CN119702639B - A waste recycling and processing device for titanium alloy pipe processing with a screening structure - Google Patents

Abstract

The invention discloses a waste recycling device with a screening structure for processing titanium alloy pipes, which comprises a cleaning impurity collecting structure, wherein a screening pushing compression structure is arranged in the cleaning impurity collecting structure, the cleaning impurity collecting structure comprises a machine box with a feeding hopper, through holes for facilitating the through connection of parts are formed in the two sides of the machine box in a penetrating manner, a through hole plate with a discharge hole is fixedly arranged in the machine box, a through frame which is embedded and penetrated with one side of the machine box is fixedly arranged above the through hole plate, a groove is formed in the upper part of the through frame, a sliding groove is formed in the inner side of the through frame, another sliding groove is formed in the inner side of the groove, a leakage hole is formed in the groove in a penetrating manner, and a liquid outlet groove is formed in the rear side of the through frame.

Description

A waste recycling and processing device for titanium alloy pipe processing with a screening structure

Technical Field

The invention relates to the technical field of titanium alloy pipe processing, in particular to a waste material recovery and processing device for titanium alloy pipe processing with a screening structure.

Background Art

Titanium alloy tubes are tubes made of titanium alloys. Titanium alloys can be divided into three categories according to their organization. They have high mechanical properties, excellent stamping properties, and can be welded in various forms. The strength of the welded joint can reach 90% of the strength of the base metal, and the cutting performance is good. Titanium tubes have high corrosion resistance to chlorides, sulfides and ammonia. The corrosion resistance of titanium in seawater is higher than that of aluminum alloys, stainless steel, and nickel-based alloys. Titanium also has strong water impact resistance. In the production and processing of titanium alloy tubes, many unqualified products and waste materials will be generated. These unqualified products and waste materials need to be recycled to facilitate the recycling of titanium alloy tube waste. The general titanium alloy tube production environment is messy and mixed with metals of many different elements. Therefore, there will be a lot of metal fragments of different elements on the titanium alloy tube waste. If it is brought into the furnace for recycling, it will affect the overall quality of the titanium alloy tube and reduce the purity of the titanium alloy tube itself.

Summary of the invention

The purpose of the present invention is to address the shortcomings of the prior art and provide a waste recycling and processing device for titanium alloy tube processing with a screening structure to solve the problem proposed in the above background technology that the general titanium alloy tube production environment is messy and mixed with metals of many different elements. Therefore, the titanium alloy tube waste will be stained with a lot of metal fragments of different elements. If they are brought into the melting furnace for remelting, it will affect the overall quality of the titanium alloy tube and reduce the purity of the titanium alloy tube itself.

To achieve the above-mentioned purpose, the present invention provides the following technical solutions: a waste material recycling and processing device for titanium alloy tube processing with a screening structure, including a cleaning and sundry material collecting structure, wherein a screening and pushing material compression structure is provided inside the cleaning and sundry material collecting structure;

The cleaning material collection structure includes a chassis with a feed hopper, and through holes are provided on both sides of the chassis to facilitate the connection of parts, and a through-hole plate with a discharge port is fixedly installed inside the chassis;

A through frame is fixedly installed above the through-hole plate and is embedded and penetrated with one side of the chassis. A groove is opened above the through frame, and a sliding groove is opened inside the through frame. Another sliding groove is also opened inside the groove, and a leakage hole is opened through the groove.

By adopting the above technical solution, the chassis is provided to achieve opening and internal and external fixed installation.

Preferably, a liquid outlet groove is provided through the rear side of the through frame, and a hollow cavity plate is embedded and fixedly installed in the liquid outlet groove. At the same time, a conveying groove for convenient liquid diversion and conveying is provided above the hollow cavity plate. A blanking plate is fixedly installed at the lower part of the chassis body, and a guide plate extending from the outer wall of the chassis body is fixedly installed on one side of the blanking plate.

By adopting the above technical solution, the through frame is provided to achieve opening and fixed installation.

Preferably, a water tank is fixedly installed on the rear side of the chassis body, and the rear side of the water tank is fixedly installed with the hollow cavity plate through a connecting groove, and at the same time, a through-hole plate with a guide groove is fixedly installed on the upper part of the interior of the chassis body, a hopper is fixedly installed above the through-hole plate, and a spray pipe is laid and installed inside the hopper, and at the same time, the spray pipe passes through the chassis body through a branch connecting pipe, extends to the outer wall of the chassis body and is installed and connected to the high-pressure water pump, and the high-pressure water pump is installed and connected to the water tank through a connecting pipe.

By adopting the above technical solution, the hollow cavity plate is arranged to play the role of converging, conveying and collecting.

Preferably, a through-hole collecting frame is slidably installed inside the through-hole collecting frame, and a filter net that is easy to disassemble is laid inside the through-hole collecting frame. At the same time, a handle that is convenient for the operator to pull and draw is fixedly installed on one side of the through-hole collecting frame.

By adopting the above technical solution, the filter net is set to achieve interception and filtration.

Preferably, the screening, pushing and compressing structure includes a screening net with connecting rods fixed on both sides, and a sliding block matching the sliding of the guide groove is fixedly installed above the connecting rod, and at the same time, a convex rod and a hollow T-shaped rod extending through the through hole and extending to the chassis are fixedly installed at both ends of the connecting rod, and a connecting spring is arranged between the hollow T-shaped rod and the connecting rod, and one end of the connecting spring is fixedly installed on one side of the connecting rod, and the other end of the connecting spring is in contact with the inner wall of the chassis.

By adopting the above technical solution, the connecting spring is provided to penetrate and fix the two ends.

Preferably, a driving rod is installed in the hollow T-shaped rod, and a push block with a cleaning brush at the bottom is fixedly installed at one end of the driving rod, and the other end of the driving rod is fixedly connected to the output end of the adjusting cylinder. The adjusting cylinder is fixedly installed on one side of the outer wall of the chassis through a mounting frame, and the bottom of the screening net is slidably set above the through frame through another slider.

By adopting the above technical solution, the screening net is provided to drive the sliding adjustment.

Preferably, the protruding rod is in rotational contact with the cam, and the cam is fixedly installed on the rotating motor. At the same time, the rotating motor is fixedly installed on the other side of the outer wall of the chassis through a connecting frame. A rotating connecting rod is fixedly installed on the bottom of the connecting frame, and one end of the rotating connecting rod extends to the inside of the chassis and an adjusting block is fixedly installed thereon. At the same time, the adjusting block is slidably arranged above the blanking plate.

By adopting the above technical solution, the provided blanking plate can be used to collect the blanks.

Preferably, the output end of the adjusting cylinder is fixedly connected to the adjusting rod through a wrapping fixing piece, and the other end of the adjusting rod is fixedly connected to the top of the first rack through a bearing seat. At the same time, a driving gear is meshed below the first rack, and the driving gear is fixedly installed on one side of the outer wall of the chassis through a bearing frame.

By adopting the above technical solution, the package fixing parts are provided to achieve quick installation and disassembly.

Preferably, a guide slider is fixedly installed on the inner side of the bearing frame, and the guide slider is slidably matched with the second rack through a sliding bar. At the same time, a fixing rod is fixedly installed on one end of the second rack and fixedly installed with the extrusion block, and the fixing rod extends inside the chassis.

By adopting the above technical solution, the second rack is provided to achieve relative sliding adjustment.

Compared with the prior art, the invention has the following beneficial effects: the titanium alloy tube processing waste material recovery and processing device with screening structure is

(1) In this case, the following problems are solved by setting up the following in the screening and pushing compression structure: connecting rod, screening net, convex rod, hollow T-shaped rod, connecting spring, cam and rotating motor, so as to solve the problem that the general titanium alloy tube production environment is messy and mixed with metals of many different elements. Therefore, the titanium alloy tube waste will be stained with many metal fragments of different elements. If they are brought into the melting furnace for remelting, it will affect the overall quality of the titanium alloy tube and reduce the purity of the titanium alloy tube itself. When the titanium alloy tube waste falls on the screening net, the rotating motor drives the cam to rotate during operation. When the cam rotates under force, the convex rod drives the screening net to compress the connecting spring. When the cam and the convex rod are separated under force, the connecting spring recovers elasticity, thereby quickly screening and separating the titanium alloy tube and the impurity metal carried by the titanium alloy tube falling on the screening net;

(2) The above-mentioned problem is solved by cleaning the water tank, spray pipe, branch connecting pipe and branch connecting pipe provided in the debris collection structure. After the falling titanium alloy tube is initially screened, the operator controls the operation of the high-pressure water pump to transport the water in the water tank to the inside of the branch connecting pipe and the spray pipe, thereby flushing and collecting the impurities attached to the surface of the titanium alloy tube or the metal that is difficult to screen and shake off;

(3) The cleaning material collection structure is provided with: a through frame, a groove, a leaking hole, a liquid outlet trough, a hollow cavity plate and a conveying trough, so as to solve the problem that the water for spray cleaning cannot be collected and recycled. When the water sprayed and falling into the through trough falls into the through frame through the leaking hole, it is transported to the conveying trough through the liquid outlet trough. The spray water entering the conveying trough is transported to the water tank through the hollow cavity plate for recycling and collection;

(4) By cleaning the through-hole collection frame and the filter screen provided in the sundry material collection structure, impurities and dust or particles carried on the surface of the titanium alloy tube are intercepted and collected by the filter screen. At the same time, the filter screen is also used to effectively filter the spray water to prevent impurities, dust or particles from entering the water tank and causing damage to the high-pressure water pump. The through-hole collection frame is provided to facilitate the operator to pull out the through-hole collection frame, thereby replacing the filter screen inside the through-hole collection frame.

(5) The problem of the titanium alloy tubes falling on the screening net being unable to be quickly pushed out is solved by setting the driving rod, cleaning brush, pushing block and adjusting cylinder in the screening pushing compression structure. After the titanium alloy tubes are screened and cleaned, the operator controls the adjusting cylinder to drive the driving rod to move. When the driving rod is forced to move, the cleaning brush and the pushing block are simultaneously forced to move, thereby cleaning the screening net and pushing out the titanium alloy tubes falling on the screening net;

(6) The problem that the falling titanium alloy tube cannot be squeezed and collected is solved by screening the following settings in the pushing and compressing structure: the wrapping fixing, the adjusting rod, the first rack, the driving gear, the guide slider, the second rack, the sliding bar, the extrusion block, the rotating connecting rod and the adjusting block. When the falling titanium alloy tube falls on the blanking plate, the wrapping fixing and the adjusting rod are driven in reverse by the adjusting cylinder to drive the first rack to move. After the first rack moves under force, it drives the second rack to slide relative to it through the driving gear. When the second rack slides relative to it, the extrusion block and the adjusting block are driven to move relative to each other through the fixing rod, thereby squeezing and compressing the titanium alloy tube on the blanking plate. When it is convenient to discharge and transport the extruded titanium alloy tube, the operator loosens and rotates the connecting rod to pull the adjusting block out of the chassis to facilitate the discharge and transportation of the compressed titanium alloy tube. In addition, by setting the wrapping fixing, the operator can quickly install and disassemble the wrapping fixing, thereby avoiding the fixing rod being always fixed, which makes it impossible for the operator to pull and withdraw the through-hole collection frame.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of a front cross-sectional structure of the present invention;

2 is a schematic diagram of the structure of the chassis, through-hole plate, through-frame, blanking plate, material guide plate, through-port plate, hopper, spray pipe, branch connecting pipe, high-pressure water pump, through-hole collecting frame and filter screen of the present invention;

FIG3 is a schematic diagram of the structure of the through frame, grooves, sliding grooves, leak holes, liquid outlet grooves and hollow cavity plates of the present invention;

FIG4 is a schematic diagram of the partial structure of the port plate, guide groove and slider of the present invention;

FIG5 is a schematic diagram of the water tank structure of the present invention;

FIG6 is a schematic diagram of the partial structure of the hollow cavity plate and the conveying trough of the present invention;

7 is a schematic diagram of the structure of the screening net, the connecting rod, the slider, the convex rod, the hollow T-shaped rod, the connecting spring, the driving rod, the push block, the cleaning brush, the adjusting cylinder, the cam, the rotating motor, the connecting frame, the rotating connecting rod, the wrapping fixing member, the adjusting rod, the first rack, the driving gear, the bearing frame, the guide slider, the second rack, the fixing rod, the extrusion block and the adjusting block of the present invention;

FIG. 8 is a schematic diagram of the partial structure of the guide slider and the slide bar of the present invention.

In the figure: 1. Cleaning material collection structure; 101. Chassis; 102. Through-hole plate; 103. Through-frame; 104. Groove; 105. Sliding groove; 106. Leakage hole; 107. Liquid outlet groove; 108. Hollow cavity plate; 109. Conveying trough; 1010. Dropping plate; 1011. Guide plate; 1012. Water tank; 1013. Through-hole plate; 1014. Guide groove; 1015. Hopper; 1016. Spray pipe; 1017. Branch connecting pipe; 1018. High-pressure water pump; 1019. Through-hole collection frame; 1020. Filter; 2. Screening and pushing compression structure; 201. Screening net; 202. Connecting pipe; 203. Connecting rod; 203, slider; 204, convex rod; 205, hollow T-shaped rod; 206, connecting spring; 207, driving rod; 208, pushing block; 209, cleaning brush; 2010, adjusting cylinder; 2011, cam; 2012, rotating motor; 2013, connecting frame; 2014, rotating connecting rod; 2015, wrapping fixing piece; 2016, adjusting rod; 2017, first rack; 2018, driving gear; 2019, bearing frame; 2020, guide slider; 2021, sliding strip; 2022, second rack; 2023, fixing rod; 2024, extrusion block; 2025, adjusting block.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the present invention to clearly and completely describe the technical solutions in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the present invention.

Please refer to Figures 1-8. The present invention provides a technical solution: a waste recycling and processing device for titanium alloy tube processing with a screening structure, as shown in Figures 1, 2, 3, 4, 5 and 6, includes a cleaning and miscellaneous material collection structure 1, the cleaning and miscellaneous material collection structure 1 includes a chassis 101 with a feed hopper, and through holes are opened on both sides of the chassis 101 to facilitate the through connection of parts, and a through-hole plate 102 with a discharge port is fixedly installed inside the chassis 101, and the through-hole plate 102 is above A through frame 103 is fixedly installed and embedded in one side of the chassis body 101, and a groove 104 is opened on the top of the through frame 103. At the same time, a sliding groove 105 is opened on the inner side of the through frame 103, and another sliding groove 105 is also opened on the inner side of the groove 104, and a leakage hole 106 is opened through the groove 104, wherein the sliding groove 105 is opened in 2 groups of 4 strips. When 4 strips are opened by using the above structure, it is not only convenient for the sliding matching of the through hole collecting frame 1019, but also convenient for the sliding matching adjustment of the screening net 201.

In the above scheme, a liquid outlet groove 107 is provided on the rear side of the through frame 103, and a hollow cavity plate 108 is fixedly installed in the liquid outlet groove 107, and a conveying groove 109 for facilitating liquid diversion and conveying is provided above the hollow cavity plate 108. A blanking plate 1010 is fixedly installed at the lower part of the chassis 101, and a guide plate 1011 extending from the outer wall of the chassis 101 is fixedly installed on one side of the blanking plate 1010. A water tank 1012 is fixedly installed at the rear side of the chassis 101, and the rear side of the water tank 1012 is fixedly installed with the hollow cavity plate 108 through a connecting groove. At the same time, a through-hole plate 1013 with a guide groove 1014 is fixedly installed above the chassis 101, and a hopper 1015 is fixedly installed above the through-hole plate 1013. A spray pipe 1016 is installed inside the hopper 1015, and the spray pipe 1016 passes through the chassis 101 through a branch connecting pipe 1017, extends to the outer wall of the chassis 101 and is installed and connected to a high-pressure water pump 1018. The high-pressure water pump 1018 is installed and connected to the water tank 1012 through a connecting pipe. A through-hole collecting frame 1019 is slidably installed inside the through-hole collecting frame 103, and a filter screen 1020 that is easy to disassemble is laid inside the through-hole collecting frame 1019. At the same time, a handle that is convenient for the operator to pull and draw is fixedly installed on one side of the through-hole collecting frame 1019, wherein the above-mentioned components constitute a sliding matching structure, and the sliding matching structure constituted by the above-mentioned components effectively facilitates the sliding storage and sliding pulling separation of the through-hole collecting frame 1019.

As shown in Figures 7 and 8, a screening, pushing and compressing structure 2 is provided inside the cleaning and miscellaneous material collection structure 1. The screening, pushing and compressing structure 2 includes a screening net 201 with connecting rods 202 fixed on both sides, and a slider 203 that slides in the guide groove 1014 is fixedly installed above the connecting rod 202. At the same time, a convex rod 204 and a hollow T-shaped rod 205 that pass through the through hole and extend to the chassis 101 are fixedly installed at both ends of the connecting rod 202. A connecting spring 206 is provided between the hollow T-shaped rod 205 and the connecting rod 202, and one end of the connecting spring 206 is fixedly installed on one side of the connecting rod 202, and the other end of the connecting spring 206 contacts the inner wall of the chassis 101. A driving rod 207 is installed in the hollow T-shaped rod 205, and the driving rod 207 A push block 208 with a cleaning brush 209 at the bottom is fixedly installed at one end, and the other end of the driving rod 207 is fixedly connected to the output end of the adjusting cylinder 2010. The adjusting cylinder 2010 is fixedly installed on one side of the outer wall of the chassis 101 through a mounting frame, and the bottom of the screening net 201 is slidably set above the through frame 103 through another slider 203, wherein the above-mentioned components constitute a driving and adjusting structure, and the driving and adjusting structure constituted by the above-mentioned components can effectively drive the cleaning brush 209 and the push block 208 to be synchronously driven and adjusted, so as to clean the screening net 201 and push the material to be discharged, and a group of connecting rods 202 are provided, and one of the connecting rods 202 is penetrated by a material discharge trough to facilitate the pushing and discharging of the titanium alloy pipe waste after screening and cleaning.

In the above scheme, the protruding rod 204 is in rotational contact with the cam 2011, and the cam 2011 is fixedly installed with the rotating motor 2012. At the same time, the rotating motor 2012 is fixedly installed on the other side of the outer wall of the chassis 101 through the connecting frame 2013. A rotating connecting rod 2014 is fixedly installed at the bottom of the connecting frame 2013, and one end of the rotating connecting rod 2014 extends inside the chassis 101 and is fixedly installed with an adjusting block 2025. At the same time, the adjusting block 2025 is slidably arranged above the blanking plate 1010. The output end of the adjusting cylinder 2010 is fixedly connected with the adjusting rod 2016 through the wrapping fixing piece 2015, and the other end of the adjusting rod 2016 is fixedly connected with the upper part of the first rack 2017 through the bearing seat. At the same time, a driving gear 2018 is meshed with the lower part of the first rack 2017. The driving gear 2018 is fixedly installed on one side of the outer wall of the chassis 101 through the bearing frame 2019, and a guide slider 2020 is fixedly installed on the inner side of the bearing frame 2019, and the guide slider 2020 is slidably matched with the second rack 2022 through the sliding bar 2021, and at the same time, a fixing rod 2023 is fixedly installed on one end of the second rack 2022 and fixedly installed with the extrusion block 2024, and the fixing rod 2023 extends inside the chassis 101, wherein the above-mentioned components constitute a relative sliding adjustment structure, and when the relative sliding adjustment structure constituted by the above-mentioned components is utilized, the sliding directions of the second rack 2022 and the first rack 2017 are effectively made opposite, so as to facilitate the extrusion block 2024 and the adjustment block 2025 to move in the opposite direction, so as to extrude the falling titanium alloy tube and facilitate the subsequent handling.

In the above scheme, when the waste titanium alloy tube is placed inside the chassis 101 and then falls on the filter screen 1020, the rotating motor 2012 drives the cam 2011 to rotate when it is running. When the cam 2011 rotates under force, the convex rod 204 is squeezed to drive the screening net 201 to squeeze the connecting spring 206. When the cam 2011 and the convex rod 204 are separated under force, the connecting spring 206 elastically recovers, thereby quickly screening and separating the titanium alloy tube and the impurity metal carried by the falling on the screening net 201. The screened impurity metal, dust or particles fall into the through hole collection frame 1019 through the leakage hole 106 for collection. When the waste titanium alloy tube After the preliminary vibration screening of the pipe, the operator controls the high-pressure water pump 1018 to operate and transport the water in the water tank 1012 to the branch connecting pipe 1017 and the spray pipe 1016, so as to flush and collect the impurities attached to the surface of the titanium alloy pipe or the metal that is difficult to screen and shake off. The sprayed water also falls into the through frame 103 through the groove 104 and the leak hole 106, and is transported to the hollow cavity plate 108 through the liquid outlet groove 107 and the conveying groove 109. The water entering the hollow cavity plate 108 is transported to the water tank 1012 for recycling. After the waste titanium alloy pipe is cleaned, the operator controls the regulating cylinder 2010 to drive the driving rod 20 7 movement, when the driving rod 207 is forced to move, it synchronously drives the cleaning brush 209 and the pushing block 208 to move synchronously, thereby cleaning the screening net 201 and pushing the titanium alloy tube that falls on the screening net 201 to drop onto the blanking plate 1010, and at the same time, when the adjusting cylinder 2010 is driven to move, it drives the first rack 2017 to move synchronously through the wrapping fixing piece 2015 and the adjusting rod 2016, and when the first rack 2017 is forced to drive and adjust, it drives the second rack 2022 to slide relatively by driving the gear 2018, and when the second rack 2022 slides relatively, the extrusion block 2024 and the adjusting block 2025 are relatively pressed. The movement is adjusted to facilitate the falling, collection and extrusion of the titanium alloy tube. When the titanium alloy tube is compressed, the operator loosens and rotates the connecting rod 2014 to separate the adjusting block 2025 from the chassis 101, so that the extrusion block 2024 can push the compressed titanium alloy tube to discharge the material. At the same time, when the filter screen 1020 inside the through-hole collection frame 1019 needs to be pulled apart, the operator removes the wrapping fixing 2015 and rotates the adjusting rod 2016 to facilitate the operator to pull and separate the through-hole collection frame 1019, and disassemble, clean and dump the impurity metal, particles, dust and filter screen 1020 inside the through-hole collection frame 1019.

The directions or positional relationships indicated by terms such as "center", "longitudinal", "lateral", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inside" and "outside" are based on the directions or positional relationships shown in the accompanying drawings. They are merely simplified descriptions for the convenience of describing the present invention, and do not indicate or imply that the devices or elements referred to must have a specific direction, be constructed and operated in a specific direction. Therefore, they should not be understood as limitations on the protection content of the present invention.

Although the present invention has been described in detail with reference to the aforementioned embodiments, it is still possible for those skilled in the art to modify the technical solutions described in the aforementioned embodiments, or to make equivalent substitutions for some of the technical features therein. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of the present invention should be included in the protection scope of the present invention.

Claims (5)

1. The waste recycling device with the screening structure for the titanium alloy tube processing is characterized by comprising a cleaning impurity collecting structure (1), wherein a screening pushing compression structure (2) is arranged in the cleaning impurity collecting structure (1);

The cleaning impurity collecting structure (1) comprises a machine box body (101) with a feed hopper, through holes for facilitating the through connection of parts are formed in two sides of the machine box body (101), and a through hole plate (102) with a discharge hole is fixedly arranged in the machine box body (101);

A through frame (103) which is embedded and penetrated with one side of the machine box body (101) is fixedly arranged above the through hole plate (102), a groove (104) is formed above the through frame (103), meanwhile, a sliding groove (105) is formed in the inner side of the through frame (103), another sliding groove (105) is formed in the inner side of the groove (104), and a leak hole (106) is formed in the groove (104) in a penetrating mode;

The screening pushing compression structure (2) comprises a screening net (201) with connecting rods (202) fixed at two sides, a sliding block (203) matched with a guide groove (1014) in a sliding mode is fixedly installed above the connecting rods (202), meanwhile, a convex rod (204) and a hollow T-shaped rod (205) which penetrate through a through hole and extend to a machine box (101) are fixedly installed at two ends of the connecting rods (202), a connecting spring (206) is arranged between the hollow T-shaped rod (205) and the connecting rods (202), one end of each connecting spring (206) is fixedly installed on one side of each connecting rod (202), and the other end of each connecting spring (206) is in contact with the inner wall of the machine box (101);

A driving rod (207) is arranged in the hollow T-shaped rod (205) in a matched mode, a pushing block (208) with a cleaning brush (209) at the bottom is fixedly arranged at one end of the driving rod (207), the other end of the driving rod (207) is fixedly connected with the output end of an adjusting cylinder (2010), the adjusting cylinder (2010) is fixedly arranged on one side of the outer wall of the machine box (101) through a mounting frame, and the bottom of the screening net (201) is arranged above the through frame (103) in a sliding mode through another sliding block (203);

The output end of the adjusting cylinder (2010) is fixedly connected with an adjusting rod (2016) through a wrapping fixing piece (2015), the other end of the adjusting rod (2016) is fixedly connected with the upper part of a first rack (2017) through a bearing seat, meanwhile, a driving gear (2018) is meshed below the first rack (2017), and the driving gear (2018) is fixedly arranged on one side of the outer wall of the machine box (101) through a bearing frame (2019);

the inside fixed mounting of bearing bracket (2019) has direction slider (2020), and direction slider (2020) is supporting with second rack (2022) is slided through sliding strip (2021), and second rack (2022) one end fixed mounting has dead lever (2023) with extrusion piece (2024) fixed mounting simultaneously, dead lever (2023) extend in quick-witted box (101) inside.

2. The waste recycling device with the screening structure for processing the titanium alloy tube is characterized in that a liquid outlet groove (107) is formed in the rear side of the through frame (103) in a penetrating mode, a hollow cavity plate (108) is fixedly installed in the liquid outlet groove (107) in an embedded mode, meanwhile, a conveying groove (109) facilitating liquid diversion and conveying is formed in the upper portion of the hollow cavity plate (108), a blanking plate (1010) is fixedly installed below the inner portion of the machine box (101), and a material guide plate (1011) extending out of the outer wall of the machine box (101) is fixedly installed on one side of the blanking plate (1010).

3. The titanium alloy tube processing waste recycling device with a screening structure is characterized in that a water tank (1012) is fixedly arranged on the rear side of a machine box (101), the rear side of the water tank (1012) is fixedly arranged in an inlaid mode through a connecting groove and a hollow cavity plate (108), a through hole plate (1013) with a guide groove (1014) is fixedly arranged above the inner portion of the machine box (101), a hopper (1015) is fixedly arranged above the through hole plate (1013), a spraying pipe (1016) is paved inside the hopper (1015), meanwhile the spraying pipe (1016) penetrates through the machine box (101) through a branch connecting pipe (1017) and extends to the outer wall of the machine box (101) to be connected with a high-pressure water pump (1018), and the high-pressure water pump (1018) is connected with the water tank (1012) through the connecting pipe.

4. The waste recycling device with the screening structure for processing the titanium alloy tube is characterized in that a through hole collecting frame (1019) is installed in the through frame (103) in a sliding matching mode, a filter screen (1020) convenient to detach is paved in the through hole collecting frame (1019), and a handle convenient for an operator to pull and pull is fixedly installed on one side of the through hole collecting frame (1019).

5. The waste recycling device with the screening structure for processing the titanium alloy tube is characterized in that the protruding rod (204) is in rotary contact with the cam (2011), the cam (2011) is fixedly installed with the rotary motor (2012), the rotary motor (2012) is fixedly installed on the other side of the outer wall of the machine box (101) through the connecting frame (2013), the rotary connecting rod (2014) is fixedly installed at the bottom of the connecting frame (2013), one end of the rotary connecting rod (2014) extends into the machine box (101) and is fixedly provided with the adjusting block (2025), and the adjusting block (2025) is slidingly arranged above the blanking plate (1010).