A protective diamond coated tool machining cleaning device

By introducing partitioned cleaning and motor-controlled cleaning devices into diamond tool cleaning equipment, the problem of dirt splashing caused by alcohol rinsing is solved, achieving a highly efficient cleaning and drying process, and ensuring cleaning effect and equipment lifespan.

CN118162397BActive Publication Date: 2026-06-19CHANGZHOU YEGE TOOLS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
CHANGZHOU YEGE TOOLS CO LTD
Filing Date
2024-03-13
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

In existing technologies, when rinsing diamond tools with alcohol, debris and dirt easily splash and adhere to the inner wall of the cleaning device, affecting the cleaning effect and the lifespan of the device.

Method used

A protective cleaning device for diamond-coated cutting tools was designed. It is divided into an immersion zone, a brush cleaning zone, a high-pressure rinsing zone, and a drying zone by a partition. Combined with a spray washing component, a brush component, and a drying device, it realizes high-pressure rinsing of organic solvents, brush cleaning, and drying to prevent dirt from adhering. The smooth operation of the cleaning process is ensured by the control of an electric push rod and a motor.

Benefits of technology

It effectively prevents dirt from adhering to the inner wall of the cleaning device, improves cleaning efficiency and cleaning effect, avoids contamination of the next cutting tool, and extends the service life of the device.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention relates to the field of machine tool cleaning, and more particularly to a protective cleaning device for machining diamond-coated tools. Technical problem: When rinsing tools with alcohol, a large amount of debris and dirt splashes out, easily adhering to the inner wall of the end cap, hindering the cleaning of the next tool. Technical solution: A protective cleaning device for machining diamond-coated tools, including a base frame, etc. This invention controls a first electric push rod and push ring to move a partition downwards until the upper part of the partition is flush with the lower part of the cleaning tank. The partition and the cleaning tank generate relative movement, causing the cleaning tank to scrape off the dirt from the partition. After the partition descends, the organic solvent in the soaking area can flow to various areas of the cleaning tank, thereby soaking and cleaning each area of ​​the cleaning tank and preventing dirt adhering to the inner wall of the cleaning tank from contaminating the next tool.
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Description

Technical Field

[0001] This invention relates to the field of machine tool cleaning, and more particularly to a cleaning device for machining protective diamond-coated cutting tools. Background Technology

[0002] Existing Chinese patent CN111229677B discloses a fully automatic cleaning device and method for diamond tools. It achieves different cleaning processes for diamond tools through the rotation of a swing arm, which sequentially performs soaking cleaning, brush cleaning, high-pressure rinsing, and drying processes. The cleaning process is fully automatic, saving a lot of manpower and resources. The diamond tools are cleaned in a more orderly manner, improving cleaning efficiency.

[0003] However, when brushes and alcohol are used to rinse the blades, a large amount of debris and dirt on the blade surface will splash out. This debris and dirt can easily adhere to the inner wall of the device, affecting the lifespan of the device and reducing the cleaning effect on subsequent blades. Summary of the Invention

[0004] To overcome the drawback that alcohol splashes a large amount of debris and dirt when rinsing cutting tools, which easily adheres to the inner wall of the end cap and makes it difficult to clean the next tool, this invention provides a protective cleaning device for diamond-coated cutting tool machining.

[0005] The technical solution is as follows: A protective cleaning device for diamond-coated cutting tool processing includes a base frame; it also includes a conveying pipe, a cleaning bucket, partitions, a first electric push rod, a push ring, a second electric push rod, a fixed plate, a first motor, a rotating rod, a connecting cylinder, a protective bucket, a sleeve, a spraying assembly, and a brush assembly; the cleaning bucket is fixedly connected to the base frame; four partitions are slidably connected to the cleaning bucket; all the partitions divide the cleaning bucket into four areas: an immersion area, a brush cleaning area, a high-pressure rinsing area, and a drying area; a drying device is provided in the drying area; the first electric push rod is fixedly connected to the base frame; the extension and retraction of the first electric push rod... A push ring is fixedly connected to one end, and the push ring is fixedly connected to a partition plate; several second electric push rods are fixedly connected to the base frame; the telescopic ends of all the second electric push rods are fixedly connected to a fixed plate; a first motor is fixedly connected to the fixed plate; a rotating rod is fixedly connected to the output shaft of the first motor; a connecting cylinder is fixedly connected to the rotating rod; a protective bucket is fixedly connected to the connecting cylinder, and the protective bucket is in contact with the cleaning bucket; a conveying pipe is fixedly connected to the protective bucket, and the conveying pipe is connected to the soaking area; several sleeves are fixedly connected to the rotating rod, and the sleeves correspond to the four areas of the cleaning bucket; a spray washing assembly is connected in the high-pressure rinsing area; a brush assembly is connected in the brush cleaning area.

[0006] Optionally, the brush assembly includes a third electric push rod, a connecting block, a connecting rod, and brush bristles; the cleaning bucket is fixedly connected to the third electric push rod; the telescopic end of the third electric push rod is movably connected to the connecting block, and the connecting block is rotatably connected to the cleaning bucket; the connecting block is connected to the connecting rod; and the connecting rod is fixedly connected to several brush bristles.

[0007] Optionally, the spray washing assembly includes a nozzle, a discharge pipe, a DD motor, and a spray nozzle; the nozzle is fixedly connected to the high-pressure washing zone; the discharge pipe is fixedly connected to the high-pressure washing zone; the DD motor is fixedly connected to the washing tank, and the output end of the DD motor is fixedly connected to the nozzle; the nozzle is connected to the spray nozzle.

[0008] Optionally, the nozzle is configured in a curved shape.

[0009] Optionally, it also includes a second motor, a rope, and a spring rod; the second motor is fixedly connected to the connecting block; the output shaft of the second motor is wound with the rope, and the rope is fixedly connected to the connecting rod; the connecting rod is slidably connected to the connecting block.

[0010] Optionally, the connecting rod is hollow; each connecting rod has several circular holes.

[0011] Optionally, it also includes a fourth electric push rod, a rotating block, and a lever; the fourth electric push rod is fixedly connected to the outside of the soaking zone; the telescopic end of the fourth electric push rod is movably connected to the rotating block, and the rotating block is rotatably connected to the washing bucket; the rotating block is fixedly connected to several levers.

[0012] Optionally, an ultrasonic generator is installed inside the lever.

[0013] Optionally, the bristles and holes are staggered.

[0014] Optionally, it also includes a rotating system; the rotating system includes a third motor, a gear disk and a gear; the connecting sleeve is fixedly connected to the third motor; the output shaft of the third motor is fixedly connected to the gear disk; the sleeve is fixedly connected to the gear, and the gear meshes with the gear disk; the sleeve is rotatably connected to the rotating rod.

[0015] The beneficial effects of this invention are as follows: By controlling the start of an external pump, the invention delivers organic solvent to the nozzle through the nozzle. The nozzle sprays the organic solvent into the tool body in the high-pressure rinsing zone, thereby rinsing the tool body under high pressure. Since the nozzle is spherical, when the protective bucket rotates 90 degrees to reach the high-pressure rinsing zone, the organic solvent sprayed from the nozzle disperses in all directions, thereby rinsing the lower side of the protective bucket and washing away the dirt remaining in the lower side of the protective bucket, thus preventing the dirt from contaminating the next tool body.

[0016] This invention controls the first electric push rod and push ring to move the partition downwards until the upper part of the partition is flush with the lower part of the cleaning tank. The partition and the cleaning tank then move relative to each other, and the cleaning tank scrapes off the dirt from the partition. After the partition descends, the organic solvent in the soaking area can flow to each area of ​​the cleaning tank, thereby soaking and cleaning each area of ​​the cleaning tank and preventing the dirt adhering to the inner wall of the cleaning tank from contaminating the next tool body.

[0017] This invention controls the start of a third motor, which in turn drives a gear plate to rotate via its output shaft. The gear plate then drives the gears, sleeve, and cutter body to rotate, thereby increasing the cleaning and drying efficiency of the cutter body during the cleaning and drying process. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the structure of the cleaning device for machining protective diamond-coated tools according to the present invention;

[0019] Figure 2 This is a partial structural diagram of the combination of the base frame, cleaning bucket, partition plate, rotating rod, connecting cylinder and protective bucket of the cleaning device for processing protective diamond coated tools disclosed in the present invention.

[0020] Figure 3 This is a partial structural diagram of the combined cleaning bucket, rotating rod, connecting cylinder, protective bucket, sleeve and rotating system of the cleaning device for processing protective diamond coated tools disclosed in this invention;

[0021] Figure 4 This is a partial structural diagram of the cleaning device for processing protective diamond-coated cutting tools disclosed in the present invention, which includes a cleaning bucket, a partition, a fourth electric push rod, a rotating block, and a lever.

[0022] Figure 5 This is a partial structural diagram of the cleaning bucket, third electric push rod, connecting block and connecting rod of the cleaning device for processing protective diamond coated tools disclosed in the present invention.

[0023] Figure 6 This is a partial structural diagram of the combination of the third electric push rod, connecting block, connecting rod, brush, second motor, rope, and spring rod disclosed in the cleaning device for processing protective diamond-coated tools of the present invention.

[0024] The markings in the attached diagram are: 1-base frame, 2-blade body, 3-conveyor pipe, 101-cleaning bucket, 102-partition plate, 103-first electric push rod, 104-push ring, 105-second electric push rod, 106-fixed plate, 107-first motor, 108-rotating rod, 109-connecting cylinder, 1010-protective bucket, 1011-sleeve, 1012-nozzle, 1013-discharge pipe, 1014-third electric push rod, 1015-connecting block, 101 6-Connecting rod, 1017-Brush bristles, 1018-Second motor, 1019-Rope, 1020-Spring rod, 1021-Fourth electric push rod, 1022-Rotating block, 1023-Toggle lever, 1024-DD motor, 1025-Spray nozzle, 201-Third motor, 202-Gear disc, 203-Gear, 101a-Soaking area, 101b-Brush cleaning area, 101c-High-pressure rinsing area, 101d-Drying area, 1016a-Round hole. Detailed Implementation

[0025] The following description is only a preferred embodiment of the present invention and does not limit the scope of protection of the present invention.

[0026] Example 1

[0027] A cleaning device for machining protective diamond-coated tools, such as Figure 1-6 As shown, it includes a base frame 1;

[0028] It also includes a conveying pipe 3, a cleaning bucket 101, a partition 102, a first electric push rod 103, a push ring 104, a second electric push rod 105, a fixing plate 106, a first motor 107, a rotating rod 108, a connecting cylinder 109, a protective bucket 1010, a sleeve 1011, a spray washing assembly, and a brush assembly; the base frame 1 is fixedly connected to the cleaning bucket 101; the cleaning bucket 101 is slidably connected to four partitions 102; all the partitions 102 divide the cleaning bucket 101 into four areas: a soaking area 101a, a brush cleaning area 101b, a high-pressure rinsing area 101c, and a drying area 101d; a drying device is installed in the drying area 101d; the base frame 1 is bolted to the first electric push rod 103; the telescopic end of the first electric push rod 103 is fixedly connected to the push ring 104, and the push ring 104 is connected to the partition. 102 is fixedly connected; the base frame 1 is bolted to two second electric push rods 105; the telescopic ends of all the second electric push rods 105 are fixedly connected to a fixing plate 106; the fixing plate 106 is bolted to a first motor 107; the output shaft of the first motor 107 is fixedly connected to a rotating rod 108; the rotating rod 108 is fixedly connected to a connecting cylinder 109; the connecting cylinder 109 is fixedly connected to a protective bucket 1010, and the protective bucket 1010 is in contact with the cleaning bucket 101; the protective bucket 1010 is fixedly connected to a conveying pipe 3, and the conveying pipe 3 is connected to the soaking zone 101a; the rotating rod 108 is fixedly connected to several sleeves 1011, and the sleeves 1011 correspond to the four areas of the cleaning bucket 101; a spray washing assembly is connected inside the high-pressure rinsing zone 101c; a brush assembly is connected inside the brush cleaning zone 101b.

[0029] The brush assembly includes a third electric push rod 1014, a connecting block 1015, a connecting rod 1016, and brush bristles 1017; the cleaning bucket 101 is bolted to the third electric push rod 1014; the telescopic end of the third electric push rod 1014 is hinged to the connecting block 1015, and the connecting block 1015 is rotatably connected to the cleaning bucket 101; the connecting block 1015 is connected to the connecting rod 1016; and the connecting rod 1016 is fixedly connected to several brush bristles 1017.

[0030] The spray washing assembly includes a nozzle 1012, a discharge pipe 1013, a DD motor 1024, and a spray nozzle 1025; the nozzle 1012 is fixedly connected to the high-pressure washing zone 101c; the discharge pipe 1013 is fixedly connected to the high-pressure washing zone 101c; the cleaning bucket 101 is bolted to the DD motor 1024, and the output end of the DD motor 1024 is fixedly connected to the nozzle 1012; the nozzle 1012 is connected to the spray nozzle 1025.

[0031] The nozzle 1025 is curved.

[0032] It also includes a second motor 1018, a rope 1019 and a spring rod 1020; the second motor 1018 is bolted to the connecting block 1015; the output shaft of the second motor 1018 is wound with the rope 1019, and the rope 1019 is fixedly connected to the connecting rod 1016; the connecting rod 1016 is slidably connected to the connecting block 1015.

[0033] The connecting rod 1016 is hollow; each connecting rod 1016 has several round holes 1016a.

[0034] It also includes a fourth electric push rod 1021, a rotating block 1022, and a lever 1023; the fourth electric push rod 1021 is bolted to the outer side of the soaking zone 101a; the rotating block 1022 is hinged to the telescopic end of the fourth electric push rod 1021, and the rotating block 1022 is rotatably connected to the cleaning tank 101; a number of levers 1023 are fixedly connected to the rotating block 1022.

[0035] An ultrasonic generator is installed inside the lever 1023.

[0036] The bristles 1017 and the round holes 1016a are interspersed.

[0037] In use, first connect the external pump to the nozzle 1012 and the delivery pipe 3, and connect the external liquid pump to the connecting rod 1016. Then, control the second electric push rod 105 to make the fixing plate 106 drive the first motor 107 and the rotating rod 108 and their connected components to move upward. The connecting cylinder 109 drives the sleeve 1011 and the protective bucket 1010 to move upward, so that the protective bucket 1010 and the cleaning bucket 101 separate. Then, manually insert the knife body 2 to be cleaned into the sleeve 1011 located in the soaking area 101a for fixation. Then, control the second electric push rod 105 to make the first motor 107 and the rotating rod 108 and their connected components to move upward. The fixed plate 106 drives the first motor 107 and the rotating rod 108 and their connected components to move downwards. The connecting cylinder 109 drives the tool body 2, the sleeve 1011 and the protective bucket 1010 to move downwards until the tool body 2 is located in the soaking zone 101a. The protective bucket 1010 and the cleaning bucket 101 come into contact. Then, the external pump is started and organic solvent is delivered to the soaking zone 101a through the delivery pipe 3. The level of the organic solvent is equal to three-quarters of the height of the cleaning bucket 101. Thus, the organic solvent soaks the tool body 2 and dissolves the oil and impurities on the tool body 2.

[0038] During soaking, the fourth electric push rod 1021 is controlled to cause the rotating block 1022 to drive the lever 1023 to rotate up and down. As a result, the lever 1023 moves the organic solvent in the soaking zone 101a back and forth, which improves the contact efficiency of the organic solvent with the tool body 2 and improves the leaching effect. At the same time, since the lever 1023 is equipped with an ultrasonic generator, the ultrasonic generator can make the lever 1023 vibrate the organic solvent in the soaking zone 101a at high frequency, which improves the dissolution rate of the organic solvent on the oil stains and improves the soaking efficiency.

[0039] After soaking, the second electric push rod 105 is controlled to move the fixed plate 106, the first motor 107, the rotating rod 108, and their connected components upwards. The connecting cylinder 109 moves the cutter body 2, the sleeve 1011, and the protective bucket 1010 upwards, separating the protective bucket 1010 from the cleaning bucket 101. Then, the first motor 107 is started, and the output shaft of the first motor 107 causes the rotating rod 108, the connecting cylinder 109, the protective bucket 1010, the sleeve 1011, and the cutter body 2 to rotate 90 degrees clockwise from top to bottom until the cutter body... 2 is located above the brush cleaning area 101b. Then, the second electric push rod 105 is controlled to cause the fixed plate 106 to drive the first motor 107 and the rotating rod 108 and their connected components to move down. The connecting cylinder 109 drives the tool body 2, the sleeve 1011 and the protective bucket 1010 to move down until the tool body 2 passes through the two connecting rods 1016 and is located in the brush cleaning area 101b. The protective bucket 1010 and the cleaning bucket 101 are in contact. Then, the external pump is controlled to start and spray organic solvent into the tool body 2 in the brush cleaning area 101b through the delivery pipe 3.

[0040] Simultaneously, the third electric push rod 1014 is controlled to cause the connecting block 1015 to drive the connecting rod 1016 and the brush bristles 1017 to reciprocate up and down, thereby brushing the tool body 2 with the brush bristles 1017 to remove dirt from the tool body 2. During brushing, the external liquid pump is started to deliver cleaning fluid into the connecting rod 1016. The cleaning fluid is sprayed from the round hole 1016a onto the tool body 2. Because the brush bristles 1017 and the round hole 1016a are staggered, the cleaning fluid sprayed from the round hole 1016a can also rinse away the dirt remaining on the brush bristles 1017, making it easier for the next use. Since the upper side of the tool body 2 is usually less worn and sharper, while the lower side of the tool body 2 is more worn and has more dirt, the second motor 1018 is controlled. Upon startup, when the bristles 1017 contact the lower side of the blade body 2, the output shaft of the second motor 1018 winds up the rope 1019. The rope 1019 pulls the two connecting rods 1016 closer together towards the center, compressing the spring rod 1020. This allows the bristles 1017 to contact the lower side of the blade body 2 more, improving cleaning efficiency. When the bristles 1017 contact the lower side of the blade body 2, the output shaft of the second motor 1018 releases the rope 1019. Under the elastic force of the spring rod 1020, the two connecting rods 1016 move to the sides and away from each other, reducing the contact between the bristles 1017 and the upper end of the blade body 2, thus preventing the bristles 1017 from damaging the sharper blade on the upper side of the blade body 2.

[0041] After the brush cleaning is completed, the second electric push rod 105 is controlled to move the fixed plate 106, the first motor 107, the rotating rod 108, and their connected components upwards. The connecting cylinder 109 moves the cutter body 2, the sleeve 1011, and the protective bucket 1010 upwards, separating the protective bucket 1010 from the cleaning bucket 101. Then, the first motor 107 is started, and the output shaft of the first motor 107 causes the rotating rod 108, the connecting cylinder 109, the protective bucket 1010, the sleeve 1011, and the cutter body 2 to rotate 90 degrees clockwise from top to bottom until the cutter body 2 is above the high-pressure rinsing zone 101c. Next, the second electric push rod 105 is controlled to move the fixed plate 106, the first motor 107, the rotating rod 108, and their connected components downwards. The connecting cylinder 109 moves the cutter body 2, the sleeve 1011, and the protective bucket 1010 downwards until the cutter body 2 is inside the high-pressure rinsing zone 101c. When the protective bucket 1010 comes into contact with the cleaning bucket 101, the external pump is started, and the organic solvent is delivered to the nozzle 1025 through the nozzle 1012. The nozzle 1025 sprays the organic solvent into the tool body 2 in the high-pressure rinsing zone 101c, thereby rinsing the tool body 2 under high pressure. During rinsing, the DD motor 1024 is controlled to make the nozzle 1012 drive the nozzle 1025 to rotate. So that when the protective bucket 1010 rotates 90 degrees to reach the high-pressure rinsing zone 101c, the organic solvent sprayed by the nozzle 1025 disperses in all directions, thereby rinsing the lower side of the protective bucket 1010 and washing away the dirt remaining in the lower side of the protective bucket 1010, so as to avoid the dirt from contaminating the next tool body 2. The washed organic solvent wastewater flows away from the discharge pipe 1013. Since the nozzle 1025 is curved, the spray pipe 1025 collects the washed dirt into the discharge pipe 1013 when it rotates, thereby improving efficiency.

[0042] After high-pressure cleaning is completed, the second electric push rod 105 is controlled to cause the fixed plate 106 to drive the first motor 107 and the rotating rod 108 and their connected components to move upward. The connecting cylinder 109 drives the tool body 2, the sleeve 1011 and the protective bucket 1010 to move upward, so that the protective bucket 1010 and the cleaning bucket 101 separate. Then, the first motor 107 is started, and the output shaft of the first motor 107 causes the rotating rod 108, the connecting cylinder 109, the protective bucket 1010, the sleeve 1011 and the tool body 2 to rotate 90 degrees clockwise from top to bottom until the tool body... 2 is located above the drying zone 101d. The drying device is controlled to dry the tool body 2, so that the tool body 2 is dried in the drying zone 101d. After the tool body 2 is dried, the second electric push rod 105 is controlled to make the fixing plate 106 drive the first motor 107 and the rotating rod 108 and their connected components to move upward. The connecting cylinder 109 drives the tool body 2, the sleeve 1011 and the protective bucket 1010 to move upward, so that the protective bucket 1010 and the cleaning bucket 101 are separated. The tool body 2 is then manually removed from the sleeve 1011 to complete the cleaning and drying process.

[0043] After cleaning and drying, the first electric push rod 103 and push ring 104 are controlled to move the partition 102 downward until the upper side of the partition 102 is flush with the lower side of the inner side of the cleaning tank 101. The partition 102 and the cleaning tank 101 move relative to each other, and the cleaning tank 101 scrapes off the dirt from the partition 102. After the partition 102 descends, the organic solvent in the soaking area 101a can flow to each area of ​​the cleaning tank 101, thereby soaking and cleaning each area of ​​the cleaning tank 101. The organic solvent after soaking and cleaning finally flows away from the discharge pipe 1013, preventing the dirt adhering to the inner wall of the cleaning tank 101 from contaminating the next tool body 2.

[0044] Example 2

[0045] Based on Example 1, such as Figure 3 As shown, it also includes a rotating system; the rotating system includes a third motor 201, a gear disk 202 and a gear 203; the connecting sleeve 109 is bolted to the third motor 201; the output shaft of the third motor 201 is fixedly connected to the gear disk 202; the sleeve 1011 is fixedly connected to the gear 203, and the gear 203 meshes with the gear disk 202; the sleeve 1011 is rotatably connected to the rotating rod 108.

[0046] When the tool body 2 is being cleaned and dried in the cleaning bucket 101, the third motor 201 is started. The output shaft of the third motor 201 drives the gear 202 to rotate. The gear 202 drives the gear 203, the sleeve 1011 and the tool body 2 to rotate, so that the tool body 2 rotates during cleaning and drying, thereby improving the cleaning and drying efficiency.

[0047] After the first blade body 2 has finished soaking and moved upward, the connecting cylinder 109 is rotated 90 degrees so that the first blade body 2 is above the brush cleaning area 101b. Then, the second blade body 2 is inserted into the sleeve 1011, which is now above the soaking area 101a. As a result, the first blade body 2 moves downward into the brush cleaning area 101b, and the second blade body 2 follows and moves downward into the soaking area 101a for soaking.

[0048] After the first blade body 2 is brushed, the connecting cylinder 109 is moved upward and rotated 90 degrees again, so that the first blade body 2 is above the high-pressure rinsing zone 101c. At this time, the second blade body 2 is above the brush cleaning zone 101b. Then, the third blade body 2 is inserted into the sleeve 1011 above the soaking zone 101a. Thus, after the first blade body 2 moves down into the high-pressure rinsing zone 101c, the third blade body 2 follows and moves down into the soaking zone 101a for soaking.

[0049] After the first cutter body 2 is high-pressure rinsed, the connecting cylinder 109 is moved upward and then rotated 90 degrees, so that the first cutter body 2 is above the drying zone 101d. Then, the fourth cutter body 2 is inserted into the sleeve 1011 above the soaking zone 101a. As a result, the first cutter body 2 moves downward into the drying zone 101d, and the fourth cutter body 2 follows, moving downward into the soaking zone 101a for soaking. When the first cutter body 2 is high-pressure rinsed, the connecting cylinder 109 is moved upward and then rotated 90 degrees. At this time, the first cutter body 2 is cleaned and is above the soaking zone 101a. The cleaned cutter body 2 is removed and a new cutter body 2 is installed. This cycle is formed to improve cleaning efficiency.

[0050] The above description is merely an embodiment of the present invention and does not limit the patent scope of the present invention. Any equivalent structural or procedural transformations made based on the content of the present invention specification, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of the present invention.

Claims

1. A cleaning device for machining protective diamond-coated tools, comprising a base frame (1); characterized in that: It also includes a conveying pipe (3), a cleaning bucket (101), a partition (102), a first electric push rod (103), a push ring (104), a second electric push rod (105), a fixing plate (106), a first motor (107), a rotating rod (108), a connecting cylinder (109), a protective bucket (1010), a sleeve (1011), a spray washing assembly, and a brush assembly; the base frame (1) is fixedly connected to the cleaning bucket (101); the cleaning bucket (101) is slidably connected Four partitions (102) are connected; all the partitions (102) divide the washing tank (101) into four areas: soaking area (101a), brush cleaning area (101b), high-pressure rinsing area (101c), and drying area (101d); a drying device is installed in the drying area (101d); a first electric push rod (103) is fixedly connected to the base frame (1); a push ring (104) is fixedly connected to the telescopic end of the first electric push rod (103), and the push ring (104) The base frame (1) is fixedly connected to the partition plate (102); several second electric push rods (105) are fixedly connected to the base frame (1); the telescopic ends of all the second electric push rods (105) are fixedly connected to a fixed plate (106); the fixed plate (106) is fixedly connected to the first motor (107); the output shaft of the first motor (107) is fixedly connected to the rotating rod (108); the rotating rod (108) is fixedly connected to the connecting cylinder (109); the connecting cylinder (109) is fixedly connected to the protective bucket (1010). The protective bucket (1010) and the cleaning bucket (101) are in contact with each other; the protective bucket (1010) is fixedly connected to the conveying pipe (3), and the conveying pipe (3) is connected to the soaking area (101a); the rotating rod (108) is fixedly connected to several sleeves (1011), and the sleeves (1011) correspond to the four areas of the cleaning bucket (101); the high-pressure rinsing area (101c) is connected to the spray washing assembly; the brush cleaning area (101b) is connected to the brush assembly; The spray washing assembly includes a nozzle (1012), a discharge pipe (1013), a DD motor (1024), and a spray nozzle (1025); the nozzle (1012) is fixedly connected to the high-pressure rinsing zone (101c); the discharge pipe (1013) is fixedly connected to the high-pressure rinsing zone (101c); the DD motor (1024) is fixedly connected to the cleaning tank (101), and the output end of the DD motor (1024) is fixedly connected to the nozzle (1012); the nozzle (1012) is connected to the spray nozzle (1025). After cleaning and drying, control the partition (102) to move until it is flush with the lower side of the cleaning tank (101). During this process, the partition (102) and the cleaning tank (101) will move relative to each other. The cleaning tank (101) will scrape off the dirt from the partition (102). After the partition (102) descends, the organic solvent in the soaking zone (101a) will flow to each area of ​​the cleaning tank (101) for soaking and cleaning. When the first motor (107) and the second electric push rod (105) work together to move the protective bucket (1010) to the high-pressure flushing zone (101c), the organic solvent sprayed from the nozzle (1025) disperses in all directions, thereby flushing the lower side inside the protective bucket (1010).

2. The cleaning device for machining protective diamond-coated tools according to claim 1, characterized in that, The brush assembly includes a third electric push rod (1014), a connecting block (1015), a connecting rod (1016), and brush bristles (1017); the third electric push rod (101) is fixedly connected to the cleaning bucket (101); the telescopic end of the third electric push rod (1014) is movably connected to the connecting block (1015), and the connecting block (1015) is rotatably connected to the cleaning bucket (101); the connecting block (1015) is connected to the connecting rod (1016); the connecting rod (1016) is fixedly connected to several brush bristles (1017).

3. The cleaning device for machining protective diamond-coated tools according to claim 1, characterized in that, The nozzle (1025) is curved.

4. The cleaning device for machining protective diamond-coated tools according to claim 2, characterized in that, It also includes a second motor (1018), a rope (1019) and a spring rod (1020); the second motor (1018) is fixedly connected to the connecting block (1015); the output shaft of the second motor (1018) is wound with the rope (1019), and the rope (1019) is fixedly connected to the connecting rod (1016); the connecting rod (1016) is slidably connected to the connecting block (1015).

5. A cleaning device for machining protective diamond-coated tools according to claim 2, characterized in that, The connecting rod (1016) is hollow; each connecting rod (1016) has several round holes (1016a).

6. A cleaning device for machining protective diamond-coated tools according to claim 1, characterized in that, It also includes a fourth electric push rod (1021), a rotating block (1022) and a lever (1023); the fourth electric push rod (1021) is fixedly connected to the outside of the soaking area (101a); the rotating block (1022) is movably connected to the telescopic end of the fourth electric push rod (1021), and the rotating block (1022) is rotatably connected to the cleaning bucket (101); the rotating block (1022) is fixedly connected to several levers (1023).

7. A cleaning device for machining protective diamond-coated tools according to claim 6, characterized in that, An ultrasonic generator is installed inside the lever (1023).

8. A cleaning device for machining protective diamond-coated tools according to claim 5, characterized in that, The bristles (1017) and round holes (1016a) are interspersed.

9. A cleaning device for machining protective diamond-coated tools according to claim 1, characterized in that, It also includes a rotating system; the rotating system includes a third motor (201), a gear disk (202) and a gear (203); the connecting sleeve (109) is fixedly connected to the third motor (201); the output shaft of the third motor (201) is fixedly connected to the gear disk (202); the sleeve (1011) is fixedly connected to the gear (203), and the gear (203) meshes with the gear disk (202); the sleeve (1011) is rotatably connected to the rotating rod (108).