Purging device and two-vessel assembly production line

Abstract

The application discloses a blowing device and a two-vessel assembly production line. The blowing device is used for blowing stacked and placed material to be blown. The blowing device comprises a bearing base frame, a material placing tray of the bearing base frame is used for placing the material to be blown, a blowing mechanism is arranged on the bearing base frame in a lifting mode, and the blowing mechanism is arranged towards the material to be blown. The application can be used for blowing oxygen to the two-vessel assembly placed in a stacking mode, has high blowing efficiency, can ensure blowing quality, eliminates subjectivity and fatigue of manual blowing, and greatly reduces labor cost.

Description

Technical Field

[0001] This application relates to the field of two-component manufacturing technology, and more specifically, to a purging device and a two-component production line. Background Technology

[0002] In the production of air conditioning equipment's two-phase (condenser and evaporator) components, after the components are taken off the production line at high temperatures, oxide layer impurities easily form on the copper and iron metal surfaces of the components. Therefore, the components need to be transferred to an oxide scale removal area for cleaning and coating. Oxide scale removal is a common process in the metal processing field. After metal materials undergo hot processing (such as hot rolling, forging, welding, etc.), an oxide scale will form on the surface. The oxide scale is mainly composed of metal oxides, and its presence will affect the quality of subsequent processing, product performance, and appearance. Therefore, it needs to be removed by blowing the oxide scale.

[0003] Currently, the oxide scale removal operation of the two components after high-temperature welding is mainly carried out manually by workers using air blowing equipment. However, this manual blowing method is not only inefficient, but also cannot guarantee the blowing quality. It is easily affected by the subjective consciousness and fatigue of the workers. At the same time, it also has the problem of excessively high labor costs. Utility Model Content

[0004] The purpose of this application is to provide a purging device and a production line for two-component components. The purging device can be used to blow off oxide scale from stacked two-component components. It has high purging efficiency, can ensure purging quality, eliminates the subjectivity and fatigue problems of manual purging, and can also greatly reduce labor costs.

[0005] To achieve the above objectives, in a first aspect, this application provides a purging device for purging stacked materials to be purged, the purging device comprising:

[0006] A support frame, the support frame having a material placement tray for placing the material to be purged;

[0007] A blower mechanism is provided, which is vertically and flexibly mounted on the support frame and is oriented toward the material to be blown.

[0008] In the implementation of the above technical solution, the purging device can be used to remove oxide scale from the stacked two-component assembly. After the two-component assembly is removed from the high-temperature welding line, it can be stacked and then transported to the material placement pallet on the support frame. The blower mechanism, which is lifted and set on the support frame, blows the stacked two-component assembly from top to bottom. Multiple rounds of repeated blowing can be performed during the blowing process. This purging operation does not require the participation of personnel, has high purging efficiency, can ensure purging quality, eliminates the subjectivity and fatigue problems of manual purging, and can also greatly reduce labor costs.

[0009] In a preferred embodiment of this application, there are two blower mechanisms, which are respectively and vertically mounted on opposite sides of the support frame.

[0010] In the implementation of the above technical solution, two blower mechanisms are used, which are respectively set on opposite sides of the supporting base frame. During the blowing operation, the blower mechanism can blow the material to be blown from both sides, so that the air blown out by the blower mechanism is more sufficient and uniform, and better covers the material to be blown, thereby further improving the blowing quality and blowing efficiency, and effectively reducing the blowing operation time.

[0011] In a preferred embodiment of this application, the two blowers move synchronously up and down on the support frame.

[0012] In the implementation of the above technical solution, the two blower mechanisms move up and down synchronously, that is, the two blower mechanisms are at the same horizontal height and move up and down synchronously, which can make the blowing effect of the two blower mechanisms on the material to be blown better.

[0013] In a preferred embodiment of this application, the blower mechanism includes a blower guide plate, the blower guide plate having a blower section and a side section.

[0014] The blowing section of the air guide plate faces the material to be blown, and the air guide plate is provided with an air outlet; the side of the air guide plate is provided with an air inlet, and the air inlet is connected to the air outlet.

[0015] The air inlet is connected via an air inlet pipe to an external air supply mechanism used in conjunction with the blower guide plate.

[0016] In the implementation of the above technical solution, the blower mechanism adopts a blower guide plate. The blower guide plate has a plate structure. During blowing, the air blown out by the blower guide plate is more uniform and dispersed, and is better directed to the material to be blown, which can have a better blowing effect on the material to be blown. In addition, the air supply structure of the blower guide plate is relatively simple, which makes it easy to supply air to the blower guide plate.

[0017] In a preferred embodiment of this application, the air outlet is formed by a plurality of air holes provided on the air blowing part of the air blowing guide plate. The plurality of air holes are distributed in two rows on the air blowing part of the air blowing guide plate, and the two rows of air holes are staggered on the air blowing part of the air blowing guide plate.

[0018] In the implementation of the above technical solution, the air outlet is formed by two rows of air holes, and the holes on the two rows of air holes are staggered, which makes the air blown out by the air guide plate more uniform, delicate and dispersed, and less mutually interfered, thus achieving a more ideal blowing effect on the material to be blown.

[0019] In a preferred embodiment of this application, the supporting frame includes a conveying mechanism, the material placement tray, and a support.

[0020] The material placement tray is mounted on the conveying mechanism, and the support is mounted on the conveying mechanism; the blower mechanism is vertically and flexibly mounted on the support.

[0021] In the implementation of the above technical solution, the material placement tray is mounted on the conveying mechanism. The material placement tray can move under the action of the conveying mechanism, which facilitates the feeding and discharging of the material to be purged. This also facilitates the docking and cooperation between the purging device and other equipment or devices in the production line, improving automated operation. The bracket setting facilitates the lifting and lowering of the blowing mechanism. This structural design of the supporting frame is more reasonable and scientific. It not only improves the flexibility of the purging device, but also facilitates the realization of the functions of the purging device. It also makes the overall structure of the purging device simpler and lighter, and reduces the production cost of the purging device.

[0022] In a preferred embodiment of this application, the conveying mechanism includes two parallel conveying wheel sets and a transmission drive component.

[0023] Both of the two conveyor wheel sets are equipped with conveyor belts, and the two conveyor wheel sets are connected by a connecting shaft. The transmission drive component is driven to one of the two conveyor wheel sets.

[0024] The material placement tray is mounted on the two conveyor belts.

[0025] In the implementation of the above technical solution, the transmission drive component of the conveying mechanism is driven to one of the transmission wheels in the two conveying wheel sets. Under the drive of the transmission drive component, the transmission wheel connected to the transmission drive component is driven, and the transmission wheel will drive the other three transmission wheels to rotate, thereby driving the material placement pallet mounted on the two conveyor belts to move. This structure of the conveying mechanism can move the material placement pallet relatively stably and smoothly, and has a good moving driving effect.

[0026] In a preferred embodiment of this application, each of the two conveyor wheel sets is provided with a connecting plate, the bracket is a gantry frame, and the bracket is mounted on the conveying mechanism by connecting the connecting plates on the two conveyor wheel sets through its two sides;

[0027] A lifting drive mechanism is provided on the side of the bracket, and the blower mechanism is mounted on the lifting drive mechanism.

[0028] In the implementation of the above technical solution, the bracket adopts a gantry structure, which makes it easy to mount the bracket on the conveying mechanism, and also facilitates the installation of the lifting drive mechanism and the blower mechanism on the bracket.

[0029] In a preferred embodiment of this application, the lifting drive mechanism includes a lead screw assembly and a lifting drive component.

[0030] The lead screw assembly is vertically disposed on the side of the bracket, and the lifting drive component is disposed on the top of the bracket and is drivenly connected to the lead screw assembly.

[0031] The blower mechanism is mounted on the lead screw assembly via a slider.

[0032] In the implementation of the above technical solution, the lead screw assembly will rotate under the action of the lifting drive mechanism, which in turn can drive the slider to rise and fall. The rise and fall of the slider drives the rise and fall of the blower mechanism, realizing the up and down blowing of the material to be blown. This lifting drive mechanism can drive the rise and fall of the blower mechanism more stably and smoothly, making the blower mechanism more effective in blowing the material to be blown.

[0033] Secondly, this application provides a two-component assembly line, including the aforementioned purging device.

[0034] This application discloses a purging device and a two-component assembly line, which, compared with the prior art, have at least the following advantages:

[0035] The purging device of this application is suitable for purging stacked materials to be purged, especially for removing oxide scale from stacked two-component systems. It includes a support frame and a blower mechanism. The support frame has a material placement tray for holding the material to be purged. The blower mechanism is vertically mounted on the support frame and faces the material to be purged. After the two-component system has undergone high-temperature welding, it can be stacked, and then transported to the material placement tray on the support frame. The blower mechanism, vertically mounted on the support frame, blows the stacked components up and down. Multiple rounds of repeated purging can be performed during this process. This purging operation requires no human intervention, has high purging efficiency, ensures purging quality, eliminates the subjectivity and fatigue issues of manual purging, and significantly reduces labor costs.

[0036] The two-component assembly line of this application includes the above-mentioned blowing device. The blowing device can be used to blow oxide scale off stacked two-component assemblies, and can be connected and cooperated with other equipment or devices in the two-component assembly line. It can blow oxide scale off the two-component assemblies without the need for personnel to participate in the blowing operation, and the blowing efficiency is high. It can ensure the blowing quality and improve the production efficiency of the two-component assemblies. Attached Figure Description

[0037] To more clearly illustrate the technical solutions of the embodiments of this application, the accompanying drawings used in the embodiments of this application will be briefly introduced below. It should be understood that the following drawings only show some embodiments of this application and should not be regarded as a limitation of the scope. For those skilled in the art, other related drawings can be obtained based on these drawings without creative effort.

[0038] Figure 1 This is a three-dimensional structural schematic diagram of the purging device provided in the embodiments of this application;

[0039] Figure 2 This is a three-dimensional structural diagram of a purging device provided in this application embodiment, on which the material to be purged is placed;

[0040] Figure 3 This is a three-dimensional structural diagram of the blower mechanism provided in the embodiments of this application;

[0041] Figure 4 This is a partial structural schematic diagram of the purging device provided in the embodiments of this application.

[0042] Reference numerals: 10-Bearing base frame; 11-Conveying mechanism; 111-Conveying wheel assembly; 112-Conveyor belt; 113-Transmission drive component; 114-Connecting plate; 12-Material placement tray; 13-Support; 20-Blowing mechanism; 21-Blowing guide plate; 211-Blowing outlet; 212-Air inlet; 22-Slider; 30-Lifting drive mechanism; 31-Screw assembly; 32-Lifting drive component. Detailed Implementation

[0043] The technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, and not all embodiments. The components of the embodiments of this application described and shown in the accompanying drawings can be arranged and designed in various different configurations. Therefore, the following detailed description of the embodiments of this application provided in the accompanying drawings is not intended to limit the scope of the claimed application, but merely represents selected embodiments of this application. All other embodiments obtained by those skilled in the art based on the embodiments of this application without inventive effort are within the scope of protection of this application.

[0044] In this application, the terms "upper," "lower," "left," "right," "front," "rear," "top," "bottom," "inner," "outer," "middle," "vertical," "horizontal," "lateral," and "longitudinal" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. These terms are primarily for the purpose of better describing this application and its embodiments, and are not intended to limit the indicated device, element, or component to having a specific orientation, or to be constructed and operated in a specific orientation.

[0045] Furthermore, in addition to indicating location or positional relationship, some of the aforementioned terms may also have other meanings. For example, the term "above" may also be used in some cases to indicate a certain dependency or connection relationship. Those skilled in the art can understand the specific meaning of these terms in this application based on the specific circumstances.

[0046] Furthermore, the terms "installation," "setup," "equipped with," "connection," and "linked" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral structure; they can refer to a mechanical connection or a point connection; they can refer to a direct connection or an indirect connection through an intermediate medium, or an internal connection between two devices, components, or parts. Those skilled in the art can understand the specific meaning of these terms in this application based on the specific circumstances.

[0047] Furthermore, the terms "first," "second," etc., are primarily used to distinguish different devices, elements, or components (which may be the same or different in specific type and construction), and are not intended to indicate or imply the relative importance or quantity of the indicated devices, elements, or components. Unless otherwise stated, "a plurality of" means two or more.

[0048] Currently, the oxide scale removal operation of the two components after high-temperature welding is mainly carried out manually by workers using air blowing equipment. However, this manual blowing method is not only inefficient, but also cannot guarantee the blowing quality. It is easily affected by the subjective consciousness and fatigue of the workers. At the same time, it also has the problem of excessively high labor costs.

[0049] To address the problems in the prior art, this application provides a purging device and a two-component production line, which can be used to blow off oxide scale from stacked two-components. The purging efficiency is high, the purging quality can be ensured, the subjectivity and fatigue problems of manual purging are eliminated, and the labor costs can be greatly reduced.

[0050] Example 1

[0051] See Figure 1 and Figure 2 ,in, Figure 1 This is a three-dimensional structural diagram of the purging device provided in the embodiments of this application. Figure 2 This is a three-dimensional structural diagram of a purging device provided in this application, on which the material to be purged is placed. Figure 2 In the process, the material to be purged placed on the purging device consists of two stacked components.

[0052] The purging device according to an embodiment of this application includes:

[0053] The support frame 10 has a material placement tray 12, which is used to place the material to be purged.

[0054] The blower mechanism 20 is mounted on the support frame 10 in a height-adjustable manner, and the blower mechanism 20 is oriented toward the material to be blown.

[0055] The purging device of this application embodiment is suitable for purging stacked materials to be purged, and is particularly suitable for purging oxide scale from stacked two-component devices. In this embodiment, the purging device is described and explained using the purging device of this application embodiment to purge stacked two-component devices.

[0056] Understandably, a two-component assembly does not refer to a combination of a condenser assembly and an evaporator assembly; rather, a two-component assembly refers to either a condenser assembly or an evaporator assembly.

[0057] In this embodiment, the supporting base frame 10 is the main frame structure of the purging device, and the material placement tray 12 is used to place the material to be purged (i.e., the stacked two-component assembly). Preferably, the area of ​​the material placement tray 12 can be larger than the area of ​​the largest two-component assembly, so that it can fully support the two-component assembly and can be applied to all two-component assemblies.

[0058] In this embodiment, the blower mechanism 20 is vertically mounted on the support frame 10. When the blower mechanism 20 blows the material to be blown, the material to be blown can be blown up and down by the lifting and lowering movement of the blower mechanism 20, so that the material to be blown can be spread in the vertical direction and the material to be blown can be completely blown.

[0059] In some embodiments, limit photoelectric sensors can be set at the upper and lower limit positions of the blowing mechanism 20 or at the highest and lowest points corresponding to the material to be blown, and the lifting and lowering movements of the blowing mechanism 20 can be adjusted using the limit photoelectric sensors.

[0060] The blowing device of this application embodiment, when used to blow oxide scale off two stacked components, can stack the two components after they have been welded at high temperature, and then transport the stacked components to the material placement tray 12 on the support frame 10. The blowing mechanism 20, which is lifted and lowered on the support frame 10, blows the stacked components up and down. Multiple rounds of blowing can be performed during the blowing process. This blowing operation does not require the participation of personnel, has high blowing efficiency, can ensure the blowing quality, eliminates the subjectivity and fatigue problems of manual blowing, and can also greatly reduce labor costs.

[0061] In this embodiment, two blower mechanisms 20 are provided. The two blower mechanisms 20 are respectively mounted on opposite sides of the support base 10 in a liftable manner, and the two blower mechanisms 20 are respectively located on both sides of the material to be blown.

[0062] In the above structure, two blower mechanisms 20 are respectively set on opposite sides of the support base 10. During the blowing operation, the blower mechanism 20 can blow the material to be blown from both sides, so that the air blown by the blower mechanism 20 is more sufficient and uniform, and better covers the material to be blown, thereby further improving the blowing quality and blowing efficiency, and effectively reducing the blowing operation time.

[0063] Preferably, the two blower mechanisms 20 move up and down synchronously on the support frame 10.

[0064] For example, when the material to be blown is about to be blown, the two blower mechanisms 20 can be adjusted to the same horizontal height so that the two blower mechanisms 20 move up and down synchronously.

[0065] In the above structure, the two blower mechanisms 20 move up and down synchronously, that is, the two blower mechanisms 20 are at the same horizontal height and move up and down synchronously, which can make the blowing effect of the two blower mechanisms 20 on the material to be blown better.

[0066] Example 2

[0067] See Figures 1 to 3 Based on the above embodiment one, the difference between this embodiment and embodiment one is that the blowing device in this embodiment includes a blowing guide plate 21, which has a blowing part and a side part.

[0068] The blowing section of the air guide plate 21 faces the material to be blown, and the air guide plate 21 is provided with an air outlet 211; the side of the air guide plate 21 is provided with an air inlet 212, and the air inlet 212 is connected to the air outlet 211.

[0069] The air inlet 212 is connected to an external air supply mechanism for use with the air blower guide plate 21 via an air inlet pipe.

[0070] In this embodiment, the air guide plate 21 has a long strip-shaped plate structure. Specifically, the air guide plate 21 is a long trapezoidal columnar plate, and the air guide plate 21 is set parallel to the material to be blown. Preferably, the length of the air guide plate 21 can be set according to the length or width of the two-component assembly with the largest size, so that the air guide plate 21 can cover the two-component assembly during blowing, and can cover two-component assemblies of all sizes.

[0071] In this embodiment, the air inlet 212 can be disposed on one side of the air guide plate 21; for example, the external air supply mechanism used in conjunction with the air guide plate 21 can be a compressed air pipeline installed on the production line.

[0072] Preferably, an electromagnetic valve can be installed at one end of the air inlet pipe connected to the external air supply mechanism used in conjunction with the blower guide plate 21. The supply and cut-off of the air source can be controlled by the electromagnetic valve. By controlling the supply and cut-off of the air source, gas can be supplied only when the blower mechanism 20 is performing a purging operation, thereby reducing energy waste.

[0073] In the above structure, the blower mechanism 20 adopts a blower guide plate 21. The blower guide plate 21 is a plate structure. During blowing, the air blown by the blower guide plate 21 is more uniform and dispersed, and is better directed to the material to be blown, so as to have a better blowing effect on the material to be blown. In addition, the air supply structure of the blower guide plate 21 is relatively simple, which makes it easy to supply air to the blower guide plate 21.

[0074] In this embodiment, the air outlet 211 is formed by a plurality of air holes provided on the air blowing part of the air blowing guide plate 21. The plurality of air holes are distributed in two rows on the air blowing part of the air blowing guide plate 21, and the two rows of air holes are staggered on the air blowing part of the air blowing guide plate 21.

[0075] Specifically, two rows of air holes are distributed along the length of the air guide plate 21.

[0076] In the above structure, the air outlet 211 is formed by two rows of air holes, and the holes on the two rows of air holes are staggered, which makes the air blown out by the air guide plate 21 more uniform, delicate and dispersed, and less mutually interfered, thus achieving a more ideal blowing effect on the material to be blown.

[0077] Example 3

[0078] See Figures 1 to 4 Based on the above embodiment one or embodiment two, the difference between this embodiment and embodiment one or embodiment two is that the purging device in this embodiment includes a conveying mechanism 11, a material placement tray 12, and a support 13 on the support frame 10.

[0079] The material placement tray 12 is mounted on the conveying mechanism 11, and the bracket 13 is set on the conveying mechanism 11; the blower mechanism 20 is vertically mounted on the bracket 13.

[0080] In this embodiment, the conveying mechanism 11 can be placed on a supporting surface, such as the ground; the material placement tray 12 is square, and the material placement tray 12 moves under the action of the conveying mechanism 11.

[0081] In some implementations, the position of the material to be blown can be detected and determined by setting up a photoelectric sensor. For example, the photoelectric sensor can be set on the bracket 13. The operation of the conveying mechanism 11 can be controlled by the photoelectric sensor detecting and determining the position of the material to be blown. For example, when the photoelectric sensor detects and determines that the material to be blown is placed on the material placement tray 12, the operation of the conveying mechanism 11 can be controlled so that the conveying mechanism 11 moves the material placement tray 12 to the blowing operation area of ​​the blowing mechanism 20. When the photoelectric sensor detects and determines that the material to be blown has reached the blowing operation area of ​​the blowing mechanism 20, the conveying mechanism 11 can be controlled to stop working.

[0082] In the above structure, the material placement tray 12 is mounted on the conveying mechanism 11. The material placement tray 12 can move under the action of the conveying mechanism 11, which facilitates the feeding and discharging of the material to be purged. This also facilitates the docking and cooperation between the purging device and other equipment or devices in the production line, improving automated operation. The bracket 13 facilitates the lifting and lowering of the blowing mechanism 20. This structural design of the supporting frame 10 is more reasonable and scientific. It not only improves the flexibility of the purging device, but also facilitates the realization of the functions of the purging device. It also makes the overall structure of the purging device simpler and lighter, and reduces the production cost of the purging device.

[0083] Example 4

[0084] See Figures 1 to 4 Based on the above embodiment three, the difference between this embodiment and embodiment three is that the purging device in this embodiment includes two parallelly arranged transmission wheel sets 111 and a transmission drive component 113.

[0085] Each of the two conveyor wheel sets 111 is equipped with a conveyor belt 112. The two conveyor wheel sets 111 are connected by a connecting shaft. The transmission drive component 113 is driven to one of the transmission wheels in the two conveyor wheel sets 111.

[0086] The material placement tray 12 is mounted on two conveyor belts 112.

[0087] In this embodiment, each transmission wheel assembly 111 includes two transmission wheels, and the transmission drive component 113 may be a transmission drive motor.

[0088] In the above structure, the transmission drive 113 of the conveying mechanism 11 is driven to one of the transmission wheels in the two conveying wheel sets 111. Under the drive of the transmission drive 113, the transmission wheel connected to the transmission drive 113 is driven, and the transmission wheel will drive the other three transmission wheels to rotate, thereby driving the material placement tray 12 mounted on the two conveyor belts 112 to move. This structure of the conveying mechanism 11 can move the material placement tray 12 relatively stably and smoothly, and has a good moving driving effect.

[0089] In this embodiment, each of the two conveyor wheel sets 111 is provided with a connecting plate 114, and the bracket 13 is a gantry frame. The bracket 13 is connected to the connecting plate 114 on the two conveyor wheel sets 111 through its two sides and is mounted on the conveying mechanism 11.

[0090] A lifting drive mechanism 30 is provided on the side of the bracket 13, and the blower mechanism 20 is provided on the lifting drive mechanism 30.

[0091] In this embodiment, when there are two blower mechanisms 20, a lifting drive mechanism 30 is provided on both sides of the bracket 13, and the two blower mechanisms 20 are respectively provided on the lifting drive mechanism 30 on both sides of the bracket 13.

[0092] In this embodiment, a support plate is also connected between the two conveyor wheel sets 111. The support plate is located below the material placement tray 12 and can be used to support the material placement tray 12.

[0093] In the above structure, the support 13 adopts a gantry structure, which makes it easy for the support 13 to be mounted on the conveying mechanism 11, and also makes it easy for the lifting drive mechanism 30 and the blower mechanism 20 to be mounted on the support 13.

[0094] In this embodiment, the lifting drive mechanism 30 includes a lead screw assembly 31 and a lifting drive component 32.

[0095] The lead screw assembly 31 is vertically disposed on the side of the bracket 13, and the lifting drive component 32 is disposed on the top of the bracket 13 and is drivenly connected to the lead screw assembly 31.

[0096] The blower mechanism 20 is mounted on the lead screw assembly 31 via a slider 22.

[0097] Preferably, the lifting drive 32 can be a servo motor. Using a servo motor can drive the lead screw assembly 31 more precisely, making the lifting adjustment of the blower mechanism 20 more precise.

[0098] In the above structure, the lead screw assembly 31 rotates under the action of the lifting drive mechanism 30, which in turn drives the slider 22 to rise and fall. The rise and fall of the slider 22 drives the rise and fall of the blower mechanism 20, thereby achieving the up and down blowing of the material to be blown. This lifting drive mechanism 30 can drive the rise and fall of the blower mechanism 20 more stably and smoothly, making the blower mechanism 20 more effective at blowing the material to be blown.

[0099] Example 5

[0100] See Figures 1 to 4 This application provides a two-component production line, including a purging device from any of the embodiments one to four above.

[0101] The two-component production line of this application includes a purging device of any one of the above embodiments one to four. The purging device can be used to blow off the oxide scale from stacked two-components and can be connected and cooperated with other equipment or devices in the two-component production line. It can perform the oxide scale blowing operation of the two-components without the need for personnel to participate, and the purging efficiency is high, which can ensure the purging quality and improve the production efficiency of the two-components.

[0102] In all the above embodiments, "large" and "small" are relative terms, "more" and "less" are relative terms, and "upper" and "lower" are relative terms. The embodiments of this application will not elaborate further on the expression of such relative terms.

[0103] It should be understood that phrases such as "in one embodiment," "in this embodiment," "in this application embodiment," or "as an optional implementation" throughout the specification mean that a specific feature, structure, or characteristic related to an embodiment is included in at least one embodiment of this application. Therefore, phrases such as "in one embodiment," "in this embodiment," "in this application embodiment," or "as an optional implementation" appearing throughout the specification do not necessarily refer to the same embodiment. Furthermore, these specific features, structures, or characteristics can be combined in any suitable manner in one or more embodiments. Those skilled in the art should also understand that the embodiments described in the specification are all optional embodiments, and the actions and modules involved are not necessarily essential to this application.

[0104] In the various embodiments of this application, it should be understood that the sequence number of each process does not necessarily imply the order of execution. The execution order of each process should be determined by its function and internal logic, and should not constitute any limitation on the implementation process of the embodiments of this application.

[0105] The above description is merely a specific embodiment of this application, but the scope of protection of this application is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the scope of the technology disclosed in this application should be included within the scope of protection of this application. Therefore, the scope of protection of this application should be determined by the scope of protection of the claims.

Claims

1. A purging device, characterized in that, The purging device is used to purge stacked materials to be purged, and includes: The support frame (10) has a material placement tray (12) for placing the material to be purged; A blower mechanism (20) is provided, which is vertically mounted on the support frame (10) and is positioned facing the material to be blown.

2. The purging device according to claim 1, characterized in that, There are two blower mechanisms (20), and the two blower mechanisms (20) are respectively mounted on opposite sides of the support frame (10) in a liftable manner.

3. The purging device according to claim 2, characterized in that, The two blower mechanisms (20) move up and down synchronously on the support frame (10).

4. The purging apparatus according to any one of claims 1-3, characterized in that, The blower mechanism (20) includes a blower guide plate (21), which has a blower section and a side section. The blowing section of the blowing guide plate (21) faces the material to be blown, and the blowing section of the blowing guide plate (21) is provided with an air outlet (211); the side of the blowing guide plate (21) is provided with an air inlet (212), and the air inlet (212) is connected to the air outlet (211). The air inlet (212) is connected via an air inlet pipe to an external air supply mechanism for use in conjunction with the blower guide plate (21).

5. The purging device according to claim 4, characterized in that, The air outlet (211) is formed by a plurality of air holes provided on the air blowing part of the air blowing guide plate (21). The plurality of air holes are distributed in two rows on the air blowing part of the air blowing guide plate (21), and the two rows of air holes are staggered on the air blowing part of the air blowing guide plate (21).

6. The purging apparatus according to any one of claims 1-3, characterized in that, The supporting frame (10) includes a conveying mechanism (11), a material placement tray (12), and a support (13). The material placement tray (12) is mounted on the conveying mechanism (11), and the bracket (13) is mounted on the conveying mechanism (11); the blower mechanism (20) is vertically mounted on the bracket (13).

7. The purging device according to claim 6, characterized in that, The transmission mechanism (11) includes two parallel transmission wheel sets (111) and a transmission drive component (113). Each of the two conveyor wheel sets (111) is provided with a conveyor belt (112), and the two conveyor wheel sets (111) are connected by a connecting shaft. The transmission drive (113) is driven to one of the transmission wheels in the two conveyor wheel sets (111). The material placement tray (12) is mounted on the two conveyor belts (112).

8. The purging device according to claim 7, characterized in that, Each of the two conveyor wheel sets (111) is provided with a connecting plate (114). The bracket (13) is a gantry frame. The bracket (13) is connected to the connecting plate (114) on the two conveyor wheel sets (111) through its two sides and is mounted on the conveying mechanism (11). A lifting drive mechanism (30) is provided on the side of the bracket (13), and the blower mechanism (20) is provided on the lifting drive mechanism (30).

9. The purging device according to claim 8, characterized in that, The lifting drive mechanism (30) includes a lead screw assembly (31) and a lifting drive component (32). The lead screw assembly (31) is arranged vertically on the side of the bracket (13), and the lifting drive (32) is arranged on the top of the bracket (13) and is drivenly connected to the lead screw assembly (31). The blower mechanism (20) is mounted on the lead screw assembly (31) via a slider (22).

10. A two-component assembly line, characterized in that, Includes the purging device as described in any one of claims 1-9.

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