JP2014081147A - Air conditioner outdoor unit - Google Patents

Abstract

An outdoor unit of an air conditioner having improved heat exchange performance by improving the ventilation of a heat exchanger provided on a side surface and a heat exchanger on the back of a machine room.
A heat exchanger on a side surface and a rear surface, a propeller fan as a blower that sucks and discharges an air flow from the heat exchanger, a mouth ring that is a fan casing, a machine room containing a compressor, etc. The mouth ring wraps part of the discharge side of the propeller fan and expands on the suction side, and the propeller fan has an outer diameter that increases from the expanded portion to the suction side. Try to get close to the room.
[Selection] Figure 1

Description

  The present invention relates to an air conditioner that mainly uses a propeller fan as a blower for an outdoor unit.

  As a background art in this technical field, there is JP-A-11-248198 (Patent Document 1). In this publication, the outer diameter of the propeller fan that overlaps the mouth ring in the axial direction in the vicinity of the outer periphery of the rear edge of the propeller fan is local in the axial direction, and is at least one larger than the maximum outer diameter portion upstream and downstream. In addition, an example is described in which the inner diameter portion of the mouth ring corresponding to this portion is larger than the maximum inner diameter on the upstream side. Moreover, there exists Unexamined-Japanese-Patent No. 2000-205601 (patent document 2). This publication describes an example in which a partition-like wind flow guide that reaches the front panel against the side surface and the rear surface of the L-shaped heat exchanger is provided.

Japanese Patent Laid-Open No. 11-248198 JP 2000-205601 A

  Propeller fans are widely installed as blowers in outdoor units of air conditioners. In recent years, the need for energy saving performance is increasing, and not only reducing the input of the propeller fan, but also trying to improve the heat exchange performance by installing as many heat exchangers as possible. For example, heat exchangers are often arranged not only on the back surface, which is the mainstream direction of the propeller fan, but also on the side surfaces of the outdoor unit. However, since the mainstream of the propeller fan is in the axial direction, it is not easy to suck from the heat exchanger provided on the side. In particular, the mouth ring, which is the casing of the propeller fan, hinders ventilation to the side heat exchanger. According to Patent Document 1, although the efficiency of the propeller fan is improved by partially changing the fan diameter of the propeller fan and locally changing the mouth ring shape accordingly, this point is sufficiently considered. This could hinder energy saving performance. According to Patent Document 2, although the ventilation from the side heat exchanger is improved by the partition-like wind flow guide, the ventilation from the rear heat exchanger at the back of the wind flow guide is obstructed and the total flow to the heat exchanger is reduced. Ventilation could be hindered. In addition, there was a risk that ventilation from the rear heat exchanger on the machine room side where the compressor and the like were housed would not be improved.

  An object of the present invention is to provide an outdoor unit of an air conditioner that can improve the energy exchange performance by improving the heat exchange performance while reducing the input of the propeller fan.

  In order to solve the above problems, for example, the configuration described in the claims is adopted.

  The present application includes a plurality of means for solving the above-mentioned problems. For example, in an outdoor unit of an air conditioner equipped with a heat exchanger, a mouth ring having a suction port with an expanded curved surface, A propeller fan with a large diameter is provided on the heat exchanger side, and ventilation from the heat exchanger provided on the side of the fan is improved to improve heat exchange performance.

  ADVANTAGE OF THE INVENTION According to this invention, the outdoor unit for air conditioners which improved the heat exchange performance can be provided.

It is an example of center sectional drawing of the outdoor unit of an air conditioner. It is the example of the figure which removed the fan grill of the outdoor unit of the air conditioner, exposed the propeller fan, and was seen from the discharge side. It is an example of the figure which expanded the propeller fan vicinity of FIG. It is an example of the figure which shows the wind speed distribution of the side surface heat exchanger 110a of FIG. It is an example which shows the air blower performance of the outdoor unit of an air conditioner. It is an example which shows the air blower performance of the outdoor unit of an air conditioner. It is an example which shows the air blower performance of the outdoor unit of an air conditioner. It is an example which shows the air blower performance of the outdoor unit of an air conditioner.

  The outdoor unit of the air conditioner is connected to the indoor unit via a refrigerant pipe, electric wiring, etc., and is configured to perform indoor air conditioning. One embodiment of the present invention will be described with reference to the drawings.

  1 and 2, the outdoor unit 100 houses a heat exchanger 110, a fan motor 120, a propeller fan 130 as a blower, a mouth ring 140, and a machine room 151 in which a compressor 150 is housed in a unit frame. The front panel 101 and the side panel 102 are enclosed. The machine room 161 is partitioned by a partition plate 160 composed of a side surface portion 160a corresponding to the side surface of the propeller fan 130 and a back surface portion 160b, and the air flow of the air blown by the propeller fan 130 does not pass therethrough. The propeller fan 130 has a fan boss 131 and a fan blade 132 (in this case, three blades are taken as an example), and is rotated by the fan motor 120, whereby the heat exchanger 110 is shown as indicated by an arrow 170 in FIG. Inhale and discharge from the side. The fan motor 120 is located on the air suction side of the propeller fan 130 and is attached to the unit frame body by the motor stay 121. The motor stay 121 has a frame structure so that the pressure loss with respect to the air flow is minimized. The fan motor 120 is provided in parallel with the main flow direction of the propeller fan 130 so as not to obstruct the directivity and pressure resistance of the main flow. For safety, a fan grill 103 is provided outside the discharge port 104 on the discharge side of the propeller fan 130 to prevent contact from the outside of the housing. The fan grill 103 has a shape that combines frames, and has a structure that minimizes obstacles to ventilation and that is considered in terms of safety.

  The heat exchanger 110 is a cross fin type heat exchanger composed of heat transfer tubes and heat exchange fins, and is formed in an L shape in plan view, and side heat exchange is performed along the side and back of the frame. 110a and rear heat exchanger 110b are arranged on the suction side of propeller fan 130. The heat exchanger 110 exchanges heat between the air ventilated by the propeller fan 130 and the heat medium in the heat transfer tubes via the heat transfer tubes and the heat exchange fins, and the heat exchange amount increases as the air volume increases. The heat pump performance of the outdoor unit 100 is improved, and the energy saving performance of the air conditioner is improved.

The mouth ring 140 is disposed outside the outer periphery of the propeller fan 130 and guides the air flow 170 blown by the propeller fan 130 to be discharged from the discharge port 104. The mouth ring 140 is expanded to the heat exchanger 110 side. The suction side curved surface 140a, the air guide portion 140b, and the discharge side curved surface 140c expanded to the discharge side. The mouth ring 140 wraps a part of the discharge side, which is also the rear edge side of the propeller fan 130, and the fan blade 132 of the propeller fan 130 is wrapped by the mouth ring 140 so that the leading edge tip side protrudes to the suction side. There are not open areas. Furthermore, the diameter of the propeller fan 130 has partially changed, and is particularly large on the suction side. A line connecting the ends of the changing fan outer diameter is an outer diameter line 133 in cross section. At this time, when viewed from the discharge side of the propeller fan 130 with the fan grill 103 removed, a part of the fan blade 132 appears as a fan diameter enlarged portion 201 hidden behind the discharge port 104 as shown in FIG. Thus, since the diameter of the propeller fan 130 on the suction side is large, the propeller fan 130 is first brought close to the side heat exchanger 110a. Therefore, the air flow 170a from the side heat exchanger 110a can be strengthened, and the heat exchange performance is improved. Furthermore, as indicated by the outline 133, the diameter of the propeller fan 130 is reduced toward the rear heat exchanger 110b, and the curved portions 110c of the side heat exchanger 110a and the rear heat exchanger 110b are curved. It becomes almost parallel. Therefore, the ventilation from the bent portion 110c is also improved, and the air flow 110b of the rear heat exchanger, which is the main flow of the propeller fan 130, and the wind speed distribution are smoothly connected, which contributes to the improvement of the overall heat exchange performance. In the present embodiment, the airflow 171a is appropriately formed by the curved surface of the suction side curved surface 140a with respect to the side surface heat exchanger 110a, and is behind the mouth ring 140. It is possible to ventilate the partial heat exchanger, and it is possible to effectively use all of the side heat exchanger 110a, which contributes to the improvement of the heat exchange performance.
On the other hand, a part of the fan blade 132 reaches from the side surface of the machine room side partition plate 160a to the extended region of the air path of the rear heat exchanger 110b on the rear side of the machine room on the back side of the machine room rear partition plate 160b. Further, the machine room side plate is close to the machine room 151 side as shown in the machine room side outline 133b obtained by the fan outer diameter of the propeller fan 130 protruding from the mouth ring 140. The distance is such that interference with 160 does not occur and noise increases. Therefore, the ventilation 170c from the rear heat exchanger 110b on the machine room side is strengthened, and the heat exchange performance can be improved by using the rear heat exchanger 110b efficiently. In addition, by strengthening the airflow 170c, for example, when the heat exchanger of the outdoor unit 100 is provided in a position corresponding to the side panel 102 in a U shape instead of an L shape, the heat at that position is also provided. Contributes to improved ventilation of the exchanger.

  The shape of the air guide part 140b of the mouth ring 140 may be a right cylinder. In the case of a straight cylinder, the airflow 170 is propelled by the propeller fan 130 to discharge the airflow for discharging the airflow from the outlet 104, so that the discharged airflow is likely to have linearity. At this time, since the so-called shortcut wind in which the airflow 170, particularly the airflow 170a sucked from the side heat exchanger 110a wraps around the side surface and is sucked again from the side heat exchanger 110a, is prevented. Suppresses and improves overall heat exchange performance. Alternatively, the air guide portion 140b may have a throttle shape in which the cross section is inclined and the inner diameter is gradually narrowed. At this time, since the sucked airflow 170 is smoothly connected from the suction-side curved surface portion 140a, it is prevented that the airflow is largely separated at the air guide portion 140b, which contributes to reduction of input and noise as a blower. , Contributes to the energy saving performance of air conditioners. Alternatively, the air guide section 140b may have a multistage shape in which the throttle is the first stage, the right cylindrical shape is the second stage, and the two are smoothly connected. At this time, it becomes possible to achieve both separation of the air flow from the suction-side curved surface 140a and securing linearity at the time of discharge, which contributes to improvement in energy saving of the air conditioner. Note that the diameter of the propeller fan 130 does not change linearly as shown by the outline 133 in the figure, but the discharge side is almost constant and increases toward the suction side. The combination of the cylinders is preferable because it is easy to secure the clearance dimension between the propeller fan 130 and the mouth ring 140, specifically, to make it constant.

  Note that the flow field of the propeller fan 130 as a blower is complicated. For example, a blade tip leakage flow occurs in the clearance between the fan blade 132 and the mouth ring 140, which becomes one of the starting points and is discharged from the blade tip to the discharge side. The blade tip vortex is formed, and the blade tip vortex interferes with the flow field on the suction surface 140a of the mouth ring 140 or directly collides with the curved surface. Therefore, preferable arrangement and configuration are conceivable as components for improving the heat exchange performance and further improving the blower performance. A specific arrangement and configuration are shown using FIG.

  For example, if the curvature Rs of the suction-side curved surface 140a of the mouth ring 140 is too large, the clearance management becomes difficult and it becomes difficult to suppress the leakage flow. As a result, neither the propeller fan input nor noise is affected. If the curvature is too small, the input will decrease, but it will become more sensitive to disturbance of the suction section and interference with the tip vortex, increasing noise. Therefore, Rs / Dm is preferably 3% or more and 15% or less with respect to Rs and the maximum fan diameter Dm. In addition, if the amount Hm of the propeller fan 130 wrapped by the mouth ring 140 is too large, it is difficult to contribute to improvement of energy saving performance, such as difficulty in securing an airflow from the side heat exchanger 110a. If it is too small, the open area of the propeller fan 130 increases and the directivity and rectification of the airflow are lowered, and not only the heat exchange performance but also the blower performance is lowered. Therefore, Hm / Hf is preferably 9% or more and 50% or less with respect to Hm and fan height Hf. The gaps Gs and Gm between the end portion of the suction side curved surface 140a and the side heat exchanger 110a and the machine room side partition plate 160a are made somewhat small because the mouth ring does not move. Further, the gaps Gh and Gp between the propeller fan 130 and the side heat exchanger 110a and the machine room partition plate 160 are almost equal to suck airflow from the side heat exchanger 110a (Gp is almost equal to Gh). Since the fan is a rotating body, it is difficult to control the dimensions, so it is preferable to use 1.5 to 3 times Gs or Gm in order to make it wider and to achieve both airflow enhancement. Further, the maximum diameter position 301 of the propeller fan 130 is preferably approximately half the position of the side heat exchanger 110a in order to increase the airflow from the side heat exchanger 140a. Further, the maximum diameter position 302 of the propeller fan 130 is on the extension line of the partition plate 160b, and the airflow from the rear heat exchanger 110b located in the shadow of the partition plate is secured.

FIG. 4 shows an example of the result of improving the air permeability in the side surface heat exchanger 110a with the above configuration. If an axis is provided with a central section in the direction away from the front panel 101 as shown in the axis 301 of FIG. 3, the front panel is provided at the position where the maximum wind speed is obtained by standardizing the maximum wind speed as 1. Move away from the position. When the end surface of the suction curved surface portion 140a of the mouth ring 140 is set to 0, the side heat exchanger 110a is wrapped by the mouth ring 140 at a value smaller than 0. Compared to the conventional example, in the present invention, the curvature of the mouth ring suction inlet 140a is appropriate and the diameter of the propeller fan 130 is large, so that the wind speed at the end of the lap portion is large and at a position away from the lap. The wind speed is high. Also, because the suction side curved surface 140a is appropriately formed, it is regularized by flowing along the curved surface, and the back side of the wrapped mouth ring is not a simple turbulent vortex flow, but from the vortex flow and the side heat exchanger. The suction air merges and the side heat exchanger becomes an air flow that promotes heat exchange even in the shadow portion of the mouth ring. Furthermore, this vortex merges with the airflow of the suction and becomes an airflow that accelerates the suction air. Therefore, it contributes to improved heat exchange performance.
On the other hand, in this example, not only the heat exchange performance was improved, but also the performance as a blower was improved. Fig. 5 and Fig. 6 show graphs of the input to the fan motor and the noise measurement results against the air volume. The air volume is indicated by Q, the minimum and maximum values under actual use conditions. In this example, both input and noise were reduced in the entire air volume range compared to the conventional example. For example, at an intermediate airflow of 0, the input decreased by 6L when the value at the maximum airflow was 100L, and the noise decreased by 1N when the value at the maximum airflow was 10N. Input reduction contributes directly to the energy-saving performance of air conditioners. Noise reduction contributes to the improvement of user comfort, and even if it is used as the same noise, heat exchange performance can be improved by increasing the air volume, contributing to energy saving performance.

  7 and 8 show a comparison of the air blowing performance with the case where the propeller fan 130 is not wrapped according to the present embodiment. The ratio Hm / Hf is the ratio of the amount Hm of the propeller fan 130 wrapped by the mouth ring 140 and the height Hf of the propeller fan. Shown as input and noise measurement results. When Rs / Dm, which is the ratio of the curvature Rs of the suction side curved surface of the mouth ring 140 and the maximum diameter Dm of the propeller fan 130 is within the range of the present embodiment, if Hm / Hf is large, the propeller fan 130 Airflow improves directivity and rectification, and reduces input. In the conventional example, Rs / Dm is preferably small. When the Hm / Hf increases beyond the range of the present embodiment, the noise increases when the Hm / Hf increases, because the region where the wind speed is high increases. However, the noise reduction effect can be obtained within the range of the present embodiment. When Rs / D0 is small, the amount of lap by the mouth ring 140 of the propeller fan 130 increases, the wind speed is high, and the interference of the blade tip vortex increases and noise increases. If Rs / D0 is large, the effect does not affect the air blowing performance and does not contribute to the improvement of energy saving performance. In particular, it is generally said that if the diameter of the propeller fan 130 is increased, the rotational speed is reduced and the input is reduced at the same air volume. However, the fan diameter is not simply increased, but the fan diameter is reduced to the suction side as in this embodiment. This is an effect obtained by securing the curvature of the suction surface of the mouth ring at a larger portion.

100 ... outdoor unit, 110a ... side heat exchanger, 110b ... back heat exchanger, 130 ... propeller fan, 140 ... mouth ring, 160 ... machine room divider.

Claims (2)

It has a heat exchanger on the side and back, a propeller fan as a blower that sucks and discharges airflow from the heat exchanger, a mouth ring that is a fan casing, and a machine room that houses a compressor,
The mouth ring wraps a part of the discharge side of the propeller fan and expands on the suction side, and the propeller fan has an outer diameter that increases from the expanded portion to the suction side, and the side heat exchanger and An outdoor unit of an air conditioner characterized by being close to a machine room.   According to claim 1, the gaps Gs and Gm of the widened portion and the side heat exchanger and the machine room, and the gap Gh and Gp of the propeller fan and the side heat exchanger and the machine room, and the height Hf of the propeller fan and the mouth ring Rs / Dm is 3% or more and 15% or less, Hm / Hf is 9% or more and 50% or less, Gp is almost equivalent to Gh, and the lap amount is Hm and the maximum diameter Dm of the propeller fan. Gm is an outdoor unit of an air conditioner characterized in that it is about 1.5 to 3 times Gs or Gm.