JP2009063189A - Indoor unit of air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an indoor unit of an air conditioner preventing the easy losing of balance of a lifter suspended with two strings and, even if losing the balance, capable of quickly restoring to its original attitude. <P>SOLUTION: This indoor unit 2 has a flat panel 4 having a rectangular vertical projection plane and suspended from a body 20 with a first suspension string 711 and a second suspension string 712. The first suspension string 711 suspends a first suspension point adjacent to a first side 401 of the flat panel 4, while the second suspension string 712 suspends a second suspension point adjacent to a second side 402, or the opposite side of the first side 401. The positions of the first suspension point and the second suspension pint are so set as preventing the orthogonal crossing of a two-point passing line F, which orthogonally crosses with a plumb line G passing the center of gravity of the flat panel 4 and passes through the first suspension point and the second suspension point, with the first side 401 and the second side 402. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an indoor unit of an air conditioner, and more particularly to an indoor unit that closes a suction opening provided on a lower surface with a panel.

Conventionally, as a ceiling-mounted indoor unit, an indoor unit that closes a central opening of a decorative panel with a liftable center panel or a suction grill is widely known (for example, see Patent Document 1). In the indoor unit described in Patent Document 1, the suction grille is suspended by two strings, and the suction grille is manually pulled down during maintenance, and after the maintenance is finished, the string is wound up by the lifting device and lifted. To do.
Japanese Patent Laid-Open No. 10-332172

  In the indoor unit as described above, the suction grille is only suspended by two strings, and when the lifting device lifts the suction grille, the posture of the suction grille tends to collapse and even if it reaches the suction opening. It may not be possible to close it correctly.

  The subject of this invention is providing the indoor unit of the air conditioning apparatus which can return to the original attitude | position quickly when the attitude | position of the raising / lowering member suspended with two strings is hard to collapse.

  The indoor unit of the air conditioning apparatus according to the first aspect of the present invention includes a main body, an elevating member, and an elevating means. The lifting member has a rectangular or square vertical projection surface, and is suspended from the main body by the first hanging strap and the second hanging strap. The lifting / lowering means feeds and winds up the first hanging strap and the second hanging strap. The first hanging strap hangs the first hanging point in the vicinity of the first side that forms one side of the lifting member, and the second hanging strap is the second hanging point in the vicinity of the second side that is the opposite side of the first side. Hanging. The first suspension point and the first suspension point are arranged so that a two-point passing line that intersects the vertical line passing through the center of gravity of the elevating member and passes through the first suspension point and the second suspension point is not orthogonal to the first side and the second side. The position of 2 hanging points is set.

  In this indoor unit, by setting the two-point passing line so as not to be orthogonal to the first side and the second side, the horizontal posture at the time of raising and lowering is lost compared to the case of being orthogonal to the first side and the second side. It becomes difficult. Furthermore, the return when the horizontal posture is lost is also accelerated.

  An indoor unit of an air conditioner according to a second aspect of the present invention is the indoor unit of the air conditioner according to the first aspect of the present invention, wherein the first suspension point is formed on the first rib that rises from the vicinity of the first side. The second suspension point is included in the first suspension hole, and the second suspension point is included in the second suspension hole formed in the second rib protruding from the vicinity of the second side. The two-point passing line is not orthogonal to the longitudinal direction of the first rib and the second rib.

  In this indoor unit, by setting the two-point passing line so as not to be orthogonal to the first rib and the second rib, the horizontal posture at the time of raising and lowering is lost compared to the case of being orthogonal to the first rib and the second rib. It becomes difficult.

  An indoor unit of an air conditioner according to a third aspect of the invention is the indoor unit of an air conditioner according to the second aspect of the invention, wherein a first hook that hangs on the first suspension hole is provided at the tip of the first suspension string, A second hook that hangs on the second suspension hole is provided at the tip of the second suspension string.

  In this indoor unit, the first hook is hooked on the first suspension hole and the second hook is hooked on the second suspension hole, so that the first hook and the second hook are not used. The horizontal posture is difficult to collapse.

  In the indoor unit of the air conditioner according to the first aspect of the present invention, the two-point passing line is set so as not to be orthogonal to the first side and the second side, thereby comparing with the case of being orthogonal to the first side and the second side. , The horizontal posture during elevation is less likely to collapse. Furthermore, the return when the horizontal posture is lost is also accelerated.

  In the indoor unit of the air conditioner according to the second aspect of the present invention, the two-point passing line is set not to be orthogonal to the first rib and the second rib, thereby comparing with the case of being orthogonal to the first rib and the second rib. , The horizontal posture during elevation is less likely to collapse.

  In the indoor unit of the air conditioner according to the third aspect of the invention, the first hook and the second hook are not used by making the first hook hook on the first suspension hole and the second hook hook on the second suspension hole. Compared to the case, the horizontal posture during elevation is less likely to collapse.

  Embodiments of the present invention will be described below with reference to the drawings. The following embodiments are specific examples of the present invention and do not limit the technical scope of the present invention.

<Indoor unit>
Fig.1 (a) is a perspective view at the time of the operation stop of the indoor unit which concerns on one Embodiment of this invention, FIG.1 (b) is a perspective view at the time of the operation | movement of the indoor unit. 1 (a) and 1 (b), an indoor unit 2 of an air conditioner has a main body 20 having a suction opening 21 and an air outlet 22 on the lower surface, a flat panel 4 that opens and closes the suction opening 21, and suction from the suction opening 21. A filter 6 is provided for removing dust contained in the air. The suction opening 21 and the air outlet 22 are adjacent to each other, and the area of the suction opening 21 is larger than that of the air outlet 22 and occupies a considerable range of the lower surface of the main body 20.

(Flat panel 4)
The flat panel 4 is large enough to block the entire suction opening 21 and is suspended by two strings 71 extending from the main body 20 side. The two cords 71 support both ends in the longitudinal direction of the flat panel 4, and the cord 71 that lifts the front end in FIG. 1 (b) is in the vicinity of the first end 4 a away from the air outlet 22. The string 71 that is connected and lifts the end on the back side in FIG. 1B is connected to the vicinity of the second end 4b close to the outlet 22.

  During operation, the flat panel 4 descends to open the suction opening 21, but the amount of descending is different between the first end 4a and the second end 4b, and the first end 4a is larger than the second end 4b. Since it descends, the flat panel 4 rotates so as to be inclined with respect to the ceiling surface, and opens the suction opening 21.

(Filter 6)
FIG. 2 is a perspective view of the filter. In FIG. 2, the filter element 6c is held by a frame 6a. Moreover, the long sides which the flame | frame 6a opposes are connected by the reinforcement arm 6b, and the bending of a long side is suppressed.

  The plain weave or twill filter element 6c is a net-like member pleated with polyethylene terephthalate fiber (hereinafter referred to as PET fiber). In order to protect the shape of the fold mountain, the reinforcing arm 6b is formed of the filter element 6c. It is molded into a shape that matches the fold mountain.

  By reducing the fiber of the filter element 6c, the ventilation resistance can be lowered without deteriorating the performance of removing the dust of the filter 6, but the strength for maintaining the fiber crease is weakened. However, it also has the function of maintaining the fold mountain. In addition, fibers having different materials and diameters may be interwoven between PET fibers so as to increase the strength of maintaining the fiber crease.

  FIG. 3 is a perspective view at the time of maintenance of the indoor unit according to the embodiment of the present invention. In FIG. 3, the flat panel 4 can be lowered and raised with the filter 6 mounted thereon, and the user can remove the filter 6 and clean it without looking up at the ceiling.

  A string 71 for lifting the flat panel 4 is connected to the lifting unit 7. When the lifting unit 7 feeds the string 71, the flat panel 4 is lowered, and when the string 71 is wound up, the flat panel 4 is raised.

  For convenience, a position at which the user can remove the filter 6 from the flat panel 4 without climbing on a stand or the like during maintenance is referred to as a maintenance position. Further, a position where the flat panel 4 opens the suction opening 21 during operation is called an open position, and a position where the flat panel 4 closes the suction opening 21 when operation is stopped is called a closed position.

(Elevating unit 7)
FIG. 4 is a front view of the inside of the lifting unit. In FIG. 4, the lifting unit 7 includes a pulley 72, a winding gear 73, a driving gear 74, a motor 75 and a switch 76 in addition to the string 71.

  The pulley 72 has a pulley portion 72 a and a cam portion 72 b that are integrally formed. The pulley portion 72 a supports the string 71 and rotates as the string 71 moves. The cam portion 72b includes a small-diameter curved surface, a large-diameter curved surface, and a plane connecting both the curved surfaces.

  In the winding gear 73, a bobbin 73a and a gear portion 73b for winding the string 71 are integrally formed. The drive gear 74 meshes with the gear portion 73b of the winding gear 73 and rotates the bobbin 73a.

  The motor 75 is a stepping motor and rotates the drive gear 74. The number of rotations of the motor 75 is controlled by the number of pulses supplied from the control unit 10. The control unit 10 includes a CPU, a memory, and a motor drive circuit, and is disposed at another position away from the lifting unit 7. The motor 75 and the control unit 10 are electrically connected by a wire harness.

  The switch 76 is a micro switch having a lever 76a and is turned on when the lever 76a is pressed. The lever 76a is always in contact with the cam portion 72b of the pulley 72 and is pushed when facing the large-diameter curved surface of the cam portion 72b. The switch 76 is also electrically connected to the control unit 10 by a wire harness.

(Operation of the lifting unit 7)
In FIG. 4, when the lifting unit 7 feeds the string 71, the motor 75 rotates the drive gear 74 in the CW direction. As a result, the winding gear 73 rotates in the direction in which the string 71 is fed out. On the other hand, when the elevating unit 7 winds the string 71, the motor 75 rotates the drive gear 74 in the CCW direction. As a result, the winding gear 73 rotates in the direction of winding the string 71. The string feeding amount and winding amount are proportional to the rotation amount of the motor 75, and the control unit 10 controls the number of pulses supplied to the motor 75 to control the feeding amount and winding amount of the string 71. Is done.

  Since the flat panel 4 is connected to the tip of the string 71, tension is always generated in the string 71, and when the string 71 is drawn out or when the string 71 is wound up, the pulley portion 72 a is connected to the string 71. It rotates by frictional force. At this time, since the cam portion 72b also rotates, the switch 76 issues an ON signal when the lever 76a faces the large diameter curved surface of the cam portion 72b, and issues an OFF signal when the lever 76a faces the small diameter curved surface. While the pulley 72 is rotating, an ON signal and an OFF signal are alternately generated, and these signals are all input to the control unit 10.

  However, when the string 71 is loosened due to some reason and the tension is lost, for example, when the flat panel 4 is lowered by feeding the string 71 for maintenance, before the flat panel 4 reaches the predetermined feeding amount, When landing on a table or the like and stopping, the frictional force between the string 71 and the pulley portion 72a decreases, and the pulley 72 stops. For this reason, either the on signal or the off signal is continuously output from the switch 76. At this time, since the signal from the switch 76 is constant when the motor 75 is rotating, the control unit 10 estimates that the flat panel 4 has been stopped by some obstacle, and immediately stops the motor 75. Let

(Panel support means 8 and filter support state switching means 9)
FIG. 5 is a partial perspective view when the inside of the indoor unit in FIG. 1A is viewed from above. In FIG. 5, the flat panel 4 is provided with ribs 41 and bearings 42. A hole 41a and a groove 41b are formed in the rib 41, and the tip of the string 71 is connected to the hole 41a. The bearing 42 is formed to be a long hole.

  The frame 6a of the filter 6 is fixed to the second frame 61, and the second frame 61 is detachably supported on the flat panel 4. A slide member 62 slidable in the direction of arrow B is accommodated at the end of the second frame 61. The slide member 62 has an inclined portion 62a, a protruding portion 62b, and a locking portion 62c. In FIG. 5, the protrusion 62 b of the slide member 62 is fitted in the groove 41 b of the rib 41, so that the filter 6 is supported by the flat panel 4.

  A drive unit 50, a shaft 43, and a push cam 63 are installed above the flat panel 4. The drive unit 50 can move the shaft 43 and the push cam 63 in the direction of arrow A. At this time, the shaft 43 is inserted into the bearing 42 and the flat panel 4 is rotatably supported by the shaft 43. This series of operations is a connecting operation, and the bearing 42, the shaft 43 and the drive unit 50 serve as the panel support means 8.

  At the same time that the shaft 43 is inserted into the bearing 42, the push cam 63 is inserted into the second frame 61 while pushing the inclined portion 62 a of the slide member 62. At this time, the protrusion 62b is disengaged from the groove 41b, and the locking portion 62c is hung on the main body 20. As a result, the filter 6 supported by the flat panel 4 is supported by the main body 20. This series of operations is a switching operation, and the slide member 62, the push cam 63, and the drive unit 50 become the filter support state switching means 9.

(Drive unit 50)
FIG. 6 is a cross-sectional view showing the inside of the drive unit. In FIG. 6, the drive unit 50 includes a case 51, a motor 52, a pinion gear 53, a rack 54, and a crankshaft 55. The interior of the case 51 is partitioned into three sections, a first section 511, a second section 512, and a third section 513. The motor 52 is a stepping motor, and the number of rotations is controlled by the number of pulses supplied from the control unit 10. The motor 52 is housed in the first section 511, but the rotation axis is in the second section 512.

  The pinion gear 53 and the rack 54 are housed in the second section 512 in a state of being engaged with each other. Since the pinion gear 53 is connected to the rotating shaft of the motor 52, the pinion gear 53 rotates by the rotation of the motor 52, and the rack 54 slides.

  The crankshaft 55 has one rotation center shaft 55a and three crankshafts 551, 552, and 553. The rotation center shaft 55 a is supported by the third section 513, and the first crank shaft 551 is connected to the rack 54. Further, the second crankshaft 552 is connected to the shaft 43, and the third crankshaft 553 is connected to the push cam 63.

(Operation of drive unit 50)
In FIG. 6, when the motor 52 rotates the pinion gear 53 in the C direction, the rack 54 slides in the D direction. At this time, since the first crankshaft 551 connected to the rack 54 also moves in the D direction, the crankshaft 55 rotates in the E direction about the rotation center shaft 55a. As a result, the second crankshaft 552 pushes the shaft 43 in the direction of arrow A, and the third crankshaft 553 pushes the push cam 63 in the direction of arrow A.

(Slide member 62)
FIG. 7 is a perspective view of the second frame and the slide member. In FIG. 7, the slide member 62 has an inclined portion 62a, a protruding portion 62b, a locking portion 62c, and a square hole 62d. A stop plate 61a of the second frame 61 enters one end of the square hole 62d, and a spring 64 is disposed between the stop plate 61a and the other end of the square hole 62d. When the inclined portion 62a is pushed by the push cam 63 (see FIG. 5) and the slide member 62 moves in the direction of the arrow B, the spring 64 is compressed while moving. Receive drag in the opposite direction.

(Operation of the slide member 62)
FIG. 8 is a perspective view showing a state in which the shaft and the push cam of FIG. 5 are moved. In FIG. 8, when the push cam 63 pushes the inclined portion 62 a of the slide member 62, a force in the arrow B direction acts on the slide member 62 and moves. By this movement, the protrusion 62b is detached from the groove 41b, and the support of the flat panel 4 with respect to the filter 6 is released. At the same time, the locking portion 62c protrudes and hangs on the main body 20, so that the filter 6 is supported by the main body 20.

(Operation of flat panel 4 during operation)
FIG. 9 is a perspective view showing a state in which the flat panel of FIG. 8 is opened. In FIG. 9, when the string 71 is unwound, the flat panel 4 is lowered by its own weight. Since the bearing 42 is formed into a long hole, there is a vertical clearance between the bearing 42 and the shaft 43 even when the shaft 43 is inserted into the bearing 42. As a result, the second end portion 4 b of the flat panel 4 is lowered and stopped by the vertical clearance between the bearing 42 and the shaft 43. Thereafter, the first end 4a of the flat panel 4 is lowered by a predetermined distance while rotating around the shaft 43, and the suction opening 21 is opened. In addition, in order to restrict the movement of the flat panel 4 in the axial direction on the shaft 43, a restricting portion 43 a made of a cylinder having a diameter larger than that of the shaft 43 is formed.

  On the other hand, when the string 71 is wound from the above open state, the first end 4a rotates in the direction of closing the suction opening 21 around the shaft 43, and the first end 4a and the second end 4b are the same. When the height is reached, the flat panel 4 becomes substantially horizontal, and then both the first end 4a and the second end 4b rise by the clearance between the bearing 42 and the shaft 43, and the suction opening 21 is opened. close.

  The operation in which the flat panel 4 rotates about the shaft 43 to open the suction opening 21 is when the indoor unit 2 starts operation. At this time, the filter 6 includes the locking portion 62c of the slide member 62 as the main body. 20 does not follow the operation of the flat panel 4.

(Operation of flat panel 4 during maintenance)
When performing maintenance such as cleaning of the filter 6, the string 71 is unwound from the state shown in FIG. The state of FIG. 5 is a state in which the protrusion 62b is fitted in the groove 41b and the filter 6 is connected to the flat panel 4, and the flat panel 4 and the filter 6 can be lowered together. Further, since the shaft 43 is not inserted into the bearing 42, the flat panel 4 can be lowered horizontally without rotating.

(Position maintenance method of flat panel 4)
In the present embodiment, the flat panel 4 is suspended at two points to maintain a horizontal posture. Here, details of how to suspend the flat panel 4 will be described.

  FIG. 10 is a perspective view of a flat panel. In FIG. 10, the flat panel 4 is suspended by two lifting units 7. For convenience, one of the short sides of the flat panel 4 is the first side 401, the rib 41 on the first side 401 side is the first rib 411, the hole 41a formed in the first rib 411 is the first suspension hole 411a, and the first side The lifting unit 7 on the 401 side is referred to as a first lifting unit 701, and the string 71 adjusted to the first lifting unit 701 is referred to as a first hanging string 711. A first hook 711a is connected to the tip of the first hanging strap 711, and the first hook 711a is hooked on the first hanging hole 411a, thereby connecting the first hanging strap 711 and the first rib 411. Complete.

  Also, the side opposite to the first side 401 is the second side 402, the rib 41 on the second side 402 side is the second rib 412, the hole 41a formed in the second rib 412 is the second suspension hole 412a, and the second The lifting / lowering unit 7 on the side 402 side is referred to as a second lifting / lowering unit 702, and the string 71 adjusted to the second lifting / lowering unit 702 is referred to as a second hanging string 712. A second hook 712a is connected to the tip of the second hanging strap 712, and the second hook 712a is hooked on the second hanging hole 412a, thereby connecting the second hanging strap 712 and the second rib 412. Complete.

  An overhead line passing through the center of the first suspension hole 411a and the center of the second suspension hole 412a is a two-point passage line F, and intersects the vertical line G passing through the center of gravity of the flat panel 4. The two-point pass line F divides the flat panel 4 into two regions, and the center of gravity of each of the two regions is balanced with respect to the two-point pass line F. A horizontal posture can be maintained by two-point suspension.

  In the present embodiment, the center point of the first suspension hole 411a and the center point of the second suspension hole 412a are adjusted so that the two-point passing line F is not orthogonal to the first side 401 and the second side 402. Has been. This is because, by doing so, it has been verified by experiments that the posture when the flat panel 4 is raised and lowered is not easily collapsed.

  FIG. 11 is a graph showing the relationship between the elapsed time when the flat panel is moved up and down and the torque acting on the two-point passing line. In FIG. 11, the horizontal axis represents the elapsed time during ascent and the vertical axis represents the torque acting on the two-point passing line F. The curve indicated by the dotted line is the result of the two-point pass line F measured by the flat panel 4 orthogonal to the first side 401 and the second side 402. The curve indicated by the solid line is the result of the two-point pass line F being It is the result measured with the flat panel 4 that is not orthogonal to the first side 401 and the second side 402.

  As shown in FIG. 11, the flat panel 4 in which the two-point passing line F is not orthogonal to the first side 401 and the second side 402 has a long time until the balance is lost after starting to move up and down, and thus maintains a horizontal posture. It turns out that it is easy to do.

  The reason why the flat panel 4 in which the two-point passing line F is not orthogonal to the first side 401 and the second side 402 is easy to maintain the horizontal posture is not clear, but a hypothesis could be made. The hypothesis will be described.

(First hypothesis of the two-point suspension equilibrium principle of the flat panel 4)
When the flat panel 4 is suspended at two points, the horizontal posture is maintained in a stopped state unless the gravity acting on each of the two regions divided by the two-point pass line F is balanced with respect to the two-point pass line F. Can't keep up. In an actual design, the flat panel 4 is asymmetric in the front-rear direction, the left-right direction, and the up-down direction, so that the vertical projection areas are different even if the respective weights are equal.

  For example, when the flat panel 4 is set so that the two-point passing line F is orthogonal to the first side 401 and the second side 402, the flat panel 4 is divided into two rectangles having the same weight and different vertical projection areas. When the flat panel 4 is moved up and down in this state, the flat resistance of the flat panel 4 can be maintained because air resistance corresponding to the respective vertical projection areas acts on the two areas divided by the two-point passing line F. Disappear. That is, the horizontal posture at the time of ascending / descending is less likely to collapse as the difference in vertical projection area between the two regions is smaller, and the horizontal return is also faster.

  Therefore, in order to balance the area of each of the two regions divided by the two-point passage line F, the first suspension hole 411a and the second suspension line 411a and the second side 402 are not perpendicular to each other. The second suspension hole 412a needs to be set.

(Second hypothesis of the two-point suspension equilibrium principle of the flat panel 4)
The first hypothesis is valid only when the flat panel 4 has an asymmetric shape in the front-rear, left-right, and up-down directions. However, actually, even if the flat panel 4 has a symmetrical shape in the front-rear, left-right, and up-down directions, the two-point passing line F is set so as not to be orthogonal to the first side 401 and the second side 402. As a result, it has been confirmed that the horizontal posture at the time of ascending / descending is not easily collapsed and the horizontal return is also accelerated.

  Accordingly, a hypothesis has been made for the equilibrium principle when the flat panel 4 has a symmetrical shape in the front-rear, left-right, and up-down directions, and will be described below with reference to the drawings.

  FIG. 12 is a plan view of a flat panel that forms a rectangular parallelepiped symmetrical in the front-rear, left-right, and up-down directions. In FIG. 12, each of points G1 to G4 and points g1 to g4 is the center of gravity of each of the two regions divided by the two-point passing lines F1 to F4. Only the two-point passing line F <b> 1 is orthogonal to the first side 401 and the second side 402.

  The distance of the perpendicular drawn from each of the points G2 to G4 and the points g2 to g4 to the corresponding two-point passing lines F2 to F4 increases as the relative angle between the two-point passing lines F2 to F4 and the two-point passing line F1 increases. In other words, when the center of gravity position of each of the two regions is viewed along the two-point passing line, the center of gravity position increases as the relative angle between the two-point passing line F2 to F4 and the two-point passing line F1 increases. It turns out that it leaves | separates from a two-point passing line.

  When the two-point pass line is considered as the center of the balance, the center of gravity of each of the two regions corresponds to both ends of the balance. Empirically, considering that the longer balance is easier to balance than the shorter balance, it is estimated that the horizontal position is easier to maintain as the center of gravity of each of the two regions is farther from the two-point passing line.

  From the above, even if the flat panel 4 has a symmetrical shape in the front-rear, left-right, and up-down directions, the first passing line F is not orthogonal to the first side 401 and the second side 402. The suspension hole 411a and the second suspension hole 412a need to be set.

(Other factors that enable two-point suspension equilibrium of the flat panel 4)
The presence of the first rib 411, the second rib 412, the first hook 711a, and the second hook 712a makes it easier to maintain the horizontal posture when the flat panel 4 is raised and lowered. The first rib 411 and the second rib 412 have a certain thickness, the first suspension hole 411 a penetrates in the thickness direction of the first rib 411, and the second suspension hole 412 a is the second rib 412. It penetrates in the thickness direction. Therefore, since the thickness of the first rib 411 is held by the first hanging strap 711 and the thickness direction does not coincide with the two-point pass line F, compared with the case where the thickness direction matches the two-point pass line F. The resistance when rotating around the two-point passing line F increases. Similarly, since the thickness of the second rib 412 is held by the second hanging strap 712 and the thickness direction thereof does not coincide with the two-point passage line F, the thickness direction coincides with the two-point passage line F. Thus, the resistance when rotating around the two-pass line F increases.

  That is, since the rotation around the two-point passing line F is prevented, the horizontal posture of the flat panel 4 is easily maintained. In particular, when the first hook 711a is hung on the first hanging hole 411a and the second hook 712a is hung on the second hanging hole 412a, the frictional force between the first rib 411 and the first hook 711a, Since the frictional force between the two ribs 412 and the second hook 712a further acts, the resistance when rotating around the two-point passing line F increases, and the horizontal posture of the flat panel 4 becomes difficult to collapse.

<Features>
(1)
In the indoor unit 2, the flat panel 4 having a rectangular vertical projection surface is suspended from the main body 20 by a first hanging strap 711 and a second hanging strap 712. The first hanging strap 711 hangs the first hanging point in the vicinity of the first side 401 of the flat panel 4, and the second hanging strap 712 is in the vicinity of the second side 402 that is the opposite side of the first side 401. 2 hanging points. The two-point passing line F intersecting the vertical line G passing through the center of gravity of the flat panel 4 and passing through the first hanging point and the second hanging point is not perpendicular to the first side 401 and the second side 402. The positions of the first hanging point and the second hanging point are set. As a result, compared to the case where the first side 401 and the second side 402 are orthogonal to each other, the horizontal posture of the flat panel 4 is not easily collapsed. Furthermore, the return when the horizontal posture is lost is also accelerated.

(2)
In the indoor unit 2, the first suspension point is included in the first suspension hole 411 a formed in the first rib 411 that protrudes from the vicinity of the first side 401, and the second suspension point is from the vicinity of the second side 402. It is contained in the 2nd suspension hole 412a formed in the 2nd rib 412 which protrudes. The two-point passing line F is not orthogonal to the longitudinal direction of the first rib 411 and the second rib 412. As a result, compared to the case where the first rib 411 and the second rib 412 are orthogonal to each other, the horizontal posture of the flat panel 4 when it is raised and lowered is less likely to collapse.

(3)
In the indoor unit 2, a first hook 711 a that is hooked to the first suspension hole 411 a is provided at the tip of the first suspension string 711, and a second hook 712 a that is hooked to the second suspension hole 412 a is provided at the tip of the second suspension string 712. Is provided. As a result, compared to the case where the first hook 711a and the second hook 712a are not used, the horizontal posture when the flat panel 4 is raised and lowered is less likely to collapse.

  As described above, according to the present invention, the stable posture of the flat panel can be maintained even by two-point suspension, which is useful for an indoor unit of a type of air conditioner that lifts and lowers the flat panel by two-point suspension. .

(A) The perspective view at the time of the operation stop of the indoor unit which concerns on one Embodiment of this invention. (B) The perspective view at the time of operation | movement of the indoor unit. The perspective view of a filter. The perspective view at the time of the maintenance of the indoor unit which concerns on one Embodiment of this invention. The front view inside a raising / lowering unit. The partial perspective view when the inside of the indoor unit of Fig.1 (a) is seen from upper direction. Sectional drawing which shows the inside of a drive unit. The perspective view of the 2nd frame and a slide member. The perspective view of the state which moved the axis | shaft and push cam of FIG. The perspective view of the state which opened the flat panel of FIG. Flat panel perspective view The graph showing the relationship between the elapsed time at the time of flat panel raising / lowering and the torque acting around the two-point passing line. The top view of the flat panel which comprises the rectangular parallelepiped symmetrical to front and rear, right and left, and an up-down direction.

Explanation of symbols

2 Indoor unit 4 Flat panel (elevating member)
7 Lifting unit (lifting means)
20 body 401 first side 402 second side 411 first rib 411a first hanging hole 412 second rib 412a second hanging hole 711 first hanging string 711a first hook 712 second hanging string 712a second hook

Claims (3)

A body (20);
An elevating member (4) whose vertical projection surface is rectangular or square and is suspended from the main body (20) by a first suspension string (711) and a second suspension string (712);
Elevating means (7) for feeding and winding the first hanging strap (711) and the second hanging strap (712);
With
The first hanging string (711) hangs a first hanging point in the vicinity of the first side (401) forming one side of the elevating member (4),
The second hanging strap (712) hangs a second hanging point in the vicinity of the second side (402) that is the opposite side of the first side (401),
A two-point passing line intersecting a vertical line passing through the center of gravity of the elevating member (4) and passing through the first hanging point and the second hanging point is the first side (401) and the second side ( 402) the positions of the first suspending point and the second suspending point are set so as not to be orthogonal to
Air conditioner indoor unit (2). The first suspension point is included in a first suspension hole (411a) formed in a first rib (411) protruding from the vicinity of the first side (401),
The second suspension point is included in a second suspension hole (412a) formed in a second rib (412) protruding from the vicinity of the second side (402),
The two-point passing line is not orthogonal to the longitudinal direction of the first rib (411) and the second rib (412).
The indoor unit (2) of the air conditioning apparatus according to claim 1. A first hook (711a) that is hooked on the first suspension hole (411a) is provided at a tip of the first suspension string (711),
A second hook (712a) that is hooked on the second suspension hole (412a) is provided at the tip of the second suspension string (712).
The indoor unit (2) of the air conditioning apparatus according to claim 2.

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