JP2005233191A - Drain pump and air conditioning system equipped therewith - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the operating noises of a drain pump during low pump head. <P>SOLUTION: The drain pump 8 comprises a pump casing 81 and an impeller 82. The pump casing 81 has a drain inlet 81a provided at the lower end for sucking drain water and a drain outlet 81b provided at the side for discharging the drain water. The impeller 82 has a shaft portion 91 arranged in the pump casing 81 extending in the vertical direction, a main blade 92 arranged on the outer periphery side of the shaft portion 91, an auxiliary blade 94 arranged on the lower side of the main blade 92, and a disc catch pan portion 93 arranged between the main blade 92 and the auxiliary blade 94 and having an opening portion 93a at the center. The catch pan portion 93 also has an annular partition portion 93b extending upward from the outer peripheral edge. The outer peripheral edge of the main blade 92 is arranged lower than the upper end of the partition portion 93b. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a drain pump and an air conditioner including the drain pump.

  In the air conditioner, a drain pump may be provided to discharge drain water generated in the heat exchanger during cooling operation or dry operation. Such a drain pump is built in the ceiling-embedded air conditioner 1 shown in FIGS. 14, 15, and 16, for example. Here, FIG. 14 is an external perspective view of the air-conditioning apparatus 1 (ceiling is omitted). 15 is a schematic side cross-sectional view of the air conditioner 1, and is a cross-sectional view taken along the line AA of FIG. FIG. 16 is a schematic plan cross-sectional view of the air conditioner 1, and is a cross-sectional view taken along the line BB of FIG.

  The air conditioner 1 includes a casing 2 that houses various components therein, and a decorative panel 3 that is disposed below the casing 2. Specifically, the casing 2 of the air conditioner 1 is disposed by being inserted into an opening formed in the ceiling U of the air conditioning room. And the decorative panel 3 is arrange | positioned so that it may fit in opening of the ceiling U. FIG. Inside the casing 2, a blower 4 that mainly sucks the air in the air-conditioned room into the casing 2 through the suction port 31 of the decorative panel 3 and blows it out in the outer peripheral direction, and heat disposed so as to surround the outer periphery of the blower 4. An exchanger 6 is arranged. The decorative panel 3 is formed with an inlet 31 for sucking air in the air-conditioned room and an outlet 32 for blowing air from the casing 2 into the air-conditioned room.

  A drain pan 7 for receiving drain water generated in the heat exchanger 6 is disposed below the heat exchanger 6. The drain pan 7 is attached to the lower part of the casing 2. The drain pan 7 includes a suction hole 71 formed so as to communicate with the suction port 31 of the decorative panel 3, a blowout hole 72 formed so as to correspond to the blower outlet 32 of the decorative panel 3, and a bottom of the heat exchanger 6. And a drain receiving groove 73 formed on the side for receiving drain water. A bell mouth 5 for guiding air sucked from the suction port 31 to the impeller 41 of the blower 4 is disposed in the suction hole 71 of the drain pan 7. Then, the drain water accumulated in the drain receiving groove 73 is discharged to the outside of the casing 2 in a portion of the drain receiving groove 73 of the drain pan 7 where the heat exchanger 6 is not disposed (specifically, between the blowout holes 72). A drain pump 308 is disposed. The drain pump 308 is connected via a discharge pipe (not shown) disposed outside the casing 2.

  As shown in FIG. 17, such a drain pump 308 is mainly disposed in a pump casing 81 having a drain suction port 81 a at a lower end portion and a drain discharge port 81 b at a side portion, and the pump casing 81. An impeller 382 that can rotate around a shaft portion 91 that extends vertically in the pump casing 81 and a motor 83 that is disposed on the upper side of the pump casing 81 and rotationally drives the shaft portion 91 of the impeller 382 are provided. Yes. A motor mounting bracket 89 for mounting the drain pump 308 to the casing 2 of the air conditioner 1 is mounted on the side surface of the motor 83. Here, FIG. 17 is a side view of a conventional drain pump 308 (a cross section of the pump casing 81 is shown). Further, the rotation axis of the shaft portion 91 of the impeller 382 is P-P.

  The pump casing 81 mainly has an opening in the upper part, and a casing main body 84 arranged so as to surround the side of the impeller 82, and a casing lid 85 arranged so as to cover the upper opening of the casing main body 84. And a sealing member 86 for sealing between the casing main body 84 and the casing lid 85. The casing main body 84 has a cylindrical main body portion 84a that is reduced in diameter as it goes downward, a tubular suction portion 84b that extends downward from the lower end portion of the main body portion 84a and has a drain suction port 81a at the lower end portion, It has a tubular discharge nozzle portion 84c that extends sideways from a drain discharge port 84b formed in a side portion of the main body portion 84a. As shown in FIG. 16, the discharge nozzle portion 84 c partially penetrates the side plate of the casing 2 of the air conditioner 1. The casing lid 85 mainly has an air introduction portion 85a formed of a through hole communicating with the atmosphere and the inside of the pump casing 81 at a substantially central position.

  As shown in FIGS. 18 and 19, the impeller 382 mainly includes a shaft portion 91 connected to a drive shaft of the motor 83, a main blade 392 disposed in the main body portion 84 a, and a lower portion of the main blade 392. The auxiliary blade 94 arranged on the side, and a disc-shaped receiving tray 93 that is disposed between the main blade 392 and the auxiliary blade 94 and has an opening 93a formed of an annular through hole in the center. Yes. Here, FIG. 18 is an enlarged view showing the vicinity of the pump casing 81 of FIG. FIG. 19 is a plan view of a conventional drain pump 308 (illustrated with the motor 83 and the casing lid 85 omitted).

The shaft portion 91 penetrates through the air introduction portion 85 a and is arranged so that a gap is formed between the outer peripheral surface of the shaft portion 91 and the inner peripheral surface of the air introduction portion 85 a of the casing lid 85.
The main blades 392 are, for example, radially from the four first blades 395 extending radially from the outer peripheral surface of the shaft portion 91, and from the outer peripheral edge of the opening 93a of the tray portion 93 between the circumferential directions of the first blades 395. It is composed of four second blades 396 that extend. The height position of the upper end portion of the first blade 395 (hereinafter, as shown in FIG. 18, the height from the upper end surface of the opening 93a to the upper end portions of the first blade 395 and the second blade 396 is defined as the blade height H1. Is the same height from the inner periphery to the outer periphery. The blade height H1 at the upper end of the second blade 396 is the same height as the first blade 395 from the inner periphery to the outer periphery.

  The saucer portion 93 is disposed along the reduced diameter portion of the main body portion 84 a, and an annular partition portion 93 b extending upward from the outer peripheral edge portion thereof is disposed so as to connect the outer peripheral edge portion of the main blade 392. ing. The upper end portion of the partition portion 93b is disposed at a position lower than the upper end portion of the main blade 392 (hereinafter, as shown in FIG. 18, the upper end portion of the partition portion 93b of the saucer portion 93 from the upper end surface of the opening portion 93a. The height up to the portion is defined as a tray height H2). That is, the upper end portion of the main blade 392 protrudes above the upper end portion of the partition portion 93b in a side view of the impeller 382. Further, the outer dimension D of the partition portion 93b is substantially the same as or slightly smaller than the outer diameter of the main blade 392. The auxiliary blades 94 are four blades that are disposed in the suction portion 84 b and extend radially from the outer peripheral surface of the shaft portion 91.

  In the drain pump 308 having such a configuration, when the motor 83 is driven, the impeller 82 is rotated in a predetermined direction. Then, since a part of the suction portion 84b is submerged below the surface of the drain water accumulated in the drain receiving groove 73 of the drain pan 7, the drain water accumulated in the drain receiving groove 73 is drained by the auxiliary blade 94. It is sucked in from the suction port 81a, rises in the suction portion 84b, and reaches the main body portion 84a. And the drain water which reached | attained the main-body part 84a is pressure | voltage-risen by the main blade | wing 392, Then, it discharges outside from the drain discharge port 81b to the casing 2 of the air conditioning apparatus 1 via the discharge nozzle part 84c. Specifically, drain water discharged from the drain discharge port 81b is discharged through a discharge pipe disposed outside the casing 2 and connected to the discharge nozzle portion 84c. Here, the water surface that has risen up to the main body portion 84a is substantially vertically divided by the tray portion 93, partially blocked so that the flow of the drain water is restricted, and the drain water in contact with the main blade 392 is discharged. (For example, see Patent Documents 1, 2, 3, and 4).

  Moreover, the drain pump 308 can adjust the discharge flow rate by the water level h (see FIG. 18) without starting and stopping. That is, in the drain pump 308, the discharge flow rate decreases when the water level h decreases, and the discharge flow rate increases when the water level h increases. When the water level h rises to a certain water level, the maximum discharge flow rate is reached, and even if the water level h rises further, the discharge flow rate does not change. For this reason, even if the amount of drain water generated in the heat exchanger 6 changes, the operation is stably performed at a water level where the amount of drain water generated and the discharge flow rate balance.

  Here, in the main body portion 84a of the drain pump 308, as the water level h decreases, the air layer (see the gas-liquid interface X in FIGS. 18 and 19) expands concentrically with the shaft portion 91 of the main blade 392. The effective area where the water supply work of the main blade 392 can be performed is reduced, and the discharge flow rate of the drain pump 308 is reduced. On the contrary, when the water level h rises, the air layer shrinks, so that the effective area where the main blade 392 can perform the water feeding work increases, and the discharge flow rate of the drain pump 308 increases. Thus, the conventional drain pump 308 has a structure in which the discharge flow rate can be adjusted by the water level h.

For example, the back pressure may be reduced depending on the installation conditions (pipe length, inner diameter, height, etc.) of the discharge pipe connected to the drain discharge port 81b. In such a case, since the head of the drain pump 308 is lowered, the air layer expands concentrically with the shaft portion 91 of the main blade 392.
Such a drain pump 308 generally has a pumping efficiency because a gas-liquid interface between air and water is formed at a portion where the main blade 392 is disposed, as compared with a pump of a type in which the impeller is completely submerged. Low and loud driving noise. And this driving | running | working sound is mainly generated when the main blade | wing 392 stirs an air layer, and becomes so loud that the air layer expands to the outer peripheral side of the main blade | wing 392. In particular, at the low head, the gas-liquid interface between air and water (see the gas-liquid interface Y in FIGS. 18 and 19) expands to the outer peripheral portion where the peripheral speed is high, so that a very loud driving sound is generated. This operating sound is particularly problematic when the blower 4 of the air conditioner 1 has a low air volume or when the air-conditioned room is quiet.

On the other hand, as shown in FIG. 20, the main blade 392 (specifically, for the purpose of reducing the operation sound by allowing the gas-liquid interface Y to smoothly flow over the upper end of the partition portion 93b. Specifically, on the outer peripheral portion of the first and second blades 395 and 396), only on the portion above the upper end portion of the partition portion 93b (that is, the portion between the blade height H1 and the tray height H2). Although some have adopted an impeller 382 provided with inclined portions 395a and 396a, even in this case, the driving sound cannot be sufficiently reduced.
JP-A-10-115294 JP 2000-80996 A JP 2000-240581 A JP 2001-342984 A

  An object of the present invention is to reduce the operation sound of a drain pump at a low head.

The drain pump according to claim 1 includes a casing and an impeller. The casing has a drain suction port for sucking drain water into the lower end portion and a drain discharge port for discharging drain water to the side portion. The impeller includes a shaft portion disposed so as to extend in the vertical direction in the casing, a main blade disposed on the outer peripheral side of the shaft portion, an auxiliary blade disposed below the main blade, a main blade, and an auxiliary It has a disc-shaped saucer part which is arranged between the blades and has an opening in the center. The saucer portion further includes an annular partition portion extending upward from the outer peripheral edge portion thereof. The main wing is disposed at a position where the inner peripheral portion is higher than the upper end portion of the partition portion, and the outer peripheral edge portion is disposed at a position lower than the upper end portion of the partition portion.

In this drain pump, the inner peripheral part of the main blade is arranged at a position higher than the upper end part of the partition part, and the outer peripheral edge part of the main blade having a high peripheral speed is lower than the upper end part of the partition part. Therefore, the collision between the gas-liquid interface and the outer periphery of the main blade can be mitigated even when the gas-liquid interface between air and water expands to the outer periphery with a high peripheral velocity at the low head. Driving noise can be reduced. In particular, when the low water level operation condition overlaps with the low head operation condition, the operation sound can be effectively reduced.

  In addition, since the portion arranged at a position lower than the upper end of the partition is the outer peripheral edge of the main blade having a high peripheral speed and a large influence on the operation sound, the air in the vicinity of the outer peripheral portion of the main blade is not affected. While reducing the collision between the liquid interface and the main blade, the effect on the inner periphery of the main blade, which has a relatively small influence on operating noise, is reduced by reducing the effect of reducing the collision between the gas-liquid interface and the main blade. Since the effective area capable of carrying out the water supply work is ensured, it is possible to suppress the decrease in the performance of the drain pump as much as possible.

Thereby, in this drain pump, the driving | running sound at the time of a low head can be made small, suppressing the fall of pump performance.
A drain pump according to a second aspect is the drain pump according to the first aspect, wherein the outer peripheral edge portion of the main blade is disposed on the inner peripheral side of the inner peripheral surface of the partition portion.
In this drain pump, the outer peripheral edge portion of the main blade is disposed on the inner peripheral side with respect to the inner peripheral surface of the partition portion of the tray portion, and the diameter of the main blade is smaller than the diameter of the inner peripheral surface of the tray portion. Therefore, the effect of relieving the collision between the gas-liquid interface and the main blade at the outer peripheral edge of the main blade can be enhanced.

A drain pump according to a third aspect is the drain pump according to the first or second aspect, wherein the main blade is inclined so that the blade height decreases as the outer peripheral portion thereof moves toward the outer peripheral edge portion.
In this drain pump, it is formed so that the blade height of the outer peripheral portion of the main blade becomes lower toward the outer peripheral edge portion, and in the outer peripheral portion of the main blade, the effective area capable of performing the water supply work of the main blade However, it is possible to further suppress a decrease in the performance of the drain pump.

Air conditioning apparatus according to claim 4, wherein the heat exchanger, the drain pan for reserving the drain water generated in the heat exchanger, in any one of claims 1 to 3 for discharging the drain water collected in the drain pan And a drain pump.
In this air conditioner, since the drain pump having a low operating sound at the low head is used for discharging the drain water accumulated in the drain pan, the noise of the entire air conditioner can be reduced.

As described above, according to the present invention, the following effects can be obtained.
In the invention concerning Claim 1, the driving | running sound at the time of a low head can be made small.
In the invention concerning Claim 2, the effect which relieve | moderates the collision with the gas-liquid interface in the outer peripheral part of a main blade | wing and a main blade | wing can be heightened.
In the invention concerning Claim 3, the performance fall of a drain pump can be suppressed.

In the invention concerning Claim 4 , the noise of the whole air conditioning apparatus can be made small.

Hereinafter, embodiments of a drain pump according to the present invention and an air conditioner including the same will be described with reference to the drawings.
[First Embodiment]
(1) Configuration and Operation of Drain Pump FIGS. 1 and 2 show a drain pump 8 according to a first embodiment of the present invention used in the air conditioner 1 (see FIGS. 14 to 16) and the like. Here, FIG. 1 is an enlarged view showing the vicinity of the pump casing 81 of the drain pump 8 according to the first embodiment of the present invention. FIG. 2 is a plan view of the drain pump 8 according to the first embodiment of the present invention (illustrated with the motor 83 and the casing lid 85 omitted). Since the drain pump 8 has the same configuration as the conventional drain pump 308 except for the impeller 82, the description thereof is omitted.

  The impeller 82 mainly includes a shaft portion 91 connected to the drive shaft of the motor 83, a main blade 92 disposed in the main body portion 84 a of the pump casing 81, and an auxiliary blade disposed on the lower side of the main blade 92. 94 and a disc-shaped saucer portion 93 disposed between the main blade 92 and the auxiliary blade 94 and having an opening 93a formed of an annular through hole at the center. Here, since the impeller 82 has the same configuration as the conventional impeller 382 except for the main blade 92, the description thereof is omitted.

  The main blades 92 are, for example, four first blades 95 extending radially from the outer peripheral surface of the shaft portion 91 and radially from the outer peripheral edge of the opening 93a of the tray portion 93 between the circumferential directions of the first blades 95. It consists of four second blades 96 that extend. The number of first blades 95 and second blades 96 constituting the main blade 92 is not limited to the above number, and various numbers can be selected.

  The height position of the upper end portion of the first blade 95 (hereinafter, as shown in FIG. 1, the height of the first blade 95 and the second blade 96 from the upper end surface of the opening 93a is referred to as the blade height H1). Except for the inclined portion 95a formed on the outer peripheral portion, the height is the same from the inner peripheral portion to the outer peripheral portion. The blade height H1 at the upper end of the second blade 96 is the same height as the first blade 95 from the inner periphery to the outer periphery, except for the inclined portion 96a formed on the outer periphery. Moreover, like the main blade 392 of the conventional drain pump 308, the portion excluding the inclined portion 96a of the main blade 92 is the upper end of the partition portion 93b (specifically, the tray height) in the side view of the impeller 82. It protrudes above H2).

The inclined portions 95a and 96a are formed so as to cut out part of the outer peripheral portions of the first blade 95 and the second blade 96, and are inclined so that the blade height H1 decreases toward the outer peripheral portion. Has the shape. Further, the outer peripheral edge portions of the inclined portions 95a and 96a are disposed at a position lower than the upper end portion of the partition portion 93b.
In addition, the inclined portions 95a and 96a have the outer diameters of the first blade 95 and the second blade 96 shorter than the outer dimension D of the partition portion 93b, and further shorter than the diameter d of the inner peripheral surface of the partition portion 93b. So that it is cut out. For this reason, the outer peripheral edge part of the 1st blade | wing 95 and the 2nd blade | wing 96 is arrange | positioned rather than the inner peripheral surface of the partition part 93b at the inner peripheral side. The inclined portions 95a and 96a may be linearly inclined as shown in FIG. 1 or may be inclined to draw a curved surface.

In the drain pump 8 having the main blade 92 formed with such inclined portions 95a and 96a, as in the main body portion 84a of the conventional drain pump 308, the shaft portion 91 of the main blade 92 decreases as the water level h decreases. And the air layer expands concentrically. In particular, at the low head, the gas-liquid interface between air and water (see the gas-liquid interface Y in FIGS. 1 and 2) expands to the outer peripheral portion where the peripheral speed is high.
However, in the drain pump 8, since the inclined portions 95a and 96a are formed on the outer peripheral portion of the main blade 92, the outer peripheral edge portion of the main blade 92 is disposed at a position lower than the upper end portion of the partition portion 93b. Since the collision between the liquid interface Y and the outer peripheral portion of the main blade 92 can be alleviated, the operation sound generated when the main blade 92 stirs the air layer can be reduced.

  Moreover, since the portion disposed at a position lower than the upper end of the partition portion 93b is the outer peripheral edge of the main blade 92 having a high peripheral speed and a large influence on the driving sound, While reducing the collision between the gas-liquid interface Y and the main blade in the vicinity, the effect of reducing the collision between the gas-liquid interface and the main blade is reduced for the inner peripheral portion of the main blade 92 that has a relatively small influence on the operation sound. Thus, an effective area where the water supply work of the main blade 92 can be performed is ensured. Thereby, the fall of the discharge flow rate of the drain pump 8 is suppressed, and the fall of pump performance can be suppressed as much as possible.

Further, in the drain pump 8, the outer peripheral edge portion of the main blade 92 is disposed on the inner peripheral side with respect to the inner peripheral surface of the partition portion 93 b of the tray portion 93. An effect of reliably mitigating the collision between the main blade 92 and the main blade 92 can be obtained.
Further, in the drain pump 8, the blade height H1 of the outer peripheral portion of the main blade 92 is formed so as to decrease toward the outer peripheral portion, and the water supply work of the main blade 92 is performed on the outer peripheral portion of the main blade 92. Since it is easier to secure an effective area that can be used, the deterioration of the pump performance of the drain pump 8 can be further suppressed.

  Thus, in this drain pump 8, the operation sound at the time of a low head can be made small, suppressing the fall of pump performance. In addition, since the drain pump 8 having a low operating noise at the time of such a low head is used for discharging drain water accumulated in the drain pan 7 of the air conditioner 1, the noise of the entire air conditioner 1 can be reduced. Thus, when the air blower 4 of the air conditioner 1 has a low air volume or when the air-conditioned room is quiet, a problem that the operation sound of the drain pump is anxious is less likely to occur.

(2) Experimental Example Next, regarding the drain pump 8 having the main blade 92 having the inclined portions 95a and 96a of the present embodiment and the drain pump 308 having the conventional main blade 392, the operation sound of the drain pump alone. And the experimental result which measured the head which is one of pump performance is demonstrated. Here, FIG. 3 is a graph showing measured values of the operation sound of the drain pump alone under various water level and head conditions. FIG. 4 is a graph showing measured values of the head at various rotational speeds. Moreover, as a conventional drain pump, it is more than the drain pump (henceforth the prior art example 1) provided with the main blade | wing which does not have the inclination part shown by FIG. 18, and the upper end part of the partition part 93b shown by FIG. A drain pump (hereinafter, referred to as Conventional Example 2) provided with main blades having inclined portions 395a and 395b formed only on the upper portion was prepared, and the operation sound and the head were measured.

  In the drain pump of the conventional example 1, as shown in FIG. 3, the operation sound is loudest at the low water level and the low head (about 46 dBA), and the operation sound is reduced to about 43 dBA at the high water level and the low head. Furthermore, when the head becomes larger, the driving sound tends to decrease to about 30 dBA. Further, as shown in FIG. 4, the lifting height tends to rise as the number of rotations increases. Further, in the drain pump of the conventional example 2, as shown in FIG. 3, the operation sound in the case of the low water level and the low head is improved as compared with the conventional example 1, but the operation sound is most pronounced in the case of the low water level and the low head. Is large (about 42 dBA), the driving sound is reduced to about 40 dBA at a high water level and a low head, and when the head is increased, the driving sound tends to be reduced to about 30 dBA.

  On the other hand, in the drain pump 8 of the present embodiment, as shown in FIG. 3, the operation sound is lower than the operation sounds of the drain pumps of the conventional examples 1 and 2 at the low water level and the low head (about 32 dBA). In the case of the water level and low head, the operation sound increases to about 37 dBA (however, it is lower than the operation sound under the same conditions of the drain pumps of the conventional examples 1 and 2), and further, the operation sound is about 30 dBA It tends to decline. Further, as shown in FIG. 4, the head is slightly smaller than the head of the drain pump of the first conventional example, but tends to rise upward as the rotational speed increases.

  Here, in the case of the low water level and the low head, the operation sound is lower than the operation sound of the drain pump of the conventional example 1, as described above, the inclined portion 95a on the outer peripheral portion of the main blade 92, It is thought that it originates in having formed 96a. Moreover, the operating noise of the drain pump of the conventional example 2 is smaller than that of the inclined portions 95a and 96a formed on the main blade 92 of the drain pump 8 of the present embodiment and the drain pump of the conventional example 2. This is due to the difference in shape from the inclined portion formed on the main blade. Specifically, the inclined portions 95a and 96a formed on the main blade 92 of the drain pump 8 of the present embodiment are arranged at positions where the outer peripheral edge portion is lower than the upper end portion of the partition portion 93b. This is because the inclined portions 395a and 395b formed on the main blade of the drain pump of Conventional Example 2 are formed only in the portion above the upper end portion of the partition portion 93b. Moreover, in the drain pump 8 of the present embodiment, the outer peripheral edge portion of the main blade 92 is disposed on the inner peripheral side with respect to the inner peripheral surface of the partition portion 93b of the tray portion 93. It is presumed that the effect of reducing the collision between the gas-liquid interface Y and the main blade 92 is enhanced. In addition, the operation noise increases in the case of a high water level and a low head because the inner peripheral portion of the main blade 92 has the same shape as the main blade 392 of the drain pumps of the conventional example 1 and the conventional example 2. It is thought that there is.

As for the lifting height, by forming the inclined portions 95a and 96a on the main blade 92, the effective area where the main blade 92 can perform water feeding work is slightly reduced. Since the area is secured, it is only slightly smaller than the head of the drain pump of Conventional Example 1, and the pump performance of the drain pump 8 is suppressed as much as possible.
Thus, like the drain pump 8 of this embodiment, by arrange | positioning the outer-periphery edge part of the main blade | wing 92 in a position lower than the upper end part of the partition part 93b, at the time of a low head, suppressing the fall of pump performance. In particular, in the case where the low water level operation condition overlaps with the low head operation condition, it has been confirmed that the operation sound can be effectively reduced.

[Second Embodiment]
(1) Configuration and Operation of Drain Pump FIGS. 5 and 6 show a drain pump 108 according to a second embodiment of the present invention used in the air conditioner 1 (see FIGS. 14 to 16) and the like. Here, FIG. 5 is an enlarged view showing the vicinity of the pump casing 81 of the drain pump 108 according to the second embodiment of the present invention. FIG. 6 is a plan view of the drain pump 108 according to the second embodiment of the present invention (illustrated with the motor 83 and the casing lid 85 omitted). The drain pump 108 has the same configuration as the conventional drain pump 308 except for the impeller 182, and thus the description thereof is omitted.

  The impeller 182 mainly includes a shaft portion 91 connected to the drive shaft of the motor 83, a main blade 192 disposed in the main body portion 84 a of the pump casing 81, and an auxiliary blade disposed below the main blade 192. 94 and a disc-shaped saucer portion 93 disposed between the main blade 192 and the auxiliary blade 94 and having an opening portion 93a formed of an annular through hole in the center. Here, since the impeller 182 has the same configuration as the conventional impeller 382 except for the main impeller 192, the description thereof is omitted.

  The main blades 192 are, for example, four first blades 195 extending radially from the outer peripheral surface of the shaft portion 91 and radially from the outer peripheral edge of the opening 93a of the tray portion 93 between the circumferential directions of the first blades 195. It consists of four second blades 196 that extend. The number of first blades 195 and second blades 196 constituting the main blade 192 is not limited to the above number, and various numbers can be selected.

  The height position of the upper end portion of the first blade 195 (hereinafter, as shown in FIG. 5, the height of the first blade 195 and the second blade 196 from the upper end surface of the opening 93a is defined as the blade height H1). The blade height H1 decreases from the inner periphery to the outer periphery (specifically, the upper end of the outer periphery of the partition portion 93b). That is, the inclined portion 195a formed only on the outer peripheral portion of the first blade 95 of the first embodiment is formed on the entire first blade 195. Further, the blade height H1 at the upper end portion of the second blade 196 is formed with an inclined portion 196a so that the blade height H1 decreases from the inner peripheral edge portion toward the outer peripheral edge portion, similarly to the first blade 195. ing. That is, the inclined portion 196a formed only on the outer peripheral portion of the second blade 96 of the first embodiment is formed on the entire second blade 196. In addition, the outer peripheral edge part of the 1st blade | wing 195 and the 2nd blade | wing 196 is arrange | positioned in the same height position as the upper end part (specifically, saucer height H2) of the partition part 93b, and is 1st Embodiment. Like the inclined parts 95a and 96a, the outer peripheral edge part of the 1st blade | wing 195 and the 2nd blade | wing 196 is not arrange | positioned in the position lower than the upper end part of the partition part 93b. Since these inclined portions 195a and 196a are formed from the inner peripheral edge of the main blade 192 to the outer peripheral edge (specifically, from the outer peripheral surface of the shaft portion 91 to the outer peripheral edge of the partition portion 93b), Compared to the inclined portions 95a and 96a of the first embodiment, it is gently inclined. Thus, the 1st blade | wing 195 and the 2nd blade | wing 196 have blade | wing height H1 lower in an outer peripheral part than an inner peripheral part. The inclined portions 195a and 196a may be linearly inclined as shown in FIG. 5, or may be inclined to draw a curved surface.

  In the drain pump 108 having the main blade 192 in which the inclined portions 195a and 196a are formed, as in the main body portion 84a of the conventional drain pump 308, the shaft portion 91 of the main blade 192 decreases as the water level h decreases. And the air layer expands concentrically. In particular, at the time of low head, the gas-liquid interface between air and water (see the gas-liquid interface Y in FIGS. 5 and 6) expands to the outer peripheral portion where the peripheral speed is high.

However, in this drain pump 108, the blade height H1 is lower at the outer peripheral portion than the inner peripheral portion by forming the inclined portions 195a, 196a on the entire main blade 192, and the gas-liquid interface Y and the main blade 192 are reduced. Since the collision with the outer peripheral portion of the main blade 192 can be alleviated, the operation sound generated by the main blade 192 stirring the air layer can be reduced.
Moreover, when the water level h rises, the air layer shrinks (see the gas-liquid interface X in FIGS. 5 and 6). At this time as well, the inclined portions 195a and 196a formed on the entire main blade 192 cause the gas-liquid The collision between the interface X and the main blade 192 can be alleviated, and the operation sound generated when the main blade 192 stirs the air layer can be reduced.

  Thus, in this drain pump 108, when the gas-liquid interface between air and water expands to the outer peripheral portion having a high peripheral velocity at the low head, and when the water level rises and the water level is low at the low head. In any case where the gas-liquid interface is located on the inner periphery, the collision between the gas-liquid interface and the main blade 192 can be alleviated, so even when the position of the gas-liquid interface changes due to a change in the water level. The driving noise at the time of low head can be reduced. Further, since the drain pump 108 having a low operation sound at the time of such a low head is used for discharging drain water accumulated in the drain pan 7 of the air conditioner 1, the noise of the entire air conditioner 1 can be reduced. Thus, when the air blower 4 of the air conditioner 1 has a low air volume or when the air-conditioned room is quiet, a problem that the operation sound of the drain pump is anxious is less likely to occur.

(2) Experimental Example Next, regarding the drain pump 108 having the main blade 192 having the inclined portions 195a and 196a of the present embodiment and the drain pump 308 having the conventional main blade 392, the operation sound of the drain pump alone. And the experimental result which measured the head which is one of pump performance is demonstrated using FIG.3 and FIG.4.

  In the drain pump 108 of the present embodiment, as shown in FIG. 3, the operation sound is lower than that of the drain pumps of the conventional examples 1 and 2 at the low water level and the low head (about 36 dBA, but the first The operation noise of the drain pump 8 of the embodiment is larger than that of the drain pump 8 under the same condition), and the operation sound is reduced to about 35 dBA at the high water level and low head (and the drain pump 108 of the first embodiment under the same condition). Furthermore, when the head is increased, the driving sound tends to decrease to about 30 dBA. Further, as shown in FIG. 4, the lift is slightly smaller than the lift of the drain pump of the conventional example 1 (however, it is about the same as the lift of the drain pump 108 of the first embodiment). As the number increases, it tends to rise.

  Here, in the case of the low water level and the low head, the operation sound is lower than the operation sound of the drain pump of the conventional example 1, as described above, the inclined portion 195a on the outer peripheral portion of the main blade 192, It is thought that it originates in having formed 196a. The reason why the operating sound of the drain pump 8 of the first embodiment is larger is that the inclined portions 195a and 196a are more gently inclined than the inclined portions 95a and 96a of the first embodiment. The outer peripheral edge portion of 192 is not disposed at a position lower than the upper end portion of the partition portion 93b, and the effect of reducing the collision between the gas-liquid interface and the main blade 192 in the outer peripheral portion of the main blade 192 is the same as that of the first embodiment. This is considered to be because it is slightly smaller than the inclined portions 95a and 96a. In addition, in the case of the low water level and the low head, the operation sound is lower than the operation sound of the drain pump of the conventional example 2 not only in the outer peripheral portion of the main blade 192 but also in the entire main blade 192, the inclined portion 195a, This is considered to be due to the formation of 196a. Further, the operation noise is reduced when the water level is high and the head is low. The main blades 92 are formed with inclined portions 195a and 196a, and the main blades of the drain pumps of the conventional examples 1 and 2 and the first embodiment. Unlike the main blade 92 of the drain pump 8, it is considered that this is because an effect of relaxing the collision between the gas-liquid interface and the main blade 192 in the inner peripheral portion of the main blade 192 is obtained.

  Regarding the lift, by forming the inclined portions 195a and 196a on the main blade 192, the effective area where the main blade 192 can perform water feeding work is slightly reduced, but the main blade 92 has the inclined portion 195a, As a result of the formation of 196a, an effective area in the outer peripheral portion of the main blade 192 is secured, so that it is equivalent to the drain pump 8 of the first embodiment, that is, slightly smaller than the head of the drain pump of the conventional example 1. The reduction in the pump performance of the drain pump 108 is suppressed as much as possible.

  As described above, by forming the inclined portions 195a and 196a on the entire main blade 192 as in the drain pump 108 of the present embodiment, it is possible to suppress not only the low head and the low water level but also the low pump level while suppressing the deterioration of the pump performance. It has been confirmed that the operation sound can be reduced even at the head and at the high water level, and as a result, the effect of reducing the change in the operation sound due to the change in the head and the water level is obtained.

[Third Embodiment]
(1) Configuration and Operation of Drain Pump FIGS. 7 and 8 show a drain pump 208 according to a third embodiment of the present invention used in the air conditioner 1 (see FIGS. 14 to 16) and the like. Here, FIG. 7 is an enlarged view showing the vicinity of the pump casing 81 of the drain pump 208 according to the third embodiment of the present invention. FIG. 8 is a plan view of the drain pump 208 according to the third embodiment of the present invention (illustrated with the motor 83 and the casing lid 85 omitted). Since the drain pump 208 has the same configuration as the conventional drain pump 308 except for the impeller 282, the description thereof is omitted.

  The impeller 282 is mainly disposed between the shaft portion 91 connected to the drive shaft of the motor 83, the auxiliary blade 94 disposed below the main blade 292, and the main blade 292 and the auxiliary blade 94. It is comprised from the disk-shaped saucer part 93 which has the opening part 93a which consists of a cyclic | annular through-hole in the cage | basket | center. Here, since the impeller 282 has the same configuration as the conventional impeller 382 except for the main impeller 292, the description thereof is omitted.

  The main blades 292 are, for example, radially from the four first blades 295 extending radially from the outer peripheral surface of the shaft portion 91 and from the outer peripheral edge of the opening 93a of the tray portion 93 between the circumferential directions of the first blades 295. It is composed of four second blades 296 that extend. The number of first blades 295 and second blades 296 constituting the main blade 292 is not limited to the above number, and various numbers can be selected.

  The height position of the upper end portion of the first blade 295 (hereinafter, as shown in FIG. 7, the height of the first blade 295 and the second blade 296 from the upper end surface of the opening 93a is defined as the blade height H1). Since the uneven portion 295a is formed, the first blade 295 changes in an uneven shape from the inner peripheral edge to the entire outer peripheral edge. Further, the blade height H1 at the upper end portion of the second blade 96 changes in a concavo-convex shape from the inner peripheral edge portion to the entire outer peripheral edge portion of the second blade 296 because the uneven portion 296a is formed.

  In the present embodiment, the concavo-convex portions 295a and 296a are triangular wave-shaped portions, and are inclined so that the blade height H1 becomes lower as the outermost peripheral portion approaches the outer peripheral portion (hereinafter, the inclined portions 295b and 296b). And). The inclined portions 295b and 296b are formed so as to cut out part of the outer peripheral portions of the first blade 295 and the second blade 296, and the outer peripheral edge portion thereof is the upper end portion of the partition portion 93b (specifically, It is arranged at a position lower than the tray height H2).

  The inclined portions 295b and 296b have the outer diameters of the first blade 295 and the second blade 296 shorter than the outer dimension D of the partition portion 93b, and further shorter than the diameter d of the inner peripheral surface of the partition portion 93b. So that it is cut out. For this reason, the outer peripheral edge part of the 1st blade | wing 295 and the 2nd blade | wing 296 is arrange | positioned rather than the inner peripheral surface of the partition part 93b at the inner peripheral side. The shapes of the concavo-convex portions 295a and 296a are not limited to those of the present embodiment, and other shapes such as a rectangular wave shape and a sine wave shape are also applicable.

  In the drain pump 208 including the main blade 292 on which the uneven portions 295a and 296a having the inclined portions 295b and 296b are formed, the water level h decreases as in the main body portion 84a of the conventional drain pump 308. The air layer expands concentrically with the shaft portion 91 of the main blade 292. In particular, at the time of low head, the gas-liquid interface between air and water (see the gas-liquid interface Y in FIGS. 7 and 8) expands to the outer peripheral portion where the peripheral speed is high.

  However, in this drain pump 208, the outer peripheral edge portion of the main blade 292 is formed on the outer peripheral portion of the main blade 292 so that the outer peripheral edge of the main blade 292 is separated from the partition portion 93b. Since the collision between the gas-liquid interface Y and the outer periphery of the main blade 292 can be mitigated, the main blade 292 has the same configuration as the drain pump 8 of the first embodiment. Driving noise generated by stirring the air layer can be reduced.

  In addition, when the water level h rises, the air layer shrinks (see the gas-liquid interface X in FIGS. 7 and 8). Even in this case, the uneven portions 295a and 296a are the main blades 292 as a whole as in this embodiment. In the same manner as in the drain pump 108 of the second embodiment, the bumps 295a and 296a can alleviate the collision between the gas-liquid interface X and the main blade 292, and the main blade 292 Driving noise generated by stirring the air layer can be reduced.

  And since the drain pump 208 with such a low operating noise at the time of a low head is used for the discharge of the drain water accumulated in the drain pan 7 of the air conditioner 1, the noise of the entire air conditioner 1 can be reduced. Thus, when the air blower 4 of the air conditioner 1 has a low air volume or when the air-conditioned room is quiet, a problem that the operation sound of the drain pump is anxious is less likely to occur.

[Other Embodiments]
As mentioned above, although embodiment of this invention was described based on drawing, a specific structure is not restricted to these embodiment, It can change in the range which does not deviate from the summary of invention.
(1) Modification of First Embodiment In the main blade 92 constituting the impeller 82 of the drain pump 8 of the first embodiment, the inclined portions 95a and 96a are shorter than the diameter d of the inner peripheral surface of the partition portion 93b. The outer peripheral edge portions of the first blade 95 and the second blade 96 are arranged on the inner peripheral side with respect to the inner peripheral surface of the partition portion 93b by being cut out as described above, but as shown in FIG. The outer peripheral edge portions of 95a and 96a may be formed so as to contact the inner peripheral surface of the partition portion 93b.

Even in this case, since the outer peripheral edge portions of the first blade 95 and the second blade 96 are disposed at a position lower than the upper end portion of the partition portion 93b, the operation at a lower head than the drain pumps of the conventional examples 1 and 2 is performed. It is estimated that the sound can be reduced.
Further, the main blade 92 constituting the impeller 82 of the drain pump 8 of the first embodiment has a shape inclined so that the blade height H1 decreases linearly as the inclined portions 95a and 96a move toward the peripheral edge. However, as shown in FIG. 10, a part of the outer periphery of the first blade 95 and the second blade 96 is notched in a polygonal line, or as shown in FIG. 95 and the part of the outer peripheral part of the 2nd blade | wing 96 may be the shape notched straightly in the perpendicular direction.

Even in this case, since the outer peripheral edge portions of the first blade 95 and the second blade 96 are disposed at a position lower than the upper end portion of the partition portion 93b, the operation at a lower head than the drain pumps of the conventional examples 1 and 2 is performed. It is estimated that the sound can be reduced.
(2) Modification of Second Embodiment In the main blade 192 constituting the impeller 182 of the drain pump 108 of the second embodiment, the inclined portions 195a and 196a are formed from the inner peripheral edge portions of the first blade 195 and the second blade 196. The blades are formed so that the blade height decreases toward the outer peripheral edge (specifically, the upper edge of the outer peripheral edge of the partition portion 93b). Although the collision with the blade 192 can be reliably mitigated to reduce the driving noise at the time of the low head (see FIG. 3), as shown in FIG. 12, the inclined portions 95a and 96a of the first embodiment are used. Similarly, the outer peripheral edge portions of the inclined portions 195a and 196a are disposed at positions lower than the upper end portion of the partition portion 93b, and the inclined portions 195a and 196a are shorter than the diameter d of the inner peripheral surface of the partition portion 93b. Is cut out like Also good.

In this case, since the effect of alleviating the collision between the gas-liquid interface and the main blade 92 at the outer peripheral portion of the main blade 92 can be enhanced, the operation sound at the low head and at the low water level can be further reduced. It is estimated that
(3) Modification of Third Embodiment In the main blade 292 constituting the impeller 282 of the drain pump 208 of the third embodiment, the inclined portions 295a and 296a are one of the outer peripheral portions of the first blade 295 and the second blade 296. Are formed by cutting out the outer diameter of the first blade 295 and the second blade 296 to be shorter than the outer dimension D of the partition portion 93b. While the collision with the blade 292 can be reliably mitigated, the driving noise at the low head and low water level is greatly reduced (see FIG. 3), but as shown in FIG. Without making the outer diameter of the second blade 296 smaller than the outer dimension D of the partition part 93b, a part of the outer peripheral part may be cut out toward the outer peripheral edge part of the partition part 93b.

  In this way, the effect of mitigating the collision between the gas-liquid interface and the main blade 292 at the outer peripheral portion of the main blade 292 is reduced, but still the operation sound is reduced to the same level as the drain pump 108 of the second embodiment. It is estimated that an effect can be obtained.

  If the present invention is used, the operation sound of the drain pump at the time of low head can be reduced.

It is an enlarged view which shows the pump casing vicinity of the drain pump concerning 1st Embodiment of this invention. 1 is a plan view of a drain pump according to a first embodiment of the present invention (illustrated with a motor and a casing lid omitted). It is a graph which shows the actual measurement value of the operation sound in the drain pump single-piece | unit in the conditions of various water levels and a head. It is a graph which shows the actual measurement value of the head in various rotation speed. It is an enlarged view which shows the pump casing vicinity of the drain pump concerning 2nd Embodiment of this invention. It is a top view (a motor and a casing lid are omitted) of a drain pump concerning a 2nd embodiment of the present invention. It is an enlarged view which shows the pump casing vicinity of the drain pump concerning 3rd Embodiment of this invention. It is a top view (a motor and a casing lid are omitted) of a drain pump concerning a 3rd embodiment of the present invention. It is a side view of the impeller of the drain pump concerning other embodiment of this invention. It is a side view of the impeller of the drain pump concerning other embodiment of this invention. It is a side view of the impeller of the drain pump concerning other embodiment of this invention. It is a side view of the impeller of the drain pump concerning other embodiment of this invention. It is a side view of the impeller of the drain pump concerning other embodiment of this invention. 1 is an external perspective view of a ceiling-embedded air conditioner. FIG. 17 is a schematic side cross-sectional view of a ceiling-embedded air conditioner, and is a cross-sectional view taken along line AA in FIG. 16. FIG. 16 is a schematic plan cross-sectional view of a ceiling-embedded air conditioner, and is a cross-sectional view taken along line BB in FIG. 15. It is a side view of a conventional drain pump (a cross section of a pump casing is shown). It is an enlarged view which shows the pump casing vicinity of FIG. It is a top view of a conventional drain pump (illustrated with the motor and casing lid omitted). It is a side view of the impeller of the drain pump of another conventional example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Air conditioning apparatus 6 Heat exchanger 7 Drain pan 8, 108, 208 Drain pump 81 Pump casing (casing)
81a Drain suction port 81b Drain discharge port 82, 182, 282 Impeller 91 Shaft portion 92, 192, 292 Main blade 93 Receptacle portion 93a Opening portion (opening)
93b Partition 94 Auxiliary blade H1 Blade height H2 Sauce tray height

Claims (6)

A casing (81) having a drain suction port (81a) for sucking drain water into a lower end portion and a drain discharge port (81b) for discharging drain water on a side portion;
A shaft portion (91) disposed so as to extend in the vertical direction in the casing, a main blade (92) disposed on the outer peripheral side of the shaft portion, and an auxiliary blade disposed on the lower side of the main blade ( 94) and an impeller (82) having a disc-shaped saucer portion (93) disposed between the main blade and the auxiliary blade and having an opening (93a) in the center,
The tray portion further includes an annular partition portion (93b) extending upward from the outer peripheral edge portion thereof,
The outer peripheral edge portion of the main blade is disposed at a position lower than the upper end portion of the partition portion,
Drain pump (8).   The drain pump (8) according to claim 2, wherein an outer peripheral edge portion of the main blade (92) is disposed on an inner peripheral side with respect to an inner peripheral surface of the partition portion (93b).   The drain pump (8) according to claim 1 or 2, wherein the main blade (92) is inclined so that the blade height (H1) decreases as the outer peripheral portion thereof moves toward the outer peripheral portion. A casing (81) having a drain suction port (81a) for sucking drain water into a lower end portion and a drain discharge port (81b) for discharging drain water on a side portion;
A shaft portion (91) disposed so as to extend in the vertical direction in the casing, a main blade (192) disposed on the outer peripheral side of the shaft portion, and an auxiliary blade disposed on the lower side of the main blade ( 94) and an impeller (82) having a disc-shaped saucer portion (93) disposed between the main blade and the auxiliary blade and having an opening (93a) in the center,
The main blade (192) is formed such that the blade height (H1) decreases from the inner periphery to the outer periphery.
Drain pump (108). A casing (81) having a drain suction port (81a) for sucking drain water into a lower end portion and a drain discharge port (81b) for discharging drain water on a side portion;
A shaft portion (91) disposed so as to extend vertically in the casing, a main blade (292) disposed on the outer peripheral side of the shaft portion, and an auxiliary blade (under the main blade) ( 94) and an impeller (82) having a disc-shaped saucer portion (93) disposed between the main blade and the auxiliary blade and having an opening (93a) in the center,
The main blade (292) has at least an outer peripheral portion formed with uneven portions (295a, 296a) in which the blade height (H1) changes into an uneven shape,
Drain pump (208). A heat exchanger (6);
A drain pan (7) for collecting drain water generated in the heat exchanger;
The drain pump (8, 108, 208) according to any one of claims 1 to 5, wherein the drain water accumulated in the drain pan is discharged.
An air conditioner (1) comprising:

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