Automatic gas-liquid separation condenser for central air conditioning unit
By combining the installation of the bayonet device and the turbulence component, multi-level impurity interception and efficient gas-liquid separation are achieved in the automatic gas-liquid separator condenser for central air conditioning units. This solves the problems of single installation and insufficient efficiency in existing technologies, and ensures the safe and stable operation of the compressor.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- SHAANXI HENGCHI INFRASTRUCTURE & INSTALLATION ENGINEERING CO LTD
- Filing Date
- 2026-05-12
- Publication Date
- 2026-06-12
AI Technical Summary
Existing gas-liquid separators and condensers cannot achieve multi-level pre-interception of impurities, have a single installation form, cannot adapt to different space requirements, and have insufficient gas-liquid separation and condensation efficiency.
By combining components such as the Gulfstream device, the turbulence component, and the flow splitter, and through horizontal or bent series installation, multi-level impurity interception and efficient gas-liquid separation are achieved. During the condensation process, the cross wheel and centrifugal ring of the turbulence component are used for multi-level interception and condensation.
It achieves multi-level interception of impurities, adapts to different installation space requirements, improves gas-liquid separation and condensation efficiency, and ensures the safe and stable operation of the compressor.
Smart Images

Figure CN122191848A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of gas-liquid separation technology, and in particular to an automatic gas-liquid separator condenser for central air conditioning units. Background Technology
[0002] The core purpose of installing a gas-liquid separator condenser in a central air conditioning unit is to ensure the absolute safety and high efficiency of the compressor during operation. Before the refrigerant enters the compressor's suction port, a physical structure completely separates the liquid and gaseous refrigerants, ensuring the compressor is always in a "pure gas phase" compression state. This effectively avoids serious malfunctions such as compressor valve damage and lubricant dilution failure caused by "liquid slugging." Simultaneously, this device can temporarily store excess liquid refrigerant and achieve controlled evaporation when the system load fluctuates or liquid return is abnormal, significantly improving the system's operational stability and energy efficiency under varying operating conditions.
[0003] The existing gas-liquid separator condensers have the following technical problems: (1) During the condensation of refrigerant, it is impossible to achieve multi-level pre-interception of impurities, which causes impurities in the refrigerant to clog the gas-liquid separation equipment; (2) The existing gas-liquid separator condensers only have one installation form, and when there is insufficient horizontal or vertical installation space, it is impossible to make appropriate changes to the installation structure; (3) The existing technology often uses a single interception structure or centrifugal structure for gas-liquid separation. This single processing method cannot further improve the overall efficiency of gas-liquid separation and condensation. Therefore, an automatic gas-liquid separator condenser for central air conditioning units that can pre-intercept impurities at multiple levels, can change its own structure according to the installation space, and can further improve the overall efficiency of gas-liquid separation and condensation is needed to solve the shortcomings of the existing gas-liquid separator condensers. Summary of the Invention
[0004] The purpose of this invention is to provide an automatic gas-liquid separator condenser for central air conditioning units, in order to solve existing technical problems such as how to achieve multi-level pre-interception of impurities, how to change its own structure according to the installation space, and how to further improve the overall efficiency of gas-liquid separation and condensation.
[0005] To address the aforementioned technical problems, the present invention adopts the following technical solution: an automatic gas-liquid separator condenser for a central air conditioning unit, comprising a bayonet device, a protection component, a connecting component, a turbulence-distributing component, and a flow-dividing device; two bayonet devices are respectively fixedly connected to the turbulence-distributing component and the flow-dividing device; the protection component is fixedly installed on the periphery of the bayonet device; the connecting component is fixedly installed on the periphery of the turbulence-distributing component and the flow-dividing device; one end of the turbulence-distributing component is fixedly connected to one end of the flow-dividing device; when the turbulence-distributing component and the flow-dividing device are simultaneously in a horizontal state, the front end of the turbulence-distributing component is fixedly connected to one bayonet device, the rear end of the turbulence-distributing component is fixedly connected to the front end of the flow-dividing device, and the rear end of the flow-dividing device is fixedly connected to another bayonet device, thereby achieving a horizontal series installation of the entire device; when the horizontal installation space is insufficient, the turbulence-distributing component and the flow-dividing device are simultaneously converted to a vertical state, the front end of the turbulence-distributing component is fixedly connected to one bayonet device in the horizontal direction, the upper end of the turbulence-distributing component is fixedly connected to the lower end of the flow-dividing device, and the upper end of the flow-dividing device is fixedly connected to another bayonet device in the vertical direction, thereby achieving a bent series installation of the entire device.
[0006] Furthermore, the Gulfstream device includes a Gulfstream base, a circulating water pump, a circulating pipe, a cold liquid inlet, a series base, a series slot, a cold liquid cavity, and a flexible protrusion; the rear end of the Gulfstream base is fixedly connected to the front end of the series base; the circulating water pump is fixedly installed at the upper end of the Gulfstream base; both ends of the circulating pipe are fixedly installed inside the circulating water pump and the cold liquid inlet, respectively; the cold liquid inlet is fixedly installed at the upper end of the Gulfstream base; the series slot is fixedly installed on the side of the series base; the cold liquid cavity is fixedly installed at the front end of the Gulfstream base; the flexible protrusion is fixedly installed inside the series slot; a transverse connecting pipe is fixedly installed inside the Gulfstream base in the transverse direction; the transverse connecting pipe is used for the series connection of multiple bend channels; the bend channels are fixedly installed inside the Gulfstream base.
[0007] Furthermore, the protective assembly includes a protective housing, a rigid bump, a series insert, and a supplementary plate; the series insert is fixedly installed inside the protective housing; the series insert is inserted into the inside of the series slot; the rigid bump is fixedly installed inside the series insert; the rigid bump is inserted into the inside of the flexible bump; and the supplementary plate is slidably installed at the rear end of the protective housing in a horizontal direction.
[0008] Furthermore, the connecting assembly includes a connecting housing and an adhesive strip; the connecting housing is fixedly installed between the protective housings of the two protective assemblies; the adhesive strip is fixedly installed on the inner side of the connecting housing.
[0009] Furthermore, the turbulence assembly includes a turbulence connector, a turbulence groove, a first flexible sleeve, a turbulence base, a turbulence inclined channel, a first cross wheel, and a second cross wheel; the turbulence connector is fixedly installed at the front end of the first flexible sleeve; the turbulence connector is inserted into the interior of the series base; the flexible protrusion is inserted into the turbulence groove; the first flexible sleeve is fixedly installed at the front end of the turbulence base; the turbulence inclined channel is fixedly installed inside the turbulence connector; the angle between the slope surface on the turbulence inclined channel and the horizontal plane is 3°; the upper and lower ends of the first cross wheel are rotatably connected to the interior of the turbulence inclined channel; the upper and lower ends of the second cross wheel are rotatably connected to the interior of the turbulence inclined channel.
[0010] Furthermore, the spoiler assembly also includes an upper baffle, a lower baffle, a first servo, and a second servo; the side of the upper baffle is fixedly installed on the output end of the first servo; the first servo is fixedly installed on the upper end of the spoiler base in the lateral direction; the side of the lower baffle is fixedly installed on the output end of the second servo; and the second servo is fixedly installed on the lower end of the spoiler base in the lateral direction.
[0011] Furthermore, the diversion device includes a collection assembly, a diversion base, a second flexible sleeve, a diversion connector, and a diversion groove; the collection assembly is fixedly installed inside the diversion base; the diversion base is fixedly installed at the front end of the second flexible sleeve; a drain port is provided on the side of the diversion base; the second flexible sleeve is fixedly installed at the front end of the diversion connector; the diversion connector is inserted into the interior of the series base; and the flexible protrusion is inserted into the interior of the diversion groove.
[0012] Furthermore, the diversion device also includes a liquid storage cavity, a filter plate, a first centrifugal loop, a second centrifugal loop, a liquid-blocking baffle, a conical platform, and a spiral channel; the liquid storage cavity is fixedly installed on the outer side of the first centrifugal loop; an electromagnetic valve is also provided at the lower end of the liquid storage cavity; the filter plate is fixedly installed on the inner cylindrical surface of the first centrifugal loop; the filter plate is also in communication with the internal space of the liquid storage cavity; the first centrifugal loop is fixedly installed inside the diversion base; the second centrifugal loop is fixedly installed inside the diversion base; the second centrifugal loop is located inside the first centrifugal loop; the liquid-blocking baffle is fixedly installed on the inner cylindrical surface of the second centrifugal loop; the conical platform is fixedly installed inside the diversion base; and the spiral channel is fixedly installed on the outer surface of the conical platform.
[0013] Furthermore, the collection assembly includes a collection channel, a collection box, an air outlet, and a conical cover; the collection channel is fixedly installed vertically at the lower end of the collection box; the collection channel is also connected to the liquid storage cavity and the air outlet respectively; the conical cover is fixedly installed at the lower end of the collection box; the conical cover is fixedly installed at the upper end of the conical platform; the collection box is fixedly installed at the upper end of the first centrifugal ring and the second centrifugal ring; an exhaust pump is installed inside the collection box; the air outlet is fixedly installed horizontally inside the collection box; the air outlet is connected to the exhaust pump inside the collection box.
[0014] The beneficial effects of the present invention compared with the prior art are: (1) When there is enough horizontal installation space, the turbulence component and the diverter are placed in a horizontal state, and then the turbulence connector at the front end of the turbulence component is inserted into the series base on the Gulfstream device, and then the turbulence base at the rear end of the turbulence component is welded to the diverter base at the front end of the diverter device, and finally the diverter connector at the rear end of the diverter device is inserted into the series base of the Gulfstream device, thereby realizing the overall horizontal series installation. When there is insufficient horizontal installation space, the turbulence component and the diverter device are simultaneously converted to a vertical state, and then the turbulence connector on the turbulence component is bent to a horizontal state. At this time, the first flexible sleeve will become a 90° bent state, thereby realizing the overall bent series installation of the device. (2) The gaseous refrigerant enters the interior of the bend channel from the lower opening of the bend channel. At this time, the cooling water in the cold liquid cavity will exchange heat with the gaseous refrigerant, and initially convert the gaseous refrigerant into a gas-liquid coexisting state refrigerant. Then, the refrigerant enters the turbulence inclined channel in the turbulence joint in the turbulence assembly through the bend channel. At this time, the refrigerant will collide with the first cross wheel and the second cross wheel, causing the gaseous refrigerant to further condense into a gas-liquid coexisting state refrigerant. Then, the refrigerant enters the turbulence base and collides and condenses continuously with the upper baffle and the lower baffle. At the same time, the first cross wheel, the second cross wheel, the upper baffle and the lower baffle will also intercept impurities in the refrigerant, thereby realizing the functions of continuous condensation and multi-level impurity interception. (3) When the gas-liquid coexisting refrigerant enters from the turbulence base into the first centrifugal ring channel and the second centrifugal ring channel in the distribution base, the centrifugal force will drive the liquid refrigerant through the filter plate into the liquid storage cavity. Then the remaining refrigerant enters from the rear end opening of the second centrifugal ring channel into the space between the second centrifugal ring channel and the conical platform. The liquid blocking baffle will further prevent the flow of the liquid refrigerant. At this time, the remaining gaseous refrigerant will be sucked upward to the outlet by the suction of the exhaust pump in the collection box and discharged through the distribution joint and the bay flow device, thereby recirculating and condensing. The collected liquid refrigerant will be discharged through the electromagnetic valve at the lower end of the liquid storage cavity and the drain port on the side of the distribution base. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the overall assembly structure of the present invention in its working state. Figure 1 .
[0016] Figure 2 This is a schematic diagram of the overall assembly structure of the present invention in its working state. Figure 2 .
[0017] Figure 3 This is a schematic diagram of the structure of the Gulfstream device of the present invention. Figure 1 .
[0018] Figure 4 This is a schematic diagram of the structure of the Gulfstream device of the present invention. Figure 2 .
[0019] Figure 5 This is a schematic diagram of the structure of the protective component of the present invention.
[0020] Figure 6 This is a schematic diagram of the structure of the connecting component of the present invention.
[0021] Figure 7 This is a schematic diagram of the structure of the turbulence-disrupting component of the present invention. Figure 1 .
[0022] Figure 8 This is a schematic diagram of the structure of the turbulence-disrupting component of the present invention. Figure 2 .
[0023] Figure 9 This is a schematic diagram of the structure of the turbulence-disrupting component of the present invention. Figure 3 .
[0024] Figure 10 This is a schematic diagram of the flow diversion device of the present invention. Figure 1 .
[0025] Figure 11 This is a schematic diagram of the flow diversion device of the present invention. Figure 2 .
[0026] Figure 12 This is a schematic diagram of the structure of the components of the present invention.
[0027] In the diagram: 1-Gulfstream device; 2-Protective component; 3-Connecting component; 4-Breakthrough component; 5-Diverter; 101-Gulfstream base; 102-Circulating water pump; 103-Circulating pipe; 104-Cold liquid inlet; 105-Series base; 106-Series slot; 107-Horizontal connecting pipe; 108-Bent channel; 109-Cold liquid cavity; 110-Flexible protrusion; 201-Protective shell; 202-Rigid protrusion; 203-Series insert; 204-Supplementary plate; 301-Connecting shell; 302-Adhesive strip; 401-Breakthrough connector; 402-Breakthrough groove; 403-First flexible sleeve; 404- 405-Breakthrough base; 406-First cross wheel; 407-Second cross wheel; 408-Upper baffle; 409-Lower baffle; 410-First servo motor; 411-Second servo motor; 501-Collection assembly; 502-Diverter base; 503-Second flexible sleeve; 504-Diverter connector; 505-Diverter groove; 506-Liquid storage cavity; 507-Filter plate; 508-First centrifugal ring channel; 509-Second centrifugal ring channel; 510-Liquid blocking baffle; 511-Conical platform; 512-Spiral channel; 513-Collection channel; 514-Collection box; 515-Air outlet; 516-Conical cover. Detailed Implementation
[0028] The technical solution of the present invention will be further described below with reference to the accompanying drawings and specific embodiments.
[0029] The accompanying drawings are for illustrative purposes only and are schematic diagrams, not actual pictures. They should not be construed as limiting the invention. To better illustrate the embodiments of the invention, some parts in the drawings may be omitted, enlarged, or reduced, and do not represent the actual product dimensions. It is understandable to those skilled in the art that some well-known structures and their descriptions may be omitted in the drawings.
[0030] Figures 1 to 12 This is a preferred embodiment of the present invention.
[0031] like Figure 1 and Figure 2 As shown, two Gulfstream devices 1 are fixedly connected to the spoiler assembly 4 and the diverter 5, respectively; the protection assembly 2 is fixedly installed on the periphery of the Gulfstream device 1; the connecting assembly 3 is fixedly installed on the periphery of the spoiler assembly 4 and the diverter 5; one end of the spoiler assembly 4 is fixedly connected to one end of the diverter 5; when the spoiler assembly 4 and the diverter 5 are both in a horizontal state, the front end of the spoiler assembly 4 is fixedly connected to one Gulfstream device 1, the rear end of the spoiler assembly 4 is fixedly connected to the front end of the diverter 5, and the rear end of the diverter 5 is fixedly connected to the other Gulfstream device 1, thereby realizing the horizontal series installation of the entire device; when the horizontal installation space is insufficient, the spoiler assembly 4 and the diverter 5 are simultaneously converted to a vertical state, the front end of the spoiler assembly 4 is fixedly connected to one Gulfstream device 1 in the horizontal direction, the upper end of the spoiler assembly 4 is fixedly connected to the lower end of the diverter 5, and the upper end of the diverter 5 is fixedly connected to the other Gulfstream device 1 in the vertical direction, thereby realizing the bent series installation of the entire device.
[0032] like Figure 3 and Figure 4 As shown, in the Gulfstream device 1, the rear end of the Gulfstream base 101 is fixedly connected to the front end of the series base 105; the circulating water pump 102 is fixedly installed at the upper end of the Gulfstream base 101; the two ends of the circulating pipe 103 are respectively fixedly installed inside the circulating water pump 102 and inside the cold liquid port 104; the cold liquid port 104 is fixedly installed at the upper end of the Gulfstream base 101; the series slot 106 is fixedly installed on the side of the series base 105; the cold liquid cavity 109 is fixedly installed at the front end of the Gulfstream base 101; the flexible protrusion 110 is fixedly installed inside the series slot 106; the transverse connecting pipe 107 is fixedly installed inside the Gulfstream base 101 in the transverse direction; the transverse connecting pipe 107 is used for the series connection between multiple bent channels 108; the bent channels 108 are fixedly installed inside the Gulfstream base 101.
[0033] like Figure 5As shown, in the protection assembly 2, the series plug 203 is fixedly installed on the inner side of the protection housing 201; the series plug 203 is inserted into the inside of the series slot 106; the rigid protrusion 202 is fixedly installed on the inner side of the series plug 203; the rigid protrusion 202 is inserted into the inside of the flexible protrusion 110; and the supplementary plate 204 is slidably installed in the horizontal direction at the rear end of the protection housing 201.
[0034] like Figure 6 As shown, in the connecting assembly 3, the connecting housing 301 is fixedly installed between the protective housings 201 of the two protective assemblies 2; the adhesive strip 302 is fixedly installed on the inner side of the connecting housing 301.
[0035] like Figure 7 , Figure 8 , Figure 9 As shown, in the turbulence assembly 4, the turbulence connector 401 is fixedly installed at the front end of the first flexible sleeve 403; the turbulence connector 401 is inserted into the interior of the series base 105; the flexible protrusion 110 is inserted into the turbulence groove 402; the first flexible sleeve 403 is fixedly installed at the front end of the turbulence base 404; the turbulence inclined channel 405 is fixedly installed inside the turbulence connector 401; the angle between the inclined surface of the turbulence inclined channel 405 and the horizontal plane is 3°; the upper and lower ends of the first cross wheel 406 are respectively rotatably connected to the interior of the turbulence inclined channel 405; the upper and lower ends of the second cross wheel 407 are respectively rotatably connected to the interior of the turbulence inclined channel 405; the side of the upper baffle 408 is fixedly installed at the output end of the first servo 410; the first servo 410 is fixedly installed at the upper end of the turbulence base 404 in the lateral direction; the side of the lower baffle 409 is fixedly installed at the output end of the second servo 411; the second servo 411 is fixedly installed at the lower end of the turbulence base 404 in the lateral direction.
[0036] like Figure 10 , Figure 11As shown, in the diversion device 5, the package assembly 501 is fixedly installed inside the diversion base 502; the diversion base 502 is fixedly installed at the front end of the second flexible sleeve 503; a drain port is provided on the side of the diversion base 502; the second flexible sleeve 503 is fixedly installed at the front end of the diversion connector 504; the diversion connector 504 is inserted into the inside of the series base 105; the flexible protrusion 110 is inserted into the inside of the diversion groove 505; the liquid storage cavity 506 is fixedly installed on the outside of the first centrifugal ring 508; a solenoid valve is also provided at the lower end of the liquid storage cavity 506; the filter plate 5 07 is fixedly installed on the inner cylindrical surface of the first centrifugal channel 508; the filter plate 507 is also connected to the internal space of the liquid storage cavity 506; the first centrifugal channel 508 is fixedly installed inside the diversion base 502; the second centrifugal channel 509 is fixedly installed inside the diversion base 502; the second centrifugal channel 509 is located inside the first centrifugal channel 508; the liquid blocking baffle 510 is fixedly installed on the inner cylindrical surface of the second centrifugal channel 509; the conical platform 511 is fixedly installed inside the diversion base 502; the spiral channel 512 is fixedly installed on the outer surface of the conical platform 511.
[0037] like Figure 10 , Figure 12 As shown, in the collection assembly 501, the collection channel 513 is fixedly installed vertically at the lower end of the collection box 514; the collection channel 513 is also connected to the liquid storage cavity 506 and the air outlet 515 respectively; the conical cover 516 is fixedly installed at the lower end of the collection box 514; the conical cover 516 is fixedly installed at the upper end of the conical platform 511; the collection box 514 is fixedly installed at the upper end of the first centrifugal ring channel 508 and the second centrifugal ring channel 509; an exhaust pump is provided inside the collection box 514; the air outlet 515 is fixedly installed horizontally inside the collection box 514; the air outlet 515 is connected to the exhaust pump inside the collection box 514.
[0038] Working principle of the invention: Figure 1 and Figure 2 The invention provides usage methods and corresponding scenarios. The attitude control of the separation and condensation process is determined by the Gulfstream device 1, the turbulence component 4, and the flow splitting device 5. The attitude of the Gulfstream device 1 is determined by the turbulence component 4, and the attitude of the turbulence component 4 is determined by the flow splitting device 5. Therefore, the flow splitting device 5 is the core of the separation and condensation process.
[0039] Taking a preferred embodiment as an example, such as Figure 3 , Figure 4 and Figure 5As shown, gaseous refrigerant enters the interior of the bent channel 108 through the lower opening. At this time, cooling water enters the cold liquid cavity 109 through the cold liquid port 104, the circulation pipe 103, and the circulation water pump 102. Subsequently, the cooling water exchanges heat with the gaseous refrigerant, causing the gaseous refrigerant to initially convert into a gas-liquid coexisting state refrigerant. The series base 105 is used for the insertion of the turbulence connector 401 and the diversion connector 504. The series slot 106 is used for the insertion of the series plug 203 in the protective assembly 2. The rigid protrusion 202 is used to lift the flexible protrusion 110. The supplementary plate 204 is used to fill the gap left at the bottom after the overall bent state of the device is spliced. The transverse connecting pipe 107 in the Gulfstream base 101 is used for the transverse connection of the bent channel 108. The protective shell 201 is used to fix the series plug 203.
[0040] like Figure 6 , Figure 7 , Figure 8 and Figure 9 As shown, when the refrigerant enters the turbulence channel 405 within the turbulence connector 401 through the bend channel 108, it collides with the first cross wheel 406 and the second cross wheel 407, causing the gaseous refrigerant to further condense into a gas-liquid coexisting state. Subsequently, the refrigerant enters the turbulence base 404 and continuously collides and condenses with the upper baffle 408 and the lower baffle 409. Simultaneously, the first cross wheel 406, the second cross wheel 407, the upper baffle 408, and the lower baffle 409 also intercept impurities in the refrigerant, thus achieving continuous condensation and multi-layered impurity interception. The turbulence groove 402 is used for the insertion of the flexible protrusion 110. Position; the first servo motor 410 inside the turbulence base 404 drives the upper baffle 408 to rotate counterclockwise, and the second servo motor 411 drives the lower baffle 409 to rotate clockwise, so that the upper baffle 408 and the lower baffle 409 move closer to each other, thereby reducing the gap between the upper baffle 408 and the lower baffle 409, and thus enhancing the obstruction effect of the upper baffle 408 and the lower baffle 409 on the refrigerant; the connecting housing 301 on the connecting assembly 3 is used to cover the periphery of the turbulence base 404 and the diversion base 502; the adhesive strip 302 on the inner side of the connecting housing 301 is used for the adhesive installation of the connecting housing 301; the first flexible sleeve 403 is used for deformation during bending installation.
[0041] like Figure 10 , Figure 11 and Figure 12As shown, when there is sufficient horizontal installation space, the spoiler assembly 4 and the diverter device 5 are placed horizontally. Then, the spoiler connector 401 at the front end of the spoiler assembly 4 is inserted into the series base 105 on the Gulfstream device 1. Next, the spoiler base 404 at the rear end of the spoiler assembly 4 is welded to the diverter base 502 at the front end of the diverter device 5. Finally, the diverter connector 504 at the rear end of the diverter device 5 is inserted into the series base 105 of the Gulfstream device 1, thereby achieving a horizontal series installation. When there is insufficient horizontal installation space, the spoiler assembly 4 and the diverter device 5 are simultaneously converted to a vertical configuration. In the straight state, the turbulence connector 401 on the turbulence assembly 4 is then bent to a horizontal state. At this time, the first flexible sleeve 403 will be bent at 90°, thereby realizing the bending series installation of the entire device. When the gas-liquid coexisting refrigerant enters from the turbulence base 404 into the first centrifugal channel 508 and the second centrifugal channel 509 in the diversion base 502, the centrifugal force will drive the liquid refrigerant through the filter plate 507 into the liquid storage cavity 506. Then, the remaining refrigerant enters the second centrifugal channel 509 from the rear opening of the second centrifugal channel 509. Between 09 and the conical platform 511, the liquid-blocking baffle 510 further impedes the flow of liquid refrigerant. At this time, the remaining gaseous refrigerant is drawn upwards to the outlet 515 by the suction of the exhaust pump in the collection box 514, and discharged through the diverter 504 and the bayonet device 1, thus undergoing recirculation and condensation. The collected liquid refrigerant is discharged through the solenoid valve at the lower end of the liquid storage cavity 506 and the drain port on the side of the diverter base 502. When the exhaust pump in the collection assembly 501 exhausts gas into the outlet 515, the gas flow rate in the outlet 515 increases, making... The pressure inside the vent 515 decreases, and the pressure difference causes the gaseous refrigerant remaining in the liquid storage cavity 506 to rise and enter the vent 515 through the collection channel 513. The conical cover 516 is fixedly installed on the upper end of the conical platform 511. When the refrigerant spirals upward in the spiral channel 512, the centrifugal force will throw the liquid refrigerant against the inner wall of the spiral channel 512, and the inner wall of the spiral channel 512 will increase the resistance to the upward movement of the liquid refrigerant. The second flexible sleeve 503 is used to accommodate bending deformation. The diversion groove 505 is used for the insertion of the flexible protrusion 110.
[0042] This invention is not limited to the specific embodiments described above. Any modifications made by those skilled in the art based on the above concept without creative effort are within the protection scope of this invention.
Claims
1. An automatic gas-liquid separator condenser for a central air conditioning unit, comprising a vortex device (1), a protection component (2), a connection component (3), a turbulence component (4), and a flow divider (5), characterized in that: Two Gulfstream devices (1) are fixedly connected to a spoiler assembly (4) and a flow divider (5) respectively; a protection assembly (2) is fixedly installed on the periphery of the Gulfstream device (1); a connecting assembly (3) is fixedly installed on the periphery of the spoiler assembly (4) and the flow divider (5); one end of the spoiler assembly (4) is fixedly connected to one end of the flow divider (5); when the spoiler assembly (4) and the flow divider (5) are both in a horizontal state, the front end of the spoiler assembly (4) is fixedly connected to one Gulfstream device (1), and the rear end of the spoiler assembly (4) is fixedly connected to the front end of the flow divider (5). The rear end of the diversion device (5) is fixedly connected to another Gulfstream device (1), thereby realizing the horizontal series installation of the entire device; when the horizontal installation space is insufficient, the turbulence component (4) and the diversion device (5) are simultaneously converted to a vertical state, the front end of the turbulence component (4) is fixedly connected to a Gulfstream device (1) in the horizontal direction, the upper end of the turbulence component (4) is fixedly connected to the lower end of the diversion device (5), and the upper end of the diversion device (5) is fixedly connected to another Gulfstream device (1) in the vertical direction, thereby realizing the bending series installation of the entire device.
2. The automatic gas-liquid separator condenser for a central air conditioning unit according to claim 1, characterized in that: The Gulfstream device (1) includes a Gulfstream base (101), a circulating water pump (102), a circulating pipe (103), a cold liquid inlet (104), a series base (105), a series slot (106), a transverse connecting pipe (107), a bend channel (108), a cold liquid cavity (109), and a flexible protrusion (110). The rear end of the Gulfstream base (101) is fixedly connected to the front end of the series base (105). The circulating water pump (102) is fixedly installed on the upper end of the Gulfstream base (101). The two ends of the circulating pipe (103) are respectively fixedly installed inside the circulating water pump (102) and the cold liquid inlet (104). The interior of 04); the coolant port (104) is fixedly installed on the upper end of the Gulfstream base (101); the series slot (106) is fixedly installed on the side of the series base (105); the coolant cavity (109) is fixedly installed on the front end of the Gulfstream base (101); the flexible protrusion (110) is fixedly installed inside the series slot (106); the transverse connecting pipe (107) is fixedly installed inside the Gulfstream base (101) in the transverse direction; the transverse connecting pipe (107) is used for the series connection between multiple bent channels (108); the bent channels (108) are fixedly installed inside the Gulfstream base (101).
3. The automatic gas-liquid separator condenser for a central air conditioning unit according to claim 2, characterized in that: The protective assembly (2) includes a protective shell (201), a rigid protrusion (202), a series plug (203), and a supplementary plate (204); the series plug (203) is fixedly installed inside the protective shell (201); the series plug (203) is inserted into the inside of the series slot (106); the rigid protrusion (202) is fixedly installed inside the series plug (203); the rigid protrusion (202) is inserted into the inside of the flexible protrusion (110); and the supplementary plate (204) is slidably installed at the rear end of the protective shell (201) in the horizontal direction.
4. An automatic gas-liquid separator condenser for a central air conditioning unit according to claim 3, characterized in that: The connecting assembly (3) includes a connecting housing (301) and an adhesive strip (302); the connecting housing (301) is fixedly installed between the protective housings (201) of the two protective assemblies (2); the adhesive strip (302) is fixedly installed on the inside of the connecting housing (301).
5. An automatic gas-liquid separator condenser for a central air conditioning unit according to claim 4, characterized in that: The turbulence assembly (4) includes a turbulence connector (401), a turbulence groove (402), a first flexible sleeve (403), a turbulence base (404), a turbulence inclined channel (405), a first cross wheel (406), and a second cross wheel (407). The turbulence connector (401) is fixedly installed at the front end of the first flexible sleeve (403). The turbulence connector (401) is inserted into the interior of the series base (105). The flexible protrusion (110) is inserted into the turbulence groove (402). The first flexible sleeve (403) is fixedly installed at the front end of the turbulence base (404). The turbulence inclined channel (405) is fixedly installed inside the turbulence connector (401). The angle between the slope surface on the turbulence inclined channel (405) and the horizontal plane is 3°. The upper and lower ends of the first cross wheel (406) are rotatably connected to the interior of the turbulence inclined channel (405). The upper and lower ends of the second cross wheel (407) are rotatably connected to the interior of the turbulence inclined channel (405).
6. An automatic gas-liquid separator condenser for a central air conditioning unit according to claim 5, characterized in that: The spoiler assembly (4) also includes an upper baffle (408), a lower baffle (409), a first servo (410), and a second servo (411); the side of the upper baffle (408) is fixedly installed on the output end of the first servo (410); the first servo (410) is fixedly installed on the upper end of the spoiler base (404) in the lateral direction; the side of the lower baffle (409) is fixedly installed on the output end of the second servo (411); the second servo (411) is fixedly installed on the lower end of the spoiler base (404) in the lateral direction.
7. An automatic gas-liquid separator condenser for a central air conditioning unit according to claim 6, characterized in that: The diversion device (5) includes a collection assembly (501), a diversion base (502), a second flexible sleeve (503), a diversion connector (504), and a diversion groove (505); the collection assembly (501) is fixedly installed inside the diversion base (502); the diversion base (502) is fixedly installed at the front end of the second flexible sleeve (503); a drain port is provided on the side of the diversion base (502); the second flexible sleeve (503) is fixedly installed at the front end of the diversion connector (504); the diversion connector (504) is inserted into the inside of the series base (105); and the flexible protrusion (110) is inserted into the inside of the diversion groove (505).
8. An automatic gas-liquid separator condenser for a central air conditioning unit according to claim 7, characterized in that: The diversion device (5) also includes a liquid storage cavity (506), a filter plate (507), a first centrifugal ring channel (508), a second centrifugal ring channel (509), a liquid blocking baffle (510), a conical platform (511), and a spiral channel (512); the liquid storage cavity (506) is fixedly installed on the outside of the first centrifugal ring channel (508); a solenoid valve is also provided at the lower end of the liquid storage cavity (506); the filter plate (507) is fixedly installed on the inner cylindrical surface of the first centrifugal ring channel (508); the filter plate (507) is also connected to the liquid storage cavity (509). 6) The internal space is connected; the first centrifugal ring channel (508) is fixedly installed inside the diversion base (502); the second centrifugal ring channel (509) is fixedly installed inside the diversion base (502); the second centrifugal ring channel (509) is located inside the first centrifugal ring channel (508); the liquid blocking baffle (510) is fixedly installed on the inner cylindrical surface of the second centrifugal ring channel (509); the conical platform (511) is fixedly installed inside the diversion base (502); the spiral channel (512) is fixedly installed on the outer surface of the conical platform (511).
9. An automatic gas-liquid separator condenser for a central air conditioning unit according to claim 8, characterized in that: The collection assembly (501) includes a collection channel (513), a collection box (514), an air outlet (515), and a conical cover (516). The collection channel (513) is fixedly installed at the lower end of the collection box (514) in a vertical direction. The collection channel (513) is also connected to the liquid storage cavity (506) and the air outlet (515) respectively. The conical cover (516) is fixedly installed at the lower end of the collection box (514). The conical cover (516) is fixedly installed at the upper end of the conical platform (511). The collection box (514) is fixedly installed at the upper end of the first centrifugal ring channel (508) and the second centrifugal ring channel (509). An exhaust pump is installed inside the collection box (514). The air outlet (515) is fixedly installed inside the collection box (514) in a horizontal direction. The air outlet (515) is connected to the exhaust pump inside the collection box (514).