Air conditioner test power-on device and air conditioner test system
By designing an air conditioner test power-on device, the device automatically adapts to the number of live wires of different air conditioner models by utilizing the movement and rotation of the control mechanism and linkage base. This solves the problem of insufficient versatility in existing technologies and achieves automated, rapid power-on and efficient testing.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- GREE ELECTRIC APPLIANCE INC OF ZHUHAI
- Filing Date
- 2022-09-30
- Publication Date
- 2026-06-23
AI Technical Summary
The existing air conditioner withstand voltage test electrode docking fixture can only be used for air conditioner models with the same number of live wires, which is not very versatile. It is necessary to manually replace the supply electrode to adapt to air conditioner models with different numbers of live wires, which increases the workload of manual labor and affects the efficiency of test operations.
Design an air conditioner testing and power-on device, including a first control mechanism, a linkage base, and a power-on component. By moving and rotating the control mechanism and the linkage base, it can automatically switch to be used for different models of air conditioners, realize automated and rapid power-on of the terminal block, and use multiple sets of conductive rods to adapt to air conditioners with different numbers of live wires.
It improves the versatility and efficiency of air conditioner testing, reduces the intensity of manual labor, and realizes automated power-on operation for different models of air conditioners.
Smart Images

Figure CN115566487B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of air conditioning testing technology, and in particular to an air conditioning testing power-on device and an air conditioning testing system having the air conditioning testing power-on device. Background Technology
[0002] After the outdoor unit of the air conditioner is fully assembled, online testing is required. This involves electrically connecting the newly installed outdoor unit to the power-on mechanism of the air conditioning testing system, followed by testing and operation to ensure that the newly installed outdoor unit meets various performance requirements, thereby ensuring its safety and practicality. The electrical connection between the outdoor unit and the power-on mechanism is as follows: a terminal block is installed on the electrical box of the outdoor unit. The terminal block has screw holes and screws forming wire connectors. The conductive rod of the power-on mechanism can be connected to these wire connectors, which include neutral, live, ground, and signal wire connectors.
[0003] An existing air conditioner withstand pressure test electrode docking fixture includes a motor, a reducer, a docking mechanism, a first telescopic cylinder, a second telescopic cylinder, a supply electrode, a receiving electrode, a clamping cylinder, a column, a synchronous belt, and a track. The docking mechanism is mounted on the track and is driven by the motor and reducer via the synchronous belt. The first telescopic cylinder is mounted on the docking mechanism, and a fixing plate is mounted on one end of the first telescopic cylinder. The second telescopic cylinder is mounted on the fixing plate. The supply electrode is mounted on one end of the second telescopic cylinder, and the receiving electrode is mounted on the column. This achieves automatic docking between the power supply mechanism and the wire connector, saving labor and improving the automation level of the fixture.
[0004] However, different air conditioner models have different numbers of live wires in their electrical connectors. For example, some models have one live wire, some have two, and some have three. Existing air conditioner withstand voltage test electrode docking fixtures can only be used for air conditioners with the same number of live wires, limiting their applicability and versatility. If it is necessary to use other air conditioner models with different numbers of live wires, the supply electrodes need to be manually replaced to adapt to the different models, increasing the workload and affecting the efficiency of the test. Summary of the Invention
[0005] The primary objective of this invention is to provide an air conditioner testing power-on device that can automatically switch between different air conditioner models and is highly versatile, thereby improving testing efficiency and reducing manual labor intensity.
[0006] A second objective of the present invention is to provide an air conditioning test system having the above-mentioned air conditioning test power-on device.
[0007] To achieve the first objective of this invention, the present invention provides an air conditioner testing power-on device, comprising a first control mechanism, a first linkage seat, a second control mechanism, a second linkage seat, a third control mechanism, a third linkage seat, a first power-on component, and a second power-on component. The first control mechanism can control the first linkage seat to move vertically and / or horizontally. The second control mechanism is disposed on the first linkage seat and can control the second linkage seat to move vertically and / or horizontally. The third control mechanism is disposed on the second linkage seat and can control the third linkage seat to rotate. The first power-on component and the second power-on component are distributed on the third linkage seat around the rotation axis of the third linkage seat. The first power-on component includes a first signal line conductive rod, a first ground wire conductive rod, a first neutral wire conductive rod, and a first live wire conductive rod. The second power-on component includes a second signal line conductive rod, a second ground wire conductive rod, a second neutral wire conductive rod, and a second live wire conductive rod. The number of first live wire conductive rods is not equal to the number of second live wire conductive rods.
[0008] As can be seen from the above scheme, the conveyor line of the air conditioning testing system controls the movement of the tooling plate, on which the outdoor unit of the air conditioner under test is placed, thereby conveying the outdoor unit of the air conditioner under test to the power-on testing position of the air conditioning testing power-on device of the present invention. Subsequently, the first control mechanism of the air conditioning testing power-on device of the present invention controls the first linkage seat to move in the vertical and / or horizontal direction, so that the second control mechanism, the second linkage seat, the third control mechanism, the third linkage seat, the first power-on component and the second power-on component move together in the vertical and / or horizontal direction to the terminal block of the outdoor unit of the air conditioner under test. At this time, the first power-on component and the second power-on component are located outside the outdoor unit of the air conditioner under test. Then, the second control mechanism of the air conditioning testing power-on device of the present invention... The mechanism controls the second linkage seat to move vertically and / or horizontally, causing the third control mechanism, the third linkage seat, the first power-on component, and the second power-on component to move vertically and / or horizontally until they are electrically connected to the terminal block of the outdoor unit of the air conditioner under test. At this time, the first signal line conductive rod, the first ground wire conductive rod, the first neutral wire conductive rod, and the first live wire conductive rod of the first power-on component are inserted into the outdoor unit of the air conditioner under test and electrically connected to the terminal block. Alternatively, the second signal line conductive rod, the second ground wire conductive rod, the second neutral wire conductive rod, and the second live wire conductive rod of the second power-on component are inserted into the outdoor unit of the air conditioner under test and electrically connected to the terminal block. This automatically and quickly powers on the terminal block of the outdoor unit of the air conditioner under test, ensuring reliable and safe automated control. Furthermore, the first and second power-on components of the air conditioner testing power-on device of the present invention are distributed on the third linkage seat around the rotation axis of the third linkage seat. The third control mechanism can control the rotation of the third linkage seat. The number of first live wire conductive rods in the first power-on component is not equal to the number of second live wire conductive rods in the second power-on component. Therefore, the air conditioner testing power-on device of the present invention can switch between powering on the first power-on component or the second power-on component by controlling the rotation of the third linkage seat through the third control mechanism according to the different models of the outdoor unit of the air conditioner under test. This allows the air conditioner testing power-on device of the present invention to be applicable to the power-on operation of at least two different models of air conditioners. Compared with the existing air conditioner withstand voltage test electrode docking fixture, which can only be used for air conditioners with one type of live wire, the air conditioner testing power-on device of the present invention can automatically switch to be used for different models of air conditioners, which is highly versatile. Moreover, compared with the existing devices that require manual replacement of power-on components to adapt to air conditioners with different numbers of live wires, the air conditioner testing power-on device of the present invention can automatically switch between powering on the first power-on component or the second power-on component, thereby improving the efficiency of the test operation and reducing the intensity of manual labor.
[0009] In a preferred embodiment, the air conditioner test power-on device further includes a fourth control mechanism, a fourth linkage seat, a fifth control mechanism, a fifth linkage seat, a third power-on component, and a fourth power-on component. The fourth control mechanism is mounted on the first linkage seat and can control the fourth linkage seat to move vertically and / or horizontally. The fifth control mechanism is mounted on the fourth linkage seat and can control the rotation of the fifth linkage seat. The third power-on component and the fourth power-on component are distributed on the fifth linkage seat around the rotation axis of the fifth linkage seat. The third power-on component includes a third signal line conductive rod, a third ground wire conductive rod, a third neutral wire conductive rod, and a third live wire conductive rod. The fourth power-on component includes a fourth signal line conductive rod, a fourth ground wire conductive rod, a fourth neutral wire conductive rod, and a fourth live wire conductive rod. The number of third live wire conductive rods is not equal to the number of fourth live wire conductive rods.
[0010] A further proposed solution is to have a first baffle on the second linkage seat, and the first or second power-on component can be located directly below the first baffle in the vertical direction.
[0011] A further proposed solution is to have a second baffle on the fourth linkage seat, and the third or fourth power-on component can be located directly below the second baffle in the vertical direction.
[0012] A further proposed solution is that the second control mechanism is a first moving cylinder, which is mounted on a first linkage seat, and the first piston rod of the first moving cylinder is connected to the second linkage seat. The moving direction of the first piston rod is inclined relative to the vertical direction.
[0013] A further proposed solution is that the fourth control mechanism is a second moving cylinder, which is mounted on the first linkage seat, and the second piston rod of the second moving cylinder is connected to the fourth linkage seat. The moving direction of the second piston rod is inclined relative to the vertical direction.
[0014] A further proposed solution is that the third control mechanism is a first rotary cylinder, which is mounted on the second linkage seat and can control the rotation of the third linkage seat; and / or, the fifth control mechanism is a second rotary cylinder, which is mounted on the fourth linkage seat and can control the rotation of the fifth linkage seat.
[0015] A further embodiment includes a third support base and multiple third elastic elements in the third power-on component. The third support base is mounted on the fifth linkage base. The third signal line conductive rod, the third ground wire conductive rod, the third neutral wire conductive rod, and the third live wire conductive rod are movably supported on the third support base. One third elastic element can force the third signal line conductive rod to move away from the third support base, one third elastic element can force the third ground wire conductive rod to move away from the third support base, one third elastic element can force the third neutral wire conductive rod to move away from the third support base, and one third elastic element can force one third live wire conductive rod to move away from the third support base. The fourth power-on assembly further includes a fourth support base and a plurality of fourth elastic elements. The fourth support base is disposed on the fifth linkage base. The fourth signal line conductive rod, the fourth ground wire conductive rod, the fourth neutral wire conductive rod, and the fourth live wire conductive rod are movably supported on the fourth support base. One fourth elastic element can force the fourth signal line conductive rod to move away from the fourth support base. One fourth elastic element can force the fourth ground wire conductive rod to move away from the fourth support base. One fourth elastic element can force the fourth neutral wire conductive rod to move away from the fourth support base. One fourth elastic element can force a fourth live wire conductive rod to move away from the fourth support base.
[0016] A further embodiment includes a first support base and multiple first elastic elements in the first power-on assembly. The first support base is mounted on a third linkage base. The first signal line conductive rod, the first ground wire conductive rod, the first neutral wire conductive rod, and the first live wire conductive rod are movably supported on the first support base. One first elastic element can force the first signal line conductive rod to move away from the first support base, one first elastic element can force the first ground wire conductive rod to move away from the first support base, one first elastic element can force the first neutral wire conductive rod to move away from the first support base, and one first elastic element can force one first live wire conductive rod to move away from the first support base. The second power-on assembly further includes a second support base and a plurality of second elastic elements. The second support base is disposed on a third linkage base. The second signal line conductive rod, the second ground wire conductive rod, the second neutral wire conductive rod, and the second live wire conductive rod are movably supported on the second support base. One second elastic element can force the second signal line conductive rod to move away from the second support base. One second elastic element can force the second ground wire conductive rod to move away from the second support base. One second elastic element can force the second neutral wire conductive rod to move away from the second support base. One second elastic element can force a second live wire conductive rod to move away from the second support base.
[0017] To achieve the second objective of this invention, this invention provides an air conditioning testing system, including an air conditioning testing power-on device, which is the air conditioning testing power-on device described above. Attached Figure Description
[0018] Figure 1This is a first-view structural diagram of an embodiment of the air conditioner testing and power-on device of the present invention.
[0019] Figure 2 This is a second-view structural diagram of an embodiment of the air conditioner testing and power-on device of the present invention.
[0020] Figure 3 This is an exploded view of an embodiment of the air conditioner testing and power-on device of the present invention.
[0021] Figure 4 This is a cross-sectional view of the second power-on component in an embodiment of the air conditioner test power-on device of the present invention.
[0022] The present invention will be further described below with reference to the accompanying drawings and embodiments. Detailed Implementation
[0023] See Figures 1 to 3 This embodiment discloses an air conditioner testing power-on device 1, including a first control mechanism, a first linkage seat 12, a second control mechanism, a second linkage seat 15, a third control mechanism, a third linkage seat 17, a first power-on component 2, and a second power-on component 3. The first control mechanism can control the first linkage seat 12 to move in the vertical and / or horizontal direction. The second control mechanism is disposed on the first linkage seat 12 and can control the second linkage seat 15 to move in the vertical and / or horizontal direction. The third control mechanism is disposed on the second linkage seat 15 and can control the third linkage seat 17 to rotate. The first power-on component 2 and the second power-on component 3 are distributed on the third linkage seat 17 around the rotation axis of the third linkage seat 17. In this embodiment, the first power-on component 2 includes a first signal line conductive rod 21, a first ground wire conductive rod 22, a first neutral wire conductive rod 23, and a first live wire conductive rod 24. The second power-on component 3 includes a second signal line conductive rod 31, a second ground wire conductive rod 32, a second neutral wire conductive rod 33, and a second live wire conductive rod 34. The number of first live wire conductive rods 24 is not equal to the number of second live wire conductive rods 34.
[0024] The air conditioning testing system's conveyor control fixture plate moves, with the outdoor unit of the air conditioner under test placed on it. This transports the outdoor unit to the power-on testing position of the air conditioning testing power-on device 1 in this embodiment. Subsequently, the first control mechanism of the air conditioning testing power-on device 1 controls the first linkage seat 12 to move vertically and / or horizontally, causing the second control mechanism, second linkage seat 15, third control mechanism, third linkage seat 17, first power-on component 2, and second power-on component 3 to move vertically and / or horizontally to the terminal block of the outdoor unit of the air conditioner under test. At this time, the first power-on component 2 and second power-on component 3 are located outside the outdoor unit of the air conditioner under test. Then, the second control mechanism of the air conditioning testing power-on device 1 controls the second linkage seat 15 to move vertically and / or horizontally to the terminal block of the outdoor unit of the air conditioner under test. The seat 15 moves vertically and / or horizontally, causing the third control mechanism, the third linkage seat 17, the first power-on component 2, and the second power-on component 3 to move vertically and / or horizontally to electrically connect with the terminal block of the outdoor unit of the air conditioner under test. At this time, the first signal line conductive rod 21, the first ground wire conductive rod 22, the first neutral wire conductive rod 23, and the first live wire conductive rod 24 of the first power-on component 2 are inserted into the outdoor unit of the air conditioner under test and electrically connected with the terminal block. Alternatively, the second signal line conductive rod 31, the second ground wire conductive rod 32, the second neutral wire conductive rod 33, and the second live wire conductive rod 34 of the second power-on component 3 are inserted into the outdoor unit of the air conditioner under test and electrically connected with the terminal block. This automatically and quickly powers on the terminal block of the outdoor unit of the air conditioner under test, ensuring reliable and safe automated control. Furthermore, in this embodiment, the first power-on component 2 and the second power-on component 3 of the air conditioner testing power-on device 1 are distributed and arranged on the third linkage seat 17 around the rotation axis of the third linkage seat 17. The third control mechanism can control the rotation of the third linkage seat 17. The number of first live wire conductive rods 24 in the first power-on component 2 is not equal to the number of second live wire conductive rods 34 in the second power-on component 3. Therefore, in this embodiment, the air conditioner testing power-on device 1 can switch between powering on the first power-on component 2 or the second power-on component 3 by controlling the rotation of the third linkage seat 17 through the third control mechanism according to the different models of the outdoor unit of the air conditioner under test. Powering on electrical component 3 enables the air conditioner testing power-on device 1 of this embodiment to be applicable to the power-on operation of at least two different air conditioner models. Compared with the existing air conditioner withstand voltage test electrode docking fixture, which can only be used for air conditioner models with one number of live wires, the air conditioner testing power-on device 1 of this embodiment can automatically switch to be used for different air conditioner models, which is highly versatile. Moreover, compared with the existing devices that require manual replacement of power-on components to adapt to air conditioner models with different numbers of live wires, the air conditioner testing power-on device 1 of this embodiment can automatically switch between powering on the first power-on component 2 or powering on the second power-on component 3, thereby improving the efficiency of the test operation and reducing the intensity of manual labor.
[0025] To further enhance the versatility of the air conditioner testing power-on device 1 in this embodiment, the air conditioner testing power-on device 1 in this embodiment also includes a fourth control mechanism, a fourth linkage seat 19, a fifth control mechanism, a fifth linkage seat 111, a third power-on component 4, and a fourth power-on component 5. The fourth control mechanism is disposed on the first linkage seat 12 and can control the fourth linkage seat 19 to move in the vertical and / or horizontal direction. The fifth control mechanism is disposed on the fourth linkage seat 19 and can control the fifth linkage seat 111 to rotate. The third power-on component 4 and the fourth power-on component 5 are distributed on the fifth linkage seat 111 around the rotation axis of the fifth linkage seat 111. The third power-on component 4 includes a third signal line conductive rod 41, a third ground wire conductive rod 42, a third neutral wire conductive rod 43, and a third live wire conductive rod 44. The fourth power-on component 5 includes a fourth signal line conductive rod 51, a fourth ground wire conductive rod 52, a fourth neutral wire conductive rod 53, and a fourth live wire conductive rod 54. The number of third live wire conductive rods 44 is not equal to the number of fourth live wire conductive rods 54. Therefore, the air conditioner testing power-on device 1 of this embodiment can switch between powering on the first power-on component 2 or the second power-on component 3 by controlling the rotation of the third linkage seat 17 through the third control mechanism, or by controlling the rotation of the fifth linkage seat 111 through the fifth control mechanism to switch between powering on the third power-on component 4 or the fourth power-on component 5, so that the air conditioner testing power-on device 1 of this embodiment can be used for powering on at least four different models of air conditioners, making the air conditioner testing power-on device 1 of this embodiment more versatile.
[0026] In this embodiment, the first control mechanism is a dual-axis module 11 composed of a motor and a lead screw, which controls movement in both the vertical and horizontal directions. This allows control of the first linkage seat 12's movement in both directions. The dual-axis module 11 is mounted on the power-on test position of the air conditioning test system via a mounting plate 10. Secondly, the second control mechanism is a first moving cylinder 13, which is mounted on the first linkage seat 12. The first piston rod of the first moving cylinder 13 is connected to the second linkage seat 15, and its movement direction is inclined relative to the vertical direction. This allows the first piston rod to control the second linkage seat 15 to move in an inclined direction relative to the vertical direction, thus enabling movement of the second linkage seat 15 in both the vertical and horizontal directions. This design is simple and provides stable and reliable operation. Furthermore, the third control mechanism is a first rotating cylinder 16, which is mounted on the second linkage seat 15 and controls the rotation of the third linkage seat 17. The fifth control mechanism is a second rotating cylinder 110, which is mounted on the fourth linkage seat 19 and controls the rotation of the fifth linkage seat 111. Furthermore, in this embodiment, the fourth control mechanism is a second moving cylinder 18, which is mounted on the first linkage seat 12. The second piston rod of the second moving cylinder 18 is connected to the fourth linkage seat 19. The moving direction of the second piston rod is inclined relative to the vertical direction, so that the second piston rod can control the fourth linkage seat 19 to move in an inclined manner relative to the vertical direction, thereby enabling the fourth linkage seat 19 to move in both the vertical and horizontal directions. The structure is simple and the operation is stable and reliable.
[0027] To prevent the pending power-on components from being contaminated by dust and other environmental factors, a first baffle 112 is provided on the second linkage seat 15 in this embodiment. The first power-on component 2 or the second power-on component 3 can be located directly below the first baffle 112 in the vertical direction. The first baffle 112 can shield the power-on component located directly below it from dust, thereby ensuring the working reliability of the power-on component. In addition, a second baffle 113 is provided on the fourth linkage seat 19 in this embodiment. The third power-on component 4 or the fourth power-on component 5 can be located directly below the second baffle 113 in the vertical direction. The second baffle 113 can shield the power-on component located directly below it from dust, thereby ensuring the working reliability of the power-on component.
[0028] See Figure 4In this embodiment, the second power-on component 3 also includes a second support base 35 and multiple second elastic elements. The second support base 35 is disposed on the third linkage base 17. The second signal line conductive rod 31, the second ground wire conductive rod 32, the second neutral wire conductive rod 33, and the second live wire conductive rod 34 are movably supported on the second support base 35. One second elastic element can force the second signal line conductive rod 31 to move away from the second support base 35, one second elastic element can force the second ground wire conductive rod 32 to move away from the second support base 35, one second elastic element can force the second neutral wire conductive rod 33 to move away from the second support base 35, and one second elastic element can force the second live wire conductive rod 34 to move away from the second support base 35. This allows the second signal line conductive rod 31, the second ground wire conductive rod 32, the second neutral wire conductive rod 33, and the second live wire conductive rod 34 to be stably electrically connected to the corresponding wire connectors on the terminal block, thereby improving the reliability and stability of power-on.
[0029] Specifically, in this embodiment, the second elastic element is a second compression spring 36. The second power-on assembly 3 also includes multiple second guide sleeves 37, which are fastened to the second support base 35. A second signal line conductive rod 31 is movably disposed through one second guide sleeve 37, a second ground wire conductive rod 32 is movably disposed through one second guide sleeve 37, a second neutral wire conductive rod 33 is movably disposed through one second guide sleeve 37, a second live wire conductive rod 34 is movably disposed through one second guide sleeve 37, and a second compression spring 36 is sleeved on the second signal line conductive rod 31 and abuts against the end face of the second guide sleeve 37 and the second signal line conductive rod 36. Between the shoulders of pole 31, a first copper nut 38 is connected to one end of the second signal line conductive rod 31 near the end face of the second guide sleeve 37. The first copper nut 38 secures the external wire to the second signal line conductive rod 31, and the first copper nut 38 can press against the end face of the second guide sleeve 37 to limit the displacement of the second signal line conductive rod 31 forced away from the second support base 35 by the second compression spring 36. A second compression spring 36 is sleeved on the second ground wire conductive rod 32 and abuts against the end face of the second guide sleeve 37 and the shoulder of the second ground wire conductive rod 32. A second copper nut is connected to one end of the second ground wire conductive rod 32 near the end face of the second guide sleeve 37. 38. A second copper nut 38 secures the external wire to the second ground conductor rod 32, and the second copper nut 38 can press against the end face of the second guide sleeve 37 to limit the displacement of the second compression spring 36 that forces the second ground conductor rod 32 away from the second support base 35; a second compression spring 36 is sleeved on the second neutral conductor rod 33 and abuts against the end face of the second guide sleeve 37 and the shoulder of the second neutral conductor rod 33; a third copper nut 38 is connected to one end of the second neutral conductor rod 33 near the end face of the second guide sleeve 37, the third copper nut 38 secures the external wire to the second neutral conductor rod 33, and the third copper nut 38 can press against the end face of the second guide sleeve 37 to limit the displacement of the second ground conductor rod 32 that forces the second ground conductor rod 32 away from the second support base 35; a second compression spring 36 is sleeved on the second neutral conductor rod 33 and abuts against the shoulder of the second neutral conductor rod 33; a third copper nut 38 is connected to one end of the second neutral conductor rod 33 near the end face of the second guide sleeve 37, and the third copper nut 38 can press against the end face of the second neutral conductor rod 33. The second compression spring 36 is used to limit the displacement of the second neutral wire conductive rod 33 from the second support base 35 on the end face of the sleeve 37; a second compression spring 36 is sleeved on the second live wire conductive rod 34 and abuts between the end face of the second sleeve 37 and the shoulder of the second live wire conductive rod 34; a fourth copper nut 38 is connected to one end of the second live wire conductive rod 34 near the end face of the second sleeve 37; the fourth copper nut 38 secures the external wire to the second live wire conductive rod 34, and the fourth copper nut 38 can press against the end face of the second sleeve 37 to limit the displacement of the second live wire conductive rod 34 from the second support base 35 by the second compression spring 36.
[0030] The structure of the first power-on component 2 in this embodiment is basically similar to that of the second power-on component 3 in this embodiment, except that the number of live wire conductive rods is different. The first power-on component 2 in this embodiment also includes a first support base 25 and multiple first elastic elements. The first support base 25 is set on the third linkage base 17. The first signal wire conductive rod 21, the first ground wire conductive rod 22, the first neutral wire conductive rod 23, and the first live wire conductive rod 24 are movably supported on the first support base 25. One first elastic element can force the first signal wire conductive rod 21 to move away from the first support base 25, one first elastic element can force the first ground wire conductive rod 22 to move away from the first support base 25, one first elastic element can force the first neutral wire conductive rod 23 to move away from the first support base 25, and one first elastic element can force the first live wire conductive rod 24 to move away from the first support base 25. This allows the first signal wire conductive rod 21, the first ground wire conductive rod 22, the first neutral wire conductive rod 23, and the first live wire conductive rod 24 to be stably electrically connected to the corresponding wire connectors on the terminal block, thereby improving the reliability and stability of power-on.
[0031] The structure of the third power-on component 4 in this embodiment is basically similar to that of the second power-on component 3 in this embodiment, except that the number of live wire conductive rods is different. Therefore, the third power-on component 4 in this embodiment also includes a third support base 45 and multiple third elastic elements. The third support base 45 is set on the fifth linkage base 111. The third signal line conductive rod 41, the third ground wire conductive rod 42, the third neutral wire conductive rod 43, and the third live wire conductive rod 44 are movably supported on the third support base 45. One third elastic element can force the third signal line conductive rod 41 to move away from the third support base 45, one third elastic element can force the third ground wire conductive rod 42 to move away from the third support base 45, one third elastic element can force the third neutral wire conductive rod 43 to move away from the third support base 45, and one third elastic element can force one third live wire conductive rod 44 to move away from the third support base 45. This allows the third signal line conductive rod 41, the third ground wire conductive rod 42, the third neutral wire conductive rod 43, and the third live wire conductive rod 44 to be stably electrically connected to the corresponding wire connectors on the terminal block, thereby improving the reliability and stability of power-on.
[0032] The structure of the fourth power-on component 5 in this embodiment is basically similar to that of the second power-on component 3 in this embodiment, except that the number of live wire conductive rods is different. Therefore, the fourth power-on component 5 in this embodiment also includes a fourth support base 55 and multiple fourth elastic elements. The fourth support base 55 is set on the fifth linkage base 111. The fourth signal wire conductive rod 51, the fourth ground wire conductive rod 52, the fourth neutral wire conductive rod 53, and the fourth live wire conductive rod 54 are movably supported on the fourth support base 55. One fourth elastic element can force the fourth signal wire conductive rod 51 to move away from the fourth support base 55, one fourth elastic element can force the fourth ground wire conductive rod 52 to move away from the fourth support base 55, one fourth elastic element can force the fourth neutral wire conductive rod 53 to move away from the fourth support base 55, and one fourth elastic element can force one fourth live wire conductive rod 54 to move away from the fourth support base 55. This allows the fourth signal wire conductive rod 51, the fourth ground wire conductive rod 52, the fourth neutral wire conductive rod 53, and the fourth live wire conductive rod 54 to be stably electrically connected to the corresponding wire connectors on the terminal block, thereby improving the reliability and stability of power-on.
[0033] The above embodiments are merely preferred examples of the present invention and are not intended to limit the scope of the present invention. Therefore, all equivalent changes or modifications made to the structure, features and principles of the present invention in accordance with the claims of the present invention should be included in the scope of the present invention patent application.
Claims
1. An air conditioner testing and power-on device, comprising a first control mechanism and a first linkage seat, wherein the first control mechanism can control the first linkage seat to move in the vertical direction and / or the horizontal direction, characterized in that: The air conditioner test power-on device further includes a second control mechanism, a second linkage seat, a third control mechanism, a third linkage seat, a first power-on component, and a second power-on component. The second control mechanism is disposed on the first linkage seat and can control the second linkage seat to move in the vertical direction and / or the horizontal direction. The third control mechanism is disposed on the second linkage seat and can control the third linkage seat to rotate. The first power-on component and the second power-on component are distributed on the third linkage seat around the rotation axis of the third linkage seat. The first power-on component includes a first signal line conductive rod, a first ground wire conductive rod, a first neutral wire conductive rod, and a first live wire conductive rod. The second power-on component includes a second signal line conductive rod, a second ground wire conductive rod, a second neutral wire conductive rod, and a second live wire conductive rod. The number of the first live wire conductive rods is not equal to the number of the second live wire conductive rods. The second linkage seat is provided with a first baffle, and the first power-on component or the second power-on component may be located directly below the first baffle in the vertical direction.
2. The air conditioner testing and power-on device according to claim 1, characterized in that: The air conditioner test power-on device further includes a fourth control mechanism, a fourth linkage seat, a fifth control mechanism, a fifth linkage seat, a third power-on component, and a fourth power-on component. The fourth control mechanism is disposed on the first linkage seat and can control the fourth linkage seat to move in the vertical direction and / or the horizontal direction. The fifth control mechanism is disposed on the fourth linkage seat and can control the fifth linkage seat to rotate. The third power-on component and the fourth power-on component are distributed on the fifth linkage seat around the rotation axis of the fifth linkage seat. The third power-on component includes a third signal line conductive rod, a third ground wire conductive rod, a third neutral wire conductive rod, and a third live wire conductive rod. The fourth power-on component includes a fourth signal line conductive rod, a fourth ground wire conductive rod, a fourth neutral wire conductive rod, and a fourth live wire conductive rod. The number of third live wire conductive rods is not equal to the number of fourth live wire conductive rods.
3. The air conditioner testing power-on device according to claim 2, characterized in that: The fourth linkage seat is provided with a second baffle, and the third or fourth power-on component may be located directly below the second baffle in the vertical direction.
4. The air conditioner testing power-on device according to claim 1, characterized in that: The second control mechanism is a first movable cylinder, which is mounted on the first linkage seat, and the first piston rod of the first movable cylinder is connected to the second linkage seat. The moving direction of the first piston rod is inclined relative to the vertical direction.
5. The air conditioner testing power-on device according to claim 2, characterized in that: The fourth control mechanism is a second moving cylinder, which is mounted on the first linkage seat, and the second piston rod of the second moving cylinder is connected to the fourth linkage seat. The moving direction of the second piston rod is inclined relative to the vertical direction.
6. The air conditioner testing power-on device according to claim 2, characterized in that: The third control mechanism is a first rotary cylinder, which is mounted on the second linkage seat and can control the rotation of the third linkage seat; And / or, the fifth control mechanism is a second rotary cylinder, which is mounted on the fourth linkage seat and can control the rotation of the fifth linkage seat.
7. The air conditioner testing power-on device according to claim 2, characterized in that: The third power-on component also includes a third support base and a plurality of third elastic elements. The third support base is disposed on the fifth linkage base. The third signal line conductive rod, the third ground wire conductive rod, the third neutral wire conductive rod and the third live wire conductive rod are movably supported on the third support base. One of the third elastic elements can force the third signal line conductor rod to move away from the third support base; one of the third elastic elements can force the third ground conductor rod to move away from the third support base; one of the third elastic elements can force the third neutral conductor rod to move away from the third support base; one of the third elastic elements can force a third live conductor rod to move away from the third support base. And / or, the fourth power-on component further includes a fourth support base and a plurality of fourth elastic elements, the fourth support base being disposed on the fifth linkage base, and the fourth signal line conductive rod, the fourth ground wire conductive rod, the fourth neutral wire conductive rod and the fourth live wire conductive rod being movably supported on the fourth support base respectively; One of the fourth elastic elements can force the fourth signal line conductor rod to move away from the fourth support base; one of the fourth elastic elements can force the fourth ground conductor rod to move away from the fourth support base; one of the fourth elastic elements can force the fourth neutral conductor rod to move away from the fourth support base; and one of the fourth elastic elements can force a fourth live conductor rod to move away from the fourth support base.
8. The air conditioner testing power-on device according to any one of claims 1 to 7, characterized in that: The first power-on component also includes a first support base and a plurality of first elastic elements. The first support base is disposed on the third linkage base, and the first signal line conductive rod, the first ground wire conductive rod, the first neutral wire conductive rod and the first live wire conductive rod are respectively movably supported on the first support base. One of the first elastic elements can force the first signal line conductor rod to move away from the first support base; one of the first elastic elements can force the first ground conductor rod to move away from the first support base; one of the first elastic elements can force the first neutral conductor rod to move away from the first support base; and one of the first elastic elements can force a first live conductor rod to move away from the first support base. And / or, the second power-on component further includes a second support base and a plurality of second elastic elements, the second support base being disposed on the third linkage base, and the second signal line conductive rod, the second ground wire conductive rod, the second neutral wire conductive rod and the second live wire conductive rod being movably supported on the second support base respectively; One of the second elastic elements can force the second signal line conductor rod to move away from the second support base; one of the second elastic elements can force the second ground conductor rod to move away from the second support base; one of the second elastic elements can force the second neutral conductor rod to move away from the second support base; and one of the second elastic elements can force a second live conductor rod to move away from the second support base.
9. An air conditioning testing system, including an air conditioning testing power-on device, characterized in that: The air conditioner test power-on device is the air conditioner test power-on device according to any one of claims 1 to 8.