CN108731131B - Chassis structure, air conditioner outdoor unit and air conditioner - Google Patents

Chassis structure, air conditioner outdoor unit and air conditioner Download PDF

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Publication number
CN108731131B
CN108731131B CN201810854240.6A CN201810854240A CN108731131B CN 108731131 B CN108731131 B CN 108731131B CN 201810854240 A CN201810854240 A CN 201810854240A CN 108731131 B CN108731131 B CN 108731131B
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China
Prior art keywords
chassis
annular protrusion
air conditioner
spacer
outdoor unit
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CN201810854240.6A
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CN108731131A (en
Inventor
卢超群
董宏达
刘武祥
杨霄
田振
林盖
周杨
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Aux Air Conditioning Co Ltd
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Aux Air Conditioning Co Ltd
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Priority to CN201810854240.6A priority Critical patent/CN108731131B/en
Publication of CN108731131A publication Critical patent/CN108731131A/en
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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F1/00Room units for air-conditioning, e.g. separate or self-contained units or units receiving primary air from a central station
    • F24F1/06Separate outdoor units, e.g. outdoor unit to be linked to a separate room comprising a compressor and a heat exchanger
    • F24F1/60Arrangement or mounting of the outdoor unit
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02TCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
    • Y02T10/00Road transport of goods or passengers
    • Y02T10/80Technologies aiming to reduce greenhouse gasses emissions common to all road transportation technologies
    • Y02T10/88Optimized components or subsystems, e.g. lighting, actively controlled glasses

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Other Air-Conditioning Systems (AREA)

Abstract

The invention provides a chassis structure, an air conditioner outdoor unit and an air conditioner, wherein the chassis structure comprises a chassis body, the chassis body is connected with a front panel of the air conditioner outdoor unit through a pump leg bolt, a spacer is arranged on a wind-isolating vertical plate, and the spacer is inserted into a passageway on the chassis body. The chassis structure of the invention utilizes the pump leg bolt to connect the front panel with the chassis, and the integral connection of the front panel and the chassis with the pump leg bolt is realized by extruding the pump leg bolt in the chassis forming process, thereby improving the connection stability of the front panel and the chassis, avoiding loosening and reducing the installation procedure of the outdoor unit; the spacer is additionally arranged on the wind-isolating vertical plate to extend the wind-isolating vertical plate into the passageway on the chassis body, so that the full sealing of the compressor is realized, and insects are prevented from entering the compressor to influence the operation of the compressor.

Description

Chassis structure, air conditioner outdoor unit and air conditioner
Technical Field
The invention relates to the technical field of air conditioners, in particular to a chassis structure, an air conditioner outdoor unit and an air conditioner.
Background
In the existing air conditioner outdoor unit, the chassis is connected with the front panel through threads, after the air conditioner outdoor unit is used for a long time, a thread fastener for connecting the chassis and the front panel can generate a thread slipping phenomenon, so that the chassis and the front panel are connected loose, and the front panel falls off over time, thereby influencing the operation of the outdoor unit.
Disclosure of Invention
In view of the above, the present invention is directed to a chassis structure for solving the problem that the fixed connection between the chassis and the front panel is loose after the outdoor unit of an air conditioner is used for a long time.
In order to achieve the above purpose, the technical scheme of the invention is realized as follows:
the chassis structure comprises a chassis body, wherein the chassis body is connected with a front panel of an air conditioner outdoor unit through a pump leg bolt, a spacer is arranged on a wind isolating vertical plate, and the spacer is inserted into a passageway on the chassis body.
Further, the pump leg bolt comprises a round table and an annular protrusion, wherein the annular protrusion is arranged at the lower end of the round table, and when the pump leg bolt is subjected to pressure, the annular protrusion deforms and extends radially to the annular protrusion.
Further, the annular bulge is a hollow circular ring, and the round table coincides with the axis of the annular bulge.
Further, the diameter of the round table is larger than that of the annular protrusion.
Further, as the distance from the circular truncated cone increases, the inner diameter of the annular protrusion gradually increases.
Furthermore, the passageway is provided with a plug-in groove, and the spacer is inserted into the plug-in groove.
Further, the cutting is additionally arranged on the spacer, the spacer is movably connected with the wind-isolating vertical plate, and the height position of the spacer on the wind-isolating vertical plate is adjustable.
Further, the spacer is provided with a special-shaped opening, the wind-isolating vertical plate is inserted into the special-shaped opening, and the distance between the middle parts of the special-shaped opening is smaller than the distance between the two ends.
Compared with the prior art, the chassis structure has the following advantages:
(1) According to the chassis structure, the annular protrusions are arranged on the pump leg bolts, the pump leg bolts are used for connecting the front panel with the chassis, the front panel and the chassis are connected with the pump leg bolts in a non-welding mode through the annular protrusions of the extrusion pump leg bolts, the integral connection of the front panel and the chassis is achieved, looseness is avoided, and the stability of the connection of the front panel and the chassis is improved.
(2) The chassis structure of the invention completes the integral connection of the chassis and the front panel in the process of chassis molding, reduces the assembly procedures of the chassis and the front panel, and improves the production efficiency.
(3) The chassis structure of the invention is characterized in that the wind-isolating vertical plate is additionally provided with the spacer to extend the wind-isolating vertical plate into the passageway on the chassis body, so that the full sealing of the compressor is realized, and insects are prevented from entering the compressor to influence the operation of the compressor.
Another objective of the present invention is to provide an outdoor unit of an air conditioner, which solves the problem that the fixed connection between the chassis and the front panel is loose after the outdoor unit of the air conditioner is used for a long time.
In order to achieve the above purpose, the technical scheme of the invention is realized as follows:
an air conditioning outdoor unit comprising the chassis structure of any one of the above.
The air conditioner outdoor unit and the chassis structure have the same advantages compared with the prior art, and are not described in detail herein.
The invention also provides an air conditioner to solve the problem that the fixed connection between the chassis and the front panel is loose after the air conditioner outdoor unit is used for a long time.
In order to achieve the above purpose, the technical scheme of the invention is realized as follows:
an air conditioner comprises an air conditioner indoor unit and the air conditioner outdoor unit, wherein the air conditioner indoor unit is communicated with the air conditioner outdoor unit through a pipeline.
The air conditioner has the same advantages as the air conditioner outdoor unit compared with the prior art, and the description thereof is omitted.
Drawings
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention. In the drawings:
fig. 1 is a schematic structural view of a pump leg bolt according to embodiment 1 of the present invention;
FIG. 2 is a schematic view showing the structure of an annular protrusion according to embodiment 2 of the present invention;
FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2;
FIG. 4 is a schematic view showing the structure of an annular protrusion according to embodiment 6 of the present invention;
FIG. 5 is a schematic view showing the structure of an annular protrusion according to embodiment 7 of the present invention;
FIG. 6 is a cross-sectional view taken along line B-B of FIG. 5;
FIG. 7 is a schematic view showing the structure of an annular protrusion according to embodiment 10 of the present invention;
FIG. 8 is a schematic view showing the structure of a chassis according to embodiment 11 of the present invention;
fig. 9 is a schematic structural view of the chassis body in embodiment 12 and embodiment 14 of the present invention;
FIG. 10 is a schematic view showing the structure of the chassis in embodiment 14 of the present invention;
fig. 11 is a schematic structural view of a chassis structure according to embodiment 15 of the present invention;
FIG. 12 is an enlarged view of a portion of the portion of FIG. 11I in example 16 of the present invention;
FIG. 13 is a schematic cross-sectional view of a reinforcing bar according to embodiment 17 of the present invention;
FIG. 14 is an enlarged view of a portion of FIG. 11I in example 19 of the present invention;
FIG. 15 is an enlarged view of a portion of FIG. 11I in embodiment 20 of the present invention;
FIG. 16 is an enlarged view of a portion of FIG. 11I in example 21 of the present invention;
FIG. 17 is an enlarged view of part of the portion I of FIG. 11 in example 22 of the present invention;
FIG. 18 is an enlarged view of a portion of FIG. 11I in another aspect of embodiment 22 of the present invention;
FIG. 19 is an enlarged view of a portion of I in FIG. 11 in example 23 of the present invention;
FIG. 20 is a schematic cross-sectional view of a reinforcing bar according to embodiment 24 of the present invention;
FIG. 21 is an enlarged view of a portion of FIG. 11 at I in example 25 of the present invention;
fig. 22 is a schematic structural diagram of an outdoor unit chassis of an air conditioner according to embodiment 26 of the present invention;
FIG. 23 is a partial view of embodiments 27 to 30 of the present invention at a diversion ramp;
FIG. 24 is a cross-sectional view of the deflector incline plane of example 31 along the length of the chassis;
FIG. 25 is a partial view of the flow ramp according to embodiment 32 of the present invention;
FIG. 26 is a cross-sectional view of the deflector incline plane of example 34 of the present invention along the width of the chassis;
FIG. 27 is a partial isometric view of a chassis insect control structure according to embodiment 35 of the present invention;
FIG. 28 is an enlarged view of part of the portion of FIG. 27 at I in example 36 of the present invention;
FIG. 29 is an enlarged view of a portion of FIG. 27 at I in example 37 of the present invention;
FIG. 30 is an enlarged view of a portion of FIG. 27 at I in example 38 of the present invention;
FIG. 31 is an enlarged view of a portion of FIG. 27 at I in example 39 of the invention;
FIG. 32 is a schematic diagram of a card slot in embodiment 39 of the present invention;
FIG. 33 is an enlarged view of a portion of FIG. 27 at I in embodiment 40 of the present invention;
FIG. 34 is an enlarged view of a portion of FIG. 27 at I in example 41 of the present invention;
FIG. 35 is an enlarged view of a portion of FIG. 27 showing an alternative embodiment 41 of the present invention;
FIG. 36 is a schematic view showing the structure of a separator in example 42 of the present invention;
FIG. 37 is a front view of a separator according to embodiment 43 of the present invention mounted on a wind riser;
FIG. 38 is a side view of a septum of embodiment 43 of the present invention mounted on a riser;
FIG. 39 is a partial isometric view of a chassis insect control structure in accordance with example 44 of the invention;
FIG. 40 is an enlarged view of a portion of FIG. 39I in both embodiment 45 and embodiment 46 of the present invention;
FIG. 41 is an enlarged view of a portion of FIG. 39 at I in example 47 of the invention;
FIG. 42 is a schematic diagram showing the structure of a weep hole in an embodiment 48 of the present invention;
FIG. 43 is a top view of the attachment slot of example 49 of the present invention at the weep hole;
fig. 44 is a top view of a mating groove at a weep hole according to another embodiment 49 of the present invention.
Reference numerals illustrate:
211-chassis body, 2111-chassis bottom, 2112-chassis first rim, 2113-chassis second rim, 2118-drainage, 2119-drainage, 213-stiffener, 2131-first stiffener, 2132-second stiffener, 2133-stiffener, 2134-cross section, 2135-recess, 2136-gusset, 214-diversion ramp, 2141-overflow hole, 215-support boss, 216-aisle, 2161-mating groove, 2162-water seepage hole, 2163-mating groove side wall, 217-fold-over tab, 2171-seventh through hole, 2172-snap groove, 23-wind-blocking riser, 233-spacer, 2331-stiffener, 2332-third stiffener, 25-pumping bolt, 251-bolt body, 252-253-annular boss, 2531-hollow, 2532-arc piece, 2533-inclined face, 2534-pressing control, 2535-pressing portion.
Detailed Description
It should be noted that, without conflict, the embodiments of the present invention and features of the embodiments may be combined with each other.
In addition, all directions or positional relationships mentioned in the embodiments of the present invention are positional relationships based on the drawings, and the "up-down, left-right, front-rear" coordinate systems appearing in the drawings are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention.
For convenience of description, five surfaces constituting the casing of the outdoor unit of the air conditioner will be referred to as: the air conditioner comprises a chassis, a top cover plate, a front panel, a left side plate and a right side plate, wherein the front panel is a plate body where an air outlet of an air conditioner outdoor unit is positioned; the left side plate is a plate body on the left side of the front panel when the left side plate is right seen from the front panel of the air conditioner outdoor unit; the right side plate is a plate body on the right side of the front panel when the right side plate is right looking at the front panel of the air conditioner outdoor unit; the chassis is a plate body positioned at the bottom when the air conditioner outdoor unit is normally placed; the top cover plate is a plate body positioned at the top when the air conditioner outdoor unit is normally placed.
The technical features and advantages of the present invention are described in more detail below with reference to the accompanying drawings.
Example 1
As shown in fig. 1, a schematic structural view of the pump leg bolt 25 of the present invention is shown. The pump leg bolt 25 includes a circular table 252 and an annular protrusion 253, the annular protrusion 253 is disposed at the lower end of the circular table 252, and the annular protrusion 253 deforms and extends radially to the annular protrusion 253 when receiving pressure.
In the chassis forming process, the annular protrusion 253 is inserted into a chassis hole, the round table 252 is pressed on the chassis and runs downwards, the lower die is propped against the annular protrusion 253, the annular protrusion 253 is extruded by the round table 252 in the downward movement process of the upper die, so that the annular protrusion 253 is deformed, the material around the annular protrusion 253 radially extends to the annular protrusion 253, the annular protrusion 253 is flattened to be attached to the bottom surface of the chassis, and after the chassis is formed, the pump leg bolt 25 is connected with the chassis.
Thus, due to the annular protrusion 253, the pump leg bolt 25 in the embodiment has the function of completing the connection between the pump leg bolt 25 and the chassis in the chassis molding process, so that the molding process of the chassis and the pump leg bolt 25 is reduced, and the production efficiency is improved. In the extrusion process, pressure can impact the internal stress structure of the annular protrusion 253, and as the annular protrusion 253 is inserted into the chassis hole, the chassis hole can generate a reaction force to offset a part of impact received by the stress structure of the annular protrusion 253, so that the risk of structural fracture of the annular protrusion 253 in the extrusion process is reduced. And annular bulge 253 sets up in the lower extreme of round platform 252, and annular bulge 253 can not influence the major structure of pump foot bolt 25 after taking place deformation, and then can not influence the connection, the fixed action of pump foot bolt 25 as the fastener, and the suitability of pump foot bolt 25 is stronger.
In addition, the annular protrusion 253 is of a hollow structure, so that the extrusion force required in the chassis forming process can be greatly reduced, the requirement on processing equipment is low, and the fault tolerance is high; during the collapsing process, the annular protrusion 253 extends radially outward with less stress structure variation, reducing the risk of structural fracture.
Example 2
As described above for the pump leg bolt 25, the present embodiment is different from the above in that, as shown in connection with fig. 1, the pump leg bolt 25 in the present embodiment includes a bolt body 251, a circular truncated cone 252, and an annular protrusion 253. The round table 252 is a solid cylinder, the annular bulge 253 is a hollow circular ring, and the hollow structure of the annular bulge 253 enables the annular bulge 253 to be easier to deform when being stressed. As shown in fig. 2, the annular protrusion 253 in this embodiment includes a hollow portion 2531, and the hollow portion 2531 is cylindrical, so that the material around the annular protrusion 253 is uniformly distributed, and the material is convenient to uniformly extend in the radial direction in the extrusion process.
The upper end of round platform 252 and the lower extreme integrated into one piece of bolt body 251, the lower extreme integrated into one piece of round platform 252 and the upper end of annular protruding 253, the connection between bolt body 251, round platform 252, the annular protruding 253 is comparatively firm, the structure is comparatively stable like this. The diameter of the circular table 252 is larger than that of the annular protrusion 253, so that after the annular protrusion 253 is inserted into the chassis hole, the circular table 252 can abut against the upper surface of the chassis, and the annular protrusion 253 is positioned; and the annular protrusion 253 can be fixed in position by pressing the circular table 252 during the pressing process. The axis of the round table 252 coincides with the axis of the annular protrusion 253, so that the annular protrusion 253 is stressed uniformly in the extrusion process and can extend radially uniformly.
Thus, the hollow portion 2531 of the annular protrusion 253 in this embodiment is cylindrical, so that the material around the annular protrusion 253 can be uniformly extended in the radial direction during the extrusion process, and the connection between the pump leg bolt 25 and the chassis is also relatively firm.
Example 3
As described above, the pump leg bolt 25 according to the present embodiment is different from the above embodiment in that the annular protrusion 253 is internally provided with a plurality of reinforcing ribs, and the reinforcing ribs are integrally formed with the inner wall of the hollow portion 2531. The ribs prevent the annular protrusion 253 from extending radially inward after compression during extrusion. The reinforcing ribs are uniformly distributed inside the annular protrusions 253, are parallel to each other, and the planes of the reinforcing ribs are perpendicular to the cross section of the annular protrusions 253, so that the arrangement can ensure that a small number of reinforcing ribs are used and the effect of the reinforcing ribs that the annular protrusions 253 extend inwards in the radial direction after being pressed can be fully exerted. In this way, not only is material saved, but also the molding effect of the pump leg bolt 25 and the chassis is ensured.
Example 4
As described above, the pump leg bolt 25 is different from the present embodiment in that the annular protrusion 253 is internally provided with a supporting frame, the supporting frame and the annular protrusion 253 are integrally formed, and the end portions of the supporting frame are fixed on the inner wall of the hollow portion 2531. The support shelf may further prevent the annular protrusion 253 from extending radially inward after compression during extrusion. In this way, the molding effect of the pump leg bolt 25 and the chassis can be further ensured. In this embodiment, the preferred support frame is a cross structure, and the end parts of the cross structure are integrally formed with the inner wall of the hollow part 2531, so that the stability of the structure is ensured. The support frame is positioned in a plane parallel to the cross section of the annular protrusion 253 to maximize the support effect of the support frame.
Example 5
As described above for the pump leg bolt 25, this embodiment is different from the above in that, as shown in connection with fig. 3, the inner diameter of the annular protrusion 253 gradually increases with increasing distance from the circular truncated cone 252, and the outer diameter remains unchanged. The inner diameter is the diameter of the cross section of the hollow portion 2531, and the outer diameter is the diameter of the outer circle of the cross section of the annular protrusion 253. Because the internal diameter of annular bulge 253 increases gradually, hollow portion 2531 is loudspeaker form, and annular bulge 253 can be comparatively easy when the atress radially extend outward, has reduced the extrusion force that needs in the chassis shaping in-process, and is low to the requirement of processing equipment, has reduced the shaping degree of difficulty of pump foot bolt 25 and chassis, and fault tolerance is high.
Example 6
As described above for the pump leg bolt 25, this embodiment is different from the above embodiment in that, as shown in fig. 4, the inner diameter and the outer diameter of the annular protrusion 253 are gradually increased with the distance from the circular table 252. The annular bulge 253 and the hollow portion 2531 in the embodiment are both in a horn shape, and the annular bulge 253 can extend to the radial outside more easily when being stressed, so that the extrusion force required in the chassis forming process is further reduced, the requirement on processing equipment is low, and the forming difficulty of the pump leg bolt 25 and the chassis is reduced to a greater extent.
Example 7
As described above, the present embodiment is different from the pump leg bolt 25 in that, as shown in connection with fig. 5, the annular protrusion 253 is provided with slits dividing the annular protrusion 253 into a plurality of arc-shaped pieces 2532. The mechanical connection between the arc-shaped parts 2532 on the two sides of the fine seam of the annular protrusion 253 can be eliminated by the fine seam on the annular protrusion 253, and the arc-shaped parts 2532 are easier to deform when being stressed, so that the annular protrusion 253 is easier to deform when being stressed, the extrusion force required in the chassis forming process is further reduced, and the forming difficulty of the pump leg bolt 25 and the chassis is further reduced.
Example 8
As described above, the pump leg bolt 25 of the present embodiment is different from the above-described embodiment in that, as shown in fig. 6, the inner side of the end of the annular protrusion 253 remote from the circular truncated cone 252 is an inclined surface 2533, and the inclined surface 2533 is inclined in the radial direction of the annular protrusion 253. In the process of stressing the annular protrusion 253, as the inner side of one end of the annular protrusion 253 far away from the circular table 252 is the inclined surface 2533, the area of the contact surface between the lower end of the annular protrusion 253 and the lower chassis die is smaller, and the friction force applied to the lower end of the annular protrusion 253 by the lower chassis die is smaller, and the friction force has the function of preventing the annular protrusion 253 from extending to the radial direction of the annular protrusion 253. Thus, the annular protrusion 253 can extend radially outwards more easily when being stressed, so that the extrusion force required in the chassis forming process is further reduced, and the forming difficulty of the pump leg bolt 25 and the chassis is further reduced.
Example 9
As with the pump leg bolt 25 described above, this embodiment differs therefrom in that the end of the arcuate member 2532 remote from the boss 252 is curved radially of the annular projection 253. Like this, arc 2532 can be easier when the atress extend to radial outside to annular protruding 253 also is easier when the atress extend to radial outside, has further reduced the extrusion force that needs in chassis shaping in-process, has further reduced the shaping degree of difficulty of pump foot bolt 25 and chassis.
Example 10
As described above, the pump leg bolt 25 of the present embodiment is different from the above-mentioned embodiment in that, as shown in fig. 7, a pressure control member 2534 is further disposed in the annular protrusion 253, the pressure control member 2534 includes a pressing portion 2536 and a plurality of abutting portions 2535, the pressing portion 2536 extends out of the annular protrusion 253 from an axis of the annular protrusion 253, and the abutting portions 2535 are respectively fixed on an inner side of each arc-shaped member 2532 and integrally formed with the arc-shaped members 2532. In the extrusion process, the lower die first abuts against the extrusion portion 2536, and after the extrusion portion 2536 is stressed, the acting force is transmitted to the arc-shaped member 2532 through the abutting portion 2535, so that the arc-shaped member 2532 bends towards the radial direction or the periphery of the annular protrusion 253. Like this, owing to the effect of pressure control 2534, arc 2532 can be easier extend radially outwards, has further reduced the extrusion force that needs in chassis shaping in-process, has further reduced the shaping degree of difficulty of pump foot bolt 25 and chassis.
Example 11
The chassis structure of the outdoor unit of the present embodiment is used for solving the problem of poor molding process effect between the chassis body 211 and the front panel of the outdoor unit of the air conditioner. As shown in fig. 8, a schematic structural view of the chassis structure of the present invention is shown. The chassis structure comprises a chassis body 211 and a pump leg bolt 25, wherein the chassis body 211 is connected with a front panel of the air conditioner outdoor unit through the pump leg bolt 25.
It should be noted that, embodiments 1 to 10 mainly solve the problems of a plurality of molding processes and low production efficiency between the pump leg bolt 25 and the chassis, and the chassis in embodiments 1 to 10 may be replaced by the chassis body 211 and the front panel of the outdoor unit of the air conditioner in the present embodiment.
Like this, chassis body 211 passes through pump foot bolt 25 and links to each other with the front panel of air condensing units, can accomplish the connection of pump foot bolt 25 and chassis body 211 and the integration of chassis body 211 and front panel when chassis body 211 shaping, has reduced the shaping technology between chassis body 211 and the front panel, has improved production efficiency. And the chassis body 211 is integrated with the front panel, and compared with the prior clamping, screw connection and other modes, the connecting structure between the chassis body 211 and the front panel of the air conditioner outdoor unit can not loosen, thereby improving the stability of the structure of the air conditioner outdoor unit and being beneficial to prolonging the service life of the air conditioner outdoor unit.
Example 12
As described above, the present embodiment is different from the chassis structure described above in that, as shown in fig. 9, the chassis includes a chassis body 211, the chassis body 211 includes a turnup edge 217, and the turnup edge 217 is perpendicular to the chassis body 211 and is integrally formed with the chassis body 211. The flanging 217 is provided with a circular seventh through hole 2171, and the diameter of the seventh through hole 2171 is slightly larger than that of the annular protrusion 253, so that the annular protrusion 253 can be conveniently and exactly inserted into the seventh through hole 2171, and the annular protrusion 253 is prevented from shaking. The front panel of the air conditioner outdoor unit is provided with a matching hole at a position corresponding to the seventh through hole 2171.
In the process of forming the front panel and the chassis body 211 of the outdoor unit of the air conditioner, the annular protrusion 253 is inserted into the seventh through hole 2171 and then inserted into the mating hole of the front panel. The first mold for molding presses the circular table 252 and moves leftwards (leftwards as shown in fig. 8), the second mold abuts against the annular protrusion 253, the first mold presses the annular protrusion 253 through the circular table 252 in the leftward movement process, the annular protrusion 253 is deformed, materials around the annular protrusion 253 extend radially to the annular protrusion, the annular protrusion 253 is flattened to be attached to the left side face of the front panel, and after the chassis body 211 is molded, the chassis body 211 is connected with the front panel.
Example 13
As described above, the chassis structure in this embodiment is different from the above-described chassis structure in that the outer wall of the annular protrusion 253 is provided with a cutting, the seventh through hole 2171 is provided with a slot adapted to the cutting, and the cutting and the annular protrusion 253 are integrally formed, so as to form a stable structure. During the extrusion process, the pressure may cause the annular protrusion 253 to rotate within the seventh through hole 2171, affecting the molding process between the front panel and the pump leg bolt 25. In this embodiment, due to the cooperation of the insert and the slot, the annular protrusion 253 is prevented from rotating, so that the molding process of the front panel and the pump leg bolt 25 is ensured to be smoothly performed.
It should be noted that, in this embodiment, the insert may be disposed on an inner wall of the seventh through hole 2171 and integrally formed with the seventh through hole 2171, and the slot may be disposed on an outer wall of the annular protrusion 253.
Example 14
As described above, the chassis structure of this embodiment is different from the above structure in that, as shown in fig. 9, the hinge 217 is provided with a clamping groove 2172 adapted to the round table 252. As shown in fig. 10, the shape and the size of the clamping groove 2172 are the same as those of the round table 252, the round table 252 is embedded in the clamping groove 2172, and the side surface of the round table 252 is flush with the surface of the turnover sheet 217, and is the side surface of the round table 252 away from the annular protrusion 253. In the extrusion process, the structure of the round table 252 may be damaged by excessive pressure, and in this embodiment, the round table 252 is embedded into the clamping groove 2172, so that the pressure applied to the round table 252 is reduced, and the clamping groove 2172 plays a role in protecting the structure of the round table 252, so that the structural damage of the round table 252 can be avoided. And the circular table 252 is embedded into the clamping groove 2172, so that the firmness of the chassis structure is enhanced, and the shaking of the pump leg bolt 25 in the seventh through hole 2171 can be avoided.
Example 15
The air condensing units chassis that this embodiment provided is mainly used to solve the problem that the air condensing units chassis is easy to deform because of insufficient strength in the side close to the front panel, as shown in fig. 11, the technical scheme that this embodiment adopts is: the chassis of the outdoor unit of the air conditioner comprises a chassis body 211, and a reinforcing rib 213 is arranged on one side of the chassis body 211 close to the front panel of the outdoor unit. The strength of the outdoor unit chassis at the side close to the front panel is enhanced by providing the reinforcing ribs 213.
Example 16
As shown in fig. 12, the difference between the present embodiment and the above embodiment is that the stiffener 213 in the present embodiment includes the first stiffener 2131 and the second stiffener 2132, and the first stiffener 2131 and the second stiffener 2132 are fixedly connected, and the manner of fixing connection may be welding or integrally forming, and the present embodiment is preferably integrally forming, which makes the structure of the stiffener 213 simple and easy to process. The chassis body 211 has a rectangular parallelepiped structure, and includes a chassis bottom surface 2111 and a chassis first frame 2112 perpendicular to the bottom surface 2111, and the frame 2112 is located in the length direction of the chassis body 211. The first reinforcing ribs 2131 are located on the chassis bottom surface 2111 and perpendicular to the chassis first side frame 2112, and the second reinforcing ribs 2132 are located on the chassis first side frame 2112 and perpendicular to the chassis bottom surface 2111, i.e. the reinforcing ribs 213 extend from the upper edge of the chassis first side frame 2112 to the chassis bottom surface 2111. In this way, not only the strength of the chassis bottom surface 2111 is reinforced, but also the strength of the chassis first side frame 2112 is increased. Because the chassis and the front panel of the outdoor unit are fixedly connected at the first frame 2112 of the chassis, the strength of the connection between the chassis and the front panel of the outdoor unit is also improved by the arrangement of the reinforcing ribs 213, so that the connection between the chassis and the front panel of the outdoor unit is not easy to deform when being impacted.
Further, the reinforcing rib 213 may be extended from the chassis body 211 to the connection position between the front panel of the outdoor unit and the chassis body, i.e. the reinforcing rib 213 is added on the front panel of the outdoor unit corresponding to the reinforcing rib 213 on the chassis body 211, so as to enhance the strength of the connection position between the front panel of the outdoor unit and the chassis body 211.
When the reinforcing ribs 213 on the chassis body 211 are improved, the reinforcing ribs 213 on the front panel of the outdoor unit are adaptively improved, so that the strength of the joint of the chassis body 211 and the front panel of the outdoor unit is improved.
Example 17
As shown in fig. 13, this embodiment is different from the above embodiment in that the cross section 2134 of the reinforcing rib 213 in this embodiment has a trapezoid structure with an open bottom side, and the raised edges of the reinforcing rib 213 are rounded. The rounding treatment can reduce the concentrated stress at the bending position of the reinforcing rib 213 on one hand, and prevent the bending position of the reinforcing rib 213 from breaking due to larger concentrated stress when the reinforcing rib 213 is impacted; on the other hand, the chamfering operation eliminates the edges of the reinforcing ribs 213, so that all the surfaces on the reinforcing ribs 213 are in smooth transitional connection, thereby improving the aesthetic degree of the reinforcing ribs 213, preventing the cutting in the process of assembling or disassembling the outdoor unit, and improving the safety of the assembling or disassembling operation.
Example 18
The difference between this embodiment and the above-mentioned embodiment is that the intervals between the reinforcing ribs 213 in this embodiment are equal, so that the arrangement is not only attractive, but also the chassis can uniformly absorb the impact force received, and the chassis is prevented from being deformed due to uneven stress.
Example 19
As shown in fig. 14, this embodiment is different from the above-described embodiment in that the reinforcing ribs 213 in this embodiment are provided on the chassis bottom surface 2111, and the chassis first side frame 2112 is not provided. The reinforcing ribs 213 are only arranged on the bottom surface 2111 of the chassis, so that the strength of the chassis body 211 on the side close to the front panel can be enhanced, the processing steps are reduced, raw materials are saved, and the production cost is reduced.
Example 20
As shown in fig. 15, this embodiment is different from the above-described embodiment in that the reinforcing ribs 213 in this embodiment are provided obliquely on the chassis bottom surface 2111. The reinforcing ribs 213 may be inclined to the left or to the right. Because of the limitation of the structure, the space on the chassis body 211 near the front panel is usually smaller, and the reinforcing ribs 213 are obliquely arranged, so that longer reinforcing ribs 213 can be formed, and the strength of the chassis body 211 is further improved.
Similarly, the reinforcing ribs 213 may be disposed obliquely to the chassis first side frame 2112, or to the chassis bottom surface 2111 and the chassis first side frame 2112.
Example 21
As shown in fig. 16, the present embodiment is different from the above-described embodiment in that the reinforcing ribs 213 in the present embodiment are provided on the chassis first side frame 2112, and are not provided on the chassis bottom surface 2111. The reinforcing ribs 213 are only arranged on the first side frame 2112 of the chassis, so that the strength of the chassis body 211 on the side close to the front panel can be enhanced, the processing steps are reduced, raw materials are saved, and the production cost is reduced.
Example 22
As shown in fig. 17, this embodiment is different from the above embodiment in that the reinforcing strips 2133 are added to the edges of the reinforcing ribs 213 in this embodiment. The reinforcing bars 2133 serve to increase the strength of the reinforcing bars 213, thereby further increasing the strength of the chassis body 211. Specifically, the reinforcement bars 2133 are formed by extending the edges of the first reinforcement bars 2131 along the length direction of the chassis body 211, and the reinforcement bars 213 with the reinforcement bars 2133 are in a cross structure, so that the strength is high, the impact resistance is strong, and the chassis is not easy to deform when being impacted greatly.
Similarly, the reinforcement bars 2133 may be formed by extending the edges of the second reinforcement bars 2132 along the length of the chassis body 211.
Further, as shown in connection with fig. 18, the reinforcing bars 2133 between the adjacent reinforcing bars 213 are connected to each other. The reinforcing ribs 213 are integrally connected by the reinforcing bars 2133, so that the strength of the reinforcing ribs 213 is improved, and the strength of the chassis body 211 is further improved.
Example 23
As shown in fig. 19, this embodiment is different from the above embodiment in that the reinforcing ribs 213 in this embodiment are welded to the chassis first side frame 2112. The reinforcing rib 213 and the chassis first side frame 2112 form a four-sided enclosed structure, which strengthens the strength of the joint of the reinforcing rib 213 and the chassis body 211, so that the joint of the reinforcing rib 213 and the chassis body 211 is not easy to deform in an outward expansion manner when the chassis body 211 is impacted. In addition, the connection mode of the reinforcing ribs 213 and the chassis body 211 is set to be welding, so that the chassis body 211 can be made into a general structure, different numbers of reinforcing ribs 211 are welded on the chassis bodies 211 of different types according to actual needs, or the reinforcing ribs 213 are welded at different positions of the chassis bodies 211 of different types, thereby not only enhancing the strength of the chassis body 211, but also expanding the application range of the chassis body 211 and improving the universality of the chassis body 211.
Similarly, the ribs 213 may be welded to the chassis bottom surface 2111, or welded to both the chassis bottom surface 2111 and the chassis first rim 2112.
Example 24
As shown in fig. 20, the difference between the present embodiment and the above embodiment is that the cross section 2134 of the reinforcing rib 213 in the present embodiment is a U-shaped structure, which may be formed by bending or by rounding, and the present embodiment is preferably formed by bending, and the U-shaped structure of the reinforcing rib 213 is formed by bending, so that the rounding operation can be omitted, the manufacturing process of the chassis body 211 is simplified, and the production efficiency is improved.
Similarly, the cross section 2134 of the reinforcing bead 213 may be provided in a circular arc shape to simplify the processing of the reinforcing bead 213.
Example 25
As shown in fig. 21, the present embodiment is different from the above embodiment in that the reinforcing rib 213 in the present embodiment is provided with the rib plate 2136 in the recess 2135 to increase the strength of the reinforcing rib 213, thereby further increasing the strength of the chassis body 211.
Example 26
The difference with the above embodiment is that the chassis structure provided in this embodiment is mainly used for solving the problem that the accumulated water on the chassis is difficult to drain cleanly, as shown in fig. 22, the technical scheme adopted in this embodiment is as follows: a diversion slope 214 is provided on the chassis body 211, and the diversion slope 214 is inclined from the chassis second frame 2113 in the width direction of the chassis body 211 toward the chassis bottom surface 2111 of the chassis body 211.
The guiding inclined plane 214 is used for guiding the condensed water to flow into the water channel along the guiding inclined plane 214, and the guiding inclined plane 214 is set as an inclined plane, so that the water flow speed of the condensed water dropping onto the guiding inclined plane 214 into the water channel can be increased, and the condensed water can smoothly flow into the water drain hole along the water channel to be discharged.
Example 27
As shown in fig. 23, the difference between the present embodiment and the above embodiment is that the guiding inclined plane 214 in the present embodiment is disposed at the falling position of the condenser in the width direction of the chassis body 211, so as to receive the condensed water generated during the operation of the condenser.
The chassis main body 211 has a rectangular parallelepiped shape as a whole, and is provided with a chassis second frame 2113 and a chassis bottom surface 2111 in the width direction. The highest position of the diversion inclined plane 214 is connected with the chassis second frame 2113, the lowest position of the diversion inclined plane 214 is connected with the chassis bottom surface 2111, and the side edge of the diversion inclined plane 214, which is connected with the highest position and the lowest position, is connected with the chassis first frame 2112.
Example 28
As shown in fig. 23, the difference between the present embodiment and the above embodiment is that the chassis body 211 in the present embodiment is further provided with a condenser supporting convex hull 215, and the supporting convex hull 215 divides the diversion inclined plane 214 into a plurality of sections. The supporting convex hull 215 is used for supporting the condenser, so that the condenser can be stably placed on the chassis body 211.
Specifically, the supporting convex hulls 215 located in the width direction of the chassis body 211 divide the diversion inclined plane 214 into a plurality of sections, so that the supporting convex hulls 215 and the diversion inclined plane 214 at the second frame 2113 of the chassis are arranged in a crossing manner, and therefore, the condenser can be stably placed on the chassis body 211 and can be guided to flow into a water channel rapidly.
The side surface of the supporting convex hull 215 connected to the diversion slope 214 is inclined toward the diversion slope. In this way, the condensed water dropped onto the supporting convex hull 215 can quickly flow onto the diversion slope 214 along the side surface of the supporting convex hull 215, and the drainage efficiency of the chassis body 211 is further improved.
Example 29
As shown in fig. 23, the present embodiment is different from the above embodiment in that the chassis body 211 in the present embodiment is further provided with a drainage surface 2118, and the drainage surface 2118 is fixedly connected with the diversion slope 214. The drain surface 2118 serves to collect and drain condensed water flowing in from the diversion slope 214, and the drain surface 2118 and the diversion slope 214 are provided in fixed connection so as to enhance the connection strength of the diversion slope 214 and the chassis body 211.
Example 30
As shown in fig. 23, this embodiment is different from the above-described embodiment in that a drain hole 2119 is provided in the drain surface 2118 in this embodiment, and the drain hole 2119 discharges condensed water flowing onto the drain surface 2118. A drain hole 2119 is added to further drain the water on the chassis.
The side surface of the supporting convex hull 215 is further connected to the draining surface 2118, and the side surface connected to the draining surface 2118 is inclined toward the draining surface 2118, so that the condensed water dropped onto the supporting convex hull 215 can quickly flow onto the draining surface 2118 along the side surface of the supporting convex hull 215 and drain from the draining hole 2119, further improving the draining efficiency of the chassis body 211.
Example 31
As shown in fig. 24, the difference between the present embodiment and the above embodiment is that the overflow hole 2141 is added on the guiding inclined plane 214 in the present embodiment. By adding the overflow hole 2141, the condensed water on the diversion slope 214 can be discharged from the overflow hole 2141 when flowing through the overflow hole 2141, so that the condensed water flowing through the overflow hole 2141 does not need to flow into the water discharge surface 2118 and is discharged through the water discharge hole 2119, thereby achieving the purpose of further discharging accumulated water on the chassis body 211.
Example 32
As shown in fig. 25, the difference between the present embodiment and the above embodiment is that the guiding inclined plane 214 in the present embodiment is a stepped surface, and the stepped surface is provided with the overflow hole 2141. The arrangement not only quickens the water flow speed of the condensed water which drops onto the diversion inclined plane 214 and flows into the water discharge surface 2118, so that the condensed water can smoothly flow into the water discharge hole 2119 along the water discharge surface 2118 for discharge, but also increases the strength of the diversion inclined plane 214; on the basis, the diversion inclined plane 214 is fixedly connected with the chassis second frame 2113, the side surface of the supporting convex hull 215, the chassis first frame 2112 and the drainage surface 2118, so that the strength of the chassis body 211 is also improved.
Example 33
The present embodiment is different from the above-described embodiment in that the water discharge surface 2118 in the present embodiment is inclined from the center in the width direction of the chassis body 211 toward the chassis first rim 2112. By this arrangement, the drain surface 2118 forms an inclined angle with the bearing surface bearing the chassis of the outdoor unit of the air conditioner, so that the speed of the condensed water flowing from the diversion slope 214 onto the drain surface 2118 flowing into the drain hole 2119 is increased, and the drain hole 2119 is arranged at the lowest position of the drain surface 2118, so that the condensed water is further thoroughly drained.
Example 34
As shown in fig. 26, the difference between the present embodiment and the above embodiment is that the diversion slope 214 in the present embodiment is inclined from the center of the width direction of the chassis body 211 toward the chassis first rim 2112 on the nearer side, and the overflow hole 2141 is located at the lowest position of the diversion slope 214. Thus, the condensed water dropped onto the diversion slope 214 flows into the overflow hole 2141 along the diversion slope 214 to be discharged, and does not need to flow into the water discharge surface 2118 to be discharged through the water discharge hole 2119, so that the water discharge efficiency is improved, and the accumulated water on the chassis body 211 is avoided.
Example 35
The difference from the above embodiment is that the chassis structure provided in this embodiment is mainly used for solving the problem that the chassis of the outdoor unit of the air conditioner cannot prevent insects, as shown in fig. 27, the technical scheme adopted in this embodiment is as follows: the chassis insect prevention structure comprises a wind isolation vertical plate 23, wherein a spacer 233 is arranged on the wind isolation vertical plate 23, and the spacer 233 is inserted into a passageway 216 on the chassis body 211. The air isolation vertical plate 23 is extended into the passageway 216 on the chassis body 211 by additionally arranging the spacer 232 on the air isolation vertical plate 23, so that the full sealing of the compressor is realized, insects are prevented from entering the compressor, and the work of the compressor is influenced.
Example 36
As shown in connection with fig. 28, this embodiment differs from the above-described embodiments in that the shape of the spacer 232 in this embodiment matches the cross-sectional shape of the passageway 216. Thus, the sealing between the spacer 232 and the passage on the chassis body 211 is better, and the insect prevention effect is better.
Example 37
As shown in fig. 29, this embodiment is different from the above embodiment in that reinforcing plates 2331 are provided on both side surfaces of the spacer 233 in this embodiment, and the reinforcing plates 2331 connect the spacer 233 and the aisle. The reinforcing plate 2331 is used for improving the strength of the spacer 233 to reduce shaking of the spacer 233 generated when the spacer 233 vibrates with the compressor, thereby preventing the spacer 233 from breaking during the vibration process and losing the insect-proof effect.
Example 38
As shown in fig. 30, the present embodiment is different from the above embodiment in that the lower end of the spacer 233 in the present embodiment is in contact with the aisle 216, and the lower end of the spacer 233 has a saw-tooth structure. In this way, the condensed water can pass through the gaps between the saw teeth, and meanwhile, the contact seal is formed between the spacer 233 and the passage on the chassis body 211, so that the sealing effect is better, and the insect prevention effect is better.
Example 39
As shown in fig. 31, the present embodiment is different from the above embodiment in that the spacer 233 in the present embodiment is additionally provided with the insert 2332, the wind-blocking riser 23 is additionally provided with the clamping groove 2333, and the insert 2332 is inserted into the clamping groove 2333. In this way, the spacer 233 and the wind isolation vertical plate 23 form movable connection, and the spacer 233 matched with different aisle shapes can be selected according to actual needs, so that the universality of the wind isolation vertical plate 23 is improved.
Specifically, as shown in fig. 32, the locking groove 2333 is an L-shaped groove, and is formed by recessing the spacer 233, and the sealing between the wind blocking vertical plate 23 and the aisle 216 is achieved by inserting the insert bar 2332 into the locking groove 2333, thereby achieving the purpose of insect prevention.
Example 40
As shown in fig. 33, the difference between the present embodiment and the above embodiment is that the clamping groove 2333 in the present embodiment is a U-shaped groove welded on the partition board. Thus, the wind-isolating vertical plate 23 can be made into a general structure, so that the die opening is reduced, and the production cost is reduced; the clamping grooves 2333 can be welded at different positions on the wind isolation vertical plate 23 according to actual needs, or the clamping grooves 2333 with different numbers can be welded on the wind isolation vertical plate 23 so as to adapt to different outdoor unit models.
Example 41
As shown in fig. 34, this embodiment is different from the above embodiment in that a third reinforcing rib 2334 is provided on the spacer 233 in this embodiment, and the third reinforcing rib 2334 is press-molded from the spacer 233. The third reinforcing ribs 2334 improve the strength of the spacer 233, and prevent the spacer 233 from being broken due to severe shaking caused by vibration of the compressor, thereby losing the insect-proof effect; the third reinforcing rib 2334 is manufactured by adopting stamping forming, has a simple structure, is easy to realize, has high production efficiency, and is suitable for mass production.
Further, the third reinforcing rib 2334 may be provided not only on the spacer 233 but also to extend from the lower end of the wind-blocking riser 23 to the spacer 233, as shown in fig. 35, so that the strength of the spacer 233 is enhanced, and the strength of the lower end of the wind-blocking riser 23 is also enhanced to reduce the shaking of the spacer 233.
Example 42
As shown in fig. 36, this embodiment is different from the above-described embodiment in that the spacer 233 in this embodiment is provided with a burring structure. The arrangement of the flanging structure increases the contact area between the spacer 233 and the passageway 216, so that the vertical fixation of the wind-blocking vertical plate 23 on the chassis is more stable.
Example 43
As shown in fig. 37, the difference between the present embodiment and the above embodiment is that a plurality of spacers 233 are disposed under the wind-isolation riser 23 in the present embodiment, the spacers 233 are movably connected with the wind-isolation riser 23, and the height position of the spacers 233 inserted on the wind-isolation riser 23 is adjustable. So set up, not only can reach the protection against insects effect, still realized the spacer 233 to the self-adaptation adjustment of different passageway 216 shapes, like this, can make the passageway 216 of different shapes through adjusting spacer 233 with the wind-proof riser 23 into general structure, improved the commonality of wind-proof riser 23.
As shown in fig. 38, the spacer 233 is of a bilaterally symmetrical clip structure, a special-shaped opening is formed in the spacer 233, the upper end of the special-shaped opening is V-shaped, the spacer riser 23 is conveniently guided to be inserted into the spacer 233, the distance between the middle parts of the special-shaped opening is smaller than the distance between the two ends, and the minimum distance between the middle parts is smaller than the thickness of the spacer riser 23, so that the spacer riser 23 can be clamped by the minimum distance between the middle parts of the special-shaped opening and cannot slide down when being inserted into the spacer 233, and the depth of the special-shaped opening can meet the requirements of the spacer 233 on different positions of the channel 216 so as to realize self-adaptive adjustment.
The principle of the spacer 233 to achieve adaptive adjustment is: when installing the wind-proof riser 23, according to the width of passageway 216, insert corresponding quantity of spacer 233 on wind-proof riser 23, the depth that the wind-proof riser 23 inserted into spacer 233 can be satisfied, this moment the wind-proof riser 23 just is held by spacer 233 can, insert the wind-proof riser 23 with spacer 233 vertically into passageway 216, in this course, spacer 233 moves down along with wind-proof riser 23, spacer 233 that the distance from passageway 216 lateral wall is minimum contacts passageway 216 first, and stop on passageway 216 lateral wall by the hindrance of passageway 216 lateral wall, along with the downward movement of wind-proof riser 23, spacer 233 land is continued to stop on passageway 216 until spacer 233 that is located above the bottom surface of passageway 216 drops to the bottom surface of passageway 216, this moment the wind-proof riser 23 still does not install in place, need continue exerting pressure to impel the downward movement of wind-proof riser 23, along with the downward movement of wind-proof riser 23, the depth that spacer 233 inserted into spacer 233 also increases correspondingly, spacer 233's height on wind-proof riser 23 increases, and until the height of spacer 233 on passageway 216 lateral wall is stopped by passageway 216 lateral wall is stopped, spacer 233 is installed on the bottom surface of passageway 216, the height is adjusted to be in the condition that the vertical flange is contacted with the bottom surface of the upper surface of passageway 216 immediately, the bottom surface is formed by the vertical flange is installed on the bottom surface of the upper side of the vertical flange of the passageway 216, the bottom surface is formed, the height is adjusted.
Further, edges of the spacers 233 are rounded, so that gaps are formed between the respective spacers 233 for the condensed water to pass through. The number of the spacers 233 can be increased or decreased according to practical situations, so as to ensure the sealing between the spacers 233 and the passageway 216, and the gap formed is insufficient for insects to enter, thereby achieving the insect-preventing effect.
Example 44
The difference from the above embodiment is that the chassis structure provided in this embodiment is mainly used to solve the problem that the chassis of the outdoor unit of the air conditioner cannot prevent insects. As shown in fig. 39, the technical scheme adopted in this embodiment is as follows: the chassis insect prevention structure comprises a passage 216, and a plug-in groove 2161 is arranged on the passage 216. The plug-in slot 2161 is used for inserting the spacer 233, so that the spacer 233 and the passageway 216 form a fully sealed structure, and insects are effectively prevented from entering the area where the compressor is located, and the compressor is not affected.
Example 45
As shown in fig. 40, the present embodiment is different from the above embodiment in that the insertion groove 2161 in the present embodiment is recessed by the aisle 216. In this way, after the spacer 233 is inserted into the passageway 216, the spacer 233 is further inserted into the insertion groove 2161, so that the fixing of the wind-isolating vertical plate in the vertical direction of the chassis is firmer, the spacer 233 can be limited from shaking in the length direction of the passageway 216 in the working process of the outdoor unit, and the damage of vibration generated during the operation of the compressor to the spacer 233 is reduced.
Example 46
As shown in fig. 40, the present embodiment is different from the above-described embodiment in that the bottom of the insertion groove 2161 in the present embodiment is provided with the water seepage hole 2162. The water penetration holes 2162 serve to drain condensed water penetrated from a gap between the spacer 233 and the passage 216 so as not to form water accumulation in the insertion groove 2161, corrode the spacer 233 inserted in the insertion groove 2161, and reduce the strength and the like of the spacer 233.
Example 47
As shown in connection with fig. 41, the present embodiment is different from the above-described embodiment in that the plug recess 2161 in the present embodiment includes a recess bottom surface and a plug recess side wall 2163, the recess bottom surface being flush with the bottom surface of the aisle 216, the plug recess side wall 2163 being higher than the bottom surface of the aisle 216. In this way, the shaking of the spacer 233 in the longitudinal direction of the passage 216 is restricted by the insertion groove side wall 2163, and damage to the spacer 233 caused by vibration generated during operation of the compressor is reduced.
Specifically, the plug groove side wall 2163 is connected with the convex hulls on two sides of the passageway 216, so that the strength of the passageway 216 is enhanced, the connection between the plug groove side wall 2163 and the passageway 216 is an arc surface, and the arc surface is tangential to the bottom surface and the side surface of the passageway 216, so that on one hand, the concentrated stress at the connection between the plug groove side wall 2163 and the passageway 216 is reduced, and on the other hand, the contact between the plug groove side wall 2163 and the passageway is formed, the contact area is increased, and the connection between the plug groove side wall 2163 and the passageway 216 is firmer and more stable.
Example 48
As shown in fig. 42, the present embodiment is different from the above-described embodiment in that the water penetration holes 2162 in the present embodiment are zigzag. The serrated water seepage holes 2162 are continuous and dense, so that the contact between the side wall 2163 of the plug slot and the bottom surface of the passageway 216 is ensured, the fixation of the side wall 2163 of the plug slot in the passageway 216 is more stable, and the quick passing of condensed water is facilitated.
Example 49
As shown in fig. 43, the present embodiment is different from the above-described embodiment in that the water penetration holes 2162 in the present embodiment are staggered on the side wall 2163 of the mating groove. The water seepage holes 2162 are arranged in a staggered mode, so that on one hand, condensed water can flow out of the inserting grooves 2161 from the staggered water seepage holes 2162, and on the other hand, the staggered water seepage holes 2162 are opaque on the inserting grooves, so that the sight of insects can be blocked, the insects can be prevented from passing through the front road and abandoning the climbing in, and the insect prevention effect is achieved.
Specifically, the water seepage holes 2162 are staggered and obliquely arranged on the plug slot side walls 2163, the inclined directions of the water seepage holes 2162 on the two plug slot side walls 2163 are opposite, the cross sections of the water seepage holes 2162 are square, U-shaped, V-shaped, semicircular or trapezoid and other common shapes, and the cross sections of the water seepage holes 2162 are smaller, so that insects cannot enter the water seepage holes 2162.
The plug slot side walls 2163 and the spacers 233 are made of the same steel sheet, and have a small thickness, and if staggered water seepage holes 2162 are formed in one plug slot side wall 2163, the operation is complicated, so that the water seepage holes 2162 are arranged on the two plug slot side walls 2163 in a crossing manner, so that the use strength of the plug slot side walls 2163 is ensured. For the plug slot side wall 2163 with a certain thickness, the staggered water seepage holes 2162 on one plug slot side wall 2163 can be adopted to better prevent insects from climbing in.
Similarly, the inclination direction of the water penetration holes 2162 may be set to be the same, so that the purpose of supercooling condensation water passing through the insertion groove 2161 and insect prevention can be achieved.
Further, as shown in fig. 44, the water seepage holes 2162 may be arranged perpendicular to the side wall 2163 of the insertion slot, and the perpendicular water seepage holes 2162 are easy to process with high efficiency, and shorten the flow path of the condensed water in the insertion slot 2161, so as to facilitate the passage of the condensed water.
Example 50
The embodiment provides an air conditioner outdoor unit, which comprises any one of the chassis structures. The air conditioner outdoor unit can complete the connection of the chassis body and the pump leg bolt and the integral connection of the chassis body and the front panel in the process of forming the chassis body, so that the forming process is reduced, the production efficiency is improved, and the stability of the integral structure of the chassis body and the front panel is enhanced; meanwhile, the reinforcing ribs 213 are arranged on one side of the chassis close to the front panel and at corresponding positions on the front panel, so that the strength of the joint of the chassis and the front panel is enhanced; and a spacer 233 is arranged at the passage 216 to realize a full sealing structure of the compressor, thereby achieving the insect prevention effect and ensuring the normal operation of the compressor of the outdoor unit.
Example 51
The embodiment provides an air conditioner, which comprises an air conditioner indoor unit and the air conditioner outdoor unit, wherein the air conditioner indoor unit is communicated with the air conditioner outdoor unit through a pipeline. The production efficiency of the air conditioner is improved by reducing the molding process and the manufacturing process of the air conditioner outdoor unit, and the purpose of prolonging the service life of the air conditioner is achieved by enhancing the stability of the structure of the outdoor unit.
The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims (10)

1. The utility model provides a chassis structure, includes wind isolation riser (23), chassis body (211) and pump foot bolt (25), its characterized in that, be equipped with a plurality of spacers (233) on wind isolation riser (23), be equipped with special-shaped opening on spacer (233), form bilateral symmetry's clamping piece structure, the upper end of special-shaped opening is the V type, the interval of special-shaped opening mid portion is less than the interval at both ends, the minimum interval of special-shaped opening mid portion is less than the thickness of wind isolation riser (23), wind isolation riser (23) are arranged in inserting in the special-shaped opening, in order with spacer (233) swing joint, spacer (233) are in height position adjustable on wind isolation riser (23), spacer (233) are inserted in passageway (216) on chassis body (211), be close to front panel one side on chassis body (211) and be equipped with strengthening rib (213), chassis body (211) pass through pump foot bolt (25) links to each other with the front panel of air condensing units.
2. The chassis structure according to claim 1, wherein the pump leg bolt (25) includes a circular truncated cone (252) and an annular protrusion (253), the annular protrusion (253) is provided at a lower end of the circular truncated cone (252), and the annular protrusion (253) is deformed to extend radially of the annular protrusion (253) when being subjected to pressure.
3. The chassis structure according to claim 2, characterized in that the annular protrusion (253) is a hollow circular ring, the circular table (252) coinciding with the axis of the annular protrusion (253).
4. A chassis structure according to claim 2 or 3, characterized in that the diameter of the truncated cone (252) is larger than the annular protrusion (253).
5. The chassis structure according to claim 2, wherein the inner diameter of the annular protrusion (253) gradually increases with increasing distance from the circular table (252).
6. A chassis structure according to claim 2 or 3, characterized in that the outer diameter of the annular protrusion (253) remains unchanged with increasing distance from the circular table (252).
7. The chassis structure according to claim 1, wherein the reinforcing ribs (213) are located on a chassis bottom surface (2111) of the chassis body (211) and/or a chassis first rim (2112) in a longitudinal direction of the chassis body (211).
8. The chassis structure according to claim 7, characterized in that the edges of the reinforcement ribs (213) extend out of the reinforcement strips (2133) in the length direction of the chassis body (211).
9. An outdoor unit of an air conditioner, comprising the chassis structure of any one of claims 1 to 8.
10. An air conditioner, characterized by comprising an air conditioner indoor unit and the air conditioner outdoor unit of claim 9, wherein the air conditioner indoor unit is communicated with the air conditioner outdoor unit through a pipeline.
CN201810854240.6A 2018-07-30 2018-07-30 Chassis structure, air conditioner outdoor unit and air conditioner Active CN108731131B (en)

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