possible to prevent the phenomenon when the suction hole 22 of the lower surface does not function, arising depending on different circumstances due to the difference in environmental conditions in which the air conditioner 100 is installed.

Here, it is possible to appropriately determine the specific numerical value to the extent that the suction resistance portion 50 blocks the portion 21a of the rear side of the suction hole 21 of the upper surface based on calculations, simulations, experiments or the like, upon further consideration of pressure loss and the like in addition to a condition in which the amount of air flow from the internal fan 15 is the smallest amount of air flow, a condition in which approximately 30% or more or about 50% or more of the rear side portion 21a is blocked, and the condition in which the velocity of the air which is sucked from the suction port 22 of the lower surface is about 0.5 m / s or more.

(1-9) Other configurations

In addition to the above, the air conditioner 100 includes an internal control part (which is not shown in the drawing) that controls various devices that form the air conditioner 100. The internal part for control is a microcomputer that is formed by a central processor and memory and is located in the front section casing 11. For example, the inner part for control is connected to the damper motor and the fan motor of the indoor unit, and controls open By removing and closing the horizontal shutter 23a and adjusting the angle of the horizontal shutter 23A, controlling the air flow from the indoor fan 15 and the like by controlling the electric motor drives.

(2) Characteristics

(2-1)

The suction hole 21 of the upper surface and the suction hole 22 of the lower surface are formed in the air conditioner 100 in accordance with the present embodiment, and the suction hole 21 of the upper surface, which faces the rear side heat exchange portion 13c, is blocked by the suction resistance portion 50. Because of this, the amount of room air that is sucked in from the suction port 21 of the upper surface is reduced by the suction resistance portion 50. As a result, the degree of increase in room air that is sucked in from the suction hole 21 of the upper surface is reduced to some extent by the suction resistance portion 50 even when the air conditioner 100 according to the present embodiment is set in such environmental conditions that occurs an increase in room air that is sucked from the suction port 21 of the upper surface, if it is assumed that the suction resistance portion 50 is not provided. Accordingly, it is possible to reduce the degree of change in the relationship between the amount of room air that is sucked from the suction opening 21 of the upper surface and the amount of room air that is sucked from the suction hole 22 of the lower surface, and it is possible to prevent the phenomenon when the suction hole 22 of the lower surface is not functioning, which arises depending on different circumstances due to differences in environmental conditions.

In addition, by reducing the degree of change in the relationship between the amount of room air that is sucked from the suction hole 21 of the upper surface and the amount of room air that is sucked from the suction hole 22 of the lower surface, the change in the amount of room air that passes into the chamber heat exchanger 13, which caused by environmental conditions, reduced. That is, it is possible that the amount of room air that passes into the chamber heat exchanger 13 is substantially constant regardless of the environmental conditions in which the air conditioner 100 is installed. Accordingly, a difference in the characteristics of the air conditioner 100 due to the installation location can be prevented.

(2-2)

In particular, the suction resistance portion 50 is located on the rear side portion 21 a of the suction opening 21 of the upper surface, which faces the rear side heat exchange portion 13 c. As a result, the amount of room air that is sucked from the suction port 21 of the upper surface is reduced. As a result, the degree of change in the relationship between the amount of room air that is sucked from the suction port 21 of the upper surface and the amount of room air that is sucked from the suction port 22 of the bottom surface can be further reduced.

(2-3)

In addition, the suction resistance portion 50 is made in a simple manner using another element in the casing 11 and reliably blocks a portion 21a of the rear side of the suction hole 21 of the upper surface in the casing 11.

(2-4)

In addition, the suction resistance portion 50 is configured to extend along the entire length of the suction hole 21 of the upper surface in the longitudinal direction. Because of this, it is possible that the suction resistance portion 50 blocks along the entire length of the suction hole 21 of the upper surface in the longitudinal direction.

(2-5)

Furthermore, by the suction resistance portion 50 overlapping approximately 30% or more of the rear side portion 21a of the upper surface suction hole 21, it is possible for the lower surface suction hole 22 to function reliably by reducing the degree of change in the ratio between the amount of room air that is sucked from the suction hole 21 of the upper surface, and the amount of room air that is sucked from the suction hole 22 of the lower surface.

(2-6)

Furthermore, by the suction resistance portion 50 overlapping approximately 50% or more of the rear side portion 21a of the upper surface of the suction hole 21, it is possible to further reduce the degree of change in the relationship between the amount of room air that is sucked from the suction hole 21 of the upper surface and the number of room air that is sucked from the suction hole 22 of the lower surface.

(2-7)

In addition, in the present embodiment, the suction resistance portion 50 blocks air that is sucked from the rear side portion 21a of the upper surface of the suction hole 21 to the extent that the air velocity that is sucked from the lower surface of the suction hole 22 is about 0.5 m / s or more. Due to this, it is possible to reliably reduce the degree of change in the relationship between the amount of room air that is sucked from the suction hole 21 of the upper surface and the amount of room air that is sucked from the suction hole 21 of the lower surface, which depends on the environmental conditions in which the air conditioner 100 is installed.

(3) Modified Examples

An embodiment of the present invention has been described below based on the drawings, but the detailed configuration is not limited to the embodiment described below, and modifications are possible in a volume that does not depart from the essence of the present invention.

(3-1) Modified Example A

In the embodiment described above, the suction resistance portion 50 is described as being formed by another element in the casing 11. However, the suction resistance portion 50 can be formed by the portion of the casing 11. In this case, the suction resistance portion 50 is formed, for example, using the plate 11a of the upper surface of the casing 11, passing to reduce the suction hole 21 of the upper surface.

Because of this, the suction resistance portion 50 can be made in a simple manner, and costs can be limited compared to the case when the suction resistance portion 50 is formed by another element.

(3-2) Modified Example B

In FIG. 2, 7 and 8 in the embodiment described above, the case is shown where the suction resistance portion 50 comes into contact with the back surface plate 11c of the casing 11, so that there are no gaps, and extends to the front surface side of the casing 11. However, part 50 for the suction resistance can block at least a portion of the rear side portion 21a of the upper surface of the suction hole 21 in a position separated from the rear surface plate 11c.

In addition, in FIG. 8, in the embodiment described above, a case is shown where the suction resistance portion 50 comes into contact with both the left side end portion 11d and the right side end portion 11e of the casing 11. However, the suction resistance portion 50 does not necessarily come into contact with the end part 11d of the left side and / or the end part 11e of the right side of the casing 11 and can be separated from the end part 11d of the left side and / or the end part 11e of the right side of the casing 11.

(3-3) Modified Example C

In addition, a suction resistance portion in accordance with the present invention is provided to block the flow of room air that is sucked from the rear side portion 21a of the suction opening 21 of the upper surface, as described above. As a result, a suction resistance portion can be provided to block at least a portion of the rear side portion 21a in a position that is separated downward from the plate 11a of the upper surface of the casing 11.

Industrial applicability

As described above, in accordance with the present invention, it is possible to reduce the degree of change in the relationship between the amount of room air that is sucked from the suction port of the upper surface and the amount of room air that is sucked from the suction port of the lower surface, and it is possible to prevent a phenomenon when the suction port of the bottom surface does not function, arising depending on different circumstances due to differences in environmental conditions. As a result, the air conditioner in accordance with the present invention is effective as an indoor unit, which is a wall type and which is installed in various environmental conditions.

List of Reference Items

100 - air conditioning

11 - casing

11a - plate of the upper surface

11b - front surface plate

11c - back surface plate

13 - chamber heat exchanger

13a, 13b - heat exchange part of the front side

13c - heat exchange part of the rear side

15 - indoor fan

17 - lower frame

21 - suction hole of the upper surface

21a is a section of the rear side of the suction hole of the upper surface

22a is a plot of the front side of the suction hole of the upper surface

22 - suction hole of the lower surface

23 - ventilation hole

25 - filter

30 - cleaning device

32 - part for actuating the filter

34 - part for driving brushes

40 - supporting element

50 - part for suction resistance

List of bibliographic references

Patent Literature

PTL 1: Japanese Patent Application Publication No. 2001-311530

Claims (6)

1. Wall-mounted air conditioner (100), comprising
a casing (11) which has a suction hole (21) of the upper surface, which is formed from the front side to the rear side of the upper surface, and a suction hole (22) of the lower surface, which is formed on the lower surface;
a fan (15), which is located inside the casing and generates a stream of air that is sucked from the suction hole of the upper surface and the suction hole of the lower surface;
a heat exchanger (13) that is formed inside the casing by connecting the front side heat exchange parts (13a, 13b) that cover the front side of the fan and the rear side heat exchange part (13c) that covers the back side of the fan, in the form of an inverted V in the form of a side surface ; and
a suction resistance portion (50) that blocks the flow of air that is sucked from the suction port (21) of the upper surface, and where the suction resistance in the suction port portion of the upper surface that faces the heat exchange portion of the rear side is greater than the suction resistance in the suction port portion the upper surface, which faces the heat exchange parts of the front side,
moreover, the fan generates a stream of air that is sucked from the suction hole of the upper surface and the suction hole of the lower surface and passes into the heat exchange part (13c) of the rear side,
the suction resistance portion (50) is located in the suction hole (21) of the upper surface, which faces the rear side heat exchange portion (13c), and
a suction resistance portion (50) is formed by a portion of the casing (11). 2. The air conditioner (100) according to claim 1, wherein the suction resistance portion (50) is located in a portion (21a) of the rear side of the suction hole (21) of the upper surface that faces the rear side heat exchange portion (13c). 3. Air conditioning (100) according to claim 1 or 2, in which the part (50) for suction resistance is configured to extend along the entire length of the suction hole (21) of the upper surface in the longitudinal direction. 4. An air conditioner (100) according to claim 1 or 2, wherein the suction resistance portion (50) covers approximately 30% or more of a portion (21a) of the rear side of the suction port (21) of the upper surface. 5. The air conditioner (100) according to claim 4, wherein the suction resistance portion (50) covers approximately 50% or more of a portion (21a) of the rear side of the suction port (21) of the upper surface. 6. Air conditioning (100) according to claim 1 or 2, in which the speed of the air that is sucked from the suction hole (22) of the lower surface is approximately 0.5 m / s or more.

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