KR101158125B1 - Indoor unit of air conditioner - Google Patents

Abstract

The present invention relates to an indoor unit of an air conditioner, and more particularly, to an indoor unit of an air conditioner, in which an air guide unit for guiding air to be flown is provided to enable efficient air flow.

The indoor unit of the air conditioner according to the present invention is provided with a main body 100 which secures an internal space while forming an external appearance, and the air sucked into the main body 100 is heat-exchanged provided in the lower half of the main body 100. A heat exchanger 200, a blower 400 provided above the heat exchanger 200 to forcibly flow the air inside the main body, and air provided above the blower 400 to flow And an air guide part 510 mounted on the lower surface of the discharge unit 500 to guide the air flowing from the lower side of the discharge unit 500 to the inside. It is done. According to the indoor unit of the air conditioner configured as described above, there is an advantage that the noise is reduced and the air conditioning efficiency is improved.

Air conditioner, indoor unit, discharge unit, bottom grill, air guide part, blower

Description

Indoor unit of air conditioner {Indoor unit of air conditioner}

1 is a perspective view showing the appearance of a conventional indoor air conditioner indoor unit.

Figure 2 is a front sectional view showing an indoor unit of a general air conditioner according to the prior art.

3 is a perspective view showing a discharge part of a conventional indoor air conditioner indoor unit.

Figure 4 is a perspective view showing a state in which the front panel of the air conditioner indoor unit employing a preferred embodiment according to the present invention is removed.

Figure 5 is an exploded perspective view showing the internal configuration of the indoor unit of the air conditioner employing a preferred embodiment according to the present invention.

Figure 6 is a partial perspective view showing the discharge portion of the indoor unit of the air conditioner employing a preferred embodiment of the present invention.

Figure 7 is a perspective view showing a discharge guide portion which is a main configuration of the indoor unit of the air conditioner employing a preferred embodiment of the present invention.

8 is a front view showing a discharge guide part which is a main part of an indoor unit of an air conditioner in which a preferred embodiment according to the present invention is employed;

Explanation of symbols on the main parts of the drawings

100. Body 100 '. Base panel

120. Front Panel 122. Front Top Panel

124. Front lower panel 126. Control part

140. Left panel 142. Left suction grill

144. Left discharge grill 146. Left filter

160. Right side panel 162. Right side suction grill

164. Right discharge grill 166. Right filter

180. Rear Panel 200. Heat Exchanger

220. Front cover 240. Indoor heat exchanger

242. Left Heat Exchanger 244. Right Heat Exchanger

260. Refrigerant piping 262. Refrigerant piping holes

264. Hole cover 266. Piping groove

280. Rear cover 400. Blower unit

420. Fan motor 422. Motor support

440. Blowing fan 460. Fan housing

500. Discharge unit 510. Air guide part

512. Bends 514. Fasteners

516. Fastening Boss 516 '. Fastening hole

520. Bottom grill 530. Sliding power means

530 '. Power Means Support 532. Sliding Motor

534. Central gear 536. Power transmission gear

538. Power transmission unit 540. Discharge frame

550. Sliding ejection part 552. Sliding part

552 '. Power Transmission Hole 554. Discharge Guide

556. Discharge floatation plate 558. Fixed piece

The present invention relates to an indoor unit of an air conditioner, and more particularly, to an indoor unit of an air conditioner, in which an air guide unit for guiding air to be flown is provided to enable efficient air flow.

Air conditioners are in increasing demand to create a more comfortable and comfortable living environment. This air conditioner is a device for maintaining the air of the space for air conditioning in the most optimal state according to the purpose, in general, the air conditioner is installed in a room or wall of the room such as a vehicle, office or home to cool the room As a cooling / heating device for heating or heating, a device constituting a series of refrigeration cycles consisting of a compressor, a condenser, an expansion valve, and an evaporator.

In particular, an air conditioner is equipped with a condenser and a compressor and is mainly installed outdoors (sometimes referred to as 'outdoor' or 'heat sink'), and an indoor unit ('indoor' or installed with an evaporator and installed mainly in the room). Also referred to as 'heat absorbing side' can be divided into a separate type of air conditioner is installed separately, and an integrated air conditioner is installed integrally with the outdoor unit and the indoor unit.

In addition to cooling and heating, an air conditioner has a variety of functions such as an air purifying function that suctions and filters contaminated air in a room and then re-supplies clean air into the room, and a dehumidification function that reinjects humid air into dry and dry air. Additional features are being added.

Hereinafter, the indoor unit of the separate type air conditioner will be described with reference to the drawings.

1 is a perspective view showing the interior of the conventional indoor air conditioner of the conventional air conditioner, Figure 2 is a front sectional view showing the indoor unit of the conventional air conditioner according to the prior art.

According to these drawings, the outer surface of the air conditioner is formed by the outer case 10, the outer case 10 is the front panel 20 to form a front appearance and the rear panel 30 to form a rear appearance, It consists of a left panel 40 to form a left side appearance, and a right panel 50 to form a right side appearance, the lower surface of the outer case 10 while forming the bottom surface of the outer case 10 The lower panel 60 is further provided.

In the lower half of the left panel 40 and the right panel 50, the left side suction grille 42 and the right side air in which the left side air of the space for air conditioning is sucked into the outer case 10 are the outer case. There is provided a right suction grille 52 which is sucked into the interior of 10.

The upper half of the left panel 40 and the right panel 50 is provided with a left side discharge port 44 and a right side discharge port 54 through which air harmonized inside the outer case 10 is discharged into a space for air conditioning. do.

An interior heat exchanger 11 is installed inside the outer case 10 to heat-exchange the air sucked into the outer case 10 through the left suction grille 42 and the right suction grille 52. The indoor heat exchanger 11 is formed of a left heat exchanger 11 'through which the air sucked through the left suction grille 42 is heat-exchanged and a right heat exchanger 11 "sucked through the right suction grille 52. The indoor heat exchanger 11 is mounted to be inclined at a predetermined angle, and is provided in a substantially "V" shape when viewed from the front.

The lower end of the indoor heat exchanger 11 is mounted on the upper surface of the drain pan part 12. The drain pan part 12 is formed in a substantially "∩" shape on the upper surface of the lower panel 60, the upper surface is formed flat, the portion where the lower end of the indoor heat exchanger 11 is recessed downward condensed water Will be collected.

In the center portion between the left heat exchanger 11 ′ and the right heat exchanger 11 ″, the refrigerant pipe 13 is elongated in the longitudinal direction to guide the flow of the refrigerant, which is a working fluid flowing from the outdoor unit, although not shown. The upper end of the refrigerant pipe 13 is provided with a pipe cover 14 to cover the front of the bent portion in which the refrigerant pipe 13 is bent, the pipe cover 14 has a substantially "∩" shape when viewed from the front Molded.

The motor housing 15 is provided above the pipe cover 14. The motor housing 15 is formed to surround a fan motor (not shown) that provides rotational power of the blower fan 16 to be described later, and is formed to protect the fan motor (not shown).

An upper side of the fan motor (not shown) is provided with a blowing fan 16 for forcibly flowing the air introduced into the outer case 10 by the rotational movement. The blowing fan 16 is axially coupled with the fan motor (not shown) to rotate in rotation by the rotational power provided from the fan motor.

Due to the rotational movement of the blower fan 16, a suction force is generated inside the outer case 10, and the air in the space for air conditioning is sucked by the left suction grille 42 and the right suction grille 52. It is sucked into the inside of the outer case (10) through.

The blower fan 16 is formed by attaching a wing having an “X” shape to the outer circumferential surface of the cylindrical body, and the blower fan 16 moves downward air by rotating. A fan housing 17 is provided at an outer side of the blower fan 16.

The fan housing 17 has an upper surface and a lower surface opened to guide the air flowing downward from the lower side by the rotational movement of the blower fan 16, and at the same time, protects the blower fan 16. Done. The fan housing 17 has a cross-sectional area of the upper and lower surfaces is formed wider than the cross-sectional area of the central portion, the upper side of the fan housing 17 is provided with a discharge portion 70 for discharging the harmonized air into the space for air conditioning.

3 is a perspective view showing a discharge part and a blowing fan of a conventional indoor air conditioner indoor unit. Looking at the discharge portion with reference to the drawings, the discharge portion 70 is formed in the shape of a rectangular parallelepiped as a whole to form an internal space.

The lower surface of the discharge portion 70 is formed in a substantially rectangular plate shape with a predetermined thickness, and the upper and lower surfaces are provided with a lower surface frame 71 formed in a lattice shape. The lower frame 71 is a passage through which air flowing upward due to the rotational movement of the blowing fan 16 flows into the discharge part 70.

The discharge frame 72 is mounted on the top surface of the bottom frame 71. The discharge frame 72 is formed in the shape of a rectangular parallelepiped having an approximately lower surface, and the center portion of the side surface except the upper surface is cut off so that pillars are formed at each corner and the upper surface is shaped to be shielded.

A discharge guide 73 for guiding the flow of air discharged in each direction is provided at a central portion of each side of the discharge frame 72 cut out to form a plurality of layers. Sliding means 74 is further provided inside the discharge frame 72 to provide sliding power so that the discharge part 70 can slide in the vertical direction.

Although not shown, the sliding means 74 is mounted to an inner central portion of the discharge frame 72 and is fixed to a central portion of the lower frame 71. Therefore, the central portion of the lower frame 71 is shielded by the sliding means 74.

According to the indoor unit of the air conditioner is configured as described above the following problems occur.

The central portion of the lower frame 71 is shielded by the sliding means 74, the lower frame 71 is discharged by the lower air flows upward due to the rotational movement of the blower fan (16) 70 is a passage flowing into the interior.

Therefore, a problem arises in that the flow is prevented by the central portion of the lower frame 71 in which air in the space for air conditioning flowing upward is shielded due to the rotational movement of the blower fan 16.

When the air flowing upward flows backward, a problem occurs in that the amount of air that is discharged to the space for air conditioning through the discharge unit 70 is reduced, and thus the amount of air discharged is reduced. As a result, the air conditioning efficiency of the entire air conditioner is reduced.

In addition, there is a problem that noise is generated as the air flowing upwards flows backward, and the user's emotional discomfort increases due to the noise.

The efficiency of the air conditioner is reduced, the user's emotional discomfort is increased, the reliability of the product is reduced, the sales volume of the product is reduced due to the decrease in reliability, which causes a problem that hinders the development of the industry.

An object of the present invention for solving the problems as described above is to provide an indoor unit of the air conditioner to prevent the back flow of air by improving the air flow path.

The indoor unit of the air conditioner according to the present invention for achieving the above object, the main body to secure the internal space while forming an external appearance, and the air is provided in the lower half of the main body is heat exchanged A heat exchanger, a blower provided above the heat exchanger to forcibly flow the air inside the main body, and air provided above the blower to be blown by the blower to inject the air introduced therein. And a discharge unit for discharging, and an air guide unit mounted to the discharge unit to guide the air blown from the blower to flow into the discharge unit.

The discharge unit includes a lower surface grill formed in a lattice shape to form a lower surface, a sliding discharge portion provided on an upper surface of the lower surface grill and sliding upward and downward, a discharge frame for guiding vertical sliding of the sliding discharge portion; It is characterized in that it comprises a sliding power means provided in the discharge frame to provide a sliding power of the discharge frame.

The air guide portion is characterized in that mounted on the lower surface of the lower grill.

The air guide portion is characterized in that the recess is rounded in the opposite direction to the flow direction of the air blown from the blower.

The upper surface of the air guide portion is characterized in that it is further provided with a fastening protrusion protruding upward to be engaged with the bottom grill.

The edge of the air guide portion is characterized in that it is further provided with a fastening piece protruding upward to be fastened with the lower grill.

According to the indoor unit of the air conditioner configured as described above, there is an advantage that the noise is reduced and the air conditioning efficiency is improved.

Hereinafter, an indoor unit of an air conditioner configured as described above will be described in detail with reference to the drawings.

Figure 4 is a perspective view showing a state in which the front panel of the air conditioner indoor unit employing a preferred embodiment of the present invention is removed. Referring to the air conditioner indoor unit with reference to Figure 4, the indoor unit of the air conditioner is provided with a main body 100 to secure the internal space while forming an external appearance.

The main body 100 is formed in the shape of a long rectangular parallelepiped to secure the internal space, the front panel (120 of FIG. 5) forming the front appearance and the left panel 140, the right side appearance to form the left side appearance It consists of a right panel 160 to form a rear panel (180 of FIG. 5) to form a rear appearance, the base panel 100 'is provided with each panel is seated while forming the bottom surface.

In the lower half of the left panel 140, a left suction grill 142, which is a passage through which air in a space for air conditioning is sucked into the main body 100, is formed in a grill shape while having a rectangular shape. In the upper half of the left panel 140, the left discharge grill 144, through which the air harmonized inside the main body 100, is discharged into a space for air conditioning, is formed in a shape of a long rectangular shape.

The inner lower half of the main body 100 is provided with a heat exchanger 200 for exchanging heat while the air of the space for air conditioning is sucked into the main body 100. At the lower end of the heat exchanger 200, a drain 300 for collecting condensed water generated by the heat exchanger 200 is mounted on an upper surface of the base panel 100 ′.

That is, the drain portion 300 is formed on the upper surface of the base panel 100 'in a substantially "대략" shape when viewed from the front, and the heat exchanger 200 is mounted on the upper surface of the drain portion 300. Is mounted.

The front cover 220 is formed on the front surface of the heat exchange part 200 to form a long rectangular plate shape and shields the front surface of the heat exchange part 200. An indoor heat exchanger 240 through which a working fluid refrigerant flows is mounted.

The refrigerant pipe 260 for guiding the flow of the refrigerant, which is a working fluid flowing inside the indoor heat exchanger 240, is formed in the longitudinal direction at the center of the front cover 220. The refrigerant pipe 260 is formed into a cylindrical pipe shape having a predetermined diameter, and passes through the front cover 220 through the refrigerant pipe hole 262 formed in the upper half of the front cover 220 to exchange the indoor heat. It is fastened with the machine 240.

An air blowing unit 400 is provided on an upper side of the front cover 220. The blower 400 generates a suction force inside the main body 100 to suck air in a space for air conditioning into the main body 100 to force flow from below to upward, such a blower 400 The upper side of the) is provided with a discharge unit 500 for discharging the air flowing upward through the blower 400 to the outside of the main body 100, that is, the space for air conditioning.

Looking at the internal configuration of the air conditioner indoor unit according to the present invention configured as described above in detail with reference to Figure 5, Figure 5 is an exploded perspective view showing the internal configuration of an air conditioner indoor unit employing a preferred embodiment of the present invention Is shown.

According to the drawing, the front panel 120 forming the front appearance of the main body 100 is formed of a front upper panel 122 and a front lower panel 124. The front upper panel 122 forms a front exterior of the upper half of the main body 100, and the front lower panel 124 forms a front exterior of the lower half of the main body 100. The central portion of the front upper panel 122 is further provided with a control unit 126 for displaying the state of the space for air conditioning or the operating state of the air conditioner.

The rear of the upper front panel 122 is mounted with a control unit 128 for controlling the operation of the main body 100, the control unit 128 is formed into a rectangular parallelepiped shape with an open front to form an internal space A main board 128 "is further provided in the control box 128 'and in the inner space of the control box 128', in which a plurality of electrical components are mounted.

The left suction grille 142 is formed in the lower half of the left panel 140 forming the left side appearance of the main body 100, and air in the space for air conditioning is sucked into the inner side of the left suction grille 142. It is further provided with a left filter 146 for filtering the foreign matter contained in the air when the suction.

In the lower half of the right panel 160 forming the outer surface of the right side of the main body 100, the right side suction, which is a passage through which the air in the right side of the main body 100, that is, the air of the space for air conditioning, is sucked into the inside of the main body 100. The grill 162 is formed in a shape corresponding to the left suction grill 142, and the inside surface of the right suction grill 162 contains foreign substances sucked into the air when the air in the space for air conditioning is sucked in. A right filter 166 for filtering is further provided.

A circular rear suction hole 182 is formed in the lower half of the rear panel 180 forming the rear exterior of the main body 100. The air in the space for air conditioning in the rear of the main body 100 is sucked into the inside of the main body 100 through the rear suction port 182. The rear suction port 182 may further include a rear filter or a rear grill.

The base panel 100 ′ is provided under the lower end of the main body 100, which forms a lateral appearance with a plurality of panels. Therefore, each panel is supported while the lower end of the main body 100 is mounted on the upper surface of the base panel 100 '.

The drain part 300 is mounted on an upper surface of the base panel 100 ′. The drain portion 300 is formed in a substantially "∩" shape when viewed from the front and the top surface is formed flat. More specifically, the upper end cross-sectional area of the drain 300 is formed to be narrower than the lower end cross-sectional area. In other words, the left side surface of the drain portion 300 forms a right slope while having a predetermined angle upwards, and the right side surface forms a left slope while having a predetermined angle upwards.

The central portion of the drain portion 300 is molded to be recessed downward to have a predetermined depth. This is to collect the condensed water generated in the heat exchanger 200 mounted on the upper surface of the drain 300. The condensed water collected on the upper surface of the drain part 300 is discharged to the outside of the main body 100 through a drain hose (not shown). A plurality of ribs 320 are provided on left and right sides of the drain part 300 to reinforce the strength of the drain part 300.

An upper surface of the drain portion 300 is equipped with a heat exchanger 200 that exchanges heat with a refrigerant that is a working fluid while the air in the space for air conditioning flows upward. The front cover 220 is formed on the front surface of the heat exchange part 200 to form the front surface of the heat exchange part 200. The front cover 220 is formed in an inverted trapezoidal shape having a long upper side and a shorter lower side, and a refrigerant pipe 260 for guiding the flow of the refrigerant, which is a working fluid, is bent to the rear of the front cover 220 at the center of the upper half. Refrigerant piping holes 262 are formed perforated.

The refrigerant pipe hole 262 is perforated in a substantially "∩" shape when viewed from the front, the refrigerant pipe hole 262 is shielded the front surface by the hole cover 264. The hole cover 264 has a front surface formed in a shape corresponding to the refrigerant pipe hole 262, the center portion is formed to protrude round to the front.

A pipe receiving groove 266 in which the refrigerant pipe 260 is accommodated is formed from the lower end of the refrigerant pipe hole 262 to the lower end of the front cover 220. The pipe receiving groove 266 is recessed to the rear to accommodate the refrigerant pipe 260 therein.

The rear side of the front cover 220 is equipped with an indoor heat exchanger 240 which is bent a plurality of round pipes having a predetermined diameter and molded into a generally rectangular plate shape. A refrigerant, which is a working fluid flowing while being guided by the refrigerant pipe 260, flows inside the indoor heat exchanger 240.

In addition, the indoor heat exchanger 240 is formed of a left heat exchanger 242 provided on the left side and a right heat exchanger 244 provided on the right side, and is generally mounted in a substantially "V" shape when viewed from the front. That is, the left heat exchanger 242 has a lower end mounted on the upper left half of the drain portion 300 and is provided with an inclined left toward the upper side. The right heat exchanger 244 is provided with a lower end mounted on the upper right side of the drain portion 300 and having a right inclination upward.

As described above, the indoor heat exchanger 240 is mounted at an angle with a predetermined angle so that the air in the space for air conditioning suctioned through the left suction grill 142 and the right suction grill 162 flows upward. This is to form a more smooth flow path. The rear cover 280 is mounted on the rear side of the indoor heat exchanger 240 in the same shape and size as the front cover 220.

The blower 400 is provided above the heat exchanger 200. The lowermost side of the blower 400 is provided with a motor support 422 is fixed to the fan motor 420 to generate rotational power by the application of an external power source. The motor support 422 is fastened to the front cover 220 and the front end of the heat exchanger 200, the upper end and the rear end of the rear cover 280 is fastened.

The fan motor 420 is mounted on the upper surface of the motor support 422. The blower fan 440 is axially coupled to the fan motor 420 at the upper side of the fan motor 420. The blower fan 440 is molded into a shape in which a wing is provided on a cylindrical outer circumferential surface having a predetermined diameter.

The blower fan 440 is a type of axial blower fan, in which air flows in a direction parallel to the axis of rotation, that is, a flow direction of both the inlet and outlet of the air coincides with the axis of rotation. These axial blowers are mainly used to increase the speed of the fluid, so that the flow rate is used where much flow rate is required but pressure is not.

The blowing fan 440 is formed obliquely so that the fan blade 444 has a right downward slope on the outer peripheral surface of the cylindrical body 442. The fan blade 444 is provided with three wings, the upper end is located above the upper end of the body 442, the lower end is located below the lower end of the body 444.

In addition, the fan blade 444 is mounted while twisting from the upper side to the lower side to generate a suction force inside the main body 100 while rotating by the rotational power of the fan motor 420, the suction force Due to this, the air of the space for air conditioning is sucked into the main body 100. The air sucked into the main body 100 flows from below to upward by the rotational movement of the blowing fan 440.

The outer side of the blowing fan 440 is provided with a fan housing 460 is formed to surround the outer surface of the blowing fan 440. The fan housing 460 is formed with the upper and lower surfaces opened, and the cross-sectional areas of the upper and lower surfaces are formed with the same area as that of the cross section of the main body 100.

The fan housing 460 is formed in an arcuate shape such that a cross-sectional area of the center portion is narrower than that of the upper and lower surfaces. That is, it is molded in a shape corresponding to the body 442 of the blowing fan 440. The fan housing 460 serves to guide the flow of air flowing by the blowing fan 440 while protecting the blowing fan 440. The upper surface portion of the fan housing 460 is formed so that the center portion is recessed downward, the lower surface portion is molded so that the center portion is recessed upward.

On the other hand, the discharge unit 500 is provided on the upper side of the blower 400. The discharge unit 500 is provided with a lower surface grill 520 for forming a lower surface of the discharge unit 500 while ensuring the straightness of the air guided by the fan housing 460. The lower surface grill 520 is formed in a rectangular plate shape having a predetermined thickness as a whole, the upper surface and the lower surface is formed in a grid shape to ensure the straightness of the air flowing upward.

An air guide part 510 is mounted on the bottom surface of the bottom grill 520 to guide the air that is guided by the fan housing 460 and flows upward. The air guide part 510 is generally formed in a substantially square plate shape, and the center part is recessed and molded downward. The cross-sectional area of the air guide part 510 has an area smaller than the area of the cross-section of the lower grill 520. That is, the air guide 510 is mounted to the center portion of the lower grill 520.

The upper surface of the lower grill 520 is formed in a rectangular box shape, the discharge frame 540 is formed so that the upper and lower surfaces are opened. The upper and lower surfaces of the discharge frame 540 are molded in an open state, and each side surface thereof is formed by cutting off a central portion thereof.

Sliding power means 530 is provided inside the discharge frame 540 to provide sliding power of the sliding discharge unit 550 which will be described later. The sliding power means 530 is provided with a sliding motor 532 for generating a sliding power by applying external power.

In addition, the center gear 534 is axially coupled to the sliding motor 532 and the power transmission gear 536 and the power transmission gear 536 rotated by the rotation of the central gear 534. The upper surface is formed in a cylindrical shape having a predetermined diameter, the outer peripheral surface is formed in a spiral shape and the power transmission unit 538 is provided on each of the front and rear sides is mounted. The sliding power means 530 is mounted on the upper surface of the lower grill 520 while being fixed by the power means support 530 ′.

On the other hand, the upper side of the sliding power means 530 is provided with a sliding discharge unit 550 for discharging the harmonized air flowing upward through the blower 400 into the space for air conditioning. The sliding discharge unit 550 is coupled to the sliding power means 530 is provided with a sliding portion 552 sliding in the vertical direction by the power of the sliding power means 530, the upper side of the sliding portion 552 It is provided with a discharge guide 554 for guiding the air discharged into the space for air conditioning.

A power transmission hole 552 ′ through which the power transmission unit 538 penetrates is formed in the sliding part 552. The inner circumferential surface of the power transmission hole 552 ′ is formed into a helical shape corresponding to the spiral shape formed on the outer circumferential surface of the power transmission part 538, and is driven by the rotation of the power transmission part 538. As the inner circumferential surface of 552 ′ moves up and down along the spiral formed on the outer circumferential surface of the power transmission portion 538, the sliding portion 552 on which the power transmission hole 552 ′ is formed slides in the vertical direction.

That is, the power transmission hole 552 'is formed at a position corresponding to the power transmission part 538 in the sliding part 552, and the power transmission part 538 is fastened through the power transmission hole 552'. As a result, the thread formed on the inner circumferential surface of the power transmission hole 552 'is joined to the thread formed on the outer circumferential surface of the power transmission unit 538.

When the inner circumferential surface thread of the power transmission hole 552 ′ and the outer circumferential surface thread of the power transmission unit 538 are fastened together, the power transmission hole 552 ′ is driven by the rotation of the power transmission unit 538. Will rotate along the thread of

In this case, the power transmission hole 552 'is rotatably formed by using a bearing or the like in the sliding part 552, and the power transmission hole 552' is rotated by the rotation of the power transmission part 538 to slide. The unit 552 slides in the vertical direction.

The discharge guide 554 has a predetermined thickness, and is formed to be provided in the cut-out portion of each surface of the discharge frame 540, and each corner portion is fixed to the fixing piece 558 to be described later in the fitting engagement Is fastened.

That is, fastening grooves (not shown) are cut and molded in the left and right directions to the fixing piece 558, and the edges of each of the discharge guides 554 are coupled to the fastening grooves by interference fit.

The upper surface of the sliding portion 552 is formed in a substantially rectangular plate shape, the discharge unit upper plate 556 for shielding the upper surface of the discharge unit 500 and the upper surface of the main body 100 is provided at the same time, the discharge upper plate At each corner, a fixing piece 558 fixing the discharge guide 554 extends downward to be fastened to the sliding part 552.

Figure 6 is a partial perspective view showing the discharge unit of the air conditioner indoor unit employing a preferred embodiment according to the present invention, Figure 7 is a main part of the air conditioner indoor unit employing a preferred embodiment according to the present invention The perspective view which shows the air guide part which is a structure is shown. 8 is a front view showing a discharge guide part, which is a main component of an indoor unit of an air conditioner in which a preferred embodiment according to the present invention is employed.

Looking at the discharge unit and the air guide portion in more detail with reference to these drawings, the lower surface of the discharge unit 500 is formed by the lower grill 520, the lower portion of the lower grill 520, the center of the lower air guide portion ( 510 is mounted. In the inner center of the discharge unit 500 is provided with a sliding power means 530 formed of a plurality of parts, including the power transmission unit 538. In addition, the discharge guide 554 is fixed to each of the cut surfaces of the discharge frame 540 to guide the discharged air.

At this time, the lower surface of the sliding power means 530 is shielded by the air guide portion 510, the harmonized air flowing upward from the blower 400 is provided in the central portion of the lower grill 520 Guided by the air guide 510 flows to the portion except the center portion of the grill 520. That is, the air guide part 510 serves to guide the air blown from the blower part 400 to the lower grill 520.

Looking at the air guide portion 510 in more detail, the air guide portion 510 is formed in a rectangular plate shape, the center portion is formed to be recessed rounded downward. That is, since air flows downward and upward toward the air guide part 510, the air guide part 510 may be described as being recessed to be rounded in a direction opposite to the direction in which air flows. A bent part 512 is formed to be bent upward along the upper edge of the air guide part 510.

At each corner of the bent portion 512, a fastening piece 514 extends upward to be fastened between the lattice formed on the bottom grill 520 and the lattice. The fastening piece 514 is formed to protrude round the center portion outward, the horizontal length of the fastening piece 514 between the grating and the grating to be fitted between the grating and the grating formed on the lower grill 520 It is formed to a length corresponding to the width.

That is, each fastening piece 514 formed on the upper surface of the air guide part 510 is mounted on the lower surface grill 520 while being fastened by being interposed between the lattice of the lower surface grill 520 and the lattice.

In addition, the upper surface of the air guide portion 510 is formed so that the fastening boss 516 protrudes upward so that the air guide portion 510 is fastened to the lower grill 520 by a screw. A fastening hole 516 ′ is formed in the center of the fastening boss 516 so that the screw penetrates upward from the bottom surface of the air guide part 510.

Preferably, a plurality of the fastening bosses 516 are provided, and the air guide portion 510 is screwed into a fastening hole 516 ′ formed through the fastening boss 516 through a lower portion of the air guide portion 510. ) Is mounted on the bottom surface of the bottom grill 520.

Hereinafter will be described the operation of the indoor unit of the air conditioner employing a preferred embodiment of the present invention configured as described above.

First, the user applies external power to operate the air conditioner. When external power is applied, power is applied to the fan motor 420 provided in the blower 400, and the sliding motor 532 of the sliding power means 530 provided in the discharge unit 500. ) Is also supplied with power.

When external power is applied to the fan motor 420 provided in the blower 400, the fan motor 420 generates rotational power. The rotational power generated by the fan motor 420 is transmitted to the blowing fan 440 axially coupled with the fan motor 420 so that the blowing fan 440 rotates. Due to the rotational movement of the blowing fan 440, the air in the space for air conditioning is sucked into the main body 100 through the left suction grill 142 and the right suction grill 162.

The air for air conditioning sucked into the inside of the main body 100 through the left suction grill 142 and the right suction grill 162 flows upward by the rotational movement of the blower fan 440 and the indoor heat exchanger ( 240) pass between. At this time, the air flowing upward and the refrigerant which is the working fluid flowing inside the indoor heat exchanger 240 are heat-exchanged.

The air heat-exchanged while passing through the indoor heat exchanger 240 flows upward and is guided by the fan housing 460 to flow into the discharge unit 500.

On the other hand, when the user applies the external power for the use of the air conditioner, the power is also applied to the sliding motor 532 of the sliding power means 530. When power is applied to the sliding motor 532, the sliding motor 532 generates rotational power, and the central gear 534 coupled to the sliding motor 532 by shaft coupling rotates by the rotational power. .

When the central gear 534 is rotated, the power transmission gear 536 which is fixed while being engaged with the central gear 534 is rotated. When the power transmission gear 536 is rotated, the power transmission part 538 protruded upward on the upper surface of the power transmission gear 536 is rotated.

When the power transmission unit 538 is rotated, the power transmission hole 552 'which is fastened while the power transmission unit 538 is rotated is rotated. When the power transmission hole 552 ′ rotates, the sliding part 552 slides in the vertical direction.

When the sliding part 552 slides upward, the sliding discharge part 550 slides upward, and when the sliding discharge part 550 slides upward, the heat exchange part 200 and the refrigerant pipe ( A compressor (not shown) mounted on an outdoor unit (not shown) connected to the outdoor unit 260 is driven, and when the compressor (not shown) is driven, an interior of the indoor heat exchanger 240 provided in the heat exchange unit 200 is provided. Heat exchange with the refrigerant which is a working fluid flowing in the flows upward in the body (100).

The air flowing upward is discharged into the space for air conditioning through the sliding discharge unit 550 sliding upward.

The scope of the present invention is not limited to the above embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

In the indoor unit of the air conditioner according to the present invention configured as described in detail above, the air in the space for air conditioning is sucked and flows upward while flowing upward through the blower.

Harmonized air flowing upward while passing through the blower is guided by the air guide to flow into the discharge unit.

As such, when guided by the air guide flows into the discharge unit, the reverse flow of the harmonized air flowing upwards is prevented, so that the air flows smoothly.

When the harmonious air flows smoothly, the harmonious air flowing into the discharge unit flows smoothly, so the amount of air flowing into the discharge unit increases, and the amount of air flowing into the discharge unit increases. When the amount of air discharged into the space for air conditioning increases, there is an effect that the air conditioning efficiency is improved.

In addition, there is an effect that the noise caused by the flow of air is reduced while the flow of the air flowing upwards inside the main body is smooth. If the noise of the air conditioner is reduced, there is also an effect to solve the user's emotional complaints.

As the efficiency of the air conditioner is improved, the efficiency of energy use is also improved, and as the user's emotional dissatisfaction is resolved, the reliability of the product is also improved.

As the reliability of the product is improved, there is also an effect of increasing the sales volume of the product, and the increase of the sales volume also contributes to the development of the industry.

Claims (6)

The main body to secure the internal space while forming the external appearance, A heat exchanger provided at the lower half of the main body to exchange heat with the air sucked into the main body; A blower provided above the heat exchanger to forcibly flow air in the main body; A discharge unit which is provided above the blower and is blown by the blower, and discharges the introduced air to the outside; The indoor unit of the air conditioner is mounted to the discharge unit including an air guide unit for guiding the air blown from the blower to the discharge unit. The method of claim 1, wherein the discharge unit, A lower surface grill formed into a lattice shape to form a lower surface, A sliding discharge portion provided on an upper surface of the lower surface grill and sliding in a vertical direction; A discharge frame for guiding vertical sliding of the sliding discharge unit; The indoor unit of the air conditioner, characterized in that it comprises a sliding power means provided in the discharge frame to provide a sliding power of the discharge frame. The indoor unit of an air conditioner according to claim 2, wherein the air guide part is mounted on a bottom surface of the bottom grill. The indoor unit of an air conditioner according to claim 1, wherein the air guide part is recessed roundly in a direction opposite to the flow direction of the air blown by the blower. The indoor unit of an air conditioner of claim 2, further comprising a fastening protrusion protruding upward from the upper surface of the air guide part so as to be engaged with the lower surface grill. The indoor unit of the air conditioner of claim 2, wherein the air guide unit further comprises a fastening piece protruding upwardly to be engaged with the bottom grill.

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